JP2021139634A - Bus bar module - Google Patents

Abstract

To provide a bus bar module having excellent responsibility and capable of accurately measuring a temperature of a bus bar.SOLUTION: A bus bar module includes: a bus bar 2; a resin case part 14 molded in the bus bar by a resin; and a temperature sensor 3 attached to an inside of the resin case part. Inner walls are constituted by at least the resin case part so as to obtain a storage space to store the temperature sensor. The temperature sensor includes: an element body arranged at a distal end part and having a thermosensitive element; and a pair of lead wires connected to the thermosensitive element. The element body is inserted to the storage space. A portion between the element body and the resin case part is filled with an insulating adhesive resin.SELECTED DRAWING: Figure 1

Description

The present invention relates to a bus bar module used as a wiring member for a battery or an automobile and to which a temperature sensor is attached.

It is known that a bus bar used as a wiring member for a battery or an automobile is equipped with a temperature sensor to detect the temperature of the bus bar.
In the past, the temperature sensor of the finished product was attached to the bus bar, but since the temperature sensor was fixed using a resin coat that covered the entire bus bar, there was the inconvenience that the heat capacity increased and the responsiveness deteriorated. .. In addition, since the amount of resin to be fixed varies, the heat capacity and responsiveness vary.
Further, when the temperature sensor is attached to the bus bar by the lock mechanism, the structure is complicated and the cost is high, and the fixing is insufficient due to the release of the lock mechanism, so that the measurement accuracy is deteriorated. In addition, there is a problem that the contact is poor due to the deviation of the tolerance and the heat collection from the bus bar is poor.
Therefore, as a structure for attaching the temperature sensor without using a resin coat or a lock mechanism, a structure in which a storage case for the temperature sensor is attached to the bus bar has been proposed.

Conventionally, for example, in Patent Document 1, a storage case formed in an L shape with the tip portion bent downward is inserted into a temperature sensor insertion space of a bus bar module attached to a portion to be measured, and a thermistor is inserted in the storage case. The temperature sensor mounting structure is described in which the temperature detection wire including the lead wire and the electric wire is stored according to the shape of the storage case, and the thermistor, the lead wire, and a part of the electric wire are covered with a metal heat collecting member. Has been done.

Japanese Unexamined Patent Publication No. 2018-151349

The following problems remain in the above-mentioned conventional technology.
That is, in the above-mentioned conventional technique, heat collection and heat transfer are deteriorated due to poor contact between the storage case and the bus bar (due to tolerance, warpage, sink marks, etc.) and deterioration of the mounting state of the storage case, and the responsiveness is also deteriorated. There was a problem that the temperature measurement accuracy was lowered at the same time.

The present invention has been made in view of the above-mentioned problems, and an object of the present invention is to provide a bus bar module which is excellent in responsiveness and can measure a bus bar temperature with high accuracy.

The present invention has adopted the following configuration in order to solve the above problems. That is, the bus bar module according to the first invention includes a bus bar, a resin case portion formed of resin in a part of the bus bar, and a temperature sensor mounted in the resin case portion, and at least the resin case portion. The inner wall is formed by the above, and has a storage space capable of accommodating the temperature sensor. The element main body is inserted into the storage space, and an insulating adhesive resin is filled between the element main body and the resin case portion.

In this bus bar module, a resin case portion molded of resin is provided in a part of the bus bar, and at least the inner wall is formed by the resin case portion to have a storage space in which a temperature sensor can be stored, and the element body is inserted into the storage space. Since the insulating adhesive resin is filled between the element body and the resin case, the element body is resin-sealed in the resin case integrated with the bus bar by insert molding, so that the bus bar is formed. Good heat collection from the resin and high responsiveness can be obtained.
That is, the element body is embedded in the resin case integrated with the bus bar with an adhesive resin, and fixed and positioned on the bus bar, which is the object to be measured, so that high temperature measurement accuracy and high-speed response can be obtained. .. Further, by positioning the element body in the resin case portion, it is possible to suppress variations in responsiveness. Furthermore, since the resin case part is directly integrated with the bus bar by insert molding without preparing a separate member such as a storage case, the resin case part can be set as small as possible, the heat capacity can be reduced, and the cost can be reduced. It becomes possible to plan. Since the adhesive resin is injected only into the gap between the element body and the storage space and is limited to a small amount, it is possible to suppress an increase in heat capacity and also to suppress variations in heat capacity and responsiveness. ..

