DE10035859A1 - AC- bushing, e.g. for equipment containing a superconductor in a cryostat, has two branches with cooled bushing conductors and Peltier element formed by section of bushing conductor - Google Patents

Abstract

The AC feed-through between a power source in a room temperature environment and a device in a low-temperature environment, which AC feed-through has two branches with cooled feed-through conductors (31) leading from the room temperature environment to the low-temperature environment. The feed-through conductors (31) are cooled by at least one Peltier element (33) which is in heat-conducting contact with the feed-through conductor (31) or which is formed by at least a section of the feed-through conductor. According to a preferred embodiment, there is at least one Peltier element (33) which is in heat-conducting contact with the lead-through conductor (31) and which is fed by a supply energy tapped through the lead-through.

Description

Technical field

The invention relates to an alternating current feedthrough between a current source in a room temperature environment and a device in a low temperature Surroundings. It relates in particular to an AC implementation with the in The preamble of claim 1 features specified.

State of the art

In the case of cooled devices, for example a superconductor in a cryostat exhibit the problem of heat loss through current feedthroughs. Gas-cooled bushings are often used to reduce these heat losses used. This is particularly useful for devices that have a bathroom a liquid cooling medium such as helium is present. All in the cold area losses, i.e. thermal losses of the cryostat, losses in the Superconductors, heat input via leads etc. cause part of the Cooling medium evaporates. The heat capacity of the vaporized, cold gas used to cool the bushings. In the case of liquid nitrogen however, due to the relatively large enthalpy of vaporization of nitrogen  resulting gas quantity and thus the cooling capacity of the gas is relatively low. The Adding additional cooling gases or liquids would be cumbersome to implement and therefore uneconomical.

In document EP-A-0 843 323 it was recently proposed that Cooling bushings of a superconducting DC coil by the current-carrying feedthrough conductor partially made of an n-doped semiconductor current-carrying bushing is made of a p-doped semiconductor. The Peltier effect then leads to cooling of the coil-side ends of the Conductor conductor and a corresponding heating of the Current source-side ends of the current feed-through conductor. Such a facility is based on the fact that the current only flows in one direction and therefore comes for AC (AC) applications out of the question.

Presentation of the invention

The invention is therefore based on the object AC feedthrough to a cooled device is available too ask what disadvantages of bushings according to the prior art overcomes and which works particularly effectively when at the cooling of the device does not result in large amounts of cooling gas.

This object is achieved by the invention as set out in the claims is defined.

The invention is essentially characterized in that for cooling the Implementation leader is a Peltier element, which by at least  a part of the feed-through conductor is formed or which in heat-conducting Contact to the implementation manager. This solution has the advantage that in addition to the Peltier element, only a unidirectional power supply Current flow must be present. It is therefore simple and inexpensive and without large or difficult to achieve due to the geometries used Installations can be implemented.

In a preferred embodiment, the Peltier element is fed directly from the device power supply. It follows that the Peltier element can work at the potential of the leadthrough leader and none electrical insulation problems arise. The thermal coupling of the Elements to the implementation manager therefore pose no problems, even if the Implementation is a high voltage bushing. The can continue Energy transfer from the power source to the feed of the Peltier element be designed so that the power supply to the Peltier element essentially proportional to the current in the feedthrough conductor and thus to the load current of the Device is. No separate regulation of the Peltier elements is then necessary, since the cooling output automatically corresponds to the current output of the cooled Adapts device. So you get a self-regulating, actively cooled Execution.

Brief description of the drawings

In the following, the invention will be described with reference to exemplary embodiments which are shown in the accompanying drawings are shown schematically, explained in more detail. In the The drawings show:  

Fig. 1 is a schematic representation of a first embodiment of the invention, are formed in the Peltier elements by portions of the through-conductor,

Fig. 2 and 3 a schematic illustration of further exemplary embodiments by means of metal conductors which are in thermal contact with Peltier elements, and

FIGS. 4 and 5 each show a schematic representation of a direct and an inductive pick-off of electrical energy to the bushing conductor for the supply of Peltier elements.

