DE1401524B1 - Gas cooling machine, in particular small gas cooling machine - Google Patents

Description

The invention relates to a gas refrigeration machine, in particular a very small gas refrigeration machine, which after the modified Stirling cycle works, each with a compression and expansion cylinder, the are arranged parallel to each other and in each of which one is connected to a piston rod Compression piston or expansion piston is displaceable, as well as with one between the cylinders switched on regenerator and with heat exchangers at the end of the cylinder, the two being Piston rods are driven by the same crankshaft.

In a known refrigeration machine of this type, the regenerator is spatially between the two cylinders arranged; the heat exchangers are located behind the cylinders and next to the regenerator. This Construction requires a large amount of space. The distance between the two cylinders must be at least the width of the regenerator. Such a machine cannot be manufactured as a miniature refrigeration machine.

The invention is based on the object of avoiding these disadvantages and having a refrigerating machine to create small dimensions. Such, motor-driven refrigerating machines with two small pistons are used to generate refrigeration for electronic and similar applications. There is a great need, particularly in the fields of electronics and aerospace engineering small chillers that generate temperatures of around 100 ° K or below.

According to the invention this is achieved in that the regenerator is at the outer end of the compression cylinder arranged and only connected to the expansion cylinder via a short line is, at the head of which is connected to the connecting line for forwarding the useful cold A heat exchanger equipped end piece made of highly thermally conductive material, while a heat exchanger serving to dissipate heat in the head of the compression cylinder itself is arranged.

Such a refrigeration machine can have very small dimensions and a very low weight produce. Together with an electric motor, it can form a single whole. An outer one No gas source or compressor is required. The machine does not use any valves or expansion ports or constrictions so that blockages and other operational problems are avoided are. As a single unit, it is able to maintain temperatures down to -180 ° C.

Due to the special arrangement of the heat exchangers in the refrigeration machine after In addition, an increase in heat dissipation and large flow cross-sections and so that a good level of efficiency is achieved.

The heat exchangers are preferably designed as perforated plates.

An extremely small three-dimensional shape is obtained if, according to a further development of the invention, the crankshaft is mounted in a housing, which at the same time forms the cylinder and directly to the crankshaft connecting the driving motor or its transmission.

Preferably, a flexible line made of material with good cold conductivity is attached to the cooled end piece connected.

The invention will now be described in greater detail using an exemplary embodiment shown in the drawing explained.

F i g. 1 illustrates the four basic stages of operation of the modified Stirling cycle;

F i g. Fig. 2 is a theoretical indicator diagram thereof;

F i g. 3 schematically shows an indicator diagram as it is actually obtained;
ίο F i g. 4 shows, partly as a sectional view, a refrigeration machine according to the invention.

The modified Stirling cycle as shown in FIG. 1 is illustrated schematically given representation of the individual stages, has an indicator diagram of the in F i g. 2 and 3 respectively. The ideal cycle comprises the following stages, where V is the volume, P is the pressure and T is the temperature and the index c refers to the compression space and ao the index E refers to the expansion space:

1. Isothermal compression of the gas in V _c while V _E is zero. The heat of compression is given off at the head of the compressor at the temperature T _c ; ideally the

^a5 process can be considered isothermal. In the indicator diagram according to FIG. 2, this stage runs from A to B according to the isothermal curve at temperature T _c.

2. Gas transport at constant volume from V _c to V _E and volume reduction in V _c .

During this process, the gas gives off heat by passing through a regenerator, so that it reaches V _E at temperature T _n.

3. Isothermal expansion of the gas in V _E with V _c as zero. The cold generated by the expansion results in heat which is absorbed in the expander at the temperature T ₁₁ , so that in the ideal case the process can be regarded as isothermal. In the indicator diagram, this stage runs as an isothermal curve at temperature T _E from point C to point D.

4. Gas transfer at constant volume from V _E to V _c . At this stage, which is shown in the diagram by the isochoric path from point D to

is shown at item-4, no work is done; this is achieved by a simultaneous and uniform decrease in V _E and an increase in V _c . During this process, the gas decreases as it passes through the

_C regenerator stored there during the stage 2 heat to and arrives at the temperature T _c by V.

The invention makes use of this Stirling circle process in a correspondingly modified form. As can be seen from Fig. 4, the refrigerator has According to the invention, an electric motor 1, the shaft of which is connected to a reduction gear 2. The output shaft 3 revolving at reduced speed of this transmission is with the one End of the crankshaft 4 connected, the other end 5 rests in a bearing 6 which is in a cylindrical, Airtight housing 7 is arranged, the bottom 8 of which is attached to the gear housing 2. the Cranks 9 and 10 on the shaft 4 are arranged so that the piston rods 11 and 12, which are at 9 and 10, respectively are stored, go back and forth almost harmoniously with a phase angle of about 90 °.

