KR102070948B1 - Movable hydrogen evaluation facility device - Google Patents

Abstract

The present invention relates to movable hydrogen evaluation inspection equipment and, more specifically, to movable hydrogen evaluation inspection equipment, capable of performing various hydrogen evaluation inspections and rapidly inspecting a large amount of hydrogen. According to the present invention, the movable hydrogen evaluation inspection equipment comprises: a dispenser connection unit (10); a hydrogen cylinder module (50) in which one or more cylinders (52) are connected in parallel to form one module; a hydrogen weighing device (70); and a vent (80) for discharging hydrogen filled in the cylinders (52) to the air.

Description

Mobile hydrogen evaluation facility device

The present invention relates to a mobile hydrogen evaluation test equipment. More specifically, when hydrogen is supplied to a hydrogen vehicle from a dispenser provided at a hydrogen charging station to charge hydrogen to the hydrogen vehicle, whether the pressure and temperature of hydrogen is maintained in a normal state and is supplied to the hydrogen vehicle. , Whether hydrogen supplied to a hydrogen vehicle is supplied in a quantitative manner, various hydrogen evaluation tests can be performed including the purity of the supplied hydrogen, and a number of cylinders filled with hydrogen for the evaluation and inspection of hydrogen are parallel Since it can be connected and modularized, it is possible to simultaneously test hydrogen supplied by multiple dispensers, or to check a large amount of hydrogen in a short time, and various devices provided to check the state, quantity, and purity of hydrogen supplied from the dispenser Evaluation of hydrogen by moving directly to a hydrogen charging station located at a remote location provided on a mobile trailer The present invention relates to a mobile hydrogen evaluation and inspection facility.

There is a growing interest in reducing energy resources and reducing carbon emissions worldwide, and the need for eco-friendly vehicles is increasing.

As the ultimate eco-friendly vehicle, hydrogen vehicles are attracting attention and are becoming a good alternative to solving the above-mentioned problems in terms of transportation.

The hydrogen vehicle can be divided into a hydrogen electric vehicle or a hydrogen fuel cell vehicle in which a motor is operated by turning the engine on hydrogen and producing electricity from hydrogen and charging the produced electricity to a battery.

The initial market for hydrogen vehicles is open, and the construction of a hydrogen charging infrastructure to become a full-fledged issue has become an issue.

Japan, the United States, Europe, and China are continuously investing in expanding the infrastructure of hydrogen charging stations, and Korea is in a position to keep pace with it.

The hydrogen filling station basically consists of a hydrogen storage container for storing hydrogen, a compressor for increasing the pressure of hydrogen, and a dispenser for charging hydrogen to the car.

The hydrogen storage container stores hydrogen at 400 atmospheres, and when the pressure of the supplied hydrogen is low, the pressure is increased using a compressor.

High-pressure hydrogen storage and liquefied hydrogen storage are the most representative storage methods for hydrogen, and high-pressure hydrogen storage is currently widely used.

Hydrogen vehicles are charged with 5 to 6 kg of hydrogen, it takes 3 to 5 minutes to charge, and when high-pressure hydrogen is injected at high speed, heat may be generated depending on the injection pressure, which may lead to safety accidents.

Therefore, when hydrogen is charged to a hydrogen vehicle from a dispenser operated in a hydrogen charging station, whether the pressure state, temperature state, etc. of the charged hydrogen flows to a steady state, whether the charged hydrogen is supplied in a quantitative amount, or what is the purity state of the hydrogen. There is a need for a device capable of evaluating and inspecting whether or not, and it is necessary to periodically inspect hydrogen supplied from a dispenser using a hydrogen evaluating test device.

However, at present, most hydrogen charging stations are scattered in remote locations, and the apparatus capable of testing hydrogen is also relatively complex and has a sensitive structure, which makes it difficult to evaluate and test the hydrogen supplied from the hydrogen charging station.

Prior Art Document: KR Registered Patent Publication No. 10-1124983 (2012.03.27.announcement)

The present invention has been devised to solve the above problems, and when hydrogen is supplied to a hydrogen vehicle from a dispenser provided at a hydrogen charging station to charge hydrogen to a hydrogen vehicle, the pressure and temperature of hydrogen is normal. Maintaining the state, whether it is supplied to a hydrogen vehicle, whether hydrogen is supplied to a hydrogen vehicle in a quantitative manner, and can perform various hydrogen evaluation tests, including the purity of the hydrogen supplied, hydrogen for the evaluation and inspection of hydrogen Multiple cylinders filled with A can be connected in parallel and modularized, so that hydrogen supplied from multiple dispensers can be simultaneously inspected, or a large amount of hydrogen can be inspected in a short time. Various devices equipped to check the purity are equipped in a mobile trailer and placed on a remote location. Directly to a hydrogen station and it is an object to provide a removable hydrogen evaluation test equipment apparatus which can evaluate a hydrogen test.

