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Permit 82-19-CUP - GENERAL ELECTRIC - SATELLITE ANTENNA CONDITIONAL USE
82-19-cup 401 tukwila parkway ge earth satellite antenna ;7908 ' 4, City of Tukwila 6200 Southcenter Boulevard November 22, 1982 Dear Mr. Way: CVB /blk attachment Tukwila Washington 98188 Gary L. VanDusen, Mayor Mr. Gerald Way, Project Manager General Electric Co. 401 Tukwila Parkway Tukwila, WA 98188 Re: Satellite (Dish) Antenna System At the regular Tukwila Planning Commission meeting November 18, 1982, the Planning Commission approved your application for conditional use of an earth satellite communication antenna and equipment facility as depicted on Exhibits B,C, and D of the application and subject to the following conditions: ) Perimeter landscaping shall be installed prior to final inspection of the facility, subject to staff approval. 2) Control of any emitted radiation of any measureable frequency or wave- length shall be maintained within safe limits as established for this type of facility. 3) Emergency power 'equipment, such as a gasoline- powered generator, shall be installed in an enclosed structure so as to control noise propagation. . 4) The conditional use permit is issued for the benefit of General Electric Company or its corporate subsidiaries and is not transferrable. The Planning Commission shall reserve the right to review the conditional use permit on an anni1 basis to assure compliance with the terms thereof. 5) Building structure be compatible with the surrounding buildings' structure. During discussion of your application'for a conditional use permit, it was suggested that the project be reviewed by Andover Architectural Control for building design and landscaping, in accord with the property's convenant.. If you have any questions regarding this matter, please call me at 433 -1849. Sincerely, Caroline V. Berry Assistant Planner PLANNING COMMISSION STAFF REPORT AGENDA ITEM • 82 -19 -CUP G.E. Co. Earth Satellite Antenna INTRODUCTION 41,1 The General Electric is requesting , approval of a conditional use permit to 1 1,. 72 - � install an exterior, ground -Rased dish ■ 1 antenna and freestanding equipment room on vacant land at the sourtherly edge of their existing warehouse site at 401 Tukwila Parkway. The antenna is to become part of the company's orbital satellite voice -grade international network telephone system. Exhibit "A" depicts the proposed "" r--_� communication system in conceptual form. , ^�� ��j FINDINGS -4., , 1 c -v L C4. �t G- H - =_o \� Om � ! ( o f 1) The proposed communication satellite - >> `` I c � �\,� .;: ui ment complex will be - ` °' ' �J — "` ` antenna and a q P P F-i-94 ' I (i 1I 62 I..'.. located on vacant property immediately - * � � , j DM west of the existing G.E. Company ,'� a '� � • co _ ^. t • �k }t i 7 r V baseball field. The City's recreation i1; is �' ;: ;! J ;; n r•, ( director has determined that the + 1' � �' c ,� !) c« I i�, �! avoid .physical encroachment on the . • --� . i c..z } baseball play -area. CITY OF TUKWILA PLANNING DIVISION CNovember 18, 1982 2) The proposed site is zoned C -M (Industrial Park); the satellite antenna system falls under the general conditional use permit requirement of TMC Section 18.64.020(1). 3) Maximum height of the proposed antenna is 31 feet; the equipment room is of single -floor design. As the basic structural height limitation in this geographic area is 115' per TMC 18.50.030, the proposed project is consistent with zoning contraints. 4) Minimum setback standards for the C -M zone have been far exceeded in the project description. 5) A Declaration of Non - significance under provisions of the State Environmental Policy Act has been granted by the responsible official for this project. 6) The antenna perimeter will be enclosed with a chain -link fence and security lighting will be provided per police department specifications. Page -2- Planning Commission 82 -19 -CUP G.E. Co. EaLLh Satellite Attenna November 18, 1982 CONCLUSIONS TMC Section 18.64.050 specified the criteria to be used by the Planning Commission in deciding to grant a conditional use permit; our response to each criteria is as follows: ' (T The proposed use will not be materially detrimental to the public welfare or injurious to the property or improvements in the vicinity of the proposed use or in the district in which the subject property is situated; Response: The proposed equipment will be placed in a remote area of the G.E. site and will have minimal apparent exposure to the public at large due to its distance from public thoroughfares. Unresolved topic of concern to staff is the potential health hazard which the antenna system presents,if any,from emission of radio - frequency and electromagnetic radiation. We are concerned particularly with affects of proximity and exposure to the system by persons using the adjacent recreation field. It is expected that the applicants will be prepared to demonstrate the radiation safety of this system at the Public Hearing. (2) The proposed use shall meet or exceed the performance standards that are required in the district it will occupy; Response: The proposed project is generally consistent with the established light - industrial use characteristics of the Andover Industrial Park area. (3) The proposed development shall be compatible generally with the surrounding land uses in terms of traffic and pedestrian circulation, building and site design; • Response: The proposed communications center is unmanned except during periods of maintenance activity and will have no impact on traffic circulation. Although the equipment is situated some distance away from a public travel -way, we suggest that the appearance of the chain -link enclosure and the non - descript equipment building would be enhanced by perimeter landscape. (4) The proposed use shall be in keeping with the goals and policies of the comprehensive .:land use policy plan; Response: While the comprehensive plan is largely silent on the matter of siting communication equipment, it does allude to the wisdom of encouraging uses which are supportive to existing industrial activities. With adequate protection of its surroundings from any hazardous radiation emission, the project should be viewed as consistent with the comprehensive plan. Page -3- Planning Commission 82 -19 =CUP G.E. Co, Ea.th_Satellite Attenna • November 18, 1982 (5) A ZZ measures have been taken to minimize the possible adverse impacts which the proposed use may have on the area in which it is located. Response: The following steps have been, or will be taken, to insure that the proposed communications system will intergrate successfully . with its surroundings: RECOMMENDATION Staff recommends approval of application 82 -19 -CUP for installation and use of an earth satellite communication antenna and equipment facility as depicted on Exhibits B, C, and D and subject to the following conditions: 1) Perimeter landscaping shall be installed prior to final inspection of the facility, subject to staff approval. 2) Control of any emitted radiation of any measureable frequency or wavelength shall be maintained within safe limits as established for this type of facility. . MC /blk 1) Provisions of approved security fencing and lighting. 2) Adequate separation to prevent interference with on -going use of the adjoining baseball field. 3) Significant separation of the facility from public travelways. 4) Control of R.F. or electromagnetic radiation within accepted safety limits. 5) Undergrounding of power and transmission cable linkages. 3) Emergency power equipment, such as a.gasoline- powered generator, shall be installed in an enclosed structure so as to control noise propagation. 4) The conditional use permit is issued for the benefit of General Electric* Company.'.or its corporate subsidiaries and is not transferrable. The Planning Commission shall reserve the right to review the conditional use permit on an .annual basis to Assure compliance with the terms thereof. 1 Each Network Access Center (NAC) communicates through an SBS satellite positioned in geosynchronous orbit. The radio frequency terminal (RFT) consists of a rooftop or ground mounted antenna, its frame or foundation, and the RE electronic equipment shelter. The intraNAC facility link (IFL) connects the RFT to the SBS equipment room. The SBS equipment room contains telecommunications switching equipment, transmission equipment, and terminal connection blocks for the NAC. The demarc /modem room contains terminal blocks connecting customer facilities or facilities provided by other common carriers to the NAC. PLANNING DEPT EXHIBIT A M F SZ - 19 GuP t SBS Network Access Center Components Figure 1 -1 2 c SATELLITE BUSINESS SYSTEMS Latitude 47 °27'36" Longitude 122 °15'03" NEARFIELD OBSTRUCTION DATA 2 HMAX 0 s e tl s h s ❑ Roof Mount GRADE ROOF Ground Elev. Roof Elev. Height Load Frame Height Top Antenna Elev. Top of Antenna ANTENNA 7.6 METER NEC OVERALL HEIGHT OF ANTENNA AT ANGLE 0 ELEVATION OF ANTENNA AT GIVEN SATELLITE POSITION (1001 VERTICAL DISTANCE FROM ROOF TO TOP OF LOADFRAME HORIZONTAL DISTANCE FROM ANTENNA PIVOT AXIS TO ANY VERTICAL OBSTRUCTION OVERALL HEIGHT OF OBSTRUCTION FROM TOP OF LOADFRAME OR TOP OF CONCRETE FOUNDATION N Azimuth FOR 100° SAT. 150 °57'28" W Elevation Angle 8 31°18'44" ELEVATION (AMSL) UI4 EX Ground Mount 25'• Location SEATTLE. WA. 2 0 O Ground Elev. Concrete Pad Elev. 1 • Height Top Antenna 31 .19' Elev. Top of Antenna 57.19' Customer GENERAL ELECTRIC COMPANY LU -.• f• -. • • V ' G 5555.. - -. t• ... f1- Z.. e1 I MI MI u Z ✓ 4 1• ti l..• a% •!fit L-a. at • L :1.1 • a i,t• t.1 : � NOTES J}\ F.177— •' cD.G7n•aor :.•• 1 • ..• 1 . /+ e••cluslto Jrt•. �e4• . b .15 :A:II• n. • /. aJ « Sa 7P 1• :s•f• .... I • eL. �M a•T .4 € e.. 21 • a. /v. to.. •• l.1 •.:L•1 � co.x..e_D or... &MI •••1Je7. owl. ••v MV•.a _•Y. 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NIN060 SMALL WATT. ►00517. LEVI 1 •PIt'M0•T INO IN C2011117 CAIN. • • .T00 NYNII.INDIC.TIS tit Teal. 1113N01q' .0345. NONO151M0• r•5 /lq I • i s •d •••• t•.t. 01•1010555 TO SA UM.. weer •0• M 4•10. r& W2 »10+10.00 113000,6/1• 1) 1- • ■•••• •••• I•..•••••• 10 00 t'tt.Ow 1a ••<•••. IA A•••■T12 [00•111't - 00 5 •■• taw, .VOW. PLANNING DEPT R. • RAILROAD SPUR EXHIBIT M.F. 61.' (9" GUI! SO r•grev• _T _ I •..• r• .4. I 1 /Ih 4t... t CCvCD11 ovu.t -12 CTO.* • 0J.O -0 •11•• - V•.D.. 6 0..•WU A at Vtway. 391L ?1C- C9 ® - 4 5 4_1 1;.. 1•. 4.'. 2.40 •••• •••• • 5 . .4 1 : 1 a. 4 1' w e • 1116 -w ttT 11 11••• ••••••• fw•4a: 1..w t T � ••t,•n 2•• 0•_00V111. 11.144111171313 55 9 . . ee l_Y 92%4. R5.-A' I.::),IG Wo' >h' 1'1.:- v 51..3••• C 7 1itTeT'A -t i ' - DETAIL or CUR!. 3141 TO STRUT • SCAtI •1•1' • 317E PLAID •• .•••..1.••1••A•..•'. /..••r.. - - GAT. Si. .10 •...1,. • . 5..5.420. J,w !0444 N. 1t •04 lI N O•■• vv ...TA •. 1 05.•55. -••. •••.• t••■••• .. ht.-... • a•• •■ 4`.&.6•62 3 •0• W •.00.4..5 4 .0•• 151.1 _0.6 •• 1••• •• 40.0• I•• f 1.J. ...) •■••. 4.+2• •' 1••t• G .5 • • . --w -.• p•••_O.t. 5 Mari ••0050 'I AS BUILT DRAWINGS DA _JuNE 2s I,:x OPAIC• AND WAR•!-IOUSS BUILDING G EN IERAI. ELECTRIC •COMPANY TY•.WI.4 W■1•3 I BINDON AND WRIGHT. ARCHITECTS Al 340 34011044 111611.011111 • • • 1{46116 W/I1MINOTON i • • 0.•0 Al 441 VQti • TO APPROX LOCAT. OF TELCO ENTRANCE FACILITIES 2 V . - • EXISTING GE FACILITY POWER CONVEYANCEr—'d. . 1 I • . . • 1 t • r 1. ■ • 111S'.0' N.T.S. . . • GENERAL NOTES 1. !FL LENGTH - AN7-o 2. IFL COMPOSITION A. 6-1/4* COAXIAL CASLES tO lb;/100' CAN B.. 1•18 PAR CABLE INC lbs/100' C. I-11 PAIR CABLE 117 1111/100' 3. IFL CONVEYANCE A. UTERI- BURIED COMM • EXPOSED FLEXIBLE SEAL TIER CONDUIT r I. mono - wpm also, float . C. PtA.L NOTES (li N(EDED) - ANGLE 801ES • 24•124"XII• • STRAIGHT IDIES • 2411218' • 4. MINIkiN BENDING RADIUS • 74* ' _ RiCIL tovielk • '- 1 r3' f •OOYC• 105.0 _ 21'•0' MTS - -- TACO cowv[YA m= PROPOSED SBS EOUIPVEpT . ..ROOM,; OWE $TA O$NO • pac inE[NED N1NLDN0) MTTOET nOeM 45 - • • Mopf*Tr LINE •41r•04-w)E5111.e4 X • 35.0 • Anurw COOIEYMIM 47.77.115. N. Lac 1 22'15'03' W. Lana. • =Silo Number MS 1578 IV NE -SERIES. DES MOINES Meg 0., 21 1/2• E 118 tr.rr K..... T0• W. Long. 9Z' W. Long. Sr w. Long. 100• W. Lang. 108 Long. Pedestal Aj*YWIN Tar mem Awl Vows* ..Er 1 19 .1 2' 11• 16 111•38'15• 28'03'51' 147•22•3r 30 150.57'28• 31•18'U 160.58 33•12 136. 12' or SHELTER 4 1 SBS NOTE: ' Tint sin GE SEATTLE,' WA. x • • NEC 7.6 ANTENNA MSEE OW* NO. I50.O04047 . 1 • P1ANN1{�dG DEPT • • • • • RFT AND IFL LAYOUT PLAN • I • 0 Kowa CONVEUNCL AKPa01WATELT •714•4'1' •-•—• MCO CONVITANCA ANNOximnrtr'sow,j tn.A04110 •6447gLT tNr!e: ....• . • SATELLITE BUSINESS SYSTEMS 8283 GREENSBORO DRIVE. McLEAN. VA. 22102 . . I Cron No. 0 16- 05 -00i a • .w BULE t /ati 1'-o' Al SG EO sr. R . 