JPH09223527A - Conductive clip - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a conductive clip whose conductive members can be reliably electrically continued with each other without complicating the constitution of the conductive members and which can also be easily mounted and demounted. SOLUTION: A guide metal fitting 20 installed in a holding metal fitting 10 formed in a U shape so as to be taken in and out from between its opening ends, is provided with a pair of guide pieces 24 erected so as to be opposed to each other, and a first spring part 24d by folding back inside a central part by dividing the opening ends into three parts and a second spring part 24e by folding back both side parts outside, are formed on the opening ends of the guide pieces 24. When a conductive member arranged between the guide pieces 24 is pushed in the holding metal fitting 24 together with the guide metal fitting 20, a conductive clip 2 is installed in the conductive member in a condition where the second spring part 24e is exposed outside when the first spring part 24d is brought into close contact with the conductive member. When the other conductive member is brought into contact with this exposed second spring part 24e, both conductive members can be reliably electrically continued with each other.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention sandwiches an end portion of a first conductive member and abuts on a second conductive member disposed near the end portion of the first conductive member so that both conductive members can be connected to each other. The present invention relates to a conducting clip that conducts each other.

[0002]

2. Description of the Related Art Conventionally, for example, Japanese Patent Application Laid-Open No. 53-6 has been used as a device for surely connecting electrically conductive members formed separately.
As disclosed in Japanese Patent No. 4401, a shield plate disposed on a bottom wall of a groove for supporting a shield plate formed in a conductive frame forming a casing and supported by the frame and the groove of the frame. There is known an electrically conductive contact plate member that contacts both of the above and the above and makes them conductive with each other.

This contact plate is provided with a large number of elastic projections formed by cutting and raising a tongue-like portion formed by cutting a substantially U-shape on a predetermined surface side, and the width of the contact plate is a groove. Is provided with a large number of serrated projections formed on the sides of the contact plate to be slightly wider than the width of the bottom wall of the contact plate. Toward the bottom wall of the groove, from one end of the groove along the bottom wall of the groove,
By sliding, the contact plate material is attached to the groove.

At the time of this attachment, the projection formed on the side portion of the plate material scrapes off the oxide film on the side wall surface of the concave groove, so that a good conductive state is established between the contact plate material and the concave groove, that is, the frame. And the elastic projections are brought into close contact with the end of the shield plate inserted in the groove by its elastic force, thereby ensuring a good conduction state between the contact plate material and the shield plate, and It is designed to ensure a good electrical connection between the frame and the shield plate.

[0005]

However, in such a contact plate material, as described above, the attachment to the concave groove must be performed by sliding from one end of the concave groove, and the attaching work is troublesome. At the same time, if the width of the contact plate (that is, the height of the protrusion formed on the side of the contact plate) is too large, it becomes difficult to insert the contact plate into the groove, and conversely the width of the contact plate is small. If it is too large, the contact plate will fall off easily even if it is inserted into the groove. Therefore, the width of the contact plate must be finished with high accuracy, and there is a problem that manufacturing is difficult.

This contact plate cannot be used unless one conductive member has a concave groove and the other conductive member has a projection to be inserted into the concave groove. There was also a problem that it could only be used for the intended purpose. In other words, for example, when such a contact plate material is dare to be used in order to ensure electrical continuity between the housing having the opening and the lid that closes the opening, a concave groove is formed in the opening edge portion and the lid. You have to bother to form the protrusions,
There is a problem that the structure of the casing to be electrically connected is complicated.

The present invention has been made to solve the above problems.
An object of the present invention is to provide a conductive clip that can reliably conduct electrical conduction between conductive members without complicating the structure of the conductive members that should be conducted to each other, and that is easily removable.

[0008]

In order to achieve the above object, the invention according to claim 1 stores the connecting portion of the guide fitting between the holding pieces of the holding member and holds the guide piece. When the guide piece is pulled out from the open end, the open end of the guide piece is wider than the open end of the sandwiching piece.

When the guide metal fitting with the open end of the guide piece largely opened is pushed between the holding pieces of the holding member, the guide metal piece slides while the guide piece abuts against the open end of the holding piece. The elastic member is elastically deformed so that the space between the open ends thereof is narrowed, and is housed in the holding member.

Therefore, the end portion of the first conductive member formed thicker than the width of the open end of the sandwiching piece is sandwiched between the guide pieces that are pulled out from the holding member, and the first conductive member is guided. If you push it between the clamps together with the metal fittings,
The conductive member is guided by the guide fitting and inserted while pushing the width of the open end of the sandwiching piece open. As a result, the conductive clip is inserted into the first conductive member while the width of the open end of the sandwiching piece is pushed open. Is attached to the end of.