The mobile hydrogen evaluation and inspection facility apparatus according to the present invention devised to achieve the above object is connected to a dispenser, a dispenser connection unit 10 through which hydrogen flows from the dispenser; A hydrogen cylinder module 50 in which one or more cylinders 52 filled with hydrogen introduced from the dispenser connection part 10 are connected in parallel to form one module; A hydrogen weight meter 70 provided to measure the weight of the total hydrogen charged in each cylinder 52 constituting the hydrogen cylinder module 50 for each unit of the hydrogen cylinder module 50; And a vent 80 connected to each cylinder 52 constituting the hydrogen cylinder module 50 to discharge hydrogen filled in the cylinder 52 into the air, and the hydrogen cylinder module 50 and a hydrogen weight meter (70) is installed in the mobile trailer 500 includes a movable.

In addition, the hydrogen cylinder module 50 composed of one or more cylinders 52 includes one or more other hydrogen cylinder modules 50 connected in parallel, and one or more hydrogen cylinder modules 50 in parallel. When configured, it may further include that the hydrogen weight meter 70 is separately provided below each hydrogen cylinder module 50 connected in parallel to measure the weight of hydrogen for each unit of the hydrogen cylinder module 50. have.

In addition, the first check valve unit 20 provided on the conduit connected to the rear of the dispenser connection unit 10 to block the reverse flow of the inlet side hydrogen flowing through the dispenser connection unit 10; An inlet flow meter 30 provided at the rear of the first check valve unit 200 to measure the flow rate of hydrogen on the inlet pipe side flowing through the dispenser connecting portion 10; When the hydrogen filled in the cylinder 52 constituting the hydrogen cylinder module 50 is discharged to the outside, the outlet flowmeter 90 provided on the pipeline connected to the vent 80 to check the flow rate of the discharged hydrogen ); Connected to a pipeline branched in parallel on a pipe to which the vent 80 is connected, and connected to a hydrogen purity inspection device, a hydrogen purity inspection device connection unit provided to inspect the purity of hydrogen flowing out of the hydrogen cylinder module 50 ( 100); And an analog pressure gauge 112, a digital pressure gauge 114, an analog temperature gauge 116, and a digital temperature gauge 118. When hydrogen flows through the pipeline, the temperature and pressure of the hydrogen at one or more points When it is necessary to measure the state, the temperature and pressure of the corresponding point may be further displayed by an analog method or may further include a gauge unit 110 provided to obtain digitally digitized temperature and pressure data.

According to the present invention, it is possible to safely and easily perform various tests for evaluating hydrogen charged in a hydrogen vehicle, and it is possible to flexibly operate an inspection device according to the amount of hydrogen to be inspected and perform inspection. .

In addition, various devices necessary for the hydrogen evaluation test are installed or provided in a movable trailer, and there is an effect of performing various types of hydrogen evaluation tests by directly moving to a hydrogen charging station located scattered at a remote location.

1 is a view showing a state in which a mobile hydrogen evaluation and inspection equipment according to a preferred embodiment of the present invention is installed on a trailer,
2 is a hydraulic circuit diagram of a mobile hydrogen evaluation and inspection equipment according to a preferred embodiment of the present invention,
3 is a view showing a side of a trailer in which a mobile hydrogen evaluation and inspection facility according to the present invention is installed,
4 is a view showing a plane of a trailer in which a mobile hydrogen evaluation and inspection facility according to the present invention is installed,
5 is a view showing a plane of the lifting frame,
6 is a view showing the front of the lifting frame,
7 is a view showing a plane of the lifting frame coupled to the support frame,
8 is a view showing the front of the lifting frame coupled to the support frame,
9 is a view showing a side of the lifting frame coupled to the support frame,
10 is a view showing the state in which the explosion-proof enclosure is provided,
11 is a view showing a state in which the explosion-proof enclosure is provided,
12 is a view showing a state in which the lifting unit is installed on the trailer,
13 is a view showing a vent.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, it should be noted that in adding reference numerals to the components of each drawing, the same components have the same reference numerals as possible, even if they are displayed on different drawings. In addition, in describing the present invention, when it is determined that detailed descriptions of related well-known configurations or functions may obscure the subject matter of the present invention, detailed descriptions thereof will be omitted. In addition, although preferred embodiments of the present invention will be described below, the technical spirit of the present invention is not limited to or limited thereto, and can be variously implemented by a person skilled in the art.

