KR101618347B1 - Coolant calorimeter that can do pressure cycle test - Google Patents

Abstract

The present invention relates to an apparatus to measure heat quantity generated in testing components under various environmental conditions in order to test a performance and durability of the component using coolant such as a battery for electric vehicle, a radiator, etc. The present invention is able to increase a reliability of a test to test the performance and durability of components under various environmental conditions by performing the test by adding an accurate pressure required repeatedly in a predetermined pattern cycle to circulating coolant; equalizing the temperature of the coolant; and preventing air from flowing into the coolant. The coolant heat quantity measuring apparatus of the present invention comprises: a pressurization container (81) installed in an upper part of a coolant container (80), has smaller volume and area per square meter than the coolant container (80), and is formed to supply compressed air; a heater (82) installed in one side in the coolant container (80); a coolant return pipe (83) installed in an edge where the heater (82) is installed in the upper part of the coolant container (80); a coolant supply pipe (84) installed in an opposite edge of the coolant return pipe (83) on a lower part of the coolant container (80); and a coolant guide plate (85) which guides coolant, flowing from the coolant return pipe (83) of the upper part to the coolant container (80), to pass the heater (82) and flow in the coolant supply pipe (84) of the lower part.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a cooling water calorimeter,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for measuring the amount of heat generated in a test part under various environmental conditions in order to test the performance and durability of components using cooling water such as a battery for an electric vehicle and a radiator, It is a cooling water calorimeter that increases the reliability of parts performance and durability test under various environmental conditions by repeatedly applying the exact pressure required, making the cooling water temperature uniform, and preventing the air inflow to the cooling water. .

Batteries for electric vehicles generate a lot of heat during use, so they are intended to be used while cooling water is flowing to cool the battery. In addition, since the vehicle is driven in a low-temperature environment and a high-temperature environment, the battery should be made to exhibit its function in such a driving environment.

Therefore, various performance and durability tests shall be performed on the battery samples to determine whether the manufactured batteries comply with these requirements. Examples of such tests are Low Temperature Wake Up Test, Power Temperature Cycle Test, Pressure, Vibration, and Temperature Cycle Test. In order to control the temperature around the sample, a test is carried out in a chamber, and a sample is placed in a vibration device inside the chamber in order to perform vibration test while vibration is applied.

As shown in FIG. 1, the cooling water heat quantity measuring apparatus includes a cooling water tank (10) for storing cooling water, adjusting the temperature of the cooling water and applying pressure to the cooling water, A cooling device (30) including a heating device (20) including a heater (21), a heat exchanger (31) installed inside the cooling water container (10) A flow rate control device 40 including a circulation pump 41 for circulating the cooling water in the cylinder 10 to allow passage through the battery sample s, a pressure sensor 51 provided in front of the sample s, A pressure control device 50 including a back pressure regulating valve 52 provided at the rear of the sample s and a temperature sensor 61 provided in front of the sample s for measuring the calorific value of the cooling water obtained by the sample s A temperature sensor 62 provided at the rear of the sample s, Room temperature and pressure sensing device 60 comprises a differential pressure sensor 63 for measuring the pressure difference between the back and the like.

The cooling water tank 10 is a pressure vessel capable of withstanding pressure, and a level gauge 11 is provided so that the amount of cooling water can be known from the outside.

The heating device 20 includes a heater 21, a driver 22 for driving the heater 21, a controller 23 for controlling the driver 22, And a temperature sensor 24. The heating of the cooling water is performed by comparing the temperature preset in the controller 23 with the temperature sensed by the temperature sensor 24 so that when the temperature of the cooling water is lower than a preset temperature by a predetermined amount, The cooling water is heated.

The cooling device 30 is a general device that cools the cooling water by heat exchange between the refrigerant and the cooling water. The cooling device 30 includes a heat exchanger 31, an accumulator 32, a compressor 33, a condenser 34, And a pump 35. The cold refrigerant flowing through the refrigerant pipe and the cooling water are subjected to heat exchange in the heat exchanger (31) to cool the cooling water.

 The temperature of the cooling water is controlled to a set temperature by the heating device 20 and the cooling device 30 as described above.

The flow controller 40 includes a circulation pump 41 for circulating cooling water in the cooling water cylinder 10, a driver 42 for driving the circulation pump 41, a flow meter 43 for sensing the flow rate of the cooling water, And a controller 44 for controlling the controller. The flow rate is controlled by comparing the flow rate preset in the controller 44 with the flow rate sensed by the flow meter 43 and controlling the circulation pump 41 so that the predetermined amount of cooling water flows.

