DE19535144A1 - Domestic freezer with fast-freeze facility - Google Patents

Abstract

The freezer (10) has 2 separate storage compartments (12,13) with different capacities within a common thermally-insulated housing (11), provided with respective evaporators (21,26) which are connected in series. The evaporator (26) for the storage compartment with the greater capacity can be disconnected from the refrigeration circuit via a blocking valve (25) in the coupling line (24) between the evaporators, for acting as a reservoir for the refrigeration medium when the other compartment is operated in a fast-freeze mode.

Description

The invention relates to a refrigerator with at least two arranged within its housing, thermally from one another of separate freezer compartments, each one by one Evaporator is cooled, which via a connecting line are connected to each other in terms of flow and which Refrigerant can be applied via a control device are.

In the case of fresh food, which is caused by freezing over one should preserve for a longer period of time taking care to freeze this as soon as possible to undergo. To avoid the frozen food during of the freezing process due to insufficient freezing speed loss of quality, e.g. B. in the form of a ge suffered from tasty impairment is possible for one to ensure that the frozen goods freeze as quickly as possible.  

The invention has for its object a freezer to train according to the preamble of claim 1, that the freezing speed for frozen food is simple Way is significantly increased.

This object is achieved according to the invention in that the freezer compartments with different useful contents are equipped with the for cooling the freezer the larger usable evaporator by an in the connecting line arranged shut-off device the refrigerant flow can be decoupled and as a reservoir for liquid refrigerant.

The solution according to the invention means that Possibility created to cool the freezer with the lower useful content serving evaporator with the to operate compressors designed for both evaporators, whereby as a result of the oversize for this evaporator sional compressor the evaporation pressure and thus the Evaporation temperature in the for cooling the freezer with the lower usable evaporator sinks. This is the cooling capacity of this evaporator significantly increased and thus a much faster Freezing of freshly frozen food is possible. Furthermore, for the freezer compartment there is the smaller one Net capacity with the same thermal insulation of this subject a ge less heat, which also reduces evaporation temperature drops and thus the cooling capacity of the evaporator he increased.  

The following equation applies to the cooling capacity:

Q = K · A · Δ T

* Q = cooling capacity [W]
K = heat transfer coefficient [W / m²K]
A = freezer contact surface to heat exchange surfaces [m²]
Δ T = temperature difference between the frozen goods and the refrigerant to be evaporated.

The cooling capacity for the entire freezer is like this designed that the cheapest for the entire device according to the standard Energy consumption is achieved. Here is the compressor selected that he specified in the norms conditions with a favorable efficiency. The amount of refrigerant is also optimized Energy consumption matched. Furthermore, the two are freezers compartments of the freezer at the same time side by side drivable. In addition, the separation of the the larger useful content for cooling the freezer compartment Refrigerant located evaporator avoided that the Compressor can suck in liquid refrigerant and thus Takes damage.

One is particularly expedient and can be controlled in a time-optimized manner Shut-off device if according to an advantageous embodiment tion of the object of the invention is provided that as Locking device an electrically controllable shut-off valve til serves.

According to a preferred embodiment of the subject of Invention is provided that the shut-off valve in the Ver tie line essentially at the same time as the tax  medium when controlling the evaporator in the freezer less useful content from its pass mode in its Lock mode switches.

Such a solution ensures that only nor to operate the evaporator to cool the Freezer compartment with a smaller usable refrigerant remains in the refrigeration cycle, the amount of refrigerant in about evenly distributed over both evaporators, if the compressor stays in Dau for a certain period of time had been in operation.

According to a further preferred embodiment of the The object of the invention is that the verb cable to cool the freezer compartment Evaporator serving less useful content at least 50% from its refrigeration effective evaporator surface is technically connected.

In this way, the freezer compartment can be smaller Useful content during normal operation of the freezer, in which both freezer compartments are in the refrigeration cycle sufficient cooling, for example for a ** - Create freezer compartment.

According to a next preferred embodiment of the The object of the invention is that the Ankopp connection of the connecting line to the for cooling the freezer lower useful content serving evaporator on arranged upstream section of its evaporator surface is.  

