JP6238161B2 - Connection structure between battery assembly and terminal with conductive path - Google Patents

Description

  The present invention relates to an electrical connection structure in a bus bar module used in, for example, a hybrid vehicle or an electric vehicle, and more specifically to a connection structure between a battery assembly and a terminal with a conductive path.

  For example, in a hybrid vehicle or an electric vehicle, a battery assembly 101 as shown in FIGS. 9 and 10 is mounted as a high voltage battery. The battery assembly 101 includes a plurality of batteries 102 arranged, and each battery 102 is provided with a pair of electrodes 103 used as a plus electrode and a minus electrode. Here, the pair of electrodes 103 are provided so as to protrude one by one from the left and right sides of the battery 102. The battery assemblies 101 are arranged on the side portions of the adjacent batteries 102 so that the facing electrodes 103 become a positive electrode and a negative electrode.

  Reference numeral 104 denotes a conventional bus bar module. The bus bar module 104 is an elongate member having a plurality of portions for connecting the opposing electrodes 103 (the positive electrode and the negative electrode) as described above. Here, the bus bar module 104 is provided on each of the left and right sides of the battery assembly 101. . 10 and 11, the bus bar module 104 includes a plurality of bus bars 105, voltage detection terminals 107 provided at the terminals of the electric wires 106, and a case 108.

  The bus bar 105 is made of a conductive metal plate. The bus bar 105 has a flat plate shape, and electrode insertion holes 109 and 109 are formed at predetermined positions. The opposing electrodes 103 (plus electrode and minus electrode) are inserted into the electrode insertion holes 109 and 109. 11 and 12, the voltage detection terminal 107 is made of a conductive metal plate, and includes a flat plate-like electrical contact portion 110 and a wire connection portion 111 continuous to the electrical contact portion 110. An electrode insertion hole 112 is formed through the center of the electrical contact portion 110. In addition, an insertion convex portion 113 is formed at one end of the electrical contact portion 110. Note that an electric wire connecting portion 111 is coupled to the other end of the electric contact portion 110. The electric wire connecting portion 111 is formed as a portion that crimps and connects the end of the electric wire 106.

  10 and 11, the case 108 is a resin molded product having an insulating property, and includes a bus bar housing function portion 114, a wire housing function portion 115, and a plurality of connecting portions 116 that connect them. The whole is formed in a long shape as shown in the figure. In addition, the connection part 116 is short, and the shape is formed so that it may become a groove shape.

  In the bus bar housing function portion 114, a plurality of housing fixing portions 117 for the bus bar 105 and the electrical contact portion 110 are formed. A pair of lock portions 118 for fixing the bus bar 105 is formed in the accommodation fixing portion 117. Further, penetrating portions 119 and 119 penetrating in the axial direction of the electrode 103 and receiving portions 120, 120 and 121 for the bus bar 105 are also formed (see FIG. 14). The through portions 119 and 119 and the receiving portions 120, 120, and 121 are formed on the bottom wall 122. In addition, an insertion recess 123 with respect to the insertion protrusion 113 of the electrical contact portion 110 is also formed in the housing fixing portion 117.

  The terminal of the electric wire 106 drawn out from the voltage detection terminal 107 is accommodated in the connecting portion 116. Moreover, the electric wire 106 is accommodated in the electric wire accommodation functional part 115 and wired in a predetermined state. A cover 124 is formed at a plurality of locations in the electric wire housing function portion 115. The plurality of electric wires 106 accommodated and routed in the electric wire accommodating function portion 115 are covered and protected by a cover 124.

  In the above configuration and structure, as shown in FIG. 13, the bus bar 105 is first fixed to the housing fixing portion 117 of the case 108. Then, the electrical contact portion 110 is fixed so as to overlap with a predetermined position on the bus bar 105. The electrical contact portion 110 is fixed by inserting the insertion convex portion 113 at one end into the insertion concave portion 123 of the housing fixing portion 117. When the electric wire 106 drawn out from the voltage detection terminal 107 is accommodated and routed in the electric wire accommodating function portion 115 and then the cover 124 is closed, the assembly of the bus bar module 104 is completed.

  When the bus bar module 104 is attached to the battery assembly 101, the electrode 103 is inserted into the electrode insertion holes 109 and 112 of the bus bar 105 and the electrical contact portion 110. At this time, the seat portion 125 of the electrode 103 is inserted into the through portion 119. Further, the seat portion 125 also receives the bus bar 105 by this seat surface (electrode seat surface). When the nut 126 is tightened on the electrode 103, the electrical connection is completed and the mounting of the bus bar module 104 to the battery assembly 101 is also completed.

  Note that description of the detailed structure of the bus bar module 104 is omitted here (for example, the technique disclosed in Patent Document 1 below is helpful).

JP 2013-17332 A

  By the way, in the above prior art, as an electrical connection structure between the battery assembly 101 and the bus bar module 104, as shown in FIGS. 13 and 14, a through portion formed in the housing fixing portion 117 of the case 108. Since the electrode 103 and the seat 125 are inserted into the 119, the through-hole 119 must be at least larger than the diameter of the seat 125 (than the electrode seat surface). Therefore, if the diameter of the seat portion 125 is increased by a change or the like, the size of the housing fixing portion 117 is also increased, and as a result, the case 108 is increased in size.

