KR102115455B1 - Hydrogen gas filling nozzle - Google Patents

Abstract

The present invention relates to a hydrogen charging nozzle for charging hydrogen. According to an embodiment of the present invention, the hydrogen charging nozzle comprises: a nozzle inlet which is coupled to a hydrogen charge hole to inject hydrogen gas; a detachable clamp which is installed on the nozzle inlet and to attach and detach the nozzle inlet to/from the hydrogen charge hole; a nozzle main body which connects the nozzle inlet to a gas hose supplying the hydrogen gas; a gas supply valve which is installed on the nozzle main body to supply hydrogen gas from the gas hole to the nozzle inlet or block the hydrogen gas; an operation lever which operates the supply valve to supply or block hydrogen gas to or from the supply valve; a blocking cover which surrounds a circumference of the nozzle inlet to block outer air from being introduced into the nozzle inlet; and a medium spray unit which sprays a drying medium into the blocking cover to prevent the air from being introduced into the blocking cover so that the detachable clamp can be prevented from being frozen by moisture of the introduced air not to be operated in accordance with the supply of hydrogen gas at the nozzle inlet. Accordingly, the present invention can prevent the nozzle inlet at the hydrogen charge hole from coming in contact with outer air and not being separated by freezing by moisture.

Description

Hydrogen gas filling nozzle

The present invention relates to a hydrogen filling nozzle for filling hydrogen.

In general, when hydrogen is burned, only a very small amount of nitrogen oxides are generated, other pollutants are not generated, and an almost infinite amount of water on the earth is made from raw materials, and after use, it is recycled back to water, so there is no worry of exhaustion. Therefore, it is spotlighted as an energy to replace fossil fuels.

An example of using hydrogen is a hydrogen vehicle, and a hydrogen vehicle uses hydrogen or a motor to charge the battery using hydrogen.

On the other hand, hydrogen vehicles charge hydrogen through the nozzles of hydrogen chargers, and the nozzles of hydrogen chargers have been disclosed as "gas filling nozzles" in Korean Patent Registration No. 10-2034518 (announced on October 21, 2019).

The above-described conventional gas filling nozzle is coupled to a receptacle provided in an external device, and in a gas filling nozzle filling a gas storage portion of an external device, a gas supply pipe supplying gas therein is accommodated. A nozzle body to which a driving lever operated by a user is hinged; A driving unit accommodated inside the nozzle body and generating a reciprocating driving force in a direction toward one end of the nozzle body by a rotational driving force of the driving lever; It is disposed at one end of the nozzle body, and includes a coupling portion that is coupled to or disengaged from the receptacle provided in the external device by the reciprocating driving force of the driving portion, and the driving portion generates at least one rotational driving force by rotation of the driving lever. Pinion; And one end engaged with each of the at least one pinion, the other end connected to the engaging portion, and at least one rack that reciprocates linearly when each of the at least one pinion rotates by the rotational driving force of the driving lever. It was composed.

The conventional gas filling nozzle of this configuration was able to easily and securely couple the filling nozzle to the receptacle.

However, since the conventional gas filling nozzle is supplied with hydrogen gas at a low temperature below zero, as the external air is contacted in the state where the coupling portion is coupled to the receptacle, the coupling portion is frozen by moisture contained in the air, so that the filling is completed. There was a problem that could not separate the coupling.

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a hydrogen charging nozzle that can be easily separated after charging is completed by preventing freezing of the coupling portion.

Hydrogen filling nozzle according to an embodiment of the present invention for achieving the above object is coupled to the hydrogen filling nozzle injection port for injecting hydrogen gas, is installed in the nozzle injection port detachable to detach the nozzle injection port to the hydrogen filling port A clamp, a nozzle body connecting the nozzle inlet and a gas hose for supplying the hydrogen gas, and a gas supply valve installed in the nozzle body to supply or block hydrogen gas from the gas hose to the nozzle inlet, and the supply valve Depending on the supply of hydrogen gas from the nozzle injection port, the operating lever for operating the supply valve to supply or block the hydrogen gas, the outer cover wraps around the nozzle inlet to block the outside air from entering the nozzle inlet, and the nozzle inlet The detachable clamp includes a medium injection unit that blocks the inflow of air into the interior of the blocking cover by spraying a drying medium into the interior of the blocking cover to prevent freezing due to moisture of the introduced air.

