JP6959729B2 - Connection structure - Google Patents

Description

The present invention relates to a connection structure for connecting wiring from a power supply facility and an outdoor outlet.

The consumer receives electricity (commercial electricity) from the electric power company and uses the electricity in the load equipment (general electric facilities) on the premises. It is also possible to install power generation equipment such as solar power generation equipment on the premises to operate the load equipment (for example, Patent Document 1), and sell the surplus power generated by the power generation equipment to the electric power company. Is.

Currently, a single-phase three-wire system is used as a power generation facility such as a solar power generation facility or a fuel cell. However, when energy-saving equipment becomes widespread and the demand for electric power on the premises decreases in the future, it is not always necessary to use a single-phase three-wire system. It is conceivable to install a small output power generation facility.

Then, not only the power generation equipment can be connected to the secondary side of the service circuit breaker of the distribution board, but also the power generation equipment can be directly connected to the secondary side of the molded case circuit breaker which is a single-phase two-wire system. Further, in this case, by directly connecting the power generation facility to the existing outdoor outlet outdoors, it is possible to effectively utilize the existing premises wiring and reduce the construction cost.

Some conventional outdoor outlets have a canopy formed upward in order to prevent rainwater from entering (for example, Patent Document 2). The conventional outdoor outlet has a structure in which the plug can be easily attached and detached based on the fact that the plug is frequently attached and detached.

Japanese Unexamined Patent Publication No. 2013-247737 Japanese Unexamined Patent Publication No. 2011-8947

As described above, when a power supply facility such as a power generation facility is directly connected to an existing outdoor outlet, the connection between the plug and the outdoor outlet will not fall off for a long period of time in order to ensure stable operation of the power supply facility. It is necessary to provide. However, the conventional outdoor outlet has a structure in which the plug can be easily attached and detached, and the development of a technique for suppressing the plug from coming off from the outdoor outlet is desired.

In view of such a problem, an object of the present invention is to provide a connection structure capable of suppressing the plug from coming off from an outdoor outlet.

To solve the above SL problems, connection structure of the present invention, opened downward, eaves is arranged above, electricity and outdoor outlet connected to the electric power system, and power supply equipment, power supply equipment A plug that is provided at the end of the wiring that is not connected to the power supply equipment of the wiring and that can be attached to and detached from the outdoor outlet from below, and an outdoor outlet that extends from the plug and is wrapped around the eaves. It is provided with a mounting member that can be mounted on the.

According to the present invention, it is possible to suppress the plug from coming off from the outdoor outlet.

It is explanatory drawing which showed the basic connection mode of the electric power system. It is a figure for demonstrating the connection structure of an outdoor outlet and a wiring in 1st Embodiment. FIG. 2 is a view taken along the line III of FIG. It is a figure for demonstrating the 2nd to 4th Embodiment. It is a figure for demonstrating the 5th Embodiment. It is a figure for demonstrating the sixth embodiment. It is a figure for demonstrating the 7th Embodiment. It is a figure for demonstrating 8th Embodiment. It is a figure for demonstrating the 9th Embodiment. It is a figure for demonstrating tenth and eleventh embodiments. It is a figure for demonstrating the twelfth to thirteenth embodiments. It is a figure for demonstrating the fifteenth embodiment. It is a figure for demonstrating the 16th-19th Embodiment. It is a figure for demonstrating the twentieth embodiment. It is a figure for demonstrating the 21st Embodiment.

Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The dimensions, materials, other specific numerical values, etc. shown in the embodiment are merely examples for facilitating the understanding of the invention, and do not limit the present invention unless otherwise specified. In the present specification and drawings, elements having substantially the same function and configuration are designated by the same reference numerals to omit duplicate description, and elements not directly related to the present invention are not shown. do.

(Power system 100)
FIG. 1 is an explanatory diagram showing a basic connection mode of the power system 100. The electric power system 100 receives electricity (commercial electric power) from the electric power system 14 through the service line 12. The electric power system 100 is configured for each consumer of low-voltage power reception, and the range thereof is not limited to houses and the like as long as it is an electric facility for general use, such as hospitals, factories, hotels, leisure facilities, commercial facilities, and condominiums. It may be a building unit or a part of a building.

Further, the power system 100 includes a power meter 112, a distribution board 114, a premises wiring 116, and an outlet 118.

