JP2010040254A - Fusible link - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fusible link capable of aiming at downsizing and reduction in man-hour, while preventing slanted clamping of a nut in clamping one on a stud bolt fitted to the fusible link. <P>SOLUTION: The fusible link 1 directly attached to a post of a vehicle-use battery is provided with a plurality of busbars 10 formed of a conductive metal plate material, a fusible element part arranged so as to electrically connect between the plurality of busbars, a stud bolt 4 erected on the busbars 10 to be an external connection terminal, and a housing 5 insulation-coating the busbars 10. The fusible link 1 is further provided with a guide member 6 arranged coaxially with the stud bolt 4 so as to surround the same 4 and detachable from the housing 5, and, in clamping the nut 8 onto the stud bolt 4, a nut-clamping tool 15 is guided by the guide member 6 to clamp the nut 8. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a fusible link.

  Today's automobiles are becoming more automated, and are equipped with various electronic devices for travel control, electrical junction boxes, and fusible links.

  The fusible link is equipped with a fuse holder to which the fusible link is attached, and the bus bar and wire harness are connected to the connection terminal of the fusible link attached to the fuse holder using nuts and bolts. Has been.

  Hereinafter, a connection terminal fixing structure disclosed in Patent Document 1 will be described as an example of a conventional fusible link.

  As shown in FIG. 15, the connection terminal fixing structure 41 is applied to an electrical connection box 42 mounted on an automobile. A fusible link holder (hereinafter simply abbreviated as a holder) 43 is provided on the upper surface of the electrical junction box 42, and a fusible link (hereinafter simply abbreviated as F / L) 44 is detachably attached to the holder 43. It is supposed to be installed. The F / L 44 includes a pair of fuse terminals and a fuse element connected between the terminals.

  On the other hand, the connection terminal 46 connected to the electric wire 45 is inserted from the lower surface in the electrical connection box 42. The connection terminal 46 is fastened and fixed to the fuse terminal by a bolt 48 together with the bus bar disposed in the electrical connection box 42.

  When the fastening is performed, the bolt 48 is held using an impact wrench (not shown) and screwed into a nut provided in the electrical connection box 42. At this time, guide portions 49a and 49b are formed toward the tightening position in order to guide the impact wrench to the screwing position and to further prevent the bolt 48 from falling off.

As described above, in the connection structure of the connection terminal disclosed in Patent Document 1, the connection terminal 46 is fastened and fixed by using the bolt 48, but there is also a connection structure by tightening the nut.
Hereinafter, the fusible link disclosed in Patent Document 2 will be described as an example of nut tightening.

  As shown in FIG. 16, the fusible link 51 includes a standard specification unit 52 that is commonly installed in all the vehicles to be mounted, and an optional specification unit that is arbitrarily installed in a specific vehicle among all the vehicles to be mounted. 53. The option specification unit 53 is detachably combined with the standard specification unit 52.

  Each of the standard specification unit 52 and the optional specification unit 53 includes a fusible link structure constituted by bus bars (not shown), and insulating cases 54 and 55 that cover most parts of the fusible link structure from the outside. ing. One end of each fusible link component is provided with a load side connection terminal connected to the power supply side connection terminal 56 via a fusible portion (not shown). The load side connection terminals are provided in the housings 57a and 57b.

  The connection terminal 58 is an alternator connection terminal that is electrically connected to the power supply side connection terminal 56, and is a bolt fixed in an upright state. A connection terminal to which an electric wire (not shown) is connected is inserted into the connection terminal 58 and fastened using a nut.

  In this tightening and fixing, a nut is set on a tool (socket), the nut is applied to the top of the connection terminal 58 along a semicircular guide portion 59, and is rotated and screwed together. Then, after tightening and fixing are completed, only the tool is lifted to complete the tightening operation.

