JP5277061B2 - Fusible link unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fusible link unit including a plurality of fusible links connected to a battery terminal allowing for changing an intersection angle of the fusible links and for easily changing the changed intersection angle. <P>SOLUTION: The fusible link unit 1 equipped with a plurality of fusible links 9, 11 connected to the battery terminal includes a holding member 5 which is configured separately from each fusible link and engages with the first fusible link 9 and the second fusible link 11 crossing the first fusible link 9 at a predetermined cross angle X to retain the predetermined cross angle X. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a fusible link unit, and more particularly to a fusible link unit that is used in the vicinity of a battery terminal of an automobile or the like.

  FIG. 17 is a perspective view showing a schematic configuration of a conventional fusible link unit (fuse unit) 200.

  In the conventional fusible link unit 200 described in Patent Document 1, a regulating wall 206 facing the inner wall 204 of one divided body 202 is erected on the inner wall 210 of the other divided body 208. The regulating wall 206 is provided with an inclined wall surface 212 that is inclined in a direction away from the inner wall 204 of one divided body 202.

  Falling prevention ribs 214 are provided at both ends of the restriction wall 206. One split body 202 is provided with a flexible arm body 218 having a hook 216, and the other split body 208 is provided with a notch 220 in the restriction wall 206 to constitute a first locking means. A locking projection is provided on 202, and an engagement groove 222 that engages with the locking projection is provided on the other divided body 208 to constitute a second locking means. Further, the engagement groove 222 is provided in the extending wall 228 from the side walls 224 and 226 of the other divided body 208.

  Moreover, patent document 2 can be hung up as a literature relevant to a prior art.

JP 2002-329457 A JP 2008-41379 A

  By the way, in the conventional fusible link unit 200, in order to maintain the L-shaped bending form, the resin body (divided body) 202, 208 constitutes the locking means, and the locking means is constituted. Holes are required on the busbar and resin body. Thereby, the mechanical strength with respect to the tightening torque when the wire harness (W / H) is connected is weakened.

  Further, in the fusible link unit 200, an L-shaped (90 ° bend) shape is maintained, but depending on how the fusible link unit 200 is used, the fusible link unit 200 is installed around the fusible link unit 200. In order to avoid interference with the equipment being used, an intersection angle other than 90 ° (eg, 110 ° or 120 °) may be required.

  The present invention has been made in view of the above problems, and in a fusible link unit having a plurality of fusible links connected to battery terminals, the intersection angle between fusible links can be changed. It is an object of the present invention to provide a fusible link unit that can easily maintain the crossing angle.

  According to a first aspect of the present invention, in the fusible link unit including a plurality of fusible links connected to battery terminals, the fusible links are configured separately from the fusible links. A first fusible link that is one of the fusible links, and another fusible link of the plurality of fusible links that has a predetermined crossing angle with respect to the first fusible link. A first holding member that engages with a second fusible link that intersects at the first fusible link and maintains the predetermined angle of intersection between the first fusible link and the second fusible link. It is a Bulllink unit.

  According to a second aspect of the present invention, in the fusible link unit according to the first aspect, the fusible link is configured separately from each of the fusible links, the second fusible link, and the plurality of fusible links. A second fusible link engaged with a third fusible link that is another fusible link of the links and intersects the second fusible link at a predetermined crossing angle; It is a fusible link unit which has the 2nd holding member which hold | maintains the said predetermined | prescribed intersection angle in a link and a said 3rd fusible link.

According to a third aspect of the present invention, in the fusible link unit according to the first or second aspect, each of the fusible links intersecting each other at a predetermined intersection angle is provided with a recess. The fusible link unit is configured such that the first holding member is inserted into the recess to hold the predetermined intersection angle between the fusible links.

  According to the present invention, in a fusible link unit including a plurality of fusible links connected to battery terminals, the intersection angle between fusible links can be changed, and it is easy to maintain the changed intersection angle. There is an effect that there is.