The watt hour meter 112 is connected to the power system 14 via a service line 12 and measures the current value (consumption and power sale) flowing between the service line 12 and the power system 100.

The distribution board 114 is connected to the power meter 112 and indicates a service breaker (service breaker) 114a indicating the contracted capacity, a leakage breaker (leakage breaker) 114b that cuts off the supply of electricity in response to the detection of leakage, and the premises. It has a circuit breaker (safety breaker) 114c that is connected to the wiring 116 and cuts off the supply of electricity when the current flowing through the premises wiring 116 exceeds the breaking capacity (for example, 20A).

The consumer connects the load equipment 16 to the outlet 118, which is the end of the premises wiring 116, and receives power through the wiring breaker 114c. The load equipment 16 can be connected to an indoor outlet 118a or an outdoor outdoor outlet 118b.

Here, an attempt is made to add a power generation facility (power supply facility) 120 to the power system 100 described above. By adjusting the output voltage, the power generation facility 120 supplies electric power to the load facility 16 that consumes electric energy in preference to the electric power system 14. Examples of the power generation facility 120 include renewable energy power generation facilities such as a solar power generator, a wind power generator, a hydraulic power generator, a geothermal power generator, a solar heat generator, and an atmospheric heat generator, a fuel cell, and an internal combustion power generation device. A storage battery or the like can be used.

Such a power generation facility 120 is generally used by being connected to a single-phase three-wire (200V). In this case, an interconnection circuit breaker (200V) is provided in place of the wiring circuit breaker 114c, and the power generation facility 120 is connected to the interconnection circuit breaker, or a separate individual circuit breaker is cut off from the primary side of the leakage circuit breaker 114b. The power generation facility 120 must be connected via a circuit breaker (200V).

However, in the future, when energy-saving equipment becomes widespread and the power demand of the power system 100 decreases, the power line among the single-phase three-wires as in this embodiment does not necessarily require the single-phase three-wire power generation equipment. A small-output power generation facility connected only to a single-phase two-wire system (R-phase and N-phase, or T-phase and N-phase) consisting of either one of a certain R-phase or T-phase and an N-phase that is a neutral wire. 120 will be installed.

In this way, if the power generation facility 120 can be operated with a single-phase two-wire system, the outdoor branch from the existing premises wiring 116 is branched as shown by the white arrow in FIG. 1 without the intervention of an interconnection circuit breaker or the like. The power generation facility 120 can be connected to the outlet 118b through an individual circuit breaker 122 that prevents overcurrent and electric leakage. With such a configuration, it is possible to effectively utilize the existing premises wiring 116, reduce the construction cost, and simplify the wiring in the electric power system 100.

(Embodiments 1 to 4)
FIG. 2 is a diagram for explaining a connection structure 132 between the outdoor outlet 118b and the wiring 130 according to the first embodiment. As shown in FIG. 2, the individual circuit breaker 122 is housed inside the protective housing 134. The protective housing 134 is made of, for example, plastic, metal, or the like. In the individual circuit breaker 122, the protective housing 134 prevents rainwater from entering and prevents failure due to external pressure. Two support rods 136 are fixed to the back surface 134a of the protective housing 134. A leg portion 136a having a U-shaped cross section is fixed to the lower end of the support rod 136, and the support rod 136 is arranged on the mounting surface. An anchor 138 is fixed to one of the support rods 136, and the anchor 138 prevents the support rod 136 and the protective housing 134 from tipping over.

One end of the wiring 140 is connected to the individual circuit breaker 122. The other end of the wiring 140 is connected to the power generation facility 120 (see FIG. 1). That is, one end of the wiring 140 is an end that is not the connection side with the power generation facility 120. An insertion hole 134c through which the wiring 140 is passed is formed on the side surface 134b of the protective housing 134.

Further, a plug 142 is provided at one end of the wiring 130. The plug 142 is removable to the outdoor outlet 118b. An insertion hole 134e through which the wiring 130 is passed is formed on the upper surface 134d of the protective housing 134. One end of the wiring 130 projects to the outside of the protective housing 134. The other end of the wiring 130 is connected to the individual circuit breaker 122. The wiring 130 is electrically connected to the power generation facility 120 via the individual circuit breaker 122 and the wiring 140.

The eaves portion 144 is arranged above the outdoor outlet 118b. The eaves portion 144 suppresses the ingress of rainwater into the outdoor outlet 118b. The outdoor outlet 118b is open downward, and the plug 142 is inserted into the outdoor outlet 118b from below.

