KR20210025245A - Cooling water heating device for battery with heat transfer structure for improving thermal fuse reaction rate - Google Patents

Abstract

A battery outer case heating device with a heat transfer structure for improving thermal fuse reaction rate, according to the present invention, comprises: a lower housing (100) having an inlet portion (110) into which cooling water is introduced and an outlet portion (120) through which the cooling water is discharged; a heating plate (200) coupled to cover and close an open upper side of the lower housing (100); a heating member (300) provided in an inner space formed by the coupling of the lower housing (100) and the heating plate (200); a thermal fuse (400) coupled on the heating plate (200); and an upper housing (500) coupled to an upper end of the lower housing (100). The heating plate (200) includes a main plate (210) having a structure covering the open upper side of the lower housing (100) and a fuse plate (220) on which the thermal fuse (400) is mounted in a state of being seated in a plate hole (212) formed in the main plate (210). The thickness of the fuse plate (220) is kept smaller than that of the main plate (210). In a state in which the thermal fuse (400) is placed in a fuse seating part (222) which is grooved downward on the center of the fuse plate (220), a fuse cover (410) is covered on the thermal fuse (400) to be combined.

Description

Cooling water heating device for battery with heat transfer structure for improving thermal fuse reaction rate

The present invention relates to a cooling water heating device for a battery, and more particularly, a heat transfer structure in which the thickness of the fuse plate on which the thermal fuse is seated is adjusted so that the reaction speed of the thermal fuse can be adjusted according to whether the flowing cooling water is in a normal state. It relates to a cooling water heating device for a battery having a.

Vehicles powered by engines using gasoline or diesel as an energy source are currently the most common types of vehicles, but these vehicle energy sources require a new energy source due to various causes such as environmental pollution as well as reduction of oil reserves. As it is increasingly emerging, electric vehicles, hybrid cars, and fuel cell vehicles are currently being commercialized or under development.

However, in electric vehicles, hybrid cars, and fuel cell vehicles, unlike vehicles that use engines using petroleum as an energy source, heating systems using coolant cannot or are difficult to apply. That is, in the case of a vehicle that uses an engine that uses oil as an energy source as a driving source, a lot of heat is generated from the engine, a coolant circulation system is provided to cool the engine, and the heat absorbed from the engine is heated indoors. To use it. However, since much heat such as that generated by the engine is not generated from the driving sources of electric vehicles, hybrid cars, and fuel cell vehicles, there is a limitation in using such a conventional heating method.

Accordingly, in electric vehicles, hybrid cars, and fuel cell vehicles, various studies have been conducted, such as adding a heat pump to the air conditioning system so that it can be used as a heat source, or having a separate heat source such as an electric heater. have.

Among them, electric heaters are widely used because they can more easily heat cooling water without significantly affecting the air conditioning system. Electric heaters include an air-heated heater that directly heats air blown into the interior of a vehicle, and a coolant-heated heater (or coolant heater) that heats the coolant.

In Korean Patent Laid-Open Patent (10-2019-0024388) that proposes a cooling water heating type heater, it is possible to prevent overheating of the heating element by improving the overheat detection responsiveness of the heating element, and the failure factor at the part where the thermal fuse is coupled is reduced. A cooling water heater with improved durability is disclosed.

On the other hand, looking at the process of coupling the thermal fuse on the cooling water heating type heater, the thermal fuse in a state in which a cover plate on which a thermal fuse is placed on a lower housing is fastened, and a controller that penetrates the thermal fuse is disposed at a distance above the cover plate. The upper end of the upper housing is coupled in a pressurized manner using a protrusion formed at the lower end of the upper housing.

Looking at the above structure, it can be seen that the temperature or heat of the heating element is transmitted to the thermal fuse through the cover plate, so that overheating can be detected.Under this structure, the thermal fuse is applied only when sufficient heat is applied to the cover plate. There is a problem that the cutoff temperature set in is reached.

That is, when the thermal fuse is blocked only after excessive heat transfer from the heating element to the cover plate, the cover plate is thermally deformed, and as a result, the overall structural deformation of the cooling water heating type heater can be made.

Republic of Korea Patent Application Publication No. 10-2019-0024388 "Cooling water heater" (2019.03.08.)

