DE102023107225A1 - Vacuum-insulated refrigerator and/or freezer - Google Patents

Abstract

The present invention relates to a refrigerator and/or freezer with a vacuum-insulated body and a cooled interior located in the body, which has at least two compartments that can be operated at different temperatures. The device has a single evaporator and at least one flow channel, which is designed to guide air from a first compartment for cooling a second compartment along at least one wall of the second compartment and then return it to the first compartment.

Description

The present invention relates to a refrigerator and/or freezer with a vacuum-insulated body and a cooled interior located in the body, which has at least two compartments that can be operated at different temperatures.

Household refrigeration appliances, in which a significant part of the insulation effect is provided by vacuum insulation, are increasingly in focus due to growing energy efficiency requirements. The use of vacuum insulation also has consequences for the design of the refrigeration system.

Due to the vacuum insulation, the requirement for cooling capacity in the cooled state (which is crucial for the energy consumption of the device) is low. Nevertheless, high cooling capacities must be available under load, although losses in efficiency may be accepted here.

• Geräte gemäß der ersten Konfiguration verfügen über einen zwischen Kühlteil und Gefrierteil angebrachten Verdampfer, der über Luftregelung sowohl Luft aus dem Kühlteil als auch aus dem Gefrierteil abkühlen kann, wobei die in der Luft enthaltene Feuchte am kalten Verdampfer kondensiert. Da die Lufträume von Kühl- und Gefrierteil dabei nicht getrennt sind, kann es zu Geruchsübertrag zwischen den Kompartimenten kommen, außerdem wird die Luft auf Gefrierteiltemperatur getrocknet, wodurch im Kühlteil eine sehr geringe Luftfeuchte herrscht, was bei offener Lagerung von Lebensmitteln zu deren Austrocknung führt.

From the state of the art, there are mainly two relevant configurations for refrigeration in fridge-freezer combinations:

• Devices in the first configuration have an evaporator installed between the refrigerator and freezer compartments, which can cool air from both the refrigerator and freezer compartments via air control, with the moisture contained in the air condensing on the cold evaporator. Since the air spaces between the refrigerator and freezer compartments are not separated, odors can be transferred between the compartments. In addition, the air is dried to freezer compartment temperature, which means that there is very low humidity in the refrigerator compartment, which leads to food drying out when stored openly.

The second common configuration involves devices that have two evaporators, which can be controlled separately with refrigerant, e.g. using a solenoid valve, allowing the two compartments of the device to be controlled independently.

However, these conventional solutions severely limit the arrangement of the refrigeration technology in the device and require, for example, that the evaporator cannot be arranged as a replaceable module on the floor or ceiling of the device, as the refrigeration technology must be attached to the rear wall of the device. Furthermore, in the first configuration, for example, the evaporator must be located between the compartments, as otherwise moist air from the cooling part would have to flow through areas that are at temperatures below freezing on the way to the evaporator, where ice would build up.

The present invention is based on the object of mitigating or completely eliminating the disadvantages of the prior art. In particular, the present invention is based on the object of enabling a cost-effective and flexible possibility of arranging the refrigeration technology, which, for example, allows the evaporator to be arranged in the base of the device.

This object is achieved by a refrigerator and/or freezer with the features of claim 1. Further advantageous modifications of the invention are the subject of the subclaims.

According to this, it is provided that the refrigerator and/or freezer has a single evaporator and a flow channel which is designed to guide air from a first compartment (e.g. a freezer compartment, also referred to as freezer part) for cooling a second compartment (e.g. a refrigerator compartment, also referred to as refrigerator part) along at least one wall of the second compartment and then return it to the first compartment.

The air cooling the freezer compartment can thus be used to cool the refrigerator compartment without the need for a second evaporator or for an exchange of air between the freezer compartment and the refrigerator compartment.

According to one embodiment, the device (preferably) has a single fan with which air can be moved through the flow channel. In addition, a flow control element is preferably arranged in the flow channel, which can be designed, for example, in the form of a movable slide or a movable flap and with which the air flow in the flow channel can be divided into the first and second compartments. The air flow can thus be divided into channel areas of the first and second compartments.

According to one embodiment, the device further comprises a control unit which is designed to control the flow control element to distribute the air flow to the compartments or to the channels assigned to them depending on the reported cooling requirements of the compartments.

It is thankful that the air flow supplied to the freezer compartment is more than twice as large, preferably more than three times as large as a portion of the air flow that can be fed to a cooling compartment.

