KR20180094569A - Hydrogen holding capacity measuring device - Google Patents

Abstract

The present invention relates to a device to measure a hydrogen storage capacity and, more specifically, to the device to measure a hydrogen storage capacity, which includes a pressure detection unit to increase reliability in a hydrogen storage capability test. According to the present invention, the device to measure a hydrogen storage capacity comprises: a hydrogen generation unit (100) to generate hydrogen for measuring a hydrogen storage capability of a plate-structured test target (1); and a hydrogen measurement unit (200) to measure whether the hydrogen generated from the hydrogen generation unit (100) penetrates the plate-structured test target (1). The hydrogen measurement unit (200) comprises: a pressure detection unit (210) to detect a pressure change as the hydrogen generated from the hydrogen generation unit (100) penetrates the plate-structured test target (1); and a hydrogen penetration time measurement unit (230) to measure an elapsed time (Δt) from an operate time (T_i) of the hydrogen generation unit (100) to a time (T_e) when the pressure changed detected by the pressure detection unit (210) is fit to a preset condition.

Description

[0001] Hydrogen holding capacity measuring device [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a hydrogen storage capacity measuring apparatus, and more particularly, to a hydrogen storage capacity measuring apparatus provided with a pressure sensing unit.

Generally, in the production of an enamel steel sheet, water vapor and enamel coating glaze moisture are hydrolyzed during the firing process, resulting in generation of hydrogen gas and solidification of the steel sheet.

If the hydrogen solubilization capacity (also referred to as hydrogen storage capacity) of the steel sheet is insufficient, the hydrogen dissolved in the steel sheet structure becomes supersaturated during the cooling process, and hydrogen of the supersaturated powder is discharged to the outside of the steel sheet structure do. At this time, the enamel coating layer coated on the surface of the steel sheet causes a fish scale phenomenon in which fish scale-like cracks are generated by the supersaturated hydrogen gas pressure as described above.

The degree of occurrence of the fish scale phenomenon as described above is related to the hydrogen employment ability of the enamel steel sheet, which determines the quality of the product. The larger the hydrogen employment capacity is, the smaller the possibility of occurrence of the fish scale becomes.

On the other hand, the hydrogen employment ability of the steel sheet for enamel is evaluated through the hydrogen permeation test. The hydrogen permeation test is carried out to investigate the diffusion behavior of hydrogen or to evaluate the resistance to the fish scale of an enamel steel sheet. The time taken until the hydrogen generated at one side of the steel sheet test specimen passes through to the opposite side of the specimen is measured will be.

The longer the measured hydrogen permeation time, the greater the hydrogen abstraction capacity of the steel sheet. This is because the time required for the hydrogen generated from one side of the steel sheet to be saturated with the inside of the steel sheet and then transmitted to the opposite side becomes longer as the hydrogen solubility of the steel sheet increases.

As known measurement methods, there are an electrochemical method, a visual observation method, a method using a gas chromatograph, and a volumetric method. An electrochemical method measures a current generated when a hydrogen atom causes a molecular reaction on the transmission surface of a steel sheet , The visual observation method is a method of directly observing the formed hydrogen bubbles, and a method of using gas chromatography is a method of analyzing the amount of hydrogen generated by using a carrier gas such as argon (Ar) by gas chromatography, The amount of hydrogen bubbles in the trapped aqueous solution is measured by a change in the tank.

The electrochemical method [Korean Patent No. 92744] can measure the hydrogen permeation time comparatively accurately, such as obtaining the diffusion coefficient of hydrogen. However, preprocessing and preparation of the specimen such as palladium (Pd) There is a problem that it is difficult.

The visual inspection method [Korean Patent Registration No. 149691] is the most widely used method for the hydrogen permeation test of the steel plate for bumper steel, which is advantageous in that the production cost of the measuring device is low. However, since the test piece must be observed for a long time, There is a problem in that the measurement error is very large because the result is caused or the result may vary according to the observer's subjective opinion.

