EP1332324A1

EP1332324A1 - Refrigeratory and refrigerating device for a zeotropic refrigerating agent mixture

Info

Publication number: EP1332324A1
Application number: EP01983535A
Authority: EP
Inventors: Walter Holz; Friedrich Arnold; Joachim Kunz; Walter Lipp
Original assignee: BSH Bosch und Siemens Hausgeraete GmbH
Current assignee: BSH Hausgeraete GmbH
Priority date: 2000-10-27
Filing date: 2001-10-09
Publication date: 2003-08-06
Also published as: CN1243940C; CN1471621A; WO2002035162A1; DE10053420A1; BR0114867A

Abstract

A refrigeratory (1) for a zeotropic refrigerating agent mixture which can be used in a refrigerating device consisting of at least two refrigerating zones maintained at different temperatures, comprising two elements (2,4) placed behind each other in a refrigerating agent circuit, one being upstream (2) and the other downstream (4), in addition to a refrigerating agent collector (5). The refrigerating agent collector (5) is placed in thermal contact with the downstream element (4).

Description

Evaporator and refrigerator for a zeotropic mixture of refrigerants

The present invention relates to an evaporator for use in a refrigeration device and a refrigeration device which are suitable for operation with a zeotropic cold mixture.

Mixtures are referred to as zeotropic if their boiling temperature changes in the course of an evaporation process depending on the changing proportions of the various components in the mixture. A zeotropic mixture used as a refrigerant is e.g. a mixture of propane and isobutane.

Such a mixture has already been used in a single-temperature refrigerator.

When using zeotropic mixtures in refrigeration devices with at least two cold zones kept at different temperatures, problems arise with the structure of the evaporators that can be used in such a refrigeration device.

In order to make these problems clear, FIG. 1 shows a schematic illustration of a conventional evaporator 1 'for a refrigeration device with two refrigeration zones. The evaporator 1 'comprises two plate-like elements connected in series in a refrigerant circuit, an upstream element 2, into which refrigerant coming from a compressor (not shown) is fed via a pressure line 3, and a downstream element 4, into which the refrigerant enters, after it has run through meandering lines of the upstream element 2. These two elements 2, 4 each form evaporator boards of a freezer compartment and a refrigerator compartment of a combined household refrigerator.

A refrigerant collecting container 5 is arranged in the refrigerant circuit in such a way that the escaping refrigerant flows through it. The collecting container 5 serves to collect the refrigerant when the compressor is idle when the refrigeration device is operating intermittently. To do this, it must be located in the coldest area of the refrigerant circuit. This coldest area is the upstream element 2 or Freezer board. Therefore, the collecting container 5 is integrated in the upstream element 2.

Such a construction is not suitable for use with zeotropic mixtures. If the higher-boiling component of the mixture condenses in the collecting container 5, an undesirably high temperature is set in the region of the collecting container 5, which can be higher than the intended operating temperature of the freezer compartment.

This makes the evaporator unsuitable for use with zeotropic refrigerant mixtures.

The object of the invention is therefore to provide a refrigeration device with at least two refrigeration zones at different temperatures and a refrigerant evaporator for such a refrigeration device, which are suitable for operation with zeotropic refrigerant mixtures.

The object is achieved by an evaporator with the features of claim 1. In this evaporator, the refrigerant collecting container is in thermal contact with the downstream element. As a result, it does not reach temperatures as low as the collecting container of the evaporator from FIG. 1, and it is also not necessarily the coldest point of the refrigerant circuit already occur when only the boiling point of one of the two components of the mixture is below.

The refrigerant storage tank is preferably connected downstream of the evaporator element, i.e. Refrigerant that reaches the evaporator has previously absorbed heat from the two elements of the refrigerant circuit one behind the other.

Both elements are preferably formed in a common plate-like carrier. In order to avoid excessive heat transfer between the two elements, these are expediently thermally delimited from one another by a cutout formed in the carrier. As a result of the variability of the boiling point of the zeotropic mixture, relatively high temperature differences can occur between the expanded refrigerant at the inlet of the upstream element and the refrigerant at the outlet of the downstream element. In order to avoid undesired heating of the refrigerant at the inlet through the outlet, it is therefore provided according to one embodiment of the invention that the downstream element has an outlet connection for the refrigerant that is spaced apart from an inlet exclusion of the upstream element.

In a second embodiment, as in the evaporator of FIG. 1, it is provided that the inlet and outlet connections for the refrigerant are arranged together on the upstream element. In this case, a necessary outlet refrigerant line extends from the downstream element to the outlet connection, preferably along an edge region of the upstream element, in order to keep the heat exchange of the outlet refrigerant line with freshly supplied refrigerant as low as possible.

For the same purpose, the outlet refrigerant line can be thermally delimited from the main part of the upstream element by a cutout formed in the carrier.

Furthermore, it can be provided that the edge region, which receives the outlet refrigerant line, is embedded in a thermally insulating body. This body can in particular be an insulation layer of a wall of the refrigeration device.