The medium injection unit may include a medium nozzle unit installed on the nozzle body to spray the drying medium between the blocking cover and the nozzle injection port, and a media hose supplying the drying medium to the medium nozzle unit through the nozzle body. have.

It may include a medium supply valve which is installed between the medium nozzle unit and the medium hose to supply or block the drying medium supplied to the medium nozzle unit through the medium hose according to the operation of the operation lever.

The blocking cover may be formed in a bellows shape so that an end portion of the blocking cover is in close contact with the circumference of the hydrogen charging port.

The drying medium may include dry air or nitrogen below a preset humidity.

According to the present invention, the blocking cover blocks the inflow of external air containing moisture, and the drying medium is sprayed from the medium injection part inside the blocking cover to block the inflow of outside air, thereby preventing the nozzle from entering the hydrogen outlet according to freezing. It is possible to prevent the inlet is not separated.

In addition, when using dry air as a drying medium, it is possible to prevent generation of ice by removing moisture inside the blocking cover, and when nitrogen is used as the drying medium, fire can be prevented by inertness of nitrogen. When the hydrogen gas is leaked, nitrogen reacts with the hydrogen to be converted into ammonia gas, thereby preventing the explosion of the hydrogen gas from occurring.

1 is a perspective view schematically showing a hydrogen charging nozzle according to an embodiment of the present invention.
Figure 2 is a side view schematically showing a hydrogen charging nozzle according to an embodiment of the present invention, showing the state before bonding to the hydrogen charging port.
3 is a side view schematically showing a hydrogen charging nozzle according to an embodiment of the present invention, showing a state after being coupled to a hydrogen charging port.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

The hydrogen charging nozzle 100 according to an embodiment of the present invention is described as supplying hydrogen to the hydrogen charging port 200 of a hydrogen vehicle, but hydrogen is supplied to various industrial facilities or hydrogen supply devices where the hydrogen charging port 200 is installed. It can be charged.

1 to 3, the hydrogen filling nozzle 100 according to an embodiment of the present invention may include a nozzle injection port 120.

The nozzle injection port 120 is coupled to the hydrogen charging port 200 to inject hydrogen gas into the hydrogen vehicle through the hydrogen charging port 200.

The nozzle injection port 120 may include a first hermetic seal 123, a second hermetic seal 125, and a return unit 121.

The first hermetic seal 123 and the second hermetic seal 125 are installed to be spaced apart inside the nozzle inlet 120, between the hydrogen filling port 200 and the nozzle inlet 120 fitted to the nozzle inlet 120. Can be confidential.

The first hermetic seal 123 and the second hermetic seal 125 may be formed of a material having hydrogen embrittlement.

In addition, the return unit 121 is a hydrogen gas flowing out between the first hermetic seal 123 and the second hermetic seal 125, that is, the hydrogen gas flowing out between the hydrogen filling port 200 and the nozzle injection port 120 By inhaling the hydrogen charging nozzle 100 may be returned to the hydrogen charger is installed.

Here, the hydrogen charger means a device in which a hydrogen charging nozzle 100 is installed to supply hydrogen gas.

On the other hand, the return unit 121 is connected to the hydrogen charger through the return hose 165, including the return hose 165, and inhaling the hydrogen gas flowing out according to the operation of the return pump from the hydrogen charger to return to the hydrogen charger It can prevent the outflow of hydrogen gas.

The nozzle injection port 120 may be combined in a form fitted to the hydrogen charging port 200, and the nozzle injection port 120 may include a detachable clamp 130.