430IaW R (q /,/T O•TE. ♦ 1 hat CONTRACT NO 00011 tOENT. • City of Tukwila Washington 6200 South Center Boulevard Tukwila, Washington 98188 GW /lmb General Electric Information Services Company 401 N. Washington Street, Rockville, Maryland 20850 (301)340.4000 October 15, 1982 SUBJECT PROPERTY: General Electric Company 401 Tukwila Parkway Tukwila (Seattle) WA 98188 To Whom It May Concern: Legal Description of Property: Lot & Block Code 2380 Vol 66, Page 36, King County, Washington "Lot 3, Andover Industrial Park #1, less U.P. Railroad operating right of way ". According to Tukwila City Assessor, this is the legal description of the property. Copy of 1982 Real Estate Tax Statement reflecting text of same description. Cordially, GENERAL ELECTRIC U.S.A. City of Tukwila 6200 Southcenter 8aievard Tukwila Washiigton 98188 MASTER LAND DEVELOPMENT APPLICATION FORM SUPPLEMEN'"RY QUESTIONAIRE edule C CONDITIONAL USE PERMIT APP. PRESENT USE OF LAND OR IN STRUCTURES) : GENERAL ELECTRIC COMPANY WAREHOUSE. LOT OF PROPOSAL IS ADJACENT, VACANT, WEEDED, FLAT, UNIMPROVED. IF THE STRUCTURE IS VACANT, INDICATE WHEN VACANCY BEGAN AND WHAT USE WAS BEFORE VACANCY: ACTIVE BUSINESS OF GENERAL ELECTRIC'S MAJOR APPLIANCE BUSINESS GROUP. DETAIL DESCRIPTION OF PROPOSED USE (For example, discuss manufacturing processes used, wholesale /retail /warehouse functions, outside storage of goods or equip- ment, or other information which will facilitate understanding of.the' activities you propose to develop on this site) INSTALLATION OF DISH ANTENNA ON VACANT OWNED LOT. WILL FACILITATE USE OF SATELLITE FOR GENERAL ELECTRIC COMPANY'S VOICE GRADE INTERNATIONAL NETWORK TELEPHONE SYSTEM. ERATION THE ANTENNA SITE WILL • ' E OPERATE INDEPENDANTLY AND BE UNMANNED EXCEPT FOR EQUIPMENT FAILURE AND MAINTENANCE. SITE USE STATISTICS: NO. OF ROOMS (MOTEL /HOTEL ONLY) ' N/A ❑ N/A MANUFACTURING/WAREHOUSE FLOOR AREA N /A* se ft ❑ N/A OFFICE FLOOR AREA N/A se it Q N/A NO. OF EMPLOYEES ANTICIPATED Unmanned amr1o„Qns ❑ NiA TOTAL ON -SITE PARKING PROVIDED None space ❑ N/A FLOORS OF CONSTRUCTION PROPOSED 1* moors ❑ N/A *Single level structure is proposed 1800 square foot on slab to house communication equipment and support equipment. Control Number MASTER LAND DEVELOPMENT APPLICATION FORM FEES: RCPT. M.F. EPIC. NOTE: Please. write legibly or type all requested information -- incomplete applications will not be accepted for processing. / SECTION I. - GENERAL DATA 1) APPLICANT'S NAME General Electric Co TELEPHONE: 01) 340 - 5801 2) APPLICANT'S ADDRESS 401 N. Washington St ZIP: Rockville, Md. 208 0 3) PROPERTY OWNER'S NAME Gen Elect Co ThJ1pHONE : 214 ) 343 - 5500 4),,.PR6PERTY OWNER'S ADDRESS 401 Tukwila . Pkwy ZIP Tukwila, Wa. 98188 5), LOCATION OF PROJECT: (geographic or legal descrip.) Same as OWNER o AMS 1578 IV NE - SERIES V891 - DES MOINES Mag Dec 211 E TOPOGRAPHIC - DESMOINES QUADRANGLE WASHINGTON -KING CO 47 ° 27'36 "N, 122 ° 15'03 6 W. Vacant owned property at end of treets: EVANS/ 6) NAME OF PRQJECT(OPTIONAL) Satellite (Dish) Antenna System BLACK DR. SECTION II: PROJECT INFORMATION 7) BRIEFLY DESCRIBE THE PROJECT YOU PROPOSE: Dish antenna system on vacant land owned by General Electric Tukwila Parkway, Tukwila, Lot faces Evans Black Drive at rear of bu 8) DO YOU PROPOSE TO DEVELOP THIS PROJECT IN PHASES? OYES 1:11,N° �) PROJECT 'NO CHANGE a. NET ACRES 5.4 b. GROSS ACRES a. NAME: b. NAME: 7.5 Installation of 7.7 .meter uri anned c. PARKING SPACES 93 d. FLOORS OF CONSTRUCTION ADDRESS: ADDRESS: 1 e. LOT AREA COVERAGE BLDG. 8 3 k SQ.FT. LANDSCAPE n/a SQ. FT. PAVING n / a SQ. FT. 10) DOES THE AVERAGE SLOPE OF THE SITE ECCEED 10%? EI YES 1:10 11) E`CISTING ?ONING INDUSTRIAL P' 'EX STING CCtVIP.PLAN 13) IS THIS SITE DESIGNATED FOR SPECIAL CONSIDERATION YES © NO DN THE CITY'S ENVIRONMENTAL BASE MAP? 14) IF YOU WISH TO HAVE COPIES OF CITY CORRESPONDENCE, STAFF REPORTS, OR OTHER DOCUMENTS SENT TO ADDRESSES OTHER THAN APPLICANT OR PROPERTY OWNER, PLEASE INDICATE BELOW. Co 0 E 401 ilding. OVER ► , being duly sworn, declare that I am the contract purc aser • owner of t e property involved in this application and that the foregoing statements and answers herein contained and the information herewith submitted are in all respects true and correct to the best o my knowledge and belief. Subscribed and sworn before me this 19 •th day of (letnhPr , 19 _12 DATE Oct 19 1982 gnature Cont act aser or owner) No ary Public in and f he State onNISPt Maryland. Comm Exp. 7 -1 -86 residing at 5426 Amhprcaood 'lane Rockville, Md 20853 SECTION IV: SUPPORTING MATERIAL REQUIREbEENTS TYPE OF APPLICATION REZONING [IC0NDITIONAL USE [1VARLANCE F7CMIPREHENSIVE PLAN AMENDMENT SHORELINE MGMT . PERMIT SUPPORTING MATERIAL ** SCHEDULE E, 1,2,3,4,5,9 'SCHEDULE C, .2,3,5,9 SCHEDULE F, 3,5,9 SCHEDULE D, 2,3,4,5,9 SCHEDULE B, 2,3,4,5,8 ri WAIVER SCHEDULE A, 3,9,10 S HORT SUBDIVISION 3,4,7 [1SUBDIVISION 2,3,4,5,9 ,12 r1BINDING SITE IMPROVEr1ENT PLAN 2,3,4,6,9 r1ARCHITEC11JPAL REVIEW 9,10 LANDSCAPE REVIEW 11 * *SEE TABLE 1 FOR DESCRIPTION + OPTIONAL AT STAFF'S DIRECTION SATELLITE BUSINESS SYSTEMS SBS COMPLIANCE WITH RADIO- FREQUENCY EMISSION GUIDELINES SATELLITE BUSINESS SYSTEMS 8283 Greensboro Drive McLean, Virginia 22102 12/81 T l (SE3S1 SATELLITE BUSINESS SYSTEMS SBS Compliance With Raido- Frequency Emission Guidelines A. System Characteristics. The SBS earth station employs a 5.5 -meter (approximately 18 -foot) diameter antenna dish which transmits a narrow beam of radio signals to the SBS satellite located 22,300 miles above the equator. These radio signals are transmitted at a frequency of 14 giga- hertz, in the microwave portion of the radio - frequency spectrum. Microwaves, like other radio waves, are non - ionizing. They should not be confused with the ionizing emissions associated with nuclear energy. "Microwave" is a general term referring to any electromagnetic (radio) frequency between 30 million cycles per second (30 mega- hertz) and 300 billion cycles per second (300 gigahertz). The total electromagnetic spectrum includes everything from high energy X -rays, the visible light spectrum, the microwave spectrum and on down to very low frequencies, including the 60 -cycle waves•emitted by household electric wiring. Micro- waves include FM radio, television, and CB transmission signals, as well as radar and numerous other uses. • SATELLITE BUSINESS SYSTEMS The total power transmitted from an SBS earth station antenna under operating conditions is less than 400 ' watts - much less than from a typical commercial broadcasting station. This low -power signal is concentrated by the antenna dish into a highly directional beam carefully focused to reach the SBS satellite. The transmission beam is similar to a spotlight; it is about equal in diameter to the diameter of the dish, and widens gradually as it extends upward. B. Safety Guidelines. The microwave occupational exposure limit currently recommended by the Occupational Safety and Health Administration (OSHA) is a power density of 10 milliwatts per square centimeter, averaged over any six - minute period (one milliwatt is 0.001 watts). The American National Standards Institute (ANSI) has proposed that this level be reduced to 5 milliwatts per square centimeter in the frequency range of 1.5 to 100 gigahertz, which includes the SBS transmission. 'C. Compliance Of SBS System. The power density of the operational signal in the immediate vicinity of an SBS transmitter is well within both existing and proposed U.S. Government standards, even when measured close to the dish SATELLITE BUSINESS SYSTEMS jSBS and directly under the signal beam. The safety of microwave - signal levels at ,SBS earth stations has been demonstrated both by calculation and by actual, repeated measurement. In the early design stages of its system, SBS engineers determined through calculations that the microwave power- density levels surrounding the antenna would be well below the exposure limits set by OSHA and other governmental agencies. The validity of these previously calculated power densities has been confirmed to be several orders of magnitude below the maximum allowable levels, by actual measurement. Following the first installations of SBS earth stations, steps were taken to perform microwave - emission measurements. Since the power- density levels present in the close vicinity of the antenna were below that capable of being measured by present -day radiation - hazard meters such as are used for microwave ovens, broadcast transmitters, and similar devices, the measurements were performed using a calibrated microwave horn and power meter. Participating in the microwave - emission tests was Dr. Peter Polson, a second independent consultant with expertise both in biological science and in engineering. SATELLITE BUSINESS SYSTEMS Dr. Poison was engaged to examine the SBS earth - station characteristics and to draw conclusions as to its safety. He has concluded that the SBS system is safe. A copy of a statement to that effect (which he prepared for, and presented to, the Zoning Board of the City of El Monte, California), together with Dr. Poison's credentials, is attached. PETER POLSON, PH.D. 18985 Tuggle Avenue Cupertino, California 95014 •• (408) 257 -3376 (415) 965 -5682 SPECIALIZED ' Biological effects of nonionizing electromagnetic radiation. PROFESSIONAL • Biomedical engineering - -broad expertise between engineering COMPETENCE and various life sciences disciplines (neurophysiology, cell biology, immunology, developmental psychobiology, respiration physiology, reproductive physiology, ocular science, hyperthermia,• cancer, toxicology, etc.) ACADEMIC B.E. (Elec.)(Honours),1965, University of Adelaide, Australia BACKGROUND B.Sc. (Physiology),1972, University of Adelaide, Australia Ph.D. (Brain Research), 1972, University of Adelaide, Australia Postdoctoral Fellow, 1972, McMaster University, Hamilton, Ontario, Canada • EMPLOYMENT 1980 - present: NASA - -Ames Research Center HISTORY Biosystems Division Moffett Field, CA94035 Technical Manager, Aerospace Technology, Life Sciences Flight Experiments Project Office -- Experiment Manager, Spacelab Life Sciences experiments 1973 -1980: SRI International Menlo Park, CA94025 Senior Biomedical Engineer, Toxicology Laboratory (1978 -1980) Senior Biomedical Engineer, Environmental Physiology Program (1975 -1978) Research Engineer, Electromagnetic Techniques Laboratory (1973 -1975) Representative research assignments at SRI: Development, promotion, and supervision of program of research on biological effects of nonionizing electromagnetic radiation. Specific contracts included the following: • • Assessment of the Biological Effects and Potential Hazards that may be associated with the use of Nonionizing Electro- magnetic Radiation, Office of Telecommunications Policy, Executive Office of the President of the U.S.A.(Project Leader) • Environmental Impact Statement for PAVE PAWS (Air Force) radar installation, Otis Air Force Base, Massachusetts (Task Lea Ier) • Environmental Impact Statement for PAVE PAWS (Air Force) radar installation, Beale Air Force Base, California (Task Leader) . Study of the Biological and Ecological Effects of Energy Transmission by Microwaves (Solar Satellite Power ystm ) , NASA -Ames Research Center (Project Leader) EMPLOYMENT • Effects of microwave radiation on the blood -brain barrier, • HISTORY U.S. Air Force (Co- Project Leader) _ (Continued) • Investigation of Ocular Effects of Chronic Exposure of Primates to Microwave Radiation, U.S. Army Medical Research and Development Command (Project Supervisor) • Neurophysiologic and Social Behavioral Response of Squirrel Monkeys Exposed to Electromagnetic Radiation, U.S. Environ- mental Protection Agency (Co- Project Leader) • Behavioral and Electroencephalographic Responses of Squirrel Monkeys Exposed In Utero to 2450 -MHz Electromagnetic Radiation, U.S. Environmental Protection Agency (Co- Project Leader) • Mortality in Rats Exposed to CW Microwave Radiation at 0.95, 2.45, 4.54, and 7.44 GHz, U.S. Army Mobility Equipment R &D Command (Project Leader) ' Client - Private Contracts -- Conducted research on several classified or client- private contracts on nonionizing electromagnetic radiation effects (Project Leader on each) PUBLICATIONS "An.Analysis of the Electrical Activity of the Mammalian Olfactory System," Ph.D Thesis, University of Adelaide, 1971. "A Microwave Exposure System for Primates," L. Heynick, P. Polson, • and A. Karp, Radio Science,.Vol. 12, No. 6S, pp.103 -110, 1977. "Biological and Behavioral Effects of Pre- and Postnatal Exposure to 2450 -MHz Electromagnetic Radiation in the Squirrel Monkey," J. Kaplan, P. Polson, C. Rebert, and K. Lunan, Radio Science, (In Press). Author or Co- Author of numerous SRI Reports. PROFESSIONAL ASSOCIATIONS 1972 -1973: McMaster University Hamilton, Ontario, Canada Postdoctoral Fellow, Electrical Engineering Department Bioengineering research on application of electromyographic signals 1971 -1972: South Australian Institute of Technology Adelaide, South Australia Lecturer (U.S. equiv.of assistant professor) in digital communications 1965 -1971: University of Adelaide Adelaide, South Australia Postgraduate research student, Departments of Electrical Engineer- ing, and of Human Physiology and Pharmacology. Interdisciplinary research between engineering and physiology Institute of Electrical and Electronics Engineers (IEEE) Member, Committee on Man and Radiation (COMAR) Member, Committee on Energy Member, Technical Program Committee and Session Chairman, 1975 International Microwave Symposium American National Standards Institute (ANSI), Committee C95.4 "Nonionizing Radiation Peak -Power Hazards" International Microwave Power Institute New York Academy of Sciences American Association for the Advancement of Science Bioelectromagnetics Society 2 SUMMARY CONCLUSION SATELLITE BUSINESS SYSTEMS SBS Earth Station Independent Consultant Analysis ISSUE Concern has been expressed during the application process for a Condi- tional Use Permit that the installation of an earth station on the roof of the Wells Fargo Building located in El Monte, California, by Satellite Business Systems (SBS) may cause nearby persons to be exposed to microwave radiation and thereby create a hazard to their health. It is my opinion, based on current scientific evidence and research, that the potential hazards to human health from stray radiofrequency radiation (RFR) in the vicinity of the proposed SBS earth station on the roof of the Wells Fargo Building located in El Monte, California, are negligible. QUALIFICATIONS I am acting as an independent, expert consultant to SBS in responding to concerns expressed by the City of El Monte regarding a Conditional Use Permit application by Wells Fargo. My qualifications are being provided. I have previously acted as an expert consultant to SBS in a similar, successful, application by SBS and Allstate Insurance Company to the Menlo Park (California) Planning Commission for a Use Permit and Architectural Control for an earth terminal installation on the Allstate property in Menlo Park, and in an application before the Planning and Zoning Commission of the City of Los Angeles. 