DE10318895B3 - Cooling device for slow cooling of superconductive component e.g. HTS power transformer, has semi-permeable membrane for separation of liquid cooling medium and gaseous cooling medium - Google Patents

Abstract

The cooling device (1) has a closed cooling circuit (2) filled with a cooling medium which is liquefied upon cooling and containing a cryogenerator (3), a pump (6) and a pressure generator (7), providing a raised internal pressure relative to the cryogenerator. A semi-permeable element (20), e.g. a siphon, between the cryogenerator and the pressure generator allows passage of the liquid cooling medium but blocks the gaseous cooling medium.

Description

The invention relates to a device to cool down a component with a closed cooling circuit, which with a cooling down from a gaseous into a liquid State passing coolant filled and is a cryogenerator for cooling the coolant, a pump and pressure generating means to create an opposite the cryogenerator Has internal pressure.

Such a device is from the in CP613, Advances in Cryogenic Engineering: Proceedings of the Cryogenic Engineering Conference, Vol.47, 2002, pp. 473-480 Post "1 ATM Subcooled Liquid Nitrogen Cryogenic System with GM Refrigerator for a HTS Power Transformer "of the Authors S. Yoshida et al. already known. The device known there has a first cryostat with a cold room for receiving a superconducting transformer. The cold room is included liquid Filled with nitrogen. To increase of the pressure in the cold room is this over a control valve connected to a pressurized gas cylinder, the gaseous nitrogen contains. There is also a second cryostat with liquid nitrogen filled refrigerator intended. In the cold room are cooling units as well as a pump. Frozen nitrogen is pumped through a supply line in the cold room pumped the superconducting transformer, with heating nitrogen over a Derivation is fed back to the refrigerator.

The previously known device is liable the disadvantage is that the pump is only for pumping liquid nitrogen is designed and for this reason in a liquid nitrogen filled cryostat to be ordered. The additional however, the second cryostat is extensive. In addition, before commissioning the cold room with externally cooled liquid Filled with nitrogen become. Subsequently the pump pumps the liquid Nitrogen from the cold room in the previously unfilled cold room of the transformer. In this way, the sensitive superconducting Transformer suddenly to the temperature of the liquid nitrogen cooled. Such a sudden cooling can however lead to mechanical stresses on the component to be cooled, which damage to the Component or even its destruction in the wake.

According to the state of the art Pumps known to be both liquid as well as gaseous Pump nitrogen. It would be therefore a device with such a pump and with a cooling unit conceivable that the coolant is at room temperature gradually in the device cooling down, until a sufficient amount of the coolant condenses and that to be cooled Component completely in a liquid Phase is arranged. Pumps that are capable of both gaseous and also liquid coolant to circulate, are expensive, however. About that beyond is their funding with gaseous coolant only slight, so that long cooling times are accepted would.

The object of the invention is a To provide device of the type mentioned, the one gradually and quick at the same time Cooling one Component allowed.

The invention solves this problem in that a semipermeable les between the cryogenerator and the pressure generating means Element is provided that allows the passage of liquid coolant for gaseous coolant however impermeable is.

According to the invention, the semipermeable Elements creates a pressure difference in the device that together with the pump or alone, without the support of the pump circulate of the gaseous refrigerant effected in the device. The pressure difference arises on both sides of the semi-permeable element by liquefying the gaseous coolant in the cryogenerator and the evaporation of the liquid coolant in the pressure generating means, on the other hand. During the upheaval the gaseous coolant slowly cooled by the cryogenerator until in an operating state the revolution of the refrigerant taken over by the pump with a sufficiently high delivery rate becomes. The semi-permeable element is used to build up the pressure difference between the cryogenerator and the pressure generating means. It essentially forces the gaseous coolant to flow through of the cooling circuit in a direction in which it is almost bridged by the cooling circuit. Enabled in the operating state the semipermeable element, on the other hand, is the mass transfer of the liquid coolant from the cryogenerator to the pressure generators. The semipermeable Element can be designed in any way within the scope of the invention.

However, the semipermeable element is advantageously a siphon. The siphon has a U-shaped knee section, in which a liquid phase of the coolant generated during cooling can settle. The knee section merges into an overflow on the side of the siphon facing the pressure generating means. If the liquid column in the legs of the U-shaped knee section exceeds the overflow, liquid coolant flows to the pressure generating means. Due to the liquid phase of the knee section, however, there is a substance transfer Port of the coolant essentially interrupted in the vapor phase.

It is advantageously used as a coolant Nitrogen used.

With an appropriate further development of the Invention is in the refrigeration cycle a phase separator for collecting liquid coolant is provided. The phase separator allows the liquid to be filtered out Proportion of the coolant, so that only gaseous coolant circulates in the device. On the remaining in the phase separator liquid can be used if necessary, for example in the operating state so that liquid Coolant, that exclusively circulated by the pump for cooling is used.

