AT7706U1 - COMPRESSOR WITH INTEGRATED VERDUNSTERSCHALE - Google Patents

Abstract

Compressor for hermetically sealed small refrigeration machines, which has a cylinder with a piston guided therein for the compression of a working medium and with a compressor housing (1) is completed. According to the invention it is provided that laterally projecting boundary walls (3) are provided, which surround the compressor housing (1) along a circumferential line of the compressor housing (1) and form an upwardly open container (5), wherein the compressor housing (1) at least partially extends into the interior of the enclosed by the boundary walls (3) volume.

Description

AT 007 706 U1

The present invention relates to a compressor for hermetically sealed small refrigerating machines according to the preamble of claim 1, as well as a small refrigerating machine according to the preamble of claim 7.

Compressors of the type mentioned in a known manner, a cylinder with a guided therein-5 th piston for compressing a working fluid. The cylinder is arranged within a compressor housing, which is penetrated by the supply and discharge pipes of a working medium to and from the cylinder and open into the supply and discharge pipes. The compressor itself is in turn arranged on a small refrigerating machine with a cooling space.

In the course of operation of such a small refrigeration condensed liquid condensates, in particular because of locally occurring, low temperatures condensed humidity, which is collected in storage tanks. These sumps must either be emptied regularly, or they ensure adequate evaporation performance due to suitable design and arrangement, so that condensed liquid is transferred back into the gaseous state and escapes from the field of small refrigeration machine. An advantageous arrangement of the collecting container is approximately in the vicinity of the compressor, since the compressor is a heat source. The heat emitted by the compressor thereby promotes the evaporation of the condensed liquid in the sump. According to the prior art, it is therefore intended to carry out the collecting container as a separate component, which is mounted in the region of the compressor. However, such an arrangement has the disadvantage that the heat emitted by the compressor is not optimally utilized. Furthermore, the installation of the separate collection container on the compressor or in the vicinity of the compressor requires additional assembly steps, such as its positioning and its attachment by means of various fastening means.

It is therefore the object of the invention, by means of a new arrangement of a container for taking-up condensed liquid to create a compressor or a small refrigerating machine, so that the heat given off by the compressor is optimally utilized. Preferably, this also simplifies the assembly steps necessary for the assembly of such a compressor. This object is achieved by the features of claims 1 and 7, respectively.

Claim 1 refers to a compressor for hermetically sealed Kleinkältema-30 machines, which has a cylinder with a piston guided therein for the compression of a working fluid and is completed with a compressor housing. According to the invention it is provided that laterally projecting boundary walls are provided which tightly surround the compressor housing along a circumferential line of the compressor housing and form an open-topped container, wherein the compressor housing extends at least partially into the interior of the 35 enclosed by the boundary walls volume. This has the consequence that the bottom of the container is at least partially formed by the compressor housing itself, so that the condensed liquid wets the compressor housing. Thus, the heat transfer from the interior of the compressor housing via the compressor housing to the condensed liquid in the interior of the collecting container is optimized. However, it also follows that the collecting container is not a separate component but a part of the compressor housing, which, depending on the embodiment, makes it possible to simplify its assembly.

For example, it may be provided according to claim 2, that the boundary walls are formed by a metal sleeve, which is tightly secured to the compressor housing. In the course of assembly, therefore, only the metal collar must be applied to the compressor housing and secured by means of suitable fasteners such as adhesive, screws, flange or the like. An additional simplification of the assembly is possible with the features of claim 3. Claim 3 provides for a compressor housing, which is formed by an upper housing part and a lower housing part, to carry out the boundary walls with the upper housing part in one piece. Alternatively, according to claim 4, the boundary walls can be made in one piece with 50 the lower housing part.

In order to optimize the evaporation, it can be provided according to claim 5, that the boundary walls are inclined relative to the vertical in the outer space of the container, wherein according to claim 6, the inclination angle is preferably between 10 ° and 45 °.

Claim 7 finally provides a small refrigeration machine, which has a compressor having a 55 cylinder with a piston guided therein for compressing a working medium and 2 AT 007 706 U1 a compressor housing is completed, and a collecting container for condensed liquid, wherein the compressor housing at least partially disposed in the interior of the collecting container. For example, the collecting container can be arranged below the compressor, with the compressor housing at least partially penetrating into the volume enclosed by the collecting container. Such an arrangement also improves the heat transfer from the compressor to the liquid in the collecting container.

The invention will be explained in more detail below with reference to the accompanying drawings. It shows the

1 is a perspective view of a compressor according to the prior art, FIG. 2 is a perspective view of a compressor according to the invention with a condensed liquid collecting container according to an embodiment of the invention, FIG.

