KR102083334B1 - Sensing structure of coolant temperature by securing separation distance between coolant flow path and built-in temperature sensor - Google Patents

Abstract

According to the present invention, the structure for sensing the temperature of the coolant for cooling the charger for the battery for the electric vehicle includes a flow path housing 10 in which a coolant flow path for cooling water flow is formed; A circuit board 20 in which a plurality of electronic devices are integrally formed while being spaced apart from the flow path housing 10; A built-in temperature sensor 30 for measuring the temperature in close contact with the surface of the flow path housing 10 in an integrated state on the circuit board 20; And a binding means 40 fixedly coupled to the flow path housing 10 while passing through the circuit board 20, with the built-in temperature sensor 30 on the top surface of the flow path housing 10. A sensor seating portion 11 protruding upward is formed for contact, and the sensor seating portion 11 compares the lower seating point of the built-in temperature sensor 30 with other points on the upper surface of the flow path housing 10. By constructing so as to protrude to the upper side to secure the separation distance between the electronic elements mounted on the circuit board and the flow path housing, the charger for the battery for the electric vehicle through the built-in temperature sensor 30 mounted on the circuit board 20 It is characterized in that it eliminates the need to use an external temperature sensor by sensing the temperature of the cooling water to perform cooling.

Description

Sensing structure of coolant temperature by securing separation distance between coolant flow path and built-in temperature sensor}

The present invention relates to a structure for sensing the temperature of a coolant that cools a charger for an electric vehicle battery through a built-in temperature sensor mounted on a PCB without using an external temperature sensor.

As environmental regulations have recently been strengthened, eco-friendly vehicles such as hybrid vehicles (HEV), plug-in hybrid vehicles (PHEV), and battery electric vehicles (BEV) have attracted attention. In particular, the growth of PHEV, which uses only BEV, which uses purely electric energy, and battery energy and engine at the same time, and which can be charged externally, is remarkable.

Battery electric vehicles and plug-in hybrid vehicles require a charger to charge the battery. Battery chargers are classified into slow, rapid, and ICCB according to the charging time, and classified into on-board or off-board depending on the location.

The slow charger and the quick charger are charged using 220V or 380V power separately installed, and the ICCB is a cable that can be charged at home. In slow charging, the high voltage battery is charged through a separately installed charger (OBC) in the vehicle.

The rapid charging method has a disadvantage in that a charging station is essential despite the short charging time. Currently, charging stations are installed in Korea's KEPCO offices, public parking lots, large marts, and apartment houses, but this is not enough. Therefore, all BEVs and PHEVs are equipped with a built-in charger (OBC) that allows charging anywhere in the home power plug.

The eco-friendly on-board charger (OBC) is a vehicle-mounted charger that slowly charges the vehicle's high-voltage battery with AC 110V / 220V power while the vehicle is parked. The battery charging method (constant current, constant voltage) is controlled internally through cooperative control with the BMS.

OBC converts AC, which is a commercial power source, into DC to charge the battery inside the vehicle. OBC is an input filter that removes noise from AC power, which is generally an input power source, a PFC (Power Factor Corrector) circuit that increases energy efficiency, a DC / DC converter for stably supplying power to batteries, charging stations, and other inside the vehicle. It consists of a control circuit that communicates with the device and controls the OBC.

OBC generates heat during charging, and such heat generation adversely affects the performance and lifespan of the power conversion components, so a cooling system must be provided to solve the heat generation.

Looking at the process of cooling the OBC among the power conversion components constituting the vehicle using the cooling system, the cooling water flows on the flow path housing connected to the circuit board for cooling of electronic devices integrated in the circuit board constituting the OBC. Thereby performing the cooling function.

In the past, an external temperature sensor was used to check the proper temperature of the cooling water flowing in the flow path housing. It can occur, and the price of the external temperature sensor is high, so there is a problem that the design cost increases.

On the other hand, when the temperature of the cooling water flowing in the flow path housing is sensed by installing the built-in temperature sensor on the circuit board, due to the structural constraint that the built-in temperature sensor must be installed to connect the circuit board and the flow path housing, As the distance approaches, as a result, there is a disadvantage that the insulation of electronic devices mounted on the circuit board is poor.

In addition, there is a problem that the temperature of the flow path housing rises as the distance between the circuit board and the flow path housing approaches.

An object of the present invention is to solve the problem of using a conventional external temperature sensor, the temperature of the cooling water to perform the cooling of the charger for the battery for the electric vehicle through the built-in temperature sensor mounted on the circuit board without using an external temperature sensor It is characterized in that it provides a structure that ensures a separation distance between the electronic elements mounted on the circuit board and the flow path housing by configuring to protrude an area contacting the built-in temperature sensor from the upper plate constituting the flow path housing.

