JP2021170448A - Battery terminal - Google Patents

Abstract

To provide a battery terminal which can be appropriately fitted to a battery post.SOLUTION: A battery terminal 1 comprises: a battery terminal body 20 which is provided with post insertion holes 20f, 20g into which a battery post P is inserted along an axial direction X, and flange parts 20fa, 20ga which protrude along the axial direction X from edges of the post insertion holes 20f, 20g, respectively; a fastening mechanism 30 which couples the battery terminal body 20 to the battery post P by fastening the battery terminal body 20 with the battery post P inserted in the post insertion holes 20f, 20g; and a temporary fastening member 40 which is provided on the battery terminal body 20 separately from the fastening mechanism 30 so as to reduce the diameter of the post insertion hole 20f by fastening the flange part 20fa with the battery post P inserted in the post insertion holes 20f, 20g.SELECTED DRAWING: Figure 1

Description

The present invention relates to a battery terminal.

As a conventional battery terminal, for example, Patent Document 1 discloses a battery terminal with a resin component, which is formed by assembling a resin component for a battery terminal to a battery terminal connected to a battery post of a battery.

Japanese Unexamined Patent Publication No. 2010-160990

By the way, the battery terminal with resin parts described in Patent Document 1 described above is properly attached to the battery post by, for example, restricting the assembly angle of the battery terminal with respect to the battery post by the resin parts for the battery terminal. In this case, for the battery terminal with resin parts, for example, it is necessary to manufacture the resin parts for the battery terminal for each size of the battery to be mounted and the required assembly angle, and there is room for further improvement in this respect.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a battery terminal that can be properly attached to a battery post.

In order to achieve the above object, the battery terminal according to the present invention has a post insertion hole into which a battery post is inserted along the axial direction, and a flange portion protruding from the edge of the post insertion hole along the axial direction. A tightening mechanism for fastening the battery terminal body to the battery post by tightening the battery terminal body in a state where the battery post is inserted into the post insertion hole. A temporary tightening member provided in the battery terminal body separately from the tightening mechanism and tightening the flange portion to reduce the diameter of the post insertion hole in a state where the battery post is inserted into the post insertion hole. It is characterized by being prepared.

Further, in the battery terminal, the temporary tightening member may be formed in an annular shape and mounted on the flange portion along the axial direction.

Further, in the battery terminal, the temporary tightening member may have a circular cross-sectional shape.

Further, in the battery terminal, the battery terminal main body faces each other along the axial direction, and includes the post insertion hole and a pair of plate-shaped portions on which the flange portion is formed, respectively, and the temporary tightening is performed. The member is a first diameter-reduced portion that sandwiches and tightens the flange portion of one of the pair of plate-shaped portions, and the flange of the other plate-shaped portion of the pair of plate-shaped portions. The first reduced diameter portion and the second reduced diameter portion include a second reduced diameter portion that sandwiches and tightens the portions, and a connecting portion that connects the first reduced diameter portion and the second reduced diameter portion. Can be mounted on each of the flange portions along a direction intersecting the axial direction via a notch provided in each.

Further, in the battery terminal, the pair of plate-shaped portions are formed so that the flange portions project from each other along the axial direction, and the temporary tightening member is formed by the first reduced diameter portion. And, with the second reduced diameter portion attached to each of the flange portions, the pair of plate-shaped portions between the first reduced diameter portion and the second reduced diameter portion in the axial direction. Can be sandwiched.

Further, in the battery terminal, the tightening mechanism may fasten the battery terminal body to the battery post by rotating a fastening member extending along the axis direction around the axis direction. can.

The battery terminal according to the present invention is to fasten the battery terminal body to the battery post by tightening the battery terminal body by a tightening mechanism in a state where the battery post is inserted into the post insertion hole formed in the battery terminal body. Can be done. In this case, with the battery post inserted in the post insertion hole, the battery terminal tightens the flange of the battery terminal body with a temporary tightening member provided separately from the tightening mechanism to reduce the diameter of the post insertion hole. can do. With this configuration, before the battery terminal body is tightened by the tightening mechanism, the battery terminal body can be temporarily tightened with respect to the battery post by a temporary tightening member to regulate the rotation around the battery post. On that basis, the battery terminal can be fastened to the battery terminal body by a tightening mechanism. As a result, the battery terminal has an effect that it can be properly attached to the battery post.

FIG. 1 is a perspective view showing a schematic configuration of a battery terminal according to the first embodiment. FIG. 2 is an exploded perspective view showing a schematic configuration of the battery terminal according to the first embodiment. FIG. 3 is a perspective view showing a schematic configuration of the battery terminal according to the first embodiment. FIG. 4 is an exploded perspective view showing a schematic configuration of the battery terminal according to the first embodiment. FIG. 5 is a cross-sectional view showing a schematic configuration of the battery terminal according to the first embodiment. FIG. 6 is an exploded perspective view showing a schematic configuration of the battery terminal according to the second embodiment. FIG. 7 is a perspective view showing a schematic configuration of the battery terminal according to the second embodiment. FIG. 8 is a cross-sectional view showing a schematic configuration of the battery terminal according to the second embodiment.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the drawings. The present invention is not limited to this embodiment. In addition, the components in the following embodiments include those that can be easily replaced by those skilled in the art, or those that are substantially the same.