As described above, the sandwiching piece whose width at the open end is pushed open acts as a leaf spring and presses the surface of the first conductive member by the elastic force to return to the original shape and sandwiches it. At this time, the guide piece interposed between the sandwiching piece and the first conductive member is biased by the sandwiching piece and comes into close contact with the surface of the first conductive member, so that the guide metal fitting and the first conductive member are surely conducted. To do.

On the other hand, the spring portion formed so as to project to the outside of the holding member is biased to the second conductive member disposed near the end portion of the first conductive member to which the conductive clip is attached. Because of the contact, the guide fitting is surely conducted to the second conductive member. Therefore, according to the conductive clip of the present invention, the first conductive member and the second conductive member can be surely conducted through the guide metal fitting, and the first conductive member is guided by the guide metal fitting while being sandwiched. Since the first conductive member is thicker than the width of the open end of the sandwiching piece, it can be easily mounted, and the workability of mounting is good.

As described above, according to the conductive clip of the present invention, since the first conductive member and the second conductive member can be surely conducted to each other, for example, the gap between the both conductive members should be passed. By using it as an electromagnetic wave shielding material to shield electromagnetic waves, or by attaching a conduction clip to the end of the board that is inserted into the guide rail and inserting the conduction clip in the guide rail, The pattern on the substrate formed at the position where the guide fitting abuts can be used for grounding to the housing via the conductive guide rail.

In the conducting clip of the present invention, since the holding member and the guide metal member are formed separately, they can be made of materials different from each other. Depending on the material, either conductive or insulating material may be used. For example, when the conductive clip is attached to the first conductive member, the guide metal fitting and the holding member are in close contact with each other. Therefore, if the holding member is made of a conductive material, the holding member also serves as the second conductive member. Can be conducted.

Beryllium copper is often used as the material for this type of clip, but beryllium copper tends to rust when touched with bare hands. Further, for example, if the guide metal fittings rust, the conductivity deteriorates. To prevent this, gloves must be worn during work or transportation, which is troublesome to handle.

Therefore, as in the invention described in claim 2,
If the holding member is made of an insulating material, it will be possible to work without directly contacting the beryllium copper part, so handling will be easier, and the guide fitting will not rust and the conductivity will deteriorate. It can be prevented. Further, even if an electronic component or the like is arranged in the vicinity of the base of the holding member, it is not electrically connected to this and high safety can be secured.

According to the third aspect of the invention, when the conductive clip is attached to the end of the first conductive member, the end of the sandwiching piece guides the open end of the guide piece to the guide fitting. Is inserted between the spring part that is folded back in the outer direction and the main body of the guide piece, that is, the spring part is located outside the holding piece. Therefore, the holding piece of the holding member is inserted through this spring part. It is possible to achieve conduction with the second conductive member arranged at a position opposed to.

Further, according to the invention described in claim 4, when the conductive clip is attached to the end of the first conductive member, the spring portion projects from the opening formed in the base of the holding member. Therefore, it is possible to achieve conduction with the second conductive member arranged at a position facing the base portion.

Further, in the invention described in claim 5, at least a part of the open end portion of the guide piece is folded back in a space into which the first conductive member is inserted, that is, inward of the guide metal member, and is a leaf spring. Since the conductive clip is attached to the first conductive member, the conductive clip comes into contact with the first conductive member while being urged not only by the urging force from the holding member but also by its own elastic force. To do.

Therefore, according to the conductive clip of the present invention,
The guide metal fitting can be surely brought into close contact with the first conductive member, and the conduction between them can be made more reliable.
Further, according to the conductive clip of the present invention, the end portion of the folded back guide piece comes into contact with the first conductive member on which the conductive clip is mounted in a biased state, so that the width of the first conductive member is the sandwiching piece. Even if the width is slightly smaller than the width of the first conductive member, the first conductive member can be reliably sandwiched, and it can be applied to the first conductive member having a wider range of thickness.

Next, in the invention according to claim 6, the projection formed on the holding piece of the holding member is loosely fitted into the long hole formed on the guide piece of the guide fitting, thereby moving the guide fitting. The direction is restricted only to the direction in which the guide piece is taken in and out from between the open ends of the sandwiching piece, and moreover, the guide metal piece is prevented from coming off the holding member by engaging with the edge of the elongated hole.