The pressure control device 50 compares the pressure sensed by the pressure sensor 51 provided in front of the sample s with the preset pressure in the controller 53 and outputs the pressure to the back pressure regulating valve 52 provided behind the sample s, So that the pressure of the cooling water flowing into the sample s becomes a predetermined pressure.

The temperature and pressure sensing device 60 includes a temperature sensor 61 provided in front of the sample s and a temperature sensor 62 provided in the rear of the sample s to measure the amount of heat of the cooling water obtained by the sample s. And senses the pressure difference between the front and the rear of the sample s by the differential pressure sensor 63. [ The sensed temperature and pressure differences are sent to a separate data acquisition device, which calcu- lates the calorie by computing these values. The larger the calorific value measured, the greater the cooling effect of cooling water.

In addition, a pressure cycle pressurizing device 70 is constituted to repeatedly pressurize and pressurize the cooling water with a predetermined pattern. A regulator 71 for applying air pressure to the cooling water inside the cooling water bottle 10 using electricity and air, And a controller 73 for controlling the regulator 71 by comparing a pressure measured by the pressure sensor 72 with a preset pressure, a pressure sensor 72 for sensing the pressure inside the cooling water bottle 10, . The regulator (71) is supplied with air at a predetermined pressure. The controller 73 controls the regulator 71 to repeatedly apply the air pressure of the predetermined pattern.

As described above, the cooling water heat quantity measuring apparatus senses the temperature in front of and behind the sample s while controlling the temperature, the flow rate and the pressure of the cooling water to predetermined values, So that the calorie can be measured. When the amount of heat received from the sample (s) through the cooling water passing through the sample (s) is large, it means that the cooling performance of the sample (s) is excellent. Such a coolant calorimeter side is placed under a bad condition such as temperature and vibration by putting the sample (s) in a chamber, and the sample (s) is charged and discharged as in the actual situation.

However, in the conventional cooling water heat quantity measuring apparatus, as shown in the figure, the cooling water cylinder 10 is vertically erected and air is introduced into the upper portion, and the cooling water is supplied from the lower portion and returned to the upper portion.

In the cooling water cylinder 10 having such a structure, since the volume of the air inside the cooling water cylinder 10 is large when the pressure cycle is applied and the air is a compressible fluid, expansion and contraction are good and it is difficult to accurately control the pressure with time There is a problem.

In addition, the cooling water flows downward in the vertical direction through the air from above the cooling water bottle 10, so that air flows into the cooling water. In addition, since the cooling water tends to flow without passing through some of the heaters 21, The temperature is not uniform and the temperature control is difficult. And thus the reliability of various performance and durability tests of the sample (s) is degraded.

SUMMARY OF THE INVENTION The present invention is conceived to solve the problems of the prior art cooling water calorie measuring apparatus as described above and it is an object of the present invention to provide a cooling water calorimeter which can easily and accurately realize a pressure cycle of a predetermined pattern when performing a pressure cycle test in which a certain pattern of pressure is repeatedly applied to cooling water , Cooling water flow measurement which can increase the reliability of the performance and durability test of the sample by preventing the inflow of air into the circulating cooling water and flowing all the cooling water in the cooling water tube through the heater to increase the heating efficiency and uniform the cooling water temperature And an object thereof is to provide a device.

In order to accomplish the above object, the present invention provides a cooling water calorie measuring device configured to cool heat generated in a sample by heat exchange with cooling water during a performance and durability test of the sample; A cooling water passage for storing the cooling water, and a pressure control device for applying pressure to the cooling water in the cooling water passage; A cooling water flow meter for measuring the amount of heat transferred from the sample to the cooling water in the heat exchange process, the cooling water flow meter comprising: a pressure passage for supplying compressed air with a volume and a flat area smaller than the cooling water passage, A coolant return pipe provided at an edge of the upper portion of the coolant passage where the heater is installed; a cooling water supply pipe provided at an opposite edge of the coolant return pipe at a lower portion of the coolant passage; And a cooling water guide plate for guiding the cooling water flowing into the cooling water tank from the cooling water return pipe of the cooling water returning pipe to flow into the cooling water supply pipe at the lower portion through the heater portion.

