KR20070059123A - Arrangement and method for treatment of compressed gas - Google Patents

Abstract

An arrangement for use with a liquid cooled and/or lubricated compressor (10) for compressing gas, and incorporating provision to add liquid for cooling purposes to the gas prior to entry of the gas into the compressor, in which down stream of the compressor there is a liquid/gas separator (11) to separate the liquid from the gas and in which there is means (29) to recover heat from the liquid, and in which there is at least one filter (17 or 18) in the gas stream downstream of the liquid/gas separator, and there is a heater (19) in the gas stream downstream of the filter in which the gas is heated using heat recovered from the liquid (at 29), whereby to regulate the temperature of the pressurised gas. There may be a heat exchanger (14) between the separator and the filter. There may be a refrigerant dryer group (15) arranged to cool the gas after the liquid has been separated from the gas and before the gas is passed through the filter.

Description

Apparatus and method for processing compressed gas {ARRANGEMENT AND METHOD FOR TREATMENT OF COMPRESSED GAS}

The present invention relates to an apparatus for pretreating compressed gas for separation in an air-gas or other gas-gas separation unit, preferably by membrane filtration, such as membrane filtration. The apparatus includes a heat recovery device for a gas compressor and relates to a method for recovering heat from a compressor cooling fluid for adjusting the temperature of the compressed gas before entering the gas separation unit.

In the pretreatment of air or other gases for membrane-based air-gas or other gas-gas separation units, it is important that the air injected into the separation unit meet the specified criteria. The dew point of the air should be such as to avoid condensation. The air must be filtered at an acceptable temperature thereby avoiding carry over to the aerosol and particles. The air must be at the proper operating temperature for effective membrane separation. This is particularly important and the temperature must be adjusted before entering the separation unit, thereby achieving the highest possible operation of the separation unit. The present invention relates to heat recovery from compressor cooling fluids for continuous temperature control of the air supply to meet these criteria.

The present invention provides an apparatus for use in a compressor for gas compression that is liquid cooled and / or lubricated, and together with the addition of liquid to the gas for cooling purposes prior to the introduction of the gas into the compressor, the downstream of the compressor ( downstream, there is a liquid / gas separator for separating the liquid from the gas, there are means for recovering heat from the liquid, one or more filters in the gas flow downstream of the liquid / gas separator, There is a heater in the gas stream, where the gas is heated using heat recovered from the liquid, thereby regulating the temperature of the compressed gas prior to gas inlet into the separation unit.

It is preferred that there is a heat exchanger in the gas flow between the liquid / gas separator and the at least one filter, and that heat exchanger refrigerant from an external source is used to cool the gas flow.

It is also preferred that a refrigerant dryer group is arranged to cool the gas after the liquid is separated from the gas and before the gas passes through the one or more filters.

The at least one filter may be an integrated particle filter or a carbon filter for removing steam from the cooling liquid.

The at least one filter may comprise two stage filtration, the first filtration stage comprising an integrated particle filter and the second filtration stage comprising a carbon filter for removing vapor from the cooling liquid.

The present invention includes a membrane gas separator unit, used in conjunction with the apparatus described above, arranged to receive gas from a heater using the heat recovered from the liquid before the liquid passes through the filter.

The present invention includes a compressor for use in combination with the apparatus described above to compress the gas. The compressor may be a screw compressor, which may be cooled or cooled and lubricated by oil or other suitable cooling fluid.

The present invention also includes a method of recovering heat from a compressed gas compressed gas that is liquid cooled and / or lubricated, which method prior to the introduction of gas into the compressor, prior to the introduction of the gas into the compressor, the liquid into the gas for direct or cooling purposes Adding, separating the liquid from the gas after the gas leaves the compressor, recovering heat from the liquid, passing the gas through one or more filters, and downstream of the filter, Heating the gas using heat recovered from the liquid before gas passes through the filter, thereby adjusting the temperature of the compressed gas.

