DE102021212929A1 - Refrigeration device, evaporator assembly for a refrigeration device, holder and method for fixing a sensor device to a tube of an evaporator - Google Patents

Abstract

A holder for fixing a columnar sensor device to a tube of an evaporator comprises a first frame part extending in a longitudinal direction of the holder, a second frame part extending in the longitudinal direction of the holder, which is arranged spaced apart from the first frame part in a transverse direction of the holder, one of the first and the second frame part connecting transverse web, which extends in the transverse direction of the holder between the first and the second frame part, a first snap clip formed on the first frame part, which is arranged on the first frame part at a distance from the transverse web in relation to a vertical direction of the holder, extending in an arc from the first frame part in extends in the direction of the second frame part and ends at a distance from the second frame part, and a second snap-in bracket formed on the second frame part, which is arranged on the second frame part at a distance from the transverse web in relation to the vertical direction of the holder and spaced from the first snap-in bracket in relation to the longitudinal direction of the holder , extends in an arc from the second frame part in the direction of the first frame part and ends at a distance from the first frame part, the sensor device being receivable between the frame parts in such a way that a sensor longitudinal axis extends in the longitudinal direction of the holder, and the holder being attached to the tube of the evaporator in such a way can be fixed in that the tube can be accommodated between the snap brackets and the frame parts and the snap brackets partially enclose the tube, and the sensor device can be fixed between the tube and the crossbar.

Description

TECHNICAL AREA

The present invention relates to a refrigeration device, in particular a household refrigeration device such as a refrigerator, a freezer or a fridge-freezer combination, an evaporator assembly for a refrigeration device and a holder and a method for fixing a sensor device to a tube of an evaporator.

STATE OF THE ART

In refrigeration appliances, such as household refrigeration appliances, a refrigerant circuit is usually provided, in which a refrigerant is circulated, which evaporates in an evaporator, absorbing heat from a refrigeration or storage compartment of the refrigeration appliance, and condenses in a condenser, giving off heat to the environment. For various reasons, it can be desirable here to detect a temperature on a tube of the evaporator by means of a sensor device.

In particular in so-called no-frost refrigeration devices, in which air is circulated by means of a fan between the storage compartment and an evaporator chamber in which the evaporator is accommodated, condensation can form and ultimately the evaporator can ice up. A defrosting process is therefore usually carried out at regular intervals, which can, for example, include heating the evaporator when the refrigerant circulation is interrupted. The energy required to completely defrost the evaporator is influenced by many factors. For this reason, it is advantageous to monitor the heater using a temperature sensor that measures the temperature at the evaporator.

The reliability of the measurement results can be improved by good heat-conducting contact between the sensor device and the tube of the evaporator.

The JP H10 153491 A discloses an evaporator with an evaporator tube to which a columnar sensor device is fixed by means of a holder. The holder has an open channel section, in which the sensor device is accommodated, and two clamp elements in the shape of a segment of a circle, which are arranged opposite one another with respect to a longitudinal extension of the channel section. The evaporator tube is clamped between the clamp elements.

SUMMARY OF THE INVENTION

It is one of the objects of the present invention to provide improved solutions for fixing a columnar sensor device to a tube of an evaporator, in particular such solutions that facilitate simple and secure assembly.

This object is achieved according to the invention by a holder with the features of claim 1, an evaporator assembly with the features of claim 12, a refrigeration device with the features of claim 14 and by a method with the features of claim 15.

According to a first aspect of the invention, a holder is provided for fixing a columnar, for example cylindrical, sensor device to a tube of an evaporator for a refrigeration appliance. The holder comprises a first frame part that extends in the longitudinal direction of the holder and a second frame part that extends in the longitudinal direction of the holder and is arranged at a distance from the first frame part in a transverse direction of the holder, wherein the sensor device can be accommodated between the frame parts in such a way that a sensor longitudinal axis of the sensor device is in extends the holder longitudinal direction. The transverse direction of the holder extends transversely to the longitudinal direction of the holder. The holder also includes a crossbar connecting the first and the second frame part, which extends in the holder transverse direction between the first and the second frame part, a first snap clip or snap hook formed on the first frame part, which is spaced apart from the crossbar in relation to a vertical direction of the holder is arranged on the first frame part, extends in an arc from the first frame part in the direction of the second frame part and ends at a distance from the second frame part, in particular in relation to the vertical direction of the holder, and a second snap-in bracket formed on the second frame part, which is spaced apart in relation to the vertical direction of the holder is arranged on the second frame part at a distance from the first snap-on bracket in relation to the transverse web and in relation to the longitudinal direction of the holder, extends in an arc from the second frame part in the direction of the first frame part and ends at a distance from the first frame part, in particular in relation to the vertical direction of the holder. The vertical direction of the holder extends transversely to the longitudinal direction of the holder and transversely to the transverse direction of the holder. The holder can be fixed to the tube of the evaporator in such a way that the tube can be accommodated between the snap brackets and the frame parts in relation to the vertical direction of the holder and the snap brackets partially enclose the tube, with the sensor device in relation to the holder rhochrichtung can be fixed between the tube and the crosspiece.

