JP6865487B1 - Power supply for electric fence - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply device for electric fence integrated with a solar panel, which can easily put the power supply device for electric fence into a standby state with a full charge and start using it at any time. SOLUTION: A solar panel 12 integrally provided in a housing 11 of an electric power supply device 10 is provided, and a rechargeable battery and a high voltage pulse are generated from a battery voltage inside the housing 11. A housing for a solar panel-integrated electric power supply equipped with a booster circuit that outputs from an output terminal provided outside the body and a regulator that is connected to the solar panel to control the input voltage and charge the battery appropriately. A socket 20 for the AC adapter, which is the connection part of the output plug of the AC adapter, is provided in a part of the case, and by connecting this socket to the battery via a regulator inside the housing, low cost and easy additional charging is possible. It is a power supply device for electric fences with improved convenience. [Selection diagram] Fig. 1

Description

The present invention relates to an electric fence power supply using a solar panel, and in particular, an electric fence including an integrated solar panel in which the solar panel is incorporated in or attached to a housing of the electric fence power supply. Regarding power supply for power supply.

Conventionally, a high voltage (6000 to 10000V) electric pulse (hereinafter simply referred to as a pulse) is applied to a conductive wire (hereinafter simply referred to as a wire) laid on a fence to give an electric shock to livestock and wild animals that touch the wire. Electric fences for animals that give and drive away are known. Such electric fences are installed on columns installed at intervals around cultivated land, etc. where we want to prevent the invasion of animals, fences with wires insulated from the ground, and overhead wires. It is equipped with a power supply device that applies voltage pulses at regular time intervals.

Early electric power supplies were mechanical, using a rechargeable secondary battery (hereinafter referred to as the battery) as the power source, boosting the battery voltage, and intermittently energizing with a spring to generate a pulsed high-voltage voltage. While consuming a large amount of electricity, it was necessary to consider high voltage in consideration of safety. Therefore, the practical distance of the fence that can be connected to the electric power supply device at that time was only about 100 to 200 m. However, advances in semiconductor technology have made it possible to generate high-voltage pulses in an extremely short time, making it possible to achieve both performance and safety, improving economic efficiency, and making electric fences more widespread. ..

As such an electric fence, Patent Document 1 discloses that a battery is used as a power source of the electric fence power supply device. Further, Patent Document 2 discloses that a battery is housed in a power storage container of an electric power supply device and a connection terminal for connecting an external power source such as an automobile battery is provided on the outside of the power storage container. ing.

In an electric fence device that uses a battery, the performance of the electric fence cannot be maintained when the battery voltage drops, so it is necessary to replace the battery regularly. It was a hassle.

Therefore, in recent years, power supply devices that combine batteries with solar panels have begun to spread. In an electric power supply that also uses a solar panel, the power generated by the solar panel is used to charge the battery and generate high-voltage pulses when there is sunlight in the daytime, and the battery is used at night when there is no sunlight. Is used to generate high voltage pulses. In the electric power supply device using such a solar panel together, the trouble of battery replacement can be saved. The solar panel is often placed separately from the electric power supply, but the solar panel is installed in the housing of the electric power supply, or the solar panel is attached to the outside of the electric power supply housing. Power supplies for electric fences with integrated solar panels are also widespread.

Patent Document 3 discloses a power supply device for electric fence including a solar cell (solar panel) and a battery. In Patent Document 3, when solar energy is obtained, the electric power from the solar cell is used for the bare electric wire, the battery is charged with the surplus electric power, and when the solar energy cannot be obtained, the electric power of the battery is used. It is disclosed. Further, Patent Document 3 shows a connection example in which an AC power supply is used without using a solar cell. In this case, the AC power supply is supplied via a transformer and an AC-adapter equipped with a DC converter. Is connected to the pulse generator.

