DE10050074A1 - Refrigeration device with temperature sensor has infrared sensor for detecting operating temperature of refrigeration device, namely operating temperature of inner volume of device - Google Patents

Abstract

The refrigeration device has a temperature sensor in the form of an infrared sensor (7) for detecting an operating temperature of the refrigeration device, namely the operating temperature of an inner volume (6) of the refrigeration device. The infrared sensor is in visual contact with a black body (11) mounted in the internal volume.

Description

The invention relates to a refrigerator with a temperature sensor for detecting a loading operating temperature of the refrigerator.

For the detection of an operating temperature such as an interior temperature or the temperature of an evaporator in refrigeration devices such as refrigerators, Freezers or combination appliances traditionally temperature dependent Resistors used, which come to life via a wiring harness with a control circuit cooling operation are connected.

This technique, which has long been common, has a number of disadvantages. For one thing it is necessary to attach the temperature-sensitive resistor directly to the location gene whose temperature is to be recorded. The control circuit, however, based on the temperature detected by the temperature sensor controls the operation of a chiller, is usually located in an uncooled outside area of the refrigerator, to avoid malfunctions due to condensation on the control circuit. The resulting local separation of the control circuit and temperature sensor makes its installation cumbersome and accordingly expensive.

Wiring is required to measure the temperature sensitive Resistance to lead to the control circuit. This wiring is sensitive to Interference from electromagnetic interference. In addition, the recorded temp not necessarily that of the location to be monitored, but the temperature that arises in the temperature-sensitive resistor. To falsify the tem To avoid temperature measurement, it is therefore necessary to use this well against the uncooled insulate the outside area.

In particular if such a conventional temperature sensor for monitoring the Temperature of an evaporator is used, the strong temperature swan to which such a sensor is exposed and that of -40 ° C with normal cooling operation up to + 8 ° C during defrost operation, to considerable mechani  insulation loads of temperature-sensitive resistance, the failures can result.

The object of the present invention is to provide a refrigerator with a temperature sensor admit, in which the assembly of the temperature sensor is simplified, in which the Emp sensitivity of the measurement signal of the temperature sensor against electromagnetic interference is reduced, and in which a failure due to thermal stresses out is closed.

The object is achieved by a refrigeration device according to claim 1.

The operating temperature to be recorded with the infrared sensor of this refrigerator can an interior temperature of the refrigerator. In this case, the interior of the Refrigerator a black body can be provided with which the infrared sensor in There is eye contact.

The temperature of an evaporator of the evaporator also comes as the operating temperature to be measured Refrigeration device in question. In this case, the infrared sensor is preferably with one Interior of the refrigerator facing surface of the evaporator in eye contact. This directly allows the temperature of those relevant for cooling the interior Measure the surface of the evaporator instead of when measuring with a temperatu sensitive resistance more easily attainable, but possibly by heat inflow from outside falsified temperature of the back. Since the infrared sensor is not in immediate Rem contact must be arranged with the object whose temperature he is measuring , it is possible to place it in close proximity to the control circuit, in particular to be arranged on a common circuit board with the control circuit; so the tax circuit and the temperature sensor prefabricated as one unit and at Mon days are installed together in the refrigerator according to the invention.

Since the temperature of the infrared sensor is not decisive for the measurement result, it can be installed in an uncooled outside area of the refrigerator. In one In such a case, it is desirable that it be passed through from a measuring surface to be monitored an infrared-transmissive window is separated, which has an unimpeded inflow of Heat is blocked in the interior of the refrigerator.  

If the distance between the infrared sensor and the one to be monitored by it Measurement area is large, it is desirable that a lens for imaging between the two the measuring surface is provided on a radiation-sensitive surface of the sensor. there can this lens in particular form the window mentioned above at the same time.

Further features and advantages of the invention result from the following description Description of exemplary embodiments with reference to the accompanying figures. Show it:

Figure 1 is a schematic section through part of the housing of a refrigerator according to the Invention according to a first embodiment of the invention. and

Fig. 2 shows an analog section according to a second embodiment of the invention.

Fig. 1 shows a highly schematic section through the upper front corner of the hous ses a refrigerator according to the invention. The refrigerator comprises a thermally insulating housing, of which part of an upper side 1 and a front side 2 with a door 3 mounted thereon can be seen in FIG. 1.

Above the door 3 , a panel 4 is mounted on the front side 2 , in which it can be a simple plastic molded part without significant thermal insulation effect.

In the space enclosed by the panel 4 and the front side 2, a control circuit and, on its surface facing the interior 6 of the refrigerator, an infrared sensor 7 is mounted on a circuit board 5 . Such an infrared sensor can detect the intensity of infrared radiation in different spectral ranges and, based on the intensity distribution, allow a conclusion to be drawn about the temperature of the radiation source. This infrared sensor z. B. be of a similar type to those z. B. in so-called "ear thermometers" for body temperature measurement. Although the infrared radiation from the inside of a refrigerator is significantly weaker and longer on average than that of a human body, on the other hand, the requirements for measurement accuracy when controlling a refrigerator are significantly lower than when measuring body temperature, so that such an infrared sensor can also be used to control one Refrigeration device is considered suitable.