According to a second aspect of the invention, an evaporator assembly for a refrigerator comprises an evaporator with an evaporator tube, a columnar, e.g. cylindrical sensor device, which is preferably designed to detect a temperature on the evaporator tube, and a holder according to the first aspect of the invention, the holder being designed is fixed to the tube of the evaporator, that the tube is accommodated between the snap brackets and the frame parts with respect to a vertical direction of the holder and the snap brackets partially enclose the tube, and wherein the sensor device is fixed between the tube and the crosspiece with respect to the vertical direction of the holder.

According to a third aspect of the invention, a refrigeration appliance, in particular a household refrigeration appliance such as a refrigerator, a freezer or a fridge-freezer combination, comprises a refrigeration compartment or storage compartment for accommodating refrigerated goods and a refrigerant circuit with an evaporator assembly according to the second aspect of the invention, which is thermally the cold compartment is coupled to extract heat from the cold compartment.

According to a fourth aspect of the invention, a method for fixing a columnar, in particular cylindrical, sensor device to a tube of an evaporator by means of a holder is provided according to the first aspect of the invention. The method includes positioning the sensor device in the holder between the frame parts in such a way that the sensor longitudinal axis is aligned along the holder longitudinal direction, positioning the holder with the sensor device arranged therein on the tube in such a way that the holder longitudinal direction is aligned transversely to the tube and the tube in relation is arranged on the longitudinal direction of the holder between the snap brackets, and fixing the holder on the pipe by rotating the holder about an axis of rotation extending in the vertical direction of the holder, so that the pipe engages or snaps in between the snap brackets and the frame parts.

One idea on which the invention is based is to use a holder to latch or clip an elongated, columnar sensor device, which can have a temperature sensor such as a PTC element, to an evaporator tube, in particular by rotating the holder. For this purpose, the holder is provided with two elongated side or frame parts which are connected by a crossbar and between which the sensor device can be accommodated. The transverse web is arranged at an upper end of the frame parts in relation to the vertical direction of the holder. At a lower end of the frame parts in relation to the vertical direction of the holder, a first and a second snap clip are formed spaced apart from one another in the longitudinal direction of the holder. The snap brackets are elastic and are dimensioned in such a way that they are elastically deformable. Furthermore, each snap clip extends in an arc between a first end connected to the respective frame part and a second or free end, which is located at a distance from the respective other frame part in relation to the vertical direction of the holder. Thus, between the free end of the respective snap bracket and the respective other frame part, there is a window or gap through which the evaporator tube can be pressed with a corresponding rotation of the holder with elastic deformation of the snap bracket. When the holder is fixed to the evaporator tube, the sensor device is clamped between the tube and the crossbar of the holder or is in contact with these parts.

One advantage of the invention is that the holder can be fixed to the pipe in a simple manner by rotating it about an axis of rotation extending transversely to the pipe or in the vertical direction of the holder due to the arrangement and design of the snap-in brackets. Contact between the sensor device and the tube is improved by the transverse web.

Advantageous refinements and developments result from the dependent claims referring back to the independent claims in connection with the description.

According to some embodiments, it can be provided that the holder has a first nose, which is formed on the first frame part and is arranged at a distance from the transverse web in relation to the vertical direction of the holder, and a second nose, which is formed on the second frame part and is arranged in relation to the vertical direction of the holder is arranged at a distance from the transverse web, so that the sensor device can be fixed in relation to the vertical direction of the holder by the first and the second contact projection and the transverse web. The lugs protrude from the respective frame part in the direction of the respective other frame part. The lugs and the crosspiece thus jointly determine a position of the sensor device in relation to the vertical direction of the holder. This makes it easier to hold or fix the sensor device relative to the holder even in a state in which the holder is not fixed to the pipe.

According to some embodiments, it can be provided that the first lug and the second lug are spaced apart in relation to the longitudinal direction of the holder det are arranged relative to one another, and the transverse web is arranged between the first and the second nose with respect to the longitudinal direction of the holder. This prevents the sensor device from tilting about an axis extending in the transverse direction of the holder.

According to some embodiments, it can be provided that the first snap clip and the second snap clip are at a distance from one another in relation to the longitudinal direction of the holder, which is greater than an outside diameter of the tube of the evaporator. This further facilitates assembly, since in this way there is sufficient space between the snap brackets to accommodate the pipe therebetween when the holder is positioned with its holder longitudinal direction transverse to the pipe.