Japanese Unexamined Patent Publication No. 2005-151748

JP-A-2019-146535

JP-A-11-169007

In Japan, most of the electric fences are used for vermin countermeasures (measures to prevent vermin such as wild boar from entering the fields), but the season of damage by vermin is limited. Also, in heavy snowfall areas, the electric fence is buried in the snow in winter and is not useful as an electric fence, and if the power supply device for the electric fence is left unattended, it will be damaged by the snow load. It is usual to store the device in a barn or the like. However, in the case of a power supply device for electric fences with an integrated solar panel, there is a strong tendency to switch it off and store it in the barn as it is.

However, when stored in the barn, the solar panel of the electric power supply with integrated solar panel is not exposed to the sun, so the battery is not charged, and dark current flows inside the circuit, causing the battery to discharge fairly quickly, and in some cases. In the following spring, the recharge function was often lost due to the complete discharge of the battery. The user purchased a solar panel-integrated electric power supply because it does not require a dry battery and is economical and can improve the environment, but the solar panel-integrated electric power supply does not work the following spring. It is a big miscalculation.

On the other hand, a similar problem occurred in the power supply device for electric fences with integrated solar panels displayed on the shelves of dealers. Since the solar panel cannot fully charge the battery only with the lighting inside the store, the solar panel-integrated electric power supply that was exhibited for a long time may not be usable by the user immediately after the sale, and complaints have been received. Was being done. Dealers who want to avoid complaints can take out the battery from the solar panel integrated electric power supply and charge it regularly, or every few months from the shelf or warehouse the solar panel integrated electric power supply. It was necessary to take the device outdoors and charge it with sunlight. These took a lot of time and effort, and some dealers hesitated to handle the power supply for electric fences with integrated solar panels.

In this way, the power supply for electric fence with integrated solar panel has an extremely ideal configuration, but even if the battery is fully charged at the time of shipment from the manufacturer, it takes at least a few months to reach the final user, on average. It takes 6 to 10 months, so the dealer had to recharge at some point. Similarly, if the power supply device for electric fences with integrated solar panels is stored in a barn where the sun does not shine when the electric fences are not used, the electric fences often become unusable due to the voltage drop of the battery when reused. Was.

The present inventor has a regulator that controls the input voltage from the solar panel to properly charge the built-in battery in the power supply device for electric fence integrated with the solar panel, so that it is built in without using an expensive charger. We have found that the battery can be charged, and have come up with the present invention. That is, the present invention is an electric power supply device for charging a battery with a solar panel, particularly a solar panel integrated type in which a battery is built in and the solar panel is integrally incorporated or attached to a housing of the power supply device. By providing an inexpensive AC adapter connection terminal with a constant output voltage in the housing of the electric power supply, the AC adapter can be used to easily put the electric power supply into a standby state with a full charge and use it at any time. An object of the present invention is to provide a solar panel-integrated electric power supply that can be started.

In the electric power supply device of the present invention that achieves the above object, a solar panel is integrally provided in a housing, and a rechargeable battery and a high voltage pulse are generated inside the housing by being connected to the battery. A booster circuit that controls the voltage and a regulator that controls the voltage input from the solar panel to properly charge the battery are provided, and an output terminal that connects to the booster circuit is provided on the outer surface of the housing. In the power supply device, a connection part with the output terminal of the AC adapter capable of charging the battery is provided in a part of the housing, and this connection part is a power supply device for electric fence connected to the regulator inside the housing. Is.

According to the electric power supply device of the present invention, even if the built-in battery cannot be charged by the solar panel, the built-in battery can be simply connected to the AC adapter connection portion provided in the housing. Since it can be charged, it has the following effects.

(1) Since the battery of the electric power supply device stored in the shelves or warehouse of the store can be easily charged without any hassle, the electric battery is heated immediately after the sale of the device due to insufficient charging of the battery. You can avoid complaints that does not work.
(2) Even when the power supply for the electric fence is stored in a barn, etc. when the farmer does not use the electric fence, the battery of the power supply can be charged appropriately with the AC adapter without any hassle. It will be possible to improve the convenience of reusing the battery at any time and prevent the battery from being consumed due to insufficient charging.

