JP6698452B2 - Wiring device for electricity meter - Google Patents

Description

  The present invention relates to a wire meter for an electric energy meter, which facilitates connection between an external terminal of the electric energy meter and a terminal on the side where the performance test is performed in a performance test of the electric energy meter.

  In a performance test for inspecting whether a conventional watt-hour meter satisfies a predetermined standard, it is necessary to connect a product and a test device to supply electric power to the product during the test. Since the outer size of the product and the terminal position of the watt hour meter differ depending on the model, in order to efficiently carry out such wiring work, it is necessary to provide a wire connector that can easily handle many types of products. There is.

  As such a wire connector, for example, one described in Patent Document 1 is known. This conventional wire connector has terminals that are slidably attached to the wire receiver cradle to the left and right. During the performance test, slide this terminal to the left and right according to the type of each watt-hour meter, and then connect it to the watt-hour meter terminal.

  However, in the wire connection device described in Patent Document 1, each terminal can be slid in one direction in the left-right direction, but it is difficult to adjust the position of the terminal in the front-back direction. That is, the terminals of the watt hour meter may be different in two directions such as front, rear, left and right depending on the type, so it is desirable that the terminals of the wire connector be adjusted in two directions such as front, rear, left and right.

  As another wire connection device, for example, one described in Patent Document 2 is known. This wire connector has terminals that are slidably attached to the left and right of the wire receiver pedestal, and the pedestal itself is slidably attached to the fixed frame of the wire connector in the front-rear direction. .. Each terminal is positioned in the left-right and front-back directions by a positioning block fixed to the wire connector. As a result, it is possible to connect the terminals according to the terminal positions that differ depending on the type of watt-hour meter.

JP 2001-235527 A JP, 2008-185402, A

  The conventional watt-hour meter wiring device has a structure in which the terminals can be adjusted independently for different terminal positions in two directions depending on the type of watt-hour meter, and the positioning block can be replaced to adjust the terminal position. Is being carried out. Therefore, changing the terminal position may require replacement of the positioning block, and may require visual adjustment by the operator when positioning the terminal in the engaging recess of the positioning block. There was a problem that it was difficult to replace.

  The present invention has been made to solve the above problems, and easily sets the position of each terminal and connects to various types of watt hour meters having different positions of external terminals in two directions. An object of the present invention is to provide a wire connector for an electric energy meter that can be used.

The power meter wire connection device of the present invention is
In a watt hour wire connecting device connected to each of the external terminals of the watt hour meter having a plurality of external terminals,
A fixed frame,
A direction along any one of the fixed frames is a left-right direction, a direction orthogonal to the left-right direction is a front-rear direction, and a direction orthogonal to both the left-right direction and the front-rear direction is a vertical direction,
A first cam portion fixed to the fixed frame;
A second cam portion fixed to the fixed frame and arranged below the first cam portion;
A terminal unit having a plurality of terminals connected to the plurality of external terminals of the electricity meter,
The first cam portion has a plate-shaped first cam plate that is movable in the left-right direction with respect to the fixed frame,
The first cam plate is provided with a first cam groove, the position of which in the front-rear direction is changed in the left-right direction, and the terminal portion being movably along a side surface and engaged from below,
The second cam portion has a plate-shaped second cam plate movable in the front-rear direction with respect to the fixed frame,
The second cam plate has a plurality of second cam grooves in which the plurality of terminals of the terminal portion are engaged one by one from below so as to be movable along a side surface,
In the front-rear direction, the plurality of second cam grooves have portions where the intervals between the second cam grooves in the left-right direction are different from each other .

According to the electric power meter wiring device of the present invention,
The position of each terminal can be easily set and connected to various types of watt-hour meters having different positions of the external terminals in two directions.