According to some embodiments, it can be provided that the first snap-in bracket is provided with a convexly curved radius in an end region which faces the second frame part. As an alternative or in addition, it can be provided that the second snap-in bracket is provided with a convexly curved radius in an end region which is located facing the first frame part. A convexly curved edge can thus be provided at the free ends of the snap brackets. This makes it easier for the snap brackets to slide off the tube when the holder is rotated and the tube is thereby pushed through the gap between the frame parts and the respective snap bracket.

According to some embodiments, it can be provided that the holder has a securing element with a connecting piece, which is connected to the first and/or the second frame part and protrudes beyond the first frame part in relation to the holder transverse direction, and a locking piece, which in relation to the The holder vertical direction protrudes from the connecting piece in the same direction as the snap brackets from the frame parts, the second snap bracket being arranged between the locking piece and the first snap bracket with respect to the holder longitudinal direction. Accordingly, the locking piece protrudes beyond the frame parts in relation to the vertical direction of the holder. Furthermore, the second snap clip is located adjacent to the locking piece with respect to the longitudinal direction of the holder and opposite thereto with respect to the transverse direction of the holder. When the holder is fixed on the tube, the tube is thus arranged between the locking piece and the second snap bracket with respect to the holder transverse direction. This ensures that the holder is not unintentionally released from the pipe.

According to some embodiments, it can be provided that the locking piece has an edge which is oriented away from the first frame part and runs inclined relative to the holder transverse direction in the direction of the first frame part. This inclined edge makes it easier for the locking piece to slide off the pipe during assembly of the holder on the pipe, during which the securing element, in particular the connecting piece, is elastically deformed.

According to some embodiments, it can be provided that the first frame part and the second frame part each have a shoulder protruding in the holder transverse direction in a first end region. This makes it easier to fix the sensor device in the holder in relation to the longitudinal direction of the holder.

According to some embodiments, it can be provided that the heels are each provided with a bevel. This makes it easier to insert the sensor device between the frame parts.

According to some embodiments, it can be provided that the first frame part and the second frame part are connected to one another in the first end region between the shoulder and one end by a bottom web. This web forms a physical separation or barrier between a cable of the sensor device and the tube when the holder is mounted on the tube, which is particularly advantageous with regard to possible corrosion problems, for example when the tube is made of aluminum and the cable is made of PVC. Optionally, the bottom bar can be arranged in relation to the vertical direction of the holder in such a way that the frame parts protrude over the bottom bar, so that a trough or an open channel is formed in which the cable can be routed.

According to some embodiments, it can be provided that the first frame part and the second frame part are connected to one another in a second end region by an end web extending in the holder transverse direction. This further facilitates the determination of the position of the sensor device in relation to the longitudinal direction of the holder.

According to some embodiments, it can be provided that the evaporator tube has a depression in which the sensor device is arranged. This further facilitates close contacting of the sensor device with the pipe.

According to some embodiments, it can be provided that the frame parts, the crossbar, the snap brackets and possibly also the lugs, the end web, and the securing element are formed in one piece. For example, the entire holder can be produced in a plastic injection molding process.

The features and advantages disclosed herein in connection with one aspect of the invention are also disclosed for the other aspects.

character list

• 1 eine vereinfachte, schematische Schnittansicht eines Kältegeräts gemäß einem Ausführungsbeispiel der Erfindung;
• 2 eine Draufsicht auf einen Halter gemäß einem Ausführungsbeispiel der Erfindung;
• 3 eine perspektivische Ansicht des in 2 gezeigten Halters; und
• 4 eine Draufsicht auf den in den 2 und 3 gezeigten Halter und einer in diesem positionierten Sensoreinrichtung;
• 5 eine Schnittansicht von Halter und Sensoreinrichtung, die sich bei einem Schnitt entlang der in 4 eingezeichneten Linie A-A ergibt;
• 6 eine perspektivische Teilansicht einer Verdampferbaugruppe gemäß einem Ausführungsbeispiel der Erfindung;
• 7 eine weitere perspektivische Teilansicht der in 6 gezeigten Verdampferbaugruppe;
• 8 eine perspektivische Darstellung eines Rohrs eines Verdampfers der in den 6 und 7 gezeigten Verdampferbaugruppe;
• 9 den Schritt eines Positionierens der Sensoreinrichtung in dem in den 2 und 3 gezeigten Halter in einem Verfahren gemäß einem Ausführungsbeispiel der Erfindung;
• 10 die Schritte eines Positionierens des Halters an einem Rohr und des Drehens des Halters in einem Verfahren gemäß einem Ausführungsbeispiel der Erfindung; und
• 11 ein Ablaufdiagramm eines Verfahrens zum Fixieren einer säulenförmigen Sensoreinrichtung an einem Rohr eines Verdampfers mittels eines Halters gemäß einem Ausführungsbeispiel der Erfindung.

