JP2013042746A - Electric fence - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electric fence allowing passage of a man through a desired position without getting electrical shock and enabling easy confirmation of imposed voltage.SOLUTION: The electric fence includes an electrically conductive member encircling a prescribed area; a first voltage generation circuit electrically connected with the electrically conductive member and imposing a first voltage to the electrically conductive member; a third voltage generation circuit electrically connected with the electrically conductive member and imposing a third voltage lower than the first voltage to the electrically conductive member when a second voltage lower than the first voltage is imposed to the electrically conductive member; and an announcing device detachably attached to the electrically conductive member in an electrically conductive manner and provided with a first announcing means issuing an announcement when the announcing device is connected to the electrically conductive member imposed with the first voltage, a second voltage generating means capable of generating the second voltage, and a second announcing means for issuing an announcement when the second voltage is generated by the second voltage generating means.

Description

  The present invention relates to an electric fence. Specifically, for example, it relates to an electric fence for protecting a field from wild animals.

  In rural areas in mountainous areas, electric fences are often used to prevent wild animals such as deer and frogs from entering the fields.

  In the electric fence, the voltage generated from the voltage generator in the power supply unit is applied to the bare wire that runs around the field, and wild animals such as deer and moths that are in contact with the bare wire are It is a fence for repelling by electric shock.

FIG. 5 shows a conventional electric fence.
As shown in FIG. 5, the conventional electric fence 100 includes a bare electric wire (103 a to 103 d) that is locked and stretched by an insulator (101 a to 101 d) attached to a support column 102 placed around the field. Is provided.

  Further, the bare wires (103a to 103d) are connected by the upper and lower connections 104 made of bare wires every about 50 m.

  Further, among the bare wires (103a to 103d), the first bare wire 103d closest to the ground surface is located at a height of about 20 cm from the ground surface, and the second bare wire 103c is from the bare wire 103d. The third stage bare electric wire 103b is located at a height of about 40 cm upward from the bare electric wire 103c, and the fourth stage bare electric wire 103a is arranged from the bare electric wire 103b. It is located at a height of about 50 cm upward.

  A power supply device 105 having a voltage generator that generates a predetermined voltage applied to the stretched bare wires (103a to 103d) is electrically connected to the bare wire 103c.

  When a deer or a shark tries to invade a field surrounded by such an electric fence 100 and comes into contact with a stretched bare electric wire (103a to 103d), the deer or the frog is shown as an arrow in FIG. Output terminal 106 of power supply device 105, output line 107 of power supply device 105, bare wire 103c, vertical connection 104, bare wires (103a, 103b and 103d), wild animals 108 such as deer and moth, underground 109, ground rod 110, the ground wire 111, and the ground terminal 112 pass through a high current (impact current) that can give an impact to an animal or a human.

  As a result, wild animals 108 such as deer and moths are repulsed by electric shock.

  By the way, during energization of the electric fence 100, it may be necessary to enter a field. This is the case for weeding, fertilizing and other cases. In this case, it is necessary to dig into the gap between several bare wires (103a to 103d) that are energized and enter the field. However, of course, as shown in FIG. 6, since a person contacts a bare electric wire (103a-103d), it receives an electric shock and cannot enter a field easily.

  Therefore, there is a case where an instrument called a gate as shown in FIG. 7 is used in order for a person to enter the field during energization.

  As shown in FIG. 7, one end of the conductive wire inserted in the longitudinal direction in the substantially central portion of the instrument 120 formed in a cylindrical shape with an insulating material is electrically connected to the metal piece 121 processed into a hook shape. It is connected.

  Further, the hook-shaped metal piece 121 is hooked on a receiving metal fitting 125, and the receiving metal fitting 125 is electrically connected to the bare electric wire 126.

  The other end of the conductive wire is electrically connected to a metal piece 122 processed into a circular shape. A spiral spring 123 is attached to the circular metal piece 122, and a bare electric wire 124 is connected to the spring 123.

Thus, the bare wire 126 and the bare wire 124 are in a state of being electrically connected via the gate.
Moreover, as shown in FIG. 8, the gate is attached to each stage of the stretched bare electric wires (103a to 103d).

Next, the usage of the gate is as follows.
When a person tries to enter the field, as shown in FIG. 9, the instrument 120 formed in a cylindrical shape with an insulating material is grasped by hand, the hook-shaped metal piece 121 is detached from the receiving metal fitting 125, and energization is performed. Cut off.

  Then, as shown in FIG. 9, a person enters the field from the place where the gate is removed.

  For example, Patent Document 1 describes an entrance / exit of an electric fence as shown in FIG. That is, the structure of the entrance / exit of the electric fence described in patent document 1 is as follows.

  One frame 201C of the left and right frames constituting the body frame (201A to 201D) with the net 202 stretched on one body column 203A of the pair of body columns (203A, 203B) is opened and closed by a hinge part (204A, 204B). A means 205 for supporting the other frame 201A of the left and right frames is provided on the other main body column 203B.

  Also, the bare wires (208A to 208D) at the top of the left and right frames (201A, 201C) feed with the bare wires (209A to 209D) on the one frame 201C side of the left and right frames provided with the hinged portions (204A, 204B). It electrically connects with the electric wire (210A-210D).