Ways of Carrying Out the Invention

In Fig. 1 a to a temperature T ₀ and cooled example. Located in a cryostat device 1 is shown, eg., A superconducting coil, a superconducting material containing current limiter or any other chilled device. The device must be supplied with alternating current. A current source 3 is in an environment with room temperature T ₁ . Two branches 5 , 7 of a current lead-through serve to supply electrical energy in the form of alternating current from the current source to the device. Each branch 5 , 7 is subdivided into two strands of feed-through conductors 9 , 11 and 13 , 15 , respectively, a first strand 9 , 13 each being a section made of an n-doped semiconductor and a second strand 11 , 15 being a p -doped semiconductor manufactured section. Suitable semiconductor materials are doped BiTe, low-temperature side possibly doped Si or Ge or other doped semiconductors known to the person skilled in the art. In each strand, an element 17 , 19 , 21 , 23 with a diode characteristic, namely a diode, is attached in series with the semiconductor — on the low temperature side or, as in the example shown, on the room temperature side. The elements 17 , 21 of the first strands allow a current to flow from the current source to the device and block in the direction from the device to the current source. The elements 19 , 23 of the second strands, on the other hand, allow current to flow from the device to the power source and block in the opposite direction. This ensures that the current is conducted over the strand with the n-doped semiconductor during the half-wave, in which the current flows from the room temperature side to the cooled device, and during the other half-wave over the strand with the p-doped semiconductor , Thus, the current increases in either case, the way room temperature side, metallic supply conductor 25 - n-type semiconductor 9 and 13 - low temperature side, metallic and / or superconducting supply conductors 27 - Device 1 - Low-temperature side, metallic and / or superconducting supply conductors 27 - p-type semiconductor 11 or 15 - metallic supply conductor 25 on the room temperature side. The Peltier effect therefore removes heat from the low-temperature side transitions between the metallic and / or superconducting supply lines 27 and the semiconductors, while the room temperature-side transitions between the metallic supply lines 25 and the semiconductors are warmed up. The bushings formed at least in sections by semiconductors therefore serve themselves as Peltier elements, their energy supply, ie supply, is designed by the current source, the Peltier element supply current is equal to the load current and consequently strictly proportional to it.

A second exemplary embodiment, which is shown in FIG. 2, provides that the current leadthrough is made from any conductor material, for example from copper or brass or from another metal, a combination of metals and / or possibly semiconductors. In FIG. 2, as well as in Fig. 3, a single branch is illustrated only 31 of the bushing. The feed-through conductor 31 is in thermal contact with one or more Peltier elements 33 , through which a supply current flows in the order n-semiconductor 33 a - metal 33 b - p-semiconductor 33 c. The contacts between the semiconductors 33 a, 33 c and the metal 33 b are thereby cooled. The thermal contact of the Peltier elements 33 with the feed-through conductor 31 is formed by a heat-conducting contact body 35 or a contact film, or possibly only one contact surface. The contact body 35 , the contact film or the contact surface are of course arranged at the cooled end of the Peltier element, that is, in the example shown on the metal 33 b. The Peltier elements 33 are supplied with electrical energy by direct current supply means 37 . In the example shown, a total of three Peltier elements 33 are present, which are connected in series with one another. However, just a single or any number of Peltier elements can also be provided, and the Peltier elements can also be connected partially or completely in parallel, depending on the combination of available supply voltage and electrical resistance of the elements.

The embodiment of FIG. 3 also provides a current feed-through conductor made of any conductor material. A Peltier element now has a section 47 made of n-semiconductors running along the feed-through conductor 41 and in thermal contact with the latter via a contact body 45 , a contact film or a contact surface, a metallic section 49 running on the low-temperature side and a section 51 made of p-semiconductors. The section of p-type semiconductors is also in thermal contact with the feed-through conductor 41 . Sections 47 , 51 consist of a sequence of different, for example differently doped materials or a material with a concentration gradient, so that there is a cooling effect over different areas of sections 47 , 51 .

The Peltier elements of FIGS. 2 and 3 can be supplied via an external power supply, which is designed, for example, as a conventional direct current source that can be regulated by hand and / or controlled by control means. However, the Peltier elements can also be supplied in such a way that the energy supply of the feed means is provided by the current source 3 , that is to say there are energy transmission means for transmitting energy from the current source to the feed means of the Peltier elements. 4 and 5 will now be still illustrated by the Fig., As can happen.