2 DISCUSSION Radiofrequency radiation (RFR), also known as nonionizing electro- magnetic radiation, which is the type of radiation transmitted by the earth station, may be loosely defined as that portion of the electromagnetic spectrum from infrared frequencies down to the extremely low frequency (ELF) band. It includes AM, FM and TV broadcast bands, radar bands, CB communication frequencies, microwave oven frequencies, industrial, scientific and medical (ISM) bands, and so on. Radiofrequency radiation must be carefully distinguished from the potentially biologically harmful ionizing radiation, which (loosely) extends upwards from ultraviolet frequencies, and includes gamma rays and x -rays. The RFR biological effects literature currently comprises, by various estimates, somewhere between 6,000 and 10,000 articles. There is clearly a large amount of information available on known effects, or lack thereof, when RFR interacts with biological tissues. There is also a substantial ongoing research effort by several Federal Government agencies to further define RFR biological effects. While a Senior Research Professional at SRI International, (formerly Stanford • Research Institute), I was involved in five separate projects specifically involved in review, analysis and critique of this RFR biological effects litera- ture. I am presently involved in two additional literature review and analysis projects as a consultant to SRI. There is general agreement that there is no reliable evidence of any biological effect at exposure levels less than approximately 100 microwatts per square centimeter, average power density. 3 Present research interest centers on some effects that are purported to occur under very specialized experimental situations for exposures between 100 and approximately 2,000 microwatts per square centimeter. "There is no evidence that these effects even at these higher levels, if they are truly RFR related, are likely to be hazardous. SBS has provided me with calculations of power densities around an earth station transmitting under normal operating conditions and I have personally witnessed power density measurements in the vicinity of an operating SBS radio frequency terminal. For continuous wave (C\V) operation, the calculated power densities at all distances greater than 10 meters from the center of the dish, and for all angles from boresight greater than approximately 17.5 are always less than 100 microwatts per square centimeter. Under typical planned operating • ... conditions, transmissions is 1 /16th CW operation (1:16 duty cycle). The actual power densities will be orders of magnitude less than 100 microwatts per square centimeter. Further, there is additional rapid decrease of power density as either distance from the antenna increases, or angle from boresight increases. Actual preliminary measurements by SBS personnel of power densities around an operating field site effectively verify the low calculated power densities. CONCLUSION Under all operational conditions that are foreseen, calculations and actual measurements show that potential human exposure will always be considerably less than that known to produce any effects, deleterious or not. 91-tf Peter Poison, Ph.D. loir`,SI Design Criteria for Customer Premise. Earth Station GENERAL ELECTRIC COMPANY MAJOR APPLIANCE BUSINESS GROUP 401 TUKWILA PARKWAY TUKWILA, WASHINGTON 98188 SEPTEMBER 16, 1982 (Date) es SBS FACILITIES DESIGN ENGINEER Robert J. Hartson Tel. (703) 442 - 5236 SATELLITE BUSINESS SYSTEMS 8283 Greensboro Drive McLean, Virginia 22102 SATELLITE BUSINESS SYSTEMS DESIGN CRITERIA CUSTOMER PREMISE EARTH STATION TABLE OF CONTENTS Section Page 1.0 INTRODUCTION 1.1 General 1 1.2 CPES Description 1 1.3 General Customer /SBS Responsibilities 3 1.4 General Design Requirements 5 1.5 Design Criteria 7 2.0 RADIO FREQUENCY TERMINAL (Ground Mount) 2.1 General 8 2.2 RFT Orientation 8 2.3 Structural Criteria 8 2.4 Electrical Criteria 8 2.5 Grounding Criteria 9 2.6 Fencing 9 2.7 Construction Details 9 & 10 3.0 INTRA- FACILITY LINK 3.1 General 11 3.2 Conveyance Design 11 3.3 Special Requirements 13 3.4 Construction Details 13 O sas SATELLITE BUSINESS SYSTEMS Page Section 4.0 NAC EQUIPMENT ROOM 4.1 General 15 4.2 Architectural Criteria 15 4.3 Structural Criteria 16 4.4 Mechanical Criteria 17 4.5 Electrical Criteria - AC System 18 4.6 Electrical Criteria - DC System 20 4.7 Electrical and Signal Grounding 21 4.8 Lightning Protection 21 4.9 Fire Protection and Personal Safety 22 4.10 Construction Details 22 5.0 DEMARCATION /MODEM ROOM /AREA 5.1 General 23 5.2 Architectural Criteria 23 5.3 Mechanical Criteria 24 5.4 Electrical Criteria 24 APPENDICES A List of Abbreviations B Site Unique Data C SBS Standard Drawings & Criteria D RFT Foundation Loads SATELLITE BUSINESS SYSTEMS SATELLITE BUSINESS SYSTEMS 1.1 General DESIGN CRITERIA CUSTOMER PREMISE EARTH STATION SECTION 1.0 INTRODUCTION This document presents technical criteria to assist you and /or your Architect /Engineer (A -E) to design the structures and interfaces required to accept the SBS supplied equipment; and to insure an environment designed for the proper operation of the earth station equipment. This document does not presume to treat any other aspect of equipment and /or construction you may desire that is related to the Customer Premise Earth Station (CPES) installation. This document is intended to be a complete stand alone document providing you with all the data required for the interface design. Please study it carefully and thoroughly. If there is any aspect of which you are unsure or which creates conflict, contact your SBS Facilities Design Engineer, immediately. He will provide clarification and /or resolve the conflict before you start design. Additionally, SBS maintains a Design Quality Assurance team to review the interface design and provide assistance throughout the entire design process. The overall objective of this document is to present an interface design which can be implemented successfully at least cost to you, the customer. Finally, the SBS Facility Design Engineer normally functions as a consultant to you, and does not directly interface with your A -E, unless you so designate. 1.2 CPES Description 1.2.1 A Customer Premise Earth Station (CPES), See Figure 1 -1, consists of: a. Radio Frequency Terminal (RFT) is a complete assembly consisting of a parabolic antenna, a concrete ground foundation or steel roof load frame and a weatherproof electronic equipment shelter. The antenna and equipment shelter are furnished and installed by SBS. The foundation is designed, furnished and installed by the customer. The equipment shelter is a fiberglass enclosure housing the RF equipment. The signal between the antenna and the RF equipment in the shelter is conducted through a connecting wave guide. 1 Each Network Access Center (NAC) communicates through an SBS satellite positioned in geosynchronous orbit. The radio frequency terminal (RFT) consists of a rooftop or ground mounted antenna, its frame or foundation, and the RF electronic equipment shelter. The intraNAC facility link (IFL) connects the RFT to the SBS equipment room. The SBS equipment room contains telecommunications switching equipment, transmission equipment, and terminal connection blocks for the NAC. The demarc/modem room contains terminal blocks connecting customer facilities or facilities provided by other common carriers to the NAC. 2 SBS Network Access Center Components Figure 1.1 SATELLITE BUSINESS SYSTEMS b. The Intra - Facility Link (IFL) is a group of cables joining the RFT with the SBS Equipment Room. The IFL cabling is a single link carrying all of a customer's satellite communications. c. The SBS Equipment Room is space on a customer's premises that houses telecommunications switching equipment and transmission terminal equipment. The physical requirements of the room itself and its principal elements are detailed elsewhere in this document. d. The Demarcation /Modem Room contains terminal blocks for connecting the CPES to the customer's voice, data processing, or teleconferencing equipment and telephone company owned telephone cable. 1.3 General Customer /SBS Responsibilities Specific responsibilities for actions are described in Figure 1 -2 and subsequent sections of this document. In general, the pertinent customer /SBS responsibilities associated with the design, construction and installation of a CPES are divided as follows: 1.3.1 Customer Responsibilities o Secure all required local, county, or state permits, approvals, variances and authorizations associated with the installation, operation and construction of the CPES, including installation of the antenna and shelter(s). SBS will provide a data package for roof mounted antennas that indicates specific details of the antenna and shelter when the information is necessary to obtain permits. o Provide all modification /rehabilitation work on existing utilities, roads, structure, or grounds necessary to accommodate the CPES. o Perform all subsequent site planning, engineering, civil works construction, and installation of security lighting and fencing, parking apron, access road, drainage structures, grading, landscaping, foundations (including designing, furnishing, and installing the antenna foundation and grounding. Provide source of, or tie into electrical power, air conditioning, and fire detection or alarm systems. o Provide aesthetic considerations as desired and /or required by local authorities. 3 CUSTOMERISBS RESPONSIBILITY MATRIX* SURVEYS, AUTHORIZATIONS & LICENSES Perform site survey Secure FCC authorizations, as necessary Secure all other authorizations and licenses, as necessary, Including state & local licenses and authorizations, bldg. permits, & zoning variances Complete FCC Environmental Questionnaire & perform frequency coordination Perform Propagation and Rain Scatter Analysis PLANNING, DESIGN & CONSTRUCTION Field engineering (soil boring /surveys) X Design engineering (A &E design) X General contractor (construction) X ANTENNA SITE & SIGHTING — ROOF-LEVEL INSTALLATION Cut out roof X Build frame X Move, rig and emplace RFT • • Install RFT Sight antenna Install IFL conveyance X Install IFL (charges per tariff) Install power X SBS EQUIPMENT ROOM Renovate or construct site X Provide utilities X Install air conditioning X Install heating X Install lighting X Install telephone Install adequate electric service X Shipping costs (charges per tariff) X Move, rig and emplace equipment Install interface panel Install PAS Install TDMA Burst Modem Install SCC Install RF•AUX Cabinet Test Installed SBS equipment Provide physical security of SBS equipment X • This table shows where primary responsibility Iles. Whenever the Customer. or SBS does not have primary responsibility, they will serve in a support role.. • • Customer pays actual charges per tariff. 4 Primary Responsibility CUSTOMER SBS X X X ANTENNA SITE & SIGHTING — GROUND-LEVEL INSTALLATION Build suitable foundation for RFT X Install power X Install IFL conveyance X Install IFL (charges per tariff)* X Move, rig and emplace RFT X Install RFT X Sight antenna X Install fence X Rev. B 3/26/82 SBS; SATELLITE BUSINESS SYSTEMS The customer may find it desirable to include SBS in the review and approval cycle of civil designs and to request recommendations and /or concurrences during the construction phase in order to ensure mutual satisfaction with the completed work. Although SBS will review the design, the responsibility for the design remains with the customer. 1.3.2 SBS Responsiblities o Provide the customer with technical data required to obtain zoning reclassifications, variances, or special use permits including antenna /shelter design data. o Secure all Federal Communications Commission (FCC) permits and authorizations required to allow the operation of the SBS System. o Erect, mount, and sight the antenna and secure the baseplates of the mounting frame to the anchor bolts; mount the RFT equipment shelter and install interconnections. o Install obstruction lighting when required by FAA. 1.4 General Design Requirements 1.4.1 Site Investigation The customer's A -E is to investigate the building and grounds to determine that local conditions will permit the installation of CPES components. 1.4.2 Facility Design The customer's A -E is to prepare construction drawings and specifications for any modifications to existing structures or for new construction required to incorporate the CPES components. All design work is to conform to requirements of local building codes and regulations. SBS is concerned only with the interface with the SBS equipment. 1.4.3 As -Built Drawings The customer's A -E is to prepare, at the completion of construction, as -built drawings showing final conditions. The as -built drawings are to be developed from the original drawings. SBS will require one sepia of the as -built drawings. 5 SE SATELLITE BUSINESS SYSTEMS 1.4.4 Project Schedule The following are key milestones for this design and construction project: o Design Completion November 15, 1982 o Start Construction November 30. 1982 o Construction Complete (BOW February 15, 1983 o As -built drawings complete As Required by Customer 1.4.5 Design Review A design review of the customer's A -E developed drawings and specifications will be accomplished at 30%, and 90% completion levels. The review will be conducted in McLean, VA by the Facility Design Engineer with the assistance of SBS's Quality Assurance group and other SBS departments. The review will be confined to the interface aspects of the design and is intended to assure that the SBS CPES components will function properly in the customer's facility. This review will be accomplished within 10 working days of receipt of the design documents. The following criteria are established to define what is expected at each stage of review. SBS requires three copies of the design documents to facilitate the review. O 30% Review This is basically for a conceptual exchange, early in the design process, to assure that the customer's design is proceeding in the right direction. Preliminary design drawings, sketches, layouts, etc. are necessary for the review. O 90% Review This review is to be conducted when the design is essentially complete. Complete design (final) drawings, specifications and design calculations are required. Only response to review comments should be necessary to complete the documents. 