KR100433323B1 - Method and apparatus for producing a pressurized high purity liquid carbon dioxide stream - Google Patents

Abstract

The present invention provides a method and apparatus for producing a high purity compressed liquid carbon dioxide stream. In the present invention, the feed stream is purified by passing through a purge filter and condensed in a condenser. The condensed liquid then enters and exits the first and second compression accumulation chambers alternately. The first and second compression accumulation chambers are heated with an electric heater to compress the liquid in the chamber to the required or desired distribution pressure of the compressed liquid carbon dioxide stream. This compressed liquid carbon dioxide stream is discharged from the first and second compression accumulation chambers alternately by emptying the opposite chamber when either one of the first and second compression accumulation chambers is filled on a continuity basis. The compressed liquid carbon dioxide stream can be further purified in a dust filter.

Description

TECHNICAL AND APPARATUS FOR PRODUCING A PRESSURIZED HIGH PURITY LIQUID CARBON DIOXIDE STREAM}

The present invention relates to a method and apparatus for producing a purified, compressed liquid carbon dioxide stream which condenses a feed stream consisting of carbon dioxide vapor into a liquid and then heats and compresses it inside a chamber. More particularly, the present invention relates to a method and apparatus for producing the liquid carbon dioxide stream using two chambers capable of continuously distributing the compressed liquid carbon dioxide stream.

Highly compressed and purified liquid carbon dioxide is required in various industrial processes. This highly compressed liquid is produced by purifying industrial grade liquid carbon dioxide available at a pressure of about 13 to about 23 bar and pumping it to a pressure of about 20 to about 68 bar.

However, with this pumping process there is a problem that impurities such as particulates or hydrocarbons can be introduced into the product stream as a byproduct of mechanical pumping. As discussed herein, this problem is overcome by the present invention.

The present invention seeks to provide a process for producing compressed liquid carbon dioxide by introducing a feed stream consisting of carbon dioxide vapor into a purge filter. The purified feed stream is condensed inside a condenser having a sump and an intermediate liquid stream is introduced into the first and second compression accumulation chambers from the condenser sump. The first and second compression accumulation chambers are heated to compress the liquid contained in the chamber and the compressed liquid carbon dioxide is dispensed from the first and second compression accumulation chambers.

An intermediate liquid stream is selectively introduced into the first and second compression accumulation chambers and the intermediate liquid stream is introduced into the first and second compression accumulation chambers before the first and second compression accumulation chambers are evacuated. It is optionally dispensed from the chamber to be introduced elsewhere. This allows for continuous distribution of the compressed liquid carbon dioxide stream. Each of the first and second compression accumulation chambers is evacuated to the collection tank of the condenser before introducing the intermediate liquid stream.

Preferably, each of the first and second compression accumulation chambers is electrically heated. In addition, it is preferable to condense the feed stream inside the condenser by indirectly exchanging heat with the refrigerant stream. Further processing may be by introducing a compressed carbon dioxide stream into the particulate filter.

In another aspect, the present invention seeks to provide an apparatus for producing a compressed liquid carbon dioxide stream. The apparatus of this aspect is provided with a purification filter for purifying a feed stream consisting of carbon dioxide vapor and using a condenser having a collection tank for condensing the feed stream. The first and second compression accumulation chambers are combined with heaters for heating these chambers to compress the liquid contained therein.

A flow network coupled to the compression accumulation chamber includes conduits connecting the first and second compression accumulation chambers for discharging the compressed liquid carbon dioxide stream to the collection tank of the condenser. The flow network selectively introduces an intermediate liquid stream from the condenser collection tank into the first and second compression accumulation chambers and selectively introduces compressed liquid carbon dioxide from the first and second compression accumulation chambers so that one of the chambers is evacuated. It has a valve previously associated with a conduit that allows the intermediate liquid stream to be introduced into another chamber. The conduit also includes an exhaust pipe that respectively exhausts the chambers before introducing an intermediate liquid stream between the first and second compression accumulation chambers and the condenser.

