WO2016111218A1 - Temperature fuse structure, and electric connection box - Google Patents

Abstract

A temperature fuse structure 13 disconnects the electrical connection between a first conductive path 14 and a second conductive path 15 that are provided on a substrate 11, wherein the temperature fuse structure is provided with the following: a metal member 17 that is connected to the first conductive path 14 by solder 19 and connected to the second conductive path 15 by solder 20, the metal member having a higher melting point than the solder 19 and the solder 20; and a biasing section 18 that applies a bias to the metal member 17 in a disconnection direction, which is a direction by which the first conductive path 14 would be electrically disconnected from the second conductive path 15.

Description

Thermal fuse structure and electrical junction box

This relates to a thermal fuse structure that cuts off the electrical connection when the temperature rises.

Conventionally, a thermal fuse structure that cuts off an electrical connection when the temperature rises is known (for example, see Patent Document 1). The thermal fuse described in Patent Document 1 is provided with a heat-meltable metal between a pair of mounting plates and a member that does not melt in the heat-meltable metal. In this thermal fuse, when the temperature rises and the hot-melt metal melts, the non-melting member falls by gravity, and the hot-melt metal is pulled down by the non-melting member, and the electrical connection is cut off. The

JP-A-60-193222

By the way, in general, when a non-melting member is fixed by a heat-meltable metal, the non-melting member does not fall even if the heat-melting metal is melted due to a high viscosity of the molten heat-melting metal. Sometimes. For this reason, according to the thermal fuse described in Patent Document 1 described above, there is a concern that a member that does not melt does not fall even if the temperature rises and the hot-melt metal melts. In other words, the thermal fuse described in Patent Document 1 described above is concerned with certainty.

This specification discloses a technique that can more reliably cut off the electrical connection when the temperature rises.

A thermal fuse structure disclosed in the present specification is a thermal fuse structure that blocks electrical connection between a first conductive path and a second conductive path provided on a substrate, and includes a first heat-meltable structure. It is connected to the first conductive path via a conductive material, and is connected to the second conductive path via a heat-meltable second conductive material, and the first conductive material and the The metal member having a melting temperature higher than the melting temperature of each of the second conductive materials, and the metal member is biased in a blocking direction that blocks electrical connection between the first conductive path and the second conductive path. And an urging section.

According to the above thermal fuse structure, the metal member is urged by the urging portion in the direction of cutting off the electrical connection between the first conductive path and the second conductive path, so that the temperature rises and the first When the conductive material and the second conductive material are melted, the metal member is detached from the substrate, and the electrical connection between the first conductive path and the second conductive path is interrupted. In this thermal fuse structure, since it is not necessary to drop the metal member by gravity, the electrical connection between the first conductive path and the second conductive path is made as compared with the conventional case where the member that does not melt is dropped by gravity. It can shut off more reliably.

The metal member includes a connection portion to which the first conductive path and the second conductive path are connected, and an extension having a surface extending from the connection portion and spaced from the substrate. And an urging portion that urges the extending portion in the blocking direction.

For example, it is assumed that the metal member is a thin flat plate and is provided so as to be attached to the substrate. In this case, if the metal member is to be removed by urging the side end surface of the metal member, it is difficult to urge the metal member because the thickness of the metal member is thin. According to the above thermal fuse structure, the extending portion is urged, so that the metal member can be urged more reliably.

The extending portion may extend from the connection portion to the opposite side of the substrate, and the urging portion may urge the extending portion in a direction substantially parallel to the substrate.

According to the above thermal fuse structure, the metal member can be urged in the blocking direction by urging the extending portion in a direction substantially parallel to the substrate by the urging portion.

Further, a through hole is formed in the substrate between the first conductive path and the second conductive path, the biasing portion faces the substrate, and the first conductive path and the The metal member may be urged in a direction substantially perpendicular to the substrate through the through hole from the side opposite to the second conductive path.

According to the above thermal fuse structure, by urging the metal member in a direction substantially perpendicular to the substrate through the through hole from the opposite side to the first conductive path and the second conductive path by the urging portion, The metal member can be urged in the blocking direction.

5. The thermal fuse structure according to claim 1, wherein an electrical junction box disclosed in the present specification interrupts electrical connection between the first conductive path and the second conductive path. And a substrate on which the first conductive path and the second conductive path are provided, a heating element mounted on the substrate, and a housing to which the substrate is fixed.

According to the electrical junction box, the electrical connection between the first conductive path and the second conductive path can be more reliably interrupted when the temperature rises.

