Related Manuals for Optex Fiber SenSys Terrain Defender TD 100
Summary of Contents for Optex Fiber SenSys Terrain Defender TD 100
- Page 1 ™ Terrain Defender ™ TD100 Installation Manual Confidential – Limited Distribution PM-ENG-090 Rev A...
- Page 2 ® © Copyright 2021, Fiber SenSys , Inc. all rights reserved. No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopy, recording, or any information storage and retrieval system, without permission in writing from Fiber SenSys, Inc. This manual is provided by Fiber SenSys, Inc.
- Page 3 FCC Interference Statement (Part 15.105 (b)) This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a residential installation. This equipment generates, uses, and can radiate radio frequency energy and, if not installed and used in accordance with the instructions, may cause harmful interference to radio communications.
- Page 4 ISED Compliance Statement – Canada Fiber SenSys Inc. has not approved any changes or modifications to this device by the user. Any changes or modifications could void the user’s authority to operate the equipment. Fiber SenSys Inc. n’a approué aucune modification apportée à l’appareil par l’utilisateur, quelle qu’en soit la nature.
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Page 5: Table Of Contents
Table of Contents Introduction ......................8 Theory of Operation ..................9 Site Overview ....................11 Safety ........................ 20 Restricted Access ..................20 Electrical Safety .................... 20 Covers and Panels ..................20 Inspection ..................... 21 System Planning ....................22 Installing Sensor Cable ..................24 Cable installation overview ................ - Page 6 • Step 20 .................... 50 • Step 21 .................... 50 • Step 22 .................... 51 SUMA Flash Testing ..................52 • Step 1 ....................52 • Step 2 ....................52 • Step 3 ....................53 • Step 4 ....................53 TDR8 Relay Module ..................
- Page 7 Grounding ......................79 Product Specifications ..................80 TD100™ Processor ..................80 TDR8™ Relay Module .................. 80 TD24PSU ..................... 81 TD48PSU ..................... 82 Terrain Defender Sensing Cable (TDSC) and Lead-in Cable ......83 TD Enclosure ....................83 Glossary of Technical Terms ................84 Confidential –...
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Page 8: Introduction
1. Introduction TD100™ is a covert buried line intrusion detection sensor. It utilizes two parallel leaky coaxial cables to create an invisible electromagnetic field that follows the cables around corners and up and down hills. The transmit (TX) cable creates a field that couples into the parallel receiver (RX) cable. -
Page 9: Theory Of Operation
Theory of Operation The basic concept behind E2EC is illustrated in Figure 2. TD100 #1 TD100 #2 Lead-in Lead-in Cable Cable More Sensor In-Line In-Line TX Cable Cables in Connections Connections Networked System RX Cable Figure 2. System E2EC The leaky coaxial sensor cable is a standard coaxial cable with an aperture or a continuous slot in the outer conductor to allow Radio Frequency (RF) energy to couple between the signal traveling inside the cable to a surface wave traveling outside the cable but bound to the cable. - Page 10 TD100 #2 TD100 #1 Terrain Defender Sensing Cable (TDSC) TX 2 TX 1 RX 2 RX 1 Uniform Sensitivity RX 1 Response RX 2 Response Figure 3. End-to-End Correlation (E2EC) The E2EC process takes into account the complex product of the signal seen from both ends of the cables.
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Page 11: Site Overview
The blue ovals depict contours of equal sensitivity. The thresholds are typically set to detect a person up to 1 meter above ground and 0.5 meters on either side of the cable pair. A TD100 system is composed of the following components: •... - Page 12 The RF Ports of each processor are terminated by one of the following • Sensor cable with a processor at both ends of cables • SMA terminator on TD100 TX/RX ports • Sensor cable with End of Line Terminators (EOLT) There are many possible combinations of the above configurations to describe a perimeter and the mode of operation when one considers the possible ways to terminate a processor.
- Page 13 or TD48PSUs along the perimeter to provide additional redundancy in a power supply failure scenario. These redundancies would adapt for an open circuit or short circuit cable fault. E2EC is unique to Terrain Defender products. E2EC describes a means of processing response information from both ends of the cables in a process referred to as Dual-Ended operation.
