KR102539226B1 - Cooling system for hydrogen station - Google Patents

Abstract

The present invention relates to a hydrogen cooling system for a hydrogen filling station, comprising: a first storage unit for storing fuel in a liquid state, a second storage unit for storing fuel in a gaseous state, and liquid fuel supplied from the first storage unit; 2 It is characterized in that it includes a mixing unit for generating fuel having a set temperature by mixing the gaseous fuel supplied from the storage unit.

Description

Hydrogen cooling system for hydrogen filling station {COOLING SYSTEM FOR HYDROGEN STATION}

The present invention relates to a hydrogen cooling system for a hydrogen filling station, and more particularly, to a hydrogen cooling system for a hydrogen filling station for cooling hydrogen supplied to a hydrogen fuel cell vehicle.

In general, as a low-emission vehicle to cope with recent environmental problems, a hydrogen fuel cell vehicle using gas fuel such as hydrogen gas is attracting attention, and in order to promote the spread of such a hydrogen fuel cell vehicle, Development of a hydrogen filling station for recharging hydrogen stably and efficiently in a fuel tank is being actively conducted.

When hydrogen is charged in a hydrogen fuel cell vehicle, as hydrogen is charged into a fuel tank at a high pressure, a temperature rise due to adiabatic compression occurs, which acts as a cause of reducing charging efficiency. Therefore, in order to improve the efficiency of the charging operation, a process of cooling the hydrogen before charging the hydrogen fuel cell vehicle is required.

In a conventional hydrogen cooling system, a compressor, a condenser, an expansion valve, and an evaporator are connected by a refrigerant pipe, and the evaporator cools hydrogen through a precooler provided to exchange heat with a circulation pipe through which heat medium oil passes. However, in the conventional hydrogen cooling system, energy efficiency decreases as hydrogen is indirectly cooled by thermal oil, and it is difficult to supply hydrogen at a sufficient pressure to a charger due to a volume decrease due to hydrogen cooling.

The background art of the present invention is disclosed in Korean Patent Registration No. 10-1683715 (registered on December 1, 2016, title of the invention: precooler for hydrogen charger).

An object of the present invention is to provide a hydrogen cooling system for a hydrogen filling station capable of quantitatively adjusting the cooling temperature of hydrogen.

In addition, an object of the present invention is to provide a hydrogen cooling system for a hydrogen filling station capable of preventing the pressure of hydrogen supplied to a hydrogen charger from dropping.

In order to solve the above problems, a hydrogen cooling system for a hydrogen filling station according to the present invention includes: a first storage unit for storing fuel in a liquid state; a second storage unit for storing fuel in a gaseous state; and a mixing unit mixing the liquid fuel supplied from the first storage unit and the gaseous fuel supplied from the second storage unit to generate fuel having a set temperature.

In addition, the liquid fuel supplied from the first storage unit to the mixing unit is heated to the set temperature, and the gaseous fuel supplied from the second storage unit to the mixing unit is cooled to the set temperature.

In addition, a first transfer unit provided between the first storage unit and the mixing unit and applying an external force to the liquid fuel stored in the first storage unit to transfer the liquid fuel to the mixing unit.

In addition, a second delivery unit for transferring the liquid fuel stored in the first storage unit to the mixing unit in association with a change in flow rate of the gaseous fuel supplied from the second storage unit to the mixing unit.

In addition, the second delivery unit may include a moving unit connected to the second storage unit and formed in the form of a Venturi tube; a suction unit connected to the first storage unit and the flow unit and sucking liquid fuel supplied from the first storage unit into the flow unit; and an injection unit configured to inject gaseous fuel supplied from the second storage unit to the flow unit and liquid fuel sucked into the flow unit from the first storage unit to the mixing unit.

In addition, a control unit for adjusting the supply amount of liquid fuel supplied from the first storage unit to the mixing unit; further includes.

In addition, the control unit controls the amount of heat required to cool the amount of gaseous fuel supplied from the second storage to the amount of heat required to heat the amount of liquid fuel supplied from the first storage to the set temperature. The amount of liquid fuel supplied to the first storage unit is adjusted to correspond to this.