Further, an electric wire tube (tube) 146 is provided between the plug 142 and the protective housing 134. The wiring 130 is inserted inside the conduit 146. The conduit 146 is made of, for example, an impact resistant synthetic resin. In the wiring 130, as compared with the case where the electric wire pipe 146 is not provided, the electric wire pipe 146 prevents rainwater from entering and prevents failure due to external pressure.

FIG. 3 is a view taken along the line III of FIG. In FIG. 3, the protective housing 134, the wirings 130 and 140, the plug 142, and the individual circuit breaker 122 are extracted and shown. As shown in FIG. 3, an opening / closing door 134g is provided on the front surface 134f of the protective housing 134 (omitted in FIG. 2).

Further, the electric wire tube 146 is sandwiched between the plug 142 and the protective housing 134. That is, one end of the conduit 146 comes into contact with the plug 142 to support the plug 142 from below. One end of the conduit 146 is not fixed to the plug 142, but simply presses the plug 142 upward. The other end of the conduit 146 is fixed to the protective housing 134. One end of the conduit 146 is arranged in a positional relationship in which the plug 142 cannot be pulled out. That is, the distance between one end of the conduit 146 and the plug 142 is shorter than the distance required for inserting and removing the plug 142.

Here, the case where the outdoor outlet 118b is located vertically above the protective housing 134 has been described. However, even if the outdoor outlet 118b is arranged at a position different from the position vertically above the protective housing 134, for example, as the electric wire pipe 146, a vent, an elbow, a straight pipe, or the like can be combined to form the outdoor outlet 118b from the protective housing 134. Conduit 146 can be arranged up to the plug 142). Further, the electric wire tube 146 may be thermally processed to deform the electric wire tube 146.

The support rod 136, the legs 136a, and the anchor 138 are not indispensable configurations, and the protective housing 134 may be fixed to an installation surface such as a wall with a fastening member such as a screw (screw). In this case, for example, the protective housing 134, the conduit 146, and the plug 142 may be integrated into a unit, and then the protective housing 134 may be fixed to the installation surface with a fastening member.

In the first embodiment, the plug 142 is supported by the conduit 146, and the wiring 130 is housed and protected by the conduit 146. Therefore, the plug 142 is robustly and electrically completely connected to the outdoor outlet 118b, and tension is unlikely to act on the connection portion (connection point) between the plug 142 and the outdoor outlet 118b. In this way, prevention (falling off) of the plug 142 from the outdoor outlet 118b is suppressed.

FIG. 4 is a diagram for explaining the second to fourth embodiments. As shown in FIG. 4A, in the second embodiment, the protective housing 134A of the power generation facility 120 is used instead of the protective housing 134 of the individual circuit breaker 122. In this case, the plug 142 is attached to one end of the conduit 146, and the plug 142 is connected to the outdoor outlet 118b. After that, the other end of the conduit 146 is fixed to the protective housing 134A. The protective housing 134A is provided with a mechanism for fixing the conduit 146.

As shown in FIG. 4B, in the third embodiment, the protective housings 134 and 134A are not provided, and the spacer 148 is arranged between the other end of the conduit 146 and the ground G. Here, the case where the spacer 148 is arranged has been described, but the spacer 148 is not an essential configuration. For example, when the ground G is concrete or the like, the other end of the conduit 146 may be arranged directly on the ground G without arranging the spacer 148. Further, on the outer peripheral surface 146a of the electric wire tube 146, an outer hole 146b that penetrates to the inside of the electric wire tube 146 is formed. The wiring 130 extends from the plug 142 through the inside of the conduit 146 and from the outer hole 146b to the outside of the conduit 146.

As shown in FIG. 4 (c), in the fourth embodiment, the conduit 146 is supported by the saddle 150. The saddle 150 has a curved curved portion 150a, and flat surface portions 150b are formed at both ends of the curved portion 150a. The flat surface portion 150b extends parallel to the installation surface. A fastening hole is formed in the flat surface portion 150b, and the saddle 150 is fixed to the installation surface by inserting the fastening member 152 into the fastening hole. The saddle 150 surrounds the conduit 146 between the curved portion 150a and the installation surface to support the conduit 146.

