JP5693525B2 - Cable and electric shock device using the cable - Google Patents

Description

  The present invention relates to a cable and an electric shock device using the cable, and more particularly, it is used together with an electric fence formed by energizing a wire stretched on the ground or used alone, so that the upper part of the electric fence is exceeded. The present invention relates to a cable that can be used for small animals, such as monkeys, birds, and mice that can pass between electric fences, and to which the electric fence is not effective, and an electric shock device that uses the cables.

  Conventionally, an electric fence is provided at the boundary of a place where grazing animals such as cows and horses are grazed on a ranch or the like, and is installed for the purpose of enclosing the animals so as not to escape from the grazing land. The electric fence is composed of a plurality of conductive wires (wires) spanned from the ground at predetermined intervals from posts (posts) made of insulating material embedded in the ground at a predetermined distance. A high voltage (several thousand volts) is applied to the conductive wire (see Patent Document 1). When an animal such as a cow or horse touches the electric fence, the electric fence receives an electric shock due to the high voltage output from the power supply device (power unit) for the electric fence. (High-voltage electricity output from the power unit passes through the animal body and returns to the ground of the power unit through the ground).

  On the other hand, the electric fence is used not only for the purpose of preventing the animal from escaping as described above, but also for the purpose of preventing the animal from approaching. For example, in order to prevent crops cultivated in a farmer's field from being damaged by animals such as monkeys and foxes, the field is surrounded by an electric fence. In recent years, it has been reported that in orchards and other farms, wild trees are eaten and devastated by wild birds. In such orchard farmers, electric fences are stretched around the orchard trees. It has been broken.

  For example, in the case of an electric fence for monkey countermeasures, a plus wire (bare wire) and a minus wire are stretched between posts at a predetermined interval and wired. This is because the monkey does not get an electric shock unless it holds both poles of the wire. In addition, for small animals such as mice that devastate farm fields, electric fences with narrower spacing between the wires spanning the poles, and electric fences using crossed netting wires have been put to practical use. Yes.

JP 2004-283012 A

  By the way, an electric fence shocks an animal by touching a high voltage (shock electricity) between positive and negative generated by a power unit, and usually the ground is a negative pole. However, because the birds are flying in the air, even if the birds fly and stop on the wire of one electric fence, the birds can only touch one of the poles. Cannot be given. The same applies to animals that can jump on electric fences, such as monkeys, because monkeys touch only one pole if they ride on one wire of the electric fence without touching the ground. 、 Electricity does not flow to the monkey and it cannot give an electric shock. For this reason, in orchards and the like, wildlife damage was a serious problem.

  In addition, in a monkey-preventing electric fence in which a plus wire and a minus wire are stretched between posts at a predetermined interval, electric leakage occurs when the plus wire and the minus wire come into contact with each other. In addition, if the space between the plus and minus wires is made fine so that the electric fence operates effectively even for small animals such as mice, the wires are bare wires, so management between the wires is not possible. Difficult to spark, or to prevent it, there is a problem that the required output cannot be secured if the voltage is lowered.

  For example, in an electric fence with a narrow interval between the wires that span the struts, or an electric fence that uses crossed nets, plus and minus wires are placed in parallel, but the wires are exposed. In addition, there is a problem that spark is easily caused when the applied voltage is increased. Normally, the voltage applied to the electric fence is 6000 V to 10000 V, but in an electric fence with a narrow interval between wires spanning the columns, an electric fence using crossed nets, etc. Since the width of the arranged wire was about 1 cm, the applied voltage had to be reduced to 3000V to 4000V in order to prevent sparks. In addition, when grass grows around the wire, the electric leakage becomes intense, the voltage of the electric fence itself decreases and the effect as an electric fence is completely lost, and when the wire deteriorates over time, the conductive wire pops out, There was a problem that both poles were in contact. Furthermore, in electric fences that use a narrower gap between the wires that span the struts or wires that cross and mesh, it is difficult to expose a part of the conductive wire to the surface and the cost is high. was there.

  Therefore, the present invention not only eliminates the need for maintenance management to prevent sparks by covering and fixing the positive conductive wire and the negative conductive wire of the cable containing the wire with an insulating material. Even if the power is supplied to the wire from the power supply device of the electric fence, there is no spark even at a narrow interval, and a cable that can provide great benefits such as transmission over a longer distance and the cable are used. The purpose is to provide an electric shock device.

  In the cable according to the first aspect of the present invention that achieves the above object, the conductive wire is covered with an insulating member, and the conductive wire is exposed to a part of the outer surface of the insulating member by the conductor in the longitudinal direction. The conductive cable and the insulating member are formed in a flat shape having a bottom surface, an upper surface, and two side surfaces and extended, and the upper surface is formed in the longitudinal direction with at least two grooves that can receive the conductive cable in proximity to each other. A flat cable, and the conductive cable is formed by being inserted into at least two grooves so that the exposed portion of the conductor is exposed from the groove.

  The cable of the second form is the same as that of the cable of the first form, but the bottom surface of the flat cable is formed into a flat surface, and one side of the side is provided with a connection protrusion and the other is provided with a connection groove at a position facing the connection protrusion. When the plurality of flat cables are placed on a flat surface, the side surfaces of the adjacent flat cables can be connected to each other by a connection protrusion and a connection groove.

In the third form of the cable, the conductive wire is covered with an insulating member, and the conductive wire is exposed continuously in a longitudinal direction to a part of the outer surface of the insulating member by the conductor, and the insulating member is a bottom surface. , Formed in a shape having an upper surface and two side surfaces, stretched, a groove on the upper surface for receiving a conductive cable is formed in the longitudinal direction, a bottom surface is formed on a flat surface, and one of the side surfaces is connected A projection cable and a socket cable provided with a connection groove on the other side of the connection protrusion. The conductive cable exposes the exposed portion of the conductor so that a part of the conductor is exposed from the groove. Thus, when the plurality of socket cables are placed on a flat surface, the side surfaces of the adjacent socket cables can be connected by the connection protrusion and the connection groove.

The cable of the fourth form is a conductive cable in which a conductive wire is covered with a conductor, and an insulating member is formed in a shape having a bottom surface, a top surface, and two side surfaces and is extended, and the top surface can receive a conductive cable. One groove is formed in the longitudinal direction, the bottom surface is formed as a flat surface, and one side surface includes a connection projection, and the other includes a socket cable provided with a connection groove at a position facing the connection projection, When the cable is inserted into the groove so that a part of the conductor is exposed from the groove and a plurality of socket cables are placed on a plane, the side surfaces of adjacent socket cables are connected to each other by the connection protrusion and the connection groove. It is a cable characterized by being connectable.