Also, the fuel is hydrogen.

The hydrogen cooling system for a hydrogen filling station according to the present invention can quantitatively control the amount of heat required for heat exchange of the fuel by independently supplying liquid fuel and gaseous fuel to the mixing unit by the first storage unit and the second storage unit. can improve energy efficiency.

In addition, the hydrogen cooling system for a hydrogen filling station according to the present invention directly mixes liquid fuel and gaseous fuel by the mixing unit, so that the fuel is cooled more rapidly than the case where the fuel is cooled by a refrigerant circulating through an existing pre-cooler. and induce an efficient heat exchange reaction.

In addition, the hydrogen cooling system for a hydrogen filling station according to the present invention can supplement the internal pressure that is reduced due to cooling of gaseous fuel due to heating and vaporization of liquid fuel, thereby preventing a decrease in charging efficiency.

In addition, in the hydrogen cooling system for a hydrogen filling station according to the present invention, the liquid fuel can be actively supplied by the first transfer unit provided to apply an external force to the liquid fuel supplied from the first storage unit.

In addition, the hydrogen cooling system for a hydrogen filling station according to the present invention can deliver liquid fuel supplied from the first storage unit to the mixing unit without a separate driving force generating device by the second transmission unit, thereby reducing installation and operation costs. there is.

1 is an installation state diagram schematically showing an installation state of a hydrogen cooling system for a hydrogen filling station according to an embodiment of the present invention.
2 is a conceptual diagram schematically showing the configuration of a hydrogen cooling system for a hydrogen filling station according to an embodiment of the present invention.
3 is a conceptual diagram schematically illustrating the configuration of a control unit according to an embodiment of the present invention.
4 is a conceptual diagram schematically showing the configuration of a hydrogen cooling system for a hydrogen filling station according to another embodiment of the present invention.
5 is a cross-sectional view schematically showing the configuration of a second storage unit according to another embodiment of the present invention.
6 is an operation diagram schematically showing an operating state of a second storage unit according to another embodiment of the present invention.

Hereinafter, an embodiment of a hydrogen cooling system for a hydrogen filling station according to the present invention will be described with reference to the accompanying drawings.

In this process, the thickness of lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of a user or operator. Therefore, definitions of these terms will have to be made based on the content throughout this specification.

In addition, in this specification, when a part is said to be “connected (or connected)” to another part, this is not only the case where it is “directly connected (or connected)”, but also “with another member in between” It also includes cases where it is indirectly connected (or connected). In this specification, when it is said that a certain part "includes (or includes)" a certain component, this does not exclude other components unless otherwise stated, but "includes (or includes)" other components. It means you can.

Also, like reference numerals may refer to like elements throughout this specification. Even if the same reference numerals or similar reference numerals are not mentioned or described in a particular drawing, the numerals may be described based on another drawing. In addition, even if there are parts not marked with reference numerals in specific drawings, the parts can be described based on other drawings. In addition, the number, shape, size, and relative difference of the detailed components included in the drawings of the present application are set for convenience of understanding, and may be implemented in various forms without limiting the embodiments.

1 is an installation state diagram schematically showing the installation state of a hydrogen cooling system for a hydrogen charging station according to an embodiment of the present invention, and FIG. 2 schematically shows the configuration of a hydrogen cooling system for a hydrogen charging station according to an embodiment of the present invention. It is a conceptual diagram that represents

1 and 2, the hydrogen cooling system 1 for a hydrogen filling station according to an embodiment of the present invention includes a first storage unit 100, a second storage unit 200, and a first transmission unit 400. , a mixing unit 400, and a control unit 500.

Hereinafter, the fuel will be described as hydrogen, but the fuel is not limited thereto, and design changes can be made to various types of fuel including hydrogen and injected into the hydrogen fuel cell vehicle 4 .

