JP6534018B2 - Wiring device and wiring system - Google Patents

Description

  The present invention relates to a wiring device and a wiring system, and more particularly to a wiring device and a wiring system attached to a construction surface of a building.

  Conventionally, a switch device installed in a state where the rear portion is embedded in an embedding hole provided in a wall of a building has been proposed (see, for example, Patent Document 1).

  The switch device includes a quick connect type terminal device to which a wire from a power supply or load is connected. The terminal device comprises a terminal plate and a lock spring. The lock spring has a lock spring portion at a portion close to the wire insertion hole and a pressing spring portion at a far portion. When the core wire of the electric wire is inserted between the terminal plate and the locking spring portion, the locking spring portion bites into the core wire, whereby the electric wire is prevented from coming off. Further, the terminal board and the core wire of the wire are electrically connected by the pressing spring portion pressing the core wire of the wire against the terminal plate.

Japanese Patent Laid-Open No. 2002-8470

  During installation of the switch device, if the wire is not sufficiently inserted into the terminal device, the pressing spring portion weakens the force of pressing the core of the wire against the terminal plate as compared with the case where the wire is inserted to the specified position. The contact resistance between the core wire of the electric wire and the terminal board may increase. In addition, when the switch device is used for a long time, the force of the lock spring pressing the core of the wire against the terminal plate weakens due to the secular change of the lock spring or the vibration applied to the switch, and the core wire of the wire and the terminal plate The contact resistance between them may be increased. If the contact resistance between the core wire of the wire and the terminal plate increases, Joule heat generated at the contact portion between the core wire of the wire and the terminal plate may increase when power is supplied, but the switch device is embedded in the wall As a result, it was not possible to easily grasp the use state of the switch device.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a wiring apparatus and a wiring system in which the usage state can be grasped.

A wiring system according to an aspect of the present disclosure includes a wiring device, a data acquisition device, and a management device. The wiring device measures a temperature of a case attached to a construction surface, a terminal device held by the case and connected with an electric wire introduced into the case from the outside of the case, and the terminal device A measurement unit, a notification unit that performs a notification operation when the measurement temperature of the measurement unit becomes higher than an allowable range, and a transmission unit that transmits the measurement result of the measurement unit to an external device. The data collection device is installed on a distribution board that distributes power to a branch circuit to which the wiring device is connected, and collects the measurement results of the measurement unit transmitted from the transmission unit. The management device receives the measurement result of the measurement unit collected by the data collection device from the data collection device, and manages the measurement result of the measurement unit.

The wiring device according to an aspect of the present disclosure is the wiring device included in the wiring system, and the transmission unit transmits the measurement result of the measurement unit to the data collection device.

  According to the present invention, it is possible to provide a wiring device and a wiring system capable of grasping the use state.

It is a block diagram of a wiring device of an embodiment. It is an exploded perspective view of a wiring device of an embodiment. It is a sectional view showing the construction state of the wiring device of an embodiment. It is a block diagram showing a modification of a wiring device of an embodiment. It is a perspective view in the state where the cover of the wiring device of an embodiment was removed. It is a rear view of the wiring apparatus of embodiment. It is a bottom view of a contact device and a terminal device with which a wiring device of an embodiment is provided. It is a perspective view of a contact device and a terminal device with which a wiring device of an embodiment is provided. It is a front view which shows the modification of the terminal device with which the wiring apparatus of embodiment is provided. It is a rear view which shows the modification of the wiring apparatus of embodiment. It is a block diagram showing a modification of a wiring device of an embodiment. It is a system configuration figure of a wiring system of an embodiment.

  Hereinafter, embodiments of a wiring apparatus according to the present invention and a wiring system using the same will be described based on the drawings. However, the configuration described below is merely an example of the present invention. The present invention is not limited to the following embodiments, and various modifications can be made according to the design and the like without departing from the technical concept of the present invention.

  FIG. 1 is a block diagram of a wiring device 1 of the present embodiment. The wiring apparatus 1 of the present embodiment is a switch, and the first connection unit 11, the second connection unit 12, the contact device 13, the signal processing unit 14, the notification unit 15, the measurement unit 16, and the signal terminal A communication unit 18 and a power supply unit 19 are provided.

  The wiring device 1 includes a case 100 held by a mounting frame 20 fixed to the peripheral edge of a hole 51 provided in a wall member 50, and an operation handle 120 (see FIGS. 2 and 3). In the case 100, the first connection portion 11, the second connection portion 12, the contact device 13, the measurement unit 16, the signal processing unit 14, the notification unit 15, the signal terminal 17, and the communication unit 18 And the power supply unit 19 are held. Case 100 is attached to wall material 50 in the state where a part was embedded at hole 51 of wall material 50 using attachment frame 20 (refer to Drawing 3). In addition, the wiring apparatus 1 is not limited to what is attached to a wall surface, It may be attached to construction surfaces, such as a ceiling surface and a floor surface.

  An electric wire L1 from an external power source 2 such as a commercial AC power source is electrically connected to the first connection portion 11.

  The electric wire L2 from the electric device 3 is electrically connected to the second connection portion 12. In addition, the electric equipment 3 is equipped with the JEM-A terminal 301 defined by the Japan Electric Industrial Standards.

  The contact device 13 is provided in the middle of an electric path electrically connecting the first connection portion 11 and the second connection portion 12. The contact device 13 is switched on / off in accordance with the operation of the operation unit. When the contact device 13 is turned on, power is supplied from the external power supply 2 to the electric device 3. When the contact device 13 is turned off, the power supply from the external power supply 2 to the electric device 3 is cut off.

  The signal processing unit 14 implements a predetermined function by executing a program stored in the memory.

  When the notification signal is input from the signal processing unit 14, the notification unit 15 performs a notification operation by, for example, ringing a buzzer.

  The measuring unit 16 measures the physical quantity inside the case 100. The physical quantity measured by the measurement unit 16 is a physical quantity related to the use state of the wiring device 1 and is, for example, a temperature or a current. The measuring unit 16 may measure the physical quantity on the surface of the case 100.

  The signal terminal 17 is connected to the JEM-A terminal 301 of the electric device 3 via the signal line L3.

  The communication unit 18 outputs an on / off signal to the electric device 3 via the signal terminal 17. The communication unit 18 also receives a monitor signal indicating the operating state from the electric device 3 via the signal terminal 17. The communication unit 18 also has a function as a transmission unit that transmits the measurement result of the measurement unit 16 to an external device. The communication unit 18 transmits the measurement result of the measurement unit 16 to an external device by a wireless communication method. Here, the communication unit 18 communicates by a wireless communication method which does not require a license. As this type of communication method, for example, a specific low power wireless communication, a wireless communication method based on IEEE 802.15.1 which is a communication standard of IEEE (The Institute of Electrical and Electronics Engineers), a wireless according to IEEE 802.15.4 There is a communication method etc.

  The power supply unit 19 receives power supply from the external power supply 2 connected to the first connection unit 11 and supplies power necessary for operation to circuits such as the signal processing unit 14.

  In the wiring device 1, the measurement unit 16 measures the temperature inside the case 100. The signal processing unit 14 periodically takes in the measurement result of the measurement unit 16, compares the measurement result of the measurement unit 16 with the preset allowable range, and when the measurement result is out of the allowable range, an abnormality occurs. And outputs a notification signal to the notification unit 15. At this time, the notification unit 15 sounds a buzzer to notify the person in the vicinity of the occurrence of an abnormality. The signal processing unit 14 may output a signal to turn off the electrical device 3 from the communication unit 18 to the electrical device 3 when the occurrence of an abnormality is detected. At this time, the electric device 3 stops its operation in response to the signal input from the wiring device 1 to the JEM-A terminal 301, and can stop the current flowing to the electric device 3 through the wiring device 1 it can.

