JP2019096583A - Connection structure of electric device - Google Patents

Abstract

To provide a connection structure of an electric device capable of accurately positioning and connecting a terminal to be connected to a screw terminal of the electric device.SOLUTION: The connection structure of an electric device for electrically connecting screw terminals 12u to 12w formed on an electric device 10 and a connection terminal 37 formed on a terminal component 32 for a main terminal which is a member to be connected is provided with a detent mechanism for engaging the screw terminals and the terminal to be connected with each other.SELECTED DRAWING: Figure 8

Description

  The present invention relates to a connection structure of an electric device having a screw terminal such as a thermal overload relay or a magnetic contactor.

  As a connection structure of this kind of electrical equipment, for example, in a thermal overload relay, as described in Patent Document 1, three main terminals and four auxiliary terminals are provided. Each of these terminals is composed of a screw terminal including a terminal plate formed with a female screw and a terminal screw screwed to the female screw of the terminal plate. To this screw terminal, usually, a crimp terminal attached to a connection cord or a core wire exposed from a coating of the connection cord is connected. In this case, with the crimp terminals and core wires disposed on the terminal plate, the terminal screws having the washers inserted therein are screwed into the female screw portions of the terminal plates and tightened. In addition to the crimp terminal and the core wire of the cord, an intermediate part called an electrical device such as another magnetic contactor or an add-on part is connected to the screw terminal.

JP, 2014-107023, A

  By the way, when connecting a to-be-connected member individually to the screw terminal provided in the electric equipment, as described above, the mounting terminal of the to-be-connected member is placed on the terminal plate of the screw terminal and then the washer is mounted. The inserted terminal screw is screwed into a female screw formed on the terminal plate and tightened. For this reason, when the terminal screw and the washer come into contact with the connected terminal and start tightening, the connected terminal rotates with the rotation of the terminal screw. Therefore, there is a problem that the connection position of the connection target member deviates from the normal connection position. For this reason, when mounting the terminal cover which covers a to-be-connected member, mounting | wearing of a terminal cover may become difficult in some cases. In addition, the member to be connected collides with the partition provided in the electric device by corotation, and the partition may be damaged, which may deteriorate the insulation performance or prevent the terminal connection at the regular position.

  Therefore, the present invention has been made focusing on the above-mentioned problems of the prior art, and provides a connection structure of an electric device capable of accurately positioning and connecting a terminal to be connected to a screw terminal of the electric device. The purpose is that.

  In order to achieve the above object, one aspect of the connection structure of an electric device according to the present invention is an electrical connection that electrically connects a screw terminal formed in the electric device and a connected terminal formed in the connected member. It is a connection structure of equipment. This connection structure is provided with a detent mechanism that engages with the screw terminal and the connected terminal.

  According to one aspect of the present invention, since the anti-rotation mechanism is provided to the screw terminal and the connection terminal, when the terminal screw is tightened in a state where the connection terminal is disposed on the terminal plate of the screw terminal Accurate positioning can be performed by stopping the co-rotation of the connected terminal.

It is a front view of the electric equipment which shows one embodiment of the present invention. It is a rear view of the electric equipment which shows one embodiment of the present invention. It is a top view of the electric equipment which shows one embodiment of the present invention. It is a perspective view showing a thermal overload relay. It is a top view in the state where the terminal cover was removed. It is a perspective view in the state where the terminal cover was removed. It is sectional drawing on the VII-VII line of FIG. It is sectional drawing on the VIII-VIII line of FIG. It is sectional drawing on the IX-IX line of FIG. It is sectional drawing on the XX line of FIG. It is sectional drawing on the XI-XI line of FIG. It is a front view of a terminal cover.

  Next, an embodiment of the present invention will be described with reference to the drawings. In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals. However, the drawings are schematic, and the relationship between the thickness and the planar dimension, the ratio of the thickness of each layer, etc. may be different from the actual one. Therefore, specific thicknesses and dimensions should be determined in consideration of the following description. Moreover, it is a matter of course that parts having different dimensional relationships and ratios among the drawings are included.

