KR20210083555A - Device of low temperature oil―pressure testing and control method of the same - Google Patents

Abstract

A low-temperature hydraulic test apparatus according to the present invention comprises: a cooling chamber provided with a cooling device for lowering an internal temperature; an internal oil tank provided inside the cooling chamber to inject oil into a test object inside the cooling chamber; an external oil tank provided outside the cooling chamber to inject oil into the internal oil tank; a return line for injecting used oil into an external oil tank after the test of the test object; and a control unit for controlling the injection of oil from the external oil tank to the internal oil tank, the injection of oil from the internal oil tank to the test object, and a return line.

Description

Low-temperature hydraulic testing apparatus and its control method {DEVICE OF LOW TEMPERATURE OIL—PRESSURE TESTING AND CONTROL METHOD OF THE SAME}

The present invention relates to a low-temperature hydraulic testing apparatus and a method for controlling the same, and more particularly, to a technology capable of injecting low-temperature oil into a test jig for testing and circulating the used oil.

Metal materials have various physical properties such as toughness, ductility, brittleness, and stiffness, and due to these properties, a device capable of testing from a high temperature of about 150°C to a low temperature of about -40°C is required to verify the product. .

In order to understand the hydraulic performance of the product, a jig for mounting the product is provided, and to apply hydraulic pressure to the inside of the jig, oil is usually injected from the oil tank to the test jig using a pump equipped with a motor.

In the case of a device that tests high-temperature hydraulic performance, heat dissipation of the motor of the pump does not need to be taken into consideration, but if a pump equipped with a motor is used to test low-temperature hydraulic performance, it is necessary to test the low-temperature hydraulic performance by heat of the motor it gets difficult

In addition, in order to maintain the temperature of the oil at a low temperature, it is sometimes used to lengthen the flow path with the test jig, but as the flow path lengthens, there is a problem that the oil flow rate at low temperature does not flow.

In addition, in the process of lowering the temperature of the oil to a low temperature, moisture condensed inside the test jig and mixed with the oil, thereby affecting the viscosity of the oil, and thus there was a problem in that it was not possible to proceed with an accurate test.

The matters described as the above background art are only for improving the understanding of the background of the present invention, and should not be taken as acknowledging that they correspond to the prior art already known to those of ordinary skill in the art.

KR 10-2019-0072975 A

The present invention has been proposed to solve this problem, and as a device for testing a test subject requiring a low-temperature hydraulic test,

a cooling chamber provided with a cooling device for lowering the internal temperature; an internal oil tank provided inside the cooling chamber to inject oil into the test object inside the cooling chamber; an external oil tank provided outside the cooling chamber to inject oil into the internal oil tank; a return line for injecting used oil into an external oil tank after the test of the test subject; and a control unit for controlling the injection of oil from the external oil tank to the internal oil tank, the injection of oil from the internal oil tank to the test object, and a return line.

The internal oil tank is formed in plurality, and a first pump connected between the external oil tank and the internal oil tank to inject the oil of the external oil tank into the internal oil tank; and the controller further includes the external oil tank before the start of the test. to control the operation of the first pump to inject oil into the internal oil tank.

An air compressor provided outside the cooling chamber and connected to the internal oil tank to inject the oil in the internal oil tank into the test object by pneumatic pressure; the control unit further includes, at the start of the test, the oil injected into the internal oil tank is cooled. It is characterized in that the operation of the air compressor is controlled so that the cooled oil is injected into the test object afterward.

It further comprises a first valve for controlling the inflow of oil from the internal oil tank to the test object, and the control unit controls the first valve to apply or release the inflow of oil from the internal oil tank to the test object. .

It characterized in that it further comprises; a drain chamber for collecting the oil used after the test of the test subject.

The drain chamber further includes an oil level sensor for measuring the level of the oil inside, and a second pump for injecting the oil of the drain chamber into the external oil tank in the return line, and the control unit is controlled by the oil level sensor. When it is confirmed that the set amount of oil is collected in the drain chamber, the second pump is controlled to inject the collected oil into the external oil tank.