1 is a perspective view showing a schematic configuration of a fusible link unit according to a first embodiment of the present invention. It is a perspective view which shows schematic structure of the bus bar used for a fusible link unit. It is a III arrow directional view in FIG. It is a perspective view which shows schematic structure of the member for holding used for a fusible link unit. It is a perspective view which shows schematic structure of the member for holding | maintenance which concerns on a modification. It is a figure which shows the state which installed the fusible link wire in the fusible link unit, and is a figure corresponding to FIG. It is a VII arrow line view in FIG. It is a VIII arrow line view in FIG. It is IX arrow line view in FIG. It is a figure which shows schematic structure of the fusible link unit which concerns on the 2nd Embodiment of this invention. It is a figure which shows an example of the installation aspect of a fusible link unit. It is a figure which shows another example of the installation aspect of a fusible link unit. It is a figure which shows another example of the installation aspect of a fusible link unit. It is a figure which shows the installation form of a fusible link unit in case the distance between the bottom face of the recessed part in which the battery terminal is standingly arranged, and the upper surface of a battery differ. It is a figure which shows the installation form of the member for holding | maintenance. It is a figure which shows the modification of the installation form of the member for holding | maintenance. It is a perspective view which shows schematic structure of the conventional fusible link unit.

[First Embodiment]
FIG. 1 is a perspective view showing a schematic configuration of a fusible link unit 1 according to the first embodiment of the present invention, and FIG. 2 is a perspective view showing a schematic configuration of a bus bar 3 used in the fusible link unit 1. FIG.

  3 is a perspective view taken along the line III in FIG. 1, FIG. 4 is a perspective view showing a schematic configuration of a holding member 5 used in the fusible link unit 1, and FIG. It is a perspective view which shows schematic structure of the member 5a for use.

  FIG. 6 is a diagram illustrating a state in which the fusible link wire 7 is installed in the fusible link unit 1, and corresponds to FIG. 3.

  7 is a view taken along arrow VII in FIG. 1, FIG. 8 is a view taken along arrow VIII in FIG. 7, and FIG. 9 is a view taken along arrow IX in FIG.

  The fusible link unit (fuse unit) 1 is connected to, for example, a battery terminal (not shown in FIG. 1) of an automobile and is used in the vicinity of the battery of the automobile, and is connected to the battery terminal. A plurality of fusible links 9 and 11 and a holding member 5 are provided.

  The holding member 5 is separate from the fusible links 9 and 11 and is made of a highly rigid material such as metal. Then, the holding member (lock piece; metal piece) 5 is engaged with the fusible link 9 and the fusible link 11, and a predetermined crossing angle (bending angle) between the fusible link 9 and the fusible link 11. X (see FIG. 3) is defined and held.

  In addition, the fusible link 9 is one fusible link of the plural fusible links 9 and 11 as already understood, and the fusible link 11 is the other fusible link of the plural fusible links. One fusible link that is adjacent to and connected to the fusible link 9 and intersects the fusible link 9 at a predetermined intersection angle X.

  In addition, recesses 13 and 15 are provided in the fusible links 9 and 11 that intersect each other at a predetermined intersection angle X, respectively. The holding member 5 is inserted into the recesses 13 and 15 to define and hold a predetermined crossing angle X between the fusible links 9 and 11.

  The fusible link unit 1 will be described in more detail.

  The fusible link unit 1 includes a plurality of (for example, two) fusible links 9 and 11 as described above. Each fusible link 9, 11 includes a bus bar 3 made of a conductive material such as metal, and resin bodies 19, 21 made of an insulating resin.

  That is, the fusible link unit 1 includes a predetermined number of bus bars (one bus bar formed integrally or one bus bar integrally formed by joining a plurality of materials) and a predetermined bus bar 3. A plurality of (for example, two) resin bodies 19 and 21 provided integrally with one bus bar 3 so as to cover a plurality of places are provided.

  In the case where a fusible link unit is configured by two fusible links 9 and 11, a resin body 19 covers a predetermined portion on one side of one bus bar 3, and The resin body 21 covers a predetermined portion on the other side. The portion on the side where the resin body 19 is provided constitutes the fusible link 9, and the portion on the side where the resin body 21 is provided constitutes the fusible link 11.