  Here, the case 100 is attached to a construction surface (for example, a wall surface) using an attachment frame 20 for attaching the embedded wiring device to the construction surface. A maximum of three embedded wiring fixtures can be attached to the mounting frame 20, and the size of this wiring fixture is referred to as one module size. In the present embodiment, the case 100 is formed in a three-module size (approximately the same size as three wiring fixtures of one-module size arranged in the lateral direction). , All the components of the wiring device 1 are accommodated.

  In the present embodiment, the entire configuration of the wiring device 1 is housed in one case 100, but as shown in FIG. 4, the wiring device 1 includes two cases 100 and 117, and the configuration of the wiring device 1 May be divided into two cases 100 and 117 and stored. The case 100 and the case 117 are formed in, for example, one module size. The first connection portion 11, the second connection portion 12, the contact device 13, and the measuring portion 16 are housed in the case 100, and the configuration is such that the measuring portion 16 is added to a general switch. . Inside the case 117, the signal processing unit 14, the notification unit 15, the signal terminal 17, the communication unit 18, and the power supply unit 19 are accommodated. The case 100 and the case 117 are attached to the same mounting frame 20. The measuring unit 16 housed in the case 100 and the signal processing unit 14 housed in the case 117 are electrically connected via the signal line L4 wired between the cases 100 and 117. Further, the power supply unit 19 housed in the case 117 obtains electric power from the electric path in the case 100 via the electric wire L5 wired between the cases 100 and 117. The case 117 may be formed in a two-module size (a size substantially the same as a size in which two wiring fixtures of one-module size are arranged in the lateral direction). And the case 117 can be attached side by side.

  Next, the structure of the wiring device 1 provided with the two cases 100 and 117 will be described based on FIGS. 2, 3 and 5 to 10. Although a wide handle type switch is illustrated as the wiring device 1 in FIGS. 2, 3 and 5 to 10, a switch other than the wide handle type may be used. Further, in FIGS. 2, 3, and 5 to 10, the illustration of the case 117 is omitted, and only the case 100 is illustrated. In the following description, unless otherwise noted, description will be made according to the directions of upper, lower, left, right, front and back indicated by arrows in FIG. 2, but the direction when using the wiring device 1 is not limited to the above.

  The case 100 of the wiring apparatus 1 includes a body 101 and a cover 102 as shown in FIGS. 2 and 3. As shown in FIG. 5, the body 101 is formed of a thermosetting resin (for example, urea resin etc.) into a box shape having an open front side. The inside of the body 101 is divided into three storage spaces 112 to 114 in the left-right direction by ribs projecting from the inner wall. The terminal device 130 is accommodated in the storage space 112 on the left side and the storage space 113 on the right side, and the contact device 13 is accommodated in the central storage space 114. The cover 102 is formed of a thermosetting resin (for example, urea resin) in a box shape with an open rear side. The cover 102 is attached to the body 101 so as to close the opening on the front side of the body 101. When the cover 102 is attached to the body 101, the projections 110 provided on the surface of the body 101 fit into the holes 111 provided in the cover 102, and the state where the cover 102 and the body 101 are joined is maintained. Be

  On the left side surface and the right side surface of the case 100, two mounting claws 103 for mounting the case 100 to the mounting frame 20 are provided. In the right side wall of the case 100, a slit is formed around a portion provided with the two mounting claws 103, and a portion provided with the two mounting claws 103 (this portion is referred to as the movable piece 104) The front end side of the case 100 is supported in a cantilever manner. Therefore, the two attachment claws 103 provided on the movable piece 104 can be moved to the inside of the case 100 by pushing the projection 105 provided on the rear of the movable piece 104.

  Two cylindrical shafts 106 for supporting the operation handle 120 are provided on the left side of the front surface of the case 100 so as to be vertically aligned.

  A push button 107 is attached to the front of the case 100 so as to be movable in the front-rear direction. An opening / closing mechanism (not shown) of the contact device 13 is configured such that the on / off of the contact device 13 housed inside the case 100 is alternately switched each time the push button 107 is pressed.

  Further, as shown in FIG. 6, two through holes 108 are provided on the left and right of the rear portion of the case 100 (that is, the rear wall of the body 101). The through hole 108 penetrates the rear wall of the body 101 in the front-rear direction. Electric wires (the above-mentioned electric wires L1 and L2) inserted into the through hole 108 from the outside of the case 100 are introduced into the inside of the case 100 through the through hole 108 and electrically connected to the terminal device 130 housed in the inside of the case 100. Connected

  Here, the configurations of the contact device 13 and the terminal device 130 will be described based on FIGS. 7 and 8.

  First, the configuration of the terminal device 130 will be described. The terminal device 130 includes two terminal plates 131 and 132 and four lock springs 140. The terminal device 130 includes a wire holding portion as its component. The wire holding portion is formed of a material that deforms in response to a temperature change, and changes to a shape such that the contact pressure with the wire increases when the temperature exceeds a predetermined temperature. Here, the specified temperature is a temperature higher than the temperature generated in the terminal device 130 in the normal use state, and is set to a temperature of about 60 ° C. In the present embodiment, the terminal boards 131 and 132 are wire holding parts.

  The terminal plates 131 and 132 are each formed of a shape memory alloy having conductivity. Inside the case 100, storage spaces 112 and 113 are provided on the left and right sides, the terminal plate 131 is stored in the storage space 112 on the left side, and the terminal plate 132 is stored in the storage space 113 on the right side.

  Each of the terminal boards 131 and 132 includes two terminal holding portions 133. Each terminal holding portion 133 includes a central piece 134 and two leg pieces 135 and 136 which project from the central piece 134 in a direction orthogonal to the central piece 134. The terminal holding portion 133 is formed in a U-shape, as viewed in the vertical direction (the direction perpendicular to the paper surface in FIG. 7), by the central piece 134 and the leg pieces 135 and 136. The terminal plates 131 and 132 are accommodated in the inside of the case 100 such that the opening of the U-shaped terminal holding portion 133 faces the rear side (the lower side in FIG. 7). One lock spring 140 is disposed in the terminal holding portion 133.

  The lock spring 140 is formed by bending a strip of elastic metal material (for example, stainless steel). The lock spring 140 includes a central piece 141, a lock piece 142 and a pressing piece 143. The central piece 141 is formed in a rectangular plate shape. The locking piece 142 is formed to be U-shaped with the locking piece 142 and the central piece 141 by bending one end side in the longitudinal direction of the central piece 141 in the opposite direction. The pressing piece 143 has an S-shaped shape as viewed in the vertical direction (direction perpendicular to the sheet of FIG. 7) by bending the end opposite to the locking piece 142 in the longitudinal direction of the central piece 141. It is formed. The lock spring 140 causes the central piece 141 to face one leg piece 135 of the terminal holding portion 133 and causes the locking piece 142 and the pressing piece 143 to face the other leg piece 136 of the terminal holding portion 133. , And the terminal holding portion 133. When the terminal plates 131 and 132 and the lock spring 140 are housed in the body 101, the lock piece 142 is positioned at a position (that is, the rear side) close to the rear wall of the body 101 where the through hole 108 opens. The pressing piece 143 is located on the front side of the locking piece 142.

