DE102008047818A1 - Refrigerator/freezer for refrigerating foodstuffs, has temperature zones operating as refrigerating and freezer zones, and capillary pipes attached to outlets of valve, where two pipes include identical lengths and identical flow rates - Google Patents

Abstract

The refrigerator/freezer has temperature zones operating as refrigerating zones and freezer zones. A compressor (80) includes a magnet valve (40) and two vaporizers (60, 70), where three capillary pipes (50, 52, 54) are attached to respective outlets (42, 44) of the magnetic valve. The two of the three capillary pipes include identical lengths and identical flow rates. One of the vaporizers is switchable between the refrigerating zones and the freezer zones by an input unit i.e. touchscreen. An operating condition of the refrigerator/freezer is displayed via an output unit i.e. LED. An independent claim is also included for a method for operating a refrigerator/freezer with temperature zones.

Description

The The present invention relates to a refrigerator and / or freezer with at least two temperature zones and a method for operating such Refrigerator and / or freezer.

So far known cooling and / or freezers if provided as a combi unit executed in her inner container a cooling part or a cooling zone and, mostly underneath, a freezer compartment or a freezer compartment. In this case, both the freezer compartment and the refrigerator part is associated with an evaporator. When A disadvantage of this arrangement, however, proves that in the refrigerator section So far, only temperatures were achievable, for the cooling of z. Food suitable, but not for a freezing zone are sufficient.

This however means a limitation of Variability, because the user does not meet his needs Storage space inside the refrigerator and / or freezer can exploit. The user is limited to the factory default storage size for cooling zone and Freezing zone limited.

It is therefore the object of the present invention, a cooling and / or freezer of the type mentioned in an advantageous manner on, in particular to the effect that it can be used more variably.

These The task is performed by a cooling and / or freezer solved with the features of claim 1. After that it is planned that a cooling and / or freezer has at least two temperature zones, wherein at least one Temperature zone both as a cooling zone as well as a freezing zone is operable. A temperature zone can in this context, for example, by the cooling part or the freezer compartment of a refrigerator and / or freezer be formed, it may as well as a preferably separate area within a refrigerator or freezer section, the for taken a separate cooling zone or freezing zone. In particular, there is the advantage that a cooling and / or freezer can be used much more variably than previously known cooling devices have made possible because now the user is free to demand cooling zones and freezing zones within the cooling and / or freezer to dispose of. For example, in this context, it is conceivable that for the storage of larger quantities Frozen goods the normally provided storage space in Freezing compartment or in the freezing zone is not sufficient, so that the user is now able to the storage space of the freezing zone to increase, by the so far at least partially operated as a cooling zone cooling area switched to freezing operation.

From Advantage is when the cooling and / or freezer at least one compressor, at least one solenoid valve and at least having two evaporators. This gives the advantage that no special components and / or special electronics are used have to. Advantageously, it is thus possible already existing and proven components, such. B. Solenoid valves and electronic systems use.

It can be provided that the coolant circuit upstream the at least one solenoid valve has a dryer and a condenser.

Furthermore Is it possible, that the coolant circuit has at least three capillary tubes. By means of these capillary tubes can the coolant led to the evaporators become.

From It is advantageous if the capillary tubes at the at least one outlet of the solenoid valve are connected.

Of Furthermore, it can be provided that the solenoid valve has two solenoid valve outputs, wherein the first Solenoid valve output is connected to a first capillary tube and at the second solenoid valve output, the second and third Kapillarroh are connected. This results in the advantage, as needed on the Capillary tubes coolant in Cooling circuit to distribute. For example, it can be achieved that, depending on cooling requirements one, two or three capillary tubes lead coolant. Basically it is possible connect several capillary tubes to the solenoid valve outputs, preferably three or more capillary tubes at the second solenoid valve output.

Further It is conceivable that at least two capillary tubes of the same length and have the same flow. This allows a uniform pressure and flow distribution can be achieved.

Especially it is advantageous if the second and the third capillary tube, which are connected to the second solenoid valve output, the same Length and have the same flow. This results in the advantage that, for example, in a switching state of the solenoid valve, wherein the first solenoid valve with connected first capillary tube is closed and wherein the second solenoid valve output open is, the second and the third capillary tube, which are thus parallel are switched, inject the same amount of coolant, preferably in the respective evaporator.