The external oil tank includes a heater that raises the oil temperature inside the external oil tank, and the heater increases the oil temperature inside the external oil tank to separate oil, moisture and foreign substances into upper and lower parts by specific gravity. do.

electrode rods provided inside the external oil tank and having different lengths of anode and cathode; and a second valve provided at the lower part of the external oil tank to discharge the material inside the external oil tank, wherein the control unit adjusts the oil and moisture separated by the heater to the predetermined height by the electrode rod. When the separation is confirmed, the second valve is operated to discharge moisture and foreign substances.

The control unit is characterized in that the oil separated from the external oil tank to the upper part by the heater is injected back into the internal oil tank through the first pump.

A control method for controlling a low-temperature hydraulic test apparatus, comprising: a first oil injection step of injecting oil from an external oil tank into an internal oil tank; an oil cooling step of cooling the oil in the internal oil tank by the cooling chamber; a second oil injection step of injecting oil from the cooled internal oil tank as a test object; and an oil return step of injecting the oil used for the test of the test subject to the external oil tank through the return line.

The first oil injection step is characterized in that oil from the external oil tank is injected into the internal oil tank by a first pump connected between the external oil tank and the internal oil tank.

The second oil injection step is characterized in that the oil in the internal oil tank is injected as a test subject due to the pneumatic pressure of the air compressor connected to the internal oil tank.

In the oil return step, the return line includes a first valve and a drain chamber; The oil used for the test object is discharged to the drain chamber through the first valve and collected.

In the oil return step, the return line further includes a second pump connected between the drain chamber and the external oil tank; It is characterized in that the oil collected in the drain chamber is injected into the external oil tank through the second pump.

Further comprising; an oil heating step of heating the oil inside the external oil tank through a heater mounted on the external oil tank, wherein the oil heating step heats the oil injected from the drain chamber into the external oil tank to obtain oil and moisture by specific gravity And it is characterized in that the foreign material is separated into an upper portion and a lower portion.

Moisture checking step of checking the height of the water and foreign substances separated in the oil heating step; and an impurity discharging step of discharging moisture and foreign substances to the outside through a second valve connected to the external oil tank; in the moisture checking step, oil and moisture are separated by a predetermined height by an electrode provided inside the external oil tank It is characterized in that when it is confirmed that the impurity discharge step is started.

The oil separated from moisture and foreign substances in the oil heating step is again injected into the internal oil tank.

The first pump used when oil is injected from the external oil tank into the internal oil tank inside the cooling chamber is provided outside the cooling chamber, so that the heat generated by the cooling pump's power source does not affect the cooling chamber and the test object, enabling normal testing has the effect of making

The oil in the internal oil tank is cooled and the cooled oil is injected into the test target due to the pneumatic pressure of the air compressor, so that the oil can be stably injected. Also, since the air compressor is located outside the cooling chamber, the heat of the air compressor is removed from the cooling chamber. And it has the effect of enabling a normal test without affecting the test subject.

The oil used for the test is injected into the external oil tank through the return line, so the oil used for the test can be reused.

The oil cooled by the heater in the external oil tank is heated and separated into oil, moisture and foreign substances, and when the height of moisture and foreign substances is reached by the electrode by the preset height, the second valve discharges the moisture and foreign substances. It has the effect of maintaining the viscosity and performing a normal test with the reused oil.

1 is a perspective view of a low-temperature hydraulic test apparatus according to an embodiment of the present invention.
2 is a cross-sectional view of an external oil tank among components of a low-temperature hydraulic test apparatus according to an embodiment of the present invention.
3 is a control flowchart of a low-temperature hydraulic test apparatus according to an embodiment of the present invention.

Specific structural or functional descriptions of the embodiments of the present invention disclosed in the present specification or application are only exemplified for the purpose of describing the embodiments according to the present invention, and the embodiments according to the present invention are implemented in various forms. and should not be construed as being limited to the embodiments described in this specification or application.