The detachable clamp 130 is formed with a through portion 131 into which a hydrogen charging port 200 is inserted and injected into the center, and the detachable clamp 130 is a clamp block 133 divided into a circumference around the through portion 131. ) A plurality of are arranged, and each clamp block 133 may be rotatably coupled by an end of the opposite direction in which the hydrogen charging port 200 is inserted.

The plurality of clamp blocks 133 arranged in the circumferential direction is the end of the nozzle injection port 120 when the hydrogen charging port 200 is inserted into the through portion 131 in the state where the end facing the hydrogen charging port 200 is opened. By the detachable clamp 130 is pushed into the inside, the end of the clamp block 133 that has been opened shrinks, it is possible to fix the nozzle inlet 120 to the hydrogen charging port 200.

At this time, the end portion of the hydrogen charging port 200 may be formed with a striking portion 210 that extends over the inside of the through portion 131 of the detachable clamp 130, and a straddling portion 210 at the end of the detachable clamp 130. A protrusion 135 protruding toward the center of the through part 131 may be formed to span the lower end of the.

In the embodiment, the desorption clamp 130 is configured to be coupled to the hydrogen charging port 200 in the form of an opening or an umrad, but various known types of desorption are detachably coupled to the hydrogen charging port 200 without leakage of hydrogen gas. It may be implemented as a clamp 130.

1 to 3, the hydrogen charging nozzle 100 according to an embodiment of the present invention may include a nozzle body 110.

In the nozzle body 110, a nozzle injection port 120 may be installed, and a gas hose 160 for supplying hydrogen gas and a nozzle injection port 120 are connected to the nozzle to supply hydrogen gas supplied through the gas hose 160. It can be supplied to the inlet 120.

The gas hose 160 may supply hydrogen to the nozzle inlet 120 by receiving hydrogen gas from a hydrogen tank in which hydrogen gas is stored or a hydrogen charger that receives and delivers hydrogen gas from the hydrogen tank.

The nozzle inlet 120 may be formed at one end of the nozzle body 110, the gas hose 160 may be formed at the other end of the nozzle body 110, the nozzle body 110 is easily gripped by the operator In order to charge hydrogen gas, it may be formed in the same shape as a refueling gun installed in a refueling machine.

On the other hand, the nozzle body 110 may be provided with a flow meter capable of checking the supply amount of hydrogen gas, a lamp or a confirmation window to check the supply state, or the like.

2 and 3, the hydrogen filling nozzle 100 according to an embodiment of the present invention may include a gas supply valve 150.

The gas supply valve 150 may be installed inside the nozzle body 110 to supply or block hydrogen gas supplied through the gas hose to the nozzle inlet 120.

The gas supply valve 150 can supply or block hydrogen gas by connecting the gas hose and the nozzle inlet 120, and the gas supply valve 150 is implemented as an electronically operated solenoid valve or a mechanically operated valve, It may be implemented in the form of integrally forming the structure of the valve inside the nozzle body (110).

The structure of the gas supply valve 150 may have a variety of well-known valve structures, so a detailed description is omitted.

1 to 3 The hydrogen charging nozzle 100 according to the embodiment of the present invention may include an operating lever 115.

The operation lever 115 operates the gas supply valve 150 to open or block the gas supply valve 150 to supply gas to the nozzle injection port 120 through the gas hose or to block the gas supply valve 150.

When the operating lever 115 is rotatably coupled to the nozzle body 110 like a brake of a bicycle and wraps the operating lever 115 in the nozzle body 110, the gas supply valve 150 is opened to open the gas hose. When the hydrogen gas is supplied from the nozzle injection port 120, and the operating lever 115 is placed on the nozzle body 110, the gas supply valve 150 supplies hydrogen gas supplied from the gas hose. Can be blocked.

In the embodiment, the operating lever 115 is configured to open or shut off the gas supply valve 150 as it rotates in the nozzle body 110, but the operating lever 115 is implemented as an electrical switch and is gas-dependent according to the operation of the switch. It may be configured to open or shut off the supply valve 150.