The bus bar module according to the second invention is characterized in that, in the first invention, the inner wall of the storage space is composed of the resin case portion and the bus bar.
That is, in this bus bar module, since the inner wall of the storage space is composed of the resin case portion and the bus bar, the metal surface of the bus bar becomes a part of the inner wall and the resin case portion of the heat receiving surface can be omitted. By making the distance from the element body closer, the heat conduction to the element body is further improved, and the response can be made faster.

The bus bar module according to the third invention is characterized in that, in the first or second invention, a part of the resin case portion covers a part of the outer surface of the bus bar.
That is, in this bus bar module, since a part of the resin case part covers a part of the outer surface of the bus bar, the contact surface between the resin case part and the bus bar increases, and more from the bus bar to the resin case part. Heat can be collected.

The bus bar module according to the fourth invention has, in any one of the first to third inventions, a second extending portion in which the bus bar extends in parallel with the first extending portion and the first extending portion. And a U-shape including a connecting portion for connecting the tip end portion of the first extending portion and the tip end portion of the second extending portion, the first extending portion, the connecting portion, and the first It is characterized in that three of the inner walls of the storage space are formed by the two extending portions.
That is, in this bus bar module, since the first extending portion, the connecting portion, and the second extending portion form three of the inner walls of the storage space, the metal surface formed by the bus bar constitutes the three inner walls. Therefore, higher responsiveness and temperature measurement accuracy can be obtained.

In the bus bar module according to the fifth invention, in any one of the first to third inventions, in any of the first to third inventions, the bus bar has a first extending portion and the first extending portion. It has an L-shape including a second extending portion extending from the tip end portion of the portion in a direction orthogonal to the first extending portion, and the first extending portion and the second extending portion are described as described above. It is characterized in that two of the inner walls of the storage space are configured.
That is, in this bus bar module, since two surfaces of the inner wall of the storage space are formed by the first extending portion and the second extending portion, the metal surface formed by the bus bar constitutes the two inner walls. Higher responsiveness and temperature measurement accuracy can be obtained.

The bus bar module according to the sixth aspect of the invention is characterized in that, in any one of the first to fifth inventions, all the inner walls of the storage space are formed by the inner surface of the resin case portion.
That is, in this bus bar module, since all the inner walls of the storage space are formed by the inner surface of the resin case portion, the shape of the storage space can be arbitrarily set by molding the resin case portion, and the storage space can be stored. It is easy to form a storage space corresponding to the size and shape of the element body and the like.

In any one of the first to sixth aspects of the invention, the bus bar module according to the seventh aspect includes a pair of electric wires in which the temperature sensor is connected to the pair of lead wires, and the lead wire is connected to the element body. It is characterized in that up to the connection portion with the electric wire is inserted into the storage space.
That is, in this bus bar module, since the element body to the connection portion between the lead wire and the electric wire is inserted in the storage space, the element body is more firmly fixed and the entire lead wire is in the storage space. It can be buried to obtain even higher responsiveness and temperature measurement accuracy.

According to the present invention, the following effects are obtained.
That is, according to the bus bar module according to the present invention, a resin case portion formed of resin is provided in a part of the bus bar, and at least the inner wall is formed by the resin case portion to have a storage space for accommodating a temperature sensor. Since the main body is inserted into the storage space and the insulating adhesive resin is filled between the element main body and the resin case part, the element main body is resin-sealed in the resin case part integrated with the bus bar by insert molding. By being stopped, heat collection from the bus bar is good, and high responsiveness can be obtained.
As described above, since the bus bar module of the present invention has high thermal responsiveness and little variation in thermal responsiveness, it is possible to measure the temperature of the bus bar with high accuracy.