(3) Even if the battery of the electric power supply is not fully charged by the solar panel due to unseasonable weather, if you bring back the electric power supply and charge it, it will be fully charged in 2 to 3 hours. Therefore, an electric power supply can be used as a countermeasure against animal damage at night.
(4) There are 6V, 9V, and 12V types of sealed batteries used as built-in batteries, and when charging outside the electric power supply, conventional chargers with dedicated charging functions are used. It was charging. However, in the present invention, the battery is appropriately supplied by the regulator built in the electric power supply device only by supplying electricity of a predetermined voltage (for example, 12V) from the AC adapter without taking out the battery from the electric power supply device. Can be charged. Therefore, in the present invention, it is not necessary to prepare an expensive dedicated charger for each battery having a different voltage, and the AC adapter itself is extremely low in cost as compared with the dedicated charger, so that the overall cost can be suppressed. Is possible and has great economic benefits.

(A) is a diagram for explaining the configuration of the electric fence, and (b) is one of the power supply devices for electric fence integrated with the solar panel in the form in which the solar panel is incorporated in the housing in the electric fence shown in (a). The housing of the embodiment is a perspective view seen from the front side, and (c) is a perspective view of the housing of the solar panel integrated electric power supply device shown in (b) seen from the back side. It is a block diagram which shows the internal structure of the power supply device for electric fence integrated with the solar panel shown in FIGS. 1 (b) and 1 (c). (A) shows the first embodiment of the socket for the AC adapter shown in FIG. 1 (c), and is a partially enlarged perspective view showing a state in which the waterproof cap is opened and the output plug of the AC adapter is inserted. (B) is a partially enlarged cross-sectional view showing a state in which the waterproof cap shown in (a) closes the socket for the AC adapter. It is a partially enlarged sectional view of the housing of the part of the socket for AC adapter shown in FIG. 3A. (A) shows a second embodiment of the AC adapter socket shown in FIG. 1 (c), and is an AC adapter provided with a second waterproof cap for waterproofing the output plug of the AC adapter in addition to the waterproof cap. A partially enlarged perspective view of the socket for use, (b) is a partial view of the plug seal portion of the second waterproof cap shown in (a) as viewed from the direction of arrow A, and (c) is a partial view of the plug seal portion shown in (b). A cross-sectional view taken along line BB, (d) is a partially enlarged cross-sectional view showing a waterproof portion when the output plug of the AC adapter is inserted into the plug seal portion shown in (c), and (d) is shown in (a). It is a partially enlarged perspective view which shows the state which the output plug of the AC adapter is connected to the socket for the AC adapter shown by using the 2nd waterproof cap. (A) is a perspective view of the housing of an example of a power supply device for electric fence integrated with a solar panel in which a solar panel is attached to the upper part of the housing, and (b) is shown in (a). A perspective view of the housing of the power supply device for electric fence integrated with a solar panel as viewed from the rear side, (c) is a perspective view showing the mounting position of the AC adapter socket shown in (b) in a partially enlarged manner. It is a figure.

Hereinafter, examples of the electric power supply device of the present invention will be described with reference to the accompanying drawings. In the embodiment of the electric power supply device of the present invention described below, an embodiment having a structure in which rainwater does not enter the inside of the power supply device from the AC adapter socket provided in the power supply device will be described. ..

FIG. 1A illustrates the configuration of an embodiment of an electric fence 40 including a fence 1 and an electric fence power supply device 10. The fence 1 is installed around a cultivated land or the like where animals are to be prevented from invading, and the wire 2 is insulated from the ground on a support column 3 formed of an insulator erected at a certain distance. It is an overhead wire. Since the wires 2 are installed according to the size of the animal to be prevented from invading, they are generally installed in a plurality of stages at predetermined intervals. In the embodiment shown in FIG. 1A, three wires 2 are overheaded on the fence 1 in three stages, and the height applied to one wire 2 is between the three wires 2. A crossover 2c is provided so that the voltage pulse reaches the wires 2 in all stages.