The electric shock apparatus according to the first aspect of the present invention that achieves the above object is an electric shock apparatus using the cable of the first or second aspect , wherein at least one flat cable is placed on a plane, At least one of the electric shock devices is connected to a high voltage power source.

The electric shock device of the second form is an electric shock device using the cable of the third or fourth form , and is placed on a plane in a state where at least two socket cables are connected, and at least one of the conductive wires. Is connected to a high voltage power supply.

  The cable of the present invention and the electric shock device using the cable are configured so that at least two of the conductive wires in the cable are exposed on the cable without exposing at least two positive and negative conductive wires. The connection to the surface of the cable with a conductor with a predetermined resistance value eliminates the need for maintenance management to prevent sparks, and also supplies the cable with all the output from the electric fence power supply. However, sparks do not occur even at narrow intervals, power can be transmitted over longer distances, and electric shock can be applied when animals touch the positive and negative conductors exposed on the cable surface. Can bring.

  In addition, the cable of the present invention improves the workability, and at the same time, solves the problem of the conductive wire jumping out of the cable and greatly improves the practicality. In particular, the conductor exposed on the surface of the cable has a predetermined resistance value even if it is laid on the land where some electrically conductive materials such as grass and flowers are prosperous and these are in contact with the cable of the present invention. Therefore, there is an effect that the electric leakage can be reduced as much as possible and the shock electricity can be sent stably over a longer distance.

(A) to (f) are perspective views showing various examples of the first embodiment of the cable. (A) is a fragmentary perspective view which shows the structure made into the net shape using the cable of the structure of FIG.1 (d), (b) is a side view of a part of (a). (A) to (c) is a perspective view showing various examples of the second embodiment of the cable, and (d) is a perspective view showing an example of the third embodiment of the cable. (A)-(d) is a perspective view which shows the various examples of 4th Embodiment of a cable. (A), (b) is a perspective view which shows the example of 5th Embodiment of a cable. (A), (b) is a perspective view which shows the example of 6th Embodiment of a cable. (A) is sectional drawing which shows the example of 7th Embodiment of a cable, (b) is a perspective view which shows the structure of the strand wire of (a). (A) is a perspective view showing an example of a configuration of an electric fence using a cable, (b) is a cross-sectional view showing an example of a configuration of a simple electric fence using a cable, and (c) is a simple electric fence using a cable. It is sectional drawing which shows another example of the structure of. (A) to (d) is a cross-sectional view showing still another example of the first embodiment of the cable described in FIGS. 1 (a) and 1 (b). It is sectional drawing which shows the modification of the cable of the 2nd form shown to Fig.3 (a). (A) is a top view which shows the example of 8th Embodiment of an electroconductive cable, (b) is a perspective view of the electroconductive cable containing the cross section in the BB line of (a), (c) is C of (a). The perspective view of the conductive cable including the cross section in the -C line, (d) is a perspective view showing a short circuit process at the end of the conductive cable shown in (a), (e) is the top surface of the conductive cable shown in (a) It is a perspective view which shows the short circuit process in FIG. (A) is sectional drawing which shows the example of 8th Embodiment of an electroconductive cable, (b) is a perspective view which shows the example which wound and used the electroconductive cable of (a) around the metal pipe. (A) is sectional drawing which shows the example of 9th Embodiment of an electroconductive cable, (b) is sectional drawing of the modification of (a), (c) is sectional drawing of the modification of (b), (d) (A) is sectional drawing of another modification shown to (a), (e) is a perspective view which shows the state which attached the electrically conductive cable shown to (b) to the metal pipe. (A) is a fragmentary perspective view which shows the example of the electric shock apparatus using the electrically conductive cable of 10th Embodiment, (b) is an expanded partial sectional view of a part of (a), (c) is another of (a) The expanded fragmentary sectional view of a part, (d) is a fragmentary sectional view which shows the same site | part as (c) of the electric shock apparatus using the 1st modification of the electrically conductive cable of 10th Embodiment, (e) is 10th. Sectional drawing which shows another example of the flat cable of the electric shock apparatus using the conductive cable of embodiment of this, (f) is sectional drawing which shows the state which connected the flat cable shown to (e). (A) is the fragmentary perspective view which shows the Example at the time of comprising the electric shock apparatus shown in Fig.14 (a) so that connection is possible, (b) is the side view after the connection of (a). (A) is an enlarged partial sectional view of a part of the electric shock device using the second modified example of the conductive cable of the tenth embodiment, and (b) is a third modified example of the conductive cable of the tenth embodiment. (C) is an enlarged partial cross-sectional view of a part of an electric shock device using a fourth modified example of the conductive cable of the tenth embodiment, and (d) is a first partial cross-sectional view of the electric shock device using Sectional drawing of another Example of the electric shock apparatus using the 3rd modification of the electrically conductive cable of 10 embodiment, (e) used the 5th modification of the electrically conductive cable of 10th Embodiment. Sectional drawing of the Example of an electric shock apparatus, (f) is the fragmentary perspective view of the electric shock apparatus of another Example using the electrically conductive cable of 10th Embodiment. (A) is a partial enlarged perspective view of a baseboard to which the conductive cable of the tenth embodiment can be attached, and (b) is a perspective view of a room to which the baseboard of (a) is attached.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of a cable of the present invention and an electric shock device using the cable will be described in detail based on specific examples with reference to the accompanying drawings.

  FIGS. 1A to 1F show various examples of the cable 11 according to the first embodiment. The cable 11 according to the first embodiment includes two conductive wires 1 and 2, an insulating member 3 covering the conductive wires 1 and 2, and a conductor 4. A cable 11 shown in FIG. 1A has an elliptical cross section, and is disposed in an insulating member 3 in a state where the plus-side conductive wire 1 and the minus-side conductive wire 2 are insulated by the insulating member 3. The plus side conductive wire 1 and the minus side conductive wire 2 are connected to the surface of the cable 11 by a conductor 4 having a predetermined resistance value. That is, the conductor 4 whose one end is connected to the plus-side conductive wire 1 or the minus-side conductive wire 2 is exposed on the surface of the cable 11. In this configuration, although not shown, markings may be provided on the surface of the cable 11 to display the polarity of the conductor 4.