In addition, the embodiments described below illustrate apparatuses and methods for embodying the technical idea of the present invention, and the technical idea of the present invention includes materials, shapes, structures, and the like of components. The arrangement etc. are not specified to the following. The technical idea of the present invention can be variously modified within the technical scope defined by the claims described in the claims.
One embodiment of the present invention will be described with reference to a thermal overload relay which is one of the electric devices.
In the thermal overload relay (thermal relay) 10, as shown in FIG. 1, three external connection pins 11u, 11v and 11w are disposed in parallel and projecting downward from the top on the front. These external connection pins 11 u, 11 v and 11 w are inserted into other electric devices to be connected, for example, spring terminals formed in an electromagnetic contactor.

  Further, as shown in FIG. 4, the thermal overload relay 10 has three main terminals 12u, 12v and 12w arranged in parallel in the left-right direction on the back surface. As shown in FIG. 6, the main terminal 12 u is fixed in a state in which the left and right side surfaces are in contact with the side wall 13 a and the partition wall 13 b extending in the front-rear direction of the thermal overload relay 10. As shown in FIG. 6, the main terminal 12 v is fixed in a state in which the left and right side surfaces are in contact with the partition walls 13 b and 13 c extending in the front-rear direction of the thermal overload relay 10. As shown in FIG. 6, the main terminal 12 w is fixed in a state in which the left and right side surfaces are in contact with the partition walls 13 c and 13 d extending in the front-rear direction of the thermal overload relay 10.

  Furthermore, as shown in FIG. 4, the thermal overload relay 10 has a step-like shape in which two auxiliary terminals 14a, 14b and 14c, 14d are juxtaposed in the left-right direction outside the main terminal 12w on the back surface. It is arranged in two stages. The auxiliary terminals 14a to 14d are also fixed in a state in which the left and right side surfaces are in contact with the partitions 13d and 13e extending in the front-rear direction formed in the thermal overload relay 10 and the side wall 13f.

  The main terminals 12 u to 12 w and the auxiliary terminals 14 a to 14 d have a screw terminal structure including the terminal plate 15 and the terminal screw 16. The terminal plate 15 is made of a conductive metal material. In the terminal plate 15, as shown in an enlarged view in FIG. 9, a cylindrical portion 17 which protrudes downward in the central portion is formed by burring. A female screw 18 is formed on the inner peripheral surface of the cylindrical portion 17. A washer 19 is attached to the terminal screw 16, and the terminal screw 16 is screwed into the female screw 18.

Each terminal plate 15 is formed with a protrusion 20 having a semicircular cross-section which extends in the left-right direction in the radial direction through the center of the female screw 18 as shown in FIG. The protrusion 20 serves as a first engaging portion that forms the locking mechanism RS. When pressing the terminal board 15, the protrusion 20 is formed by embossing from the lower surface side.
The terminal screw 16 is screwed into the female screw portion 18 of the terminal plate 15. The terminal screw 16 rotatably holds the washer 19 on the head side. The washer 19 can also be separate from the terminal screw 16.

  Further, as shown in FIG. 7, the thermal overload relay 10 is internally provided with three bimetals 21u, 21v and 21w. The bimetals 21u to 21w are heated when the current flowing between the external connection pins 11u to 11w and the main terminals 12u to 12w is in an overcurrent state, and the conduction path is interrupted by a shifter, release lever, and contact reversing mechanism not shown. Tripped.

Furthermore, as shown in FIG. 3, the thermal overload relay 10 has a reset rod 21 protruding on the upper surface for releasing the trip state.
Spring terminal parts, which are connection members serving as add-on parts enabling connection to the thermal overload relay 10 by the spring terminals, to the main terminals 12 u to 12 w and the auxiliary terminals 14 a to 14 d of the thermal overload relay 10 31 is connected.

The spring terminal part 31 is composed of the main terminal part 32 and the auxiliary terminal parts 33A and 33B.
As shown in FIG. 4, FIG. 5 and FIG. 8, three main terminal terminal components 32 are prepared so as to be individually connected to the main terminals 12u to 12w.
Each of the main terminal terminal components 32 has an insulating case 35 molded of, for example, a synthetic resin material. As shown in FIGS. 5 and 9, the insulating case 35 is formed substantially in a U-shape as viewed from the side by a bottom plate 35a, a front plate 35b, a rear plate 35c and a left side plate 35d. .

