JP2016050882A - Temperature sensor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a temperature sensor that can precisely detect the temperatures of a battery.SOLUTION: A temperature measuring unit 12 detects the temperatures of a battery by getting in contact with the battery. A holding unit 13 holds the temeperature measuring unit 12. A spring 15 is provided between the holding unit 13 and a holding cover 14 for installing the temperature sensor 1 to a battery module, to allow the temperature measuring unit 12 to be energized to the battery. The holding cover 14 has a pair of rail parts 142 sandwiching the holding unit 13 and extending along an energization direction Y1. The rail parts 142 regulate the movement of the holding unit 13 to the directions other than the direction Y1.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a temperature sensor, and more particularly to a temperature sensor for detecting a temperature to be detected.

  Conventionally, a battery mounted on a vehicle such as a hybrid vehicle or an electric vehicle is configured by connecting a plurality of battery cells in series with a bus bar in order to obtain a high voltage. For this reason, the battery module comprised from this bus bar and the resin-made bus-bar accommodating part which accommodates a bus bar is attached to the battery. In addition, a temperature sensor that detects the temperature of the battery (detection target) is attached to the battery module in order to prevent overcharge and overdischarge of the battery.

  As such a temperature sensor, for example, the one shown in Patent Document 1 is known. The temperature sensor includes a sensor main body that detects the temperature of the battery, and a housing portion that holds the sensor main body. An elastic locking piece that locks to the bus bar housing portion of the battery module is projected from the housing portion.

JP 2009-250768 A

  Since the temperature sensor described above is attached to a battery module provided separately from the battery to be detected, the distance between the temperature sensor and the battery changes when the battery module moves relative to the battery due to vibration. . Due to this distance change, the output of the temperature sensor fluctuates, and there is a problem that the temperature of the battery cannot be detected accurately.

  Therefore, an object of the present invention is to provide a temperature sensor that can accurately detect the temperature of a detection target.

  The invention according to claim 1, which has been made to solve the above-described problem, is a temperature sensor for detecting the temperature of a detection target, and a temperature measurement unit that detects the temperature in contact with the detection target; A first holding unit that holds the temperature measuring unit, a second holding unit that holds the first holding unit, and is attached to the attachment target, and the temperature measuring unit is biased toward the detection target An urging portion provided between the first holding portion and the second holding portion, wherein the second holding portion has a direction other than the urging direction of the urging portion. The temperature sensor has a restricting portion that restricts the movement of the first holding portion in the direction.

  According to a second aspect of the present invention, the restricting portion includes a pair of rail portions that extend along the biasing direction with the first holding portion sandwiched therebetween, and the second holding portion. Are provided on the pair of flexible arm portions respectively protruding from the outside of the pair of rail portions toward the attachment target, and the first pair of flexible arm portions, and are locked to the attachment target. The temperature sensor according to claim 1, further comprising a locking portion.

  According to a third aspect of the present invention, the first holding part is provided in a hollow shape, and a first opening for inserting one end of the temperature measuring part into the inside from a direction orthogonal to the urging direction; A second locking portion that locks with one end of the temperature measuring unit, and a second opening for exposing the other end of the temperature measuring unit to the outside, the first opening and the first The temperature sensor according to claim 1, wherein the two openings communicate with each other.

  According to a fourth aspect of the present invention, the first holding unit has a terminal connected to the temperature measuring unit or a lead wire connected to the terminal in a direction orthogonal to both the urging direction and the insertion direction of the temperature measuring unit. The temperature sensor according to claim 3, wherein a third opening is provided for pulling out, and the first opening and the third opening communicate with each other.

  According to a fifth aspect of the present invention, the restricting portion is composed of a pair of rail portions that sandwich the first holding portion between each other and extend along the urging direction, and the first holding portion. Is provided in a hollow shape, a first opening for inserting one end of the temperature measuring unit into the inside from a direction orthogonal to the urging direction, and a second engagement locking with one end of the temperature measuring unit. And a second opening for exposing the other end of the temperature measuring unit to the outside, the first opening and the second opening are communicated, and the first opening is The temperature sensor according to claim 1, wherein the temperature sensor is blocked by the rail portion.