Furthermore, it can be provided that the first and second capillary tubes lead to a first evaporator associated with a freezing zone and the third capillary tube leads to a second evaporator associated with the temperature zone operable both as a cooling zone and as a freezing zone. This results in the advantage that due to the aforementioned arrangement, a parallel coolant injection for the first and second evaporator is possible, but not every evaporator is individually connected to a suction pipe on the compressor, but the Kühlteilverdampferausgang is connected to the Gefrierteilverdampferereingang. Furthermore, the suction pipe is connected to the outlet of the freezer. By this series connection of the evaporator with only a single suction pipe connection thus the well-known problem of refrigerant displacement can be solved. In addition, the problem of the heating of the freezer compartment or the freezer compartment, which occurs during a series injection of coolant into the refrigerator compartment, is prevented by the parallel injection. Thus it is prevented, as is the case with standard devices, however, that the heat absorbed in the cooling part is transported through the freezer part, with the result that the freezer part would heat up. However, this is advantageously not the case in the aforementioned embodiment. In the parallel injection thus coolant is injected simultaneously into the evaporator, which is associated with a cooling zone, as well as in the evaporator, which is associated with a freezing zone, in parallel, thus preventing heating in the freezing zone.

Furthermore is possible, in that input means are provided, by means of which the second evaporator between the operating modes as a cooling zone and Freeze zone is switchable and / or output means, by means of which the operating state can be displayed. The input means can hereby exist in a shift key. After that is conceivable, the output means as an LED display, which indicates the respective operating state. It's just as good conceivable that the input and output means, for example, in a Touch screen or a display with associated keys are executed, so that the user can easily and intuitively between the operating modes can switch or the respective operating state of the temperature zones can show.

Further is possible, that the cooling and / or freezer one defrost heater each for having the evaporator. As a result, the efficiency of the cooling and / or freezer increase. Furthermore, there is the advantage that the evaporator z. In regular intervals or to defrost automatically when needed, without the user must intervene.

The The invention further relates to a method for operating a Cooling and / or freezer with the features of claim 12. Thereafter, it is provided that at a cooling and / or freezer at least one temperature zone with at least two temperature zones in a first operating mode as a cooling zone and in a second Operating mode is operated as a freezing zone.

there Is it possible, that the at least two temperature zones each have an evaporator is assigned, wherein the coolant the evaporators at least partially by means of parallel injection supplied becomes. As a result, the well-known problem of refrigerant displacement solved become. The series connection of the evaporator to each other, so that one evaporator outlet with the evaporator inlet of the other Vaporizer, prevents the evaporator, which is associated with the freezing zone, unintentionally deposits refrigerant.

Of Furthermore, it can be provided that the coolant circuit at least a solenoid valve and at least two capillary tubes, the are connected to a solenoid valve output and each to one Lead evaporator, the coolant with the same pressure and flow rate through the capillary tubes flows. As a result, the effect of the parallel injection is enhanced since a uniform pressure and flow distribution of the coolant can be adjusted in the capillary tubes. The parallel injection allows one particularly advantageous, because simple and efficient design the method according to the invention. For example, this can mean the same cooling capacity in both zones be achieved because the respective evaporator in parallel with the same Amount of coolant be supplied.

Prefers It will, if it is in the conduct of the procedure to operate a cooling and / or freezer a cooling and / or freezer according to one of the claims 1 to 11 acts.

Further Details and benefits will now be based on one in the single Figure illustrated embodiment be explained in more detail.

The single figure shows an embodiment a refrigerant circuit according to the invention for a cooling and / or Freezer, preferably a combination device.

The coolant circuit 10 a cooling and / or freezing appliance, not shown, in this case has a condenser in its lower region 20 on, from which the coolant via the connecting line 22 to the dryer 30 to be led. The coolant leaves the dryer 30 over the connecting line 32 leading to the solenoid valve 40 leads.