6 • Rev. A 3/26/82 SATELLITE BUSINESS SYSTEMS 1.4.6 Completed Documents SBS will require the following data at the completion of design: o Construction drawings - 1 sepia o Specifications - 1 copy o Structural Calculations for RFT - 1 copy 1.5 Design Criteria The remainder of this document presents technical criteria to guide the design of the elements of the CPES and to define the interfaces between Customer provided facilities and SBS provided equipment. The following data are included in this design document: o Appendix A LIST OF ABBREVIATIONS o Appendix B SITE UNIQUE DATA, includes earth station location data drawings and other data to permit the integration of the earth station into the customer's facility. o Appendix C SBS STANDARD DRAWINGS AND CRITERIA, includes technical data pertaining to the characteristics of equipment SBS will furnish and install to assist in describing the interfaces with the customer's facility. Only data pertinent to this site are included. o Appendix D RFT FOUNDATION LOADS, includes dead load and wind load reactions for the antenna that are needed for design of the foundation or load frame. C SATELLITE BUSINESS SYSTEMS RADIO FREQUENCY TERMINAL (RFT) � SBS\ SATELLITE BUSINESS SYSTEMS 2.1 General o The Radio Frequency antenna, antenna su shelter(s) and inte pedestal azimuth fo summarized in Appen 2.2 RFT Orientation The pedestal azimuth mus and referenced true nort Registered Land Surveyor for the survey are to be survey is to be made uti true north referenced gr accuracy. 2.3 Structural Criteria o The RFT foundation 125 mph without dam load reactions for .o The foundation desi conditions existing the Customer's resp 2.4 Electrical Criteria I ESIGN CRITERIA CUSTOMER PREMISE EARTH STATION RADIO ( SECTION 2.0 FREQUENCY TERMINAL GROUND MOUNT) Rev. A 3/26/82 Terminal (RFT) consists of the parabolic port structure, RF communication equipment connecting hardware. The type of antenna, the antenna and other pertinent data are ix B. be established frgm a properly monumented survey to within - 1 by the customer's A copy of the surveyor's computations provided to SBS. A back -up or check izing USGS maps or other information on ds or monuments to guarantee survey s to be designed to withstand winds up to ge. See Appendix D for dead load and wind he antenna. n is to take into account the subsurface at the site. The soils investigation is nsibility. o The RFT operates on 120/208 volts, 3 phase "Y ", 60 Hz power. o Two power circuits re required; one conditioned and one unconditioned. Eac circuit has three phase conductors, one neutral conductor ad a ground (green) wire (5 wire circuit), wh are directly onnected on the shelter power box. o Phase conductors will be labeled A,B, and C from left to right for phase rotation in this sequence. 8 SATELLITE BUSINESS SYSTEMS 9 Rev. A 3/26/82 2.4 Electrical Criteria (Cont'd.) o Power requirements for the RFT are specified on the foundation layout in Appendix C. o Lighting is to be provided to illuminate the rear of the antenna and the shelter door. Additional lighting may be required for monitoring entry or personnel safety. Check with the SBS Facilities Design Engineer for specific details. o Both RFT power feeders are to terminate at disconnect switches located within 5 feet of the shelter power entry panel. o The Customer's electrical contractor is to furnish and install the liquid tight metal flexible conduit and power feeders between disconnect switch and the shelter terminal box after the shelter has been set in place. o Power feeders should be run underground in separate conveyances. Criteria for trenching and cable separation is shown on the RFT Foundation Layout in Appendix C. 2.5 Grounding Criteria The grounding system must comply with NFPA #70 and #78 and SBS Drawing #250 -00 -220 (See Appendix C), and includes: o A ground connection to the building system or to a ground ring with ground rods installed around the RFT. o Ground connections to the antenna and shelter. (See Appendix C) 2.6 Fencing o Specify a 6' chain link fence with barbed wire or a 7' chain link fence. (See Appendix B for fence location) o Fence dimensions and desired location of entry are presented in Appendix B. o Ground the fence when it is within 6' of the antenna or shelter. 2.7 Construction Details o The final position of the anchor bolts is to be established using a template provided by SBS, which shall be orientated on the pedestal azimuth by a registered surveyor. SATELLITE BUSINESS SYSTEMS 10 2.7 Construction Details (Cont'd.) o The anchor bolts for the shelter shall be located from the final position of the antenna anchor bolts. o SBS will provide three days notice of the date the shelter(s) will be in place and ready for power connection. Connection • are to be completed by the customer within 48 hours after the shelter(s) are set in place. C SATELLITE BUSINESS SYSTEMS SECTION 3 INTRA - FACILITY LINK (IFL); SBS) SATELLITE BUSINESS SYSTEMS 3.1 General 3.2.1 RFT Terminal DESIGN CRITERIA CUSTOMER PREMISE EARTH STATION SECTION 3.0 INTRA - FACILITY LINK (IFL) The Intra - facility Link (IFL) connects the Radio Frequency Terminal to the SBS Equipment Room. The customer is responsible for design and construction of the conveyance or cable support SBS will supply and install the coaxial signal and control cables. See Appendix B, IFL Routing Drawing, for proper size of conveyance, minimum allowable bend radius, pull box sizes, and the preferred routing. The IFL route with conveyance or cable supports should be the shortest, most direct route consistent with the building details and good engineering practice. 3.2 Conveyance Design A conveyance or cable support is required between the IFL entrance box on the RFT shelter and the RF AUX Rack in the Equipment Room. o For a single shelter, terminate the IFL conveyance within 5' of the IFL entrance on the shelter. See Appendix C. o For dual shelters see Appendix C, RFT Foundation Layout for details. 3.2.2 Equipment Room Terminal o The RF AUX rack is the IFL terminus in the Equipment Room. It can be entered from either the top or bottom. o If the RF AUX is to be entered from above, use rigid conduit above the ceiling and terminate in flexible conduit ending 70" above raised floor on the center of the rack. Provide end fitting hardware for the end of the flexible conduit. o If the RF AUX is to be entered from below, terminate the rigid conduit at the perimeter wall around the raised floor. 11 Rev. 'A 3/26/82 SATELLITE BUSINESS SYSTEMS 12 Rev. A 3/26/82 3.2.3 Conduit o Except for buried conduit, use electrical metallic tubing with standard threadless fittings, wherever possible. o Except for buried conduit, use EMT with compression fittings in wet areas where local codes permit. o Conduit is not required when cables are protected against weather, mechanical damage, electrical interference, and unauthorized personnel, unless required by local regulations. o Conduit should be used above existing or proposed suspended ceilings. o PVC type 40 heavy wall is preferred if IFL is to be run underground. Protect conduit from surface loads. See Appendix C for separation of buried power and IFL conveyances and trench details. Provide a ground conductor for lightning protection if PVC conveyance is used and there is not a metallic power conveyance above the PVC conveyance. o Conduit is required in a plenum area to meet National Electric Code 300 -22. 3.2.4 Pull Boxes o Use pull boxes sized as shown in Appendix B. o Space pull boxes so that there are no more than four 90° bends and a maximum of 200 ft. of conduit between one end of the conduit and an intermediate pull box, or between pull boxes. o Locate pull boxes in accessible locations. 3.2.5 Cable Support o Provide cable bundle supports not more than 100 ft. apart on vertical runs. o On horizontal runs of exposed cable, provide a messenger wire and appropriately spaced hangers. The runs must be in an accessible location for ease of attaching cables. 3.2.6 Routing Restrictions o Do not route IFL conveyance along the same route as power cables over 600 volts. - SATELLITE BUSINESS SYSTEMS 13 Rev. A 3/26/82 3.2.6 Routing Restrictions (Cont'd.) o Cross high voltage power cables at right angles. o Do not route IFL close to steam or hot water pipes, hot structures or under parallel water or steam pipes. o Separate the IFL and lightning conductors by a minimum of 6 ft. If this separation is not possible, bond the metal IFL conveyance to the lightning conductor with #4 AWG bare copper wire. o Separate power and IFL conveyance by the minimums shown in Appendix C. 3.3 Special Requirements o Plans and elevations of the IFL conveyance must be in sufficient detail to accurately indicate the total length of IFL run. o Provide a dimensioned isometric drawing of the IFL route showing locations of end boxes, pull boxes, angle boxes, bends and type of conduit (rigid, flexible, etc.) 3.4 Construction Details o Specify that exposed conduit above a roof must be marked with yellow and black stripes. o Specify that conduit must be clean and free of burrs that could damage cable or impede pulling. o Specify that conduit and pull boxes are to have identification tags at each pull box and at the ends, and the conveyance must be provided with caps and bushings. o Specify that a Greenlee or equal measuring pull tape must be installed in the conveyance. o Specify that the IFL conveyance is to be installed in two stages. Stage 1 includes the installation up to the pull box near the shelter. Stage 2 consists of installing the liquid tight flexible metal conduit between the end pull box and the shelter. The flexible conduit is to be installed "finger tight" to the shelter IFL box. o SBS will provide three days notice of the date the shelter(s) will be in place and ready for the IFL conduit connection(s). Connection is to be completed by the customer within 48 hours after the shelter(s) are set in place. SATELLITE BUSINESS SYSTEMS 14 3.4 Construction Details (Cont'd.) o Specify that the underground conduit route be marked and the location identified on the As -Built drawings to avoid inadvertent damage from subsequent construction. (SBS ( SATELLITE BUSINESS SYSTEMS SATELLITE BUSINESS SYSTEMS 4.1 General The SBS Equipment Room includes the room where the communications equipment is installed, a DC power room, and the Customer's Demarc (Demarcation) Room. See Appendix B for the configuration and location of the rooms. The rooms are generally unmanned, except for periodic maintenance and testing. o SBS will furnish and install the SBS equipment indicated on the Equipment Floor Plan included in Appendix B. It is the Customer's responsibility to have the room prepared with critical and utility power, and air conditioning installed and operable by the specified BOD date. 4.2 Architectural Criteria 4.2.1 Floors DESIGN CRITERIA CUSTOMER PREMISE EARTH STATION SECTION 4.0 SBS EQUIPMENT ROOM o The Equipment Room is to have a raised floor with bolted steel framing on a 24" X 24" grid, 12" above finished floor, surfaced with high pressure plastic laminate. The floor must be capable of supporting a uniform load of 250 psf and a concentrated load of 1000 lbs. on one square inch. - The floor grid must be located as shown o,i the Equipment Room Floor Plan in Appendix B and grounded in at least two locations. - The area under the Main Distribution Frame (MDF) in the equipment room must be clear of pipes, conduit, cables, etc. - A temporary ramp is to be provided by Customer for moving equipment onto the raised floor. 15 , SBS) SATELLITE BUSINESS SYSTEMS 16 Rev. A 3/26/82 4.2.1 Floors (Cont'd.) - Openings are to be cut in the raised floor to provide cable access to the SBS installed equipment. See Appendix C for size of cutouts. SBS will provide templates or size and locations of cutouts. o DC Power Room floor coating must be resistant to battery electrolyte. Adequate protection must be provided to prevent spilled electrolyte from seeping under the raised floor of the Equipment Room. Wall base must be compatible. As an alternative, the floor may be painted and a drip pan installed under the batteries. A drip pan is required when the batteries are installed on a raised floor. 4.2.2 Walis o Partitions shall be provided to totally enclose SBS Equipment Room and DC Power Room. 4.2.3 Doors o All doors must be at least 3' wide and 7' high. Exterior doors are to be keyed for Customer security of the SBS equipment. The Customer must limit access to safety, security and building maintenance personnel. 4.2.4 Acoustic Treatment o Walis adjoining corridors or other office spaces and ceilings may be insulated, as required by the Customer, to maintain a typical business office atmosphere. 4.2.5 Ceilings o Suspended ceilings are not required in any of the Equipment Room areas. o If provided the ceiling must be at least 8' -0" above the raised floor in the Equipment Room. 4.3 Structural Criteria o Equipment will be located in positions shown on the Equipment Room Floor Plan in Appendix B. o The size and weights of the various cabinets, racks and frames are shown in Appendix C, Communications Equipment Characteristics. ssl SATELLITE BUSINESS SYSTEMS 4.4 Mechanical Criteria o Air conditioning will be required on a 24 hr /day, 365 day per year basis in the Equipment Room. The DC Power Room can be air conditioned or ventilated. o Temperature and humidity limits are as follows: ▪ Equipment Room: 75° ± 5° F and 40% to 60% relative humidity. ▪ DC Power Room: Average ambient over a 24 hr. period, 59° to 86° F, 0 to 90% relative humidity. o Controls for the air conditioning system are to be located within the Equipment Room or in an air handling unit. o Equipment heat load is tabulated on the Equipment List in Appendix B. 4.4.1 Air Distribution 4.4.2 Ventilation 4.4.3 Eyewash Provide and install an eyewash (meeting OSHA and local regulations) adjacent to the batteries. 