EA017961B1 - Refrigeration appliance comprising a plurality of shelves - Google Patents

Abstract

The invention relates to a refrigeration appliance comprising at least two compartments (2, 3) designed for two different storage temperatures. The refrigeration appliance has a branched refrigerating circuit, a first branch (15) of the refrigerating circuit is routed via an evaporator (5) of the warmer compartment (3) and a second branch (18) is routed via an evaporator (4) of the cooler compartment (2). The evaporator (4) of the cooler compartment (2) comprises two conduits (16, 19), a first (16) in the first branch (15) being mounted upstream of the evaporator (5) of the warmer compartment (3) and the second (19) being associated with the second branch (18).

Description

Technical field

The present invention relates to a refrigerating apparatus, in particular a domestic refrigerating apparatus, which comprises at least two compartments designed to maintain different storage temperatures. Such appliances, also called combination refrigerators, typically have a refrigerator compartment and a freezer compartment. In addition, there may be, for example, a zero-temperature compartment or a cellar.

State of the art

In simple devices of this type, evaporators of each compartment are sequentially connected to the refrigeration circuit. The distribution of refrigerating power among the compartments is strictly defined by the design of the device and depends, for example, on the sequence of location of the evaporators in the refrigeration circuit and on their relative sizes. If the distribution of the refrigerating capacity corresponds to the cold storage needs of the compartments, a suitable temperature will be established in the compartments, even if the refrigerant circuit can only be controlled by measuring the temperature in one of the compartments. If, for example, due to the unusual ambient temperature, the ratio of the department’s need for cold will shift, this will lead to insufficient or excessive cooling of some compartment.

In most cases, when the evaporators are connected in series to the refrigeration circuit, the evaporator of the refrigerator compartment is located in front of the evaporator of the freezer compartment (in the order of movement of the refrigerant). The refrigerant that evaporates in the refrigeration compartment evaporator during the resting phase of the circuit displaces the colder refrigerant in the evaporator of the freezer compartment further downstream of the circuit, and this leads to undesired heat entering the freezer compartment.

In order to regulate the temperature in two or more refrigerated compartments of a refrigerating appliance independently of each other, it is necessary to arrange for each compartment its own refrigeration circuit, which is associated with significant costs, or to construct a branched refrigeration circuit in which evaporators of different compartments will be located in several branches parallel to each other refrigeration circuit, and a valve will be provided to selectively supply refrigerant to one branch or another.

This solution is less expensive than separate refrigeration circuits, however, there is an interaction between the branches that reduces the efficiency of the refrigeration circuit. If, for example, refrigerant has been supplied to the evaporator of the cold compartment (for example, the freezer compartment) for a long time and the temperature in the compartment has dropped to a value at which the flow of refrigerant is stopped, the liquid refrigerant will be stored for a long time in the evaporator of this compartment without participating in circulation. If, immediately after the completion of the refrigerant supply to the cold compartment, it is necessary to cool the warmer compartment, for example the refrigerator compartment, then only a small amount of refrigerant will be available for this. The pressure in the refrigeration circuit will be low, and the efficiency will be low. Efficiency will only increase when most of the refrigerant in the cold compartment evaporator evaporates again and returns to the circuit. However, this is due to an increase in temperature in the colder compartment, i.e. the operating pressure of the refrigerant, which ensures efficient operation, is achieved only shortly before the need for cold again arises in the colder compartment. Thus, the efficiency of the refrigeration circuit deteriorates over a significant part of the operating time of this circuit.

Disclosure of invention

The objective of the invention is to develop a refrigeration apparatus with at least two compartments that are designed to maintain different storage temperatures, and in the refrigeration apparatus it will be possible to realize independent cooling of compartments with good efficiency and a refrigeration circuit of simple design.

The problem is solved by a refrigerating apparatus with at least two compartments and a branched refrigerant circuit, the first branch of which passes through the evaporator of the warmer compartment, and the second branch passes through the evaporator of the colder compartment, the evaporator of the colder compartment contains two refrigerant pipelines, the first of which is included in the first branch in front of the evaporator of the warmer compartment, while the second pipeline refers to the second branch.

This design allows the refrigerant to be supplied to the second branch only when its supply to the first branch would lead to supercooling of the warmer compartment. As a result, firstly, the frequency with which refrigerant is supplied to the second branch is reduced, as a result of which, at the end of the supply, liquid refrigerant can remain in the evaporator. Secondly, since the second branch should be used only when there is a risk of supercooling of the warmer compartment, it is less likely that soon after the refrigerant is fed into the second branch, the need for cold will arise in the warmer compartment, and only the suboptimal one will be available to supply the first branch amount of refrigerant.