1 is a view showing a state in which a mobile hydrogen evaluation and inspection facility is installed in a trailer according to a preferred embodiment of the present invention, Figure 2 is a hydraulic circuit diagram of a mobile hydrogen evaluation and inspection facility according to a preferred embodiment of the present invention, 3 is a view showing a side of a trailer on which a mobile hydrogen evaluation and inspection facility is installed according to the present invention, and FIG. 4 is a view showing a plane of a trailer on which the mobile hydrogen evaluation and inspection facility is installed according to the present invention, FIG. Is a view showing the plane of the lifting frame, FIG. 6 is a view showing the front of the lifting frame, FIG. 7 is a view showing the plane of the lifting frame coupled to the support frame, and FIG. 8 is a front view of the lifting frame coupled to the support frame Drawing, Figure 9 is a view showing the side of the lifting frame coupled to the support frame, Figure 10 is a front view showing a state in which the explosion-proof enclosure is provided Figure, Figure 11 is a view showing a state in which the explosion-proof enclosure is provided, Figure 12 is a view showing a state in which the lifting unit is installed on the trailer, Figure 13 is a view showing a vent.

1 to 13, the dispenser connection part 10, the first check valve part 20, the inflow part flow meter 30, and the second check are provided for the mobile hydrogen evaluation inspection facility device according to the preferred embodiment of the present invention. The valve part 40, the hydrogen cylinder module 50, the third check valve part 60, the hydrogen weight measuring instrument 70, the vent 80, the outlet flowmeter 90, the hydrogen purity inspection device connection part 100, It comprises a gauge unit 110, an integrated cylinder valve 120, a lifting frame 200, a cylinder fixture 220, a support frame 300, a trailer 500.

First, the mobile hydrogen evaluation and inspection facility according to the present invention, when hydrogen is supplied to a hydrogen vehicle from a dispenser provided at a hydrogen charging station to charge hydrogen to a hydrogen vehicle, the pressure and temperature of hydrogen are in a normal state. Maintaining and supplying hydrogen vehicles, whether hydrogen is supplied to hydrogen vehicles in quantitative quantities, and can perform a variety of hydrogen evaluation tests including the purity of hydrogen supplied.

In addition, one of the cylinders filled with hydrogen, which is the object of the evaluation test, may be configured singly or one or more in parallel to form a hydrogen cylinder module 50, and the hydrogen cylinder module 50 may also include one or more hydrogen cylinders. The module 50 is additionally configured in parallel to simultaneously test hydrogen supplied from multiple dispensers, or to inspect a large amount of hydrogen within a short period of time.

In addition, the dispenser connecting portion 10 shown in Figure 2, the first check valve portion 20, the inlet flow meter 30, the second check valve portion 40, a hydrogen cylinder module 50 consisting of one or more cylinders, The third check valve unit 60, the hydrogen weight meter 70, the vent 80, the outlet flow meter 90, the hydrogen purity inspection device connection unit 100, the gauge unit 110, the integrated cylinder valve 120 Various hydraulic devices provided to inspect the state, quantity, and purity of hydrogen supplied from the dispenser, including the ones installed in the mobile trailer 500 as shown in FIGS. 1 and 12, move directly to a hydrogen charging station located at a remote location. It can be tested for evaluation of hydrogen, which has its characteristics.

In addition, a mobile hydrogen evaluation and inspection facility equipped with a hydrogen cylinder module for lifting and moving according to the present invention can be used to inspect various types of gas chargers including LPG and CNG as well as hydrogen.

Hereinafter, the components and functions of the mobile hydrogen evaluation and inspection equipment equipped with the hydrogen cylinder module 50 for lifting and lowering according to the preferred embodiment of the present invention will be described in detail.

First, referring to FIG. 2, various valves including a dispenser connector 10 and a check valve shown on a hydraulic circuit of a mobile hydrogen evaluation test facility equipped with a hydrogen cylinder module 50 for lifting movement according to the present invention And various gauges including pressure gauges and temperature gauges, flow meters, cylinders, and vents are connected on a pipeline through which hydrogen flows, so a detailed description of the pipeline is omitted.

Referring to FIG. 2, the dispenser connection unit 10 is connected to a dispenser provided at a hydrogen charging station to supply hydrogen gas used as fuel for a hydrogen vehicle, and hydrogen is introduced from the dispenser.

When one or more dispensers are supplied with hydrogen for inspection, or when a large amount of hydrogen is supplied to perform hydrogen evaluation inspection within a short period of time, one or more of the dispenser connection units 10 connected to the dispensers are parallel to each other as shown in FIG. 2. When the dispenser connecting portion 10 is configured in parallel, it can be merged in the first check valve portion 20 described below to flow hydrogen to the rear.

Referring to FIG. 2, the first check valve unit 20 is provided on a conduit connected to the rear of the dispenser connection unit 10 to block the reverse flow of hydrogen flowing through the dispenser connection unit 10.

