RU2731573C2 - Refrigerator and/or freezer - Google Patents

Abstract

FIELD: refrigerating equipment.

SUBSTANCE: invention relates to a refrigerator and/or a freezer comprising at least one housing and at least one cooled inner space located in said housing. Unit has at least one coolant circuit intended for cooling of internal space. Coolant circuit comprises at least one condenser. At least one heat pipe is in direct or indirect thermal contact with condenser and is located in such a way that it forms at least part of the frame heater of the unit and/or is in thermal contact with the external shell of the unit.

EFFECT: increasing efficiency of use of heat released by condenser.

7 cl

Description

This invention relates to a refrigerator and / or freezer, comprising at least one housing, which contains at least one insulating body for a full vacuum, and at least one cooled internal space located in this housing, and this unit contains at least one circuit refrigerant for cooling the interior space, this refrigerant circuit having at least one condenser.

Numerous embodiments of this kind of refrigerators and, accordingly, freezers are known from the prior art.

Refrigerant condensation occurs in the condenser and generates heat.

This heat in the known units is usually carried away by natural and forced convection into the surrounding space.

Thus, the present invention is based on the object of further improving the refrigerator and / or freezer of the type mentioned at the outset, so as to ensure efficient use of the heat generated by the condenser.

This problem is solved by a refrigerator and / or freezer with the features of the independent claim 1 of the claims.

According to the invention, at least one Heatpipe is provided, which is in direct or indirect thermal contact with the condenser, and which is arranged so that it forms at least part of the frame heater of the unit and / or is in thermal contact with the external unit shell.

Thus, thanks to the invention, the heat generated in the region of the condenser is used, namely for operating the frame heater and / or for heating at least part of the outer shell of the unit according to the invention.

A frame heater is to be understood as a heater that heats a specific part of the housing of the unit, namely the area directed towards the closure element and surrounding the open side of the housing.

This frame heater can be made to run around the perimeter, or it surrounds the said opening only partially, for example, in a U-shape, and its task is to prevent freezing of the unit in the area of the opening, and thus in the area of the closure element, for example, door, cover or a box.

Heating the outer shell of the unit has the advantage that unwanted condensation on the outer shell of the unit is prevented. Preferably, the heating system for the outer shell is designed in such a way that the temperature of the outer shell is maintained above the melting point of water.

Thanks to this invention, it is possible to use the waste heat, which is still generated in the condenser, in an expedient way, rather than simply dissipating it into the space surrounding the unit. This use consists in one or both of the named alternatives in the form of a frame heater and thus a heating system for the outer shell of the unit.

The heat pipe can be filled with water or an aqueous solution as a heat exchange medium. The operation of this kind of heat pipe is based on the principle that the heat exchange medium evaporates on one side of this heat pipe, and condensation occurs in another place and preferably in the other end region of this heat pipe. Due to this, in one area of this heat pipe, heat is supplied, and in another area in which condensation takes place, heat is removed from this heat pipe. This amount of rejected heat according to the invention can now be used to form a frame heater or to heat the outer shell of the unit.

Thus, according to the invention, it is possible to dispense with a separate frame heater, which, for example, forms a component of the refrigerant circuit, as well as a separate heating system for the outer shell, for example by means of a foil heating element.

Instead of water or aqueous media, any other heat exchange media with which the heat pipe is filled can also be considered.

In another embodiment of the present invention, it is provided that the heat pipe is designed as a gravity heat pipe.

This means that the reverse flow of the heat exchange medium in the region where evaporation occurs occurs under the action of gravity, and not other effects, for example, capillarity. It is therefore preferred that the heat pipe does not have capillaries for transporting the heat exchange medium.

In another embodiment of the present invention, it is provided that the capacitor is connected to at least one heat storage and is preferably located in a liquid bath, in particular in a water bath.

This embodiment of the present invention takes advantage of the fact that the thermal energy of a heat accumulator charged with heat by means of a capacitor can be used to drive the heat pipe and thereby transport the heat to another location in the unit.

The condenser can be located, for example, in a heat accumulator, for example, in a liquid bath, or otherwise connected to a heat accumulator. The present invention therefore concerns not only the case where said at least one heat pipe is in thermal contact with the capacitor, but also the case where said at least one heat pipe is in thermal contact with a heat accumulator that in turn is in thermal contact with the capacitor.

It is also not imperative that the heat pipe be in direct contact with the outer shell. It is sufficient if the thermal connection between the outer shell of the unit (and the heat pipe) is at such a distance that condensation on the outer shell can be reliably prevented.

In another embodiment of the present invention, only one heat pipe is installed. The unit can also contain several heat pipes, which are in direct or indirect thermal contact with the capacitor, respectively, with the thermal storage of the capacitor.

Furthermore, it can be provided that the greater part of the heat generated in the condenser is removed by means of the at least one heat pipe. It is possible, for example, that more than 50%, preferably more than 80% of the heat generated in the condenser is removed by means of the at least one heat pipe.

Other details and advantages of the present invention are explained in more detail in the embodiment described below.