The invention is explained below with reference to the figures of the drawings. From the figures show:

• 1 a simplified, schematic sectional view of a refrigerator according to an embodiment of the invention;
• 2 a plan view of a holder according to an embodiment of the invention;
• 3 a perspective view of the in 2 holder shown; and
• 4 a top view of the in the 2 and 3 shown holder and positioned in this sensor device;
• 5 a sectional view of the holder and sensor device, which can be seen in a section along the 4 plotted line AA results;
• 6 a perspective partial view of an evaporator assembly according to an embodiment of the invention;
• 7 another perspective partial view of in 6 shown evaporator assembly;
• 8th a perspective view of a tube of an evaporator in the 6 and 7 shown evaporator assembly;
• 9 the step of positioning the sensor device in the in the 2 and 3 shown holder in a method according to an embodiment of the invention;
• 10 the steps of positioning the holder on a pipe and rotating the holder in a method according to an embodiment of the invention; and
• 11 a flowchart of a method for fixing a columnar sensor device to a tube of an evaporator by means of a holder according to an embodiment of the invention.

In the figures, the same reference symbols designate identical or functionally identical components, unless otherwise stated.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

1 shows schematically a refrigeration device 300 in the form of a household refrigeration device, in particular a refrigerator. However, the invention is not limited to a refrigerator, but can equally be implemented in a fridge-freezer combination, a freezer or another household refrigeration appliance. As in 1 shown schematically, the refrigeration device 300 comprises a storage or refrigeration compartment 310 for accommodating refrigerated goods such as food or beverages, and a refrigerant circuit 320 which is designed to extract heat from the storage compartment 310 and release it to the environment.

The refrigerant circuit 320 includes in particular an evaporator assembly 200 and can also have a compressor 321 for circulating a refrigerant in the refrigerant circuit 320, a condenser 322 and a throttle point 323. The evaporator assembly 200 has an evaporator 210, e.g. in the form of a finned evaporator, and is thermally coupled to the refrigeration compartment 310. For example, the evaporator 200 can be arranged in an evaporator chamber 312 that is separated from the refrigeration compartment 310 by a partition 311, with a fan 315 circulating air between the refrigeration compartment 310 and the evaporator chamber 312 via openings 313, 314 in the partition 311, so that heat can be exchanged between the Evaporator 210 and the air takes place. In the evaporator 210, the refrigerant evaporates while absorbing heat from the air circulated by the fan 315 and is conveyed by the compressor 321 into the condenser 322, where it condenses while giving off heat to the environment. At the throttle point 323, the refrigerant is expanded.

The evaporator 200 has an evaporator tube 211 through which the refrigerant is conducted. As in 1 shown only symbolically, a sensor device 220 is fixed to the evaporator tube 211 in the evaporator assembly 200, in particular via a holder 100 (in 1 Not shown). The sensor device 220 can, for example, have a temperature sensor, for example in the form of a PTC element, in order to detect a temperature on the evaporator tube 211 . This may be advantageous, for example, to implement an evaporator 210 defrosting process in which ice is thawed from the evaporator 210 that may form on the evaporator 210 as a result of condensation of water from the circulated air. An exemplary sensor device 220 is shown, for example, in 4 recognizable. As in 4 As shown, the sensor device 220 may include a columnar housing 225 in which the temperature sensor (not shown) is accommodated. The housing 225 can be cylindrical, for example det be as in 4 shown purely as an example. Furthermore, the sensor device 220 can have a cable 226 in order to forward the measurement signals recorded by the sensor.

The 2 and 3 show a holder 100 for fixing a columnar sensor device 220 to the tube 211 of the evaporator 210. As in FIGS 2 and 3 shown, the holder 100 comprises a first side or frame part 1, a second side or frame part 2, a crosspiece 3, a first snap bracket 4 and a second snap bracket 5. Optionally, the following can also be provided: a first nose 6, a second nose 7, a securing element 8 and/or an end web 9. A bottom web 35 can also optionally be provided.

As in particular in 2 is shown, the frame parts 1, 2 extend along a holder longitudinal direction L and are arranged spaced apart from one another in a holder transverse direction C extending transversely to the holder longitudinal direction L. The frame parts 1, 2 can be designed as essentially plate-shaped, elongate parts which each extend between a first end 11A, 21A and a second end 12A, 22A with respect to the longitudinal direction L of the holder. Furthermore, the frame parts 1, 2 each extend in a vertical direction H of the holder, which runs transversely to the longitudinal direction L of the holder and to the transverse direction C of the holder. As in 2 shown by way of example, the first frame part 1 can form a shoulder 13 projecting in the holder transverse direction C in the direction of the second frame part 2 in a first end section 11 facing the first end 11A. In the same way, the second frame part 2 can form a shoulder 23 protruding in the holder transverse direction C in the direction of the first frame part 1 in a first end section 21 facing the first end 21A. Paragraphs 13, 23 can in particular form an incline in relation to the vertical direction H of the holder, as is shown in 2 is shown schematically.