In the second to fourth embodiments, as in the first embodiment, the plug 142 is robustly and electrically completely connected to the outdoor outlet 118b, and tension acts on the connection portion between the plug 142 and the outdoor outlet 118b. It has a structure that is difficult to do. In this way, the plug 142 is prevented from falling off from the outdoor outlet 118b.

(Embodiments 5-9)
FIG. 5 is a diagram for explaining a fifth embodiment. As shown in FIGS. 5 (a) and 5 (b), in the fifth embodiment, the first to fourth described above are in that the band portion (mounting member) 142b protrudes from the main body portion 142a of the plug 142. It is different from the embodiment of. The band portion 142b is made of metal, for example.

The back surface 154a of the mounting plate 154 of the outdoor outlet 118b is mounted on an installation surface such as a wall. The eaves 144 are attached to the front surface 154b of the attachment plate 154. Of the front surface 154b of the mounting plate 154, a fastening hole 154c through which the fastening member 152 is inserted is opened below the eaves portion 144. The fastening hole 154c is provided for mounting the mounting plate 154 on the installation surface.

The band portion 142b is provided on the mounting plate 154 side of both side surfaces 142c of the main body portion 142a. The band portion 142b is integrally formed with the main body portion 142a or is fixed to the main body portion 142a. The band portion 142b extends from both side surfaces 142c of the main body portion 142a. The band portion 142b is provided with a band hole 142d at a position facing the fastening hole 154c. The fastening member 152 is inserted into the fastening hole 154c from the band portion 142b side through the band hole 142d. The band portion 142b is fixed to the mounting plate 154 by the fastening member 152. That is, the plug 142 is fixed to the mounting plate 154. Since the fastening hole 154c provided for mounting the mounting plate 154 on the installation surface is used for fixing the band portion 142b, it is not necessary to perform any processing on the outdoor outlet 118b side, and the cost can be reduced.

FIG. 6 is a diagram for explaining a sixth embodiment. As shown in FIGS. 6A and 6B, in the sixth embodiment, the fastening target of the band portion (mounting member) 142bA is different from that of the fifth embodiment. The band portion 142bA is made of metal, for example. Of the outdoor outlet 118b, a fastening hole (not shown) through which the fastening member 152 is inserted is opened in the lower surface 158 where the insertion port 156 into which the plug 142 is inserted is formed.

The band portion 142bA is provided on the upper surface 142e side of the both side surfaces 142c of the main body portion 142a facing the lower surface 158 of the outdoor outlet 118b. The band portion 142bA is integrally formed with the main body portion 142a or is fixed to the main body portion 142a. The band portion 142bA extends from both side surfaces 142c of the main body portion 142a. The band portion 142bA is provided with a band hole 142dA at a position facing the fastening hole of the lower surface 158 of the outdoor outlet 118b. The fastening member 152 is inserted from the band portion 142bA side through the band hole 142dA into the fastening hole on the lower surface 158. Moreover, the installation work is easy. In this way, the band portion 142bA is fixed to the outdoor outlet 118b by the fastening member 152. That is, the plug 142 is fixed to the outdoor outlet 118b.

FIG. 7 is a diagram for explaining a seventh embodiment. As shown in FIGS. 7 (a) and 7 (b), in the seventh embodiment, the plate portion (mounting member) 160 is provided. The plate portion 160 is made of metal, for example. One plate portion 160 is provided on each of both side surfaces 142c of the main body portion 142a. One end of the plate portion 160 is provided on the upper surface 142e side of the side surface 142c of the main body portion 142a. The plate portion 160 is integrally formed with the main body portion 142a or is fixed to the main body portion 142a. The plate portion 160 extends from both side surfaces 142c of the main body portion 142a.

The plate portion 160 is wound around the eaves portion 144 of the outdoor outlet 118b, and the other ends of the two plate portions 160 intersect above the eaves portion 144. A plate hole 160a is formed on the other end side of the plate portion 160, and the plate holes 160a of the two plate portions 160 are overlapped with each other.

The fastening member 152 is inserted through the two plate holes 160a. One end and the other end of the plate 160 are fastened by the fastening member 152. Since the plate portion 160 is wound around the eaves portion 144 of the outdoor outlet 118b, the plug 142 is supported by the entire outdoor outlet 118b. Further, since the plate portion 160 is made of metal, slipping from the eaves portion 144 is prevented.

