KR102541990B1 - Battery Temperature Sensor - Google Patents

Abstract

A battery temperature sensor according to an embodiment of the present invention includes a sensor unit formed of a sensing element for measuring temperature and a pair of lead parts extending from the sensing element and electrically connected to a lead wire; and a body portion that is folded along a falling line to form a housing in which the sensor unit is installed, wherein the body portion has a first seating portion on one side of which the sensor unit is seated, and the sensing element is exposed at the seating position. Correspondingly, it is characterized in that a sensing hole is formed, thereby facilitating assembly man-hours and improving durability and versatility of the product.

Description

Battery Temperature Sensor {Battery Temperature Sensor}

The present invention relates to a battery temperature sensor, and more particularly, to a battery temperature sensor having a structure suitable for measuring the temperature of a vehicle battery.

In general, since an electric vehicle or a hybrid vehicle requires a high-output and large-capacity battery, a battery cell module in which a plurality of battery cells are stacked and electrically connected in series or parallel is used. At this time, since overvoltage, overcurrent, and overheating may occur in some battery cells in the battery cell module composed of a plurality of battery cells, the temperature at which the temperature of the battery cells is measured in order to prevent the safety of occupants and the risk of secondary accidents have a sensor

Accordingly, a temperature sensor used to measure the temperature of a battery cell needs to be formed in a structure to be more easily mounted on a battery cell module. Therefore, the conventionally used film-type temperature sensor is most suitable, but the film-type temperature sensor has a problem in that it is very vulnerable to external temperature and external force.

Therefore, in order to solve the above problems, insert injection or a method of inserting a temperature sensor into a housing and curing through a filler has been developed, but the production process is complicated and the cost is increased, resulting in a problem of lowering the productivity of the product.

Embodiments of the present invention have been made to solve the above problems, and an object of the present invention is to provide a battery temperature sensor with improved durability and versatility while simplifying the production process.

A battery temperature sensor according to the present invention includes a sensor unit formed of a sensing element for measuring temperature and a pair of lead parts extending from the sensing element and electrically connected to a lead wire; and a body portion that is folded along a falling line to form a housing in which the sensor unit is installed, wherein the body portion has a first seating portion on one side of which the sensor unit is seated, and the sensing element is exposed at the seating position. Correspondingly, it is characterized in that a sensing hole is formed.

The main body portion may be formed symmetrically about the falling line, and coupling portions complementary to each other and fixed when forming the housing may be formed.

When the housing is formed, the main body portion may further include a second seating portion formed to face the first seating portion and accommodating one side of the sensor portion, and a tensioner that presses the sensing element in correspondence with the position of the sensing hole. there is.

Close contact ends may be formed along the circumference of the sensor unit to be in close contact with each other when forming the housing.

When forming the housing, the main body portion is preferably formed with both side surfaces concave so as to be fixed between the battery cells through a cylinder.

As described above, according to the problem solving means of the present invention, various effects including the following can be expected. However, the present invention is not established when all of the following effects are exhibited.

In the battery temperature sensor according to the present invention, the structure in which the sensor unit is assembled is formed inside the body unit to be fixed without a separate process, and at the same time, the body unit is folded along a folding line to form a housing, thereby significantly simplifying the production process and improving product productivity.

In addition, when forming the housing, the assembly of the battery temperature sensor is completed without additional processes such as ultrasonic welding by providing coupling parts that are complementary to each other and fixed, thereby minimizing damage to the sensor unit that may occur during the production process and improving workability and productivity Maximize the improvement effect.

In addition, a sensing hole is formed on the first side of the main body to correspond to the position of the sensing element, and the sensing element is brought into close contact with the sensing hole on the second side to improve the reaction speed of the sensing element to temperature, thereby improving the reliability of the product.

In addition, when forming the housing, both sides of the main body are concave to be fixed between the battery cells through a cylinder, thereby realizing miniaturization of the battery cell module and improving workability.

1 is a perspective view of a battery temperature sensor according to an embodiment of the present invention;
Figure 2 is a perspective view in another direction of Figure 1;
Figure 3 is a perspective view of a dismantled state of the main body of Figure 1;
Figure 4 is a cross-sectional view in the IV-IV direction of Figure 1;
5 is a cross-sectional view in the direction V-V of FIG. 1;
6 is a cross-sectional view in the VI-VI direction of FIG. 1;
Figure 7 is a view showing how the main body of Figure 3 forms a housing.

With reference to the following drawings, specific embodiments of the present invention will be described in detail. However, detailed descriptions of well-known functions or configurations will be omitted in order not to obscure the gist of the present invention.

