CN217926187U

CN217926187U - Compressed air supercharging device

Info

Publication number: CN217926187U
Application number: CN202222075857.2U
Authority: CN
Inventors: 许雷明; 徐兆平; 龚宇杰; 戴涵洋
Original assignee: Jiangsu Changbao Steel Tube Co ltd
Current assignee: Jiangsu Changbao Steel Tube Co ltd
Priority date: 2022-08-08
Filing date: 2022-08-08
Publication date: 2022-11-29
Anticipated expiration: 2032-08-08

Abstract

The utility model discloses a compressed air supercharging device, including air supply, at least two sets of booster pump group, at least bipartition collection outlet duct and collection outlet duct, wherein every group booster pump group includes two at least booster pumps, the air supply import of booster pump pass through the pipeline with the air supply links to each other, the pressure boost power supply import of booster pump pass through the pipeline with the air supply links to each other, and every diversity outlet duct corresponds a booster pump group, and the gas outlet of the booster pump of same group booster pump group connects in parallel to the diversity outlet duct that corresponds, the export of diversity outlet duct and connect to collection outlet duct, local equipment high pressure demand can be solved to it, satisfies equipment normal operating pressure and flow.

Description

Compressed air supercharging device

Technical Field

The utility model relates to a compressed air supercharging device.

Background

At present, compressed air is the second largest power energy next to electric power, and is a multi-purpose process air source, and the application range of the compressed air is in the industries and departments of petroleum, chemical engineering, metallurgy, electric power, machinery, light industry, textile, automobile manufacturing, electronics, food, medicine, biochemistry, national defense, scientific research and the like, but most of the existing compressed air supercharging devices can only output compressed air directionally to single equipment and cannot meet the requirement of local high pressure inside the equipment, for example, the Chinese patent with the publication number of CN 202382731U discloses an efficient energy-saving compressed air supercharging device, compressed air after supercharging is stored in an air storage tank to supply air to air equipment, and the requirement of local high pressure inside the equipment cannot be met.

Disclosure of Invention

The utility model aims to solve the technical problem that overcome prior art's defect, provide a compressed air supercharging device, it can solve local equipment high pressure demand, satisfies equipment normal operating pressure and flow.

In order to solve the technical problem, the technical scheme of the utility model is that: a compressed air charging apparatus comprising:

a gas source;

each group of booster pump units comprises at least two booster pumps, the air source inlets of the booster pumps are connected with the air source through pipelines, and the boosting power source inlets of the booster pumps are connected with the air source through pipelines;

at least two branch air outlet pipes, each branch air outlet pipe corresponds to one booster pump group, and air outlets of booster pumps of the same group of booster pump groups are connected to the corresponding branch air outlet pipes in parallel;

and the outlet of the diversity air outlet pipe is connected to the total air outlet pipe in parallel.

Furthermore, the compressed air supercharging device also comprises a gas-liquid separator, and an inlet of the gas-liquid separator is connected with an outlet of the main gas collecting and discharging pipe.

Further, the compressed air supercharging device further comprises a dryer, an inlet of the dryer is connected with the gas-liquid separator, and an outlet of the dryer is connected to each gas-using device.

Furthermore, the pipeline comprises an air source air inlet collecting pipe and a pressurizing power source air inlet collecting pipe which are correspondingly arranged with each group of pressurizing pump groups, a plurality of air source air inlet interfaces are arranged on the air source air inlet collecting pipe, a plurality of pressurizing power source air inlet interfaces are arranged on the pressurizing power source air inlet collecting pipe, air source inlets of the pressurizing pumps of the same group of pressurizing pump groups are connected to the corresponding air source air inlet interfaces of the air source air inlet pipe, and pressurizing power source inlets of the pressurizing pumps of the same group of pressurizing pump groups are connected to the pressurizing power source air inlet interfaces of the pressurizing power source air inlet collecting pipe.

