KR20240043208A - Evaluation apparatus for hydrogen pressure - Google Patents

Abstract

A high-pressure hydrogen evaluation device including a first pressurizing unit that receives air and pressurizes it and a second pressurizing unit that receives air pressurized by the first pressurizing unit and pressurizes the air is disclosed.

Description

High-pressure hydrogen evaluation device {EVALUATION APPARATUS FOR HYDROGEN PRESSURE}

The present invention relates to an evaluation device that can evaluate high-pressure hydrogen or high-pressure nitrogen.

In particular, the present invention relates to an improved evaluation device that solves problems in evaluating existing high-pressure hydrogen or high-pressure nitrogen.

Hydrogen is in the spotlight as a new energy source. Recently, as the demand for eco-friendly energy increases, parts using hydrogen are being manufactured, and the use of these parts is spreading to all fields.

What is most needed for parts using hydrogen is a device that controls and evaluates pressure. Because hydrogen is light and highly explosive, handling high-pressure hydrogen can be considered life-threatening.

However, handling high-pressure hydrogen requires precise devices, and most of these devices are expensive and difficult to order and manufacture. In addition, devices utilizing high-pressure hydrogen are experiencing frequent minor breakdowns due to the high pressure.

Therefore, most companies currently request performance tests from overseas to check whether the product operates, rather than testing the performance of the parts themselves. As a result, problems such as the company's funds being leaked overseas and the inability to properly inspect performance are occurring.

The purpose of the present invention is to solve the problems described above and to provide a device that ensures safety when controlling high-pressure hydrogen pressure.

In addition, the purpose of the present invention according to one embodiment is to provide a device that does not frequently break down and is easy to repair even if a break down occurs.

In addition, the present invention according to one embodiment can supply hydrogen at a set pressure, allowing self-assessment of performance/safety.

The present invention according to one embodiment may include a first pressurizing unit that receives air and pressurizes it, and a second pressurizing unit that receives air pressurized by the first pressurizing unit and pressurizes the air.

It may further include a tank part in which air supplied by the first pressurizing part is located between the first pressurizing part and the second pressurizing part.

It may include a chamber part connected to the second pressurizing part, and the second pressurizing part and the chamber part may be connected through a connection pipe part.

The connection pipe part is connected to the second pressurizing part, and is disposed in a form that surrounds a gland in which the other side has a smaller diameter than one side and a flow path of a set diameter is formed, and the part in which the diameter of the gland is reduced. It may be characterized by including a coupler formed with a flow path communicating with the flow path.

The first pressurizing part may be connected to a recovery line through which air connected to the consumed air is supplied again.

The present invention according to one embodiment can be formed with the above configuration to ensure safety.

Meanwhile, in the present invention according to one embodiment, the connection between devices is strong so that no breakdown occurs, and even if a breakdown occurs, it can be repaired very easily.

Additionally, since the present invention according to one embodiment pressurizes hydrogen in two stages, hydrogen at a set pressure can be applied.

Figure 1 shows a high-pressure hydrogen evaluation device of the present invention according to an embodiment.
Figure 2 shows the connector part of the high-pressure hydrogen evaluation device of the present invention according to one embodiment.
Figure 3 shows with emphasis the recovery line of the high-pressure hydrogen evaluation device of the present invention according to one embodiment.

Since the present invention can be modified in various ways and can have various embodiments, specific embodiments will be exemplified and explained in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all transformations, equivalents, and substitutes included in the spirit and technical scope of the present invention.

The terms used in the present invention are only used to describe specific embodiments and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In the present invention, terms such as 'include' or 'have' are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. At this time, note that in the attached drawings, like components are indicated by the same symbols whenever possible. Additionally, detailed descriptions of well-known functions and configurations that may obscure the gist of the present invention will be omitted. For the same reason, some components are exaggerated, omitted, or schematically shown in the accompanying drawings.

Figure 1 shows a high-pressure hydrogen evaluation device of the present invention according to an embodiment.

Figure 2 shows the connector part of the high-pressure hydrogen evaluation device of the present invention according to one embodiment.

Figure 3 shows with emphasis the recovery line of the high-pressure hydrogen evaluation device of the present invention according to one embodiment.

The high-pressure hydrogen evaluation device of the present invention according to one embodiment may include a pressurizing unit 100, a chamber unit 200, an evaluation unit, and a recovery line 500.

The pressurizing unit 100 can pressurize gas into high-pressure gas. The pressing unit 100 may include a first pressing unit 110 and a second pressing unit 130. Here, the pressurizing unit 100 of the present invention can pressurize using the air boosting method.

The first pressurizing unit 110 may pressurize gas through a low pressure booster. The first pressurizing unit 110 may have a compression ratio of about 30 times. That is, the first pressurizing unit 110 can perform 30 times compression. That is, the first pressurizing unit 110 can compress 7 bar gas 30 times and pressurize it to 210 bar. Here, since the nitrogen supplied from the main gas tank to the first pressurizing unit 110 is 20 bar, a total of 230 bar of pressurized gas can be supplied to the second pressurizing unit 130.

The second pressurizing unit 130 can pressurize the gas through a high pressure booster. The second pressurizing unit 130 may have a compression ratio of 150 times. That is, the second pressurizing unit 130 can perform 150 times compression. That is, the second pressurizing unit 130 can compress 8.5 bar gas 150 times and pressurize it to 1250 bar. Therefore, the air pressurized to high pressure through the second pressurizing unit 130 is supplied together with the 230 bar gas pressurized by the first pressurizing unit 110, so a total of 1,505 bar of gas can be supplied to the chamber unit 200.

Meanwhile, a tank unit 120 in which air pressurized through the first pressurizing unit 110 is located may be disposed between the first pressurizing unit 110 and the second pressurizing unit 130.