Moreover, the usage method of the entrance / exit of the electric fence of patent document 1 is as follows.
If the fixing of the means 205 for fixing the main body frame 201A is released and the main body frame is pulled forward, the main body frame 201 is opened around the hinged portions (204A, 204B), and can freely enter and exit. When closing, after closing the main body frame 201, the main body frame 201A is fixed again by means 205 for fixing.

JP 11-206305 A

  In this way, with conventional electric fences, you can remove the gate or open the main frame to enter the field surrounded by the electric fence without electric shock, but you can enter without electric shock. It was only from the place where the gate and doorway (hereinafter referred to as “gate” etc.) were installed, and could not enter the field from any place.

  In addition, in an electric fence stretched around 500 m, there are usually two or three places such as gates.

  In this case, in order to invade any place in the field, move to the installation location such as a gate and release the connection of the gate as shown in FIG. 9 or release the fixing of the main body frame. After entering the field and weeding, we have to go out of the electric fence from the gate and connect the gate and fix the main frame again.

  Therefore, it takes time and labor to enter a field surrounded by an electric fence, which is inconvenient.

  In addition, it is conceivable to increase the number of installation locations such as gates, but if the number of installation locations such as gates is increased, the cost increases, and the bare wires (103a to 103d) are locked to the insulators (101a to 101d). Compared to the case, it takes much time to install the gates.

In some cases, a gate or the like is not used at all, which is further inconvenient.
In this case, in order to invade any place in the field, it moves along the bare wires (103a to 103d) of the electric fence 100 to the place where the power supply device 105 is installed, and the power switch of the power supply device 105 is turned off to energize. Stop.

  Then, it returns to the place where it should invade, crawls through the gaps of several bare wires (103a to 103d), and enters the field. After completing the weeding work, etc., the gap between several bare wires (103a to 103d) is scraped again, goes out of the electric fence 100, and further moves to the place where the power supply device 105 is installed. The switch must be turned on.

In this way, the conventional electric fence was inconvenient because it had to be moved to the installation location of the gate and the power supply device in order to pass through the electric fence without human beings being electrocuted. There has been a demand for an electric fence that allows people to pass through without any electric shock at any point.
There was also a demand to easily confirm whether or not an impact voltage is applied to the fence line of the electric fence.

  The present invention has been made in view of the above points, and an object of the present invention is to provide an electric fence that allows a person to pass through a desired position without electric shock and easily check a voltage state. .

  In order to achieve the above object, an electric fence according to the present invention includes a conductive member formed around a predetermined region, and is electrically connected to the conductive member and applies a first voltage to the conductive member. The first voltage generating circuit is electrically connected to the conductive member, and the first voltage is applied when a second voltage having a voltage value lower than the first voltage is applied to the conductive member. A third voltage generating circuit that applies a third voltage having a voltage value lower than the voltage of the first conductive member to the conductive member; and a first voltage that is detachably and electrically connected to the conductive member; A first notifying means for notifying when connected to the applied conductive member; a second voltage generating means capable of generating the second voltage; and the second voltage generating means comprising the second voltage generating means. Annunciator having second notifying means for notifying when voltage is generated Equipped with a.

  Here, a second voltage that is electrically connected to the conductive member and has a voltage value lower than the first voltage when a second voltage having a voltage value lower than the first voltage is applied to the conductive member. A third voltage generating circuit that applies a voltage of 3 to the conductive member has a voltage value lower than the first voltage applied to the conductive member by simply applying the second voltage at an arbitrary place. Therefore, even if a person touches the conductive member to which the third voltage having a voltage value lower than the first voltage is applied, it may enter or exit the fence. it can.

Further, since the notification device is detachably and electrically connected to the conductive member, the notification device can be connected to a desired position of the conductive member.
In addition, since the notification device has first notification means for notifying when connected to the conductive member to which the first voltage is applied, it is possible to know whether or not the first voltage is applied to the conductive member. it can.

In addition, since the notification device has the second voltage generating means capable of generating the second voltage, the notification device is electrically connected to the conductive member, the second voltage is applied to the conductive member, and the third voltage is generated. The voltage generation circuit can apply the third voltage to the conductive member.
In addition, since the notification device has the second notification means for notifying when the second voltage generation means generates the second voltage, it is possible to know the generation of the second voltage. In a state where the notification device is connected to the conductive member, it can be known that the third voltage is applied to the conductive member.

  In the electric fence according to the present invention, the first notification means may notify the third voltage when applied to the conductive member in a mode different from that when connected to the conductive member to which the first voltage is applied. In this case, the state in which the first voltage is applied to the conductive member and the state in which the third voltage is applied to the conductive member can be distinguished.

  In the electric fence of the present invention, the notification device may have a third notification means for notifying when the third voltage is applied to the conductive member.

  Further, in the electric fence of the present invention, when the first notification means is a means for notifying by emitting a sound, for example, the means for notifying by emitting light may miss the light emission, and means for notifying by emitting light. It is easier for a person to notice that the first voltage is applied to the conductive member.

In the electric fence according to the present invention, the notification device may include a hook-shaped hook portion that is hooked on the conductive member and a grounding portion that is grounded to the ground.
In this case, the notification device can be detachably and electrically connected to the conductive member simply by hooking the hook-shaped hook portion on the conductive member.

  The electric fence according to the present invention can pass through at a desired position without an electric shock, and can easily check the voltage state.