The attachment of the board 5 with the control circuit in the front of the refrigerator has the advantage that it is possible to mount on the board 5 display elements such as a light emitting diode 8 , which are visible to a user through a window 9 of the panel 4 , so that who can easily convince the proper functioning of the refrigerator at any time. Also regulators, e.g. B. for setting a target temperature of the interior, can be mounted directly on the board 5 and are still easily accessible to a user.

The infrared sensor 7 is opposite to a recessed in the front 2 window 10 made of an infrared transparent material through which the characteristic heat radiation of an attached in the interior 6 black body 11 can fall substantially unhindered on the radiation-sensitive surface of the infrared sensor 7 .

With the help of this black body 11 , it is possible to specifically measure the temperature in a critical area of the interior 6 . The front upper area of the interior 6 , where the black body 11 is shown in the figure, is such an area, since the heat flow into the interior 6 , which is strongest along the edges of the door 3 , generally results in this area set the highest temperatures in the interior.

However, it is also possible to omit the black body 11 , so that the infrared sensor 7 has a "clear view" of the interior 6 through the window 10 . The water interior 6 also has the radiation characteristic of a black body in thermal equilibrium; so that if the black body 11 is omitted , the infrared sensor 7 can measure a temperature which is averaged over the entire field of view of the infrared sensor 7 . With such an arrangement, there is the particularity that the measured values detected by the infrared sensor 7 can be "falsified" if there is refrigerated goods in its field of vision, which has only recently been loaded into the refrigerator and has not yet assumed its internal temperature. The infrared radiation power of a body increases much more than linearly with its temperature. Such "warm" refrigerated goods can therefore "outshine" its cold surroundings to a certain extent. In such a case, the temperature detected by the infrared sensor is higher than an arithmetic mean of the temperature formed taking into account the “warm” refrigerated goods. Such adulteration may be desirable here, however, because it makes it possible to regulate the cooling capacity of the refrigeration device well before the heat introduced with the new refrigerated goods has spread inside. In this way, heating of the interior by a newly brought, relatively warm refrigerated goods is reliably prevented without this requiring any complex circuitry measures.

FIG. 2 shows a section analogous to that of FIG. 1 through a further developed variant of a refrigeration device according to the invention. In addition to the elements of the refrigerator already shown in FIG. 1 and described above, FIG. 2 also shows part of the rear wall 13 of its housing and an evaporator plate 14 arranged thereon. In this variant, the window 10 is replaced by a lens 15 , which consists of the same material as the window 10 and can be inserted in a corresponding manner into the front 2 of the housing.

The lens 15 has the effect that in the Fig. 2 bounded by dashed lines field of view is restricted 16 of the lens as compared to the embodiment of FIG. 1, and only a limited area 17 of the evaporator plate 14 is detected. With this arrangement, accurate monitoring of the temperature of the evaporator plate 14 is possible across the interior 6 .

Since the infrared sensor 7 is not exposed to the temperature fluctuations in the evaporator plate itself, its lifespan is not impaired thereby, and malfunctions in the operation of the refrigeration device are avoided.

Various further developments of the exemplary embodiments described above are possible within the scope of the present invention. So it is z. B. conceivable to mount a plurality of infrared sensors on the circuit board 5 , each of which monitor a field of view in the interior 6 of the refrigerator via a separate window. Such a differentiated temperature monitoring enables the control circuit z. B., newly introduced cooling belt, which leads only locally to increased temperature readings, to distinguish from a general malfunction, in which the temperature of the entire interior 6 rises as a result of a cooling failure.

Claims (10)

1. Refrigeration device with a temperature sensor for detecting an operating temperature of the device, characterized in that the temperature sensor is an infrared sensor ( 7 ). 2. Refrigeration device according to claim 1, characterized in that the operating temperature is the temperature of an interior ( 6 ) of the refrigeration device. 3. Refrigerating appliance according to claim 2, characterized in that the infrared sensor ( 7 ) is in eye contact with a black body ( 11 ) arranged in the interior ( 6 ). 4. Refrigerator according to claim 1, characterized in that the operating temperature is the temperature of an evaporator ( 14 ) of the refrigerator. 5. Refrigerating device according to claim 4, characterized in that the infrared sensor ( 7 ) is in eye contact with a surface of the evaporator ( 14 ) facing the interior ( 6 ) of the refrigerating device. 6. Refrigerating appliance according to one of the preceding claims, characterized in that the infrared sensor ( 7 ) is connected to a control circuit for the operating temperature and is arranged in the immediate vicinity of the latter. 7. Refrigerating appliance according to claim 6, characterized in that the infrared sensor ( 7 ) is arranged on a common circuit board ( 5 ) with the control circuit. 8. Refrigeration device according to one of the preceding claims, characterized in that the temperature sensor is mounted in an uncooled outer area of the refrigeration device and is separated from a measurement area to be monitored by an infrared-transparent window ( 10 , 15 ). 9. The refrigerator according to claim 8, characterized in that the Temperatursen sensor is accommodated under a front panel ( 4 ) of the refrigerator. 10. Refrigerating appliance according to one of the preceding claims, characterized by a lens ( 15 ) for imaging a measuring surface ( 17 ) on a radiation-sensitive surface of the temperature sensor.