1 to 3, the hydrogen filling nozzle 100 according to an embodiment of the present invention may include a blocking cover 140.

The blocking cover 140 may be installed to enclose the circumference of the nozzle injection port 120 at an end facing the hydrogen charging port 200 at the nozzle injection port 120.

The blocking cover 140 may be formed in an open shape at the bottom, and prevents external air from flowing into the hydrogen injection part as it is in close contact with the circumference of the filling injection port while the hydrogen filling nozzle 100 is inserted into the filling inlet. At the same time, the drying medium to be described below may be supplied to the interior of the blocking cover 140 to prevent external air from flowing into the blocking cover 140.

On the other hand, the blocking cover 140 is formed in the shape of a bellows (bellows), is formed in a length longer than the length of the nozzle inlet 120, the blocking cover 140 in a state in which the nozzle inlet 120 is coupled to the filling inlet While being pressurized by the elastic force, it can be sealed in close contact with the circumference of the nozzle injection port 120.

A discharge hole 141 through which the drying medium is discharged is formed around the blocking cover 140 to discharge the drying medium continuously supplied to the inside of the blocking cover 140 to the outside, and the pressure of the blocking cover 140 is increased. The blocking cover 140 may be prevented from swelling.

In addition, the inside of the blocking cover 140 is coated with a material having hydrogen embrittlement or a cover formed of a material having hydrogen embrittlement to form a blocking cover 140 to minimize the small image of the blocking cover 140 due to hydrogen embrittlement. You may.

2 and 3, the hydrogen filling nozzle 100 according to an embodiment of the present invention may include a medium injection unit 170.

The medium injection unit 170 supplies a drying medium between the nozzle inlet 120 and the blocking cover 140 so that air containing moisture flows into the interior of the blocking cover 140 and freezes in the nozzle injection port 120. It can be prevented from occurring.

Here, since hydrogen gas is injected in a compressed state due to its characteristics, it expands and is injected in a cooled state to minimize the volume of hydrogen gas. At this time, the ambient air contacts the periphery of the nozzle inlet 120, and the air The desorption clamp 130 of the nozzle injection port 120 is frozen by the moisture contained in the nozzle injection port 120 from the hydrogen charging port 200 cannot be separated.

Accordingly, the media injection unit 170 blocks the inflow of external air containing moisture as the drying medium is injected into the interior of the blocking cover 140, and at the same time external air that has been introduced into the blocking cover 140 is external. It is possible to prevent the nozzle injection port 120 is not separated from the hydrogen charging port 200 by icing by releasing to.

The drying medium may be dry air or nitrogen dried below a preset humidity.

When a dry air is used as the drying medium, while the dry air having a predetermined humidity or less is supplied to the inside of the blocking cover 140, the air introduced into the blocking cover 140 is discharged to the outside, and the dried air is inside. Since the moisture is absorbed and released into the discharge hole 141, moisture is removed from the inside of the blocking cover 140, thereby preventing the separation of the nozzle inlet 120 due to freezing.

On the other hand, when using nitrogen as a drying medium, it is possible not only to block the inflow of air by the inertness of nitrogen, but also to prevent the occurrence of fire, and when the hydrogen to be charged is partially discharged, it reacts with hydrogen gas. Because it generates ammonia gas, it can reduce the risk of explosion of hydrogen gas.

The media injection unit 170 may include a media nozzle unit 171, a media hose 175, and a media supply valve 173.

The media nozzle unit 171 may be installed between the nozzle injection port 120 and the blocking cover 140 in the nozzle body 110 to spray the drying medium between the nozzle injection port 120 and the blocking cover 140.

The media nozzle unit 171 may form a plurality of nozzle holes around the nozzle injection port 120 to spray the drying medium through the plurality of nozzle holes.

The drying medium may be continuously sprayed by the media nozzle unit 171 until the filling is completed and discharged through the discharge hole 141 of the blocking cover 140.

