RU2477826C2 - Refrigerating device with temperature sensor holder - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: invention refers to a refrigerating device with a cooling agent circulation system that includes a cooling agent compressor, a condenser, an evaporator with an evaporation plate for heat energy transfer from a refrigerating compartment of the refrigerating device to the cooling agent circulation system, and a temperature sensor for determination of evaporation plate temperature through sensitive surface of temperature sensor, which is connected to the evaporation plate by means of a holder. Holder is made so that immediate contact of sensitive surface of temperature sensor to evaporation plate of the evaporator that is located inside the refrigerating compartment is provided.

EFFECT: use of the present invention allows improved determination of evaporation plate temperature.

10 cl, 5 dwg

Description

Technical field

The present invention relates to a refrigerating apparatus with a refrigerant circulation system, the refrigerant circulating system comprising a refrigerant compressor, a condenser, an evaporator with an evaporation plate for transferring heat energy from the refrigeration compartment of the refrigerating apparatus to the refrigerant circulation system and with a temperature sensor for detecting the temperature of the evaporating plate through the touch surface temperature sensor, which is connected via a holder to the evaporation plate.

State of the art

US 1,886,042 describes a refrigeration apparatus with an automatic temperature control system. The evaporator described there has a loop-shaped tube with refrigerant, on which a fastening section of the metal bracket is directly fixed by soldering or riveting. On the metal bracket opposite the mounting section, rigidly connected to the refrigerant pipe, two clamps are provided for the temperature sensor. The clamps are designed to fully grasp the cylindrical body of the temperature sensor. To hold the temperature sensor in its position, it is rigidly connected to the clamps by soldering. Heat transfer from the refrigerant pipe to the temperature sensor occurs through heat transfer through the middle portion of the clamp. To change the thermal conductivity, the middle section of the metal clamp is equipped with several holes.

US 2,419,376 discloses a metal bracket similar to the above prior art for connecting a temperature sensor to a refrigerant pipe. The metal bracket shown there is made by the team and consists of two hemispheres having the same shape and lying opposite each other, which are connected by bolts. Each hemisphere has two channel sections that are connected to each other, adjacent to the longitudinal sides. Between the respective two channel sections lying opposite each other, the sensor housing or the refrigerant pipe is clamped. Bolts pass between the sensor housing and the refrigerant pipe. Thus, due to the separate arrangement of these two components, heat transfer can occur exclusively through prefabricated metal staples.

DE-OS 1751713 describes the construction of a thermostat temperature sensor on an evaporator plate of a chiller machine. A plastic body is provided to connect the temperature sensor to the evaporator plate. This plastic body has a blind hole, made with the possibility of installation in it with elastic expansion of the tubular temperature sensor. The plastic body has one or two longitudinal grooves, through which the plastic body is put on the evaporation plate with geometric and force closure so that the edge section of the evaporation plate enters the longitudinal groove. Since the evaporation plate and the temperature sensor are kept at a distance from each other by the plastic body, heat transfer from the evaporation plate to the temperature sensor can occur exclusively through the plastic body. Thus, the cooling of the evaporation plate is transmitted to the temperature sensor only with a time delay.

DE 9112478 U1 discloses a device for measuring the internal temperature of a refrigerator, such as a refrigerator. The temperature sensor is held in place on the carrier element. The supporting element has two side tabs lying opposite each other, which are retracted under the hook-shaped holding elements of the supporting plate. The carrier plate, for its part, is fixed on the inner side of the inner wall, which faces the intermediate space between the inner wall and the outer wall of the refrigerator body. The carrier plate is filled in the intermediate space together with the carrier and the temperature sensor using foamed polyurethane.