4.4.4 Signs ▪ The SBS equipment will operate with air directly discharged into the room. Duct systems or ceiling air plenums are desirable when high air volume is encountered such as with units exceeding 10 ton capacity. ▪ The raised floor should not be used as an air plenum where sections 800 -3 and 300 -22 of the NEC is enforced under local codes. The standard SBS cable is PVC jacketed and does not meet UL standard 910, where cable is installed in a raised floor used as an air plenum. Air must be exhausted from the DC Power Room ( and not returned to building air distribution system) to prevent a buildup of hydrogen in excess of 3% by volume during recharging. Specify 50 CFM exhaust fan minimum. Provide No Smoking" sign for DC Power Room. 17 Rev. A 3/26/82 SW� SATELLITE BUSINESS SYSTEMS Rev. A 3/26/82 4.5 Electrical Criteria - AC System 4.5.1 SBS Equipment Room and DC Power Room o Voltage for unconditioned power requirements is to be 120/208, 3 phase, 60 Hz. o Conditioned Power requirements must meet the following limits: Voltage: 208Y/120, +8 %, -12% ▪ Phase: 3 phase, 5 wire, 120° ± 2° Frequency: 60 Hz, + 0.5 Hz ▪ Harmonic Content 5° total ▪ Unbalanced Voltage: 2.5% max. one phase to another Transient Voltage Envelope Time Voltage 0.0 0 0.8 microsec 1000 50 microsec 500 100 microsec 0 o Separate circuits and receptacles must be provided for each piece of communications equipment shown on the Equipment Room Floor Plan. See APPENDIX B for locations. o Conditioned power is to terminate in receptacles located under the raised floor panel to the rear of the equipment. The SCC receptacle as an exception must be located under a right side floor panel viewed from the front. The last three feet of the conduit terminating in the outlet box should be flexible. o Phase Rotation on three phase power must sequence through Phase A, B, C in a clockwise direction from the ground pin, when viewing the face of the receptacle, or from neutral pin in a 5 wire system. Phase rotation at switches and breakers must be A,B,C from left to right. o A preferred power distribution system is shown on the Power Distribution Drawing in Appendix C. This drawing also defines the interface between customer installed and SBS installed portions of the system. RFT power may be supplied from the Equipment Room as shown, or from a source close to the RFT. 18 ''SBS\ SATELLITE BUSINESS SYSTEMS Rev. A 3/26/82 4.5.2 Electrical Power Requirements o Conditioned and unconditioned power requirements are presented in Appendix B. o Equipment receptacles are specified on the Communications Equipment Characteristics , Appendix C. 4.5.3 Emergency Controls An Emergency Power Off (EPO) switch is to be installed on the wall of the Equipment Room near the main entrance. o The EPO is to disconnect the conditioned power and de- energize all air conditioners or air handlers servicing the SBS Equipment Room, plus all AC operated equipment within the room, except lights. The EPO should operate a shunt trip mechanism which is mechanically held and electrically operated. Electrically held mechanisms are not acceptable. o The button can be the "Pull to Operate" or "Push to Operate" type. A push -to- operate switch must be protected by a cover to prevent accidental operation. The EPO must be clearly labeled. o All DC operated equipment within the Equipment Room (48 VDC) is to remain energized. o At sites where UPS power is available, the UPS power should be used to power the EPO switch. 4.5.4 Lighting o Minimum illumination at 30" above the floor must be: Equipment Room: 50 ft. candles DC Power Room: 20 ft. candles o Fluorescent lights are to be used in the Equipment Room. Incandescent or fluorescent lights can be used in the DC Power Room. o Emergency lights are to be provided as required by code, and in Equipment Room in basement or windowless Equipment Room. 19 / (SBS ) SATELLITE BUSINESS SYSTEMS 20 4.5.5 Convenience Outlets (Utility Power) o Duplex outlets with ground are to be installed in the Equipment Room on perimeter walls above the raised floor on each equipment aisle and at the desk, minimum of one each wall. o One duplex outlet must be provided in the DC Power Room. 4.5.6 Administrative o Telephone Conveyances - where required by local code or local telephone company. As a minimum the Customer must provide: - A 3/4" conduit and outlet from the Demarc Room or Telco closet to the vicinity of the desk shown on the floor plan. A 3/4" conduit and outlet between the Demarc Room or Telco closet and the wall nearest SCC -0. - SBS will order phone service for these two outlets. 4.6 Electrical Criteria - DC System 4.6.1 General SBS will furnish and install a 48 VDC power system for powering communications equipment. The system consists of the appropriate sized rectifiers, power board, battery rack and batteries. The Customer is to provide and install a fused disconnect switch at the battery rack, a conduit from the switch to the power board, AC receptacles for the rectifiers, and a conveyance from the power board to the equipment racks, or to the perimeter of the raised floor if local codes do not require a conveyance under the raised floor. 4.6.2 DC Power System Criteria o The fused 48 VDC, 2 pole disconnect switch is to be installed on a wall to one side of the battery rack. The switch and fuse capacity must be sufficient for the current shown in Appendix C. ;SBS SATELLITE BUSINESS SYSTEMS Rev. A 3/26/82 4.6.2 DC Power System Criteria (Cont'd) o Conduit is to be installed between the rectifier and the batteries terminating on the wall behind the rectifiers. Conduit sizes for the DC wireway of various PAS power configurations are indicated in Appendix C. o One AC power receptacle for each rectifier is to be installed on the wall behind and next to the rectifier /power board. When the rectifiers /power board are installed on a raised floor, the AC receptacles must be under the floor panel to the rear of the equipment. See Appendix C, PAS DC Power System for the receptacle type and number of wires, and Appendix B for the power requirements. o If the rectifiers and power board are immediately adjacent to the Equipment Room wall, provide a 6" X 12" opening under the raised floor at the perimeter wall. If local codes require a conveyance to transit the DC Power Room floor, provide one 4" X 4" raceway to the underfloor area for each VPA, CTA and EC equipment row. The conveyance, when required, is to run under the center of the equipment row. 4.7 Electrical and Signal Grounding o The grounding system shall comply with NEC and local code requirements. 4.7.1 Grounding Criteria o Refer to Grounding Drawing, Appendix C. o A signal ground must be installed in the Equipment Room under the raised floor within 3' of the RF AUX rack, in accordance with Appendix C. The customer is to furnish and install the signal ground system including the signal ground bus. SBS will install ground leads to equipment in the room. 4.8 Lightning Protection The power source should be protected when the primary power is supplied overhead, the area is subject to electrical storms, or protection is required by local code. 21 SBS) SATELLITE BUSINESS SYSTEMS 4.9 Fire Protection and Personal Safety o SBS will supply portable fire extinguishers for the Equipment Room. o Fire detectors of the ionization or photoelectric type satisfying NFPA 72E must be installed in the Equipment Rooms. The detectors are to provide a contact closure during an alarm, with contacts having a minimum AC /DC rating of 0.5 amps., 600 volts. Wires from alarms may be connected to the building monitoring system and must be run to the bottom of the primary CTA rack and a 10' long coil left for connection by SBS. The wires can be run exposed. Existing detectors can be used with an alarm contact added. o A sprinkler system is not required by SBS. Where an automatic water sprinkler system exists provide automatic on /off sprinkler heads (if acceptable to local authorities) and an automatic power disconnect. o Provide intrusion detectors in the Equipment Room which will close contacts whenever the exterior door or operable window is opened. Detector leads may be extended to the building central monitor and a parallel set of leads must be run to the bottom of the CTA rack. A 10' coil of wire is to be left for connection by SBS. 4.10 Construction Details o The customer is to specify that all switch and circuit breaker control levers and fuse casings t�iat feed power to the Equipment Room are to be marked with a dab of orange paint or plastic tape to identify the SBS circuits. o The customer's contractor is to demonstrate the operation of the contractor - installed equipment, including the air conditioning system and eye wash before BOD. o SBS will supply templates or cutout sizes and dimensions for locating cutouts for each piece of equipment. Cutouts must be made to ± 1/8" tolerance and gaskets installed on the cut edges. To maintain the structural integrity of the floor panels, no floor grids are to be cut. 22 Rev. A 3/26/82 C SATELLITE BUSINESS SYSTEMS SATELLITE BUSINESS SYSTEMS Rev. A 3/26/82 5.1 General o The Demarc /Modem Room provides space for the interface between the Telco and the SBS Equipment Room. It may also provide space for the Customer's multiplex /modem equipment and interface connections to the Customer's PABX. o The Demarc facility should be be located adjacent to the SBS Equipment Room with a common wall between the two areas. The size and location of the Demarc facility is presented in Appendix B. o A suggested routing of the Telco cables between the building main frame room and the Demarc Room is shown in Appendix B. The Customer should work with Telco and SBS Business Relations Department to get agreement on details of Telco cable conveyance and supports for both inside and outside plant. This is to include but not be limited to Telco routing, size and number of conveyances, location and size of boxes, elbow radius and number of bends. o A separate conveyance may be required for data or a tele - conferencing facility. Check Appendix B for details. 5.2 Architectural Criteria 5.2.1 Floors DESIGN CRITERIA CUSTOMER PREMISE EARTH STATION SECTION 5 DEMARC /MODEM ROOM /AREA o There are no special flooring requirements. If the floor is exposed concrete, it should be painted or hardened to minimize dusting. 5.2.2 Walls o Walls are to extend from floor to floor. 23 SATELLITE BUSINESS SYSTEMS 5.2.2 Walls (Cont'd.) o On the wall common to the Demarc and E 4' X 8' X 3/4" panel(s) of painted ply Telco cable termination and cross conn equipment. See floor plan for the Dem for the number of required panels. Th installed with the long dimension vert 6" above finished floor. Provide wall penetrations for SBS cables from under to the underfloor area of the Equipmen for number required. 5.2.3 Doors o The exterior door should be a minimum keyed separately from door into Equipm nt Room. 5.2.4 Ceiling o None Required o When required by Telco, customer is t for Telco grounding for terminal bloc boards. As a minimum, the conveyance conduit from the street side of the w valve or from an acceptable ground point. 5.2.5 Acoustic Treatment o None Required 5.3 Mechanical Criteria o No special air conditioning or ventilation is required. The ambient temperature and humidity shou d be the same as the other utility areas of the building. 5.4 Electrical Criteria 24 • Rev. A 3/26/82 uipment Room, install ood to accommodate ctions to SBS rc Room in Appendix B plywood should be cal and the bottom edge blockout or sleeved eath the plywood panels Room. See Appendix B '0" X 7'0 ". Door to be install a conveyance s mounted on Demarc should be a 1" PVC ter meter and shut off o Lighting should be provided by fluore• cent fixture which will result in a minimum of 50 foot candle. measured 30" above the floor. o One duplex convenience outlet, with g ound, is to be provided. o Power for all modems, multiplex or other equipment customer wishes to install, is to be provided. LIST OF ABBREVIATIONS SATELLITE BUSINESS SYSTEMS LIST OF ABBREVIATIONS AC Alternating Current A/C Air Conditioning A -E Architect /Engineer - Customer's in -house design engineers or outside firm AISC American Institute of Steel Construction ASTM American Society for Testing and Materials A/D Analog to Digital BM Burst Modem (See also TDMA) BOD Beneficial Occupancy Date. - Date all site preparation work complete and SBS can occupy site. CA Communications Adapter CNS Communications Network Service COAX Coaxial CPES Customer Premise Earth Station CTA Concentrated Test Access CTAU Concentrated Test Access Unit ° Degrees DA Data Aggregator DC Direct Current DEM Demodulator DTA Digital Test Adapter EC Echo Canceller EMC Electromagnetic Capability EMI Electromagnetic Interference EMT Electrical Metallic Tubing A -1 C� SATELLITE BUSINESS SYSTEMS ES Earth Station F Fahrenheit FCC Federal Communications Commission FUT Future GHz Gigahertz HAC Hughes Aircraft Company Hz Hertz (Cycle per Second) HVAC Heating, Ventilating and Air Conditioning IFL Intra- Facility Link kHz Kilohertz KVA Kilovolt Amps LV Low Voltage M Million MDF Main Distribution Fra e MHz Million Cycles per Second MODEM Modulator - Demodulator ms Millisecond NEC Nippon Electric Co., td. NEMA National Electrical M nufactureres Association NFPA National Fire Protect on Association O &M Operations and Mainte ance OSHA Occupational Safety a d Health Administration PABX Private Automatic Bra ch Exchange PAS Port Adapter System PBX Private Branch Exchange PVC Polyvinyl Chloride A -2 SATELLITE BUSINESS SYSTEMS RATS Remote Access Test REC Rectifier RF Radio Frequency RF -AUX Radio Frequency Auxiliary RFT Radio Frequency Terminal RMS Root Mean Square SBS Satellite Business Systems SCC Satellite Communications Controller TBD To be Defined or Determined TDM Time Division Multiplex TDMA Time Division Multiple Access TELCO Telephone Company TRANS Transponder V Voice or Volt VPA Voice Port Adapter A -3 SATELLITE BUSINESS SYSTEMS Item .I Earth Station Location Data M RFT Layout Plan IFL Routing rl Equipment Room Floor Plan it MAC Equipment List Power and. Air Conditioning Requirements in Telco /Teleconferencing /Data Conveyances APPENDIX B SITE UNIQUE DATA 0 0 SBS Rev. Drawing No. No. 016 -05 -005 016 -05 -002 016 -05 -002 016 -05 -001 016 -05 -004 016 -05 -002 A DC POWER ROOM PAS DC SYSTEM - UNCONDITIONED POWER EQUIP KVA BTUH REMARKS PAS 4 16.4 6370 BTUH NAC EQUIPMENT ROOM - COND POWER 1 EQUIP UNIT RQMTS TOTAL RQMTS KVA BTUH QTY KVA BTUH VPA 0 2218 2 From PAS DC 4436 CTA 0.05 341 2 .1 682 DTA 0.3 900 1 .3 900 RATS 0.40 1360 0 - -- - -- SCC 7.2 15400 2 14.4 30800 B.M. 0.80 2400 2 1.6 4800 RF AUX 0.30 1025 1 .3 1025 D.A. 1.0 2400 1 1.0 2400 EC ** 0 4890 1 From PAS DC 4890 H — . *40 EC's IN PAS AUX new TOTAL 17.7 49933 EARTH STATION POWER REOUIREMENTS COMPONENTS COND. UNCOND, 3 RADIO FREQ TERMINA 6.2 41 .5 EQUIPMENT ROOM 17.7 - -- POWER ROOM - - -- 16.4 TOTAL, ?3.9 57.9 * EQUIP & POWER ROOM AIRCONDITIONINO RQMTS EQUIPMENT ROOM BTUH DC POWER ROOM BTUH TOTAL 49933 6370 56303 SCALE NONE DATE NOTES: NfVn*o- wrcawo CONTRACT N SITE: G.E.