阅读说明：本技术 一种利用空气能实现蒸汽连续压缩的装置及方法 (Device and method for realizing continuous compression of steam by utilizing air energy ) 是由 胡雪蛟 章先涛 余沛源 曾远航 于 2020-06-24 设计创作，主要内容包括：本发明公开了一种利用空气能实现蒸汽连续压缩的装置及方法,属于工业蒸汽压缩技术领域,包括：进汽管线,用于输入低压低温蒸汽；排汽管线,用于输出高压高温蒸汽；一对活塞式压缩缸,其分别纵向设置,均包括缸体、活塞、以及往复组件,缸体内位于活塞上方的空间为蒸汽缸,蒸汽缸通过第一阀门连接进汽管线,并通过第二阀门连接排汽管线；活塞向下运行时,开启第一阀门以输入低压低温蒸汽,活塞运行到最低点时,关闭第一阀门,活塞向上运行到最高点时,开启第二阀门以输出高压高温蒸汽；两个蒸汽缸交替进行进汽和排汽。本发明的有益效果：实现蒸汽压缩的连续工作模式,实现了利用空气能压缩蒸汽的连续运行,不需要额外的电力输入,系统结构简单。(The invention discloses a device and a method for realizing continuous compression of steam by utilizing air energy, belonging to the technical field of industrial steam compression and comprising the following steps: the steam inlet pipeline is used for inputting low-pressure low-temperature steam; the steam exhaust pipeline is used for outputting high-pressure high-temperature steam; the pair of piston type compression cylinders are respectively and longitudinally arranged and respectively comprise a cylinder body, a piston and a reciprocating assembly, the space above the piston in the cylinder body is a steam cylinder, and the steam cylinder is connected with a steam inlet pipeline through a first valve and is connected with a steam exhaust pipeline through a second valve; when the piston moves downwards, the first valve is opened to input low-pressure and low-temperature steam, when the piston moves to the lowest point, the first valve is closed, and when the piston moves upwards to the highest point, the second valve is opened to output high-pressure and high-temperature steam; the two steam cylinders alternately perform steam admission and steam exhaust. The invention has the beneficial effects that: the continuous working mode of vapor compression is realized, the continuous operation of compressing vapor by utilizing air energy is realized, no extra electric power input is needed, and the system structure is simple.)

1. An apparatus for achieving continuous compression of vapor using air energy, the apparatus comprising:

the steam inlet pipeline (1) is used for inputting low-pressure low-temperature steam;

the steam exhaust pipeline (4) is used for outputting high-pressure high-temperature steam;

a pair of piston type compression cylinders (6) which are longitudinally arranged, wherein each piston type compression cylinder (6) comprises a cylinder body (7), a piston (21) and a reciprocating assembly for controlling the piston (21) to longitudinally reciprocate, a space above the piston (21) in the cylinder body (7) is a steam cylinder (23), and the steam cylinder (23) is connected with the steam inlet pipeline (1) through a first valve (a) and is connected with the steam exhaust pipeline (4) through a second valve (b);

when the piston (21) runs downwards, the first valve (a) is opened to input low-pressure low-temperature steam, when the piston (21) runs to the lowest point, the first valve (a) is closed, and when the piston (21) runs upwards to the highest point, the second valve (b) is opened to output high-pressure high-temperature steam;

at least two of the steam cylinders (23) alternately perform steam admission and steam exhaust.

2. The device according to claim 1, characterized in that the bottom of the cylinder (7) is provided with a fixed partition (22), and the space in the cylinder (7) between the piston (21) and the fixed partition (22) is an air cylinder (24).

3. The apparatus of claim 2, wherein the reciprocating assembly comprises a counterweight liquid disposed within the steam cylinder (23), and an energy storage device (26) disposed within the air cylinder (24) and connecting the piston (21) and the fixed diaphragm (22).

