WO2014095720A1 - Refrigeration appliance having an ice maker temperature sensor - Google Patents

Abstract

The invention relates to a refrigeration appliance having an ice maker (110), which has an ice cube tray (202), a temperature sensor (300) being fastened to the ice cube tray (202). According to the invention, the temperature sensor (300) is arranged outside an air flow (I) flowing out of an outlet opening (400) of the refrigeration appliance (100) for cooling the ice cube tray (202).

Description

 Refrigerating appliance with an ice maker temperature sensor

The invention relates to a refrigerator with an icemaker having an ice cube tray, wherein a temperature sensor is attached to the ice cube tray. Refrigeration appliances, in particular designed as household appliances refrigerators are known and are used to housekeeping in households or in the catering sector to store perishable food and / or drinks at certain temperatures. From US 5,769,541 a refrigerator with an icemaker is known, which has an ice cube tray to which a temperature sensor is attached to measure the temperature of the ice cube tray. In order to avoid a falsification of the measured values, a covering body is provided according to US Pat. No. 5,769,541, which prevents a falsification of the measured value due to an air flow impinging on the temperature sensor. However, this requires a complicated structure.

It is therefore the object underlying the invention to provide a refrigeration device with a simplified structure. This object is achieved by the subject matter having the features of the independent claim. Advantageous developments are subject of the dependent claims, the description and the drawings.

The present invention is based on the recognition that it is possible to dispense with a shielding body when an airflow can not hit the temperature sensor.

According to a first aspect, the object according to the invention is achieved by a refrigeration device, in which the temperature sensor is arranged outside an airflow flowing out of an outlet opening for cooling the ice cube tray. As a result, the technical advantage is achieved that no air flow impinges on the temperature sensor and causes a Messwertverfälschung. Thus, it is possible to dispense with a shielding body. A refrigeration appliance is understood in particular to be a household appliance, that is to say a refrigeration appliance which is used for housekeeping in households or in the gastronomy sector, and in particular serves to store food and / or drinks at specific temperatures, such as, for example, a refrigerator, a freezer, a refrigerator - / Freezer, a freezer or a wine fridge.

In an advantageous embodiment, the temperature sensor is off-center on the

Ice cube tray arranged. As a result, the technical advantage is achieved that the temperature sensor is not located in an area in which the from the

Outflow opening flowing air flow hits the ice cube tray to cool water in the ice cube tray, so that it freezes.

In a further advantageous embodiment, the ice cube tray has a longitudinal axis of symmetry, and the temperature sensor is arranged at a distance at a distance from the longitudinal axis of symmetry. As a result, the technical advantage is achieved that the temperature sensor on the one hand can accurately detect the temperature of the ice cube tray, but on the other hand is not affected by the air flow. In a further advantageous embodiment, the ice cube tray has a transverse axis of symmetry, and the temperature sensor is arranged at a distance from the transverse axis of symmetry. As a result, the technical advantage is achieved that the temperature sensor can detect the temperature of the ice cube tray and is also arranged outside the air flow.

In a further advantageous embodiment, the ice cube tray has at least two ice cube depressions, wherein the temperature sensor is arranged between the two ice cube depressions. The ice cube wells are filled with liquid water, which then freezes to ice and forms ice cubes. As a result, the technical advantage is achieved that the temperature sensor detects the temperature of the ice cube tray particularly accurately. In a further advantageous embodiment, the temperature sensor is arranged in a receptacle of the ice cube tray. The recording can be integrally formed on the ice cube tray. As a result, the technical advantage is achieved that the temperature sensor has a defined position and thus a correct detection of the temperature of the ice cube tray is ensured.

In a further advantageous embodiment, the temperature sensor is attached to the ice cube tray with a retaining clip. As a result, the technical advantage is achieved that the temperature sensor is securely attached to the ice cube tray and the contact ensures a measurement error-free detection of the temperature of the ice cube tray.

In a further advantageous embodiment, the retaining clip is fastened with a latching connection to the ice cube tray. Thereby, the technical advantage is achieved that the retaining clip without the use of fasteners, such. Screws, can be fastened. This simplifies the assembly.

In a further advantageous embodiment, the latching connection comprises a latching hook of the retaining clip and a bracket of the ice cube tray, wherein the latching hook engages in the bracket. As a result, the technical advantage is achieved that a particularly mechanically stable latching connection is given.