Japanese Patent Laid-Open No. 10-92484 JP 2005-310710 A

  It is known that oblique tightening occurs when bolt tightening is performed as shown in Patent Documents 1 and 2 or when a nut is tightened. This is a state in which the pitch of the bolt and the nut does not match, and the nut is screwed obliquely, and a sufficient force is not applied to the tightening position, resulting in contact failure and the like.

In order to solve the above problem, the following measures have been conventionally taken.
The first countermeasure is a method in which an operator rotates a fastening bolt or nut with a finger about two turns to perform temporary setting when performing a screw tightening operation. However, this measure has a problem that the working tact time becomes long and the production cost becomes high.

  The second countermeasure is to provide an incomplete threaded portion, that is, a portion without a screw, at the tip of the screw to set the expansion of the nut. This screw is called a rod end bolt. However, this measure increases the cost of bolts, and when applied to the fusible link, the protective wall for protecting the bolts increases as the bolt length increases, making the fusible link large. There are problems such as

  On the other hand, the fusible link 44 disclosed in Patent Document 1 includes guide portions 49a and 49b for restricting the axial wobbling of an impact wrench, which is a tightening tool, at the tightening position of the bolt 48. However, in this configuration, since the bolt fastening position is provided inside the fusible link, the degree of freedom in design is reduced.

  Further, the fusible link 51 shown in Patent Document 2 includes a guide portion 59 formed by insert molding around a connection terminal (stud bolt) 58. The guide portion 59 has effects such as guidance at the time of fastening the nut and protecting the connection terminal 58 at the time of carrying in to prevent damage. However, in this configuration, the height of the guide portion 59 is higher than that of the connection terminal 58, and the guide portion 59 remains protruding even after the nut is tightened. For this reason, when the height of the upper part of the fusible link 51 is reduced, it is also an obstacle to the wearability of the cover.

  The present invention has been made in view of the above problems, and its object is to prevent diagonal tightening of a nut when a connection terminal is fastened with a nut to a stud bolt for electrical connection provided in a fusible link. It is to provide a fusible link of configuration.

The object of the present invention is achieved by the following constitution.
(1) A plurality of bus bars formed from a conductive metal plate material and a low melting point metal that is arranged so as to be electrically connected between the plurality of bus bars and melts by energization heat generation when a current exceeding the rating flows. A soluble body part of
A stud bolt standing on the bus bar and serving as an external connection terminal;
A housing for insulatingly covering the bus bar;
A fusible link directly attached to a vehicle battery post,
A guide member disposed concentrically with the stud bolt so as to surround the stud bolt and detachable from the housing;
A fusible link characterized in that when a nut is fastened to the stud bolt, a nut fastening tool is guided by the guide member to fasten the nut.

(2) The guide member includes a cylindrical body that surrounds the stud bolt in the axial direction, and a flexible leg portion that extends to a housing-side portion of the cylindrical body and has a first locking portion. Is provided,
A portion corresponding to the flexible leg portion of the housing is formed with a through hole in which the first locking portion is locked,
The fusible link according to (1), wherein the guide member can be attached to and detached from the housing by engaging and disengaging the first locking portion with the through hole.

(3) A flexible arm having a second locking portion that is locked to the nut fastening tool at the time of nut tightening work at a portion of the cylindrical member of the guide member on the nut fastening tool insertion side. Part is provided,
The locking force in the first locking portion of the flexible leg is set to be smaller than the locking force in the second locking portion of the flexible arm portion,
After the nut is fastened, the guide member is removed from the housing by being pulled up integrally with the nut fastening tool in a state of being locked to the nut fastening tool. Fusible link.

