EP2796812A1 - Refrigeration and/or freezer device - Google Patents

Abstract

The present invention relates to a refrigerator and / or freezer with at least one first and at least one second evaporator and at least one in the flow direction of the refrigerant downstream of the evaporator compressor, wherein at least a first suction line from the first evaporator to the compressor and at least one second Suction line from the second evaporator extends to the compressor and wherein in the compressor at least one valve is arranged, which is connected to one or both of the suction lines such that by means of the valve, the flow of refrigerant through one or both of said suction lines is variable.

Description

The present invention relates to a refrigerator and / or freezer with at least one first and at least one second evaporator and at least one in the flow direction of the refrigerant downstream of the evaporator compressor.

From the prior art refrigerators and / or freezers are known, the refrigerant circuit has two evaporators, which are assigned to different compartments.

FIG. 4 shows such known from the prior art arrangement. The reference numeral 10, a compressor is characterized, which is followed by a condenser 20. Downstream of the condenser 20 are the evaporators 30, 40, of which the evaporator 30, the refrigerator part evaporator and the evaporator 40 is the Gefiertierteverdampfer.

Reference numeral 50 denotes a solenoid valve located on the pressure side of the compressor 10.

Depending on the position of the solenoid valve 50, the two evaporators 30, 40 are flowed through in succession by refrigerant or only the freezer evaporator 40 is flowed through by refrigerant.

If both evaporators 30, 40 are flowed through in succession by refrigerant, there is the disadvantage that comparatively warm refrigerant passes from the refrigerated part evaporator 30 into the freezer evaporator 40, which impairs its efficiency. If the evaporation temperature is lowered so much that a favorable evaporation temperature is present in the freezer compartment evaporator 40, there is the disadvantage that the evaporation temperature for the refrigerator compartment evaporator 30 is too low, which is also associated with disadvantages in terms of efficiency.

Another disadvantage is that the illustrated use of the solenoid valve 50 requires a plurality of solder joints, so that the production of the refrigerant circuit designed as relatively complex and therefore expensive and susceptible to leakage.

The present invention has the object of developing a refrigerator and / or freezer of the type mentioned in such a way that this has an efficiently operable and comparatively simple design refrigerant circuit.

This object is achieved by a refrigerator and / or freezer with the features of claim 1. Thereafter, it is provided that at least a first suction line from the first evaporator to the compressor and at least one second suction line from the second evaporator to the compressor runs and that in the compressor at least one valve is arranged, which is so connected to one or both of the suction lines in that the flow of refrigerant through one or both of said suction lines can be changed by means of the valve.

The arrangement of the at least one valve in or at the intake of the compressor can be dispensed with an arrangement of the solenoid valve in the lines of the refrigerant circuit and it eliminates solder joints that would otherwise be required for mounting the solenoid valve in the lines of the refrigerant circuit.

The integration of the valve in the compressor thus results in a simplification of the refrigerant circuit and thus a cost advantage over the known from the prior art solutions in which the valve is not arranged in the compressor.

In a further embodiment of the invention, it is provided that the first and the second evaporator in the refrigerant circuit are arranged such that the first evaporator is always flowed through by refrigerant regardless of the valve position and the second evaporator is not flowed through by refrigerant in at least one valve position. The second evaporator can thus be operated in this valve position in the bypass.

The named first evaporator may be, for example, a freezer evaporator and the second evaporator may be, for example, a refrigerated part evaporator, resulting in the advantage of an efficient and energy-saving system.

The device can thus have at least one freezer compartment with at least one freezer evaporator associated therewith and at least one refrigerator compartment with at least one refrigerator compartment evaporator associated therewith, wherein the first evaporator is the freezer compartment evaporator and the second evaporator is the refrigerator compartment evaporator. Likewise, it is conceivable that the first evaporator is the refrigerator part evaporator and the second evaporator and the freezer evaporator. The term "cooling part" in this context means a conventional cooling part and / or a cold storage compartment. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the first and the second evaporator are connected in parallel in the refrigerant circuit. This embodiment makes it possible that either one or the other evaporator is flowed through by refrigerant or at correspondingly faster timing flow through both evaporators of refrigerant.

Furthermore, it can be provided that in the flow direction of the refrigerant upstream of the evaporator at least one, preferably exactly one capillary is provided and that in the flow direction of the refrigerant downstream of the capillary at least one branch line is provided, extending between the capillary and the first evaporator and between the capillary and the second evaporator.

The terms "upstream" and "downstream" and "before" and "after" indicate the position of the individual components relative to each other in the flow direction of the refrigerant, as it results in the operation of the compressor.

In the embodiment, there is exactly one or at least one capillary between the condenser and the evaporators, the capillary being associated with both evaporators, i. flows through both during operation of the first and during operation of the second evaporator of refrigerant. After the capillary, the refrigerant line divides into a number of branch lines corresponding to the number of evaporators, with at least one of the branches leading to the evaporators in each case.

The invention also includes an embodiment in which at least one, preferably exactly one capillary is provided per evaporator in the flow direction of the refrigerant upstream of the evaporator, and that at least one branch line is provided in the flow direction of the refrigerant upstream of the capillaries and leads to the capillaries.