It is a perspective view which shows the 1st Embodiment of the bus bar module which concerns on this invention. It is sectional drawing which shows the bus bar module in 1st Embodiment. It is a perspective view which shows the bus bar in 1st Embodiment. In the first embodiment, it is the right side view which shows the bus bar module before attaching the temperature sensor. It is a perspective view which shows the state which attached the bus bar module to a motor in 1st Embodiment. It is a perspective view which shows the 2nd Embodiment of the bus bar module which concerns on this invention. In the second embodiment, it is a perspective view seen from the right side which shows the bus bar module before the temperature sensor is attached. It is a perspective view which shows the 3rd Embodiment of the bus bar module which concerns on this invention. In the third embodiment, it is a perspective view seen from the right side which shows the bus bar module before the temperature sensor is attached.

Hereinafter, the first embodiment of the bus bar module according to the present invention will be described with reference to FIGS. 1 to 5. In some of the drawings used in the following description, the scale is appropriately changed as necessary in order to make each part recognizable or easily recognizable.

As shown in FIGS. 1 to 5, the bus bar module 1 of the present embodiment includes a bus bar 2, a resin case portion 14 formed of resin on a part of the bus bar 2, and a temperature mounted in the resin case portion 14. It is equipped with a sensor 3.
The bus bar module 1 of the present embodiment has an inner wall formed by at least the resin case portion 14 and has a storage space S capable of accommodating the temperature sensor 3.
In FIG. 4, the resin case portion 14 is hatched for easy viewing. Hereinafter, hatching is also applied to FIGS. 7 and 9.

As shown in FIG. 2, the temperature sensor 3 is connected to an element body 4 having a heat-sensitive element 4a provided at the tip thereof, a pair of lead wires 5 connected to the heat-sensitive element 4a, and a pair of lead wires 5. It is provided with a pair of electric wires 6 provided.
The element body 4 is inserted into the storage space S, and an insulating adhesive resin 7 is filled between the element body 4 and the resin case portion 14.

As shown in FIG. 4, the bus bar 2 includes a first extending portion 8, a second extending portion 9 extending in parallel with the first extending portion 8, and a tip portion of the first extending portion 8. It is U-shaped with a connecting portion 10 that connects the tip of the second extending portion 9, and the inner wall of the storage space S is formed by the first extending portion 8, the connecting portion 10, and the second extending portion 9. Three of them are composed.

That is, the inner wall of the storage space S is composed of the resin case portion 14 and the bus bar 2.
Three of the inner walls of the storage space S are composed of inner surfaces of the first extending portion 8, the connecting portion 10, and the second extending portion 9, and two of the inner walls of the storage space S ( The upper and lower surfaces) are formed of the inner surface of the resin case portion 14.

Further, a part of the resin case portion 14 covers a part of the outer surface of the bus bar 2.
That is, the resin case portion 14 has a first protruding portion 14a that covers the outer surface of the first extending portion 8, a second protruding portion 14b that covers the outer surface of the second extending portion 8, and the outside of the connecting portion 10. It is provided with a third protruding portion 14c that covers up to the side surface.

Further, the element main body 4 to the connecting portion 5a between the lead wire 5 and the electric wire 6 are inserted into the storage space S.
The connection portion 5a connects the lead wire 5 and the electric wire 6 by laser welding.

The bus bar 2 is provided with two projecting portions 8a on the side portion of the first extending portion 8 for attaching and connecting to a vehicle-mounted battery, a motor, or the like.
Further, the bus bar 2 is made of a metal such as Cu.
The element body 4 includes a heat-sensitive element 4a such as a chip thermistor, a sealing glass portion 4b in which the heat-sensitive element 4a is covered with glass, and a resin-coated portion 4c in which the sealing glass portion 4b is covered with resin. There is.

The resin-coated portion 4c is also formed so as to cover the pair of lead wires 5.
The electric wire 6 includes an electric wire core wire 6a and an electric wire covering portion 6b that covers the electric wire core wire 6a.
As the adhesive resin 7, an insulating resin such as a silicone resin or an epoxy resin can be used, and a resin having good thermal conductivity is particularly preferable.