Preferably, the heater is an electric heater and the condenser is an external cooling circuit with a heat exchanger in which the feed stream is condensed through indirect heat exchange of the feed stream and the refrigerant. A particulate filter may be further coupled to the flow network of the compressed liquid carbon dioxide stream generating device to purify the compressed liquid carbon dioxide stream.

1 shows an apparatus for producing high purity compressed liquid carbon dioxide according to the present invention.

Referring to the figure, a device 1 according to the invention is disclosed. Feed stream 10 consisting of carbon dioxide vapor enters purge filter 12 which may be any coalescing and / or selective adsorptive filter available. Position valves 14 and 16 to separate purge filter 12 separately.

After purification, the feed stream is condensed into liquid 20 through condenser 18 with a collection tank. This condensation takes place in an external cooling unit 22, in which the refrigerant circulates in the heat exchanger 24, which preferably consists of a tube and a shell. In this regard, condenser 18 may consist of a heat exchanger which feeds to a separate collection tank. Additional isolation valves 23 and 25 can be arranged to separate the cooling units 22 separately. The liquid level is controlled by a pressure differential detector 26 which detects the pressure difference between the liquid and the gas in the condenser 18. Although not disclosed, the regulator in the form of a logic computer that can change the program arbitrarily receives a signal from the pressure differential detector 26 and activates the cooling unit 22 when the liquid 20 drops below the specified level.

As can be seen in the above discussion, since the vapor condenses in the condenser 18, the more volatile impurities are in the uncondensed vapor and the less volatile impurities condense into the liquid and any impurities in the vapor can occur. Although not disclosed, a sampling tube can be connected to condenser 18 to sample and draw as much liquid and vapor as necessary to lower the concentration of impurities in condenser 18.

The intermediate liquid stream consisting of high purity liquid 20 enters the first and second compression accumulation chambers 28 and 30. In apparatus 1 the first and second compression accumulation chambers 28 and 30 are preferably heated with electric heaters 33 and 34, respectively, to compress the liquid up to the distribution pressure of the compressed liquid carbon dioxide stream.

The liquid enters and exits the first and second compression accumulation chambers 28 and 30 by a flow network, including inlet tubes 32 which feed the intermediate liquid stream into the compression accumulation chambers 28 and 30. The compressed liquid carbon dioxide stream exits through the discharge conduit 35 in the first and second compression accumulation chambers 28 and 30. Then, the first and second compression accumulation chambers 28 and 30 are respectively exhausted through the exhaust pipe 36 to the condenser 18.

The flow in the flow network is regulated by the valve network. In this regard, control valves 38 and 40 regulate the flow of the intermediate liquid stream exiting condenser 18 and into the first and second compression accumulation chambers 28 and 30. Regulating valves 42 and 44 regulate the flow of outlet line 35. Control valves 46 and 48 regulate exhaust of the first and second compression accumulation chambers 28 and 30.

When the second compression accumulation chamber 30 is almost empty, the control valve 42 is opened and the control valve 44 is closed to discharge the compressed liquid carbon dioxide stream in the first compression accumulation chamber 28. At the same time, the second compression accumulation chamber is in the compressed state by the electric heater 34, so that the control valve 48 is opened and exhausted at the same pressure as the condenser 20. This allows the second compression accumulation chamber 30 to be able to accept a larger amount of intermediate liquid stream through the introduction tube 32. By this time the regulating valve 40 remains open. If the second compression accumulation chamber 30 is cold and is measured by the pressure difference detector 52, the control valves 40 and 48 are closed, and the liquid in the second compression accumulation chamber 30 is heated and compressed by the electric heater 34.

When the first compression accumulation chamber is almost empty as measured by the pressure differential detector 50, the control valve 42 is closed and the control valve 44 is opened to release the compressed liquid carbon dioxide stream from the second compression accumulation chamber 30. At the same time, when the first compression accumulation chamber is compressed by the electric heater 33, the control valve 46 is opened to be exhausted at the same pressure as the condenser 20. Open the control valve 38 to fill the first compression accumulation chamber 28 with the intermediate liquid stream. Once measured by the pressure differential detector, the first compression accumulation chamber 28 is filled, the control valves 38 and 46 are closed and the liquid in the first compression accumulation chamber 28 is heated and compressed with an electric heater 33.