Using the gas chromatograph [Harada Toshihiro; Kawasaki Tetsuki Technical Report, 5 (1973) 2, p.242], it is possible to evaluate the amount of generated hydrogen accurately, but since the measurement period is very long, hydrogen permeation There is a problem that the thin steel sheet which can occur can not be measured.

As a means of solving this problem, when a certain amount of dye solution is put into a capillary having an inner diameter of 1 mm or less and the height of the order is changed by the amount of generated hydrogen bubbles, the volume of the capillary is multiplied by the cross- However, since the optical sensing device is used to measure the change in the height of the order, the dye must be added to the solution of the permeation tank, and since the optical sensing device is repeatedly moved vertically to obtain the height change, There is a problem that the noise signal is disturbed by the influence of the external light source.

Also, if the water droplets remaining inside the capillary tube are not blown off with dry air after the test, it is difficult to automate the hydrogen permeation test because the following test results are different due to the compression phenomenon of the trapped air between the water droplet and the water- have.

Another volumetric method is to use a capacitive level sensor to measure the height of the liquid, which has the advantage of being able to detect micro-height changes in the liquid, while the volume change of the liquid due to heat generated during electrolysis There is a problem in that it is difficult to prevent even a very small amount of leak in the production of the apparatus because it is a method of measuring errors in measurement and basically measuring the volume of minute volume of the apparatus and there is a problem that it is vulnerable to a working environment such as vibration .

It is an object of the present invention to provide a hydrogen permeation time measuring unit for measuring an elapsed time from a point of time when the hydrogen generator is operated to a time point when a pressure change sensed by the pressure sensor matches a preset condition And a hydrogen storage capacity measuring device.

SUMMARY OF THE INVENTION The present invention has been made to achieve the above-mentioned object of the present invention. The present invention provides a hydrogen generating apparatus comprising: a hydrogen generating unit for generating hydrogen for measuring a hydrogen-containing capability of a plate- And a hydrogen measurement unit 200 for measuring whether or not the hydrogen generated in the hydrogen generating unit 100 has passed through the inspection target 1 of the plate structure, A pressure sensing unit 210 for sensing a pressure change caused by the hydrogen generated in the generator 100 passing through the inspection target 1 of the plate structure; The elapsed time? T from the operating time T _i of the hydrogen generator 100 to the time point T _e at which the pressure change sensed by the pressure sensing unit 210 meets predetermined conditions is measured And a hydrogen permeation time measuring unit (230).

The hydrogen generating unit 100 forms a hydrogen generating space P1 together with the object to be inspected 1 and includes a container 110 in which an electrolytic solution containing an electrolyte is contained in the hydrogen generating space P1, ; And a power applying unit for applying power to each of the hydrogen generating space P1 and the inspection target 1 to generate hydrogen from the electrolytic solution containing the electrolyte.

The hydrogen measuring unit 200 includes a receiving space P2 containing distilled water and containing the hydrogen generated in the hydrogen generating unit 100 and permeated through the inspection target 1, A measurement space forming unit 220 having a measurement space P3 filled with a measurement gas so as to generate a change in volume and pressure in accordance with the amount of hydrogen permeated, A pressure sensing unit 210 installed in the measurement space P3 to sense a pressure change in the measurement space P3 by the flow of distilled water through the hydrogen permeated through the inspection object 1; A time point T _e at which the pressure change sensed by the pressure sensing unit 210 from the operation time T _i of the hydrogen generator 100 is in accordance with a predetermined condition, And a hydrogen permeation time measuring unit 230 for measuring the elapsed time up to a predetermined time.

The hydrogen measuring unit 200 may be configured to receive hydrogen generated in the hydrogen generating unit 100 and permeate the inspection object 1 and may include nitrogen and / A measuring space forming unit 220 forming a receiving space P2 into which at least one of argon is injected; A pressure sensing part 210 installed in the measurement space forming part 220 to sense the pressure of the accommodation space P2 changed by the hydrogen permeated through the inspection object 1; And a hydrogen permeation time measuring unit 230 connected to the pressure sensing unit 210 and measuring the elapsed time? T.