  As described above, according to the first aspect of the present invention, the first holding unit that holds the temperature measuring unit by the urging unit is urged toward the detection target. The distance to the detection target does not fluctuate. In addition, since the movement of the first holding unit in a direction other than the urging direction is regulated by the regulating unit, the temperature measuring unit is not inclined with respect to the urging direction and does not contact the detection target. The temperature of the detection target can be detected.

  According to the second aspect of the invention, the movement of the first holding portion can be restricted with a simple configuration in which the first holding portion is sandwiched between the pair of rail portions. In addition, if the distal ends of the pair of flexible arm portions are brought close to each other, the engagement between the attachment target and the first locking portion provided on the flexible arm portion can be easily released. Can be replaced.

  According to the third aspect of the present invention, since the first opening and the second opening communicate with each other, one end of the temperature measuring unit is exposed with the other end of the temperature measuring unit exposed from the second opening. Can be inserted into the first holding portion through the first opening and can be locked by the first locking portion. Thereby, even if it does not insert-mold a temperature measuring part in a 1st holding | maintenance part, since a temperature measuring part can be easily hold | maintained in a 1st holding | maintenance part, cost reduction can be aimed at.

  According to the fourth aspect of the present invention, since the first opening and the third opening communicate with each other, one end of the temperature measuring unit is connected to the first opening in a state where the terminal or the lead wire is pulled out from the third opening. It can be inserted into the first holding part from the opening and locked by the second locking part. Thereby, even if it does not insert-mold a temperature measuring part in a 1st holding | maintenance part, the terminal of a temperature measuring part can be pulled out in the direction orthogonal to both the urging | biasing direction and the insertion direction of a temperature measuring part.

  According to the fifth aspect of the present invention, since the first opening is closed by the rail portion, it is not necessary to separately provide the rail portion and a member for closing the first opening, so that the number of parts can be reduced. Cost can be reduced.

It is a perspective view which shows the temperature sensor of this invention in 1st Embodiment. (A) is an exploded perspective view of the temperature sensor shown in FIG. 1, and (B) is an exploded perspective view of the temperature measuring unit shown in (A). It is a perspective view which shows the state which attached the temperature sensor shown in FIG. 1 to the battery module. FIG. 4 is a cross-sectional perspective view taken along the line II in FIG. 3. It is the II sectional view taken on the line of FIG. It is a perspective view which shows the temperature sensor of this invention in 2nd Embodiment. It is a disassembled perspective view of the temperature sensor shown in FIG. It is a perspective view of the temperature measuring part and holding | maintenance part which comprise the temperature sensor shown in FIG. It is the II-II sectional view taken on the line of FIG. It is a perspective view which shows the state attached to the battery module shown in FIG. It is III-III sectional drawing of FIG.

(First embodiment)
Hereinafter, the temperature sensor of the present invention in the first embodiment will be described with reference to FIGS. This temperature sensor is for detecting the temperature of a battery (= detection target) mounted on the vehicle. The battery is constituted by connecting a plurality of battery cells in series by a bus bar in order to obtain a high voltage. For this reason, the battery module (= attachment object) comprised from the resin bus bar accommodating part which accommodates a some bus bar and a bus bar is attached to the electrode side of a battery. The temperature sensor is attached to the battery module (specifically, the bus bar housing portion of the battery module).

  As shown in FIGS. 1 to 5, the temperature sensor 1 includes a temperature measuring unit 2 that contacts the battery and detects a temperature, and a resin-made holding unit 3 that holds the temperature measuring unit 2 (= first holding unit). ) And the holding unit 3 and the resin holding cover 4 (= second holding unit) attached to the battery module 100 and the temperature measuring unit 2 are held so as to be biased toward the battery. And a spring 5 (= biasing portion) provided between the cover 4 and the holding portion 3.

  As shown in FIG. 2B, the temperature measuring unit 2 includes a thermistor 21 that detects the temperature, and a heat transfer case 22 that houses the thermistor 21 and transfers heat from the battery to the thermistor 21. .

  The thermistor 21 has a main body 21A and a pair of terminals 21B protruding from the main body 21A. Each of the pair of terminals 21B is bent at approximately 90 degrees so that the tip portion is along the arrangement direction of the pair of terminals 21B (a pinching direction Y2 described later in the present embodiment). Further, the tip portions of the pair of terminals 21B are bent at different positions from the main body portion 21A so that the tip portions of the terminals 21B are arranged along the biasing direction Y1 of the spring 5.