For convenience of description of the invention, the direction in which the wire extends is defined as the extension direction, and the direction in which the main body is folded is defined as the assembly direction.

1 is a perspective view of a battery temperature sensor according to an embodiment of the present invention, FIG. 2 is a perspective view in another direction of FIG. 1 , and FIG. 3 is a perspective view of a disassembled state of the main body of FIG. 1 . 4 is a cross-sectional view in the direction IV-IV of FIG. 1, FIG. 5 is a cross-sectional view in the direction V-V of FIG. 1, and FIG. 6 is a cross-sectional view in the direction VI-VI of FIG. FIG. 7 is a diagram illustrating a method of forming a housing by the main body of FIG. 3 .

1 to 7, the battery temperature sensor 10 according to an embodiment of the present invention is electrically connected to a sensing element 110 for measuring temperature and a cable 300 extending from the sensing element 110. It includes a sensor unit 100 formed of a pair of lead units 120 and a body unit 200 that is folded along a folding line 210 to form a housing in which the sensor unit 100 is installed, The main body part 200 has a first seating part 221 on one side where the sensor part 100 is seated, and a sensing hole 222 is formed corresponding to the seating position so that the sensing element 110 is exposed. characterized by being

The battery temperature sensor 10 measures the temperature of the battery cell and transmits it as electrical information to an external device through the cable 300 to provide improved safety and reliability.

The sensor unit 100 includes a sensing element 110 for measuring temperature, a pair of lead parts 120 extending from the sensing element 110 and electrically connected to a cable 300, and a sensor element 110. It is formed of a film 130 formed on the outside, converts the temperature of the battery cell into electrical information, and transmits it to an external device.

The sensing element 110 includes various elements such as a thermistor element using an NTC characteristic in which the resistance value decreases exponentially as the temperature increases, a thermistor element using a PTC characteristic in which the resistance value increases exponentially as the temperature increases, and a thermocouple. can be formed as

In addition, for convenience of description, the film-type temperature sensor in which the film 130 is formed on the outside of the sensing element 110 is described as a standard, but in the case where epoxy or glass coating is formed on the outside of the sensing element 110, a separate The film 130 is not required, and even in the case of a thermocouple, the temperature element is exposed and formed as it is to measure the temperature through the sensing hole 222 .

The lead part 120 extends from the sensing element 110 but is branched from one side to form a pair, and is electrically connected to the covering part 310 of the pair of cables 300 to transmit temperature information of the battery cell to the outside. Form a circuit so that it can be transmitted to the device.

The film 130 is formed outside a part of the sensing element 110 and the lead part 120 to protect the sensing element 110 from the outside. At this time, it is preferable that the film 130 is formed of silicon having relatively fast heat conduction so that the responsiveness of the sensing element 110 is not deteriorated.

In addition, the film 130 is formed to have the same shape as the first seating portion 221 on which the sensor unit 100 is seated, guides the seating position of the sensor unit 100 and primarily fixes the film 130 to further improve workability. and the part where the sensor unit 100 and the lead unit 120 are not formed can be pressed by the contact protrusion 238, thereby minimizing the separation defect that may occur in the sensing element 110 during the production process. At the same time, the sensor By improving the fixing force of the unit 100, higher product reliability is provided.

The body part 200 is integrally formed, but is folded along the folding line 210 to form a housing in which the sensor part 100 is installed therein, thereby protecting the sensor part 100 from the outside and at the same time more easily installing it in the battery cell. It is possible to be, and the coupling part 240 is formed to be complementary to each other, so that a separate fusion process can be excluded, thereby simplifying the production process and reducing production costs.

At this time, the main body 200 is opened to one side to form a housing along the folding line 210, and is formed as it is by injection molding so that the sensor unit 100 is moved to one side of the main body 200. By inserting it, the time required for the production process of the battery temperature sensor 10 can be reduced.

In addition, the body portion 200 may be formed of a material capable of injection molding such as engineering plastic, and may be formed of the same material as the tensioner 232 and integrally formed, but considering the elasticity and strength, the tensioner 232 It is the same that may be formed of stainless steel, a press form having elasticity, or the like, and may be integrally formed with the body portion 200 through insert injection.

However, hereinafter, description will be made based on one embodiment of the present invention in which the body portion 200 is folded along the folding line 210 to form a housing. to be omitted.

Specifically, the body portion 200 is formed of a first side surface 220 and a second side surface 230 folded around a folding line 210 and disposed opposite to each other, and the first side surface 220 and the second side surface 230 ) extends from the folding surfaces 225 and 235 connected to the folding line 210, the installation surfaces 226 and 236 extending from the folding surfaces 225 and 235 and concave inward, and the installation surfaces 226 and 236, respectively. The ends are formed of fastening surfaces 227 and 237 that are fastened to each other so that the housing can be formed without a separate additional process.