FIG. 5 shows a state in which the bus bar module 1 of the present embodiment is attached to the motor M.
In FIG. 5, the protruding portion 8a is welded to the side surface of the coil portion of the motor M to attach the bus bar module 1.

As described above, in the bus bar module 1 of the present embodiment, the bus bar 2 is provided with a resin case portion 14 formed of resin, and at least the inner wall is formed by the resin case portion 14 and has a storage space S capable of accommodating the temperature sensor 3. Since the element body 4 is inserted into the storage space S and the insulating adhesive resin 7 is filled between the element body 4 and the resin case portion 14, the resin integrated with the bus bar 2 by insert molding. Since the element main body 4 is resin-sealed in the case portion 14, heat collection from the bus bar 2 is good, and high responsiveness can be obtained.

That is, the element main body 4 is embedded in the resin case portion 14 integrated with the bus bar 2 with the adhesive resin 7, and fixed and positioned on the bus bar 2 which is the measurement target, thereby achieving high temperature measurement accuracy and high-speed response. Can be obtained. Further, by positioning the element main body 4 in the resin case portion 14, it is possible to suppress variations in responsiveness.

Further, since the resin case portion 14 is directly integrated with the bus bar 2 by insert molding without separately preparing a separate member such as a storage case, the resin case portion 14 can be set as small as possible, the heat capacity can be reduced, and the heat capacity is low. It becomes possible to reduce the cost. Since the adhesive resin 7 is injected only into the gap between the element body 4 and the storage space S and is limited to a small amount, it is possible to suppress an increase in heat capacity and also suppress variations in heat capacity and responsiveness. be able to.

Further, since the inner wall of the storage space S is composed of the resin case portion 14 and the bus bar 2, the metal surface formed by the bus bar 2 becomes a part of the inner wall, and the resin case portion 14 on the heat receiving surface can be omitted. By making the distance from the element body 4 close, the heat conduction to the element body 4 is further improved, and a higher speed response can be achieved.
Further, since a part of the resin case portion 14 covers a part of the outer surface of the bus bar 2, the contact surface between the resin case portion 14 and the bus bar 2 increases, and more from the bus bar 2 to the resin case portion 14. It becomes possible to collect heat.

Further, since the first extending portion 8, the connecting portion 10, and the second extending portion 9 form three surfaces of the inner wall of the storage space S, the metal surface formed by the bus bar 2 constitutes the three surfaces of the inner wall. Therefore, higher responsiveness and temperature measurement accuracy can be obtained.
Further, since the element main body 4 to the connection portion 5a between the lead wire 5 and the electric wire 6 are inserted into the storage space S, the element main body 4 is more firmly fixed and the entire lead wire 5 is the storage space S. It is buried inside, and even higher responsiveness and temperature measurement accuracy can be obtained.

Next, the second and third embodiments of the bus bar module according to the present invention will be described below with reference to FIGS. 6 to 9. In the following description of each embodiment, the same components described in the above embodiment are designated by the same reference numerals, and the description thereof will be omitted.

The difference between the second embodiment and the first embodiment is that the bus bar 2 is U-shaped in the first embodiment, whereas the bus bar module 21 of the second embodiment is shown in FIGS. 6 and 7. As described above, the bus bar 22 is L-shaped.
That is, the bus bar 22 of the second embodiment has a first extending portion 20 and a second extending portion 29 extending in a direction orthogonal to the first extending portion 20 from the base end portion of the first extending portion 20. As shown in FIG. 7, the first extending portion 20 and the second extending portion 29 form two surfaces of the inner wall of the storage space S.
In the third embodiment, the tip portion 20a of the first extending portion 20 is a protruding portion for attaching and connecting to an in-vehicle battery, a motor, or the like.