From the restrictive part of the claims EP 190793 A1, a refrigerator with a temperature sensor is known, and the refrigerator is configured to determine the surface temperature of the evaporator plate by means of a temperature sensor. The temperature sensor is pushed through the tube to the evaporator plate. The tube on the back of the inner wall of the refrigerator extends to the evaporator and is secured there snugly. For its fastening on the evaporation plate, the tube is fixed in a holder made in the form of a clamping part made of plastic. Heat is transferred from the evaporator plate to the temperature sensor by means of a tube adjacent to the evaporator plate.

Disclosure of invention

The objective of the invention is to create the ability to better determine the temperature of the evaporation plate.

The problem is solved by means of a refrigerating apparatus with the features of claim 1 of the claims.

Due to the fact that the holder is made on the evaporation plate for the direct adherence of the sensor surface of the temperature sensor, the temperature of the evaporation plate can be measured by the sensor surface of the temperature sensor without loss and without time delay. By directly fitting the sensor to the evaporator, the temperature is measured accurately. If the temperature can be determined more accurately, the surface of the evaporator can be significantly reduced compared to the hitherto known sensor mounts. As a result, a reduction in production costs is possible since even less material is required to produce a smaller evaporator surface. Otherwise, the surface area of the evaporator is larger than necessary, which corresponds to greater cooling capacity.

Usually in the case of domestic refrigerators and refrigeration units, an evaporator located inside is used for heat extraction. To reduce the energy consumption of the product, along with a sensor for measuring the temperature in the inner chamber, a sensor for measuring the temperature of the evaporator is also used. This additional sensor for measuring the temperature of the evaporator can also serve as a defrost sensor in this regard. Due to technological conditions, especially in the case of refrigeration units, an evaporation plate is provided which, after filling the cavity of the household appliance with foam, is brought into its correct position. This means that by the time the foam is filled, the later position of the evaporation plate has not yet been determined. Therefore, the sensor for measuring the temperature of the evaporator cannot, as in the case of foam-filled evaporators, be fixed in the installed sockets. In the case of foam-filled evaporators, the position of the evaporation plate is determined, and thus the sensor for measuring the temperature of the evaporator can be inserted into the nests, and then the nest is sealed only with sealing means, for example, butyl sealant. However, in these sockets the exact position of the sensor is not guaranteed. There is uncertainty about whether the sensor accepts the measured temperature directly adjacent to the evaporator plate or only through heat transfer through the air. Based on this knowledge, the invention provides for fixing a sensor for measuring the temperature of the evaporator using the holder directly on the evaporation plate. Thus, it is constantly guaranteed that the sensor surface of the temperature sensor is directly adjacent to the evaporation plate. In this case, the holder ensures that the sensor directly adjoins the evaporator plate also in the case when the evaporator plate is moved or mounted in its exact position during manufacture or installation.

The holder may have a receptacle with a recess for the sensor surface of the temperature sensor, which fixes the pre-installed temperature sensor on the holder. A fundamentally different receiving socket may be provided on the holder. However, on the one hand, the receiving socket must fix the temperature sensor in a certain position, so the receiving socket must be adapted to the shape of the temperature sensor. On the other hand, the touch surface of the temperature sensor should lie directly, constantly and tightly on the surface of the evaporation plate, so the receiving socket does not completely cover the temperature sensor, but leaves at least a significant part of the touch surface free. Thus, the evaporation plate can adhere to the sensor surface.

At the same time, the receiving socket can have a grooved shape suitable for the shape of the temperature sensor, and for fixing the previously mounted temperature sensor on the holder, cover the temperature sensor by more than 180 °. This embodiment is preferably suitable for temperature sensors that have a substantially cylindrical appearance. In this case, the receiving socket must surround the housing of the temperature sensor in the form of a shell, and it is not required that the receiving socket completely covers the housing. On the contrary, it is only necessary to cover the temperature sensor by more than half of its circumference. Thus, an undercut is formed on the receiving socket, for which the temperature sensor can be fixed so that it will hold securely. The amount by which the temperature sensor should cover the receiving socket depends essentially on the material properties, in particular on the elasticity of the material used for the receiving socket or for the holder. The strength or sensitivity of the temperature sensor also plays a role. According to the invention, the holder is made of plastic.

