EP2369280A2 - Method and device for producing cold gaseous or liquid air - Google Patents

Abstract

The method involves conveying air to a heat exchanger (21), and cooling the air in the heat exchanger by heat exchange with liquefied cryogenic coolant e.g. liquid nitrogen. The cryogenic coolant is vaporized, and the air to be cooled is passed through an air drier (26) e.g. adsorber drier, membrane drier and coolant drier, before supplying the air to the heat exchanger. The coolant evaporated in the heat exchanger is used as an operating agent in the air drier, and the evaporated cryogenic coolant is released to an expansion machine (32). An independent claim is also included for a device for producing cryogenic gaseous or liquefied air comprising a heat exchanger with a surface for thermal contact of air with evaporated cryogenic coolant.

Description

The invention relates to a method for producing cryogenic gaseous or liquefied air, is conveyed in the air to a heat exchanger and cooled there in heat exchange with a liquefied, cryogenic refrigerant, wherein the cryogenic refrigerant evaporates. The invention further relates to a corresponding device.

The cooling of cold chambers, cold rooms or the transport cooling are usually carried out today with conventional chillers. Disadvantages are the often high cost of the machines and their high maintenance, the limited cooling capacity, energy requirements and emissions in the form of noise, exhaust gases u. dergl. An alternative is the direct cooling of the area to be cooled with a cryogenic refrigerant, such as liquefied nitrogen or solid carbon dioxide (dry ice). If these refrigerants are introduced directly into the area to be cooled, although you have a technically simple and effective cooling, closed Cold rooms can no longer be done without breathing apparatus or a thorough previous ventilation. For certain applications, such as cryotherapy, therefore, partly liquid air is used as the refrigerant. The disadvantage here is that liquid air must be produced industrially and transported over long distances. Since liquid air does not in itself constitute a stable system, but over time concentrates with the gradual evaporation of the nitrogen content of oxygen, special safety measures are required to ensure the economic viability of the use of liquid or cryogenic gaseous air for the purchaser, in particular for small customers drastically reduce customers far from the liquid air production site.

The object of the present invention is therefore to provide a method and a device which enables economical production of cryogenic gaseous or liquefied air even in smaller quantities on site.

This problem is solved in a method of the type mentioned above in that the air to be cooled passes through a device for air drying before being fed to the heat exchanger, is used in the vaporized in the heat exchanger refrigerant as operating equipment.

According to the invention, therefore, the cryogenic gaseous or liquefied air is produced by thermal contact with a liquefied cryogenic refrigerant which is at a temperature below the desired temperature, in particular below the liquefaction temperature of air. For example, liquid nitrogen is used as the cryogenic refrigerant. During the heat exchange, the cryogenic refrigerant evaporates at least partially and subsequently serves as a means for a device for drying the air to be cooled. The previous drying of the air is essential in the generation of cold gaseous or liquid air by heat exchange with a cold medium, since the water vapor contained in the air to be cooled leads to ice formation, which can affect the operability of the production facility quickly. The vaporized refrigerant can be used in various ways as a resource in the device for air drying. For example, even after the evaporation in the heat exchanger still very cold gaseous refrigerant can be used to remove water vapor contained in the air by way of condensation. If, as an alternative or in addition to such a refrigerant drying, a membrane is used for separating the water vapor from the air, the gaseous refrigerant can be used as purge gas. In a further variant, absorption drying takes place by means of an absorbent. Here, the vaporized refrigerant can be used to regenerate the water-loaded adsorbent. By combining air cooling on the one hand with air drying on the other hand, a high efficiency of the method according to the invention is achieved. The inventive method allows the production of economically usable amounts of cryogenic gaseous or liquid air even in relatively small and compact system on site; There is only a supply of the user with cryogenic liquefied inert gas, for which there are no comparable with the transport of liquid air complex security requirements.

The pressure caused by the evaporation of the refrigerant pressure is used in an advantageous development of the invention in an expansion machine for generating energy, in particular electrical and / or mechanical energy. The energy generated in the expansion of the evaporated liquid refrigerant is then used to operate a conveyor for conveying the air to be cooled to the heat exchanger, so that provided for the operation of the conveyor motor for the same power can be dimensioned much smaller or even eliminated altogether.