By such a coupling of the connecting line read during normal operation, in which the Evaporators of both freezer compartments are in the refrigeration cycle, generate sufficiently low temperatures so that the freezer times less useful content even during normal operation bes as *** - freezer or **** - freezer application fin that can.

An additional increase in cooling capacity and thus the Freezing speed in the freezer compartment less useful content tes arises if after a further advantageous off design of the subject of the invention is provided, that a fan in the freezer with less useful content is arranged, which when driving the in this Freezer located evaporator by the control means is put into operation.

The Ver is particularly inexpensive to manufacture steamer system if after a next advantageous Ausge staltung the object of the invention is provided that the evaporator used to cool the freezer compartments in Flow direction of the refrigerant driven by the compressor each have a throttle to reduce its pressure upstream direction, which is essentially an iden table flow volume per unit of time.

The cooling capacity of the has a particularly high cooling capacity Freezer of larger useful content serving evaporators, if after a further advantageous embodiment of the Ge The object of the invention is provided that the coupling the connecting line to the for cooling the freezer compartment Larger useful evaporator on the outlet side  Section of an evaporator surface is arranged.

In a particularly simple manner with little effort control means for controlling the refrigerant both freezer compartments of the freezer can be operated if after a further preferred embodiment of the object the invention provides that the for cooling the Ge evaporator serving freezer capacity its control by the control means the other Ver steamer connected in series and with this over the connecting line is fluidly connected.

According to a further preferred embodiment of the counter state of the invention it is provided that the evaporator Cooling of the freezer compartments as a wire tube evaporator with in evaporator shelves arranged at different altitudes are trained.

Such a solution is a particularly inexpensive cold transmission to the frozen goods guaranteed.

Those for cooling the freezer are particularly space-saving Serving evaporator can be trained if after an old one native embodiment of the subject of the invention can be seen that the evaporators for cooling the freezer compartments are designed as evaporator boards.

According to a last preferred embodiment of the counter state of the invention it is provided that the freezer with the lower useful content in the housing of the freezer arranged above the freezer compartment with the larger usable content is.  

A solution according to these features has the advantage that ne ben a relieved loading of the to the faster dispensing freezer serving the freezer compartment Useful content a significantly cheaper access to control the freezing condition of the frozen food is created.

The invention is described in the following description one shown in simplified form in the accompanying drawing Embodiment explained. Show it.

Fig. 1 shows a household freezer in a schematic representation with two thermally separated from each other, a different useful content on pointing freezer compartments, with evaporators arranged therein and a refrigerant circuit for their supply with refrigerant with a magnetic valve in a first, both evaporators in series with Working position and refrigerant

Fig. 2 shows the household freezer according to Fig. 1, but the solenoid valve in its second, only the evaporator in the freezer lower useful content with refrigerant working position.

In Fig. 1, a purely schematically illustrated household freezer 10 is shown, in the heat-insulating housing Ge 11 two superposed freezer compartments 12 and 13 are provided. These are thermally separated from one another by a heat-insulating intermediate shelf 14 and have a useful content of different sizes, the freezer compartment 12 equipped with the lower useful content being arranged at the top.