On the other hand, a receiving slot for forming a recess may cover the temperature sensor by less than 360 °. The receiving socket can be completely closed 360 °, and a notch can be made separated from the receiving socket. If the receiving socket is designed so that its functions coincide with the functions of the recess, then the support of the receiving socket for the formation of the recess should cover the temperature sensor by less than 360 °. Consequently, a recess is formed by the free region of the non-adjacent end portions of the receptacle spanning the temperature sensor. The receiving socket in this regard can be made in the form of a plastic part in which the temperature sensor is fixed. The receiving socket forms part of the sensor holder. From a technology point of view, it will be advantageous if the temperature sensor is pre-mounted on the holder. Then the holder, together with the pre-mounted temperature sensor, is mounted on the evaporator plate. A further advantage arises when a defective temperature sensor can subsequently be replaced in a simple manner by the fact that the defective sensor is disconnected from the receiving socket and a new, operable sensor is clamped in the receiving socket.

In another embodiment of the invention, the holder may have positioning means that cooperate with counter means of positioning the evaporator plate in the mounting position of the holder. The positioning means and response positioning means serve to ensure that the holder is mounted on the evaporator plate in the correct position. The holder can also be fixed on a site other than the evaporation plate, for example on the housing of the refrigeration apparatus. However, this will only be advisable when an accurate, constant distance from the holder to the evaporator plate is guaranteed. The most reliable is the direct mounting of the holder on the evaporation plate. This also has the advantage that even after mounting the holder and the temperature sensor, the evaporation plate can be changed in its position. In this case, there is no danger that the sensor surface of the temperature sensor may lose its position of constant contact with the evaporation plate. When the position of the evaporation plate changes, the holder moves synchronously with the temperature sensor, as a result of which the exact contact of the sensor surface with the evaporation plate is maintained.

The positioning means can be formed by at least one jumper connected to the holder, which in the mounting position enters the return slot as the positioning response means on the evaporation plate. The jumper and slot define the installation direction. Preferably, two parallel bridges and reciprocal slots are provided. Thus, the holder can be pushed along the evaporator plate in the longitudinal direction of the jumpers along original guides. Additionally, a stop may be provided on the holder or on the evaporation plate, on which the mounted holder is in its correct mounting position. The stop prevents further mounting of the holder beyond the boundaries of the correct mounting position.

The holder may in particular have fixing means which, for mounting the holder on the evaporation plate, interact with the counter fixing means of the evaporation plate. By means of fixing means, the holder is held securely on the evaporation plate. This may be particularly advantageous also during the manufacture of the refrigeration apparatus. Thus, the holder can be pre-mounted on the evaporator plate, in particular together with a temperature sensor. This may eliminate the need for time-consuming mounting of the holder on an evaporation plate already integrated in the refrigerator. Simple installation is achieved by the fact that the holder can be pre-mounted on a free, accessible on all sides of the evaporation plate outside the refrigerator. The locking means prevents the pre-mounted holder from being disconnected, especially during the integration of the evaporator plate into the refrigeration unit.

For this, the fixing means can be formed by a fixing protrusion that is connected to the holder, the fixing protrusion in the mounting position being fixed in the opening of the evaporation plate. The elasticity of the fixing means is created by the elastic properties of the holder made of plastic. Therefore, springy elastic fixing means and a locking protrusion are provided on the holder or are preferably made integrally with it by injection molding. Due to the fact that the locking protrusion is made on the holder, it will be sufficient to provide the evaporation plate with a simple opening in which the locking protrusion enters.