It is a perspective view which shows the structure of the wire connection device for electric energy meters of Embodiment 1 of this invention. It is a perspective view which shows the structure of the connection part of the wire connection device for electric energy meters shown in FIG. 1 from a lower side to an upper side. It is a perspective view which shows the structure of the 1st cam part of the connection part shown in FIG. 2 from the right rear side. It is a perspective view which shows the structure of the 2nd cam part of the connection part shown in FIG. 2 from the right rear side. It is a perspective view which shows the structure of the terminal part of the connection part shown in FIG. 2 from the front right side. It is a perspective view which shows the structure of each terminal of the terminal part shown in FIG. 5 from the front right side. It is a top view which shows the structure of the 1st cam plate of the 1st cam part shown in FIG. It is a top view which shows the structure of the 2nd cam plate of the 2nd cam part shown in FIG. It is a perspective view which shows the 1st state of the connection part shown in FIG. It is a perspective view which shows the 2nd state of the connection part shown in FIG. It is a perspective view which shows the 3rd state of the connection part shown in FIG. It is a perspective view which shows the 4th state of the connection part shown in FIG.

Embodiment 1.
Hereinafter, embodiments of the present invention will be described. First Embodiment FIG. 1 is a perspective view showing the configuration of a power meter wire connector according to a first embodiment of the present invention. FIG. 1 shows a state in which the watt-hour meter is installed in the watt-hour meter wiring device. FIG. 2 is a perspective view showing the configuration of the wire connection portion of the wire connecting device for an electric energy meter shown in FIG. 1 from the lower side Z2 to the upper side Z1. The connection part in FIG. 2 shows the part excluding the lower fixed frame, the moving frame, and the support shaft. FIG. 3 is a perspective view showing the configuration of the first cam portion of the connection portion shown in FIG. 2 from the right rear side.

  FIG. 4 is a perspective view showing the configuration of the second cam portion of the wire connection portion shown in FIG. 2 from the right rear side. FIG. 5 is a perspective view showing the configuration of the terminal portion of the connection portion shown in FIG. 2 from the front right side. FIG. 6 is a perspective view showing the configuration of each terminal of the terminal portion shown in FIG. FIG. 7 is a plan view showing the configuration of the first cam plate of the first cam portion shown in FIG. FIG. 8 is a plan view showing the configuration of the second cam plate of the second cam portion shown in FIG. 9 to 12 are perspective views showing the first to fourth states of the wire connection portion shown in FIG.

  In FIG. 1, a wire meter 100 for an electric energy meter according to Embodiment 1 of the present invention includes a fixed frame 6, a moving frame 3, and a wire connection portion 10. The fixed frame 6 is formed by fixing the lower fixed frame 1 and the upper fixed frame 2 to the support shaft 4. The movable frame 3 is installed between the lower fixed frame 1 and the upper fixed frame 2 so as to be movable in the vertical direction Z with the support shaft 4 as a guide. The wire connection portion 10 is fixed to the lower Z2 surface of the upper fixed frame 2. The watt-hour meter 5 is arranged on the surface of the upper side Z1 of the moving frame 3. When the moving frame 3 is moved to the upper side Z<b>1, the electric energy meter wiring device 100 connects the electric power meter 5 arranged on the moving frame 3 to a terminal 68 of the wiring portion 10 described later.

  In FIG. 2, the wire connection portion 10 includes a first cam portion 20, a second cam portion 40, and a terminal portion 60. Therefore, the wire connection portion 10 refers to a portion excluding the lower fixed frame 1, the moving frame 3, and the support shaft 4 from the power meter wire connector 100. The first cam portion 20, the second cam portion 40, and the terminal portion 60 are sequentially arranged from the upper side Z1 of the upper fixed frame 2 toward the lower side Z2.

  In FIG. 3, the first cam portion 20 includes four first shaft holders 21, two first shafts 22, two first guide blocks 23, and a first cam plate 24. The four first shaft holders 21 are fixed to the front side Y1 and the rear side Y2 of the left side X1 and the right side X2 of the surface of the lower side Z2 of the upper fixed frame 2, respectively. Both ends of the two first shafts 22 are held by the first shaft holder 21 and are arranged parallel to the left-right direction X of the upper fixed frame 2.