The housing includes a first case to which the substrate is fixed and a second case to be assembled to the first case, and the biasing portion is provided in the second case. The urging portion abuts on the metal member when the first case and the second case are assembled, and bends the metal member in a direction opposite to the blocking direction. Energized in the shut-off direction.

According to the electrical junction box, the metal member is attached in the blocking direction for blocking the electrical connection between the first conductive path and the second conductive path by the work of assembling the first case and the second case. The urging portion can be deflected to urge. For this reason, working efficiency improves compared with the case where the operation | work which bends a biasing part separately from the operation | work which assembles a 1st case and a 2nd case.

According to the thermal fuse structure disclosed in this specification, the electrical connection can be more reliably interrupted when the temperature rises.

Sectional drawing which simplifies and shows the electrical junction box which concerns on Embodiment 1. Sectional drawing which simplifies and shows the electrical-connection box when a 1st electrically conductive material and a 2nd electrically conductive material fuse | melt Sectional drawing which simplifies and shows the electrical junction box which concerns on Embodiment 2. Sectional drawing which simplifies and shows the electrical junction box which concerns on Embodiment 3. Sectional drawing which simplifies and shows the electrical junction box which concerns on other embodiment

<Embodiment 1>
A first embodiment of the technology disclosed in this specification will be described with reference to FIGS.

(1) Configuration of Electrical Junction Box With reference to FIG. 1, an electrical junction box 1 according to the first embodiment will be schematically described. The electrical junction box 1 is a device that is mounted on a vehicle (not shown) and that turns on / off current supplied from a power source to a load such as an in-vehicle electrical component. The electrical junction box 1 includes a synthetic resin case 10, a printed circuit board 11 accommodated inside the case 10, a heating element 12, and a thermal fuse structure 13. The case 10 is an example of a housing. The printed board 11 is an example of a board. In the following description, the arrow P indicates the up and down direction, and the upper side of the arrow P will be referred to as the upper side, and the lower side will be described as the lower side. In addition, the arrow line Q indicates the horizontal direction, the left side of the arrow line Q is set as the left side, and the right side is described as the right side.

Case 10 includes a lower case 10A and an upper case 10B. The upper case 10B is provided with a power supply side connector (not shown) to which a power supply is connected and a load side connector (not shown) to which a load such as an in-vehicle electrical component is connected. The lower case 10A is an example of a “first case”, and the upper case 10B is an example of a “second case”.

The printed circuit board 11 is fixed to the lower case 10A. The printed circuit board 11 is provided with a conductive path made of copper or the like by a known printed wiring technique, and the heating element 12 and a part of the thermal fuse structure 13 are mounted thereon. The heating element 12 is an FET (Field Effect Transistor), an IPD (Intelligent Power Device), a coil, or the like. The heating element 12 is not limited to these.

In the example shown in FIG. 1, at least a first conductive path 14, a second conductive path 15, and a third conductive path 16 are provided on the printed board 11. One end of the third conductive path 16 is connected to the power supply side connector (not shown), and the other end is connected to the heating element 12. One end of the first conductive path 14 is connected to the heating element 12, and the other end is connected to a metal member 17 described later of the thermal fuse structure 13. The second conductive path 15 has one end connected to the metal member 17 and the other end connected to a load-side connector (not shown).

The thermal fuse structure 13 includes a metal member 17 mounted on the printed circuit board 11 and an urging portion 18 formed integrally with the upper case 10B. The metal member 17 is formed by bending an elongated metal plate into an L shape. In the following description, the portion of the metal member 17 that extends in the horizontal direction (the direction indicated by the arrow Q) in FIG. 1 is referred to as a connection portion 17A, and is approximately on the opposite side from the left edge of the connection portion 17A to the printed board 11. A portion extending vertically is referred to as an extension portion 17B. In FIG. 1, the surface facing the left side of the extending portion 17 </ b> B is an example of “a surface provided apart from the substrate”.

The connecting portion 17A has a downward facing surface connected to the first conductive path 14 via the solder 19 and connected to the second conductive path 15 via the solder 20. The solder 19 is an example of a “heat-melting first conductive material”, and the solder 20 is an example of a “heat-melting second conductive material”.

When the heating element 12 generates heat, the heat is transmitted to the solders 19 and 20 through the first conductive path 14 or as radiant heat, and the temperature of the solders 19 and 20 rises. The melting temperature of the solders 19 and 20 is higher than the temperature that rises due to the heat transmitted when the temperature of the heating element 12 is within a normal range, and the temperature at which the printed board 11 and the case 10 are ignited or smoked. Let it be a lower temperature. The melting temperature of the metal member 17 is higher than the melting temperatures of the solders 19 and 20.