The household freezer 10 is equipped with a refrigeration system 15 , which has a designed for simultaneous cooling of the two freezer compartments 12 and 13 Käßmittelver 16 . A condenser 17 is connected on the pressure side to the refrigerant compressor 16 and is connected on the outlet side to a 3/2-way solenoid valve 18 which can be electrically controlled as a control means. The Ma solenoid valve 18 , which is controlled by an electronic evaluation circuit depending on the temperature prevailing in the freezer compartment 13 and can be brought into two different working positions I and II, has at its two outputs each one to reduce the pressure flowing from the condenser 17 flowing refrigerant serving throttle tubes 19 and 20 , which are spiral-shaped and which have an identical flow resistance for liquid refrigerant. The throttle tube 19 is the Zulaufsei te provided as an evaporator board, arranged in the freezer 12 evaporator 21 , the Kältemit tel-channel arrangement 22 is formed in turns on the evaporator board. The evaporator 21 is connected on the outlet side to the suction side of the refrigerant compressor 16 and, on its inlet side facing the throttle tube 19, has a connection point 23 arranged near its refrigerant injection point (not shown). This is used for fluidic connection of the refrigerant channel arrangement 22 of the evaporator 21 to a connecting line 24 , the flow cross section of which can be blocked by a shut-off valve designed as an electrically controllable shut-off valve 25 . Due to the refrigeration connection of the United connecting line 24 to the refrigerant channel arrangement 22 of the evaporator 21 , liquid refrigerant from the connec tion line 24 is almost over 100% of the refrigeration effective men evaporator surface of the evaporator 21 , so that a high cooling capacity is generated for this. The evaporator 21 is connected in terms of flow technology via the connecting line 24 to an evaporator 26 which is arranged in the freezer compartment 13 and is also in the form of a plate. To connect the Ver connecting line 24 to the evaporator 26 is provided 28 while the inlet-side end of the refrigerant channel arrangement 27 verbun with the throttle pipe 20 the on auslaufseiti towards the end of its refrigerant channel arrangement 27 constitutes a terminal.

In Figs. 1 and 2, different operating states are characterized by reinforced solid Li nien of the household-Ge freezing cabinet 10 and the refrigeration system 15 shown, wherein the operation state shown in Fig. 1 shows the normal operation in which the solenoid valve 18 in its working Stel lung II and the shut-off valve 25 is operated in its pass mode, so that the evaporator 26 in the freezer compartment 13 is connected to the evaporator 21 in the freezer compartment 12 in series connection. In this working position II of the Magnetven valve 18 , the refrigerant generated by the refrigerant compressor 16 refrigerant flow to its pressure reduction on the evaporator-specific operating pressure of the evaporator 26 is supplied to the throttle tube 20 , from where it is arranged via the injection point, not shown, of the evaporator 26 in its refrigerant channel 27 overflows. At the outlet end of the refrigerant channel arrangement 27 , the refrigerant flow enters the connecting line 24 via the connection point 28 and is supplied via the connection point 23 to the refrigerant channel arrangement 22 of the evaporator 21 , from where it is in gaseous form on the outlet side of the refrigerant channel arrangement 22 State is sucked in from the suction side of the refrigerant compressor 16 . Due to the working position II of the solenoid valve 18 , both evaporators 21 and 26 are charged with liquid refrigerant, so that the freezer compartments 12 and 13 reach their intended operating temperature.

After the household freezer 10 has been operating for some time in its "normal operation", which cools both freezer compartments 12 and 13 , the liquid refrigerant is distributed approximately uniformly in the evaporator system, consisting of the evaporator 21 and the evaporator 26 . If the solenoid valve 18 is now switched to its working position I by the manual actuation of an electrical switch (not shown) for the purpose of a rapid freezing process in the freezer compartment 12 , with the shut-off valve 25 passing into its blocking operation simultaneously with the switching operation of the solenoid valve 18 , this is in the evaporator 26 located liquid refrigerant from the refrigeration circuit of the refrigerant compressor 16 uncoupled. The refrigerant compressor 16 , which is designed per se with regard to its delivery volume to the supply of both evaporators 21 and 26 with liquid refrigerant, is operated in a largely underfilled manner. This manifests itself in a strong reduction in the evaporation pressure for the refrigerant and thus a significant reduction in the evaporation temperature, which is additionally influenced by the lower heat input due to the lower useful content of the freezer compartment 12 . The liquid refrigerant remaining in the refrigerant circuit is fed from the refrigerant compressor 16 via the solenoid valve in its working position I to the throttle tube 19 , from where it passes through the unillustrated injection point of the evaporator 21 , which is only in the refrigeration circuit with the compressor 16 , to the refrigerant channel arrangement 22 of the evaporator 21 is supplied, from where it is supplied via the outlet side of the refrigerant channel arrangement 22 to the suction side of the compressor 16 .

In the event that during the freezing process in Ge freezer compartment 12, the temperature in the freezer compartment 13 rises to an inadmissibly high level, the solenoid valve 18 is switched by a temperature evaluating the temperature in the freezer compartment 13 , electronic evaluation circuit (not shown) in its working position II, whereby the evaporator 26 for cooling the Ge freezer 13 is coupled back into the refrigerant circuit.