  Here, when the wire 500 is inserted into the through hole 108 of the case 100, the conductor portion 501 of the wire 500 is inserted between the lock spring 140 and the leg piece 136. At this time, when the tip end of the locking piece 142 bites into the conductor portion 501 of the wire 500, the wire 500 is less likely to come off. Further, when the pressing piece 143 is bent against the conductor portion 501 of the electric wire 500, an elastic force is generated in the pressing piece 143, and the conductor portion 501 of the electric wire 500 is pressed against the leg piece 136 by this elastic force. Thereby, the conductor portion 501 of the electric wire 500 is electrically connected to the leg piece 136, and the conductor portion 501 of the electric wire 500 is electrically connected to the terminal holding portion 133 (the terminal plate 131 or the terminal plate 132). Further, the contact pressure between the conductor portion 501 of the electric wire 500 and the leg piece 136 is secured by the elastic force generated in the pressing piece 143.

  Inside the case 100, a release button (not shown) is accommodated so that a part thereof is opposed to the locking piece 142. As shown in FIG. 6, a through hole 109 is provided on the rear wall of the case 100 at a position corresponding to the release button. When removing the wire 500 connected to the terminal device 130, insert the tip of the tool into the through hole 109, and press the release button with this tool, and the lock 142 is separated from the conductor portion 501 of the wire 500 by the release button. It is bent in the direction. As described above, when the electric wire 500 is pulled out with the locking piece 142 separated from the conductor portion 501 of the electric wire 500, the electric wire 500 can be easily removed from the terminal device 130. Here, one of the first connection portion 11 and the second connection portion 12 is configured of the terminal plate 131, the two lock springs 140, and one release button, and the first connection portion 11 and the second connection portion The other of the twelve is comprised of a terminal plate 132, two lock springs 140 and one release button.

  In the present embodiment, the terminal plates 131 and 132 are formed of a shape memory alloy having conductivity (for example, a shape memory alloy of Ni—Ti and Cu—Zn—Al). When the terminal plates 131 and 132 reach the specified temperature or more, the inner dimensions of the U-shaped portions on both sides of the lock spring 140, that is, the inner dimensions D1 of the two leg pieces 135 and 136 (see FIG. 7) The central piece 134 is curved so as to be smaller than the case below. For example, if the insertion of the wire 500 into the terminal device 130 is insufficient at the time of construction work, or if the position of the wire 500 is shifted due to vibration applied during use, the wire 500 with respect to the terminal plate 131 or the terminal plate 132 The contact pressure may be lower than the specified contact pressure. When the contact pressure of the electric wire 500 with respect to the terminal plate 131 or the terminal plate 132 becomes lower than the specified contact pressure, the contact resistance between the terminal plate 131 or 132 and the electric wire 500 increases, and the Joule heat of the terminal device 130 The temperature rises. When the temperature of the terminal plate 131, 132 becomes equal to or higher than the specified temperature due to the influence of Joule heat, the terminal plate 131, 132 is deformed so that the central piece 134 is curved while keeping the two leg pieces 135, 136 parallel. As a result, the inner dimension D1 of the leg pieces 135 and 136 is reduced. When the inner dimension D1 of the leg pieces 135 and 136 decreases with the electric wire 500 connected to the terminal device 130, the amount of deflection of the lock spring 140 (pressing piece 143) increases and the contact applied to the electric wire 500 from the pressing piece 143 The pressure increases. Therefore, the contact resistance between terminal board 131 or terminal board 132 and electric wire 500 is reduced, and the Joule heat generated at the contact portion between terminal board 131 or terminal board 132 and electric wire 500 is reduced, and electrical connection Reliability also improves.

  In the wiring device 1 of the present embodiment, the lock spring 140 may be formed of an elastic shape memory alloy instead of the terminal plates 131 and 132. In the case where the lock spring 140 is formed of a shape memory alloy, the lock spring 140 may be deformed so as to narrow the distance from the terminal plate 131 or the terminal plate 132 when the temperature exceeds a predetermined temperature. When the contact pressure of the wire 500 with respect to the terminal plate 131 or the terminal plate 132 becomes lower than a prescribed contact pressure due to the connection work at the time of construction or the vibration applied from the outside during use, the terminal plate 131 or 132 and the wire Contact resistance between 500 and increases. Here, when the contact resistance between the terminal plate 131 or 132 and the electric wire 500 increases, Joule heat generated in the contact portion between the terminal plate 131 or 132 and the electric wire 500 increases, and the terminal is caused by Joule heat. The temperature of the device 130 rises. When the temperature of the lock spring 140 becomes equal to or higher than a predetermined temperature due to the influence of Joule heat, the lock spring 140 is deformed so that the bending state of the bent portions 144 and 145 of the pressing piece 143 becomes gentle. As a result, the distance between the pressing piece 143 and the leg piece 136 decreases, and the amount of deflection of the pressing piece 143 generated when the pressing piece 143 hits the wire increases, so the contact pressure applied to the wire 500 by the pressing piece 143 increases. Do. Therefore, the contact resistance between terminal board 131 or terminal board 132 and electric wire 500 is reduced, and the Joule heat generated at the contact portion between terminal board 131 or terminal board 132 and electric wire 500 is reduced, and electrical connection Reliability also improves. The terminal plates 131 and 132 and the lock spring 140 are both formed of a shape memory alloy, and the terminal plate 131 or the terminal plate 132 and the electric wire 500 have a large contact pressure when the temperature exceeds a prescribed temperature. The plates 131 and 132 and the lock spring 140 may be respectively deformed.

  Further, in the wiring apparatus 1 of the present embodiment, as shown in FIG. 9, the lock spring 140 is on the opposite side of the electric wire 500, and the terminal plate 131 or the leg piece 135 of the terminal plate 132 and the lock spring 140 You may provide the press body 146 arrange | positioned between. Then, the pressing body 146 may be formed of a shape memory alloy, and the pressing body 146 may be deformed so as to press the lock spring 140 in the direction approaching the electric wire 500 when the temperature exceeds a predetermined temperature.

  The pressing body 146 is an elongated plate made of a shape memory alloy, and is formed in a V shape which is bent at an obtuse angle at the middle in the longitudinal direction. The pressing body 146 is disposed between the lock spring 140 and the leg piece 135 such that the longitudinal ends are in contact with the leg piece 135 and the longitudinal middle portion is in contact with the central piece 141 of the lock spring 140. It is done. The pressing body 146 is deformed so that the bending angle at the middle in the longitudinal direction becomes smaller when the temperature exceeds a predetermined temperature. Therefore, when the temperature is equal to or higher than the specified temperature, the amount of protrusion D2 from the line connecting the both ends in the longitudinal direction to the intermediate part in the longitudinal direction becomes larger than in the case of less than the specified temperature. Is pushed in the direction approaching the wire 500. Therefore, when the temperature becomes equal to or higher than the specified temperature, the contact pressure applied to the electric wire 500 from the pressing piece 143 increases, so the contact resistance between the terminal plate 131 or 132 and the electric wire 500 decreases. Therefore, the Joule heat generated at the contact portion between the terminal board 131 or the terminal board 132 and the electric wire 500 is reduced, and the reliability of the electrical connection is also improved.

  Next, the configuration of the contact device 13 will be described with reference to FIGS. 7 and 8. The contact device 13 includes a fixed contact 121 and a movable contact 122.

  The terminal holding portion 133 of the terminal plate 131 is provided with a terminal piece 137 which protrudes from the central piece 134 toward the terminal plate 132 and is bent so that the tip thereof protrudes rearward (the lower side in FIG. 7). It is done. A fixed contact 121 is fixed to the end of the terminal piece 137 on the surface facing the terminal plate 132.

  The terminal holding portion 133 of the terminal plate 132 is provided with a support piece 138 which protrudes rearward from the center piece 134 and is bent so that the tip thereof protrudes toward the terminal plate 131 side. The lower end portion of the plate-like open / close element 123 is in contact with the tip end portion of the support piece 138.