The bottom plate portion 35a is formed in a rectangular shape as viewed from a plane extending in the front-rear direction. As shown in FIG. 9, an engagement protrusion 35a1 protruding downward is formed on the lower surface of the bottom plate portion 35a on the front end side. The engagement protrusion 35a1 engages with an engagement hole 57 of the terminal cover 51 described later.
The front plate portion 35b includes a first vertical plate portion 35b1 extending upward from the front end of the bottom plate portion 35a, and a second vertical plate portion 35b2 extending upward and forwardly from the upper end of the vertical plate portion 35b1. The second vertical plate portion 35b2 is configured by a curved plate portion 35b3 that extends and curves upward and rearward from the second vertical plate portion 35b2.

The back surface plate portion 35c extends upward from the rear end of the bottom plate portion 35a to the upper end of the second vertical plate portion 35b2 of the front surface plate portion 35b.
The left side plate 35d extends upward from the left end of the bottom plate 35a, and is substantially equal to the upper ends of the front side plate 35d1 and the rear side plate 35c having substantially the same height as the upper end of the curved plate 35b3 of the front side plate 35b. It comprises with back side board part 35d2 of height. An annular peripheral wall 36 projecting to the right end side is formed on the inner surface of the left side surface plate portion 35d.

As shown in FIGS. 5 and 9, the annular peripheral wall 36 includes a bottom wall 36a, a front wall 36b, an upper wall 36c, and a rear wall 36d, which are continuous with each other. The bottom wall portion 36a is opposed to the bottom plate portion 35a at a predetermined interval.
The front wall portion 36 b extends upward from the front end of the bottom plate portion 35 a and is opposed to the front plate portion 35 b at a predetermined interval. The front wall portion 36b is formed with a stepped portion 36e which is shifted rearward on the side of the bottom wall portion 36a, and an engagement protrusion 36f which protrudes forward on an intermediate portion in the vertical direction.

The top wall 36c slightly extends rearward from the upper end of the front wall 36b. The rear wall 36d is a vertical wall extending downward from the rear end of the upper surface 36c, an inclined wall extending obliquely backward from the vertical wall, and a lower wall 36a extending downward from the inclined wall. And a vertical wall to reach.
Further, as shown in FIG. 8, the insulating case 35 holds a connection terminal 37 formed of a conductive metal material such as an iron material. The connection terminal 37 includes a terminal portion 37a and a U-shaped conductive plate portion 37b continuous to the terminal portion 37a.

  The terminal portion 37a protrudes forward through the window portion 35b4 between the first vertical plate portion 35b1 and the second vertical plate portion 35b2 of the front plate portion 35b of the insulating case 35, and has a tip thereof enlarged as shown in FIG. A through hole 37 c through which the terminal screw 16 can be inserted is formed. Further, in the terminal portion 37a, as shown in an enlarged view in FIG. 8, an engagement groove 37d having a triangular cross-sectional shape extending in the left-right direction in the radial direction centering on the through hole 37c is formed on the lower surface side. The engagement groove 37d engages with the protrusion 20 formed on the terminal plate 15 of the main terminals 12u to w to constitute a second engagement portion of the rotation prevention mechanism RS.

  The U-shaped conductive plate 37b includes a front plate 37b1 extending downward from the rear end of the terminal 37a, a bottom plate 37b2 extending rearward from the lower end of the front plate 37b1, and a rear end of the bottom plate 37b2 And a rear surface plate portion 37b3 that extends upward. As shown in FIG. 4, an engagement plate portion 37 b 4 protruding rightward is formed on the right side surface of the bottom plate portion 37 b 2. An engagement protrusion 37b5 that protrudes forward is formed on the inner surface on the upper end side of the rear surface plate portion 37b3.

  The U-shaped conductive plate 37b is held by the insulating case 35 along the inner surfaces of the front plate 35b, the bottom plate 35a, and the rear plate 35c. Here, in the U-shaped conductive plate portion 37b, the front plate portion 37b1 and the bottom plate portion 37b2 are between the front plate portion 35b and the bottom plate portion 35a of the insulating case 35 and the front wall portion 36b and the bottom wall portion 36a of the annular peripheral wall 36. And is held by the insulating case 35.