The crossbar 3 can, as in 2 shown, be designed as a plate-shaped web which connects the first and the second frame part 1, 2 and extends in the holder transverse direction C between the first and the second frame part 1, 2. In particular, the crossbar 3 can be arranged in a central area of the frame parts 1, 2 with respect to the longitudinal direction L of the holder, ie in an area which is spaced apart from the first and second ends 11A, 21A and 12A, 22A. In 3 It can also be seen that the transverse web 3 is provided at an upper end of the frame parts 1, 2 with respect to the vertical direction of the holder.

The optional end web 9 extends at the respective second end 12A, 22A in the holder transverse direction C between the first and the second frame part 1, 2. The end web 9 in particular extends in the holder vertical direction H, as is shown in 3 is shown.

The first snap clip 4 can be arranged, for example, in the second end region 12 of the first frame part 1 and is preferably connected to a lower end of the first frame part 1 in relation to the holder vertical direction H, as is shown in particular in 3 is recognizable. In general, the first snap clip 4 is arranged on the first frame part 1 at a distance from the transverse web 3 with respect to a vertical direction H of the holder. As in 3 shown, the first snap clip 4 extends in an arc from the first frame part 1 in the direction of the second frame part 2 and ends at a distance from the second frame part 2. In particular, a free end 42 of the first snap clip 4, i.e. the end facing away from the first frame part 1, is in Located at a distance from the second frame part 2 with respect to the holder vertical direction H, so that a gap g4 is formed between the lower end of the second frame part 2 and the free end 42 of the first snap bracket 4 .

The second snap clip 5 can be arranged, for example, in the first end region 21 of the second frame part 2 and is preferably connected to a lower end of the second frame part 2 in relation to the holder vertical direction H, as is shown in particular in 3 is recognizable. In general, the second snap bracket 5 is arranged on the second frame part 2 at a distance from the transverse web 3 with respect to a vertical direction H of the holder and at a distance from the first snap bracket 4 with respect to the longitudinal direction L of the holder. As in 3 shown, the second snap bracket 5 extends in an arc from the second frame part 2 in the direction of the first frame part 1 and ends at a distance from the first frame part 1. In particular, a free end 52 of the second snap bracket 5, i.e. one that faces away from the second frame part 2, is in Located at a distance from the first frame part 1 in relation to the holder vertical direction H, so that a gap g4 is formed between the lower end of the first frame part 1 and the free end 52 of the second snap bracket 5 .

As in 2 can also be seen, the crossbar 3 can be arranged in relation to the holder longitudinal direction H in particular between the first and the second snap bracket 4, 5. The first snap clip 4 and the second snap clip 5 can also have a distance d45 from one another in relation to the longitudinal direction L of the holder, which is greater than an outer diameter d211 of the Tube 211 of the evaporator 210, so that the tube 211 can be received between the snap brackets 4, 5 when the holder 100 is positioned relative to the tube 211 in such a way that the holder longitudinal direction L extends transversely to the tube 211, as in FIG 10 shown.

2 shows further by way of example that the first snap clip 4 can be provided with a convexly curved radius r4 in the area of the free end 42, in a section facing the second snap clip 5. The radius r4 thus connects, as in 2 shown, a lateral portion which is oriented towards the second snap bracket 5, with a front portion which is oriented towards the second frame part 2. Alternatively or additionally, the second snap clip can also be provided with a convexly curved radius r5 in the region of the free end 52 in a section facing the first snap clip 4 .

The first lug 6 is formed on the first frame part 1 and can, for example, be arranged at a distance from the transverse web 3 in relation to the longitudinal direction L of the holder, in particular at a distance from the transverse web 3 in the direction of the first end 11A of the first frame part 1, as shown in FIG 2 shown as an example. The first lug 6 is also arranged at a distance from the transverse web 3 with respect to the vertical direction H of the holder and can be formed, for example, in the region of the lower end of the first frame part 1 . As in particular in the 2 and 5 As can be seen, the first lug 6 forms a projection on the first frame part 1 with respect to the holder transverse direction C and protrudes from it in the direction of the second frame part 2 . How 5 further shows, the first nose 6 can have a triangular cross-section.

