DE102012004624A1 - Evaporator for refrigerator and/or freezer, has a temperature sensor which is arranged such that the sensor does not contact with the expiring moisture and the sensor temperature is always maintained to a predetermined value - Google Patents

Abstract

The evaporator comprises a refrigerant circuit for cooling the interior space of the refrigerator and/or freezer, and a temperature sensor for sensing the evaporator temperature. The temperature sensor is arranged such that it does not contact with the expiring moisture of the evaporator and the sensor temperature is always greater than 0[deg] C. The temperature sensor is not directly arranged on the evaporator or on the evaporator surface, and a protective sheath is provided around the sensor and is located between the evaporator and the sensor.

Description

The present invention relates to an evaporator for a refrigerator and / or freezer with at least one refrigerant circuit comprising at least the evaporator for cooling an interior of the device, wherein further at least one temperature sensor is provided with a sensor arranged such that by the sensor of the temperature sensor is a temperature characteristic of the evaporator temperature can be determined.

From the prior art, it is known to measure the temperature of the evaporator of a refrigerator and / or freezer by means of a temperature sensor whose sensor technology, such. B. a thermocouple, located directly on the evaporator. For free-hanging evaporators, a sensor pocket is provided which is located on the evaporator and in which the temperature sensor or its sensor is accommodated. With foamed-in evaporators, the sensor system is either foamed in or fixed to the rear wall in the interior of the device. This sensor is located at or near the coldest point of the evaporator.

Evaporators must be defrosted from time to time to remove the ice that forms on the evaporator during operation. For this purpose, the operation of the compressor of the refrigerant circuit is interrupted and measured by means of the aforementioned sensors of the temperature sensor, the temperature at the evaporator. This can be recognized if the evaporator is reliably defrosted. The compressor only switches on again when the sensor system of the named temperature sensor has reached a temperature at which the evaporator was definitely completely defrosted.

In this approach, it can be ensured that the evaporator is reliably defrosted, but there is a problem that the sensor of the temperature sensor comes in contact with moisture. In particular, the sensor of the temperature sensor comes during the defrosting with liquid water in contact. There is a risk that the moisture or water penetrates into the sensor and damage it, which can lead to their failure. Another problem may be that water enters the sensor, freezes and then thaws again. Due to the consequent volume increase further damage to the sensor may occur. The damage or failure of the sensor has the consequence that the temperature of the evaporator can not be reliably determined, so that the defrosting of the evaporator is not guaranteed with certainty.

The present invention has the object of developing an evaporator of the type mentioned in such a way that the life of the sensor of the temperature sensor is extended over the known from the prior art arrangements.

This object is achieved by an evaporator with the features of claim 1. Thereafter, it is provided that the temperature sensor is arranged such that the sensor does not come into contact with humidity located on the evaporator and / or such that the temperature present at the sensor is permanently> 0 ° C.

Preferably, it is provided that the sensor system is arranged such that it is not directly exposed to the moisture that accumulates during defrosting of the evaporator.

This ensures that the sensor of the temperature sensor is not exposed to direct contact with water, whereby the probability of damage to the sensor is reduced by penetrating water or moisture accordingly.

If the sensors are arranged in a region in which there is always a temperature of> 0 ° C, damage caused by icing of the sensor can be ruled out.

The temperature sensor can be derived from the sensor system, i. H. the actual measuring device for measuring the temperature and one or more other elements, such. B. a protective cover for the sensors, etc., which surrounds the sensor partially or completely.

In a preferred embodiment of the invention, it is provided that the sensor system of the temperature sensor is not arranged directly on the evaporator, but that at least one thermally conductive element is provided which extends between the evaporator and the sensor. The sensor is thus not directly in this embodiment of the invention on the evaporator or on the evaporator surface, but spaced from this / this. This spacing may, but need not be, perpendicular to the evaporator surface.

It is essential in this case that the sensor is arranged at a distance from the evaporator surface. The temperature sensor may be in direct communication with the evaporator and may include, for example, a shroud or spacer in contact with the evaporator with which the sensor is spaced from the evaporator surface.

The contact with the evaporator is thus made in this case by a thermally conductive element, which consists for example of metal or graphite or other heat-conducting element. This thermally conductive element can form an enclosure of the sensor system.

This thermally conductive element may for example be formed as a block, rod, web, pin, bolt or the like and lead to a certain distance between the sensor and the area of the evaporator on which the element is arranged. This ensures that the water or moisture of the evaporator is not in direct contact with the sensor. Rather, for example, during the defrosting process, the water runs off the surface of the evaporator, but does not come into direct contact with it due to the spacing of the sensors. By the said spacing can be further achieved that the temperature present at the sensor never falls below freezing.

As stated above, it is conceivable that the spacing from the evaporator surface in the direction perpendicular to the evaporator surface or board takes place. However, this is not absolutely necessary. An arrangement in which the sensor is arranged close to the surface of the evaporator is also included in the invention. It is essential that, due to the said element, the temperature at the evaporator surface is not measured by the sensor system, but rather in the region of the element on which the sensor system is arranged.

