GROUNDING DEVICE FOR ELECTRIC FENCE

Abstract

A disclosed electric fence system includes an electric fence; an energizer for generating a plurality of electric pulses applied to the electric fence; a detection circuit for monitoring a voltage of the electric fence; and a grounding device for grounding the electric fence when the electric fence is off. The grounding device is connected to the electric fence, the energizer, the detection circuit, and the ground.

Claims

13. An electric fence system comprising: an electric fence; an entryway connected to the electric fence and providing access to an area fenced by the electric fence; and an electrical control system in electrical communication with the electric fence and the entryway such that when the electric fence and the entryway are off the entryway is grounded and the electric fence is ungrounded.

14. The electric fence system of claim 13, wherein the electrical control system comprises: a voltage output device for generating a plurality of electric pulses to the entryway; and a grounding device for grounding the entryway when the entryway is off, wherein when the entryway is off, all voltage on the entryway flows to the grounding device.

15. The electric fence system of claim 14, further comprising a voltage return device, wherein when the entryway is on, voltage pulses are output from the voltage output device to the entryway and then to the voltage return device.

16. The electric fence system of claim 14, wherein when the electric fence is off, voltage on the electric fence floats on the electric fence.

17. The electric fence system of claim 14, wherein the grounding device comprises a plurality of isolation relays.

18. The electric fence system of claim 15, wherein the grounding device comprises a plurality of isolation relays, and wherein each of the plurality of isolation relays is in electrical communication with a respective terminal of one of the voltage output device and the voltage return device.

19. The electric fence system of claim 15, wherein the electrical control system further comprises a power supply to supply power to the voltage output device, the grounding device, and the voltage return device.

20. The electric fence system of claim 14, wherein the electric fence and the entryway are off when the electric fence and the entryway are not receiving electrical pulses from the voltage output device because power for the electric fence and the entryway is shut off or because of a malfunction in the electric fence system.

21. The electric fence system of claim 14, wherein the voltage on the electric fence and the entryway comprise one of potential voltage and induced voltage.

22. An electric fence system comprising: an electric fence comprising: a first fence panel comprising a first plurality of fence sections, each fence section of the first plurality of fence sections being arranged in a first vertical sequence with the other fence sections of the first plurality of fence sections, a second fence panel comprising a second plurality of fence sections, each fence section of the second plurality of fence sections being arranged in a second vertical sequence with the other fence sections of the second plurality of fence sections; and an electrical control system in electrical communication with the first and second fence panels, the electrical control system comprising: a voltage output device for generating a plurality of electric pulses to the electric fence, a voltage return device, and a grounding device that can selectively connect the electrical control system to a ground when the electric fence is off, wherein when the electric fence is off, all voltage on the electric fence flows to the grounding device.

23. The electric fence system of claim 22, wherein the electrical control system and the electric fence are connected such that a voltage flows from the electrical control system to the first fence panel, then to the second fence panel, and then back to the electrical control system.

24. The electric fence system of claim 23, wherein the electrical control system and the electric fence are connected such that the voltage flows from the voltage output device to the first fence panel, then to the second fence panel, and to the voltage return device when the electric fence is on.

25. The electric fence system of claim 24, wherein the voltage output device comprises a positive and a negative terminal, each connected to a respective one of the first plurality of fence sections.

26. The electric fence system of claim 24, wherein the first plurality of fence sections of the first fence panel comprises at least four fence sections, wherein the voltage output device comprises a positive and a negative terminal, each connected to a respective two of the first plurality of fence sections.

27. The electric fence system of claim 26, wherein the positive and negative terminals are connected to alternating fence sections such that no two adjacent sections are attached to the same terminal.

28. The electric fence system of claim 24, wherein the voltage return device comprises a positive and a negative terminal, each connected to a respective one of the second plurality of fence sections.

29. The electric fence system of claim 24, wherein the second plurality of fence sections of the second fence panel comprises at least four fence sections, and wherein the voltage return device comprises a positive and a negative terminal, each connected to a respective two of the second plurality of fence sections.

30. The electric fence system of claim 22, wherein the positive and negative terminals are connected to alternating fence sections such that no two adjacent sections are attached to the same terminal.

31. The electric fence system of claim 22, wherein the grounding device comprises a plurality of isolation relays and each of the plurality of isolation relays is connected to a respective terminal of one of the voltage output device and the voltage return device.