The second lug 7 is formed on the second frame part 2 and can, for example, be arranged at a distance from the transverse web 3 in relation to the longitudinal direction L of the holder, in particular at a distance from the transverse web 3 in the direction of the second end 22A of the second frame part 2, as shown in FIG 2 shown as an example. In general, the second lug 7 can be arranged at a distance from the first lug 6 in relation to the longitudinal direction L of the holder. Furthermore, the transverse web 3 can optionally be arranged between the first and the second nose 6, 7 in relation to the longitudinal direction L of the holder, as shown in FIG 2 shown as an example. In relation to the vertical direction H of the holder, the second lug 7 is arranged at a distance from the transverse web 3 and can be formed, for example, in the area of the lower end of the second frame part 2 . As in particular in the 2 and 5 As can be seen, the second lug 7 forms a projection on the second frame part 2 with respect to the holder transverse direction C and protrudes from it in the direction of the first frame part 1 . How 5 also shows that the second nose 7 can have a triangular cross-section.

The optional securing element 8 has a connection piece 80 and a locking piece 81 . The connecting piece 80 can be designed, for example, as a plate-shaped part, as in 2 shown by way of example, and is connected to the first and/or the second frame part 1,2. As in 2 shown as an example, the connecting piece 80 can be connected, for example, to the first ends 11A, 21A of the frame parts 1, 2 and can extend from them in the lateral direction, in particular in such a way that it protrudes beyond the first frame part 1 in relation to the holder transverse direction C, as in 2 shown.

The locking piece 81 is connected to the connecting piece 80, for example to an end of the same which is remote from the frame parts 1, 2, as in FIG 2 shown and protrudes from the connector 80 with respect to the vertical direction H. The second snap clip 5 is arranged between the locking piece 81 and the first snap clip 4 with respect to the longitudinal direction L of the holder. As in 3 shown as an example, the connecting piece 80 can protrude in relation to the vertical direction H in particular over the lower ends of the frame parts 1, 2. In general, the locking piece 80 protrudes from the connecting piece 80 in the same direction as the snap brackets 4, 5 from the frame parts 1, 2 with respect to the holder vertical direction H. As in FIG 3 can also be seen, the locking piece 81 can be designed in particular as a plate-shaped part with a trapezoidal circumference. In general, the locking piece 81 can have an edge 81A which is oriented away from the first frame part 1 and runs inclined relative to the holder transverse direction C in the direction of the first frame part 1 .

The optional bottom bar 35 is arranged in the first end region 11, 21 of the frame parts 1, 2. As in 2 As can be seen, the bottom web 35 extends in the holder transverse direction C between the frame parts 1, 2, in particular in an area between the respective first end 11A, 21A of the frame parts 1, 2 and the optional paragraph 13, 23. As in 2 As can be seen, the bottom web 35 can end at a distance from the paragraphs 13, 23 in relation to the longitudinal direction L of the holder. The bottom bar 35 can be arranged between the upper and the lower end of the frame parts 1 , 2 with respect to the vertical direction H of the holder, so that at least the upper end of the frame parts 1 , 2 projects beyond the bottom bar 35 .

The holder 100 may be integral as a whole or may be formed as one piece, for example from a plastics material. That is, the frame parts 1, 2, the cross bar 3, the snap bracket 4, 5, the lugs 6, 7, the securing element 8, the end web 9 and the bottom web 35 can all be formed in one piece and can be produced, for example, in an injection molding process.

4 shows the holder 100 with a sensor device 220 positioned in the holder 100. 5 shows a sectional view of the holder 100 with the sensor device 220 positioned therein. As in FIGS 4 and 5 shown, the sensor device 220 can be fixed in the holder 100 . Sensor device 220 is accommodated between frame parts 1, 2 in a fixed state on holder 100 with respect to holder transverse direction C, with a longitudinal sensor axis A220 of sensor device 220, which can be defined, for example, by the cylinder axis of housing 225, extending along in the Extends holder longitudinal direction L200. As in 5 As can be seen, the position of the sensor device 220 in relation to the holder transverse direction C is fixed by the frame parts 1, 2, with a certain amount of play being able to exist between the frame parts 1, 2 and the sensor device 220. It is not absolutely necessary for the frame parts 1 , 2 to be in contact with the sensor device 220 .

As in 5 also shown, the position of the sensor device 220 in relation to the vertical direction H of the holder is fixed by the lugs 6 , 7 and the crosspiece 3 . Here, too, it is conceivable that the lugs 6 , 7 and the transverse web 3 bear against the sensor device 220 . However, this is not mandatory.

With respect to the longitudinal direction L of the holder, the sensor device 220 can be prevented from falling out by the shoulders 13, 23 and the end web 9, as in FIG 4 apparent. The cable 226 of the sensor device 220 can rest on the bottom bar 35 and be guided through the frame parts 1, 2 in the area of the bottom bar 35 with respect to the holder transverse direction C, as is shown in FIG 4 is shown.