At this time, the first and second side surfaces 220 and 230 are divided based on the folding line 210 for convenience of description, and are connected through the folding line 210 to be integrally formed.

Therefore, each of the folding surfaces 225 and 235 is connected through a folding line 210, and the outer surfaces of the installation surfaces 226 and 236 are formed concavely so that when an external force is generated during housing formation, the sensor unit disposed inside distributes stress ( 100) while minimizing the effect of external force, and at the same time maximizing the effect of improving workability by easily disposing between cylindrical battery cells.

In addition, the folding surfaces 225 and 235 are formed with a gap formed inwardly in a folded state along the falling line 210 to enable elastic deformation. Accordingly, when the battery temperature sensor 10 is mounted between the batteries, the folding surfaces 225 and 235 are pressurized from the outside to narrow the gap and are inserted. This makes it more stable to mount.

The fastening surfaces 227 and 237 are formed by being bent from one side to the opposite direction so that each end can be fastened. At this time, in order to facilitate the fastening, it is preferable that the fastening surfaces 227 and 237 are formed by bending in opposite directions from one side.

Since the common shape of the first and second side surfaces 220 and 230 has been described in detail above, the structure in which the sensor unit 100 formed inside the first and second side surfaces 220 and 230 is fixed will be described in detail. let it do At this time, the structures formed on the first side surface 220 and the second side surface 230 are formed differently in order to fix the sensor unit 100 and measure the temperature. Therefore, the first and second sides 220 and 230 are respectively described, but the same structure is described on the first side 220 and omitted on the second side 230 in order to avoid duplication of description.

A first seating portion 221 on which the sensor unit 100 is installed is formed on the inside of the installation surface 226 of the first side surface 220, corresponding to the location where the sensing element 110 is disposed. A sensing hole 222 penetrating through 221 is formed to maintain the reaction rate of the sensing element 110 to a temperature of the battery cell at a predetermined level or more even when installed inside the housing.

At this time, a seating groove 223 in which each pair of cables 300 are seated is formed on one side of the first seating portion 221, and the covering portion 310 of the cable 300 and the lead portion of the sensor unit 100 are formed. 120 can be connected more stably, and at the same time, the defect rate of the battery temperature sensor 10 is reduced by preventing the covering portions 310 formed on each of the pair of cables 300 from coming into contact with each other.

In addition, a close contact end 224 is formed on the first side surface 220 to surround the outside of the first seating portion 221 and the seating groove 223, and the sensor unit 100 is installed on the first seating portion 221. ) is primarily fixed, and at the same time, it comes into contact with the contact end 224 formed on the second seating portion 231 to prevent foreign substances from entering.

A second seating portion 231 is formed on the inside of the installation surface 236 of the second side surface 230 to correspond to the first seating portion 221, and to correspond to the position of the sensing element 110, the first side surface 220 ), the sensing element 110 is brought into close contact with one side of the sensing hole 222 by the tensioner 232 which is convexly formed to provide elastic force, thereby improving the reaction speed.

Specifically, the tensioner 232 is in contact with one side of the sensor unit 100 by folding of the body unit 200, elastically deforms as the body unit 200 is fastened, and adheres to one side of the sensor unit 100, The sensing element 110 is brought into close contact with one side of the sensing hole 222 . Accordingly, the sensing element 110 adheres closely to the cylindrical battery cell, which is the temperature sensing target, to improve the reaction speed, and at the same time, the tensioner 232 partially absorbs the load transmitted to the sensor unit 100 by an external force generated from the outside, thereby improving durability. It improves.

In addition, the tensioner 232 may be formed on the second side surface 230 in the assembly direction as well as in the extension direction, so that one side of the body portion 200 is not opened and is injection molded as it is in the housing shape. The sensor unit 100 can be inserted in an extension direction from one end of the housing.

At this time, the tensioner 232 is connected to the second side surface 230 in the extension direction to improve workability by preventing the incision formed by the tensioner 232 from being interfered with when the sensor unit 100 is inserted.