In a further advantageous embodiment, a shielding body is arranged between the ice cube tray and the retaining clip. As a result, the technical advantage is achieved that turbulences, caused by the flow of pleasure, the temperature sensor can not reach and cause Messwertverfälschung. Thus, the measurement accuracy is increased.

In a further advantageous embodiment, the shielding body is made of foam. As a result, the technical advantage is achieved that, on the one hand, the temperature sensor is shielded by the shielding body from measurement errors causing air flows and on the other side of the shielding body has a low thermal capacity, so that the inertia of the temperature sensor is only slightly reduced by the shielding. Thus, a quick temperature detection with the temperature sensor is possible.

In a further advantageous embodiment, the air flow flows in the direction of the longitudinal axis of symmetry of the ice cube tray. As a result, the technical advantage is achieved that the entire surface of the ice cube tray is streamed by the air flow and cooled, so that a rapid and uniform temperature reduction of the ice cube tray is given.

According to a second aspect, the object of the invention is achieved by an ice cube container for such a refrigeration device. As a result, the technical advantage is achieved that no air flow impinges on the temperature sensor and causes a Messwertverfälschung.

According to a third aspect, the object according to the invention is achieved by a temperature sensor assembly comprising a temperature sensor and a retaining clip for such a refrigeration device or for such an ice maker. As a result, the technical advantage is achieved that no air flow impinges on the temperature sensor and causes a Messwertverfälschung. In an advantageous embodiment, a shielding body is provided for mounting between the retaining clip and an ice cube tray. As a result, the temperature measurement of the ice cube tray with the temperature sensor is further improved.

Further embodiments will be explained with reference to the accompanying drawings. Show it:

1 is a front view of a refrigerator,

 2 is a perspective view of an ice maker,

 Fig. 3 is a section through Fig. 2, and

4 is a built-in refrigeration icemaker,

 Fig. 5 is an exploded view of a temperature sensor assembly, and

6 shows a temperature sensor assembly attached to an ice cube tray. Fig. 1 shows a refrigerator as an embodiment of a refrigeration device 100 with a right refrigerator door 102 and a left refrigerator door 104 on its refrigeration front. The refrigerator is used, for example, for cooling food and includes a refrigerant circuit with an evaporator (not shown), a compressor (not shown), a condenser (not shown) and a throttle body (not shown).

The evaporator is designed as a heat exchanger in which, after expansion, the liquid refrigerant is absorbed by heat from the medium to be cooled, i. Air inside the refrigerator, is evaporated.

The compressor is a mechanically driven component that draws refrigerant vapor from the evaporator and expels it at a higher pressure to the condenser.

The condenser is designed as a heat exchanger in which, after compression, the evaporated refrigerant is released by heat to an external cooling medium, i. the ambient air is liquefied.

The throttle body is a device for the continuous reduction of the pressure by reduction in cross section.

The refrigerant is a fluid used for heat transfer in the refrigeration system that absorbs heat at low temperatures and low pressure of the fluid and releases heat at higher temperature and pressure of the fluid, usually including changes in the state of the fluid.

With the right refrigerator door, a right refrigeration compartment 106 can be opened, which is designed as a freezer in the present embodiment. With the left refrigerator door 104, a left cold compartment 108 can be opened, which is formed in the present embodiment as a cooling compartment.

In the right refrigeration compartment 106, an ice maker 1 10 is arranged, which in the present embodiment, ice cubes prepared from water and also provides crushed ice. A delivery of ice cubes and / or crushed ice is through the right Refrigeration device door 102 on the refrigerator front side possible without the right refrigerator door 102 must be opened.

Fig. 2 shows the ice maker 1 10. The ice maker 1 10 has in the present embodiment, a frame 200, which is made of plastic in the present embodiment. On the frame 200, an ice cube tray 202 is rotatably mounted. In order to rotate the ice cube tray 202, a drive 204 is provided, which is formed in the present embodiment by an electric motor.