Therefore, according to the conductive clip of the present invention,
Even when it is not attached to the first conductive member, the holding member and the guide fitting do not come apart and are always integrated, so that the workability of attachment can be further improved.
Also, by restricting the movement direction of the guide metal fittings,
Since the guide fitting is always stored in a predetermined position of the holding member, it looks good when mounted.

[0023]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a perspective view showing the overall configuration of the conducting clip 2 of the first embodiment. As shown in FIG. 1, the conductive clip 2 of the present embodiment includes a holding metal fitting 10 as a holding member having a substantially U-shaped cross section, and a guide metal fitting 20 configured to be accommodated in the holding metal fitting 10. It is composed by.

Of these, the holding metal fitting 10 has a thickness of 0.3 mm.
The base part 1 formed by molding a metal plate of
2 and a pair of sandwiching pieces 14 that are erected so as to face each other by bending both ends of the base portion 12. The width between the pair of sandwiching pieces 14 is formed so that the open end side is narrower than the base 12 side. Further, near the open end of each holding piece 14, a tongue-shaped portion formed by making a U-shaped cut in three directions other than the open end side is cut and raised inward of the holding metal fitting 10. A pair of protrusions 16 are formed respectively.

On the other hand, the guide fitting 20 has a thickness of 0.05 m.
m of a metal plate is formed, and the connecting portion 22 formed to have the same width as the width of the open ends of the pair of sandwiching pieces 14 and both ends of the connecting portion 22 are bent so that they face each other. It is composed of a pair of upright guide pieces 24. As a material of the guide metal fitting 20, beryllium copper, copper alloy such as phosphor bronze, or stainless steel can be used.

The guide piece 24 has a parallel portion 24a having the same width as the connecting portion 22 from the side closer to the connecting portion 22, and the width between the pair of guide pieces 24 increases as the distance from the connecting portion 22 increases. First inclined portion 24b, first inclined portion 2
The second slanted portion 24 having a gentler inclination than 4b.
c, the first spring portion 24d and 3 in which the open end of the guide piece 24 is divided into approximately three parts and the central portion is folded back inward.
A second spring portion 24e is formed by folding back both sides of the divided open end portion. Further, each guide piece 24 is formed with a pair of elongated holes 26 from the parallel portion 24a to the second inclined portion 24c. In addition, in the present embodiment, the second spring portion 24e corresponds to the spring portion of the present invention described above.

The holding metal fitting 10 and the guide metal fitting 20 respectively have the projections 16 formed on the holding piece 14 of the holding metal fitting 10 in the elongated holes 26 formed in the guide piece 24 of the guide metal fitting 20, respectively. It is assembled by fitting. In addition, here, the thickness of the holding metal fitting 10 is 0.3.
mm, and the thickness of the guide metal fitting 20 is 0.05 mm, but the invention is not limited to this.
The thickness may be appropriately set so that the required elastic force can be obtained according to the size.

2A is a side view of the guide metal fitting 20 alone, FIG. 2B is a side view of the holding metal fitting 10 alone, and FIG.
[FIG. 3] is a side view of a conduction clip 2 of this embodiment, which is formed by assembling a guide metal fitting 20 and a holding metal fitting 10. In the conduction clip 2 having such a structure, when the guide metal fitting 20 is pushed into the holding metal fitting 10, the guide metal fitting 20 causes the guide metal piece 2 to move.
4 slides in the direction regulated by the projection 16 and the elongated hole 26 while abutting on the open end of the sandwiching piece 14, and is elastically deformed so that the space between the open ends of the guide pieces 24 is narrowed and stored in the holding metal fitting 10. To be done. At this time, the second spring portion 24e
The holding metal 10 is sandwiched between the second inclined portion 24c and the opposite side, that is, the outside of the holding metal 10 is exposed.

On the contrary, when the guide fitting 20 is pulled out from the holding fitting 10, the guide fitting 20 returns to the original shape in which the open end of the guide piece 24 is wider than the width of the open end of the holding piece 14. Also, when the guide fitting 20 is pulled out, the long hole 26
Since the end portion of the and the projection 16 are engaged with each other, the guide metal fitting 20 is held integrally with the holding metal fitting 10 without coming off from the holding metal fitting 10.

