KR101949490B1 - hydrogen gas charging apparatus - Google Patents

Abstract

The present invention relates to a cooling device for a hydrogen gas charger in a new structure, capable of effectively cooling heating medium oil for cooling hydrogen gas. According to the present invention, the cooling device for charging hydrogen gas can effectively cool the heating medium oil by cooling the heating medium oil passing through a circulation pipe (10) twice as a refrigerant extruded by a compressor (50) passes through a first to second heat exchanger (30). Also, a part of the refrigerant is supplied to an auxiliary heat exchanger (45), and the refrigerant passing through a second connection pipe (42) is supplied to the compressor (50) after being cooled. The refrigerant is suddenly expanded and, therefore, cannot smoothly circulate to the compressor (50). So, the cooling device for a hydrogen gas charger can prevent the compressor (50) from being damaged.

Description

[0001] The present invention relates to a cooling apparatus for a hydrogen gas filling apparatus,

The present invention relates to a cooling device for a hydrogen gas charger of a new structure capable of effectively cooling a heating medium oil for cooling hydrogen gas.

Generally, when charging a hydrogen car with hydrogen, the vehicle must be charged with the hydrogen cooled to below -60 ° C.

Therefore, the hydrogen gas filling device used for filling the hydrogen vehicle with hydrogen is provided with a pre-cooler for cooling the hydrogen gas by using the cooled heat medium oil, and a cooling device for cooling the heat medium oil is connected to the pre- do.

The refrigerating apparatus includes a compressor, a condenser, an expansion valve, and an evaporator connected by a refrigerant pipe. The evaporator is heat-exchanged with a circulation pipe through which the heat medium oil passes, and the refrigerant compressed by the compressor passes through the condenser Exchanges heat with the heat medium oil passing through the circulation pipe while expanding in the evaporator through the expansion valve, and then circulates to the compressor, thereby rapidly cooling the heat medium oil passing through the circulation pipe.

Such a cooling device is the same as a general cooling cycle, and a detailed description thereof will be omitted.

However, in such a cooling device, the refrigerant expands rapidly due to heat exchange with the circulation pipe in the evaporator, so that the refrigerant expanded in a state where the compressor is operated can not be smoothly circulated to the compressor, .

Therefore, there is a need for a new method to solve such a problem.

10-1683715,

SUMMARY OF THE INVENTION It is an object of the present invention to provide a cooling device for a hydrogen gas charger having a novel structure capable of effectively cooling a heating medium oil for cooling hydrogen gas.

According to an aspect of the present invention, there is provided a cooling device for a hydrogen gas charger that is connected to a circulation pipe connected to a pre-cooler and cools a heating medium oil passing through the circulation pipe, 10 is provided with a storage tank 11 for storing thermal oil in an intermediate portion thereof and a supply portion 12 for supplying the thermal oil discharged from the precooler to the storage tank 11, And a discharge unit 13 for supplying the thermal oil stored in the supply unit 12 to the precooler. The cooling device for the hydrogen gas charger includes a first heat exchanger 20 connected to an intermediate portion of the supply unit 12, A second heat exchanger 30 connected to an intermediate portion of the refrigerant pipe 13 and connected to the first and second heat exchangers 20 and 30 through a refrigerant pipe 40 to compress the refrigerant, A compressor (50) for supplying the refrigerant to the heat exchanger (20, 30) (40) includes a first connection pipe (41) connecting the compressor (50) and the cooling means (60), and a second connection pipe The connecting portion 42a is connected to the cooling means 60 and the first and second branching portions 42b and 42c and the first and second branching portions 42b and 42c are connected to each other. Is connected to the first and second heat exchangers (20, 30) by branching from the other side of the connecting portion (42a) so that the cooling means (60) and the first and second heat exchangers (20, 30) A first circulation pipe 43 for connecting the first heat exchanger 20 and the second branch 42c to each other and a second circulation pipe 43 for connecting the second heat exchanger 30 and the compressor An auxiliary heat exchanger 45 provided in a connecting portion 42a of the second connecting pipe 42 and a connecting portion 42a of the second connecting pipe 42. The second circulating pipe 44, An auxiliary supply pipe 46 branched from the auxiliary heat exchanger 45 and connected to the auxiliary heat exchanger 45, A cooling device for hydrogen gas charger, comprising a step of including joyeol heat exchanger (45) and a secondary circulation pipe 47 for connecting the compressor (50) is provided.