  The two first guide blocks 23 are arranged between the first shaft holders 21 so as to be movable in the left-right direction X using the respective first shafts 22 as guides. The two first guide blocks 23 are fixed to the first cam plate 24 at the center position in the left-right direction X. Therefore, the first cam plate 24 of the first cam portion 20 is held by the first shaft holder 21, and the first guide block 23 moves linearly with respect to the first shaft 22 in the left-right direction X as a guide. It is configured to be movable in the left-right direction X with respect to the fixed frame 6.

  In FIG. 4, the second cam portion 40 includes four second shaft holders 41, two second shafts 42, four second guide blocks 43, and a second cam plate 44. The four second shaft holders 41 are fixed to the left side X1 and the right side X2 of the front side Y1 and the rear side Y2 of the surface of the lower side Z2 of the upper fixed frame 2, respectively. Both ends of the two second shafts 42 are held by the second shaft holder 41, and are arranged parallel to the front-rear direction Y of the upper fixed frame 2.

  The four second guide blocks 43 are movable in the front-rear direction Y by using each second shaft 42 as a guide, and one second guide block 43 is arranged between the second shaft holders 41 with respect to one second shaft 42. Further, the other second guide block 43 is arranged on the rear side Y2 (outside) of the second shaft holder 41. The first connecting plate 45 is fixed across the second guide blocks 43 formed between the second shaft holders 41 so as to connect in the left-right direction X.

  The third pin 46 is fixed to the central portion of the upper side Z1 of the first connecting plate 45 so as to project to the upper side Z1. The third pin 46 engages with a third cam groove 25 of the first cam plate 24, which will be described later. The four second guide blocks 43 are fixed to the second cam plate 44 at four corners in the front-rear direction Y and the left-right direction X. Therefore, the second cam plate 44 of the second cam portion 40 is held by the second shaft holder 41, and the linear motion of the second guide block 43 moving in the front-rear direction Y with respect to the second shaft 42 is used as a guide. It is configured to be movable in the front-rear direction Y with respect to the fixed frame 6.

  The configuration of the terminal portion 60 will be described with reference to FIGS. 5 and 6. In FIG. 5, the same parts as the second shaft holder 41 and the second shaft 42 described for the second cam portion 40 are shown for clarifying the positional relationship. However, the second cam plate 44 is omitted. The terminal portion 60 includes two third guide blocks 61, six terminal blocks 66, two third shaft holders 64, and two third shafts 65.

  The two third guide blocks 61 are arranged between the second shaft holders 41 so as to be movable in the front-rear direction Y using the two second shafts 42 as guides. The second connecting plate 62 is fixed so as to straddle the two third guide blocks 61 in the left-right direction X. The first pin 63 is fixed to the center of the upper side Z1 of the second connecting plate 62 so as to project to the upper side Z1. The first pin 63 engages with the first cam groove 30 of the first cam plate 24, which will be described later. The two third shaft holders 64 are fixed to the outer side surfaces of the left side X1 and the right side X2 of each third guide block 61 so as to project to the lower side Z2.

  The two third shafts 65 are disposed so as to penetrate the six terminal blocks 66 so as to connect in the left-right direction X. The two third shafts 65 are held and fixed to both ends of the two third guide blocks 61 in the left-right direction X via third shaft holders 64. The six terminal blocks 66 are arranged between the third shaft holders 64 so as to be independently movable in the left-right direction X using the two third shafts 65 as guides. Each of the six terminal blocks 66 includes a second pin 67 protruding and fixed to the upper side Z1 and a terminal 68 protruding and fixed to the lower side Z2.