The hydrogen generating unit 100 and the hydrogen measuring unit 200 are arranged vertically and the inspection object 1 is automatically charged between the hydrogen generating unit 100 and the hydrogen measuring unit 200 And a transfer tool 400 for loading and unloading the object 1 to be inspected.

The hydrogen storage capacity measuring apparatus according to the present invention can detect a change in pressure in a measurement space which is changed by a flow of distilled water generated by hydrogen permeating the object to be inspected, Can be increased.

The hydrogen storage capacity measuring apparatus according to the present invention measures an elapsed time from a point of time when the hydrogen generator is operated to a time point when the pressure change in the measurement space sensed by the pressure sensing unit corresponds to a predetermined condition, There is an advantage that measurement is possible.

The hydrogen storage capacity measuring apparatus according to the present invention further comprises a transfer tool for loading and unloading an object to be inspected and a solution circulating, storing and filtering system for supplying, discharging and filtering the solution for inspection, And automation of the entire process for inspecting the inspection object.

In addition, the hydrogen storage capacity measuring apparatus according to the present invention is advantageous in that it is possible to carry out the inspection without subjecting the inspection object to a separate pretreatment, thereby facilitating preparation of the test procedure.

1 is a block diagram showing a hydrogen storage capacity measuring apparatus according to the present invention.
Fig. 2 is a conceptual diagram showing an example of the hydrogen storage capacity measuring apparatus of Fig. 1. Fig.

Hereinafter, a hydrogen storage capacity measuring apparatus according to the present invention will be described with reference to the accompanying drawings.

As shown in FIGS. 1 and 2, the hydrogen storage capacity measuring apparatus according to the present invention includes: a hydrogen generator 100 for generating hydrogen for measuring a hydrogen-containing capacity of an inspection object 1 having a plate structure; And a hydrogen measurement unit 200 for measuring whether or not the hydrogen generated in the hydrogen generation unit 100 has passed through the inspection object 1 having a plate structure. The hydrogen measurement unit 200 includes a hydrogen generation unit 100 A pressure sensing part 210 for sensing a pressure change due to permeation of the hydrogen generated in the test object 1 having the plate structure; Hydrogen permeability measuring the elapsed time t from the operating point T _i of the hydrogen generator 100 to the point of time T _e at which the pressure change sensed by the pressure sensing unit 210 meets a predetermined condition And a time measuring unit 230.

Here, the object 1 to be inspected can be various objects as long as the object is to measure the hydrogen-containing ability.

For example, the inspection object 1 may be an enamel steel sheet having a shape of a plate structure and measuring the hydrogen-containing ability.

The hydrogen generator 100 may have various configurations as long as the hydrogen generator 100 generates hydrogen permeating the inspection target 1 having a plate structure in order to measure the hydrogen-containing ability of the inspection target 1. [

For example, the hydrogen generating unit 100 forms the hydrogen generating space P1 together with the object to be inspected 1, and the container 110 in which the electrolytic solution containing the electrolyte is contained in the hydrogen generating space P1, Wow; And a power application unit for applying power to each of the hydrogen generation space P1 and the inspection object 1 to generate hydrogen from the electrolytic solution containing the electrolyte.

The container 110 may take various forms as long as it forms the hydrogen generating space P1 together with the object 1 so that the electrolytic solution containing the electrolyte can be contained therein.

The container 110 may be formed of various materials as long as it does not react with an electrolytic solution containing an electrolyte such as glass, acrylic, or Teflon.

Meanwhile, the container 110 may be further provided with a vertically movable upper portion for automation of the upper and lower motions.

The upper and lower portions are provided for automation of the upper and lower motions of the container 110, and various configurations are possible as long as they are provided for vertical movement of the container 110 such as an air cylinder, a mechanical cylinder, and the like.

For example, the container 110 is formed in a cylindrical shape having upper and lower openings, and can be placed on the upper side of the inspection target 1 by the upper and lower edges to form the hydrogen generating space P1.