In this embodiment, the electric power supply device 10 is attached to the tip of a post 5 standing on the ground. A battery is built in the electric power supply device 10, and a solar panel 12 integrally provided in the housing 11 of the electric power supply 10 is exposed on the outer surface of the housing 11. A power supply lead wire 6 and a ground wire 7 are drawn out from the electric power supply device 10, and the power supply lead wire 6 is connected to one of the three wires 2 by an alligator clip 6a. Further, the ground wire 7 is connected to the ground rod 4 embedded in the ground by an alligator clip 7a. A high-voltage pulse is generated in the electric power supply device 10, and the generated high-voltage pulse is output to the power supply lead wire 6 at regular time intervals and applied to one of the three wires 2. It is also applied to the other wire 2 through the crossover wire 2c.

FIG. 1B is a view of the housing 11 of the solar panel-integrated electric power supply device 10 shown in FIG. 1A as viewed from the front surface 11a side. The front surface of the housing 11 of the electric power supply device 10 is inclined so that sunlight can reach the solar panel 12 well. Further, there is a mode changeover switch 13 on the upper side of the front surface of the housing 11 of the electric power supply device 10. The mode changeover switch 13 has a mode in which the output interval of the high-voltage pulse output from the electric power supply device 10 is set to a normal interval (1.3 seconds), a mode in which the output interval is set to a short interval (1.1 seconds), and only at night. It switches between a pulse output mode, a battery voltage check mode, and a power off mode. Further, the uppermost portion of the housing 11 is a handle 11c.

FIG. 1C is a view of the housing 11 of the electric power supply device 10 shown in FIG. 1B as viewed from the back surface 11b side. On the back surface 11b of the housing 11 of the electric power supply device 10, the output terminal 16 to which the power supply lead wire 6 shown in FIG. 1A is connected and the ground terminal 17 to which the ground wire 7 is connected are on the left side. It is provided in. Further, on the right side of the back surface 11b of the housing 11 of the electric power supply device 10, an AC adapter socket 20 for connecting the output plug of the AC adapter described later is provided. Further, there is a battery cover 14 that can be opened by loosening the screw 14s at the center of the back surface 11b of the housing 11 of the electric power supply device 10. The battery cover 14 is opened when the battery is replaced. A post mounting portion 15 for inserting the post 5 shown in FIG. 1A is formed on the lower side of the battery cover 14.

FIG. 2 is a block diagram showing an example of the internal configuration of the solar panel integrated power supply device 10 for electric fence shown in FIGS. 1 (b) and 1 (c). A solar panel 12 is integrally provided in the housing 11 of the electric power supply device 10. The voltage obtained from the solar panel 12 is input to the regulator 21. Further, the output plug of the AC adapter 8 that generates a DC voltage from a commercial power supply of 100 V is connected to the socket 20 for the AC adapter. The DC voltage input to the AC adapter socket 20 is input to the regulator 21.

The regulator 21 is connected to the solar panel 12, the battery 18, and the socket 20 for the AC adapter, and the higher input voltage is sent to the battery 18 by the built-in determination circuit to charge the battery 18. When the AC adapter 8 is connected to the AC adapter socket 20, it is possible to prevent the voltage from being input from the solar panel 12 to the regulator 21. At this time, the AC adapter socket 20 is provided with a switch for turning on / off the circuit connecting the solar panel 12 and the regulator 21, so that this switch is turned off when the AC adapter 8 is connected to the AC adapter socket 20. It should be.

The booster circuit 22 generates a high voltage pulse from the voltage of the battery-18 according to the mode when the mode changeover switch 13 is in the normal interval mode, the short interval mode, or the mode for outputting the pulse only at night. The high-voltage pulse generated by the booster circuit 22 is applied to the wire 2 of the fence 1 installed outside the electric power supply device 10 through the power supply lead wire 6 connected to the output terminal 16. .. The ground terminal 17 provided on the housing 11 is connected to the ground rod 4 by the ground wire 7 and is grounded. The grounding in the housing 11 connected to the ground terminal 17 is not shown except for the booster circuit 22.