In other words, control is preferably carried out in such a way that the proportion of the air flow generated by the fan which does not run, for example, in a flow channel along the cooling part wall is at least twice as large, preferably more than 3 times as large, as the proportion which runs along the cooling part wall.

According to one embodiment, the flow channel runs in a wall of the cooled interior or on a wall of the cooled interior behind a shield. The flow channel is preferably located in front of a vacuum insulation element in the direction of the cooled interior. A device according to the invention can also have several flow channels or a branched flow channel.

According to one embodiment, the flow channel extends over a large part of the surface of the wall, preferably over a proportion of 60% to 100%, preferably between 75% and 100%, in particular between 80% and 100% of the surface of the wall. In this way, the largest possible proportion of the surface of the wall can be used for heat exchange and for cooling the compartment.

According to one embodiment, the shield is made at least partially from metal and/or plastic and seals the flow channel hermetically against the interior of the compartment. For example, the shield can be a plate made from metal and/or plastic. The use of metal facilitates heat exchange and offers a particularly high-quality appearance.

Preferably, the flow channel and a separating plate separating the at least two compartments are also designed in such a way that an exchange of air between the compartments is avoided.

According to one embodiment, the flow channel runs embedded in a rear wall of a compartment operable as a cooling compartment and is designed to initially guide air coming from a compartment operable as a freezing compartment upwards in the rear wall of the cooling compartment and then preferably downwards on both sides back to the freezing compartment.

Alternative air flow patterns are of course conceivable: The air can be returned to the freezer compartment on one side and the flow channel is not limited to a rear wall of the compartment. The air can be returned on both sides or on one side of the rear wall and/or one or both side walls of a compartment. The flow channel can also use the entire or substantially entire surface of a rear wall of the compartment to introduce air and the air can be returned on the entire or substantially entire surface of one or both side walls of the compartment. The flow channel can also have one or more branches.

According to one embodiment, the flow channel is designed to introduce air coming from a cooling compartment into an air flow associated with a freezing compartment in the direction of the air flow.

This increases the introduction of air through the Bernoulli effect and the resulting suction effect of the air in the channel into which it is introduced.

The flow channel can be designed such that in the region of the introduction of the air coming from the cooling compartment into the air flow associated with the freezing compartment, the flow velocity of the air flow associated with the freezing compartment is locally increased.

A refrigerator and/or freezer according to the invention is preferably fully vacuum insulated. Preferably, the cooled interior of the device is thus essentially completely surrounded by a vacuum insulation element (with the door closed). For example, the body of the device can each have a vacuum insulation element, for example in the form of a plate, on the side walls, the base plate and the ceiling. The door of the device also preferably has such a vacuum insulation element. In principle, a single vacuum insulation element can also be provided, which forms the body. In this case, the vacuum insulation element can have the shape of a box or trough.

It should be noted at this point that when the articles "a" and "an" are used in this disclosure, they are not necessarily to be interpreted as "exactly one". Thus, if an element is mentioned in the singular, the present disclosure also includes embodiments with this element in the plural, and vice versa.

It should also be noted that the present disclosure is not limited to the feature combinations and embodiments explicitly mentioned therein. It is therefore self-evident to the person skilled in the art that the The features mentioned in the following disclosure may also be claimed in other combinations or in isolation.

Further details and advantages of the invention are explained in more detail with reference to an embodiment shown in the drawing.

• 1: einen Querschnitt durch ein Kühl-und Gefriergerät gemäß einer Ausführungsform der Erfindung, und
• 2: einen zweiten Querschnitt durch das Kühl-und Gefriergerät gemäß 1 1.

Show it:

• 1 : a cross section through a refrigerator and freezer according to an embodiment of the invention, and
• 2 : a second cross-section through the refrigerator and freezer according to 1 1.

Preferably, a refrigeration technology with base module 2 for a vacuum-insulated fridge-freezer combination 1 is realized by guiding cold air 3 from the freezer compartment 4 along the walls 5 of the refrigerator compartment 6 without there being an exchange of air between the two compartments 4, 6.

• Zunächst liegt im Gefrierteil 4 des Geräts der Verdampfer 7 vor.

The concept is illustrated by the example in the drawing:

• First, the evaporator 7 is located in the freezer compartment 4 of the appliance.

