KR20120096747A - Apparatus for supplying steam - Google Patents

Abstract

PURPOSE: A steam supplying device is provided to efficiently maintain the compression efficiency of a compression unit even though a heating capacity of an evaporator is small, thereby efficiently enhancing the entire efficiency of a steam supplying device. CONSTITUTION: A steam supplying device comprises an evaporator(100), a compression unit(200), a first flow path(300), a second flow path(400), a third flow path(500), a first valve(600), and a second valve(700). The evaporator generates steam. The compression unit compresses the steam discharged from the evaporator. The first flow path makes the steam discharged from the compression unit flow into the compression unit. The second flow path makes the steam discharged from the compression unit flow into the evaporator. The third flow path discharges the steam discharged from the compression unit to a facility utilizing steam. The first valve opens/closes the first flow path. The second valve opens/closes the second flow path.

Description

Apparatus for supplying steam

The present invention relates to a steam supply device for supplying steam to a device using steam.

Steam supply devices are known that produce steam at high temperatures and pressures for use in various chemical processes, cooking of food or disinfecting certain objects. Such a steam supply device may evaporate water to produce steam, and then compress it with a compressor and supply it to a steam utilization facility.

However, in the case of the steam supply device which compresses the steam and supplies the steam to the steam utilization facility, the flow rate of steam generated in the evaporator is often smaller than the optimum operating flow rate of the compressor. When the flow rate of the steam generated by heating in the evaporator is not sufficient, the compression efficiency of the compressor is significantly lowered, and the overall efficiency of the steam supply device is significantly reduced.

In order to solve the above problems, the steam supply device according to an aspect of the present invention, even if the flow rate of the steam generated by heating in the evaporator is less than the flow rate for the efficient operation of the compressor, effectively maintain the compression efficiency of the compression unit It is an object of the present invention to provide a steam supply device.

In order to achieve the above object, a steam supply apparatus according to an embodiment of the present invention, an evaporator for generating steam from the liquid, a compression unit for compressing the steam flowing out of the evaporator, and the steam discharged from the compression unit A first flow path through which the inlet of the compression unit can be introduced, a second flow path through which the steam discharged from the compression unit can flow into the evaporator, and a steam flow out of the compression unit to the steam utilization facility; And a third flow path, a first valve for opening and closing the first flow path, and a second valve for opening and closing the second flow path.

According to the steam supply device according to an embodiment of the present invention, even when the heating capacity of the evaporator is small, the compression efficiency of the compression unit can be effectively maintained. Thus, the overall efficiency of the steam supply device can be effectively increased.

In addition, the steam supply device of the present embodiment can effectively prevent stall of the compression unit.

1 is a view schematically showing the configuration of a steam supply apparatus according to an embodiment of the present invention.
FIG. 2 is a view schematically showing some operation forms of the steam supply device of FIG. 1.
3 is a view schematically showing some other operation of the steam supply device of FIG. 1.
FIG. 4 is a view schematically showing another operation mode of the steam supply device of FIG. 1.

Hereinafter, a steam supply apparatus according to an embodiment of the present invention will be described with reference to the drawings.

1 is a view schematically showing the configuration of a steam supply apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the steam supply device 1 according to the present embodiment includes an evaporator 100, a compression unit 200, a first flow path 300, a second flow path 400, a third flow path 500, And a first valve 600, a second valve 700, a third valve 800, a first cooler 810, 820, a second cooler 830, a gas-liquid separator 910, 920, 930, and a fourth flow path 950. .

The evaporator 100 generates steam by heating the introduced liquid (W). The inside of the evaporator 100 may be maintained at a pressure lower than atmospheric pressure, in which case the boiling point of the liquid W may be lower than the boiling point under atmospheric pressure. By lowering the boiling point of the liquid (W) in this way, it is possible to reduce the amount of heat required for evaporation of the liquid (W). Hereinafter, the liquid W flowing into the evaporator 100 will be described as an example.

The compression unit 200 is for compressing steam, ie, water vapor flowing out of the evaporator 100, and may include various types of compressors, such as a centrifugal or axial compressor. In addition, the compression unit 200 may be configured in a form in which a plurality of compressors are connected in multiple stages. Referring to FIG. 1, it can be seen that the compression unit 200 of the steam supply device 1 according to the present embodiment includes three compressors 210, 220, and 230 connected in multiple stages. Hereinafter, for convenience of description, each compressor 210, 220, 230 will be referred to as a first compressor 210, a second compressor 220, and a third compressor 230 in order from the uppermost stage.