  The heat transfer case 22 is made of metal, and has an elliptical cylindrical side wall 22A, a bottom wall 22B continuous with the side wall 22A, and an end of the side wall 22A on the opening 22C side in the longitudinal direction of the ellipse (a pin which will be described later in this embodiment). And a flange 22D protruding in the direction Y2).

  The body portion 21 </ b> A of the thermistor 21 is inserted into the inside through the opening 22 </ b> C of the heat transfer case 22, and the terminal 21 </ b> B of the thermistor 21 protrudes from the opening 22 </ b> C of the heat transfer case 22. The heat transfer case 22 is filled with, for example, a resin such as epoxy, and thereby the thermistor 21 is fixed in the heat transfer case 22.

  As shown in FIG. 1, the holding portion 3 is sandwiched between a pair of rail portions 42 protruding from a holding cover 4 described later. The holding portion 3 is held by the holding cover 4 so as to be movable in the urging direction Y1 of the spring 5 while being in sliding contact with the pair of rail portions 42. In the present embodiment, the urging direction Y1 is along the vertical direction.

  The holding unit 3 is provided in a substantially box shape, and is insert-molded so as to hold a part of the temperature measuring unit 2 described above as shown in FIGS. 2 and 4. Specifically, one end of the heat transfer case 22 on the flange 22D side is held in the holding unit 3, and the other end of the heat transfer case 22 on the bottom wall 22B side protrudes from the bottom surface of the holding unit 3 toward the battery, Exposed. Further, the tips of the pair of terminals 21B of the thermistor 21 protrude from one of the side surfaces of the holding portion 3 sandwiched between the pair of rail portions 42 and are exposed.

  The ends of the pair of terminals 21 </ b> B exposed to the outside are connected to the lead wire 6 by solder or the like, and the connection portion with the lead wire 6 is covered with the insulating tube 7. Further, on the upper surface of the holding portion 3, a groove 31 along an orthogonal direction Y <b> 3 orthogonal to the sandwiching direction Y <b> 2 of the pair of rail portions 42, and a spring attachment projecting from the bottom surface of the groove 31 toward the holding cover 4. Part 32 is provided. The spring mounting portion 32 is provided in a circular column shape, and one end of the spring 5 is fitted and fixed.

  Moreover, as shown in FIG. 2, the convex part 33 protrudes from the side surface pinched | interposed into a pair of rail part 42 in the holding | maintenance part 3, respectively. The convex portion 33 is inserted into the rail slit 45 along the urging direction Y <b> 1 provided on the rail portion 42. In the present embodiment, the convex portion 33 is provided at the end portion on the side away from the battery on the side surface of the holding portion 3.

  In addition, as shown in FIG. 2, the protrusion 33 and the protruding opening to the outside of the holding portion 3 at the tip of the pair of terminals 21B are provided side by side along the urging direction Y1. Thereby, the pair of terminals 21B exposed to the outside of the holding portion 3 is inserted into the rail slit 45, and the pair of terminals 21B and the holding cover 4 do not interfere with each other. Further, at the four corners of the bottom surface of the holding portion 3, there are provided concave portions 34 in which holding portion locking claws 46 of the holding cover 4 described later are locked.

  The holding cover 4 includes an upper wall 41, a pair of rail portions 42 (= regulating portions) protruding from both ends in the sandwiching direction Y <b> 2 of the upper wall 41 toward the holding portion 3, and a battery module from the outside of the pair of rail portions 42. A pair of wing parts 43 (= flexible arm parts) respectively projecting toward 100, and a module locking claw 44 (= first engagement) provided on each of the pair of wing parts 43 and locked to the battery module 100. Stop portion).

  The upper wall 41 is provided in a rectangular plate shape in which the sandwiching direction Y2 is long. A spring mounting portion 41 </ b> A that protrudes toward the holding portion 3 is provided at substantially the center of the upper wall 41. The spring mounting portion 41A is provided in a circular column shape, and the other end of the spring 5 is fitted and fixed.

  The pair of rail portions 42 sandwich the holding portion 3 between them and extend along the urging direction Y1. The pair of rail portions 42 are provided with rail slits 45 along the urging direction Y <b> 1 and holding portion locking claws 46 that are locked to the concave portions 34 of the holding portion 3.