The cooling water heat amount measuring apparatus of the present invention is characterized in that the cooling water pail is arranged in a cylindrical shape in a horizontal direction, and the pressure pail is arranged in a cylindrical shape in a vertical direction.

The cooling water heat quantity measuring apparatus of the present invention is further characterized in that the heater is installed horizontally at a position eccentric downward from the center of the flange plate which is the substrate of the cooling water conduit, And the heater is vertically installed at an intermediate point in the horizontal direction of the heater.

The cooling water heat quantity measuring apparatus of the present invention is characterized in that a piercing plate for vertically stirring the cooling water having passed through the heater to a uniform temperature is installed on the cooling water supply pipe side of the cooling water pipe.

The cooling water heat quantity measuring apparatus of the present invention is also characterized in that the cooling water return pipe provided at the upper edge of the cooling water tube has two cooling water return pipes for returning the cooling water having passed through the sample and one cooling water return pipe for returning cooling water cooled by the cooling device The cooling water supply pipe provided at the lower portion of the cooling water tube is provided on the front side of the cooling water tube and includes two cooling water supply pipes for supplying cooling water to the sample and one cooling water supply pipe for supplying cooling water to the cooling device, .

The cooling water calorie measuring apparatus according to the present invention is capable of easily implementing a pressure cycle when a pressure cycle test is performed because a pressurizing cylinder having a small volume of internal air is additionally provided on the cooling water cylinder for repeatedly applying a certain pattern of pressure to the cooling water In addition, since the cooling water is filled in the cooling water tank to prevent the cooling water from flowing into the cooling water supply pipe from the cooling water return pipe and the cooling water in the cooling water pipe passes through the heater by the cooling water guide plate, The cooling water temperature becomes uniform and the reliability of the performance and durability test of the sample can be enhanced.

1 is a configuration diagram of a conventional cooling water heat quantity measuring apparatus,
FIG. 2A is a front sectional view of a cooling water bottle and its related components applied to a cooling water heat quantity measuring apparatus according to the present invention,
Figure 2b is a top view of the cooling water canister and its associated components of Figure 2a,
FIG. 3 is a side view of a cooling water guide plate installed in the cooling water tank of FIG.
4 is a side view of a perforated plate installed in the cooling water container of FIG.

Hereinafter, a cooling water calorie measuring apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

The cooling water heat quantity measuring apparatus of the present invention is configured to cool the heat generated in the sample (s) by the heat exchange with the cooling water in the process of testing the performance of the sample (s) and the durability as in the conventional cooling water measuring apparatus of Fig. 1 , A cooling water passage for storing the cooling water, and a pressure control device (50) for applying pressure to the cooling water in the cooling water passage. The heat transferred from the sample (s) to the cooling water is measured.

As shown in FIGS. 2A and 2B, the cooling water heat quantity measuring apparatus of the present invention is installed at the upper part of the cooling water cylinder 80 to more precisely control the pressure applied to the cooling water, And a pressurizing cylinder 81 having a small area and adapted to supply compressed air at an upper portion thereof. The cooling water cylinder (80) is arranged in a cylindrical shape in the horizontal direction, and the pressure cylinder (81) is arranged in a cylindrical shape in the vertical direction. The cooling water cylinder (80) is a pressure vessel manufactured to withstand high pressure.

A regulator port 81a for installing the regulator 71 shown in Fig. 1 and a pressure sensor port 81b for installing the pressure sensor 72 are formed on the upper surface of the pressure cylinder 81. As shown in Fig. Compressed air is supplied through the regulator port 81a and is supplied into the pressurizing cylinder 81 with a predetermined pattern pressure regulated by the regulator 71. [

A heater 82 is installed at one side of the inside of the cooling water cylinder 80. The heater 82 is installed horizontally at a position eccentric downward from the center of the flange plate 80a which is a substrate of the cooling water cylinder 80 .

A sample s such as a battery and a cooling water return pipe 83 for receiving cooling water returning through the cooling device 30 are installed on the upper portion of the cooling water bottle 80. The cooling water return pipe 83 is installed at the edge of the side where the heater 82 is installed do. The cooling water supply pipe 84 for supplying the cooling water to the sample s and the cooling device 30 is installed at the lower portion of the cooling water pipe 80 and is provided at the opposite edge of the cooling water return pipe 83.