(4) The inner surface of the flexible leg is brought into contact with the nut fastening tool when the nut is fastened to elastically deform the flexible leg, and the nut is fastened by the elasticity of the flexible leg. A first tapered surface pressed against the tool;
A second tapered surface that abuts against an edge of the through hole of the housing and elastically deforms the flexible leg;
The deformation of the flexible leg due to the first taper surface while the second taper surface is locked to the edge due to the deformation of the flexible leg due to the guide being brought into contact with the edge. And a locking groove that is unlocked by,
After the nut fastening, the flexible leg is elastically deformed by the contact between the nut fastening tool and the first tapered surface, and the engagement between the locking groove and the edge is released, and The fusible link according to (2), wherein the guide member is removed from the housing integrally with the nut fastening tool by pressing the first tapered surface against the nut fastening tool.

  According to the configuration (1), the nut fastening tool is guided by the guide member by attaching the guide member around the stat bolt and tightening the nut, so that no eccentricity or shaft runout occurs. For this reason, slant tightening of the nut can be prevented.

  Moreover, since the said guide member can be removed after nut fastening, a fusible link can be made low-profile. Further, after the guide member is removed, a fusible link cover or the like for covering the external connection terminal can be attached using the guide member attaching portion of the housing.

  According to the configuration of (2), the flexible leg portion having the first locking portion is deformed to engage / disengage from the housing, so that the guide member can be attached and detached with a simple configuration. .

  According to the configuration of (3), when the nut fastening is finished, the second locking portion formed on the flexible arm portion is locked to the nut fastening tool. The guide member can be removed integrally.

  According to the configuration of (4), when the nut fastening is finished, the first taper surface formed on the flexible leg is in pressure contact with the tool, and the engagement between the locking groove and the through-hole edge is performed. The match is released. For this reason, the guide member can be removed integrally with the nut fastening tool.

  As described above, according to the present invention, the guide member constituted by the cylindrical body is attached around the stud bolt, so that the nut fastening tool is guided by the guide member when the nut is fastened to the stud bolt. Thus, eccentricity and shaft runout of the tool can be suppressed. Thereby, the nut is not obliquely tightened, and the reliability of the fusible link can be improved.

  Further, the flexible leg portion provided on the guide member is provided with a first locking portion that can be removed from the through hole when the nut tightening is completed, and the flexible arm portion includes a nut when the nut tightening is completed. Since the 2nd latching | locking part which latches the tool for fastening is provided, a guide member can be removed integrally with the tool for nut fastening, and the effort and man-hour of removal can be reduced.

  In addition, the flexible leg has a locking groove in which the first tapered surface that is in pressure contact with the nut fastening tool and the edge of the through hole are released when the nut is tightened. Since the guide member can be removed integrally with the nut fastening tool, the time and labor for removal can be reduced.

Further, the height of the fusible link can be reduced by removing the guide member.
Furthermore, another member, for example, a fusible link cover or the like, can be attached using a through hole for attaching a guide member formed in the housing.

DESCRIPTION OF EMBODIMENTS Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the drawings.
FIG. 1 is a perspective view of a fusible link according to an embodiment of the present invention, FIG. 2 is a side view of the fusible link, FIG. 3 is a perspective view showing a configuration of a guide member, and FIG. FIG.

  As shown in FIGS. 1 and 2, a fusible link 1 according to an embodiment of the present invention includes a plurality of conductive metal bus bars 10 having power supply side connection terminals 2 connected to a battery (not shown), and a plurality of bus bars 10. The bus bar 10 includes a plurality of fusible portions 3 made of a low-melting-point metal that are electrically connected to each other and a stud bolt 4 as an external connection terminal connected to another electric device, for example, an alternator. The portion is covered with a housing 5 made of synthetic resin. The stud bolt 4 is erected at one end of the bus bar 10. The stud bolt 4 is surrounded by a guide member 6 formed in a substantially hollow cylindrical shape having an axial notch 6a.

  A crimp terminal 7 shown in FIG. 1 is attached to the stud bolt 4 and fastened by a nut 8. The electric wire 9 connected to the crimp terminal 7 is led out from a notch 6a formed in the guide member 6, and is routed toward an alternator (not shown).