FIG. 3A shows a first embodiment of the AC adapter socket 20 shown in FIG. 1C, and shows an embodiment in which the AC adapter socket 20 is provided with the waterproof cap 30. There is. In this embodiment, since the output plug 23 of the AC adapter is cylindrical, the plug insertion hole 25 of the socket 20 for the AC adapter is also a circular hole, but the shape of the output plug 23 of the AC adapter is square or an automobile. In the case of the connector shape used for the harness of the above, the shape of the plug insertion hole 25 of the AC adapter socket 20 also matches the shape of the output plug 23. When the outside of the output plug 23 is a negative electrode, the AC adapter socket 20 has a disc-shaped negative electrode 24 made of a conductive metal, and a plug insertion hole 25 is provided in the center of the disc-shaped negative electrode 24. ing. There is a positive electrode 26 inside the plug insertion hole 25.

The waterproof cap 30 is made of rubber and is fixed around the AC adapter socket 20 by a ring-shaped base 32. An arm portion 31 is connected to a part of the side surface of the base portion 32, and a lid member 33 is provided at the tip end portion of the arm portion 31 extending from the base portion 32. A waterproof protrusion 34 is provided on one surface of the lid member 33, and a hollow portion 35 for receiving the positive electrode 26 of the AC adapter socket 20 is provided at the tip of the waterproof protrusion 34. Further, the diameter of the waterproof protrusion 34 is formed to be slightly larger than the inner diameter of the plug insertion hole 25 in the AC adapter socket 20, and the waterproof protrusion 34 is inserted into the plug insertion hole 25 in a compressed state. When the waterproof protrusion 34 is inserted into the plug insertion hole 25, the plug insertion hole 25 becomes watertight by the waterproof protrusion 34, and the AC adapter socket 20 is waterproofed.

FIG. 3B shows a state in which the waterproof protrusion 34 of the waterproof cap 30 shown in FIG. 3A is fitted into the plug insertion hole 25 of the AC adapter socket 20 to close the plug insertion hole 25. is there. In this state, the arm portion 31 of the waterproof cap 30 is folded back, the waterproof protrusion 34 is inserted into the plug insertion hole 25 in a compressed state, and the lid member 33 is in close contact with the disc-shaped negative electrode 24 of the AC adapter socket 20. doing.

FIG. 4 is an enlarged view of an embodiment of a cross section of the housing 11 provided with the AC adapter socket 20 shown in FIG. 3 (a). The tubular negative electrode 27 of the AC adapter socket 20 is inserted into the AC adapter socket mounting hole 11h provided in the housing 11, and one end of the tubular negative electrode 27 serves as a discoid negative electrode 24. It is exposed on the body 11. The inside of the tubular negative electrode 27 is a plug insertion hole 25, and the positive electrode 26 is inside the plug insertion hole 25. The base portion 32 of the waterproof cap 30 is provided around the disc-shaped negative electrode 24, and the lid member 33 is located at the tip end portion of the arm portion 31 extending from the base portion 32. When the waterproof protrusion 34 projecting from the lid member 33 is fitted into the plug insertion hole 25, the positive electrode 26 is inserted into the hollow portion 35 of the waterproof protrusion 34.

A positive lead wire 29a is connected to the positive electrode 26, and a negative lead wire 29b is connected to the inside of the tubular negative electrode 27. The negative lead wire 29b can also be connected to the outside of the tubular negative electrode 27. The positive lead wire 29a is connected to the regulator 21 shown in FIG. 2, and the negative lead wire 29b is connected to the ground inside the housing 11. The portion of the tubular negative electrode 27 where the positive lead wire 29a and the positive electrode 26 are connected and the portion where the negative lead wire 29b is connected to the inner wall of the tubular negative electrode 27 are sealed with an insulating sealing material 28. Therefore, even when the waterproof cap 30 does not block the plug insertion hole 25, the water that has entered through the plug insertion hole 25 does not enter the inside of the housing 11.

In the first embodiment of the AC adapter socket 20, when the AC adapter is not connected, the waterproof cap 30 covers the plug insertion hole of the AC adapter socket 20 to make it waterproof as shown in FIG. 3 (b). .. When connecting the output plug 23 of the AC adapter to the socket 20 for the AC adapter, as shown in FIG. 3A, the waterproof protrusion 34 of the waterproof cap 30 is pulled out from the plug insertion hole 25 to output the AC adapter. The main body 23b of the plug 23 may be gripped and the output plug 23 may be inserted into the plug insertion hole 25.