The urging portion 18 has an arm portion 21 extending in a bar shape downward from the upper wall of the upper case 10B, and a protrusion 22 protruding from the distal end portion of the arm portion 21 toward the extending portion 17B side (right side in FIG. 1). And have.

The arm portion 21 is provided substantially above the extension portion 17B, and is assembled in a state where the protrusion 22 is bent to the left side by contacting the extension portion 17B. For this reason, the extension part 17B is always urged | biased on the right side by the elastic force which the arm part 21 tends to return to an original shape. The right side is an example of “blocking direction” and “direction substantially parallel to the substrate”.

Here, assembling the urging portion 18 in a bent state can be performed by assembling the lower case 10A and the upper case 10B. Specifically, the protrusion 22 has an inclined surface 22A that is inclined to the right when not bent. When the upper case 10 </ b> B is assembled to the lower case 10 </ b> A from above, the biasing portion 18 abuts the inclined surface 22 </ b> A against the metal member 17, and the arm portion 21 is bent to the left side by the reaction force received by the protrusion 22 from the metal member 17. As a result, the biasing portion 18 is assembled in a bent state.

(2) Operation of Thermal Fuse Structure Next, the operation of the thermal fuse structure 13 will be described with reference to FIG. If the heating element 12 generates abnormal heat for some reason, and the temperature of the solders 19 and 20 exceeds the melting temperature, the solders 19 and 20 are melted. When the solders 19 and 20 are melted, the metal member 17 is released from the printed board 11 by being pushed rightward by the urging portion 18. As a result, the electrical connection between the first conductive path 14 and the second conductive path 15 is interrupted before ignition or smoke generation occurs.

(3) Effects of Embodiment According to the thermal fuse structure 13 according to the first embodiment described above, the urging portion 18 connects the metal member 17 to the first conductive path 14 and the second conductive path 15. Since it is energized in the blocking direction to block, when the temperature rises and the solders 19 and 20 are melted, the metal member 17 is detached from the printed circuit board 11, and the first conductive path 14 and the second conductive path 15 Is disconnected. In this thermal fuse structure 13, since it is not necessary to drop the metal member 17 by gravity, the first conductive path 14 and the second conductive path 15 are compared with the case where a member that does not melt is dropped by gravity as in the prior art. The electrical connection can be cut off more reliably.

In addition, in the case of a configuration in which a non-melting member falls and pulls a heat-meltable metal as in the conventional case, even if a non-melting member falls, because of the high viscosity of the molten heat-meltable metal, There is also a concern that it takes time until the non-molten member falls after the meltable metal melts. On the other hand, according to the thermal fuse structure 13, since the metal member 17 is urged by the urging portion 18, the metal member 17 can be quickly removed when the temperature rises and the solders 19 and 20 are melted. Safety is improved.

Furthermore, according to the thermal fuse structure 13, the metal member 17 has an extending portion 17 </ b> B having a surface provided apart from the printed board 11. For example, it is assumed that the metal member 17 is a thin flat plate and is provided so as to be attached to the printed board 11. In this case, if it is attempted to remove the metal member 17 by urging the side end surface of the metal member 17, it is difficult to urge the metal member 17 because the thickness of the metal member 17 is thin. According to the thermal fuse structure 13, the extending portion 17 </ b> B is urged, so that the metal member 17 can be urged more reliably.

Further, according to the thermal fuse structure 13, by urging the extending portion 17B extending from the connecting portion 17A to the opposite side of the printed circuit board 11 by the urging portion 18 in a direction substantially parallel to the printed circuit board 11, The metal member 17 can be urged in the “blocking direction”.

Further, according to the electrical junction box 1 according to the first embodiment, the biasing portion 18 can be bent so as to bias the metal member 17 by the work of assembling the lower case 10A and the upper case 10B. For this reason, working efficiency improves compared with the case where the operation | work which bends the urging | biasing part 18 separately from the operation | work which assembles lower case 10A and upper case 10B.

<Embodiment 2>
A second embodiment of the technique disclosed in this specification will be described with reference to FIG.
As shown in FIG. 3, the electrical junction box 201 according to the second embodiment includes a thermal fuse structure 213 instead of the thermal fuse structure 13 according to the first embodiment. The metal member 217 according to the second embodiment includes a first extension portion 217B that extends substantially perpendicularly from the right edge of the connection portion 217A to the side opposite to the printed board 11 (upper side in the drawing), and a first extension. It has a second extending portion 217C that extends substantially perpendicularly from the tip of the portion 217B to the opposite side (right side of the drawing) from the connecting portion 217A.