  The insulating member 3 can be made of an insulating resin such as polyethylene, polypropylene, and vinyl chloride. On the other hand, the conductor 4 can be obtained by mixing the insulating member 3 with a predetermined conductive agent. For example, a portion having a certain resistance value is formed by mixing a certain amount of a conductive material such as carbon into the insulating member 3 described above. Since the insulating member 3 and the base material of the conductor 4 are the same, the insulating member 3 and the portion of the conductor 4 having this resistance value are well-suited even in the drawer molding at the time of cable processing. The conductor 4 is not peeled off. The resistance value of the conductor 4 is set so that a voltage felt by a bird or monkey as a shock is felt by this cable. For example, the resistance value of the conductor 4 may be 0.5 ohm or more per 1 mm thickness.

  The cable 11 shown in FIG. 1B also has an elliptical cross section, and is arranged in a state where the plus-side conductive wire 1 and the minus-side conductive wire 2 are insulated by the insulating member 3 in the insulating member 3. The plus side conductive wire 1 and the minus side conductive wire 2 are connected to the surface of the cable 11 by a conductor 4 having a predetermined resistance value. The cable 11 in FIG. 1B is different from the cable 11 in FIG. 11A in that the conductors 4 that connect the plus-side conductive wire 1 to the surface of the cable 11 are provided in two places. Accordingly, the conductor 4 connected to the plus-side conductive wire 1 is exposed on the surface of the cable 11 at two adjacent locations. Thus, when the plus-side conductive wire 1 is connected to two places on the surface of the cable 11 and the minus-side conductive wire 2 is connected to one place on the surface of the cable 11, by visual inspection from the outside of the cable 11, It can be determined which is the conductor 4 connected to the plus-side conductive wire 1.

  In the cable 11 shown in FIG. 1C, the cross-sectional shape of the insulating member 3 is merely changed from an elliptical shape to a shape in which two circles are partially overlapped, and the plus-side conductive wire 1 and the minus-side conductive wire. 2 and the structure of the conductor 4 are the same as those of the cable 11 shown in FIG. That is, the cable 11 shown in FIG. 1C has a shape in which a part of the side surface of the cylinder 11A provided with the plus-side conductive wire 1 and the cylinder 11B provided with the minus-side conductive wire 2 are joined and overlapped in parallel. doing. In this example, the polarity of the conductor 4 can be determined by visual inspection from the outside by changing the colors of the cylinder 11A and the cylinder 11B or by marking the outer surface of the cable 11 to indicate the polarity of the conductor 4. can do.

  In the cable 11 shown in FIG. 1 (d), the side surfaces of the cylinder 11A and the cylinder 11B in the cable 11 shown in FIG. 1 (c) are not directly connected to each other, but are connected at a predetermined interval by the connection plate 11C. Only the point is different from the cable 11 of FIG. In the cable 11 shown in FIG. 1 (d), if attachment holes 11H are provided in the connection plate 11C at a predetermined interval, a bamboo-like rod having a node or a locking projection in the middle is provided in the attachment hole 11H. By inserting a rod and standing a bamboo-like rod or rod on the ground, it can be easily stretched. Also in the cable 11 of this example, the polarity of the conductor 4 can be determined from the outside by marking any part of the cylinder 11A, the cylinder 11B, or the connection plate 11C.

  Further, in the cable 11 shown in FIG. 1E, the conductor 4 connected to the plus-side conductive wire 1 in the cable 11 shown in FIG. 1D is 2 like the cable 11 explained in FIG. The only difference is that it is provided at the location. Further, in the cable 11 shown in FIG. 1 (f), one side surface of the insulating member 3 having the elliptical cross section having the plus side conductive wire 1 and the minus side conductive wire 2 is extended laterally by the support wall 11D. A flat base 11E is formed at the tip. The plus-side conductive wire 1 and the minus-side conductive wire 2 in this example are connected to the surface of the cable 11 on the side opposite to the support wall 11D by the conductor 4. The cable 11 in this example can be installed on the floor surface or the like by the base 11E.

  In the cable 11 of the first embodiment configured as described above, the plus-side conductive wire 1 and the minus-side conductive wire 2 are connected to the surface of the cable 11 by the conductor 4. Therefore, if the cable 11 is stretched so that the conductor 4 is exposed in the horizontal direction, when the bird stops on the cable 11, the bird grasps the periphery of the cable 11 with its feet, so the feet are positive. Since both the conductor 4 connected to the side conductive wire 1 and the minus side conductive wire 2 are touched and an electric shock is received, the cable 11 cannot be approached. Similarly, when the monkey jumps on the cable 11, the hand grasps the cable 11, so that the hand touches both the conductor 4 connected to the plus side conductor wire 1 and the minus side conductor wire 2 and receives an electric shock. The cable 11 cannot be approached.

  In the cable 11 according to the first embodiment configured as described above, the plus-side conductive wire 1 and the minus-side conductive wire 2 are connected to the surface of the cable 11 by the conductor 4. The exposed portion of the cable 11 on the surface does not come into contact even when the cable 11 is orthogonal. Therefore, the cable 11 of the first embodiment can be made orthogonal to form the network 10 as shown in FIGS. 2 (a) and 2 (b). And by using this net | network 10, the net-type electric shock fence as an electric shock apparatus can be comprised.

  When forming the net 10 as shown in FIGS. 2A and 2B with the cables 11 orthogonal to each other, a member made of an insulator is inserted into a portion where the cables 11 intersect, You may make it completely fix the part which 11 crosses with resin. Even if the cable 11 is stretched in a ladder shape without being orthogonal, it is effective for an animal such as a monkey that can grab the ladder and climb. Further, the cable 11 of this example does not need to be simply arranged parallel to the plane as long as the distance is maintained. For example, the cable 11 in this example can be arranged in a spiral shape.

  3A to 3C show various examples of the cable 12 of the second embodiment. The cable 12 of the second embodiment is different from the first cable 11 in that the fins 5 are added to the first cable 11. The fins 5 are used to isolate the cables 12 to which a high voltage is applied so that the conductors 4 do not contact each other. The number of fins 5 may be one or plural. Further, the material of the fin 5 may be a flexible material or a hard material. Further, the fin 5 may be formed integrally with the cable 12 or may be separate from the cable 12. In this example, an example in which the fin 5 is formed integrally with the cable 12 will be described.

  The cable 12 shown in FIG. 3 (a) is formed by integrally forming fins 5 extending in an oblique direction on both sides of the connection plate 11C of the cable 11 described in FIG. 1 (d). The direction in which the fins 5 extend may be the same or different from the connection plate 11C. One of the fins 5 in this example is inclined toward the cylinder 11A, and the other is inclined toward the cylinder 11B. The cable 12 shown in FIG. 3A is different only in that the fins 5 of the cable 12 shown in FIG. 3A are provided in a direction perpendicular to the connection plate 11C. In the cable 12 shown in FIG. 3C, fins 5 extending in an oblique direction are integrally formed in a portion of the cable 11 described in FIG. 1A away from the portion where the conductor 4 is exposed. It is a thing.