FIG. 5A shows a second embodiment of the AC adapter socket 20 shown in FIG. 1C. In the first embodiment, only the waterproof cap 30 is provided on the AC adapter socket 20, but in the second embodiment, the AC adapter socket 20 is provided with the second waterproof cap 60 in addition to the waterproof cap 30. ing. In the first embodiment, when the output plug 23 of the AC adapter is connected to the socket 20 for the AC adapter, the connection portion between the output plug 23 of the AC adapter and the socket 20 for the AC adapter is not waterproof. On the other hand, in the second embodiment, the output plug 23 of the AC adapter is connected to the socket 20 for the AC adapter by using the second waterproof cap 60 to connect the output plug 23 of the AC adapter and the socket 20 for the AC adapter. The part is waterproof.

Since the structure of the waterproof cap 30 in the second embodiment is the same as that in the first embodiment, the description of the structure of the waterproof cap 30 will be omitted, and only the structure of the second waterproof cap 60 will be described. The second waterproof cap 60 is connected to an arm portion 61 extending from a part of the ring-shaped base portion 32 of the waterproof cap 30, a plug seal portion 62 provided at the tip end portion of the arm portion 61, and a side surface of the plug seal portion 62. A locking projection 63 is provided. The structure of the plug seal portion 62 is shown in FIG. 5 (b) when the plug seal portion 62 is viewed from the direction of arrow A and FIG. 5 (c) showing a cross section of the plug seal portion 62 along the line BB. ..

The plug insertion hole 64 through which the output plug 23 of the AC adapter shown in FIG. 3A is inserted and the main body 23b of the output plug 23 of the AC adapter are inserted into the plug seal portion 62 adjacent to the plug insertion hole 64. Then, a main body seal hole 65 for sealing the main body and a guide slope 67 for guiding the main body 23b of the output plug 23 to the main body seal hole 65 are provided adjacent to the main body seal hole 65. The inner diameter of the main body seal hole 65 is slightly smaller than the outer diameter of the main body 23b of the output plug 23. Further, the housing 11 is provided with a locking protrusion insertion hole 68 into which the locking protrusion 63 can be fitted at a position facing the locking protrusion 63 when the arm portion 61 is bent.

In the second embodiment, when the output plug 23 of the AC adapter is inserted into the plug insertion hole 25 of the socket 20 for the AC adapter, the output plug 60 is inserted using the second waterproof cap 60. First, the output plug 23 of the AC adapter is inserted into the plug insertion hole 64 of the plug seal portion 62, and the insertion is continued as it is. Then, the end surface of the main body 23b of the output plug 23 of the AC adapter is guided by the guide slope 67 and enters the main body seal hole 65 of the plug seal portion 62, and eventually the end surface of the main body 23b reaches the bottom surface of the main body seal hole 65. In this state, the end face and the side surface of the main body 23b are sealed by the seal portion 66 as shown in FIG. 5 (d).

In the locking projection 63, the output plug 23 is inserted into the plug insertion hole 64 of the plug seal portion 62, the main body 23b of the output plug 23 is in close contact with the main body seal hole 65, and the arm portion 61 is bent to form the output plug 23. Is inserted into the plug insertion hole 25, and reaches directly above the locking projection insertion hole 68 provided in the housing 11. Therefore, the output plug 23 is continuously inserted into the plug insertion hole 25, and the locking projection 63 is pushed into the locking projection insertion hole 68. Since the outer diameter of the locking protrusion 63 is formed to be slightly larger than the inner diameter of the locking protrusion insertion hole 68, if the locking protrusion 63 is pushed into the locking protrusion insertion hole 68 in this state, the locking protrusion 63 will be formed. It is fitted into the locking projection insertion hole 68 in a compressed state, and the output plug 23 is connected to the plug insertion hole 25 in a state of being waterproofed by the plug seal portion 62.