In this embodiment, not one or more common capillaries is provided, but it is associated with each evaporator at least one capillary. In this case, there is a branch between the condenser and the capillaries in front of the capillaries, which connects the condenser outlet to the respective capillaries.

Furthermore, it can be provided that the first and the second evaporator are arranged such that in the operating state in which an evaporator is flowed through by refrigerant and the other evaporator is shut off by the valve, the evaporator shut off by the valve is partially or completely emptied , If the operation of the compressor flows through one of the evaporators of refrigerant and the other evaporator is shut off by the valve arranged on the compressor, the refrigerant is sucked out of the "shut off" evaporator in this embodiment, which brings the advantage of an optimized defrost with it.

Furthermore, it can be provided that at least one liquid separator is arranged in at least one of the suction lines, which prevents the compressor from being exposed to liquid refrigerant and that the suction line is frosted.

It is preferably provided that apart from the one or more valves of the compressor in the refrigerant circuit, there are no other valves. The "steering" of the refrigerant flow through the refrigerant circuit is in this case exclusively by means of the compressor or the valves. On solder joints in the line system of the refrigerant circuit for the arrangement of one or more valves can thus be omitted.

It is particularly advantageous if the valve is a solenoid valve and preferably a multi-way valve. Depending on the position of the solenoid valve, one or the other suction line can be released or shut off. Instead of a multi-way valve, the use of one or preferably a plurality of stop valves is possible and included before the invention.

The use of a stop valve is possible, which is preferably not used for temperature control.

The compressor is preferably a variable speed, preferably a variable speed compressor.

Figur 1:

eine schematische Ansicht eines Kältemittelkreislaufes mit zwei in Serie betreibbaren Verdampfern;

Figur 2:

eine schematische Ansicht eines Kältemittelkreislaufes mit zwei parallel geschalteten Verdampfern und einer gemeinsamen Kapillare;

Figur 3:

eine schematische Ansicht eines Kältemittelkreislaufes mit zwei parallel geschalteten Verdampfern und mehreren Kapillaren und

Figur 4:

eine schematische Ansicht eines Kältemittelkreislaufes gemäß dem Stand der Technik.

Further details and advantages will be explained with reference to an embodiment shown in the drawing. Show it:

FIG. 1:

a schematic view of a refrigerant circuit with two operable in series evaporators;

FIG. 2:

a schematic view of a refrigerant circuit with two parallel evaporators and a common capillary;

FIG. 3:

a schematic view of a refrigerant circuit with two parallel evaporators and a plurality of capillaries and

FIG. 4:

a schematic view of a refrigerant circuit according to the prior art.

FIG. 1 shows by the reference numeral 10 a compressor into which two separate suction lines 12, 14 open.

Downstream of the compressor 10 is the condenser 20. This is followed by the freezer evaporator 40th

Downstream of the freezer compartment evaporator 40, a branching point 100 is provided, of which firstly the suction line 12 and, secondly, a line 16 goes out, leading to the cooling part evaporator 30. Between the cooling part evaporator 30 and the compressor 10, the suction line 14 extends.

In the suction line 12 is the refrigerant collector 50, which prevents liquid refrigerant from entering the suction line 12.

In the compressor 10 is an unillustrated solenoid valve into which the ends of the suction lines 12, 14 open. The solenoid valve is thus not arranged in the suction line, but is located directly in the compressor 10 in its intake.

Like this FIG. 1 As can be seen, this is the only valve of the refrigerant circuit, ie, neither in the conduit system upstream nor downstream of the compressor, a further valve is arranged.

From the in FIG. 1 arrangement shown, the following advantages arise:

For the two illustrated evaporators 30, 40 different evaporation temperatures can be realized.

When the compressor starts, the valve is controlled so that the refrigerant flows through the cooling part evaporator 30. The liquid refrigerant that accumulates in the freezer compartment evaporator 40 during the service life of the compressor flows into the refrigeration section evaporator 30. The refrigerant evaporates in the refrigerated compartment evaporator 30, because there the temperature level is significantly higher than in freezer compartment evaporator 40, so that little or no liquid refrigerant gets to the compressor.

Due to the fact that the refrigerant is always injected only in the freezer evaporator, which is connected upstream of the refrigerator part evaporator, results in a higher freezing capacity. When storing a larger amount of warm goods in the refrigerator, the freezer temperatures are not affected.

Behind, ie downstream of the state of the art according to FIG. 4 known solenoid valve eliminates two solder joints, resulting in a simplification of the production of the refrigerant circuit and thus results in a cost advantage.

If the valve is switched in the compressor so that only the freezer evaporator 40, but not the cooling part evaporator 30 is flowed through by refrigerant, there is an optimized defrost in the cooling part evaporator 30, since this is sucked empty (pump-down).

FIG. 2 shows an embodiment in which the two evaporators 30, 40 are connected in parallel. Also in this embodiment, a solenoid valve is disposed neither in the pressure line, nor in the suction line. Rather, in this embodiment, the solenoid valve is located directly in the intake of the compressor 10th

In these open the two suction lines 12, 14, wherein the suction line 12 extends from the evaporator 30 to the compressor 10 and the suction line 14 from the evaporator 40 to the compressor 10.