The present invention further relates to an evaporator for a refrigerator and / or freezer with at least one refrigerant circuit comprising at least the evaporator for cooling an interior of the device, wherein the evaporator has a cold area and a comparatively warm area and wherein the Further provided at least one temperature sensor with a sensor, which is arranged such that a temperature characteristic of the evaporator temperature can be determined by the sensor of the temperature sensor. It is provided that the sensor of the temperature sensor is arranged in said warm region of the evaporator. This reduces the likelihood that the water in contact with the sensor will freeze.

It should be noted at this point that the term "temperature characteristic for the evaporator temperature" means that a temperature can be present at the sensor system which can correspond to the evaporator temperature or else differs from the evaporator temperature, but allows conclusions to be drawn about the evaporator temperature. The characteristic of the evaporator temperature, which is measured by the sensor, for example, may be above the evaporator temperature and in particular over the coldest evaporator temperature and / or the temperature at the location of the evaporator on which said thermally conductive element is arranged.

The present invention also comprises a combination of the two embodiments of claims 1 and 3. It is thus conceivable that the designed according to claim 3 evaporator according to the characterizing features of claim 1 or 2 is formed.

In a further embodiment of the invention, it is provided that the cold region of the evaporator is formed by the region or comprises the region in which the refrigerant exits the evaporator, or the area extending upstream thereto, and that the warm region of the evaporator through the Area is formed or includes the area in which the refrigerant enters the evaporator, or the area extending downstream thereof.

It is also conceivable that the evaporator is flowed through from top to bottom of refrigerant and that the warm area is higher up on the evaporator than the cold area. In this case, it is preferable that the temperature sensor in the upper, d. H. warmer area of the evaporator is located.

Another way to prevent the icing of the sensors of the temperature sensor is thus not the sensor of the temperature sensor in the cold region of the evaporator, which is usually formed by the lower portion, but in the relatively warm region of the evaporator, usually through the upper Area is formed to arrange.

As stated above, the thermally conductive element may consist of metal or graphite or may comprise one or more of these materials. However, the invention also includes other thermally conductive elements. These must have the property of establishing a connection between the evaporator and the sensor of the temperature sensor, which ensures that a temperature or a temperature curve is measured at the sensor, the representative, d. H. characteristic of the temperature or temperature curve of the evaporator. Thus, a conclusion can be drawn from the temperature measured by the sensor to the temperature of the evaporator.

It is preferably provided that said thermally conductive element communicates with the coldest region or a comparatively cold region of the evaporator. This is usually in the lower part of the evaporator.

It is preferably provided that the sensor system is arranged in a region in which the temperature is always> 0 ° C and / or in a region in the temperature curve has the same course as the temperature curve of the evaporator itself.

Ideally, the thermal connection between the sensor system and the evaporator at the sensor system always results in a temperature> 0 ° C. or temperature curve, ie. H. a temporal course of the temperature whose temperature values are always> 0 ° C. The temperature curve may be shifted in relation to the temperature curve of the evaporator, in particular at the coldest point of the evaporator, but has the same course as the temperature curve on the evaporator itself.

Preferably, it is thus provided that the sensor system of the temperature sensor is arranged so that the temperature measured by the sensor has the same course as the temperature curve on the evaporator itself, but is shifted toward higher temperatures. This can be achieved by the fact that the sensor of the temperature sensor by the said thermal element only indirectly and not directly with the evaporator or the evaporator surface is in communication. If the said thermally conductive element is arranged at a cold or the coldest point of the evaporator, measures the sensor, which is spaced by the conductive element of this cold or coldest spot, a correspondingly higher temperature.

It is also conceivable that the sensors of the temperature sensor - as stated above - is directly or indirectly in communication with a comparatively warm region of the evaporator. In this case, there is a shift in the measured temperature relative to a cold and preferably the coldest region of the evaporator.

Preferably, it is provided that the temperature measured at the sensor of the temperature sensor is always or largely predominantly> 0 ° C.

The present invention further relates to a refrigerator and / or freezer with at least one refrigerant circuit, wherein the refrigerant circuit comprises at least one evaporator according to one of claims 1 to 9. The refrigerant circuit usually comprises at least one compressor, which is followed by at least one condenser, in which the compressed refrigerant passes into the liquid state of matter. After flowing through the condenser, the refrigerant passes through at least one throttle capillary into the evaporator in which it partially or completely evaporates by absorbing heat from the interior to be cooled. From the evaporator, the refrigerant flows through the suction line back to the compressor, so that there is a total of a closed refrigerant circuit.

The evaporator according to the invention can be freely suspended or foamed. He can directly in the compartment to be cooled, such as. B. in a refrigeration or freezer compartment or in a cooling air duct, from which the cold air enters the compartment in a suitable manner.

Further details and advantages will be explained in more detail with reference to an embodiment described below.

The exemplary embodiment relates to a refrigerator and / or freezer in whose at least one cooled interior at least one inventive evaporator is arranged. The evaporator is arranged freely suspended.