In the present invention, one or more check valve parts are provided, and the main flow of hydrogen is provided at a branch in parallel and prevents backflow of hydrogen flowing into various hydraulic devices including cylinders provided at the rear of the branch. It is provided for.

Referring to FIG. 2, the inlet flow meter 30 is provided at the rear of the first check valve unit 200 to measure the flow rate of hydrogen on the inlet pipe side flowing through the dispenser connecting portion 10.

Referring to FIG. 2, the second check valve unit 40 is located at the rear of the inlet flow meter 30, and the hydrogen cylinder module 50 described below forms one or more modules and is provided in parallel. At this time, the second check valve unit 40 is branched in a parallel form around the center, and is provided to prevent backflow of hydrogen flowing into the hydrogen cylinder module 50 provided in parallel.

Referring to Figure 2, the hydrogen cylinder module 50 is composed of a cylinder 52 filled with hydrogen flowing from the dispenser connection unit 10, and one or more cylinders 52 are connected in parallel to form one module. do.

Here, as well as one cylinder 52 constituting the hydrogen cylinder module 50 can be installed alone, at this time to form a module.

Each cylinder 52 constituting the hydrogen cylinder module 50 is a configuration required for the quantitative inspection of hydrogen supplied from the dispenser through the dispenser connecting portion 10, and when the quantitative inspection of hydrogen is completed, each cylinder 52 The filled hydrogen is discharged to the outside through the vent 80 described below.

Here, the cylinder 52 filled with hydrogen supplied from the dispenser through the dispenser connecting portion 10 may be installed in the same specification as the hydrogen storage tank installed in the hydrogen vehicle.

When filling the cylinder 52 constituting the hydrogen cylinder module 50 with hydrogen, each cylinder 52 may be sequentially filled with hydrogen, or a plurality of cylinders 52 may be simultaneously charged with hydrogen, either Alternatively, several cylinders 52 may be selected to selectively fill hydrogen.

Referring to FIG. 2, the third check valve 60 is branched to each cylinder 52 in which hydrogen is connected in parallel in a hydrogen cylinder module 50 composed of one or more cylinders 52 connected in parallel. When there is, one or more cylinders 52 are provided at a point where they are branched in parallel in order to prevent the incoming hydrogen from flowing backward.

Meanwhile, when hydrogen is supplied from one or more dispensers and hydrogen is simultaneously inspected, or when a large amount of hydrogen is supplied from the dispenser and the number of cylinders 52 to be filled is more necessary, one or more cylinders 52 as shown in FIG. 2 ), One or more other hydrogen cylinder modules 50 may be connected in parallel to the hydrogen cylinder module 50 to configure the hydrogen cylinder module 50 itself.

Referring to FIG. 2, when one or more hydrogen cylinder modules 50 are added and configured in parallel, a pipeline is branched from the second check valve unit 40 and flows on one pipeline through the dispenser connection unit 10. The hydrogen to be branched from the second check valve unit 40 is introduced into the hydrogen cylinder module 50 connected in parallel. (More precisely, it is introduced into each cylinder 52 connected in parallel from the hydrogen cylinder module 50)

2 and 8, the hydrogen weight meter 70 is provided below the hydrogen cylinder module to measure the weight of the total hydrogen charged in each cylinder 52 constituting the hydrogen cylinder module 50.

Here, the hydrogen weight gauge 70 measures the weight of the total hydrogen filled in each cylinder constituting the hydrogen cylinder module 50 for each hydrogen cylinder module 50 unit.

As shown in FIG. 2, the hydrogen weight meter 70 constitutes the hydrogen cylinder module 50 when one hydrogen cylinder module 50 or one or more hydrogen cylinder modules 50 are connected in parallel and additionally configured. In order to measure the weight of the total hydrogen charged in each cylinder 52 for each hydrogen cylinder module 50, it is separately provided below each hydrogen cylinder module 50 connected in parallel.

When measuring the weight of the hydrogen filled in each cylinder 52 constituting the gas cylinder module using the hydrogen weight meter 70, it is necessary to measure the weight of only pure hydrogen flowing through the dispenser connection 10 have.

Therefore, for the other components in which the weight is measured by the hydrogen weight gauge 70 in addition to the weight of hydrogen, including the weight of the entire cylinder 52 itself constituting the hydrogen cylinder module 50, the hydrogen weight gauge 70 The weight of only hydrogen charged in each cylinder 52 constituting the hydrogen cylinder module 50 is measured by zero calibration.

Hydrogen charged in each cylinder 52 constituting the hydrogen cylinder module 50 for the flow pressure, flow temperature, and quantitative inspection of hydrogen is discharged to the outside through the vent 80 when the evaluation test is completed.