The cooling water return pipe 83 at the upper edge of the cooling water cylinder 80 is cooled by two cooling water return pipes 83a and 83b through which the cooling water having passed through each of the two samples s is returned, The cooling water supply pipe 84 provided at the lower portion of the cooling water pipe 80 is provided on the front side of the cooling water pipe 80 to connect the two samples s, And two cooling water supply pipes 84a and 84b for supplying cooling water to the cooling device 30 and one cooling water supply pipe 84c for supplying the cooling water to the cooling device 30. [

The reason why there are two cooling water return pipes 83a and 83b and cooling water pipes 84a and 84b as described above is that two samples s can be operated at the same time. That is, two cooling water heat quantity measuring apparatuses of Fig. 1 are connected in parallel to the cooling water cylinder 80. If one sample (s) is to be tested, shut off the shutoff valve on the coolant supply piping which is not tested, so that no cooling water flows through the coolant piping.

And a cooling water guide plate 85 for guiding the cooling water introduced into the cooling water cylinder 80 from the upper cooling water return pipe 83 to flow into the lower cooling water supply pipe 84 through the heater 82 is provided . The cooling water guide plate 85 is formed with a through hole 85a so as to allow the heater to pass therethrough and is installed perpendicularly to the midpoint of the heater 82 in the horizontal direction.

A piercing plate 86 is vertically provided at the cooling water supply pipe 84 side of the cooling water pail 80 to stir the cooling water having passed through the heater 82 to a uniform temperature.

A temperature sensor 87 is provided in front of the cooling water cylinder 80 and a level gauge 88 for indicating the cooling water level of the cooling water cylinder 80 is provided outside the cooling water cylinder 80. And an over-temperature sensor 89 for detecting the temperature of the cooling water in the cooling water bottle 80 when the temperature of the cooling water is higher than a predetermined temperature.

The other components of the cooling water calorimeter are the same as the conventional ones.

The cooling water calorie measuring device of the present invention is used for performance and durability test of not only a vehicle battery but also all components that make cooling water flow for cooling such as a radiator. In this specification, cooling water is referred to as cooling water, but it should be interpreted as a term including all types of liquid used for cooling, such as pure water, antifreeze, oil and the like.

The cooling water heat quantity measuring apparatus of the present invention having the cooling water cylinder 80 constituted as above operates as follows.

The cooling water in the cooling water cylinder 80 is heated by the heater 82 to a predetermined temperature in a conventional manner. When it is necessary to cool the cooling water, the cooling water is returned to the cooling water cylinder 80 through the cooling water return pipe 83c after cooling some cooling water through the cooling water supply pipe 84c to the conventional cooling device 30, Cool the cooling water. The cooling water is controlled to a predetermined temperature by the heating and cooling process, and the cooling water is filled beyond the cooling water tank 80 so as to reach the lower portion of the pressurizing cylinder 81 located at the upper portion. That is, the pressurizing cylinder 81 contains only a small amount of air as compared with the conventional one.

The cooling water circulated through the circulation pump 41 is returned to the cooling water cylinder 80 through the cooling water return pipes 83a and 83b and the cooling water is circulated through the cooling water supply pipe 84a (84b) to the sample (s).

When the cooling water flows through the cooling water cylinder 80, the cooling water is introduced into the cooling water cylinder 80 from the upper portion of the cooling water cylinder 80 and is lowered toward the end of the heater 82 by the cooling water induction plate 85, Through the through-hole 85 of the heater 82. In this process, the cooling water is heated. Since all the cooling water passes through the heater 82, the heating efficiency is good and the temperature uniformity is also improved. Since the heater 82 is eccentrically installed at the lower part, the cooling water flowing into the cooling water cylinder 80 at a high speed passes through the heater 82 at a lower speed, so that the heating efficiency becomes better.

Since the cooling water cylinder 80 of the present invention has no air inside it, the cooling water flowing from the cooling water return pipes 83a, 83b and 83c is not mixed with the air of the pressurizing cylinder 81 at all, ). ≪ / RTI >

In addition, a piercing plate 86 is provided at the outlet of the cooling water pail 80 so that the outflowed cooling water flows out after stirring, so that the temperature of the cooling water becomes uniform.

Air pressure is applied to the cooling water cylinder 80 and the pressure cylinder 81. The cooling water is repeatedly supplied in a pressure cycle of a predetermined pattern through the regulator 71 provided in the regulator port 81a in the upper portion of the pressure cylinder 81 And pressurized. Therefore, the performance of the sample (s) can be tested under harsh conditions and the durability test can be performed, and the test period can be shortened accordingly.

