DE19919938A1 - Method and device for better use of the cooling energy of a cryogenic electricity - Google Patents

Abstract

Method and device for the better use of the cooling energy of a cryogenic stream, preferably an exhaust gas stream of an immersion freezer charged with liquid nitrogen. DOLLAR A According to the invention, the cryogenic stream (4) with a cooling air stream (5), which has a higher average temperature than the cryogenic stream (4) and which is used to cool a room and / or device (9), before it is fed into the Room and / or the device (9) merged. For this purpose, the (exhaust air) line of the cryogenic stream (4) opens into the line of the cooling air stream (5) and the line of the cooling air stream (5) is assigned to a room and / or device (9) to be cooled. DOLLAR A The cryogenic stream (4) is preferably sucked in by the cooling air stream (5). The cooling air flow (5) in turn is preferably carried out in a circuit.

Description

The invention relates to a method for better use of the cooling energy cryogenic stream, preferably an exhaust gas stream of one with liquid nitrogen charged freezer.

The invention further relates to a device for better use of the cooling energy a cryogenic stream, preferably an exhaust gas stream one with liquid nitrogen-fed immersion freezer, the cryogenic stream over at least one (Exhaust air) line is led.

With a variety of devices or devices, such as cryogenic (Immersion) Freezers, which serve to freeze food, can be due to the design not the full heat content of the medium used for freezing, in which it can be, for example, liquid nitrogen. Depending on The design of the device and the method implemented in it are therefore important a loss in terms of the heat content of the medium used.

With cryogenic (immersion) freezers, the resulting cold exhaust gas - its temperature is in the range of -150 ° C to -10 ° C - usually mixed with room air and to the Atmosphere. Mixing with room air must therefore take place because conventional fans for gases with the low temperatures mentioned - due to thermal expansion, the greases used for the bearings and the factory materials for such fans - are not suitable. In principle, however, are fans s known that can pump gases with correspondingly low temperatures, however these fans are comparatively expensive, prone to malfunction and maintenance-intensive.

The devices mentioned, such as cryogenic (immersion) freezers, are often used where conventional refrigeration systems are also available. Under The term "conventional refrigeration systems" are, for example, cold rooms or - understand storage, conventional freezers, compressor rooms, etc.  

The object of the present invention is to provide a method and an apparatus for specify better use of the cooling energy of a cryogenic electricity by means of the or by means of the mentioned disadvantages of the prior art Procedures can be avoided.

This is according to the inventive method for better use of the Cold energy of a cryogenic stream is achieved in that the cryogenic stream with a cooling air flow that has a higher average temperature than the cryogenic Has electricity and is used to cool a room and / or device in front of it Feed into the room and / or the device is merged.

The device according to the invention for better use of the cooling energy of a cryo gene current is characterized in that the (exhaust air) line of the cryogenic Current flows into the line of the cooling air flow and the line of the cooling air stream is assigned to a room and / or device to be cooled.

According to the invention, the cryogenic exhaust gas is now no longer with ambient air mixed and released into the atmosphere, but with a cooling air flow that serves to cool another room and / or device, brought together and mixed. This leads to a heat exchange between the cryogenic Electricity and the cooling air flow, which increases the energy expenditure for cooling the Cooling air flow reduced.

According to an advantageous embodiment of the method according to the invention better use of the cooling energy of a cryogenic electricity will be used by the Cooling air flow sucked in. In principle, however, it is also possible that the cryogenic exhaust air by means of appropriate devices, such as a compressor, the Cooling air flow is supplied.

The cooling air flow is preferably used to cool a room and / or device serves, in a cycle, that is taken from the room and / or the device and this again - after cooling - supplied. The promotion of cooling air The current is preferably carried out by means of at least one fan and the Feeding the cryogenic stream into the cooling air stream again preferably in Flow direction in front of the fan.  

The method according to the invention and the device according to the invention further forming it is proposed that the cooling air flow in a circuit with at least two fans of different sizes and the feed of the cryogenic flow to the cooling air flow between the fans.

The method according to the invention, the device according to the invention and others Refinements of the same or the same, the subject matter of subclaims in the following, using the exemplary embodiment shown in the figure game explained in more detail.

The figure shows a cryogenic (immersion) freezer 1 and a conventional freezer 9 . Food 3 is frozen in the cryogenic (immersion) freezer 1 in a liquid nitrogen bath 2 , which has a temperature of approximately -196 ° C. The exhaust gas from the cryogenic immersion freezer 1 , which has, for example, a temperature of -120 ° C., is drawn off from the (immersion) freezer 1 via the exhaust air line 4 .

The conventional freezer 9 , in which there is, for example, a temperature between -30 and -40 ° C., has a conventional cooling system in which the cooling air obtained in the freezer 9 , which has a temperature of approximately -35, for example, has a ring line 5 ° C, deducted and mixed in the area 8 of the ring line 5 with the exhaust gas from the exhaust air line 4 of the cryogenic freezer 1 . The gas stream supplied to the conventional freezer 9 now has a temperature of approximately -40 ° C., depending on the amount of the added exhaust air from the (immersion) freezer 1 .

Two differently dimensioned fans 6 and 7 are provided in the ring line 5 , which is preferably designed to be insulated. Since the two fans 6 and 7 promote different volume flows, a negative pressure is generated at the connection (area 8 ) between the exhaust air line 4 and the ring line 5, as a result of which the exhaust gas is sucked out of the exhaust air line 4 into the cooling air flow of line 5 . This leads to an optimal mixing of the two streams, which results in a very good direct heat exchange between the streams. The flow rate or throughput of the two fans 6 and 7 is preferably regulated in such a way that the temperature at the fan 7 does not drop below a minimum value which is determined by the mode of operation of the conventional freezer 9 .