At this time, a sealing means for preventing leakage of the electrolytic solution containing electrolyte may further be provided on the lower side of the container 110.

The sealing means may be provided to prevent leakage of the electrolytic solution. The sealing means may be provided in various positions as long as it is provided at a position where the container 110 and the object 1 are coupled to each other to prevent leakage of the electrolytic solution. It is possible.

As an example, the sealing means may be a sealing member 130 installed at a joining position of the container 110 and the object 1 to be inspected, as shown in Fig.

The electrolytic solution is a solution to be electrolyzed by a power application unit described later, and various solutions are possible.

By way of example, the electrolytic solution may comprise H ₂ SO ₄ , As ₂ O ₃ , HgCl ₂ ≪ / RTI >

 The electrolytic solution is preferably maintained at a specific temperature. The container 110 is provided with a temperature sensing unit (not shown) for measuring the temperature of the electrolytic solution and a temperature controller A temperature control unit 120 may be additionally provided.

The temperature regulator 120 may be configured to have a variety of configurations in which the temperature of the electrolytic solution can be maintained within a specific temperature range.

For example, the temperature regulating unit 120 includes a heat generating unit 121, a heat transfer rod 122 coupled to the heat generating unit 121 and extending into the interior of the container 110, And a cooling unit (not shown) for cooling the heat generating unit 121, and the like.

The power applying unit may be configured to generate hydrogen from an electrolytic solution containing an electrolyte, and may have a variety of configurations.

For example, the power applying unit may be electrically connected to the electrode unit 150 located inside the container 110 and the object to be inspected 1.

The electrode unit 150 may be configured to be electrically connected to the object 1 to be inspected through the electrolytic solution, and may have various configurations.

The electrode unit 150 may be made of various materials as long as the electrode unit 150 is installed considering the electrolytic characteristics such as a platinum electrode, a titanium back-plated electrode, and a stainless steel electrode.

In addition, the electrode unit 150 can have various forms as long as it can be electrically connected to the object 1 to which the electric power is applied.

Specifically, the power applying unit may apply the negative (-) and positive (+) electrodes to the object 1 and the electrode unit 150, respectively.

The hydrogen measuring unit 200 may have various configurations as a configuration for measuring whether or not hydrogen generated in the hydrogen generator 100 has passed through the inspection target 1 having a plate structure.

For example, the hydrogen measuring unit 200 may include a pressure sensing unit 210 for sensing a pressure change of hydrogen generated in the hydrogen generating unit 100 as the hydrogen permeates through the inspection target 1 having a plate structure; Hydrogen permeability measuring the elapsed time t from the operating point T _i of the hydrogen generator 100 to the point of time T _e at which the pressure change sensed by the pressure sensing unit 210 meets a predetermined condition And a time measuring unit 230.

Here, the pressure P measured by the pressure sensing unit 210 can be calculated from the pressure change in the measurement space using the gas state equation, PV = nRT.

For example, when the gas constant R in the measurement space is previously calculated through experiments or the like, and the temperature is constant in the measurement space, the value of the volume can be known according to the measured pressure.

In this way, it is possible to calculate the volume change and the like from the pressure change in the measurement space.

For example, when the pressure change sensed by the pressure sensing unit 210 is preset, a measurement of the elapsed time? T is performed when the pressure change is maintained for a predetermined time or more in consideration of a measurement error or the like (T _e ).

The pressure sensing unit 210 may be configured to sense a change in pressure of the hydrogen generated by the hydrogen generating unit 100 when the hydrogen is transmitted through the inspection object 1 having a plate structure.