The ice cube tray 202 is made in the present embodiment of a plastic and has a plurality of recesses 210, of which in FIG. 2, only two for reasons of simplicity by the reference numeral 210 are indicated. The recess 210 serves to receive liquid water, which freezes in the sequence to water ice cubes. To check if the freezing process has been completed, an ice level detector 206 is provided. In the present exemplary embodiment, the ice level detector has a magnetic sensor (not shown) with which the ice height in the depressions 210 is measured. Demolding of ice cubes is then accomplished by having the drive 204 rotate the ice cube tray 202, e.g. Rotated 150 ° to 180 °, so that the ice cubes fall out of the ice cube tray 202.

A temperature sensor assembly 208 monitors the temperature of the ice cube tray 202 so as to ensure that ice cubes are not ejected from the ice cube tray 202 until they are frozen.

In order to measure the temperature of the ice cube tray 202 with the temperature sensor assembly 208 unadulterated, in the present exemplary embodiment, the temperature sensor assembly 208 is arranged eccentrically on the ice cube tray 202.

In the present exemplary embodiment, the ice cube tray 202 has a longitudinal axis of symmetry X and a transverse axis of symmetry Y. In the present Embodiment, the temperature sensor assembly 208 with a distance 212 offset from the longitudinal axis of symmetry 200 X and with a distance 214 offset from the transverse axis of symmetry Y arranged.

Furthermore, the temperature sensor assembly 208 in the present embodiment is disposed between two adjacent recesses 210 of the ice cube tray 202, and thus is located immediately adjacent to the water or ice located in the recesses 210. Thus, with the temperature sensor assembly 208, it becomes possible to measure the temperature of the ice cube tray 202 unadulterated. FIG. 3 shows that a temperature sensor 300 belonging to the temperature sensor assembly 208 is accommodated in a receptacle 306 of the ice cube tray 202 in the present exemplary embodiment. The receptacle 306 is integrally formed on the ice cube tray 202 in the present embodiment. It is thus formed integrally with the ice cube tray 202.

In addition to the temperature sensor 300, the temperature sensor module 208 includes a measuring line 302, with which the measured value acquired by the temperature sensor 300 is forwarded to further components (not shown) of the refrigerating device 100 for controlling the refrigerating device 100.

It can also be seen from FIG. 3 that the arrangement of the temperature sensor 300 in the receptacle 306 makes it close to an ice cube dish surface 304 of the ice cube tray 202 and thus enables an immediate detection of the temperature of the ice cube tray 202.

FIG. 4 shows that water that has been introduced into the depressions 210 of the ice cube tray 202 is cooled by an air flow I emerging from an outlet opening 400 of the refrigerator 100 until this water has been frozen to ice. It can be seen from the FIG. 4 that the temperature sensor 300 outside the air flow is located by the eccentric arrangement of the temperature sensor assembly 203 with the temperature sensor 3 on the ice cube tray 202 at a distance 212 from the longitudinal axis of symmetry X and at a distance 214 from the longitudinal axis of symmetry Y I, which exits from the outlet opening 400. Thus, the temperature detected by the temperature sensor 300 is not corrupted by the air flow I, so that the temperature sensor 300 detects the actual temperature of the ice cube tray 202. 5 shows the temperature sensor assembly 208 in an exploded view.

In the present exemplary embodiment, the temperature sensor assembly 208 includes the temperature sensor 300 with its measuring line 302, a retaining clip 500 for fastening the temperature sensor assembly 208 to the ice cube tray 202 and a shielding body 502.

The retaining clip 500 is made of plastic in the present embodiment. In the present embodiment, the retaining clip 500 three extensions 504, which in the present embodiment, in each case a latching hook 506 is assigned. In this case, the latching hooks 506 in the present embodiment on insertion bevels 508 to facilitate the mounting of the retaining clip of the ice cube tray 202.

In the present embodiment, the retaining clip is made with the three hooks 504 in the present embodiment with the latching hook 506 in one piece from plastic.

In the present exemplary embodiment, the shielding body 502 has a substantially cuboidal shape. In the present embodiment, the shielding body 502 is made of foam.