  The movable contact 122 is fixed to a part corresponding to the fixed contact 121 in the switch 123. The switch 123 swings between an on position where the movable contact 122 contacts the fixed contact 121 and an off position where the movable contact 122 separates from the fixed contact 121, with the contact point with the support piece 138 as a fulcrum As such, it is housed inside the case 100.

  When the push button 107 is pressed while the movable contact 122 is in contact with the fixed contact 121, the open / close device 123 is moved to the off position by the open / close mechanism (not shown) and the movable contact 122 is separated from the fixed contact 121 It becomes a state. On the other hand, when the push button 107 is pressed in a state where the movable contact 122 is separated from the fixed contact 121, the open / close device 123 is moved to the on position by the open / close mechanism, and the movable contact 122 is in contact with the fixed contact 121. Thus, each time the push button 107 is pressed once, the on state and the off state of the contact device 13 are switched.

  Next, the operation handle 120 will be described. As shown in FIG. 2 and FIG. 3, the operation handle 120 is formed in a rectangular plate shape in which the dimension in the horizontal direction and the dimension in the vertical direction are larger than the front surface of the push button 107. On the back surface (rear surface) of the operation handle 120, a bearing (not shown) to which the shaft 106 is rotatably attached is provided at a position facing the shaft 106 of the case 100. The operation handle 120 is rotatably supported on one end side (left side) in the left-right direction on the front surface of the case 100 by holding the shaft 106 in the bearing portion. Therefore, when the right side of the operation handle 120 is pushed backward, the operation handle 120 rotates around the portion supported by the shaft 106, and a protrusion (not shown) provided on the back surface of the operation handle 120 pushes the push button 107. It is configured to push in.

  As described above, in FIGS. 2, 3, and 5 to 10, the case 117 for storing the signal processing unit 14 and the like is not shown, but the case 117 has the shaft 106 and the push button 107 on the front surface. It has the same structure as the case 100 except that it is not provided.

  Next, the mounting frame 20 will be described with reference to FIGS. 2 and 3. The mounting frame 20 is formed of a synthetic resin or metal in a rectangular frame shape having a window hole 23 to which the cases 100 and 117 are attached. The mounting frame 20 intersects the direction in which the pair of first beam portions 21 opposed to each other across the window hole 23 in the longitudinal direction (vertical direction in FIG. 2) and the pair of first beam portions 21 (see FIG. In the left and right direction of 2), a pair of second beam portions 22 facing each other across the window hole 23 are provided. That is, a space surrounded by the pair of first beam portions 21 and the pair of second beam portions 22 is a window hole 23.

  In each of the pair of first beam portions 21, the first beam portion 21 is fixed to the wall material 50 in a state where the back surface side of the first beam portion 21 is in contact with the surface of the wall material 50 (see FIG. 3) An insertion hole 24 is provided for inserting a screw (not shown) for the purpose. Each of the pair of first beam portions 21 is provided with a screw hole 25 formed with a screw groove on the inner peripheral surface at the center in the left-right direction outside the insertion hole 24.

  In each of the pair of second beam portions 22, as shown in FIGS. 2 and 3, the case 100 is held at the attachment positions of both side portions and the central portion in the longitudinal direction (vertical direction) of the second beam portion 22. The first holding unit is provided. That is, in each of the pair of second beam portions 22, two through holes 221 are provided at the central portion in the longitudinal direction of the second beam portion 22. The two through holes 221 are provided at the same intervals as the two mounting claws 103 on one side of the case 100. The attachment claws 103 of the case 100 disposed at the attachment position of the central portion are respectively inserted into the two through holes 221. Further, in each of the pair of second beam portions 22, two through holes 222 and 223 are provided on one end side (upper side) in the longitudinal direction. The mounting claws 103 of the case 100 are respectively inserted into the two through holes 222 and 223 when the case 100 is arranged at the upper mounting position. Further, in each of the pair of second beam portions 22, two through holes 222 and 223 are provided on the other end side (lower side) in the longitudinal direction. The mounting claws 103 of the case 100 are respectively inserted into the two through holes 222 and 223 when the case 100 is arranged at the lower mounting position. That is, a first holding portion is configured by a pair of through holes 221 for holding the case 100 at the attachment position of the central portion, and a pair of through holes 222 and 223 for holding the case 100 at the attachment positions on both sides.

  Further, the mounting frame 20 of the present embodiment is configured to be able to hold the case 100 at a predetermined mounting position other than both side portions and the central portion in the longitudinal direction of the second beam portion 22. In the present embodiment, the case 100 can be attached to the attachment frame 20 at two attachment positions (the first intermediate position and the second intermediate position) other than the both sides and the central part. Here, the first intermediate position is a mounting position between the mounting position at one end side (upper side) in the longitudinal direction and the mounting position at the central portion. The second intermediate position is an attachment position between the attachment position on the other end side (lower side) in the longitudinal direction and the attachment position at the central portion.

  Each of the pair of second beam portions 22 is provided with a second holding portion so that the case 100 can be held at each of the first intermediate position and the second intermediate position. That is, in each of the pair of second beam portions 22, the through holes 224 are provided between the through holes 221 and the through holes 223 adjacent in the longitudinal direction of the second beam portion 22. Therefore, when the case 100 is attached to the first intermediate position, the upper attachment claw 103 of the case 100 is inserted into the upper through hole 223, and the lower attachment claw 103 of the case 100 is inserted into the upper through hole 224. Be inserted. When the case 100 is attached to the second intermediate position, the lower attachment claw 103 of the case 100 is inserted into the lower through hole 223, and the upper attachment claw 103 of the case 100 is inserted into the lower through hole 224. Be inserted. Here, the through hole 223 and the through hole 224 constitute a second holding portion. The through holes 221, 222 and 224 are formed slightly larger than the width of the mounting claws 103. On the other hand, the through hole 223 doubles as a first holding portion and a second holding portion. The through holes 223 are formed in the other through holes 221 and 222, respectively, so that both the mounting claws 103 of the case 100 arranged on both sides and the mounting claws 103 of the case 100 arranged at an intermediate position can be inserted. The width dimension is formed larger than 224.

  The case 100 can be attached to the attachment frame 20 by the first holding portion or the second holding portion, and the case 100 is attached to the attachment frame 20 with the front end portion of the case 100 protruding forward from the window hole 23.

  Next, the decorative member 30 attached to the front side of the mounting frame 20 will be described.

  As shown in FIG. 2, the decorative member 30 includes an inner frame 310 attached to the front side of the attachment frame 20 and a cover body 320 attached to the front side of the inner frame 310. The cosmetic member 30 has a function of making the mounting frame 20 invisible from the front side and exposing only the operation handle 120 operated by a person to the front side.

  The middle frame 310 is formed of a synthetic resin material in a rectangular frame shape having a pair of horizontal pieces 311 and a pair of vertical pieces 312. Here, the window hole 313 surrounded by the pair of horizontal pieces 311 and the pair of vertical pieces 312 is continuous with the window hole 23 of the mounting frame 20 in the front-rear direction with the middle frame 310 attached to the mounting frame 20 It is provided in the position.

  Each of the pair of horizontal pieces 311 is provided with an insertion hole 314 for inserting a screw at a central portion in the left-right direction. In each of the pair of vertical pieces 312, rectangular through holes 315 are formed in the central portion and both side portions in the longitudinal direction (vertical direction).

  The cover body 320 is a molded product of synthetic resin, and includes a front plate 321 and a side plate 322. The front plate 321 has a rectangular shape in which the four corners are curved when viewed from the front-rear direction, and is formed in a curved shape that bulges forward from the periphery toward the center. A rectangular window hole 323 is provided at the center of the front plate 321 so as to penetrate in the front-rear direction. Further, on the back surface of the front plate 321, a locking portion (not shown) is provided which is inserted into the through hole 315 at a portion corresponding to the through hole 315 of the middle frame 310 and hooked on the peripheral edge of the through hole 315. ing.