A yet further advantageous embodiment of the invention provides that the evaporated cryogenic refrigerant is used for precooling the air supplied to the heat exchanger. In this case, the remaining residual cold of the evaporated cryogenic refrigerant is used to further improve the efficiency of the method according to the invention. Additionally or alternatively, the evaporated cryogenic refrigerant is preferably used for cooling the conveyor.

Preferably, the air to be cooled is sucked in because of the pressure drop occurring in the cooling of the air in the heat exchanger and by the device for air drying. In this case, a conveyor for conveying the air to the heat exchanger is unnecessary, or it can be at least dimensioned smaller.

The object of the invention is also achieved by a device for generating cryogenic gaseous or liquefied air, comprising a heat exchanger having an air inlet line and an air outlet line and heat exchanger surfaces for thermally contacting air with a liquefied cryogenic refrigerant and a vaporized cryogenic refrigerant outlet line. The device according to the invention is characterized in that a device for drying the air is provided in the air inlet line, which is also connected to the outlet line for vaporized cryogenic refrigerant and in which the cryogenic refrigerant can be used as operating means in the device for drying the air.

The device according to the invention therefore comprises a heat exchanger in which, on suitable heat exchanger surfaces, such as pipe walls, the air to be cooled enters into heat exchange with a liquefied cryogenic refrigerant. During heat exchange, the air is cooled and optionally liquefied, while at the same time the refrigerant evaporates. The vaporized refrigerant is then supplied via the vaporized refrigerant outlet line to the air drying device where it is used as a drying agent for the air. The device according to the invention has only a few components that can be assembled very compact and thus have only a small space requirement. For supply, it essentially requires only liquefied cryogenic refrigerant, such as liquid nitrogen, which can be delivered and stored at low cost even in smaller quantities of a few cubic meters or even less than 1 m ³ . As a result, the device according to the invention can be easily carried on refrigerated vehicles or in refrigerated containers, for example, or placed in closed rooms, for example in the rooms of a doctor's office or a fitness studio.

The device for air drying preferably comprises an adsorption dryer, a membrane dryer or a refrigerant dryer. In an absorption dryer water vapor is removed from the air by means of an absorber, wherein the absorber is loaded with water vapor. In order to maintain the functioning of the absorber, it is therefore necessary to regenerate it from time to time by applying a dry gas, in this case the vaporized cryogenic refrigerant. In order to enable continuous operation, the absorption dryer preferably comprises two mutually employable units, one of which is used in each case for drying the air, while the other passes through a regeneration phase. In a membrane dryer, such as in the DE 19812960 C1 and the documents cited therein, the separation of the water vapor from the air by a water vapor-selective membrane. Again, the membrane requires regeneration by a purge gas, as the evaporated in the context of the present invention cryogenic refrigerant from the heat exchanger is used. In a refrigeration dryer, the separation of the water vapor by condensing takes place during cooling of the air in thermal contact with the still very cold evaporated refrigerant. In this case, a pre-cooling of the air takes place at the same time, which further increases the economic efficiency of the plant.

An advantageous development of the invention provides that a conveying device is provided for conveying air into the heat exchanger and the outlet line for evaporated cryogenic refrigerant is flow-connected to an expansion machine, wherein the expansion machine is operatively connected via means for transmitting energy to the conveyor. The expansion engine, which includes, for example, a turbine or a lift cylinder, generates mechanical or electrical energy by expansion of the refrigerant used to operate the conveyor. In this way, the amount of the conveyor to their operation - for example by means of a motor - from the outside, such as through a power grid, supplied energy can be at least significantly reduced.

Preferably, a recuperator is provided in the air inlet line, which has a supply line connected to the outlet line for evaporated cryogenic refrigerant and a heat exchanger surface for transferring heat from the air from the air inlet line to the evaporated cryogenic refrigerant. In this way, the residual refrigeration contained in the evaporated cryogenic refrigerant is used to lower the refrigerant demand of the system. As mentioned above, this process can also be used to compensate for water vapor from the air to be cooled.

An advantageous development of the invention provides that the heat exchanger and / or the recuperator is / are integrated in a tank for the liquefied cryogenic refrigerant. As a result, heat losses are reduced as well as the space requirement of the device and further increases the efficiency. Likewise, it proves to be advantageous to arrange a connected to the air outlet line reservoir for liquid air within the reservoir for the liquefied cryogenic refrigerant. In this way, the temperature of the liquefied air remains below the boiling point of the nitrogen whereby one - under Safety issues problematic - accumulation of oxygen in the liquid air is avoided.