  The second pin 67 engages with second cam grooves 51, 52, 53, 54, 55, 56 of the second cam plate 44 described later, respectively. Therefore, each terminal 68 of the terminal portion 60 is moved in the front-rear direction Y by using the linear motion of the third guide block 61 moving in the front-rear direction Y with respect to the second shaft 42 held by the second shaft holder 41. Moving. Furthermore, each terminal 68 of the terminal portion 60 moves independently in the left-right direction X using the movement of the terminal block 66 in the left-right direction X with respect to the third shaft 65 held by the third shaft holder 64 as a guide. Configured to be possible.

  In FIG. 7, the first cam plate 24 of the first cam portion 20 will be described. The first cam plate 24 includes a first cam groove 30 and a third cam groove 25. The first cam groove 30 and the third cam groove 25 extend in the left-right direction X and are formed at different positions in the front-rear direction Y, here, inclined in the front-rear direction Y. The first cam groove 30 is formed with a first flat portion 26, a second flat portion 27, a third flat portion 28, and a fourth flat portion 29 as flat portions having side surfaces parallel to the left-right direction X, and connects these. It is composed of

  The first flat portion 26 is arranged on the front side Y1 of the first cam plate 24. The second flat portion 27 is arranged on the rear side Y2 of the first flat portion 26. The third flat portion 28 is arranged on the rear side Y2 with respect to the second flat portion 27. The fourth flat portion 29 is arranged on the rear side Y2 with respect to the third flat portion 28. The third cam groove 25 is arranged on the front side Y1 of the first cam groove 30 so as to have a shape that is the front-back inversion of the first cam groove 30. Incidentally, each flat portion 26 to 29 is shown by a dotted line so that its positional relationship becomes clear. Also in each of the following flat portions, the same is indicated by the dotted line in the drawing, and thus the description thereof will be appropriately omitted.

  The first flat portion 26, the second flat portion 27, the third flat portion 28, and the fourth flat portion 29 are also formed in the third cam groove 25 at the same position as the first cam groove 30 in the left-right direction X. The third pin 46 of the second cam portion 40 engages with the third cam groove 25. The first pin 63 of the terminal portion 60 engages with the first cam groove 30. Therefore, the first cam plate 24 configures the first cam groove 30 and the third cam groove 25 as described above to drive the second cam portion 40 and the terminal portion 60 in the front-rear direction Y in synchronization with each other. ..

In FIG. 8, the second cam plate 44 of the second cam portion 40 will be described. The second cam plate 44 is formed with a plurality of six second cam grooves 51, 52, 53, 54, 55, 56 extending in the front-rear direction Y here. Since the six second pins 67 shown above are engaged, the same number of six second cam grooves 51, 52, 53, 54, 55, 56 are formed.
The second cam groove 51 is formed on the leftmost side X1. The second cam groove 52 is formed on the right side X2 of the second cam groove 51. The second cam groove 53 is formed on the right side X2 of the second cam groove 52. A second cam groove 54 is formed on the right side X2 of the second cam groove 53. A second cam groove 55 is formed on the right side X2 of the second cam groove 54. The second cam groove 56 is formed on the right side X2 of the second cam groove 55.

  In the second cam groove 51, a first flat portion 47, a second flat portion 48, a third flat portion 49, and a fourth flat portion 50 are formed as flat portions having side surfaces parallel to the front-rear direction Y. It is formed by connecting these. The first flat portion 47 is arranged on the rear side Y2 of the second cam plate 44. The second flat portion 48 is arranged on the front side Y1 with respect to the first flat portion 47. The third flat portion 49 is arranged on the front side Y1 with respect to the second flat portion 48. The fourth flat portion 50 is arranged on the front side Y1 with respect to the third flat portion 49. The first flat portion 47, the second flat portion 48, the third flat portion 49, and the fourth flat portion 50 are also formed in the other second cam grooves 52, 53, 54, 55, 56 in the front-back direction Y. It is formed at the same position as the cam groove 51.