The media hose 175 may be coupled to the nozzle body 110 to supply a drying medium to the media nozzle unit 171.

The media hose 175 may receive the drying medium stored in the media storage tank according to the type of the drying medium and supply it to the media nozzle unit 171 through the supply hose.

For example, when the dry medium is nitrogen, nitrogen compressed in the media storage tank may be configured to be supplied to the media nozzle unit 171 through the media hose 175.

As another example, when the drying medium is dry air, the outside air is sucked by a blower fan, and the air sucked is heated by a hot wire to remove moisture from the medium hose 175 to supply the medium nozzle unit 171. can do.

Here, the medium hose 175 is formed integrally with the gas hose 160, and may be configured to supply hydrogen gas to one space and a drying medium to the other through an internal space divided into two. have.

The medium supply valve 173 is installed inside the nozzle body 110, and connects the medium hose 175 and the medium nozzle unit 171 to each other to connect the drying medium supplied through the medium hose 175 to the medium nozzle unit ( 171).

The medium supply valve 173 may be implemented as an electronically controlled solenoid valve or a mechanically operated valve, and the medium supply valve 173 is a nozzle body in the form of forming a nozzle structure inside the nozzle body 110 ( 110) may be integrally formed.

In addition, the medium supply valve 173 is operated together with the gas supply valve 150 according to the operation of the operation lever 115, and when the gas supply valve 150 supplies hydrogen gas, the medium supply valve 173 also has a drying medium. When supplying, and the gas supply valve 150 blocks the supply of hydrogen gas, the medium supply valve 173 can also block the supply of the drying medium.

On the other hand, the medium supply valve 173 and the gas supply valve 150 may have different flow paths, and the valve structure for opening or blocking may be shared, and may be configured in an integrated form to simultaneously supply or block hydrogen gas and drying medium. .

It will be described the effect and effect between each configuration described above.

In the hydrogen charging nozzle 100 according to an embodiment of the present invention, when the nozzle injection port 120 is inserted into the hydrogen charging port 200, the through portion 131 of the detachable clamp 130 installed in the nozzle injection port 120 is filled. Lifting and joining the protruding portion 135 of the desorption clamp 130 to the striking portion 210 of the hydrogen charging port 200.

At this time, the blocking cover 140 is in close contact with the circumference of the hydrogen charging port 200 while being compressed.

When the operating lever 115 is operated in a state in which the nozzle injection port 120 is coupled to the hydrogen filling port 200, the gas supply valve 150 is opened, and the hydrogen gas stored in the hydrogen tank supplies the media hose 175. The hydrogen gas supplied through and supplied to the medium hose 175 is injected into the hydrogen filling port 200 through the nozzle injection port 120.

At the same time, as the medium supply valve 173 is opened together with the gas supply valve 150 according to the operation of the operation lever 115, the drying medium is installed in the nozzle body 110 through the medium hose 175 to the medium nozzle unit ( 171) is injected through the drying medium is injected through the nozzle injection port 120 and the blocking cover 140, the air that has flowed into the blocking cover 140 through the discharge hole 141 of the blocking cover 140 As it is released, the dry medium is also discharged, and thus, it is possible to prevent external air containing moisture from entering the blocking cover 140.

Here, when the outside air flows into the blocking cover 140, freezing occurs between the desorption clamp 130 or the nozzle injection port 120 and the hydrogen charging port 200 by the temperature of the supplied hydrogen gas, Because the detachable clamp 130 does not operate due to this freezing, the nozzle injection port 120 cannot be separated from the hydrogen filling port 200, so the drying medium blocks outside air from flowing into the blocking cover 140. By doing so, it is possible to prevent the nozzle injection port 120 from being separated from the hydrogen charging port 200 due to freezing.

On the other hand, when the supply of hydrogen gas is completed and the operation lever 115 is operated, the gas supply valve 150 and the medium supply valve 173 block the supply of hydrogen gas and the supply of the drying medium, and the hydrogen charging port 200 ) To remove the nozzle inlet 120 to complete hydrogen charging.