  Hereinafter, the guide member 6 will be described. The guide member 6 is formed in a hollow cylindrical body 6b as shown in FIG. 3, and a notch 6a is formed in a part thereof. In the present embodiment, three flexible leg portions 11 are formed at the lower portion of the guide member 6, and a locking portion 12 is formed at the lower end of each flexible leg portion 11 toward the inner side. Yes. Each locking portion 12 is formed with a first tapered surface 13a and a second tapered surface 13b.

  On the other hand, in the housing 5, a through hole 14 as shown in FIG. 4 is formed around the standing position of the stud bolt 4 at a position corresponding to the flexible leg 11. Although three through holes are formed in this embodiment, FIG. 4 shows two through holes 14 for convenience of illustration.

  When the guide member 6 is attached to the housing 5, each flexible leg 11 is aligned with each through-hole 14, and the guide member 11 is pressed downward as indicated by an arrow A in FIG. 4. As a result, the second tapered surface 13b comes into contact with the edge of the through hole 14, and the entire flexible leg 11 is bent and deformed outward as indicated by the imaginary line. If the pressing is further continued in the direction of arrow A from this state, when the locking piece 12 passes through the through hole 14, the flexible leg 11 is automatically restored to its original state, that is, in a linear form by its own elasticity. The guide member 6 is attached to the housing 5.

  When the guide member 11 is attached, the periphery of the stud bolt 4 is surrounded by the guide member 11 as shown in FIGS. In this state, the crimp terminal 7 is mounted on the stud bolt 4 as described above, and a nut fastening tool (for example, an impact wrench) 15 in which the nut 8 is set is inserted into the guide member 11 to operate the tool 15. The nut 8 is rotated.

  The tool 15 rotates the nut 8 without any eccentricity or shaft wobbling by the guide action of the guide member 11, screwing the nut 8 into the stud bolt 4, and tightening without oblique tightening.

After the nut 8 is fastened, the guide member 6 is removed as follows.
That is, the guide member 6 is picked with fingers and pulled out as it is. At this time, the first tapered surface 13a abuts on the edge of the through hole 14, and the flexible portion 11 is elastically deformed as indicated by an imaginary line in FIG. When the guide portion 11 is further lifted from this state, the locking piece 12 passes through the through hole 14 and is removed.

  As described above, according to the present embodiment, the guide member 6 can be easily attached to the housing 5, the nut 8 can be fastened to the stud bolt 4 without eccentricity or shaft runout, and then the guide member 6 can be easily removed. it can.

  Therefore, it is not necessary to use an expensive rod-end bolt for the stud bolt 4, and it is possible to save the trouble of temporarily setting the nut 8 by turning it with fingers when fastening the nut.

If the guide member 6 remains attached, the height of the fusible link 1 is the height indicated by H in FIG. However, in the configuration of the present embodiment, since the guide member 6 can be removed, the height of H-B is omitted, and the height to the stud bolt 2 becomes the height of the fusible link 1. Therefore, the fusible link 1 can be reduced in height by removing the guide member 6.
In addition, the inner diameter, thickness, height, and the like of the guide member 6 can be freely changed as necessary.

Next, the guide member 21 in 2nd Embodiment of this invention is demonstrated.
5 is a perspective view showing the structure of the guide member, FIG. 6 is a plan view of the vicinity of the stud bolt showing the form of the attachment position of the guide member, FIG. 7 is a sectional view showing the action of the guide member at the time of fastening the nut, and FIG. FIG. 10 is a cross-sectional view of the guide member showing the operation when the nut is fastened, and FIG. 8 and 9, the stud bolt 4, the crimp terminal 7, and the nut 8 are not shown.

  Three flexible legs 26 are provided below the guide member 21. A first locking portion 27 is provided at the lower end of the flexible leg portion 26. As shown in FIGS. 7 and 8, the first locking portion 27 has a first tapered surface 27a and a second tapered surface 27b. Further, the guide member 21 is formed with two flexible arm portions 23 at opposing positions by forming two slits 22a and 22b at predetermined intervals in the cylindrical body 21a.