  Further, as shown in FIG. 9, a terminal spring 38 formed in an inverted U-shape with a conductive spring material is held by the insulating case 35. The terminal spring 38 includes a front plate portion 38a, a curved plate portion 38b and an inclined plate portion 38c. The front plate portion 38 a extends upward from the step portion 36 e of the front wall portion 36 b of the annular peripheral wall 36 along the front wall portion 36 b. The curved plate portion 38b is bent from the upper end of the front plate portion 38a and extends rearward between the curved plate portion 35b3 of the front plate portion 35b of the insulating case 35 and the upper surface wall portion 36c of the annular peripheral wall 36. There is. The inclined plate portion 38c is bent in a dog-leg shape rearward and downward from the rear end of the curved plate portion 38b and extended, and the tip end thereof is engaged with the lower end side of the engagement protrusion 37b5 of the U-shaped conductive plate portion 37b. .

A spring terminal 39 is configured by the terminal spring 38 and the rear surface plate portion 37 b 2 of the U-shaped conductive plate portion 37 b of the connection terminal 37.
Further, as shown in FIG. 10, the auxiliary terminal terminal parts 33A and 33B are formed in a similar shape smaller than the main terminal terminal part 32 described above. Therefore, although the detailed explanation about terminal parts 33A and 33B for auxiliary terminals omits this, insulating case 45, annular peripheral wall 46, connected terminal 47, and terminal spring 48 are provided. Here, as shown in the enlarged view in FIG. 10, the terminals of the main terminals 12u to 12w of the thermal overload relay 10 are connected to the terminals to be connected 47 in the same manner as the terminals 37 to be connected of the main terminal terminal part 32. An engaging groove 47x is formed as a second engaging portion having a triangular cross-sectional shape that engages with the protrusion 20 formed on the surface 15. A locking mechanism RS is configured by the engagement groove 47x and the protrusion 20. In addition, two terminal springs 48 are disposed in parallel in the auxiliary terminal terminal parts 33A and 33B.

  Further, the auxiliary terminal terminal parts 33B attached to the lower side auxiliary terminals 14c and 14d have a longer length of the connection terminal 47 than the auxiliary terminal terminal parts 33A attached to the upper side auxiliary terminals 14a and 14b. It is set. Therefore, as shown in FIG. 10, when the auxiliary terminal terminal parts 33A and 33B are attached to the auxiliary terminals 14a, 14b and 14c, 14d, the locking positions of the terminal springs 48 do not overlap in the vertical direction. .

Furthermore, on the front end side of the bottom plate portion 45a of the insulating case 45, as shown in FIG. 11, an engagement protrusion 45x that protrudes downward is formed on the lower surface. The engagement projection 45x is engaged with an engagement hole 59 formed in a long groove 58 of a terminal cover 51 described later through a through hole formed in the U-shaped conductive plate portion 47b of the connection terminal 47.
Then, the main terminal terminal parts 32 are individually attached to the main terminals 12u to 12w of the thermal overload relay 10, and the auxiliary terminal terminal parts 33A and 33B are individually attached to the auxiliary terminals 14a, 14b and 14c, 14d. In this state, the terminal cover 51 is attached so as to cover all of the main terminal terminal parts 32 and the auxiliary terminal parts 33A and 33B.

As shown in FIG. 12, the terminal cover 51 has a terminal component storage portion 52 for storing the main terminal terminal components 32 and a terminal component storage portion 53A for separately storing the auxiliary terminal terminal components 33A and 33B. 53 B are formed separated by the insulating partition 54.
As shown in FIG. 12, in the terminal component storage portion 52, an engagement plate portion 37b4 formed on a back surface plate portion 37b3 of the U-shaped conductive plate portion 37b of the connection terminal 37 engages with the inner peripheral surface The groove 52a is formed.

  Further, as shown in FIG. 5, a collar 55 that covers the main terminals 12 u to 12 w of the thermal overload relay 10 is formed on the top of the terminal component storage 52. Similarly, a collar portion 56 covering the auxiliary terminals 14a and 14b is formed on the top of the terminal component storage portion 53A. In the collar portion 55, engaging long holes 55a and 55b are formed through which the engaging portions 13g formed at the upper ends of the partition walls 13b and 13c of the thermal overload relay 10 engage. In the collar portion 56, an engagement long hole 56a which is engaged with an engagement portion 13g formed at the upper end of the partition 13e of the thermal overload relay 10 is formed penetrating.

