JPH08128901A - Temperature sensor and pack battery - Google Patents

Abstract

PURPOSE: To provide a compact pack battery of which a thin temperature sensor is mass-produced inexpensively, short-circuit of the lead wire of the temperature sensor is effectively prevented, and a battery temperature is precisely detected. CONSTITUTION: A temperature sensor is provided with a sensor element 1 which detects a temperature, a lead wire 2 connected to the sensor element 1, and a package 3 which covers a part of the lead wire 2 and the sensor 1. The package 3 is a two-layer insulation film 3A adhered to each other, and the sensor element 1 and part of the lead wire 2 are pinched between the two-layer insulation film 3A. A temperature sensor which makes the package 3 a two-layer laminated insulation film 3A is built in a pack battery in a state adhered to the surface of the battery.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a temperature sensor and a battery pack incorporating the temperature sensor.

[0002]

2. Description of the Related Art In a conventional temperature sensor, as shown in FIG. 1, a lead wire is connected to a sensor element 1, and the sensor element 1 and the tip of the lead wire 2 are covered with a package 3 such as an epoxy resin. There is. As the sensor element 1, an element whose resistance changes with temperature is used. The temperature sensor having this structure is manufactured by connecting the lead wire 2 to the sensor element 1 by a method such as soldering, and applying a paste-like epoxy resin to the tip ends of the sensor element 1 and the lead wire 2 and the surface thereof. To be done. When the tips of the lead wires 2 approach each other, a protective tube 4 is inserted into the lead wires 2 and epoxy resin is applied to the lead wires 2 in order to prevent a short circuit.

Further, the battery pack has a built-in temperature sensor 5 for detecting the battery temperature and controlling the charging state. This is because if the battery is rapidly charged while the battery temperature rises, the battery performance will decrease. The temperature sensor 5 is closely attached to the surface of the battery with silicon resin or the like in order to detect the battery temperature accurately. FIG. 2 shows a battery pack containing four prismatic batteries 6 and a temperature sensor 5. In the battery pack of this figure, the tip of the temperature sensor 5 is sandwiched between the prismatic batteries 6 so that the temperature sensor 5 can detect the battery temperature more accurately. When the tip of the temperature sensor 5 is brought into contact with the surface of the battery pack, it becomes difficult for the temperature sensor 5 to detect the battery temperature more accurately. Temperature sensor 5
This is because one side of is on the surface of the battery pack and is cooled. Both sides of the temperature sensor 5 sandwiched between the batteries are in contact with the surface of the battery, and the battery temperature can be detected more accurately.

[0004]

As shown in FIG. 1, a protective tube 4 is inserted into a lead wire 2 to form a sensor element 1
The temperature sensor 5 covered with the tip end of the lead wire 2 and the epoxy resin package 3 has a drawback that the portion of the sensor element 1 for detecting the temperature becomes thick. This is because the package 3 made of epoxy resin becomes thicker and the thicker lead wire 2 is covered with the epoxy resin by inserting the protective tube 4. The temperature sensor 5 without the protective tube 4
The problem that the protective tube 4 thickens the sensor part can be solved. However, the temperature sensor 5 without the protective tube 4 has a drawback that the lead wire 2 is easily short-circuited. Also,
Even if the protective tube is omitted, the sensor cannot be made so thin. This is because the epoxy resin that is the package of the sensor element is considerably thick.

By thinning the epoxy resin which is the package, the sensor portion can be thinned. However, when the epoxy resin of the package is made thin, the reliability is significantly reduced. This is because the package cannot protect the sensor element sufficiently. Further, the temperature sensor using an epoxy resin as a package has a defect that when the lead wire is pulled, the epoxy resin is easily cracked. In order to prevent this drawback, it is necessary to make the epoxy resin thicker. As described above, the conventional temperature sensor has a drawback that it is difficult to make the sensor portion thin.