Fig. 3 is a section through the median plane E of the compressor of FIG. 2, wherein the interior of the compressor has not been shown, and

4 is a detailed view of the compressor according to section A of Fig. 3, 15 Fig. 5 is a detail view of the compressor according to detail A of Fig. 3 for a further imple mentation of the invention,

Fig. 6 is a detail view of the compressor according to section A of Fig. 3 for a further embodiment of the invention, and

Fig. 7 is a detail view of the compressor according to section A of Fig. 3 for a further embodiment of the invention.

Fig. 1 shows a perspective view of a compressor according to the prior art. The compressor is arranged approximately by means of fasteners 4 within a small refrigeration machine. Although a collecting container may be provided in the interior of the small refrigerating machine, which, however, is designed as a separate component and in particular not as an integral part of the compressor housing 1. As mentioned, such an arrangement has the disadvantage that the heat emitted by the compressor is not optimal is being used. Furthermore, the installation of the separate collection container on the compressor or in the vicinity of the compressor requires additional assembly steps, such as its positioning and its attachment by means of various fastening means. In contrast, FIG. 2 shows a perspective view of a compressor according to the invention with a condensed liquid collecting vessel 5. The compressor is arranged approximately by means of fasteners 4 within a small refrigeration machine. The container 5 is formed by upwardly projecting, lateral boundary walls 3, which tightly surround the compressor housing 1, so that the liquid 35 collected in the interior of the container 5 also remains in the interior. The heat released in the interior of the compressor housing 1 is therefore transferred directly to the liquid in the container 5 wetting the compressor housing 1. This has the consequence on the one hand that the evaporation of the collected liquid is optimized, and on the other hand that the compressor housing 1 and thus the inside of the compressor is cooled. However, cooling the interior of the compressor also causes an increase in performance of the compressor 40, since the resulting due to the compression of the working fluid in the cylinder heat dissipates more quickly and the thermodynamic efficiency is thereby improved. For the realization of the collecting container 5 different embodiments are now possible. To explain some of the various embodiments, a section through the center plane E of the compressor of FIG. 2 is shown in FIG. 3, wherein the interior of the Ver-45 was not shown. FIG. 3 also shows a detail A, which is shown enlarged in FIGS. 4 to 7 for explaining different embodiments of the collecting container 5.

As can be seen initially in FIG. 4, the compressor housing 1 can be formed by an upper housing part 1a and a lower housing part 1b, wherein the boundary walls 3 50 according to a first embodiment with the lower housing part 1 b are made in one piece. This is particularly possible with housings made of metal or plastic, such as by deep drawing in the course of the production of the corresponding housing part 1 b. The compressor housing 1 extends at least partially into the interior of the enclosed by the boundary walls 3 volume. These portions of the compressor housing 1 form in this Ausfüh-55 tion form an inner, lateral boundary of the container 5, which terminates tightly with the bottom 2 of the container 5 3 AT 007 706 U1. The heat released in the interior of the compressor housing 1 is in turn transferred directly to the liquid in the container 5 wetting the compressor housing 1, with the advantages mentioned above. The boundary walls 3 should be designed inclined relative to the vertical S in the outer space of the container 5, so that the space enclosed by the boundary walls 3 5 volume is increased above the liquid collected in the container 5. This promotes the evaporation of the liquid. Preferred values of the inclination angle α are about 10 "to 45". This means for the embodiment shown in Fig. 4, that the boundary wall 3 is at least partially designed as a truncated cone shell. The height H of the boundary wall 3 will be matched to the amounts of the resulting, condensed liquid 10.

Fig. 5 shows a detailed view according to the detail A in Fig. 3 for a further embodiment of the invention. Here, the upwardly projecting, lateral boundary walls 3 of the container 5 are designed as a sleeve 3, which tightly surrounds the compressor housing 1 and is supported on the lower housing part 1 b. The cuff 3 may be made of a metal 15, for example. The circumferential profile on one side of the sleeve 3 corresponds to a circumferential course of the surface of the compressor housing 1, so that in the course of mounting the sleeve 3, it only needs to be applied and fastened to the compressor housing 1. The attachment of the sleeve 3 to the compressor housing 1 can be done using conventional fasteners such as adhesive, screws, welds, flange or the like. It only has to be ensured that the contact area between the collar 3 and the compressor housing 1 is tight, so that the condensed liquid collected within the collar 3 remains in the collecting container 5 formed by the collar 3 and the compressor housing 1. The sleeve 3 will be designed in its dimensions so that it is seated on the compressor housing 1, so that the compressor housing 1 extends at least partially into the interior of the enclosed by the sleeve 3 volume.