The first storage unit 100 stores fuel in a liquid state. The first storage unit 100 according to an embodiment of the present invention may be formed in the form of a tank for storing fuel in a low-temperature liquid state inside a sealed storage space. In this case, the temperature of the fuel stored in the first storage unit 100 may be maintained at about -210°C. The first storage unit 100 may be formed in the form of a double wall having an outer wall and an inner wall to minimize evaporation of fuel, and an insulating material may be filled between the inner and outer cylinders. The size and number of the first storage unit 100 can be variously changed according to the storage capacity of the liquid fuel to be stored. The first storage unit 100 may be connected to a mixing unit 300 to be described later through a pipe. The first storage unit 100 may deliver the liquid fuel stored therein to the mixing unit 300 through a pipe by the operation of the first transmission unit 400 to be described later. A solenoid valve may be installed in a pipe connected to the first storage unit 100 to adjust a flow rate of liquid fuel supplied from the first storage unit 100 to the mixing unit 300 .

The second storage unit 200 stores fuel in a gaseous state. The second storage unit 200 according to an embodiment of the present invention may be formed in the form of a tank for storing fuel in a high-pressure gas state inside a sealed storage space. The second storage unit 200 receives and stores gaseous fuel from the compressor 2 that compresses the gaseous fuel generated from the reformer to a high pressure. The material of the second storage unit 200 may include a material such as steel or aluminum, which has excellent durability at high pressure and high thermal conductivity. The second storage unit 200 may be formed as a double wall having an outer wall and an inner wall, and a vacuum may be formed between the outer wall and the inner wall. The size and number of the second storage unit 200 can be variously changed according to the storage capacity of the gaseous fuel to be stored. The temperature of the gaseous fuel stored in the second storage unit 200 may be maintained at about 30°C. A plurality of second storage units 200 may be provided, and in this case, each second storage unit 200 may individually store high-pressure gaseous fuel. The second storage unit 200 is connected to a mixing unit 300 to be described later through a pipe. The second storage unit 200 may deliver gaseous fuel to the mixing unit 300 by a pressure difference between the pressure of the gaseous fuel stored therein and the internal pressure of the mixing unit 300 . A solenoid valve may be installed in a pipe connected to the second storage unit 200 to adjust a flow rate of gaseous fuel supplied from the second storage unit 200 to the mixing unit 300 .

The mixing unit 300 mixes the liquid fuel supplied from the first storage unit 100 and the gaseous fuel supplied from the second storage unit 200 to generate fuel having a set temperature. More specifically, the mixing unit 300 directly mixes the liquid fuel supplied from the first storage unit 100 and the gaseous fuel supplied from the second storage unit 200 . The mixing unit 300 heat-exchanges both gaseous fuel and liquid fuel to a point where the mixed gaseous fuel and liquid fuel are set to the same pressure and the same temperature by making thermal equilibrium. That is, the mixing unit 300 cools the gaseous fuel supplied from the second storage unit 200 to a set temperature through a heat exchange action, and heats and vaporizes the liquid fuel supplied from the first storage unit 100 to a set temperature. let it Here, various design changes are possible for the set temperature within a temperature range between the temperature of the liquid fuel supplied from the first storage unit 100 and the temperature of the gaseous fuel supplied from the second storage unit 200 . Accordingly, the mixing unit 300 may induce a more rapid and efficient heat exchange reaction compared to a case where the fuel is cooled by a refrigerant or the like circulating through the existing precooler. In addition, the mixing unit 300 can quantitatively control the amount of heat required for heat exchange of the fuel by directly mixing gaseous fuel and liquid fuel in an amount supplied, thereby improving energy efficiency. In addition, the mixing unit 300 can compensate for the reduced internal pressure due to the cooling of the gaseous fuel due to the heating and vaporization of the liquid fuel, so that the fuel with sufficient pressure can be supplied to the charger 3.