Further, on the lower surface side of the terminal component storage portion 52, as shown in FIG. 9, an engagement hole 57 with which an engagement protrusion 35a1 formed on the insulating case 35 of the main terminal terminal component 32 engages is It is formed to be extended. When the terminal cover 51 is mounted on the front end side of the engagement hole 57, a hook portion 52d is formed to be snap fit-coupled after passing over the engagement protrusion 35a1.
On the other hand, an elongated groove 58 having a width that prevents insertion of a tool is formed on the lower surface side of the terminal component storage portion 53B, and an engagement protrusion formed on the lower surface of the auxiliary terminal component 33B on the bottom surface of the front end of the elongated groove 58. An engagement hole 59 with which 45x engages is formed through. As shown in FIG. 11, a hook portion 53d is formed on the upper surface of the end portion of the bottom plate portion 53c of the terminal component storage portion 53B of the terminal cover 51, in which the engagement hole 59 is formed. When the terminal cover 51 is attached, the hook portion 53 d passes over the engaging protrusion 45 x formed on the auxiliary terminal portion 33 B to be snap fit-coupled.

Furthermore, on the rear end side of the upper surface of the terminal component storage portion 52, an insertion hole 52b for inserting an electrical connection portion 61 such as a single wire, a stranded wire or a stranded wire with a ferrule terminal of the main terminal connection cable 60 The tip end side of the inclined plate portion 38c is formed to face and penetrate.
Further, on the front surface side of the insertion hole 52b in the upper surface of the terminal component storage portion 52, an insertion hole 52c for inserting a clamp release tool for pressing the terminal spring 38 to separate from the electrical connection portion 61 is formed through There is.

  Similarly, an insertion hole for inserting an electrical connection portion such as a single wire, a stranded wire, or a stranded wire with a ferrule terminal of an auxiliary terminal connection cable (not shown) on the rear end side of the upper surface of the terminal component storage 53A and 53B. Two pieces 53 a are formed so as to face the two terminal springs 48. In addition, two insertion holes 53b are formed through the clamp release tool for pressing the terminal spring 48 to separate from the electrical connection portion on the front surface side of the insertion hole 53a on the upper surface of the terminal component storage portions 53A and 53B. It is formed.

Next, the operation of the present invention will be described.
In order to use the thermal overload relay 10 having a screw terminal shown in FIG. 4 as a thermal overload relay having a spring terminal, first, as shown in FIGS. 4 and 5, the thermal overload relay 10 The main terminal terminal components 32 are individually attached to the main terminals 12i (i = u, v, w) of the relay 10. Similarly, the terminal component 33A for the auxiliary terminal is individually attached to the auxiliary terminal 14j (j = a, b) of the thermal overload relay 10, and the auxiliary terminal 14k (k = c, d) is separately the auxiliary terminal. The terminal part 33B is mounted.

In order to mount the terminal component 32 for the main terminal to the main terminal 12i, first, the terminal screw 16 screwed to the female screw portion 18 of the terminal plate 15 of the main terminal 12i is removed together with the washer 19. In this state, the terminal portion 37 a of the connection terminal 37 protruding from the main terminal terminal component 32 is placed on the terminal plate 15.
At this time, the engaging groove 37 d formed in the terminal portion 37 a of the connection terminal 37 is engaged with the protrusion 20 formed in the terminal plate 15. Since terminal plate 15 is non-rotatably fixed by side walls 13a and 13f and partition walls 13b to 13e, terminal component 32 for the main terminal extends in the front-rear direction perpendicular to the front end face of thermal overload relay 10. To be positioned.

In this state, the terminal screw 16 mounted with the washer 19 is screwed into the female screw portion 18 of the terminal plate 15 through the through hole 37 c of the connection terminal 37 and tightened.
At this time, the engagement groove 37 d is engaged with the projection 20 in a state where the upper surface of the washer 19 is in contact with the head of the terminal screw 16 and the lower surface is in contact with the upper surface of the terminal portion 37 a of the connected terminal 37. The main terminal terminal part 32 is held by hand until the start of the connection. After that, when the worker releases the holding of the main terminal terminal part 32 and tightens the terminal screw 16, the engagement groove 37d and the projection 20 are engaged with each other, thereby positioning and By exerting both functions of the rotation stopper, the rotation of the terminal screw 16 accurately positions and fixes the main terminal terminal part 32 without rotating. Therefore, the mounting operation of the main-terminal terminal component 32 to the main terminal 12i can be easily performed in a short time.