32. The electric fence system of claim 22, wherein the electric fence further comprises an entryway between the first and second fence panel.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0014] FIG. 1 illustrates a block diagram of an exemplary electric fence system 100, according to disclosed embodiments;

[0015] FIG. 2 illustrates a block diagram of an exemplary grounding device 106, according to disclosed embodiments;

[0016] FIG. 3 illustrates an exemplary electric fence system 100, according to disclosed embodiments; and

[0017] FIG. 4 illustrates another exemplary electric fence system 100 indicating a connection between the electric fence 110 and the control center 304, according to disclosed embodiments.

DETAILED DESCRIPTION

[0018] Perimeter fencing such as electric fencing is helpful in keeping trespassers (e.g., human, wildlife, etc.) from entering and damaging outdoor structures such as, for example, power plants, electrical sub-stations, and the like. The present disclosure provides an electric fence system including a grounding device, configured to divert any potential voltage or induced voltage that could be on the electric fence to ground when the power input to the electric fence is shut off.

[0019] FIG. 1 illustrates a block diagram of an exemplary electric fence system 100. As shown in FIG. 1, in an embodiment, the electric fence system 100 includes an electrical control system 101, an electric fence 110, and ground 112. The electrical control system 101 further includes direct current (DC) power supply 102, energizer 104, grounding device 106, and detection circuit 108. The DC power supply 102 is used to provide power, e.g., a 12 volts DC power, to the energizer 104, the grounding device 106, and the detection circuit 108. The energizer 104 can generate high voltage (e.g., 10,000 volts) electrical pulses to be applied to the electric fence 110. The grounding device 106 is used to divert any potential voltage or induced voltage on the electric fence 110 to ground 112 when no high voltage electric pulses are applied to the electric fence 110 due to a DC power outage or the electric fence system 100 being shut down. The detection circuit 108 is used to monitor the electric fence voltage. If there is no fence voltage for a period of time, i.e., no high voltage electric pulses are applied to the electric fence 110 for a period of time, then an alarm is triggered to notify an operator that the electric fence 110 is not working properly. In an embodiment, the detection circuit 108 may include a voltage sensor. The electric fence 110 may include exposed conductive elements (e.g., stainless steel or aluminum) configured to divert the electrical pulses via contact with the electric fence 110, such that the electric fence 110 may be used as a deterrent barrier against entry to a particular area (e.g., a power station).

[0020] In an embodiment, the electric fence system 100 can further include a power source electrical circuit 114, configured to supply alternating current (AC) 110V.

[0021] In an embodiment, the electrical control system 101, including DC power supply 102, energizer 104, grounding device 106, and detection circuit 108, can be placed in the same case, enclosure, or box called, e.g., control center or control system. The case, enclosure, or box can be made of any materials, e.g., metal, plastic, etc.

[0022] FIG. 2 illustrates a block diagram of an exemplary grounding device 106. As shown in FIG. 2, the grounding device 106 includes one or more isolation relays. For example, in the embodiment shown in FIG. 2, there are four isolation relays 202, 204, 206, and 208 rated at 10,000 volts, i.e., the four isolation relays 202, 204, 206, and 208 can withstand up to 10,000 volts. Isolation relay 202 includes coil 210 and switch 212; isolation relay 204 includes coil 214 and switch 216; isolation relay 206 includes coil 218 and switch 220; isolation relay 208 includes coil 222 and switch 224.

[0023] Each switch is in an open position during a normal operation when the electric fence 110 is on. When the power of the electric fence 110 is shut off, each switch is closed. Then the electric fence 110 is connected to the ground through the grounding device 106. In an embodiment, one end of the switch 212 is connected to the ground 112 (e.g., the ground of a power station), while the other end of the switch 212 is connected to a positive terminal of the energizer 104 (i.e., a positive terminal of high voltage pulse output). One end of the switch 216 is connected to the ground 112, while the other end of the switch 216 is connected to a negative terminal of the energizer 104 (i.e., a negative terminal of high voltage pulse output). One end of the switch 220 is connected to the ground 112, while the other end of the switch 220 is connected to a negative terminal of the detection circuit 108 (i.e., a negative terminal of high voltage pulse return). One end of the switch 224 is connected to the ground 112, while the other end of the switch 224 is connected to a positive terminal of the detection circuit 108 (i.e., a positive terminal of high voltage pulse return). The high voltage pulses are output from the energizer 104 to the electric fence 110, and then returned to the detection circuit 108 from the electric fence 110.