The supply means according to Fig. 4 consist of a direct tap of the drop across the feedthrough conductor 61 voltage. This voltage is rectified by a rectifier 63 and applied to one or more Peltier elements according to FIG. 2 or 3.

As shown in FIG. 5, the feed means can also tap the supply energy inductively. For this purpose, for example, the feed line 73 to the lead-through conductor 71 or possibly the lead-through conductor 71 itself or a section 75 of the lead-through running on the low temperature side has a section in the form of a loop 77 or a coil. Another coil 81 attached near the loop 77 serves as a tapping means. The voltage generated by induction across the winding is rectified by a rectifier 83 and applied to one or more Peltier elements according to FIG. 2 or 3.

The feed means according to FIGS. 4 and 5 have the property that the current coming from you to feed the Peltier elements is essentially proportional to the current that flows through the bushing. Only effects that result from different heating of the different materials or non-linearities of the rectifiers can cause minor deviations from this proportionality.

It should also be mentioned that the operations described above are natural are by no means the only embodiments of the invention, but still in can be changed in several ways. The supply voltage for the Peltier For example, elements can also be connected directly to the voltage source and parallel to the cooled one Device tapped and rectified. Of course, further are Combinations of the arrangements described above are possible.  

LIST OF REFERENCE NUMBERS

1

contraption

3

power source
5, 7, branches of the current feedthrough

9

.

11

.

13

.

15

Strands of lead-through conductors

17

.

19

.

21

.

23

Elements (diodes)

25

metallic feeder

27

low-temperature feeder

31

Through conductors

33

Peltier elements

33

a n semiconductor

33

b metal

33

c p semiconductors

35

Contact body

37

DC power supply means

41

Through conductors

45

Contact body

47

Section made of n-semiconductors

49

metallic section

51

Section from p-semiconductors

61

Through conductors

63

rectifier

71

Through conductors

73

supply conductors

75

section running on the low temperature side

77

loop

81

Kitchen sink

83

rectifier

Claims (8)

1. AC feed-through between a power source ( 3 ) in a room temperature environment and device ( 1 ) in a low-temperature environment, which AC feed-through two branches ( 5 , 7 ) with cooled, from the room temperature environment to the low-temperature environment leading leadthrough conductors ( 9 , 11 , 13 , 15 , 31 , 41 , 51 , 61 , 71 ), characterized in that it contains at least one Peltier element. 2. AC feedthrough according to claim 1, characterized in that a Peltier element is formed by at least a portion of a feedthrough conductor ( 9 , 11 , 13 , 15 ). 3. AC implementation according to claim 2, characterized in that each branch (p. 7) is divided into two parallel strands ( 9 , 11 , 13 , 15 ), the first strand ( 9 , 13 ) being one of an n -doped semiconductor manufactured section and the second strand ( 11 , 15 ) made of a p-doped semiconductor manufactured section, and the first strand further has an element ( 17 , 21 ) with diode characteristic connected in series with the semiconductor section, which allows a current flow from the current source ( 3 ) to the device ( 1 ), and that the second strand further has an element ( 19 , 23 ) with diode characteristic connected in series with the semiconductor, which allows a current flow from the device ( 1 ) to Power source ( 3 ) allowed 4. AC bushing according to claim 1, characterized by a Peltier element with feed means, which Peltier element is in heat-conducting contact with a feed-through conductor ( 31 , 41 , 51 , 61 , 71 ). 5. AC implementation according to claim 4, characterized by energy transmission means for transmitting energy from the power source ( 3 ) to the feed means of the Peltier element. 6. AC implementation according to claim 5, characterized in that the feed means via means for tapping supply energy via implementation as well as a means of rectification. 7. AC implementation according to claim 6, characterized in that the means for tapping the supply energy make direct contact the power line on the room temperature side and on the low temperature Side of a lead-through for tapping the one above the Feedthrough conductor have falling voltage. 8. AC feedthrough according to claim 6, characterized in that the feed has at least one loop ( 77 ) and that the means for tapping the supply energy have a coil ( 81 ) which is positioned so that when there is an alternating current flow through the alternating current Performing a voltage is induced across the coil ( 81 ).