  Under the present circumstances, the protrusion 20 formed in the terminal board 15 of the main terminal 12i is formed in semicircle shape seeing from the side, and the engaging groove 37d formed in the terminal part 37a of the to-be-connected terminal 37 seeing from the side It is formed in the shape of a triangle. Therefore, even if the cross-sectional shapes of the projection 20 and the engagement groove 37d are not accurately formed, positioning and rotation prevention can be performed accurately by the centering function of the triangular engagement groove 37d.

  Next, the auxiliary terminal terminal parts 33B are individually attached to the auxiliary terminal 14k. Also in this case, a protrusion 20 is formed on the terminal plate 15 of the auxiliary terminal 14k, and an engagement groove 47d is formed on the connection terminal 47 of the auxiliary terminal component 33B. Therefore, the auxiliary terminal terminal parts 33B can be individually mounted on the auxiliary terminal 14k in the same procedure as the mounting of the main terminal terminal parts 32 on the main terminals 12i. At this time, the positioning function and the anti-rotation function are exhibited by the projection 20 and the engagement groove 47d, and the work of attaching the terminal component 33B for the auxiliary terminal to the auxiliary terminal 14k can be easily performed in a short time. .

  Further, the auxiliary terminal terminal parts 33A are individually attached to the auxiliary terminals 14j. Also in this case, the ridges 20 are formed on the terminal plate 15 of the auxiliary terminal 14j, and the engaging groove 47d is formed on the connection terminal 47 of the auxiliary terminal component 33A. Therefore, the auxiliary terminal terminal parts 33A can be individually attached to the auxiliary terminals 14j in the same procedure as the attachment of the auxiliary terminal parts 33B to the auxiliary terminals 14j. At this time, the positioning function and the anti-rotation function are exhibited by the projection 20 and the engagement groove 47d, and the mounting work of the terminal component 33B for the auxiliary terminal to the auxiliary terminal 14j can be easily performed in a short time. .

  In this manner, the mounting of the main terminal terminal components 32 and the auxiliary terminal terminal components 33A and 33B on the main terminals 12u to 12w and the auxiliary terminals 14a to 14d of the thermal overload relay 10 is completed. In this state, as shown in FIGS. 5 and 6, the main terminal terminal components 32 and the auxiliary terminal terminal components 33A and 33B extend in the front-rear direction and are accurately aligned and held in the left-right direction.

  In this state, the main terminals 12u to 12w, the auxiliary terminals 14a and 14b of the thermal overload relay 10, the connected terminals 37 of the main terminal terminal parts 32, the terminal springs 38, and the connected terminals of the auxiliary terminal parts 47 And the terminal spring 48 is exposed. Therefore, the terminal cover 51 is mounted so as to cover the main terminals 12u to 12w, the auxiliary terminals 14a and 14b, the main terminal terminal components 32 and the auxiliary terminal terminals 33A and 33B.

  In mounting the terminal cover 51, first, each terminal component storage portion 52 of the terminal cover 51 is made to face the main terminal terminal component 32, and the terminal component storage portions 53A and 53B are opposed to the auxiliary terminal terminal components 33A and 33B. Let In this state, by pushing the terminal cover 51 to the back side of the thermal overload relay 10, the partition walls 13b and 13c of the thermal overload relay 10 are formed in the engaging long holes 55a and 55b formed in the collar 55. The engaging part 13g formed in is engaged.

  At the same time, the hook portion 52 d passes over the engaging protrusion 35 a 1 formed on the bottom surface of the main terminal terminal component 32, and the engaging protrusion 35 a 1 is snap fit-engaged with the engaging hole 57. Further, the hook portion 53d formed on the lower surface of the terminal component storage portion 53B rides over the engagement projection 45x formed on the bottom surface of the auxiliary terminal portion 33B, and the engagement projection 45x is snap fit coupled to the engagement hole 59. Ru.