An object of the present invention is to solve the above problems, on a heating plate having a main plate having a structure covering the open upper side of the lower housing and a fuse plate installed in a plate hole formed through the main plate, the thickness of the fuse plate Is kept smaller than that of the main plate, and according to whether or not the coolant supplied to the lower housing flows normally, heat transfer to the thermal fuse mounted on the upper end of the fuse plate is facilitated, thereby improving the reaction speed of the thermal fuse. It characterized in that it provides a cooling water heating device for a battery.

A battery external heating device having a heat transfer structure for improving the reaction speed of a thermal fuse according to the present invention for achieving the above object includes an inlet part 110 into which coolant is introduced and an outlet part 120 through which coolant is discharged. Lower housing 100; A heating plate 200 coupled to cover and close the open upper side of the lower housing 100; A heating member 300 provided in an inner space formed by the combination of the lower housing 100 and the heating plate 200; A thermal fuse 400 coupled to the heating plate 200; And an upper housing 500 coupled to an upper end of the lower housing 100, wherein the heating plate 200 has a main plate 210 having a structure covering the open upper side of the lower housing 100, and It includes a fuse plate 220 in which the thermal fuse 400 is mounted while seated in a plate hole 212 formed in the main plate 210, and the thickness of the fuse plate 220 is the main plate ( 210) is maintained in a smaller state, and the thermal fuse 400 is placed in the fuse seating portion 222 grooved downwardly on the central portion of the fuse plate 220, and the fuse cover 410 is It is characterized in that the thermal fuse 400 is coupled in such a manner that it is overlaid.

The lower end of the fuse seating part 222 is set to have the same height as the lower end of the main plate 210 or lower than the lower end of the main plate 210.

The fuse cover 410 is a structure having a hollow shape having a structure in which the lower part is opened, and a cover body in the shape of a hollow box accommodating the thermal fuse 400 therein and a pressing protrusion protruding on the inner upper surface of the cover body Includes.

According to the present invention, all the objects of the present invention described above can be achieved.

The external heating device for a battery having a heat transfer structure for improving the reaction speed of a thermal fuse according to the present invention includes a main plate having a structure covering the open upper side of the lower housing and a fuse plate installed in a plate hole formed through the main plate. On the plate, the thickness of the fuse plate is kept smaller than that of the main plate, and heat transfer to the thermal fuse mounted on the upper end of the fuse plate is facilitated according to whether the coolant supplied to the lower housing flows normally.

That is, in the present invention, cooling is performed through smooth heat transfer through the fuse plate under steady state flow in which the coolant flow through the lower housing is smoothly performed, thereby enabling immediate temperature sensing of the cooling water through the thermal fuse, and Under abnormal flow in which the flow of cooling water through the cooling water is not smoothly performed, heat through the heating element is directly transferred to the fuse plate due to insufficient cooling water, thereby enabling immediate high-temperature detection of the thermal fuse.

In the present invention, heat transfer from the heating element to the thermal fuse is directly achieved through a fuse plate coupled on the central portion of the main plate coupled to the lower housing, and power cut off by the thermal fuse is efficiently prevented through the above process. Let's do it.

The present invention stably fixes the thermal fuse using a fuse cover and a heating plate before coupling the upper housing to the lower housing, thereby preemptively performing a quality inspection during the process of assembling the cooling water heating device for the battery. To be able to do it.

1 is a perspective view from one direction of an external heating apparatus for a battery having a heat transfer structure for improving a thermal fuse reaction speed according to an embodiment of the present invention.
2 shows an exploded state of the cooling water heating device for a battery of FIG. 1.
3 is a cross-sectional view taken along AA of the cooling water heating device for a battery of FIG. 1.
4 is a cross-sectional view taken along BB of the cooling water heating device for a battery of FIG. 1.
5 shows a configuration in which the thermal fuse is stably fixed using an outer plate and a fuse cover forming a heating plate.
6 and 7 show a heat transfer process applied to the thermal fuse according to the coolant flow state in the lower housing, and FIG. 6 shows a steady state process in which direct heat transfer from the coolant to the thermal fuse is smoothly performed, and FIG. 7 It shows an abnormal state process in which heat is transferred from the heating element to the fuse plate and the thermal fuse.

Hereinafter, the configuration and operation of an embodiment of the present invention will be described in detail with reference to the drawings.