In the mounted state, the shielding body 502 holds air turbulences of the airflow I from the temperature sensor 300 and thus ensures measurement-error-free detection of the temperature of the ice cube tray 202. FIG. 6 shows that the holding clamp 500 is fastened to the ice cube tray 202 by three latching connections 600 in the present exemplary embodiment , In this case, each of the three latching connections 600 is formed by a bracket 602, which is integrally formed in the present embodiment on the ice cube tray 202 and in each of which a latching hook 506 engages. Thus, in the present embodiment, the bracket 602 integrally formed on the ice cube tray 202. By three locking connections 600 in the present embodiment ensures that the temperature sensor is held securely in its receptacle 306 and thus ensures that the temperature sensor 300 detects the temperature of the ice cube tray 202 without measuring errors. In operation, the wells 210 of the ice cube tray 202 are filled with water and subsequently cooled down by the air flow I exiting the outlet opening 400 of the refrigeration device 100, so that the water in the wells 210 freezes to ice. During this process, the temperature is detected with the temperature sensor 300, which is not acted upon by the air flow I due to its eccentric arrangement, so that an erroneous measured value detection by the temperature sensor 300 due to the air flow I is excluded.

When the temperature value detected by the temperature sensor 300 detects a predetermined threshold value, the ice cubes frozen in the recesses 210 of the ice cube tray 202 are frozen and can be ejected from the ice cube tray 202 by inverting the ice cube tray 202 by means of the driver 204. Then the ice cubes are ready to be removed.

LIST OF REFERENCE NUMBERS

100 refrigeration unit 400 outlet opening

102 right refrigerator door

 104 left refrigerator door 500 retaining clip

106 right cold compartment 502 shielding body

108 left cold compartment 504 extension

 1 10 Ice maker 506 Snap hook

 508 insertion bevel

200 frames

 202 ice cube tray 600 latching connection

204 Drive 602 bracket

 206 ice level detector

 208 Temperature sensor module I Air flow

210 recess X longitudinal axis of symmetry

212 Distance Y lateral symmetry axis

214 distance

300 temperature sensor

 302 measuring line

 304 ice cube tray surface

 306 recording

Claims

Refrigeration appliance (100) with an ice maker (110) having an ice cube tray (202), wherein a temperature sensor (300) is fastened to the ice cube tray (202), characterized in that the temperature sensor (300) outside one of an outlet opening ( 400) of the refrigeration device (100) outflowing

Air flow (I) for cooling the ice cube tray (202) is arranged.

Refrigerating appliance (100) according to claim 1, characterized in that the

 Temperature sensor (300) is arranged off-center on the ice cube tray (200).

Refrigerating appliance (100) according to claim 1 or 2, characterized in that the

Ice cube tray (202) has a longitudinal axis of symmetry (X), and the

Temperature sensor (300) with a distance (212) spaced from the

Longitudinal axis of symmetry (X) is arranged.

Refrigerating appliance (100) according to claim 1, 2 or 3, characterized in that the

Ice cube tray (202) has a transverse axis of symmetry (Y), and the

Temperature sensor (300) with a distance (214) spaced from the

Transverse symmetry axis (Y) is arranged.

Refrigerating appliance (100) according to one of the preceding claims, characterized

characterized in that the ice cube tray (202) at least two

Ice cube depressions (210), wherein the temperature sensor (300) between the two ice cube recesses (210) is arranged.

Refrigerating appliance (100) according to one of the preceding claims, characterized

in that the temperature sensor (300) is arranged in a receptacle (306) of the ice cube tray (202).

7. Refrigerating appliance (100) according to one of the preceding claims, characterized

 in that the temperature sensor (300) is fastened to the ice cube tray (202) with a retaining clip (500).

8. Refrigerating appliance (100) according to claim 7, characterized in that the

 Retaining clip (500) with a latching connection (600) on the ice cube tray (202) is attached.

9. Refrigerating appliance (100) according to claim 8, characterized in that the

 Locking connection (600) comprises a latching hook (506) of the retaining clip (500) and a bracket (602) of the ice cube tray (202), wherein the latching hook (506) engages in the bracket (602).

10. Refrigerating appliance (100) according to claim 7, 8 or 9, characterized in that between the ice cube tray (202) and the retaining clip (500)

 Shielding body (502) is arranged.

1 1. Refrigerating appliance (100) according to claim 10, characterized in that the

 Shielding body (502) is made of foam.

12. Refrigerating appliance (100) according to one of the preceding claims, characterized

 characterized in that the air flow (I) in the direction of a

 Longitudinal axis of symmetry (X) of the ice cube tray (202) flows.