In the flow path 150 connecting the outlet of the evaporator 100 and the inlet of the compression unit 200, that is, the inlet of the first compressor 210, a decompression passage 160 capable of depressurizing the inside of the evaporator 100 is provided. Can be connected. The decompression passage 160 may be provided with a decompression pump 170 for forcibly extracting air or water vapor in the evaporator 100 so as to reduce the pressure in the evaporator 100.

The first flow path 300 connects the outlet of the third compressor 230 and the inlet of the first compressor 210 so that the compressed steam flowing out of the compression unit 200 can be reintroduced into the inlet of the compression unit 200. Connect. In the present embodiment, the first passage 300 is connected to the first compressor 210 via a gas-liquid separator 910 connected to the inlet of the first compressor 210. A check valve 320 may be disposed in the first passage 300 to prevent steam from flowing back from the inlet of the compression unit 200 toward the outlet of the compression unit 200. In addition, a bypass valve may be disposed in the first passage 300 to block the first passage 300 in advance when it is determined that the first passage 300 is not necessary.

The second flow path 400 connects the outlet of the final compressor, that is, the third compressor 230 and the evaporator 100 so that the compressed steam flowing out from the compression unit 200 may be introduced into the evaporator 100. do. A check valve 410 may be disposed in the second passage 400 to prevent steam from flowing back from the evaporator 100 in the direction of the outlet of the compression unit 200.

In the present embodiment, each of the first flow path 300 and the second flow path 400 is connected to an outlet of the compression unit 200 by being connected to the flow path 550 directly connected to the outlet of the compression unit 200, and directly to the outlet. A first exhaust flow path 350 for discharging steam to the external atmosphere is connected to the connected flow path 550. The first exhaust flow path 350 is for adjusting the amount of steam circulating through the compression unit 200, and the valve 352 of the first exhaust flow path 350 is adapted to the amount of steam circulating through the compression unit 200. Thus the opening and closing can be controlled. A silencer 360 may be disposed in the first exhaust passage 350 to reduce noise caused by the discharge of the high temperature and high pressure steam.

The third flow path 500 of the compression unit 200 to allow the compressed steam flowing out from the compression unit 200 to flow out to the steam using equipment (U), that is, the equipment for performing physical and chemical processes using steam. Connect the outlet to the steam utility (U). The third flow path 500 may be a flow meter 520 for measuring the flow rate of the steam flowing into the steam utilization facility (U).

In the present embodiment, the second exhaust passage 510 is connected to the third passage 500. The second exhaust passage 510 discharges water vapor of the third passage 500 to the outside according to the opening and closing of the valve 512, and may be used to adjust operating conditions of the steam supply device 1. For example, the second exhaust flow path 510 may be used to adjust the initial operating conditions of the compression unit 200, and the operating conditions of the steam supply device 1 in the case of not supplying steam to the utilization facility U. It may also serve to vent vapors to the outside for continued maintenance.

The first valve 600 opens and closes the first flow path 300 to allow or block the flow of compressed steam in the first flow path 300. That is, the first valve 600 allows or blocks the flow of compressed steam from the outlet of the compression unit 200 to the inlet of the compression unit 200. The first valve 600 may be a pressure reducing valve that opens when the pressure of the outflow steam of the compression unit 200 reaches a predetermined pressure.

The second valve 700 serves to open and close the second channel 400 so as to allow or block the flow of compressed steam in the second channel 400. That is, the second valve 700 allows or blocks the flow of compressed steam from the outlet of the compression unit 200 to the inlet to the evaporator 100. In addition, the second valve 700 may adjust the opening degree of the second passage 400 to control the flow rate of the compressed steam flowing through the first passage 300. The second valve 700 may be formed of an electronic valve that can be controlled electronically.

The first coolers 810 and 820 are disposed between the first to third compressors 210, 220 and 230, and serve to cool the steam by adding moisture to the compressed steam flowing out of the front compressor and entering the rear compressor. That is, the first coolers 810 and 820 are disposed between the first compressor 210 and the second compressor 220, and between the second compressor and the third compressor 230, respectively, and are compressed by the first compressor 210 to be second. Water is injected into the compressor 220 and the steam compressed by the second compressor 220 is injected into the third compressor 230 to cool the sprayed water. The first coolers 810 and 820 receive water from the outside to inject moisture into the compressed steam, and the valves 814 and 824 for controlling the flow rate of water flowing into the flow paths 812 and 822 of the water flowing into the first coolers 810 and 820. ) Is placed.

The second cooler 930 is disposed in the first passage 300, and adds moisture to the compressed steam passing through the first passage 300 to inject moisture into the first passage 300 so as to cool the steam. Play a role. The second cooler 830 receives water from the outside so as to inject water into the compressed steam of the first flow path 300, and flows the flow of water into the flow path 832 of the water flowing into the second cooler 830. A controllable valve 834 is disposed.