Further, an air source air inlet valve is arranged on the air source air inlet interface;

and/or a supercharging power source air inlet interface is provided with a supercharging power source air inlet valve.

Further, booster pump group is equipped with two sets ofly, air supply collection intake pipe correspondence is equipped with two, pressure boost power source collection intake pipe correspondence is equipped with two, the pipeline still includes total intake pipe and branch intake pipe, the air supply with the import of total intake pipe links to each other, the export of total intake pipe with branch intake pipe's middle part links to each other, branch intake pipe's both ends are equipped with two respectively and lead to flange, and an air supply collection intake pipe and a pressure boost power source collection intake pipe are connected respectively at two lead to flange's both ends.

Furthermore, in order to realize the pressure regulating function of each booster pump, a pressure regulating valve and a pressure-increasing pressure gauge are connected to the inlet of a boosting power source of each booster pump.

Furthermore, a pressure gauge for collecting pressure in the diversity air outlet pipe is connected to the diversity air outlet pipe.

Furthermore, a stop valve is connected between the diversity air outlet pipe and the total diversity air outlet pipe.

Furthermore, an air outlet valve is connected between the air outlet of the booster pump and the corresponding diversity air outlet pipe.

After the technical scheme is adopted, the utility model discloses gas with air supply output passes through pipeline reposition of redundant personnel to air supply collection intake pipe and pressure boost power source collection intake pipe, through air supply collection intake pipe with gas water conservancy diversion to the air supply import of booster pump in, as the air supply of booster pump, through pressure boost power source collection intake pipe with gas water conservancy diversion to the pressure boost power source import of booster pump, as the pressure boost power source of booster pump, and the pressure of the gas of the pressure boost power source import that accessible air-vent valve and the adjustment of pressure boost gauge get into the booster pump, thereby adjust the boost pressure of booster pump, then through the air supply water conservancy diversion after a plurality of booster pumps with the pressure boost to the diversity outlet duct, at last water conservancy diversion to the total set outlet duct, reach the pressure of required air supply, rethread vapour and liquid separator and desicator's aftertreatment, provide equipment for the use, simultaneously can also control the action of booster pump through the controller, with the air supply pressure of adjustment integrated device output, the requirement of equipment to pressure has been satisfied well.

Drawings

Fig. 1 is a schematic structural view of the compressed air supercharging device of the present invention.

Detailed Description

In order that the present invention may be more clearly understood, the following detailed description is given with reference to the accompanying drawings.

As shown in fig. 1, in the present embodiment, a compressed air charging apparatus includes:

a gas source 1;

each group of booster pump sets comprises five booster pumps 18, the air source inlets of the booster pumps 18 are connected with an air source 1 through pipelines, and the boosting power source inlets of the booster pumps 18 are connected with the air source 1 through pipelines;

two branch air outlet pipes 2 are arranged, each branch air outlet pipe 2 corresponds to one booster pump group, and air outlets of booster pumps 18 of the same group of booster pump groups are connected in parallel to the corresponding branch air outlet pipes 2;

the outlet of the total air collecting and discharging pipe 3 and the outlet of the diversity air discharging pipe 2 are connected with the total air collecting and discharging pipe 3 in parallel.

The number of the booster pump groups is not limited to this, the number of the booster pumps 10 in each booster pump group is not limited to this, and the number of the gas collecting and discharging pipes 2 and the gas collecting and discharging pipes 2 is not limited to this.

As shown in fig. 1, in this embodiment, the compressed air supercharging device may further include a gas-liquid separator 4, an inlet of the gas-liquid separator 4 is connected to an outlet of the main gas collecting and discharging pipe 3, and the gas-liquid separator 4 is configured to perform gas-liquid separation on the compressed gas.

As shown in fig. 1, in the present embodiment, the compressed air pressurizing device may further include a dryer 5, an inlet of the dryer 5 is connected to the gas-liquid separator 4, an outlet of the dryer 5 is connected to each gas appliance, and the dryer 5 is configured to perform a drying process on the gas after gas-liquid separation.