Further, the engagement plate portion 37 b 4 formed in the U-shaped conductive plate portion 47 b of the main terminal terminal component 32 engages with the engagement groove 52 a formed in the terminal component storage portion 42.
Therefore, the terminal cover 51 is non-removably mounted on the thermal overload relay 10 via the main terminal terminal part 32 and the auxiliary terminal terminal parts 33A, 33B. That is, the engaging projection 45x formed on the insulating case 45 of the auxiliary terminal part 33B is formed on the bottom of the long groove 58 where insertion of a tool formed on the lower surface of the terminal part storage 53B of the terminal cover 51 is not possible. The engagement hole 59 is engaged. Therefore, since the tool can not be inserted into the long groove 58, the engaged state between the engagement hole 59 and the engagement protrusion 45x can not be released, and the long groove 58, the engagement hole 59, and the hook portion 53d And the terminal cover 51 can not be removed.

If any one of the main terminal terminal parts 32 covered by the terminal cover 51 and the auxiliary terminal parts 33A and 33B fails, the terminal cover 51 is broken to replace the broken terminal parts. The new terminal cover 51 is attached.
Thus, by mounting the terminal cover 51, the state shown in FIGS. 1 to 3 is obtained, and the main terminals 12u to 12w, the auxiliary terminals 14a and 14b, the main terminal terminal parts 32 and the auxiliary terminal terminal parts 33A and 33B. All the conductive parts of the Therefore, an electric shock accident can be prevented in advance. Further, since the main terminal terminal component 32 and the auxiliary terminal terminal components 33A and 33B are insulated by the insulating partition 54 formed in the terminal cover 51, it is possible to reliably insulate the respective terminal components.

Then, the thermal overload relay 10 with screw terminals is mounted by mounting the main terminal terminal parts 32 and the auxiliary terminal plug parts 33A, 33B and the terminal cover 51 to the thermal overload relay 10 with screw terminals. The thermal overload relay can have a spring terminal.
In this state, conductive connection portions such as single wires, stranded wires, and stranded wires with ferrule terminals of connection cable 60 are inserted into insertion holes 52b and 53a of terminal cover 51, and terminal springs 38 and 48 are formed into U-shaped conductive plate portions. Separate from 37b and 47b. As a result, the tips of the terminal springs 38 and 48 contact the conductive connection portions, and the conductive connection portions are sandwiched between the terminal springs 38 and 48 and the U-shaped conductive plate portions 37 b and 47 b.

  At this time, since the diameter of the single wire or the stranded wire of the connection cable 60 for the main terminal is large, a large force is required when holding between the terminal spring 38 and the U-shaped conductive plate portion 37b. For this reason, a cantilever load is applied to the side opposite to the terminal portion 37 a of the connected terminal 37 of the main terminal terminal component 32. However, the engagement plate portion 37 b 4 of the bottom plate portion 37 b 2 of the U-shaped conductive plate portion 37 b is engaged with the engagement groove 52 a formed on the inner surface of the terminal component storage portion 52 of the terminal cover 51. Therefore, the cantilever load applied to the main terminal terminal component 32 can be dispersed in and supported by the terminal cover 51, and deformation of the terminal portion 37a of the connection terminal 37 can be prevented.

Also, in order to remove the electrical connection portion 61 of the connection cable 60 from the spring terminal 39, insert a tool such as a minus screwdriver into the tool insertion hole 52c (or 53b) to make the inclined plate portion of the terminal spring 38 (or 48) 38c (or 48c) is separated from the electrical connection 61 to release the locked state, and the electrical connection 61 is pulled out.
In the above embodiment, although the case where the ridges 20 are formed on the terminal plate 15 and the engagement grooves 37d and 47x are formed on the connected terminals 37 and 47, the present invention is not limited to this. Engaging grooves may be formed on the plate 15 and protrusions may be formed on the connected terminals 37 and 47.
Furthermore, a protrusion and an engaging groove are formed on the terminal plate 15 with the cylindrical portion 17 interposed therebetween, and an engaging groove opposed to the protrusion and a protrusion opposed to the engaging groove are formed on the connected terminals 37 and 47 You may do so.