- Page 14 ◄RX2 RX1► ◄RX2 RX1► ◄TX2 ◄TX2 TX1► TX1► Figure 7. Processor Termination When only one TX/RX pair of a processor is being used, the other pair should have SMA terminators installed. As previously described Single-Ended operation allows TD100 to provide Fail-Safe operation. Other leaky coaxial cable sensors on the market today all operate in Single-Ended Mode.
- Page 15 Master Network TD24/48PSU Controller TD100 (24 or 48VDC) Ethernet PC/WUI Lead-in Cables Redundant Power (TX/RX in separate conduits) Coil of excess Lead-in SUMA Start-up Module Sensor Cables Assembly SUMA Start-up Module Figure 9. Connections to the TD100 The TD100 processor connects to the sensor cables using factory-made lead-in cables. The lead-in cables are 10 m (30 ft) long, with connectors and ferrite beads attached.
- Page 16 Figure 10. TD100 inside optional TD Outdoor Enclosure Each lead-in cable connects to the sensor cable inside the SUMA, a waterproof enclosure. The SUMAs are installed “in-line” with the sensor cables. The connections inside the enclosures are made utilizing a Start-Up Module (SUM). The SUM uses spring-loaded lever-action terminal blocks to make the power and sensor connections, then an SMA bulkhead for the lead-in connection.
- Page 17 10Ω Earth to TD24/48PSU TD100 Ground resistance (24 or 48VDC) Ground Rod/Plate SUMA Ground Rod/Plate Centered between SUMA SUMA Figure 11. System grounding Power is provided to the sensor cables at the SUM. For Fail-Safe operation, DC power is supplied independently to the TX and RX cables. Each processor collects its power over the lead-in cables with a diode “OR”...
- Page 18 Voltage drops as power passes down the Terrain Defender Sensor Cable (TDSC) from each TD100 TD24PSU can power up to 3 units TD48PSU can power up to 6 units TD24PSU TD48PSU TD100 TD100 TD100 TD100 TD100 TD100 Middle (48VDC) Lead Middle Middle Middle...
- Page 19 This Introduction to TD100 provides the background for the reader to be ready to understand and appreciate the detailed information provided in the following manuals: 1. Installation Manual – Describes how one should design and install TD100 at a specific site.
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Page 20: Safety
2. Safety As comprehensive as these manuals are, TD100 is intended to be installed by trained professionals having experience in security system construction and safety. The following icons may appear throughout this manual: CAUTION: Identifies conditions or practices that could result in damage to equipment and/or loss/contamination of data. -
Page 21: Inspection
Inspection The TD100 should be inspected for shipping damage. If any damage is found, notify Fiber SenSys and file a claim with the carrier. Save the shipping container for possible inspection by the carrier. FCC Rules Note: FCC Part 15 Clause 15.21: “Changes or modifications not expressly approved by the party responsible for compliance could void the user's authority to operate the equipment.”... -
Page 22: System Planning
3. System Planning Survey the Site Every site is unique, and each with its challenges. To ensure the best performance of the TD100 system, this section will help guide you through the process and provide you the tools needed for the best design and solution. Note: Please contact Fiber SenSys to help you with your TD100 site design As comprehensive as these manuals are, the TD100 is intended to be installed by trained professionals. - Page 23 Site Desired Security Level o Is TD100 being used as part of a layered perimeter security system? o Detection flow – will the system be detecting intruders from outside to in or inside to out? o What is the desired primary detection target? Nuisance Sources o Moving vehicles within 3 m (10 ft) o Going under fences or within 2 m (6.6 ft)
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Page 24: Installing Sensor Cable
4. Installing Sensor Cable Cable installation overview System performance starts with the proper installation of the sensor cables. To install the cables and cable fittings, perform the following steps in order: • Verify the site plans, cable routing, and note potential hazard areas from the check-list provided earlier, such as;... -
Page 25: Planning The Cable Installation
