CN216050046U - Data acquisition system of energy supplementing equipment of hydrogen station - Google Patents

Abstract

The utility model discloses a data acquisition system of energy supplementing equipment of a hydrogen station in the technical field of data acquisition systems of the energy supplementing equipment, which comprises an air inlet pipe, an air outlet pipe and a mounting block, the mounting block is internally provided with a containing groove, the containing groove is internally provided with a buffer mechanism, the left side wall of the containing groove is provided with an air inlet, the right side wall of the holding tank is provided with an air outlet, the right end of the air inlet pipe is communicated with the air inlet through a sealing mechanism, the left end of the gas outlet pipe is communicated with the gas outlet through the sealing mechanisms, the number of the sealing mechanisms is two, the utility model can effectively buffer the impact force generated by hydrogen with higher initial speed, therefore, the damage of impact force to data acquisition equipment (such as a flowmeter and a pressure gauge) is effectively avoided, the construction cost of the hydrogen station is reduced, the device is convenient to disassemble and assemble, has better refitting performance compared with the prior art, and is suitable for popularization and use.

Description

Data acquisition system of energy supplementing equipment of hydrogen station

Technical Field

The utility model relates to the technical field of energy supplementing equipment data acquisition systems, in particular to a data acquisition system of energy supplementing equipment of a hydrogen station.

Background

The existing data acquisition system of the energy supplementing equipment of the hydrogen refueling station is easy to damage after being used for a long time, and the reason is that the initial speed of hydrogen in a pipeline is high under the high pressure generated by a compressor, so that the data acquisition equipment (a flowmeter, a pressure gauge and the like) is easy to damage due to impact, and the construction cost of the hydrogen refueling station is increased, so that the need of developing the data acquisition system of the energy supplementing equipment of the hydrogen refueling station is necessary.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a data acquisition system of energy supplementing equipment of a hydrogen refueling station, which can effectively buffer the impact force generated by the impact of hydrogen with higher initial speed on the surface of a buffer disc by matching an air inlet pipe, an air outlet pipe, a mounting block and a buffer mechanism, thereby effectively reducing the initial speed of the hydrogen, avoiding the impact force from damaging the data acquisition equipment (a flowmeter, a pressure gauge and the like), reducing the construction cost of the hydrogen refueling station and solving the problem that the existing data acquisition system of the energy supplementing equipment of the hydrogen refueling station is easy to damage after being used for a long time.

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides a hydrogenation station benefit can equipment data acquisition system, includes intake pipe, outlet duct and installation piece, the inside holding tank that is equipped with of installation piece, the inside buffer gear that is equipped with of holding tank, holding tank left side wall is equipped with the air inlet, holding tank right side wall is equipped with the gas outlet, the intake pipe right-hand member is linked together by sealing mechanism with the air inlet, the outlet duct left end is also linked together by sealing mechanism with the gas outlet, and sealing mechanism quantity is two.

Preferably, buffer gear includes annular spacing groove, buffer disc, through-hole, annular limiting plate, spacing pipe, spacing hole, spring, connecting rod and stopper, the holding tank cell wall is equipped with annular spacing groove, the inside vertical buffer disc that is equipped with of holding tank, the buffer disc disk body evenly is equipped with the through-hole, the welding of buffer disc outer wall has annular limiting plate, the annular limiting plate body slides in annular spacing inslot portion.

Preferably, annular spacing groove right side wall is that circular array welding has spacing pipe, spacing pipe left end is equipped with spacing hole, spacing inside being equipped with the spring, spacing downthehole portion runs through there is the connecting rod, the connecting rod right-hand member is located spacing inside and the welding has the stopper, stopper right side wall is laminated with the spring left end, the connecting rod left end welds with annular limiting plate right side wall.

Preferably, the left side wall of the buffer disc is arc-shaped, and a filter screen is fixedly connected inside the through hole.