- SEATTLE 1 016 05 -004 Au rN Col 1. SEE 883 STANDARD DRAWING 250-00 -218 FOR COMMUNICA- TIONS EQUIPMENT CHARA''-ER■ I8TICS. 2. SEE 8B3 STANDARD DRAWING SBS 250 -00 -228 FOR DC , POWER EQUIPMENT CHARAC- TERISTICS. 3. SEE SBS STANDARD DRAWING SBS 250 -00 -204 FOR RFT CHARACTERISTICS. 4.LOADS INDICATED HEREON ARE FOR SBS - PROVIDED EQUIPMENT. LOADS FOR HVAC, LIGHTS, RECEPTA- CLES, ALARMS, AND OTHER SUCH ITEMS MUST BE ADDED TO THE INDI CAZED TOTALS. SATELLITE BUSINESS SYSTEMS 8283 GREENSBORODBIVE. McLEAN. VA 22102 DRAWN BY E1[ ; CODE (DENT TITLE NAC EOUPMENTUST POWER and AIR CONDITIONING REQUIREMENTS REV I SHEET / or / 1•••9 mum 10114 Earth Station Name I G.E. SEATTLE I Date 8/21/82 Customer I GENERAL ELECTRIC COMPANY Division Street Customer Address Site Address TI PO MAJOR APPLIANCF RIIS . (iRnh Ip 2500 CAMBRIDGE ROAD 401 TUKWILA PKWY City SCHENECTADY, N.Y. 12345 TUKWILA,WA. County SCHENECTADY KING • Type Facility: • Antenna Size: • Manufacturer: • Type Mount: • Elevation AMSL • Number Shelters I • M/S ►: CNS - A • CNS•B • Other • 5.5 meters 7.6 meters • 7.7 meters al NEC • HAC Ground O Roof (ft): Ground 25 ' Roof Pivot Axis 37.43' 1 •- Number Lines: 152 • Number Voice Ports. 152 • Antenna Coordinates • USGS Map Number Satellite 70 W. Long. 92° W. Long. 97° W. Long. 100° W. Long. 103 °W. Long. Pedestal Azimuth 47°27 ' 36" N Lat. 122°15'03" W Long. AMS 1578 IV NE - SERIESTitie DES MOINES Mag. Dec. 21 1/2° E V891 Position True North Azimuth Elevation Angle 119 °42'14" 16 °05'38" 141 °38'15" 28 °03'51" 147 °22'32" 30 °11'05" 150°57' 28" 31°18'44" 160 °58'50" 33 °42'49" 136° 42' 08" Comments CLEAR LINE -OF -SIGHT FOR ALL SATELLITE POSITIONS Prepared Checked Approved. ROBERT J. HARTSON .rT 3/21/82 • 1 Name Date ° • "' 7 { `c f= - F , -' I Yz— / Name ate/,1 r' v i /�Sv Name Dal ✓ ✓✓ SATELLITE BUSINESS SYSTEMS SBS Drawing #016 -04 -005 EARTH STATION LOCATION DATA •• SBS SATELLITE BUSINESS SYSTEMS Title APPENDIX C SBS STANDARD DRAWINGS AND CRITERIA O 5.5 Meter NEC RFT - Single Shelter 250 -00 -202 Ground Mount - Foundation Layout ❑ 5.5 Meter NEC RFT - Single Shelter 250 -00 -203 Roof Mount - Foundation Layout al 7.6 Meter NEC RFT - Single Shelter 250 -00 -204 A Ground Mount - Foundation Layout O 7.6 Meter NEC RFT - Single Shelter 250 -00 -205 Roof Mount - Foundation Layout ❑ 5.5 Meter HAC RFT - Single Shelter 250 -00 -206 Ground Mount - Foundation Layout ❑ 5.5 Meter HAC RFT - Single Shelter 250 -00 -207 Roof Mount - Foundation Layout O 7.7 Meter HAC RFT - Single Shelter 250 -00 -208 Ground Mount - Foundation Layout O 7.7 Meter HAC RFT - Single Shelter 250 -00 -209 Roof Mount - Foundation Layout O 5.5 Meter NEC RFT - Dual Shelter 250 -00 -210 Ground Mount - Foundation Layout O 5.5 Meter NEC RFT - Dual Shelter 250 -00 -211 Roof Mount - Foundation Layout O 7.6 Meter NEC RFT - Dual Shelter 250 -00 -212 Ground Mount - Foundation Layout ❑ 7.6 Meter NEC RFT - Dual Shelter 250 -00 -213 Roof Mount - Foundation Layout O 5.5 Meter HAC RFT - Dual Shelter 250 -00 -214 Ground Mount - Foundation Layout O 5.5 Meter HAC RFT - Dual Shelter 250 -00 -215 Roof Mount - Foundation Layout ❑ 7.7 Meter HAC RFT = Dual Shelter 250 -00 -216 Ground Mount - Foundation Layout SBS Drawing No Revision SBS: SATELLITE BUSINESS SYSTEMS ❑ 7.7 Meter HAG RFT - Dual Shelter 250 -00 -217 Roof Mount - Foundation Layout ® Communications Equipment Character- 250 -00 -218 istics t Separation of IFL and Power Cables 250 -00 -219 • SBS CPES Ground Mount 250 -00 -220 Earth Station Grounding ❑ SBS CPES Roof Mount 250 -00 -221 Earth Station Grounding NJ Power Distribution 250 -00 -004 RFT and Equipment Room ❑ D.C. Power PAS 1200 -1 250 -00 -222 O D.C. Power PAS 1200 -2 250 -00 -223 O D.C. Power PAS 1200 -3 250 -00 -224 O D.C. Power PAS 1200 -4 250 -00 -225 O D.C. Power PAS 2 250 -00 -226 ❑ D.C. Power PAS 3 250 -00 -227 L 7 D.C. Power PAS 4 250 -00 -228 ❑ D.C. Power PAS 5 250 -00 -229 ❑ Power Distribution - Dual Shelter 250 -00 -230 RFT and Equipment Room Rev. A 3/26/82 1' -3 3/4" (400) 7 7/8" (200) PEDESTAL AZIMUTH SEE NOTE 2. 5' -3" (1600) 4-15/16' .B' ANCHOR BOLTS 4- 15/16" • CC C n OI v ANTENNA PIVOT AXIS W.!, 1' -7 3/4" 3 15/16 (100) (200) ANCHOP BOLTS 77/6" 3 /1",d ANCHOR BOLTS J 3 15/16" FOR LADDER. FURNISHED (100) AND INSTALLED BY SBS 7 7/8" 4- 15/16" Al ANCHOR BOLTS (200) APPROXIMATE LOCATION OF GROUNDING PIGTAIL. SEE 5B5 DRAWING N0. 250 -00 -220 FOR EARTH STATION GROUNDING TYPICAL ANTENNA ANCHOR BOLT ANTENNA BASE PLATE / NUTS ___ // / 7 LEVELING NUTS n 15/16" ANCHOR BOLTS, NUTS & WASHER FURNISHED BY SOS INSTALLED BY CUSTOMER 7 1/8" METRIC COARSE SCREW THREAD 7' -10 1/2" (2400) 7 7/0" (200) 4- 15(16 ".H ANCHOR BOLT 7' -0" x CC CO a RFT SHELTER N0. 2 (IF REQUIRED) 9 5 /8 ".8'ANCHOR BOLT & DOUBLE HEX NUTS' FURNISHED 6 INSTALLED BY CUSTOMER. HOLD DOWN PLATES FURNISHED WITH SHELTER & INSTALLED BY SOS TYPICAL SHELTER ANCHOR BOLT RF FOUNDATION PLAN LAYOUT (TYP) 2 5/8" (TYP) 2" _2 5/8" (TYP) a e0 m 6' -6" 6" CHANNEL SKID 8'x10' RFT SHELTER N0. 1 5/8" 0 ANCHOR BOLT (TYP) 7' -8 1/2" PLAN SECTION ft 3" CLR I. 'v 4' X 4' C OF APRON _ 9" (TYP) - 1 - B" CONCRI GROUNI TEMPORARY FOUNDATION FOR ANTENNA ASSEMBL) FOR USE BY SBS IN ERECTING ANTENNA (SEE NOTE 4 ) GENERAL NOTES: STRUCTURAL I. CUSTOMER TO ARRANGE FOR COMPLETE FOUNDAT INVESTIGATION AND DESIGN. FOUNDATIONS I BE CONCRETE PADS, PIERS, PILING, CAISSOI ETC. AS RECOMMENDED BY THE FOUNDATION I GINEER AFTER INVESTIGATION. 2. AZIMUTH OF ANTENNA (PEDESTAL AZIMUTH) 51 ON PLAN AND /OR SBS DESIGN CRITERIA 15 AZIMUTH FROM TRUE NORTH. CUSTOMERS 4/] ESTABLISH RELATIONSHIP OF TRUE NORTH Ti MONUMENTED BASE LINE OR PHYSICAL FEATURI AT THE SITE THAT CAN BE READILY IDENTII OR REPRODUCED PRIOR TO START OF CONSTRUC' 3. ANTENNA ANCHOR BOLTS TO BE SET AND ALIGN USING TEMPLATE FURNISHED BY SBS. m ©aim® Mil WICERIII 1allril IIIIM _•_ MA -MU Mid =I(SM M. -MEM Y A'i'd IFL BOX ON/ SHELTER A/C A/C CONCRETE APRON AND STEP TO GRADE.TOP TO BE 10" ABOVE BOTTOM OF SHELTER SKID RETE ND LINE LY ,T I ON MAY DNS, EN- SHOWN S THE 1/E TO TO A IRE(S) IIFIED ICTION. 1NED FLEX TERMINATION BY CUSTOMER UNISTRUT P2000 RACK FINISHED GRADE 11' -10" ANTENNA PIVOT AXIS W.P. FLEXIBLE CONDUIT BY CUSTOMER PVC POWER CONDUIT 1 EACH CRITICAL, NON - CRITICAL SAND COVER SAND BED 3" (TYP) • ■ 12 VARIES RIGID PVC CONDUIT SECTION SELECT BACKFILL MARKER TAPE 82 BARE COPPER GROUND IFL CONDUIT NON- CRITICAL POWER STUB UP � � CONNECTION IFL CONNECTION DISCONNECT SWITCH WIRING TROUGH WHERE APPLICABLE POWER CONDUIT GALVANIZED RIGID CONDUIT SAW CUT EXISTING PAVING 0 PVC CONDUIT FOR IFL 4. A 25'DIAMETER (MIN) LEVEL AREA I5 REQUIRED FOR SBS ASSEMBLY OF THE ANTENNA REFLECTOR. THIS 25' AREA SHOULD BE CONTIGUOUS TO THE ANTENNA FOUNDATION, BUT NOT CLOSE ENOUGH TO INTERFERE WITH ERECTION OF THE ANTENNA BASE MOUNT. CONTACT SBS FACILITIES DESIGN ENGINEER FOR ASSISTANCE IN LOCATION. IF LEVEL CON- CRETE AT LEAST 6" THICK 1S NOT AVAILABLE FOR THIS 25' DIA AREA, THE CUSTOMER IS TO PROVIDE TEMPORARY FOUNDATIONS AS INDICATED IN THE CENTER OF THE ASSEMBLY AREA, WHICH CAN DE REMOVED AFTER ANTENNA ERECTION. THE REFLECTOR AND REFLECTOR ASSEMBLY JIG WILL WEIGH 5900 LB5. 1 NON- CRITICAL POWER DISCONNECT SWITCH SELECT .BACKFILL MARKER TAPE POWER CONDUIT 1 EA CRITICAL, NON- CRITICAL CONCRETE 14 1/2' SHELTER PLAN - ELECTRICAL CONNECTIONS UNISTRUT P2000 RACK CRITICAL POWER DISCONNECT SWITCH SWITCH ASSEMBLY BENEATH ROADWAY TRENCH SECTIONS 8 1/2 ;11 j WIRING TROUGH WHERE APPLICABLE PATCH ASPHALT PAVING REPLACE BASE COURSE _ �\ CRITICAL (CONDITIONED) POWER DISCONNECT SWITCH. NON- CRITICAL AND CRITICAL POWER CONDUIT _ CRITICAL (CONDITIONED) POWER "1 \ CONNECTION POWER BOX ON SHELTER olz =is , SHELTER GROUND LUG ON 5KI0 AT THIS END CONDUIT FOR IFL ELEVATION SELECT BACKFILL RIGID STEEL POWER CONDUIT 1 EA CRITICAL, NON CRITICAL SCALE: DATE: SITE GENERAL NOTES: ELECTRICAL 1. RAINTIGHT POWER DISCONNECT SWITCHES TO RE LO- CATED CONVENIENT TO SHELTER DOOR AND EASILY ACCESSIBLE. "LIQUID -TITE" FLEXIBLE CONDUIT OR EQUAL TO BE INSTALLED BETWEEN THE POWER SWITCHES AND SHELTER POWER BOX. FIVE WIRES TO BE CONNECTED BETWEEN EACH SWITCH AND POWER BOX. TYPICAL LOCATION AS INDICATED ON DRAWING. 2. IFL CONDUIT I5 TO TERMINATE 6 INCHES ABOVE GRADE. "LIQUID -TITE" FLEXIBLE CONDUIT TO RE ATTACHED "FINGER - TIGHT" TO THE 1FL BOX. ALL CONDUITS TO BE PROTECTED TO PREVENT ENTRY OF WATER AND DIRT DURING CONSTRUCTION. 3. RIGID PVC CONDUIT I5 PERMITTED UNDERGROUND WHERE APPROVED BY LOCAL CODE. HOWEVER. STUB- UPS TO BE GALVANIZED RIGID CONDUIT WITH MIN- IMUM 3 FOOT RADIUS BEND. ELECTRICAL POWER REQUIREMENTS (Single Shelter) CONDITIONED POWER 6.2 KVA UNCONDITIONED POWER 41.5 KVA, WITH DEICER UNCONDITIONED POWER 6.5 KVA,WITHOUT DEICER NONE 01 -18 82 NON- CRITICALPOWER DISCONNECT SWITCH SITE LIGHT DISCONNECT SNITCH WHERE APPLICABLE CONCRETE FOOTING. DEPTH AS REQUIRED. 2' -0" MIN FINISHED MARKER TAPE GALVANIZED RIGID CONDUIT APPROVED BY CONTRACT NO.: GRADE jY ?7. CONDUIT FOR IFL RIGID STEEL SATELLITE BUSINESS SYSTEMS 8283 GREENSBORO DRIVE, McLEAN, VA. 22102 DRAWN BY CODE IDENT. H.A. TITLE. 7 "b 'METER NEC RTF GROUND MOUNT - FOUNDATION LAYOUT MONO: E SH STANDARD DRAWING 250 -00 -204 I R A V .: I1 EET 1 PIM um MI M M MI 1I A )PDnT :TAD() * +V•M ow fig COMMUNICATIONS EQUIPMENT CHARACTERISTICS EQUIP. ITEM TITLE SIZE (Inches) WBGHT (Ibs.) A.C. VOLTAGE NO. PHASES NO. WIRES RECEPTACLE MIN CIRCUIT BREAKER REMARKS NEMA HUBBELL RUSSELL & STOLL W D H VPA VOICE PORT ADAPTER 21 23.6282.68 770 (48VDC) NONE 8'x9' FLOOR CUTOUT CTA CONCENTRATED TEST ACCESS 21 23.6282.68 660 120 1 3 * L5 -20R IG 2310 20A -1P 8'x9' FLOOR CUTOUT DTA DIGITAL TEST ADAPTER 21 23.6282.68 440 120 1 3 * L5 -20R IG 2310 20A -1P 8'x9' FLOOR CUTOUT PAS AUX PORT ADAPTER SYSTEM AUXILARY 21 23.6282.68 440 120 1 3 L5 -20R 2310 20A -1P 8'x9' FLOOR CUTOUT SCC SATELLITE COMMUNICATIONS CONTROLLER 32.0694.7170.75 2850 208 3 4 3754 30A -3P 3'x17 -1 /2' a 4' DIA. FLOOR CUTOUT BM BURST MODEM 23 24 72 700 208/120 3 5 * L21 -30R IG 2810 20A -3P 8'x9' FLOOR CUTOUT RF AUX RADIO FREQUENCY AUXILARY 23 26 71.75 200 120 1 3 * L5 -20R IG 2310 20A -1P 8'x9' FLOOR CUTOUT DA DATA AGGREGATOR 25.2232.75 71.56 675 208/120 3 5 * L21 -30R IG 2810 20A -3P 6'x10' FLOOR CUTOUT MDF MANN DISTRIBUTION FRAME 24 32 84 700 NONE OMIT FLOOR PANEL UNDER FRAME i CUT DTA PANEL 2' BEYOND EC ECHO CANCELLER 21 23.6 82.6 440 (48VDC) NONE 8'x9' FLOOR CUTOUT * RECEPTACLE REQUIRED WITH ISOLATED GROUND • S SATELLITE BUSINESS SYSTEMS 8283 GREENSBORO D: VE.MCLEAN.VA.22102 SCALE NOTE APPROVED St 0 OMWN RI 1/11/12 m+rR cT • • COOEIOENT TITLE COMMUNICATIONS tOUIPMENT CHARACTERISTICS srtE_ STAND/MD D AWP 0 I DWG . 50 -00 -211 I REV: I /.F/ PIM um MI M M MI TABLE 3 -1 SEPARATION OF IFL AND POWER CABLES* TYPE OF INSTALLATION BURIED AERIAL CONDUIT/ MH SYSTEM RISERS WI BU.ILDING IFL AND POWER EACH IN SEPARATE STEEL CONDUITS 3" CONCRETE 4" MASONRY 12" EARTH SAME AS BURIED 2" IFL IN PLASTIC CONDUIT AND POWER IN STEEL CONDUIT 12" VERT. AND HORIZ. SAME AS BURIED 2" IFL DIRECT BURIED AND POWER IN STEEL CONDUIT 12" VERT. AND HORIZ SAME AS BURIED IFL CABLE IN BUNDLE IN AIR AND POWER IN STEEL CONDUIT 6" . 1 IFL CABLE BUNDLED TOGETHER WITH GROUNDED MESSENGER AND POWER IS ON POLE 24 INCHES BELOW POWER r • ■ NOTE REFERENCE: NATIONAL ELECTRICAL SAFETY CODE ANSI C -2 1981, PARA 238, 320B 341B & 352 DWG. N0.: 250 -00 -219 K•z DC GROUND NEC 250 -93 MIN 250 MGM LEAVE EXTRA 5 FT. COILED AT POWER80ARD LOCATION SBS INSTALLATION CUSTOMER INSTALLATION NOTES: CLOSEST BUILDING GROUND ELECTRODE NEC 250 -81 12/0 r5S POWERBOARD 1 1 +48VDC • 1 1. ALL GROUNDING CONOUCTOFS SHALL BE GREEN INSULATED CABLE PER NATIONAL ELECTRIC CODE (NEC) EXCEPT AT RFT WHERE BARE CONOUCTOTS CAN BE USED. 2. IFL CONDUIT AND MESSENGER CABLE, WHERE USED SHALL BE GROUNDED AT RFT TO PERIMETER GROUND WITH EXOTHERMIC CONNECTOR BELOW GRADE. 3. USE GROUND CLAMP TO RAISED FLOOR PEDESTAL IN TWO PLACES. USE 12 AWG COPPER GREEN INSULATED WIRE TO GROUND BUS AS SHOWN. 4. GROUNDING SHALL SATISFY NFPA 170. 5. LIGHTNING PROTECTION SHALL SATISFY NFPA 178. 6. DRAWING IS TYPICAL, ACTUAL NUMBER OF POWER CIRCUITS WITH GROUND IS DETERMINED BY NUMBER OF SETS OF EQUIPMENT, IE 2 -SCC's REQUIRE 2 CIRCUITS. SEE EQUIPMENT LIST IN APPENDIX B. 7. SIGNAL GROUND 19" X 2" X 1/4" COPPER GROUND BAR WITH LUGS AND STANDOFF INSULATORS ATTACHED TO SUBFLOOR. GROUND BAR LORAIN PRODUCTS /4361 -039 GROUND LUG, 12/0 LORAIN PRODUCTS /4835 -526 11 -16 GROUND LUG LORAIN PRODUCTS 14835 -523 INSULATED STANDOFF LORAIN PRODUCTS 14133 -036 8. OUTDOOR MOUNTED AIR CONDITIONING EQUIPMENT SHALL BE GROUNDED OUTD00RS TO NEAREST AVAILABLE GROUND PER NEC OR TO COPPERWELD GROUND ROD. 9. GROUND CABLE BURIED IN A TRENCH OVER TOP OF PVC CONDUIT SHALL BE CONNECTED TO THE GROUND LOOP AT THE RFT • SIGNAL GROUND, SEE N0TE7 UNDER RAISED FL00R AT RF AUX RACK SBS INSTALLATION CUSTOMER INSTALLATION CRITICAL POWER PANEL STANDARD GROUNDING TYPE RECEPTACLES NEC 410 -58 (ONE FOR EACH RECTIFIER) SEE EQUIPMENT LIST APPENDIX 8 • UP SULATED EQUIPMENT GROW BUS RECEPTACLE WITH INSULATED GROUND NEC -74 (TYPICAL) MAIN POWER DISTRIBUTION PANEL NEUTRAL • EQUIPMENT GROUND BUS NOTE: NEUTRAL, FRAME, EQUIPMENT GROUND INTERCONNECTED NEC 250 -5 AC GROUNDING CONDUCTOR NEC 250 -94 NEC 250 -26 BONDING JUMPER EQUIPMENT GROUND FRO POWER SOURCE POWER CONOITIO GROUND N I I IEUTRAL 1 I NEUTRAL 1 1 1 1 1 1 1 I I 1 I 1 1 I MCLT 1 1 L____J L____J L____J L__ SCC RF AUX CTA -0 DTA -0 EQUIPMENT ROOM IND FROM •J• 1 11 • OWER ONDITIONER ROUND NEUTRAL A -0 -- 1 E I I NE UTRAL I I I I NEUTRAL GROUNDED AT SOURCE BM I I � I L 1 PAS -AUX — NEUTRAL 1 I I I L____J RECEPTACLE FOR PAS -AUX BY SOS GREEN EQUIPMENT GROUND WIRE INSTALLED WITH ALL POWER CIRCUITS GREEN GROUND CONDUCTOR • 1uI RAISED FLOOR (NOTE 3 RANSFORMER IF INSTALLED) NEUTRAL SHOWN FOR CLARITY d DIFFERENCE — FROM GROUND 82 AWG BARE COPPER PIGTAIL FOR CONNECTION TO END OF NIPPON SHELTER SKID OR GROUND LUG ON SIDE OF HAC SHELTER. SBS WILL MAKE CONNECTION TO SHELTER. 