The solenoid valve 40 has two outputs in the embodiment shown here 42 and 44 on, where the capillary tubes 50 . 52 and 54 are connected. It is at the first solenoid valve output 42 a first capillary tube 50 connected to the evaporator inlet 72 of the evaporator 70 communicates. Here is the evaporator 70 associated with a freezing zone.

At the second solenoid valve output 44 are parallel the capillary tubes 52 and 54 connected, each having the same length and the same flow. This will ensure that through the capillary tubes 52 and 54 the same amount of coolant can be injected.

The capillary tube 52 also performs like the capillary tube 50 to the evaporator entrance 72 of the evaporator 70 which is associated with a cooling zone. The third capillary tube 54 leads coolant to the evaporator inlet 62 of the evaporator 60 which is associated with a temperature zone which can be operated both as a cooling zone and as a freezing zone. The evaporator 60 has at its lower end the outlet 64 on top of which the evaporator 60 flowed through coolant via the line 66 to the evaporator inlet 72 of the evaporator 70 is supplied.

This results in the following arrangement: In the case where the solenoid valve output 44 opens, coolant is parallel and evenly over the capillary tubes 52 and 54 simultaneously via the evaporator inlets 62 and 72 the evaporators 60 and 70 fed. About the line 66 also gets coolant from the evaporator 60 to the evaporator 70 guided. At the same time, however, is prevented by the parallel injection, that the freezing zone, which is the evaporator 70 is assigned, heated. However, the series connection further prevents the refrigerant from being displaced. The coolant leaves the evaporator 70 over the evaporator outlet 74 and the line 76 and will be over the line 76 the compressor 80 fed. The coolant will go over the line after exiting the compressor 82 supplied to the condenser, whereby the prescribed path of the coolant in the coolant circuit 10 starts again.

In the case where the solenoid valve output 42 is open, only the evaporator 70 supplied with coolant. This is particularly advantageous when the the evaporator 60 associated temperature zone is operated as a cooling zone, which does not require constant cooling.

As a further circuit is conceivable that both the solenoid valve output 42 as well as the solenoid valve output 44 are open. For this purpose, if necessary, the solenoid valve 40 adapt.

The user can now operate the refrigerator and / or freezer as follows:
The refrigerator and / or freezer, preferably designed as a combined appliance, has two temperature zones, wherein at least one temperature zone is operated as a cooling zone in a first operating mode and as a freezing zone in a second operating mode. Depending on requirements, the refrigerator section can also be operated as a freezer compartment.

This is made possible by the fact that the at least two temperature zones, ie the cooling part and the freezer part, each an evaporator 60 . 70 is assigned, wherein the coolant the evaporators 60 . 70 is supplied by parallel injection. In combination of parallel injection into the evaporator 60 . 70 and the series connection of the evaporator 60 . 70 to each other, so that the one evaporator output 66 with the evaporator inlet 72 the other evaporator 70 Connected, that is achieved in the evaporator 60 , which is assigned to the cooling zone, absorbed heat, which is a heat flow through the evaporator 70 , which is associated with the freezing zone, is transported by the separate or parallel injection of coolant into the evaporator 70 is compensated. At the same time, the generally known problem of refrigerant displacement is solved by this embodiment of the method.

In the first operating mode, in which the refrigerator and / or freezer, which is preferably designed as a combination appliance, is operated with a refrigerating section and a freezer compartment, it is possible, for reasons of efficiency, to maintain the freezing temperature in the freezer compartment via the first capillary tube 50 Coolant in the evaporator associated with the cooling part 70 be injected. The solenoid valve 40 that the capillary tubes 50 . 52 . 54 of the coolant circuit 10 locks or releases, is connected in this case such that the first solenoid valve input 42 is open while the second solenoid valve output 44 Is blocked.

The solenoid valve 40 is controlled by a device control and regulation unit, not shown. The temperature in the respective zones, that is to say in the first operating mode with cooling zone and freezing zone, is monitored by the device control and regulation unit by means of sensor elements which are not shown in greater detail.

In the first operating mode, as far as necessary to maintain the cooling temperature in the cooling section, the solenoid valve output is provided by the device control and regulation unit 44 open.

