DE3424916A1 - Refrigerating installation - Google Patents

Abstract

In a refrigerating installation with a horizontal liquefier (16), a heat exchanger for undercooling and overheating the refrigerant as well as a refrigerant separator, the heat exchanger and the refrigerant separator comprise a common annular space (62) which directly surrounds the liquefier casing (20). In this installation, the annular space is connected in its lower region to the evaporator (16) and in its upper region to the compressor (10), the liquefier (16) having in its lower region a collecting space (54), bordering the annular space (62), for the liquefied refrigerant. As a result, the number of the individual elements required for the construction of a refrigerating installation is reduced at the same time as the function is improved. <IMAGE>

Description

The invention relates to a refrigeration system each with ' at least one evaporator, a horizontal condenser with a jacket exposed to refrigerant, in particular a tubular boiler condenser, a heat exchanger for the subcooling and overheating of the refrigerant as well as a refrigerant separator.

From the general prior art it is known in such a refrigeration system, in the refrigerant circuit, starting from the compressor and viewed in the direction of flow of the refrigerant, a condenser, a refrigerant subcooler, an expansion valve, an evaporator, the refrigerant separator and a refrigerant superheater to insert. The refrigerant subcooler and superheater consists of a surface heat exchanger, one side into the connection from the condenser to the expansion valve and the other

it

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July 4th, 1984 ζ 3424916

Page is switched on in the connection from the evaporator to the compressor, so that one in the refrigerant circuit internal heat exchange takes place. The disadvantage of such a system is mainly to be seen in the fact that for their Construction of a large number of separate devices (condenser, heat exchanger, evaporator and refrigerant separator) is required, the accommodation of a large space and / or space requirements and expensive Requires mounting frame and / or supporting structures. Even if the devices are grouped together are, the disadvantages of a large space requirement and complex supporting structures remain.

The invention is therefore based on the object of specifying a refrigeration system of the type mentioned, whose Space requirements for the apparatus, in particular for condensers, heat exchangers and liquid separators, in a simple manner Is reduced in a manner and therefore inexpensively. In addition, the possibility should be given that To be able to combine apparatus into a compact unit with little space requirement. Last but not least should the proper functioning of the equipment can at least be maintained or even improved.

This object is now achieved according to the invention in that the heat exchanger for subcooling and overheating and the refrigerant separator have a common Include annular space that immediately surrounds the jacket of the condenser and that in the lower area to the evaporator, in the upper area, however, is connected to the compressor, with the condenser in the lower area has a collecting space adjoining the annular space for the liquefied refrigerant.

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July 4, 1984 3.42-916

The heat exchanger and the refrigerant separator thus consist of a common annular space which borders on the jacket of the condenser, which is acted upon by refrigerant. Since the connection line to the evaporator is in the deepest area of the annulus, the suction line of the compressor
but connected in the highest area of the annulus
there is a long way to go for the deposition of
liquid refrigerant, e.g. B. in the form of drops, that

is carried along by the refrigerant vapor. The deposition

is further improved by the upward flow of the refrigerant vapor, since the force of gravity,
which acts on the refrigerant droplets carried along,
promotes their departure. Also will the deposition

still promoted by the fact that the flow cross-section of the Annular gap is designed such that from the refrigerant inlet to the refrigerant outlet approximately constant Flow velocity prevails in the annulus. After all, the refrigerant

Centrifugal force acting on droplets when flowing through of the annular space contributes to the separation of refrigerant droplets.

Since the refrigerant coming from the evaporator and at most slightly overheated, after entering the annular space, directly exchanges heat with the collecting space for the liquefied refrigerant adjoining there, there is a
at least sufficient subcooling of the liquefied
Refrigerant before it is discharged to the expansion valve
guaranteed. Since, as the refrigerant vapor continues to flow upwards in the annular space, it exchanges heat with the hot refrigerant vapor in the condenser

Mp.no. 613/84 July 4, 1984

is sufficient overheating of the upward flowing Guaranteed refrigerant vapor, so that the compressor only sucks in dry refrigerant vapor from the annular space. This rules out liquid hammers, and a dilution of the lubricating oil is avoided as well as a Reduction in the degree of delivery of the compressor as a result of post-evaporation switched off.