  Here, in a state where the mounting frame 20 to which the cases 100 and 117 are attached is fixed to the wall member 50 with a screw and the decorative member 30 is attached to the front surface of the mounting frame 20, only the operation handle 120 is exposed from the window hole 323 , And the operation handle 120 can be operated.

  By the way, the measurement part 16 of the wiring apparatus 1 of this embodiment is provided with the temperature measurement part 161 which measures temperature inside the body 101 (namely, inside the case 100), as shown in FIG. The temperature measurement unit 161 is, for example, a thermistor or a resistance temperature detector, and is disposed in the housing space 113 in which the terminal device 130 is housed inside the case 100. The temperature measurement unit 161 is electrically connected to the signal processing unit 14 housed in the case 117 via a wire (not shown). The signal processing unit 14 periodically measures the temperature inside the case 100 (the temperature of the storage space 113 in the present embodiment) based on the output of the temperature measurement unit 161. Although the measurement unit 16 measures the temperature inside the case 100 in the present embodiment, the temperature may be measured at one or more of the terminal plates 131 and 132, the lock spring 140, and the case 100. FIG. 8 exemplifies a temperature measurement point by the measurement unit 16. The measuring unit 16 has, for example, a measuring point P1 provided on the central piece 134 of the terminal plate 131, 132, a measuring point P2 provided on the leg piece 135 of the terminal plate 131, and a measuring point P3 provided on the central piece 141 of the lock spring 140. It may be attached to one or more of them to measure its temperature.

  For example, when the contact between the terminal plate 131, 132 and the wire 500 becomes insufficient due to poor connection during construction or the influence of vibration applied during use, the contact resistance between the terminal plate 131, 132 and the wire 500 increases. The Joule heat generated at the contact portion between the terminal plates 131 and 132 and the electric wire is increased. When the Joule heat increases compared to the normal use state, the temperatures of the terminal plates 131 and 132, the lock spring 140 and the case 100 rise. When the signal processing unit 14 periodically takes in the measurement temperature from the measurement unit 16 and the measurement temperature of the measurement unit 16 deviates from the preset allowable range, that is, when the measurement temperature of the measurement unit 16 becomes higher than the allowable range, It is determined that the temperature is abnormally rising, and a notification signal is output to the notification unit 15. When the notification unit 15 receives a notification signal from the signal processing unit 14, the notification unit 15 performs a notification operation by, for example, ringing a buzzer, and it is around that the temperature of the wiring apparatus 1 is higher than the allowable range. Inform the person.

  In addition, the physical quantity which the measurement part 16 measures is not limited to temperature, You may measure physical quantities other than temperature. In addition to the above-mentioned temperature measurement part 161, measurement part 16 may be provided with force measurement part 162 which measures the size of external force added to lock spring 140 (refer to Drawing 8). The force measuring unit 162 is, for example, a piezoelectric element using a piezo effect, and is attached to a portion of the central piece 141 of the lock spring 140 facing the leg piece 135. When the electric wire is connected to the terminal device 130, when the pressing piece 143 presses the electric wire, a reaction force is applied from the electric wire to the lock spring 140, and the central piece 141 is pressed against the leg piece 135 by this reaction force. The signal processing unit 14 can measure the external force applied from the electric wire to the lock spring 140 by periodically capturing the output of the force measurement unit 162. In a state where the electric wire is connected to the terminal device 130, the reaction force applied from the electric wire to the lock spring 140 is equal to the force with which the lock spring 140 presses the electric wire against the leg piece 136. Further, in a state where the electric wire is connected to the terminal device 130, current flows through the terminal plate 131 or the terminal plate 132 and the electric wire, and current flows between the terminal plate 131 or the terminal plate 132 and the lock spring 140. Absent. Therefore, by attaching the force measuring portion 162 to the lock spring 140, the force by which the lock spring 140 presses the electric wire against the leg piece 136 is used without affecting the current flowing through the terminal plate 131 or the terminal plate 132 and the electric wire. It can measure.

  When the signal processing unit 14 determines the external force applied to the lock spring 140 based on the output of the force measurement unit 162, the signal processing unit 14 compares the external force applied to the lock spring 140 with a preset allowable range. When the external force applied to the lock spring 140 is below the lower limit value of the allowable range, the signal processing unit 14 determines that the contact pressure between the terminal plate 131 or the terminal plate 132 and the electric wire is not sufficiently obtained. Output a notification signal. Further, when the external force applied to the lock spring 140 exceeds the upper limit value of the allowable range, the signal processing unit 14 determines that the contact pressure between the terminal plate 131 or the terminal plate 132 and the electric wire is excessive. Output a notification signal. In addition, although the force measurement part 162 is attached to the center piece 141, you may measure the external force which is attached to the press piece 143 and added to the press piece 143. FIG. In addition, if it is possible to affect the current flowing through the terminal plate 131 or the terminal plate 132 and the wire, the force measuring unit 162 is provided on the leg piece 136 and the force with which the wire is pressed against the leg piece 136 is directly It may be measured.

  The measuring unit 16 may measure the input current from the external power supply 2 as a physical quantity. As shown in FIG. 10, on the rear surface of the case 100, a Rogowski coil 160 as a current sensor is disposed around the through hole 108 into which the electric wire from the external power supply 2 is inserted. The measuring unit 16 measures the input current from the external power supply 2 based on the output of the Rogowski coil 160. The signal processing unit 14 periodically takes in the measurement result of the input current from the measurement unit 16 and compares the measurement result of the input current with the level of the preset allowable range. When the measurement result of the input current exceeds the allowable range, the signal processing unit 14 determines that an abnormal current exceeding the allowable range is flowing, and outputs a notification signal to the notification unit 15. As a result, it is possible to notify the surrounding person that an abnormal current is flowing in the wiring device 1. Note that the Rogowski coil 160 is disposed around the through hole 108 into which the electric wire from the electric device 3 is inserted, and the measuring unit 16 generates the load current flowing to the electric device 3 based on the output of the Rogowski coil 160. It may be measured. Since the Rogowski coil 160 is disposed around the through hole 108, it becomes less susceptible to the magnetic field generated by the current flowing through the electric path in the case 100, and the current can be measured more accurately.

  Further, in the wiring device of the present embodiment, as shown in FIG. 11, a blocking portion 150 which is switched on / off by the signal processing portion 14 is provided between the first connection portion 11 and the second connection portion 12. May be

  The blocking unit 150 includes a contact 151 provided on an electric path that electrically connects the first connection unit 11 and the second connection unit 12. The contact point 151 is, for example, a semiconductor power device such as a triac. In the normal state where the off control signal is not input from the signal processing unit 14, the blocking unit 150 turns on the contact 151, and turns off the contact 151 when the off control signal is input from the signal processing unit 14.

  The signal processing unit 14 outputs a notification signal to the notification unit 15 when the measurement result of the physical quantity (for example, temperature, external force applied to the lock spring 140, or current) measured by the measurement unit 16 deviates from the preset allowable range. And causes the notification unit 15 to perform a notification operation. When the signal processing unit 14 determines that the signal processing unit 14 is abnormal based on the measurement result of the measurement unit 16, the signal processing unit 14 outputs an off control signal to the blocking unit 150 and causes the blocking unit 150 to turn off the contact 151. Therefore, when the measurement result of the measurement unit 16 is out of the allowable range, the blocking unit 150 turns off the contact point 151. Therefore, when the use state of the wiring apparatus 1 becomes abnormal, the power supply to the electric device 3 is interrupted. can do.