A further embodiment of the invention provides that the recuperator is designed as a cold storage. The recuperator is connected to an exhaust pipe of the tank for liquid refrigerant and is constantly, so even during breaks in the flow of evaporating refrigerant and stores its cold content. In this way, the recuperator is quickly operational even after prolonged breaks and the cold of evaporating refrigerant during the break is used.

Preferably, the conveyor includes a fan or a compressor, which is arranged on the input side of the heat exchanger and by means of which the air is pressed into the heat exchanger. Alternatively, however, it is also conceivable that the conveyor is arranged on the output side of the heat exchanger; If the air is liquefied in the heat exchanger, the delivery device in this case comprises a pump which pumps off the liquefied air from the heat exchanger, while at the same time fresh air flows into the heat exchanger.

A preferred use of the method or the device according to the invention consists in the cooling of walk-in spaces such as refrigerators for storing temperature-sensitive goods or cold chambers for therapeutic purposes.

• Fig. 1: Das Schaltbild einer erfindungsgemäßen Vorrichtung zum Erzeugen von tiefkalter gasförmiger oder verflüssigter Luft in einer ersten Ausführungsform und
• Fig. 2: Das Schaltbild einer erfindungsgemäßen Vorrichtung zum Erzeugen von tiefkalter gasförmiger oder verflüssigter Luft in einer zweiten Ausführungsform.

Reference to the drawings, embodiments of the invention will be explained in more detail below. In a schematic view show:

• Fig. 1 The diagram of a device according to the invention for producing cryogenic gaseous or liquefied air in a first embodiment and
• Fig. 2 : The circuit diagram of an apparatus according to the invention for producing cryogenic gaseous or liquefied air in a second embodiment.

In the Fig. 1 1 includes a heat exchanger 2 equipped with an air inlet duct 3, an air outlet duct 4, a refrigerant inlet duct 5 and a refrigerant outlet duct 6. The refrigerant input line 5 is in fluid communication with a tank 7 for a liquefied cryogenic refrigerant, for example, a stand tank for liquid nitrogen. In the air input line 3, a conveyor 8, for example, a compressor or a fan, arranged by means of which air is conveyed to the heat exchanger 2 out. The refrigerant outlet line 6 opens into an expansion machine 9 in which energy released during the expansion of gaseous refrigerant is converted into mechanical or electrical energy. Expansion machine 9 and conveyor 8 are operatively connected to each other in such a way that the energy generated in the expansion machine 9 is used to operate the conveyor 8 via suitable energy transmission means 10. For example, the energy transmission means 10 comprise a shaft, by means of which the mechanical energy generated in the expansion machine is transferred directly to the conveyor 8 or the expansion machine 9 comprises a generator for generating electrical energy, directly or indirectly, for example via a power grid, for operating the conveyor 8th is being used.

Downstream of the conveyor 8, a device 11 for drying the air to be supplied to the heat exchanger 2 is provided in the air inlet line 3. As a device 11, for example, a refrigerant dryer, a membrane dryer or an absorption dryer is provided. The device 11 is connected to the refrigerant outlet line 6 and thus enables the use of the cryogenic refrigerant evaporated in the heat exchanger 2 as operating means for the device 11; In the examples mentioned, the evaporated cryogenic refrigerant thus serves as a regeneration gas for regenerating an absorber and / or as a purge gas for regenerating a membrane dryer and / or as a refrigerant for condensing water vapor from the air to be dried.

The air outlet line 4 opens into a storage tank 12 for liquid air, which is arranged in the exemplary embodiment within the tank 7 for the liquid cryogenic refrigerant and is thermally connected to the liquid phase of the stored in the tank 7 refrigerant. From the reservoir 12, the generated air can be stored and if necessary taken over a removal line 13, wherein, if necessary, a pressure build-up evaporator 14 is used. The arrangement of the storage tank 12 within the liquid phase of the stockpiled in the storage tank 7 refrigerant whose temperature is maintained at a temperature equal to or below the boiling point of nitrogen in the reservoir 12, thereby ensuring that the composition of the liquid air in the reservoir 12 remains substantially constant and no accumulation of liquid oxygen in the storage tank 12 takes place. In the context of the invention, the arrangement of the reservoir 12 within the tank 7, moreover, by no means absolutely necessary, but it has the stated thermodynamic advantages.