FIG. 8 is a diagram for explaining the eighth embodiment. As shown in FIGS. 8A and 8B, in the eighth embodiment, a stay member (mounting member) 162 such as a saddle is provided. The stay member 162 is formed separately from the plug 142. The stay member 162 has a flat surface portion 162a. The flat surface portion 162a extends in the plane direction perpendicular to the installation surface. The flat surface portion 162a has a larger outer shape than the lower surface 142g of the plug 142. At one end of the flat surface portion 162a, a groove portion 162b recessed on the installation surface side is formed. Here, the case where the groove portion 162b is formed has been described, but an elongated hole may be formed instead of the groove portion 162b. A bent portion 162c is formed at the other end of the flat surface portion 162a. The bent portion 162c bends downward from the flat surface portion 162a.

The mounting plate 154 is provided with a fastening hole 154c. The bent portion 162c is provided with a through hole 162d at a position facing the fastening hole 154c. The fastening member 152 is inserted into the fastening hole 154c from the bent portion 162c side through the through hole 162d. The bent portion 162c is fixed to the mounting plate 154 of the outdoor outlet 118b by the fastening member 152. That is, the stay member 162 is fixed to the mounting plate 154. Here, the case where the stay member 162 is fixed to the mounting plate 154 has been described, but the stay member 162 may be mounted on the installation surface. However, when the stay member 162 is fixed to the mounting plate 154, since the fastening hole 154c provided for mounting the mounting plate 154 on the installation surface is used for fixing the stay member 162, some processing is performed on the outdoor outlet 118b side. It is not necessary to perform the above, and the cost can be reduced.

The flat surface portion 162a extends from the bent portion 162c to the lower part of the plug 142. The wiring 130 is inserted into the groove portion 162b of the flat surface portion 162a. The lower surface 142 g of the plug 142 is supported from below by the flat surface portion 162a. Since the stay member 162 is fixed to the mounting plate 154 by the fastening member 152, the plug 142 is also supported with the same robustness as screwing. Moreover, the installation work is easy. The shape of the stay member 162 makes it possible to avoid interference with the plug 142 connected to other adjacent outlets. When the wiring 130 is supported and attached by a jig or the like, it is preferable to support the position of the wiring 130 close to the plug 142.

FIG. 9 is a diagram for explaining a ninth embodiment. As shown in FIGS. 9A and 9B, in the ninth embodiment, unlike the eighth embodiment, the spacer 166 is provided between the plug 142 and the stay member 162. The spacer 166 has a flat plate shape and is provided with a groove portion 166a. The groove portion 166a extends in the direction perpendicular to the installation surface.

The bent portion 162cA of the stay member 162 is bent above the flat surface portion 162a. The bent portion 162cA is fixed to the mounting plate 154 of the outdoor outlet 118b by the fastening member 152. Here, the case where the bent portion 162cA is fixed to the mounting plate 154 has been described, but the bent portion 162cA may be mounted on the installation surface. The flat surface portion 162a is provided with a long hole 162bA. Here, the case where the elongated hole 162bA is formed has been described, but a groove portion may be formed instead of the elongated hole 162bA. That is, one end of the elongated hole 162bA may be opened to the outer surface of the stay member 162. The wiring 130 is inserted through the elongated hole 162bA.

At the time of mounting, first, the bent portion 162cA of the stay member 162 is fixed to the front surface 154b of the mounting plate 154 by the fastening member 152. The flat surface portion 162a extends from the bent portion 162cA to the lower part of the plug 142. After that, the spacer 166 is sandwiched between the flat surface portion 162a of the stay member 162 and the plug 142. That is, the spacer 166 is interposed between the lower surface 142 g of the plug 142 and the flat surface portion 162a. At this time, the wiring 130 is inserted into the groove portion 166a of the spacer 166. The lower surface 142 g of the plug 142 is supported from below by the flat surface portion 162a. In the ninth embodiment, as in the eighth embodiment described above, when the bent portion 162cA is fixed to the mounting plate 154, the stay member has a fastening hole 154c provided for mounting the mounting plate 154 on the installation surface. Since it is used for fixing 162, it is not necessary to perform any processing on the outdoor outlet 118b side, and the cost can be reduced.