12 AWG BARE COPPER PIGTAIL EXTENDING 3' ABOVE FOUNDATION, FOR CONNECTION TO ANTENNA BY SBS. SEE ANTENNA FOUNDATION LAYOUT FOR NUMBER AND LOCATION OF CONNECTIONS. 06. LOCATE AT OPPOSITE SIDE OF GATE FROM OTHER FENCE GROUND. POWER SWITCHES CRITICAL NEUTRAL - • • r' I �Q. TYPICAL ANTENNA SUPPORT LEGS X EUTRAL--.- +l.— GROUND TERMINAL UTILITY • •' 1 1 WT MITER L J O SBS TRANSFORMER (IF INSTALLED) /'"GROUND TERMINAL j/ POWER BOX ON SHELTER X X DATE: 1 /26 /e2 Odra 9 02 AWG BARE COPPER BURIED PERIMETER GROUND NEC 250 -81. CONTRACT ENCLOSING CHAIN LINK FENCE 5/8" / x 10' -0" COPPER CLAD GROUND ROD (TYPICAL) EXOTHERMIC WELD BELOW GRADE GROUND EQUIPMENT AT SWITCH OR TRANSFORMER NEC 250 -26 LOCATE APPROX. MID -WAY BETWEEN END POSTS OR AT GATE POST EXOTHERMIC CONNECTOR BELOW GRADE EXOTHERMIC CONNECTOR TO POST BELOW GRADE. IF FABRIC IS VINYL COATED PROVIDE FOR BONDING BETWEEN FABRIC AND POST. TYPICAL EACH LEG ANTENNA SUPPORT GROUND CONNECTED FIRST TO GROUND ROD THEN INTERCONNECT TO PERIMETER GROUND GROUND FENCE WHERE IT IS WITHIN 6 FT OF ANTENNA SHELTER OR POWER (TYPICAL] SCALE NONE SATELLITE BUSINESS SYSTEMS 8283 GREENSBORO DRIVE. McLEAN, VA. 22102 APPROVED ev:(A jb DRAWN BY:. OFF CODE IDENT: — m` SBS CPES GROUND MOUNT EARTH STATION GROUNDING SITE 2 a stair STANDARD DRAWING I 250 -00 -220 1 OF 1 CO 0 1 1 RECTIFIERS PAS -PWR. BDS * ** I * ** EMERG. POWER OFF C1 SWITCH I � SHUNT TRIP L_ ) HVAC o AO UTILITY MAIN POWER DIF. � T) ) LIGHTS Al 208Y/ 120V,30 4W,6OHZ POWER SERVIC MAIN F WAL RECEPT • CRITICAL POWER * ** AS RE * EXISTING HVAC,LIGHTS&RECEPTACLES MA USED IN LIEU OF DEDICATED CIRCUITS * * PROVIDE SEPARATE ALARM CONTACTS f * * * SEE NAC EQUIPMENT LIST FOR NUMBEF BATTERY ROOM VENTILATION POWER CONDITIONER A4 FIRE/ INTRUSION ALARM ** * ** DA PAS AUX TEST Ell. * ** SCALE: N.T.S. DATE: 7/25/79 f DISCONNECT SWITCHES REVISION RECORD F:�v::•f. . • APP I B,B1,B2, APPROVED BY: F CONTRACT Nd.: AUTO./ WD OR. p'R �r /1 c ot. SATELLITE BUSINESS SYSTEMS 8283 GREENSBORO DRIVE, McLEAN, VA. 22102 DRAWN BY: f:',CK CODE IDENT.: — TITLE: POWER DISTRIBUTION RFT & EQUIPMENT ROOM SITE: DWG. NO.: STANDARD DRAWING 250 -00 -004 REV.: SHEET A 1OF1 STRIBUTION I LL 'ACLE 2' :C * DISTRIBUTION it I� ECEPTACLES PLUGg 'AY BE FPR SBS 14 OF UNIT f G A3 C TDMA * ** DESIGN LOADS TOTAL (MAX.) TOTAL HEAT REJECTION KVA BTU /HR. 16.4 6370 ELECTRICAL DETAILS RECTIFIER RACK DETAILS BATTERY CAPACITY ND. OF RECTIFIERS RATING OF RECTIFIERS RECEPTACLE POWER TYPE (NEMA) SWITCH RATING FUSE RATING CC0PBLERSIZE PER TERMINAL DIMENSIONS WEIGHTS (11 6 0 H 1 2 1176AH 2 100A 115 -300 200A 200A 250808 24 3/8" 30" 84" 392 497 EQUIPMENT ROOM RATS PAS I AUX VPA END CLOSURE (TYP) 4 "04" WIREWAY FOR EACH ROW CONTAIN- ING CIA, DTA, PAS AUX L VPA RACKS 1 5ODI11 OOI ooOI O 1 OlO0I 1 FUSED BATTERY DISCONNECT SWITCH. MOUNT BOTTOM 4 FT ABOVE FINISHED FLOOR (SEE TABLE) CABLE TRAY OR CONDUIT BATTERY RACK AC OUTLET RECEPTACLES MOUNT 1' ABOVE FINISHED FLOOR - RECTIFIER /POWER 80ARD 1 1 2 I (A IiEQ'D) s 0 TYPICAL BATTERY ROOM PLAN SEE APPENDIX B FOR SPECIFIC LAYOUT 3' -0" MIN. .a CLEARANCE 1) SEPARATE AC CIRCUIT REQUIRED FOR EACH RECTIF ER. 2) FOR UP TO 30' RUNS FROM FUSED DISCONNECT SWITCH TO POWER DISTRIBUTION BOARD ' SIZE CONDUCTORS FOR LONGER RUNS FOR MAXIMUM OF 0.5 VOLT DROP. 3) HIGHEST NUMBER RACK INCLUDES THE POWER DISTRIBUTION BOARD. 4) PROVIDE 5 AMP FUSES, OU55MAN INURE M281 308 TYPE GLR OR EQUAL 5 EQUIPMENT RACKS -? EQUIPMENT ROOM HI WALL --- I -RAISED FLOOR 4' X 4" LATIN WIREWAY (SQUARE DADA SERIES. OR EQUAL) WITH HINGED COVER. WIREWAY TO BE MOUNTED ON SIDE WITH HINGE ON BOTTOM. RUN FULL LENGTH OF RACKS 6 PROVIDE END CLOSURE. BATTERY /RECTI NOTE -1: CUSTOMER TO FURNISH AND INSTALL WIREWAY, CABLE 'TRAY OR CONDUIT FOR RECTI- FIERS. FUSED DISCONNECT SWITCH AND AC POWER RECEP- TACLES WITH APPROPRIATE WIRE AND CONDUIT. BUSHED EDGE O `POWER (POB) RECTI RUN WI WALL A WITH I 2: 585 WILL FURNISH AND INSTALL BATTERY RACKS. BATTERIES. CABLES FROM BATTERIES TO FUSED DISCONNECT SWITCH. CABLE BETWEEN RECTIFIERS AND FUSED DISCONNECT SWITCH. RECTIFIERS AND PAS EQUIPMENT RACKS INCLUD- ING CABLE BETWEEN PA5 EQUIPMENT AND RECTIFIERS. BATTERY RACK DATA (CAD) NUMBER OF SUPPORTS DIMENSIONS WEIGHT WITH 23 BATTERIES L w H 4 @32" SPACING 108" 30 1/2" 22 5/8" 51580 :CTIFIER R00M SHED END -STOP AT OVERHEAD iE OF POB CONDUIT OWER DISTRIBUTION BOARD P08) BATTERY RACK IECTIFIERS N WIREWAY THROUGH LL AND MAKE FLUSH TH INSIDE SURFACE .E SBS ELEVATION ri n n n W SECTION BATTERY RACK NOTE: BATTERY RACK, ANCHOR BOLTS, BATTERIES FURNISHED AND INSTALLED BY SBS. SCALE NONE DATE 2 -3 -82 SITE STANDARD DRAWING NeVNION APPROVEOBY. O,M_3 CONTRACT NO DWG NO 250 -00 -228 AUVN REV SATELLITE BUSINESS SYSTEMS 8283 GREENSBORO ,PRIVE. McLEAN. VA. 22102 DRAWN BY CODE IDENT TITLE D.C. POWER PAS 4 SHEET ICW1 S (LBS) 2 97 4 3 tf FUSED DISCONNECT SWITCH WITH BUSHED OPENING ON BOTTOM - BY CUSTOMER SEE NOTE 4 CABLES IN AIR - BY SBS SBS) SATELLITE BUSINESS SYSTEMS APPENDIX D RFT FOUNDATION LOADS ❑ NEC 5.5 METER ANTENNA OD NEC 7.6 METER ANTENNA ❑ HAC 5.5 METER ANTENNA ❑ HAC 7.7 METER ANTENNA SATELLITE BUSINESS SYSTEMS DESIGN LOADS FOR THE NEC 7.6 METER ANTENNA Wind load reactions are indicated herein for the following wind velocities: Operation: 20.8 m/s (75 km /h) Survival: 55.6 m/s (200 km /H) The foundation reactions are based on the wind tunnel data from "Air Loads and Pressure Distribution on a Parabolic Antenna Model," MIT Lincoln Laboratory Report 71G -5. Y so BASE 1 BASE 2 BASE 3 BASE 4 X Y Z Mx My X Y Z X Y Z X Y Z 0 m /s. 0 0.071 0.002 -4.042 0.000 -0.873 -0.066 0.001 0.021 -0.002 -0.107 0.458 -0.002 0.104 0.442 20.8 0° 0.836 -0.025 -2.143 0.001 -0.872 0.988 3.024 -1.732 -0.001 -0.104 0.431 -0.001 0.074 0.298 45 0.809 -0.139 -2.194 0.002 -0.868 0.989 0.132 -1.703 -0.001 -0.104 0.434 -0.001 0.085 0.349 90° 0.065 0.5191- 4.009 -0.011 -0.865 -0.148 - 0.343 0.159 -0.001 -0.019 0.059 -0.003 0.161 0.690 135 -0.161 0.602 -4.699 0.013 - 0.881 -0.517 -0.396 0.771 -0.001 - 0.011 0.045 -0.004 0.178 0.767 180° -0.399-0.006 -5.310 0.000 -0.895 -0.727 -0.006 1.120 -0.003 - 0.115 0.502 -0.002 0.126 0.551 55.6 0° 5.513 -0.191 9.465 0.008 -0.873 7.430 0.163 - 12.446 0.003 -0.085 0.265 0.005 -0.107 -0.585 45 5.322 -0.999 9.105 0.015 -0.837 7.441 0.933 -12.468 0.001 -0.086 0.289 0.006 -0.029 -0.217 90° 0.033 3.681 -3.804-0.078 -0.822 -0.651 -2.449 1.004 0.007 0.523 -2.376 -0.009 0.514 2.205 135 -1.744 4.267 -9.714-0.090 -0.932 -3.269 -2.821 5.357 0.006 0.552 -2.477 -0.013 0.632 2.753 180 -3.269-0.055 - 13.062 -0.002 - 1.029 -4.768 0.035 7.836 -0.006 -0.165 0.775 -0.007 0.265 1.218 �..:. E`. r " F -ire �r1 itiu:.wq:.� n S.eL e+-. „r . l:..- .•srs.i aTi.�.v. V co BASE 1 B1 SE 2 BASE 3 BASE 4 X Y Z Mx My X Y Z X Y Z X Y Z • 0 m/s 0 0.006 -0.061 -3.990 0.001 -0.855 -0.055 -0.039 0.003 -0.001 -0.051 0.207 -0.003 0.151 0.653 20.8 0 0.783 -0.538 -2.215 0.017 -0.860 0.932 0.109 -1.639 -0.002 -0.181 0.769 -0.001 -0.009 -0.067 45 0.756 -0.644 -2.254 0.018 -0.852 0.937 0.216 - 1.648 -0.002 - 0.179 0.765 -0.001 0.003 -0.014 90° 0.100 0.466 - 3.839 -0.010 -0.847 -0.075 -0.386 0.038 0.000 0.041 -0.206 -0.004 0.209 0.901 135 - 0.130 0.697 - 4.478 -0.016 -0.863 -0.414 -0.482 0.602 0.000 0.091 -0.424 -0.004 0.272 1.180 180° -0.386 0.208 - 5.179-0.008 -0.873 -0.676 -0.115 1.034 -0.001 0.026 -0.126 -0.004 0.257 1.129 55.6 0 5.209 -3.452 8.637 0.112 -0.887 6.967 1.015 - 11.676 -0.003 -0.975 4.203 0.010 -0.987 -4.470 45 5.014 -4.210 8.357 0.118 -0.834 7.004 1.778 - 11.741 -0.005 -0.964 4.176 0.012 -0.906 -4.089 90° 0.346 3.686 -2.914-0.079 -0.797 -0.197 -2.501 0.250 0.008 0.601 -2.728 -0.010 0.563 2.416 135 -1.285 5.332 -7.462-0.125 -0.907 -2.608 -3.184 4.259 0.009 0.959 -4.284 -0.015 1.007 4.402 180 -3.112 1.852 - 12.449 -0.065 -0.980 -4.467 -0.574 7.336 -0.001 0.499 -2.165 -0.011 0.904 4.041 Table -2 7. 614 ANTENNA LOAD ON EACH BASE ANTENNA ATTITUDE CONDITION DEL = 0° WIND: V = 0 m/s (DEAD LOAD) si = +20 V = 20.8 m/s (75 KM /H) V = 55.6 m/s (200 KM /H) WIND DIRECTION: ' = 0 - 180 ° UNIT: TON(X,Y,Z), TON - M(Mx,My) V 9 BASE 1 BASE 2 BASE 3 BASE 4 X Y Z Mx My X Y Z X Y Z X Y Z 0 m/s 0 0.060 0.065 -3.979-0.001 -0.853 -0.056 0.042 0.004 -0.003 -0.115 0.667 -0.001 0.047 0.191 20.8 ' 0 0.787 0.489 -2.155-0.015 -0.849 0.948 -0.062 -1.666 -0.001 -0.017 0.048 -0.001 0.150 0.631 45 0.761 0.369 -2.217-0.013 -0.847 0.949 0.048 -1.667 -0.001 -0.020 0.063 -0.001 0.160 0.681 90° 0.015 0.547 -4.049-0.011 -0.847 -0.197 -0.293 0.240 -0.002 -0.076 0.314 -0.002 0.096 0.400 135 -0.229 0.476 -4.719 -0.008 -0.862 -0.554 -0.301 0.834 -0.002 -0.119 0.506 -0.003 0.065 0.267 180° -0.385 -0.220 -5.196 0.007 -0.877 -0.684 0.127 1.048 -0.004 -0.248 1.090 -0.001 -0.015 -0.074 - 55.6 0 5.232 3.082 8.993-0.096 -0.822 7.085 -0.698 - 11.871 0.009 0.822 -3.741 -0.001 0.777 3.322 45 5.047 2.225 8.548-0.088 - 0.811 7.087 0.084 - 11.878 0.007 0.802 -3.631 0.000 0.851 3.675 90° -0.257 3.491 -4.483-0. -0.813 -1.061 -2.234 1.687 0.006 0.405 -1.847 -0.009 0.394 1.676 135 -1.991 2.987 -0.243-0.048 -0.914 -3.602 -2.398 5.912 0.002 0.101 -0.478 -0.010 0.175 0.732 180 -3.106-1.965-12.640-0.060 -1.025 -4.524 0.649 7.430 -0.011 -0.821 3.676 -0.002 -0.393 -1.693 w+•ea.a Iw.e._vn..d .... -r sx.v Ir+.- .-vw. .vr."r.. _I .. _ . r.. -.�.1 c. • .. -c.. ... .....rz+� V 9 BASE 1 BASE 2 BASE 3 BASE 4 X Y Z Mx My X Y Z X Y Z X Y Z " 0 m/s 0 0.169 0.002-3.762 0.000 -0.478 -0.167 0.001 0.197 -0.001 -0.054 0.226 -0.001 0.051 0.210 20.8 0 0.817-0.015-2.352 0.001 -0.496 0.898 0.015 -1.571 0.000 -0.031 0.110 0.000 0.001 -0.020 45 0.763-0.079-2.371 0.001 -0.481 0.875 0.125 -1.533 0.000 -0.031 0.114 0.000 0.013 0.032 90° 0.165 0.441-3.726-0.012 -0.475 -0.251 -0.329 0.338 0.000 0.060 -0.285 -0.003 0.138 0.589 135 0.007 0.507-4.506-0.014 -0.523 -0.645 -0.379 0.991 0.000 0.054 -0.254 -0.003 0.179 0.777 180° -0.156-0.018-5.234 0.000 -0.560 -0.914 0.012 1.433 -0.002 -0.097 0.426 -0.002 0.103 0.452 55.6 0 4.776-0.120 6.269 0.007 -0.604 7.405 0.099 - 12.376 0.006 0.109 -0.595 0.008 -0.297 -1.429 45 4.388 -0.572 6.133 0.009 -0.501 7.241 0.881 - 12.106 0.004 0.109 -0.570 0.010 -0.219 -1.057 90° 0.140 3.124-3.507 -0.083 -0.457 -0.766 -2.351 1.201 0.009 0.757 -3.408 -0.011 0.670 2.908 135 -0.981 3.593-9.050-0.097 -0.799 -3.569 -2.702 5.846 0.007 0.715 -3.188 -0.017 0.963 4.241 180 -2.149-0.138-14.232 0.000 -1.060 -5.478 -0.075 8.994 -0.010 -0.357 1.650 -0.010 0.421 1.933 Table -4 7.6M ANTENNA LOAD ON EACH BASE ANTENNA ATTITUDE CONDITION °EL = 20 WIND: V = 0 m/s (DEAD LOAD) Oy = 0 . V = 20.8 m/s (75 KM /H) V = 55.6 m/s (200 KM /H) WIND DIRECTION: 9 = 0° ~180° Emmt Nn!li M UNIT: TON(X,Y,Z), TON - M(Mx,My) V V BASE 1 BASE 2 BASE 3 BASE 4 X Y Z Mx My X Y Z X Y Z X Y Z 0 m/s • 0 0.166-0.046-3.690 0.000 -0.469 -0.164 -0.047 0.193 0.000 0.010 -0.062 -0.002 0.099 0.424 20.8 0° 0-779-0.492-2.375 0.016 -0.488 0.838 0.097 -1.463 -0.001 -0.119 0.496 0.001 -0.097 -0.459 45 0.733-0.529-2.377 0.015 -0.474 0.824 0.199 -1.448 -0.001 -0.113 0.475 0.001 -0.081 -0.384 90° 0.199 0.407-3.562-0.013 -0.466 -0.186 -0.382 0.231 0.001 0.130 -0.599 -0.003 0.187 0.804 135 0.054 0.572-4.290-0.019 -0.511 -0.549 -0.462 0.833 0.001 0.179 -0.812 -0.004 0.280 1.220 180° -0.147 0.140-5.087-0.010 -0.545 -0.869 -0.100 1.360 -0.001 0.074 -0.334 -0.004 0.252 1.114 55.6 0° 4.526-3.219 5.660 0.116 -0.606 6.926 0.981 - 11.580 -0.001 -0.908 3.904 0.015 -1.299 -5.855 45 4.198-3.483 5.650 0.112 -0.506 6.861 1.707 - 11.476 -0.003 -0.868 3.755 0.016 -1.185 -5.328 90° 0.339 3.170-2.779 -0.086 -0.446 - 0.322 -2.428 0.465 0.011 0.861 -3.880 -0.011 0.721 3.126 135 -0.632 4.348-7.959-0.132 -0.769 -2.905 -2.997 4.745 0.011 1.211 -5.396 -0.019 1.382 6.083 180 -2.065 1.275-13.625- -1.011 -5.175 -0.424 8.493 -0.003 0.465 -1.998 -0.015 1.189 5.328 w1.5C•ar7 04,47,6:121 V i BASE 1 BASE 2 BASE 3 BASE 4 X Y Z Mx My X Y Z X Y Z X Y , 2 0 m/s 0 0.146 0.050-3.732 0.000 -0.467 -0.143 '3.050 0.157 -0.002 -0.112 -0.483 0.000 -0.005 -0.033 20.8 0° 0.760 0.462-2.381-0.014 -0.482 0.870 -0.068 -1.524 0.000 0.062 -0.299 0.000 0.098 0.406 45 0.701 0.368-2.416-0.012 -0.468 0.839 0.052 -1.474 0.000 0.054 -0.261 0.000 0.103 0.433 90° 0.111 0.452-3.776-0.010 -0.465 -0.286 -0.270 0.395 -0.001 -0.011 0.032 -0.002 0.072 0.302 135 -0.044 0.415-4.539-0.007 -0.511 -0.670 -0.287 1.032 -0.001 -0.071 0.303 -0.002 0.058 0.244 180 -0.163-0.174-5.153 0.010 -0.547 -0.853 0.123 1.333 -0.004 -0.258 1.414 -0.001 -0.058 -0.258 55.6 0 4.518 2.984 5.881 -0.101 -0.576 7.061 -0.785 - 11.804 0.013 1.124 -5.080 0.001 0.725 3.095 45 4.096 2.315 5.627-0.093 -0.477 6.842 0.062 - 11.444 0.010 1.069 -4.810 0.003 0.761 3.281 90° -0.103 2.913-4.046-0.074 -0.452 -1.156 -2.224 1.849 0.008 0.605 -2.729 -0.010 0.544 2.355 135 -1.206 2.649-9.470-0.054 -0.784 -3.892 -2.349 6.382 0.002 0.177 -0.798 -0.013 0.443 1.940 180 - 2.047 - 1.540 - 13.836 0.064 -1.040 -5.192 0.569 8.520 -0.015 -1.150 5.159 -0.004 -0.385 -1.634 IIMENPRit Table -6 7.6M ANTENNA LOAD ON EACH BASE ANTENNA ATTITUDE OEL = 20° Oy = -20 s� illom NW - CONDITION MIND: V = 0 m/s (DEAD LOAD) V = 20.8 m/s (75 KM /H) V = 55.6 m/s (200 104 /H) MIND DIRECTION: 9 = 0 ° '180 ° UNIT: TON(X,Y,Z), TON - M(Mx,My) V co BASE 1 BASE 2 BASE 3 BASE 4 X Y Z Mx My X Y Z X Y Z X Y Z ' 0 m/s 0 0.075 0.002 -3.277 0.000 -0.350 -0.074 0.001 0.046 -0.001 -0.016 0.053 0.000 0.012 0.037 20.8 00 0.514 -0.014 -2.462 0.001 -0.371 0.0847 0.011 -1.478 0.001 0.024 -0.137 0.001 -0.056 -0.278 45 0.504 -0.008 -2.484 0.000 -0.370 0.851 0.115 -1.486 0.000 0.037 -0.192 0.001 -0.018 -0.107 90° 0.075 0.329 -3.220 -0.012 -0.347 -0.155 -0.268 0.183 0.001 0.121 -0.558 -0.002 -0.126 0.534 135 0.007 0.377 -4.037 -0.014 -0.418 -0.519 -0.301 0.784 0.000 0.107 -0.491 -0.003 0.185 0.801 180° -0. -0.007 -4.738 0.000 -0.469 -0.748 0.005 1.160 -0.002 -0.080 0.350 -0.002 0.084 0.370 55.6 00 3.204 -0.115 2.519 0.008 -0.502 6.470 0.070 - 10.798 0.009 0.267 -1.299 0.011 -0.472 -2.204 45 3.129 -0.067 2.363 -0.006 -0.493 6.499 0.807 - 10.855 0.006 0.363 -1.689 0.011 -0.203 -0.987 90° 0.079 2.327 -2.872 -0.084 -0.327 - 0.653 -1.913 1.017 0.011 0.957 -4.296 -0.011 0.819 3.571 135 -0.404 2.667 -8.686 -0.098 - 0.832• -3.241 -2.153 5.292 0.007 0.859 -3.818 -0.018 1.237 5.469 180 -0 -0.060 - 13.669 -0.001 -1.199 -4.871 0.026 7.969 -0.011 -0.472 2.167 -0.011 0.525 2.405 Table -7 '7.6M ANTENNA LOAD ON EACH BASE ANTENNA ATTITUDE CONDITION DEL = 40 WIND: V = 0 m/s (DEAD LOAD) Oy = 0° . V = 20.8 m/s (75 1M /H) V = 55.6 m/s (200 KM /H) WIND DIRECTION: 0 -180° UNIT: TON(X,Y,Z) , TON - M(Mx,My) �,..