Figure 15. Cable Plow (left) and Walk-behind Trencher (right) Planning the Cable Installation TD100 sensor cables must maintain a minimum spacing of 1 m (3.3 ft), and maximum of 2 m (6.6 ft). Spacing throughout the sensor run must be consistent. 1.5 m is standard for all military applications. -
Page 26: Width Of Sensor Cable Trenches
Width of sensor cable trenches o Using a cable plow, the cutting blade should be at a minimum, twice the width of the outer diameter of the sensor cable. ▪ Cable diameter: 16.39 mm (.65 in) ▪ Plow blade diameter width (minimum): 32.8 mm (1.3 in) ▪... -
Page 27: Soil
Soil Burial depths are dependent on soil type, asphalt, crushed stone, and concrete. o Standard soil is the simplest of mediums to install. Maintain 23 cm (9 in) burial depth. o There are various clay soil consistencies. Knowing which you are working with will help when planning the site civil work and TD100 components. -
Page 28: Crushed Stone
o If the asphalt layer is <10 cm (<4 in), a 23 cm (9 in) burial depth is acceptable unless clay is present, then that would need to be factored in. Work with a Fiber SenSys Support Representative to determine the best method when installing TDSC. o If the asphalt layer is >10 cm (>4 in), reduce the burial depth equally every additional inch up to 16.5 cm (6.5 in). -
Page 29: Concrete
o If the crushed stone layer is >10 cm (>4 in), reduce the burial depth equally every additional inch up to 16.5 cm (6.5 in). For example, 12.7 cm (5 in) top cover in crushed stone would require 20.3 cm (8 in) burial depth, 2.5 cm (1 in) additional crushed stone reducing the total burial depth by 2.5 cm (1 in). - Page 30 Deployment Medium Depth Diagram Soil 23 cm (9 in) Moderate to heavy 10 cm (6 in) clay soil (If needed, adding an additional TD100 Processor will improve performance in these conditions.) Asphalt or crushed 23 cm (9 in) stone that is <10 cm (>4 in) thick Asphalt or crushed Reduce sensor...
- Page 31 Concrete >10 cm (>4 6.4 cm (2.5 in) Transition from 6.4 cm (2.5 in) concrete to soil concrete side transitioning to 23 cm (9 in) over a span of 76 cm (30 in) Figure 22. Burial Depth Table Confidential – Limited Distribution Page 31...
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Page 32: Start-Up Module Assembly (Suma) / Start-Up Modules (Sum)
5. Start-Up Module Assembly (SUMA) / Start-Up Modules (SUM) The TD100 product uses a standard, modified coaxial cable sensor element. The cable has two outer jackets separated by a flooding compound designed for direct burial. Beneath the two jackets, there is an outer conductor which has two parts; a foil tape that allows for a slotted aperture and a braided conductor that provides a low resistance DC path to accommodate power supplied over the cable. - Page 33 There is passive circuitry inside the SUM that connects the RF from the lead-in cable to the leaky sensor cable, providing lightning suppression and 24 or 48VDC power over each sensor cable. In most applications, there are two SUMs inside a SUMA to support sensor cables going in opposite directions.
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Page 34: Preparing Installation Of Start-Up Module Assembly (Suma) To Td100 Processor Connection
Jacket: Thermoplastic Elastomer Overall Braid: Tinned Copper Center Conductor: Solid Bare Copper 6.10 mm 4.52 mm 3.94 mm 3.81 mm 1.42 mm Dielectric: Foam Polyethylene Outer Conductor: Aluminum Tape Figure 26. Lead-in Cable Overview (Cross Section) The TD100 system was designed so that the sensor cable can be installed around the entire perimeter and then TD100 and SUMA units added after installing where they are needed to meet soil conditions or site infrastructure locations with its in-line processing design. - Page 35 Ground Rod Figure 27. Trenches and Grounding Rod between BSEs Figure 28. Sensor cables and lead-in cables in place Start-Up Module Assembly locations In this example, the SUMAs have sensor cables entering from both directions, requiring two SUMs inside each for the TX and RX cables. The ground rod or plate should have 10 Ω resistance maximum;...
- Page 36 Figure 29. TX and RX SUMA The bend radius for the lead-in cable is 9 cm (3.5 in). This should be adhered to for the coils of spare cable at the SUMAs and inside the processor enclosure. The coils of spare cable at the SUMA need ferrite bead clamps applied, as shown in, Figure 30.