  The resin body 19 and the resin body 21 are provided on the bus bar 3 by, for example, insert molding (integrated with the bus bar 3), and the bus bar 3 is exposed between the resin body 19 and the resin body 21. Yes. The fusible link 9 and the fusible link 11 are connected to each other at a portion where the bus bar 3 is exposed (hinge portion 59).

  Then, by bending the bus bar 3 in the thickness direction at a portion where the bus bar 3 is exposed (hinge portion 59), the fusible link 9 and the fusible link 11 may have a predetermined crossing angle (may be 180 °). Cross at X. Further, the bus bar 3 is connected to a battery terminal (not shown), whereby the fusible link unit 1 (the fusible links 9 and 11) is connected to the battery terminal.

  The holding member 5 is configured separately from the bus bar 3 and the resin bodies 19 and 21. The resin body 19 is provided with a recess 13 into which one portion in the longitudinal direction of the holding member 5 is inserted and fitted. The resin body 21 has the other portion in the longitudinal direction of the holding member 5. A recess 15 is provided to be inserted and fitted.

  In addition, the holding member 5 is bent at a predetermined angle Y (see FIG. 4) at an intermediate portion in the longitudinal direction. Then, the holding member 5 is fixed to the fusible links 9 and 11 by inserting and fitting the holding members 5 into the concave portions 13 and 15 of the resin bodies 19 and 21, and the fusible links. The crossing angle X between 9 and the fusible link 11 is fixed and held at the same angle as the bending angle Y of the holding member 5. That is, the intersection angle X between the fusible link 9 and the fusible link 11 can be regulated (defined) by adjusting the bending angle Y of the holding member 5.

  In more detail, the second embodiment will be described with reference to FIG. 10 and the like, but in the case where the fusible link unit 1a is configured by three fusible links 23, 25, 27, one A predetermined portion on one side of the bus bar 29 is covered with a resin body 31, a predetermined portion in the middle of one bus bar 29 is covered with a resin body 33, and a predetermined portion on the other side of one bus bar 29 is covered. Is covered with a resin body 35. And the site | part in which the resin body 31 is provided comprises the fusible link 23, the site | part in which the resin body 33 is provided comprises the fusible link 25, and the resin body 35 is provided. The fusible link 27 constitutes the portion on the side that is on the side.

  The resin body 31, the resin body 33, and the resin body 35 are provided on the bus bar 29 by insert molding, for example, in the same manner as when the fusible link unit is configured by the two fusible links 9, 11. The bus bar 29 is exposed between the resin body 31 and the resin body 33 and between the resin body 33 and the resin body 35. The fusible link 23 and the fusible link 25 are connected to each other at a portion (hinge portion 97) where the bus bar 29 is exposed, and the fusible link 25 and the fusible link 27 are exposed to the bus bar 29. The other parts (hinge part 99) are connected to each other.

  The fusible link 23 and the fusible link 25 intersect at a predetermined intersecting angle by bending the bus bar 29 at each portion (the hinge portions 97 and 99) where the bus bar 29 is exposed. And the fusible link 27 cross each other at a predetermined crossing angle. By connecting the bus bar 29 to the battery terminal 93 (see FIG. 11 and the like), the fusible link unit 1a (each fusible link 23, 25, 27) is connected to the battery terminal 93.

  Similarly to the case where the fusible link unit 1 is constituted by the two fusible links 9 and 11, the resin bodies 31, 33 and 35 have recesses 37, 39 and 41 (see FIG. 10B). ) Is provided. Then, a holding member 43 is inserted and fitted into the recess 37 of the resin body 31 and the recess 39 of the resin body 33, and another holding member 45 is inserted into the recess 39 of the resin body 33 and the recess 41 of the resin body 35. Is inserted and fitted so that the crossing angle between the fusible links 23, 25 and 27 is fixed and held (see FIG. 15).

  It is to be noted that the holding member 43 inserted and fitted in the recess 37 of the resin body 31 and the recess 39 of the resin body 33 and the recess 39 of the resin body 33 and the recess 41 of the resin body 35 are fitted. The holding member 45 is separate from the holding member 45 (see FIG. 15). However, these holding members 43 and 45 may be connected to each other to form one holding member 47 (see FIG. 16). ).