It is the schematic which shows an example of the circuit diagram before a notification device is connected to a fence line in the electric fence of this invention. It is the schematic which shows an example of a circuit diagram when a notification device is connected to the fence line in the electric fence of the present invention. It is the schematic which shows an example of a circuit diagram when a notification device is connected to a fence line in the electric fence of the present invention, and the power supply of the notification device is turned on. It is the schematic which shows an example of the circuit diagram when the power supply of a notification device is turned off after the state shown in FIG. It is the schematic which shows the installation aspect of the conventional electric fence. It is the schematic which shows a mode that a person scrapes and divides the conventional electric fence which is supplying with electricity. It is the schematic which shows the structure of the gate used for the conventional electric fence. It is the schematic which shows the conventional electric fence using the gate shown by FIG. It is the schematic which shows the state by which the gate of the conventional electric fence was removed. It is the schematic which shows the structure of the entrance / exit of the conventional electric fence.

Hereinafter, embodiments of the present invention will be described with reference to the drawings to facilitate understanding of the present invention.
FIG. 1 is a schematic diagram showing an example of a circuit diagram before a notification device is connected to a fence line in the electric fence of the present invention.

  In FIG. 1, the electric fence 1 of the present invention includes a fence wire (an example of a conductive member) 31 that is stretched around a column that is erected around a predetermined area (for example, a field area). Here, the fence wire 31 is a bare electric wire.

  Moreover, although not shown in figure, the fence wire 31 is comprised with the four bare electric wires, and the four bare electric wires are mutually stretched | stretched substantially parallel and separated by predetermined length.

  In addition, the electric fence 1 of the present invention is electrically connected to the fence line 31 via the output terminal 16 and applies an impact voltage (first voltage) to the fence line 31 (first voltage). Voltage generation circuit) 14.

  The electric fence 1 of the present invention is electrically connected to the fence line 31 via the output terminal 16 and has an impact voltage stop command voltage (second voltage) having a voltage value lower than the first voltage. When a voltage is applied to the fence line 31, a notification voltage generation circuit (third voltage generation circuit) 26 that applies a notification voltage (third voltage) having a voltage value lower than the first voltage to the fence line 31 is provided. Prepare.

  In addition, the electric fence 1 of the present invention is detachably and electrically connected to the fence line 31 and also generates a buzzer (first output) when connected to the fence line 31 to which the first voltage is applied. 3), a stop command voltage generating circuit (an example of the second voltage generating means) 5 capable of generating the second voltage, and a stop command voltage generating circuit 5 are the second Is provided with an LED (which is an example of a second notification means) 4 that emits light when the above voltage is generated.

In addition, the notification device 2 includes a hook-shaped hook portion 10 that is hooked on the fence line 31 and a grounding portion 11 that is formed of a conductive material and is grounded to the ground.
The grounding part 11 is brought into contact with the ground, and the hooking part 10 of the notification device 2 is hooked and brought into contact with the fence line 31, and the second voltage is applied from the notification device 2 while grounding between the fence line 31 and the ground. Apply to fence wire 31.

The stop command voltage generation circuit 5 is connected to the LED 4 and the power switch 7.
The power switch 7 is connected in series to a 9V power source 6.

The buzzer 3 is connected in series to the first signal extension 8.
The first signal extension 8 is connected between the first resistor R1 and the second resistor R2.

  The first resistor R1 and the second resistor R2 are connected in parallel to a surge absorber (surge protection device) 9. Here, the resistance value of the first resistor R1 is larger than the resistance value of the second resistor R2.

  The power supply device 12 includes an impact voltage generation circuit 14, a notification voltage generation circuit 26, a 12V power supply 27, and a power switch 28.

  Further, the impact voltage generation circuit 14 and the notification voltage generation circuit 26 are connected in parallel to each other, and both are connected to the output transformer 15.

The winding end 15 </ b> A of the secondary winding of the output transformer 15 is connected to the fence line 31 via the output terminal 16.
The winding start 15B of the secondary winding of the output transformer 15 is connected to one end of the surge absorber 17, and the other end of the surge absorber 17 is grounded.

A protection circuit 29 is connected to the other end of the surge absorber 17, and an amplifier circuit 30 is connected in series to the protection circuit 29.
A second signal extension 18 is connected in series with the amplifier circuit 30.

  A charge / discharge circuit 19 is connected in series to the second signal extension 18. The charging / discharging circuit 19 includes a fifth resistor R5 and a sixth resistor R6 connected in parallel to each other.

  The first determination unit 20 is connected to the charge / discharge circuit 19 in series. Here, the negative terminal of the first determination unit 20 is connected to the charge / discharge circuit 19.

The first transistor 21 is connected to the first determination unit 20.
One end of the fourth resistor R4 is connected to the first transistor 21, and the other end of the fourth resistor R4 is connected to the second transistor 22, the second determination unit 23, and the third resistor R3. Is connected.
Here, the plus terminal of the second determination unit 23 is connected to the other end of the fourth resistor R4.

The second transistor 22 and the third resistor R3 are connected in parallel to each other.
One end of the power switch 28 is connected to a connection point between the second transistor 22 and the third resistor R3, and the other end of the power switch 28 is connected to a 12V power source 27.

The oscillation circuit 13 is connected to the second transistor 22.
In addition, an impact voltage generation circuit 14 is connected in series to the oscillation circuit 13.

The fourth transistor 25 is connected to the connection point between the second transistor 22 and the third resistor R 3, and the fourth transistor 25 is also connected to the notification voltage generation circuit 26 and the third transistor 24. Has been.
The third transistor 24 is connected to the second determination unit 23.