In the following description, of the first direction, the second direction, and the third direction that intersect each other, the first direction is referred to as "axis direction X", and the second direction is referred to as "first width direction Y". The third direction is called "second width direction Z". Here, the axial direction X, the first width direction Y, and the second width direction Z are substantially orthogonal to each other. The axial direction X typically corresponds to the direction along the central axis C1 of the battery post provided with the battery terminal, the height direction of the battery, and the like. The first width direction Y typically corresponds to the tightening direction of the battery terminal, the short side direction of the battery, and the like. The second width direction Z typically corresponds to the direction in which the fastening portion and the holding portion are lined up, the long side direction of the battery, and the like. Further, the first width direction Y and the second width direction Z typically correspond to the intersection direction intersecting the axial direction X. Typically, with the battery terminals installed in the vehicle and the vehicle located in the horizontal plane, the axial direction X is along the vertical direction, and the first width direction Y and the second width direction Z are along the horizontal direction. Unless otherwise specified, each direction used in the following description shall represent a direction in which each part is assembled to each other.

[Embodiment 1]
The battery terminal 1 of the present embodiment shown in FIGS. 1 and 2 is a component for electrically connecting the battery B and the connection terminal T as a connection partner member by being assembled to the battery post P.

The battery B is mounted on a vehicle or the like as a power storage device. In the battery B, a battery post P is erected in a battery housing Ba that houses the battery liquid and various components. The battery post P is a lead electrode and is erected on one surface of the battery housing Ba, typically, a surface located on the upper side in the vertical direction with the battery B mounted on the vehicle. The battery post P projects from the upper surface of the battery housing Ba in the vertical direction toward the upper side in the vertical direction. The battery post P is formed in a columnar shape, more specifically, a columnar shape tapered so that the diameter decreases toward the tip side. The battery post P is arranged so that the central axis C1 is along the axis direction X (vertical direction), and extends in a columnar shape along the axis direction X. A total of two battery posts P are provided in one battery B, one as a positive electrode (plus (+) electrode) and one as a negative electrode (minus (-) electrode) (one in FIGS. 1, 2 and the like). Only the side is shown). Further, the connection terminal T is provided at the end of the electric wire W distributed to the vehicle equipped with the battery B, and constitutes a connection partner member. The battery terminal 1 is fastened to the battery post P configured as described above, and the connection terminal T is electrically connected.

The battery terminal 1 of the present embodiment can be properly attached to the battery post P by providing a temporary tightening member 40 separately from the tightening mechanism 30 that fastens the battery terminal body 20 to the battery post P. The configuration is realized. Hereinafter, each configuration of the battery terminal 1 will be described in detail with reference to each figure.

Specifically, as shown in FIGS. 3, 4, and 5, the battery terminal 1 includes a stud bolt 10, a battery terminal body 20, a tightening mechanism 30, and a temporary tightening member 40.

The stud bolt 10 is a fastening member that is held by the battery terminal body 20 and to which the connection terminal T is electrically connected. The stud bolt 10 includes a base portion 10a and a shaft portion 10b, and these are integrally formed of a conductive metal material. The base portion 10a is a portion held by the battery terminal main body 20 and constitutes a so-called bolt head. The base portion 10a is formed as a portion having a diameter larger than that of the shaft portion 10b, and constitutes a pedestal portion on which the shaft portion 10b is erected. The shaft portion 10b is a portion formed so as to project from the base portion 10a to one side along the axial direction X and to which the connection terminal T is fastened. The shaft portion 10b is formed in a substantially columnar shape whose central axis is along the axis direction X. The shaft portion 10b is formed with a screw groove on the outer peripheral surface on which the nut 11 can be screwed.

The battery terminal body 20 is a main portion that has conductivity and is fastened to the battery post P. The battery terminal body 20 includes a fastening portion 21 fastened to the battery post P and a holding portion 22 for holding the stud bolt 10, and these are integrally formed of a conductive metal material. The fastening portion 21 and the holding portion 22 are adjacently connected and electrically connected along the second width direction Z.

The fastening portion 21 includes a pair of plate-shaped portions 20a and 20b, and a bending connecting portion 20c. The holding portion 22 includes a pair of holding plate-shaped portions 20d and 20e. The battery terminal body 20 is formed by, for example, performing a press bending process on a conductive metal plate to form a pair of plate-shaped portions 20a and 20b, a bent connecting portion 20c, and a pair of holding plate-shaped portions 20d. , 20e are integrally formed. As a whole, the battery terminal body 20 is folded back in a substantially U shape with the bent connecting portion 20c interposed therebetween, and the plate-shaped portion 20a, the holding plate-shaped portion 20d, the plate-shaped portion 20b, and the holding plate-shaped portion 20e are in the axial direction, respectively. It is composed of a two-layer laminated structure that is laminated so as to face each other along X.

More specifically, the pair of plate-shaped portions 20a and 20b are formed in a substantially rectangular annular shape and a plate shape, each having various uneven shapes and notch shapes. The plate-shaped portions 20a and 20b extend in the plate thickness direction along the axial direction X and along the first width direction Y and the second width direction Z. The plate-shaped portion 20a and the plate-shaped portion 20b are integrally formed so that the ends on one side (opposite side of the holding portion 22 side) of the second width direction Z are continuous with each other via the bending connecting portion 20c. NS. The pair of plate-shaped portions 20a and 20b are located so as to face each other along the axial direction X in a state of being spaced along the axial direction X. In the fastening portion 21, the plate-shaped portion 20a is located on the upper side in the vertical direction (the side opposite to the installation surface of the battery post P), and the plate-shaped portion 20b is located on the lower side in the vertical direction (the installation surface side of the battery post P). To position.