  The rail slit 45 is provided so as to extend to the end portion on the battery side in the urging direction Y1 in the pair of rail portions 42. The holding portion locking claws 46 are provided so as to protrude inward from the end portions on the battery side in the urging direction Y1 of the pair of rail portions 42. Further, the holding portion locking claws 46 are provided on both sides in the orthogonal direction Y3 with the rail slit 45 interposed therebetween.

  The pair of wing parts 43 are provided obliquely so as to be separated from each other as the battery module 100 is approached, and the tip side is provided flexibly in the sandwiching direction Y2. The pair of wings 43 are also provided with wing slits 47 along the urging direction Y1. The wing slit 47 is provided so as to face the rail slit 45 in the sandwiching direction Y2, and extends from the module locking claw 44 to the end on the battery side in the urging direction Y1. Even when the holding unit 3 and the holding cover 4 are close to each other, the pair of terminals 21B exposed to the outside of the holding unit 3 are inserted into the wing slit 47, and thus the pair of terminals 21B and the holding cover 4 may interfere with each other. Absent. The module locking claw 44 protrudes toward the outside in the sandwiching direction Y2, and is locked to the locking projection 104 of the battery module 100 as shown in FIGS.

  Next, assembly of the temperature sensor 1 described above will be described. First, the holding | maintenance part 3 of the state holding the temperature measuring part 2 is shape | molded by insert molding. Thereafter, the holding portion 3 is inserted between the pair of rail portions 42 from the holding portion locking claw 46 side. At this time, the convex portion 33 of the holding portion 3 is inserted from the opening of the rail slit 45 on the battery side. Thereafter, the holding part 3 and the holding cover 4 are brought close to each other with the spring 5 being sandwiched between the holding part 3 and the holding cover 4, and the holding part 3 is locked to the concave part 34 of the holding part 3 at the tip of the rail part 42. The claw 46 is locked.

  Next, the battery module 100 to which the above-described temperature sensor 1 is attached will be described. The battery module 100 includes an upper wall 101 that overlaps the upper surface of the battery electrode, and a substantially rectangular through hole 102 (FIGS. 4 and 5) for attaching the temperature sensor 1 that passes through the upper wall 101. , Is provided. The through hole 102 is provided in such a size that the temperature measuring unit 2 protruding from the bottom surface of the holding unit 3 of the temperature sensor 1 cannot pass through the holding cover 4. As a result, the holding cover 4 of the temperature sensor 1 is supported by the peripheral edge of the through hole 102, and as shown in FIG. 5, the temperature measuring unit 2 protrudes through the through hole 102 and the bottom wall 22B of the battery is It abuts on the upper surface 200.

  Further, a pair of mounting walls 103 are provided upright from the edge of the through hole 102 so as to face each other in the orthogonal direction Y3. The side away from the battery in the urging direction Y1 between the pair of mounting walls 103 and both sides of the sandwiching direction Y2 are opened. The mounting wall 103 is provided with a locking projection 104 that is locked to the module locking claw 44 of the holding cover 4. The locking projections 104 are provided at both ends of the mounting wall 103 in the sandwiching direction Y2 and at the end portion on the side away from the battery in the biasing direction Y1. When the temperature sensor 1 is inserted from the opening on the side away from the battery in the urging direction Y1 between the pair of mounting walls 103, the module locking claw 44 of the temperature sensor 1 and the locking projection 104 of the battery module 100 are engaged. The temperature sensor 1 does not come off from the pair of mounting walls 103.

  When the module locking claw 44 of the temperature sensor 1 and the locking projection 104 of the battery module 100 are locked, the bottom wall 22B of the temperature measuring unit 2 is brought into contact with the battery, and the holding unit 3 is held by the holding cover. It moves to the side farther from the battery than the position where it engages with the four retaining portion locking claws 46. Thereby, the spring 5 contracts and the temperature measuring unit 2 is urged toward the battery.