  In the drawing, the power source and the power switch are shown to be arranged inside the notification device and the power supply device. However, the drawing schematically shows that the notification device and the power supply device have a power supply and a power switch. Of course, the power supply and the power switch may be arranged outside the notification device or the power supply device.

Next, the operation of the electric fence of the present invention will be described.
As shown in FIG. 1, when the power switch 28 of the power supply device 12 is “ON” and the notification device 2 is not connected to the fence line 31, an impact from the stop command voltage generation circuit 5 is applied to the fence line 31. The voltage stop command voltage (second voltage) is not given.

  Further, since the power switch 28 of the power supply device 12 is “ON”, the voltage of the power supply 27 is applied to the impact voltage generation circuit 14 to generate the first voltage. Then, only the impact voltage (first voltage) from the impact voltage generation circuit 14 is applied to the fence line 31.

  The first voltage applied to the fence line 31 is pulsed electricity generated at 1.1 second intervals, the voltage at no load is 10,000 V, and the cycle is 1.1 seconds.

The generated first voltage is applied to the fence line 31. When a wild animal or the like comes into contact with the fence line 31, the wild animal receives an impact and dissipates.
Moreover, since a person also receives an impact when touching the fence wire 31, it cannot crawl between bare wires and enter the fence.

  In the power supply device 12, the voltage of electricity flowing from the output transformer 15 is temporarily lowered by the protection circuit 29. Then, the lowered voltage is returned to about 10 V by the amplifier circuit 30. Next, the voltage returned to around 10 V (1.1 seconds / once) is applied to the second signal extension 18.

In addition, in the second signal extension unit 18, the voltage application time is extended for 0.2 seconds, and the input unit of the charge / discharge circuit 19 has a voltage of about 10V for the first 0.2 seconds out of 1.1 seconds. Since voltage is applied, the capacitor 19A is charged through the fifth resistor R5 for 0.2 seconds.
Depending on the direction of the diode, the capacitor 19A is not charged through the sixth resistor R6.

Next, since the voltage is not applied to the input part of the charge / discharge circuit 19 for 0.9 seconds after 0.2 seconds, the input part of the charge / discharge circuit 19 is 0 V for 0.9 seconds.
Then, the electricity charged in the capacitor 19A is discharged at a stroke to the input part which is 0V due to the potential difference. The discharge path is a path that passes through the fifth resistor R5 and the sixth resistor R6.

  By being discharged at once, the voltage does not exceed the reference value (8 V) of the first determination unit 20 in the charge / discharge circuit 19.

In addition, since the reference value (8 V) of the first determination unit 20 is not exceeded, an “L” (low) signal voltage is applied to the input unit of the operational amplifier (op-amp) of the first determination unit 20.
The operational amplifier of the first determination unit 20 outputs an “H” (high) signal voltage at the output unit when an “L” signal voltage is applied to the input unit. Since the “L” signal voltage is applied, the output unit outputs the “H” signal voltage.

Further, since the first determination unit 20 outputs a signal voltage of “H”, the first transistor 21 is activated.
Further, since the first transistor 21 is activated, the second transistor 22 and the oscillation circuit 13 are also activated.

In addition, a low voltage (L) signal voltage divided by the fourth resistor R4 of the third resistor R3 and the fourth resistor R4 is applied to the input unit of the operational amplifier of the second determination unit 23.
Note that the resistance value of the third resistor R3 is larger than that of the fourth resistor R4.

  In addition, the operational amplifier of the second determination unit 23 outputs the “H” signal voltage at the output unit when the “H” signal voltage is applied to the input unit. Therefore, the output unit outputs a signal voltage of “L”.

  Further, since the second determination unit 23 outputs the L signal voltage, the third transistor 24 does not operate, and further, the fourth transistor 25 does not operate.

  Further, since the fourth transistor 25 does not operate, the notification voltage generation circuit 26 connected to the fourth transistor 25 does not operate, and naturally the notification voltage (third voltage) is not generated.

Further, since the power switch 7 of the notification device 2 is “off”, the stop command voltage generation circuit 5 is not operated.
Further, since the stop command voltage generation circuit 5 is not operated, the second voltage is not generated, and as a result, the LED 4 does not emit light.

  Moreover, since the hook part 10 of the notification device 2 is not connected to the fence line 31, no voltage is applied to the first resistor R1 and the second resistor R2. Therefore, no voltage is applied to the first signal extension 8 and the buzzer 3, and the buzzer 3 does not operate.

Next, as shown in FIG. 2, the grounding portion 11 is brought into contact with the ground, and the hook-shaped hooking portion 10 of the notification device 2 is hooked on the fence line 31.
Then, the first voltage applied to the fence line 31 is applied to the hooking unit 10.

  In addition, since the first resistor R1 and the second resistor R2 are connected in parallel to the surge absorber 9, the reference value (4.5V) of the first signal extension 8 is obtained by the surge absorber 9 and the divided voltage. ) Exceeding 1) is applied to the second resistor R2 once every 1.1 seconds.

Moreover, in the 1st signal extension part 8, the time which requires the voltage exceeding the reference value (4.5V) of the 1st signal extension part 8 is extended by 0.3 second.
Then, the buzzer 3 sounds for the extended 0.3 second, and no sound is generated for 0.8 seconds. Such an intermittent sound is repeated until the power switch 7 of the notification device 2 is turned “on” in a state where the hooking portion 10 is connected to the fence line 31.