Although one spacer 166 is shown in FIG. 9A, a plurality of spacers 166 may be sandwiched depending on the gap between the plug 142 and the flat surface portion 162a. The spacer 166 fills the gap between the plug 142 and the flat surface portion 162a, and the plug 142 is firmly fixed by the stay member 162. Here, the case where the spacer 166 is provided has been described, but instead of the spacer 166, an incompressible fixing member such as an electric wire pipe may be provided.

The elongated hole 162bA extends longer in the direction parallel to the installation surface (arrow B in FIG. 9A) than in the vertical direction of the installation surface (arrow A in FIG. 9A). Therefore, for example, even if the fastening member 152 is attached near the center of the outdoor outlet 118b in a direction parallel to the installation surface and the plug 142 is located in the direction of arrow B with respect to the fastening member 152, the direction is opposite to that of arrow B. Even if it is located at, the wiring 130 is unlikely to interfere with the inner wall surface of the elongated hole 162bA. Moreover, the installation work is easy. The shape of the stay member 162 makes it possible to avoid interference with the plug 142 connected to other adjacent outlets.

In the fifth to ninth embodiments, as in the first embodiment, the plug 142 is robustly and electrically completely connected to the outdoor outlet 118b, and tension acts on the connection portion between the plug 142 and the outdoor outlet 118b. It has a structure that is difficult to do. In this way, the plug 142 is prevented from falling off from the outdoor outlet 118b.

(Embodiments 10 to 19)
FIG. 10 is a diagram for explaining the tenth and eleventh embodiments. As shown in FIG. 10A, in the tenth embodiment, the fastening band 168 is provided. The fastening band 168 is composed of, for example, a plastic binding band. The fastening band 168 is wound around the entire circumference of the plug 142 and the outdoor outlet 118b, including the installation surface side of the wiring 130 and the upper surface 144a of the eaves portion 144, of the lower surface 142 g of the plug 142, and the plug 142 is wound outdoors. Bind to outlet 118b.

As shown in FIG. 10B, in the eleventh embodiment, the fastening band 168 is provided, and the main body portion 142a of the plug 142 is provided with a plurality of tapered surfaces 142f having different inclination angles from each other. The tapered surface 142f is formed between both side surfaces 142c and the lower surface 142g of the plug 142. By providing the tapered surface 142f, for example, even if the upper surface 144a of the eaves portion 144 is an inclined surface, the fastening band 168 is provided on the surface having the closest inclination angle to the upper surface 144a of the eaves portion 144 among the plurality of tapered surfaces 142f. By wrapping the fastening band 168, slippage of the fastening band 168 is suppressed, and it is possible to prevent the fastening band 168 from falling off from the tapered surface 142f.

FIG. 11 is a diagram for explaining the twelfth to thirteenth embodiments. As shown in FIG. 11A, in the twelfth embodiment, the protruding portion 142h is formed on the lower surface 142g of the plug 142. The protruding portion 142h is provided on the installation surface side of the lower surface 142g with respect to the wiring 130. A through hole 142i is formed in the projecting portion 142h so as to penetrate parallel to the installation surface and in the horizontal direction. The fastening band 168 is wound around the entire circumference of the plug 142 and the outdoor outlet 118b through the through hole 142i.

As shown in FIG. 11B, in the thirteenth embodiment, the orientation of the plug 142 is 90 degrees different from that of the twelfth embodiment. The protrusion 142hA and the through hole 142iA are formed in accordance with the orientation of the plug 142. That is, even in the thirteenth embodiment, the through hole 142iA penetrates in the parallel and horizontal direction to the installation surface. The fastening band 168 is wound around the entire circumference of the plug 142 and the outdoor outlet 118b through the through hole 142iA.

In the twelfth and thirteenth embodiments, since the fastening band 168 is inserted into the through holes 142i and 142iA, the fastening band 168 does not slip off from the plug 142.

Further, as shown in FIG. 11C, in the fourteenth embodiment, the plug 142 is provided with both the protruding portion 142h and the protruding portion 142hA. A through hole 142i is formed in the protruding portion 142h, and a through hole 142iA is formed in the protruding portion 142hA. By providing both the through holes 142i and 142iA having different penetration directions in this way, the plug 142 can be shared regardless of whether the attachment direction of the plug 142 is any of the twelfth and thirteenth embodiments. Is possible.