  Further, in the above prior art, as an electrical connection structure between the battery assembly 101 and the bus bar module 104, a pair of lock portions 118 for fixing the bus bar 105 are provided as shown in FIG. Since it is formed in the housing fixing part 117, the peripheral wall 127 of the housing fixing part 117 is formed high (the wall is made high) or a notch (a part for enabling bending) is formed for the lock part 118. Have to do. Therefore, there is a problem that the case 108 becomes larger in the height direction.

  The problems as described above lead to an increase in the mold cost and parts cost of the case 108. Moreover, it leads to influence on simplification and standardization of the structure of the case 108 and the like.

  The present invention has been made in view of the above circumstances, and provides a connection structure between a battery assembly and a terminal with a conductive path, which can suppress cost increase and can be simplified and standardized. Is an issue.

The connection structure between the battery assembly of the present invention and the terminal with a conductive path according to claim 1 made to solve the above problems is connected to a battery assembly composed of a plurality of batteries and the electrode of the battery. A terminal with a conductive path, and an insulating case that accommodates at least the conductive terminal body in the terminal with the conductive path, and forming a through-hole penetrating in the axial direction of the electrode in the case, A flat electrical contact portion having an electrode insertion hole is formed in the terminal body, and the electrical contact portion is formed in a shape protruding from the bottom surface of the case on the battery side through the through portion. Forming a terminal fixing portion at the periphery of the penetrating portion to fix the electric contact portion in a state protruding from the bottom surface to the battery side, and as a configuration of the fixed portion on the terminal body side, At one end of the contact The first fixed portion is formed in the attached state, the conductive path connecting portion is formed in the stepped state on the other end side opposite to the one end, and the conductive path connection is provided at the other end position. A second fixed part that is fixed together with the part is formed .

  According to the present invention having such a feature, since the electric contact portion of the terminal with the conductive path protrudes in a flat plate state toward the battery side from the bottom surface of the case, the electrode seat surface in the battery assembly is temporarily increased. Even if it is necessary to change the electrode or the like, the case itself does not increase in size. For example, the size of the electrode seat surface may be changed by changing the electrode insertion hole of the electrical contact portion. In addition, if the electrode pitch does not change, the case or the like can continue to be used.

Further, according to the present invention, since the electric contact portion protrudes toward the battery side from the bottom surface of the case and is fixed in the protruding state, the connection between the bottom surface of the case and the battery side, for example, It does not occur .
Moreover, according to this invention, it has the to-be-fixed part by the side of a terminal main body as a part fixed to a case regarding the terminal with a conductive path. The fixed part includes a first fixed part, a conductive path fixing part, and a second fixed part, and is arranged so as to straddle one end of the electrical contact part and the other end on the opposite side. As for fixing to the case, it is not fixed in a biased state concentrated in one place, but fixed in a stable state.
Furthermore, according to the present invention, regarding the shape of the terminal body, the first fixed portion and the conductive path fixing portion are formed in a stepped state with respect to the electric contact portion, so that the electric contact portion becomes a concave portion, Therefore, it becomes a shape which makes it easy to make an electrical contact part protrude in the battery side rather than the bottom face of a case.

The connection structure between the battery assembly of the present invention and the terminal with a conductive path according to claim 2 made to solve the above problems is connected to a battery assembly composed of a plurality of batteries and the electrode of the battery. A terminal with a conductive path, and an insulating case that accommodates at least the conductive terminal body in the terminal with the conductive path, and forming a through-hole penetrating in the axial direction of the electrode in the case, A flat electrical contact portion having an electrode insertion hole is formed in the terminal body, and the electrical contact portion is formed in a shape protruding from the bottom surface of the case on the battery side through the through portion. the the periphery of the penetrating part forming a terminal fixing portion than the bottom surface of the electrical contact portion is fixed to remain protruding to the battery side, as a configuration the pin solid tough, the through portion On the bottom side at the first edge side Forming a first terminal fixing portion on the side away from the battery, and forming a conductive path mounting portion on the second edge side opposite to the first edge portion on the side farther from the battery than the bottom surface. And the 2nd terminal fixing | fixed part fixed with the said conductive path mounting part is formed in the position of said 2nd edge part, It is characterized by the above-mentioned.

According to the present invention having such a feature, since the electric contact portion of the terminal with the conductive path protrudes in a flat plate state toward the battery side from the bottom surface of the case, the electrode seat surface in the battery assembly is temporarily increased. Even if it is necessary to change the electrode or the like, the case itself does not increase in size. For example, the size of the electrode seat surface may be changed by changing the electrode insertion hole of the electrical contact portion. In addition, if the electrode pitch does not change, the case or the like can continue to be used.
Further, according to the present invention, since the electric contact portion protrudes toward the battery side from the bottom surface of the case and is fixed in the protruding state, the connection between the bottom surface of the case and the battery side, for example, It does not occur.