  A cable 13 shown in FIG. 3D shows an example of the configuration of the cable 13 according to the third embodiment. In the cable 13 of the third embodiment, a plurality of plus-side conductive wires 1 (three in this example) and a plurality of minus-side conductive wires 2 (two in this example) are arranged in the insulating member 3. Is. The cross section of the insulating member 3 has a trapezoidal shape upside down, and the plurality of positive side conductive wires 1 and negative side conductive wires 21 are all exposed on the lower bottom surface of the trapezoidal shape of the cable 13 by the conductor 4. Yes. In particular, the plus-side conductive wires 1 on both sides are exposed by the conductor 4 at the connecting portion between the lower base of the trapezoid and the hypotenuse.

  Furthermore, in the cable 13 of this example, not only the two negative conductive wires 21 are exposed to the lower base surface of the trapezoid of the cable 13 by the conductor 4, but also the upper base surface of the trapezoid. Is also exposed. Therefore, in the cable 13 of this example, if the upper base side of the trapezoid is installed on a conductive attachment surface, a potential difference is generated between the attachment surface and the positive conductor 4 exposed on the lower base surface of the trapezoid. It becomes easy to shock animals.

  FIGS. 4A to 4D show various examples of the cable 14 of the fourth embodiment. The cable 14 of the fourth embodiment is provided with the fins 5 in the same manner as the cable 12 of the second embodiment. However, the cable 12 of the second embodiment does not have the conductor 4 and has a positive-side conductivity. The difference is that a part of the wire 1 and the negative conductive wire 2 are directly exposed on the surface of the cable 14. The fins 5 are used to isolate the cables 14 to which a high voltage is applied so that the plus-side conductive wires 1 or the minus-side conductive wires 2 are not in contact with each other.

  The number of fins 5 may be one or plural. Further, the material of the fin 5 may be a flexible material or a hard material. Further, the fin 5 may be formed integrally with the cable 14 or may be separate from the cable 14. In this example, an example in which the fin 5 is formed integrally with the cable 14 will be described.

  The cable 14 shown in FIG. 4 (a) has the same shape as the cable 12 shown in FIG. 3 (a), but does not have the conductor 4, and a part of the plus-side conductive wire 1 and the minus-side conductive wire 2 are directly connected. The difference is that the cable 14 is exposed on the surface. The cable 14 shown in FIG. 4 (b) has the same shape as the cable 12 shown in FIG. 3 (b), but there is no conductor 4, and a part of the plus-side conductive wire 1 and the minus-side conductive wire 2 are directly connected. The difference is that the cable 14 is exposed on the surface. The cable 14 shown in FIG. 4C is different in that one of the cables 14 shown in FIG. 4A (the fin on the right side in the figure) has two fins 5. Further, the cable 14 shown in FIG. 4D is different in that the number of fins 5 of the cable 14 shown in FIG.

  In the cable 14 of the fourth embodiment, as shown in FIG. 4A, a flexible material is used for the fin 5, and the fin 5 is extended obliquely, so that the cable 14 is sandwiched between the insulators. In this case, it is possible to prevent the spark at the insulator portion by taking the shape of the fin 5 covering the conductive wires 1 and 2 on the positive side or the negative side exposed on the surface of the cable 14. Moreover, the cable 14 shown in FIGS. 4C and 4D shows an example in which the shapes of the left and right fins 5 are different, and the fins 5 are coupled by turning the cable 14 shown in FIG. 4D upside down. If arranged in such a manner, it is possible to construct a block type cable in which the plus-side conductive wires 1 and the minus-side conductive wires 2 are alternately arranged.

  In addition, the cables 12 and 14 provided with the fins 5 of the second and fourth embodiments can be stretched between the posts using a normal insulator. This is because of the function of the fin 5, sufficient insulation is provided between the conductors 4 and 4 in the second embodiment, and between the positive conductive line 1 and the negative conductive line 2 in the fourth example. This is because the creepage distance can be earned, so that no spark or electric leakage occurs in the insulator.

  FIG. 5A shows an example of the cable 15 of the fifth embodiment. In the cable 15 of this example, the plus-side conductive wire 1 and the minus-side conductive wire 2 are disposed in a corner portion on both sides of one long side of the insulating member 3 having a rectangular cross section with a part thereof exposed. A rib 6 is provided between the plus-side conductive wire 1 and the minus-side conductive wire 2. The rib 6 prevents the plus-side conductive wire 1 and the minus-side conductive wire 2 from contacting each other even when conductors overlap in a direction orthogonal to the cable 15. In the cable 15 of the fifth embodiment, the plus side conductive wire 1, the minus side conductive wire 2, and the long side on the side without the rib 6 can be attached to a plane.

  FIG. 5B shows another example of the cable 15 of the fifth embodiment. The difference from the cable 15 shown in FIG. 5A is that the plus-side conductive wire 1 and the minus-side conductive wire. Two ribs 6 are provided in parallel between the two ribs, and attachment holes 7 are formed in a region between the two ribs 6 at a predetermined interval. Therefore, in the cable 15 of the example shown in FIG. 5B, the cable 15 can be fixed to a flat surface by inserting the attachment member 9 such as a nail or a screw into the attachment hole 7.

  Fig.6 (a) shows the example of the cable 16 of 6th Embodiment. The cable 16 in this example is a modification of the cable 11 described in FIG. In the cable 11 described with reference to FIG. 1C, the plus-side conductive wire 1 is arranged in a cylinder 11 </ b> A constituted by the insulating member 3, and the minus-side conductive wire 2 is constituted by the cylinder 11 </ b> B constituted by the insulating member 3. It was arranged in the inside. On the other hand, the example shown in FIG. 6A is different in that the plus-side conductive wire 1 is arranged in a prism 16D formed of the insulating member 3. Similarly to the cable 11 shown in FIG. 1C, the minus side conductive wire 2 is arranged in a column 16 </ b> B formed of the insulating member 3.