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Page 37: Start-Up Module Assembly (Suma), Start-Up Module (Sum), And Sensor Cable Preparation And Installation
Start-Up Module Assembly (SUMA), Start-Up Module (SUM), and Sensor Cable Preparation and Installation Figure 32. Tool Kit contents Step 1 Remove the cover and endplate caps from the SUMA. Figure 33. SUMA with cover and endplate caps being removed Step 2 Remove two cable port tabs offset from one another for example, top left port and the lower right port. -
Page 38: Step 3
Figure 34. SUMA tab removal Step 3 The cable is cut in the middle of the SUMA location to create two cable ends. A coaxial cable cutter should be used. Figure 35. Coaxial Cable Cutter Rotate the tool around the sensor cable as you apply pressure. It only requires a small amount of pressure to cut through the jackets, the outer conductor, and the heavy copper- clad aluminum center conductor. -
Page 39: Step 5
Remove one of the two seven-entry silicon grommets provided in the SUMA kit. Pull the sensor cable through the large center hole from the outside of the grommet, which does not have the markings for cable sizing, through to the inside of the grommet, which has sizing information. -
Page 40: Step 6
Step 6 Using the TD100 Coax Cable Strip Template seen in, Figure 40, cut through the outer PVC jacket from the end of the cable 75 mm (3 in) using the adjustable blade ringer, Figure 41. Figure 39. Stripping the sensor cable using the DW-ENG-51 template It is preferable to score the second polyethylene (PE) jacket but DO NOT cut through the second jacket. -
Page 41: Step 7
Figure 41. Adjustable Blade Ringer Step 7 Twist the outer PVC jacket and remove it from the sensor cable. This will expose the second jacket, which will be covered in flooding compound. The flooding compound can be easily removed using a cable gel solvent. The flooding compound is to seal any pin holes in the outer jacket resulting from direct burial. - Page 42 Shield Slot Figure 44. Cable end shield slot identification Confidential – Limited Distribution Page 42...
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Page 43: Step 9
Step 9 Using a pair of pliers, tear off the second layer of polyethylene jacket where it was scored to expose the slotted shield and drain wire. Figure 45. Second jacket slit from cable end to first strip location, outer jacket Step 10 Fold back the braided drain wire, then measure 16 mm (0.63 in) from the outer jacket and cut the remaining 59 mm (2.32 in) off the shield and foam dielectric using the second... -
Page 44: Step 11
Figure 46. Setting the second adjustable blade ringer to a safe cutting depth Figure 47. Ring cutting the shield and foam dielectric with adjustable blade ringer tool placed on the material to be removed CAUTION: The cable shield and drain wire must not contact the center conductor, which will cause a short on the system. -
Page 45: Step 12
Figure 48. Marking the center conductor (top); the finished center conductor cut to length (bottom) Step 12 Separate the drain wire into two equal portions and twist as shown in Figure Figure 49. Equally divided drain wire and trimmed center conductor Confidential –... -
Page 46: Step 13
Step 13 Remove the lid from the Start-Up Module (SUM) by removing the screws on the two-hole sensor clamp. Set it aside, being careful not to lose the screws. Figure 50. Removing the SUM lid Step 14 Flip-up the large orange lever of the center conductor terminal block and the two smaller levers on each side of the large center block. -
Page 47: Step 15
Step 15 Connect lead-in to SMA female onto the board with fingers. These have fine threads, so care should be taken when beginning to screw connectors on, do not cross-thread. Once the connector is finger tight, use the 5/16 in (8 mm) wrench, turn until the connector is snug. -
Page 48: Step 18
Verify that there are no strands of drain wire or shield shorting to the center conductor and that the connections are secure. Ensure the drain wire is positioned at the top of the sensor cable. The SUM lid has an indent centered on the clamp to accommodate the drain wire. Carefully place the SUM cover onto the lower chassis making sure to align the clamp screws. -
Page 49: Step 19
Step 19 Apply silicone grease to the grommets and reinsert them in the cable ports. This step includes inserting the unused grommets with silicone into the unused cable ports. Figure 56. Applying silicone grease to the SUMA grommets Lubricate underneath and around the sides of the endplate caps with the silicone lubricant. Figure 57. - Page 50 Step 20 Tighten the end cap bolts using a 3/8 in (9.5 mm) nut driver. Tighten evenly until the endplate cap is fully sealed. Figure 58. Securing the end cap bolts (left), the caps completely secure (right) CAUTION: Do not use power tools to tighten bolts as this can damage the end caps and enclosure lid.