[0024] When the electric fence 110 is on (i.e., in a normal operation mode), a coil in each isolation relay is energized, and the associated switch is in an open position due to the magnetic force generated by the energized coil. All the switches are in an open position and are isolated from each other. When the electric fence 110 is off (e.g., the power for the electric fence 110 is shut off, or there is any malfunction in the electric fence system 100), the coil in each isolation relay is de-energized, and thus no magnetic force is generated. Accordingly, the switch in each isolation relay is in a closed position due to the loss of the magnetic force. If the switch in each isolation relay is in a closed position, the positive terminal of high voltage pulse output, the negative terminal of high voltage pulse output, the positive terminal of high voltage pulse return, and the negative terminal of high voltage pulse return are all connected to the ground 112, and thus the high voltage applied to the electric fence 110 can be eliminatedi.e., run to the ground 112to secure the safety of the electric fence 110.

[0025] In an embodiment, when the electric fence 110 is on, the coils 210, 214, 218, and 222 are energized, and the switches 212, 216, 220, and 224 are all in an open position due to the magnetic force generated by the energized coils 210, 214, 218, and 222, respectively. All the switches 212, 216, 220, and 224 are in an open position and are isolated from each other. When the electric fence 110 is off, the coils 210, 214, 218, and 222 are de-energized, and thus no magnetic force is generated. Accordingly, the switches 212, 216, 220, and 224 are all in a closed position due to the loss of the magnetic force, and the positive terminal of high voltage pulse output, the negative terminal of high voltage pulse output, the positive terminal of high voltage pulse return, and the negative terminal of high voltage pulse return are all connected to the ground 112.

[0026] As shown in FIGS. 1 and 2, the grounding device 106 is electrically connected to the energizer 104 (the beginning of the electric fence system 100 circuit) and the detection circuit 108 (the end of the electric fence system 100 circuit). Thus, even if the electric fence 110 is disconnected or damaged internally, or any adjacent fence panels of the electric fence 110 are physically separated from each other, the fence panels that are connected to the energizer 104 and the detection circuit 108 (i.e., fence panels connected to two ends of the damaged/disconnected/unbonded electric fence 110) are still properly grounded.

[0027] FIG. 3 illustrates an exemplary electric fence system 100. As shown in FIGS. 1 and 3, the electric fence system 100 includes an electric fence 110, and a case or enclosure 304 accommodating the electrical control system 101, which includes DC power supply 102, energizer 104, grounding device 106, and detection circuit 108. In an embodiment, the case or enclosure 304 can be called control center or control system. In an embodiment, the electric fence system 100 further includes an entryway 302. The entryway 302 is grounded, while the electric fence 110 is floating (i.e., ungrounded). In an embodiment, the case or enclosure 304 is placed on one side of the entryway 302. The case or enclosure 304 can be made of any materials, e.g., metal, plastic, etc.

[0028] FIG. 4 illustrates another exemplary electric fence system 100, indicating a connection between the electric fence 110 and the control center 304. As shown in FIG. 4, the electric fence 110 can include one or more fence panels, e.g., fence panel 402 and fence panel 404. Each fence panel 402, 404 includes one or more fence sections. For example, the fence panel 402 includes fence section 406, fence section 408, fence section 410, and fence section 412. The fence panel 404 includes fence section 414, fence section 416, fence section 418, and fence section 420. The positive terminal of the energizer 104 (i.e., a positive terminal of high voltage pulse output) is connected to the fence section 406 and the fence section 410. The negative terminal of the energizer 104 (i.e., a negative terminal of high voltage pulse output) is connected to the fence section 408 and the fence section 412. The positive terminal of the detection circuit 108 (i.e., a positive terminal of high voltage pulse return) is connected to the fence section 414 and the fence section 418. The negative terminal of the detection circuit 108 (i.e., a negative terminal of high voltage pulse return) is connected to the fence section 416 and the fence section 420. When the electric fence 110 is on, the electric pulses (i.e., high voltage pulses) are output from energizer 104 and returned back to the detection circuit 108 through the electric fence 110. When the electric fence 110 is off due to, e.g., power outage or any malfunction in the electric fence system 100, the floating fence panel 402 and fence panel 404 are connected to the ground 112 through the grounding device 106.

[0029] The elements of the figures are not exclusive. Other embodiments may be derived in accordance with the principles of the invention to accomplish the same objectives. Although this invention has been described with reference to particular embodiments, it is to be understood that the embodiments and variations shown and described herein are for illustration purposes only. Modifications to the current design may be implemented by those skilled in the art, without departing from the scope of the invention. [0030] 1-12. (canceled)