The pair of plate-shaped portions 20a and 20b are formed in a substantially rectangular annular shape as described above by forming the post insertion holes 20f and 20g, respectively. The post insertion holes 20f and 20g are holes into which the battery post P is inserted along the axial direction X, and penetrate the plate-shaped portions 20a and 20b along the axial direction X, respectively. The post insertion holes 20f and 20g are formed in a substantially circular shape according to the outer diameter shape of the battery post P. The post insertion hole 20f and the post insertion hole 20g are formed in a positional relationship in which a pair of plate-shaped portions 20a and 20b face each other along the axial direction X in a state of being stacked vertically via the bending connecting portion 20c. The post insertion holes 20f and 20g are formed with a taper corresponding to the taper of the battery post P on the inner peripheral wall surface thereof. Here, the pair of plate-shaped portions 20a and 20b are formed so that the inner diameter of the post insertion hole 20f located on the side opposite to the installation surface of the battery post P is relatively small, and is located on the installation surface side of the battery post P. The inner diameter of the post insertion hole 20 g to be formed is formed to be relatively large. The inner peripheral wall surfaces of the post insertion holes 20f and 20g come into contact with the battery post P in a state where the battery post P is inserted.

Then, the pair of plate-shaped portions 20a and 20b of the present embodiment are formed with flange portions 20fa and 20ga protruding from the edges of the post insertion holes 20f and 20g along the axial direction X, respectively. The flange portion 20fa is formed in the plate-shaped portion 20a so as to project from the edge of the post insertion hole 20f along the axial direction X to the side opposite to the plate-shaped portion 20b (the side opposite to the installation surface of the battery post P). .. On the other hand, the flange portion 20ga is formed in the plate-shaped portion 20b so as to project from the edge of the post insertion hole 20g along the axial direction X to the side opposite to the plate-shaped portion 20a (the installation surface side of the battery post P). That is, the pair of plate-shaped portions 20a and 20b are formed so that the flange portions 20fa and 20ga project from each other along the axial direction X.

The flange portion 20fa forms the tapered inner peripheral wall surface of the post insertion hole 20f by folding back the metal plate constituting the plate-shaped portion 20a to the side opposite to the plate-shaped portion 20b. Similarly, in the flange portion 20ga, the metal plate constituting the plate-shaped portion 20b is folded back to the side opposite to the plate-shaped portion 20a to form the tapered inner peripheral wall surface of the post insertion hole 20g. The flange portions 20fa and 20ga are formed in a substantially arc shape along the edges of the post insertion holes 20f and 20g, respectively, so as to surround the post insertion holes 20f and 20g. Here, the flange portions 20fa and 20ga are formed in a substantially arc shape whose central axis is along the axis direction X.

Then, in the fastening portion 21, a slit (gap) 20h is formed over the pair of plate-shaped portions 20a and 20b and the bending connecting portion 20c. The slit 20h extends along the second width direction Z at the end of the pair of plate-shaped portions 20a and 20b on the bending connecting portion 20c side and is continuous with the post insertion holes 20f and 20g, and at the bending connecting portion 20c. It extends along the axial direction X. In other words, the slit 20h is formed so as to extend from the post insertion holes 20f and 20g to the bending connecting portion 20c so as to divide a part of the plate-shaped portions 20a and 20b. The flange portions 20fa and 20ga described above are formed in a substantially arc shape in which a portion corresponding to the slit 20h is cut out. In the fastening portion 21, the portion where the slit 20h is formed at the end portion of the pair of plate-shaped portions 20a and 20b on the bending connecting portion 20c side constitutes the tightening end portion 20i. The tightening end portion 20i is a portion that is tightened by the tightening mechanism 30 when the battery terminal body 20 is fastened to the battery post P.

The pair of holding plate-shaped portions 20d and 20e are formed in a substantially rectangular plate shape with various uneven shapes and notched shapes, respectively. The holding plate-shaped portions 20d and 20e extend in the plate thickness direction along the axial direction X and along the first width direction Y and the second width direction Z. The holding plate-shaped portion 20d is integrally formed with the plate-shaped portion 20a so as to be continuous along the second width direction Z. The holding plate-shaped portion 20e is integrally formed with the plate-shaped portion 20b so as to be continuous along the second width direction Z. Here, the holding plate-shaped portions 20d and 20e are continuous with a step between the plate-shaped portions 20a and 20b, respectively. In the pair of holding plate-shaped portions 20d and 20e, an insertion hole 20j is formed on the holding plate-shaped portion 20d side. The insertion hole 20j is a hole through which the shaft portion 10b of the stud bolt 10 is inserted.

In the holding portion 22, for example, the pair of holding plate-shaped portions 20d and 20e are bent in a state where the shaft portion 10b of the stud bolt 10 is inserted into the insertion hole 20j in advance before the bending process. As a result, the holding portion 22 is in a state in which a pair of holding plate-shaped portions 20d and 20e are vertically laminated along the axial direction X, and the laminated holding plate-shaped portions 20d and 20e make the stud bolt 10 The base portion 10a of the above is sandwiched and held along the axial direction X. That is, the pair of holding plate-shaped portions 20d and the holding plate-shaped portions 20e are laminated so as to face each other and hold the base portion 10a between them.

In the stud bolt 10, the shaft portion 10b is inserted into the insertion hole 20j with the base portion 10a held between the holding plate-shaped portion 20d and the holding plate-shaped portion 20e, and the insertion hole 20j is inserted along the axial direction X. Penetrate. As a result, the shaft portion 10b of the stud bolt 10 is exposed by protruding from the insertion hole 20j along the axial direction X, and the connection terminal T is fastened to the exposed shaft portion 10b via the nut 11 so that the stud bolt 10 can be electrically connected. Is. The stud bolt 10 has a shaft portion 10b in which a nut 11 is screwed into the shaft portion 10b in a state where the connection terminal T is assembled so that the shaft portion 10b is inserted into the insertion hole Ta of the connection terminal T. The connection terminal T is fastened to the connection terminal T, and the connection terminal T and the holding plate-shaped portion 20d of the fastening portion 21 are electrically connected to each other.