1 to 3, a battery external heating apparatus having a heat transfer structure for improving a thermal fuse reaction speed according to the present invention is formed in a concave container shape with an open upper side, and an inlet portion 110 into which coolant flows into The lower housing 100 having the outlet portion 120 from which the coolant is discharged, the heating plate 200 coupled to cover the open upper side of the lower housing 100, the lower housing 100 and the heating plate 200 The heating member 300 provided in the inner space formed by the combination of ), the thermal fuse 400 coupled to the heating plate 200, the lower side is formed in a concave container shape, and the upper end of the lower housing 100 The upper housing 500 coupled to the heating plate 200 can be separated on the sealing member 600 and the lower housing 100 disposed on the coupling portion of the lower housing 100 and the upper housing 500 based on the heating plate 200. And a water temperature sensor (not shown) that is coupled to each other.

The heating member 300 is configured to supply power through a separate HV battery (not shown) having a variable range of 200 to 460V, and is connected from the HV battery to the heating member 300 by a voltage connector, which is an HV cable, The positive electrode cable extending from the voltage connector is connected to the positive electrode of the heating member 300 through a thermal fuse 400. Meanwhile, the negative cable extending from the voltage connector is connected to the negative electrode of the heating member 300. On the positive cable extending from the voltage connector, an ON/OFF switch for opening and closing a circuit by a control unit and a thermal fuse 400 operating according to its own temperature are connected.

The thermal fuse 400 has a structure connected to the anode cable and the anode of the heating member 300 through cold pins formed at both ends thereof, and facilitates replacement of the thermal fuse 400. When the thermal fuse 400 inserted in the power circuit is opened using a cold pin, power to the heating member 300 is cut off.

The lower housing 100 is formed in the shape of a container that is concave downward and can be arranged so that the open side faces upward, and an inlet 110 through which cooling water is introduced is formed on one side in the length direction, and the cooling water is discharged on the other side in the length direction. The outlet portion 120 may be formed.

The lower housing 100 may be formed of, for example, a metal material, and may be formed of various materials or shapes.

The heating plate 200 may be coupled to the lower housing 100 in a manner that covers and closes the open upper side of the lower housing 100, and the open upper opening of the lower housing 100 is sealed by the heating plate 200. Can be. It becomes a cooling water flow path through which cooling water flows in the first space, which is an internal space formed by the combination of the lower housing 100 and the heating plate 200, and when cooling water flows into the inlet pipe, the lower housing 100 ) May be configured to pass through the first space and be discharged through the outlet pipe, which is the outlet unit 120.

The heating plate 200 has a structure in contact with the heating member 300 at the lower side and the thermal fuse 400 at the upper side. Through the above structure, it functions to transfer heat from the heating member 300 to the thermal fuse 400.

4 and 5, the heating plate 200 is seated in the main plate 210 having a structure covering the open upper side of the lower housing 100 and the plate hole 212 formed in the main plate 210. It includes a fuse plate 220 on which the thermal fuse 400 is mounted in the state.

The fuse plate 220 has a fuse seating portion 222 that is an area protruding downward, for example, pressing on the central portion of a panel having a rectangular rectangular shape in which a round is formed on an outer corner portion as a whole. Thus, a fuse seating portion having a predetermined height difference from the peripheral portion can be formed.

The thermal fuse 400 is disposed in the fuse seating portion 222 formed concave from the upper surface of the fuse plate 220 to the lower side, so that the heat from the heating member 300 can be directly transmitted through only the fuse plate 220. have.

As an example, the fuse seating portion 222 may have the same height as the lower end of the main plate 210. In the above, the heating member 300 contacts the lower ends of the main plate 210 and the fuse plate 220 so that heat transfer is achieved.

Meanwhile, as another example, the fuse seating portion 222 is set to have a lower position than the lower end of the main plate 210. In the above, the heating member 300 contacts only the lower end of the fuse plate 220 to transfer heat, while the heating member 300 prevents contact on the lower end of the main plate 210 so that the thermal fuse 400 through the fuse plate 220 It may be in the form of intensive heat transfer to the phase.

Hereinafter, with reference to FIGS. 6 and 7, in a state where the thickness of the fuse plate is kept smaller than that of the main plate, heat transfer to the thermal fuse mounted on the top of the fuse plate according to whether the coolant supplied to the lower housing flows normally. A structure in which the reaction speed of the thermal fuse is improved by smoothing it will be described.