By combining the heat exchanger and the refrigerant separator into one common, the condenser surrounding annular space thus not only results in the desired reduction in the construction of a Refrigeration system required individual elements with the advantage of a small space and / or space requirement, but in addition, the advantage of improved refrigerant separation with simultaneous refrigerant subcooling and refrigerant overheating. There are thus the demands to be made on a refrigeration system compact design with undiminished good and operationally reliable function fully fulfilled.

An advantageous development of the invention can consist in that the annular space forms the jacket of the condenser surrounds at least approximately concentrically and is released in the direction of the longitudinal axis of the condenser the condenser connections largely across the whole Length of the sheath extends. This simplifies the structure and the annulus at the same time provided with sufficient flow cross-section. The flow cross section is advantageously chosen so that a flow velocity in the annulus that promotes the excretion of entrained liquid droplets of the refrigerant vapor.

Mp.no. 613/84 July 4, 1984

In order to achieve an even supply of the refrigerant vapor to the annulus and to ensure a good heat exchange To achieve promotional loading of the refrigerant collecting space, it is recommended that the annular space in the deepest area at least one, preferably several evaporator connections arranged axially one behind the other which are aligned approximately in the radial direction on the jacket of the condenser.

To the liquid refrigerant accumulating in the annulus to be able to discharge in a simple manner, it is favorable that at the periphery of the annular space, seen in cross section, on both sides of the evaporator connection or the evaporator connections each have a collecting channel for the the outer wall is provided downwardly flowing liquid refrigerant, the collecting channel in each case Extends largely over the entire axial length of the annular space and at least one preferably to the damper leading reflux line is provided.

Here it is easiest that the gutter in each case is formed by an approximately vertical wall which is attached to the outer wall of the annulus, itself extends approximately over the entire length of the annulus and preferably one fifth to one third of the radial width of the annulus protrudes into the annulus.

Another development of the invention, the simple design of the collecting space for the refrigerant as well as a good heat exchange allowed, can advantageously consist in that the collecting space between

Mp.no. 613/84

^{4 Jul1 19M} 40 3424916

one running approximately horizontally in the interior of the condenser, preferably below the cooling water pipes Partition wall and the arcuate area of the condenser jacket running below the partition wall is formed, the plenum only at a single axial end with the interior of the condenser is in communication and at its other end with a connection for the discharge line of the liquid refrigerant is provided.

In order to influence the overheating of the refrigerant vapor and / or to keep it within the desired limits, it is recommended that the condenser jacket is provided with thermal insulation, which - in cross section seen - in the annulus approximately from a fifth to a third starting from the partition wall, preferably a quarter of the periphery upwards and in the axial direction over the entire length of the annular space extends.

A very even flow through the annular space with improved separation of refrigerant droplets and Increased heat exchange is given when, according to a further embodiment of the invention, in the highest In the area of the annular space, a collecting channel for the gaseous refrigerant is arranged, to which the connection for the suction side of the compressor and that opens through evenly distributed openings with the annular space is connected, the flow cross-sections of the passage openings preferably being wedge-shaped Slots are formed. The dimensions of these slots are determined by pressure drop calculations, see above that even suction over the entire length of the separator is guaranteed.

Mp.no. 613/84 July 4, 1984

Another, likewise recommendable development of the invention is that the flow cross-section of the annular space is chosen so that there is a flow velocity of the gaseous refrigerant from about 0.2 to 0.6 m per second, preferably 0.3 to 0.5m per second. These flow velocities facilitate the separation of the entrained

Refrigerant droplets.
10

A particularly preferred development of the refrigeration system according to the invention with a horizontal, cylindrical Evaporator, preferably tubular boiler evaporator, can consist in that the condenser is arranged above the evaporator with a longitudinal axis running in the same direction is and both are combined into one unit, and that the collecting channels through approximately vertical running discharge lines are connected to the part of the evaporator in which the boiling liquid refrigerant stands. As a result, those apparatus of the refrigeration system that have a large structural volume are a structural unit with a small Space and space requirements combined. From a technical point of view, this results in short connecting lines between the individual devices and to the Compressor and simple support structures with a clear, easy-to-assemble structure. Furthermore the summary of the aforementioned devices gives an aesthetic overall picture of the system.