According to another aspect of the present invention, the cooling means 60 includes a heat exchanger 61 provided in the middle of the first connection pipe 41, a water supply pipe 62 connected to the heat exchanger 61, (63) is provided to cool the refrigerant passing through the first connection pipe (41) to cool the hydrogen gas.

According to another aspect of the present invention, the cooling means 60 includes a cooling pipe 64 provided at an intermediate portion of the first connection pipe 41, and a plurality of cooling fins And a cooling fan 66 provided in front of the cooling fin 65 and blowing air to the cooling fin 65. The cooling pipe 64 is disposed so as to be spaced apart from each other in the vertical direction And a plurality of U-shaped tubes (64b) arranged in a zigzag shape at opposite ends of the straight tube (64a) so that the straight tubes (64a) are connected to each other, wherein the straight tube And a spiral protrusion 64c is formed on an outer circumferential surface of the hydrogen gas supply passage 64a.

According to another aspect of the present invention, the projecting portion 64c of the straight tube 64a is formed by a molding apparatus 70, and the molding apparatus 70 includes a bed 71, And a supporting table 73 provided on the other side of the bed 71. The supporting table 73 is provided on the other side of the bed 71 and extends in the front and rear direction. And the other side is rotatably engaged with the support base 73 and is rotated by the driving means 74b and is supported on the outer side of the linear tube 74. [ And a chuck 75 coupled to one side of a straight tube 64a coupled to the outside of the forming core 74 to be rotatably coupled to the feed belt 72, (71) so as to be positioned between the conveying table (72) and the support table (73), and is supported by the forward and backward driving means (77) And a molding unit (76) for molding the protrusion (64c) by pressing the outer circumferential surface of the straight tube (64a), which is positioned on the outer side of the molding core (74) Is provided in the bed 71 and is adjusted in the forward and backward direction by the forward and backward driving means 77 and the through hole 76b through which the shaping core 74 and the straight pipe 64a pass passes the front and rear faces A plurality of hydraulic cylinders 76c provided so that a piston rod extends into the through hole 76b and a plurality of hydraulic cylinders 76c provided on the piston rod of the hydraulic cylinder 76c, And a molding wheel (76d) for pressing the outer surface of the molding core (74a) inward to mold the circumferential surface of the molding core (74) so as to correspond to the shape of the molding core (74) A cooling device is provided.

The cooling device for filling hydrogen gas according to the present invention is characterized in that the refrigerant extruded from the compressor (50) passes through the first to second heat exchangers (30) to cool the heat medium oil passing through the circulation pipe Not only the heat medium oil can be effectively cooled but also a part of the refrigerant is supplied to the auxiliary heat exchanger 45 and the refrigerant passing through the second connection pipe 42 is cooled and supplied to the compressor 50, So that the compressor 50 can not be smoothly circulated to the compressor 50, thereby preventing the compressor 50 from being damaged.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a configuration diagram showing a cooling apparatus for filling a hydrogen gas according to the present invention;
2 is a configuration diagram showing a second embodiment of a cooling apparatus for filling a hydrogen gas according to the present invention;
3 is a front view showing the cooling means of the second embodiment of the cooling apparatus for filling hydrogen gas according to the present invention,
4 is a side sectional view showing a straight tube of a second embodiment of a cooling apparatus for filling a hydrogen gas according to the present invention,
5 is a side view showing a molding apparatus according to a second embodiment of the oil cooling system according to the present invention,
6 is a front view showing a molding unit of the molding apparatus according to the second embodiment of the oil cooling system according to the present invention;
Figs. 7 to 10 are reference views showing the operation of the molding apparatus according to the second embodiment of the oil cooling system according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 shows a cooling device for a hydrogen gas charger according to the present invention. The cooling device is connected to a circulation pipe 10 connected to a pre-cooler, and the heat medium oil passing through the circulation pipe 10 is cooled Do.