Additionally, the pressure of the air supplied from the second pressurizing unit 130 to the chamber unit 200 can be changed by an expansion valve. That is, the expansion valve linearly changes the area of the valve and supplies pressure at a variable level, so that gas at a set pressure can be supplied to the chamber unit 200.

The chamber unit 200 may be connected to the second pressurizing unit 130 and the connector unit 400, and the chamber unit 200 may be connected to the control unit 300 again through the connector unit 400. Here, the chamber unit 200 may be a temperature variable chamber whose temperature can be changed.

The present invention is connected between the second pressurizing part 130 and the chamber part 200, and between the chamber part 200 and the control part 300 through a connector part 400, so that the coupling is detachably connected, thereby improving convenience. It is characterized by being In the past, due to the nature of high-pressure equipment, all devices were connected integrally due to concerns about piping leakage. However, in this case, maintenance and repairs are difficult. The present invention is characterized in that each part is connected through a unique connector part 400 to solve this problem.

The connector portion 400 may include a gland 410, a collar 430, and a coupler 420.

That is, with the coupler 420 in between, the gland 410 is assembled on the left and the collar 430 is assembled on the right, as shown in FIG. 2.

Here, the coupler 420 has a diameter on the left side that is larger than the diameter on the right side, as can be seen in (a) of FIG. 2. And the diameter of the center portion of the coupler 420 is arranged to be the same as the diameter of the right side.

However, the inner space of the coupler 420 is formed on the left side to be larger than the right side. Here, the gland 410 is formed to have a smaller diameter on the right side than on the left side. Therefore, the left side of the coupler 420 is arranged to surround the right side of the gland 410.

A coke 430 may be placed on the right side of the coupler 420. The collar 430 has a shape corresponding to the gland 410 and has a diameter on the left side that is smaller than the diameter on the right side. Therefore, the right side of the coupler 420 may be arranged to surround the left side of the collar 430.

That is, based on the coupler 420, the gland 410 and the collar 430 may be arranged in a shape that is surrounded by the left and right sides of the coupler 420, respectively.

The coupler 420 may include a small flow path between the left and right sides. Here, the flow path of the coupler 420 is formed to communicate with the flow path of the gland 410 and the flow path of the collar 430.

And a nut 440 may be disposed on the outside of the coupler 420. Here, since the nut 440 presses the coupler 420, the airtightness of the coupler 420, the collar 430, and the gland 410 can be strengthened by pressing the coupler 420 more strongly.

In this way, the connection pipe portion 400 of the present invention is connected to pipes each connected through a gland 410, a coupler 420, and a collar 430. Therefore, the present invention can increase confidentiality between each component. At the same time, if necessary, the gland 410, coupler 420, and collar 430 can be separated and each component can be dismantled for inspection, repair, etc. However, the present invention can connect each component airtightly by interconnecting them later.

Additionally, the present invention may further include a recovery line 500. The recovery line 500 may be a recycled line to reuse the utilized high-pressure gas.

As can be seen in Figure 3, the recovery line 500 of the present invention may include a recovery pressure tank and a solenoid valve.

To reuse high-pressure gas, the high-pressure gas must be decompressed. However, if you want to depressurize a high-pressure gas, a lot of time may be consumed. In order to solve this problem, the present invention includes a recovery pressure tank and a solenoid valve to shorten the decompression time.

When high-pressure gas is supplied, the recovery pressure tank can recover some of the high-pressure gas. Here, the recovery pressure tank may refer to tanks that supply gas. That is, it may be a main tank that supplies gas and a tank that is connected to the main tank and is branched and connected to a line through which high-pressure recovered gas is supplied. They store some of the high-pressure gas and play the role of lowering the pressure of the high-pressure gas.

And, if needed later, it can serve to supply the stored gas back to the line. Therefore, the present invention can shorten the time for decompression.

The solenoid valve can discharge high-pressure gas to a safely connected outside depending on the power supply. That is, the solenoid valve can open the valve when power is supplied to release gas to the outside.

As such, the present invention uses a plurality of recovery pressure tanks and a solenoid valve to form a gas bypass line, thereby shortening the decompression time and resupplying the gas so that it can be used semi-permanently.

Above, an embodiment of the present invention has been described, but those skilled in the art can add, change, delete or add components without departing from the spirit of the present invention as set forth in the patent claims. The present invention may be modified and changed in various ways, and this will also be included within the scope of rights of the present invention.

100: Pressure part
110: first pressurizing part
120: tank part
130: second pressurizing part
200: Chamber part
300: control unit
400: Connector part
410: gland
420: Coupler
430: Cola
440: nut
500: recovery line

Claims (5)

A first pressurizing unit that receives air and pressurizes it; and
A second pressurizing unit that receives air pressurized by the first pressurizing unit and pressurizes the air.
A high-pressure hydrogen evaluation device comprising a. According to paragraph 1,
Between the first pressurizing part and the second pressurizing part, it further includes a tank part where the air supplied by the first pressurizing part is located.
A high-pressure hydrogen evaluation device characterized by a. According to paragraph 1,
It includes a chamber part connected to the second pressurizing part,
The second pressurizing part and the chamber part are connected through a connector part.
A high-pressure hydrogen evaluation device characterized by a. According to paragraph 3,
The connector part
It is connected to the second pressurizing part, and is disposed in a form that surrounds a gland in which the diameter of the other side is reduced compared to one side and a flow path of a set diameter is formed, and the part of the gland with a reduced diameter, and is in communication with the flow path of the gland. Containing a coupler with a flow path formed
A high-pressure hydrogen evaluation device characterized by a. According to paragraph 1,
The first pressurizing part is connected to a recovery line through which air connected to the consumed air is supplied again.
A high-pressure hydrogen evaluation device characterized by a.

Images