Referring to FIGS. 2 and 13, the vent 80 is connected to each cylinder 52 constituting the hydrogen cylinder module 50 through a pipeline, and is provided to discharge hydrogen filled in the cylinder 52 into external air. .

Referring to FIG. 13, the vent 80 is composed of a plurality of parts, and is mounted on the trailer 500 to be portable. When using the vent, each part can be assembled and used at the site of use.

When the vent 80 is installed, for safety, the hydrogen cylinder module 50 is installed in a place spaced a predetermined distance from the trailer 500.

Also, referring to FIG. 13, a silencer 82 is attached to the vent 80 to reduce noise generated when high pressure hydrogen is discharged.

Referring to Figure 2, the outlet flowmeter 90 is described below to examine the flow rate of the discharged hydrogen when the hydrogen filled in the cylinder 52 constituting the hydrogen cylinder module 50 is discharged to the outside It is provided on the conduit connected to the vent 80.

Accordingly, the flow rate of hydrogen introduced from the dispenser is measured through the inflow flowmeter 30, and the flow rate when the hydrogen filled in the cylinder 52 constituting the hydrogen cylinder module 50 is discharged is measured through the outflow flowmeter. By measuring and comparing the two flow rates, the flow rate of hydrogen flowing from the dispenser and filling the hydrogen cylinder module 50 and hydrogen flowing out of the hydrogen cylinder module 50 are the same, or hydrogen lost on a pipeline or a hydraulic device. You will be able to check whether there is.

Referring to FIG. 2, the hydrogen purity inspection device connection unit 100 is connected to a pipeline branched in parallel on a pipeline to which the vent 80 is connected, and is connected to a hydrogen purity inspection device to be discharged from the hydrogen cylinder module 50 It is provided to check the purity of hydrogen.

Referring to Figure 2, the gauge unit 110 includes an analog pressure gauge 112, a digital pressure gauge 114, an analog temperature gauge 116, a digital temperature gauge 118, and hydrogen to flow through the pipeline. When it is necessary to measure the temperature and pressure state of hydrogen at one or more points, the temperature and pressure data at the corresponding point are displayed in an analog method or measured by a digital data acquisition system to digitally measure the temperature and pressure data. It is provided for acquisition, and digitally measured temperature and pressure values are plotted in real time in graph form through a terminal including a PC.

Referring to Figure 2 in the present invention as an embodiment of the present invention, between the first check valve unit 20 and the inlet flow meter 30, between the second check valve unit 40 and the third check valve unit 60 The gauge portion 110 including the analog pressure gauge 112, the digital pressure gauge 114, the analog temperature gauge 116, and the digital temperature gauge 118 is provided on the pipeline.

2, when the hydrogen cylinder module 50 is provided in parallel as shown in FIG. 2, the second check valve unit 40 in which the hydrogen cylinder module 50 added in parallel branches off And a third check valve unit 60 positioned in front of the hydrogen cylinder module 50 to be added in parallel.

Here, the analog pressure gauge 112 measures the pressure state of hydrogen at a corresponding hydrogen flow point that needs to be measured when the gas flowing through the dispenser connection part 10 flows through the pipeline to display the pressure in an analog manner. It is provided.

The digital pressure gauge 114 measures the pressure state of hydrogen at a corresponding hydrogen flow point that needs to be measured by a digital data acquisition system when the gas introduced through the dispenser connection part 10 flows through the pipeline, and is digitally quantified. It is provided to store the pressure data and to plot the measured pressure value into a graph displayed in real time.

The analog temperature gauge 116 is provided to display the temperature in an analog manner by measuring the temperature state of hydrogen at a corresponding hydrogen flow point that needs to be measured when the gas introduced through the dispenser connection part 10 flows through the pipeline. .

The digital temperature gauge 118 measures the temperature of hydrogen at a corresponding hydrogen flow point that needs to be measured with a digital data acquisition system when the gas introduced through the dispenser connection 10 flows through the pipeline, and is digitally quantified. It is provided to store temperature data and to plot the measured temperature values in a graph format in real time.

Referring to Figure 2, the integrated cylinder valve 120 is a relief valve for adjusting the pressure of hydrogen when hydrogen flows into or out of the cylinder 52 constituting the hydrogen cylinder module 50, and controls the flow of hydrogen into and out. Each cylinder (52) constituting the hydrogen cylinder module (50) to individually control the flow state of hydrogen flowing into or out of each cylinder (52) constituting the hydrogen cylinder module (50), including an on-off valve for Is located in front of.

On the other hand, as described above, in the present invention, the hydrogen cylinder module 50 is placed on the hydrogen weight gauge 70 as shown in FIGS. 8 and 9 to measure the weight of hydrogen.