The circulation pipe 10 is provided with a storage tank 11 for storing thermal oil in an intermediate portion thereof and a supply portion 12 for supplying the thermal oil discharged from the precooler to the storage tank 11, The circulation pump 14 is provided in the discharge part 13 and supplies the circulation pump 14 to the supply part 12. The circulation pump 14 is provided in the discharge part 13, So that the heat medium oil stored in the storage tank 11 is circulated to the precooler through the discharge portion 13. [

The cooling device for the hydrogen gas charger according to the present invention is characterized in that the cooling device for the hydrogen gas charger includes a first heat exchanger 20 connected to the middle part of the supply part 12 and a second heat exchanger 20 connected to the middle part of the discharge part 13 A second heat exchanger 30 connected to the first heat exchanger 20 and the second heat exchanger 30 through a refrigerant pipe 40 and compressing the refrigerant to be supplied to the first and second heat exchangers 20 and 30 And a cooling unit 60 provided at an intermediate portion of the refrigerant pipe 40 to cool the refrigerant passing through the refrigerant pipe 40. [

The refrigerant supplied through the compressor 50 is evaporated while passing through the first and second heat exchangers 20 and 30 and flows through the supply unit 12 and the discharge unit 13 And is configured to cool the heat medium oil.

The refrigerant pipe 40 comprises a first connection pipe 41 connecting the compressor 50 and the cooling means 60, a connection portion 42a and first and second branch portions 42b and 42c And the first and second branch portions 42b and 42c branch from the other side of the connection portion 42a and are connected to the first and second heat exchange portions 42a and 42b, A second connection pipe 42 connecting the cooling unit 60 and the first and second heat exchangers 20 and 30 by being connected to the first heat exchanger 20 and the second heat exchanger 20, A second circulation pipe 44 connecting the second heat exchanger 30 and the compressor 50 to each other and a second circulation pipe 44 connecting the second circulation pipe 43 to the second branch pipe 42c, An auxiliary heat exchanger 45 provided at a connection portion 42a of the first connection pipe 42 and an auxiliary supply pipe 46 branched from the connection portion 42a of the second connection pipe 42 and connected to the auxiliary heat exchanger 45, , An auxiliary circulation pipe (47) connecting the auxiliary heat exchanger (45) and the compressor (50) It is sex.

At this time, expansion valves 42d, 42e, and 46a are provided at the intermediate portions of the first and second branch portions 42b and 42c and the auxiliary circulation pipe 47 so that the refrigerant flows through the expansion valves 42d and 42e, 46a, and then supplied to the first and second heat exchangers (20, 30) and the auxiliary heat exchanger (45).

An intermediate portion of the second circulation pipe 44 is provided with an accumulator 44a for primarily storing the refrigerant.

The compressor 50 compresses the refrigerant introduced through the second circulation pipe 44 and the auxiliary circulation pipe 47 to a high pressure and supplies the refrigerant to the first connection pipe 41 so that the refrigerant flows into the refrigerant pipe 40 Through the first and second heat exchangers (20, 30) and the auxiliary heat exchanger (45).

The cooling means 60 includes a heat exchanger 61 provided at an intermediate portion of the first connection pipe 41 and a water pipe 62 and a drain pipe 63 connected to the heat exchanger 61, So that the refrigerant passing through the first connection pipe (41) can be cooled.

The operation of the thus configured hydrogen gas filling cooling apparatus will be described below.

First, when the circulation pump 14 is driven, the heat medium oil supplied from the precooler is stored in the storage tank 11 through the supply unit 12 and then supplied to the precooler through the discharge unit 13.

When the compressor 50 is driven, the refrigerant is compressed and supplied to the first connection pipe 41, and then flows to the connection portion 42a of the second connection pipe 42 through the cooling means 60 .

At this time, when the cooling means 60 is driven, the cold water supplied to the water supply pipe 62 is heat-exchanged with the refrigerant passing through the heat exchanger 61 while passing through the heat exchanger 61, After cooling the refrigerant whose temperature has been increased while being compressed, it is discharged to the drain pipe (63).

A portion of the refrigerant supplied to the connecting portion 42a of the second connection pipe 42 is cooled through the auxiliary heat exchanger 45 And is supplied to the auxiliary heat exchanger 45 to secondarily cool the refrigerant passing through the connection part 42a of the second connection pipe 42 and then to the auxiliary circulation pipe 47 through the auxiliary circulation pipe 47, (50).