  FIG. 6B shows another example of the cable 16 of the sixth embodiment. The cable 16 in this example is a modification of the cable 11 described in FIG. In the cable 11 described in FIG. 1C, the diameter of the cylinder 11A on which the plus-side conductive wire 1 is arranged is the same as that of the cylinder 11B on which the minus-side conducting wire 2 is arranged. On the other hand, in the example shown in FIG. 6B, the diameter of the cylinder 16A on which the plus-side conductive wire 1 is arranged is configured to be larger than the diameter of the cylinder 16B on which the minus-side conducting wire 2 is arranged.

  Thus, by making the shape of the insulating member 3 covering the plus-side conductive wire 1 different from the shape of the insulating member 3 covering the minus-side conductive wire 2, which is the plus-side conducting wire 1 from the outside of the cable 16. It can be determined whether the conductor 4 is connected to the. It is very important to determine which is the conductor 4 connected to the plus-side conductive wire 1 from the outside of the cable 16. The reason is that when connecting a cable and extending the cable, if the polarity of the cable to be connected is wrong, it will not be used as an electric fence. As another method for determining which is the conductor 4 connected to the plus-side conductive wire 1 from the outside of the cable 16, the conductor wire connected to the conductor 4 is on the plus side on the surface of the insulating member of the cable. There is a method such as printing the display of the negative or negative side.

  FIG. 7A shows an example of the cable 17 of the seventh embodiment, which is a modification of the cable 11 described in FIG. In the cable 11 described with reference to FIG. 1A, single-wire (monofilament) wires are used for both the positive-side conductive wire 1 and the negative-side conductive wire 2. In the cable 17 of the seventh embodiment, A stranded wire (multifilament) 8 as shown in FIG. 7B is used for the conductive wire, for example, the positive-side conductive wire 1. In the cable 17 of the seventh embodiment, both conductive wires can be stranded wires 8.

  Thus, the cable can be stretched more strongly by using at least one of the plus-side conductive wire 1 and the minus-side conductive wire 2 as the stranded wire 8. Further, if the coating on the side where the conductive wire of the cable is a stranded wire is peeled and the cable is fixed to a metal post, it becomes difficult for the monkey to climb the post. The reason is that the poles of the cables other than the post and the stranded wire are different, and an electric shock is received when a monkey touches them.

  Currently, there are two types of electric fences. One is to attach an insulator or a clip to the post and lay an electric fence wire (bare wire). The other is that a part or all of the fence is formed of a net.

  It is common to attach an insulator or clip to the post and wire the wire (bare wire) of the electric fence, but if the floor is concrete or completely dry on the ground, even if the electric fence Even if the wire was touched, an electric shock was not generated between the ground and the animal, and an electric shock could not be given to the animal. Therefore, a method has been adopted in which the wires to be wired are alternately wired to different poles on the secondary side of the power supply device of the electric fence. Specifically, it is a method of arranging a fence wire and an earth return wire, but if these wires are brought too close to the energizing wires, sparks or electric leakage will occur, and conversely, the distance between these wires and the energizing wires will be increased. There was a problem that animals would get entangled if spread too much.

  With respect to such problems of the conventional electric fence, the cable shown in the present invention has a conductor connected to the plus-side conductive wire and a conductor connected to the minus-side conductive wire on the surface of one cable, or Since some of the plus-side conductive wires themselves and some of the minus-side conductive wires themselves are exposed without being in contact with each other, animals of the kind that grab the cable of the electric fence against the electric fence, for example, birds and monkeys , An electric shock can be applied when one cable is gripped.

  Fig.8 (a) shows an example of the structure of the electric fence 20 which uses the 1st to 7th cables 11-17 (these are named generically and the cable 22). The cable 22 can be bridged between the posts 21 and the posts 21 in the same manner as a conventional energizing wire. The post 21 can be made of a flexible material to which some force is applied. In this example, one cable 22 is attached to one post 21, but a plurality of cables 22 may be attached to the post 21 in parallel.

  FIG. 8B shows an example of the configuration of the simple electric fence 20 in which the attachment rings 24 are provided at predetermined intervals on the existing fences or fences 23 and the cables 22 are inserted through the attachment rings 24. The mounting ring 24 is preferably provided with a mounting shaft for separating the cable 22 from the top surface of the existing fence or fence 23. The mounting ring 24 is made of a conductor and is brought into contact with the ground side of the cable 22 or is made of an insulator.

  FIG. 8C shows another configuration of the simplified electric fence 20 in which at least one stay 25 is provided at a predetermined interval on the side surface of the existing fence or fence 23 and the cable 22 is attached to the tip of the stay 25. An example is given. The number of stays 25 is three in this example, but the number of stays 25 is not particularly limited. In this example, the length of the stay 25 is longer as it is closer to the ground. However, the length of the stay 25 may be shorter as it is closer to the ground, or may be all the same length.

  FIGS. 9A to 9D show the configuration of still another example of the cable 11 of the first embodiment described in FIG. Therefore, the same constituent members will be described with the same numbers. The cable 11 shown in (a) has the conductor 4 drawn out in a parallel and oblique direction. The cable 11 shown in (b) is one in which the conductors 4 are pulled out in parallel and in the same direction. The cable 11 shown in (c) is obtained by projecting the conductor 4 of the cable 11 shown in FIG. Further, the cable 11 shown in FIG. 9D has a groove 30 formed on the opposing surface of the insulating member covering the cable 11 to increase the edge distance between the conductive wires 1 and 2.

  FIG. 10 shows a configuration of a modified example of the cable 12 of the second embodiment described with reference to FIG. In the cable 12 of the second embodiment described with reference to FIG. 3A, the fins 5 are linear, but in this modified example, the fins 5 cover the positive conductive wires 1 and the negative conductive wires 2. Different points are provided.

  In conventional electric fences in which part or all of the fence is made up of a mesh, when the conducting wire is woven into the mesh, the mesh often twists synthetic resin filaments together. Because it was made, it was a capillary phenomenon, and when it rained, an electrical leakage occurred as if the grass was on the fence. In addition, when a system obstacle that does not energize is installed in the lower part of the fence, including a metal net, etc., when an animal such as a monkey starts climbing, there is a gap between the wires installed in front of or above the fence. There was a problem that occurred and easily penetrated or caused electric leakage.

  On the other hand, as shown in FIG. 2, the wire does not generate sparks or electric leakage even if it is knitted vertically and horizontally, so that a net of a desired size can be easily formed. For example, an electric shock can be applied to a bird or monkey when a part of the net is grabbed. For this reason, a desired range can be protected from damage by birds and monkeys.

  In addition, the cables may be arranged so as to be wound around the entire tree, attached at regular intervals under the tree, or installed at regular intervals on crops susceptible to damage.