4. The device as claimed in claim 3, characterized in that the top of the steam cylinder (23) is also provided with a radiator (27);

a liquid channel (28) is further arranged on the piston (21) in a penetrating mode, and the liquid channel (28) is further connected with a liquid drainage pipeline (5) through a third valve (c);

when the piston (21) moves to the lowest point, the third valve (c) is opened to discharge at least part of the counterweight liquid, the third valve (c) is closed after the liquid discharge is finished, and the piston (21) starts to move upwards.

5. The device according to claim 2, characterized in that said reciprocating assembly comprises a push-pull device connected to said piston (21) and an energy storage device (26) arranged in said air cylinder (24) and connecting said piston (21) and said fixed partition (22).

6. A device according to claim 3 or 5, characterized in that the energy storage means (26) are of the type comprising springs and shock absorbers.

7. The apparatus of claim 1, wherein the low pressure, low temperature steam has a pressure value in the range of 1.2kPa to 50 kPa.

8. A method for realizing continuous compression of vapor by utilizing air energy, which is characterized in that the device for realizing continuous compression of vapor by utilizing air energy is based on any one of the claims 1 to 7; the method comprises the following steps:

in the expansion process, the first valve (a) and the second valve (b) are closed initially, the piston (21) is located at the highest point, the reciprocating assembly applies downward pulling force to the piston (21), the piston (21) runs downwards, the first valve (a) is opened when the piston (21) runs downwards, the steam cylinder (23) is in an expansion state and inputs low-pressure low-temperature steam through the steam inlet pipeline (1), and when the piston (21) runs to the lowest point, the first valve (a) is closed;

in the compression process, the reciprocating assembly applies upward thrust to the piston (21), the piston (21) moves upwards, the steam cylinder (23) is in a compression state and compresses low-pressure low-temperature steam to obtain high-pressure high-temperature steam when the piston (21) moves upwards, and when the piston (23) moves to the highest point, the second valve (b) is opened, and the high-pressure high-temperature steam is output through the steam outlet pipeline (4);

each piston type compression cylinder (6) compresses low-pressure low-temperature steam through the expansion process and the compression process to obtain high-pressure high-temperature steam, and the two piston type compression cylinders (6) alternately perform the expansion process and the compression process.

9. The method according to claim 8, wherein when the reciprocating assembly comprises a weighted liquid, during the expansion process, the piston (21) moves to the lowest point, the third valve (c) is opened, at least part of the weighted liquid is discharged through the discharge line (5), and after the discharge is finished, the third valve (c) is closed, at which point the expansion process is finished;

in the compression process, condensing high-pressure and high-temperature steam through a radiator (27) to obtain condensed water, and dripping the condensed water into the counterweight liquid.

10. The method according to claim 8, wherein when the reciprocating assembly comprises the push-pull device, a downward pulling force is applied to the piston (21) by the push-pull device during the expansion process;

during the compression process, an upward thrust is applied to the piston (21) by the push-pull device.

Technical Field

The invention relates to the technical field of industrial vapor compression, in particular to a device and a method for realizing continuous compression of vapor by utilizing air energy.

Background

The steam compressor is a key device for processing steam generated by the heat recovery system through compression action so as to improve the temperature and pressure of the steam, and is used for pressurizing and heating low-pressure and low-temperature steam so as to meet the temperature and pressure requirements required by the process or engineering.

The air energy steam compressor is a device which utilizes the pressure difference between air and low-pressure steam, recovers air pressure energy to compress the steam, realizes temperature rise and pressure rise of the low-pressure low-temperature steam, and has good economic benefit due to no need of extra power input.

However, the limited air energy vapor compressor has limited working modes, and the non-continuity of the vapor compression process caused by the start and stop of the control valve is a periodic working state in nature. Therefore, the development of a vapor compression device capable of continuous compression is a problem to be solved at present.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a device and a method which can continuously work and can realize continuous compression of steam by utilizing air.