  According to the temperature sensor 1 described above, since the holding unit 3 that holds the temperature measuring unit 2 is urged toward the battery by the spring 5, the distance between the temperature measuring unit 2 and the battery varies due to vibration or the like. There is no. More specifically, even if the battery module 100 is displaced in a direction away from the battery due to vibration or the like, the holding unit 3 is biased toward the battery by the spring 5, so the holding unit 3 is displaced in a direction approaching the battery. , The distance does not change. In addition, the movement of the holding portion 3 in a direction other than the urging direction Y1 is restricted by the pair of rail portions 42. More specifically, since the side surface of the holding portion 3 is sandwiched between the pair of rail portions 42, the movement in the sandwiching direction Y <b> 2 is restricted, and the convex portion 33 of the holding portion 3 is inserted into the rail slit 45. Movement in the direction Y3 is also restricted. Thereby, since the temperature measuring part 2 does not incline with respect to the urging | biasing direction Y1, and contacts a battery, the temperature of a battery can be detected correctly.

  Further, according to the temperature sensor 1 described above, the movement of the holding unit 3 can be restricted with a simple configuration in which the holding unit 3 is sandwiched between the pair of rail units 42. In addition, if the tips of the pair of wings 43 are brought close to each other, the latching projection 104 of the battery module 100 and the module latching claw 44 can be easily unlocked. Can be exchanged.

(Second Embodiment)
Next, the temperature sensor of the present invention in the second embodiment will be described with reference to FIGS. This temperature sensor is for detecting the temperature of the battery as in the first embodiment, and is attached to the battery module.

  As shown in FIGS. 6 to 11, the temperature sensor 11 includes a temperature measuring unit 12, a holding unit 13 (= first holding unit), and a holding cover 14 (= second), as in the first embodiment. Holding portion) and a spring 15 (= biasing portion). Similar to the first embodiment, the temperature measuring unit 12 includes a thermistor 121 and a heat transfer case 122.

  Similar to the first embodiment, the thermistor 121 includes a main body 121A and a pair of terminals 121B protruding from the main body 121A, as shown in FIG. In the second embodiment, the pair of terminals 121B are not bent and protrude straight. And the lead wire 16 is connected to the front-end | tip of a pair of terminal 121B.

  The heat transfer case 122 includes a circular cylindrical side wall 122A, a bottom wall 122B continuous with the side wall 122A, and a flange 122D protruding from the end of the side wall 122A on the opening 122C side. In the second embodiment, the flange 122D is provided so as to protrude from the entire edge of the opening 122C at the end of the side wall 122A.

  The main body 121A of the thermistor 121 is inserted into the inside from the opening 122C of the heat transfer case 122, and the terminal 121B of the thermistor 121 protrudes to the outside from the opening 122C of the heat transfer case 122. The heat transfer case 122 is filled with, for example, a resin such as epoxy, and thereby the thermistor 121 is fixed to the heat transfer case 122.

  The holding part 13 is sandwiched between a pair of rail parts 142 protruding from a holding cover 14 described later. The holding portion 13 is held by the holding cover 14 so as to be movable in the urging direction Y1 of the spring 15 while being in sliding contact with the pair of rail portions 142.

  The holding | maintenance part 13 is provided in the hollow substantially box shape. The holding unit 13 includes a rectangular upper wall 131, a pair of side walls 132 and 133 erected from the edges of both sides of the upper wall 131 in the orthogonal direction Y3 toward the battery side in the biasing direction Y1, and the upper wall 131. , And a side wall 134 projecting from the edge on one side (left side in the drawing) in the sandwiching direction Y2 toward the battery side in the biasing direction Y1.

  The upper wall 131 is provided with a columnar spring mounting portion 131 </ b> A that protrudes toward the holding cover 14. From the upper wall 131, as described above, the three side walls 132, 133, 134 are erected, and the side wall is not erected from the edge of the other side (right side of the drawing) of the sandwiching direction Y2 in the upper wall 131. . Further, the holding portion 13 is not provided with a bottom wall. Accordingly, the holding portion 13 has a first opening O1 for inserting one end of the temperature measuring portion 12 on the flange 122D side into the inside from a direction orthogonal to the urging direction Y1 (the sandwiching direction Y2 in this embodiment). A second opening O2 for exposing one end of the temperature measuring unit 12 on the bottom wall 122B side to the outside is provided, and the first opening O1 and the second opening O2 are communicated with each other. That is, in the second embodiment, the insertion direction of the temperature measuring unit 2 is the sandwiching direction Y2.