  FIG. 11A shows the configuration of the cable 18 of the eighth embodiment. FIG. 11B is a perspective view of the cable 18 including a cross section taken along line BB in FIG. 11A, and FIG. 11C is a perspective view of the cable 18 including a cross section taken along line CC in FIG. FIG. The cable 18 in this example has a semi-cylindrical cross section, and four conductive wires (two plus-side conductive wires 1 and two minus-side conductive wires 2) are provided in parallel inside.

  The two plus side conductive wires 1 are led to the surface of the cable 18 by the conductor 4 as shown in FIG. On the other hand, the two negative conductive wires 2 are led to the surface of the cable 18 by two conductors 4 respectively. Further, the two minus side conductive wires 2 are connected to each other by a connecting line 2 </ b> C in the middle of the cable 18. Further, the two plus-side conductive lines 1 are connected by a connecting line 1C in the middle of the cable 18 as shown in FIG. 11 (c). Therefore, in the cable 18 of this example, as shown in FIG. 11A, one of the two plus-side conductive wires 1 is connected to the power source, and one of the two minus-side conductive wires 2 is connected. Just drop the book to earth. The connection lines 1C and 2C may be provided on the conductive cable 18 at predetermined intervals.

  Note that the connecting lines 1C and 2C are not provided on the cable 18 at every predetermined interval, and two wires are used at the end of the cable 18 after the cable 18 is stretched as shown in FIG. 11 (d). Alternatively, the positive side conductive wire 1 and the two negative side conductive wires 2 may be connected. Further, as shown in FIG. 11E, the connecting lines 1C and 2C are connected to the conductor 4 connected to the two plus-side conductive wires 1 or the two minus-side conductive wires 2 in the middle of the cable 18. It is also possible to provide a notch and connect two minus-side conductive wires 2 or two plus-side conductive wires 1 using the conductor 4 in the notch.

  FIG. 12A shows a modification of the cable 18 of the eighth embodiment shown in FIG. The cable 18 of this modification also has a semi-cylindrical cross section, and one plus-side conductive wire 1 and one minus-side conductive wire 2 are provided in parallel inside. The plus-side conductive wire 1 is led to the curved surface of the cable 18 by the conductor 4. On the other hand, the minus side conductive wire 2 is led to the curved surface of the cable 18 by the conductor 4 and to the flat bottom surface.

  Therefore, the cable 18 of this modification is used by laying a flat bottom surface on the floor or ground, or by wrapping the cable 18 around a conductive metal pipe 26 as shown in FIG. Can do. In this case, since the minus side conductive wire 2 inside the cable 18 is connected to the metal pipe 26 by the conductor 4, if a small animal touches the metal pipe 26 and the plus side conductor 4, it will receive an electric shock. Become. In addition, when the cable 18 of this modification is wired, a power source can be connected to the plus-side conductive wire 1 and the metal pipe 26.

  FIGS. 13A to 13D are cross-sectional views showing first to fourth examples of the cable 19 of the ninth embodiment. The cable 19 of the ninth embodiment has a substantially crescent shape whose cross section can be attached to a cylinder. To describe this shape accurately, the cross-sectional shape of the cable 19 of the ninth embodiment is a crescent shape formed by combining an arc having a large radius and an arc having a smaller radius. Therefore, the cable 19 of the ninth embodiment can be fitted and attached to a cylinder having the same radius as the inner circular arc by expanding both ends of the crescent-shaped insulating member and covering the cylinder. . That is, it can be attached to the outer surface of the metal pipe 26 as shown in FIGS. 13 (a) to 13 (d) and FIG. 3 (e).

  In the first example of the cable 19 of the ninth embodiment, there are two conductive wires (the positive side conductive wire 1 and the negative side conductive wire 2) inside the insulating member 3, and in the second and third examples, the insulating member 3 is used. Three conductive wires (one plus-side conductive wire 1 and two minus-side conductive wires 2) in the inside of the insulating member 3, and in the fourth example, five conductive wires (two plus-side wires) The conductive wire 1 and the three negative conductive wires 2) are provided in parallel to the longitudinal direction of the cable 19, respectively.

  The plus-side conductive wire 1 of the cable 19 of the ninth embodiment is led only to the outer surface of the cable 19 by the conductor 4. On the other hand, the minus-side conductive wire 2 is led to both the outer surface and the inner surface of the cable 19 by the conductor 4. In the third example shown in FIG. 13C, the two minus side conductive wires 2 are connected to each other on the inner surface of the cable 19 via the conductor 4. For this reason, when the cable 19 of the ninth embodiment is attached to the conductive metal pipe 26, the minus-side conductive wire 2 is connected to the metal pipe 26 through the conductor 4.

  Therefore, in the cable 19 of the ninth embodiment attached to the metal pipe 26 as shown in FIG. 13 (e), the power source is connected only to the positive side conductive wire 1, and the ground wire is connected to the negative side electric wire 2. The metal pipe 26 made of metal can be connected to the ground without being connected.

  In the cable 19 of the ninth embodiment configured as described above, an electric shock device can be simply configured by using the cable 19 on a metal pipe 26 or the like. Since at least one conductor 4 having a positive potential and a negative potential is exposed on the surface of the cable 19, if the cable 19 of the ninth embodiment is energized, this cable The small animal that touched 19 will receive an electric shock from the cable 19, and the small animal can be excluded. Further, the cable 19 having a large number of conductors 4 exposed on the surface of the cable 19 is likely to give an electric shock to the animal.

  FIG. 14A shows an example of an electric shock device using the conductive cable 41 of the tenth embodiment, and the electric shock device includes a flat cable 27 to which the conductive cable 41 is attached. The flat cable 27 and the conductive cable 41 are actually long, and only a part of the flat cable 27 and the conductive cable 41 is shown in this figure. FIG. 14B shows a partial cross section before the conductive cable 41 of FIG. 14A is attached, and FIG. 14C shows a partial cross section after the conductive cable 41 of FIG.

  In the conductive cable 41 of the tenth embodiment, as shown in detail in FIG. 14B, one conductive wire 42 is covered with the insulating member 3, and a part of the insulating member 3 has a resistance greater than a certain value. The cable is replaced with the conductor 4 having a value and the conductive wire 42 is connected to the surface of the insulating member 3 through the conductor 4. The flat cable 27 of this embodiment is provided with five grooves 31 in parallel on one surface thereof. The groove 31 is configured in such a shape that the conductor 4 connected to the surface of the insulating member 3 of the cable 41 can be accommodated in an exposed state.