Advantage of the present invention

The performance of the separation process depends on the relatively narrow range of operating parameters, in particular the feed air temperature and pressure. For this reason, effective control of the feed air provided to the separator is important. Certain embodiments of the present invention described above include the effective use of heat supplied to the air, arranging filters for compressed air such that the separation membranes are operated near optimum conditions, and the separation membranes are optimized for air pressure, temperature And dryness. In order to reduce the gas temperature before the filters, to preheat the gas stream after the filters, using the heat recovered from the gas stream makes efficient use of the energy applied to the system. Temperature control of the gas prior to entering the separation unit may occur from an external heating source in many prior art cases. In certain possible cases, additional heating from an external source may be required. This need is reduced and eliminated by the present invention in many cases.

The invention is particularly suitable for establishing modular systems (compressors, devices for the control of compressed gas, separation units), in which case the regulation module does not require an external heating source.

Specific embodiments of an apparatus for pretreating air for a membrane nitrogen separator will be described by way of example with reference to the accompanying process flow diagram, which shows the compressor zone and the nitrogen separator zone.

To facilitate the effective performance of the membrane nitrogen separator, the compressed air must be cooled to remove the liquid, the dew point temperature must be reduced to avoid liquid condensation, and the air has an acceptable temperature to avoid spilling into the aerosol and particles. It must be filtered at, and finally the air temperature must be increased to the operating temperature for membrane separation.

According to this example, the air in the compressor zone is sucked into the screw compressor 10 which is single stage oil cooled / lubricated through the inlet filter 9. Compressed air with droplet entrained oil passes through an oil / air separator (11) with a safety valve (12). The air passes through a compressed air aftercooler 14 (also known as a combi cooler). The post cooler 14 comprises an integrated water cooled heat exchanger, which functions as a temperature control unit for compressed air.

The air then passes through the combined water separator / cooler / dryer 15. This reduces the dew point to about 15 ° C. below the inlet temperature so that condensation will not occur further downstream. The dryer 15 has a dedicated refrigerant recycling unit with an evaporator, a compressor and a condenser.

The dryer 15 is not essential. Without the dryer, the air from compressor 10 will be at the saturation point after leaving cooler 14. In this situation the temperature of the air must be increased thereby avoiding condensation further downstream. The problem is that the increased temperature may exceed the limitations of the polymer membranes preferably used in the nitrogen separator zone.

Air from the dryer 15 passes through the check valve 16 and the ball valve 16a. The cooled air now passes through a coalescing particle filter 17 (to reserve oil aerosol overflow) and a carbon filter 18 (to remove oil vapor) with the appropriate temperature, pressure and dryness. do. Removal of the dryer 15 can lead to inefficiencies in the filters 17, 18 due to the high operating temperature.

After exiting the carbon filter 18, the air passes through the feed air heater 19 and thereby preheats the air for processing in the nitrogen separator zone. The feed air heater 19 increases the compressed air temperature to 45-50 ° C. The control valve 21 regulates the air leaving the compressor zone, which may be directed through the valve 22 to a redundant system (not shown) or through the valve 23 to the nitrogen separator zone.

Oil is introduced from the oil / air separator 11 into the cooling heat exchange circuit. The cooling liquid enters the compressed air aftercooler 14 and the oil air / water heat exchanger 27 from the inlet 24 before leaving the compressor zone by the outlet 25. Oil from the oil / air separator 11 enters the heat exchanger 27 through the three-way thermostatic valve 26 or returns to the compressor 10 through the inlet filter 9a.

According to the invention, oil from the oil / air separator unit 11 can pass to the energy recovery unit 29, which is supplied with cooling liquid from the second three-way thermostatic valve 28. The water heated in the energy recovery unit 29 is carried past the filters 18, 19 and used to raise the temperature of the air in the feed air heater 19. The filters 18, 19 can thus operate near the optimum temperature and the air can be preheated beyond these filters, thereby entering a higher temperature nitrogen separator zone suitable for the operation of the separation membranes.

The drain pipes 32, 33, 34 exit from the cooling air dryer 15, the integrated particle filter 17 and the carbon filter 17 and are directed to the external drain pipe valve 35, respectively.

The air regulated from the valve 23 is directed to the nitrogen separator zone. It comprises a membrane module bank 41, which has a plurality of membrane air gas separators. Each separator consists of a bundle of hollow fibers contained in a metal housing. The housing has three external connections 42, 43, 44. One connection is located at each end of the housing leading to the inlet 42 and the outlet 43 from the bore sides of the fibers and to the bore sides, respectively, and one side connection 44 is at the shell side of the fiber. To this. Each fiber consists of a polymer composite layer. One relatively thick layer acts as a support and the other layer (thin film) functions as a separation control layer. It is important at this stage that the operating temperature does not exceed the maximum allowable temperature of the polymer.