The Switching from the first to the second operating mode and vice versa is preferably done by user input, the corresponding Input via z. As a touch screen or a keypad or an Enter key can be entered. The operating mode is determined by the device control and control unit recorded and provided for this storage means stored.

in the second operating mode are then, for example, based on the controlled variable temperature in lower freezer compartment and upper freezer compartment, formerly as a cooling part operated by the device control and control unit monitored and both temperature zones operated in the freezing mode.

This is done by opening the solenoid valve outlet 44 parallel and even coolant into the evaporator 60 and 70 injected so in both of these evaporators 60 and 70 associated temperature zones freezing temperatures prevail. By means of the line 50 may need coolant in the evaporator 70 be supplied to a heat input through the evaporator 60 compensate for coming coolant. For this purpose, it may be provided, for example, depending on the determined actual temperatures in the respective temperature zones, that the device control and regulation unit either has both solenoid valve outputs 42 . 44 releases or in the meantime the solenoid valve output 44 locked and at the same time the solenoid valve output 42 is released.

Claims (15)

Cool- and / or freezer with at least two temperature zones, wherein at least one temperature zone both as a cooling zone as well as a freezing zone is operable. Cooling and / or freezing appliance according to claim 1, characterized in that the refrigerator and / or freezer at least one compressor ( 80 ), at least one solenoid valve ( 40 ) and at least two evaporators ( 60 . 70 ) having. Cooling and / or freezing appliance according to claim 2, characterized in that the coolant circuit ( 10 ) upstream of the at least one solenoid valve ( 40 ) a dryer ( 30 ) and a liquefier ( 20 ) having. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the coolant circuit ( 10 ) at least three capillary tubes ( 50 . 52 . 54 ) having. Cooling and / or freezing appliance according to claim 4, characterized in that the capillary tubes ( 50 . 52 . 54 ) to the at least one outlet of the solenoid valve ( 40 ) are connected. Cooling and / or freezing appliance according to claim 4 and 5, characterized in that the solenoid valve ( 40 ) two solenoid valve outputs ( 42 . 44 ), wherein at the first solenoid valve output ( 42 ) a first capillary tube ( 50 ) and at the second solenoid valve output ( 44 ) the second and third capillary tubes ( 52 . 54 ) are connected. Cooling and / or freezing appliance according to one of claims 4 to 6, characterized in that at least two capillary tubes ( 52 . 54 ) have the same length and the same flow. Cooling and / or freezing appliance according to claim 7, characterized in that the second and the third capillary tube ( 52 . 54 ) at the second solenoid valve output ( 44 ) are connected, have the same length and the same flow. Cooling and / or freezing appliance according to one of claims 6 to 8, characterized in that the first and second capillary tube ( 50 . 52 ) to a first evaporator ( 70 ) associated with a freezing zone and the third capillary tube ( 54 ) to a second evaporator ( 60 ) associated with the temperature zone which is operable both as a cooling zone and as a freezing zone. Cooling and / or freezing appliance according to claim 9, characterized in that input means are provided, by means of which the second evaporator ( 60 ) is switchable between the operating modes as a cooling zone and freezing zone and / or output means by means of which the operating state can be displayed. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the refrigerator and / or freezer each have a defrost heater for the evaporator ( 60 . 70 ) having. Method for operating a refrigerator and / or freezer with at least two temperature zones, wherein at least one temperature zone in a first operating mode as a cooling zone and in a second Operating mode is operated as a freezing zone. Method for operating a refrigerator and / or freezer according to claim 12, characterized in that the at least two temperature zones each have an evaporator ( 60 . 70 ), the coolant being supplied to the evaporators ( 60 . 70 ) is supplied at least partially by means of parallel injection. Method for operating a refrigerator and / or freezer according to claim 12 or 13, characterized in that the coolant circuit ( 10 ) at least one solenoid valve ( 40 ) and at least two capillary tubes ( 52 . 54 ) connected to a solenoid valve output ( 44 ) are connected and each to an evaporator ( 60 . 70 ), wherein the coolant at the same pressure and flow rate through the capillary tubes ( 52 . 54 ) flows. Method according to one of claims 12 to 14, characterized that it is a cooling and / or freezer according to one of the claims 1 to 11 acts.