  The distance between the second cam grooves 51, 52, 53, 54, 55, 56 in the left-right direction X is set particularly in the first flat portion 47, the second flat portion 48, the third flat portion 49, and the fourth flat portion 50. It is formed at different points in the corresponding front-back direction Y. Therefore, the second cam plate 44 is configured with the six second cam grooves 51, 52, 53, 54, 55, 56, and the six second pins 67 are engaged with these, so that the six The second cam grooves 51, 52, 53, 54, 55, and 56 are driven along the shape, that is, the six terminals 68 are engaged and driven in the left-right direction X.

  Next, the operation of the electric energy meter wiring device 100 of the first embodiment configured as described above will be described based on FIGS. 9 to 12. First, FIG. 9 shows a first state as one state of the wire connection device for an electric energy meter according to the first embodiment of the present invention. In this first state, the third pin 46 of the second cam portion 40 engages at the position of the first flat portion 26 of the third cam groove 25 formed in the first cam plate 24 of the first cam portion 20. ing. Similarly, the first pin 63 of the terminal portion 60 is engaged with the first flat portion 26 of the first cam groove 30 formed in the first cam plate 24 of the first cam portion 20. Thereby, the positions of the second cam portion 40 and the terminal portion 60 in the front-rear direction Y are determined.

  In the first state, the second pin 67 of each terminal block 66 of the terminal portion 60 has a second cam groove 51 to a second cam groove 56 formed in the second cam plate 44 of the second cam portion 40. It is engaged at the position of one flat portion 47. As a result, the position of each terminal block 66 in the left-right direction X is determined. That is, the position of each terminal 68 in the left-right direction X is determined as the position of the first flat portion 47.

  Next, from the first state shown in FIG. 9, the first cam plate 24 of the first cam portion 20 is moved in the leftward X1 direction, and the second cam plate 44 of the second cam portion 40 is moved in the rearward Y2 direction. By moving to, the state is changed to the second state shown in FIG. When the first cam plate 24 is moved in the left direction X1 from the first state shown in FIG. 9, it is engaged with the first flat portion 26 of the third cam groove 25 of the first cam plate 24. The third pin 46 of the second cam portion 40 moves from the first flat portion 26 of the third cam groove 25 to the position of the second flat portion 27. As a result, the second cam portion 40 is in the second state of the position moved to the rear side Y2 from the first state.

  Similarly, the first pin 63 of the terminal portion 60 engaged with the first flat portion 26 of the first cam groove 30 has a position from the first flat portion 26 to the second flat portion 27 of the first cam groove 30. Move to. As a result, the terminal portion 60 is in the second state in which the terminal portion 60 is moved in the front Y1 direction from the first state. When the second cam portion 40 moves to the rear side Y2 and the terminal portion 60 moves to the front side Y1, the second cam groove 51 of the second cam plate 44 engages with the first flat portion 47 of the second cam groove 56. Each second pin 67 present moves from the second cam groove 51 to the position of the first flat portion 47 of the second cam groove 56 to the second flat portion 48.

  As a result, each terminal 68 of the terminal portion 60 is in the second state in which it is moved in the left-right direction X with respect to the first state. As described above, the position of each terminal 68 from the first state to the second state is changed to the front side Y1 determined by the second flat portion 27 of the first cam groove 30 of the first cam plate 24 of the first cam portion 20. Then, in the left-right direction X, the position is changed from the second cam groove 51 of the second cam plate 44 of the second cam portion 40 to the position determined by the second flat portion 48 of the second cam groove 56.

  Next, from the second state shown in FIG. 10, the first cam plate 24 of the first cam portion 20 is moved in the leftward X1 direction, and the second cam plate 44 of the second cam portion 40 is moved in the rearward Y2 direction. By moving to, the state is changed to the third state shown in FIG. When the first cam plate 24 is moved in the leftward direction X1 from the second state shown in FIG. 10, it is engaged with the second flat portion 27 of the third cam groove 25 of the first cam plate 24. The third pin 46 of the second cam portion 40 moves from the second flat portion 27 of the third cam groove 25 to the position of the third flat portion 28. As a result, the second cam portion 40 is in the third state at the position moved to the rear side Y2 from the second state.