The 6 and 7 show a partial view of the evaporator assembly 200, the holder 100 fixing the sensor device 200 to the tube 211. As in the 6 and 7 shown, the holder 100 is fixed to the tube 211 by means of the snap brackets 4, 5. Here, the holder longitudinal direction L is aligned along the tube 211 and the tube 211 is accommodated or clamped in relation to the holder vertical direction H between the snap brackets 4, 5 and the frame parts 1, 2. The snap brackets 4, 5 embrace or enclose the tube 211 partially. As in the 6 and 7 It can also be seen that the locking piece 81 of the securing element 8 is arranged laterally adjacent to the tube 211, the locking piece 81 and the second snap clip 5 being located on opposite sides of the tube 211 in relation to the holder transverse direction C. The first snap clip 4 is located on the same side of the tube 211 as the locking piece 81 in relation to the holder transverse direction C. In this way, rotation of the holder 100 about an axis of rotation A100 extending in the holder vertical direction H is blocked, which prevents the holder from being released unintentionally 100 counteracts.

The sensor device 220 can in particular be fixed in the holder 100 as described above and is itself fixed to the pipe 211 by the fixing of the holder 100 to the pipe 211 . In 5 1 shows by way of example that the sensor device 220 is fixed in relation to the holder vertical direction H between the lugs 6 , 7 and the crossbar 3 . The sensor device 220 preferably protrudes in part beyond the lugs 6 , 7 so that it can come into contact with the tube 211 when the holder 100 is fixed to the tube 211 . As a result, the sensor device 220 is fixed in relation to the vertical direction H of the holder between the tube 211 and the crossbar 3 . However, it is also conceivable that the sensor device 220 is fixed without the lugs 6, 7 only by the tube 211 and the transverse web 3 in relation to the vertical direction H of the holder. As in 6 It can also be seen that the cable 226 can be separated from the tube 211 by the bottom bar 35 in relation to the vertical direction H of the holder, or contact between the cable 226 and the tube 211 is avoided by the optional bottom bar 35 .

8th shows an example of a view of the evaporator tube 211 without a holder 100 fixed to it. As in FIG 8th shown by way of example, the evaporator tube 211 can have a recess 212 . The holder 100 with the sensor device 220 fixed or arranged therein can in particular be positioned on the tube 211 in such a way that the sensor device 220 is arranged in the recess 212 .

11 shows schematically the sequence of a method M for fixing a columnar sensor device 220 to the tube 211 of the evaporator 210 by means of the holder 100 described above.

In a first step M1, the sensor device 220 is positioned in the holder 100 between the frame parts 1, 2 in such a way that the sensor longitudinal axis A220 is aligned along the longitudinal direction L of the holder. As is exemplified in 9 is shown, the sensor device 220 can be inserted from the first end region 11, 21 of the frame parts 1, 2 obliquely under the crossbar 3 between the frame parts 1, 2, as indicated by the arrow P1, in particular to the extent that the housing 225 in relation to the Longitudinally L completely between the end bar 9 and paragraphs 13, 23 is located. Sensor device 220 can then be tilted about an axis of rotation A221 extending in the transverse direction of the holder, as is shown in FIG 9 is indicated by the arrow P2, so that the sensor longitudinal axis A220 is aligned parallel to the longitudinal direction L of the holder. One end of the housing 225 can slide on the slopes of the paragraphs 13, 23. At the end of step M1, the sensor device 220 is in the position shown in FIGS 4 and 5 shown position.

In step M2, the holder 100 with the sensor device 220 arranged therein is positioned on the pipe 211 in such a way that the holder longitudinal direction L is aligned transversely to the pipe 211 and the pipe 211 is arranged between the snap brackets 4, 5 in relation to the holder longitudinal direction L, as is the case in 10 is shown. In relation to the holder vertical direction H, the lower ends of the frame parts 1, 2 are preferably placed on the tube 211. The snap brackets 4, 5 are positioned in relation to the vertical direction H of the holder so that they overlap the tube 211.

In step M3, the holder 100 is fixed to the tube 211. For this purpose, the holder 100 is rotated about an axis of rotation A100 extending in the holder vertical direction H in such a way that the free ends 42, 52 of the snap brackets 4, 5 are moved in the direction of the tube 211 be like this in 10 is indicated by the arrow P3. The free ends 42, 52 of the snap brackets 4, 5 thereby come into contact with the tube 211, with further rotation of the holder A100 about the axis of rotation A100 having the effect that the snap brackets 4, 5 are elastically deformed and the tube 211 through the gap g4 , g5 ( 3 ) is pushed between the free ends 42, 52 and the frame parts 1, 2 and thus engages or snaps between the snap brackets 4, 5 and the frame parts 1, 2. A sliding of the free ends 42, 52 of the snap brackets 4, 5 on the tube 211 can be prevented by the optional radii r4, r5 ( 2 and 3 ) can be facilitated. The locking piece 81 also comes into contact with the tube 211 as a result of the rotation of the holder 100 in step M3, with further rotation of the holder A100 about the axis of rotation A100 causing the connecting piece 80 and/or the locking piece 81 to be elastically deformed and that Locking piece 81 slides over the tube 211 on the opposite side. This can be facilitated by the optional beveling of the edge 81A of the securing piece 81. At the end of step M3, the holder 100 and the sensor 220 take the 6 and 7 shown position.