The invention provides a device for realizing continuous compression of steam by utilizing air energy, which comprises:

the steam inlet pipeline is used for inputting low-pressure low-temperature steam;

the steam exhaust pipeline is used for outputting high-pressure high-temperature steam;

the pair of piston type compression cylinders are longitudinally arranged, each piston type compression cylinder comprises a cylinder body, a piston and a reciprocating assembly for controlling the piston to longitudinally reciprocate, the space above the piston in the cylinder body is a steam cylinder, and the steam cylinder is connected with the steam inlet pipeline through a first valve a and is connected with the steam exhaust pipeline through a second valve b;

when the piston runs downwards, the first valve a is opened to input low-pressure low-temperature steam, when the piston runs to the lowest point, the first valve a is closed, and when the piston runs upwards to the highest point, the second valve b is opened to output high-pressure high-temperature steam;

at least two of the steam cylinders alternately perform steam admission and steam exhaust.

Preferably, a fixed partition plate is arranged at the bottom of the cylinder body, and a space between the piston and the fixed partition plate in the cylinder body is an air cylinder.

Preferably, the reciprocating assembly comprises a weighted liquid disposed within the steam cylinder, and an energy storage device disposed within the air cylinder and connecting the piston and the fixed diaphragm.

Preferably, the top of the steam cylinder is also provided with a radiator;

the piston is also provided with a liquid channel in a penetrating way, and the liquid channel is also connected with a liquid discharge pipeline through a third valve c;

and when the piston moves to the lowest point, the third valve c is opened to discharge at least part of the counterweight liquid, and after the discharge is finished, the third valve c is closed, and the piston starts to move upwards.

Preferably, the reciprocating assembly comprises a push-pull device connected with the piston and an energy storage device arranged in the air cylinder and connected with the piston and the fixed partition plate.

Preferably, the types of energy storage devices include springs and shock absorbers.

Preferably, the pressure value of the low-pressure low-temperature steam is in the range of 1.2kPa to 50 kPa.

A method for realizing continuous compression of steam by utilizing air energy is based on the device for realizing continuous compression of steam by utilizing air energy; the method comprises the following steps:

in the expansion process, the first valve a and the second valve b are closed initially, the piston is located at the highest point, the reciprocating assembly applies downward pulling force to the piston, the piston runs downwards, the first valve a is opened when the piston runs downwards, the steam cylinder is in an expansion state, low-pressure low-temperature steam is input through the steam inlet pipeline, and the first valve a is closed when the piston runs to the lowest point;

in the compression process, the reciprocating assembly applies upward thrust to the piston, the piston moves upwards, when the piston moves upwards, the steam cylinder is in a compression state and compresses low-pressure low-temperature steam to obtain high-pressure high-temperature steam, when the piston moves to the highest point, the second valve b is opened, and the high-pressure high-temperature steam is output through the steam outlet pipeline;

and each piston type compression cylinder compresses low-pressure low-temperature steam through the expansion process and the compression process to obtain high-pressure high-temperature steam, and the two piston type compression cylinders alternately perform the expansion process and the compression process.

Preferably, when the reciprocating assembly comprises a weighted liquid, in the expansion process, when the piston runs to the lowest point, the third valve c is opened, at least part of the weighted liquid is discharged through the liquid discharge line, and after the liquid discharge is finished, the third valve c is closed, and then the expansion process is finished;

and in the compression process, condensing the high-pressure high-temperature steam through a radiator to obtain condensed water, wherein the condensed water drops into the counterweight liquid.

Preferably, when the reciprocating assembly comprises the push-pull device, a downward pulling force is applied to the piston by the push-pull device during the expansion process;

during the compression process, an upward thrust is applied to the piston by the push-pull device.

The invention has the beneficial effects that:

1. the defect that the conventional air energy steam compression device operates periodically is overcome, and the alternative operation state of the double-piston type compression cylinders is utilized and the alternative control of valve control is matched, so that the two double-piston type compression cylinders alternately perform an expansion process and a compression process, the continuous working mode of steam compression is realized, and the continuous operation of compressing steam by utilizing air energy is realized.