Moreover, according to this invention, it has a terminal fixing | fixed part as a part which fixes a terminal with a conductive path regarding a case. The terminal fixing portion is configured to include a first terminal fixing portion, a conductive path placement portion, and a second terminal fixing portion, and is disposed and formed at the periphery of the penetrating portion penetrating in the axial direction of the electrode. Since the terminal fixing part is arranged so as to straddle the first edge side of the penetrating part and the second edge side located on the opposite side, with respect to fixing the terminal with the conductive path, it is at one place. It is fixed in a stable state, not fixed in a biased state that concentrates.

According to a third aspect of the present invention, in the connection structure between the battery assembly according to the first or second aspect and the terminal with a conductive path, the electrical contact portion is at least as thick as the electrical contact portion from the bottom surface. It is formed in a protruding shape.

  According to the present invention having such a feature, since the electric contact portion protrudes from the bottom surface of the case toward the battery side by this thickness, the occurrence of interference can be suppressed as described above. The axial dimension of the electrode is slightly increased and does not cause any particular problem. The effect of preventing interference is much greater than that.

According to a fourth aspect of the present invention, in the connection structure between the battery assembly according to the first, second, or third aspect and a terminal with a conductive path, the terminal body is a voltage detection terminal and the terminal with the conductive path The conductive path in is a wire.

  According to the present invention having such a feature, the connection between the battery assembly and the voltage detection terminal with electric wire is effective. The application of the present invention is not limited to voltage detection. Further, the conductive path may be a strip-shaped member having conductivity.

According to a fifth aspect of the present invention, in the connection structure of the battery assembly according to the first, second, third, or fourth aspect and the terminal with a conductive path, the electrodes facing each other in a state where the batteries are adjacent to each other. A conductive and flat connection plate for connection is further provided, and a mounting surface for the electric contact portion protruding from the bottom surface is formed on the connection plate, and the connection plate is provided on the electrode in advance. It is characterized by keeping.

  According to the present invention having such a feature, it is only necessary to provide a connection plate in advance on the electrode of the battery assembly so that the case side has only a structure related to fixing of the terminal with the conductive path. The case structure is naturally simplified.

  Further, according to the present invention, with respect to the electrical connection, at the position of the electrode, if the electrical contact portion of the terminal with a conductive path protruding from the bottom surface of the case to the battery side and the mounting surface of the connection plate are overlapped Good. Connection is easy and connection / assembly by an automatic machine becomes possible.

According to the present invention described in claim 1 or 2 , the terminal body of the terminal with a conductive path is electrically connected to the battery assembly in a state where the terminal body is accommodated in at least the case. The electrode in the battery assembly has a structure in which the plate-like electrical contact portion of the main body protrudes from the bottom surface of the case to the battery side, and is fixed in the protruding state and then connected. Even if the seating surface becomes large or it is necessary to change the electrode or the like, the case itself can be prevented from being enlarged. More preferably, since it has the above structure, it can be used regardless of the shape or size of the connection partner. Therefore, according to the present invention, it is possible to suppress the increase in cost and to increase the degree of freedom related to the connection. In addition, there is an effect that simplification and standardization can be achieved. In addition, with respect to the connection, there is also an effect that interference between the bottom surface of the case and, for example, the battery side can be prevented.

According to the first aspect of the present invention, in addition to the above effects, the following effects can also be obtained. That is, as a portion fixed to the case, since the fixed portion having a predetermined arrangement configuration is provided on the terminal body side, the fixed state can be stabilized by the fixed portion.

According to the present invention described in claim 2 , in addition to the above-described effects, the following effects can also be obtained. That is, as a portion for fixing the terminal with the conductive path, the terminal fixing portion having a predetermined arrangement configuration is provided on the periphery of the through portion of the case, so that the terminal fixing portion can stabilize the fixing state. Play.

According to the present invention described in claim 3 , in addition to the effect of claim 1 or 2 , the following effect is also achieved. In other words, since the electric contact portion only protrudes toward the battery side by this thickness, there is an effect that interference with the battery side can be prevented while suppressing an increase in size.

According to the present invention described in claim 4 , in addition to the effect of claim 1, 2, or 3 , the following effect is also achieved. That is, there is an effect that it can be applied to the connection between the battery assembly and the voltage detection terminal with electric wire.

According to the present invention described in claim 5 , in addition to the effect of claim 1, 2, 3 or 4 , the following effect is also achieved. That is, the case structure can be simplified and standardized, and the battery assembly can be connected and assembled by an automatic machine.

It is a whole perspective view which shows the connection structure of the battery assembly which concerns on this invention, and the voltage detection terminal with an electric wire. It is a disassembled perspective view which shows the structure of the connection structure of FIG. It is a perspective view which shows the state which looked at the side provided with a case and the voltage detection terminal with an electric wire from the bottom face side of the case. It is a top view which shows the state which fixed the voltage detection terminal with an electric wire to a case. It is an expansion perspective view which shows the voltage detection terminal with an electric wire. It is sectional drawing and perspective view which show the connection structure of FIG. It is sectional drawing which shows the connection structure of FIG. It is sectional drawing and a perspective view which show the fixed state of a voltage detection terminal. It is a whole perspective view which shows the connection structure of the battery assembly and bus bar module of a prior art example. It is a disassembled perspective view which shows the structure of the connection structure of FIG. It is a top view which shows the state which fixed the bus-bar and the voltage detection terminal with an electric wire of FIG. 10 to the case. It is an expansion perspective view which shows the voltage detection terminal with an electric wire of FIG. It is sectional drawing and a perspective view which show the connection structure of FIG. It is a perspective view which shows the state which looked at FIG. 13 from the bottom face side of the case.