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Page 51: Step 22
Step 22 Seat the cover on top of the enclosure body and tighten all bolts using a 3/8 in (9.5 mm) nut driver. Tighten bolts in the order shown in Figure 60. Figure 60. Tighten SUMA bolts in the order pictured Cover in full contact with base... -
Page 52: Step 20
SUMA Flash Testing Step 1 With the SUMA completed and enclosure lid fully secured using a 3/8 in (9.5 mm) nut driver, remove the air valve cap from the cover. Air Valve Figure 62. The air valve location Step 2 Pressurize the enclosure up to 5 psi. -
Page 53: Step 1
Step 3 Spray all sealing surfaces of the enclosure with all-purpose leak detector fluid or soapy water. Look for bubbles forming to determine if there are any leaks. If there are any failures in the seal, bubbles will appear and increase in size from any air escaping from the pressurized enclosure. -
Page 54: Tdr8 Relay Module
6. TDR8 Relay Module The TDR8 Relay Module connects to the TD100 and has available four inputs and eight outputs. Inputs will be annunciated via the Master Controller interface. Outputs are programable and are set by specifying a detected meter range per relay. This setting may be configured in the Master Controller or TD100 WUI. -
Page 55: Td100 Power Supply Units
7. TD100 Power Supply Units The TD100 processor is powered through the attached lead-in cables and respective sensor cables, as explained in the earlier chapters. Because this system topology is flexible with where the power supply is located, the TD24PSU or TD48PSU can be installed at or away from the perimeter and TD100 processors. -
Page 56: Battery Backup (Optional)
These individual items can be installed alongside each other, DIN rail mounted with accessory backplates, or generally mounted in the configuration most convenient for the specific site’s needs. Figure 69. Fused DC power distribution board (DP4) The typically black “Line” cable for 120 – 240 VDC and “Neutral,” typically white, would wire to the transformer, as shown in Figure 74. - Page 57 uptime for the system. The below table has precalculated the most common requirements: TD100 Units Hours Uptime 4 Hr 3 AH 5.5 AH 8 AH 12 Hr 8 AH 16 AH 24 AH 24 Hr 16 AH 32 AH 48 AH Referencing the above table, a site needing 12 hours of uptime for three TD100 units would purchase two 12 VDC 24 amp-hour (AH) batteries.
- Page 58 Once all wiring is complete, the unit should be tested before attempting to power the sensor and TD100 processor. Turn off the DP4 ON/OFF switch and confirm field DC cable ends are taped over, capped, or inserted into the relevant SUM. Testing points for the TD24PSU are the terminal screws which can be measured by making contact with the multimeter probe tips.
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Page 59: Td24Psu Test Procedure
TD24PSU Test Procedure Step 1 With the DP4 ON/OFF switch in the off position, engage the previously tested AC input and then measure and verify the AC voltage is 120 – 240 VAC and that the AC power LED on the LPS5 is illuminated. Figure 71. -
Page 60: Step 1
Figure 72. DC power testing points (red arrow) Step 3 Ensure field DC cable ends are taped over, capped, or inserted into the relevant SUM. Measure and verify the DP4 DC input voltage is 24 VDC by measuring the input points at the bottom of the board. -
Page 61: Step 4 (Optional)
Figure 73. DC power testing points (red arrow) Lastly, if applicable, measure the DC cable ends or verify TD100 power. Step 4 (Optional) If installed once the system is functioning a Battery Operational Test may be conducted. Be sure batteries have had time to charge to full capacity before continuing. Typically, 24 - 48 hours are needed, note the TD2 PSU’s maximum charge current is 0.3 A. - Page 62 Next perform the Battery Endurance Test. With the previous step complete conduct intrusion testing to verify the TD100 is annunciating alarms as usual. Monitor the TD100 for the set total hour uptime goal with the previously noted time as the start time. Once the uptime goal is reached continue monitoring the system until the low battery alarm is received.