  In the case of constructing the electric shock device, the conductive cable 41 is inserted into the groove 31 of the flat cable 27 so that the conductor 4 is exposed, and the adjacent conductive cable 41 is connected to the high voltage power source in the same manner as the embodiment described with reference to FIG. And connect to the ground respectively. In the electric shock device configured as described above, the conductors 4 connected to the positive electrode and the negative electrode are alternately exposed on the surface of the flat cable 27 after laying, so that the animal is simultaneously exposed to two adjacent conductors 4. If touched, you will receive an electric shock. The electric shock device using the flat cable 27 can be installed anywhere as needed, such as laying on the floor or attaching to the wall. Therefore, the electric shock device can be installed in a place that seems to be effective against animals, insects, and the like that are excluded by electric shock.

  FIG. 14D illustrates a state in which the first modified example of the conductive cable 41 of the tenth embodiment is inserted into the groove 31 of the flat cable 27. The conductive cable 41 described in FIGS. 14B and 14C is exposed when the conductive cable 41 is inserted into the groove 31 because the conductor 4 is exposed on the surface of the insulating member 3 in a thin line shape. The conductor 4 may not face directly above. Therefore, in the conductive cable 41 of the first modified embodiment, the conductor 4 exposed on the surface of the insulating member 3 is formed in a thick line shape. If it carries out like this, when the conductive cable 41 is inserted in the groove | channel 31, unless there is a problem, the exposed conductor 4 comes to face right above. Furthermore, it is possible to replace all the insulating members 3 covering the conductive wires 42 of the conductive cable 41 with the conductors 4. Furthermore, instead of the conductive cable 41, only the conductive wire 42 having the same diameter as that of the conductive cable 41 can be fitted into the groove 31.

  FIG. 14 (e) shows the configuration of the socket cable 28 of another embodiment of the electric shock device, and shows the socket cable 28 of the smallest unit. Therefore, the socket cable 28 of this embodiment is also made of the insulating member 3, and only one groove 31 is provided on one surface thereof. Also, on both sides of the socket cable 28. A connection protrusion 32 and a connection groove 33 for connecting the socket cable 28 are provided. As shown in FIG. 14 (f), the socket cable 28 of this embodiment can be a flat cable having a desired number of grooves by connecting the connecting protrusion 32 and the connecting groove 33.

  In this embodiment, the socket cable 28 of the minimum unit is shown as a cable having a rectangular cross section, but the cross sectional shape of the socket cable 28 is not limited to a rectangular shape. In this embodiment, the connecting protrusion 32 has a trapezoidal cross section, and the connecting groove 33 has a trapezoidal cross section, but the connecting protrusion 32 and the connecting groove 33 are not limited to a trapezoid. Any shape can be used as long as it has a function capable of being connected.

  Fig.15 (a) shows the Example at the time of comprising the electric shock apparatus shown to Fig.14 (a) so that connection is possible, (b) is a side view after connecting the electric shock apparatus of (a). is there. This figure also shows only a part of the flat cable 27 and the conductive cable 41. The flat cable 27 of this embodiment is provided with a connection protrusion 43 on one side surface and a connection groove (not shown) on the other side surface. Further, the connection protrusion 43 can be hidden from the floor surface on which the electric shock device is installed, and the edge cable 29 for gently connecting the surface of the electric shock device to the floor surface can be connected to the side surface of the flat cable 27. The electric shock device using the flat cable 27 thus connected can be laid in a wide area such as the entire floor surface.

  The flat cable 27 used as the electric shock device does not have to be particularly flat, and may have a curved surface, an uneven surface, or a hole. Further, the cable itself is not linear, and may be curved or meandering. If the flat cable 27 is flexible, it can be installed around a cylindrical pole, a square pillar, or the like by using an adhesive or a double-sided tape.

  FIG. 16 (a) shows a part of an electric shock device using the conductive cable 44 of the second modified example of the conductive cable of the tenth embodiment. The conductive cable 44 of the second modified embodiment includes a large-diameter portion that is accommodated in the groove 31 of the flat cable 27 and a small-diameter portion that is formed to have a small diameter so as to protrude from the groove 31. The conductor 4 connected to the conductive wire 42 is exposed at the small diameter portion. Accordingly, when the conductive cable 44 is fitted into the large-diameter groove 31, the small-diameter portion protrudes from the flat cable 27 and the conductor 4 faces right above.

  FIG. 16B shows a part of an electric shock device using the conductive cable 45 of the third modified example of the conductive cable of the tenth embodiment. The conductive cable 45 of the third modified example has an equilateral triangular cross section, and the conductor 4 connected to the conductive wire 42 is connected to one vertex of the equilateral triangle. The shape of the groove 31 provided in the flat cable 27 is such that one vertex of the groove 31 protrudes from the surface of the flat cable 27 when the conductive cable 45 is received. Therefore, when the conductive cable 45 is fitted into the groove 31 so that the conductor 4 is exposed, the conductor 4 faces directly upward and protrudes from the flat cable 27.

  If the conductive cable 45 having a regular triangular cross section is configured such that the conductor 4 connected to the conductive wire 42 is connected to all three vertices of the regular triangle, as shown on the right side of FIG. Even if the conductive cable 45 is fitted into the groove 31 without considering its direction, the conductor 4 always faces directly upward and protrudes from the flat cable 27.

  FIG. 16 (c) shows a part of an electric shock device using the conductive cable 46 of the fourth modified example of the conductive cable of the tenth embodiment. The conductive cable 46 of the fourth modified embodiment has an elliptical cross section, and the conductor 4 connected to the conductive wire 42 is provided on both sides of the conductive wire 42 in the major axis direction of the ellipse. Connected to the surface. And the shape of the groove | channel 31 provided in the flat cable 27 is a shape where the edge part of the long-axis direction protrudes from the surface of the flat cable 27 when the conductive cable 46 is received. Therefore, if the conductive cable 46 is fitted in the groove 31 in the long axis direction, the conductor 4 faces straight upward and protrudes from the flat cable 27 regardless of which is up.

  FIG. 16 (d) shows another example of the electric shock device using the single core cable 45 of the third modified example of the conductive cable of the tenth embodiment. The socket cable 28 of this embodiment is of a type that can accommodate one single-core cable 45, and is an embodiment in which overhang portions 34 are provided on both sides of the socket cable 28. This is to increase the edge distance for insulation when the single-core cable 45 is connected to the positive high-voltage power supply.