The refrigerant that has been secondarily cooled while passing through the second connection pipe (42) is supplied to the first branch portion (42b).

At this time, the refrigerant supplied to the first branch portion 42b is supplied to the first heat exchanger 20 to cool the heat medium oil supplied to the supply portion 12 so that the first cooled heat medium oil flows into the storage tank 11 and then supplied to the first branched section 42b through the first circulation pipe 43. [

The refrigerant supplied from the connecting portion 42a to the second branch portion 42c and the refrigerant supplied from the first branch portion 42b to the second branch portion 42c through the first heat exchanger 20 The refrigerant is circulated to the compressor (50) through the second circulation pipe (44) after being supplied to the second heat exchanger (30) and secondarily cooling the heat medium oil passing through the discharge part (13).

The refrigerant supplied to the compressor 50 through the second circulation pipe 44 and the auxiliary circulation pipe 47 is compressed by the compressor 50 and supplied to the first connection pipe 41, One cycle is repeated to repeatedly cool the heat medium oil passing through the circulation pipe (10).

The refrigerant extruded from the compressor 50 passes through the first to the second heat exchangers 30 to cool the heat medium oil passing through the circulation pipe 10 two times, Not only the heat medium oil can be effectively cooled but also a part of the refrigerant is supplied to the auxiliary heat exchanger 45 and the refrigerant passing through the second connection pipe 42 is cooled and supplied to the compressor 50, The compressor 50 can not be smoothly circulated to the compressor 50, thereby preventing the compressor 50 from being damaged.

2 to 10 illustrate another embodiment of the present invention in which the cooling unit 60 includes a cooling pipe 64 provided at an intermediate portion of the first connection pipe 41, And a cooling fan 66 provided in front of the cooling fin 65 and blowing air to the cooling fin 65. The cooling fan 65 is connected to the cooling pipe 65, So that the refrigerant can be cooled by air.

The cooling pipe 64 is provided with a plurality of rectilinear tubes 64a arranged so as to be spaced apart from each other in the vertical direction and a plurality of rectilinear tubes 64a arranged at opposite ends of the rectilinear tube 64a in a staggered manner, And a plurality of U-shaped tubes 64b.

A spiral protrusion 64c is formed on the outer circumferential surface of the rectilinear tube 64a.

4, the protrusions 64c are formed on the outer circumferential surface of the rectilinear tube 64a at a constant angle.

At this time, the protrusion 64c is formed by the molding apparatus 70. [

5 to 10, the molding apparatus 70 includes a bed 71 and a conveyance belt 72 provided at one side of the bed 71 and forward and backward by the forward and backward driving means 72a, A support base 73 provided on the other side of the bed 71 and a helical molding protrusion 74a corresponding to the protrusion 64c to be formed in the rectilinear tube 64a on the circumferential surface, And the other end is formed by a molding core 74 rotatably coupled to the support 73 and rotated by a driving means 74b and fitted to the outside of the linear tube 64a, A chuck 75 coupled to one side of a straight tube 64a coupled to the outer side of the forming core 74 to be rotatably coupled to the support table 73, And is disposed on the upper surface of the bed 71 and is adjusted in the forward and backward directions by the forward and backward driving means 77, And pressing the outer peripheral surface of the tube (64a) to the inside consists of a forming unit 76 for forming the projecting portion (64c).

The forward and backward driving means 72a connected to the conveying platform 72 uses a hydraulic cylinder which extends in the forward and backward direction and slides the conveying platform 72 in the forward and backward directions in accordance with the expansion and contraction.

The driving means 74b uses a hydraulic motor connected to the forming core 74 to rotate the forming core 74 with a strong force.

The chuck 75 is rotatably coupled to the rear side of the conveyance belt 72 through a bearing 75d and has a rear side formed with an insertion protrusion 75b inserted into a front end of the straight pipe 64a And a front end portion of the rectilinear tube 64a coupled to the insertion protrusion 75b so as to be movable forward and backward toward the circumference of the insertion protrusion 75b on the rear side of the rotation block 75a And a plurality of tanks 75c for pressure-fixing.