  Next, a wiring system using the wiring device 1 of the present embodiment will be described with reference to FIG.

  The wiring system illustrated in FIG. 12 includes the wiring device 1 described above, a distribution board 400, a data collection device 410 installed inside the distribution board 400, a management device 420, and a display terminal 430. Although only one wiring device 1 is shown in FIG. 12, the wiring device 1 may be connected to a plurality of branch circuits, or a plurality of wiring devices 1 may be connected to one branch circuit. It is also good.

  The distribution board 400 includes a master breaker 401, a plurality of branch breakers 402, a current measuring instrument 403, a measuring unit 404, a primary interconnection breaker 405, and a data collection device 410 inside a cabinet (not shown). Is housed.

  A single-phase three-wire lead-in line (not shown) of the external power supply 2 is electrically connected to the primary side terminal of the master breaker 401. A plurality of branch breakers 402 are connected to the secondary side terminal of the main breaker 401 via conductive bars 406 that constitute single-phase three-wire conductive paths.

  A branch circuit for distributing power in a building is connected to the secondary side terminal of each branch breaker 402. The above-described wiring device 1 is connected to the branch circuit branched by the branch breaker 402.

  The current measuring device 403 separately measures the current flowing to each of the plurality of branch breakers 402. Further, voltage value information of the power supply voltage is input to the current measuring instrument 403 from the measuring unit 404. The current measuring device 403 calculates the power consumption in each branch circuit based on the current value flowing in each branch breaker 402 and the voltage value information of the power supply voltage.

  The measurement unit 404 collects the power consumption in each branch circuit from the current measuring device 403 and outputs the power consumption to the data acquisition device 410.

  The primary side terminal of the primary interconnection breaker 405 is electrically connected to the primary side terminal of the master breaker 401. The secondary side terminal of the primary interconnection breaker 405 is electrically connected to the distributed power supply 407. The distributed power supply 407 is a power supply (for example, a solar power generation device or the like) in which reverse power flow to the power system is allowed. The power generated by the distributed power source 407 is used in the building and may be reversely flowed to the power system.

  The data acquisition device 410 has a function of collecting the power consumption of each branch circuit from the measurement unit 404 and collecting the measurement value of the measurement unit 16 from the wiring device 1. The power consumption of each branch circuit collected from the measurement unit 404 is an instantaneous value, and the data collection device 410 obtains the amount of used power used in each branch circuit by integrating the power consumption of each branch circuit. You can also. The data collection device 410 sends the management device 420 the power consumption of each branch circuit collected from the measurement unit 404, the amount of power used by each branch circuit, the measurement result of the measurement unit 16 collected from the wiring device 1, and the like. Send. Data communication is performed between the data collection device 410 and the wiring device 1 or between the data collection device 410 and the management device 420 by wireless communication that does not require a license. As this type of communication method, for example, a specific low power wireless communication, a wireless communication method based on IEEE 802.15.1 which is a communication standard of IEEE (The Institute of Electrical and Electronics Engineers), a wireless according to IEEE 802.15.4 There is a communication method etc. The communication method between the data collection device 410 and the wiring device 1 and the communication method between the data collection device 410 and the management device 420 are not limited to the wireless communication method, and may be a wired LAN (Local Area Network) or the like. A wired communication method may be used. In addition, both of the wireless communication method and the wired communication method may be used for the communication method between the data collection device 410 and the wiring device 1 and the communication method between the data collection device 410 and the management device 420.

  Further, the data collection device 410 stores the wiring device 1 and the branch breaker 402 connected to the branch circuit to which the wiring device 1 is connected in association with each other. The branch breaker 402 has a branch breaker having a function of switching an internal contact from the on state to the off state when an off signal is input from the outside. If the data collection device 410 determines that the state of the wiring device 1 is abnormal based on the measurement results of the measurement unit 16 collected from the wiring device 1, the branch breaker 402 corresponding to the wiring device 1 outputs an off signal. And the branch breaker 402 may be turned off. Thereby, when the state of the wiring device 1 becomes abnormal, the power supply to the wiring device 1 can be stopped.

  The management device 420 is, for example, a controller for a home energy management system (HEMS). The management device 420 collects the measurement result by the measurement unit 16 of each wiring device 1 from the data collection device 410, and monitors the state of each wiring device 1 based on the measurement result. Also, the management device 420 collects power consumption of each branch circuit from the data collection device 410, and monitors or controls a device (not shown) compatible with HEMS based on the power consumption of each branch circuit. It is configured. The device corresponding to HEMS should just be a management object required in order to grasp supply and demand of energy. Such devices include, for example, lighting devices, electric devices such as air conditioners, devices using energy such as electric vehicles, devices generating energy such as solar power generation devices and fuel cells, power storage devices, and electric vehicles Devices that store energy such as In addition, the apparatus corresponding to HEMS is not limited to said apparatus. In addition, the data collection device 410 may have the function of the management device 420. In this case, the data collection device 410 having a controller function manages the supply and demand of energy in the building, and monitors or controls devices corresponding to the HEMS.

  The display terminal 430 has a display device such as a liquid crystal display, for example, and is installed at a predetermined place in a building. Based on the display data transmitted from the management device 420, the display terminal 430 determines the state of each wiring device 1, the amount of energy used in the building, and the amount of electricity used for each room or device (power consumption or power consumption) ) Etc. on the screen.

  As described above, the wiring device 1 of the present embodiment is held by the mounting frame 20 fixed to the peripheral portion of the hole 51 provided in the construction surface (the surface of the wall material 50), and the mounting frame 20 is used. A case 100 is provided which is attached to the construction surface with a portion thereof embedded in the hole 51. The case 100 holds the first connection portion 11, the second connection portion 12 and the contact device 13. The electric wire L1 from the external power supply 2 is electrically connected to the first connection portion 11, and the electric wire L2 from the electric device 3 is electrically connected to the second connection portion 12. The first connection portion 11 and the second connection portion 12 each include a terminal device 130 to which an electric wire is electrically connected. The contact device 13 is provided in the middle of an electric path electrically connecting the first connection portion 11 and the second connection portion 12. The wiring apparatus 1 includes a measurement unit 16 that measures a physical quantity in any of the inside of the case 100 and the surface of the case 100. Furthermore, as a component of the terminal device 130, the wire holding portion is formed of a material that deforms in response to a temperature change, and changes into a shape in which the contact pressure with the wire increases when the temperature reaches a specified temperature , A lock spring 140 or a pressing body 146).

  Thereby, in the wiring apparatus 1 such as a switch, it is possible to monitor the physical quantity of the object to be measured in either the inside of the case 100 or the surface of the case 100 from the measurement result of the measuring unit 16. Furthermore, when the contact pressure of the wire with respect to the terminal board 131 or the terminal board 132 becomes lower than a prescribed contact pressure due to the influence of wiring work during construction and vibration during use, the space between the terminal board 131 or 132 and the wire Contact resistance increases, and the Joule heat increases the temperature of the terminal device 130. When the temperature of the terminal device 130 becomes equal to or higher than a prescribed temperature due to Joule heat, the shape of the wire holding portion changes to a shape in which the contact pressure with the wire increases, so the space between the terminal plate 131 or 132 and the wire The contact resistance is reduced and the reliability of the electrical connection is improved.

  In the wiring device 1 of the present embodiment, the second connection portion 12 may be configured to be connected to a plug-in plug (not shown) provided in the electric wire from the electric device 3. In addition, a circuit configured to connect the electric device 3 to the external power supply 2 between the first connection portion 11 and the second connection portion 12 may be held inside the case 100.