Specifically, as shown in fig. 1, the pipeline may specifically be of a structure including an air source air inlet collecting pipe 9 and a pressurizing power source air inlet collecting pipe 10 which are correspondingly arranged with each group of pressurizing pump sets, a plurality of air source air inlet interfaces are arranged on the air source air inlet collecting pipe 9, a plurality of pressurizing power source air inlet interfaces are arranged on the pressurizing power source air inlet collecting pipe 10, air source inlets of the pressurizing pumps 18 of the same group of pressurizing pump sets are connected to the air source air inlet interfaces of the corresponding air source air inlet pipes 9, and pressurizing power source inlets of the pressurizing pumps 18 of the same group of pressurizing pump sets are connected to the pressurizing power source air inlet interfaces of the pressurizing power source air inlet collecting pipe 10.

Specifically, an air source air inlet valve 11 is arranged on the air source air inlet interface; and a supercharging power source air inlet port is provided with a supercharging power source air inlet valve 12.

In this embodiment, as shown in fig. 1, the booster pump group is equipped with two sets ofly, air supply collection intake pipe 9 corresponds and is equipped with two, booster power supply collection intake pipe 10 corresponds and is equipped with two, the pipeline still includes total intake pipe 6 and branch intake pipe 7, air supply 1 links to each other with the import of total intake pipe 6, the export of total intake pipe 6 links to each other with the middle part of branch intake pipe 7, the both ends of branch intake pipe 7 are equipped with two respectively and lead to flange 8, an air supply collection intake pipe 9 and a booster power supply collection intake pipe 10 are connected respectively to two ends that lead to flange 8.

In the present embodiment, as shown in fig. 1, a pressure regulating valve 13 and a boost pressure gauge 14 are connected to the boost power source inlet of the booster pump 18; the pressure of the pressure increase of the pressure regulating body 18 is regulated by the pressure regulating valve 13 and the pressure regulating pressure gauge 14.

Specifically, the diversity air outlet pipe 2 is connected with a pressure gauge 15 for collecting pressure in the diversity air outlet pipe 2.

Specifically, a stop valve 16 is connected between the diversity air outlet pipe 2 and the total air outlet pipe 3, and the stop valve 16 is used for switching on and off the connection between the diversity air outlet pipe 2 and the total air outlet pipe 3.

Specifically, an air outlet valve 17 is connected between an air outlet of the booster pump 18 and the corresponding diversity air outlet pipe 2, and the air outlet valve 17 is used for switching on and off the connection between the corresponding booster pump 18 and the diversity air outlet pipe 2.

In this embodiment, the gas output from the gas source 1 is divided by the total gas inlet pipe 6 and then respectively flows into the gas source gas collecting and inlet pipe 9 and the supercharging power source gas collecting and inlet pipe 10 through the two gas dividing and inlet pipes 7, the gas is guided to the gas source inlet of the supercharging pump 18 through the gas source gas collecting and inlet pipe 9 and then serves as the gas source of the supercharging pump 18, similarly, the gas is guided to the supercharging power source inlet of the supercharging pump 18 through the supercharging power source gas collecting and inlet pipe 10 and serves as the supercharging power source of the supercharging pump 18, then the pressure of the gas entering the supercharging power source inlet of the supercharging pump 18 can be adjusted through the adjusting pressure regulating valve 13 and the supercharging pressure gauge 14, so as to adjust the supercharging pressure of the supercharging pump 18, then the supercharged gas is guided to the gas dividing and outlet pipe 2 through the plurality of the supercharging pumps 18 and finally guided to the total gas collecting and outlet pipe 3 to reach the required gas pressure, and then is subjected to the post-treatment of the gas-liquid separator 4 and the dryer 5 and is provided for the equipment, and at the same time, and the action of the supercharging pump 18 can be controlled by the controller, so as to adjust the gas source pressure output by the whole device.