5 and 6, the forming unit 76 is provided on the bed 71 and is adjusted in the forward and backward directions by the forward and backward driving means 77, A plurality of hydraulic cylinders 76c provided so that the piston rods extend into the through holes 76b, a plurality of hydraulic cylinders 76c provided so as to extend through the through holes 76b, The outer peripheral surface of the straight tube 64a is pressurized inward to be provided on the piston rod of the hydraulic cylinder 76c to mold the circumferential surface of the forming core 74 to correspond to the shape of the forming core 74 And a wheel 76d.

The forward and backward driving means 77 for moving the forming unit 76 back and forth is rotatably provided on the upper surface of the bed 71 so as to extend in the front and rear direction, A screw 77a and a driving motor 77b connected to the lead screw 77a and rotating the lead screw 77a in normal and reverse directions. When the lead screw 77a is rotated in the forward and reverse directions by the driving motor 77b, The feed block 76a is slid in the front-rear direction by the screw action of the lead screw 77a.

A method of forming the projecting portion 64c in the straight tube 64a using the molding apparatus 70 constructed as described above will be described below.

7, a worker inserts a straight tube 64a into the peripheral portion of the forming core 74 in a state in which the conveying table 72 is slid forward, and then, as shown in Fig. 8, When the conveying table 72 is slid backward, the chuck 75 is fixedly coupled to the front end of the straight pipe 64a.

When the hydraulic cylinder 76c is extended as shown in Fig. 9 in a state in which the molding unit 76 is transferred forward, the molding wheel 76d is pressed against the molding projection 74a of the molding core 74, The outer circumferential surface of the rectilinear tube 64a is pushed inward so that the protruding portion 64c is formed at the front end of the rectilinear tube 64a.

As shown in Fig. 10, when the molding core 74 is rotated by the driving means 74b and the molding unit 76 is moved backward by using the forward and backward driving means 77, The protruding portion 64c is formed so as to extend rearward from the periphery of the front end portion of the straight tube 64a while the molding wheel 76d is gradually moved backward.

That is, the molding protrusion 74a of the molding core 74 is formed in a spiral shape on the circumferential surface of the molding core 74 while the molding wheel 76d is formed only in the front-back direction together with the transfer block 76a The linear tube 64a is rotated together with the molding core 74 by rotating the molding core 74 so that a spiral protrusion 64c is formed in the linear tube 64a.

When the molding of the protruding portion 64c is completed in the straight tube 64a, the hydraulic cylinder 76c is contracted so that the molding wheel 76d is spaced outward. Then, the molding unit 76 is moved forward The shaping core 74 is rotated in the reverse direction and the straight tube 64a formed with the protrusion 64c on the circumferential surface is moved forward in the forward direction of the shaping core 74 .

When the linear tube 64a is separated from the molding core 74, the worker separates the linear tube 64a fixed to the chuck 75 and inserts a new linear tube 64a into the molding core 74, The spiral protrusion 64c can be repeatedly formed on the circumferential surface of the straight tube 64a by repeating the above-described process.

The cooling device for the hydrogen gas charger thus configured has a spiral protrusion 64c formed on the outer circumferential surface of the linear tube 64a and the air supplied to the periphery of the linear tube 64a by the cooling fan 66 Not only the contact area between the straight tube 64a and the straight tube 64a is widened but also the eddy current is generated in the air by the protrusion 64c when the air flows through the circumference of the straight tube 64a, So that the cooling efficiency of the hydraulic fluid and the refrigerant passing through the straight pipe 64a is improved.

The protruding portion 64c of the straight tube 64a is formed by a molding apparatus 70. The molding apparatus 70 is configured such that an operator joins the straight tube 64a to the periphery of the molding core 74 There is an advantage that the protrusion 64c can be formed effectively by pressing the peripheral portion of the straight tube 64a automatically.