In the second embodiment, as shown in FIG. 7, two surfaces of the inner wall of the storage space S are composed of a first extending portion 20 and a second extending portion 29 and each inner side surface, and the storage space S is formed. Three surfaces (upper and lower surfaces and surfaces facing the first extending portion 20) of the inner walls of the resin case portion 24 are formed of the inner surfaces of the resin case portion 24.
As described above, in the bus bar module 21 of the second embodiment, since the first extending portion 20 and the second extending portion 29 form two surfaces of the inner wall of the storage space S, the metal surface formed by the bus bar 22 is formed. By configuring the two surfaces of the inner wall, higher responsiveness and temperature measurement accuracy can be obtained.

Next, the difference between the third embodiment and the first embodiment is that in the first embodiment, the first extending portion 8, the connecting portion 10, and the second extending portion 9 are included in the inner wall of the storage space S. In contrast to the three surfaces, in the bus bar module 31 of the second embodiment, as shown in FIGS. 8 and 9, all the inner walls of the storage space S are composed of the inner surfaces of the resin case portion 34. That is the point.
As described above, in the bus bar module 31 of the third embodiment, since all the inner walls of the storage space S are formed by the inner surface of the resin case portion 34, the shape of the storage space S can be arbitrarily changed by molding the resin case portion 34. It becomes possible to set, and it becomes easy to form a storage space S corresponding to the size and shape of the element main body 4 or the like to be stored.

The technical scope of the present invention is not limited to each of the above embodiments, and various modifications can be made without departing from the spirit of the present invention.

For example, in each of the above embodiments, a chip thermistor is used as the heat sensitive element, but a thin film thermistor, a pyroelectric element, or the like may be used.
Further, in each of the above embodiments, the resin case portion is insert-molded into the U-shaped or L-shaped bus bar, but the resin case portion may be insert-molded into the bus bar having another shape. For example, the resin case portion may be insert-molded into an I-shaped bus bar. In this case, one surface of the inner wall of the storage space of the resin case portion can be composed of a bus bar.

1,21,31 ... Busbar module, 2,22 ... Busbar, 3 ... Temperature sensor, 4 ... Element body, 4a ... Heat sensitive element, 5 ... Lead wire, 5a ... Connection part, 6 ... Electric wire, 7 ... Adhesive resin, 8,20 ... 1st extending part, 9,29 ... 2nd extending part, 10 ... connecting part, 14,24,34 ... resin case part, S ... storage space

Claims (7)

Busbar and
A resin case part molded from resin on a part of the bus bar,
It is equipped with a temperature sensor mounted inside the resin case.
At least the inner wall is formed by the resin case portion and has a storage space capable of accommodating the temperature sensor.
The temperature sensor includes an element body having a heat-sensitive element provided at the tip thereof and an element body.
It is provided with a pair of lead wires connected to the thermal element.
A bus bar module characterized in that the element main body is inserted into the storage space, and an insulating adhesive resin is filled between the element main body and the resin case portion. In the bus bar module according to claim 1,
A bus bar module characterized in that the inner wall of the storage space is composed of the resin case portion and the bus bar. In the bus bar module according to claim 1 or 2.
A bus bar module characterized in that a part of the resin case portion covers a part of the outer surface of the bus bar. In the bus bar module according to any one of claims 1 to 3.
The bus bar is the first extending part and
The second extending portion extending parallel to the first extending portion and the second extending portion
It has a U-shape including a connecting portion that connects the tip of the first extending portion and the tip of the second extending portion.
A bus bar module characterized in that three surfaces of the inner wall of the storage space are formed by the first extending portion, the connecting portion, and the second extending portion. In the bus bar module according to any one of claims 1 to 3.
The bus bar is the first extending part and
It has an L-shape including a second extending portion extending from the tip end portion of the first extending portion in a direction orthogonal to the first extending portion.
A bus bar module characterized in that two surfaces of the inner wall of the storage space are formed by the first extending portion and the second extending portion. In the bus bar module according to any one of claims 1 to 5.
A bus bar module characterized in that all the inner walls of the storage space are formed by the inner surface of the resin case portion. In the bus bar module according to any one of claims 1 to 6.
The temperature sensor comprises a pair of wires connected to the pair of leads.
A bus bar module characterized in that a portion from the element body to a connection portion between the lead wire and the electric wire is inserted into the storage space.

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