Preferably, sealing mechanism includes connecting hole and sealed the pad, installation piece left and right sides wall symmetry is equipped with the connecting hole, intake pipe right-hand member threaded connection is inside the connecting hole that is located installation piece left side wall, outlet duct left end threaded connection is inside the connecting hole that is located installation piece right side wall.

Preferably, the sealing gasket is embedded in each connecting hole, the connecting hole in the left side wall of the mounting block is communicated with the air inlet, and the connecting hole in the right side wall of the mounting block is communicated with the air outlet.

Preferably, the number of the connecting holes is two, and the number of the sealing gaskets is two.

Compared with the prior art, the utility model has the beneficial effects that: the utility model can effectively buffer the impact force generated by impacting hydrogen with larger initial speed on the surface of the buffer disc by matching the arranged air inlet pipe, the air outlet pipe, the mounting block and the buffer mechanism, thereby effectively reducing the initial speed of the hydrogen, avoiding the impact force from damaging data acquisition equipment (a flowmeter, a pressure gauge and the like) and further reducing the construction cost of the hydrogen station.

Drawings

FIG. 1 is a schematic three-dimensional structure of the present invention;

FIG. 2 is a structural cross-sectional view of the present invention;

FIG. 3 is a side cross-sectional view of the structure of the present invention;

FIG. 4 is an enlarged view taken at A in FIG. 2;

fig. 5 is a diagram of the working system of the present invention.

In the figure: 1. an air inlet pipe; 2. an air outlet pipe; 3. mounting blocks; 3-1, accommodating a tank; 3-1-1, an annular limiting groove; 3-1-2, an air inlet; 3-1-3, air outlet; 3-2, connecting holes; 4. a buffer tray; 4-1, through holes; 4-1-1, and a filter screen; 5. an annular limiting plate; 6. a limiting pipe; 6-1, limiting holes; 7. a spring; 8. A connecting rod; 9. a limiting block; 10. and a gasket.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The utility model provides the following technical scheme: referring to fig. 1-5, a data acquisition system of energy supplementing equipment of a hydrogen station comprises an air inlet pipe 1, an air outlet pipe 2 and a mounting block 3, wherein a holding tank 3-1 is arranged inside the mounting block 3, a buffer mechanism is arranged inside the holding tank 3-1, an air inlet 3-1-2 is arranged on the left side wall of the holding tank 3-1, an air outlet 3-1-3 is arranged on the right side wall of the holding tank 3-1, the right end of the air inlet pipe 1 is communicated with the air inlet 3-1-2 through a sealing mechanism, the left end of the air outlet pipe 2 is also communicated with the air outlet 3-1-3 through the sealing mechanism, and the number of the sealing mechanisms is two;

further, the buffering mechanism comprises an annular limiting groove 3-1-1, a buffering disc 4, a through hole 4-1, an annular limiting plate 5, a limiting pipe 6, a limiting hole 6-1, a spring 7, a connecting rod 8 and a limiting block 9, the wall of the accommodating groove 3-1 is provided with the annular limiting groove 3-1-1, the inside of the accommodating groove 3-1 is vertically provided with the buffering disc 4, the disc body of the buffering disc 4 is uniformly provided with the through hole 4-1, so that hydrogen pressurized by a compressor enters the accommodating groove 3-1 through the air inlet pipe 1, impacts the surface of the buffering disc 4 firstly, then enters the air outlet pipe 2 through the through hole 4-1 and is conveyed to the hydrogenation machine through the air outlet pipe 2, the annular limiting plate 5 is welded on the outer wall of the buffering disc 4, the plate body of the annular limiting plate 5 slides inside the annular limiting groove 3-1-1, the right side wall of the annular limiting groove 3-1-1 is welded with a limiting pipe 6 in a circular array, the left end of the limiting pipe 6 is provided with a limiting hole 6-1, a spring 7 is arranged inside the limiting pipe 6, a connecting rod 8 penetrates through the limiting hole 6-1, the right end of the connecting rod 8 is positioned inside the limiting pipe 6 and is welded with a limiting block 9, the right side wall of the limiting block 9 is attached to the left end of the spring 7, the left end of the connecting rod 8 is welded with the right side wall of the annular limiting plate 5, so when hydrogen with larger speed entering the accommodating groove 3-1 from the air inlet pipe 1 impacts the surface of the buffer disc 4, the impact disc 4 is driven to move in the accommodating groove 3-1, the annular limiting plate 5 is driven to move in the annular limiting groove 3-1-1, when the annular limiting plate 5 moves in the annular limiting groove 3-1-1, the limiting block 9 is driven to move inside the limiting pipe 6 through the connecting rod 8, when the limiting block 9 moves inside the limiting pipe 6, the spring 7 is compressed to enable the spring 7 to generate elastic deformation to generate reverse acting force, so that impact force generated when hydrogen with high initial speed impacts the surface of the buffer disc 4 can be effectively buffered, the initial speed of the hydrogen can be effectively reduced, damage to data acquisition equipment (a flowmeter, a pressure gauge and the like) caused by impact force is avoided, and the construction cost of a hydrogen filling station is reduced;