The tightening mechanism 30 is a mechanism for fastening the battery terminal body 20 to the battery post P by tightening the tightening end portion 20i of the fastening portion 21 of the battery terminal body 20 along the first width direction Y. As an example, the tightening mechanism 30 includes a plate nut 31 as a penetrating member, a fastening bolt 32 as a fastening member, and a bracket 33 as a pressing force conversion member, which work together to form a tightening end portion 20i. Is generated along the first width direction Y. Here, the tightening mechanism 30 constitutes a top-tightening type mechanism for fastening the battery terminal body 20 to the battery post P by rotating the fastening bolt 32 extending along the axial direction X around the axial direction X. do. The tightening mechanism 30 is inserted into the tightening end portion 20i so that the plate nut 31 crosses the slit 20h along the first width direction Y, and the fastening bolt 32 and the bracket are inserted into the plate nut 31. By assembling 33, it is attached to the tightening end portion 20i.

The battery terminal 1 configured as described above has the tightening end portion 20i inserted by the tightening mechanism 30 in a state where the battery post P is inserted into the post insertion holes 20f and 20g of the fastening portion 21 of the battery terminal main body 20. By tightening, it is fastened to the battery post P. Although detailed description is omitted here, when the battery terminal body 20 is fastened to the battery post P, the tightening mechanism 30 is a fastening bolt with the battery post P inserted in the post insertion holes 20f and 20 g. The 32 is tightened along the axial direction X. As a result, the tightening mechanism 30 generates a tightening force along the axial direction X between the fastening bolt 32 and the plate nut 31. Then, the tightening mechanism 30 converts the generated tightening force into a pressing force along the first width direction Y by the action of the plate nut 31 and the bracket 33. Then, the tightening mechanism 30 tightens the tightening end portion 20i via the plate nut 31 and the bracket 33 by the converted pressing force so as to narrow the width of the slit 20h along the first width direction Y. .. As a result, the tightening mechanism 30 can reduce the diameter of the post insertion holes 20f and 20g, and fasten the battery terminal body 20 to the battery post P to conduct conduction.

The temporary tightening member 40 is provided in the battery terminal body 20 separately from the tightening mechanism 30, and with the battery post P inserted in the post insertion holes 20f and 20g, the flange portion 20fa is tightened to form the post insertion hole 20f. It is a member that reduces the diameter. The temporary tightening member 40 is typically a member for temporarily tightening the battery terminal body 20 to the battery post P before tightening the battery terminal body 20 by the tightening mechanism 30.

The temporary tightening member 40 of the present embodiment is composed of a ring member formed in a substantially annular shape. The temporary tightening member 40 is made of a material having relatively high rigidity. The temporary tightening member 40 is typically formed of a metal material, but is not limited to this, and may be formed of a resin material having relatively high rigidity and dilute sulfuric acid resistance. The temporary tightening member 40 is attached to the flange portion 20fa of the two flange portions 20fa and 20ga.

The temporary tightening member 40 is formed in a substantially annular shape whose central axis is along the axial direction X, corresponding to the outer shape of the flange portion 20fa formed in a substantially arc shape. The temporary tightening member 40 is formed so that the inner diameter R1 (see FIG. 4) is slightly smaller than the outer diameter R2 (see FIG. 4) of the flange portion 20fa before being mounted on the flange portion 20fa.

With this configuration, the temporary tightening member 40 is mounted on the flange portion 20fa along the axial direction X with the battery post P inserted in the post insertion holes 20f and 20g, so that the outer peripheral surface of the flange portion 20fa is attached. It is press-fitted to the side. As a result, the temporary tightening member 40 can tighten the flange portion 20fa to reduce the diameter of the post insertion hole 20f, and the battery terminal body 20 can be temporarily fixed to the battery post P.

Here, the temporary tightening member 40 has a substantially circular cross-sectional shape (see FIG. 5) in a cross section in the direction along the central axis. With this configuration, the temporary tightening member 40 can be easily press-fitted to the flange portion 20fa.

In the battery terminal 1 configured as described above, the battery post P is inserted into the post insertion holes 20f and 20g along the axial direction X in a state where the temporary tightening member 40 is not assembled. Then, the battery terminal 1 is desired with respect to the battery post P before the battery terminal body 20 is tightened (mainly fastened) by the tightening mechanism 30 in a state where the battery post P is inserted into the post insertion holes 20f and 20 g. It is aligned with the mounting position of. Then, in a state where the battery terminal 1 is aligned with the battery post P, the temporary tightening member 40 is press-fitted into the flange portion 20fa along the axial direction X, and is mounted on the flange portion 20fa. As a result, the temporary tightening member 40 tightens the flange portion 20fa to reduce the diameter of the post insertion hole 20f, and has a predetermined size on the contact surface between the inner peripheral wall surface of the post insertion hole 20f and the outer peripheral surface of the battery post P. Friction resistance can be added. As a result, in the battery terminal 1, the battery terminal body 20 is temporarily tightened with respect to the battery post P at a desired mounting position by the temporary tightening member 40, rotation around the battery post P is restricted, and the battery terminal 1 is temporarily tightened at a desired assembly angle. It is fixed. Then, the battery terminal 1 is tightened by rotating the fastening bolt 32 around the axial direction X in a state where the rotation around the battery post P is restricted by the temporary tightening member 40, thereby tightening the battery terminal main body by the tightening mechanism 30. Twenty main conclusions can be made.