  As described above, when the hooking portion 10 is connected to the fence line 31 to which the first voltage is applied while the power switch 7 of the notification device 2 is turned off, the buzzer 3 of the notification device 2 makes an intermittent sound. Since it emits, it turns out that the 1st voltage is applied to the fence line 31, and the person can recognize that it cannot enter in a fence in this state.

Next, as shown in FIG. 3, when the power switch 7 of the notification device 2 is turned on, the stop command voltage generation circuit 5 generates a second voltage of 9V.
Further, when the second voltage is generated, the LED 4 blinks.

  Further, a first voltage of 10,000 V (once every 1.1 seconds) and a second voltage of 9 V (once every 0.1 seconds) are applied to the hooking portion 10.

  Further, although the first voltage and the second voltage are applied, the first voltage exceeds the reference value (4.5 V) of the first signal extension 8 due to the surge absorber 9 and the divided voltage. Is based on the voltage (about 5V, once every 1.1 seconds).

Then, in the first signal extension unit 8, the time required for the voltage based on the first voltage (about 5 V, once in 1.1 seconds) is extended by 0.3 seconds.
As a result, the buzzer 3 sounds for 0.3 seconds extended in 1.1 seconds, and no sound is generated for 0.8 seconds.

However, after the second voltage of 9V is generated and 2 to 3 seconds have elapsed, the hooking unit 10 generates the second voltage of 9V (once every 0.1 second) and the notification voltage of the power supply device 12 is generated. The third voltage of 300 V applied from the circuit 26 (once every 0.25 seconds) is applied.
That is, only a voltage is applied to the fence line 31 so that even if a person touches the fence line 31, no electric shock is felt.

  Here, the second voltage and the third voltage are applied, but the reference value (4.5 V) of the first signal extension 8 is exceeded by the surge absorber 9 and the divided voltage. Only voltage based on voltage (about 5V, once every 0.25 seconds).

In the first signal extension unit 8, the time required for the voltage based on the third voltage (about 5 V, once in 0.25 seconds) is extended by 0.3 seconds.
Further, since the voltage based on the third voltage enters the first signal extension 8 once every 0.25 seconds, it is based on the third voltage before the extended 0.3 seconds are over. Voltage will come in, and the buzzer 3 will not emit sound and will emit a continuous tone.

  On the other hand, a first voltage of 10,000 V (once every 1.1 seconds) and a second voltage of 9 V (once every 0.1 seconds) are applied to the output terminal 16 of the power supply device 12. ing.

Moreover, although the 1st voltage and the 2nd voltage are applied, the voltage which enters into the protection circuit 29 by the surge absorber 17 and voltage division is 22V (once every 1.1 second), and 9V Voltage (once every 0.1 seconds).
When the protection circuit 29 is exited, the voltage is 10V (once every 1.1 seconds) and 1V (once every 0.1 seconds).

  Next, when entering the amplifying circuit 30, a voltage of 10V (once every 1.1 seconds) and a voltage of 1V (once per 0.1 second), but when leaving the amplifying circuit 30, 10V It becomes a voltage around (once every 1.1 seconds) and a voltage around 10V (once every 0.1 seconds).

  Further, when entering the second signal extension 18, the voltage is around 10V (once every 1.1 seconds) and the voltage around 10V (once every 0.1 seconds). When exiting the extension 18, it becomes a continuous voltage of around 10V without becoming 0V.

As a result, since a voltage of around 10 V is continuously applied to the input portion of the charge / discharge circuit 19, electricity is charged to the capacitor 19A through the fifth resistor R5.
The voltage of electricity charged in the capacitor 19A exceeds the reference value (8V) of the first determination unit 20 in 2 to 3 seconds.

Since the reference value (8 V) of the first determination unit 20 is exceeded, an “H” signal voltage is applied to the input unit of the operational amplifier of the first determination unit 20.
The operational amplifier of the first determination unit 20 outputs an “H” signal voltage at the output unit when an “L” signal voltage is applied to the input unit. Here, the “H” signal is input to the input unit. Since a voltage is applied, the output unit outputs an “L” signal voltage.

Further, since the first determination unit 20 outputs a signal voltage of “L”, the first transistor 21 does not operate.
Further, since the first transistor 21 does not operate, the second transistor 22 and the oscillation circuit 13 also do not operate.

  Further, since the oscillation circuit 13 does not operate, the impact voltage generation circuit 14 also does not operate, and no impact voltage (first voltage) is generated.

In addition, since the first transistor 21 and the second transistor 22 are not operating, no electricity flows between the first transistor 21 and the second transistor 22.
However, the voltage of the 12 V power supply 27 is applied to the input part of the operational amplifier of the second determination unit 23, that is, the signal voltage of “H” is applied.

  In addition, the operational amplifier of the second determination unit 23 outputs an “H” signal voltage at the output unit when an “H” signal voltage is applied to the input unit. Therefore, the output unit outputs an “H” signal voltage.

  Further, since the second determination unit 23 outputs a signal voltage of “H”, the third transistor 24 operates and the fourth transistor 25 also operates.

  In addition, since the fourth transistor 25 operates, the notification voltage generation circuit 26 connected to the fourth transistor 25 also operates, and the notification voltage generation circuit 26 generates a notification voltage (third voltage).