During operation of the device 1, air is supplied via the conveyor 8 to the heat exchanger 2. At present in the heat exchanger 2 heat exchanger surfaces, such as on the walls of tube bundles, through which the air or the refrigerant is passed, the air comes into thermal contact with the liquefied cryogenic refrigerant from the tank 7. The air cools and is liquefied, for example while the liquefied cryogenic refrigerant evaporates. The evaporated cryogenic refrigerant is used in the device 11 for drying the air in the manner described above as a resource. The caused by the evaporation increased pressure of the cryogenic refrigerant in the refrigerant outlet line 6 is expanded in the work in the expansion machine 9 and used to operate the conveyor 8. For example, the expansion machine comprises a turbine or a piston and a generator connected thereto, and the electrical energy generated in this generator is used to drive the conveyor 8. If more electrical or mechanical energy is generated in the expansion machine 9 than can be consumed in the conveyor 8, the excess energy can be utilized otherwise - in the case of electrical energy, for example, it can be fed into a pipeline network. If, conversely, the energy generated in the expansion machine 9 is insufficient to operate the conveyor 8, additional energy must be supplied, for example by means of a motor driving the conveyor 8, which may of course be of lower power than without the operative connection of the conveyor 8 the expansion engine 9 would be the case. The order of the components 9 and 11 can be changed with respect to the flow direction of the refrigerant on, the expansion machine 9 can therefore also be arranged upstream of the device 11. Likewise, as seen in the flow direction of the air, conceivable within the scope of the invention to provide the conveyor for air downstream of dryer and / or heat exchanger. It is also conceivable to completely dispense with a conveyor and to use the resulting due to the cooling of the air through the heat exchange with the cryogenic refrigerant negative pressure for sucking the air, in which case it must be ensured in a suitable manner that the liquefied Air is supplied to the reservoir 12.

In the device 20 in FIG Fig. 2 a heat exchanger 21 is housed within a liquefied cryogenic refrigerant tank 22. The heat exchanger 21 is connected to an air inlet line 23 through which air is passed to the heat exchanger 21 where it is cooled and / or liquefied by thermal contact with the liquefied cryogenic refrigerant present in the tank 22. In the air inlet line 23, upstream of the heat exchanger 21 in succession, a conveyor 25 which operates in the same manner as the conveyor air dryer 26 and a recuperator 27 are arranged. By way of example, the air dryer is an apparatus which, as far as possible, removes the water vapor contained in the air supplied to the heat exchanger 12 via the front section 28 of the air inlet line 23. The air dryer in the exemplary embodiment is an absorption dryer in which vaporized cryogenic refrigerant is used to regenerate the absorbent material. The recuperator 27 serves for precooling the air. Due to the thermal contact of the air to be cooled with the liquefied cryogenic refrigerant, such as liquid nitrogen in the tank 22 vaporizes a portion of the liquefied cryogenic refrigerant is discharged through a flow-connected to the gas space of the tank 22 line 30 and enters the recuperator 27. There a thermal interaction of the still provided with considerable residual refrigerant evaporated cryogenic refrigerant with the zoomed in the front portion 28 of the air inlet duct 23 air. In the recuperator 27, the air cools down while the vaporized cryogenic refrigerant is heated, fed to the air dryer 26 via a refrigerant line 31 is deprived of moisture in the air as described above. Subsequently, the refrigerant is supplied to an expansion machine 32 in which it is similar to the expansion machine 9 Fig. 1 used for energy production by relaxation. The generated electrical or mechanical energy is used to operate the conveyor 25. In the embodiment according to Fig. 2 In addition, an auxiliary motor 33 is used, which can supply additional energy to the conveyor 25. The air dried in the air dryer 26 and pre-cooled in the recuperator 27 air is fed to the heat exchanger 21, where brought into thermal contact with the liquid cryogenic refrigerant in tank 22 and liquefied, for example. The sequence of the components 32, 25, 26, 27, 21 is otherwise not mandatory and can be set differently in other embodiments of the invention. Thus, for example, a conveyor for air and downstream of the heat exchanger 2, 21 are arranged; In this case, the conveyor is, for example, a pump for liquid air. Also, the air dryer 26 (or generally an air dryer) and / or the Rekuperatur 27 (or generally a recuperator) - seen in the flow direction of the refrigerant - be arranged downstream of the expansion machine 32.