Further advantages and features of the invention are evident the following description of exemplary embodiments in conjunction with the schematic drawings.

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4th juii 1984 _Λ "3424916

Here show:

Fig. 1 is a vertical longitudinal section through a condenser surrounded by an annular space, the Part of a schematically shown

Refrigeration system is
Fig. 2 is a vertical section through the condenser

of Fig. 1 along the section line II-II, FIG. 3 shows a vertical section through the condenser according to FIG. 1 according to the section line

III-III,

4 shows a condenser and an evaporator which are combined to form a structural unit, with the condenser in a sectional view corresponding to FIG. 1, the one below

Evaporator, however, is shown in view and
Fig. 5 is a vertical section through the object of

4 according to the section line V-V. 20th

The same parts are provided with the same reference symbols in the individual figures. Also are in the Repeating individual parts are only provided with reference numerals to the extent that this is the case for the Understanding is required.

In Fig. 1 is a refrigeration system with each schematically shown compressor 10, expansion valve 12, evaporator 14 and with the condenser 16 shown in detail, which is surrounded by the annular space 62 is. This annulus forms the heat exchanger for the overheating and subcooling of the refrigerant as well as the Refrigerant separator.

Mp.no. 613/84 July 4, 1984

The condenser 16 consists of a horizontal heat exchanger with an annular-cylindrical condenser jacket 20, which surrounds the interior 22 (see FIGS. 2 and 3). If necessary, the condenser jacket can also have a have a polygonal profile, e.g. B. the profile of a regular hexagon or octagon. In the interior 22 of the condenser there are approximately horizontal cooling water pipes 24 arranged, which open at the left end of the liquefier in Ansehlußkammern 26, which with a Cooling water supply connection 28 and a cooling water discharge connection 30 are provided. At the right end of the condenser the cooling water pipes 24 open into deflection chambers 32, so that the cooling water supplied in the cooling water pipes flows back and forth.

The approximately radially extending connection 34 is provided on the right-hand end area and extends into the interior 22 opens, and to which the pressure line 36 leading to the compressor 10 is connected. In the lower part of the A further connection 38 is provided at the lowest point in the condenser, to which the discharge line 40 is connected, which leads to the evaporator 14 with the interposition of the expansion valve 12. The so far described embodiment of the condenser belongs to the prior art and is under the designation Tubular boiler condenser known. ■

In the upper area of the condenser 16 is a U-shaped distribution channel in the interior 22 above the cooling water pipes 24 42, which extend in the axial direction largely over the entire length of the interior 22

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extends, as can be clearly seen from FIGS. 1 and 2. The groove 42 runs symmetrically to one vertical plane containing the longitudinal axis 44 of the condenser. The two legs 46 of the distribution channel are tightly attached to the condenser shell and

arranged so that the connection 34 into the distribution channel 42 opens. The flow cross-section of the distribution channel is approximately 1 to 2 times the flow cross-section of connection 34. 10

At the right end 48, i.e. in the area of connection 34, the distribution channel 42 is closed by extending to the right boundary wall of the interior 22. The left end 50 of the distribution channel is open and ends a short distance from the left boundary wall of the interior 22. The upper edge of each leg 46 is longitudinally extending rectangular recesses provided so that openings 52 are formed which connect the interior of the channel 42 with the interior 22 of the condenser. How in particular can be seen from Fig. 1, a plurality of evenly distributed over the length of the legs 46 is Openings 52 are provided. The sum of the passage cross-sections of the openings 52 is approximately that Up to 2 times the flow cross section of the channel 42 or the cross section is determined by pressure drop calculations set. For the sake of clarity, the openings 52 are shown in the figures, each with a cross section, which is larger than the actual cross-section. Instead of the rectangular openings, a wedge-shaped Slot may be provided in the legs 46, starting from the connection 34 to the left end of the Distributor channel 42 widened steadily. A particularly uniform distribution is achieved in this way.