Since the embodiment according to the present invention can have various changes and can have various forms, specific embodiments are illustrated in the drawings and described in detail in the present specification or application. However, this is not intended to limit the embodiment according to the concept of the present invention with respect to a specific disclosed form, and should be understood to include all changes, equivalents or substitutes included in the spirit and scope of the present invention.

Terms such as first and/or second may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another, for example, without departing from the scope of rights according to the inventive concept, a first component may be termed a second component, and similarly The second component may also be referred to as the first component.

When a component is referred to as being “connected” or “connected” to another component, it is understood that the other component may be directly connected or connected to the other component, but other components may exist in between. it should be On the other hand, when it is said that a certain element is "directly connected" or "directly connected" to another element, it should be understood that no other element is present in the middle. Other expressions describing the relationship between elements, such as "between" and "immediately between" or "neighboring to" and "directly adjacent to", should be interpreted similarly.

The terms used herein are used only to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In this specification, terms such as “comprise” or “have” are intended to designate the existence of an embodied feature, number, step, operation, component, part, or combination thereof, but one or more other features or numbers , it should be understood that it does not preclude the existence or addition of steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as meanings consistent with the context of the related art, and unless explicitly defined in the present specification, they are not to be interpreted in an ideal or excessively formal meaning. .

The control unit 600 (controller) according to an exemplary embodiment of the present invention is a non-volatile memory (not shown) configured to store data relating to an algorithm configured to control the operation of various components of the vehicle or software instructions for reproducing the algorithm. not shown) and a processor (not shown) configured to perform operations described below using data stored in the corresponding memory. Here, the memory and the processor may be implemented as separate chips. Alternatively, the memory and processor may be implemented as a single chip integrated with each other. A processor may take the form of one or more processors.

Hereinafter, the present invention will be described in detail by describing preferred embodiments of the present invention with reference to the accompanying drawings. Like reference numerals in each figure indicate like elements.

1 is a perspective view of a low-temperature hydraulic test apparatus 1000 according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view of an external oil tank 400 among parts of a low-temperature hydraulic pressure test apparatus 1000 according to an embodiment of the present invention. 3 is a control flowchart of the low-temperature hydraulic testing apparatus 1000 according to an embodiment of the present invention.

The low-temperature hydraulic test apparatus 1000 according to an embodiment of the present invention with reference to FIGS. 1 to 3 includes a cooling chamber 100 provided with a cooling device 110 for lowering an internal temperature; an internal oil tank 300 provided inside the cooling chamber 100 to inject oil into the test object 200 inside the cooling chamber 100; an external oil tank 400 provided outside the cooling chamber 100 to inject oil into the internal oil tank 300 ; a return line 500 for injecting the oil used after the test of the test subject 200 into the external oil tank 400; and a control unit 900 for controlling the injection of oil from the external oil tank 400 to the internal oil tank 300, the injection of oil from the internal oil tank 300 to the test object 200, and the return line 500; include

The connection of the external oil tank 400, the internal oil tank 300, and the test subject 200, and the return line 500 connected from the test subject 200 to the external oil tank 400 is a pipe or It can be connected by a tube.

In addition, the control unit 900 for controlling the injection of oil from the external oil tank 400 to the internal oil tank 300, the injection of oil from the internal oil tank 300 to the test subject 200 and the return line 500 is It can be connected to a control line to send a control signal.

The test subject 200 may be fixed by a jig located inside the cooling chamber 100 , and the jig is sealed and connected to the internal oil tank 300 and the return line 500 to be cooled from the internal oil tank 300 . As the oil is injected, low-temperature hydraulic pressure can be pressurized to the test subject 200, and the test is carried out while the low-temperature hydraulic pressure is pressurized, and the oil used after the test is discharged by the return line 500 to the external oil tank. 400 may be injected.