It is located in the cooled by the inner container and a door or flap cooled interior.

The evaporator consists of a circuit board on which a refrigerant line is arranged meandering. The board and said conduit may be made of aluminum. The line can on the board z. B. be fixed by soldering.

The evaporator itself has no receptacle for fixing a temperature sensor or its sensor, such. B. from a thermocouple or other measuring device.

Instead, located on the surface of the evaporator, a metal or metal-containing element in the form of a projection, which may for example have the shape of a web or bar or the like. in its end region remote from the evaporator, the temperature sensor is received in a receptacle of this projection or connected in some other way to the projection.

By the said projection is located between the temperature sensor or its sensor and the surface of the evaporator, for example, a distance in the range of> 1 cm to <5 cm. This spacing need not be perpendicular to the evaporator surface. The said element may also be in another direction, for. B. extend obliquely relative to the evaporator surface. By the element, the sensor of the temperature sensor is spaced from the region of the evaporator on which said element is arranged on the evaporator. The spacing is thus preferably determined by the length of the element.

Due to the spacing, the sensor of the temperature sensor does not directly measure the temperature at the evaporator surface.

The metal or metal or other thermally conductive material element is seated on the surface of the evaporator or may form an integral part of the evaporator. It is preferably arranged in a relatively cold region of the evaporator, preferably in its coldest region.

By the connection by means of said element follows the measured at the sensor temperature of the evaporator temperature at the point at which said thermally conductive element is, but is displaced by a certain offset.

By the. said compound results between the evaporator and sensor thus a shift in the temperature curve at the sensor, the temperature present at the sensor is constantly> 0 ° C, but the temperature profile is the same as directly on the evaporator. The time course of the temperature at the sensor is thus the same as the time course of the temperature at the evaporator, the two temperature curves, however, are shifted by a certain differential temperature parallel to each other. This avoids the freezing of water at the sensor.

Alternatively or additionally, it may be provided to arrange the sensor system at a location of the evaporator which is warm compared to other locations of the evaporator and in particular relative to the coldest point of the evaporator. This also makes it possible to ensure that the measured temperature at the sensor of the temperature sensor has the same course as the temperature at the cold or coldest point of the evaporator, but is shifted such that the temperature at the sensor itself constantly or substantially Always > 0 ° C.

Overall, it can be achieved by the invention in a preferred embodiment, that the temperature at the sensor of the temperature sensor does not fall below 0 ° C, so that it does not cause freezing of water or in the sensor of the temperature sensor and the subsequent thawing and the consequent Damage to the sensor may occur.

Claims (10)

Evaporator for a refrigerator and / or freezer, wherein the device comprises at least one refrigerant circuit having at least the evaporator for cooling an interior of the device, wherein further provided at least one temperature sensor with a sensor which is arranged such that by the sensor the temperature sensor is a temperature characteristic of the evaporator temperature can be determined, characterized in that the sensor of the temperature sensor is arranged such that it does not come with or located on the evaporator or run off this moisture, in particular water, and / or arranged such that the temperature at the sensor is always> 0 ° C. Evaporator according to claim 1, characterized in that the sensor of the temperature sensor is not disposed directly on the evaporator or on the evaporator surface, but that at least one thermally conductive element, insbesonsdere a protective cover is provided around the sensor, located between the evaporator and the extends sensor mentioned. An evaporator for a refrigerator and / or freezer, wherein the device comprises at least one refrigerant circuit having at least the evaporator for cooling an interior of the device, wherein the evaporator has a cold area and a comparatively warm area and further that at least one Temperature sensor provided with a sensor, which is arranged such that a temperature characteristic of the evaporator temperature can be determined by the sensor of the temperature sensor, characterized in that the sensor of the temperature sensor is disposed in said warm region of the evaporator or is in communication with this area , Evaporator according to claim 3, characterized in that the evaporator according to the characterizing features of claim 1 or 2 is formed. An evaporator according to claim 3 or 4, characterized in that the cold region of the evaporator is formed by the region or comprises the region in which the refrigerant exits the evaporator and that the warm region of the evaporator is formed by the region or comprises the region in which the refrigerant enters the evaporator. Evaporator according to one of claims 3 to 5, characterized in that the evaporator is flowed through from top to bottom of refrigerant and that the warm area is located further up the evaporator than the cold area. Vaporizer according to one of claims 2 to 6, characterized in that the thermally conductive element consists of metal or graphite or comprises one or more of these materials. Vaporizer according to one of claims 2 to 7, characterized in that the thermally conductive element is in communication with a comparatively cold and preferably with the coldest region of the evaporator. Evaporator according to one of the preceding claims, characterized in that the sensor of the temperature sensor is arranged in an area in which the temperature is always> 0 ° C and / or in a region in which the temperature curve has the same course as the temperature curve of Evaporator itself or the temperature curve at the coldest point of the evaporator. Cooling and / or freezer with at least one refrigerant circuit, characterized in that the refrigerant circuit comprises at least one evaporator according to one of claims 1 to 9.