This embodiment relates to a refrigerator and / or freezer with continuous vacuum insulation. It should be understood as insulation, in which the body of the unit consists of more than 90% of the insulating surface of a continuous insulating vacuum space. This vacuum insulating space comprises at least one vacuum insulating body, preferably including a foil bag, which serves as a sheath for the vacuum insulating body, and in which a filler such as perlite is located. This foil bag is vacuum sealed and a vacuum reigns inside it, so that heat exchange is correspondingly difficult.

Typically, the foil bag envelope is an anti-diffusion insulating layer, with which the ingress of gas into the foil bag is reduced so that the increase in thermal conductivity of the resulting vacuum insulating body due to the ingress of gas is negligible during its life.

The service life should be considered, for example, a period of 15 years, preferably 20 years and especially preferably 30 years. Preferably, the increase in thermal conductivity of the vacuum insulating body due to the ingress of gas during its service life is about <100%, and particularly preferably about <50%.

Preferably, the specific gas velocity per unit surface area of the insulating layer is <10 ^-5 mbar * l / s * m ² and particularly preferably <10 ^-6 mbar * l / s * m ² (measured according to ASTM D-3985 - Standard Test Method transfer of water vapor through polymer films and protective coatings).

This gas velocity is valid for nitrogen and oxygen. For other types of gas (in particular for water vapor), low gas flow rates are also obtained, preferably in the range <10 ^-2 mbar * l / s * m ² and particularly preferably in the range <10 ^-3 mbar * l / s * m ² (measured according to ASTM F-6-1249-90). Preferably, these low gas velocities achieve the aforementioned slight increase in thermal conductivity.

The above values are given by way of example, as preferred values, which do not limit the present invention.

The vacuum insulating body can be located in the housing and / or in a closure element by means of which this housing can be closed.

However, the present invention is not limited to this kind of refrigerators, respectively, full vacuum freezers.

The present invention also covers the case when conventional thermal insulation is used, for example in the form of polyurethane foam.

The refrigerator, respectively, the freezer according to the present invention has a refrigerant circuit that includes at least one compressor, at least one condenser connected in series thereto, at least one choke connected in series thereto, in particular a capillary, as well as at least one evaporator, which receives the refrigerant leaving the capillary.

After passing through the evaporator, the refrigerant flows back through the suction line to the compressor.

The evaporator extracts heat from the interior to be cooled, and the refrigerant evaporates. The condenser serves to condense the refrigerant and heat is generated. The condenser according to this embodiment is located in a heat accumulator, for example in a water bath. When the refrigerant circuit is operating, i.e. in the operating mode of the compressor, at least part of the heat generated in the condenser is transferred to this heat accumulator.

The heat accumulator is connected to one or more heat pipes. They are filled with water and made in such a way that the heat exchange medium in them in the operating mode of the coolant circuit evaporates inside this heat pipe. The heat pipe is connected in its other end region to an outer shell, which is preferably formed as a metal shell. In this area of the heat pipe, condensation of the heat exchange medium occurs, and heat is given off, which is transferred to the outer shell of the unit. Further, the heat pipe runs from the condenser, respectively, from the specified heat accumulator to the frame heater of the unit, which runs around the open side of the unit casing, and which is designed to heat the stop surface of the door. This heat pipe therefore heats a specific area of the unit and in this case serves as a frame heater.

Thanks to the invention, the heat generated by the condenser is utilized expediently, so that the use of separate heaters can accordingly be dispensed with. Neither a separate frame heater nor a separate heater is required to heat the outer sheath to prevent condensation.

Heat pipes can transfer heat to a large area of the outer shell, or in the area of the said frame, so that heating can be carried out in a targeted manner.

Claims (7)

1. Refrigerator and / or freezer, containing at least one housing and at least one cooled internal space located in this housing, and the unit has at least one refrigerant circuit for cooling the internal space, and the refrigerant circuit contains at least one condenser, characterized in that at least one heat pipe is provided, which is in direct or indirect thermal contact with the condenser, and which is located so that it forms at least part of the frame heater of the unit and / or is in thermal contact with the outer shell of the unit. 2. A refrigerator and / or freezer according to claim 1, characterized in that the heat pipe is filled with water or an aqueous solution as a heat exchange medium. 3. Refrigerator and / or freezer according to claim 1 or 2, characterized in that the heat pipe is designed as a gravitational heat pipe. 4. Refrigerator and / or freezer according to any one of the preceding claims, characterized in that the condenser is connected to at least one heat accumulator and is preferably located in a liquid bath, in particular in a water bath. 5. Refrigerator and / or freezer according to claim 4, characterized in that said at least one heat pipe is in thermal contact with the heat accumulator. 6. Refrigerator and / or freezer according to any of the preceding claims, characterized in that either only one or several heat pipes are provided, which are in thermal contact with the condenser. 7. Refrigerator and / or freezer according to any of the preceding claims, characterized in that said at least one heat pipe is designed in such a way that more than 50%, preferably more than 80% of the condenser evolved is removed by means of the at least one heat pipe heat.