In addition, as described above, the hydrogen cylinder module 50 and the hydrogen weight meter 70 of the present invention are installed in a movable trailer 500 to move to a hydrogen charging station located at a remote location to inspect hydrogen.

If, when the hydrogen cylinder module 50 is mounted on the hydrogen weight meter 70, the trailer 500 moves, the hydrogen weight meter 70 is caused by vibrations generated by the trailer 500 in motion. There is a risk of breakage or failure.

In the present invention, in order to prevent damage or failure of the hydrogen weight gauge 70, the hydrogen cylinder module 50 moves upward and downward on the hydrogen weight gauge 70 and is placed on the hydrogen weight gauge 70 or the hydrogen weight gauge ( It is fixed at a position spaced apart from a predetermined distance away from 70).

If, when hydrogen is introduced through the dispenser inlet, is filled in each cylinder 52 constituting the hydrogen cylinder module 50, and the weight of hydrogen needs to be measured, the hydrogen cylinder module 50 is lowered by the lifting device. It is put on the hydrogen weight gauge 70, and at this time, it is possible to measure the weight of hydrogen in the filling of the hydrogen cylinder module 50.

In addition, when the trailer 500 is moved after the inspection of hydrogen is completed, the hydrogen cylinder module 50 is raised by the lifting device and is fixed at a position spaced apart from the hydrogen weight gauge 70.

Therefore, the hydrogen cylinder module 50 can be placed on the hydrogen weight gauge 70 to measure the weight of hydrogen in order to inspect the hydrogen introduced from the dispenser while the trailer 500 is stopped, and the hydrogen inspection is over. Later, by fixing the hydrogen cylinder module 50 to a position spaced upward from the hydrogen weight meter 70, it is possible to prevent damage or failure of the hydrogen weight meter 70 when the trailer 500 moves.

Hereinafter, the configuration of the trailer 500 for moving the mobile hydrogen evaluation test facility and the lifting device for lifting and lowering the hydrogen cylinder module 50 will be described in detail.

The trailer 500 is provided with a towing vehicle connecting portion 510 on one side of the front of the trailer 500 so as to be combined with the towing vehicle and move with the towing vehicle as shown in FIGS. 3 and 4, and the trailer 500 The roof of the roof is provided with one or more roof vents 520 for discharging the hydrogen leaked to the outside of the trailer 500 in case there is a leak of hydrogen during the inspection.

Referring to FIG. 3, on one surface of the trailer 500, a temperature and humidity measurement display unit capable of displaying temperature and humidity inside and outside the trailer, a hydrogen leak detector for detecting hydrogen leaking when hydrogen leaks into the trailer, A control panel 530 including a dispensing connection unit, an analog pressure gauge, a measurement display unit for displaying the temperature and pressure state of hydrogen measured in the gauge unit, and a control valve capable of controlling the flow state of hydrogen is provided.

In addition, referring to FIG. 3, the side of the trailer 500 includes an external terminal including a digital data acquisition system, a terminal equipped with a storage device for storing measured temperature and pressure states, including digital data, as digitized digital data. An external device connection port panel 540 is provided to connect with the device.

5 and 6, a plurality of frames are configured in a rectangular shape, and are provided while supporting the hydrogen cylinder module 50 outside the hydrogen cylinder module 50, and the hydrogen cylinder module ( 50) in combination with the hydrogen cylinder module 50 to move up and down.

5 and 6, a separate space is formed inside the lifting frame 200, and each cylinder 52 constituting the hydrogen cylinder module 50 is individually inserted into the separated space. Is done.

6, the lifting frame 200 and one side are coupled to each other, and each cylinder 52 constituting the hydrogen cylinder module 50 is formed inside the lifting frame 200. When individually seated and positioned in the space, each cylinder 52 is wrapped around the outer circumferential surface of each cylinder 52 so as not to be shaken by vibration or deviated from the seated position, and the position of the cylinder 52 is fixed.

When the cylinder fastener 220 surrounds and fixes the outer circumferential surface of the cylinder 52, the cylinder fastener 220 is as shown in FIG. 6 so as to be able to tighten and join the outer circumferential surface of the cylinder 52 Likewise, one or more fasteners 230 provided with bolts and nuts to adjust the fastening strength are provided.

7 to 9, the support frame 300 is composed of a plurality of frames, fixed to the inside of the trailer 500 by being combined with the trailer 500, and the lifting frame inside the support frame 300 ( 200) is located, and supports the lifting frame 200.

In the present invention, the lifting frame 200 moves up and down by a lifting device, wherein the lifting frame 200 moves up and down together with the hydrogen cylinder module 50 provided inside the lifting frame.