The internal oil tank 300 is formed in plurality, and is connected between the external oil tank 400 and the internal oil tank 300 to inject the oil from the external oil tank 400 into the internal oil tank 300 . (700); further comprising, the controller 900 controls the operation of the first pump 700 to inject oil from the external oil tank 400 to the internal oil tank 300 before the start of the test do it with

The internal oil tank 300 includes a plurality of internal oil tanks 300 when cooling the oil inside the cooling chamber 100 , so that the oil in the internal oil tank 300 can be cooled more quickly.

As for the oil pump, the external oil tank 400 is located outside the cooling chamber 100 , so that the oil in the external oil tank 400 is not cooled and the oil inside the external oil tank 400 is transferred by the first pump 700 . By injecting into the internal oil tank 300, the oil can be cooled in the internal oil tank 300, and the oil from the external oil tank 400 that has not been cooled is sent to the internal oil tank 300 to facilitate the flow of oil. can

The first pump 700 may be operated by receiving power by being connected to a power source such as a motor, and also, by positioning the first pump 700 outside the cooling chamber 100 , the power source of the first pump 700 Since the generated heat does not affect the cooled oil injected into the test subject 200 , the test can proceed normally, and also the cooling device 110 by not affecting the cooling device 110 of the cooling chamber 100 . ) has the effect of increasing the efficiency.

In addition, the first pump 700 is connected to the control unit 900 by a control line, and the control unit 900 is to be cooled by injecting the oil from the external oil tank 400 into the internal oil tank 300 before the test starts. It is possible to control the first pump 700 so that

An air compressor 800 provided outside the cooling chamber 100 and connected to the internal oil tank 300 to inject the oil of the internal oil tank 300 into the test subject 200 by pneumatic; further comprising, a control unit Reference numeral 900 is characterized by controlling the operation of the air compressor 800 so that the cooled oil is injected into the test subject 200 after the oil injected into the internal oil tank 300 is cooled at the start of the test.

The air compressor 800 connected to the internal oil tank 300 is connected in the form of a tube or tube through which air passes, so that the cooled oil in the internal oil tank 300 is tested by the pneumatic pressure of the air compressor 800 as the test target (200). ) can be injected. In addition, since the air compressor 800 is located outside the cooling chamber 100, the heat generated by the air compressor 800 does not affect the cooled oil injected into the test subject 200, so that the test can proceed normally. Also, there is an effect of increasing the efficiency of the cooling device 110 by not affecting the cooling device 110 of the cooling chamber 100 .

In addition, as a second embodiment, instead of the air compressor 800 , a cylinder (not shown) is located inside the cooling chamber 100 and connected to the internal oil tank 300 to inject the oil of the internal oil tank 300 as a test target. can do. Through this, the cooled oil can be stably injected into the test subject 200 .

It further includes; a first valve 210 for controlling the inflow of oil from the internal oil tank 300 to the test subject 200, and the control unit 900 is configured to transfer the oil from the internal oil tank 300 to the test subject 200. Characterized in controlling the first valve 210 to apply or release the inflow of

The first valve 210 is connected to the control unit 900 and the control line to control when the oil pressure is applied to the test subject 200, and oil can be applied to the test subject 200 during the test time. It is controlled so that the hydraulic pressure of the oil in the test subject 200 is released when the test is completed.

It characterized in that it further comprises; a drain chamber 600 for collecting the oil used after the test of the test subject.

The drain chamber 600 is located inside the cooling chamber 100 so that the oil used in the test object 200 can be collected so that the oil used in the test object 200 can be quickly collected in a state in which the viscosity is increased.

The drain chamber 600 further includes an oil level sensor 610 measuring the height of the oil inside, and the return line 500 has a second oil level sensor for injecting the oil of the drain chamber 600 into the external oil tank 400 . 2 pumps 510; includes, and when it is confirmed by the oil level sensor 610 that the oil is collected in the drain chamber 600 by a predetermined amount, the collected oil is transferred to the external oil tank ( 400) to control the operation of the second pump 510 for injection.