The flexible arm portion 23 is formed integrally with the cylindrical body 21a at the connecting portion 24, and the flexible arm portion 23 is bent and deformed starting from the connecting portion 24.
A second locking portion 25 is provided at the upper end of each flexible arm portion 23.

  On the other hand, in the housing 5, three through holes 14 are formed around the stud bolt 4 as shown in FIG. 6. The formation position of each through hole 14 corresponds to the formation position of each flexible leg 26.

Next, attachment of the guide member 21 will be described.
Each flexible leg 26 provided on the guide member 21 is made to correspond to each through hole 14 and is pressed downward as it is. As a result, as shown by an imaginary line in FIG. 7, the second tapered surface 27 b formed on the first locking part 27 abuts on the edge of the through hole 4, and the entire flexible leg 26 is an imaginary line. As shown, it bends and deforms. If the pressing is continued as it is, as shown by a solid line in FIG.

Next, the operation at the time of fastening the nut will be described.
The nut is set in the tool 15, and when the nut is fastened, the tool 15 is inserted into the cylindrical body 21a as shown by a solid line in FIG. At this time, the lower end portion of the tool 15 abuts on the first taper surface 28a formed on the first locking portion 25 and is pushed down as it is, as shown by a solid line in FIG. Bend and deform in the direction.

  Next, the nut is rotated by operating the tool 15, and the nut is tightened. At this time, since the position of the tool 15 is regulated by the action of the guide member 21, nut fastening is performed in a state where there is no shaft runout or the like, and diagonal fastening or the like can be prevented. And the tool 15 is latched by the 2nd latching | locking part 25 in the position which the fastening operation | work of the nut was completed.

  The tool 15 is located at the bottom in the guide portion 21 as indicated by an imaginary line in FIG. In this state, the flexible arm portion 23 returns to its original shape, and the second locking portion 25 protrudes above the tool 15. Here, the locking force by the first locking portion 27 is set smaller than the locking force by the second locking portion 25.

  When the tool 15 is pulled up after the nut is fastened, the second locking portion 25 is locked to the tool 15, so that the guide member 21 is also lifted together. When the pulling is continued, the first tapered surface 27a formed on the first locking portion 27 comes into contact with the edge portion of the through hole 14, and the flexible leg portion 26 is bent and deformed as shown in FIG. And if the tool 15 is further pulled up, the 2nd latching | locking part 27 will pass through the through-hole 14, and the guide member 21 can be removed.

  As described above, the guide member 21 in the second embodiment can prevent the tool 15 from being shaken at the time of fastening the nut, and can be detached from the housing 5 together with the tool 15 after the fastening of the nut.

Next, the guide member 31 in 3rd Embodiment of this invention is demonstrated.
FIG. 10 is a partially cutaway perspective view showing the structure of the guide member, FIG. 11 is a cross-sectional view showing the attached state of the guide member, and FIG. 12 is a cross-sectional view showing the removed state of the guide member. In addition, in FIG.11 and FIG.12, illustration of the crimp terminal is abbreviate | omitted.

  As shown in FIG. 10, the guide member 31 in the third embodiment is formed by forming two slits 32a and 32b at predetermined intervals in a cylindrical body 31a and providing flexible leg portions 33 that can be bent and deformed. . In addition, the thickness of the flexible leg portion 33 is made thinner than the thickness of the cylindrical body 31a, and the entire shape is easily bent and deformed. Note that the number of the flexible legs 33 may be one or more, preferably a plurality, and in the third embodiment, the three flexible legs 33 are provided on the cylindrical body 31a at equal intervals in the circumferential direction. It is a configuration.

  And the latching | locking part 34 is formed in the inner surface of the flexible leg part 33, ie, the surface which goes to the inner side of the cylindrical body 31a. The locking portion 34 includes a first tapered surface 34a, a second tapered surface 34b, and a concave locking groove 34c formed therebetween.