The battery terminal 1 described above is a battery terminal by tightening the battery terminal body 20 by the tightening mechanism 30 in a state where the battery post P is inserted into the post insertion holes 20f and 20g formed in the battery terminal body 20. The main body 20 can be fastened to the battery post P. In this case, the battery terminal 1 has a flange portion 20fa of the battery terminal body 20 by a temporary tightening member 40 provided separately from the tightening mechanism 30 in a state where the battery post P is inserted into the post insertion holes 20f and 20g. Can be tightened to reduce the diameter of the post insertion hole 20f. With this configuration, the battery terminal 1 temporarily tightens the battery terminal body 20 to the battery post P at a desired mounting position by the temporary tightening member 40 before tightening the battery terminal body 20 by the tightening mechanism 30. The rotation around P can be regulated. Then, the battery terminal 1 can fasten the battery terminal body 20 by the tightening mechanism 30 after restricting the assembly angle of the battery terminal body 20 with respect to the battery post P at a desired angle. As a result, the battery terminal 1 can be properly attached to the battery post P at a desired attachment position.

Further, the battery terminal 1 can be temporarily tightened at a desired mounting position by a common temporary tightening member 40 regardless of the size of the battery B to be mounted, the required mounting position, and the like, and the assembly angle can be regulated. can. As a result, the battery terminal 1 can be properly attached to the battery post P as described above after improving versatility. In this case, for the battery terminal 1, for example, it is not necessary to manufacture a stopper member or the like for each size of the battery B to be mounted and a required mounting position, so that the manufacturing cost can be suppressed.

Here, in the battery terminal 1 described above, the temporary tightening member 40 is formed in an annular shape and is mounted on the flange portion 20fa along the axial direction X. With this configuration, the battery terminal 1 can tighten the flange portion 20fa with the temporary tightening member 40 to reduce the diameter of the post insertion hole 20f, and the battery terminal body 20 can be temporarily tightened to the battery post P. can. As a result, the battery terminal 1 can be properly attached to the battery post P as described above while suppressing the manufacturing cost.

Further, since the battery terminal 1 described above has a substantially circular cross-sectional shape of the temporary tightening member 40, it can be easily press-fitted to the flange portion 20fa. As a result, the battery terminal 1 can be properly attached to the battery post P as described above after improving the assembling workability.

Further, the battery terminal 1 described above is configured to fasten the battery terminal body 20 to the battery post by rotating the fastening bolt 32 around the axial direction X. Therefore, when the fastening bolt 32 is rotated around the axial direction X, the battery terminal 1 tends to rotate as a whole around the battery post P. On the other hand, in the battery terminal 1, the battery terminal body 20 is temporarily tightened to the battery post P by the temporary tightening member 40 before the fastening work of the fastening bolt 32 as described above, so that the fastening bolt 32 is fastened. When rotated, it is possible to regulate the whole rotation around the battery post P. As a result, the battery terminal 1 can exert the effect of restricting the rotation of the battery terminal body 20 by the temporary tightening member 40 more remarkably, and exert the effect of being properly attached to the battery post P more remarkably. be able to.

[Embodiment 2]
The structure of the temporary tightening member 40 of the battery terminal according to the second embodiment is different from that of the first embodiment. In the following, the same components as those in the above-described embodiment are designated by a common reference numeral, and the common configurations, actions, and effects will be omitted as much as possible (the same shall apply hereinafter).

The battery terminal 201 of the present embodiment shown in FIGS. 6, 7, and 8 is different from the battery terminal 1 described above in that the temporary tightening member 240 is provided instead of the temporary tightening member 40. The other configurations of the battery terminal 201 are substantially the same as those of the battery terminal 1 described above.

Like the temporary tightening member 40, the temporary tightening member 240 is provided in the battery terminal main body 20 separately from the tightening mechanism 30, and the flange portion 20fa is provided with the battery post P inserted in the post insertion holes 20f and 20g. Is a member for reducing the diameter of the post insertion hole 20f by tightening. The temporary tightening member 240 is also typically a member for temporarily tightening the battery terminal body 20 to the battery post P before tightening the battery terminal body 20 by the tightening mechanism 30.

The temporary tightening member 240 of the present embodiment is composed of a spacer member including a first reduced diameter portion 241 and a second reduced diameter portion 242, and a connecting portion 243. In the temporary tightening member 240, the first reduced diameter portion 241 and the second reduced diameter portion 242, and the connecting portion 243 are integrally formed of a metal material having relatively high rigidity or the like. The temporary tightening member 240 may be formed of a resin material having relatively high rigidity and dilute sulfuric acid resistance. The temporary tightening member 240 of the present embodiment is mounted over two flange portions 20fa and 20ga.

The first reduced diameter portion 241 is a portion that is attached to the flange portion 20fa of one of the pair of plate-shaped portions 20a and 20b and that sandwiches and tightens the flange portion 20fa. The first reduced diameter portion 241 is formed in a substantially arc shape whose central axis is along the axial direction X, corresponding to the outer shape of the flange portion 20fa formed in a substantially arc shape. More specifically, the first reduced diameter portion 241 includes a pair of arm portions 241b and 241c formed in a plate shape whose thickness direction is along the axial direction X and formed in a substantially arc shape through the notch 241a. Consists of including. The first reduced diameter portion 241 has a notch 241a located on one side in the first width direction Y, and the inner peripheral surfaces of the pair of arm portions 241b and 241c are formed in a substantially arc shape corresponding to the outer shape of the flange portion 20fa. Will be done. Here, in the first reduced diameter portion 241, the inner peripheral surfaces of the pair of arm portions 241b and 241c serve as contact surfaces with the flange portion 20fa, and the inner peripheral surface (contact surface) is a taper of the outer peripheral surface of the flange portion 20fa. It is formed in a tapered shape along the shape.