In one embodiment, the hydrogen measurement unit 200 includes distilled water, a storage space P2 in which hydrogen generated in the hydrogen generation unit 100 and permeated through the inspection target 1 is received, A measurement space forming unit 220 formed with a measurement space P3 filled with the measurement gas to communicate with the accommodation space P2 and to cause volume and pressure change according to the amount of hydrogen permeation; A pressure sensing part 210 installed in the measurement space P3 and sensing a pressure change in the measurement space P3 by the flow of the distilled water through the hydrogen that has permeated the inspection object 1; An elapsed time from the operating point T _i of the hydrogen generator 100 to the point of time T _e at which the pressure change sensed by the pressure sensor 210 matches a preset condition, And a hydrogen permeation time measuring unit 230 for measuring time.

At this time, the liquid contained in the accommodation space P2 can be various liquids as long as it is a liquid that does not cause volume change by hydrogen in addition to the distilled water.

The measurement space forming unit 220 may have various structures as long as it is formed in the hydrogen generating unit 100 so that the hydrogen permeated through the inspection target 1 can be received.

For example, the measurement space forming unit 220 includes a receiving housing for storing distilled water and forming an accommodation space P2 in which the hydrogen generated by the hydrogen generating unit 100 and passed through the inspection target 1 is received, And a measuring housing 222 which is connected to the receiving housing and communicates with the receiving space P2 so that the distilled water is moved so as to form a measuring space P3 filled with the measuring gas so that a volume and a pressure change are generated in accordance with the amount of hydrogen permeated. have.

At this time, the receiving housing forms an accommodating space P2 having one side opened and covered by the inspecting means 1, and an opening 221 for the movement of the distilled water is formed at the coupling position with the measuring housing 222 .

The measurement housing 222 may have various structures and forms as long as it has a structure and a shape that are combined with the receiving housing and form a measurement space P3 in which volume and pressure change occur according to the amount of hydrogen permeation.

2, the measuring housing 222 is connected to an opening 221 formed at the lower side of the measurement space forming part 220 at one end and connected to an opening 221 formed at the lower part of the measurement space forming part 220, Quot; U " -shaped tube member in which a pressure sensing unit 210 for measuring the pressure of the refrigerant is installed.

At this time, the other end of the measurement housing 222 is formed to be higher than the height of the receiving housing so that the balance between the distilled water moving along the opening 221 and the distilled water contained in the receiving housing can be maintained.

A scale may be formed at the other end of the measurement housing 222 so as to confirm a volume change of the measurement space P3 according to the movement of the distilled water.

In order to automate the hydrogen emis- sion ability of the object to be inspected by the measuring device of the present invention, a solution circulating, storing and filtering system 600 for supplying, discharging and filtering the electrolytic solution accommodated in the hydrogen generator 100, Can be installed.

The solution circulation, storage and filtering system 600 can be configured in various forms as long as it is provided for the purpose of supplying, discharging, and filtering the electrolytic solution supplied to the hydrogen generator 100.

For example, the solution circulation, storage and filtering system 600 may include an electrolytic solution circulation pipe 610 disposed above the vessel 110 to supply the electrolytic solution to the hydrogen generation space P1, And a pump connected to the decomposition solution circulation pipe 610.

At this time, the electrolytic solution circulation pipe 610 can sequentially perform the role of a supply pipe for supplying the electrolytic solution to the container 110 and the discharge pipe for discharging the electrolyzed solution from the container 110 .

The electrolytic solution may be discharged to the outside along the decomposition solution circulation pipe 610, filtered by a separate filtration device, and re-supplied to the container 110.

In addition, the electrolytic solution circulation pipe 610 can be used for discharging the electrolytic solution excessively supplied to the container 110.

In addition, the solution circulation, storage and filtering system 600 may be applied to the hydrogen measurement unit 200 to supply and discharge the distilled water supplied to the measurement space formation unit 220.

The solution circulation, storage and filtering system 600 may further include a measurement solution circulation pipe 620 connected to the measurement space formation unit 220 to supply and discharge the distilled water.