10. Circulation tube 20. First heat exchanger
30. Second heat exchanger 40. Refrigerant tube
50. Compressor 60. Cooling means
70. Molding device

Claims (4)

A cooling device for a hydrogen gas charger which is connected to a circulation pipe (10) connected to a precooler and cools a heating medium oil passing through the circulation pipe (10)
The circulation pipe 10 is provided with a storage tank 11 for storing thermal oil in an intermediate portion thereof and a supply portion 12 for supplying the thermal oil discharged from the precooler to the storage tank 11, And a discharge unit (13) for supplying the heat medium oil stored in the tank (11) to the precooler,
The cooling device for the hydrogen gas charger
A first heat exchanger 20 connected to a middle portion of the supply unit 12,
A second heat exchanger (30) connected to an intermediate portion of the discharge portion (13)
A compressor (50) connected to the first and second heat exchangers (20, 30) through a refrigerant pipe (40) and compressing the refrigerant and supplying the refrigerant to the first and second heat exchangers (20, 30)
And a cooling unit (60) provided at an intermediate portion of the refrigerant pipe (40) for cooling the refrigerant passing through the refrigerant pipe (40)
The refrigerant pipe (40)
A first connection pipe (41) connecting the compressor (50) and the cooling means (60)
The connecting portion 42a and the first and second branching portions 42b and 42c are formed such that one side of the connecting portion 42a is connected to the cooling means 60 and the first and second branching portions 42b and 42c, 42c are connected to the first and second heat exchangers 20, 30 by branching from the other side of the connecting portion 42a to connect the cooling means 60 and the first and second heat exchangers 20, A second connection pipe 42 connecting the first connection pipe 42 and the second connection pipe 42,
A first circulation pipe 43 connecting the first heat exchanger 20 and the second branch 42c,
A second circulation pipe (44) connecting the second heat exchanger (30) and the compressor (50)
An auxiliary heat exchanger 45 provided in a connection portion 42a of the second connection pipe 42,
An auxiliary supply pipe (46) branched from the connection portion (42a) of the second connection pipe (42) and connected to the auxiliary heat exchanger (45)
And an auxiliary circulation pipe (47) connecting the auxiliary heat exchanger (45) and the compressor (50).
The method according to claim 1,
The cooling means (60)
A heat exchanger (61) provided at an intermediate portion of the first connection pipe (41)
A water supply pipe (62) connected to the heat exchanger (61), and a water discharge pipe (63)
Wherein the refrigerant passing through the first connection pipe (41) is water-cooled.
The method according to claim 1,
The cooling means (60)
A cooling pipe 64 provided at an intermediate portion of the first connection pipe 41,
A plurality of cooling fins 65 coupled to the cooling pipe 64,
And a cooling fan (66) provided in front of the cooling fin (65) and blowing air to the cooling fin (65)
The cooling tube (64)
A plurality of rectilinear tubes 64a arranged so as to be spaced apart from each other in the vertical direction,
And a plurality of U-shaped tubes (64b) arranged at opposite ends of the rectilinear tube (64a) in a zigzag shape so that the rectilinear tubes (64a) are mutually connected,
And a helical protrusion (64c) is formed on an outer circumferential surface of the rectilinear tube (64a).
The method of claim 3,
The projecting portion 64c of the straight tube 64a is molded by the molding apparatus 70,
The molding apparatus 70 includes:
A bed 71,
A conveyance belt 72 provided at one side of the bed 71 and forward and backward by the forward and backward driving means 72a,
A support 73 provided on the other side of the bed 71,
A spiral molding protrusion 74a corresponding to the protrusion 64c to be formed on the rectilinear tube 64a is formed on the circumferential surface of the rectilinear tube 64a and the other side is rotatably coupled to the supporter 73, A molded core 74 which is rotated by the outer tube 74b and the outer tube is fitted to the straight tube 64a,
A chuck 75 rotatably coupled to the conveying table 72 and coupled to one side of the straight pipe 64a coupled to the outside of the forming core 74,
Is provided on the upper surface of the bed (71) so as to be positioned between the conveying table (72) and the support table (73) and is adjusted in the forward and backward directions by the forward and backward driving means (77) And a molding unit (76) for pressing the outer circumferential surface of the combined rectilinear tube (64a) inward to form the protruding portion (64c)
The molding unit 76
The through hole 76b provided in the bed 71 and adjusted in the forward and backward directions by the forward and backward driving means 77 and passing through the forming core 74 and the straight pipe 64a passes through the front and rear surfaces A formed transport block 76a,
A plurality of hydraulic cylinders 76c provided so that a piston rod extends into the through hole 76b,
The outer peripheral surface of the straight tube 64a is pressurized inward to be provided on the piston rod of the hydraulic cylinder 76c to mold the circumferential surface of the forming core 74 to correspond to the shape of the forming core 74 And a wheel (76d).

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