The opening and, in particular, slotted response means of positioning can be made without cutting, in particular by punching the evaporator plate. This simplifies manufacturing. Thus, on the evaporation plate, it is only necessary to perform perforation in a flat, plate material, which can be performed in particular at the same working step as the perforation of the entire contour of the evaporation plate. The counterparts of the jumpers and the locking protrusions can at the same time be made in a simple manner together with a plastic holder. By simply punching the slots and openings, the subsequent position of the holder or temperature sensor on the evaporator plate can be easily determined. In particular, this position changes during mass production, that is, even during mass production, the position of the holder or temperature sensor can be changed. Changing the position of the holder or the temperature sensor is possible by simply moving the slots and openings, for example, during punching of the evaporation plates. If the position of the temperature sensor initially set by the design during the functional check of the prototypes of household appliances is negative, the position on the evaporator plate can be changed at a low cost.

In particular, two slots can be provided on the evaporator plate, parallelly running at a distance from each other and having open edges, with an opening having closed edges located between the slots. This ensures reliable fixation of the locking protrusion of the holder in the opening. For safety reasons, the holder can be designed so that it can be removed from the evaporation plate only with the help of an auxiliary tool.

Brief Description of the Drawings

One of the embodiments of the invention is described on the basis of the refrigeration apparatus, presented as an example in the figures. Other general features and advantages of the present invention follow from the detailed description of this particular embodiment.

The figures show the following.

Figure 1: axonometric projection of a refrigeration apparatus with an evaporation plate.

Figure 2: axonometric projection of the holder according to the invention.

Figa: fragment of a perspective view of the evaporation plate according to the invention with the holder of Fig.2 before installation.

Fig.3b: fragment of a perspective view of the evaporation plate with the holder of Fig.2 in its mounted position.

The implementation of the invention

The refrigerator 1 according to FIG. 1 has a double-walled enclosure 2 filled with insulating foam, which forms a lower freezer 4 that is capable of being closed by a door 3, and also a refrigerator 6 that is capable of being closed by a separate second door 5. The refrigerator 6 is divided by an intermediate wall 7 to the upper refrigerating compartment 8 and the lower compartment 9 for fresh products. The fresh food compartment 9 is operated at temperatures just above 0 ° C and is preferably used for fresh storage of perishable products, such as vegetables and salads, for example. Refrigeration compartment 8 is operated at temperatures from about 8 ° C to 6 ° C and is used to store other refrigerated products. In the present refrigeration apparatus 1, an evaporation plate 10 is shown as an example on the rear inner wall of the fresh food compartment 9. 1, for simplicity, the evaporation plate 10 is shown without other components and with fresh food compartments removed. The refrigeration apparatus 1 is driven by a refrigerant circulation system 11. For this, the refrigerant circulation system 11 as a whole comprises a refrigerant compressor 12, a condenser 13 and an evaporator 14, which is connected to the evaporator plate 10 in a heat-conducting manner and serves to transfer thermal energy from the cooling compartment of the refrigeration apparatus 1 to the refrigerant circulation system 11. In order to control or regulate the refrigerant circulation system 11 by means of the control device 11a, among other things, the temperature of the evaporation plate 10 can be used. To determine the temperature of the evaporation plate 10, a temperature sensor 15 can be used, which is secured in the refrigerator 1 by means of the holder 16 so that it the sensor surface 17 can record the temperature of the evaporation plate 10.

The holder 16 proposed by the invention is shown in FIG. The holder 16 has a rectangular flat main part 18, to the upper edge of which is adjacent the receiving socket 19. The receiving socket 19 is grooved and extends its axis of symmetry 20 parallel to the upper edge of the main part 18. The receiving socket 19 in this case has a C-shaped cross section. Both ends of the arc made in this way have a rounded edge 19a and 19b. The rounded edges 19a and 19b extend along the entire longitudinal direction of the receiving socket 19. By the rounded edges 19a and 19b, the substantially cylindrical temperature sensor 15 can be clamped in the receiving socket 19 in a radial direction to the axis of symmetry 20. During clamping, the grooved receptacle 19 expands to the diameter of the temperature sensor 15, and thus, it can be pressed into the receptacle 19. After that, the ends of the grooved receptacle 19 surround the temperature sensor 15 by the fact that the grooved receptacle 19 again elastically tapers . At least one of the ends of the grooved receiving socket 19 lying axially opposite each other has a receiving chamfer 19c that rounds the inner edge of the C-shaped receiving socket 19. Thus, alternatively to the radial installation, the temperature sensor 15 can be inserted into the receiving socket 19 is also in the axial direction, that is, in the direction of the axis of symmetry 20.