The base module 2 is an exchangeable module underneath the thermal insulation, which contains the other refrigeration technology and is arranged in the base 8 of the device 1 between its base surface 9 and the freezer section 4. The device 1 has a body 10 which is vacuum-insulated. The compartments 4 and 6 are equipped with doors 11 and 12 which are also vacuum-insulated. The compartments 4 and 6 are separated from one another by means of a partition plate 13.

A fan 14 forces the air over the evaporator 7 arranged on the floor and into an air duct 15 on the rear wall of the device.

For manufacturing reasons, it may be advantageous to provide a continuous inner container and/or body that forms the inner wall for both the refrigerator and freezer sections. In this case, the compartments are preferably separated by a subsequently mounted partition plate 13, which is designed in such a way that even in the most unfavorable operating mode, temperatures below 0°C are not present above the partition plate 13, in order to prevent food from freezing in the refrigerator section.

In the area of this partition wall 13, an adjustable flap 16 is provided in the flow channel or air channel 15, which, when closed, directs the air flow coming from below to the front (in the direction of arrow 17), where it enters the freezer compartment 4 from above.

When the flap 16 is opened, part of the air flow (in the direction of the arrows 20) is directed into a further air duct 18 and guided along the rear wall of the cooling part 6.

In the example in the drawing, an attached rear wall 19 is installed in the cooling area, which can be made of metal, but preferably of plastic. This attached rear wall 19 seals tightly against the air duct 18, so that no air from the freezer section 4 can penetrate into the cooling section 6.

The cold air cools the attached rear wall 19, which in turn serves as a rear wall heat exchanger that regulates the temperature of the cooling compartment 6.

It is advantageous to use as much of the rear wall as possible as a heat exchanger surface in order to provide sufficient power reserves even when there is a high cooling demand in the refrigerator section 6. In addition, the flow conditions should be balanced, since preferably only the freezer section fan 14 ensures the air flow in all areas.

In the example in the drawing, the air flow (in the figure shown by the arrows 20) is split at the top of the rear wall of the refrigerator compartment and led downwards on both sides. The channel 18 thus has an M-shaped design. This is shown in 2 shown.

Since the cooling requirement in the refrigerator compartment 6 is low during normal operation due to the vacuum insulation, a very small air flow is sufficient to bring the required cooling capacity to the rear wall of the device.

If a high cooling capacity is required in the refrigerator compartment, in addition to opening the flap 16 wide, an additional fan can be switched on in the refrigerator compartment 6, which improves the heat exchanger effect of the rear wall and also distributes the cold temperature present on the rear wall well in the refrigerator compartment 6.

In principle, a device according to the invention can thus have a second fan associated with the cooling compartment 6, with which air can be moved or is movable in the flow channel 15 and/or 18 for cooling the cooling compartment 6.

Since in such a case the air is significantly warmed when it re-enters the freezer compartment 4, it is preferable to first introduce it into the cold air stream of the freezer compartment 4 coming from the evaporator 7. to avoid local heating in the freezer compartment.

This can be done by a suitable air guide, e.g. a further flow channel, which can be introduced, for example, in the separating plate 13.

It is particularly advantageous if the air flows in from the refrigerator part 6 in the direction of the freezer part air flow, since this creates a suction effect at the entry point via the Bernoulli effect, which makes it much easier to control the distribution of the air flows.

The air flow in the freezer compartment 4 is designed in such a way that the amount of air transported is always significantly greater than the amount of air flowing through the rear wall of the refrigerator compartment, which offers additional advantages with regard to the efficiency of the evaporator 7.

The suction effect of the Bernoulli effect can be increased if the freezer air flow is made to have a smaller cross-section in the area where the cooling air flows in, in order to locally increase the flow speed and thus the suction effect. In the area where the air flows in, there can therefore be an area where the flow channel is narrowed.

A device according to the invention can also have a cold storage compartment (also referred to as a chill compartment). The rear wall 19 cooled by air cooling preferably functions in a similar way to the evaporator in conventional devices with a cold storage compartment and replaces it if necessary. In such a case in particular, it can be advantageous to make the shield or rear wall 19 placed on the air duct 18 out of metal in order to improve the heat transfer properties.

An advantage of the solution according to the invention is that the same, preferably replaceable, cooling module can be used in the base area 8 for freezers and fridge-freezer combinations.

In this case, the refrigeration technology of the devices preferably only differs in the type of air flow.

