KR100731146B1 - A evaluating performance test equipments of hydrogen storage - Google Patents

Abstract

An apparatus for evaluating hydrogen storage performance of a hydrogen storage tool is provided to improve evaluation convenience, rapidness and accuracy of hydrogen adsorption and release properties for the hydrogen storage tool by automatically controlling the pressure, temperature and time for hydrogen adsorption. The apparatus for evaluating hydrogen storage performance of the hydrogen storage tool comprises: a hydrogen supplying pipe(10) through which hydrogen gas is introduced; an inert gas supplying pipe(20) connected to the center of the hydrogen supplying pipe; test cells(100) for storing hydrogen, installed in the end of the hydrogen supplying pipe; a vacuum pipe connected to a high vacuum pump(31) for removing air from a region of the hydrogen supplying pipe at which the test cell is installed; and a thermostat(80) connected to a circulation device(93) capable of differently controlling the temperature of each test cells so as to perform the tests in the test cells at different temperature, wherein the pipes contain at least one valve(11, 21, 12, 22, 16, 33, 34, 41, 51, 52, 61a, 62a, 63a, 101) for controlling the flow of fluid. The apparatus comprises a controller(90) for controlling operation of the valves and components, and calculating hydrogen absorption amount by using the evaluated values from each device.

Description

A evaluating performance test equipments of hydrogen storage

1 is a block diagram showing the configuration of an apparatus for evaluating hydrogen storage performance of a hydrogen storage body according to the present invention.

* Description of symbols on the main parts of the drawings *

10: hydrogen supply pipe 11, 21: pressure control valve

12, 22: ball valve 13: line filter

14, 35: mass flow regulator 15: check valve

16, 33, 34, 41, 51, 52, 61a, 62a, 63a, 101: high pressure bellows valve

20 helium supply pipe 30 vacuum pipe

31: high vacuum pump 32: vacuum regulator

40, 50: buffer tank 42: reference cell

70: heating furnace 90: controller

91: processing temperature sensor 92: water temperature sensor

93: circulator 100: test cell

110: Dewar bottle 111: liquid nitrogen tank

The present invention relates to an apparatus for evaluating the hydrogen storage performance of a hydrogen storage body, in particular, other hydrogen storage bodies including alloys are low vacuum (10 ^-8 Torr), ultra high pressure (300 Bar), cryogenic (-196 ℃), high temperature (at room temperature The present invention relates to an apparatus for evaluating hydrogen storage performance of a hydrogen storage body for measuring and analyzing the intake and release amount of hydrogen in an extreme environment such as 1000 ° C.).

In addition, the present invention can be evaluated by measuring the adsorption-desorption characteristics of the target gas of all the adsorbents.

In general, a method of measuring the storage amount of a gas stored in a storage body in which hydrogen is stored includes a volume method of obtaining a storage amount by measuring pressure, temperature, volume, etc. when the gas is adsorbed to the storage body, and Gravimetric method for measuring the weight change before and after gas adsorption and flow that calculates the storage volume by integrating the breakdown curve by measuring the change in concentration at the outlet after passing the mixed gas of certain concentration through the gas adsorbed reservoir through the reactor Column method;

The method of measuring the storage amount of such a gas storage body has advantages and disadvantages, and in particular, a gravimetric method is frequently used.

However, the gravimetric method is expensive because accurate electronic balance is required, and the noise of the initial stage of adsorption remains a big problem due to the flow of gas at the time of supplying the adsorption gas. Not only is it difficult, but there is a problem in that the accurate storage amount cannot be measured due to the distortion of the storage amount due to buoyancy and the vortex shape caused by gas dosing.

In addition, the flow column method requires a large amount of adsorbent and consumes a lot of raw gas to obtain the adsorption amount, and the volume method can obtain a characteristic value for reliable gas adsorption and desorption with only a small amount of adsorbent and raw material gas. The temperature of the and gas supply tanks must be kept constant, and accurate volume and pressure measurements must be taken to obtain reliable data.

In addition, the above-described storage measuring method is difficult to control the desired adsorption and desorption pressure by manually operating the valve in supplying and discharging gas, and it is impossible to maintain each reactor at a minute temperature, so the reliability of the measured value is high. There was a downside to falling.

The present invention has been made to solve the above problems of the prior art, and automates the control of adsorption pressure, adsorption temperature and adsorption time of adsorption gas, which acts as an important factor in the measurement of adsorption and desorption characteristics of hydrogen in a hydrogen reservoir. This makes it easier and faster to measure the hydrogen adsorption and desorption characteristics of the reservoir, and provides more reliable data, as well as fine control of the hydrogen supply and discharge pressure, the temperature of the reactor, and the reaction holding time. It is an object of the present invention to provide an apparatus for evaluating hydrogen storage performance of a hydrogen storage body.