First, referring to FIG. 6, it can be seen a normal state in which the coolant flows smoothly to the lower housing 100. In the normal state, sufficient coolant flows in the lower housing. Heat transfer from the cooling water becomes effective. That is, under a structure in which the heating element 300 is sufficiently immersed in the cooling water so that the upper limit of the cooling water reaches the lower end of the fuse plate 220, the cooling water is transferred from the cooling water to the thermal fuse 400 through a fuse plate having a thin thickness. Enables heat transfer. Through this, in a state in which the coolant flows normally, heat supplied through the heating element is smoothly transferred to the coolant, thereby preventing abnormally high temperature heat from being transferred to the thermal fuse.

On the other hand, referring to FIG. 7, an abnormal state in which the cooling water flows to the lower housing is not smoothly performed. In the abnormal state, insufficient cooling water flows in the lower housing, and heat transfer from the cooling water through the fuse plate This will not be done effectively. That is, under the state in which the upper part of the heating element is not immersed in the cooling water and the non-contact structure between the fuse plate and the cooling water, the high-temperature heat generated from the heating element is directly transferred to the thermal fuse through a fuse plate having a thin thickness. The thermal fuse can detect an immediate abnormal overheat condition.

In addition, a voltage connector and a ground connector may be formed in the upper housing 500, and the connectors may be electrically connected to the heating plate 200.

The heating member 300 may be various types and types of heating elements capable of generating heat, and as an example, a sheath heater may be used. The heating member 300 includes a heating element that converts electrical energy into thermal energy by resistance when current flows, and an insulator that electrically insulates the heating element from the outside and transfers heat from the heating element to the outside. The heating element may be a nichrome wire, and the insulator may be magnesium oxide. The heating member 300 is configured in the shape of a heater tube made of a heating element and an insulator, thereby increasing a contact area with the heat exchange fluid, thereby enabling efficient heat exchange.

Sheath heater is an electric heating heater that can generate heat by electric resistance because the electric heating wire is embedded in the protective tube.The heating wire is built in a coil shape in a metal protective tube, and magnesium oxide, an insulating powder, is filled together to insulate the heating wire and the protective tube It's a heater. Such a sheath heater may be formed in a coil shape made by winding a heater having a long tubular length several times, and may be formed in a variety of other forms. The heating member 300 may be disposed under the heating plate 200 to be provided inside the lower housing 100, and the heating member 300 has both ends in the longitudinal direction to be coupled to the heating plate 200 to be fixed. I can. In addition, both ends of the heating member 300 in the longitudinal direction may be formed to penetrate through the heating plate 200 and protrude upward from the upper surface of the heating plate 200, and both ends of the heating member 300 are wound in a coil shape. It is formed in a straight line shape upward from both ends of the portion so that the straight portion may be coupled to pass through the heating plate 200. At this time, a straight portion through which the heating member 300 passes through the heating plate 200 may be coupled to the heating plate 200 by welding, so that the coupling portion may be sealed, and the heating member 300 may be formed by using a sealing material. It is also possible to make the part penetrating the airtight.

The thermal fuse 400 may be formed of a bimetal or the like capable of controlling an operation by blocking a current flowing when the temperature reaches a specific temperature or higher, and the thermal fuse 400 may be coupled to contact the heating plate 200. Specifically, the thermal fuse 400 may be a bimetal temperature control switch made of two types of metals having different thermal expansion coefficients, and the thermal expansion coefficient employed in the thermal fuse 400 is a stability criterion in which heat transferred from the heating member 300 is When the temperature exceeding the temperature is reached, the power-off function may be exerted.

In this case, the thermal fuse 400 may be partially inserted into the receiving groove 211 formed concave from the upper surface of the heating plate 200 to the lower side and disposed to contact the upper surface of the main plate 210. In addition, a voltage connector and a ground connector may be formed in the upper housing 500, and the connectors may be electrically connected to the heating plate 200.

The upper housing 500 may be formed of, for example, a plastic material, and may be formed in the shape of a container concave upward and disposed so that the open side faces downward. The upper housing 500 may be coupled to the upper end of the lower housing 100. For example, the upper end of the lower housing 100 and the upper end of the upper housing 500 may be arranged to be in contact with each other, and a plurality of fastening holes are formed at the upper end of the lower housing 100 by being spaced apart along the circumference, and the upper housing 500 ) Has a through hole formed at a position corresponding to the plurality of fastening holes, and can be coupled by a separate fastening means.

A thermal fuse 400 or the like may be provided in a second space, which is an internal space formed by combining the upper housing 500 and the heating plate 200.