FIG. 5E shows a state in which the output plug 23 of the AC adapter is attached to the socket 20 for the AC adapter shown in FIG. 5A by the above operation using the second waterproof cap 60. Is. The output plug 23 of the AC adapter is inserted into the plug insertion hole 25 of the socket 20 for the AC adapter in a state of being inserted into the plug insertion hole 64 of the plug seal portion 62. At this time, by fitting the locking projection 63 of the second waterproof cap 60 into the locking projection insertion hole 68 provided in the housing 11, the plug seal portion 62 does not come off from the AC adapter socket 20, and the plug seal The portion 62 is in close contact with the disc-shaped negative electrode 24 to make it waterproof.

In this way, by connecting the output plug 23 of the AC adapter to the socket 20 for the AC adapter using the second waterproof cap 60, the connection portion between the output plug 23 of the AC adapter and the socket 20 for the AC adapter is waterproofed. be able to. Therefore, the electric power supply device 10 provided with the second waterproof cap 60 can charge the battery even outdoors if the extension cord of the power supply is used and the plug portion of the AC adapter is waterproofed.

FIG. 6A shows an embodiment of a solar panel-integrated electric power supply device 50 in which the solar panel 52 is attached to the upper part of the housing 51 by using a bracket 54, as viewed from one side surface side. It is a thing. The power supply device 50 of this embodiment has a rectangular parallelepiped housing 51 and a solar panel 52 integrally provided on the upper surface of the housing 51 via a bracket 54. A battery, a booster circuit, and a regulator are built in the housing 51. A mode changeover switch 53 is provided on one side surface of the housing 51, and a handle 55 is provided on the upper surface.

FIG. 6B is a rear view of the housing 51 of the electric power supply device 50 shown in FIG. 6A. An output terminal 56 and a ground terminal 57 are provided on the back side of the housing 51, and a socket 59 to which the output plug 23 of the AC adapter 8 is connected is provided in the recess 58. FIG. 6 (c) is a perspective view showing a partially enlarged view of the mounting position of the AC adapter socket 59 shown in FIG. 6 (b). The recess 58 that opens to the back surface of the housing includes an upper base 58U, a lower base 58B, and three side surfaces 58A, and a socket 59 is provided in the upper bottom 58U. Further, the upper portion of the opening 58D of the recess 58 is covered with a cover 58C flush with the surface of the housing 51 to prevent rainwater from reaching the socket 59. The power supply device 50 of this form does not require a waterproof cap and a second waterproof cap in the socket 59, and if the extension cord of the power supply is used and the plug portion of the AC adapter is waterproofed, the battery can be charged even outdoors. It is possible.

The power supply device for an electric fence integrated with a solar panel according to the present invention has been described above based on examples, but the connection portion between the output plug 23 of the AC adapter and the socket 20 for the AC adapter and waterproofing are carried out as described above. It is not limited to the example. That is, when the output of the AC adapter is a wire, the connection portion may be a wire connection terminal instead of a socket, and may have both a socket and a connection terminal. Further, when the power supply device of the electric fence fence integrated with the solar panel is charged indoors by using the AC adapter, the second waterproof cap 60 does not have to be used because there is no risk of rainwater.

The greatest effect of the present invention is that when the voltage of the battery in the power supply device for electric fence integrated with a solar panel drops, the battery can be charged without removing the battery from the housing of the power supply device for electric fence. is there. Therefore, at a store that sells an electric power supply, the battery of the electric power supply stored in a shelf or a warehouse can be easily charged without any hassle. It is possible to avoid complaints that the electric shelves do not work due to insufficient charging of the battery immediately after sale.