With the device according to the invention, it is no longer necessary, in particular for the cooling of accessible spaces, to supply liquid air, but the required liquid air is generated on site; only the usual logistics for liquid cryogenic refrigerant (for example, liquid nitrogen) is required. The drive of the conveyor by means of expanding, evaporated cryogenic refrigerant saves the use of an engine (or reduces its performance) and therefore leads to a significantly lower noise. The device according to the invention can be used both for generating liquid air and for generating cold, gaseous air. The systems can be small in size so that they can be installed, for example, in medical practices, fitness studios or carried on mobile cooling devices.

LIST OF REFERENCE NUMBERS

1.

contraption

Second

heat exchangers

Third

Air input line

4th

Air output line

5th

Refrigerant input line

6th

Refrigerant output line

7th

tank

8th.

fan

9th

expander

10th

Energy transfer means

11th

Device for air drying

12th

Reservoir (for liquid air)

13th

withdrawal line

14th

Pressure build-up evaporator

15th-19th

-

20th

contraption

21st

heat exchangers

22nd

tank

23rd

Air input line

24th

-

25th

Conveyor

26th

air dryer

27th

recuperator

28th

Front section of the air inlet line

29th

-

30th

management

31st

Refrigerant line

32nd

expander

33rd

auxiliary engine

Claims (12)

Method for producing cryogenic gaseous or liquefied air, in which air is conveyed to a heat exchanger (2, 21) and cooled therein in heat exchange with a liquefied, cryogenic refrigerant, the cryogenic refrigerant evaporating,
characterized,
in that the air to be cooled, before being fed to the heat exchanger (2, 21), passes through a device (11, 26) for air drying, in which the refrigerant evaporated in the heat exchanger (2, 21) is used as operating medium. A method according to claim 1 or 2, characterized in that the vaporized cryogenic refrigerant in an expansion machine (9, 32) work expanded relaxed and the energy thereby obtained for conveying the air to be cooled to the heat exchanger (2,21) is used. A method according to claim 1 or 2, characterized in that the evaporated cryogenic refrigerant for pre-cooling of the heat exchanger (2, 21) supplied air and / or for cooling the conveyor (2, 21) is used. Method according to one of the preceding claims, characterized in that the air to be cooled is sucked in because of the thermal contact with the cryogenic refrigerant in the heat exchanger (2,21) resulting pressure drop and through the means (11, 26) for air drying. Device for producing cryogenic gaseous or liquefied air, comprising a heat exchanger (2, 21) having an air inlet line (6, 23) and an air outlet line (4) and heat exchanger surfaces for thermally contacting air with a liquefied cryogenic refrigerant and an outlet line (6, 30) for vaporized cryogenic refrigerant, characterized
in that in the air inlet line (3, 23) there is provided a device (11, 26) for drying the air, which is connected to the vaporized cryogenic refrigerant outlet line (6, 30) and in which the cryogenic refrigerant is used as drying medium for the air can be used. The method of claim 5, wherein the means (26) for air drying comprises an adsorption dryer, a membrane dryer or a refrigerant dryer. Apparatus according to claim 5 or 6, characterized in that a conveying device (8, 29) for conveying air into the heat exchanger (2, 21) is provided and the outlet line for evaporated cryogenic refrigerant with an expansion machine (9, 32) is fluidly connected, which is operatively connected via means for transmitting energy with the conveyor (8, 29). Apparatus according to claim 5 to 7, characterized in that in the air inlet line (3, 23) a recuperator (27) is provided, which is a flow-connected to the output line (30) for evaporated cryogenic refrigerant supply line and a heat exchanger surface for transferring heat from the air from the air inlet line (3, 23) on the evaporated cryogenic refrigerant. Apparatus according to claims 5 to 8, characterized in that the heat exchanger (2, 21) and / or the recuperator (27) and / or a reservoir for liquefied air connected to the air outlet line (6, 23) are introduced into a tank (22) for the liquefied cryogenic refrigerant is integrated. Apparatus according to claim 8 or 9, characterized in that the recuperator is designed as a cold storage. Apparatus according to claim 5 to 10, characterized in that the conveyor (8, 29) comprises a blower, a compressor or a pump for liquefied air. Use of a method according to claim 1 to 2 or a device according to claim 5 to 11 for cooling accessible spaces.

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