The thermal fuse 400 may be disposed in a fuse seating portion formed concave from an upper surface to a lower side of the fuse plate 220 so as to directly transmit heat from the heating member 300 through only the fuse plate 220.

Referring to FIGS. 4 and 5 again, a fuse plate 220, a thermal fuse 400 seated on the fuse plate 220, a fuse cover 410 fitted on the thermal fuse 400, and a fuse cover 410 A fastening structure between the fixing clip 420 connecting and fastening the heating plate 200 will be described.

The fuse plate 220 is arranged to enable thermal transfer between the thermal fuse 400 and the heating member 300 by inserting and coupling the lower end of the thermal fuse 400 to the fuse seating portion 222 formed concave from the top to the bottom. do.

The fuse cover 410 may be a structure having a hollow shape with an open lower portion. Specifically, the cover body 411 and the cover body 411 in the shape of a hollow box accommodating the thermal fuse 400 therein. It includes a pressing protrusion 413 protruding on the inner upper surface.

The way they are combined is as follows. In a state in which the thermal fuse 400 is placed in the fuse seating portion 222 grooved downwardly on the central portion of the fuse plate 220, the fuse cover 410 is coupled to the thermal fuse 400 by covering it. In the above state, the fuse cover 410 is fixed on the heating plate 200 through the fixing clip 420. The fixing clip 420 has a pressing portion 422 fastened on an upper end of the fuse cover 410 and a hook portion 424 extending downward from both ends of the pressing portion. The hook portion has a shape that extends to have a predetermined elastic force from the pressing portion, and through the process of fixing the hook portion to the top of the heating plate 200, the pressing protrusion of the cover body presses the thermal fuse 400 downward. By doing so, the adhesion to the fuse plate 220 is increased.

The heating plate 200 may be formed of a flat plate made of a metal material, and may be formed of various materials or shapes.

Meanwhile, the heating plate 200 may include a controller function. The controller serves to control the operation of the heating member 300, and both ends of the heating member 300 may be coupled to the controller to be electrically connected.

The cooling water heating device for a battery having a plate heat deformation prevention structure according to the present invention has a main plate coupled to an open upper portion of a lower housing in a state in which the heating element is coupled, and a fuse plate installed in a plate hole formed through the main plate. On the cover plate, the heat transfer structure to the thermal fuse mounted on the upper end of the fuse plate is improved by directly transferring the heat supplied through the heating element to the fuse plate.

Although the present invention has been described through the above embodiments, the present invention is not limited thereto. The above embodiments may be modified or changed without departing from the spirit and scope of the present invention, and those skilled in the art will recognize that such modifications and changes also belong to the present invention.

100: lower housing
200: heating plate
300: heating element
400: thermal fuse
500: upper housing
600: sealing member

Claims (3)

A lower housing 100 having an inlet portion 110 through which cooling water is introduced and an outlet portion 120 through which the cooling water is discharged;
A heating plate 200 coupled to cover and close the open upper side of the lower housing 100;
A heating member 300 provided in an inner space formed by a combination of the lower housing 100 and the heating plate 200;
A thermal fuse 400 coupled to the heating plate 200; And
Includes; an upper housing 500 coupled to the upper end of the lower housing 100,
When the heating plate 200 is seated in the main plate 210 having a structure covering the open upper side of the lower housing 100 and the plate hole 212 formed in the main plate 210, the thermal fuse ( Including a fuse plate 220 on which the 400) is mounted,
The thickness of the fuse plate 220 is kept smaller than that of the main plate 210,
A method in which the fuse cover 410 is covered on the thermal fuse 400 in a state in which the thermal fuse 400 is placed in a fuse seating portion 222 grooved downwardly on the central portion of the fuse plate 220 Characterized in that combined with,
Battery external heating device with heat transfer structure to improve the reaction speed of thermal fuse.
The method of claim 1,
The lower end of the fuse seating portion 222 is set to have the same height as the lower end of the main plate 210 or lower than the lower end of the main plate 210,
Battery external heating device with heat transfer structure to improve the reaction speed of thermal fuse.
The method of claim 1,
The fuse cover 410 is a structure having a hollow shape having a structure in which the lower part is opened, a cover body having a hollow box shape accommodating the thermal fuse 400 therein, and a pressing protrusion protruding on the inner upper surface of the cover body Containing,
Battery external heating device with heat transfer structure to improve the reaction speed of thermal fuse.

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