  On the other hand, in the housing 5, a through hole 14 is formed around the stud bolt 4 as shown in FIG. 11. The formation position of the through hole 14 corresponds to the formation position of the flexible leg 33.

Next, attachment of the guide member 31 will be described.
The flexible leg 33 provided on the guide member 31 is made to correspond to the through hole 14 and is pressed downward as it is. As a result, the second tapered surface 34b constituting the locking portion 34 comes into contact with the edge portion of the through hole 4, and the entire flexible leg portion 33 is bent and deformed. If the pressing is continued in this state, the second tapered surface 34b passes through the through hole 4 and the locking groove 34c engages with the edge of the through hole 14 as shown in FIG.

Next, the operation at the time of fastening the nut will be described.
The nut 8 is set in the tool 15, and when the nut is fastened, the tool 15 is inserted into the cylindrical portion 21a as shown in FIG. At this time, as the nut 8 is tightened, after the lower end portion of the tool 15 comes into contact with the first taper surface 34a and the tool 15 is further lowered, as shown in FIG. Bend and deform outward.

  During this time, the tool 15 continues to rotate and the nut is tightened. Since the position of the tool 15 is regulated by the action of the guide member 21, nut fastening is performed in a state where there is no shaft runout or the like, and diagonal fastening or the like can be prevented.

  When the nut fastening is completed, the tool 15 is positioned at the bottom in the guide member 31 as shown in FIG. In this state, the engaging groove 34 c is in a state in which the engagement with the through hole 14 is released, and the flexible leg 33 is in elastic contact with the tool 15.

  When the tool 15 is pulled up after tightening the nut, the engagement groove 34 is in a disengaged state, and the flexible leg 33 sandwiches the tool 15 between the opposing surface of the cylindrical body 31a by its own elasticity. The guide member 31 is also pulled up integrally. That is, the guide member 31 is simultaneously removed from the housing 5 by pulling up the tool 15.

  As described above, the guide member 31 in the third embodiment can prevent the shaft 15 of the tool 15 from being shaken when the nut is tightened, and can be detached from the housing 5 together with the tool 15 after the nut tightening is completed. .

  The guide member 31 in the third embodiment can be deformed as shown in FIG. In addition, since a deformation | transformation part is related with the latching piece 34 and another structure may be the same as the above, a deformation | transformation part is demonstrated below.

  That is, in the modified example, a locking portion 36 having tapered surfaces 35a and 35b is formed below the locking groove 34c. According to this configuration, the guide member 31 can be easily removed. As described above, since the guide member 31 is removed by pressing the tapered surface 34 against the tool 15, the guide member 31 can be reliably removed if the locking by the locking portion 36 is weak. Therefore, the guide member 31 can be reliably removed by forming the tapered surface 35a and facilitating the removal of the locking piece 36 as in this modification.

  As described above, the height of the fusible link can be prevented from being increased by removing the guide members 6, 21, and 31 after completion of the fastening of the nut 8 as described in the embodiments. However, since voltage is applied to the stud bolt 4, it is preferable to cover it for safety.

  Since the through hole 14 is exposed after the guide members 6, 21, 31 are removed, a fusible link cover 37 as shown in FIG. 14 is installed and fixed using the through hole 14. Good. The fusible link cover 37 is provided with leg portions 37a, 37b, and 37c having the same configuration as the flexible leg portion provided on the above-described guide member, and the leg portions 37a, 37b, and 37c are formed in the through hole 14. The fusible link cover 37 is fixed to the housing 5 by being engaged.

  Although the embodiment of the present invention has been described above, the present invention is not limited to the above, and various modifications are possible. For example, the number of flexible parts can be changed freely. The diameter, height, thickness, etc. of the cylindrical body can be freely changed according to the form of the fusible link, the thickness of the stat bolt, and the like.