  FIG. 16 (e) shows another example of the electric shock device using the single core cable 47 of the fifth modified example of the conductive cable of the tenth embodiment. The socket cable 28 of this embodiment is also of a type that can accommodate one single-core cable 47, and overhang portions 34 are provided on both sides of the socket cable 28. This is to increase the edge distance for insulation when the single-core cable 47 is connected to the positive high-voltage power supply. Further, the single core cable 47 of the fifth modified embodiment has an overhang portion on both sides of one vertex to which the conductor 4 connected to the conductive wire 42 of the single core cable 45 of the third modified embodiment is connected. It is provided. The upper surface side of the overhanging portion is smoothly curved. Accordingly, when the single-core cable 47 on the side where there is no overhanging portion is fitted into the groove 31, the conductor 4 protrudes from the flat cable 27 facing directly upward.

  FIG. 16F shows another example of the electric shock device using any of the conductive cables 41 and 44 to 47 of the tenth embodiment. This embodiment is an electric shock device provided on a member that is provided in a place where it is exposed to the outside air, but is in trouble if a bird stops. For example, in an exhaust port or an intake port 35 having an opening on the upper side, it may be difficult for a bird to stop at the opening. In such a case, two of the conductive cables 41, 44 to 47 of the tenth embodiment are arranged at the position indicated by the solid line at the end of the exhaust port or the intake port 35, and a high voltage is applied to one of them. If the other side is dropped to the ground, if the bird tries to stop at the exhaust port or the intake port 35, the feet will touch the two conductive cables 41 to 47 at the same time, so that they will receive an electric shock and the bird will approach again. Can not be.

  FIG. 17A shows a skirting board 36 to which the conductive cable 41 of the tenth embodiment can be attached. As shown in FIG. 17 (b), this skirting board 36 is a decorative horizontal plate that is attached to the lowermost part of the wall 37 of the room and is in contact with the floor 38. After the conductive cable 41 is fitted into the groove 31 of the skirting board 36, a high voltage is applied to one side and the other is dropped to the ground, so that a small animal cannot be brought close to the wall. Moreover, the electric shock device using the above-described flat cable 27 or the like can be easily laid at the position of the floor 38 indicated by a two-dot chain line in FIG.

  In addition to this, the conductive cable of the tenth embodiment can be fitted into two spiral grooves provided on a rod made of an insulator, a high voltage is applied to one side, and the other is dropped to the ground. An electric shock device that can apply an electric shock to an animal that touches or holds the rod can be configured. In addition, a similar electric shock device can be configured by providing two grooves on a flexible cable made of an insulator instead of a rod.

  Furthermore, the conductive cable of the tenth embodiment has two conductive cables in the large ridge, corner ridge, or sleeve that are the highest part of the roof in order to prevent birds from stopping on the roof. There are uses such as constructing a lightning device by laying a wall or embedding it in a roof tile. In addition, when installing an electric shock apparatus on a roof, a solar cell can be used for a power supply instead of a commercial power supply, and the obtained electric power can be stored in a capacitor (capacitor) and transformed and used.

DESCRIPTION OF SYMBOLS 1 Positive side conductive wire 2 Negative side conductive wire 3 Insulating member 4 Conductor 5 Fin 6 Rib 8 Stranded wire 10 Network 11-19, 22, 40 Cable 20 Electric fence 23 A fence or fence 24 Mounting ring 25 Stay 26 Metal pipe 27 Flat Cable 28 Socket cable 30, 31 Groove 36 Skirting board 41, 44-47 Single core cable 42 Conductive wire 43 Connecting protrusion

Claims (6)

The conductive wire (42) is covered with the insulating member (3), and the conductive wire (42) is exposed to a part of the outer surface of the insulating member (3) in the longitudinal direction by the conductor (4). A conductive cable (41) to
The insulating member (3) is formed and extended in a flat shape having a bottom surface, an upper surface and two side surfaces, and at least two grooves (31) capable of receiving the conductive cable (41) are close to the upper surface. And a flat cable (27) formed in the longitudinal direction,
The conductive cable (41) is formed by being inserted into each of the at least two grooves (31) so that an exposed portion of the conductor (4) is exposed from the groove (31). cable. A cable (40) according to claim 1, comprising:
The bottom surface of the flat cable (27) is formed into a flat surface, and one of the side surfaces is provided with a connection protrusion (43), and the other is provided with a connection groove at a position facing the connection protrusion (43).
When a plurality of the flat cables (27) are placed on a plane, the side surfaces of the adjacent flat cables (27) can be connected to each other by the connection protrusion (43) and the connection groove. And cable. The conductive wire (42) is covered with the insulating member (3), and the conductive wire (42) is exposed to a part of the outer surface of the insulating member (3) in the longitudinal direction by the conductor (4). A conductive cable (41) to
The insulating member (3) is formed in a shape having a bottom surface, an upper surface and two side surfaces and is extended, and a single groove (31) capable of receiving the conductive cable (41) is formed in the longitudinal direction on the upper surface. The socket cable (28), wherein the bottom surface is formed as a flat surface, and one of the side surfaces is provided with a connection protrusion (32) and the other is provided with a connection groove (33) at a position facing the connection protrusion (32). And
The conductive cable (41) has the groove so that an exposed portion of the conductor (4) is exposed from the groove (31) so that a part of the conductor (4) is exposed from the groove (31). (31), when the plurality of socket cables (28) are placed on a plane, the side surfaces of the adjacent socket cables (28) are connected to each other by the connection protrusion (32) and the connection groove ( 33) A cable that is connectable according to 33). A conductive cable (41) in which a conductive wire (42) is covered with a conductor (4);
The insulating member (3) is formed in a shape having a bottom surface, an upper surface and two side surfaces and is extended, and a single groove (31) capable of receiving the conductive cable (41) is formed in the longitudinal direction on the upper surface. The socket cable (28), wherein the bottom surface is formed as a flat surface, and one of the side surfaces is provided with a connection protrusion (32) and the other is provided with a connection groove (33) at a position facing the connection protrusion (32). And
The conductive cable (41) is inserted into the groove (31) so that a part of the conductor (4) is exposed from the groove (31), and a plurality of the socket cables (28) are on a plane. When the cable is placed, the side surfaces of the adjacent socket cables (28) can be connected to each other by the connection protrusion (32) and the connection groove (33). An electric shock device using the cable according to claim 1 or 2 ,
At least one flat cable (27) is placed on a plane, and at least one of the conductive wires (42) is connected to a high voltage power source. An electric shock device using the cable according to claim 3 or 4 ,
An electric shock device characterized in that at least two of the socket cables (28) are placed on a plane in a connected state, and at least one of the conductive wires (42) is connected to a high voltage power source.

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