The second pump 510 and the oil level sensor 610 are connected to the control unit 900 by a control line, and the oil used for the test of the test subject 200 is collected in the drain chamber 600, and the oil level sensor When it is confirmed by 610 that a predetermined amount has been collected, the control unit 900 controls the second pump 510 to inject oil from the drain chamber 600 into the external oil tank 400 to circulate the oil. can be reused.

Unlike the first valve 210 and the drain chamber 600 , the second pump 510 included in the return line 500 is located outside the cooling chamber 100 so that the heat generated by the second pump 510 is removed. The test can proceed normally by not affecting the cooled oil injected into the test subject 200 , and the efficiency of the cooling device 110 is improved by not affecting the cooling device 110 of the cooling chamber 100 . has an increasing effect.

The external oil tank 400 includes a heater 410 for raising the oil temperature inside the external oil tank 400; the heater 410 increases the oil temperature inside the external oil tank 400 by specific gravity. It is characterized in that oil, moisture and foreign substances are separated into upper and lower parts.

The oil to be used in the test object 200 is cooled in the internal oil tank 300 inside the cooling chamber 100 and injected into the test object 200 by the air compressor 800, and flows through the return line 500. As it is injected into the external oil tank 400, moisture may be mixed with the oil due to the inflow of external air during flow, and accordingly, the oil in which the moisture is mixed cannot be accurately tested because it affects the viscosity of the oil. Therefore, the heater 410 mounted on the external oil tank 400 heats the oil inside the external oil tank 400 to increase the temperature, and there is an effect that can separate oil, moisture, and foreign substances by specific gravity.

The external oil tank 400 includes electrode rods 420 having different lengths of positive and negative electrodes provided therein; and a second valve 430 provided at the lower portion of the external oil tank 400 to discharge the material inside the external oil tank 400; and the control unit 900 includes the oil separated by the heater 410 and It is characterized in that the second valve 430 is operated to discharge the moisture and foreign substances when it is confirmed that the moisture and the foreign substances are separated to a predetermined height by the electrode 420 .

The electrode rod 420 and the second valve 430 can be controlled by being connected to the control unit 900 and the control line, and the electrode rod 420 is mounted with different lengths of the rods connected to the positive electrode and the negative electrode, so that the external oil tank 400 is mounted differently. ) The height of the moisture and foreign substances separated in the lower part is separated by the difference in the length of the preset electrode 420? When the control unit 900, the anode of the electrode 420 is electrically energized by moisture, so that moisture and foreign substances are separated by a predetermined height? It is recognized and the second valve 430 can be controlled for a preset time to discharge moisture and foreign substances to the outside.

The control unit 900 is characterized in that the oil separated from the external oil tank 400 to the upper part by the heater 410 is injected back into the internal oil tank 300 through the first pump 700 .

The oil injected from the drain chamber 600 to the external oil tank 400 by the heater 410 is separated into oil, moisture, and foreign substances, and the oil in the upper part is reused by removing the mixed moisture, but the test can be performed accurately.

3, as a control method for controlling the low-temperature hydraulic test apparatus 1000 according to the present invention, as a control method for controlling the low-temperature hydraulic test apparatus 1000, the oil from the external oil tank 400 is transferred to the internal oil tank ( 300) a first oil injection step (S10); an oil cooling step (S11) of cooling the oil in the internal oil tank 300 by the cooling chamber 100; a second oil injection step (S12) of injecting the cooled oil from the internal oil tank 300 into the test object 200; and an oil return step (S14) of injecting the oil used for the test of the test subject 200 into the external oil tank 400 through the return line 500.

In the first oil injection step (S10), the oil in the external oil tank 400 is injected into the internal oil tank 300 in an uncooled state, so that it can flow easily, and in the oil cooling step (S11), the internal oil tank ( 300), the oil can be cooled in a state in which the oil is stabilized. In the second oil injection step (S12), oil may be injected into the test object 200, and a low-temperature hydraulic pressure may be applied to the test object 200 to proceed with the test. In addition, by injecting the oil used for the test in the oil return step (S14) into the external oil tank 400, the oil can be reused.