Due to the fact that the grooved receiving socket 19 is not made in the form of a completely closed tube, but covers less than 360 °, a recess 21 is formed due to the remaining open area. The recess 21 facilitates, in the mounted position of the temperature sensor 15 in the receiving socket 19, that the sensor surface 17 is in direct contact with the evaporation plate 10. The recess 21 is open to the side of the main part 18, on which are located two jumpers 22A, 22b, forming a means 22 of the positioning. Jumpers 22a and 22b are provided on opposite lateral edges of the main part 18. Each crosspiece 22a, 22b is L-shaped in cross section, with the fixed shelves 22.1a and 22.1b extending perpendicular to the plane of the main part 18, and the free shelves 22.2a and 22.2b extend outward from each other in a plane parallel to the passage of the main part 18. The upper end of the free shelves 22.2a and 22.2b is provided with a bevel 23a, 23b. The bevels 23a and 23b facilitate installation by means of an insertion aid, whereby the holder 16 can be pushed onto the evaporation plate 10. At the lower end of the main part 18 there is a stop 24 on which the edge of the circuit of the evaporation plate is located correct mounting position of the holder. The emphasis stepwise protrudes from the front plane of the main part 18 and preferably extends from the fixed shelf 22.1a of the web 22a to the fixed shelf 22.1b of the web 22b. In the center of the front plane of the main part 18 is a locking means 25.

The locking means 25 has a spring section 26, which is formed by the region of the main part 18. To guarantee elasticity, the spring section 26 is delimited from the main part 18 by means of a U-shaped opening 27. The spring section 26 can thereby perform an elastic movement and deviate backward. In this case, the spring portion 26 bends around its fixed fastening in the region of both ends of the U-shaped passageway 27. The free edge of the spring portion 26 carries a locking protrusion 28. The locking protrusion 28 has a substantially circular sector shape and protrudes forward from the front plane of the main part 18, as well as jumpers 22a and 22b. A beveled inlet portion 29 is provided on an upwardly pointing side of the locking protrusion 28 having a circle sector. The beveled inlet 29 extends from the main circle of the fixing protrusion 28 from the front plane of the main part 18, continuously rising to the maximum elevation of the fixing protrusion 28. The beveled inlet 29 ends preferably before reaching the diameter of the locking protrusion 28.

Fig. 3a shows the holder 16 of Fig. 2 with a mounted temperature sensor 15, as well as a portion of the evaporation plate 10 prior to installation. From the grooved receiving socket 19, a sensor surface 17 of the temperature sensor 15 protrudes beyond the recess 21. The evaporation plate 10 has two positioning means 30a and 30b in the form of slots that are responsive to the positioning means 22. The slots 30a and 30b are made with open edges and are connected to the jumpers 22a and 22b of the holder 16. The slots 30a, 30b form two opposite input edges on the circuit of the evaporation plate 10, which are beveled with the corresponding input chamfers 31a, 31b. Entrance chamfers 31a, 31b facilitate the insertion of the upper edges of the fixed shelves 22.1a and 22.1b of the holder 16 into the slots 30a and 30b of the evaporation plate 10. In the center of the tab 32 of the evaporation plate 10 made by both slots 30a and 30b, there is an opening 33a. The aperture 33a has a shape corresponding to the locking protrusion 28 of the holder 16, and this shape in particular may be round. The aperture 33a forms a fixing means 33 that is responsive to the fixing means 25. In order to move the holder 16 from the position shown in FIG. 3a to the mounting position shown in FIG. 3b, the holder is brought in from the bottom to the lower edge of the evaporation plate 10 until the upper the ends of the jumpers 22a and 22b will not fit into the slots 30a and 30b. Along with the inlet chamfers 31a, 31b, the bevels 23a and 23b of the jumpers 22a and 22b also serve as facilitating the introduction. Thus, the holder 16 can be centered in two perpendicular planes to the evaporation plate 10. After alignment, the holder 16 is shifted up until the free outer edge 34 of the foot 32 abuts on the stepped stop 24 of the holder 16. In this position, the locking protrusion 28 is fixed in the opening 33. Before fixing the locking protrusion 28 in the opening 33a, the locking protrusion 28 moves from its free position during insertion of the holder 16 due to the approach of the free outer edge 34 of the tab 32 to the beveled inlet portion at 29 in a pre-strained position, wherein the holder 16 can be advanced to the mounting position. In this case, the spring portion 26 is tilted back so that in the mounting position of the holder 16 bounce back to its original position, in which then also the locking protrusion 28 is fixed in the opening 33a of the evaporation plate 10.