An object of the present invention as described above and the hydrogen supply pipe into which the hydrogen gas flows; An inert gas supply pipe connected to an interruption of the hydrogen supply pipe; A test cell which is a hydrogen storage body installed at an end of the hydrogen supply pipe; A vacuum pipe connected with a high vacuum pump for vacuuming the hydrogen supply pipe in which the test cell is installed; The test cell is configured to include a thermostat connected to a circulating device capable of adjusting the temperature so that the experiment can be carried out at different constant temperatures, each of the pipe is provided with one or more valves to control the flow of fluid flowing inside the pipe And a controller for controlling the driving of the valve and each component and for calculating a hydrogen absorption amount from the values measured from the respective measuring devices.

Hereinafter, an apparatus for evaluating hydrogen storage performance of a hydrogen storage body according to the present invention will be described in detail with reference to the accompanying drawings.

As illustrated, the hydrogen storage performance evaluation apparatus of the hydrogen storage body according to the present invention includes a hydrogen supply pipe 10 to which hydrogen as a raw material is supplied, and an inert gas supply pipe 20.

A test cell 100, which is a hydrogen storage body, is installed at an end of the hydrogen supply pipe 10, and a high vacuum pump 31 is connected to a hydrogen supply pipe 10 in which the test cell 100 is installed in a vacuum state. Further vacuum piping is installed.

The hydrogen supply pipe 10 is connected to a hydrogen storage tank, and as a control means for controlling the flow of fluid, a ball valve 12, a mass type micro flow regulator 14, a check valve 15 and a high pressure bellows valve ( 16), a line filter 13 is provided as a means for removing impurities from the fluid.

In addition, a pressure control valve 11 for adjusting the pressure of the hydrogen discharged from the storage tank and a line filter 13 for filtering foreign substances in the supplied hydrogen is further provided.

The inert gas supply pipe 20 for the internal volume measurement and inspection is connected to the interruption of the hydrogen supply pipe 10, and the pressure control valve 21 and the ball valve 22 are installed and the amount of gas supplied thereto. The pressure can be controlled.

The ball valves 12 and 22 are manually operated valves, which are manually opened when driving the evaluation system of the present invention, and the mass flow regulator 14 is connected to a controller 90 to be described later while the evaluation system is driven. It is controlled by the step of increasing the amount of each fluid flowing in the pipe at a constant pressure step by step, and when measuring the storage volume, it prevents a sudden pressure rise, and serves to adjust the fine flow rate to accurately reach the step-by-step pressure to the target pressure.

The check valve 15 is a valve for preventing the fluid in the pipe from flowing back to the respective storage tanks when the fluid flow in the pipe is stopped due to a predetermined cause, i.e., other reasons such as the failure of the entire apparatus.

The high pressure bellows valve 16 is controlled by the controller 90 such as the mass flow controller and opened and closed by means of controlling the flow of the fluid whose flow rate is controlled by the mass flow controller 14.

At the end of the hydrogen supply pipe 10 configured as described above, the test cell 100 as the hydrogen storage body is detachably installed, and the hydrogen supply pipe 10 supplies pure hydrogen to the test cell 100. In order to maintain a vacuum state, a vacuum pipe 30 is installed as the vacuum means.

The vacuum pipe 30 has a high vacuum pump 31 is installed at one end, the other end is connected to the interruption of the hydrogen supply pipe 10, the high vacuum pump 31 is driven to the hydrogen supply pipe 10 The inside of the vacuum becomes a vacuum state, and hydrogen is stored in the test cell 100 by supplying hydrogen through the hydrogen supply pipe 109 in a vacuum state.

At the stop of the vacuum pipe 30, a vacuum regulator 32 for adjusting the degree of vacuum and a high pressure bellows valve 33 for opening and closing the flow path are further installed.

In addition, when the discharge amount is measured for the purpose of preventing a rapid flow rate discharge during the step of controlling the discharge flow rate and controlling the discharge pressure (eg, 20 times the release test method step by step at 50 kpa discharge pressure) during the desorption (release) test. In addition, an exhaust pipe provided with the micro flow rate control mass flow controller 35 is further provided.

One or more buffer tanks 40 and 50 are connected to the stop of the hydrogen supply pipe 10, and a reference cell 42 and one or more pressure sensors 61, are connected to one of the buffer tanks 40. 62 and 63 are created by range to reduce pressure measurement errors. That is, for example, 150psiA, 750psiA, and 1500psiA are installed to measure the accurate pressure change during the storage discharge test, and to detect the pressure in the pipe.