The second diameter-reduced portion 242 is a portion that is attached to the flange portion 20ga of the other plate-shaped portion 20b of the pair of plate-shaped portions 20a and 20b, and sandwiches and tightens the flange portion 20ga. The second reduced diameter portion 242 is formed in a substantially arc shape whose central axis is along the axial direction X, corresponding to the outer shape of the flange portion 20 ga formed in a substantially arc shape. More specifically, the second reduced diameter portion 242 is formed in a plate shape whose thickness direction is along the axial direction X, and is formed in a substantially arc shape through the notch 242a, similarly to the first reduced diameter portion 241. It is configured to include a pair of arm portions 242b and 242c. The second reduced diameter portion 242 has a notch 242a located on one side in the first width direction Y, and the inner peripheral surfaces of the pair of arm portions 242b and 242c are formed in a substantially arc shape corresponding to the outer shape of the flange portion 20ga. Will be done. Here, in the second reduced diameter portion 242, the inner peripheral surface of the pair of arm portions 242b and 242c serves as a contact surface with the flange portion 20ga, and the inner peripheral surface (contact surface) is a taper of the outer peripheral surface of the flange portion 20ga. It is formed in a tapered shape along the shape.

The connecting portion 243 is a portion that connects the first reduced diameter portion 241 and the second reduced diameter portion 242. The connecting portion 243 is formed in a substantially rectangular plate shape, and the plate thickness direction extends along the first width direction Y, and extends along the axial direction X and the second width direction Z. The connecting portion 243 connects the end portion of the first diameter-reduced portion 241 opposite to the notch 241a side and the end portion of the second diameter-reduced portion 242 opposite to the notch 242a side. The temporary tightening member 240 is formed in a substantially U shape as a whole by combining the first reduced diameter portion 241 and the second reduced diameter portion 242 and the connecting portion 243.

Then, in the temporary tightening member 240 configured as described above, the inner diameter R11 (see FIG. 6) of the first reduced diameter portion 241 is flanged in the state before the first reduced diameter portion 241 is mounted on the flange portion 20fa. It is formed to be slightly smaller than the inner diameter R12 (see FIG. 6) of the portion 20fa. Further, in the temporary tightening member 240 configured as described above, the inner diameter R12 (see FIG. 6) of the second reduced diameter portion 242 is flanged in the state before the second reduced diameter portion 242 is mounted on the flange portion 20ga. It is formed to be slightly smaller than the outer diameter R22 (see FIG. 6) of the portion 20ga.

With this configuration, the temporary tightening member 240 is cut so that the first reduced diameter portion 241 and the second reduced diameter portion 242 are provided in the state where the battery post P is inserted into the post insertion holes 20f and 20 g. By being attached to the flange portions 20fa and 20ga along the first width direction Y via the notches 241a and 242a, the first reduced diameter portion 241 and the second reduced diameter portion 242 are attached to the outer circumferences of the flange portions 20fa and 20ga, respectively. It is press-fitted to the surface side. As a result, the temporary tightening member 240 can tighten the flange portions 20fa and 20ga to reduce the diameter of the post insertion holes 20f and 20g, and can temporarily fix the battery terminal body 20 to the battery post P.

Further, here, in the temporary tightening member 240, in a state before the first reduced diameter portion 241 and the second reduced diameter portion 242 are mounted on the flange portions 20fa and 20ga, the interval D1 of the temporary tightening member 240 (see FIG. 6). Is formed slightly narrower than the distance D2 (see FIG. 6) of the battery terminal main body 20. Here, the interval D1 of the temporary tightening member 240 is an interval along the axial direction X between the facing surfaces of the first reduced diameter portion 241 and the second reduced diameter portion 242 in the temporary tightening member 240. On the other hand, the interval D2 of the battery terminal main body 20 is an interval along the axial direction X between the surfaces of the pair of plate-shaped portions 20a and 20b provided with the flange portions 20fa and 20ga.

With this configuration, in the temporary tightening member 240, the battery post P is inserted into the post insertion holes 20f and 20g, and the first reduced diameter portion 241 and the second reduced diameter portion 242 are mounted on the flange portions 20fa and 20ga, respectively. In this state, the pair of plate-shaped portions 20a and 20b are press-fitted so as to be sandwiched between the first reduced diameter portion 241 and the second reduced diameter portion 242 with respect to the axial direction X.

In the battery terminal 201 configured as described above, the battery post P is inserted into the post insertion holes 20f and 20g along the axial direction X in a state where the temporary tightening member 240 is not assembled. Then, the battery terminal 201 is desired with respect to the battery post P before the battery terminal body 20 is tightened (mainly fastened) by the tightening mechanism 30 in a state where the battery post P is inserted into the post insertion holes 20f and 20 g. It is aligned with the mounting position of. Then, in a state where the battery terminal 201 is aligned with respect to the battery post P, the first reduced diameter portion 241 and the second reduced diameter portion 242 of the temporary tightening member 240 have a first width via notches 241a and 242a. It is press-fitted into the flange portions 20fa and 20ga along the direction Y, and is mounted on the flange portions 20fa and 20ga. As a result, the temporary tightening member 240 tightens the flange portions 20fa and 20ga to reduce the diameter of the post insertion holes 20f and 20g, and the contact surface between the inner peripheral wall surface of the post insertion holes 20f and 20g and the outer peripheral surface of the battery post P. A frictional resistance of a predetermined magnitude can be added to the. As a result, in the battery terminal 201, the battery terminal body 20 is temporarily tightened with respect to the battery post P at a desired mounting position by the temporary tightening member 240, rotation around the battery post P is restricted, and the battery terminal 201 is temporarily tightened at a desired assembly angle. It is fixed. Then, the battery terminal 201 is tightened by rotating the fastening bolt 32 around the axial direction X in a state where the rotation around the battery post P is restricted by the temporary tightening member 240, so that the battery terminal main body by the tightening mechanism 30 is tightened. Twenty main conclusions can be made.