In the first oil injection step (S10), the oil from the external oil tank 400 is injected into the internal oil tank 300 by the first pump 700 connected between the external oil tank 400 and the internal oil tank 300 . characterized by being

By controlling the first pump 700 to inject oil into the internal oil tank 300 , the oil injected from the internal oil tank 300 can be transferred to the oil cooling step S11 .

The second oil injection step (S12) is characterized in that the oil in the internal oil tank 300 is injected into the test subject 200 due to the pneumatic pressure of the air compressor 800 connected to the internal oil tank 300 .

In the second oil injection step (S12), by injecting the cooled oil into the test subject 200 pneumatically through the air compressor 800, stable injection is possible.

It further comprises a drain step (S13) of collecting the oil used in the test object, and in the drain step (S13), the oil used in the test object is collected by the drain chamber (600).

The oil return step (S14) is characterized in that the oil collected in the drain step (S13) is injected into the external oil tank (400).

By reusing the oil used in the test through the oil return step (S14), there is an effect of reducing oil cost.

The oil heating step (S15) of heating the oil inside the external oil tank 400 through the heater 410 mounted on the external oil tank 400; further comprising, the oil heating step (S15) is the drain chamber 600 ) by heating the oil injected into the external oil tank 400 to separate oil, moisture and foreign substances into upper and lower parts by specific gravity.

The oil cooled in the oil heating step (S15) is made of moisture and foreign substances, and by heating it, the oil, moisture, and foreign substances in the external oil tank 400 are separated into the upper part and the lower part, and the oil in the upper part maintains the viscosity. And even if it is reused, there is no hindrance to the test.

Moisture confirmation step (S20) of checking the height of the moisture and foreign substances separated in the oil heating step (S15); and an impurity discharge step (S21) of discharging moisture and foreign substances to the outside through the second valve 430 connected to the external oil tank 400; When it is confirmed that oil and moisture are separated by a predetermined height by the electrode 420 provided therein, the impurity discharge step (S21) is started.

Through the impurity discharge step (S21), the oil is separated from moisture and foreign substances, and the moisture and foreign substances are discharged by the second valve provided in the lower part of the external oil tank 400, so that moisture and foreign substances are discharged inside the external oil tank 400. It has the effect of being prepared only with unmixed oil.

The oil separated from moisture and foreign substances in the oil heating step (S15) is again injected into the internal oil tank (300).

The oil in the external oil tank 400 separated in the oil heating step (S15) may be circulated through the first oil injection step (S10).

Although shown and described with respect to specific embodiments of the present invention, it is common in the art that the present invention can be variously improved and changed without departing from the spirit of the present invention provided by the following claims. It will be self-evident to those who have the knowledge of

100: cooling chamber 110: cooling device
200: test subject 210: first valve
300: internal oil tank 400: external oil tank
410: heater 420: electrode rod
430: second valve 500: return line
510: second pump 600: drain chamber
610: oil level sensor 700: first pump
800: air compressor 900: control unit
1000: low temperature hydraulic test device

Claims (17)