That is, it is possible to detect the pressure when hydrogen is supplied and to calculate the amount of storage stored in the test cell by the detected pressure change.

Process temperature sensor for sensing the temperature during the process of hydrogen is stored in the test cell 100 branched by the pipe connector at the end of the hydrogen supply pipe 10 is installed the test cell 100 ( 91) are installed.

Since the test of the test cell 100 may be performed at a constant temperature to obtain accurate data, the test cell 100 and the buffer tanks 40 and 50 may be raised to lock the inside of the thermostat by raising the thermostat 80. Perform the measurement while maintaining the temperature. The thermostat 80 is lowered by the controller to activate the sample in the test cell 100, and the heating furnace 70 is mounted on the test cell 100 to pressurize the heat and vacuum pressure by the controller program according to the activation condition of the reservoir. The storage process is activated through the process of activation.

A water temperature sensor 92 is installed in the thermostat 80 to detect the temperature of the thermostat, and the temperature sensed by the water temperature sensor 92 is transmitted to the controller 90 as a temperature condition to be tested. Allow the thermostat to maintain a constant temperature.

The heating furnace 70 was able to be used in the experiment at any required temperature range from room temperature to 1000 ℃ depending on the activation process and storage characteristics of the hydrogen storage.

In addition, when the experiment is necessary in the cryogenic temperature range from room temperature to -196 ℃ liquid nitrogen stored in the liquid nitrogen tank 111 is supplied to the Dewar bottle (110) connected to the test cell 100 Dewar bottle temperature sensor The temperature sensed by 94 was transmitted to the controller 90 to allow for experiments on the characteristics of the reservoir in the desired cryogenic state from 0 to -196 ° C.

The control of each valve, sensor, heating furnace, etc. is performed by a controller 90 composed of a microprocessor or a computer, and reflects programs for various experimental methods according to the characteristics of the specific reservoir, ideal gas and actual It also reflects the alternatives to applying constants to the gas state equation (EOS) to represent real-time measurement data, monitor real-time change trends through graphs, and perform trend tracking using scroll bars. Ideal programs can be developed and applied.

The apparatus for evaluating the hydrogen storage performance of a hydrogen storage body according to the present invention configured as described above controls the adsorption pressure, adsorption temperature, and adsorption time of adsorption gas acting as an important factor in the measurement of adsorption and release characteristics of hydrogen in the hydrogen storage body. Automated and simpler and faster measurement of hydrogen adsorption and desorption characteristics of the reservoir, not only to obtain more reliable data, but also to finely control the supply and discharge pressure of hydrogen, the temperature of the reactor, and the reaction holding time Makes it possible.

Claims (4)

A pressure regulating valve for regulating the pressure of the supplied fluid, a ball valve for manually controlling the flow of hydrogen supplied from the storage tank, a line filter for filtering impurities, a high pressure bellows valve for automatically opening and closing the flow path, A check valve for preventing a back flow of the fluid, and a hydrogen supply pipe through which hydrogen gas is introduced; An inert gas supply pipe connected to an interruption of the hydrogen supply pipe and provided with a pressure control valve for adjusting a pressure of a fluid to be supplied, and a ball valve manually controlled to control the flow of hydrogen supplied from a storage tank; A test cell which is a hydrogen storage body installed at an end of the hydrogen supply pipe; A high vacuum pump is connected to the hydrogen supply pipe in which the test cell is installed in a vacuum state, and includes a vacuum regulator for controlling the amount of air sucked by the high vacuum pump and at least one high-pressure bellows valve to control the flow path. A vacuum pipe which is connected in parallel and has a mass flow controller for controlling the discharge flow rate and pressure in the discharge pipe; The test cell is provided with a circulator for maintaining a constant temperature by heating the stored water so that the experiment can be carried out at different constant temperatures and a water temperature sensor for controlling the same, one or more buffer tanks in the interruption of the hydrogen supply pipe One of these buffer tanks is connected to a reference cell to which the test cell is to be compared and one or more pressure sensors, and the temperature in the pipe during the reaction process is adjacent to the end where the test cell of the hydrogen supply pipe is installed. A thermostat with further processing temperature sensors for sensing; An electric furnace capable of experimenting at the activation of the high temperature and the high temperature; It is configured to include a dewar bottle of low temperature regulator liquid nitrogen that can be precisely low temperature experiment at any temperature within the cryogenic range, Each of the pipes includes one or more valves for regulating the flow of fluid flowing inside the pipe, and a controller for controlling the driving of the valve and each component and calculating the hydrogen absorption amount from the values measured from the respective measuring devices. Apparatus for evaluating hydrogen storage performance of a hydrogen storage body, characterized in that. delete delete delete

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