• Ein Aspekt der vorliegenden Erfindung betrifft eine vakuumgedämmte Kühl-Gefrier-Kombination mit einem dynamisch belüfteten Verdampfer mit Abtauheizung im Gefrierteil, wobei kein weiterer Verdampfer im Gerät vorliegt und trotzdem die Luft von Kühlteil und Gefrierteil getrennt sind, wobei die Kühlung des Kühlteils durch eine Luftführung erfolgt, welche kalte Luft aus dem Gefrierteil an den Wänden des Kühlteils entlangführt und wieder ins Gefrierteil zurückführt.

In other words, aspects of the present invention can be summarized as follows:

• One aspect of the present invention relates to a vacuum-insulated fridge-freezer combination with a dynamically ventilated evaporator with defrost heating in the freezer compartment, wherein there is no further evaporator in the appliance and nevertheless the air from the refrigerator compartment and freezer compartment are separated, wherein the cooling of the refrigerator compartment is carried out by an air duct which guides cold air from the freezer compartment along the walls of the refrigerator compartment and returns it to the freezer compartment.

Preferably, the air flow from the evaporator is carried out with only one fan and the distribution of the cooling capacity between the freezer and refrigerator compartments is carried out with the help of an adjustable flap or a slider, which divides the air flow differently between the refrigerator and freezer compartments depending on the position.

Preferably, the air flow from the evaporator runs into a channel embedded in the rear wall, with the air flow in the cooling part being upwards in the channel and downwards on both sides next to the channel.

Preferably, the air flow from the wall of the refrigerator compartment enters the freezer compartment in the direction of the freezer compartment air flow when re-entering the freezer compartment, so that a suction effect occurs via the Bernoulli effect.

Preferably, the flow velocity of the freezer air stream is locally increased in the area of re-entry of the refrigerator air.

Preferably, the proportion of the air flow generated by the fan that does not run along the cooling part wall is at least twice as large, preferably more than 3 times as large, as the proportion that runs along the cooling part wall.

Claims (11)

Refrigerator and/or freezer with a vacuum-insulated body and a cooled interior located in the body, which has at least two compartments that can be operated at different temperatures, characterized in that the device has a single evaporator and at least one flow channel which is designed to guide air from a first compartment for cooling a second compartment along at least one wall of the second compartment and then return it to the first compartment. Refrigerator and/or freezer according to Claim 1 , characterized in that the device has at least one fan, by means of which air can be moved through the flow channel, and a flow control element, preferably in the form of a movable slide or a movable flap, is provided in the flow channel, by means of which the air flow can be divided into channel regions of the first and second compartments. Refrigerator and/or freezer according to Claim 1 or 2 , characterized in that the device further comprises a control unit which is designed to control the flow control element such that the air flow is divided depending on the cooling requirements of the compartments. Refrigerator and/or freezer according to Claim 3 , characterized in that the control unit is designed such that a proportion of the air flow which can be fed to a freezing compartment is more than twice as large, preferably more than three times as large, as the proportion of the air flow which can be fed to a cooling compartment. Refrigerator and/or freezer according to one of the preceding claims, characterized in that the flow channel runs in a wall of the cooled interior or on a wall of the cooled interior behind a shield and is preferably arranged in front of a vacuum insulation element in the direction of the cooled interior. Refrigerator and/or freezer according to Claim 4 , characterized in that the flow channel extends over a large part of the surface of the wall, preferably over a proportion of 60% to 100%, preferably between 75% and 100%, in particular between 80% and 100% of the surface of the wall. Refrigerator and/or freezer according to Claim 4 or 5 , characterized in that the shield is made at least partially of metal and / or plastic and seals the flow channel airtight against the interior. Refrigerator and/or freezer according to one of the preceding claims, characterized in that the flow channel in a compartment operable as a refrigerator compartment runs embedded in a rear wall of the compartment and is designed to initially guide air coming from a compartment operable as a freezer compartment upwards in the rear wall of the refrigerator compartment and then to guide it downwards on both sides back to the freezer compartment. Refrigerator and/or freezer according to one of the preceding claims, characterized in that the flow channel is designed to introduce air coming from a cooling compartment into an air flow associated with a freezing compartment in the direction of the air flow. Refrigerator and/or freezer according to one of the preceding claims, characterized in that there is a local cross-sectional taper, so that in the region of the re-entry of the refrigeration part air, the flow velocity of the freezing part air flow is locally increased. Refrigerator and/or freezer according to one of the preceding claims, characterized in that the flow channel and a partition plate separating the at least two compartments are designed such that an exchange of air between the compartments is avoided.

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