The above-mentioned embodiments further explain in detail the technical problems, technical solutions and advantages solved by the present invention, and it should be understood that the above only is a specific embodiment of the present invention, and is not intended to limit the present invention, and any modifications, equivalent substitutions, improvements, etc. made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims

1. A compressed air supercharging apparatus characterized by comprising:

a gas source (1);

each group of booster pump sets comprises at least two booster pumps (18), air source inlets of the booster pumps (18) are connected with the air source (1) through pipelines, and boosting power source inlets of the booster pumps (18) are connected with the air source (1) through pipelines;

at least two branch air outlet pipes (2), wherein each branch air outlet pipe (2) corresponds to one booster pump group, and air outlets of booster pumps (18) of the same group of booster pump groups are connected to the corresponding branch air outlet pipes (2) in parallel;

the outlet of the diversity air outlet pipe (2) is connected to the total air outlet collecting pipe (3) in parallel.

2. The compressed air charging device according to claim 1,

the gas-liquid separator is characterized by further comprising a gas-liquid separator (4), and an inlet of the gas-liquid separator (4) is connected with an outlet of the main gas collecting and discharging pipe (3).

3. The compressed air charging device according to claim 2,

the dryer is characterized by further comprising a dryer (5), wherein an inlet of the dryer (5) is connected with the gas-liquid separator (4), and an outlet of the dryer (5) is connected to each gas appliance.

4. The compressed air charging device according to claim 1,

the pipeline comprises an air source air inlet collecting pipe (9) and a pressurizing power source air inlet collecting pipe (10) which correspond to each group of pressurizing pump groups, a plurality of air source air inlet interfaces are arranged on the air source air inlet collecting pipe (9), a plurality of pressurizing power source air inlet interfaces are arranged on the pressurizing power source air inlet collecting pipe (10), air source inlet connections of the pressurizing pumps (18) of the same group of pressurizing pump groups correspond to the air source air inlet interfaces of the air source air inlet collecting pipe (9), and pressurizing power source inlet connections of the pressurizing pumps (18) of the same group of pressurizing pump groups are arranged on the pressurizing power source air inlet interfaces of the pressurizing power source air inlet collecting pipe (10).

5. The compressed air charging apparatus according to claim 4,

an air source air inlet valve (11) is arranged on the air source air inlet interface;

and/or a supercharging power source air inlet interface is provided with a supercharging power source air inlet valve (12).

6. The compressed air charging apparatus according to claim 4,

the booster pump package is equipped with two sets ofly, air supply collection intake pipe (9) correspondence is equipped with two, pressure boost power supply collection intake pipe (10) correspondence is equipped with two, the pipeline still includes total intake pipe (6) and branch intake pipe (7), air supply (1) with the import of total intake pipe (6) links to each other, the export of total intake pipe (6) with the middle part of branch intake pipe (7) links to each other, the both ends of branch intake pipe (7) are equipped with two respectively and lead to flange (8), and an air supply collection intake pipe (9) and a pressure boost power supply collection intake pipe (10) are connected respectively at the both ends of two logical flange (8).

7. The compressed air charging device according to claim 1,

and the inlet of a boosting power source of the booster pump (18) is connected with a pressure regulating valve (13) and a boosting pressure gauge (14).

8. The compressed air charging device according to claim 1,

and the diversity air outlet pipe (2) is connected with a pressure gauge (15) for collecting pressure in the diversity air outlet pipe (2).

9. The compressed air charging device according to claim 1,

and a stop valve (16) is connected between the diversity air outlet pipe (2) and the total diversity air outlet pipe (3).

10. The compressed air charging device according to claim 1,

an air outlet valve (17) is connected between the air outlet of the booster pump (18) and the corresponding diversity air outlet pipe (2).