FIG. 12 is a diagram for explaining a fifteenth embodiment. As shown in FIG. 12, in the fifteenth embodiment, the screw 170 is provided above the eaves portion 144. The screw 170 penetrates the eaves portion 144 and the mounting plate 154 and is fixed to the installation surface. A protruding portion 142hB protruding upward is provided at a portion of the screw 170 that protrudes from the eaves portion 144. A through hole 142iB is formed in the protruding portion 142hB.

Further, a protruding portion 142hC is provided at a portion of the lower surface 142g of the plug 142 that is separated from the installation surface from the wiring 130. A through hole 142iC is formed in the protruding portion 142hC.

The fastening band 168 (not shown) is inserted and fastened to both the through hole 142iB provided in the screw 170 and the through hole 142iC provided in the plug 142. Therefore, the plug 142 is fixed to the screw 170 fixed to the installation surface via the fastening band 168.

By the way, in order to fix the outdoor outlet 118b to the installation surface, the outdoor outlet 118b is formed with a hole through which a screw is inserted. Therefore, if the screw for fixing the outdoor outlet 118b to the installation surface is replaced with the screw 170 having the protruding portion 142hB and the through hole 142iB formed therein, it is not necessary to perform any processing on the outdoor outlet 118b side, and the cost can be reduced.

FIG. 13 is a diagram for explaining the 16th to 19th embodiments. As shown in FIG. 13A, in the sixteenth embodiment, the fastening band 168 is wound around the entire circumference of the plug 142 and the outdoor outlet 118b, as in the tenth embodiment. Then, among the fastening bands 168, another fastening band 168A is inserted between the fastening band 168 and the lower surface 142 g of the plug 142. The fastening band 168A is wound around the wiring 130 in addition to the fastening band 168. The inner peripheral length of the ring formed by the fastening band 168A is shorter than the outer peripheral length of the outer peripheral surface 142k of the plug 142. That is, the plug 142 cannot pass through the inside of the ring formed by the fastening band 168A. Therefore, it is possible to avoid a situation in which the fastening band 168 slips off the plug 142 without any processing on the plug 142 or the outdoor outlet 118b.

As shown in FIG. 13B, in the seventeenth embodiment, the fastening band 168B is wound around the entire circumference of the plug 142 and the outdoor outlet 118b. Then, a long hole 168Ba is formed in the fastening band 168B. The elongated hole 168Ba faces the lower surface 142g of the plug 142, and the wiring 130 is inserted therethrough. By inserting the wiring 130 into the elongated hole 168Ba, it is possible to avoid a situation in which the fastening band 168B slips off from the plug 142.

As shown in FIG. 13 (c), in the eighteenth embodiment, a string 172 is provided instead of the fastening band 168. Two strings 172 are attached to the lower surface 142 g of the plug 142 with the wiring 130 interposed therebetween. The string 172, like the fastening band 168, is wound around the entire circumference of the plug 142 and the outdoor outlet 118b. A metal wire may be used instead of the string 172. By using a string 172 or a wire, it can be easily bent along the plug 142 or the outdoor outlet 118b and becomes less slippery.

As shown in FIG. 13 (d), in the nineteenth embodiment, the tape member 174 is provided instead of the fastening band 168. Surface fasteners 174a are provided at both ends of the tape member 174, and both ends are removable by the surface fasteners 174a. The tape member 174 is wound around the entire circumference of the plug 142 and the outdoor outlet 118b, like the fastening band 168.

In the tenth to nineteenth embodiments, as in the first embodiment, the plug 142 is robustly and electrically completely connected to the outdoor outlet 118b, and tension acts on the connection portion between the plug 142 and the outdoor outlet 118b. It has a structure that is difficult to do. In this way, the plug 142 is prevented from falling off from the outdoor outlet 118b.

(20th and 21st embodiments)
FIG. 14 is a diagram for explaining a twentieth embodiment. As shown in FIGS. 14 (a) and 14 (b), in the twentieth embodiment, the surrounding member 180 is provided. The surrounding member 180 surrounds the outdoor outlet 118b and the plug 142 between the surrounding member 180 and the installation surface 182. The outdoor outlet 118b and the plug 142 can be firmly connected by the surrounding member 180, and tension can be prevented from being applied to the connection point. It is also possible to prevent the ingress of rainwater and prevent failures due to external pressure.

The surrounding member 180 has an opening on the back surface side (installation surface 182 side) of the main body portion 180a. In a state where the back side of the main body 180a is in contact with the installation surface 182, the fastening member 152 is fastened to the installation surface 182. The front surface 180b of the main body 180a is detachable with the fastening member 152.