  In the connection structure between the battery assembly and the terminal with the conductive path, at least the terminal body of the terminal with the conductive path is accommodated in the case. At this time, the electric contact part of the terminal body is protruded from the bottom surface of the case to the battery side. In addition, the electric contact portion is fixed in a state where it protrudes. Then, electrical connection is made between the electric contact portion protruding from the bottom surface and the battery side.

  Hereinafter, embodiments will be described with reference to the drawings. FIG. 1 is an overall perspective view showing a connection structure between a battery assembly and a voltage detection terminal with electric wires according to the present invention. FIG. 2 is an exploded perspective view showing the configuration of the connection structure of FIG. Furthermore, FIG. 3 is a perspective view showing a state in which the side including the case and the voltage detection terminal with electric wire is viewed from the bottom side of the case.

  1 and 2, reference numeral 1 indicates a high-voltage battery assembly mounted at a predetermined position of a hybrid vehicle or an electric vehicle. Reference numeral 2 denotes a bus bar module for electrical connection to the battery assembly 1.

  The battery assembly 1 includes a plurality of batteries 3 arranged, and each battery 3 is provided with electrodes 4 and 5 that are used as a positive electrode and a negative electrode. The electrodes 4 and 5 are provided on the upper part of the battery at a predetermined interval. The electrodes 4 and 5 are provided so as to protrude upward at different heights. The battery assembly 1 is arranged so that the electrodes 4 and 5 facing each other between adjacent batteries 3 become a plus electrode and a minus electrode. The battery assembly 1 has various forms, and the one shown in the figure is one of them.

  In FIG. 2, the electrode 4 is configured to have a cylindrical seat portion 6 having a large diameter and a bolt portion 7 provided at the center of the upper surface of the seat portion 6 (center of the electrode seat surface). The bolt part 7 has a smaller diameter than the seat part 6 (smaller diameter than the electrode seat surface), and a step is formed between the bolt part 7 and the seat part 6. This step is formed as an electrode seat surface. On the other hand, the electrode 5 is composed of only the seat portion 6 (having an electrode seat surface). The electrode seat surface is formed flat.

  The bus bar module 2 includes a first module component 8 that is provided in advance on the battery assembly 1 side, and a second module component 9 that is integrated with the first module component 8 later (note that Characterizing the above configuration, “in the bus bar module 2 for making an electrical connection to the battery assembly 1, the bus bar module 2 includes a first module component 8 and a second module component 9, The module component 8 is provided in advance on the battery assembly 1 side, and the second module component 9 is integrated with the first module component 8 later ”.

  The first module configuration unit 8 includes a plurality of bus bars 10 (connection plates). The bus bar 10 is formed by making a conductive metal flat plate into a rectangular shape, and is provided to electrically connect the electrodes 4 and 5 (plus electrode and minus electrode) facing each other between adjacent batteries 3. . Such a bus bar 10 has an electrode insertion hole 11, a mounting surface 12 for an electrical contact portion 39 to be described later, and a case facing surface 13.

  The mounting surface 12 is disposed and formed on the periphery of the electrode insertion hole 11. Moreover, the mounting surface 12 is formed in a plane. The case facing surface 13 is formed so as to be flush with the placement surface 12. The case facing surface 13 is formed as a surface facing the bottom surface 25 of the case 16 described later with a slight gap.

  As described above, the first module component 8 is provided in advance on the battery assembly 1 side, and in this embodiment, a fixing method in which the bus bar 10 is directly welded to the electrodes 4 and 5 is employed. (The fixing method is not particularly limited. In the present embodiment, the electrodes 4 and 5 are mounted on the electrode seat surfaces and welded to each other). The plurality of bus bars 10 are welded to the electrodes 4 and 5 without being in contact with each other. Reference numerals 14 and 15 indicate a first bus bar row and a second bus bar row in which a plurality of bus bars 10 are arranged in a row, respectively.

  1 to 3, the second module configuration unit 9 includes a case 16 and a plurality of voltage detection terminals 17 with wires. Regarding the second module component 9, the configuration of the first module component 8 is basically the same as that obtained by removing a plurality of bus bars from a known bus bar module.

  In this embodiment, the case 16 is a two-part molded product made of an insulating resin material, and includes a first case 18 and a second case 19 and a case connecting portion 20. The first case 18 and the second case 19 are arranged in parallel, and one end of the first case 18 is connected by a case connecting portion 20 that is continuous with one end of the second case 19. The first case 18 and the second case 19 are arranged according to the positions of the first bus bar row 14 and the second bus bar row 15 of the first module component 8. Such a case 16 is formed in the shape which becomes a substantially U shape in planar view so that it may understand also from arrangement | positioning of each part.

  Although the first case 18 and the second case 19 are slightly different in appearance when viewed from the drawings, there are many common structures in terms of function. Therefore, the configuration and structure will be described below with the first case 18 as a representative. To. Therefore, the description of the second case 19 is omitted here.