2. The air pressure in the environment is used for compressing low-pressure low-temperature steam to do work, extra power input is not needed, and the system structure is simple.

Drawings

Fig. 1 is a schematic structural diagram of an apparatus for achieving continuous compression of vapor by using air in a preferred embodiment of the present invention.

Reference numbers in the figures:

1-a steam inlet line; 2-a first compression cylinder; 21-a piston; 22-a fixed partition; 23-a steam cylinder; 24-air cylinder; 25-liquid cylinder; 26-an energy storage device; 27-a heat sink; 28-a liquid channel; 3-a second compression cylinder; 4-a steam outlet pipeline; 5-a drain line; a-a first valve; b-a second valve; c-a third valve.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples.

The invention provides a device for realizing continuous compression of steam by utilizing air, which is shown in figure 1 and comprises a steam inlet pipeline 1, a steam outlet pipeline 4 and a pair of piston type compression cylinders 6, wherein the piston type compression cylinders 6 comprise a first compression cylinder 2 and a second compression cylinder 3. The steam inlet line 1 is used for inputting low-pressure low-temperature steam into the two piston type compression cylinders 6, and the exhaust line 4 is used for receiving high-pressure high-temperature steam output from the two piston type compression cylinders 6. Two piston-type compression cylinders 6 are respectively arranged longitudinally, and each piston-type compression cylinder 6 comprises a cylinder body 7, a piston 21 arranged inside the cylinder body 7 and a reciprocating assembly for controlling the piston 21 to perform longitudinal reciprocating operation. The space above the piston 21 in the cylinder 7 is a steam cylinder 23, and the steam cylinder 23 is connected with the steam inlet pipeline 1 through a first valve a and is connected with the steam outlet pipeline 4 through a second valve b.

For each piston type compression cylinder 6, when the reciprocating assembly pulls the piston 21 downwards to run, the steam cylinder 23 is in an expansion state, the first valve a is opened, the steam cylinder 23 enters steam through the steam inlet pipeline 1, low-pressure low-temperature steam is input into the steam cylinder 23 at the moment, and when the piston 21 runs to the lowest point, the first valve a is closed. Then, the reciprocating assembly pushes the piston 21 upwards to move, low-pressure and low-temperature steam is input into the steam cylinder 23 at the moment, when the piston 21 moves to the highest point (when the piston 21 moves to the highest point, the position of the piston 21 at the initial time is returned), the second valve b is opened, steam is input into the steam cylinder 23 through the inlet and outlet pipeline 4, and at the moment, high-pressure and high-temperature steam is output outwards from the steam cylinder 23.

The steam cylinders 23 of the first compression cylinder 2 and the second compression cylinder 3 alternately perform steam admission and steam exhaust, when low-pressure low-temperature steam is input into one steam cylinder 23, the other steam cylinder 23 performs steam compression to obtain high-pressure high-temperature steam and outputs the high-pressure high-temperature steam outwards, so that the steam compression is performed uninterruptedly, and continuous work is realized.

In conclusion, the defect of periodic operation of the conventional air energy steam compression device is overcome, and the alternate operation state of the double-piston type compression cylinders is utilized and the alternate control of valve control is matched, so that the two double-piston type compression cylinders alternately perform an expansion process and a compression process, a continuous working mode of steam compression is realized, and the continuous operation of compressing steam by utilizing air energy is realized.

The air pressure in the environment is used for compressing low-pressure low-temperature steam to do work, extra power input is not needed, and the system structure is simple.

In the preferred embodiment, the bottom of the cylinder 7 is provided with a fixed partition 22, and the space in the cylinder 7 between the piston 21 and the fixed partition 22 is an air cylinder 24. Namely, the upper and lower sides of the piston 21 are provided with a steam cylinder 23 and an air cylinder 24, respectively.