In the battery terminal 201 described above, similarly to the battery terminal 1, the battery terminal body 20 is desired to be attached to the battery post P by the temporary tightening member 240 before the battery terminal body 20 is tightened by the tightening mechanism 30. Temporarily tighten at the position to regulate the rotation around the battery post P. As a result, the battery terminal 201 can be properly attached to the battery post P at a desired attachment position.

Here, in the battery terminal 201 described above, the temporary tightening member 240 includes a first reduced diameter portion 241 and a second reduced diameter portion 242, and a connecting portion 243. Then, the battery terminal 201 is attached to the flange portions 20fa and 20ga along the first width direction Y via the notches 241a and 242a, respectively, of the first reduced diameter portion 241 and the second reduced diameter portion 242. .. With this configuration, the battery terminal 201 can tighten both the flange portions 20fa and 20ga with the temporary tightening member 240 to reduce the diameter of the post insertion holes 20f and 20g, so that the battery terminal body 20 can be reliably moved by the battery post P. Can be temporarily tightened. As a result, the battery terminal 201 can be more reliably properly attached to the battery post P as described above.

More specifically, the battery terminal 201 described above has a first reduced diameter portion 241 with respect to the flange portions 20fa and 20ga formed so as to protrude from each other in the pair of plate-shaped portions 20a and 20b. The second reduced diameter portion 242 is attached. Then, in this state, the battery terminal 201 is such that a pair of plate-shaped portions 20a and 20b are sandwiched between the first reduced diameter portion 241 and the second reduced diameter portion 242, and the temporary tightening member 240 is the battery terminal main body 20. It is attached to. With this configuration, the battery terminal 201 can have a structure in which the temporary tightening member 240 does not easily come off from the battery terminal main body 20, so that the battery terminal 201 can be reliably and properly attached to the battery post P. Further, the battery terminal 201 can be prevented from rattling when the temporary tightening member 240 is securely attached to the battery terminal main body 20 so that the battery terminal 201 is mounted on the vehicle and actually used. For example, an abnormal noise can be suppressed. Can be suppressed from occurring.

In the battery terminal 201, the flange portion 20fa for mounting the first reduced diameter portion 241 is exposed to the outside, and the battery terminal 201 can be assembled to the flange portion 20fa while visually checking the first reduced diameter portion 241. Therefore, the assembly workability can be improved.

Further, here, the temporary tightening member 240 is an arm portion of the pair of arm portions 241b and 241c and the pair of arm portions 242b and 242c located on the tightening end portion 20i side in a state of being assembled to the battery terminal main body 20. The lengths of 241b and 242b are formed to be relatively shorter than those of the arm portions 241c and 242c. With this configuration, the battery terminal 201 can be configured such that when the temporary tightening member 240 is assembled to the battery terminal main body 20, the arm portions 241b and 242b do not easily interfere with the uneven shape of the battery terminal main body 20 and the tightening mechanism 30. can. In this respect as well, the battery terminal 201 can improve the assembly workability.

Further, in this case, the temporary tightening member 240 is attached to the flange portion 20fa while being slightly elastically deformed even if the arm portions 241b and 241b of the first reduced diameter portion 241 interfere with the uneven shape of the battery terminal body 20. , It is possible to return to the proper position. At this time, the temporary tightening member 240 comes off from the battery terminal main body 20 during the assembling work to the battery terminal main body 20 because the arm portions 242b and 242b of the second reduced diameter portion 242 are caught on the plate-shaped portion 20b side. It is possible to prevent the battery from being lost. In this respect as well, the battery terminal 201 can improve the assembly workability.

Further, in the battery terminal 201, the outer diameter R22 of the flange portion 20ga is formed to be larger than the outer diameter R21 of the flange portion 20fa corresponding to the taper of the battery post P as described above. In line with this, the temporary tightening member 240 is also formed so that the inner diameter R12 of the second reduced diameter portion 242 is larger than the inner diameter R11 of the first reduced diameter portion 241. Therefore, even if the temporary tightening member 240 is erroneously inverted with respect to the axial direction X and is to be assembled to the battery terminal body 20, the first reduced diameter portion 241 interferes with the flange portion 20ga, so that the battery terminal It is prevented from being assembled to the main body 20. With this configuration, the battery terminal 201 can prevent the temporary tightening member 240 from being erroneously assembled, so that the battery terminal 201 can be reliably and properly attached to the battery post P in this respect as well.

Further, in the battery terminal 201, when the temporary tightening member 240 is temporarily removed from the state where the temporary tightening member 240 is assembled to the battery terminal main body 20, the end portion of the connecting portion 243 functions as an operation grip portion. The connecting portion 243 can be gripped and easily removed. Here, the temporary tightening member 240 is provided with an operation grip portion at the end on the holding portion 22 side of the connecting portion 243, while the operation grip portion is not provided at the end on the plate nut 31 side. Interference between the temporary tightening member 240 and the plate nut 31 is suppressed. Further, due to this configuration, even if the temporary tightening member 240 is mistakenly assembled to the battery terminal main body 20 in a state of being inverted with respect to the axial direction X, the operation grip portion interferes with the plate nut 31 and causes the battery terminal. It is prevented from being assembled to the main body 20. Even with this configuration, the battery terminal 201 can prevent the temporary tightening member 240 from being erroneously assembled, so that the battery terminal 201 can be reliably and properly attached to the battery post P in this respect as well.