Separation is effected by selective penetration of gases in air through a thin film of composite polymer membranes. Nitrogen penetrates at a lower rate than other gases, and in the regulated air entering the connection 42, this nitrogen passes along the bores and exits the other end of separator 43, and oxygen and other gases pass through the membranes and It is led through the side connection 44 of the separator and into the atmosphere through the vent line.

The nitrogen separator zone outlet connection 43 is equipped with a product flow indicator 45, a flow control valve 46 and a pressure control valve 47. Quality control analyzers are equipped in a quality control group 48 that does not form part of the present invention.

Nitrogen produced in the membrane separator 41 can be directed to the product outlet 49 or to the outlet 50 during the start of production when quality changes, which also allows other gases to be released to the atmosphere. Can be.

Claims (11)

Apparatus for use in a compressor (10) for gas compression that is liquid cooled and / or lubricated, The apparatus provides for the addition of liquid to the gas for cooling purposes prior to the introduction of the gas into the compressor, Downstream of the compressor there is a liquid / gas separator 11 for separating the liquid from the gas, and means 29 for recovering heat from the liquid, one in the gas flow downstream of the liquid / gas separator. There is a filter 17 or 18 above, and there is a heater 19 in the gas flow downstream of the filter, where the gas is heated using heat recovered from the liquid, whereby the gas is separated into a gas-gas separation unit. Characterized in that for controlling the temperature of the compressed gas, Apparatus for use in compressors for gas compression that are liquid cooled and / or lubricated. The method of claim 1, Characterized in that there is a heat exchanger 14 in the gas flow between the liquid / gas separator and the one or more filters, and that heat exchanger refrigerant from an external source is used to cool the gas flow. Apparatus for use in compressors for gas compression that are liquid cooled and / or lubricated. The method according to claim 1 or 2, Characterized in that a refrigerant dryer group 15 is arranged to cool the gas after the liquid has been separated from the gas and before the gas passes through the one or more filters. Apparatus for use in compressors for gas compression that are liquid cooled and / or lubricated. The method according to any one of claims 1 to 3, The at least one filter is a coalescing particle filter, Apparatus for use in compressors for gas compression that are liquid cooled and / or lubricated. The method according to any one of claims 1 to 3, The at least one filter is a carbon filter for removing steam from the cooling liquid, Apparatus for use in compressors for gas compression that are liquid cooled and / or lubricated. The method according to any one of claims 1 to 3, The at least one filter comprises two stage filtration, the first filtration stage comprises an integrated particle filter and the second filtration stage comprises a carbon filter for removing vapor from the cooling liquid, Apparatus for use in compressors for gas compression that are liquid cooled and / or lubricated. The method according to any one of claims 1 to 6, Used with a membrane gas separator unit arranged to receive gas from the device using the heat recovered from the liquid before the liquid passes through the filter, Apparatus for use in compressors for gas compression that are liquid cooled and / or lubricated. The method according to any one of claims 1 to 7, Used with a compressor for compressing the gas, Apparatus for use in compressors for gas compression that are liquid cooled and / or lubricated. The method of claim 8, Characterized in that the compressor is a screw compressor, Apparatus for use in compressors for gas compression that are liquid cooled and / or lubricated. The method of claim 9, Characterized in that the compressor is lubricated and cooled by oil, Apparatus for use in compressors for gas compression that are liquid cooled and / or lubricated. A method for recovering heat from compressed gas from a compressor that is liquid cooled and / or lubricated, Adding liquid to the gas for cooling purposes prior to the introduction of the gas into the compressor, Separating the liquid from the gas after the gas leaves the compressor, Recovering heat from the liquid, Passing the gas through at least one filter, and Downstream of the filter, heating the gas using heat recovered from the liquid before the gas passes through the filter, Thereby adjusting the temperature of the compressed gas, A method for recovering heat from compressed gas from a compressor that is liquid cooled and / or lubricated.

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