A through hole 180d is formed in the lower surface 180c of the main body 180a. The through hole 180d is located below the plug 142, and the wiring 130 can be inserted therethrough. However, the plug 142 has a size that cannot be inserted into the through hole 180d. The plug 142 is supported from below by the lower surface 180c of the main body 180a. Here, the case where the through hole 180d is formed on the lower surface 180c of the main body portion 180a has been described, but a groove portion (U-shaped hole) may be provided instead of the through hole 180d. In this case, the groove is provided on the lower surface 180c of the main body 180a and extends from below the plug 142 to the installation surface 182.

As described above, the surrounding member 180 functions as a protective structure 184 that suppresses the tensile stress acting on the plug 142 by the lower surface 180c supporting the plug 142 from below.

FIG. 15 is a diagram for explaining the 21st embodiment. As shown in FIGS. 15A and 15B, in the 21st embodiment, the surrounding member 180 has an individual circuit breaker 122 in addition to the outdoor outlet 118b and the plug 142 between the surrounding member 180 and the installation surface 182. Surround. The outdoor outlet 118b, the plug 142, and the individual circuit breaker 122 can be firmly connected by the surrounding member 180, and tension can be prevented from being applied to the connection point. When the individual circuit breaker 122 is not a waterproof circuit breaker, the surrounding member 180 can prevent rainwater from entering. It is also possible to prevent failures due to external pressure, if necessary.

Two groove portions 180f are formed on both side surfaces 180e of the surrounding member 180. The groove portion 180f is recessed from the end portion on both side surfaces 180e on the installation surface 182 side. One support rod 186 is inserted into each of the two groove portions 180f. The individual circuit breaker 122 has, for example, a waterproof function and is fixed to the support rod 186.

Wiring 140 (not shown) is connected to the individual circuit breaker 122, and the individual circuit breaker 122 is connected to the power generation facility 120 (not shown) via the wiring 140. Further, the wiring 130 projects from the upper surface 122a of the individual circuit breaker 122, and a plug 142 is provided at one end of the wiring 130. The plug 142 is connected to an outdoor outlet 118b installed above the individual circuit breaker 122.

In the 21st embodiment, the surrounding member 180 surrounds the individual circuit breaker 122 in addition to the outdoor outlet 118b and the plug 142 between the surrounding member 180 and the installation surface 182. Therefore, the plug 142 and the entire wiring 130 are protected inside the surrounding member 180. That is, the surrounding member 180 functions as a protective structure 184 that suppresses the tensile stress acting on the plug 142.

In the 20th to 21st embodiments, as in the first embodiment, the plug 142 is robustly and electrically completely connected to the outdoor outlet 118b, and tension acts on the connection portion between the plug 142 and the outdoor outlet 118b. It has a structure that is difficult to do. In this way, the plug 142 is prevented from falling off from the outdoor outlet 118b.

Although the preferred embodiment of the present invention has been described above with reference to the accompanying drawings, it goes without saying that the present invention is not limited to such an embodiment. It is clear that a person skilled in the art can come up with various modifications or modifications within the scope of the claims, which naturally belong to the technical scope of the present invention. Understood.

For example, in the above-described embodiment, the power generation facility 120 is connected to the outdoor outlet 118b through the individual circuit breaker 122. However, for the outlet 118 including the outdoor outlet 118b, ordinary electric equipment can be used. It can be applied not only to 100V but also to 200V where an air conditioner can be used.

Further, the configurations of the above-described embodiments may be combined.

The present invention can be used in a connection structure for connecting wiring from a power supply facility and an outdoor outlet.

118b Outdoor outlet 120 Power generation equipment (power supply equipment)
130 Wiring 132 Connection structure 142 Plug 142b, 142bA Band part (mounting member)
142g Lower surface 160 Plate part (mounting member)
162 Stay member (mounting member)
166 Spacer 182 Installation surface

Claims (1)

An outdoor outlet that opens downwards, has eaves above it, and is connected to the power system.
Power supply equipment and
Wiring that is electrically connected to the power supply equipment and
A plug that is provided at the end of the wiring that is not connected to the power supply facility and that can be attached to and detached from the outdoor outlet from below.
A mounting member that extends from the plug, is wrapped around the eaves, and is attached to the outdoor outlet.
Connection structure with.

Images