- Page 63 LPS5 LPS5 Battery Fail Relay AC Fail Relay VAC Line VAC Neutral 12 VDC Battery in Series (24 VDC) + 24 VDC - 24 VDC Figure 74. TD24PSU Product Wiring Diagram Confidential – Limited Distribution Page 63...
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Page 64: Td48Psu
TD48PSU Installing the TD48PSU enclosure is similar to mounting any typical box enclosure. There is the option of using attached feet or going without and mounting directly to the enclosure’s inset nuts. The TD48PSU provides enough watts to power up to six TD100 processors, as shown in Figure 13. - Page 65 “Neutral,” typically white, and “Ground,” green, wires can be connected to the bottom of the right two terminal blocks on the AC connection points as shown in Figure The bottom 48 VDC connections on the rightmost DC terminal block section run to the TD100 SUMA TX and RX enclosures.
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Page 66: Td48Psu Test Procedure
Figure 77. Test probe in terminal block test port TD48PSU Test Procedure Step 1 With all pivoting fuse holders disconnected and circuit breaker off, engage AC input power. Measure and verify the AC voltage is 120 – 240 VAC and that the AC LED is illuminated. Figure 78. -
Page 67: Step 1
Step 2 Engage the AC fuse holder and then the circuit breaker. AC fuse holder should not be illuminated. Fuse holder illumination indicates a blown fuse. Verify DC power LED is illuminated. Step 3 Ensure field DC cable ends are taped over, capped, or inserted into the relevant SUM. Engage the DC fuse holders, then measure and verify the DC voltage is 48 VDC by measuring the user input points. - Page 68 120-240 VAC Power LED 48 VDC Power LED Fuse for AC Fuse for DC TX Circuit Breaker ON/OFF Fuse for DC RX Figure 80. TD48PSU product wiring diagram, user installed (dashed), Fiber SenSys installed (solid) Confidential – Limited Distribution Page 68...
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Page 69: Intrusion Testing
8. Intrusion Testing Upon the successful installation of a TD100 system, testing for intrusions and adjustment of sensitivity thresholds follows. This chapter provides information on intrusion testing only. For WUI interaction and setting parameters that affect the systems alarm thresholds, please see the WUI Manual. -
Page 70: Advanced Tests
Start Location 3 m (10 ft) from the closest sensor line End Location 3 m (10 ft) from the closest sensor line Entry and Exit Angle Steep, shallow, or perpendicular angles are all acceptable Number of Tests Minimum of 10 test intrusions, 10 test per 100 m (328 ft) of sensor for cable lengths greater than 100 m (328 ft) Test Interval Minimum 30 seconds between test intrusions... -
Page 71: Crawl Testing Reference Table
Crawl Testing Reference Table: Intrusion Type Crawling Crawl Speed ~15 cm/s (6 in/s) consistent throughout test Prone with chest .5 – 15 cm (1 – 6 in) from ground Body Position Start Location 3 m (10 ft) from the closest sensor line End Location 3 m (10 ft) from the closest sensor line or upon alarm activation... - Page 72 Jump Height and Speed As high and far as physically possible for test intruder Start Location 7.5 m (25 ft) from the closest sensor line as space allows 3 – 7.5 m (10 – 25 ft) from the closest sensor line as space End Location allows Entry and Exit Angle...