  Further, on the inner side surfaces of the pair of side walls 132 and 133 and the side wall 134, a locking groove 135 (= second locking portion) for fitting and locking the flange 122D of the temperature measuring unit 12 is provided. . As shown in FIGS. 7 and 9, the locking grooves 135 provided in the pair of side walls 132 and 133 are provided along the sandwiching direction Y2 and extend to both ends of the pair of side walls 132 and 133 in the sandwiching direction Y2. Has been. The locking groove 135 provided on the side wall 134 extends along the orthogonal direction Y3, and both ends are connected to the locking groove 135 provided on the pair of side walls 132 and 133.

  Further, as shown in FIG. 7 and the like, a pair of convex portions 136 are provided from both ends of the orthogonal direction Y3 on the other end surface in the sandwiching direction Y2 of the pair of side walls 132, 133. The pair of convex portions 136 extend along the biasing direction Y1, and both sides of the rail portion 142 in the orthogonal direction Y3 are sandwiched between the pair of convex portions 136. In 2nd Embodiment, the movement of the orthogonal | vertical direction Y3 of the holding | maintenance part 13 is controlled by pinching the rail part 142 between this pair of convex parts 136. FIG.

  Further, as shown in FIG. 6, the side wall 132 is provided with a third opening O3 for drawing out the lead wire 16 connected to the terminal 121B in an orthogonal direction Y3 orthogonal to both the urging direction Y1 and the sandwiching direction Y2. It has been. The third opening O3 extends to the other end of the side wall 132 in the sandwiching direction Y2, and communicates with the first opening O1.

  Moreover, the recessed part 137 where the holding | maintenance part latching nail | claw 146 of the holding | maintenance cover 14 is each latched is provided in the edge part of the urging | biasing direction Y1 battery side of the pair of side walls 132 and 133, and the pinching direction Y2. A concave portion 137 in which the holding portion locking claw 146 of the holding cover 14 is locked is also provided at the end portion of the side wall 134 in the biasing direction Y1 battery side. The recess 137 provided in the side wall 134 is provided so as to extend along the orthogonal direction Y3.

  The holding cover 14 includes an upper wall 141, a pair of rail portions 142 (= regulating members) protruding from both ends of the sandwiching direction Y <b> 2 of the upper wall 141 toward the holding portion 13, and a battery module from the outside of the pair of rail portions 142. A pair of wings 143 (= flexible arm portions) respectively projecting toward 200, and a module locking claw 144 (= first engagement) provided on each of the pair of wings 143 and locked to the battery module 200. Stop portion).

  The upper wall 141 is provided in a rectangular plate shape in which the sandwiching direction Y2 is long. In the center of the upper wall 141, a spring mounting portion 141A that protrudes toward the holding portion 13 is provided. The spring mounting portion 141A is provided in a circular column shape, and the other end of the spring 15 is fitted and fixed.

  The pair of rail portions 142 sandwich the holding portion 13 therebetween and extend along the urging direction Y1. As in the first embodiment, the pair of rail portions 142 are provided with holding portion locking claws 146 that are locked to the concave portions 137 of the holding portion 13, but are not provided with rail slits.

  The pair of wings 143 are provided obliquely so as to be separated from each other as the battery module 200 is approached, and the tip side is provided flexibly in the sandwiching direction Y2. Unlike the first embodiment, the pair of wing portions 143 of the first embodiment are not provided with wing slits. The module locking claw 144 protrudes toward the outside in the sandwiching direction Y2 and is locked to the locking part 204 of the battery module 200.

  Next, the assembly of the temperature sensor 11 described above will be described. First, as shown in FIG. 7, the lead wire 16 is connected to the tip of the terminal 121B of the thermistor 121 fixed to the heat transfer case 122 by caulking or the like. Thereafter, one end of the temperature measuring unit 12 on the flange 122D side is inserted into the inside from the first opening O1 of the holding unit 13. At this time, the flange 122D is fitted into the locking groove 135. When the flange 122D is fitted into the locking groove 135, the other end on the bottom wall 122B side of the temperature measuring unit 12 protrudes from the second opening O2. The lead wire 16 is inserted from the end portion on the other side in the sandwiching direction Y2 of the third opening O3 and pulled out from the third opening O3. As shown in FIG. 9, the temperature measuring unit 12 is inserted toward the side wall 134 until the flange 122 </ b> D is fitted in a locking groove 135 provided on the side wall 134 of the holding unit 13.