The conductive clip 2 which operates in this manner is attached to the substrate P as follows. That is, first, as shown in FIGS. 1 and 2C, the guide piece 2 of the guide fitting 20 is
4 is pulled out from the holding metal fitting 10, and the end portion of the board P to which the conductive clip 2 is to be attached is inserted between the guide pieces 24 pulled out from the holding metal fitting 10, as shown in FIG. The thickness of the substrate P is almost the same as the width between the open ends of the sandwiching pieces 14. Then, in this state, the substrate P
3 is pushed into the holding metal fitting 10 together with the guide metal fitting 20, the conductive clip 2 is attached to the substrate P as shown in FIG.

At this time, as the open end of the guide piece 24 narrows due to elastic deformation of the guide piece 24, the first spring portion 24
d contacts the surface of the substrate P, and the first spring portion 24d and the second spring portion 24d
It is elastically deformed in the direction in which the width with the inclined portion 24c is narrowed. Then, when the conductive clip 2 is attached to the substrate P, the first spring portion 24d biases the space between the sandwiching piece 14 and the substrate P in the direction of pushing open.

On the other hand, the open end of the sandwiching piece 14 is pushed open when the substrate P is inserted together with the guide piece 24, and due to the elastic force to return to the original shape,
The substrate P is pressed via the guide pieces 24. As a result, the substrate P is pressed by the urging force of the holding piece 14 and the urging force of the guide piece 24 to be strongly held, and the guide piece 24 is also pressed.
The first spring portion 24d of the above is in close contact with the substrate P. Further, at this time, the guide fitting 20 is deformed in the direction in which the interval between the pair of guide pieces 24 is narrowed, so that the parallel portions 24a formed in parallel in advance are also urged in the direction to press the substrate P and are moved toward the substrate P. In close contact.

FIG. 4 shows the conductive clip 2 of this embodiment.
FIG. 5A is a perspective view showing a shield casing used as an electromagnetic wave shielding material, and FIG. 5A shows a state in which a lid is opened,
FIG. 5B is a cross-sectional view taken along the line AA with the lid closed. As shown in FIG. 4, the shield housing B is a box-shaped main body B having an opening for inserting and removing electronic components and the like.
1 and a lid B2 attached to the main body via a hinge (not shown) to close the opening. The conductive clip 2 of the present embodiment is provided around the entire circumference of the opening end of the main body B1. Installed across. Both the body B1 and the lid B2 are made of a conductive metal plate.

As shown in FIG. 5A, the conductive clip 2 attached to the open end of the main body B1 is urged by the holding metal fitting 10 by the open end of the holding piece 14 being expanded, and the guide piece 24. The body B is deformed by the biasing force of the first spring portion 24d and the parallel portion 24a.
The opening end of No. 1 is strongly sandwiched and mounted on the opening end of the main body B1 and is surely conducted to the main body B1.

Then, as shown in FIG. 5B, the lid B
When 2 is closed, the second spring portion 24e is pressed by the lid body B2 and abuts the lid body B2 in a biased state. As a result, the guide fitting 20 and the lid B2 are surely brought into conduction, and the body B1 and the lid B2 are brought into conduction via the guide fitting 20.

Therefore, according to the conduction clip 2 of this embodiment, the main body B1 can be simply attached to the open end of the main body B1.
Electromagnetic waves that try to pass through the gap between the opening edge of the cover B2 and the lid B2 can be reliably blocked. In addition, the conductive clip 2 of the present embodiment is mounted so that the opening end of the main body B1 is located between the pair of guide pieces 24 of the guide fitting 20 and is simply attached to the opening end by pushing. The work is easy, and the main body B is used for attaching the conduction clip 2.
There is no need to perform any special processing around the opening end of No. 1 or the lid body B2 facing the opening end, and the structure of the housing B is not complicated.

Next, FIG. 6 shows the conductive clip 2 of this embodiment.
Another example of the use of the conductive substrate P1 and the conductive substrate P3 which are sandwiched by the insulative substrate P2 is held, and the conductive substrate P2 is sandwiched by the insulative substrate P2. It can be used when electrically conductive substrates P1 and P3 are electrically connected to each other. Further, it may be used when only a plurality of conductive substrates are overlapped and sandwiched and brought into contact with each other for electrical conduction.

Note that, in FIGS. 4, 5, and 6, the projection 16 of the holding metal fitting 10 is omitted in order to simplify the drawing. Further, in the above embodiment, the holding metal fitting 10 is made of a conductive material.
An insulating material such as plastic may be used as long as a sufficient holding force can be obtained when the open end of 4 is pushed open. In this case, even if electronic components are arranged in the vicinity of the end portion of the board on which the conductive clip 2 is mounted, it is possible to prevent short-circuiting between the board and the electronic components, and ensure high safety. Further, it is possible to prevent the guide fitting 20 from being easily rusted by a finger or the like and being deteriorated in conductivity of the guide fitting 20.