Depending on the position of the valve, only one or only the other of the evaporators 30, 40 can be flowed through by refrigerant. Thus, each evaporator can be optimized for itself and adapted to the prevailing refrigerator temperature. With correspondingly faster timing of the valve or valves both evaporators can be flowed through at the same time, which is also included in the invention.

In particular, for such a system, the use of a variable-speed compressor 10 is advantageous. The cooling capacity and thus the compressor speed can be adapted to the compartment to be cooled. While in the case of a freezer part, a larger cooling capacity is necessary, the cooling part can be operated with a smaller cooling capacity and thus with a lower speed of the compressor.

The system also offers the advantage that a free-hanging evaporator can be used more easily in the cooling part and the cooling in the cooling part by the separate circuits is particularly advantageous.

Apart from that, one of the evaporators can be taken out of operation, e.g. the freezer evaporator, while the other evaporator can continue to operate.

This in FIG. 2 shown system offers in addition to the integration of the valve in the compressor the advantage that only one capillary 200 is required, which brings cost advantages, and that can be omitted by the elimination of a solenoid valve in the piping solder joints and that an optimized defrost can be done.

Downstream of the capillary 200, the line branches to the evaporators 30, 40, so that refrigerant can be supplied to both the evaporator 30 and the evaporator 40.

For example, if a flow through the one evaporator, the other sealed off by the valve of the compressor evaporator can be sucked empty, resulting in an optimized defrost.

A conceivable control algorithm is that, for example, a first compartment requiring cooling is cooled and the evaporator associated therewith is flowed through until the desired temperature has been reached in the first compartment and a compartment requiring a second cooling requirement is cooled and accordingly the evaporator associated therewith is flowed through until the desired temperature is reached in the second compartment.

By switching the valve quickly, a quasi-continuous flow through both evaporators can be achieved (parallel operation), which minimizes temperature fluctuations in the respective compartments. Corresponding advantages also arise for the in FIG. 2 and 3 illustrated embodiment.

This differs from the embodiment in FIG FIG. 2 in that downstream of the condenser 20 there is a branch 110, after which there are two capillaries 210, 220 which are each connected on the outlet side to the inlet side of the respective subsequent evaporators 30, 40.

For the two evaporators 30, 40, different evaporation temperatures can be realized.

Incidentally, with respect to the embodiment according to FIG. 3 on the comments too FIG. 2 Referenced.

The control of the at least one valve of the compressor can be effected by a control or regulating unit, not shown, which switches the valve in response to the prevailing refrigeration demand and thus allows or prevents a flow through the evaporator with refrigerant.

Claims (10)

Cooling and / or freezer with at least one first and at least one second evaporator and at least one in the flow direction of the refrigerant downstream of the evaporator compressor, characterized in that at least a first suction line from the first evaporator to the compressor and at least one second suction line of the second evaporator extends to the compressor and that in the compressor at least one valve is arranged, which is connected to one or both of the suction lines such that by means of the valve, the flow of refrigerant through one or both of said suction lines is variable. The refrigerator and / or freezer according to claim 1, characterized in that the first and the second evaporator are arranged in the refrigerant circuit such that the first evaporator, regardless of the valve position Always flows through refrigerant and the second evaporator is not flowed through in at least one valve position of refrigerant. The refrigerator and / or freezer according to claim 1 or 2, characterized in that the device has at least one freezer with at least one associated Gefrierteilverdampfer and at least one cooling part and / or cold storage compartment with at least one associated therefrom Kühlteil- / cold storage compartment evaporator and that the first or second evaporator is the freezer compartment evaporator and the first or second evaporator is the refrigeration compartment / cold storage compartment evaporator. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the first and the second evaporator are connected in parallel in the refrigerant circuit. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that in the flow direction of the refrigerant upstream of the evaporator at least one, preferably exactly one capillary is provided and that in the flow direction of the refrigerant downstream of the capillary at least one branch is provided, from which Lines between the capillary and the first evaporator and between the capillary and the second evaporator extend. Cooling and / or freezing appliance according to one of claims 1 to 4, characterized in that in the flow direction of the refrigerant upstream of the evaporator per evaporator at least one, preferably exactly one capillary is provided and that in the flow direction of the refrigerant upstream of the capillary at least one branch is provided from which leads extend to the capillaries. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the first and the second evaporator in such a way are arranged such that in the operating state in which an evaporator is flowed through by refrigerant and the other evaporator is shut off by the valve of the compressor, the evaporator shut off by the valve is partially or completely sucked empty. Refrigerating and / or freezing appliance according to one of the preceding claims, characterized in that at least one liquid separator is arranged in at least one of the suction lines and / or that there are no further valves in the refrigerant circuit, with the exception of the one or more valves of the compressor. Refrigerating and / or freezing appliance according to one of the preceding claims, characterized in that it is the valve is a solenoid valve and / or that it is the compressor to a variable-speed, preferably a variable speed compressor. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that it is the at least one valve to one or more multi-way valves or one or more stop valves.

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