  Similarly, the first pin 63 of the terminal portion 60 engaged with the second flat portion 27 of the first cam groove 30 is located at the position from the second flat portion 27 to the third flat portion 28 of the first cam groove 30. Move to. As a result, the terminal portion 60 is in the third state in which the terminal portion 60 has moved in the front Y1 direction from the second state. When the second cam portion 40 moves to the rear side Y2 and the terminal portion 60 moves to the front side Y1, the second cam portion engages with the second cam groove 51 of the second cam plate 44 at the second flat portion 48 of the second cam groove 56. Each of the second pins 67 moving from the second cam groove 51 to the position of the second flat portion 48 of the second cam groove 56 to the third flat portion 49.

  As a result, each terminal 68 of the terminal portion 60 is in the third state of the position moved in the left-right direction X with respect to the second state. From the above, the position of each terminal 68 from the second state to the third state is changed to the front side Y1 determined by the third flat portion 28 of the first cam groove 30 of the first cam plate 24 of the first cam portion 20. In the left-right direction X, the position is changed from the second cam groove 51 of the second cam plate 44 of the second cam portion 40 to the position determined by the third flat portion 49 of the second cam groove 56.

  Next, from the third state shown in FIG. 11, the first cam plate 24 of the first cam portion 20 is moved in the leftward X1 direction, and the second cam plate 44 of the second cam portion 40 is moved in the rearward Y2 direction. By moving to, the state is changed to the fourth state shown in FIG. When the first cam plate 24 is moved in the left direction X1 from the second state shown in FIG. 11, the third flat portion 28 of the third cam groove 25 of the first cam plate 24 is engaged. The third pin 46 of the second cam portion 40 moves from the third flat portion 28 of the third cam groove 25 to the position of the fourth flat portion 29. As a result, the second cam portion 40 enters the fourth state, which is the position moved to the rear side Y2 from the third state.

  Similarly, the first pin 63 of the terminal portion 60 engaged with the third flat portion 28 of the first cam groove 30 is located at the position from the third flat portion 28 to the fourth flat portion 29 of the first cam groove 30. Move to. As a result, the terminal portion 60 is in the fourth state in which the terminal portion 60 is moved in the front Y1 direction from the second state. When the second cam portion 40 moves to the rear side Y2 and the terminal portion 60 moves to the front side Y1, the second cam groove 44 of the second cam plate 44 engages with the third flat portion 49 of the second cam groove 56. Each of the second pins 67 moving from the second cam groove 51 to the position of the fourth flat portion 50 from the third flat portion 49 of the second cam groove 56.

  As a result, each terminal 68 of the terminal portion 60 is in the fourth state, which is a position moved in the left-right direction X with respect to the third state. From the above, the position of each terminal 68 from the third state to the fourth state is changed to the front side Y1 determined by the fourth flat portion 29 of the first cam groove 30 of the first cam plate 24 of the first cam portion 20. Then, in the left-right direction X, the position is changed from the second cam groove 51 of the second cam plate 44 of the second cam portion 40 to the position determined by the fourth flat portion 50 of the second cam groove 56.

  Then, the position of each terminal 68 from the first state to the fourth state can be set. Then, the watt-hour meter 5 corresponding to any one of the first state to the fourth state is placed on the upper side Z1 of the moving frame 3 so that each external terminal of the watt-hour meter 5 faces each terminal 68 in the vertical direction Z. Place on. Then, the movable frame 3 is moved in the direction of the upper side Z1 with respect to the fixed frame 6 to connect the external terminal and the terminal 68. It is also possible to move the terminal 68 to the corresponding state from the first state to the fourth state shown above with the watt-hour meter 5 previously placed on the upper side Z1 of the moving frame 3. ..