When the thick temperature sensor is sandwiched between the batteries as shown in FIG. 2, the gap (t) between the batteries is widened and the outer shape of the package 3 is enlarged as shown in the sectional view of FIG. Further, in the temperature sensor 5 in which the lead wire 2 is covered with the protective tube 4, the lead wire 2 also becomes thicker, so that there is a drawback that the battery pack becomes substantially thicker. This is because the lead wire 2 projects on the surface of the battery pack.

Further, the temperature sensor which uses the protective tube to prevent the short circuit of the lead wire requires the insertion of the protective tube at the time of manufacturing. The thin lead wire 2 cannot be easily inserted into the thin protective tube 4. Therefore, there is a drawback in that it takes time and effort to insert the protective tube into the lead wire, resulting in high manufacturing cost.

The present invention was developed for the purpose of solving these drawbacks of the prior art, and an important object of the present invention is to enable mass production at low cost and to reduce the thickness of lead wires to make them short-circuited. The purpose is to provide a temperature sensor that can be effectively prevented.

Another important object of the present invention is to provide a battery pack which can detect the battery temperature accurately and can be designed compact with a small outer shape.

[0010]

The temperature sensor and the battery pack of the present invention have the following constitution in order to achieve the above-mentioned object. The temperature sensor 5 includes a sensor element 1 that detects a temperature, a lead wire 2 connected to the sensor element 1, and a package 3 that covers a part of the lead wire 2 and the sensor element 1.

The package 3 is a two-layer insulating film 3A that is in close contact with each other. The two-layer insulating film 3A sandwiches and covers a part of the sensor element 1 and the lead wire 2.

Further, the battery pack of the present invention comprises a secondary battery and a temperature sensor 5 for detecting the temperature of the secondary battery. The temperature sensor 5 has a sensor element 1 that detects a temperature, a lead wire 2 connected to the sensor element 1, and a package 3 that covers a part of the lead wire 2 and the sensor element 1.

Further, in the battery pack of the present invention, the package 3 of the temperature sensor 5 uses the two layers of the insulating film 3A which are in close contact with each other. The two-layer insulating film 3A sandwiches and covers a part of the sensor element 1 and the lead wire 2.

[0014]

In the temperature sensor of the present invention, the two closely attached insulating films 3A are used for the package 3. The temperature sensor 5 having this structure can be manufactured by sandwiching the sensor element 1 to which the lead wire 2 is connected, between two insulating films 3A that are laminated and in close contact with each other. The temperature sensor 5 manufactured in this manner can cover the lead wire 2 by sandwiching it with the insulating film 3A. For this reason, it is not necessary to insert a protective tube for insulation treatment unlike the conventional temperature sensor. For this reason,
The temperature sensor of the present invention can be insulated without short-circuiting without inserting the protective tube. The fact that no protective tube is used and the fact that two insulating films can be bonded together makes it possible to manufacture at low cost.

Furthermore, the temperature sensor of the present invention manufactured by sandwiching the sensor element between two insulating films can be made thin. The thin sheet-shaped temperature sensor is in contact with the surface of the member for detecting the temperature over a wide area, and heat is efficiently conducted. Therefore, the temperature can be measured accurately. The package 3, which is the insulating film 3A, can be thinned as a whole to stably protect the sensor element 1. This is because the sensor element 1 is covered with the insulating film 3A formed to have a uniform thickness. In the conventional temperature sensor in which the sensor element is covered with epoxy resin, it is difficult to make the package thin. This is because it is difficult to coat the surface of the sensor element with an epoxy resin having a uniform film pressure. In particular, the epoxy resin applied to the surface of the sensor element as a package becomes extremely thin at the periphery of the sensor element. Since the peripheral edge is coated with a sufficient thickness, the entire thickness becomes thick. On the other hand, in the temperature sensor of the present invention, since the sensor element is sandwiched and covered with an insulating film having a uniform film pressure, the sensor element does not become thin at the periphery of the sensor element. Can be protected.