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July 4, 1984 /! $ "

A collecting space 54 for the liquefied refrigerant is provided in the lower region of the condenser. This The collecting space is located below the cooling water pipes 24 and is upward through an approximately horizontally extending one Partition 56 limited, which, seen in cross section, extends to the condenser jacket and there is tightly attached, the cross section of the collecting space 54 accordingly has the profile of a segment of a circle. the The maximum clear height of the collecting space 54 is approximately one fifth to one tenth of the clear diameter of the Inner space 22. As can be seen from FIG. 1, the partition wall 56 and thus the collecting space 54 to extend to the right end of the interior 22, while the partition wall 56 at a distance from the left vertical boundary wall 58 of the condenser ends, thereby forming an opening 60 through which the accumulating refrigerant condensate can enter the collecting space 54. At the right end of the collecting space 54 is the deepest Place the approximately radially extending connection 38 intended for the discharge of the liquefied refrigerant. The connections 34 and 38 here run approximately in the same vertical plane. It should also be emphasized that the collecting space 54 with regard to its flow cross section is dimensioned so that normal liquid velocity (0.2 to 1.5 m / s) occurs and so that the function of a sub-cooling channel is given.

As can be seen mainly from Fig. 3, the condenser jacket is 20 surrounded concentrically by the annular space 62, the radial width of which is approximately one third to

Mp.no. 613/84.

a fifth of the diameter of the condenser shell 20 is. The annular space extends in the axial direction with one end almost to the left boundary wall 58 of the condenser, while the right end with a little The distance in front of the connections 34 and 38 ends so that the area of these connections is free. At the highest Place of the annular space 62 is an approximately radially extending connection 64 for the half axial length Suction line 66 of the compressor is provided. This connection 64 opens into a collecting channel 68, which is in extends in the axial direction in the annular space and ends at a small distance from its ends, as can be clearly seen Fig. 1 can be seen. The collecting channel 68, just like the distribution channel 42, has a U-shaped profile Legs 70 which are tightly attached to the outer jacket 72 of the annular space. The arrangement is made here in such a way that that the collecting channel 68 is formed symmetrically to a vertical plane passing through the longitudinal axis 44 of the condenser runs.

At approximately half the length of the collecting channel 68, it opens approximately radially at the highest point of the annular space arranged connection 64 in the collecting channel. The axial ends of the collecting channel 68 are closed for connection with the annular space are on both legs 70 at the upper end extending in the longitudinal direction, rectangular or wedge-shaped recesses are provided which form passage openings 74. The arrangement is here taken so that seen in the side view of FIG. 1, on both sides of the connection 64 in each leg 70 has a passage opening 74. As can also be seen from Fig. 1, the increase

νί

Mp.no. 613/84

Passage openings 74 to the axial ends of the collecting channel towards, that is, the cross-sections of the passage openings become larger, the further they are from the connection 64 are removed. The purpose of this arrangement is to distribute the refrigerant vapor evenly to be withdrawn from the annular space, whereby the admission of the condenser jacket 20 by the refrigerant vapor is even.

At the lowest point of the annular space 62 are in the longitudinal direction evenly distributed several, z. B. three pieces, connectors 76 attached to a common connecting line 78 are connected, which leads to the evaporator 14. The connections 76 are approximately radially and are accordingly aligned with the collecting space 54.

In the lower area of the annular space 62 is in cross section seen on both sides of the connections 76 in each case a collecting channel 80 running in the axial direction for the provided refrigerant running off in the annular space on the outer jacket 72. The collecting channels extend axially Direction largely over the entire length of the annulus and are formed between the outer jacket and strips 82 extending approximately vertically. The collecting channels 80 are designed and arranged symmetrically to a vertical plane passing through the longitudinal axis 44 of the condenser runs. The mutual distance between the two collecting channels 82 is approximately one third to one quarter of the circumference of the outer jacket 72. The vertical height of the strips 82 is approximately one third up to a fifth of the clear radial width of the annulus.

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At each gutter 82 is a vertically downward drainage line 84 for the collected liquid refrigerant provided. The drain lines are connected to the evaporator 14 by a line 86.