In the preferred embodiment, the reciprocating assembly includes a weighted liquid disposed within a steam cylinder 23, and an energy storage device 26 disposed within an air cylinder 24 and connecting the piston 21 and the fixed diaphragm 22. Wherein the weight fluid is preferably condensed water and the energy storage device 26 is preferably a spring and a shock absorber. The bottom of the steam cylinder 23 is a liquid cylinder 25, and the counterweight liquid is positioned in the liquid cylinder 25.

Further, a radiator 27 is arranged on the top of the steam cylinder 23. A fluid passage 28 is also provided through the piston 21, the fluid passage 28 being connected to the drain line 5 via a third valve c. When the piston 21 moves to the lowest point, the third valve c is opened to discharge at least part of the weight liquid, and after the discharge is finished, the third valve c is closed, and the piston 21 starts to move upwards.

In this embodiment, in the initial state, a certain amount of condensed water is injected into the steam cylinder 23, and the condensed water is selected as the counterweight liquid, and since the piston 21 is located at the highest position at this time, the spring is in the stretched state, for example, the spring is selected as the energy storage device 26. The first valve a, the second valve b and the third valve c of both piston compression cylinders 6 are closed. The weight of the piston 21 is G1, the cross-sectional area of the piston 21 is a1, the weight of the initial condensed water in the liquid cylinder 25 is G2, the atmospheric pressure in the environment is P1, the initial pressure in the vapor cylinder 23 is P2, and the restoring force when the energy storage device 26 is stretched is F compression.

Under the combined action of the pressure difference between the inside and outside of the steam cylinder 23, the weight of the condensed water, the weight of the piston, and the downward pulling force of the spring: (P1-P2). A2< G2+ G1+ F contract, the piston 21 starts to move downwards, the expansion process or the process is defined when the piston 21 descends, the first valve a is opened during the descending of the piston 21, the steam cylinder 23 sucks low-pressure low-temperature steam from the steam inlet pipeline 1, the third valve c on the drainage pipeline 5 connected with the liquid channel 28 on the piston 21 is opened when the piston descends to the lowest point, at least part of condensed water is drained, then the third valve c is closed, after the condensed water is drained, the steam inlet of the steam cylinder 23 is finished, and the first valve a is closed. At this time, the weight of the remaining condensed water in the steam cylinder 23 is reduced to G2min, the remaining pressure in the steam cylinder 23 is P2min, and the restoring force when the energy storage device 26 is compressed is F push.

Under the combined action of the pressure difference between the inside and outside of the steam cylinder 23, the weight of the condensed water, the weight of the piston, and the downward pulling force of the spring: (P1-P2 min). A2+ F push > G2min + G1, the piston 21 turns around and starts to move upwards, the upward movement of the piston 21 is defined as a compression process or a return stroke, low-pressure low-temperature steam is compressed when the piston 21 moves upwards to obtain high-pressure high-temperature steam, and when the piston 21 moves upwards to the highest point: (P1-P2). A2< G2+ G1+ F contracts, the second valve b is opened, at least part of high-pressure high-temperature steam in the steam cavity 23 is discharged through the steam outlet pipeline 4, and the rest part of high-pressure high-temperature steam exchanges heat with the radiator 27 at the top of the steam cylinder 23 to generate condensed water which falls back to the liquid cylinder 25, and the condensed water which falls back can supplement the condensed water discharged in the expansion process, so that the condensed water in the liquid cylinder 25 is recovered to the weight of the expansion process after each compression process is finished, and the next expansion process is ensured to be carried out smoothly.

The two piston type compression cylinders 6 have the expansion process and the compression process, and the compression of the low-pressure low-temperature steam is realized through the expansion process and the compression process to obtain high-pressure high-temperature steam, but the expansion process and the compression process are alternately performed by the two piston type compression cylinders 6, so that uninterrupted steam compression is realized.