Further, the battery pack of the present invention incorporates a thin sheet-shaped temperature sensor 5 in which the sensor element 1 is sandwiched by two insulating films 3A. The thin temperature sensor 5 can be conveniently used by being sandwiched between batteries as shown in FIGS. The thin temperature sensor 5 sandwiched between the batteries prevents the use of voids inside the battery pack due to the close spacing of the batteries. Therefore, the outer shape of the battery pack can be made small and compact. Furthermore, the thin sheet-shaped temperature sensor 5 contacts the surface of the battery over a wide area, and in particular, as shown in the figure, the temperature sensor 5 sandwiched between the batteries has both surfaces in close contact with the surface of the battery. Therefore, heat is efficiently conducted from the battery to the temperature sensor 5, and the battery temperature can be accurately detected without time delay. Furthermore, in the battery pack of the present invention, the lead wire portion of the temperature sensor can be made thin, so that as shown in FIG.
It has the feature that the thickness (W) can be reduced. This is because the lead wire does not protrude above the surface of the battery pack.

[0017]

Embodiments of the present invention will be described below with reference to the drawings. However, the embodiments described below exemplify the temperature sensor and the battery pack for embodying the technical idea of the present invention, and the present invention does not specify the temperature sensor and the battery pack as below.

Further, in this specification, for easy understanding of the claims, the numbers corresponding to the members shown in the embodiments are referred to as "claims column", "action column", and "action column". It is added to the members shown in the section of "Means for Solving the Problems". However, the members shown in the claims are
It is by no means specific to the members of the examples.

A temperature sensor 5 shown in FIG. 7 includes a sensor element 1 for detecting temperature, two lead wires 2 connected to electrodes of the sensor element 1, a part of the lead wire 2 and the sensor element 1. And a package 3 that covers and.

As the sensor element 1, an element whose electric characteristics change with temperature, for example, a thermistor element whose resistance decreases with increasing temperature can be used. The thermistor is an excellent sensor element 1 which has sufficient strength and whose resistance changes significantly with temperature. The sensor element 1 is formed in a thin plate shape in order to make the entire temperature sensor thin.

The sensor element 1 has lead wires 2 on both sides.
Are connected by soldering. In order to widen the distance between the lead wires 2, the lead wires 2 are bent outward at their tips and arranged in parallel.

The package 3 covering the sensor element 1 and the lead wire 2 is a two-layer insulating film 3A which is in close contact with each other. A part of the sensor element 1 and the lead wire 2 is sandwiched and covered between the two layers of the insulating film 3A. As the insulating film 3A, a flexible synthetic resin film having sufficient strength, for example, a synthetic resin film of polyester resin, polyethylene, polypropylene, nylon, fluororesin, styrene resin, vinyl chloride or the like is used. The thickness of the insulating film 3A is adjusted to an optimum value depending on the type of synthetic resin film used, but preferably a thickness of about 100 μm can be used. However, the insulating film 3A may have a thickness of 50 to 200 μm, for example.

In the temperature sensor 5 shown in FIG. 7, the lead wire 2 is soldered to the sensor element 1 as shown in FIG. 8, and two insulating films 3A are adhered so as to sandwich the lead wire 2 as follows. Manufactured. In order to laminate the insulating film 3A in a close contact state, an adhesive is applied to the adhesive surface of the insulating film 3A. The film thickness of the adhesive is, for example, about 10 to 100 μm, preferably about 30.
˜70 μm. The adhesive is applied to both surfaces of the two insulating films 3A to be laminated on the bonding surface. However, the insulating film 3A can be adhered by applying it on one surface. Epoxy resin is the most suitable adhesive, but polyurethane, unsaturated polyester resin, or any other adhesive that can bond the insulating film can be used.