When the elevating frame 200 moves downward, the elevating frame 200 and the hydrogen cylinder module 50 are loaded on the hydrogen weight gauge 70 and filled into each cylinder 52 constituting the hydrogen cylinder module 50. When the weight of the hydrogen is measured, and the lifting frame moves upward, the lifting frame and the hydrogen cylinder module are separated from the hydrogen weight gauge 70 and fixed at positions spaced upward.

The elevating device for elevating the elevating frame 200 includes a manual mechanical elevating device for manually elevating the elevating frame 200 or a hydraulic elevating device elevating the elevating frame 200 by hydraulic or an elevating frame 200 using an electric cylinder. ) Can be used to elevate the electric lifting device.

In one embodiment of the lifting device, in the case of a manual mechanical lifting device for manually lifting the lifting frame 200, referring to FIG. 6, jack coupling parts 210 are provided on both sides of the lifting frame 200, and FIG. 8 Screw jack mechanism 250 is connected to each jack coupling portion 210 vertically as shown in the jack coupling portion 210, the screw jack mechanism 250, as shown in Figure 7 rotating rod (270) ) Is connected, and the rotating rod 270 is connected to the lifting handle 260.

Here, when the lifting handle 260 is rotated to the left or right, the rotating rod 270 connected to the lifting handle 260 rotates, and the screw jack mechanism 250 vertically connected to the rotating rod 270 is rotated. The rotational force of the rotating rod 270 is transmitted, and at this time, the lifting frame 200 connected by the screw jack mechanism 250 and the jack coupling portion 210 moves upward or downward.

That is, the lifting handle 260 and the rotating rod 270 maintain the correct position, and only the lifting frame 200 provided with the hydrogen cylinder module 50 inside is moved upward or downward along the screw jack mechanism 250. During exercise, it is placed on the hydrogen weight meter 70 or is positioned at a position spaced upward from the hydrogen weight meter 70.

Here, referring to FIG. 7, a plurality of rotating rods 270 are provided along the outer circumference of the lifting frame 200, and a connecting link coupled with the supporting frame 300 is provided at the corner where the rotating rods 270 are connected to each other. (240) is provided, and two rotating rods 270 in the connecting link 24 are connected to each other by being engaged with each other by rotating couplings including gears.

Thus, when the lifting handle 260 is rotated, the entire rotating rod 270 provided to surround the lifting frame 200 is rotated at the same time, and this rotational force is transmitted to the screw jack mechanism 250 and the screw jack mechanism 250 ) And the lifting frame 200 connected by the jack coupling part 210 is moved up and down along the screw jack mechanism 250.

On the other hand, after measuring the weight of the hydrogen filled in the hydrogen cylinder module 50, when moving the trailer 500 while the lifting frame 200 is placed on the hydrogen weight gauge 70, the hydrogen weight gauge 70 ) May cause damage or malfunction.

Therefore, even after measuring the weight of hydrogen, if the lifting frame 200 is continuously mounted on the hydrogen weight measuring instrument 70, the operator raises the lifting frame 200 to lift the lifting frame 200 from the hydrogen weight measuring instrument 70. ) May be provided with a warning sound generating device (not shown) that transmits a warning sound including a warning sound to a worker so as to separate them.

On the other hand, the above-described hydrogen cylinder module 50, the lifting frame 200, the support frame 300, the hydrogen weight measuring instrument 70, and the lifting device for lifting the lifting frame 200 is installed inside the mobile trailer 500 It is possible to move.

Meanwhile, as described above, the hydrogen cylinder module 50 composed of one or more cylinders 52 may be configured by connecting one or more other hydrogen cylinder modules 50 in parallel.

When one or more hydrogen cylinder modules 50 are connected in parallel as shown in FIG. 2, referring to FIG. 12, the lifting frame for lifting and lowering movement by the lifting device also in parallel to the hydrogen cylinder modules 50 200), a hydrogen weight meter (70). The support frame 300 is individually provided to constitute one lifting unit 400 and is installed on the trailer 500.

When the lifting unit 400 is composed of a plurality, each lifting unit may be operated individually. That is, the lifting frame included in each lifting unit 400 independently moves up and down, and the weight of hydrogen charged in each hydrogen cylinder module can be measured through the individually equipped hydrogen weight gauge 70.

Explosion proof enclosure 350 is connected to the outside of the support frame with reference to FIGS. 10 and 11, and is provided with an electric device that can cause a spark ignition environment, including electric wiring.

Explosion-proof enclosure 350 isolates and accommodates electrical and mechanical elements that can cause ignition, including flammable and explosive gas, which can cause hydrogen to explode, during the hydrogen evaluation test. It is provided to prevent the explosion by hydrogen that can leak during the hydrogen evaluation test by blocking it.