  Thereafter, the holding portion 13 is inserted between the pair of rail portions 142 from the holding portion locking claw 146 side. Thereafter, the holding portion 13 and the holding cover 14 are brought close to each other with the spring 15 sandwiched between the holding portion 13 and the holding cover 14, and the holding portion locking provided at the tip of the rail portion 142 in the recess 137 of the holding portion 13 is held. The claw 146 is locked. At this time, the first opening O <b> 1 is closed by the pair of rail portions 142.

  Next, the battery module 200 to which the above-described temperature sensor 11 is attached will be described. The battery module 200 is provided with an upper wall 201 that is superimposed on the upper surface of the battery electrode, and a substantially rectangular through hole 202 for attaching the temperature sensor 11 that passes through the upper wall 201. The through hole 202 is provided in such a size that the temperature measuring unit 12 protruding from the bottom surface of the holding unit 13 of the temperature sensor 11 cannot pass through the holding cover 14. Accordingly, the holding cover 14 of the temperature sensor 1 is supported by the peripheral edge of the through hole 202, and the temperature measuring unit 2 protrudes through the through hole 202 and comes into contact with the upper surface of the battery.

  Further, the mounting walls 203 are erected from a pair of edge portions facing the orthogonal direction Y3 of the through hole 202, respectively. The side away from the battery in the biasing direction Y1 between the pair of mounting walls 203 and both sides of the sandwiching direction Y2 are opened. In the second embodiment, between the pair of mounting walls 203, a locking portion 204 that is locked to the module locking claw 144 of the holding cover 14 is provided. The locking portion 204 is provided so as to connect both ends of the pair of mounting walls 203 in the sandwiching direction Y2 and end portions on the side away from the battery in the biasing direction Y1. When the temperature sensor 11 is inserted from the opening on the side away from the battery in the urging direction Y1 between the pair of mounting walls 203, the module locking claw 144 of the temperature sensor 11 and the locking portion 204 of the battery module 200 are locked. Thus, the temperature sensor 11 does not come off from the pair of mounting walls 203.

  When the module locking claw 144 of the temperature sensor 11 and the locking part 204 of the battery module 200 are locked, the temperature measuring part 12 is brought into contact with the battery, and the holding part 13 is engaged with the holding part of the holding cover 14. It moves to the side farther from the battery than the position where it engages with the pawl 146. Thereby, the spring 15 contracts and the temperature measuring unit 12 is biased toward the battery.

  According to the temperature sensor 11 of the second embodiment described above, since the first opening O1 and the second opening O2 communicate with each other, the other end on the bottom wall 122B side of the temperature measuring unit 12 is connected to the second opening. One end of the temperature measuring unit 12 on the flange 122D side can be inserted into the holding unit 13 through the first opening O1 and can be locked by the locking groove 135 while being exposed from O2. Thereby, since the temperature measuring part 12 can be easily held in the holding part 13 without insert molding the temperature measuring part 2 in the holding part 3 as in the first embodiment, the cost can be reduced.

  Further, according to the temperature sensor 11 of the second embodiment described above, since the first opening O1 and the third opening O3 are in communication, the lead wire 16 is pulled out from the third opening O3. One end of the temperature measuring unit 12 can be inserted into the holding unit 13 through the first opening O1 and can be locked by the locking groove 135. Thereby, the lead wire 16 can be pulled out in the orthogonal direction Y3 orthogonal to both the urging direction Y1 and the sandwiching direction Y2 which is the insertion direction of the temperature measuring unit 12.

  Further, according to the temperature sensor 11 of the second embodiment described above, since the first opening O1 is closed by the rail portion 142, the rail portion 142 and a member that closes the first opening O1 are provided separately. Since it is not necessary, the number of parts can be reduced and the cost can be reduced.

  According to the second embodiment described above, the lead wire 16 is protruded from the third opening O3. However, the terminal 121B may be protruded as in the first embodiment. Further, the lead wire 16 protrudes from the orthogonal direction Y3 of the holding portion 13, but, similarly to the first embodiment, a slit is provided in the rail portion 142 and the wing portion 143, and the holding portion 13 is sandwiched in the sandwiching direction Y2 on the other side. You may make it protrude from provided 1st opening O1.