The confluence area of the ring line 5 and the exhaust air line 4 can preferably be designed like a venturi. As a result, the suction of the exhaust air flow from the exhaust air line 4 is facilitated and the mixing of the two streams 4 and 5 is improved.

Due to the gas temperature in the ring line 5 , conventional fans can be used for the fans 6 and 7 . In the embodiment as shown in the figure, approximately ¼ of the energy stored in the liquid nitrogen can be used, for example.

According to an advantageous embodiment of the method according to the invention and the device according to the invention, the fans 6 and 7 are regulated as a function of the temperature of the exhaust air flow in the exhaust air line 4 and / or the cooling air flow in the line 5 . As an alternative or in addition, the fans 6 and 7 can also be controlled as a function of the flow rates of one or both streams.

For this purpose, suitable devices for detecting the temperature (s) and / or the flow rate (s) - which are not shown in the figure for the sake of clarity - are to be provided in the corresponding lines 4 and / or 5 . The fan or fans 6 and 7 can then be regulated by means of a suitable control device which evaluates the data of these devices.

If the procedure shown in the figure is transferred from a conventional freezer 9, for example, to a cold room, this must be provided with a suction device by means of which the gas expanding into the cold room can be disposed of. Furthermore, the cooling room should - if it has to be used at least temporarily - have oxygen room monitoring and / or forced ventilation.

In addition, there should be a conventional exhaust gas disposal option for the freezer be provided so that even at those times when the cold room is switched off, the freezer can continue to be operated.

The method according to the invention and the device according to the invention for better use of the cooling energy of a cryogenic stream enable an effective use of the cooling energy still contained in the exhaust air, for example a cryogenic freezer. This leads to a not inconsiderable cost saving for the overall system, as shown for example in the figure. In addition, the cryogenic freezer 1 can be run colder and also run in synchronism, whereby an improvement in the product quality is achieved without the overall efficiency being impaired. In addition, inexpensive and low-maintenance standard fans can be used.

Claims (13)

1. A method for better use of the cooling energy of a cryogenic stream, preferably an exhaust gas stream of a immersion freezer charged with liquid nitrogen, characterized in that the cryogenic stream ( 4 ) with a cooling air stream ( 5 ) having a higher average temperature than the cryogenic stream ( 4 ) has and which serves to cool a room and / or device ( 9 ), before it is fed into the room and / or the device ( 9 ) is brought together. 2. The method according to claim 1, characterized in that the cryogenic stream ( 4 ) is sucked in by the cooling air stream ( 5 ). 3. The method according to claim 1 or 2, characterized in that the cooling air flow ( 5 ) is guided in a circuit. 4. The method according to any one of the preceding claims, characterized in that the cooling air flow ( 5 ) promoted by means of at least one fan and the supply of the cryogenic stream ( 4 ) to the cooling air flow ( 5 ) in the flow direction in front of the fan. 5. The method according to claim 3 or 4, characterized in that the cooling air flow ( 5 ) in a circuit with at least two differently sized fans ( 6 , 7 ) is performed and the supply of the cryogenic stream ( 4 ) to the cooling air flow ( 5 ) between the fans ( 6 , 7 ). 6. The method according to claim 4 or 5, characterized in that the control of the fan or fans ( 6 , 7 ) in dependence on the temperature of the cryogenic stream ( 4 ) and / or the cooling air stream ( 5 ). 7. The method according to any one of claims 4 to 6, characterized in that the control of the fan or fans ( 6 , 7 ) in dependence on the flow rate of the cryogenic stream ( 4 ) and / or the cooling air stream ( 5 ). 8. A device for better use of the cooling energy of a cryogenic stream, preferably an exhaust gas stream of an immersion freezer charged with liquid nitrogen, the cryogenic stream being conducted via at least one (exhaust air) line, characterized in that the (exhaust air) line of the cryogenic stream ( 4 ) opens into the line of the cooling air flow ( 5 ) and the line of the cooling air flow ( 5 ) is assigned to a room and / or device ( 9 ) to be cooled. 9. The device according to claim 8, characterized in that the line of the cooling air flow ( 5 ) is designed as a ring or return line ( 5 ). 10. Apparatus according to claim 8 or 9, characterized in that the line of the cooling air flow ( 5 ) has at least one fan and the mouth of the (exhaust air) line of the cryogenic flow ( 4 ) in the line of the cooling air flow ( 5 ) in the flow direction before Fan is arranged. 11. The device according to claim 8 or 9, characterized in that the line of the cooling air flow ( 5 ) has at least two differently sized fans ( 6 , 7 ) and the mouth of the (exhaust air) line of the cryogenic stream ( 4 ) in the line of Cooling air flow ( 5 ) between the fans ( 6 , 7 ) is arranged. 12. Device according to one of the preceding claims 8 to 11, characterized in that in the (exhaust air) line of the cryogenic stream ( 4 ) and / or in the line of the cooling air stream ( 5 ) devices for detecting the temperature and / or the flow rate of the or the streams are arranged. 13. The apparatus according to claim 12, characterized in that the devices for detecting the temperature and / or the flow rate of the flow or currents ( 4 , 5 ) are assigned to at least one or the fans ( 6 , 7 ) regulating control device.