Meanwhile, an auxiliary power device such as an uninterruptible power supply (UPS) may be provided in case electricity cannot be supplied due to power failure during a hydrogen evaluation test.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains may make various modifications, changes, and substitutions without departing from the essential characteristics of the present invention. will be. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are not intended to limit the technical spirit of the present invention, but to explain the scope of the technical spirit of the present invention. . The scope of protection of the present invention should be interpreted by the claims below, and all technical spirits within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

10-Dispenser connection 20-First check valve
30-Inlet flow meter 40-Second check valve
50-Hydrogen cylinder module 60-3rd check valve part
70-Hydrogen Weight Meter 80-Vent
90-Outflow flowmeter 100-Hydrogen purity inspection device connection
110-Gauge part 120-Integrated cylinder valve
200-Lift frame 220-Cylinder fixture
300-Support frame 350-Explosion-proof enclosure
400-lifting unit 500-trailer

Claims (3)

A hydrogen cylinder module 50 in which one or more cylinders 52 filled with hydrogen introduced from the dispenser connection part 10 are connected in parallel to form one module;
A hydrogen weight meter (70) provided to measure the weight of total hydrogen charged in each cylinder (52) constituting the hydrogen cylinder module (50);
A vent 80 connected to each cylinder 52 constituting the hydrogen cylinder module 50 to discharge hydrogen filled in the cylinder 52 into the air;
A first check valve unit 20 provided on a pipe connected to the rear of the dispenser connection unit 10 to block the reverse flow of hydrogen flowing through the dispenser connection unit 10;
An inlet flow meter 30 provided at the rear of the first check valve unit 200 to measure the flow rate of hydrogen on the inlet pipe side flowing through the dispenser connecting portion 10;
When the hydrogen filled in the cylinder 52 constituting the hydrogen cylinder module 50 is discharged to the outside, the outlet flowmeter 90 provided on the pipeline connected to the vent 80 to check the flow rate of the discharged hydrogen );
Connected to a pipeline branched in parallel on a pipe to which the vent 80 is connected, and connected to a hydrogen purity inspection device, a hydrogen purity inspection device connection unit provided to inspect the purity of hydrogen flowing out of the hydrogen cylinder module 50 ( 100);
It includes an analog pressure gauge 112, a digital pressure gauge 114, an analog temperature gauge 116, and a digital temperature gauge 118. When hydrogen flows through a pipeline, the temperature and pressure state of hydrogen at one or more points When it is necessary to measure, the gauge unit 110 is provided to display the temperature and pressure of the corresponding point in an analog method or to obtain digitally digitized temperature and pressure data.
It includes,
The hydrogen cylinder module 50 and the hydrogen weight meter 70 are installed on the mobile trailer 500 and can be moved.
Including,
When filling hydrogen in each cylinder 52 constituting the hydrogen cylinder module 50, hydrogen can be sequentially charged to each cylinder 52 or hydrogen can be simultaneously charged to a plurality of cylinders 52, either Alternatively, it is possible to selectively fill hydrogen by selecting multiple cylinders 52
It includes,
The roof of the trailer 500 is provided with one or more roof vents 520 for discharging hydrogen leaked inside the trailer 500 to the outside in case there is leakage of hydrogen during inspection
Including,
On one side of the trailer 500, a temperature and humidity measurement indicator that can display the temperature and humidity inside and outside the trailer, a hydrogen leak detector to detect hydrogen leaking when the inside of the trailer leaks, a dispensing connector, an analog pressure gauge A control panel 530 including a control valve capable of controlling the flow state of hydrogen, including a measurement display unit for displaying the temperature and pressure of hydrogen measured by the gauge unit
It includes,
On the side of the trailer 500, an external device is connected to an external device including a terminal equipped with a storage device for storing the measured temperature and pressure state, including digital data acquisition systems, notebooks, and PCs, as digital data. Port panel 540 is provided
Including,
Explosion proof provided to prevent explosion caused by hydrogen that may leak during hydrogen evaluation test by blocking the inflow of hydrogen into the inside, and providing electrical equipment that can cause a spark ignition environment, including electrical wiring inside. Enclosure (350)
A mobile hydrogen evaluation inspection equipment comprising a. According to claim 1,
The hydrogen cylinder module 50 composed of one or more cylinders 52 is configured by connecting one or more other hydrogen cylinder modules 50 in parallel.
Including,
When one or more hydrogen cylinder modules 50 are configured in parallel, the hydrogen weight is individually below each hydrogen cylinder module 50 connected in parallel to measure the weight of hydrogen for each hydrogen cylinder module 50 unit. Equipped with a measuring instrument 70
A mobile hydrogen evaluation inspection equipment comprising a. delete

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