  Further, according to the first and second embodiments described above, the coiled springs 5 and 15 are used as the urging portion, but the present invention is not limited to this. The urging unit may be any one provided between the holding units 3 and 13 and the holding covers 4 and 14 so that the temperature measuring units 2 and 12 are urged toward the battery. You may be comprised from the rubber member etc. which were provided elastically in the spring and the urging | biasing direction Y1.

  Further, according to the first and second embodiments described above, the restricting portion is constituted by the pair of rail portions 42 and 142, but is not limited thereto. As the restricting portion, any member that restricts the movement of the holding portions 3 and 13 in directions other than the urging direction Y1 of the springs 5 and 15 may be used, for example, protruding from the entire peripheral edge of the upper walls 41 and 141, You may provide in the cylinder shape which can hold | maintain the holding parts 3 and 13 inside.

  Further, according to the first and second embodiments described above, in the holding covers 4 and 14, the module locking claws 44 and 144 provided on the wing parts 43 and 143 protruding from the rail parts 42 and 142 are connected to the battery module. Although it was made to latch to 100,200, it is not restricted to this. For example, locking protrusions protruding in the orthogonal direction Y3 may be provided on the upper walls 41, 141 of the holding covers 4, 14, and the locking protrusions may be locked to the battery modules 100, 102.

  Further, the above-described embodiments are merely representative forms of the present invention, and the present invention is not limited to the embodiments. That is, various modifications can be made without departing from the scope of the present invention.

1, 11 Temperature sensor 2, 12 Temperature measuring unit 3, 13 Holding unit (first holding unit)
4, 14 Holding cover (second holding part)
5, 15 Spring 6, 16 Lead wire 21B, 121B Terminal 42, 142 Rail part (regulation part)
43,143 Wings (a pair of flexible arms)
44, 144 Module locking claw (first locking portion)
135 Locking groove (second locking part)
100, 200 Battery module (attachment target)
O1 1st opening O2 2nd opening O3 3rd opening Y1 Energizing direction Y2 Nipping direction (insertion direction)
Y3 orthogonal direction (direction orthogonal to both the urging direction and the insertion direction of the temperature measuring unit)

Claims (5)

A temperature sensor for detecting the temperature of a detection target,
A temperature measuring unit for detecting the temperature in contact with the detection target;
A first holding unit for holding the temperature measuring unit;
While holding the first holding portion, a second holding portion attached to the attachment target,
An urging unit provided between the first holding unit and the second holding unit so that the temperature measuring unit is urged toward the detection target;
The temperature sensor, wherein the second holding unit includes a regulating unit that regulates movement of the first holding unit in a direction other than the urging direction of the urging unit. The restricting portion includes a pair of rail portions that sandwich the first holding portion between each other and extend along the biasing direction.
The second holding portion is provided on each of the pair of flexible arm portions projecting from the outside of the pair of rail portions toward the attachment target, and the pair of flexible arm portions, and is attached to the attachment target. The temperature sensor according to claim 1, further comprising: a first locking portion that locks. The first holding part is provided in a hollow shape, and is engaged with a first opening for inserting one end of the temperature measuring part into the inside from a direction orthogonal to the urging direction and one end of the temperature measuring part. A second locking portion for stopping, and a second opening for exposing the other end of the temperature measuring portion to the outside, and
The temperature sensor according to claim 1 or 2, wherein the first opening and the second opening are communicated with each other. The first holding part is provided with a third opening for pulling out a terminal of the temperature measuring part or a lead wire connected to the terminal in a direction orthogonal to both the urging direction and the inserting direction of the temperature measuring part The temperature sensor according to claim 3, wherein the first opening and the third opening communicate with each other. The restricting portion includes a pair of rail portions that sandwich the first holding portion between each other and extend along the biasing direction.
The first holding part is provided in a hollow shape, and is engaged with a first opening for inserting one end of the temperature measuring part into the inside from a direction orthogonal to the urging direction and one end of the temperature measuring part. A second locking portion to be stopped and a second opening for exposing the other end of the temperature measuring portion to the outside, the first opening and the second opening are communicated,
The temperature sensor according to claim 1, wherein the first opening is blocked by the rail portion.

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