The second seating portion 231 protrudes from one side and forms close contact protrusions 238 (238) that press the sensor unit 100 to improve the fixing power of the sensor unit 100. At this time, the close contact protrusion 238 is used for sensing The element 110 and the lead part 120 are located in a position where they are not disposed and press one side of the film 130 to prevent damage that may occur to the sensor part 100 during the assembly process of the main body part 200. It is preferable to prevent, and when the sensor unit 100 without the film 130 is formed between a pair of lead units 120, preventing the lead units 120 from contacting each other to improve reliability of the product it is desirable

At this time, a seating groove 233 in which a pair of cables 300 are seated is also formed on the second side surface 230 so that the cable 300 comes into contact with the seating groove 233 formed on the first side surface 220 when the housing is formed. to improve the stability of the product, wraps around the outside of the seating groove 233 formed on the second seating portion 231 and the second side surface 230, and closes the contact end formed on the first side surface 220 when forming the housing ( 224) and a close contact end 234 is formed.

In addition, a contact protrusion 238 is formed on the inside of the second side surface 230 to protrude and adhere the film 130 to the seating groove 223 of the first side surface 220, so that the sensor unit 100 is It prevents arbitrary movement and at the same time improves the durability of the product by improving the fixing force.

At this time, the contact protrusion 238 is disposed between the lead part 120 when the sensor part 100 of the present invention is not a film type, but is coated with epoxy or glass on the outside of the sensing element 110 or formed as a thermocouple. Damage such as a short circuit that may occur between the ribs 120 is prevented.

The coupling part 240 is formed on the fastening surfaces 227 and 237 of the first and second side surfaces 220 and 230, respectively, and is formed of an outer hanger 241 and an inner hanger 242 that are complementary to each other to prevent the housing from being arbitrarily disconnected. prevent. Specifically, the coupling part 240 of one embodiment is formed at the end of the fastening surface 237 of the inner hanger 242 and the second side 230 formed at the end of the fastening surface 227 of the first side 220 As the outer hanger 241 forms a housing by folding the body portion 200, it is disposed opposite to each other, and is engaged with each other and fastened.

Therefore, the battery temperature sensor 10 of the present invention can be assembled in a one-touch method without a separate fixing member or an additional process of fastening the housing such as a welding process, thereby simplifying the production process and reducing initial investment costs, thereby improving product productivity. provides

Here, the coupling parts 240 can be formed in various shapes that are fastened to each other to generate a fixing force, and the fastening structure can be directly formed on the body part 200 to significantly reduce the time and cost required for production. have

In the cable 300, an inner conductor is exposed at one end to form a covering portion 310 electrically connected to the lead portion 120, and formed as a pair to form a circuit together with the lead portion 120 to form a sensing element. The temperature information specified in (110) is transmitted to the external device.

At this time, each coating part 310 is seated in the seating grooves 223 and 233, and is spaced apart from each other by the close contact ends 224 and 234 to fundamentally prevent a short circuit phenomenon caused by contact with each other, and the first and second side surfaces 220 and 230 ) Is formed in the seating grooves 223 and 233 and the contact ends 224 and 234 to be blocked from the outside and at the same time stably fixed to provide more improved product reliability.

In the above, preferred embodiments of the present invention have been described by way of example, but the scope of the present invention is not limited only to such specific embodiments, and appropriate changes within the scope described in the claims fall within the protection scope of the present invention. applicable

10 Battery temperature sensor
100 sensor part 110 sensing element 120 lead part
130 film
200 main body 210 folding line 220 first side
221 First seating part 222 Sensing hole 223,233 Seating groove
224,234 close end 230 second side
231 second seat 232 tensioner 238 contact protrusion
240 coupling part 241 outer hanger 242 inner hanger
300 cable 310 sheath

Claims (5)

A sensor unit formed of a sensing element for measuring temperature and a pair of lead parts extending from the sensing element and electrically connected to a lead wire; and
A main body portion forming a housing in which the sensor unit is installed by first and second side surfaces folded along a folding line and disposed opposite to each other,
Each of the first and second aspects
It is formed of a folding surface connected to the folding line, an installation surface extending from the folding surface and concave inward, and a fastening surface extending from the installation surface and fastening ends to each other,
One side of the sensor unit is seated on one of the installation surfaces, and a first seating portion having a sensing hole to expose the sensing element is formed, and the other side faces the first seating portion and the other side of the sensor unit is formed. A second seating portion to be seated is formed,
The folding surface is
A battery temperature sensor, characterized in that a gap is formed on the inside to enable elastic deformation in a folded state along the folding line.
delete According to claim 1
In the second seating part
A battery temperature sensor, characterized in that a tensioner for pressurizing the sensing element corresponding to the position of the sensing hole is further formed.
According to claim 3,
The first and second seating parts
The battery temperature sensor, characterized in that in a state in which the housing is formed by folding along the folding line, close contact ends are formed to be in close contact with each other.
According to claim 3,
The first and second aspects are
Battery temperature sensor, characterized in that both sides are formed concave to be fixed between cylindrical battery cells when forming the housing.

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