With an appropriate further development in this regard the phase separator has a collecting container which has a ending in the bottom area liquid line as well as a ending in the ceiling area Gas line to the cooling circuit is connected, with a check valve in the liquid line is provided. According to this Advantageous further development can take place after a certain start-up phase selected whether in the device is essentially vapor or liquid coolant circulated becomes. Is the shut-off valve of the liquid line closed, the liquid collects coolant in the collection container, being the gaseous Coolant over the in the ceiling area of the collecting container outflowing gas pipe its way through the cooling circuit continues. By opening the check valve is also the liquid phase of transport made possible by the cooling circuit, so because of the higher Density of liquid towards her Vapor phase through the pump essentially the liquid phase to provide the cooling effect is exploited. Of course it is also possible in the context of the invention that the gas line has a check valve, which after opening the check valve liquid line is closed so that the phase separator stops the transport of liquid coolants allowed gaseous coolant however holds back.

The pressure generating means expediently have a pressure vessel for collecting liquid coolant on, heating means arranged in the bottom region of the pressure vessel for vaporizing liquid coolant are provided. The evaporation of the coolant in the pressure vessel Pressure against the cryogenerator increased. Because of the closed design of the cooling circuit, this is semipermeable Element bridged by this, so that mass transport occurs in the gas phase. As a heating medium For example, an electric heating coil can be considered.

According to a related Further development are the pressure generating means via an Bottom area of the pressure vessel flowing liquid pipe as well as about a gas line on the cooling circuit opening in the upper region of the pressure vessel connected, being in the liquid line a check valve is arranged. According to this advantageous further development the pressure generating means have a filter property to choose from the phase circulated by the pressure generating means in the cooling circuit of the coolant on. When the shut-off valve is closed, the Liquid pressure fluid coolant collected, being gaseous Coolant over the in the upper area of the pressure vessel opens Gas line continues its way through the cooling circuit. After opening the The check valve also stands for the liquid phase of transport in the cooling circuit open. Of course it is possible within the scope of the invention, a Check valve should also be provided in the gas line.

Are advantageously in the gas line Additional heating means provided. The additional heating means can Gas on an over the boiling temperature are heated. High temperature differences in the one to be cooled Can set up can be avoided in this way.

According to a preferred further development of the invention comprises the cooling circuit one to hold the one to be cooled Component provided cold room. This is what is to be cooled Component, for example, a superconducting transformer, which in the vacuum-insulated cold room the device is arranged. After inserting the component to be cooled in the cold room can with the cooling of the refrigerant be started by activating the cryogenerator, the component gradually to the temperature of the liquid Phase of the coolant is cooled.

Further expedient configurations and advantages The invention is the subject of the following description of a Embodiment of the Invention with reference to the figure, wherein

1 shows an embodiment of a device according to the invention in a schematic sectional view.

Figure 1 shows an embodiment of a device according to the invention 1 schematically in a sectional view. The device shown 1 has a cooling circuit 2 on that via a cryogenerator 3 and a cold room 4 has a superconducting component 5 , such as a superconducting transformer. For transporting the coolant in the cooling circuit 2 is a pump 6 intended.

The pump 6 of the exemplary embodiment shown is able to transport both liquid and gaseous coolant, which in this case is realized by nitrogen. Due to the low density of the gaseous nitrogen, the delivery rate of the pump 6 based on gaseous However, nitrogen is low compared to its liquid phase.

To the delivery rate of the pump 6 increase in gaseous nitrogen, the cooling circuit 2 Pressure generating means 7 on that a pressure vessel 8th one in the ceiling area of the pressure vessel 8th outflowing gas pipe 9 as well as a liquid line opening into the floor area 10 include. In the gas pipe 9 and the liquid line 10 are check valves 11 arranged, which interrupt the mass transport in a blocking position or are permeable to both gaseous and liquid nitrogen in an open position. The pressure generating means 7 are via a heat insulated pipe 12 with the cold room 4 of the superconducting component 5 connected.

The cooling circuit 2 also has a collecting separator 13 on the also a heat-insulated pipe 14 to the cold room 4 connected. The collective separator 13 includes a collection container 15 a gas pipe opening into its ceiling area 16 as well as a liquid line opening into its bottom area 17 , The gas pipe 16 and the liquid line 17 are each with check valves 11 provided, which either allow a mass transfer or interrupt it. A pipeline 18 serves to connect the collective separator 13 to the pump 6 , whereas the pump 6 via a heat insulated pipe 19 with the cryogenerator 3 connected is.

Between the cryogenerator 3 and the pressure generating means 7 is a semi-permeable element 20 provided that is realized in the embodiment shown as a siphon. The siphon 20 has a U-shaped knee section 21 as well as an overflow 22 on, the overflow 22 in the ceiling area of the pressure vessel 8th empties.