  The first case 18 is formed so as to extend along the first bus bar row 14 of the first module component 8. In other words, the battery assembly 1 is formed in accordance with the length in the arrangement direction of the batteries 3 constituting the battery assembly 1. When the reference sign 21 is the main body portion of the first case 18, the main body portion 21 has an elongated bottom wall 22 that is substantially rectangular in plan view, and a side wall (reference number omitted) that is coupled to the periphery of the bottom wall 22. And the upper surface side is formed in a shallow box shape in an open state.

  A plurality of receiving and fixing parts 23 are formed in the main body part 21. The same number of housing fixing portions 23 as the bus bars 10 constituting the first bus bar row 14 are formed. Further, it is arranged and formed in accordance with the position of the bus bar 10.

  In the main body portion 21, an electric wire housing portion 24 is also formed in addition to the plurality of housing fixing portions 23. The electric wire accommodating portion 24 is formed as a portion for accommodating the electric wire 37 described later and for routing the electric wire 37. The electric wire accommodating portion 24 is disposed and formed around the main body portion 21.

  In FIG. 3, the bottom wall 22 is formed such that the bottom surface 25 that becomes the battery assembly 1 side (battery 3 side) is a flat surface. The bottom surface 25 corresponds to the lower surface of the bottom wall 22 in this embodiment. In such a bottom wall 22, a through portion 26 is formed in accordance with the position of the accommodation fixing portion 23 (see FIGS. 1 and 2). The penetrating portion 26 is formed as a part constituting the housing fixing portion 23. The penetration part 26 is formed so as to penetrate in the axial direction of the electrode 4. Moreover, the penetration part 26 is formed so that it may penetrate according to the shape of the electrical contact part 39 mentioned later.

  Hereinafter, the accommodation fixing part 23 and the voltage detection terminal 17 with electric wire will be described with reference to FIGS. 4 to 8. The connection structure according to the present invention will be described. 4 is a plan view showing a state where the voltage detection terminal with electric wire is fixed to the case, FIG. 5 is an enlarged perspective view showing the voltage detection terminal with electric wire, FIG. 6 is a cross-sectional view and a perspective view showing the connection structure of FIG. 7 is a cross-sectional view showing the connection structure of FIG. 1, and FIG. 8 is a cross-sectional view and a perspective view showing a fixed state of the voltage detection terminal.

  In FIG. 4, the housing fixing portion 23 is formed as a portion for housing a terminal body 38 to be described later of the voltage detection terminal 17 with electric wire. The housing fixing part 23 has the through part 26 as described above. Further, as other parts, the accommodation fixing portion 23 includes a placement portion 27, an enclosure wall 28, and a terminal fixing portion 29.

  The mounting portion 27, the surrounding wall 28, and the terminal fixing portion 29 are disposed and formed on the upper surface side of the bottom wall 22. The mounting portion 27, the surrounding wall 28, and the terminal fixing portion 29 are disposed and formed on the side away from the battery assembly 1 (battery 3) when viewed from the bottom surface 25 of the bottom wall 22.

  The placement part 27 and the terminal fixing part 29 are formed so as to be continuous with the penetration part 26, respectively. The surrounding wall 28 is formed so as to rise from the edge of the penetrating part 26 and the edge of the mounting part 27. The surrounding wall 28 is formed so as to function as a portion that protects a terminal body 38 (described later) housed in the housing fixing portion 23 from an external force. The enclosure wall 28 is not formed so high. In the present embodiment, the enclosure wall 28 is formed so as to match the length of the electrode 4 and in consideration of the tightening operation of the nut 50 described later.

  As described above, the penetrating portion 26 is formed penetrating in accordance with the shape of the electrical contact portion 39 described later. Further, in the present embodiment, the through portion 26 is formed with a wide opening so that the bus bar 10 (see FIG. 2) can be visually recognized even when the electrical contact portion 39 is accommodated.

  Here, when the reference sign 30 is the first edge in the penetrating part 26 and the reference sign 31 is the second edge located on the opposite side of the first edge 30, the placement part 27 is the second edge. It is arranged and formed on the 31 side. The mounting portion 27 is formed as a portion for mounting a later-described electric wire connecting portion 40 of the voltage detection terminal 17 with electric wire.

  The terminal fixing portion 29 has a plurality of configurations and is disposed and formed so as to straddle the first edge portion 30 and the second edge portion 31. The terminal fixing portion 29 is formed as a portion for fixing a terminal main body 38 to be described later and a portion for determining the accommodation position.

  If the reference numeral 32 is the third edge in the penetrating portion 26 and the reference numeral 33 is the fourth edge, the first edge 30 to the third edge 32 are the shape of the electrical contact portion 39 to be described later. It is formed according to. On the fourth edge 33 side, an opening (reference numeral omitted) is formed so that the bus bar 10 (see FIG. 2) can be visually recognized.

  Since the wire connecting portion 40 is placed on the placement portion 27 as described above, the placement portion 27 is effective as a portion for determining the accommodation position of the terminal body 38 to be described later. Therefore, when the reference numeral 34 is newly added to the mounting portion 27 and this is used as the electric wire connection portion mounting portion, the electric wire connection portion mounting portion 34 is the conductive path mounting portion described in the claims. And becomes one of a plurality of portions constituting the terminal fixing portion 29.