In the mixing unit 300 according to an embodiment of the present invention, one side is connected to the first storage unit 100 and the second storage unit 200 through a pipe, and the other side supplies fuel to the hydrogen fuel cell vehicle 4. It may be formed in the shape of a storage container connected to the charger to be injected. The mixing unit 300 prevents heat from leaking out or inflow from the outside during heat exchange between the liquid fuel supplied from the first storage unit 100 and the gaseous fuel supplied from the second storage unit 200. Insulation materials may be included. The set temperature at which the liquid fuel supplied from the first storage unit 100 and the gas fuel supplied from the second storage unit 200 achieve thermal equilibrium may be about -40°C.

The first delivery unit 400 is provided between the first storage unit 100 and the mixing unit 300, applies an external force to the liquid fuel stored in the first storage unit 100, and transfers it to the mixing unit 300. The first delivery unit 400 according to an embodiment of the present invention is connected to a pipe connected between the first storage unit 100 and the mixing unit 300, and receives a driving force from an external power source to flow in the pipe. It may be exemplified by a low-temperature pump that transports liquid fuel to the mixing unit 300.

3 is a conceptual diagram schematically illustrating the configuration of a control unit according to an embodiment of the present invention.

Referring to FIG. 3 , the control unit 500 controls the amount of liquid fuel supplied from the first storage unit 100 to the mixing unit 300 and the gas supplied from the second storage unit 200 to the mixing unit 300. Independent control of fuel supply. More specifically, the control unit 500 controls the supply of gaseous fuel supplied from the second storage unit 200 to the amount of heat required to heat the supply amount of liquid fuel from the first storage unit 100 to the set temperature. The amount of liquid fuel supplied to the first storage unit 100 is adjusted to correspond to the amount of heat required to be cooled to . That is, the control unit 500 determines that the difference between the temperature of the liquid fuel supplied from the first storage unit 100 and the set temperature and the difference between the temperature of the gaseous fuel supplied from the first storage unit 100 and the set temperature do not match. When the heat quantity required to reach the set temperature is different for both of them, the amount of liquid fuel supplied to the first storage unit 100 is quantitatively adjusted so that the two heat values are identical. The control unit 500 according to an embodiment of the present invention includes a flow rate measuring device for measuring the flow rate in a pipe connected between the first storage unit 100 and the second storage unit 200 and the mixing unit 300; It may include a control module such as a microprocessor for controlling the opening/closing state of the storage unit 100 and the solenoid valve installed in the pipe connected between the second storage unit 200 and the mixing unit 300 .

Hereinafter, the operation process of the hydrogen cooling system 1 for a hydrogen filling station according to an embodiment of the present invention will be described in detail.

Referring to FIGS. 1 to 3 , the control unit 500 operates a solenoid valve to open a pipe between the second storage unit 200 and the mixing unit 300 .

Gaseous fuel compressed to a high pressure by the compressor 2 and stored in the second storage unit 200 in a gaseous state flows into the mixing unit 300 along the pipe due to a pressure difference with the inside of the mixing unit 300 .

The control unit 500 operates the solenoid valve to open a pipe between the first storage unit 100 and the mixing unit 300 . At the same time, the first delivery unit 400 connected to the pipe is also operated.

The liquid fuel stored in the first storage unit 200 in a liquid state receives an external force from the first transmission unit 400 and flows into the mixing unit 300 along the pipe.

The gaseous fuel and the liquid fuel introduced into the mixing unit 300 are directly mixed inside the mixing unit 300 .

The mixing unit 300 heat-exchanges both gaseous fuel and liquid fuel to a point where the mixed gaseous fuel and liquid fuel are set to the same pressure and the same temperature by making thermal equilibrium. That is, the mixing unit 300 cools the gaseous fuel supplied from the second storage unit 200 to a set temperature through a heat exchange action, and heats and vaporizes the liquid fuel supplied from the first storage unit 100 to a set temperature. let it

In this process, the control unit 500 adjusts the supply of gaseous fuel supplied from the second storage unit 200 to the amount of heat required to heat the supply amount of liquid fuel from the first storage unit 100 to the set temperature. The amount of liquid fuel supplied to the first storage unit 100 is adjusted to correspond to the amount of heat required to be cooled to .