  The output terminal 16 of the power supply device 12 has a third voltage of 300 V output from the output transformer 15 (once every 0.25 seconds) and a second voltage of 9 V output from the notification device 2. It overlaps and takes.

Moreover, although the 2nd voltage and the 3rd voltage are applied, the voltage which enters into the protection circuit 29 by the surge absorber 17 and voltage division is 22V (once every 1.1 second), 9V Voltage (once every 0.1 seconds).
When the protection circuit 29 is exited, the voltage is 10V (once every 1.1 seconds) and 1V (once every 0.1 seconds).

  Next, when entering the amplifying circuit 30, a voltage of 10V (once every 1.1 seconds) and a voltage of 1V (once per 0.1 second), but when leaving the amplifying circuit 30, 10V It becomes a voltage around (once every 1.1 seconds) and a voltage around 10V (once every 0.1 seconds).

  When the second signal extension 18 is entered, the voltage is around 10V (once every 1.1 seconds) and the voltage around 10V (once every 0.1 seconds). When exiting the extension 18, it becomes a continuous voltage of around 10V without becoming 0V.

  Since the capacitor 19A of the charge / discharge circuit 19 has already been charged with the upper limit electricity, if a voltage of around 10V is continuously applied to the input part of such a charge / discharge circuit 19, the voltage will always be the first determination part 20 Continue to exceed the reference value (8V).

Therefore, if the notification device 2 continues to apply the second voltage to the fence line 31, the notification voltage generation circuit 26 continues to generate the notification voltage (third voltage).
Further, when the second voltage is generated, the LED 4 blinks, so that it can be confirmed that the notification device 2 is sending the second voltage to the power supply device 12 through the fence line 31.
Further, since the sound generated by the buzzer 3 of the notification device 2 changes from intermittent sound to continuous sound, it can be seen that the first voltage has stopped. Then, a person can enter the fence with peace of mind without getting an electric shock.

Further, as shown in FIG. 4, when the power switch 7 of the notification device 2 is turned “off”, the stop command voltage generation circuit 5 does not operate and the second voltage is not generated.
Since the second voltage is not generated, the LED 4 also does not emit light.

  Since the second voltage is no longer generated, only the third voltage (300 V, once in 0.25 seconds) is temporarily applied to the output terminal 16, the fence line 31, and the hooking portion 10. Become.

  Further, since the first resistor R1 and the second resistor R2 are connected in parallel to the surge absorber 9, a third voltage is applied. However, the first signal is generated by the surge absorber 9 and the divided voltage. The voltage exceeding the reference value (4.5 V) of the extension 8 is a voltage based on the third voltage (about 5 V, once every 0.25 seconds), and a voltage based on the third voltage (about 5 V, 0 .Once every 25 seconds) is applied to the second resistor R2.

In the first signal extension unit 8, the time required for the voltage based on the third voltage (about 5 V, once in 0.25 seconds) is extended by 0.3 seconds.
Further, since the voltage based on the third voltage enters the first signal extension 8 once every 0.25 seconds, it is based on the third voltage before the extended 0.3 seconds are over. The voltage comes in, and the buzzer 3 emits a continuous sound without any non-sounding time.

  On the other hand, in the power supply device 12, the voltage of electricity flowing from the output transformer 15 is temporarily lowered by the protection circuit 29. Then, the lowered voltage is returned to about 10 V by the amplifier circuit 30. Next, the voltage returned to around 10 V (0.25 second / once) is applied to the second signal extension 18.

Further, since the voltage of about 10V is applied to the input portion of the charge / discharge circuit 19 in the first 0.2 seconds in 0.25 seconds, the capacitor 19A is charged through the fifth resistor R5 for 0.2 seconds. The
Depending on the direction of the diode, the capacitor 19A is not charged through the sixth resistor R6.

Next, since the voltage is not applied to the input portion of the charge / discharge circuit 19 for 0.05 seconds after 0.2 seconds, the input portion of the charge / discharge circuit 19 is 0 V for 0.05 seconds.
Then, the electricity charged in the capacitor 19A is discharged at a stroke to the input part which is 0V due to the potential difference. The discharge path is a path that passes through the fifth resistor R5 and the sixth resistor R6.

  By being discharged at once, the voltage does not exceed the reference value (8 V) of the first determination unit 20 in the charge / discharge circuit 19.

Further, since the reference value (8 V) of the first determination unit 20 is not exceeded, an “L” signal voltage is applied to the input unit of the operational amplifier of the first determination unit 20.
The operational amplifier of the first determination unit 20 outputs an “H” signal voltage at the output unit when an “L” signal voltage is applied to the input unit. Therefore, the output unit outputs an “H” signal voltage.

Further, since the first determination unit 20 outputs a signal voltage of “H”, the first transistor 21 is activated.
Further, since the first transistor 21 is activated, the second transistor 22 and the oscillation circuit 13 are also activated.

  In addition, a low voltage (L) signal voltage divided by the fourth resistor R4 of the third resistor R3 and the fourth resistor R4 is applied to the input unit of the operational amplifier of the second determination unit 23.

  The operational amplifier of the second determination unit 23 outputs an “H” signal voltage at the output unit when an “H” signal voltage is applied to the input unit. Therefore, the output unit outputs a signal voltage of “L”.

  Further, since the second determination unit 23 outputs a signal voltage of “L”, the third transistor 24 does not operate, and further, the fourth transistor 25 does not operate.