a cooling chamber provided with a cooling device for lowering the internal temperature;
an internal oil tank provided inside the cooling chamber to inject oil into the test object inside the cooling chamber;
an external oil tank provided outside the cooling chamber to inject oil into the internal oil tank;
a return line for injecting used oil into an external oil tank after the test of the test subject; and
A low-temperature hydraulic test apparatus comprising a; a control unit for controlling the injection of oil from the external oil tank to the internal oil tank and the injection of oil from the internal oil tank to the test object. The method according to claim 1,
The internal oil tank is formed in plurality,
A first pump connected between the external oil tank and the internal oil tank to inject oil from the external oil tank into the internal oil tank; further comprising,
The control unit controls the operation of the first pump to inject oil from the external oil tank to the internal oil tank before the start of the test. The method according to claim 1,
An air compressor provided outside the cooling chamber and connected to the internal oil tank to inject the oil in the internal oil tank into the test target by pneumatic pressure;
The control unit controls the operation of the air compressor to inject the cooled oil into the test object after the oil injected into the internal oil tank is cooled at the start of the test. The method according to claim 1,
A first valve for controlling the inflow of oil from the internal oil tank to the test object; further comprising,
The control unit is a low-temperature hydraulic test apparatus, characterized in that for controlling the first valve to apply or release the inflow of oil from the internal oil tank to the test object. The method according to claim 1,
A low-temperature hydraulic test apparatus, characterized in that it further comprises; a drain chamber for collecting the oil used after the test of the test subject. 6. The method of claim 5,
The drain chamber further includes an oil level sensor that measures the height of the oil inside;
The return line includes a second pump for injecting the oil from the drain chamber into the external oil tank.
When it is confirmed by the oil level sensor that the oil is collected in the drain chamber by a predetermined amount, the control unit controls the operation of the second pump to inject the collected oil into the external oil tank. . The method according to claim 1,
The external oil tank includes a heater for increasing the temperature of the oil inside the external oil tank;
A low-temperature hydraulic test device, characterized in that the heater raises the oil temperature inside the external oil tank and separates oil, moisture, and foreign substances into upper and lower parts by specific gravity. 8. The method of claim 7,
The external oil tank is provided inside and the anode and the cathode have different lengths; and
It further includes; a second valve provided at the lower portion of the external oil tank for discharging the material inside the external oil tank;
The control unit operates the second valve when it is confirmed that the oil and moisture separated by the heater are separated to a preset height by the electrode by the electrode, and the low-temperature hydraulic test device, characterized in that the moisture and the foreign substances are discharged . 8. The method of claim 7,
The control unit injects the oil separated to the upper part by the heater from the external oil tank back into the internal oil tank through the first pump. As a control method for controlling the low-temperature hydraulic test apparatus of claim 1.
a first oil injection step of injecting oil from the external oil tank into the internal oil tank;
an oil cooling step of cooling the oil in the internal oil tank by the cooling chamber;
a second oil injection step of injecting oil from the cooled internal oil tank as a test object; and
An oil return step of injecting the oil used for the test of the test subject into an external oil tank through a return line; a control method of a low-temperature hydraulic test device comprising a. 11. The method of claim 10,
In the first oil injection step, the oil from the external oil tank is injected into the internal oil tank by a first pump connected between the external oil tank and the internal oil tank. 11. The method of claim 10,
The second oil injection step is a control method of a low-temperature hydraulic test apparatus, characterized in that the oil in the internal oil tank is injected as a test subject due to the pneumatic pressure of the air compressor connected to the internal oil tank. 11. The method of claim 10,
A drain step of collecting the oil used in the test subject; further comprising,
In the drain step, a control method of a low-temperature hydraulic test device, characterized in that the oil used for the test object is collected into a drain chamber. 14. The method of claim 13,
The oil return step is a control method of a low-temperature hydraulic test device, characterized in that the oil collected in the drain step is injected into an external oil tank. 14. The method of claim 13,
Further comprising; an oil heating step of heating the oil inside the external oil tank through a heater mounted on the external oil tank;
The oil heating step is a control method of a low-temperature hydraulic test apparatus, characterized in that by heating the oil injected into the external oil tank from the drain chamber, the oil, moisture, and foreign substances are separated into upper and lower parts by specific gravity. 16. The method of claim 15,
Moisture checking step of checking the height of the water and foreign substances separated in the oil heating step; and
Further comprising; an impurity discharge step of discharging moisture and foreign substances to the outside through the second valve connected to the external oil tank;
In the moisture confirmation step, when it is confirmed that the oil and water are separated by a predetermined height by the electrode provided inside the external oil tank, the impurity discharge step is started. 16. The method of claim 15,
The control method of a low-temperature hydraulic test device, characterized in that the oil separated from moisture and foreign substances is injected back into the internal oil tank.

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