  Incidentally, since the material of the resin body 19 appears on the inner surface of the recess 13 of the resin body 19 in the fusible link unit 1 shown in FIG. 1 and the like, the bus bar 3 is not exposed. The same applies to the inner surface of the recess 15 of the resin body 21.

  Therefore, in a state where the holding member 5 or the like is installed in the recess 13 or the like of the resin body 19, the material of the resin body 19 or the like exists between the bus bar 3 or the like and the holding member 5 or the like. The holding member 5 and the like are not in contact with each other. However, the resin body 19 and the like are provided so that the bus bar 3 and the like are exposed on the inner surface of the recess 13 and the like of the resin body 19, and the holding member 5 and the like are held in the recess 13 and the like of the resin body 19 and held with the bus bar 3 and the like. The structure which the member 5 grade | etc., Mutually contacts may be sufficient.

  Here, the fusible link unit 1 will be described in more detail with reference to FIG.

  As described above, the fusible link unit 1 includes the two fusible links 9 and 11 including the one bus bar 3 and the two resin bodies 19 and 21.

  The bus bar 3 is formed by press-molding a material made of a flat metal, and includes a battery-side flat plate portion 49, an alternator-side flat plate portion 50, a starter motor-side flat plate portion 51, and a device. Side flat plate portion 53, and first soluble portion that connects battery side flat plate portion 49 and alternator side flat plate portion 50 to each other between battery side flat plate portion 49 and alternator side flat plate portion 50. (Fuse element) 55, and a second fusible portion (fuse element) 57 that connects the starter motor side flat plate portion 51 and the device side flat plate portion 53 to each other (FIG. 2). reference).

  Before the resin bodies 19 and 21 are provided, the bus bar 3 is not bent and is formed in a flat plate shape. This facilitates insert molding of the resin bodies 19 and 21.

  In the bus bar 3 before the resin bodies 19 and 21 are provided, the battery side flat plate portion 49 and the starter motor side flat plate portion 51 are formed in one flat plate shape. A hinge portion 59 is formed at the boundary with the motor side flat plate portion 51. After the resin bodies 19 and 21 are provided on the bus bar 3, the fusible links 9 and 11 intersect at a predetermined angle X by bending the bus bar 3 in the thickness direction at the hinge portion 59. .

  Further, in the bus bar 3 before the resin bodies 19 and 21 are provided, the battery side flat plate portion 49, the alternator side flat plate portion 50, the starter motor side flat plate portion 51, the device side flat plate portion 53, and the first fusible portion. 55 and the second fusible portion 57 are located on substantially the same plane. On the other hand, the battery-side flat plate portion 49, the first fusible portion 55, and the alternator-side flat plate portion 50 are substantially identical by bending the bus bar 3 at the hinge portion 59 after the resin bodies 19 and 21 are provided on the bus bar 3. The starter motor side flat plate portion 51, the second fusible portion 57, and the device side flat plate portion 53 are positioned on substantially the same plane (another plane), and the fusible link 9 (battery side). The flat plate portion 49 and the like) and the fusible link 11 (starter motor side flat plate portion 51 and the like) intersect at a predetermined angle X.

  At the center of the battery-side flat plate portion 49, a battery terminal connection portion 61 (battery terminal connection through-hole; thickness direction of the battery-side flat plate portion 49) for connecting the fusible link unit 1 to a battery terminal (not shown). A through-hole penetrating through the substrate). At the center of the alternator side flat plate portion 50, an alternator terminal connection portion 63 (through hole for connecting an alternator terminal; thickness direction of the alternator side flat plate portion 50) for connecting the fusible link unit 1 to an alternator terminal (not shown). A through-hole penetrating through the substrate). A starter motor terminal connecting portion 65 (starter motor terminal connection) for connecting the fusible link unit 1 to a starter motor terminal (not shown) is provided at the tip end side (the side away from the hinge portion 59) of the starter motor side flat plate portion 51. Through-hole; a through-hole penetrating in the thickness direction of the starter motor side flat plate-like portion 51) is provided. At the center of the device-side flat plate portion 53, a device connection portion 67 (device connection through hole; device-side flat plate shape) for connecting the fusible link unit 1 to a terminal of an electric device (for example, a headlight) (not shown). A through-hole penetrating in the thickness direction of the portion 53 is provided.

