KR20160109652A - Multi stage compressor for vapor recirculation - Google Patents

Abstract

A multi-stage compressing device for re-circulating steam according to the present invention includes: a compressing unit formed to include at least three compressor, compressing waste stem discharged from a plant at a high temperature and a high pressure in multiple stages, and returning the compressed steam back to the plant; a low-temperature condensate tank receiving low-pressure condensate discharged between a first compressor and a second compressor; and a high-pressure condensate tank receiving high-pressure condensate discharged between the second compressor and a third compressor. The multi-stage compressing device for re-circulating the steam according to the present invention enables the waste steam discharged from the plant to be reused by compressing the waste steam at a high temperature and a high pressure in the multiple stages and enables the condensate generated during the process of compressing the waste steam to be reused by separating the condensate into the high-temperature steam and the low-temperature water and returning the high-temperature steam back to the plant, thereby improving the energy efficiency of the plant and reducing environmental pollution.

Description

[0001] Multi-stage compressor for vapor recirculation [

The present invention relates to a multi-stage compression apparatus for steam recirculation in which steam discharged after being used in a petrochemical plant is compressed into multi-stages and returned to a plant. More particularly, the present invention relates to a multi- To a steam recirculation multi-stage compression apparatus capable of returning high-temperature steam to a plant after separation.

In general, plants used in the petrochemical industry utilize high-temperature, high-pressure steam, which is supplied through a process of heating pure water.

At this time, the steam used in the plant is discharged to the outside because it is not suitable for reuse in the plant because the temperature and pressure are lowered. In this way, the steam discharged from the plant (hereinafter, So that the wastewater vapor is released as it is, resulting in a great waste of energy.

That is, in order to change the phase of pure water of low temperature to the steam of high temperature and high pressure, a lot of energy is required. If the heat source in the waste water vapor can be reused, energy required to generate high- can do. However, until now, a device for reusing the heat source in the wastewater vapor has not been commercialized, and thus, the plant is being used at a high cost.

KR 10-1176368 B1

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above-mentioned problems, and it is an object of the present invention to provide a high-temperature and high-pressure steam generator capable of converting wastewater vapor of low temperature and pressure into multi- And a high-temperature steam is recycled to the plant, thereby maximizing the energy consumption efficiency.

In order to achieve the above object, a multi-stage compression apparatus for recycling steam according to the present invention comprises at least three compressors. The multi-stage compression apparatus for multi-stage compression of waste water vapor discharged from a plant at high temperature and high pressure, ; A low pressure condensate water tank for containing low pressure condensed water discharged between the first compressor and the second compressor; And a high-pressure condensate water tank for containing high-pressure condensed water discharged between the second compressor and the third compressor.

An ejector for receiving low-pressure condensed water discharged from the low-pressure condensed water tank and high-pressure condensed water discharged from the high-pressure condensed water tank, and discharging the condensed water to a high pressure; And a phase separator for separating the condensed water discharged from the ejector into high temperature steam and low temperature water, then returning the high temperature steam to the plant, and discharging the low temperature water to the outside.

The low-pressure condensed water tank and the high-pressure condensed water tank are constructed such that the internal space is surrounded by a heat insulating layer.

The low-pressure condensate water tank and the high-pressure condensate water tank are respectively provided with pressure adjusting means for adjusting the pressure of the internal space.

Pressure condensed water valve is mounted on the outlet side of the low-pressure condensed water tank, and a high-pressure condensed water valve is mounted on the outlet side of the high-pressure condensed water tank.

Pressure condensed water into the suction chamber, a suction nozzle for sucking the low-pressure condensed water into the suction chamber in a direction perpendicular to the injection direction of the high-pressure condensed water, and a suction unit for sucking the low- And a diffuser installed in the suction chamber to discharge the condensed water in the suction chamber at a high pressure so as to be positioned on an extension line of the injection direction of the high-pressure condensed water.