Fig. 6 shows a detailed view according to the detail A in Fig. 3 for a further embodiment of the invention. The compressor housing 1 is also formed by an upper housing part 1a and a lower housing part 1b, but in this embodiment, the boundary walls 3 are made in one piece with the upper housing part 1a. Fig. 7 shows a detailed view according to the detail A in Fig. 3 for a further embodiment of the invention. In a manner similar to the embodiment according to FIG. 5, the upwardly projecting, lateral boundary walls 3 of the container 5 are designed as a sleeve 3, which tightly surrounds the compressor housing 1. In contrast to the embodiment according to FIG. 5, however, the sleeve 3 is supported on the upper housing part 1a. The cuff 3 may be made of a metal, for example. The circumferential profile on one side of the sleeve 3 in turn corresponds to a circumferential course of the surface of the housing part 1 a, so that in the course of mounting the sleeve 3 it must be applied and fixed only on the upper housing part 1 a of the compressor housing 1. The attachment of the sleeve 3 on the housing part 1a can be carried out by means of conventional fastening means such as adhesive, screws, flange connections welded joints or the like. It only has to be ensured that the contact area between sleeve 3 and housing part 1a is tight, so that the condensed liquid collected within the sleeve 3 remains in the collecting container 5 formed by sleeve 3 and housing part 1a. The sleeve 3 will in turn be designed in its dimensions so that it is seated on the housing part 1a of the compressor housing 1 45, so that the housing part 1a at least partially extends into the interior of the volume enclosed by the sleeve 3 volume. However, as can be seen in FIG. 7, the section of the housing part 1 a lying inside the sleeve 3 does not have to project beyond the height H of the container 5, so that this section forms the bottom 2 of the container 5.

As in the case of the embodiment shown in FIG. 4, in the embodiments according to FIG. 5 to 7 the boundary walls 3 should be inclined relative to the vertical S in the outer space of the container 5, so that the volume enclosed by the boundary walls 3 is above the liquid collected in the container 5 is increased. As mentioned, this promotes the evaporation of the liquid. Preferred values of the inclination angle α are again about 10 ° to 45 ". This means for the embodiments shown in FIGS. 4 to 7 that the boundary walls 3 form an upwardly widening container 5. 4

Claims (7)

AT 007 706 U1 The height H of the boundary walls 3 will again be matched to the quantities of condensate liquid produced. Alternatively to the in Figs. 2 to 7 shown arrangements, but it is also conceivable that the collecting container 5 is designed as a separate component, however, the Verdichterge-5 housing 1 is at least partially disposed in the interior of the collecting container 5. In this way too, it can be achieved that the transfer of the heat released in the interior of the compressor housing 1 to the liquid collected in the container 5 is improved. Due to the inventive design of a compressor, it is possible to optimally use the heat given off by the compressor to evaporate the collected, condensed liquid inside the collecting container 5 and to simplify the assembly steps necessary for the assembly of such a compressor. 15 20 25 30 35 40 CLAIMS: 1. Compressor for hermetically sealed small refrigeration machines, which has a cylinder with a piston guided therein for the compression of a working medium and with a compressor housing (1) is completed, characterized in that laterally projecting boundary walls (3) are that the compressor housing (1) along a circumferential line of the compressor housing (1) tightly enclose and form an upwardly open container (5), wherein the compressor housing (1) at least partially in the interior of the boundary walls (3) enclosed volume extends. 2. A compressor for hermetically sealed small refrigerating machines according to claim 1, characterized in that the boundary walls (3) are formed by a metal sleeve which is tightly secured to the compressor housing (1). 3. A compressor for hermetically sealed small refrigerators according to claim 1 or 2, characterized in that the compressor housing (1) by an upper housing part (1 a) and a lower housing part (1 b) is formed, wherein the boundary walls (3) with the upper housing part ( 1a) are made in one piece. 4. compressor for hermetically sealed small refrigeration machines according to claim 1 or 2, characterized in that the compressor housing (1) by an upper housing part (1a) and a lower housing part (1b) is formed, wherein the boundary walls (3) with the lower housing part ( 1 b) are made in one piece. 5. A compressor for hermetically sealed small refrigerators according to one of claims 1 to 4, characterized in that the boundary walls (3) relative to the vertical in the outer space of the container (5) are inclined. 6. compressor for hermetically sealed small refrigerating machines according to claim 5, characterized in that the inclination angle between 10 ° and 45 °. 7. small refrigerating machine comprising a compressor having a cylinder with a guided therein piston for compressing a working medium and with a compressor housing (1) is completed, and a collecting container (5) for condensed liquid, characterized in that the compressor housing (1 ) is at least partially disposed in the interior of the collecting container (5). 45HIEZU 3 SHEET DRAWINGS 50 5 55