When the adhesive is in an uncured state, the sensor element 1 and the lead wire 2 are sandwiched between the insulating films 3A, and the entire surface of the insulating film 3A is pressed with a uniform pressure to cure the adhesive. . The insulating films 3A adhered by applying an adhesive to both surfaces of the insulating film 3A are firmly adhered to each other via the adhesive, and also adhered to the surfaces of the sensor element 1 and the lead wire 2. Further, as shown in FIGS. 7 and 8, when the sensor element 1 is formed into a plate shape and the lead wire 2 having a square cross section is used, the insulating film 3 is formed.
It has a feature that A can be adhered to the surface of the sensor element 1 and the surface of the lead wire 2 in a wide area. The insulating film 3A, which is adhered by applying an adhesive to one surface of the adhesive surface, is brought into close contact with the insulating film 3A and one surface of the lead wire 2.

As described above, the temperature sensor 5 for adhering the insulating film 3A via the adhesive is the insulating film 3A.
There is a feature that can firmly adhere. However, in the temperature sensor of the present invention, it is not always necessary to use an adhesive to bond the insulating film. For example, an insulating film 3A having a low melting point synthetic resin film laminated on the adhesive surface can be used for adhesion. The insulating film 3A has a low melting point synthetic resin film as the adhesive surface and a high melting point synthetic resin film as the outer surface. In this insulating film, the sensor element and the lead wire are sandwiched and heated from both sides to melt and adhere the low melting point synthetic resin film on the adhesive surface. The low-melting point synthetic resin film is heated and melted to bond the adhesive surface of the insulating film, and further adhere to the sensor element and the lead wire.

Further, a hot melt adhesive can also be used for adhering the insulating film. In order to bring the insulating film 3A into close contact with the hot melt adhesive, the hot melt adhesive is applied to the adhesive surface of the insulating film 3A, and the sensor element 1 and the lead wire 2 are sandwiched between the insulating film 3A. The entire surface of the insulating film 3A is heated and pressed.

An insulating film which is adhered by using a paste-like adhesive, a hot-melt adhesive, or a low melting point synthetic resin film is required to be uniformly pressed and adhered to the entire surface. There is. In order to realize this, the entire surface of the insulating film is pressed through the rubber elastic plate.

FIG. 8 shows a state in which one temperature sensor 5 is manufactured. As shown in FIG. 9, the mass-produced temperature sensor 5 has a large number of temperature sensors 5 to which lead wires are connected side by side and is sandwiched and bonded by a long insulating film 3A. Can be cut and manufactured efficiently in large quantities. In addition, manufactured temperature sensor 5
As shown in FIG. 10, the lead wires 2 can be cut into slits.

Further, in order to partially reinforce the insulating film 3A that covers the sensor element 1, as shown by the chain line in FIG. 8, a reinforcing film 7 is sandwiched between the portions that cover the sensor element 1. The reinforcing film 7 is the sensor element 1
And the insulating film 3A. Reinforcement film 7
A tough synthetic resin film, for example, a film made of epoxy resin can be used as the material. Furthermore, the sensor element can be effectively protected from moisture by using a synthetic resin film having no air permeability and water permeability for the reinforcing film 7.

FIGS. 4 and 5 show a battery pack containing the temperature sensor 5 manufactured by the above method. In the battery pack shown in these figures, four prismatic slim batteries 6 are arranged in parallel and fixed with tape, and the surface thereof is covered with the outer skin of the heat shrinkable tube 8. The tip of the temperature sensor 5 is bent in an L shape and sandwiched between the batteries. The temperature sensor 5 has a tip end as shown in FIG. 6 so that a portion containing the sensor element 1 therein can be sandwiched between the batteries 6.
It is bent into an L shape. A portion of the tip of the temperature sensor 5 in which the sensor element 1 is incorporated is brought into surface contact with the surface of the battery over a wide area on both sides. Therefore, the heat of the battery is efficiently conducted to the temperature sensor 5. Therefore, it is not always necessary to apply a silicone resin or the like between the temperature sensor 5 and the battery, but by applying the silicone resin during this time, the heat of the battery can be more efficiently conducted to the temperature sensor 5. There is.