The first extension part 217B and the second extension part 217C are examples of “extension part”. Further, in FIG. 3, the surface facing the upper side of the second extending portion 217 </ b> C is an example of “a surface provided apart from the substrate”.

The urging portion 218 has an arm portion 221 that extends in a bar shape from the inner surface of the side wall of the upper case 210B toward the left side, and a protrusion 222 that protrudes downward from the tip portion of the arm portion 221.

The arm part 221 is substantially the same in the vertical direction (direction indicated by the arrow P) as the second extension part 217C, and the protrusion 222 abuts on the second extension part 217C from above to bend upward. It is assembled in the state. For this reason, the second extension portion 217C is always urged downward by the elastic force of the arm portion 221 trying to return to the original shape. Below is an example of the “blocking direction”.

When the heating element 12 abnormally generates heat for some reason and the solders 219 and 220 are melted, the metal member 217 is pushed by the urging portion 218 and tilted obliquely by the lever principle with the right end of the connection portion 217A as a fulcrum. As a result, the metal member 217 is detached from the printed circuit board 11, and the electrical connection between the first conductive path 14 and the second conductive path 15 is interrupted.

According to the thermal fuse structure 213 according to the second embodiment described above, the metal member 217 can be urged in the “cutting direction” by urging the second extending portion 217C downward by the urging portion 218. it can.

<Embodiment 3>
A third embodiment of the technique disclosed in this specification will be described with reference to FIG.
As shown in FIG. 4, a printed circuit board 311 is attached to an electrical connection box 301 according to the third embodiment so as to close an opening of a lower case 310 formed in a box shape opening upward. Similarly to the first embodiment, the printed circuit board 311 according to the third embodiment also includes the first conductive path 14, the second conductive path 15, and the third conductive path 16.

The metal member 317 is formed in a long and narrow plate shape, and the first conductive path 14 is connected to the surface facing downward via the solder 319 and the second conductive path 15 is connected via the solder 320. ing. As shown in FIG. 4, a through hole 311 </ b> A is formed in the printed board 311 below the metal member 317.

The urging portion 318 is formed integrally with the lower case 310, and includes a first straight portion 318A extending upward from the bottom surface of the lower case 310, and a curve extending in a semicircular shape upward from the upper end of the straight portion 318A. A portion 318B and a second straight portion 318C extending upward from the upper end of the curved portion 318B are provided. The urging portion 318 can be elastically deformed in the vertical direction by bending the curved portion 318B. It is assumed that the position of the upper end of the second straight line portion 318C when the urging portion 318 has a natural length is higher than the surface of the printed board 311.

The urging portion 318 is in contact with the metal member 317 from the bottom through the through hole 311A of the printed board 311 and is assembled in a state compressed in the vertical direction. For this reason, the metal member 317 is always urged upward by the elastic force that the urging portion 318 attempts to return to the original shape. That is, the urging portion 318 faces the printed circuit board 311 and urges the metal member 317 upward from the opposite direction side to the first conductive path 14 and the second conductive path 15 through the through hole 311A. . The upper part is an example of “blocking direction” and “direction substantially perpendicular to the substrate”.

When the heating element 12 abnormally generates heat for some reason and the solders 319 and 320 are melted, the metal member 317 is detached from the printed board 311 by being biased upward by the biasing portion 318. Thereby, the electrical connection between the first conductive path 14 and the second conductive path 15 is interrupted.

According to the thermal fuse structure 313 according to the third embodiment described above, the metal member 317 can be urged in the “cut-off direction” by urging the metal member 317 upward by the urging portion 318.

<Other embodiments>
The technical scope disclosed by this specification is not limited to embodiment described with the said description and drawing, For example, the following embodiments are also contained in the technical scope disclosed by this specification.

(1) In the first embodiment, the case where the extending portion 17B is urged to the right by the urging portion 18 has been described as an example. However, the direction of urging by the urging unit 18 is not limited to this as long as the electrical connection between the first conductive path 14 and the second conductive path 15 is interrupted. For example, the urging portion 18 may urge the extending portion 17B to the left side.
The same applies to the second embodiment, and the urging portion 218 may urge the second extending portion 217C upward. As a modified example of the second embodiment, the second extending portion 217C may extend to the left in FIG. 3 from the distal end portion of the first extending portion 217B. That is, the metal member 217 may be formed in a U shape. And the urging | biasing part 18 may urge the 2nd extension part 217C upwards.

(2) In the above embodiment, the printed circuit board 11 on which the conductive path is printed is described as an example. However, the board is not limited to the printed board 11. For example, a metal bus bar may be attached to a substrate on which a conductive path is not printed. In that case, the bus bar is an example of a conductive path.