  Further, since the fourth transistor 25 does not operate, the notification voltage generation circuit 26 connected to the fourth transistor 25 does not operate, and naturally the notification voltage (third voltage) is not generated.

  In addition, since the second transistor 22 and the oscillation circuit 13 are operating, a voltage is also applied to the impact voltage generation circuit 14 connected to the oscillation circuit 13 so that the impact voltage generation circuit 14 operates and the first voltage is Occur.

  Then, a first voltage of 10,000 V (1.1 seconds / once) is applied to the output terminal 16 through the output transformer 15, and the first voltage is also applied to the fence line 31.

  In addition, the voltage of electricity flowing from the output transformer 15 is temporarily lowered by the protection circuit 29. Then, the lowered voltage is returned to about 10 V by the amplifier circuit 30. Next, the voltage returned to around 10 V (1.1 seconds / once) is applied to the second signal extension 18.

In addition, in the second signal extension unit 18, the voltage application time is extended for 0.2 seconds, and the input unit of the charge / discharge circuit 19 has a voltage of about 10V for the first 0.2 seconds out of 1.1 seconds. Since voltage is applied, the capacitor 19A is charged through the fifth resistor R5 for 0.2 seconds.
Depending on the direction of the diode, the capacitor 19A is not charged through the sixth resistor R6.

Next, since the voltage is not applied to the input part of the charge / discharge circuit 19 for 0.9 seconds after 0.2 seconds, the input part of the charge / discharge circuit 19 is 0 V for 0.9 seconds.
Then, the electricity charged in the capacitor 19A is discharged at a stroke to the input part which is 0V due to the potential difference. The discharge path is a path that passes through the fifth resistor R5 and the sixth resistor R6.

  By being discharged at once, the voltage does not exceed the reference value (8 V) of the first determination unit 20 in the charge / discharge circuit 19. The subsequent flow is as described above.

On the other hand, the first voltage is applied to the hooking portion 10 through the fence line 31.
In addition, since the first resistor R1 and the second resistor R2 are connected in parallel to the surge absorber 9, the reference value (4.5V) of the first signal extension 8 is obtained by the surge absorber 9 and the divided voltage. ) Exceeding 1) is applied to the second resistor R2 once every 1.1 seconds.

Moreover, in the 1st signal extension part 8, the time which requires the voltage exceeding the reference value (4.5V) of the 1st signal extension part 8 is extended by 0.3 second.
Then, the buzzer 3 sounds for the extended 0.3 second, and no sound is generated for 0.8 seconds. Such intermittent sound is repeated while the hook 10 is connected to the fence line 31 with the power switch 7 of the notification device 2 turned off.

As described above, when the notification device 2 does not generate the second voltage, the third voltage is also not generated, and the state where only the first voltage is generated continues.
Moreover, since the sound which the buzzer 3 of the notification device 2 emits changes from a continuous sound to an intermittent sound, it can be seen that the first voltage is applied to the fence line 31 again. And since wild animals cannot enter the fence from outside the fence, people can work in the fence with peace of mind.

Then, the hooking part 10 of the notification device 2 is removed from the fence line 31.
Then, since the hook part 10 of the notification device 2 is not connected to the fence line 31, no voltage is applied to the first resistor R1 and the second resistor R2. Therefore, no voltage is applied to the first signal extension 8 and the buzzer 3, and the buzzer 3 does not operate.
Further, since the power switch 7 of the notification device 2 is set to “off”, the LED 4 is also turned off.
The circuit at this time is the same as the circuit shown in FIG.

  Accordingly, it is possible to eliminate the consumption of electricity for generating the intermittent sound of the buzzer 3, and the first voltage is continuously applied to the fence line 31 even if the notification device 2 is removed from the fence line 31. People can work inside the fence with peace of mind.

In addition, when a person goes out of the fence after the work in the fence is completed, the hooking portion 10 of the notification device 2 is connected to the fence line 31 and the power switch 7 of the notification device 2 is turned “ON”. .
And when a person goes out of the fence and leaves the electric fence, if the power switch 7 of the notification device 2 is turned “OFF”, the hooking portion 10 is removed from the fence line 31 and the notification device 2 is left. Good.

  Here, the electric fence of the present invention includes a conductive member formed around a predetermined region, a first voltage generation circuit that is electrically connected to the conductive member and applies a first voltage to the conductive member. A third voltage electrically connected to the conductive member and having a voltage value lower than the first voltage when a second voltage having a voltage value lower than the first voltage is applied to the conductive member; A third voltage generating circuit for applying a voltage to the conductive member; and a first voltage generation circuit that is detachably and electrically connected to the conductive member, and that is notified when the first voltage is connected to the conductive member. Annunciator comprising: a notification means; a second voltage generation means capable of generating a second voltage; and a second notification means for notifying when the second voltage generation means generates the second voltage. If the first notification means is not necessarily a buzzer Also, necessarily second notification means may not an LED.

For example, the first notification means may be an LED and the second notification means may be a buzzer.
However, the LED may miss light emission, and if the first notification means is a buzzer, it is preferable because it is easier for a person to notice that the first voltage is applied to the conductive member than the LED. .

  Further, for example, both the first notification means and the second notification means can be buzzers, and both the first notification means and the second notification means can be LEDs.