Downstream drain line 84 is provided for the collected, draining, liquid refrigerant. The drain lines 84 are connected to the evaporator 14 by a line 86.

The condenser jacket 20 is provided with thermal insulation 88 in areas in the annular space 62. This exists from circular arc-shaped thin rectangular sheets 106, which with a distance of about 2 to 6mm, preferably 4 to 5mm, run from the condenser jacket. To attach the sheets 106 are on the Periphery of the condenser jacket circular spacers adapted to the curvature of the condenser jacket 112, e.g. B. in the form of correspondingly curved flat iron, on each of which the axial Ends 108 of the sheets are attached. If necessary, further spacers can be provided, especially with long sheets. The upper and lower long end portions 110 of the sheets, which extend in the direction of the longitudinal axis 44 extend, are bent towards the condenser jacket 20 and attached to the condenser jacket. All fastenings of the spacers and the sheets are made gas-tight, so that between the Metal sheets 106 and the condenser jacket 20 each have a stationary gas that is closed off from the annular space 62

Mp.no. 613/84 July 4, 1984

layer is formed, which acts as thermal insulation. If necessary, the thermal insulation can each be formed by a plurality of metal sheets, each with a gas layer lock in. Seen in the peripheral direction, the thermal insulation covers approx. 60? the scope of the Condenser jacket. In the axial direction, the thermal insulation runs coherently approximately in the area of Connections 76. The outline of the thermal insulation is rectangular in the side view according to FIG. As shown in Fig.

^As can be clearly seen in FIG. 1, the condenser jacket 20 is not provided with thermal insulation in the area of the collecting space 54 and in an area which is adjacent to the collecting duct 68.

During operation, cooling water is passed through the cooling water pipes of the condenser, which flows through the Cooling water supply nozzle 28 is supplied from the outside and discharged to the outside again through the cooling water discharge nozzle 30 will. At the same time, the tubes 94 arranged in the evaporator 14 are connected by the connections Coolant, e.g. B. Sole acted upon. The one from the compressor 10 delivered compressed refrigerant vapor is through the pressure line 36 and the connection 34 in the Distribution channel 42 passed. From here, the refrigerant vapor flows through the openings 52 in a uniformly distributed manner into the interior 22 of the condenser, where it condenses on the cooling water pipes 24. The condensate is dripping from the cooling water pipes to the partition wall 56, which it leads through the opening 60 to the collecting space 54. To the To get connection 38, connected to the discharge line 40 is, the condensed refrigerant must flow through the entire collecting space from left to right.

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4th July 1984

Here, the liquid refrigerant is replaced by that refrigerant vapor subcooled, which is introduced from the evaporator through the connections 76 into the annulus. The cooling effect of the refrigerant vapor is due to the flow of the entering, which is directed directly at the collecting space 54 Refrigerant vapor even stronger. The liquid refrigerant is at the right end of the collecting space 54 withdrawn through the connection 38 and into the discharge line 40 passed, in which a relaxation organ, z. B. in the form of an expansion valve 12 is inserted. From the above One can clearly see that the lower one, adjoining the collecting space 54, and not with it Insulated area of the condenser serves as a subcooler for the liquid refrigerant.

The expanded refrigerant evaporates in the evaporator while cooling the refrigerant flowing through the tubes 94 14, the possibly slightly superheated refrigerant vapor, which still has refrigerant droplets with it is evenly distributed through the connecting line 78 to the lower connections 76 of the annular space. As already stated above, the refrigerant vapor flowing into the annular space 62 passes under semicircular flow upwards in heat exchange with the collecting space 54. At the same time occurs through the after upward, semicircular flow of refrigerant vapor on both sides separates the entrained Refrigerant droplets as a result of the action of gravity and / or centrifugal action. The excreted liquid Refrigerant collects in the gutter 80 and is through the drain lines 84 and line 86 the Evaporator fed for new evaporation.

vr

Mp.no. 613/84

1984

In the upper area of the annular space that is not provided with thermal insulation, the in the annular space 62 arrives Flowing refrigerant vapor in heat exchange with the hot refrigerant vapor, which comes directly from the compressor coming, located in the interior 22 of the condenser. This results in a slight overheating of the refrigerant vapor reached in the annulus, which ensures that the refrigerant vapor does not affect the compressor contains more harmful refrigerant droplets. The upper area not provided with thermal insulation of the annular space thus simultaneously serves as a superheater for the refrigerant vapor.