The battery terminal according to the above-described embodiment of the present invention is not limited to the above-described embodiment, and various modifications can be made within the scope of the claims.

In the above description, the battery terminal body 20 is integrally formed with a pair of plate-shaped portions 20a and 20b, a bent connecting portion 20c, and a pair of holding plate-shaped portions 20d and 20e by press bending of a metal plate or the like. Although it was explained as a thing, it is not limited to this. The battery terminal body 20 does not include, for example, a bent connecting portion 20c, and has an upper split body (plate-shaped portion 20a, holding plate-shaped portion 20d) forming an upper plate and a lower side forming a lower plate with respect to the axial direction X. It may have a two-layer split structure with the split body (plate-shaped portion 20b, holding plate-shaped portion 20e), and may have a structure in which the upper split body and the lower split body configured as separate bodies are integrated. ..

In the above description, the connection partner member has been described as being a connection terminal T provided at the end of the electric wire W, but the present invention is not limited to this. The connection mating member may be composed of terminals of various electronic component units such as a so-called fuse unit, for example.

In the above description, the tightening mechanism 30 has been described as forming a top-tightening type mechanism, but the present invention is not limited to this. The tightening mechanism 30 includes, for example, a bolt and a nut, and by tightening the bolt along the first width direction Y, the tightening end portion 20i is tightened along the first width direction Y laterally. It may be a tightening type.

In the above description, the pair of plate-shaped portions 20a and 20b are formed by projecting the flange portions 20fa and 20ga so as to be separated from each other along the axial direction X, but the present invention is not limited to this. The flange portion 20fa may be formed in the plate-shaped portion 20a so as to project toward the plate-shaped portion 20b along the axial direction X. The flange portion 20ga may be formed in the plate-shaped portion 20b so as to project toward the plate-shaped portion 20a along the axial direction X. For example, when the flange portions 20fa and 20ga of the pair of plate-shaped portions 20a and 20b are formed so as to project toward each other along the axial direction X, the temporary tightening member 240 is formed by the pair of plate-shaped portions 20a. , 20b may be assembled.

In the above description, the temporary tightening member 40 has been described as having a substantially circular cross-sectional shape (see FIG. 5) in the cross section in the direction along the central axis, but the present invention is not limited to this. The temporary tightening member 40 may have, for example, a substantially triangular shape, a substantially rectangular shape, a substantially polygonal shape, a substantially elliptical shape, or the like.

In the above description, the temporary tightening member 240 has been described as including the first reduced diameter portion 241 and the second reduced diameter portion 242, but the present invention is not limited to this, and the temporary tightening member 240 may be configured to include at least one of them. ..

The battery terminal according to the present embodiment may be configured by appropriately combining the components of the embodiments and modifications described above.

1, 201 Battery terminal 10 Stud bolt 10a Base 10b Shaft 11 Nut 20 Battery terminal body 20a, 20b Plate-shaped part 20c Bending connecting part 20d, 20e Holding plate-shaped part 20f, 20g Post insertion hole 20fa, 20ga Flange part 20h Slit 20i Tightening end 20j Insertion hole 21 Fastening part 22 Holding part 30 Tightening mechanism 31 Plate nut 32 Fastening bolt (fastening member)
33 Bracket 40, 240 Temporary tightening member 241 First diameter reduction part 241a, 242a Notch 241b, 241c, 242b, 242c Arm part 242 Second diameter reduction part 243 Connecting part C1 Center axis P Battery post X Axis direction Y First width Direction Z 2nd width direction

Claims (6)

A post insertion hole into which a battery post is inserted along the axial direction, and a battery terminal body having a flange portion protruding from the edge of the post insertion hole along the axial direction.
A tightening mechanism for fastening the battery terminal body to the battery post by tightening the battery terminal body with the battery post inserted in the post insertion hole.
A temporary tightening member provided in the battery terminal body separately from the tightening mechanism, and in a state where the battery post is inserted into the post insertion hole, tightens the flange portion to reduce the diameter of the post insertion hole. Characterized by preparing,
Battery terminal. The temporary tightening member is formed in an annular shape and is attached to the flange portion along the axial direction.
The battery terminal according to claim 1. The temporary tightening member has a circular cross section.
The battery terminal according to claim 2. The battery terminal body includes the post insertion hole and a pair of plate-shaped portions on which the flange portion is formed, which face each other along the axial direction.
The temporary tightening member is a first diameter-reduced portion for sandwiching and tightening the flange portion of one of the pair of plate-shaped portions, and the other plate-shaped portion of the pair of plate-shaped portions. The first reduced diameter portion and the second reduced diameter portion include a second reduced diameter portion that sandwiches and tightens the flange portion, and a connecting portion that connects the first reduced diameter portion and the second reduced diameter portion. The reduced diameter portion is attached to each of the flange portions along a direction intersecting the axial direction through a notch provided in each.
The battery terminal according to claim 1. The pair of plate-shaped portions are formed so that the flange portions project from each other along the axial direction.
The temporary tightening member has the first reduced diameter portion and the second reduced diameter portion attached to each of the flange portions, and the first reduced diameter portion and the second reduced diameter portion with respect to the axial direction. The pair of plate-shaped portions are sandwiched between the diameter portion and the diameter portion.
The battery terminal according to claim 4. The tightening mechanism fastens the battery terminal body to the battery post by rotating a fastening member extending along the axial direction around the axial direction.
The battery terminal according to any one of claims 1 to 5.

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