furthermore, the sealing mechanism comprises connecting holes 3-2 and sealing gaskets 10, the left side wall and the right side wall of the mounting block 3 are symmetrically provided with the connecting holes 3-2, the number of the connecting holes 3-2 is two, the right end of the air inlet pipe 1 is in threaded connection with the inside of the connecting hole 3-2 on the left side wall of the mounting block 3, the left end of the air outlet pipe 2 is in threaded connection with the inside of the connecting hole 3-2 on the right side wall of the mounting block 3, the sealing gaskets 10 are embedded in the connecting holes 3-2, the number of the sealing gaskets 10 is two, and the sealing gaskets 10 can effectively prevent hydrogen leakage, so that the structural design of the utility model is reasonable, the connecting hole 3-2 on the left side wall of the mounting block 3 is communicated with the air inlet 3-1-2, the connecting hole 3-2 on the right side wall of the mounting block 3 is communicated with the air outlet 3-1-3, therefore, a user can control the air inlet pipe 1 and the air outlet pipe 2 only by rotating the air inlet pipe 1 and the air outlet pipe 2 in the forward and reverse directions, The disassembly and assembly operation of the air outlet pipe 2 and the installation block 3 ensures that the utility model has simple assembly function and convenient disassembly and assembly, and compared with the prior art, the utility model also has better refitting performance and is suitable for popularization and use.

The working principle is as follows: when a hydrogenation station needs to supplement hydrogen energy, an air inlet pipe 1 can be connected to the output end of a compressor on a transport vehicle, then a stop valve and the compressor on the transport vehicle are opened, when hydrogen pressurized by the compressor enters an accommodating groove 3-1 arranged inside a mounting block 3 through the air inlet pipe 1, the hydrogen impacts the surface of a buffer disc 4 firstly, then the hydrogen passes through a through hole 4-1 and then enters an air outlet pipe 2 to be conveyed to a hydrogenation machine through an air outlet pipe 2, when the hydrogen with higher speed entering the accommodating groove 3-1 from the air inlet pipe 1 impacts the surface of the buffer disc 4, the impact disc 4 is driven to move in the accommodating groove 3-1, so that an annular limiting plate 5 is driven to move in the annular limiting groove 3-1-1, when the annular limiting plate 5 moves in the annular limiting groove 3-1-1, a limiting block 9 is driven to move inside a limiting pipe 6 through a connecting rod 8, when the limiting block 9 moves in the limiting pipe 6, the spring 7 is compressed to enable the spring 7 to generate elastic deformation to generate reverse acting force, so that impact force generated when hydrogen with high initial speed impacts the surface of the buffer disc 4 can be effectively buffered, the initial speed of the hydrogen is effectively reduced, damage to data acquisition equipment (a flowmeter, a pressure gauge and the like) caused by impact force is avoided, the construction cost of a hydrogen adding station is reduced, and the buffered hydrogen finally enters a hydrogen adding machine through the gas outlet pipe 3;

the user can control the disassembly and assembly operation of the air inlet pipe 1, the air outlet pipe 2 and the mounting block 3 only by rotating the air inlet pipe 1 and the air outlet pipe 2 forward and backward, so the utility model also has simple assembly function, is convenient to disassemble and assemble, has better refitting performance compared with the prior art, and is suitable for popularization and use.