Furthermore, the extension direction of the protrusion 20 and the engagement grooves 37d and 47x can be set arbitrarily, and it is not necessary to pass through the center of the terminal screw 16. The cross-sectional shape of the projection 20 and the cross-sectional shape of the engagement groove 37d can be any cross-sectional shape as long as they can be engaged with each other.
Further, in the above embodiment, as shown in FIG. 4, with the auxiliary terminal terminal parts 33A and the auxiliary terminal terminal parts 33B attached to the auxiliary terminals 14j and 14k of the thermal overload relay 10, for auxiliary terminals. The case where the terminal component 33B is completely exposed from the rear end of the auxiliary terminal component 33A has been described. However, the present invention is not limited to this, and the exposed region of the auxiliary terminal part 33B may be narrowed to such an extent that the insertion holes 53a and 53b of the terminal cover 51 can be desired to the outside.

Moreover, although the said embodiment demonstrated the connection structure in the case of connecting the thermal overload relay 10, the terminal component 32 for main terminals, and the terminal components 33A and 33B for auxiliary terminals, it is limited to this. The present invention can be applied to the case of connecting an electric device having a connected terminal to a screw terminal of the electric device.
Moreover, although the case where the thermal overload relay was applied as an electric device was demonstrated in the said embodiment, it is not limited to this, The electric device which has an electromagnetic contactor, an electromagnetic relay, and other screw terminals The present invention can be applied to In this case, the present invention can be applied to an electric device having only a main terminal and not having an auxiliary terminal.

  DESCRIPTION OF SYMBOLS 10 ... Thermal operation type overload relay, 11u-11w ... External connection pin, 12u-12w ... Main terminal, 13a, 13f ... Side wall, 13b-13e ... Partition, 14a-14d ... Auxiliary terminal, 15 ... Terminal board, 16 ... Terminal screw, 17: Cylindrical portion, 18: Female screw portion, 19: Washer, 20: Projection, 31: Spring terminal parts, 32: Terminal parts for main terminals, 33A, 33B: Terminal parts for auxiliary terminals, 35: Insulating case , 36: annular peripheral wall, 37: connected terminal, 37a: terminal portion, 37b: U-shaped conductive plate portion, 37b4: engaging plate portion, 37b5: engaging groove, 38: terminal spring, 45: insulating case, 45x ... Engaging projection, 46: Annular circumferential wall, 47: Connected terminal, 47b: U-shaped conductive plate portion, 48: Terminal spring, 51: Terminal cover, 52, 53A, 53B: Terminal component storage portion, 54: Insulating partition, 55, 6 ... eaves portion, 55a, 55b, 56a ... engagement elongated hole, 58 ... long groove, 59 ... engaging hole, 60 ... connection cable, 61 ... electrical connections

Claims (8)

A connection structure of an electric device for electrically connecting a screw terminal formed in the electric device and a connection terminal formed in the connection member,
The connection structure of the electric equipment which provided the rotation prevention mechanism mutually engaged with the said screw terminal and the said to-be-connected terminal.   The screw terminal has a terminal plate formed with a female screw portion, and a terminal screw screwed to the female screw portion, and extends in the radial direction of the female screw portion on the joint surface of the terminal plate with the connected terminal. The connection structure of the electric device according to claim 1, wherein a first engaging portion constituting the detent mechanism is formed.   The connected terminal has an insertion hole through which the terminal screw is inserted, and a second engagement portion forming the anti-rotation mechanism engaged with the first engagement portion is formed on the joint surface with the screw terminal. The connection structure of the electric device according to claim 2.   The said 1st engaging part and the said 2nd engaging part are comprised by the engaging groove which one side is comprised by an engagement protrusion, and the other is engaged with the said engagement protrusion. Electrical equipment connection structure.   The electric device according to any one of claims 1 to 4, wherein the connected member has the connected terminal at one end and a spring terminal electrically connected to the connected terminal at the other end. Connection structure.   The connection structure of the electric device according to any one of claims 1 to 5, further comprising a terminal cover which covers the connected member in a state where the connected member is connected to the screw terminal.   7. The electricity according to claim 6, wherein a plurality of the screw terminals are provided, the connected members are individually connected to the plurality of screw terminals, and the terminal cover collectively covers the plurality of connected members. Equipment connection structure.   The connection structure of the electric device according to claim 7, wherein a non-removable retaining mechanism is provided between the connection member and the terminal cover.

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