That is, when connected to the conductive member to which the first voltage is applied, when the second voltage generating means generates the second voltage, and when the third voltage is further applied to the conductive member Also, the buzzer can notify, or the LED can notify.
At this time, when connected to the conductive member to which the first voltage is applied, when the second voltage generating means generates the second voltage, and when the third voltage is applied to the conductive member Thus, the type of buzzer sound can be made different, and the type of LED light can be made different.

  An electric fence according to the present invention includes a conductive member formed around a predetermined region, a first voltage generation circuit that is electrically connected to the conductive member and applies a first voltage to the conductive member, A third voltage electrically connected to the conductive member and having a voltage value lower than the first voltage when a second voltage having a voltage value lower than the first voltage is applied to the conductive member A third voltage generating circuit for applying the first voltage to the conductive member; and a first voltage generating circuit that is detachably and electrically connected to the conductive member, and that is notified when the first voltage is applied to the conductive member. A notification device comprising: notification means; second voltage generation means capable of generating a second voltage; and second notification means for notifying when the second voltage generation means generates the second voltage; If the third voltage is necessarily applied to the conductive member The first announcement means may or may not notice.

For example, the annunciator may have a third notifying unit that notifies when the third voltage is applied to the conductive member, separately from the first notifying unit.
In this case, for example, if the first notification means is a buzzer, the third notification means is an LED, and if the first notification means is an LED, the third notification means is a buzzer.

  As described above, the electric fence of the present invention is electrically connected to the conductive member, and the first fence is applied when the second voltage having a voltage value lower than the first voltage is applied to the conductive member. Since the third voltage generation circuit that applies the third voltage having a voltage value lower than the voltage to the conductive member is provided, the first voltage applied to the conductive member can be simply applied at any place. Since the third voltage having a voltage value lower than the first voltage is applied to the conductive member, even if a person touches the conductive member to which the third voltage lower than the first voltage is applied, the fence You can enter and get out of the fence.

Further, since the notification device is detachably and electrically connected to the conductive member, the notification device can be connected to a desired position of the conductive member.
In addition, since the notification device has first notification means for notifying when connected to the conductive member to which the first voltage is applied, it is possible to know whether or not the first voltage is applied to the conductive member. it can.

In addition, since the notification device has the second voltage generating means capable of generating the second voltage, the notification device is electrically connected to the conductive member, the second voltage is applied to the conductive member, and the third voltage is generated. The voltage generation circuit can apply the third voltage to the conductive member.
In addition, since the notification device has the second notification means for notifying when the second voltage generation means generates the second voltage, it is possible to know the generation of the second voltage. In a state where the notification device is connected to the conductive member, it can be known that the third voltage is applied to the conductive member.

Therefore, the electric fence of the present invention can pass through at a desired position without an electric shock, and can easily check the voltage state.
Therefore, with the electric fence of the present invention, when a person enters or exits a field surrounded by the electric fence, it is not necessary to bother to move to the position of a gate or the like as in the case of a conventional electric fence. Simply apply the second voltage to the conductive member (fence line) with the instrument, and you can easily check the voltage applied to the conductive member (fence line) without electric shock at that location. You can go in and out of the fields surrounded by.

  Therefore, the electric fence of the present invention makes it safe and easy to manage weeding and fertilizing fields, etc., and can be performed in a short time, greatly reducing time and labor, and is extremely beneficial for agricultural management. is there.

1 Electric fence 2 Notification 3 Buzzer 4 LED
DESCRIPTION OF SYMBOLS 5 Stop command voltage generation circuit 6 Power supply 7 Power switch 8 1st signal extension part 9 Surge absorber 10 Hook part 11 Grounding part 12 Power supply device 13 Oscillation circuit 14 Impact voltage generation circuit 15 Output transformer 15A Winding of secondary winding End 15B Winding start of secondary winding 16 Output terminal 17 Surge absorber 18 Second signal extension 19 Charge / discharge circuit 19A Capacitor 20 First determination unit 21 First transistor 22 Second transistor 23 Second determination unit 24 Third transistor 25 4th transistor 26 Notification voltage generating circuit 27 Power supply 28 Power switch 29 Protection circuit 30 Amplifier circuit 31 Fence line R1 1st resistor R2 2nd resistor R3 3rd resistor R4 4th resistor R5 5th resistor R6 1st 6 resistors

Claims (5)

A conductive member formed around a predetermined area;
A first voltage generating circuit that is electrically connected to the conductive member and applies a first voltage to the conductive member;
The second voltage is electrically connected to the conductive member and has a voltage value lower than the first voltage when a second voltage having a voltage value lower than the first voltage is applied to the conductive member. A third voltage generating circuit for applying a third voltage to the conductive member;
A first notification means for removably and electrically connecting to the conductive member and for notifying when connected to the conductive member to which the first voltage is applied, and generating the second voltage An electric fence comprising: a possible second voltage generation means; and a second notification means for notifying when the second voltage generation means generates the second voltage. The first notification means notifies when the third voltage is applied to the conductive member in a manner different from that when the third voltage is applied to the conductive member to which the first voltage is applied. Electric fence as described in. The electric fence according to claim 1, wherein the notification device includes a third notification unit that notifies when the third voltage is applied to the conductive member. The electric fence according to any one of claims 1 to 3, wherein the first notification means is a means for issuing a sound. The notification device includes a hook-shaped hook portion hooked on the conductive member;
The electric fence according to claim 1, further comprising a grounding portion that is grounded to the ground.

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