The phase separator includes an inlet port through which the condensed water discharged from the diffuser flows, a low-temperature water discharge port through which the low-temperature water is discharged, and a high-temperature steam discharge end through which the high-temperature steam is discharged. .

By using the multi-stage compression apparatus for steam recirculation according to the present invention, the waste steam discharged from the plant can be reused by multi-stage compression at high temperature and high pressure, and the condensed water generated in the process of compressing the waste steam can be separated into high temperature steam and low temperature water The high-temperature steam can be returned to the plant for reuse, thereby improving the energy consumption efficiency of the plant and reducing environmental pollution.

1 is a schematic view of a multi-stage compression apparatus for steam recirculation according to the present invention.
2 is a sectional view of an ejector included in a multi-stage compression apparatus for steam recirculation according to the present invention.
3 is a sectional view of the phase separator included in the multi-stage compression apparatus for steam recirculation according to the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of a multi-stage compression apparatus for steam recirculation according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic view of a multi-stage compression apparatus for steam recirculation according to the present invention.

The multi-stage compression apparatus for steam recirculation according to the present invention is a system in which steam is discharged from the plant 100 to the outside after being used in the plant 100 but is compressed into multi-stages, converted into steam of high temperature and high pressure, So that the heat source and pressure contained in the wastewater vapor can be reused.

That is, the multi-stage compression apparatus for steam recirculation according to the present invention comprises a first compressor 210, a second compressor 220, and a third compressor 230 to compress the waste water steam discharged from the plant 100 into multi- Pressure state to a high-temperature and high-pressure state, and then returns it to the plant 100 as the largest component. Although only three compressors are provided in this embodiment, four or more compressors may be provided to compress the waste water vapor to a higher temperature and pressure.

In order to change the low-temperature water to the high-temperature high-pressure steam, the energy for heating the water to 100 ° C, the energy for phase-changing the water at 100 ° C with the steam at 100 ° C, The energy required to convert the waste water vapor having a temperature of 100 DEG C to a high temperature and pressure is required, It is possible to provide water vapor of high temperature and high pressure to the plant 100 with energy.

In the multi-stage compression apparatus for steam recirculation according to the present invention, since the steam of the waste water is compressed stepwise by a plurality of compressors, steam of high temperature and high pressure is obtained, and only the electric energy for starting the compressor is required. Heat energy is not required. Therefore, in an environment where the industrial electric power is low, the effect of converting the waste water vapor into the high-temperature high-pressure steam using the compressor can be obtained that the cost is greatly reduced. In addition, the multi-stage compression apparatus for recycling steam according to the present invention can reduce the environmental pollution problem because the waste water vapor used in the plant 100 is reused without being discharged to the atmosphere.

In addition, when steam is compressed using a compressor, high-temperature and high-pressure steam can be obtained, but a certain amount of condensed water is generated. In order to maintain the steam compression performance, the condensed water must be removed. In this case, when the condensed water discharge line is directly opened, the steam is discharged through the condensed water discharge line. Therefore, the multi-stage compressor for vapor recycling according to the present invention is capable of compressing the low- Pressure condensate water tank 300 for containing condensed water and a high-pressure condensate water tank 400 for containing high-pressure condensed water discharged between the second compressor 220 and the third compressor 230. [ When the low-pressure condensate water tank 300 and the high-pressure condensate water tank 400 are provided as described above, the low-pressure condensed water discharged between the first compressor 210 and the second compressor 220 is stored in the low-pressure condensate tank 300, Pressure condensed water tank 400 and the high-pressure condensed water tank 400. The high-pressure condensed water discharged from the compressor 220 and the third compressor 230 is stored in the high-pressure condensate tank 400, It is possible to prevent the phenomenon that water vapor is discharged to the condensate discharge line.

Pressure condensed water tank 300 and the high-pressure condensed water tank 400 to prevent the internal pressure of the low-pressure condensed water tank 300 and the high-pressure condensed water tank 400 from excessively increasing, Pressure adjusting means (not shown) are preferably provided. The pressure regulating means for regulating the pressure in the tank as described above is commercialized in various structures in the technical field of the present invention, and a detailed description of the structure and operation principle of the pressure regulating means is omitted.