  The resin bodies 19 and 21 are installed on the bus bar 3 by inserting bolts 69 into the alternator terminal connecting through holes 63 of the bus bar 3 and engaging nuts 71 with the device connecting through holes 67 of the bus bar 3. The nut 73 is engaged with the through hole 65 for connecting the starter motor terminal. Thereby, the bolt 69 and the nuts 71 and 73 are integrally installed on the bus bar 3 and the resin body 19 and 21.

  The bolt 69 is inserted into the alternator terminal connecting through-hole 63 of the bus bar 3 in such a manner that the head of the bolt 69 comes into contact with one surface in the thickness direction of the alternator side flat plate portion 50 and the male screw portion of the bolt 69 is the alternator. The side flat plate portion 50 protrudes from the other surface in the thickness direction.

  The engagement of the nut 71 with the device connection through-hole 67 of the bus bar 3 is such that the device connection through-hole 67 and the female thread of the nut 71 are coaxial, and the nut 71 is one side in the thickness direction of the device-side flat plate portion 53. It is made to abut on the surface. The engagement of the nut 73 with the starter motor terminal connecting through hole 65 of the bus bar 3 is performed in the same manner.

  In addition, the resin body 19 constituting the fusible link 9 is installed such that the male screw portion of the bolt 69 installed in the alternator terminal connecting through hole 63 and the alternator side flat plate portion 50 around the male screw portion. The first fusible portion 55 and its periphery are exposed, the battery terminal connecting through hole 61 and the battery side flat plate portion 49 around the through hole 61 are exposed, and the hinge 59 and the vicinity thereof are exposed. The part is exposed so as to be exposed.

  The resin body 21 constituting the fusible link 11 is installed by exposing the device connecting through-hole 67 and the female screw of the nut 71 engaged with the through-hole 67. A predetermined portion of the device-side flat plate portion 53 in the periphery is exposed, the second fusible portion 57 is exposed, and the starter motor terminal connecting through hole 65 and the female of the nut 73 engaged with the through hole 65 are exposed. The screw is exposed, the starter motor terminal connecting through hole 65 and the starter motor side flat plate portion 51 around the through hole 65 are exposed, and the hinge portion 59 and the vicinity thereof are exposed. Yes.

  Thereby, the resin body 19 and the resin body 21 are separated at the hinge portion 59.

  The exposed predetermined portion of the device-side flat plate portion 53 around the device connection through hole 67 is located on the opposite side of the nut 71 in the thickness direction of the device-side flat plate portion 53. It is a site | part of the apparatus side flat plate-like part 53, Comprising: It is a site | part around the through-hole 67 for apparatus connection. The same applies to the predetermined portion of the exposed starter motor terminal flat plate portion 51 around the starter motor terminal connecting through hole 65.

  By the way, in the initial state where the resin bodies 19 and 21 are provided on the bus bar 3 and the bus bar 3 is not bent at the hinge portion 59, the fusible link unit constituted by the fusible links 9 and 11. 1 is formed in a flat plate shape whose thickness direction substantially coincides with the thickness direction of the bus bar 3.

  The recess (slit) 13 is formed in the resin body 19, and the recess (slit) 15 is formed in the resin body 21.

  The recess 13 formed in the resin body 19 is formed on the side surface of the resin body 19. That is, the concave portion 13 is formed on the surface of the resin body 19 that is substantially orthogonal to the linear bending line of the hinge portion 59. The recess 13 is formed by a rectangular flat space. The thickness direction of the concave portion 13 substantially coincides with the thickness direction of the resin body 19 (battery side flat plate portion 49). The depth direction of the concave portion 13 substantially coincides with the width direction of the resin body 19 (the extending direction of the bending line of the hinge portion 59). The length direction of the concave portion 13 substantially coincides with the direction away from the hinge portion 59.