In order to reduce the amount of liquid refrigerant that may remain in the second branch, it is preferable that the volume of the second branch be smaller than the volume of the first branch.

- 1 017961

According to an alternative embodiment of the invention, the volume of the second branch is selected larger than the volume of the first branch. Thanks to this, the colder compartment cools much faster.

In particular, if the volume of the second branch is less than the volume of the first branch, the problem may arise that the refrigerant does not completely evaporate when passing through the second branch. When liquid refrigerant enters the compressor of the refrigeration circuit, the compressor may not work properly, resulting in the risk of damage to it. Therefore, it is advisable to provide a refrigerant reservoir in the low-pressure region of the refrigeration circuit, which is designed to trap (possibly existing) liquid refrigerant before it reaches the compressor.

Preferably, the refrigerant reservoir is located downstream of the merger of both branches, i.e. perhaps the liquid refrigerant collected in it can evaporate and return to the circuit even when the refrigerant circulates only in the first branch and does not circulate in the second branch.

It is advisable that the refrigerant flows through the reservoir in a rising direction, so that the refrigerant stored in it cannot leak in liquid form.

Preferably, both pipelines are evenly distributed over the surface of the evaporator of the colder compartment to ensure uniform cooling regardless of whether the refrigerant cooling evaporator circulates along the first or second branch.

Preferably, each of the branches comprises a throttling element. So, in the high-pressure area of the refrigeration circuit, a valve can be located designed to selectively supply refrigerant to both branches. In this case, a compact and inexpensive valve with a small channel cross section can be used.

Preferably, the length of the first refrigerant pipe on the cooler compartment evaporator is less than or equal to the length of the second refrigerant pipe.

Brief Description of the Drawings

Other features and advantages of the invention follow from the following description of embodiments based on the attached figure, which shows a diagram of a refrigeration circuit in a combined refrigeration apparatus.

The implementation of the invention

The drawing shows a very schematic front view of the housing 1 of the refrigeration unit with a freezer compartment 2 and a refrigeration compartment 3 located above it. Evaporators 4, 5 are located in both compartments 2, 3, and the evaporator 5 of the refrigeration compartment 3 is in the form of a sheet evaporator and is located on the back wall of the refrigerator compartment, and the evaporator 4 of the freezer compartment 2 can be made, for example, in the form of a plate evaporator. Evaporators 4, 5 are included in one refrigerant circuit, which also contains a compressor 6, a condenser 7, a directional distributor 8, two capillaries as throttling elements 9, 10 and a steam cap as a reservoir 11 for refrigerant.

On the guide distributor 8, the refrigeration circuit branches into two branches. The first branch 15 contains a throttling element 9, a pipe 16 on the evaporator 4 of the freezing compartment 2, and also a pipe 17 on the evaporator 5 of the refrigerating compartment 3, adjacent to it downstream. The second branch 18 comprises a throttling element 10 and a pipe 19 on the evaporator 4. At a point 20 downstream of the refrigerant reservoir 11, both branches merge again.

Both pipelines 16, 19 are approximately the same length and extend substantially next to each other over the entire surface of the evaporator 4, as a result of which the evaporator cools substantially uniformly, regardless of which of the two branches 15, 18, the refrigerant circulates .

The control circuit 12 controls the operation of the compressor 6 and the directional distributor 8 based on the temperature values measured by two sensors 13, 14 in the compartments 2, 3. For each of the compartments 2, 3, a range is specified in which the measured temperature values can fluctuate. If the temperature measured in one of the compartments exceeds a predetermined range, compressor 6 is turned on.

First, consider the case when the compressor 6 is turned on due to the fact that the temperature measured in the freezer compartment 2 exceeds the upper limit of the allowable range. If at the same time the temperature measured in the refrigerator compartment falls within the permissible range, then the directional distributor 8 is activated so that the refrigerant goes to branch 15. Since the volume of branch 18 is small compared to the volume of branch 15, at this time, of course, a small amount of liquid refrigerant can be stored in branch 18. Therefore, the proportion of circulating refrigerant in relation to the total amount of refrigerant in the refrigeration circuit is high, respectively, at the outlet of compressor 6, a high pressure, providing good cooling efficiency.