  In the first embodiment described above, the positions of the first cam plate and the second cam plate, and the positions of the first pin and the second pin are set in the respective flat portions, so that the position of each terminal is set to the first position. An example of setting from one state to the fourth state has been shown, but this is because it is easier to automatically control the position at that location when the first cam groove and the second cam groove are flat portions. Is. Therefore, it is not limited to this, and the position of each terminal can be set even at a place other than the flat portions of the first cam groove and the second cam groove.

  As in the first embodiment, the first cam plate is moved in the left-right direction to drive the terminal portion engaging with the first cam groove of the first cam plate in the front-rear direction. The lateral drive of each terminal engaging with the second cam groove of the plate is performed. That is, the front-back direction and the left-right direction of each terminal can be simultaneously positioned only by driving the first cam plate. Further, since this can be performed by a simple linear motion of the first cam plate, the automation of the motion is easy and the setup work efficiency can be realized. Therefore, it becomes easy to perform the performance test on the different types of watt-hour meters fully automatically.

  Further, the first cam groove having different positions in the front-rear direction and the plurality of second cam grooves having second position of the second cam grooves in the left-right direction differ from each other in the front-rear direction and the left-right direction. Since the positioning is performed, it is possible to change the position of each terminal of the wire connector for a watt hour meter in correspondence with various watt hour meters having external terminals having different positions in the front-rear direction and the left-right direction.

  Further, a third cam groove extending in the left-right direction and having different portions in the front-rear direction is formed in the first cam plate, the second cam plate is formed so as to be movable in the front-rear direction with respect to the fixed frame, and Since it engages with the third cam groove of the first cam plate, the second cam plate can move in the front-rear direction following the movement of the first cam plate in the left-right direction, which facilitates position control.

  Further, the position of each terminal can be easily set to any position in the front-rear direction and the left-right direction by changing the shapes of the first cam groove and the second cam groove.

  Further, since the first cam groove of the first cam plate is formed with a flat portion having a side surface parallel to the left-right direction at least at two or more locations, it is easy to control the position using this flat portion.

  Further, since the second cam groove of the second cam plate is formed with the flat portion having the side surface parallel to the front-rear direction at least at two or more locations, it is easy to control the position using the flat portion.

  In the first embodiment, an example in which four independent flat portions are formed on each of the first cam plate 24 of the first cam portion 20 and the second cam plate 44 of the second cam portion 40 is shown. However, the number is not limited to this, and the number of flat portions may be at least two or more. For example, if six independent flat portions are formed, the positions of the terminals can be controlled and used with good control, as in the first embodiment, with respect to six types of watthour meters having different terminal connection positions. it can.

Embodiment 2.
In the first embodiment described above, the second cam plate 44 of the second cam portion 40 has a structure that is movable in the front-rear direction, but the present invention is not limited to this, and the second cam plate 44 can be attached to the fixed frame. It may be a fixed structure. In this case, the first cam plate 24 of the first cam portion 20 does not need to be engaged with the third pin 46 of the second cam portion 40. The third pin 46 of the second cam portion 40 becomes unnecessary.

  If the wire connecting device for the electric energy meter in the second embodiment is configured as described above, the same effects as those in the first embodiment can be obtained, and the terminal configuration can be achieved at a lower cost than the first embodiment. It becomes possible to deal with a change in position. In addition, the position of the first cam plate can be controlled only by controlling the linear motion, and the automation can be further facilitated, and the setup work can be further efficient.

  As described above, the first cam groove of the first cam plate and the second cam groove of the second cam plate shown in the first embodiment are examples, and along the first cam groove of the first cam plate, The second cam plate is configured to move, the positioning in the front-back direction is performed, and the second cam plate is operated by the first cam plate, so that each terminal has the second cam groove as in the first embodiment. It suffices to be able to perform the positioning in the left-right direction along the.