Claims (10)

1. A refrigeration apparatus with a refrigerant circulation system (11), wherein the refrigerant circulation system (11) comprises a refrigerant compressor (12), a condenser (13), an evaporator (14) with an evaporation plate (10) for transferring heat energy from the refrigeration compartment (8) 9) of the refrigeration apparatus (1) to the refrigerant circulation system (11) and with a temperature sensor (15) for detecting the temperature of the evaporation plate (10) through the touch surface (17) of the temperature sensor (15), which is connected to the holder (16) with evaporation plate (10), distinguishing The fact that the holder (16) is made so that the sensor surface (17) of the temperature sensor (15) is in direct contact with the evaporator plate (10) of the evaporator (14) located inside the refrigerator compartment. 2. The refrigerator according to claim 1, characterized in that the holder (16) has a receiving socket (19) with a recess (21) for the sensor surface (17) of the temperature sensor (15), which fixes the temperature sensor (15) on the holder ( 16) in a predetermined position. 3. The refrigerator according to claim 2, characterized in that the receiving socket (19) has a shape suitable for the shape of the temperature sensor (15), in particular a grooved shape, and for fixing the pre-mounted temperature sensor (15) on the holder, covers the temperature sensor (15) ) more than 180 °. 4. The refrigeration apparatus according to claim 3, characterized in that the receiving socket (19) for forming a recess (21) covers the temperature sensor (15) by less than 360 °. 5. The refrigeration apparatus according to claim 1, characterized in that the holder (16) has positioning means (22) that interact with response means (30) for positioning the evaporation plate (10) in the mounting position of the holder (16). 6. Refrigeration apparatus according to claim 5, characterized in that the positioning means (22) are formed by at least one jumper (22a, 22b) connected to the holder (16), and the jumper (22a, 22b) in the mounting position is included in the return slot (30a, 30b) on the evaporation plate (10) as a response positioning means (30). 7. The refrigeration apparatus according to claim 5 or 6, characterized in that the holder (16) has a fixing means (25), which, for mounting the holder (16) on the evaporation plate (10), interacts with the reciprocal fixing means (33) of the evaporation plate ( 10). 8. The refrigeration apparatus according to claim 7, characterized in that the fixing means (25) is formed by a fixing protrusion (28) connected to the holder (16), and the fixing protrusion (28) in the mounting position is fixed in the opening (33a) of the evaporation plate ( 10). 9. The refrigerator according to claim 8, characterized in that the opening (33a) and preferably made in the form of splines (30a, 30b), the response positioning means (30) are made without cutting the metal, in particular by punching the evaporation plate (10). 10. The refrigeration apparatus according to claim 9, characterized in that two slots (30a, 30b) are provided on the evaporator plate (10), parallelly running at a distance from each other and having open edges, with an opening between the slots (30a, 30b) (33a) having closed edges.

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