1 Fence 2 Wire 3 Strut 4 Ground rod 5 Post 6 Power supply lead wire 6a, 7a Alligator clip 7 Ground wire 10,50 Electric power supply device 11, 50 Housing 11a Front 11b Back 12, 52 Solar panel 13, 53 Mode selector switch 14 Battery cover 15 Post mounting part 16, 56 Output terminal 17, 57 Ground terminal 18 Battery 20, 59 AC adapter socket 21 Regulator 22 Booster circuit 23 Output plug 23b Output plug body 25 Plug insertion hole 30 Waterproof cap 34 Waterproof Protrusion 40 Electric transformer 60 Second waterproof cap 62 Plug seal part 63 Locking protrusion 68 Locking protrusion insertion hole

Claims (3)

A solar panel is integrally provided in the housing, and inside the housing, a rechargeable battery, a booster circuit connected to the battery to generate a high voltage pulse, and a voltage input from the solar panel are supplied. A part of the housing in an electric power supply device provided with a regulator for controlling and appropriately charging the battery and an output terminal connected to the booster circuit on the outer surface of the housing. Is provided with a connection portion with the output terminal of the AC adapter capable of charging the battery, and this connection portion is connected to the regulator inside the housing.
The output terminal of the AC adapter is a plug including a positive electrode and a negative electrode, and the connection portion is a socket for receiving the plug.
The base of a rubber waterproof cap that closes the plug insertion hole of the socket to prevent water from entering when the plug of the AC adapter is not inserted is fixed to the socket.
The socket of the AC adapter is provided with a second rubber waterproof cap that prevents water from entering the inside of the housing from the connection portion between the socket and the output plug when the output plug of the AC adapter is inserted. And
The second waterproof cap is attached to the base of the waterproof cap.
The second waterproof cap is provided with an arm portion extending from the base portion of the waterproof cap, a plug seal portion provided at the tip end portion of the arm portion, and a locking projection connected to a side surface of the plug seal portion. Be,
The plug seal portion includes a plug insertion hole through which the output plug is inserted, a main body seal hole adjacent to the plug insertion hole to seal the main body of the output plug, and the output plug adjacent to the main body seal hole. A guide slope is provided to guide the main body of the main body to the main body seal hole.
The locking protrusion is fitted into the locking protrusion insertion hole provided in the housing when the output plug is connected to the socket in a state where the main body of the output plug is completely inserted into the main body seal hole. A power supply for electric spark plugs that can be inserted. A solar panel is integrally provided in the housing, and inside the housing, a rechargeable battery, a booster circuit connected to the battery to generate a high voltage pulse, and a voltage input from the solar panel are supplied. A part of the housing in an electric power supply device provided with a regulator for controlling and appropriately charging the battery and an output terminal connected to the booster circuit on the outer surface of the housing. Is provided with a connection portion with the output terminal of the AC adapter capable of charging the battery, and this connection portion is connected to the regulator inside the housing.
The output terminal of the AC adapter is a plug including a positive electrode and a negative electrode, and the connection portion is a socket for receiving the plug.
The socket is provided with a rubber waterproof cap that closes the plug insertion hole of the socket to prevent water from entering when the plug of the AC adapter is not inserted.
The waterproof cap has a base portion fixed to the socket, an arm portion extending from the base portion, a lid member provided at the tip end portion of the arm portion, and a lid member projecting from the lid member to be watertight in the plug insertion hole. It has a hollow portion that is inserted in the state and receives an electrode in the plug insertion hole.
The socket of the AC adapter is provided with a second rubber waterproof cap that prevents water from entering the inside of the housing from the connection portion between the socket and the output plug when the output plug of the AC adapter is inserted. And
The second waterproof cap is attached to the base of the waterproof cap.
The second waterproof cap is provided with an arm portion extending from the base portion of the waterproof cap, a plug seal portion provided at the tip end portion of the arm portion, and a locking projection connected to a side surface of the plug seal portion. Be,
The plug seal portion includes a plug insertion hole through which the output plug is inserted, a main body seal hole adjacent to the plug insertion hole to seal the main body of the output plug, and the output plug adjacent to the main body seal hole. A guide slope is provided to guide the main body of the main body to the main body seal hole.
The locking protrusion is fitted into the locking protrusion insertion hole provided in the housing when the output plug is connected to the socket in a state where the main body of the output plug is completely inserted into the main body seal hole. A power supply for electric spark plugs that can be inserted. The electricity according to claim 1 or 2, wherein the regulator compares the voltage input from the solar panel with the voltage input from the connection portion, controls the higher voltage, and appropriately charges the battery. Power supply for drilling .

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