[0031]

The temperature sensor and the battery pack of the present invention have the following excellent features. Mass production of temperature sensors can be done at low cost. Unlike the conventional temperature sensor, it is not necessary to coat the surface of the sensor element with epoxy resin with an accurate film thickness, and it is not necessary to insert a protective tube into the lead wire. This is because the insulating films can be closely attached to each other in a state where both surfaces of the element are sandwiched between the two insulating films.

Although the protective tube is not used, there is a feature that the lead wire of the temperature sensor can be effectively prevented from being short-circuited. This is because the temperature sensor of the present invention insulates a part of the lead wire by sandwiching it with an insulating film. In particular, since the insulating film, which is the package of the temperature sensor of the present invention, covers the sensor element and a part of the lead wire by sandwiching it, in addition to effectively preventing the short circuit of the lead wire, Unlike the conventional epoxy resin package, cracks and the like do not occur when it is pulled. Therefore, the package of the temperature sensor can have sufficient strength.

The temperature sensor can be made thin. that is,
This is because the surfaces of the sensor element and the lead wire are covered with an insulating film having a uniform film thickness. The thin temperature sensor is in surface contact with the surface of the member for detecting temperature over a wide area. Further, the distance between the sensor element and the member for detecting the temperature can be narrowed. Therefore, the temperature sensor has a feature that it can detect temperature accurately and quickly.

The battery pack can detect the battery temperature accurately and can have a small outer shape. This is because it incorporates a thin sheet temperature sensor. The thin temperature sensor is sandwiched between the batteries as shown in FIG. 6 or closely attached to the surface of the battery (not shown) to accurately detect the battery temperature. This is because the thermal resistance between the battery and the sensor element can be reduced, and the thermal conduction can be made efficient. Therefore, although the overall shape is compact, an ideal battery pack that can accurately detect the battery temperature can be realized.

[Brief description of drawings]

FIG. 1 is a perspective view showing an example of a conventional temperature sensor.

FIG. 2 is a plan view of a conventional battery pack incorporating the temperature sensor shown in FIG.

3 is a cross-sectional view of a portion of the battery pack shown in FIG. 2 having a temperature sensor.

FIG. 4 is a plan view showing a battery pack according to an embodiment of the present invention.

5 is a front view of the battery pack shown in FIG.

FIG. 6 is a cross-sectional view showing a portion with a built-in temperature sensor of the battery pack shown in FIG.

FIG. 7 is a perspective view showing a temperature sensor according to an embodiment of the present invention.

8 is a perspective view showing a manufacturing state of the temperature sensor shown in FIG.

FIG. 9 is a perspective view showing another manufacturing state of the temperature sensor according to the embodiment of the invention.

FIG. 10 is a perspective view showing a temperature sensor according to another embodiment of the present invention.

[Explanation of symbols]

 1 ... Sensor element 2 ... Lead wire 3 ... Package 3A ... Insulating film 4 ... Protection tube 5 ... Temperature sensor 6 ... Battery 7 ... Reinforcement film 8 ... Heat shrink tube

Claims (2)

[Claims] 1. A sensor element (1) for detecting temperature, a lead wire (2) connected to the sensor element (1), a part of the lead wire (2) and the sensor element (1). In a temperature sensor (5) having a covering package (3), a two-layer insulating film in which the packages (3) are adhered to each other
(3A), sensor element between two layers of insulating film (3A)
A temperature sensor characterized in that (1) and a part of a lead wire (2) are sandwiched and covered. 2. A sensor element (1) comprising a secondary battery and a temperature sensor (5) for detecting the temperature of the secondary battery, the temperature sensor (5) detecting the temperature, and the sensor element (1). ) Is connected to the lead wire (2) and a package (3) covering a part of the lead wire (2) and the sensor element (1), the package of the temperature sensor (5) ( 3) is a two-layer insulating film (3A) adhered to each other, and the sensor element (1) and a part of the lead wire (2) are sandwiched between the two-layer insulating film (3A) to provide insulation. A battery pack which is covered with a film (3A).