On the other hand, the low-pressure condensed water filled in the low-pressure condensed water tank 300 and the high-pressure condensed water filled in the high-pressure condensed water tank 400 are higher in temperature and pressure than ordinary pure water. Therefore, The energy contained in the condensed water and the high-pressure condensed water is also discarded as it is. Therefore, the multi-stage compression apparatus for steam recirculation according to the present invention can be configured to reuse the energy contained in the low-pressure condensed water and the high-pressure condensed water.

That is, the multi-stage compression apparatus for steam recirculation according to the present invention includes an ejector 500 for receiving low pressure condensed water discharged from the low pressure condensed water tank 300 and high pressure condensed water discharged from the high pressure condensed water tank 400, And a phase separator 600 for separating the condensed water discharged from the ejector 500 into high temperature steam and low temperature water and then returning the high temperature steam to the plant 100 and discharging the low temperature water to the outside . The structure and operation principle of the ejector 500 and the phase separator 600 will now be described in detail with reference to FIGS. 2 and 3. FIG.

As described above, when the ejector 500 and the phase separator 600 are additionally provided, it is possible to separate the condensed water in the liquid state into the high-temperature steam and the low-temperature water, and the high-temperature steam is returned to the plant 100 for reuse It is possible to minimize the energy to be discarded. Of course, the low-temperature water discharged to the outside contains a small amount of heat source, but the heat source included in the low-temperature water is insignificant, and therefore does not greatly affect the effluent efficiency of the wastewater.

In this case, when the low-pressure condensed water is cooled in the low-pressure condensed water tank 300 and the high-pressure condensed water is cooled in the high-pressure condensate water tank 400, the high-temperature steam obtained when the ejector 500 and the phase separator 600 are used Pressure condensed water tank 300 and the high-pressure condensed water tank 400 are preferably constructed in such a structure that the low-pressure condensed water and the high-temperature condensed water can be kept warm, that is, the internal space is surrounded by the heat insulating layer.

In order to obtain high-pressure condensed water through the ejector 500, the flow rates of the low-temperature condensed water and the high-temperature condensed water supplied to the ejector 500 must be equal to or more than a certain level. Pressure condensate valve 410 and the high-pressure condensate valve 410 should be mounted on the outlet side so as to allow the low-pressure condensed water and the high-pressure condensed water to flow into the ejector 500, respectively.

FIG. 2 is a sectional view of the ejector 500 included in the multi-stage compression apparatus for steam recirculation according to the present invention, and FIG. 3 is a sectional view of the phase separator 600 included in the multi-stage compression apparatus for steam recirculation according to the present invention.

The ejector 500 includes a suction chamber 530 having an internal space therein, an injection nozzle 510 for injecting the high-pressure condensed water into the suction chamber 530, Pressure condensed water into the suction chamber 530; and a suction unit 530 installed in the suction chamber 530 so as to be positioned on an extension line of the high-pressure condensed water in the suction direction, And a diffuser 540 for discharging the gas to the atmosphere.

When the high-pressure condensed water supplied to the injection nozzle 510 passes through the outlet of the injection nozzle 510, the pressure energy of the high-pressure condensed water is mostly converted into velocity energy, so that the high- So that the pressure inside the suction chamber 530 is lowered. When the pressure inside the suction chamber 530 is lowered, the low-pressure condensed water is sucked into the suction chamber 530 through the suction unit 520 and mixed with the high-pressure condensed water. In the suction chamber 530, The pressure rises through the diffuser 540. The diffuser 540, which increases the pressure of the fluid after mixing the two fluids having different pressures, is commercialized in various fields, so that detailed description of the operating principle of the diffuser 540 is omitted.