Then, when the nozzle injection port 120 is fitted and coupled to the hydrogen charging port 200, the first gas tight seal 123 and the second gas tight seal 125 of the nozzle injection port 120 sequentially turn around the hydrogen filling port 200. In close contact with the airtight, when the hydrogen water flows through the first airtight seal 123, hydrogen gas is supplied from the return unit 121 installed between the first airtight seal 123 and the second airtight seal 125 By inhaling and returning the return hose to the hydrogen charger through 165, the outflow of hydrogen gas can be prevented.

Therefore, the hydrogen charging nozzle 100 according to an embodiment of the present invention blocks the inflow of external air containing moisture by the blocking cover 140, and blocks the drying medium through the medium supply unit, the blocking cover 140 and the nozzle inlet By blocking the inflow of air by spraying between the (120), it is possible to prevent the nozzle injection port 120 from being unseparated from the hydrogen filling port 200 as freezing occurs.

In addition, when nitrogen is used as a drying medium, it is possible to prevent a fire from being caused by inertness of nitrogen, and also to prevent an explosion due to the outflow of hydrogen gas because it is converted into ammonia gas by reacting with hydrogen gas. .

In addition, when using dry air as a drying medium, the dry air absorbs moisture of components located inside the blocking cover 140 and is discharged to the discharge hole 141, thereby preventing generation of freezing.

In addition, it is possible to prevent the outflow of hydrogen gas by returning the hydrogen gas flowing out between the hydrogen charging port 200 and the nozzle injection port 120 by the return unit 121.

Although the embodiments of the present invention have been described above, the scope of rights of the present invention is not limited to this, and it is easily changed and equalized by those skilled in the art from the embodiments of the present invention. Includes all changes and modifications to the extent possible.

100: hydrogen filling nozzle 110: nozzle body
115: operating lever 120: nozzle inlet
121: return section 123: first hermetic seal
125: second hermetic seal 130: removable clamp
131: penetrating portion 133: clamp block
135: protrusion 140: blocking cover
141: discharge hole 150: gas supply valve
160: gas hose 165: return hose
170: medium injection unit 171: medium nozzle unit
173: medium supply valve 175: medium hose
200: hydrogen charging port 210: cross section

Claims (5)

Nozzle injection port coupled to the hydrogen charging port to inject hydrogen gas,
Desorption clamp installed in the nozzle injection port to detach the nozzle injection port to the hydrogen charging port,
A nozzle body connecting the nozzle inlet and a gas hose for supplying the hydrogen gas,
A gas supply valve installed on the nozzle body to supply or block hydrogen gas from the gas hose to the nozzle inlet,
Operation lever for operating the gas supply valve to supply or block the hydrogen gas from the gas supply valve,
A blocking cover that surrounds the periphery of the nozzle inlet and blocks outside air from entering the nozzle inlet, and
In accordance with the supply of hydrogen gas at the nozzle inlet, the desorption clamp is frozen by the moisture of the introduced air, and the drying medium is sprayed into the blocking cover to prevent the air from flowing into the blocking cover. It includes a medium injection unit to block,
The medium injection unit is installed in the nozzle body and includes a medium nozzle unit for spraying a drying medium between the blocking cover and the nozzle injection port, and a medium hose for supplying the drying medium to the medium nozzle unit through the nozzle body,
And a medium supply valve installed between the medium nozzle part and the medium hose to supply or block the drying medium supplied to the medium nozzle part through the medium hose according to the operation of the operation lever. Filling nozzle. delete delete According to claim 1,
The nozzle inlet
A hydrogen charging nozzle comprising a return unit for suctioning and returning hydrogen gas flowing between the nozzle injection port and the hydrogen charging port. According to claim 1,
The drying medium
A hydrogen charging nozzle comprising dry air or nitrogen below a preset humidity.

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