  Further, the concave portion 13 is located in the middle portion of the resin body 19 in the thickness direction in the thickness direction. More specifically, the bus bar 3 is located in the middle part of the resin body 19 in the thickness direction, but the middle part of one part in the thickness direction (one part of the resin body 19) divided by the bus bar 3 The recess 13 is located at the top.

  Further, the recess 13 is open at the side surface of the resin body 19 in the depth direction, and the bottom of the recess 13 is located at the intermediate portion of the resin body 19. Further, in the longitudinal direction, the concave portion 13 is opened at a surface of the resin body 19 facing the hinge portion 59, and the bottom portion of the concave portion 13 is located at an intermediate portion of the resin body 19.

  The second recess (slit) 15 is also formed in the same shape as the recess 13 and is provided in the resin body 21 in the same manner.

  The holding member 5 has a width substantially equal to the depth of each of the recesses 13 and 15, a thickness that is slightly smaller than the thickness of each of the recesses 13 and 15, and a length that is the length of the recess 13 and the length of the recess 15. A flat plate material slightly shorter than the sum of the lengths of the hinge portions 59 is formed in a “<” shape that is bent by a predetermined angle Y in the thickness direction at the middle portion in the longitudinal direction (FIG. 4). reference).

  By being bent in this way, the first portion 75 which is one flat plate portion with a bend line interposed therebetween and the second portion 77 which is the other flat plate portion with the bend line interposed therebetween. And are formed. The first portion 75 is inserted into the recess 13 and the second portion 77 is inserted into the recess 15.

  The corner portion of the first part 75 is provided with an oblique notch 79 (a notch formed like a chamfer when the first part 75 is viewed from the thickness direction) 79. Thus, the holding member 5 can be easily installed in the recesses 13 and 15.

  Further, the holding member 5 is prevented from slipping out of the recesses 13 and 15 when the holding member 5 is installed in the recesses 13 and 15 of the resin bodies 19 and 21. (Preventing the holding member 5 from being separated from the fusible links 9 and 11), and locking means for integrating the resin bodies 19 and 21 and the holding member 5 are provided. .

  As the locking means, a terminal lance 81 provided on one surface in the thickness direction of the first portion 75 and a terminal lance 83 provided on one surface in the thickness direction of the second portion 77. Can be raised.

  The terminal lance 81 is provided in the holding member 5 so as to be able to appear and retract. The terminal lance 81 is biased so as to protrude most from the holding member 5 by biasing means such as a spring (not shown). The terminal lance 81 is not separated from the holding member 5. The terminal lance 83 is also provided in the same manner as the terminal lance 81.

  When the holding member 5 is being installed in the recesses 13 and 15, the terminal lances 81 and 83 are depressed by the inner walls of the recesses 13 and 15, and the holding member 5 is installed in the recesses 13 and 15. In the finished state, the terminal lances 81 and 83 protrude into small recesses (not shown) provided in the inner walls of the recesses 13 and 15 of the resin bodies 19 and 21, and the protruding terminal laths 81 and 83 are The holding member 5 and the resin bodies 19 and 21 are integrated with each other by being caught in the small depression.

  As shown in FIG. 5, the holding member 5 a may be fixed to the fusible links 9 and 11 with bolts 85. In this case, without forming a recess in the resin bodies 19, 21, the holding member 5 a is attached integrally to the outer surface of the resin bodies 19, 21. The intersection angle (intersection angle between the fusible links 9 and 11) may be fixed and held.

  Here, the assembly procedure of the fusible link unit 1 will be described.

  First, the fusible link unit 1 in the initial state (not bent at the hinge portion 59) is bent at an angle close to a desired angle at the hinge portion 59. Further, the holding member 5 is bent at the desired angle at the bend line.

  Subsequently, the holding member 5 is inserted into the recesses 13 and 15, and the holding member 5 is integrally fixed to the resin bodies 19 and 21.

  Thereby, the assembly of the fusible link unit 1 is completed. The fusible link unit 1 assembled in this way is connected to a battery terminal or the like, and is integrally assembled to the battery in the vicinity of a battery such as an automobile.