  The terminal fixing portion 29 includes the first terminal fixing portion 35 arranged and formed on the first edge 30 and the second terminal fixing arranged and formed on the second edge 31 in addition to the electric wire connection portion mounting portion 34 described above. The first terminal fixing portion 35, the second terminal fixing portion 36, and the electric wire connection portion mounting portion 34.

  The 1st terminal fixing | fixed part 35 is formed as a part which fixes the terminal main body 38 mentioned later. The second terminal fixing portion 36 and the wire connection portion mounting portion 34 are each formed as a portion for determining the accommodation position of the terminal body 38, and the two are formed as portions for fixing the terminal body 38. The

  The first terminal fixing portion 35 is formed in a concave portion. Specifically, it is formed in a portion that can be inserted into a first fixed portion 47 of the terminal body 38 to be described later, that is, a portion that functions as an insertion recess. The first terminal fixing portion 35 is formed so as to fix the first fixed portion 47 and make the terminal body 38 immovable in the axial direction of the electrode 4.

  The second terminal fixing portion 36 is formed in a claw-like (so-called locking projection shape) portion having a tapered surface and a locking surface. The tapered surface is formed as a portion that slides when a second fixed portion 48 of the terminal body 38 to be described later gets over the second terminal fixing portion 36. Further, the locking surface is formed as a portion that restricts movement in the removal direction after the second fixed portion 48 gets over the second terminal fixing portion 36. In this embodiment, the locking surface is arranged and formed on the same plane as the bottom surface 25 of the first case 18.

  Since the second terminal fixing part 36 restricts the movement of the second fixed part 48 in the removal direction, it alone is effective as a part for determining the accommodation position of the terminal main body 38 to be described later, and the wire connection part mounting part. In a state of functioning together with 34, it is effective as a portion for fixing the terminal body 38.

  As can be understood from the above description, the accommodation fixing portion 23 does not need to be formed with a lock portion for the bus bar 10 as in the conventional example. This is because the bus bar 10 is not a second module component 9 but a component on the first module component 8 side.

  4 and 5, the voltage detection terminal 17 with electric wire is formed by providing a terminal body 38 (voltage detection terminal) at the end of a known electric wire 37 (conduction path). In this embodiment, the battery 3 ( A plurality of devices are provided for detecting the voltage of FIG. 1 and FIG.

  The terminal body 38 is formed into a shape as shown in the figure, for example, by pressing a conductive thin metal plate. The terminal body 38 integrally includes an electrical contact portion 39, a wire connection portion 40, and a fixed portion 41.

  The electrical contact portion 39 is a portion that performs electrical connection, and is formed in a flat plate shape whose upper surface and lower surface are flat. A circular electrode insertion hole 42 is formed through the center of the electrical contact portion 39. The electrode insertion hole 42 is formed according to the diameter of the electrode 4 (see FIG. 2).

  As will be understood from the following description, the electrical contact portion 39 is a portion that is arranged at a position protruding from the bottom surface 25 of the first case 18 because stepped portions 45 and 49 described later are continuous. It is formed. In the present embodiment, it is arranged and formed so as to protrude by the thickness of the electrical contact portion 39.

  Here, when the reference sign 43 is one end of the electrical contact portion 39 and the reference sign 44 is the other end located on the opposite side of the one end 43, the wire connecting portion 40 is disposed and formed on the other end 44 side.

  The electric wire connecting portion 40 is formed as a portion for connecting the ends of the electric wires 37 by crimping (not limited to crimping, but formed in accordance with an appropriate connection method such as pressure welding or welding). The electric wire connecting portion 40 is formed not to continue straight to the electrical contact portion 39 like a general terminal fitting, but to continue from the other end 44 of the electrical contact portion 39 in a stepped state. Reference numeral 45 indicates a stepped portion.

  Since the electric wire connection part 40 has the stepped part 45, when viewed from the electric wire connection part 40, the electric contact part 39 is arranged at a position that is lowered by one step along the axial direction of the electrode 4 (see FIG. 2). .

  The wire connection part 40 is formed as a part to be placed on the placement part 27 of the accommodation fixing part 23. Moreover, the electric wire connection part 40 of the state mounted in the mounting part 27 is to the battery 3 (refer FIG. 2) side by the electric wire connection part mounting part 34 (the same part as the mounting part 27) of the terminal fixing | fixed part 29. FIG. Movement is restricted.

  With respect to the wire connection portion 40, when a reference numeral 46 is newly added and this is used as the wire connection portion, the wire connection portion 46 corresponds to the conductive path connection portion described in the claims, and the fixed portion 41 is defined as the wire connection portion 40. It becomes one of the constituent parts.

  The fixed portion 41 is arranged and formed on the first fixed portion 47 arranged on the one end 43 side of the electric contact portion 39 and the other end 44 side of the electric contact portion 39 in addition to the electric wire connecting portion 46 described above. The first fixed portion 47, the second fixed portion 48, and the electric wire connecting portion 46 are included.

  The first fixed portion 47 is fixed by the first terminal fixing portion 35 constituting the terminal fixing portion 29. The second fixed portion 48 and the electric wire connection portion 46 are fixed by the second terminal fixing portion 36 and the electric wire connection portion placement portion 34 that constitute the terminal fixing portion 29.