More specifically, assuming that the effects of the specific heat of the liquid fuel and the heat of vaporization of the liquid fuel are ignored, the temperature of the liquid fuel supplied from the first storage unit 100 and the temperature of the gaseous fuel supplied from the second storage unit 200 When the temperature and the set temperature are determined, the amounts of heat required for the liquid fuel supplied from the first storage unit 100 and the gas fuel supplied from the second storage unit 200 to reach the set temperature are the liquid fuel and the gas fuel, respectively. It is proportional to the mass of, that is, the amount supplied.

For example, gaseous fuel is stored in the second storage unit 200 at a temperature of about -30 ° C, liquid fuel is stored in the first storage unit 100 at a temperature of about -210 ° C, and the mixing unit 300 If the set temperature of the fuel to be produced is about -40°C, the liquid fuel needs to be heated by about 170°C, while the gaseous fuel needs to be cooled by about -70°C. In this case, when the same amount of liquid fuel and gaseous fuel is supplied to the mixing unit 300, the liquid fuel supercools the gaseous fuel to a temperature lower than the set temperature due to an imbalance in heat quantity. Accordingly, the control unit 500 allows the liquid fuel supplied from the first storage unit 100 to be supplied in a smaller amount than the supply amount of the gaseous fuel supplied from the second storage unit 200 so that the liquid fuel and the gaseous fuel achieve thermal equilibrium. It is induced so that the point formed is set to the set temperature.

Meanwhile, the volume of the gaseous fuel supplied from the second storage unit 200 is reduced as it is cooled to a set temperature, thereby reducing the pressure inside the mixing unit 300 .

The liquid fuel supplied from the first storage unit 100 increases in volume as it is heated and vaporized to a set temperature, thereby increasing the internal pressure of the mixing unit 300, which is reduced due to cooling of the gaseous fuel, to the mixing unit ( In 300, the pressure value of the fuel supplied to the charger 3 is kept constant.

Hereinafter, the configuration of a hydrogen cooling system 1 for a hydrogen filling station according to another embodiment of the present invention will be described. In this process, for convenience of description, a description overlapping with the hydrogen cooling system 1 for a hydrogen filling station according to an embodiment of the present invention will be omitted.

4 is a conceptual diagram schematically showing the configuration of a hydrogen cooling system for a hydrogen filling station according to another embodiment of the present invention.

Referring to FIG. 4 , a hydrogen cooling system for a hydrogen filling station according to another embodiment of the present invention includes a second delivery unit 600 .

The second transfer unit 600 interlocks with the flow rate change of the gaseous fuel supplied from the second storage unit 200 to the mixing unit 300 to transfer the liquid fuel stored in the first storage unit 100 to the mixing unit 300. convey Accordingly, the second transfer unit 600 may transfer the liquid fuel stored in the first storage unit 100 to the mixing unit 300 without receiving a separate driving force from an external power source.

5 is a cross-sectional view schematically showing the configuration of a second storage unit according to another embodiment of the present invention. 6 is an operation diagram schematically showing an operating state of a second storage unit according to another embodiment of the present invention.

4 to 6 , the second storage part 600 according to another embodiment of the present invention includes a moving part 610, a suction part 620, and a spraying part 630.

The flow part 610 is connected to the second storage part 200 and induces a change in the flow rate of the gaseous fuel delivered from the second storage part 200 to the mixing part 300 . The moving part 610 according to this embodiment is installed in a pipe connecting the second storage part 200 and the mixing part 300. The moving part 610 may be formed in the form of a Venturi tube having a reduced diameter in some of the entire sections.

The suction unit 620 is connected to the first storage unit 100 and the moving unit 610 and sucks the liquid fuel supplied from the first storage unit 100 into the moving unit 610 . The suction part 620 according to this embodiment may be formed in the form of a pipe having one side communicated with the first storage part 100 and the other side connected to a section in which the diameter of the moving part 610 is reduced. The suction part 620 is removed from the first storage part 100 by the suction pressure generated as the flow rate of the gaseous fuel supplied from the second storage part 200 increases in the section where the diameter of the flow part 610 is reduced. The supplied liquid fuel is sucked into the moving part 610.