According to the present invention for achieving the above object, the structure for sensing the temperature of the coolant for cooling the charger for the battery for an electric vehicle includes a flow path housing 10 in which a coolant flow path for cooling water flow is formed; A circuit board 20 in which a plurality of electronic devices are integrally formed while being spaced apart from the flow path housing 10; A built-in temperature sensor 30 for measuring the temperature in close contact with the surface of the flow path housing 10 in an integrated state on the circuit board 20; And a binding means 40 fixedly coupled to the flow path housing 10 while passing through the circuit board 20, with the built-in temperature sensor 30 on the top surface of the flow path housing 10. A sensor seating portion 11 protruding upward is formed for contact, and the sensor seating portion 11 compares the lower seating point of the built-in temperature sensor 30 with other points on the upper surface of the flow path housing 10. By constructing so as to protrude to the upper side to secure the separation distance between the electronic elements mounted on the circuit board and the flow path housing, the charger for the battery for the electric vehicle through the built-in temperature sensor 30 mounted on the circuit board 20 It is characterized in that it eliminates the need to use an external temperature sensor by sensing the temperature of the cooling water to perform cooling.

The cooling water flow path 12 is connected to the entry region 13 and the entry region 13, which are formed to be inclined at a predetermined angle in an upward direction from the inlet of the flow path housing 10, and at the same time, the cooling water flow path 12 is provided with the It includes a water temperature measurement chamber 14, which is a space disposed on the lower portion, and a continuous flow area 15, which is an area extending from the water temperature measurement chamber 14 to an outlet.

The water temperature measuring chamber 14 secures a free space in a state protruding in the upper direction compared to the upper ends of the entry area 13 and the continuous flow area 15.

The built-in temperature sensor 30 employs an NTC thermistor.

According to the present invention, it is possible to achieve all the objects of the present invention described above.

The present invention has a cost advantage through a structure for sensing the temperature of the coolant flowing through the cooling plate adjacent to the PCB through the built-in temperature sensor mounted on the PCB constituting the charger for the battery for the electric vehicle.

Through this, in order to check the proper temperature of the cooling water flowing in the metal plate, the problem of the leakage of cooling water and the rising cost of using the external temperature sensor caused by using the external temperature sensor are solved.

Figure 1 shows a structure concept of sensing the temperature of the cooling water to perform the cooling of the charger for the battery for an electric vehicle according to an embodiment of the present invention.
2 shows a charger modeling image in a state in which the temperature sensing structure of the cooling water according to the present invention is reflected.
FIG. 3 shows the front view of FIG. 2.

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

In the present specification, the temperature sensing structure of the cooling water applied on the OBC, which is an on-board battery charger, is mainly described, but the present invention is not limited thereto. It is possible.

1 to 3, a charger employing a cooling water temperature sensing structure according to the present invention is spaced apart on a flow path housing 10 and a flow path housing 10 in which cooling water flow paths for cooling water flow are formed. A circuit board 20 in which a plurality of electronic devices are integratedly formed, a built-in temperature sensor 30 in close contact with the surface of the flow path housing 10 in an integrated state on the circuit board 20, and a circuit board It is provided so as to cover one side of the binding means 40 and the flow path housing 10 fixedly coupled to the flow path housing 10 in the state penetrated through the circuit board 20 and the built-in temperature sensor 30 It includes an outer cover 50 having a structure for receiving the back therein.

The cooling water channel 12 formed in the channel housing 10 may have a structure in which an inlet port is formed through one side of the channel housing 10 and an outlet port is formed through the other side.

The flow path housing 10 may include a structure in which a cooling water flow path is formed between the upper and lower plates in a state including an upper plate and a lower plate disposed below the upper plate.

The upper plate is formed with a sensor seating portion 11 protruding in an upward direction for contact with the built-in temperature sensor 30. The sensor seating portion 11 is configured to protrude the lower seating point of the built-in temperature sensor 30 to the upper side from the other point of the flow path housing 10, thereby ensuring a separation distance between the electronic elements mounted on the circuit board and the flow path housing. To do.

When the structure of the cooling water flow path 12 is described in detail, it is connected to the entry area 13 and the entrance area 13, which are formed to be inclined at a predetermined angle from the inlet to the upper direction, and at the same time, the lower phase of the built-in temperature sensor 30 It includes a water temperature measuring chamber 14, which is a space disposed in, and a continuous flow zone 15, which is an area extending from the water temperature measuring chamber 14 to the outlet.

The water temperature measuring chamber 14 secures the free space 14a in a state protruding in a relatively higher direction compared to the upper ends of the entry area 13 and the continuous flow area 15. That is, the cooling water flowing through the entry area 13 is introduced into the water temperature measurement chamber 14 having a relatively large unit flow rate, thereby causing temporary stagnation and vortex generation of the cooling water. The coolant introduced through this allows sufficient thermal exchange on the water temperature measurement chamber 14. On the other hand, the inclination angle of the portion in contact with the entry region 13 and the continuous flow region 15 on the free space 14a can be set differently. Specifically, the first inclination angle d1 connected to the entry area 13 is set more gently than the second inclination angle d2 connected to the continuous flow area 15. Between the first inclination angle d1 and the second inclination angle d2, a third inclination angle d3 having a predetermined positive inclination in the upper direction is set. Through this, the cooling water entering the free space of the water temperature measuring chamber 14 is enlarged while passing through the central region having the third inclination angle d3 while flowing in a gentle flow through the first inclination angle d1. Diffusion or dispersion of the inflow cooling water in the space is possible, and densification of the inflow cooling water in the space having a second inclination angle d2 rapidly inclined in the downward direction is possible.