Claims (4)

From the side wall of the housing 7, a flow through the regenerator 16 projects its heat to compression cylinder 13, in which a compression from the metal wool and then flows through the line sion piston 14, which is at the end of the piston rod 11 19 over the cooling end 20 and the perforated plate is attached, slides. The from the piston 14 grains 21 into the cylinder 17, in which the expansion-compressed gas runs over a piston 18 already formed as a perforated plate 5 on its inward stroke and is located in the head of the compression cylinder. The gas is thus transported with an approximately constant heat exchanger 15 and a volume between the two cylinders. Regenerator 16, which is located at the outer end of the cylinder (stage II in FIG. 1 and path from B to C in FIG ). 13 is arranged. The regenerator 16 is when the compression piston 14 is stationary on Metal network, for example metal wool high io, remains at the end of its stroke, the expan heat capacity begins, filled, which serves to move the sion piston 18 inward, so that the Compression heat from the compression heat absorbed by the expansion cylinder 17 cylinder 13 to absorb leaving gas. and the end 20 is cooled (stage III in FIG. 1 It is also at right angles from the side and path from C to D in Fig. 2). Then, when the wall of the housing 7 and immediately above the 15 the compression piston 14 runs inwards, the cylinder 13 and parallel to this an expansion piston moves the expansion piston 18 outwards, and the cylinder 17 in front, in v / which one at the end of the Piston gas flows from the cylinder 20 through the conduit rod 12 attached expansion piston 18 and 19 and the regenerator 16, where it absorbs heat, runs here. The gas leaving the regenerator 16 as it enters the heat exchanger 21 and into the passes through a short line 19 which enters the end 20 of the cylinder 17. The expansion piston 18 leads to the expansion cylinder 17. The gas is already on its inward stroke and flows on its way to the cylinder 17 - the gas is transported between the cylinders with an almost constant volume of heat, if designed as a perforated plate (stage IV in exchanger 21, the connects to line 19. Fig. 1 and route from D to A in Fig. 2).
At the head of the cylinder 17 there is to continue 25. If this cycle is repeated, the line of useful cold is a with the heat exchanger end piece 22 and the line 24 is cooled. The last 21-provided terminating piece 22 made of very hotter material can be arranged in the immediate vicinity of the conductive metal, on which a screw-cooling device is used. The cap 23 has a flexible metal line 24 to the motor 1 can be closed at a variable speed, which is guided to the object 30 to be cooled in order to adjust the cooling temperature. Both cylinders 13 and 17 are equipped with cooling enable. ribs 25 provided. The end piece 22 of the cylinder with compression and expansion cylinders of ders 17 and the cooled line 24 and also the same volume and a bore of 12.7 mm Regenerators 16 have insulation 26. (Va inches) and a stroke of also 12.7 mm The housing 7 is equipped with a filler neck 27 to 35 (V2 inches) is the maximum power, soft the introduction of the working gas. A needle machine on the shaft requires about 75 watts. A valve 28 serves as the closure of the nozzle 27. Such a refrigeration machine according to the invention works cable 29 and a plug 30 are used for connection at a cooling head temperature between 30 and the motor 1 with an (not shown) electrical - 180 ⁰ C. At - 180 ⁰ C is the cooling capacity see energy source. 40 of the machine 1 watt. In this training is In operation, the machine with the working gas, the effective dead space is less than 0.25 times z. B. hydrogen or helium, at a pressure of the effective volume of the hotter cylinder, up to 30 at via the nozzle 27 and the valve 28 while the cooling efficiency is 93% or even filled. Then the plug is connected to a suitable more, provided that the head of the expan power source is connected to the engine 1 in 45 sion cylinders to provide the gas passages and ducts, the rotation, the through the reduction gear 2 regenerator and the upper part of the Expansion drives the crankshaft 4. This in turn allows the cylinders to be adequately isolated.
Pistons 14 and 18 in cylinders 13 and 17 - The housing and cylinders can be made of thin and run here. Both cylinders are roughly made of stainless steel, while the same volume; the main body of each piston 50, cooling end 20 and flexible conduit 24 made of copper is at crankcase temperature. Anyone can pass. For the pack in the regenerator 16 Piston has piston rings and oil seal rings. is preferably lead-plated copper wool The outermost part 31 of the expansion piston 18 is used. The application of light metals such as a thermally insulated extension with some play- aluminum, magnesium and / or beryllium as well space between itself and the wall of the cylinder 17. 55 their alloys, however, is not excluded. When the compression piston 14 is moving outwards begins to the gas in the cylinder 13 claims: To compress, the expansion piston 18 is stationary at the extreme end of its stroke 1. Gas refrigeration machine, in particular ultra-small gas (stage I in FIG. 1 and path from A to B in the 60 refrigeration machine, which according to the modified diagram of FIG ). When the compression Stirling cycle is working, each with a com piston 14 moving further outward, begins compression and expansion cylinders, which move parallel to the expansion piston 18 inward, are arranged to one another and in each of which one so that the compressed gas Pressure piston or expansion piston flows out of cylinder 13, each with a piston rod, through the gas passages in perforated plate 65, whereby maximum heat transfer can be shifted, as well as with a regenerator connected between the two with minimal pressure loss and minimal dead cylinder and with space is achieved. The heated gas releases the heat exchangers at the end of the cylinder, where- when the two piston rods are driven by the same crankshaft, thereby characterized in that the regenerator (16) is at the outer end of the compression cylinder (13) and only connected to the expansion cylinder (17) via a short line (19) is connected, at the head of which is connected to the forwarding of useful cold with one to the Connecting line adjoining heat exchanger (21) provided terminating piece (22) highly thermally conductive material is located, while a heat exchanger serving to dissipate heat (15) is arranged in the head of the compression cylinder itself. 2. Gas refrigerator according to claim 1, characterized in that the heat exchanger (15 and 21) are designed as perforated plates. 3. Gas refrigeration machine according to claim 1 or 2, characterized in that the crankshaft (4) is mounted in a housing (7) which at the same time forms the cylinders (13, 17) and directly on a motor (1) or its gear (2) driving the crankshaft is connected. 4. Gas refrigeration machine according to one of the preceding claims, characterized in that that to the cooled end piece (22) a flexible line (24) made of good cold conductive Material is connected. 1 sheet of drawings