In another embodiment, the hydrogen measuring unit 200 is formed to be capable of receiving hydrogen that is generated in the hydrogen generator 100 and permeates the object 1 to be inspected. In order to minimize the change in volume due to the inflow of hydrogen, A measuring space forming unit 220 forming a receiving space P2 into which at least one of nitrogen and argon is injected; A pressure sensing part 210 installed in the measurement space forming part 220 and sensing the pressure of the accommodating space P2 changed by the hydrogen permeating the inspection object 1; And a hydrogen permeation time measuring unit 230 connected to the pressure sensing unit 210 and measuring the elapsed time? T.

At this time, the gas injected into the accommodation space P2 is a gas which is generated in the hydrogen generator 100 to prevent the volume change due to the inflow of hydrogen permeating the inspection object 1, A variety of gases can be used.

The hydrogen generating unit 100 and the hydrogen measuring unit 200 may be arranged vertically and the object 1 to be inspected may be automatically charged into the hydrogen generating unit 100 and the hydrogen measuring unit 200 A transfer tool 400 for loading and unloading the inspection object 1 may be installed.

The transfer tool 400 can be configured in various ways as long as it is provided for automatic loading and unloading of the inspection object 1. [

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 or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

1: object to be inspected 100: hydrogen generator
200: hydrogen measuring unit

Claims (5)

A hydrogen generator (100) for generating hydrogen for measuring the hydrogen-containing ability of the inspection object (1) having a plate structure;
And a hydrogen measuring unit (200) for measuring whether hydrogen generated in the hydrogen generator (100) has passed through the inspection target (1) of the plate structure,
The hydrogen measuring unit 200 measures a hydrogen concentration
A pressure sensing unit 210 for sensing a pressure change of hydrogen generated in the hydrogen generating unit 100 as the plate structure passes through the inspection target 1;
The elapsed time? T from the operating time T _i of the hydrogen generator 100 to the time point T _e at which the pressure change sensed by the pressure sensing unit 210 meets predetermined conditions is measured And a hydrogen permeation time measuring unit (230). The method according to claim 1,
The hydrogen generator (100)
A container 110 in which a hydrogen generating space P1 is formed together with the object to be inspected 1 and an electrolytic solution containing an electrolyte is contained in the hydrogen generating space P1;
And a power applying unit for applying power to each of the hydrogen generating space (P1) and the inspection target (1) to generate hydrogen from the electrolytic solution containing the electrolyte. The method according to claim 1,
The hydrogen measuring unit 200 measures a hydrogen concentration
(P2) containing distilled water and containing hydrogen that has been generated in the hydrogen generating portion (100) and permeated through the inspection target (1), and a permeable space A measurement space forming unit 220 in which a measurement space P3 filled with a measurement gas is formed to generate a change in volume and pressure according to the measurement space P3;
A pressure sensing unit 210 installed in the measurement space P3 to sense pressure change in the measurement space P3 by the flow of distilled water through the hydrogen that has passed through the inspection object 1;
A time point T _e at which the pressure change sensed by the pressure sensing unit 210 from the operation time T _i of the hydrogen generator 100 is in accordance with a predetermined condition, And a hydrogen permeation time measuring unit (230) for measuring the elapsed time up to the hydrogen permeation time measuring unit (230). The method according to claim 1,
The hydrogen measuring unit 200 measures a hydrogen concentration
At least one gas of nitrogen and argon is injected to minimize the volume change caused by the inflow of hydrogen when hydrogen generated in the hydrogen generating part 100 is permeated through the inspection object 1 A measurement space forming unit 220 forming a receiving space P2;
A pressure sensing part 210 installed in the measurement space forming part 220 to sense the pressure of the accommodation space P2 changed by the hydrogen permeated through the inspection object 1;
And a hydrogen permeation time measuring unit (230) connected to the pressure sensing unit (210) and measuring the elapsed time (? T). The method according to any one of claims 1 to 4,
The hydrogen generating unit 100 and the hydrogen measuring unit 200 are arranged vertically,
The inspection object 1 includes a transportation tool 400 for loading and unloading the inspection object 1 so that it can be automatically charged between the hydrogen generating part 100 and the hydrogen measuring part 200 Hydrogen storage capacity measurement device.

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