It is a perspective view of the nut slack fastening prevention structure of a fusible link which shows the embodiment of the present invention. It is a side view which shows the structure of a fusible link. It is a perspective view which shows the structure of a guide member. It is sectional drawing which shows the structure of a guide member. It is a perspective view which shows the 1st specific example of a guide member. It is a top view which shows the attachment position of a guide member. It is sectional drawing which shows attachment of a guide member. It is sectional drawing of the guide member which shows the effect | action at the time of nut fastening. It is sectional drawing which shows removal of a guide member. It is a perspective view which shows the 2nd specific example of a guide member. It is sectional drawing of the guide member which shows nut fastening. It is sectional drawing which shows removal of a guide member. It is sectional drawing which shows the modification of a guide member. It is a bottom view of a fusible link cover. It is a perspective view which shows the fixation structure of the conventional connection terminal. It is a perspective view which shows the conventional fusible link.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Anti-screw slack tightening structure of fusible link 2 Power supply side connection terminal 3 Soluble part 4 Stud bolt 5 Housing 6, 21, 31 Guide member 6b, 21a, 31a Cylindrical body 7 Crimp terminal 8 Nut 9 Electric wires 11, 26 33 Flexible legs
12, 25, 27, 34, 36 Locking portions 13a, 27a, 28a, 34a First tapered surface 13b, 13b, 27b, 34b Second tapered surface 14 Through hole 15 Tools 22a, 22b, 32a, 32b Slit 23 Flexible arm

Claims (4)

A plurality of bus bars formed from a conductive metal plate, and a low melting point metal fusible element that is disposed so as to be electrically connected between the plurality of bus bars and that melts by energization heat generation when a current exceeding the rating flows. And
A stud bolt standing on the bus bar and serving as an external connection terminal;
A housing for insulatingly covering the bus bar;
A fusible link directly attached to a vehicle battery post,
A guide member disposed concentrically with the stud bolt so as to surround the stud bolt and detachable from the housing;
A fusible link characterized in that when a nut is fastened to the stud bolt, a nut fastening tool is guided by the guide member to fasten the nut. The guide member is provided with a cylindrical body that surrounds the stud bolt in the axial direction, and a flexible leg portion that extends to a housing side portion of the cylindrical body and has a first locking portion. And
A portion corresponding to the flexible leg portion of the housing is formed with a through hole in which the first locking portion is locked,
2. The fusible link according to claim 1, wherein the guide member can be attached to and detached from the housing by engaging and disengaging the first locking portion with the through hole. A flexible arm portion having a second locking portion that is locked to the nut fastening tool at the time of nut tightening work is provided on a portion of the cylindrical member on the side of the nut fastening tool insertion side of the guide member. And
The locking force in the first locking portion of the flexible leg is set to be smaller than the locking force in the second locking portion of the flexible arm portion,
3. The fuse according to claim 2, wherein after the nut is fastened, the guide member is removed from the housing by being pulled up integrally with the nut fastening tool while being locked to the nut fastening tool. Bulllink. The inner surface of the flexible leg is brought into contact with the nut fastening tool when the nut is fastened to elastically deform the flexible leg, and is pressed against the nut fastening tool by the elasticity of the flexible leg. A first tapered surface,
A second taper surface that elastically deforms the flexible leg by contacting an edge of the through hole of the housing;
The deformation of the flexible leg due to the first taper surface while the second taper surface is locked to the edge due to the deformation of the flexible leg due to the guide being brought into contact with the edge. And a locking groove that is unlocked at
After the nut fastening, the flexible leg is elastically deformed by the contact between the nut fastening tool and the first tapered surface, and the engagement between the locking groove and the edge is released, and 3. The fusible link according to claim 2, wherein the guide member is detached from the housing integrally with the nut fastening tool by pressing the first tapered surface against the nut fastening tool. 4.

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