  As a result, even in the wiring device 1 such as an outlet, it is possible to monitor the physical quantity either on the inside of the case 100 or on the surface of the case 100 from the measurement results of the measuring unit 16. Furthermore, when the contact pressure of the wire with respect to the terminal board 131 or the terminal board 132 becomes lower than a prescribed contact pressure due to the influence of wiring work during construction and vibration during use, the space between the terminal board 131 or 132 and the wire Contact resistance increases, and the Joule heat increases the temperature of the terminal device 130. When the temperature of the terminal device 130 becomes equal to or higher than a prescribed temperature due to Joule heat, the shape of the wire holding portion changes to a shape in which the contact pressure with the wire increases, so the space between the terminal plate 131 or 132 and the wire The contact resistance is reduced and the reliability of the electrical connection is improved.

  In the wiring device 1 of the present embodiment, the terminal device 130 preferably includes the terminal plates 131 and 132 and the lock spring 140 (spring body). The terminal plates 131 and 132 are formed in a U-shape. The lock spring 140 is disposed to fit in the U-shaped portion of the terminal board (the terminal board 131 or the terminal board 132), and electrically connects the terminal board and the electric wire by pressing the electric wire against the terminal board. It is also preferable that the wire holding portion includes terminal plates 131 and 132. The terminal plates 131 and 132 are formed of a material (for example, shape memory alloy) that deforms in response to a temperature change, and the internal size of the U-shaped portions on both sides of the lock spring 140 decreases when the temperature exceeds a specified temperature. Deform. If the contact pressure of the wire to the terminal plate 131 or 132 is lower than the prescribed contact pressure due to the influence of wiring work during construction or vibration during use, the space between the terminal plate 131 or 132 and the wire The contact resistance increases, and the temperature of the terminal device 130 rises due to Joule heat. When the temperature of the terminal device 130 becomes equal to or higher than the specified temperature due to Joule heat, the inner dimensions of the U-shaped portions on both sides of the lock spring 140 decrease, and the contact pressure between the terminal plate 131 or 132 and the electric wire increases. Become. When the contact pressure between the terminal plate 131 or the terminal plate 132 and the electric wire is increased, the contact resistance between the terminal plate 131 or the terminal plate 132 and the electric wire is reduced, so that the reliability of the electrical connection is improved.

  In the wiring device 1 of the present embodiment, the terminal device 130 preferably includes the terminal plates 131 and 132 and the lock spring 140, and the wire holding portion preferably includes the lock spring 140. The lock spring 140 is formed of a material (for example, a shape memory alloy) that deforms in response to a temperature change, and is deformed so that the distance from the terminal board (terminal board 131 or terminal board 132) becomes narrow when the temperature reaches a specified temperature. Do. If the contact pressure of the wire to the terminal plate 131 or 132 is lower than the prescribed contact pressure due to the influence of wiring work during construction or vibration during use, the space between the terminal plate 131 or 132 and the wire The contact resistance increases, and the temperature of the terminal device 130 rises due to Joule heat. When the temperature of the terminal device 130 becomes equal to or higher than a predetermined temperature due to Joule heat, the lock spring 140 is deformed so as to narrow the distance from the terminal plate (the terminal plate 131 or the terminal plate 132). The contact pressure between 132 and the wire increases. When the contact pressure between the terminal plate 131 or the terminal plate 132 and the electric wire is increased, the contact resistance between the terminal plate 131 or the terminal plate 132 and the electric wire is reduced, so that the reliability of the electrical connection is improved.

  In the wiring device 1 of the present embodiment, the terminal device 130 preferably also includes the terminal plates 131 and 132, the lock spring 140, and the pressing body 146. The pressing body 146 may be disposed on the side opposite to the electric wire 500 with respect to the lock spring 140 and between the terminal plate 131 or the terminal plate 132 and the lock spring 140. The wire holding portion includes a pressing body 146. The pressing body 146 is formed of a material (for example, shape memory alloy) that deforms in response to a temperature change. It is also preferable that the pressing body 146 is deformed so as to press the lock spring 140 in a direction approaching the electric wire 500 when the temperature exceeds a predetermined temperature. If the contact pressure of the wire to the terminal plate 131 or 132 is lower than the prescribed contact pressure due to the influence of wiring work during construction or vibration during use, the space between the terminal plate 131 or 132 and the wire The contact resistance increases, and the temperature of the terminal device 130 rises due to Joule heat. When the temperature of the terminal device 130 becomes equal to or higher than a prescribed temperature due to Joule heat, the pressing body 146 is deformed so as to press the lock spring 140 in the direction approaching the electric wire 500, so the contact between the terminal plate 131 or 132 and the electric wire 500 The pressure increases. When the contact pressure between the terminal plate 131 or the terminal plate 132 and the electric wire 500 is increased, the contact resistance between the terminal plate 131 or the terminal plate 132 and the electric wire 500 is reduced, so that the reliability of the electrical connection is improved.

  In the wiring device 1 of the present embodiment, the measuring unit 16 may be provided on the lock spring 140. Since the physical quantity related to the lock spring 140 can be measured by the measuring unit 16, it is possible to monitor the state of the lock spring 140 which brings the terminal board 131 or the terminal board 132 into contact with the electric wire based on this physical quantity.

  In the wiring device 1 of the present embodiment, the measurement unit 16 may include a force measurement unit 162 that measures the magnitude of the external force applied to the lock spring 140. Then, when the measurement result of the force measurement unit 162 is out of the allowable range, the signal processing unit 14 (determination unit) may determine that an abnormality occurs in the connection state of the electric wire.

  For example, when the electric wire is not sufficiently connected to the terminal device 130 at the time of construction, the contact pressure between the terminal plates 131 and 132 and the electric wire is insufficient, and the magnitude of the external force applied to the lock spring 140 falls below the lower limit of the allowable range. It will be. The signal processing unit 14 determines that an abnormality has occurred in the connection state of the electric wire when the magnitude of the external force applied to the lock spring 140 falls below the lower limit value of the allowable range, so that an initial construction failure can be found.

  Also, when the contact pressure between the terminal boards 131 and 132 and the electric wire falls below the specified value in the energized state, the contact resistance between the terminal boards 131 and 132 and the electric wire becomes large, and the terminal boards 131 and 132 and the electric wire Joule heat generated at the contact site of In the present embodiment, when the temperature of the terminal plates 131 and 132 becomes equal to or higher than a prescribed temperature due to Joule heat, the wire holding portion is deformed in such a shape that the contact pressure between the terminal plates 131 and 132 and the wires increases. As a result, the external force applied to the lock spring 140 is increased, and the magnitude of the external force applied to the lock spring 140 exceeds the upper limit of the allowable range, so that the signal processing unit 14 determines the electric wire based on the measurement result of the force measurement unit 162. It can be determined that the connection status of the is abnormal.

  When the contact pressure between the terminal plate 131 or 132 and the electric wire exceeds a specified value due to the deformation of the terminal plate 131, 132, the contact resistance between the terminal plate 131 or 132 and the electric wire decreases. Joule heat is reduced. As a result, when the temperature of the terminal plate 131, 132 falls below the prescribed temperature, the terminal plate 131, 132 returns to the state before deformation, but the contact pressure between the terminal plate 131 or 132 and the wire again becomes the prescribed value. If the temperature is below the temperature, the temperature of the terminal plates 131 and 132 becomes equal to or higher than the specified temperature due to Joule heat. When the temperature of the terminal plates 131 and 132 becomes equal to or higher than a predetermined temperature, the wire holding portion is deformed into a shape in which the contact pressure between the terminal plates 131 and 132 and the wires increases. Thereby, since the external force applied to the lock spring 140 exceeds the upper limit value of the allowable range, the signal processing unit 14 can determine that the connection state of the electric wire becomes abnormal again based on the measurement result of the force measurement unit 162. Here, the signal processing unit 14 may count the number of times it is determined that the connection state of the wire becomes abnormal based on the measurement result of the force measurement unit 162, and when the count value exceeds a predetermined threshold value, The notification unit 15 may be notified of the abnormal state.