For cooling the device, for example at room temperature 1 first becomes the cryogenerator 3 put into operation. The cooling circuit filled with gaseous nitrogen 2 is slowly cooled down. The pump takes care of this 6 for a slow circulation of the gaseous nitrogen. The siphon 20 is conveniently in the immediate vicinity of the cryogenerator 3 arranged because the condensation of nitrogen occurs preferentially in its immediate vicinity. The liquid nitrogen is due to gravity in the U-shaped knee section 21 collected until the height of the liquid column in his thigh overflow 22 exceeds and liquid nitrogen in the pressure vessel 8th arrives.

In the pressure vessel 8th the liquid nitrogen collects. Its level increases as the cooling time progresses. To generate pressure is in the bottom area of the pressure vessel 8th a heating coil 23 intended. By feeding a heating current, liquid nitrogen becomes in the pressure vessel 8th from the heating coil 23 transferred into the gaseous phase and the pressure in the pressure vessel 8th towards the cryogenerator 3 elevated. Because of the in the knee section 21 liquid, the gaseous nitrogen does not get directly into the cryogenerator 3 , but is via the piping 12 . 14 . 16 . 18 and 19 into the cryogenerator 3 led, the already cooled gaseous coolant the cold room 4 , the phase separator 13 as well as the pump 6 interspersed. In the gas pipe 9 the pressure generating means 7 is in front of the check valve 11 an additional heating medium 24 provided which can heat the gaseous nitrogen to a temperature above the boiling temperature.

The shut-off valve is at the beginning of the cooling process 11 the liquid line 17 closed, so that only vapor nitrogen via the gas line 16 with the valve open 11 and over the pipes 18 and 19 to the cryogenerator 3 to be led.

Having enough liquid nitrogen in the pressure vessel 8th as well as the collection container 15 is provided, the gas line 9 the pressure generating means 7 and the gas pipe 16 of the phase separator 13 by means of the check valves 11 closed. At the same time, the check valves 11 the liquid line 10 or the liquid line 17 opened so that essentially liquid nitrogen through the pump 6 is promoted.

With the help of the device 1 can thus be the superconducting component 5 be gradually cooled. In addition, the circulation of gaseous nitrogen is essentially caused by the pressure difference, so that the cooling time is reduced. The mass flow running in the device to be cooled can thereby be achieved by means of the heating power of the heating coil 23 be regulated.

In a different embodiment, the circulation of the gaseous nitrogen is effected solely by the pressure difference caused by the vaporization of the liquid nitrogen in the pressure vessel 8th and liquefying the gaseous nitrogen in the cryogenerator 3 arises. The pump, on the other hand, is only suitable for circulating liquid nitrogen. In addition to a short cooling time, high costs for the pump can also be avoided in this exemplary embodiment of the invention.

Claims (8)

Contraption ( 1 ) for cooling a component ( 5 ) with a closed cooling circuit ( 2 ) which is filled with a coolant which changes from a gaseous to a liquid state on cooling and which has a cryogenerator ( 3 ) to cool the coolant, a pump ( 6 ) as well as pressure generating means ( 7 ) to generate a compared to the cryogenerator ( 3 ) has increased internal pressure, characterized in that between the cryogenerator ( 3 ) and the pressure generating means ( 7 ) a semi-permeable element ( 20 ) is provided, that allows the passage of liquid coolant, but is impermeable to gaseous coolant. Contraption ( 1 ) according to claim 1, characterized in that the semipermeable element is a siphon ( 20 ) is. Contraption ( 1 ) according to claim 1 or 2, characterized in that in the cooling circuit ( 2 ) a phase separator ( 13 ) is provided for collecting liquid coolant. Contraption ( 1 ) according to claim 3, characterized in that the phase separator ( 13 ) a collection container ( 15 ), which via a liquid line opening into the bottom area ( 17 ) as well as via a gas line leading into the ceiling area ( 16 ) to the cooling circuit ( 2 ) is connected, whereby in the liquid line ( 17 ) a shut-off valve ( 11 ) is provided. Contraption ( 1 ) according to one of the preceding claims, characterized in that the pressure generating means ( 7 ) a pressure vessel ( 8th ) for collecting liquid coolant, in the bottom area of the pressure vessel ( 8th ) arranged heating means ( 23 ) are provided for evaporating liquid coolant. Contraption ( 1 ) according to claim 5, characterized in that the pressure generating means ( 7 ) in the bottom area of the pressure vessel ( 8th ) flowing liquid line ( 10 ) and one in the upper area of the pressure vessel ( 8th ) opening gas pipe ( 9 ) to the cooling circuit ( 2 ) are connected, whereby in the liquid line ( 10 ) a shut-off valve ( 11 ) is arranged. Contraption ( 1 ) according to claim 6, characterized in that in the gas line ( 9 ) Additional heating medium ( 24 ) are provided. Contraption ( 1 ) according to one of the preceding claims, characterized in that the cooling circuit ( 2 ) one to hold the component to be cooled ( 5 ) provided cold room ( 4 ) includes.