�..,.«.,. i.....�.,..,J .:rn • s•c.s ; rz;v =h. b7 ,:4�� 6;3k 'u) V P BASE 1 BASE 2 BASE 3 BASE 4 X Y Z Mx My X Y Z X Y Z X Y Z r 0 m/s 0 0.083-0.038 -3.19D-0.002-0.344 -0.083 -0.052 0.062 0.000 0.057 -0.276 -0.001 0.063 0.259 20.8 0° 0.499-0.427 -2.433 0.015-0.366 0.778 0.069 -1.363 0.000 -0.069 0.271 0 002 -0.165 -0.764 45 0.500-0.420 -2.421 0.012-0.364 0.813 0.175 -1.422 0.000 -0.049 0.187 0.002 -0.125 -0.583 90° 0.109 0.306 -3.07 -0.014-0.341 -0.108 -0.327 0.106 0.002 0.203 -0.927 -0.002 0.177 0.757 135 0.045 0.377 -3.848-0.019-0.408 -0.445 -0.350 0.663 0.002 0.239 -1.082 -0.004 0.281 1.224 180° -0.065 0.020 -4.595-0.009 -0.724 -0.038 1.122 0.000 0.090 -0.409 -0.003 0.225 0.991 55.6 0 3.041 -2.806 2.194 0.116-0.499 6.037 0.805 - 10.078 0.001 -0.844 3.617 0.018 -1.560 -7.019 45 3.051-2.760 2.283 0.100-0.484 6.284 1.557 - 10.496 -0.001 -0.701 3.017 0.018 -1.275 -5.730 90° 0.265 2.407 -2.347-0.090-0.318 -0.265 -2.010 0.376 0.012 1.091 -4.903 -0.011 0.875 3.805 135 0 :185 2.908 -7.870 -0.126-0.79q -2.664 -2.174 4.338 0.011 1.350 -6.008 -0.020 1.614 7.123 180 -0.971 0.371-13.182 -0.049-1.3.51 -2.647 0.048 7.602 -0.005 0.291 -1.222 -0.016 1.217 5.465 . Table -8 7.614 ANTENNA LOAD ON EACH BASE ANTENNA ATTITUDE CONDITION °EL = 40° WIND: V = 0 m/s (DEAD LOAD) ay = +20 : V = 20.8 m/s (75 KM /H) V = 55.6 m/s (200 KM /H) WIND DIRECTION: V = 0 ° -180 ° UNIT: TON(X,Y,Z), TON- M(Mx,My) V BASE 1 BASE 2 BASE 3 BASE 4 X Y Z Mx My X Y Z X Y Z' X Y • Z 0 m/s 0 0.045 0.042 -3.280 0.002 -0.341 -0.044 0.054 -0.003 -0.001 -0.083 0.357 0.000 -0.044 -0.208 20.8.` 0° 0.463 0.399 -2.497 -0.012 -0.361 0.831 -0.047 -1.454 0.001 0.120 -0.555 0.001 0.054 0.212 45 0.440 0.396 -2.549-0.014 -0.359 0.811 -0.057 -1.421 0.001 0.121 -0.558 0.031 0.085 0.351 90 0.026 0.332 -3.276 -0.008 -0.408 -0.177 -0.203 -0.219 0.000 0.036 -0.178 -0.001 0.058 0.239 135 -0.045 0.354 -4.081 -0.007 -0.408 -0.536 -0.247 -0.812 -0.001 -0.026 0.105 -0.002 0.067 0.283 180° -0.101-0.032 -4.701 0.008 -0.457 - 0.690 0.047 1.063 -0.003 -0.239 1.060 -0.001 -0.068 -0.302 55.6 0 3.019 2.583 2.290 -0.101 -0.480 6.182 -0.664 - 10.320 0.016 1.361 -6.130 0.002 0.654 2.780 45 2.856 2.562 1.919 - 0.110 -0.471 6.033 0.076 - 10.083 0..013 1.374 -6.149 0.003 0.870 3.771 90° -0.091 2.109 -3.252 -0.072 -0.324 -0.992 -1.778 1.579 0.009 0.767 -3.450 -0.010 0.683 2.976 135 -0.593 2.265 -8.974 -0.063 -0.063 -0.814 -3.546 -2.090 0.002 0.323 -1.433 -0.015 0.743 3.287 180 -0.989-0.482-13.385 -0.047 -0.047 -1.166 -4.639 -0.001 -0.016 -1.191 5.358 -0.006 -0.216 -0.877 Table -9 7.6M ANTENNA LOAD ON EACH BASE ANTENNA ATTITUDE eEL = 40 8 Y = - 20 ° CONDITION WIND: V = 0 m/s (DEAD LOAD) V = 20.8 m/s (75 KM/H) V = 55.6 m/s (200 KM /H) WIND DIRECTION: 9' = 0 -180 UNIT: TON(X,Y,Z), TON - M(Mx,My) yc:.:m >:c• ,�...... a.u. i,... ,- i.:..,, >,_.i ... -�:� ... • V f BASE 1 BASE 2 BASE 3 BASE 4 X Y Z Mx My X Y Z X Y Z X Y Z . 0 m/s 0 -0.106 0.002 -2.553 0.000 -0.268 0.105 0.001 -0.245 0.000 0.003 -0.168 0.000 -0.036 -0.184 20.8 O o 0.144 0.000 -2.259 0.000 -0.300 0.830 0.004 -1.444 0.002 0.086 -0.420 0.002 -0.104 -0.500 45 0.040 0.093 -2.007-0.005 -0.239 0.684 -0.009 -1.201 0.002 0.158 -0.738 0.001 -0.034 -0.187 90° -0.092 0.209 -2.464-0.012 -0.264 0.032 -0.179 -0.122 0.002 0.189 -0.870 -0.001 0.101 0.418 135 -0.130 0.179 -3.179-0.010 -0.343 -0.221 -0.138 0.294 0.001 0.135 -0.622 -0.002 0.126 0.536 180° -0.151 0.003 -3.746 0.000 -0.407 -0.362 -0.002 0.524 -0.001 -0.030 0.121 -0.001 0.037 0.152 55.6 0 1.668-0.016 -0.462 0.004 -0.496 5.261 0.021 -8.771 0.010 0.417 -1.962 0.011 -0.523 -2.433 45 0.934 0.684 1.329-0.038 -0.059 4.223 -0.070 -7.043 0.013 0.928 -4.220 0.007 -0.021 -0.204 90° -0.008 1.475 -1.923-0.083 -0.239 -0.418 -1.282 -0.631 0.011 1.149 -5.158 -0.010 0.938 4.095 135 -0.275 1.261 -7.0 -0.801 -2.215 -0.992 3.587 0.004 0.765 -3.399 -0.014 1.116 4.939 180 -0.428 0.005 -1L038-0.002 -1.255 -3.218 -0.026 5.225 -0.009 -0.413 1.889 -0.010 0.483 2.203 Table -10 .7.6M ANTENNA LOAD ON EACH BASE ANTENNA ATTITUDE CONDITION 6EL = 60 HIND: V = 0 m/s (DEAD LOAD) 01 = 0 : V = 20.8 m/s (75 KM /H) V = 55.6 m/s (200 KM /H) HIND DIRECTION: 9V = 0 ~180 UNIT: TON(X,Y,Z), TON - M(Mx,My) V , f BASE 1 BASE 2 BASE 3 BASE 4 X Y Z Mx My X Y Z X Y Z X Y Z 0 m/s 0 -0.086 -0.03S -2.459 -0.003 -0.264 0.085 -0.049 -0.210 0.001 0.113 -0.532 0.000 0.017 0.046 20.8 0° 0.153 -0.357 -2.172 0.013 -0.294 0.770 0.037 -1.344 0.001 -0.005 -0.023 0.002 -0.217 -1.004 45 0.062 -0.11E -1.912 0.002 -0.235 0.664 -0.038 -1.165 0.002 0.114 -0.549 0.002 -0.107 -0.514 90° -0.061 0.185 -2.345 -0.015 -0.260 0.055 -0.236 -0.160 0.003 0.282 -1.287 -0.002 0.156 0.654 135 - 0.103 0.130 - 3. - -0.335 -0.191 -0.157 0.246 0.002 0.256 -1.165 -0.002 0.206 0.885 180° -0.136 - 0.078 -3.619 -0.006 -0.397 -0.365 0.017 0.531 0.000 0.108 -0.498 -0.002 0.142 0.610 55.6 0 1.615 - 2.300 -0.416 0.108 -0.480 4.960 0.561 -8.272 0.002 -0.726 3.091 0.018 -1.650 -7.423 45 0.970 -0.600 1.432 0.032 -0.060 4.201 0.027 -7.004 0.008 0.120 -0.653 0.012 -0.863 -3.941 90° 0.091 1.556 -1.651 -0.091 -0.233 . -0.125 -1.380 0.149 0.013 1.313 -5.900 -0.010 1.001 4.360 135 -0.205 1.161 -6.603 - 0.091 - 0.770• -1.877 -0.814 3.032 0.007 1.130 -5.033 -0.015 1.360 6.008 180 0.440 -0.318 - 10.071 -0.024 -1.210 -3.118 0.423 5.062 -0.006 0.076 -0.286 -0.011 0.902 4.052 - ANTENNA ATTITUDE CONDITION DE = 60 MIND: V = 0 m/s (DEAD LOAD) ey = +20 : V = 20.8 m/s (75 KM/H) Y = 55.6 m/s (200 KM /H) MIND DIRECTION: 9' = 0 ~180 UNIT: TON(X,Y,Z), TON - M(Mx,My) r:4tUR.ZA f::.: :a r:.wat..;q L- br:�.•.� s:tiri_� .1 :4.i;. as• 1 .....- .w...� V V BASE 1 BLSE 2 BASE 3 BASE 4 X Y Z Mx My X Y Z X Y Z X 1 Z 0 m/s 0 -0.137 0.04: -2.585 0.003 -0.260 0.137 0.052 -0.298 0.000 -0.044 0.174 0.001 -0.094 -0.435 20.8 00 0.101 0.356 -2.289 -0.012 -0.289 0.827 -0.028 -1.440 0.002 0.178 -0.819 0.001 A 0.009 0.008 45 -0.002 0.303 -2.068 - 0.012 -0.232 0.660 0.023 -1.162 0.002 0.195 -0.893 0.001 0.326 0.112 90° -0.131 0.218 -2.517 -0.007 -0.257 • 0.022 - 0.120 -0.107 0.001 0.092 -0.433 0.000 0.030 0.109 135 -0.170 0.215 -3.221 - 0.005 -0.334 -0.221 -0.119 0.293 0.000 0.013 -0.074 -0.001 0.028 0.105 180 0 -0.186 0.084 -3.753 0.005 -0.395 -0.317 -0.023 0.448 -0.002 -0.158 0.695 0.000 -0.078 -0.353 55.6 0° 1.561 2.268-0.479 -0.101 -0.467 5.047 -0.515 -8.418 0.017 1.531 -6.888 0.640 2.719 45 0.822 1.892 1.096 -0.104 -0.057 3.858 -0.156 -6.442 0.017 1.653 -7.417 0.001 0.804 3.459 90° -0.091 1.285 -2.103 -0.070 -0.238 -0.678 -1.170 1.059 0.009 0.922 -4.143 -0.009 0.787 3.433 135 -0.368 1.264 -7.104 - 0.053 -0.786 . -2.406 -1.160 3.902 0.002 0.359 -1.589 -0.012 0.769 3.411 180 ° -0.486 0.3306- 10.888 0.019 -1.215 -3.087 -0.477 5.009 -0.011 -0.861 3.881 -0.007 0.020 0.153 Table -12 7.614 ANTENNA LOAD ON EACH BASE ANTENNA ATTITUDE 8 EL= 60° OT = -20° CONDITION WIND: V = 0 m/s (DEAD LOAD) V = 20.8 m/s (75 EM /H) V = 55.6 m/s (200 KM /H) WIND DIRECTION: 9' = O -180 UNIT: TON(X,Y,Z), TON - M(Mx,My) Table - 13 7.6M ANTENNA:MAXIMUM LOAD ACTING ON EACH BASE 1 • NEC 7 1.1 ANTENNA: MAXIMUM LOAD ACTING ON EACH BASE 1 AT WIND LOAD OF 125 MPH • FORCE AND MOMENT SIGN MAX. LOAD ANTENNA ATTITUDE AND WIND DIRECTION; 0 EL 0 iYi . WIND YAW ANGLE BASE 1 -. X ( LB ) + 12154 . 0 0 deg. 0 deg. 0 deg. - 7206 . 8 0 0 180 Y ( LB) + 117 54 . 9 0 +20 135 - 9781.4 0 0 +20 0 45 0 Z ( LB) 4 ' 20866.5 31375.9 20 0 180 MX 'LB) + 853 . 5 0 +20 45 954 7 20 +20 135 MT (FLB) + - - - - • 8_672 . 2 16404.4 40 0 0 0 180 45 BASE 2 X ( LB \ + - 12D7 . 8 20 0 180 y ( LB) + • 3919 . 8 0 +20 45 - . 7 0 1 9 . 4 0 +20 . 135 Z ; LE) + 19875 20 0 60 0 180 - . 27486.9 0 -20 45 0,45 BASE 3 • X ( LB) + 37 - 35.3 40 -20 180 , Y ( LE) + 60 -20 45 - 7629 40 -20 180 % Z ( LB] + -11812 . 2 .40 -20 180 - 16351.9 60 -20 45 • BASE 4 N X ( LB/ + 39 40 +20 0,45 - . 44 1 40 +20 135 , Y ( LB) + 3558 40 +20 135 - •3637.6 60 +20 0 Z ( LB) + 15703. 4 40 60 +20 +20 135 0 - 16364 . 7 LB = POUND FORCE FLB = MOMENT-FOOT POUNDS 0EL 01* I§ 4 ' 410614 • fil 0 iffAit WIND • IPA:16,-'‘ • , Mx 1 , . I • .1 ■ 1 My (a - tit im ,,,) SATELLITE BUSINESS SYSTEMS SUMMARY SHEET ENGLISH SYSTEM H �l site plan TO /.141101t LOCAT. OV .co OMAN= FACILITIC1 :.•. . .L TWIN • 0 I* THIS INCH 1 2 EXISTING GE FACILITY , 1 • • • 115 .• NTS. FLEXIBLE RULER - 3 0 2 AW 1 • tf) GENERAL NOTES . • 1. 111. LENCEN 1101) • 2. IFL corosyrica • • A. iI-1/4" CEA1102. CRAM 00 1bs/1CO UOI E.. 1.11 FAIR CABLE 180 Ibs/100' C. I-II PAIR CAKE 117 1b4/100' S. IFL CONVEYANCE A. EXTERIOR NURIED CONDUIT r EIPOSED FLEHILt SEAL TIGIR CONDUITS I. INTERIOR - UNDER RAISED 2t000 . • . t. PILL NIXES (IT NEEDED) . ANGLE IOIES • 14•12411 STRAIGHT IDIES 24•112 • 4. IIINIDUR NADIuS • 74* 3 • 4 5 6 7 8 t. Oe 6Z Be LZ 9Z GZ VZ EZ ZZ 1Z OZ 6L Ell a 91 GI VI 'Et • Zt 11 01.1:', 1 0101 1 -0 1 0R 11 ,4 1 .01.1tIgAIIIIIIM1 1 44 1111 11 1 ,0 111 ,1 1 ! 11 (11j111111,1.1.11 1 ,011.111Till‘4441•11g41.401,Y17,11,111111.1110,11.11!! : ' : k PROPOSED SBS EOUIPMEr.ROOM.: WM STAMM • HipanswwwoBIALDWN 411‘0 I — cawrrAtacx 7 oA • - ;. ; • •• . • • I • . • ; •: . • • • • , • . • PROATATT LAt u0cAlr-os • x z 35 • AnswasCoNolnwas 17•w.ss• 122•13•03• w. LW. • UM 1,40 wow A4,1578 TV NE .461111jw. OM MINES hog. 0,21212. [ VS21 10• W. Lan. fr W. Lane. W. W. Lane. WV W. Long. • 101.w. Lorq. Pwww1 Raman 131• 42' or Woo. •••• 14 211•01'51 30•11 31 37'42'47* \ 0 )9( / . . . • . NEC 7.6 ANTENNA ' - (1.10(DO111 NO. $10•004012. • Pool, COMMAICt APPOOXIMATOX 07W . ••■•• ■••■ TELCO COMVEYNKS APPPDXIMIITELT J11104:r1:: SCA 1 OATS. T7Tlt SATELLITE BUSINESS SYSTEMS 82530REENS8ORO DRIVE. McLEAN, VA 2•2102 • Amao., geow1014.....wwwrr 60,7 CONII4CT RFT AND IFL LAYOUT-PLAN SEATTLR,'WA. • IF THIS MICROFILMED DOCUMENT IS LESS .CLEAR THAN THIS NOTICE, IT IS DUE TO I THE QUALITY OF THE ORIGINAL DOCUMENT CC01114X10. • • • 4w<tettstatat-....,........ -.117 / ; I tri .4^ TSW ".YA orr • .1 4„. SCC 1 4 1 • 1 WORK . BENCH I STORAGE CABINET. 10'-8" _ t+Atir.riLE HERE. STEP A/C UNIT .. + ' .'... 7.p".. i L . rNes F.7 o' / 0 4.7 4..7 77 17 '''''''''. -, . , ("1 i41 , ./lat • V. a3t6 .4 Ka' • • .9 • ' ; . • RS Emil DESK S C C o . , STORAGE ' CABINET 1 +is 23'78" . _ . • - 0IfropTili)rfoliffrirfiTipirfrfirrrollill Yip 0 INCH 2 3 cDuj FEY VPA .Aux C A 'o DTA 0. C A 1' — PAS' AUX I L --SA =ETV: RAIL A ir 7 ' 3? , r — — 7 1 UK* 1 — 1 1 1 mDF. • 274"9Xe" NIPPLES trivirotitiflit 7 FLEXIBLE RULER - 302AW 3 . t'"Itt:ITIA5V;FLI . r eze- , C■14; " . ••••;'. :"Tt14,1'41 ' :171 r „R, 11 1A1T. OOM_. EYE n WASH RECT. , 1 A PAS 4 BATTERIES RECT 1;43 ' STEP alt4DITIONED POMP. PANEL UNCONDITIONED POWFR PANEL. • 0 0 rX 11 • 1 2 ') PAT' ro n 5 6 TITLE: SCALE: ' 1/4". '-0" DATE: 9- le4 4,44 , '"re..7. 0 .4.W . V,' 'tt . • " ' SITE: GE . GE SEATTLE;: WA. SATELLITE BUSINESS SYSTEMS 8283 GREENSBORO DRIVE, McLEAN, VA. 22102 APPROVED BY: CONTRACT NO : spg "3 I oad EQUIPMENT ROOM LAYOUT DWG. NO.: 1 605,70:0 A. ' IF THIS MICROFILMED DOCUMENT IS LESS ! ' DRAWN CODE IDENT.: REV.: SHEET 'IN. • .1101'; • CLEAR THAN THIS NOTICE, IT IS DUE TO. I THE QUALITY OF THE ORIGINAL DOCUMENT' A I TO APPROX LOCAT.' OF TELCO ENTRANCE 'FACILITIES EXISTING GE FACILITY GENERAL NOTES 115 -0" N•T.S•, 1. 1FL LENGTH - so! =o''. 2. IFl COMPOSITION' A. 6 -1/4" COAXIAL CABLES ' 60 lbs /100' EACH B:, 1 -18 PAIR CABLE 180 lbs /100' C. . 1 -9. PAIR CABLE,' 117 1bs /100' .3. IFL CONVEYANCE A. EXTERIOR - BURIED. CONDUIT 3" - 'EXPOSED FLEXIBLE'SEAL -TIGHT CONDUIT 3" B,: INTERIOR • - UNDER.RAISED'FLOOR' C. PULL BOXES (IF. NEEDED) . - ANGLE BOXES - 24 "024 "X8 "''; • - STRAIGHT BOXES - 24 "X12 "XB" q,. MINIMUM BENOING:RADIUS - 24" r MrT,f'71 '04071. 195' -0" PROPOSED SBS' EOUIPA'1ELVT ROOM (FREE STANDING • PRE - ENGINEERED BUUILDINO)' ' ROOM PROPERTY LINE (N- 0"- 12'- 09659.510 • 'AntannaCootdlnatN' 47 °77'3A" - N Lat 122 °15'03" VV,Lg1Q. • USOSMIIPNUmbar AMS 1578 IV NE - SERIESntla DES MOINES Map Mag Dec 21' 1/2° E, V891 a.ros Pos Uon . • 70' W. Long. 9Y° W. Long. , 97• W. Long. i 100• 1N. Long. • ,108• W. Long, • Padostal Azimuth Two North Azimuth 119 ° 42'14" - .141°38'15" • 147.22'32" 150 °57'28" 160.58'50 136° 42' 08" ' llmtlo AngI 16 °05'38 ". • 28 °03'51" ••30 °11'05" 'r '31 °18'44 "'c 33.42'4 SHELTER A1, NEC. 7.6 ANTENNA .(SEE 110.250- 00401);; NOTE: DATE: ;a -15 -1112 TITLE: SATELLITE BUSINESS' SYSTEMS: 8283 GREENSBORO DRIVE; McLEAN,.VA 221021Y APPROVED BY: / '}? • CONTRACTNO.: P RAWN 5YI.624/ 7 & 1 Ill Ili III 1 11111 lit 111 Ijl I(1 [h ill Ill 111 11)'11 l�l I(1 ICI 111 11l ll Ill lit111 1fl IIT TOTITITII Ijl ( i � .," 1I 111 lit ; I l 1 ..I � . I I I Ijl i L . �. � (. I .. . � i I - . 16 _. . i . �... �, T . , OE 6z DE L6 9Z 9E VZ CZ ea IZ OZ 01 el LI 91 9I VI 'CI ZI II 01 1IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIINI .IIII1III!lDlll! 1.41 IN1111111I111111 11111101111I1UIIIIIIIIIIII111111IIIIIIIIIII, NIINIII1141111IIIIIIIIAIIIII1111II11111111111I1I11111111111lplllll 2 IF THIS MICROFILMED DOCUMENT IS LESS: CLEAR THAN THIS NOTICE, IT IS DUE TO THE QUALITY OF THE ORIGINAL DOCUMENT; i l Am,7.iF.InPSt, �t' Zy. A