The superheated refrigerant vapor then flows through the passage openings 74 into the collecting duct 68 for connection 64, the suction line 66 to the compressor 10 to the new circuit. This causes the effect described above The arrangement and design of the passage openings 74 are uniform over the length of the annular space of the superheated refrigerant vapor, so that the annular space flows evenly through and is used without gaps for heat exchange and droplet separation.

From the previous description of the operation it is clear that the design according to the invention or arrangement of condenser and annulus, the functions of the refrigerant subcooler, the refrigerant superheater and the refrigerant separator are combined in a simple manner in the annular channel 62, so that a compact, space-saving and space-saving construction of the refrigeration system is possible. In addition, the previous

Mp.no. 613/84 July 4, 1984

The functions of the annulus are significantly improved compared to the functions of known individual components are.

The degree of overheating of the refrigerant steam affect each other by changing that area of the condenser jacket 20, which by the thermal insulation 88 is covered. The smaller areas are provided with the thermal insulation 88, the larger it is available heat exchange surface with the result of greater overheating and vice versa.

In FIGS. 4 and 5, a refrigeration system is shown - partly schematically - which has a cooling system corresponding to FIG trained condenser and a horizontal, cylindrical evaporator, both of which into a compact Structural unit are summarized.

The evaporator here preferably consists of a tubular boiler evaporator to which the condenser is connected to in the same direction pointing longitudinal axis is placed directly, the longitudinal axes of both apparatuses approximately lie in a common vertical plane. The tubular boiler damper known from the prior art 114 has the following connections: on its left front side the connections 92 for the coolant, in In its highest area it is connected to the annular space 62 by the connections 76 and in the lowest area at least one connection 96 is provided for the discharge line 140 coming from the condenser, into which the Expansion valve 12 is switched. The vertical drainage lines 84 leading away from the collecting troughs 80

• Mp. No. 613/84 ' ■ "':.

y λ

are connected to the interior 98 of the evaporator 114 at the upper periphery of the evaporator. the mechanical connection between the condenser 16 and the evaporator 114 is made by several vertically extending Struts 100 reached, the lower end of which with the upper region of the shell of the evaporator 114 and their upper end is connected to the lower region of the outer jacket 72 of the annular space 62, the distance between Condenser and evaporator kept as low as possible is. In order to easily place the structural unit created in this way on a substrate, e.g. B. set up a floor can, two pairs of feet 102 are arranged on the lower periphery of the evaporator, the lower end of each is connected by a base plate 104. For the person skilled in the art, more details about this emerge clearly from the 4 and 5, to which reference is expressly made.

The operation of the refrigeration system according to FIGS. 4 and 5 proceeds corresponding to that operation which was described in more detail in connection with FIG. 1, so that here further details are not necessary.

The particular advantage of a refrigeration system according to FIGS. 4 and 5, in addition to the compressor and expansion device can be seen in the fact that only two devices combined to form a structural unit (condenser, with annulus, evaporator) are required, whereby the space - and / or space requirements of the refrigeration system with undiminished or significantly reduced with improved function compared to systems according to the prior art is.

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4th July 1984

It should also be noted that the surfaces adjoining the outer space of the condenser, annular space and evaporator with a thermal insulation, not shown in the drawings for clarity, z. B. in the form of synthetic foam or insulating wool to avoid losses.

All features and constructive features disclosed in the above description, the claims and the drawings Details can be essential to the invention both individually and in a meaningful combination with one another To be important.

The prior art referred to in the present application is contained in the book of Berliner, refrigeration technology, theory, systems, components, applications, 1st edition 1979, Vogel-Verlag, Würzburg.

It is obvious that the individual devices in the refrigeration system, such as compressor, expansion device, etc., each also available several times and connected in parallel in the Can be inserted refrigerant circuit.