  According to the fusible link unit 1, the holding member 5 configured separately from the fusible links 9 and 11 is engaged with the fusible links 9 and 11, and the intersection angle between the fusible links 9 and 11. Since X is fixed and held, the intersection angle between the fusible links 9 and 11 is changed (for example, changed to an intersection angle other than 90 ° such as 110 °), and the changed intersection angle is held. In the case of (maintenance), the bending angle Y of the holding member 5 may be changed, and the change of the crossing angle X between the fusible links 9 and 11 becomes easy.

  And even if it is a case where the use aspect (purpose) of the fusible link unit 1 changes, it installs in the circumference | surroundings of the fusible link unit 1 by changing the intersection angle X of the fusible links 9 and 11. Interference between the device and the fusible link unit 1 can be easily avoided.

  Moreover, since the fusible links 9 and 11 are held by the highly rigid holding member 5, the rigidity of the fusible link unit 1 is increased, and the wire harness (W / H) is connected to the fusible link unit 1. The mechanical strength with respect to the tightening torque is increased, and the occurrence of problems such as cracking of the resin bodies 19 and 21 can be prevented.

  In addition, since the holding member 5 is made of metal, heat generated by the fusible link unit 1 escapes to the atmosphere through the holding member 5 and the fusible link unit 1 is easily cooled.

  Further, according to the fusible link unit 1, when the intersection angle X between the fusible links 9 and 11 is defined and held, the holding member 5 is inserted into the recesses 13 and 15 of the fusible links 9 and 11. Since it is good, the assembly of the fusible link unit 1 is simplified.

  If the crossing angle X between the fusible links 9 and 11 is an obtuse angle, as shown in FIG. 6, when the fusible link unit 1 is installed on the battery terminal 93, the battery 95 and the fusible link unit 1 The space between them can be expanded, and the fusible link wire 7 provided with the connector 91 can be installed in the expanded space.

  Incidentally, as shown in FIGS. 1 and 3, ribs 87 and 89 may be provided on the resin bodies 19 and 21 of the fusible link unit 1.

  That is, elongated ribs 87 project from the surface of the resin body 19 (the surface located on the opposite side of the bus bar 3 with the recess 13 in between), and the surface of the resin body 21 (the bus bar 3 with the recess 15 in between). The strength of the resin bodies 19 and 21 may be improved by providing elongated ribs 89 protruding on the surface opposite to the surface. By improving the strength, it is possible to avoid a situation in which the resin bodies 19 and 21 are broken or damaged when the holding member 5 is installed in the recesses 13 and 15 or thereafter.

[Second Embodiment]
FIG. 10 is a diagram showing a schematic configuration of the fusible link unit 1a according to the second embodiment of the present invention. FIG. 10A is a plan view of the fusible link unit 1a, and FIG. ) Is a view taken in the direction of arrow B in FIG.

  The fusible link unit 1a according to the second embodiment is configured to include three fusible links 23, 25, and 27. The intersection angle between these fusible links is set to two holding members 43, The fusible link unit 1 according to the first embodiment is different from the fusible link unit 1 according to the first embodiment in that it is regulated using 45, and the other points are configured in substantially the same manner as the fusible link unit 1 according to the first embodiment. .

  That is, the fusible link unit 1a according to the second embodiment includes a fusible link 23 that includes a portion on one side of the bus bar 29 and the resin body 31, an intermediate portion of the bus bar 29, and a resin body. 33 and a fusible link 25 configured to include a portion on the other side of the bus bar 29 and a resin body 35.

  As shown in FIG. 15, the intersection angle between the fusible link 23 and the fusible link 25 is regulated by the holding member 43, and the intersection angle between the fusible link 25 and the fusible link 27 is maintained. It is regulated by the member 45 for use.

  At a hinge part (hinge part between the fusible link 23 and the fusible link 25) 97 and a hinge part (hinge part between the fusible link 25 and the fusible link 27) 99 shown in FIG. The bus bar 29 is bent.

  The fusible link 23 is provided with a battery terminal connecting through hole 61, the fusible link 25 is provided with fusible portions 55 and 57, and the fusible link 27 has a tab terminal. 101 is provided.

  FIG. 11 is a diagram illustrating an example of an installation mode of the fusible link unit 1a.