Next, FIG. 7 is a perspective view showing the overall construction of the conducting clip 3 of the second embodiment. As shown in FIG.
The conducting clip 3 of this embodiment has the same constitution as the conducting clip 2 of the first embodiment as a basic constitutional unit 3a.
A number of the basic structural units 3a are connected, and the structure of the holding metal fitting 11 and the guide metal fitting 21 for each basic structural unit 3a is as follows.
Since it is exactly the same as the conduction clip 2 of the first embodiment, the same reference numerals are given to the corresponding configurations, and the detailed description thereof will be omitted here. Notches 3b and 3c are formed at the boundary of the basic structural unit 3a.
It can be cut every a.

According to the conductive clip 3 of this embodiment having the above-described structure, the basic clip 3a can be cut into individual pieces to be adjusted to a desired length for use. Further, since it contacts the substrate P and the like over a wide range and clamps the substrate P, the reliability of conduction and mounting can be improved.

Next, FIG. 8 is a perspective view showing a state in which the conducting clips 4 and 5 of the third and fourth embodiments are mounted on the substrate P. As shown in FIG. 8A, in the conductive clip 4 of the third embodiment, the hole 38 is formed in the base portion 32 of the holding metal fitting 30, and the guide piece 44 is erected at the connecting portion 42 of the guide metal fitting 40. A curved portion 42a formed in a curved shape protruding toward the side opposite to the installation direction is provided.
When 0 is accommodated in the holding metal fitting 30, the curved portion 42 projects from the hole 38 provided in the base portion 32 of the holding metal fitting 30, and at the tip end portion of the guide piece 44, the connecting portion 42 A tongue-shaped portion formed by making a U-shaped cut in three directions other than the side is folded back to the inside to form a first spring portion 44d, and the surrounding portion is folded back to the outside to form a second spring portion. The structure is exactly the same as that of the first embodiment except that it is set to 44e. In this embodiment, not only the second spring portion 44e but also the curved portion 42a corresponds to the spring portion of the present invention.

FIG. 9A is a side view showing a state in which the conductive clip 4 of this embodiment is mounted on the substrate P on which the pattern G to be grounded is formed, and FIG. 9B is the conductive clip. 4 is an explanatory diagram showing a state in which the board P on which No. 4 is mounted is inserted into the guide rail GR of the housing. FIG.

As shown in FIG. 9A, on the substrate P, patterns G to be electrically connected to each other are formed at least at the portions where the first spring portions 24d are in contact with each other.
Only by mounting the conduction clip 2, the patterns G formed on the front and back surfaces of the substrate P can be surely conducted.

Then, as shown in FIG. 9B, when the end portion of the board P on which the conduction clip 4 is mounted is inserted into the guide rail GR of the housing, the second spring portion 44e and the bending portion 42a are guided. Since the rail GR comes into contact with the wall surface and the bottom surface of the rail GR, the conductive portion G formed on the substrate P is guided by the guide fitting 40.
Is surely grounded via. Further, by the urging force of the second spring portion 44e and the bending portion 42a housed in the guide rail GR in an elastically deformed state, that is, the urging force that pushes open between the holding metal fitting 10 and the guide rail GR, The end portion of the board P on which the conduction clip 2 is attached is a guide rail G.
It is securely held in R without rattling.

Therefore, according to the conductive clip 4 of this embodiment, the pattern G formed on the substrate P can be grounded easily and satisfactorily. In addition, the fourth shown in FIG.
Similar to the second embodiment with respect to the first embodiment, the conducting clip 5 of the embodiment has the conducting clip 4 of the third embodiment as a basic structural unit 5a, and a plurality of basic structural units 5a are connected.

Next, FIG. 10 shows a conducting clip 6 of the fifth embodiment. In the conducting clip 6 of this embodiment, the notch 50a is provided by notching the middle portion of the holding piece 50 of the holding metal fitting 50, which is divided into three substantially equal parts, from the open end side in a U-shape. Point, the middle portion of the guide piece 64 of the guide fitting 60, which is divided into three equal parts, is formed into a curved shape that is convex outward, and the tip end portion is folded back inward to form the second spring. 1st spring part 64d is formed by folding back inward the tip parts of both sides of the guide piece 64 divided into three parts. The configuration is exactly the same as that of the embodiment. The long holes 66 into which the protrusions 56 formed on the holding metal fitting 50 are loosely fitted are formed on both sides of the guide piece 64 divided into three parts.