In the preferred embodiment, the reciprocating assembly includes a push-pull device coupled to the piston 21 and an energy storage device 26 disposed within the air cylinder 24 and coupled to the piston 21 and the fixed diaphragm 22.

In this embodiment, in the initial state, the initial condensed water is not injected into the steam cylinder 23, but a downward pulling force is applied to the piston 21 by the push-pull device instead of the weight generated by the injection of the initial condensed water, and the piston 21 starts to move downward to enter the expansion process under the combined action of the pressure difference between the inside and the outside of the steam cylinder 23, the downward pulling force of the push-pull device, the weight of the piston, and the downward pulling force of the spring.

As above, under the combined action of the pressure difference between the inside and outside of the steam cylinder 23, the upward thrust of the push-pull device, the weight of the piston, and the upward thrust of the spring, the piston 21 starts to move upward, entering the compression process.

In the preferred embodiment, the radiator 27 is preferably a water-cooled tube condenser and an air-cooled finned condenser.

In a preferred embodiment, the first valve a, the second valve b, and the second valve c are all valves that can be automatically controlled, such as electronically controlled valves or solenoid valves.

In a preferred embodiment, the steam cylinder 23 draws in steam from the steam inlet line 1 at a pressure lower than atmospheric pressure, preferably between 1.2kPa and 50 kPa.

The invention also discloses a method for realizing continuous compression of steam by utilizing air based on the device, which comprises the following steps:

in the expansion process, the first valve a and the second valve b are closed initially, the piston 21 is positioned at the highest point, the reciprocating assembly applies downward pulling force to the piston 21, the piston 21 runs downwards, the first valve a is opened when the piston runs downwards, the steam cylinder 23 is in an expansion state, low-pressure low-temperature steam is input through the steam inlet pipeline 1, and the first valve a is closed when the piston runs to the lowest point;

in the compression process, the reciprocating assembly applies upward thrust to the piston 21, the piston 21 moves upwards, the steam cylinder 23 is in a compression state and compresses low-pressure low-temperature steam to obtain high-pressure high-temperature steam when the piston moves upwards, and when the piston moves to the highest point, the second valve b is opened, and the high-pressure high-temperature steam is output through the steam outlet pipeline 4;

a pair of piston type compression cylinders 6 is configured, each piston type compression cylinder 6 compresses low-pressure low-temperature steam through an expansion process and a compression process to obtain high-pressure high-temperature steam, and the two piston type compression cylinders 6 alternately perform the expansion process and the compression process.

The method breaks through the defect of periodic operation of the conventional air energy vapor compression device, and utilizes the alternate operation state of the double-piston type compression cylinders in cooperation with the alternate control of valve control, so that the two double-piston type compression cylinders alternately perform an expansion process and a compression process, a continuous working mode of vapor compression is realized, and the continuous operation of compressing vapor by utilizing air energy is realized.

The air pressure in the environment is used for compressing low-pressure low-temperature steam to do work, extra power input is not needed, and the system structure is simple.

In the preferred embodiment, when the reciprocating assembly comprises a weighted liquid, during the expansion process, when the piston 21 reaches the lowest point, the third valve c is opened to discharge at least part of the weighted liquid through the liquid discharge line 5, and after the liquid discharge is finished, the third valve c is closed, at which point the expansion process is finished;

in the compression process, the high-pressure high-temperature steam is condensed by the radiator 27 to obtain condensed water, and the condensed water drops into the counterweight liquid.

In the preferred embodiment, where the reciprocating assembly comprises a push-pull device, a downward pulling force is applied to the piston 21 by the push-pull device during the expansion process;

in the compression process, an upward thrust is applied to the piston 21 by the push-pull device.

The present invention is not limited to the above-described embodiments, and it will be apparent to those skilled in the art that various modifications and improvements can be made without departing from the principle of the present invention, and such modifications and improvements are also considered to be within the scope of the present invention. Those not described in detail in this specification are within the skill of the art.