  In the embodiment shown in FIG. 11, the fusible link is connected via the battery terminal connecting stud bolt 103 joined to the battery terminal connecting through hole 61 without bending the hinge portions 97 and 99 of the fusible link unit 1a. The unit 1 a is installed on the battery terminal 93, and the fusible link unit 1 a extends along the upper surface of the battery 95.

  FIG. 12 is a diagram illustrating another example of the installation mode of the fusible link unit 1a. In the aspect shown in FIG. 12, only the hinge part 97 of the fusible link unit 1a is bent at a right angle, for example. The fusible link unit 1 a is installed on the battery terminal 93 via the battery terminal connection stud bolt 103 joined to the battery terminal connection through hole 61. In this state, the fusible link 25 and the fusible link 27 of the fusible link unit 1 a extend downward along the side surface of the battery 95. In addition, in the embodiment shown in FIG. 12, the battery terminal 93 is erected in a recessed portion recessed downward from the upper surface of the battery 95 (DIN standard battery).

  FIG. 13 is a diagram showing still another example of the installation mode of the fusible link unit 1a. In the embodiment shown in FIG. 13, the hinge portions 97, 99 of the fusible link unit 1a are connected to the hinge portions 97, 99 so that the fusible links 23, 27 existing at both ends are substantially parallel to each other. Is bent to an obtuse angle. The fusible link unit 1 a is installed on the battery terminal 93 via the battery terminal connection stud bolt 103 joined to the battery terminal connection through hole 61. In the embodiment shown in FIG. 13 as well, the battery terminal 93 is erected in a recess recessed downward from the upper surface of the battery 95, as in the case shown in FIG. In the state where the fusible link unit 1 a is installed on the battery terminal 93, only the fusible link 27 extends along the upper surface of the battery 95.

  In the case shown in FIG. 13, when the distance (step size) between the flat bottom surface of the recess in which the battery terminal 93 is erected and the upper surface of the battery 95 is different (FIG. 14A). Even when the dimension h1 shown in FIG. 14 is different from the dimension h2 shown in FIG. 14B), the bending angles of the hinge portions 97 and 99 (the bending angles of the holding members 43 and 45) are changed as appropriate. As a result, the fusible link 27 farthest from the battery terminal 93 can be installed in parallel to the upper surface of the battery 95 at an appropriate distance from the upper surface of the battery 95.

  According to the fusible link unit 1a, the three fusible links 23, 25 and 27 are connected in series, and the holding members 43 and 45 adjust and hold the crossing angle between the fusible links 23, 25 and 27. Therefore, the fusible link unit 1a can be installed along the outer shape (surface) of the battery 95 having a step as shown in FIG. Thereby, the space required for installation of the fusible link unit 1a can be reduced.

  In addition, you may employ | adopt the thing provided with four or more fusible links as a fusible link unit. In this case, not all the fusible links need be connected in series, and some of them may be branched and connected in parallel.

1, 1a Fusible link unit 3, 29 Bus bar 5, 5a, 43, 45, 47 Holding member 9, 11, 23, 25, 28 Fusible link 13, 15, 37, 39, 41 Recessed part 19, 21, 31 , 33, 35 Resin body

Claims (3)

In the fusible link unit with multiple fusible links connected to the battery terminals,
Each of the fusible links is configured separately, and a first fusible link that is one fusible link of the plurality of fusible links and another fusible link of the plurality of fusible links. The first fusible link and the second fusible link are engaged with a second fusible link that intersects the first fusible link at a predetermined crossing angle. A fusible link unit comprising a first holding member that holds the predetermined crossing angle with a bull link. The fusible link unit according to claim 1,
Each of the fusible links is configured separately from the second fusible link, the second fusible link, and another fusible link of the plurality of fusible links. A second fusible link that engages with a third fusible link that intersects the link at a predetermined crossing angle to maintain the predetermined crossing angle at the second fusible link and the third fusible link; A fusible link unit comprising a holding member. The fusible link unit according to claim 1 or 2,
Each of the fusible links intersecting each other at a predetermined crossing angle is provided with a recess,
The fusible link unit, wherein the first holding member is inserted into the recess to hold the predetermined intersection angle between the fusible links.

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