The injection unit 630 injects gaseous fuel supplied from the second storage unit 200 to the flow unit 610 and liquid fuel sucked into the flow unit 610 from the suction unit 620 to the mixing unit 300. do. The injection unit 630 according to the present embodiment has one side communicating with the flow unit 610 and the other side communicating with the inside of the mixing unit 300, and a shape of a diffuser whose diameter expands along the flow direction of fuel. can be formed as The injection unit 630 reduces the flow rate of the gaseous fuel and the liquid fuel delivered from the flow unit 610 and increases the pressure so that they are injected into the mixing unit 300 with strong pressure.

The present invention has been described with reference to the embodiments shown in the drawings, but this is only exemplary, and those skilled in the art can make various modifications and equivalent other embodiments. will understand

Therefore, the technical protection scope of the present invention should be determined by the claims below.

1: Hydrogen cooling system for hydrogen filling station 2: Compressor
3: charger 4: hydrogen fuel cell vehicle
100: first storage unit 200: second storage unit
300: mixing unit 400: first delivery unit
500: control unit 600: second transmission unit
610: moving part 620: suction part
630: injection unit

Claims (8)

a first storage unit for storing fuel in a liquid state;
a second storage unit for storing fuel in a gaseous state; and
a mixing unit mixing the liquid fuel supplied from the first storage unit and the gaseous fuel supplied from the second storage unit to generate fuel having a set temperature; and
A second transfer unit for transferring the liquid fuel stored in the first storage unit to the mixing unit in conjunction with a change in flow rate of gaseous fuel supplied from the second storage unit to the mixing unit;
The mixing unit is formed to have the shape of a storage container, one side is connected to the first storage unit and the second storage unit, and the other side is connected to a charger for injecting fuel into a hydrogen fuel cell vehicle,
The mixing part includes an insulating material,
The second delivery unit,
a moving part connected to the second storage part and formed in the form of a Venturi tube;
a suction unit connected to the first storage unit and the flow unit and sucking liquid fuel supplied from the first storage unit into the flow unit; and
And an injection unit for injecting gaseous fuel supplied from the second storage unit to the flow unit and liquid fuel sucked into the flow unit from the first storage unit to the mixing unit,
The gaseous fuel stored in the second storage unit is introduced into the mixing unit by a pressure difference with the inside of the mixing unit,
The flow part changes the flow rate of the gaseous fuel delivered from the second storage part to the mixing part,
The hydrogen cooling system for a hydrogen filling station, characterized in that the intake part sucks the liquid fuel supplied from the first storage part into the flow part by suction pressure generated as the flow rate of the gaseous fuel increases in the flow part.
According to claim 1,
The liquid fuel supplied from the first storage unit to the mixing unit is heated to the set temperature,
The hydrogen cooling system for a hydrogen filling station, characterized in that the gaseous fuel supplied from the second storage unit to the mixing unit is cooled to the set temperature.
According to claim 1,
A first delivery unit provided between the first storage unit and the mixing unit and applying an external force to the liquid fuel stored in the first storage unit to deliver the liquid fuel to the mixing unit; Hydrogen cooling for a hydrogen filling station further comprising system.
delete delete According to claim 1,
The hydrogen cooling system for a hydrogen filling station, characterized in that it further comprises a; control unit for adjusting the supply amount of the liquid fuel supplied from the first storage unit to the mixing unit.
According to claim 6,
The control unit corresponds to the amount of heat required to cool the amount of gaseous fuel supplied from the second storage portion to the amount of heat required to heat the amount of liquid fuel supplied from the first storage portion to the set temperature. A hydrogen cooling system for a hydrogen filling station, characterized in that the amount of liquid fuel supplied to the first storage unit is adjusted as much as possible.
The method of any one of claims 1, 2, 3, 6, and 7,
The hydrogen cooling system for a hydrogen filling station, characterized in that the fuel is hydrogen.

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