When the conductive clip 6 of this embodiment having the above-mentioned structure is mounted on the board P, the notch 5 of the holding metal fitting 50 is attached.
The convex portion 64e projects from 0a. Therefore,
As shown in FIG. 9B, when the end portion of the board P on which the conduction clip 6 is attached is inserted into the guide rail GR,
Since the convex portion 64e slides in contact with the opening edge of the guide rail GR and is inserted into the guide rail GR while elastically deforming in the direction in which the protrusion of the convex portion 64e becomes smaller, the conduction clip 6 is attached. The board P can be easily inserted into the guide rail GR, and the convex portion 64e housed in the guide rail GR in an elastically deformed state is urged by both the surface of the board P and the side wall of the guide rail GR. Since they are in close contact with each other in a closed state, it is possible to ensure electrical conduction between them.

As in the second embodiment to the first embodiment and the fourth embodiment to the third embodiment, the conductive clip 6 of this embodiment is used as a basic constituent unit, and a plurality of the basic constituent units are connected. By doing so, the conduction clip may be configured.

[Brief description of drawings]

FIG. 1 is a perspective view showing an overall configuration of a conductive clip according to a first embodiment.

FIG. 2 is a side view of a single guide metal fitting, a single holding metal fitting, and a conduction clip in which these are assembled.

FIG. 3 is an explanatory diagram showing a method of using a conductive clip.

FIG. 4 is a perspective view showing an overall configuration of a shield housing using a conductive clip as an electromagnetic wave shield material.

FIG. 5 is a sectional view taken along the line AA of FIG. 4;

FIG. 6 is an explanatory diagram showing another usage example of the conductive clip.

FIG. 7 is a perspective view showing a configuration of a conductive clip according to a second embodiment.

FIG. 8 is a perspective view showing a configuration of a conduction clip according to third and fourth embodiments.

FIG. 9 is an explanatory diagram showing a usage state of the conductive clip of the third embodiment.

FIG. 10 is an explanatory diagram showing a configuration of a conduction clip according to a fifth embodiment.

[Explanation of symbols]

2, 3, 4, 5, 6 ... Conduction clip 10, 11, 3
0,50 ... Holding metal fitting 12,32 ... Base portion 14,34 ... Clamping piece 16,5
6 ... Protrusion 20, 21, 40, 60 ... Guide metal fitting 22, 42 ...
Connecting parts 24, 44, 64 ... Guide pieces 26, 66 ... Long holes
38 ... Hole 42a ... Curved part 50a ... Notch

Claims (6)

[Claims] 1. An end portion of a first conductive member is sandwiched, and
A conduction clip for abutting a second conductive member arranged near an end of the first conductive member to electrically connect the two conductive members to each other, the base clip having a flat plate shape and erected on both ends of the base. And a holding member formed such that the width of the holding piece on the open end side is narrower than that on the base side, and the width of the holding piece is substantially the same as the width of the open end of the holding piece. The guide piece is composed of a formed connecting portion and a pair of guide pieces erected at both ends of the connecting portion, and the guide piece is formed such that the width of the open end side is wider than the connecting portion side. The guide member is configured to be elastically deformable in the direction of opening and closing the open end of the guide member, and the holding member allows the guide member to be inserted and removed from the open end of the holding piece. While storing it, the guide fitting should be attached to the holding member. Of the second member when the
A conducting clip, characterized in that a spring portion is formed which contacts the conductive member in a biased state. 2. The conduction clip according to claim 1, wherein the holding member is made of an insulating material. 3. The conduction clip according to claim 1, wherein the spring portion is formed by folding back at least a part of an open end portion of the guide piece in an outward direction of the guide metal fitting. . 4. The spring portion projects from the connecting portion toward the base portion of the holding member, and the base portion of the holding member is formed with an opening through which the spring portion can be inserted. The conduction clip according to claim 1 or 2, which is characterized. 5. The conduction clip according to claim 1, wherein a part of the open end of the guide piece is folded back inward of the guide fitting. 6. The guide piece of the guide fitting is formed with a long hole elongated in the protruding direction of the guide piece, and the holding piece of the holding member is loosely fitted in the long hole to provide the guide fitting of the guide fitting. The conduction clip according to any one of claims 1 to 5, wherein the guide clip is formed with a protrusion that restricts the movement direction and prevents the guide fitting from falling off the holding member.