After the freezer temperature required for rapid freezing in the freezer compartment 12 has been reached, the electronic evaluation circuit switches the two control means in their operating state which acts on refrigerant with both refrigerators 12 and 13 .

Contrary to the exemplary embodiment described, the evaporators 21 and 26 can also be designed as a wire tube evaporator with evaporator stages arranged at different heights.

To increase the freezing speed in the freezer compartment 12 , a cooling air circulating ventilator can also be provided, which results in a more favorable heat transfer from the evaporator 21 to the stored food in the freezer.

Good freezing speeds for the frozen food in the freezer compartment 12 have already been obtained when its useful content is less than or equal to one fifth of the useful content of the freezer compartment 13 .

Claims (12)

1. Freezer with at least two arranged within its heat-insulating housing, thermally voneinan of the separate freezer compartments, each of which is cooled by an evaporator, which are fluidically connected to one another via a connecting line and which can be acted upon by a control means with refrigerant, characterized in that the freezer compartments ( 12 , 13 ) are equipped with different useful contents, the evaporator ( 26 ) serving to cool the freezer compartment ( 13 ) with the larger useful contents being able to be coupled out of the refrigerant flow through a shut-off device arranged in the connecting line ( 24 ) and as a reservoir for liquid refrigerant. 2. Freezer according to claim 1, characterized in that an electrically controllable shut-off valve ( 25 ) serves as the shut-off device. 3. Freezer according to claim 1 or 2, characterized in that the in the connecting line ( 24 ) arranged shut-off valve ( 25 ) substantially at the same time as the control means when it controls the evaporator ( 21 ) in the freezer ( 12 ) less useful content of his pass mode in his blocking mode switches. 4. Freezer according to one of claims 1 to 3, characterized in that the connecting line to the for cooling the freezer compartment ( 12 ) with lower useful content evaporator ( 21 ) at least 50% of its refrigeration-effective evaporator surface is technically tied. 5. Freezer according to one of claims 1 to 4, characterized in that the coupling of the connecting line device ( 24 ) to the cooling device for cooling the freezer compartment ( 12 ) serving useful content evaporator ( 21 ) is arranged on the upstream portion of its evaporator surface. 6. Freezer according to one of claims 1 to 5, characterized in that in the freezer compartment ( 12 ) less useful content a fan is arranged, which in the control of the in this freezer compartment ( 12 ) located evaporator ( 21 ) ge by the control means in operation is taken. 7. Freezer according to one of claims 1 to 6, characterized in that the cooling for the freezer compartments ( 12 , 13 ) serving evaporators ( 21 , 26 ) in the flow direction of the refrigerant driven by the compressor ( 16 ) means a throttle serving to reduce the pressure device ( 19 , 20 ) is connected upstream, which essentially have an identical flow volume per unit time. 8. Freezer according to one of claims 1 to 7, characterized in that the coupling of the Verbindungslei device ( 24 ) to the cooling device for cooling the freezer compartment ( 13 ) serving greater useful content evaporator ( 26 ) is arranged on the outlet-side section of its evaporator surface. 9. Freezer according to one of claims 1 to 8, characterized in that the serving for cooling the freezer compartment ( 13 ) larger useful content evaporator ( 26 ) upstream of the other evaporator ( 21 ) in its connection by the control means and connected with this via the Connecting line ( 24 ) is technically connected. 10. Freezer according to one of claims 1 to 9, characterized in that the evaporators ( 21 , 26 ) for cooling the freezer compartments ( 12 , 13 ) are designed as a wire tube evaporator with arranged in different heights Verdampfereta geren. 11. Freezer according to one of claims 1 to 9, characterized in that the evaporators ( 21 , 26 ) for cooling the freezer compartments ( 12 , 13 ) are formed out as evaporator boards. 12. Freezer according to one of claims 1 to 11, characterized in that the freezer compartment ( 12 ) with the gerin Geren useful content in the housing ( 11 ) of the freezer ( 10 ) above the freezer compartment ( 13 ) is arranged with the greater useful content.