As described above, the condensed water discharged through the diffuser 540 flows into the phase separator 600. At this time, the phase separator 600 has a flow path of a zigzag pattern therein, and the inlet end 610 through which the condensed water discharged from the diffuser 540 flows is located at one side lower side, and the high temperature steam The discharge end 630 is positioned on the upper side of the other side, and the low temperature water discharge end 620 through which the low temperature water is discharged is located on the bottom surface. Therefore, the condensed water flowing through the inlet end 610 is converted into the low temperature water through the process of colliding with the inner wall of the phase separator 600 and is discharged to the low temperature water discharge end 620, The enthalpy of the remaining condensed water is increased, and the enthalpy of the remaining condensed water is changed into the high temperature steam and discharged to the high temperature steam discharge end 630. At this time, the low-temperature water discharge end 620 may be provided with a low-temperature water valve 640 so that the user can select whether to discharge the low-temperature water.

When the ejector 500 and the phase separator 600 are used, some of the low-pressure condensed water and the high-pressure condensed water can be converted into the high-temperature steam usable in the plant 100. Therefore, The energy that is discarded can be significantly reduced.

In this embodiment, only the inner flow path of the phase separator 600 forms a zigzag pattern. However, the inner flow path of the phase separator 600 may be circular or spiral. In addition, the phase separator 600 can be replaced with any kind of separator that is currently commercialized, as long as it can separate the provided high-temperature high-pressure water into high-temperature steam and low-temperature water.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the present invention is not limited to the disclosed exemplary embodiments. It will also be appreciated that many modifications and variations will be apparent to those skilled in the art without departing from the scope of the invention.

100: Plant 210: First compressor
220: second compressor 230: third compressor
300: Low pressure condensate tank 310: Low pressure condensate valve
400: high pressure condensate tank 410: high pressure condensate valve
500: ejector 510: injection nozzle
520: suction portion 530: suction chamber
540: Diffuser 600: Phase Separator
610: Inflow end 620: Low temperature water outflow end
630: high-temperature steam discharge stage 640: low-temperature water valve

Claims (7)

A compression unit configured to include at least three compressors, multi-stage compressing the waste water steam discharged from the plant to high temperature and high pressure, and returning the waste water steam to the plant;
A low pressure condensate water tank for containing low pressure condensed water discharged between the first compressor and the second compressor; And
A high pressure condensate water tank for containing high pressure condensed water discharged between the second compressor and the third compressor;
Wherein the steam is recirculated to the compressor. The method according to claim 1,
An ejector for receiving low-pressure condensed water discharged from the low-pressure condensed water tank and high-pressure condensed water discharged from the high-pressure condensed water tank, and discharging the condensed water to a high pressure; And
A phase separator for separating the condensed water discharged from the ejector into high temperature steam and low temperature water, then returning the high temperature steam to the plant, and discharging the low temperature water to the outside;
Further comprising: a pressure regulator for regenerating the steam; The method of claim 2,
Wherein the low-pressure condensed water tank and the high-pressure condensed water tank are surrounded by a heat insulating layer. The method of claim 2,
Wherein the low-pressure condensate water tank and the high-pressure condensate water tank are provided with pressure adjusting means for adjusting the pressure of the internal space, respectively. The method of claim 2,
Pressure condensed water valve is mounted on the outlet side of the low-pressure condensed water tank, and a high-pressure condensate water valve is mounted on the outlet side of the high-pressure condensed water tank. The method of claim 2,
Pressure condensed water to the suction chamber; a suction unit for sucking the low-pressure condensed water into the suction chamber in a direction perpendicular to the injection direction of the high-pressure condensed water; And a diffuser installed in the suction chamber so as to be positioned on an extension line of the high-pressure condensed water to discharge the condensed water in the suction chamber at a high pressure. The method of claim 2,
The phase separator includes an inlet port through which the condensed water discharged from the diffuser flows, a low-temperature water discharge port through which the low-temperature water is discharged, and a high-temperature steam discharge end through which the high-temperature steam is discharged. And the steam is recycled to the compressor.

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