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Page 73: Maintenance, Troubleshooting, And Repair
9. Maintenance, Troubleshooting, and Repair The TD100 product is relatively maintenance-free but does require some upkeep over the system lifespan to maintain a fully operational security system. If there are issues such as a broken sensor cable or a TD100 processor the following sections will help. Maintenance Visual Inspection –... -
Page 74: Performance Testing - Every 180 Days
Figure 82. Status check using the Status tab in the Web User Interface (WUI) Items to note are Voltage, Current, Uptime, ChanA, and ChanB Cable Fault. Performance Testing – Every 180 Days: Performance testing is a must for maintaining an alarm system that consistently performs at a high level over time. -
Page 75: Troubleshooting
minimize nuisance alarms. The maintenance and/or test log should include the date, name(s) of the test personnel, inspection criteria, pass/fail assessment for output relays, and pass/fail assessment for simulated intrusions. Other optional data that can be recorded are the weather at the testing time, the number of days in operation, uptime for each TD100, and the threshold for each sensor cable at the testing time. - Page 76 the total lengths at 60 mm (2.36 in) of braided drain wire and a 30 mm (1.18 in) center conductor. Split the drain wire into two halves, as seen in Figure Insert the center conductor into the large terminal block on the cable splice assembly and clamp it shut.
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Page 77: Password Reset
Figure 85. TDSC Repair Kit with connection completed For larger breaks and cuts than can be joined together via a single repair kit’s terminal block board, use both provided repair assemblies in the kit with a length of cable between two good sections of cable. -
Page 78: Td100 Led Status Table
TD100 LED Status Table: Stage Task Color 1 Color 2 Color 3 Bootloader Waiting/Programming Initialization Power up, waiting for Blue ethernet Initialization Failure Initialization Synchronizing Blue Green Operating Armed Green Warning Warning/Alert Green Tamper TD100 cover removed Password Passwords at default Blue Green Editing enabled... -
Page 79: Grounding
10. Grounding Lightning protection circuitry for the Terrain Defender Sensor Cable (TDSC) is provided at the Start-Up Module (SUM). The ground connection is made from the SUM stainless steel enclosures ground lug, Figure 55, then routed to a ground rod or plate installed midway between the sensor cables. -
Page 80: Product Specifications
11. Product Specifications TD100™ Processor System Type Buried line, point locating, sensor for perimeter security • Two fully independent TX/RX pairs Sensing TX/RX • 15 m (49 ft) virtual zone minimum Input: 24 – 48 VDC, 12 Watts Power Specifications •... -
Page 81: Td24Psu
• Normally Open (NO) and Normally Closed (NC) configurable via WUI • 24 to 12 AWG Temperature: -40˚ C to 70˚ C (-40˚ F to 158˚ F) Environmental Humidity: 0 to 95% non-condensing Height = 10.9 cm (4.3 in) Dimensions Width = 19.60 cm (7.72 in) Depth = 4.24 cm (1.67 in) Standards and... -
Page 82: Td48Psu
Length = 10.2 cm (4 in) Depth = 6.27 cm (2.47 in) DP4: Width = 8.3 cm (3.25 in) Length = 7.6 cm (3 in) Depth = 1.9 cm (0.75 in) TD48PSU TD100 Power Supply Unit System Type 6 Units supported (Max) •... -
Page 83: Terrain Defender Sensing Cable (Tdsc) And Lead-In Cable
Terrain Defender Sensing Cable (TDSC) and Lead-in Cable • Standard Length: 10 m (30 ft) o Contact Fiber SenSys for custom lengths • The are 10 ferrite beads per lead affixed with adhesive heat shrink o Ferrite bead diameter ~19.5mm (.77 in) •... -
Page 84: Glossary Of Technical Terms
12. Glossary of Technical Terms Several technical terms are often used to describe TD100. These include the following: Correlated Bin (C-Bin) A C-Bin is the combination of a Range Bin as seen from TX/RX 1 with is complementary C-Bin from TX/RX 2. Each C-Bin corresponds to approximately 6 meters of sensor cable Contra-Directional A signal traveling down the cable (TX) is reflected and received... - Page 85 TD100™ Processor Terrain Defender Buried line sensor for intrusion detection. P# 980-34227 Lead Processor The first processor in any Terrain Defender system. Kit P# 980-04345 Middle A processor in a multi-processor site located between the Lead Processor and End. Kit P# 980-14346 End Processor The last processor in a Terrain Defender system with more than one unit.
- Page 86 For troubleshooting assistance, contact Fiber SenSys Technical Support Service: telephone, 1- 503-726-4455; email, support@fibersensys.com; or go to the Fiber SenSys website, www.fibersensys.com Confidential – Limited Distribution Page 86...