While the utility model has been described above with reference to an embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the utility model. In particular, the various features of the embodiments disclosed herein may be used in any combination, provided that there is no structural conflict, and the combinations are not exhaustively described in this specification merely for the sake of brevity and conservation of resources. Therefore, it is intended that the utility model not be limited to the particular embodiments disclosed, but that the utility model will include all embodiments falling within the scope of the appended claims.

Claims (7)

1. The utility model provides a hydrogenation station can make up equipment data acquisition system, includes intake pipe (1), outlet duct (2) and installation piece (3), its characterized in that: the air inlet pipe is characterized in that a containing groove (3-1) is formed in the installing block (3), a buffer mechanism is arranged in the containing groove (3-1), an air inlet (3-1-2) is formed in the left side wall of the containing groove (3-1), an air outlet (3-1-3) is formed in the right side wall of the containing groove (3-1), the right end of the air inlet pipe (1) is communicated with the air inlet (3-1-2) through a sealing mechanism, the left end of the air outlet pipe (2) is communicated with the air outlet (3-1-3) through the sealing mechanism, and the number of the sealing mechanisms is two.

2. The data acquisition system of the refueling station energy replenishing equipment according to claim 1, wherein: the buffer mechanism comprises an annular limiting groove (3-1-1), a buffer disc (4), a through hole (4-1), an annular limiting plate (5), a limiting pipe (6), a limiting hole (6-1), a spring (7), a connecting rod (8) and a limiting block (9), wherein the groove wall of the accommodating groove (3-1) is provided with the annular limiting groove (3-1-1), the buffer disc (4) is vertically arranged inside the accommodating groove (3-1), the disc body of the buffer disc (4) is uniformly provided with the through hole (4-1), the outer wall of the buffer disc (4) is welded with the annular limiting plate (5), and the plate body of the annular limiting plate (5) slides inside the annular limiting groove (3-1-1).

3. The data acquisition system of the refueling station energy replenishing equipment according to claim 2, wherein: annular spacing groove (3-1-1) right side wall is that circular array welding has spacing pipe (6), spacing pipe (6) left end is equipped with spacing hole (6-1), spacing pipe (6) inside is equipped with spring (7), spacing hole (6-1) inside has run through connecting rod (8), connecting rod (8) right-hand member is located spacing pipe (6) inside and has welded stopper (9), stopper (9) right side wall and spring (7) left end are laminated, connecting rod (8) left end and annular limiting plate (5) right side wall weld mutually.

4. The data acquisition system of the refueling station energy replenishing equipment according to claim 2, wherein: the left side wall of the buffer disc (4) is arc-shaped, and a filter screen (4-1-1) is fixedly connected inside the through hole (4-1).

5. The data acquisition system of the refueling station energy replenishing equipment according to claim 1, wherein: sealing mechanism includes connecting hole (3-2) and sealed pad (10), installation piece (3) left and right sides lateral wall symmetry is equipped with connecting hole (3-2), intake pipe (1) right-hand member threaded connection is inside connecting hole (3-2) that are located installation piece (3) left side wall, outlet duct (2) left end threaded connection is inside connecting hole (3-2) that are located installation piece (3) right side wall.

6. The data acquisition system of the refueling station energy replenishing equipment according to claim 5, wherein: the sealing gasket (10) is embedded in each connecting hole (3-2), the connecting hole (3-2) in the left side wall of the mounting block (3) is communicated with the air inlet (3-1-2), and the connecting hole (3-2) in the right side wall of the mounting block (3) is communicated with the air outlet (3-1-3).

7. The data acquisition system of the refueling station energy replenishing equipment according to claim 5, wherein: the number of the connecting holes (3-2) is two, and the number of the sealing gaskets (10) is two.

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