  The first fixed portion 47 is formed in a convex portion. Specifically, it is formed in a shape that becomes an insertion protrusion. The insertion protrusion is formed in a shape that can be inserted into the first terminal fixing portion 35 that functions as an insertion recess. Such a first fixed portion 47 is formed to be continuous with the one end 43 of the electrical contact portion 39 in a stepped state. The first fixed portion 47 has a stepped portion 49 like the wire connecting portion 40.

  Since the first fixed portion 47 has the stepped portion 49, the electric contact portion 39 is positioned so as to be lowered by one step along the axial direction of the electrode 4 (see FIG. 2) when viewed from the first fixed portion 47. Placed in.

  The second terminal fixing portion 36 is disposed and formed at the other end 44 of the electrical contact portion 39. Specifically, it is formed in the shape of a protruding piece that protrudes from the other end 44 on the same plane. The second terminal fixing portion 36 is formed as a portion that is hooked and locked to the locking surface of the second terminal fixing portion 36 constituting the terminal fixing portion 29.

  In the above configuration, as shown in FIGS. 6 to 8, when a plurality of voltage detection terminals 17 with electric wires are assembled to the main body portion 21 of the first case 18 (case 16), the terminal main body 38 is fixed to the corresponding housing fixing portion 23. Is done. Specifically, since the shape of the electrical contact portion 39 is a concave shape when viewed as a whole of the terminal main body 38, the electrical contact portion 39 is more battery than the bottom surface 25 through the through portion 26 when assembled. It is fixed in a state of protruding to the 3 side. Further, by assembling, the terminal main body 38 has the electric wire connecting portion 40 placed on the placing portion 27, and the electric wire 37 drawn from the electric wire connecting portion 40 is accommodated / routed in the electric wire accommodating portion 24.

  The terminal body 38 will be described in more detail. The terminal body 38 has the first fixed portion 47 inserted into the first terminal fixing portion 35 of the receiving and fixing portion 23, thereby moving the electrode 4 in the axial direction. Fixed in a regulated state. Further, the terminal body 38 is in a state in which the second fixed portion 48 is locked by the second terminal fixing portion 36 and the wire connection portion 46 is placed on the wire connection portion placement portion 34. Here, too, the movement of the electrode 4 in the axial direction is fixed in a restricted state. Further, since the terminal main body 38 has stepped portions 45 and 49, these can be brought into contact with the first edge 30 and the second edge 31 of the penetrating portion 26, and as a result, the terminal main body 38. Is fixed in a state where movement in the longitudinal direction is restricted. The terminal main body 38 is fixed in a stable state as can be seen from the fixing position.

  When the assembly of the voltage detection terminal 17 with electric wire is completed, the electrical contact portion 39 of the terminal body 38 protrudes from the bottom surface 25 of the first case 18 (case 16) to the battery 3 side. When the second module component 9 is integrated with the first module component 8 in a fixed state, the following is obtained. That is, the bolt portion 7 of the electrode 4 is inserted into the electrode insertion hole 42 of the electrical contact portion 39, and then the electrical contact portion 39 is placed in surface contact with the placement surface 12 of the bus bar 10. When the nut 50 is screwed into the bolt portion 7 of the electrode 4 using the nut 50, the electrical contact portion 39 and the bus bar 10 are completely electrically connected.

  Since the electrical contact portion 39 protrudes toward the battery 3 side, interference between the bottom surface 25 of the first case 18 and the battery 3 side does not occur during the connection.

  When the electrical contact portion 39 and the bus bar 10 are completely electrically connected, the second module component 9 is integrated with the first module component 8, so that the bus bar module 2 is completed. At the same time, the electrical connection between the bus bar module 2 and the battery assembly 1 is also completed. At this time, the electrical connection between the plurality of voltage detection terminals 17 with electric wires and the battery assembly 1 is also completed.

  As described above with reference to FIGS. 1 to 8, the flat electrical contact portion 39 of the terminal main body 38 protrudes toward the battery 3 from the bottom surface 25 of the case 16 and remains protruding. Because the structure is fixed in the state and connected on top of it, even if the electrode seating surface in the battery assembly 1 becomes larger or it is necessary to change the electrodes 4, 5, etc. However, the case 16 itself can be prevented from becoming large. More preferably, since it has the above structure, it can be used regardless of the shape or size of the connection partner. Specifically, as employed in the present embodiment, the electrical contact portion 39 protrudes from the bottom surface 25 of the case 16 toward the battery 3 and is fixed in a state in which the electrical contact portion 39 is protruded. Since it is connected to the bus bar 10 provided on the battery assembly 1 side, it can be used regardless of the shape and size of the electrodes 4 and 5 and the electrode seat surface. Therefore, it is possible to suppress the increase in cost and to increase the degree of freedom related to the connection.

  In addition, as can be seen from the configuration and structure of the bus bar module 2, there is also an effect that simplification and standardization can be achieved as compared with the conventional one. In addition, as described above, there is an effect that interference between the bottom surface 25 of the case 16 and, for example, the battery 3 side can be prevented. Furthermore, as can be seen from the configuration and structure having the terminal fixing portion 29 and the fixed portion 41, there is also an effect that the fixing state of the terminal body 38 can be stabilized.