The liquid refrigerant that can be stored in the refrigerant tank 11, when the compressor 6 is turned on, is heated by the warm, gaseous refrigerant coming from the evaporator 5, due to which it also evaporates and enters the circuit shortly after the compressor 6 is turned on.

Since the refrigerant circulates through both evaporators 4, 5, the refrigeration compartment 3 also cools. If the temperature in this compartment reaches the lower limit of its permissible

- 2 017961 range, before this happens in the freezer compartment 2, the control circuit 12 will switch the directional distributor so that the refrigerant is supplied only to the evaporator 4 of the freezer compartment via branch 18. Since the compressor channel 6 allows sufficient refrigerant to be dispensed in order to so that when the branch 15 is fed into the evaporator 5, an amount of liquid refrigerant sufficient to cool the refrigeration compartment 3 gets in, it is easy to understand that not all refrigerant will evaporate in the pipe 19 on the way along the branch 18. The remainder of the liquid the refrigerant leaving the evaporator 4 is captured by the refrigerant reservoir 11 and does not enter the compressor 6. The refrigerant reservoir 11 can be implemented in the form of a simple rising pipe section, which is more spacious than the adjacent pipe sections. Due to this, gaseous refrigerant entering the refrigerant reservoir 11 from below can pass through and possibly exit the liquid refrigerant in the cap at the upper end without entraining liquid refrigerant. The refrigerant reservoir 11 is thermally insulated, so that the passing refrigerant from the evaporator 5 is the main source supplying the heat of vaporization for the stored liquid refrigerant.

Of course, it can also happen that the temperature in the refrigerator compartment 3 exceeds the upper limit of the allowable range, while the temperature in the freezer compartment 2 remains within the allowable range. In this case, cooling of the refrigerator compartment 2 is not possible without simultaneously cooling the freezer compartment with the refrigeration circuit shown in the drawing. However, this is by no means a disadvantage, since the sizes of the evaporators 4, 5 are selected so that when the branch 15 is operating, the share of refrigerating power attributable to the refrigeration compartment 3 is greater than the average cold demand of this compartment. If the compressor 6 will constantly turn off when the temperature in either of the two compartments 2, 3 reaches the lower limit of the corresponding range, then it is possible to guarantee sufficient cooling of the refrigerating compartment 3 and to prevent overcooling of both compartments.

Since in the branch 15 the evaporator 5 of the refrigerator compartment is switched on after the evaporator of the freezer compartment 2, the unwanted intake of heat into the freezer compartment due to the refrigerant evaporating in the evaporator 5 is excluded with the compressor turned off.

Claims (9)

CLAIM 1. A refrigeration device, such as a household refrigeration device, which contains at least two compartments (2, 3), designed to maintain different storage temperatures, and a branched refrigeration circuit, the first branch (15) of which passes through the evaporator (5) of a warmer compartment (3), and the second branch (18) through the evaporator (4) of the colder compartment (2), characterized in that the evaporator (4) of the colder compartment (2) contains two pipelines (16, 19) for the refrigerant, the first (16) of which is included in the first branch (15) in front of the evaporator (5) more warm compartment (3), and the second pipeline (19) refers to the second branch (18). 2. Refrigeration apparatus according to claim 1, characterized in that the volume of the second branch (18) is less than the volume of the first branch (15). 3. The refrigeration apparatus according to claim 1, characterized in that the volume of the second branch (18) is greater than the volume of the first branch (15). 4. The refrigeration apparatus according to one of claims 1 to 3, characterized in that the length of the first pipe (16) for the refrigerant on the evaporator (4) is less than or equal to the length of the second pipe (19) for the refrigerant. 5. The refrigeration apparatus according to one of claims 1 to 4, characterized in that the reservoir (11) for the refrigerant is provided in the low-pressure region of the refrigeration circuit. 6. Refrigeration apparatus according to claim 5, characterized in that the reservoir (11) for the refrigerant is located downstream from the place (20) of the merger of both branches (15, 18). 7. Refrigeration apparatus according to claim 5 or 6, characterized in that the reservoir (11) for the refrigerant is located in the refrigeration circuit so that the refrigerant passes through this circuit in the ascending direction. 8. The refrigeration apparatus according to one of the preceding paragraphs, characterized in that both pipelines (16, 19) for the refrigerant are evenly distributed over the evaporator (4) of the colder compartment (2). 9. The refrigerator according to one of the preceding paragraphs, characterized in that each of the branches (15, 18) contains a throttling element (9, 10).