Further features and advantages of the invention result from the following description of exemplary embodiments with reference to the attached figures. Show it:

1, already treated, a schematic view of a conventional evaporator for a refrigerator with two cold zones;

2 shows an analog view of a first evaporator according to the invention; 3 shows a view of a second evaporator according to the invention,

4 shows a partial section through a cold device equipped with the evaporator from FIG. 3 at the height of the line IV-IV from FIG. 3, and

5 shows another variant of the evaporator from FIG. 3

The evaporator shown in FIG. 2 is constructed on a support in a roll-bond or Z-bond technique known per se. Two elements 2, 4 of the evaporator are thermally delimited from one another by an incision 7. Refrigerant supplied by a compressor through a pressure line 3 flows through an inlet throttle 8 or another expansion device, first of all meandering pipelines 9 of the upstream element 2 and then of the downstream element 4. Following the pipeline 9 and in front of an outlet connection 10 of the downstream element 4, a refrigerant collection container 5 is arranged integrated in the downstream element 4, one at the outlet connection 10 connected suction pipe 18 is led to the pressure line 3 and runs concentrically over a distance around the pressure line 3 to form a heat exchanger

The two elements 2, 4 form evaporator plates of a freezer zone or a cooling zone of a cold appliance. The downstream element 4 is therefore warmer on average than the upstream element 2. Recondensation in the refrigerant collector holder 5 is nevertheless possible, since the higher-boiling component of the refrigerant primarily collects there

Although this first embodiment is favorable from a thermal point of view, because no heat exchange between the refrigerant which has expanded and cooled after passing through the inlet throttle 8 and the refrigerant returning to the compressor is possible, this makes the installation of the evaporator in a cold device relatively complex from the point of view of simple assembly is therefore preferred an embodiment described below with reference to FIG. 3. This embodiment differs from that described with reference to FIG. 2 on the one hand in that the inlet and outlet lines for the refrigerant are jointly provided at one point of the upstream element 2 order refrigerant from the downstream element 4 or To lead refrigerant collection container 5 to the drain connection, an outlet refrigerant line, designated 11, is laid along the edge of the upstream element 2 at a distance from the pipe 9 thereof. In order to keep the heat exchange between the outlet refrigerant line 11 and the main region of the upstream element 2, in which the pipeline 9 extends, low, in this embodiment the incision 7 is extended by a slot 12 extending parallel to the outlet refrigerant line , The slot 12 thus delimits a narrow web on which a supply refrigerant line and the outlet refrigerant line 11 for the downstream element 4 are guided in parallel.

FIG. 4 shows a partial section through a refrigeration device equipped with the evaporator from FIG. 3 at the level of line IV-IV from FIG. 3. The partial section shows a rear wall 14 of the refrigeration device against which the evaporator rests, and sections of adjoining side walls , A slot 16 is formed on a side wall 15, into which the edge region of the upstream element 2, in which the outlet refrigerant line 11 runs, is embedded. The outlet refrigerant line 11 is largely enclosed by the insulation material of the walls 14, 15 of the refrigeration device, so that undesired heating of the freezer zone by the outlet refrigerant line 11 is avoided.

FIG. 5 shows another variant of the evaporator from FIG. 3. In this variant, the slot 12 is replaced by an elongated cutout 17 which extends over essentially the entire length of the upstream element 2 and the outlet refrigerant line 11 from the pipeline 9 of the main part of the upstream element 2 and from the supply refrigerant line separates. In this embodiment, a heat-conducting transition between this main part and the outlet refrigerant line 11 is thus practically avoided over its entire length. This variant is also suitable for the attachment shown in FIG. 4.

Claims

claims

1. refrigerant evaporator (1) for a refrigeration device with at least two cold zones kept at different temperatures, the evaporator comprising two elements (2, 4), one upstream (2) and one downstream (4), one behind the other in a refrigerant circuit, for attachment in each case the cold zones, and has a refrigerant collection container (5), characterized in that the refrigerant collection container is in thermal contact with the downstream element (4).

2. Evaporator according to claim 1, characterized in that the refrigerant collecting container (5) is connected downstream of the element (4).

3. Evaporator according to claim 1 or 2, characterized in that both elements (2, 4) are formed in a plate-like carrier and are thermally delimited from one another by a cutout (7) formed in the carrier.

4. Evaporator according to one of the preceding claims, characterized in that the downstream element (4) has an outlet connection (10) for the refrigerant.

5. Evaporator according to one of claims 1 to 3, characterized in that inlet and outlet connection for the refrigerant are arranged together on the upstream element (2), and that an outlet refrigerant line (4) from the downstream element (4) to Outlet connection extends along an edge region of the upstream element (2).

6. Evaporator according to claim 5, characterized in that the outlet refrigerant line (11) is thermally delimited against the main part of the upstream element (2) by a cutout (12, 17) formed in the carrier.

7. Evaporator according to claim 5 or 6, characterized in that the edge region is embedded in a thermally insulating body.

8. Refrigeration device with an evaporator according to claim 7, characterized in that the thermally insulating body is an insulation layer of a wall (14, 15) of the refrigeration device.