The valves described above operate in cycles so that the compressed liquid carbon dioxide stream can be continuously discharged. Preferably, the period is adjusted with a logical regulator that can be arbitrarily changed, which is not shown in this figure, connected to pressure differential detectors 50 and 52. The pressure difference detectors 50 and 52 generate a signal corresponding to the level of the liquid in the first and second compression accumulation chambers 28 and 30, in response to this signal the regulator remotely controls the above-described control valve. There is also a pressure differential detector that detects the level of the liquid in condenser 18 and stops the condensation process by turning off the cooling unit 22 before the condensation vessel is filled to receive the carbon dioxide exhausted from the compression accumulation chambers 28 and 30 during the charging cycle. Let's do it.

Preferably, the discharge pipe 35 is combined with the particulate filter 54 to remove particulate contamination of this liquid. While preferred embodiments of the present invention have been disclosed, those skilled in the art can make various changes and modifications thereto without departing from the spirit and scope of the invention.

The present invention provides a method and apparatus for producing a high purity compressed liquid carbon dioxide stream. As can be seen from the discussion above, a heater is used to compress the liquid, so that impurities cannot enter the compressed liquid carbon dioxide stream without being in contact with the mechanical compression element. In addition, since the compressor is not used, the apparatus according to the present invention is less expensive to maintain than the conventional apparatus.

Claims (8)

Introducing a feed stream consisting of carbon dioxide vapor into the purge filter; Condensing said purified feed stream within a condenser having a collection tank; Introducing an intermediate liquid stream from the collection tank into first and second compression accumulation chambers; Heating the first and second compression accumulation chambers to compress the liquid contained within the chamber to a dispensing pressure; Distributing a compressed liquid carbon dioxide stream from the first and second compression accumulation chambers; And Evacuating each of the first and second compression accumulation chambers to a condenser prior to introducing the intermediate liquid stream, The intermediate liquid stream is selectively introduced into the first and second compression accumulation chambers and the intermediate liquid stream is compressed into the first and second compression accumulation chambers before the first and second compression accumulation chambers are evacuated. Selectively distributed from the chamber to be introduced elsewhere in the accumulation chamber to ensure continuous distribution of the liquid carbon dioxide stream. Process for producing a compressed liquid carbon dioxide stream. The method of claim 1, Wherein the first and second compression accumulation chambers are electrically heated. The method of claim 1, A process for producing a compressed liquid carbon dioxide stream in which the feed stream condenses within the condenser through indirect heat exchange with the refrigerant stream. The method of claim 1, A method of producing a compressed liquid carbon dioxide stream further comprising introducing the compressed liquid carbon dioxide stream into the particulate filter. A purifying filter for purifying a feed stream composed of carbon dioxide vapor; A condenser having a collecting tank for condensing said feed stream; First and second compression accumulation chambers; A heater for compressing the liquid contained in the chamber to a dispensing pressure by heating the first and second compression accumulation chambers; A conduit for coupling the first and second compression accumulation chambers to a collection vessel of a condenser to discharge a compressed liquid carbon dioxide stream, and in combination with the conduit, wherein the intermediate liquid stream is compressed from the collection vessel of the condenser. A flow network having a valve that selectively introduces into the accumulation chamber and selectively introduces compressed liquid carbon dioxide from the first and second compression accumulation chambers so that an intermediate liquid stream is introduced into the other chamber before one of the chambers is evacuated (flow network), The conduit includes an exhaust pipe for evacuating the chambers respectively before introducing an intermediate liquid stream therein between the first and second compression accumulation chambers and the condenser; Apparatus for producing a compressed liquid carbon dioxide stream. The method of claim 5, wherein And wherein said heater is an electric heater. The method of claim 5, wherein Wherein the condenser comprises an external cooling circuit having a heat exchanger for cooling the feed stream through indirect heat exchange of the feed stream with the refrigerant stream. The method of claim 5, wherein An apparatus for producing a compressed liquid carbon dioxide stream further comprising a particulate filter coupled to the flow network to filter the compressed liquid carbon dioxide stream.