  In the wiring device 1 of the present embodiment, the measurement unit 16 may include a force measurement unit 162 that measures the magnitude of the external force applied to the lock spring 140 and a temperature measurement unit 161 that measures the temperature of the terminal device 130. Then, when the measurement result of the temperature measurement unit 161 exceeds the temperature threshold after the measurement result of the force measurement unit 162 deviates from the allowable range, the signal processing unit 14 (judgment unit) has an abnormality in the connection state of the electric wire. It may be determined that

  When the contact pressure between the terminal boards 131 and 132 and the electric wire falls below the specified value in the energized state, the contact resistance between the terminal boards 131 and 132 and the electric wire becomes large, and the contact between the terminal boards 131 and 132 and the electric wire Joule heat generated at the site increases. When the temperature of the terminal boards 131 and 132 becomes equal to or higher than a prescribed temperature due to Joule heat, the wire holding portion is deformed into a shape in which the contact pressure between the terminal boards 131 and 132 and the wires increases. As a result, the external force applied to the lock spring 140 increases, and the magnitude of the external force applied to the lock spring 140 exceeds the upper limit of the allowable range, so that the signal processing unit 14 causes the measurement result of the force measurement unit 162 to deviate from the allowable range. To detect Here, even if the wire holding portion is deformed, the contact pressure between the terminal plates 131 and 132 and the wires can not be sufficiently obtained, and the contact resistance between the terminal plates 131 and 132 and the wires increases more than usual. The Joule heat generated at the contact portion between the terminal plates 131 and 132 and the wires increases. Therefore, since the measurement result of the temperature measurement unit 161 exceeds the threshold of temperature after the measurement result of the force measurement unit 162 deviates from the allowable range, the signal processing unit 14 (judgment unit) has an abnormal connection state of the electric wire. It can detect that there is.

  In the wiring device 1 of the present embodiment, when the determination unit (the signal processing unit 14) determines that it is abnormal, the notification unit 15 may be provided to notify occurrence of an abnormality. The notification unit 15 can notify the user that an abnormality has occurred.

  In the wiring device 1 of the present embodiment, even when the determination unit (the signal processing unit 14) determines that there is an abnormality, the cutoff unit 150 that electrically isolates the first connection unit 11 and the second connection unit 12 is provided. Good. If the determination unit determines that there is an abnormality, the blocking unit 150 electrically disconnects between the first connection unit 11 and the second connection unit 12, whereby the connection between the first connection unit 11 and the second connection unit 12 is performed. Since no current flows, the wiring apparatus 1 can be protected, and the safety is improved.

  The wiring apparatus 1 of the present embodiment may include a transmission unit (communication unit 18) that transmits the measurement result of the measurement unit 16 to an external device. The transmitting unit transmits the measurement result of the measuring unit 16 to an external device, so that the state of the wiring apparatus 1 can be monitored by the external device.

  In addition, the wiring system of the present embodiment is characterized by including the above-described wiring device 1, a data collection device 410, and a management device 420. The data acquisition device 410 is installed on the distribution board 400 that distributes power to the branch circuit to which the wiring device 1 is connected, and collects the measurement results of the measurement unit 16 transmitted from the transmission unit (communication unit 18). The management device 420 receives the measurement result of the measurement unit 16 collected by the data collection device 410 from the data collection device 410, and manages the measurement result of the measurement unit 16.

  As a result, the data collection device 410 can collect the measurement results of the measurement unit 16 from the plurality of wiring devices 1 and manage the measurement results by the management device 420.

  In the wiring system of the present embodiment, the data collection device 410 may store the wiring device 1 and the branch switch connected to the branch circuit to which the wiring device 1 is connected in association. The data collection device 410 is configured to turn off the branch breaker 402 associated with the wiring device 1 based on the measurement result of the measurement unit 16 transmitted from the transmission unit (communication unit 18) of the wiring device 1 It is also good. For example, the data collection device 410 turns off the branch breaker 402 corresponding to the wiring device 1 when judging that an abnormality has occurred in the wiring device 1 based on the measurement result of the measurement unit 16 transmitted from the wiring device 1. Make it Thereby, the data acquisition device 410 can shut off the power supply to the wiring device 1 to improve the safety.

DESCRIPTION OF SYMBOLS 1 Wiring apparatus 2 External power supply 3 Electrical equipment 11 1st connection part 12 2nd connection part 13 Contact device 14 Signal processing part (judgement part)
15 notification unit 16 measurement unit 18 communication unit (transmission unit)
20 mounting frame 50 wall material (construction surface)
51 hole 100 case 108 through hole 130 terminal device 131, 132 terminal plate (electric wire holding portion)
140 Lock spring (spring, wire holder)
146 Press body (electric wire holding part)
150 breaker 160 Rogowski coil (current sensor)
161 temperature measurement unit 162 force measurement unit 400 distribution board 402 branch breaker 410 data acquisition device 420 management device L1, L2 electric wire

Claims (7)

A wiring device, a data acquisition device, and a management device;
The wiring device
A case attached to the construction surface,
A terminal device held by the case and connected to an electric wire introduced into the case from the outside of the case;
A measurement unit that measures the temperature of the terminal device;
A notification unit that performs a notification operation when the measured temperature of the measurement unit becomes higher than an allowable range ;
And a transmitter configured to transmit the measurement result of the measurement unit to an external device.
The data collection device is installed on a distribution board that distributes power to a branch circuit to which the wiring device is connected, and collects the measurement results of the measurement unit transmitted from the transmission unit.
The management device receives the measurement result of the measurement unit collected by the data collection device from the data collection device, and manages the measurement result of the measurement unit.
Wiring system characterized by   It is the said wiring apparatus with which the said wiring system of Claim 1 is provided, Comprising:
  The wiring apparatus, wherein the transmission unit transmits the measurement result of the measurement unit to the data collection device.   The terminal device includes a terminal board, and a spring for electrically connecting the terminal board and the electric wire by pressing the electric wire against the terminal board.
  The wiring device according to claim 2, wherein the measurement unit measures a temperature at at least one of the terminal plate, the spring body, and the case.   A plurality of the terminal devices,
  The case includes a first connection portion to which a wire from an external power supply is electrically connected, a second connection portion to which a wire from an electric device is electrically connected, the first connection portion, and the second connection portion. A contact device provided in the middle of the electric path electrically connecting the connection portion is further held,
  The wiring device according to claim 2, wherein the first connection portion and the second connection portion each include the terminal device.   A plurality of the terminal devices,
  In the case, a first connection portion to which a wire from an external power source is electrically connected, a second connection portion to which a plug provided on a wire from an electric device is connected, and the first connection portion And a circuit electrically connecting the second connection portion to the second connection portion,
  The wiring device according to claim 2, wherein the first connection portion includes the terminal device.   6. The apparatus according to claim 4 or 5, further comprising: a shutoff unit that electrically shuts off the first connection unit and the second connection unit when the measurement temperature of the measurement unit becomes higher than the allowable range. Wiring device as described.   The data collection device associates and stores the wiring device and a branch breaker connected to a branch circuit to which the wiring device is connected, and the measurement of the measurement unit transmitted from the transmission unit of the wiring device The wiring system according to claim 1, characterized in that the branch breaker associated with the wiring device is turned off based on the result.

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