  Further, the amount of movement in the front-rear direction can be determined by adjusting the amount of movement of the second cam plate by the amount of movement of the first cam plate depending on the shape of the first cam groove of the first cam plate. Further, the shape of the second cam groove of the second cam plate makes it possible to adjust the amount of movement of each terminal in the horizontal direction by the amount of movement of the second cam plate. Therefore, by changing the shapes of the first cam groove of the first cam plate and the second cam groove of the second cam plate and the number of the second cam grooves, it is possible to cope with various positions of the external terminals of the electricity meter. It will be possible.

  In the present invention, the respective embodiments can be freely combined, or the respective embodiments can be appropriately modified or omitted within the scope of the invention.

1 lower fixed frame, 2 upper fixed frame, 3 movable frame, 4 support shaft,
5 electricity meter, 6 fixed frame, 10 connection part, 20 first cam part,
21 first shaft holder, 22 first shaft, 23 first guide block,
24 first cam plate, 25 third cam groove, 26 first flat portion, 27 second flat portion,
28 3rd flat part, 29 4th flat part, 30 1st cam groove, 40 2nd cam part,
41 second shaft holder, 42 second shaft, 43 second guide block,
44 second cam plate, 45 first connecting plate, 46 third pin, 47 first flat portion,
48 second flat portion, 49 third flat portion, 50 fourth flat portion, 51 second cam groove,
52 second cam groove, 53 second cam groove, 54 second cam groove, 55 second cam groove,
56 second cam groove, 60 terminal portion, 61 third guide block, 62 second connecting plate,
63 first pin, 64 third shaft holder, 65 third shaft,
66 terminal block, 67 second pin, 68 terminal, 100 wattmeter connector,
X left/right direction, X1 left side, X2 right side, Y front/rear direction, Y1 front side, Y2 rear side,
Z vertical direction, Z1 upper side, Z2 lower side.

Claims (5)

In a watt hour wire connector that is connected to each of the external terminals of a watt hour meter having a plurality of external terminals,
A fixed frame ,
A direction along any one of the fixed frames is a left-right direction, a direction orthogonal to the left-right direction is a front-rear direction, and a direction orthogonal to both the left-right direction and the front-rear direction is a vertical direction,
A first cam portion fixed to the fixed frame;
A second cam portion fixed to the fixed frame and arranged below the first cam portion;
A terminal unit having a plurality of terminals connected to the plurality of external terminals of the electricity meter,
The first cam portion has a plate-shaped first cam plate that is movable in the left-right direction with respect to the fixed frame,
The first cam plate is provided with a first cam groove in which the position in the front-rear direction changes in the left-right direction, and the terminal portion is movable along the side surface and engages from below,
The second cam portion has a plate-shaped second cam plate that is movable in the front-rear direction with respect to the fixed frame,
The second cam plate has a plurality of second cam grooves in which the plurality of terminals of the terminal portion are engaged one by one from below so as to be movable along a side surface,
The plurality of the second cam grooves is a wire connecting device for an electric energy meter, which has portions in the front-rear direction in which the intervals between the second cam grooves in the left-right direction are different from each other . The position of the first cam plate in the front-rear direction changes in the left-right direction, and the second cam plate includes a third cam groove that engages from below so as to be movable along the side surface. Wiring meter for watt hour meter. The wire connection device for an electric energy meter according to claim 1 or 2, wherein the first cam groove of the first cam plate has a flat portion having a side surface parallel to the left-right direction formed at least at two or more locations. The electric energy according to any one of claims 1 to 3, wherein the second cam groove of the second cam plate has a flat portion having a side surface parallel to the front-rear direction formed at least at two or more locations. Wiring device for measurement. A moving frame on which the electric power meter is mounted so that the external terminals of the electric power meter face the respective terminals in the vertical direction,
The wire connecting device for an electric energy meter according to any one of claims 1 to 4, wherein the movable frame is configured to be vertically movable with respect to the fixed frame.

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