Knock out drums (910, 920, 930) are disposed on the inlet side of each of the compressors (210, 220, 230), and serves to separate the liquid water from the steam flowing into the compressors (210, 220, 230). That is, the gas-liquid separators 910, 920, and 930 suppress water from flowing into the compressors 210, 220, and 230 by removing water in the mists contained in the steam flowing into the compressors 210, 220, and 230.

The fourth flow path 950 connects the gas-liquid separators 910, 920, and 930 to the evaporator 100 so that water discharged from the gas-liquid separators 910, 920, and 930 is introduced into the evaporator 100. Forcibly feeding the discharge liquid reservoir 952 and the water from the discharge liquid reservoir 952 to the evaporator 100 in the fourth flow path 950 to accommodate the liquid W separated from the gas-liquid separators 910, 920, and 930. Pump 954 may be disposed.

Next, some operation forms and effects of the steam supply device 1 described above will be described.

Water is introduced into the evaporator 100 and heated to produce steam. At this time, the internal pressure of the evaporator 100 is set lower than 1 atm so that the water of the evaporator 100 can boil at 100 ° C or less. In order to set the internal pressure of the evaporator 100 to be lower than 1 atm, the internal pressure of the evaporator 100 may be dropped in advance by the pressure reducing pump 170.

Vapor generated in the evaporator 100 is introduced into the gas-liquid separator 910 located at the top. In the gas-liquid separator 910, the fumed water contained in the steam is condensed and separated from the steam.

The vapor from which the liquid water is separated after passing through the gas-liquid separator 910 flows into the first compressor 210 of the compression unit 200. As the steam passes through the first compressor 210, the pressure and the temperature rise.

The high temperature and high pressure steam flowing out of the first compressor 210 is lowered while passing through the first cooler 810. Since the first cooler 810 adds water having a temperature lower than that of the steam flowing out of the first compressor 210, the first cooler 810 cools the steam flowing out of the first compressor 210 and simultaneously increases the total amount of steam. . In addition, the first cooler 810 can effectively suppress a decrease in compression efficiency due to thermal expansion by lowering the temperature of the high temperature steam flowing out of the first compressor 210.

The steam passing through the first cooler 810 is introduced into the second compressor 220 via the gas-liquid separator 920 again. The steam passing through the second compressor 220 is compressed to a higher pressure, and the temperature increases in the compression process. The steam flowing out of the second compressor 220 is cooled by the first cooler 820 connected to the rear end of the second compressor 220. The total amount of steam further increases while the steam flowing out of the second compressor 220 is cooled by the first cooler 820.

The steam passing through the second compressor 220 and the first cooler 820 connected to the rear end flows into the third compressor 230 through the gas-liquid separator 930. The steam introduced into the third compressor 230 is further compressed.

On the other hand, in order to increase the compression efficiency of the compression unit 200, the flow rate of the steam flowing into the compression unit 200 should be secured. However, the flow rate of the steam generated in the evaporator 100 may not reach the flow rate of the steam required in the compression unit 200.

As such, when the flow rate of the steam generated in the evaporator 100 does not reach the flow rate required for the efficient operation of the compression unit 200, the second flow path 400 is opened to release the compressed steam flowing out of the compression unit 200. May be introduced into the evaporator 100.

2 is a diagram schematically illustrating a state in which the first passage 300 and the third passage 500 are blocked and the second passage 400 is opened.

Referring to FIG. 2, the high pressure compressed steam flowing out of the compression unit 200 is introduced into the evaporator 100 by opening the second flow passage 400. Since the compressed steam flowing out of the compression unit 200 is elevated in temperature through a multi-stage compressor, when the compressed steam flowing out of the compression unit 200 flows into the evaporator 100, the evaporator 100 is further increased. It will release steam. That is, since the steam flowing out from the compression unit 200 flows into the evaporator 100 while holding the energy received from the compression unit 200, the evaporator 100 effectively increases the flow rate of the effluent steam without inputting a large amount of heat. You can.

As described above, the steam supply device 1 according to the present embodiment controls the opening and closing of the second flow path 400, so that even when the heating capacity of the evaporator 100 is relatively small, the vapor output of the evaporator 100 may be compressed. Can be increased to suit the optimum operating flow rate.

Meanwhile, the steam passing through the compression unit 200 passes through the first coolers 810 and 820. The first coolers 810 and 820 add moisture to the steam, thereby further increasing the flow rate of the steam passing through the compression unit 200. can do.