  It goes without saying that the present invention can be variously modified without departing from the spirit of the present invention.

  In the above embodiment, the electrodes 4 and 5 have been described as the positive electrode and the negative electrode in the battery assembly 1, but the present invention is not limited thereto, and may be dedicated electrodes separately provided for voltage detection. Shall.

  DESCRIPTION OF SYMBOLS 1 ... Battery assembly, 2 ... Bus bar module, 3 ... Battery, 4, 5 ... Electrode, 6 ... Seat part, 7 ... Bolt part, 8 ... First module component, 9 ... Second module component, 10 ... Bus bar (Connecting plate), 11 ... Electrode insertion hole, 12 ... Placement surface, 13 ... Case facing surface, 14 ... First bus bar row, 15 ... Second bus bar row, 16 ... Case, 17 ... Voltage detection terminal with electric wire (conductive) 18 ... 1st case, 19 ... 2nd case, 20 ... case connection part, 21 ... main-body part, 22 ... bottom wall, 23 ... accommodation fixing | fixed part, 24 ... electric wire accommodation part, 25 ... bottom face, 26 DESCRIPTION OF SYMBOLS ... Penetration part, 27 ... Mounting part, 28 ... Enclosure wall, 29 ... Terminal fixing part, 30 ... First edge part, 31 ... Second edge part, 32 ... Third edge part, 33 ... Fourth edge part, 34 ... Wire connection part mounting part (conductive path mounting part, terminal fixing Fixed part), 35 ... first terminal fixing part (terminal fixing part), 36 ... second terminal fixing part (terminal fixing part), 37 ... electric wire (conductive path), 38 ... terminal body (voltage detection terminal), 39 ... 40 ... Electric wire connecting part, 41 ... Fixed part, 42 ... Electrode insertion hole, 43 ... One end, 44 ... Other end, 45, 49 ... Stepped part, 46 ... Electric wire connecting part (Conducting path connecting part, Fixed part), 47 ... first fixed part (fixed part), 48 ... second fixed part (fixed part), 50 ... nut

Claims (5)

A battery assembly comprising a plurality of batteries, a terminal with a conductive path connected to the electrode of the battery, and an insulating case that accommodates at least a conductive terminal body in the terminal with the conductive path,
And while forming the penetration part which penetrates in the direction of an axis of the electrode in the case, and forming the flat electric contact part which has the electrode penetration hole in the terminal body,
In addition, the electrical contact portion is formed in a shape protruding from the bottom surface of the case on the battery side through the penetration portion, and a terminal fixing portion is formed on a peripheral edge of the penetration portion to form the electrical contact portion. Is fixed in a state of protruding from the bottom surface to the battery side ,
As a configuration of the fixed portion on the terminal body side, a first fixed portion is formed in a stepped state on one end side of the electrical contact portion, and a stepped state is also formed on the other end side opposite to the one end. A battery assembly and a terminal with a conductive path, characterized in that a conductive path connecting portion is formed, and a second fixed portion that is fixed together with the conductive path connecting portion is formed at the position of the other end. Connection structure. A battery assembly comprising a plurality of batteries, a terminal with a conductive path connected to the electrode of the battery, and an insulating case that accommodates at least a conductive terminal body in the terminal with the conductive path,
And while forming the penetration part which penetrates in the direction of an axis of the electrode in the case, and forming the flat electric contact part which has the electrode penetration hole in the terminal body,
In addition, the electrical contact portion is formed in a shape protruding from the bottom surface of the case on the battery side through the penetration portion, and a terminal fixing portion is formed on a peripheral edge of the penetration portion to form the electrical contact portion. Is fixed in a state of protruding from the bottom surface to the battery side ,
As construction of the pin solid tough, so as to form a first terminal fixing portions on the side away from the battery than the bottom surface in the first edge side of the penetrating portion, the opposite side of the first edge A second terminal fixing that forms a conductive path placement portion on the second edge side on the side farther from the battery than the bottom surface, and fixes the conductive path placement portion at the second edge position together with the conductive path placement portion. A connection structure between a battery assembly and a terminal with a conductive path, characterized in that a portion is formed. In the connection structure of the battery assembly according to claim 1 or 2 and a terminal with a conductive path,
The connection structure between a battery assembly and a terminal with a conductive path, wherein the electrical contact portion is formed in a shape protruding from the bottom surface by at least the thickness of the electrical contact portion . In the connection structure between the battery assembly according to claim 1, 2 or 3 and a terminal with a conductive path,
A structure for connecting a battery assembly and a terminal with a conductive path, wherein the terminal body is a voltage detection terminal and the conductive path in the terminal with the conductive path is an electric wire . In the connection structure between the battery assembly according to claim 1, 2, 3 or 4, and the terminal with a conductive path,
The battery further includes a conductive and flat connection plate for connecting the electrodes facing each other in a state where the batteries are adjacent to each other, and a mounting surface for the electric contact portion protruding from the bottom surface of the connection plate. A connection structure between a battery assembly and a terminal with a conductive path, which is formed and the connection plate is provided on the electrode in advance .

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