Various ribs are provided on the water temperature measuring chamber 14 to connect the upper and lower parts. The ribs function to maintain the shape of the cooling water flow path 12 and at the same time, it is possible to set various flow paths of the introduced cooling water.

As an embodiment of the built-in temperature sensor 30, an NTC thermistor (negative temperature coefficient thermistor) is employed.

The thermistor may be a general term for an electronic component using a semiconductor whose electrical resistance varies greatly with temperature. In particular, a thermistor temperature sensor that is stable with respect to temperature and has good reproducibility of temperature characteristics is used. NTC thermistor is a thermistor that has a negative temperature coefficient and continuously changes its electrical resistance. It is mainly manufactured by metal oxide semiconductors, but there are also organic, Si single crystal, and SiC systems, all of which are used as temperature sensors.

The binding means 40 may be a structure that is radially disposed on the basis of the built-in temperature sensor 30. Illustratively, a plurality is disposed so as to have a state spaced a predetermined distance from the center of the built-in temperature sensor 30 so as not to interfere with the built-in temperature sensor 30. Coupling means 40 may be a method that is coupled to the screw coupling method on one side of the flow path housing (10).

The circuit board 20 is disposed in a manner that passes from the top of the flow path housing 10 to the water temperature measuring chamber 14 and the top of the continuous flow region 15. The built-in temperature sensor 30 connected to one end of the circuit board 20 is coupled to the upper end of the water temperature measurement chamber 14 and passes through the continuous flow region 15 of the electronic device connected to the circuit board 20. In order to prevent contact with the flow path housing 10, a spaced state is maintained. That is, the electronic device connected to the circuit board 20 is positioned on the device arrangement space generated by the continuous flow region 15 having a lower height than the free space of the water temperature measurement chamber 14.

The present invention has a cost advantage through a structure for sensing the temperature of the coolant flowing through the cooling plate adjacent to the PCB through the built-in temperature sensor mounted on the PCB constituting the charger for the battery for the electric vehicle.

The present invention has been described through the above embodiments, but the present invention is not limited thereto. The above embodiments can 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.

10: Euro housing
20: circuit board
30: built-in temperature sensor
40: binding means

Claims (4)

A flow path housing 10 having cooling water flow paths for cooling water flow;
A circuit board 20 in which a plurality of electronic devices are integrally formed while being spaced apart from the flow path housing 10;
A built-in temperature sensor 30 for measuring the temperature in close contact with the surface of the flow path housing 10 in an integrated state on the circuit board 20; And
Includes; binding means 40 fixedly coupled to the flow path housing 10 in the state that penetrates the circuit board 20;
A sensor seating portion 11 protruding upward is formed on the upper surface of the flow path housing 10 for contact with the built-in temperature sensor 30, and the sensor seating portion 11 is the built-in temperature sensor 30. By separating the lower seating point of the upper portion compared to the other points on the upper surface of the flow path housing 10 to secure a separation distance between the electronic elements mounted on the circuit board and the flow path housing,
The cooling water flow path continues on the lower portion of the built-in temperature sensor 30 at the same time as it continues from the entry region 13 and the entry region 13, which are formed to be inclined at a predetermined angle in an upward direction from the inlet of the flow path housing 10. It includes a water temperature measurement chamber 14, which is a space to be disposed, and a continuous flow area 15, which is an area extending from the water temperature measurement chamber 14 to an outlet,
The water temperature measuring chamber 14 secures the free space 14a in a state protruding in a relatively higher direction compared to the upper ends of the entry area 13 and the continuous flow area 15,
The inclination angle of the portion in contact with the entry area 13 and the continuous flow area 15 on the free space 14a is set differently,
The built-in temperature sensor 30 is coupled to the upper end of the water temperature measurement chamber 14, and passes through the continuous flow region 15 to make contact with the flow path housing 10 of the electronic device connected to the circuit board 20. In order to prevent it, to keep it apart,
Characterized in that it eliminates the need to use an external temperature sensor by sensing the temperature of the coolant for cooling the charger for the battery for the electric vehicle through the built-in temperature sensor 30 mounted on the circuit board 20,
A structure that senses the temperature of the coolant that cools the charger for the battery for the electric vehicle.
According to claim 1,
The first inclination angle (d1) connected to the entry region 13 is set more gently than the second inclination angle (d2) connected to the continuous flow region (15),
A structure that senses the temperature of the coolant that cools the charger for the battery for the electric vehicle.
delete According to claim 1,
The built-in temperature sensor 30 employs an NTC thermistor,
A structure that senses the temperature of the coolant that cools the charger for the battery for the electric vehicle.

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