Since the volume of air, which is a compressible fluid contained in the pressurizing cylinder 81, is small, the pressurization reaction time is short, and therefore, a pressure cycle of a predetermined pattern with time can be precisely implemented, .

As described above, according to the present invention, since the pressurizing cylinder 81 having a small internal volume is provided separately on the cooling water cylinder 80 in order to repeatedly apply a predetermined pattern pressure to the sample s, It is possible to easily realize an accurate pressure cycle when the pressure cycle test is performed.

Since the cooling water is filled in the cooling water tank 80, no air flows in the process of flowing the cooling water from the cooling water return pipe 83 to the cooling water supply pipe 84, and all the cooling water is heated by the cooling water guide plate 85, The temperature of the cooling water can be uniformed and the reliability of the performance of the sample s and the reliability of the durability test can be improved.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It should be within the scope of the claimed patent claims.

s: Sample 10: Cooling water tank
11: Level gauge 20: Heating device
21: heater 22:
23: controller 24: temperature sensor
30: cooling device 31: heat exchanger
32: accumulator 33: compressor
34: condenser 35: circulation pump
40: cooling device 41: circulation pump
42: driver 43: flow meter
44:
50: pressure control device 51: pressure sensor
52: back pressure regulating valve 53: controller
60: Temperature and pressure sensing device 61: Temperature sensor
62: temperature sensor 63: differential pressure sensor
70: Pressure cycle pressurizing device 71: Regulator
72: pressure sensor 73: controller
80: cooling water cylinder 80a: flange plate
81: pressurizing cylinder 81a: regulator port
81b: pressure sensor port 82: heater
83 (83a, 83b, 83c): cooling water return pipe 84 (84a, 84b, 84c): cooling water supply pipe
85: cooling water guide plate 85a: through hole
86: Perforated plate 87: Temperature sensor
88: Level gauge 89: Over temperature sensor

Claims (5)

And is configured to cool the heat generated in the sample (s) by heat exchange with the cooling water during the performance and durability test of the sample (s); A cooling water cylinder 80 for storing the cooling water and a pressure control device 50 for applying pressure to the cooling water in the cooling water cylinder 80; A cooling water heat quantity measuring device for measuring a heat quantity transferred from the sample (s) to the cooling water in the heat exchange process,
A pressurizing cylinder 81 installed on the upper portion of the cooling water cylinder 80 and having a smaller volume and area than the cooling water cylinder 80 and supplied with compressed air,
A heater 82 installed on one side of the inside of the cooling water cylinder 80,
A cooling water return pipe 83 provided at an edge of the cooling water cylinder 80 on which the heater 82 is installed,
A cooling water supply pipe 84 provided at the lower edge of the cooling water cylinder 80 at an opposite edge of the cooling water return pipe 83,
And a cooling water guide plate 85 for guiding the cooling water introduced into the cooling water cylinder 80 from the upper cooling water return pipe 83 to flow into the lower cooling water supply pipe 84 through the heater 82 Characterized by a cooling water calorimeter. The cooling water heat quantity measuring apparatus according to claim 1, wherein the cooling water cylinder (80) is arranged in a cylindrical shape in a horizontal direction, and the pressure cylinder (81) is arranged in a cylindrical shape in a vertical direction. The refrigerator according to claim 1, wherein the heater (82) is installed horizontally at a position eccentric downward from the center of a flange plate (80a) as a substrate of the cooling water cylinder (80) Wherein a through hole (85a) is formed in such a size as to allow the heater to pass therethrough, and is vertically provided at a mid-point in the horizontal direction of the heater (82). A piercing plate (86) is vertically provided on the cooling water supply pipe (84) side of the cooling water pail (80) for stirring the cooling water having passed through the heater (82) A cooling water calorimeter. The cooling water return pipe (83) provided at the upper edge of the cooling water cylinder (80) is provided with two cooling water return pipes (83a) and (83b) for returning the cooling water having passed through the sample and a cooling device And a cooling water supply pipe 84 provided under the cooling water pipe 80 is installed on the front side of the cooling water pipe 80 and is connected to the sample s And two cooling water supply pipes 84a and 84b for supplying the cooling water and one cooling water supply pipe 84c for supplying the cooling water to the cooling device 30 provided on the bottom surface of the cooling water pipe 80. [ Measuring device.

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