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Claims (10)

Claims 10 1J refrigeration system each with at least one evaporator (14; 114), a horizontal condenser (16) with a refrigerant-charged condenser jacket (20), in particular a tubular boiler condenser, a heat exchanger for subcooling and superheating of the refrigerant and a refrigerant separator, characterized in that the Heat exchangers for subcooling and superheating as well as the refrigerant separator comprise a common annular space (62) which directly surrounds the jacket (20) of the condenser (16) and which is connected to the evaporator (14; 114) in the lower area and to the upper area Compressor (10) is connected, the condenser (16) having in the lower region a collecting space (54) for the liquefied refrigerant which adjoins the annular space (62). 2. Refrigeration system according to claim 1, characterized in that the annular space (62) is the condenser jacket (20) surrounds at least approximately concentrically and descends in the direction of the longitudinal axis (44) of the condenser The release of the connections (34, 38) extends largely over the entire length of the condenser jacket (20). Mp.no. 613/84 July 4, 1984 3. Refrigeration system according to claim 1 or 2, characterized in that the annular space (62) in the deepest area at least one, preferably several evenly distributed connections axially one behind the other (76) for the evaporator (14; 114), which approximately in the radial direction on the condenser jacket (20) are aligned. 4. Refrigeration system according to one of claims 1 to 3, characterized in that on the periphery of the annular space (62), seen in cross section, on both sides of the connection or connections (76) for the evaporator one gutter (80) each for the one on the outer jacket (72) of the annular space downward flowing liquid refrigerant is provided, the collecting channel (80) extending largely over the entire axial length of the Annular space (62) extends and with at least one reflux line preferably leading to the evaporator (14) (86) is provided (Fig. 1). 5. Refrigeration system according to one of claims 1 to 4, characterized in that the collecting channel (80) in each case of an approximately vertical strip (82) is formed, which is attached to the outer jacket (72), extends approximately over the entire axial length of the Annular space (62) extends and preferably a fifth to a third of the radial width of the annular space in the annular space (62) protrudes.
30th 6. Refrigeration system according to one of claims 1 to 5, characterized in that the collecting space (54) between Mp.no. 613/84: '■' ;: one in the interior (22) of the condenser approximately horizontally, preferably below the cooling water pipes (24), running partition (56) and that below the partition (56) arranged circular arc-shaped region of the condenser jacket (20) is formed, wherein the collecting space (54) is only at one axial end with the interior (22) of the condenser in connection and at his the other end or end region is provided with a connection (38) for the discharge line for the liquid refrigerant is. 7. Refrigeration system according to one of claims 1 to 6, characterized in that the condenser jacket (20) is provided with a thermal insulation (88) which, seen in cross section, in the annular space (62) in each case approximately starting from the partition (54) over a fifth to a third, preferably a quarter, of the periphery upwards, and in the axial direction approximately over the the entire length of the annular space (62). 20th 8. Refrigeration system according to one of claims 1 to 7, characterized in that in the highest region of the Annular space (62) a collecting channel (68) is arranged for the refrigerant vapor, into which a connection (64) for the suction side of the compressor (10) opens and that through evenly distributed passage openings (74) or wedge-shaped slots with the annulus. (62) is connected, the flow cross-section of the passage openings (74) or the slots as a whole are preferably 1 to 1.5 times the flow cross-section, which the connection (64) has. Mp.no. 613/84 ... 4. juii 1984 ff 3424916 9. Refrigeration system according to one of claims 1 to 8, characterized in that the flow cross section of the Annular space (64) is chosen so that a flow rate of the refrigerant vapor flowing upwards from about 0.2 to 0.6 m per second, preferably 0.3 to 0.5 m per second. 10. Refrigeration system according to one of claims 1 to 9 with a horizontal evaporator (114), preferably one Tubular boiler evaporator, characterized in that the condenser (12) above the evaporator (114) with the same Direction extending longitudinal axes (44, 144) is arranged and both combined to form a structural unit are, and that the collecting channels (80) through approximately vertically extending discharge lines (84) with the evaporation space or interior (98) of the evaporator (114) are connected.