In addition, water discharged from the gas-liquid separators 910, 920, and 930 may be introduced into the evaporator 100 by the pump 954, and since the water has a high temperature as condensation of high temperature steam, It can be easily converted to steam without absorbing heat.

When the flow rate of the steam passing through the compression unit 200 is secured, the third valve 800 may be opened to open the third flow path 500, and the steam may be supplied to the steam using facility U.

3 is a view schematically showing a state in which the second channel 400 and the third channel 500 are opened. As shown in FIG. 3, when the third channel 500 is opened, compressed steam is used as the steam. It can be supplied to the equipment (U). The amount of steam introduced into the steam utilization facility U may be measured by the flow meter 520.

On the other hand, when the pressure difference between the inlet and the outlet of the compression unit 200 becomes greater than a predetermined range or the flow rate of steam passing through the compression unit 200 becomes lower than the predetermined range during the operation of the compression unit 200. A surge may occur.

In order to prevent stall of the compression unit 200, it is necessary to keep the pressure difference between the inlet and the outlet of the compression unit 200 at a predetermined range or less, and maintain the flow rate of the compression unit 200 at a predetermined size or more. There is.

4 is a diagram schematically illustrating a state in which the first passage 300 is opened. As illustrated in FIG. 4, the steam supply device 1 according to the present embodiment may prevent stalling in the compression unit 200 by controlling the opening and closing of the first flow path 300. That is, when the pressure difference between the inlet and the outlet of the compression unit 200 reaches a predetermined range, the first valve opens the first flow path 300 to determine the pressure difference between the inlet and the outlet of the compression unit 200. It can be kept below the range. Therefore, stall of the compression unit 200 can be effectively prevented.

When the first passage 300 is opened, the compressed steam passing through the first passage 300 is cooled while passing through the second cooler 830 and at the same time, the flow rate also increases.

Although the steam supply device 1 according to an embodiment of the present invention has been described above, the present invention is not limited thereto and may be embodied in various forms within the scope of the technical idea of the present invention.

For example, in the above embodiment, the compression unit 200 has been described as having three compressors 210, 220, and 230 connected in multiple stages, but the compression unit 200 may include two or four or more compressors connected in multiple stages. have. In addition, the compression unit 200 may be configured to have a single compressor.

In addition, the steam supply device 1 according to the above embodiment has been described as having a gas-liquid separator (910, 920, 930), the first cooler (810, 820), the second cooler (830) and the fourth flow path (950), in the present invention The steam supply device according to the present invention may be configured without a gas-liquid separator, a first cooler, a second cooler, and a fourth flow path.

In addition, although the first valve 600 of the steam supply device 1 according to the above embodiment has been described as a pressure reducing valve, the first valve 600 may be an electronic valve that can be controlled electronically. In this case, the first valve 600 may be controlled to adjust the opening and closing of the first flow path 300 according to the pressure and the flow rate of the outlet of the compression unit 200 so as to prevent stall of the compression unit 200. It may be.

In addition, the steam supply device 1 of the above-described embodiment has been described as supplying steam evaporated water to the steam using equipment (U), the steam supply device according to the present invention vaporizes the vapor by vaporizing a liquid other than water It may be supply to the utilization equipment U.

In addition, the steam supply apparatus according to the present invention can be embodied in various forms, of course.

1 ... steam supply
100 ... evaporator
200 ... compression unit
300 ... first euro
400 ... second euro
500 ... third euro
600 ... first valve
700 ... second valve
800 ... third valve
910,920,930 ... gas-liquid separator
950 ... Euro 4
U ... Steam Equipment

Claims (7)

An evaporator that generates steam from the liquid,
A compression unit for compressing the vapor discharged from the evaporator,
A first flow path through which the steam discharged from the compression unit flows into the inlet of the compression unit;
A second flow path through which the steam discharged from the compression unit flows into the evaporator;
A third flow path which allows the steam discharged from the compression unit to flow out to a steam utilization facility;
A first valve capable of opening and closing the first flow path,
And a second valve capable of opening and closing the second flow path. The method of claim 1,
And a third valve capable of opening and closing the third flow path. The method of claim 1,
The compression unit,
A steam supply device having a plurality of compressors connected in multiple stages. The method of claim 3,
And a first cooler disposed between the compressors and configured to cool the steam by adding the liquid to the steam flowing out of the compressor at the front end and flowing into the compressor at the next stage. The method of claim 1,
And a second cooler configured to cool the steam by adding the liquid to the steam passing through the first flow path. The method of claim 1,
And a gas-liquid separator for separating and discharging the liquid contained in the steam flowing into the compression unit. The method of claim 6,
And a fourth flow path for introducing the liquid discharged from the gas-liquid separator into the evaporator.

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