(3) In the above embodiment, the case where the urging portion 18 is integrally provided in the synthetic resin case 10 has been described as an example. However, the urging portion 18 may be provided other than the case 10. For example, in the example shown in FIG. 5, a biasing portion 418 similar to that of the third embodiment is integrally formed in the housing 50 of the load side connector so as to extend in the horizontal direction. In the example shown in FIG. 5, the metal member 17 shown in the first embodiment is fixed to the left and right opposite to the first embodiment, and the extending portion 17 </ b> B is urged to the left by the urging portion 418 extending from the housing 50. Yes.

(4) In the above embodiment, the case where the biasing portion 18 is made of synthetic resin has been described as an example. However, the urging portion 18 may not be made of synthetic resin. For example, a metal leaf spring, torsion spring, coil spring or the like may be fixed to the case 10 as a biasing portion 18 with a screw or the like.

(5) In the above embodiment, the case where the metal member 17 is electrically connected to the heating element 12 via the first conductive path 14 has been described as an example. On the other hand, the metal member 17 may not be electrically connected to the heating element 12 but may be provided in the vicinity of the heating element 12. Also in this case, the solder 19 and 20 are melted by the radiant heat radiated from the heating element 12, whereby the electrical connection between the first conductive path 14 and the second conductive path 15 can be cut off.

(6) In the above embodiment, the case where the urging unit 18 is provided in the case 10 has been described as an example. On the other hand, the urging unit 18 may be provided on the printed circuit board 11. For example, when the printed circuit board 11 is resin-molded, the urging portion 18 may be integrally formed, or the urging portion 18 formed of metal or the like may be fixed to the printed circuit board 11 with a screw.

(7) In the above embodiment, the solder is used as an example of the heat-meltable first conductive material and the heat-meltable second conductive material, but a brazing material such as silver solder may be used.

1: Electrical junction box 10: Case (housing)
10A: Lower case (first case)
10B: Upper case 10B (second case)
11: Printed circuit board (board)
12: Heating element 13: Thermal fuse structure 14: First conductive path 15: Second conductive path 17: Metal member 17A: Connection part 17B: Extension part 18: Energizing part 19: Solder (heat-meltable first 1 conductive material)
20: Solder (thermally meltable second conductive material)
201: Electric junction box 213: Thermal fuse structure 217: Metal member 217A: Connection part 217B: First extension part (extension part)
217C: second extension part (extension part)
218: Energizing portion 219: Solder (heat-melting first conductive material)
220: Solder (thermally meltable second conductive material)
301: Electrical junction box 311: Printed circuit board (board)
311A: Through-hole 313: Thermal fuse structure 317: Metal member 318: Energizing portion 319: Solder (thermally meltable first conductive material)
320: Solder (thermally meltable second conductive material)

Claims (6)

1. A thermal fuse structure for interrupting electrical connection between a first conductive path and a second conductive path provided on a substrate,
   The first conductive path is connected to the first conductive path via a heat-meltable first conductive material, and the second conductive path is connected to the second conductive path via a heat-meltable second conductive material. A metal member having a melting temperature higher than the melting temperature of each of the first conductive material and the second conductive material;
   A thermal fuse structure comprising: an urging portion that urges the metal member in a blocking direction that blocks electrical connection between the first conductive path and the second conductive path.
2. The metal member includes a connecting portion to which the first conductive path and the second conductive path are connected, and an extending portion having a surface extending from the connecting portion and spaced from the substrate. And
   The thermal fuse structure according to claim 1, wherein the biasing portion biases the extending portion in the blocking direction.
3. The extension portion extends from the connection portion to the opposite side of the substrate,
   The thermal fuse structure according to claim 2, wherein the urging portion urges the extending portion in a direction substantially parallel to the substrate.
4. A through hole is formed in the substrate between the first conductive path and the second conductive path,
   The urging portion faces the substrate and urges the metal member in a direction substantially perpendicular to the substrate through the through hole from a side opposite to the first conductive path and the second conductive path. The thermal fuse structure according to claim 1, wherein:
5. The thermal fuse structure according to any one of claims 1 to 4, wherein the electrical connection between the first conductive path and the second conductive path is interrupted.
   A substrate on which the first conductive path and the second conductive path are provided;
   A heating element mounted on the substrate;
   A housing to which the substrate is fixed;
   An electrical junction box.
6. The housing includes a first case to which the substrate is fixed, and a second case assembled to the first case,
   The urging portion is provided in the second case,
   The urging portion abuts the metal member when the first case and the second case are assembled and bends in a direction opposite to the blocking direction, thereby biasing the metal member in the blocking direction. The electrical junction box according to claim 5, wherein

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