Although the present invention has been explained above by way of example using exemplary embodiments, it is not limited thereto but can be modified in many different ways. In particular, combinations of the above exemplary embodiments are also conceivable.

Reference List

1

first frame part

2

second frame part

3

cross bar

4

first snap bracket

5

second snap bracket

6

first nose

7

second nose

8th

fuse element

9

end bar

11

first end area of the first frame part

11A

first end of the first frame part

12

second end area of the first frame part

12A

second end of the first frame part

13

Paragraph of the first frame part

21

first end portion of the second frame part

21A

first end of the second frame part

22

second end area of the second frame part

22A

second end of the second frame part

23

Paragraph of the second frame part

35

bottom walkway

42

free end of the first snap bracket

52

free end of the second snap bracket

80

connector

81

safety piece

81A

edge

100

holder

200

evaporator assembly

210

Evaporator

211

Pipe

220

sensor device

225

Housing of the sensor device

226

Cable

300

refrigeration device

310

refrigeration compartment

311

partition wall

312

vaporizer chamber

313

Recess of the partition wall

314

Recess of the partition wall

320

Refrigerant circulation

321

compressor

322

condenser

323

throttle point

A100

axis of rotation

A220

sensor longitudinal direction

A221

axis of rotation

C

holder transverse direction

d45

Distance between the snap brackets

d211

outside diameter of the tube

g4

gap

g5

gap

H

holder vertical direction

L

Holder longitudinal direction

r4

radius

r5

radius

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• JP H10153491A [0005]

Claims (15)

Holder (100) for fixing a columnar sensor device (220) on a tube (211) of an evaporator (210) for a refrigeration device (300), having: a first frame part (1) extending in a holder longitudinal direction (L); a second frame part (2) extending in the longitudinal direction (L) of the holder and spaced apart from the first frame part (1) in a transverse direction (C) of the holder, the sensor device (220) being able to be received between the frame parts (1, 2) in this way that a longitudinal sensor axis (A220) of the sensor device (220) extends in the holder longitudinal direction (L200); a crossbar (3) connecting the first and the second frame part (1, 2) and extending in the holder transverse direction (C) between the first and the second frame part (1, 2); a first snap bracket (4) formed on the first frame part (1), which is arranged on the first frame part (1) at a distance from the transverse web (3) in relation to a vertical direction (H) of the holder, extending in an arc from the first frame part (1) extends towards the second frame part (2) and ends at a distance from the second frame part (2); and a second snap clip (5) formed on the second frame part (2), which is spaced apart from the transverse web (3) in relation to the holder vertical direction (H) and spaced apart from the first snap clip (4) on the holder in relation to the longitudinal direction (L). second frame part (2), extending arcuately from the second frame part (2) towards the first frame part (1) and terminating at a distance from the first frame part (1); wherein the holder (100) can be fixed to the tube (211) of the evaporator (210) in such a way that the tube (211) is positioned between the snap brackets (4, 5) and the frame parts (1, 2 ) can be accommodated and the snap brackets (4, 5) partially enclose the tube (211), and the sensor device (220) can be fixed between the tube (211) and the crosspiece (3) in relation to the vertical direction (H) of the holder. Holder (100) after claim 1 , additionally comprising: a first lug (6) which is formed on the first frame part (1) and is arranged at a distance from the transverse web (3) in relation to the vertical direction (H) of the holder; and a second lug (7), which is formed on the second frame part (2) and is arranged at a distance from the transverse web (3) in relation to the holder vertical direction (H), so that the sensor device (220) in relation to the holder vertical direction (H ) can be fixed by the first and the second contact projection (4, 5) and the transverse web (3). Holder (100) after claim 2 , wherein the first lug (6) and the second lug (7) are spaced apart from one another with respect to the holder longitudinal direction (L), and the transverse web (3) with respect to the holder longitudinal direction (L) between the first and the second lug ( 6, 7) is arranged. Holder (100) according to one of the preceding claims, wherein the first snap clip (4) and the second snap clip (5) are at a distance (d45) from one another in relation to the longitudinal direction (L) of the holder, which is greater than an outer diameter (d211) of the Tube (211) of the evaporator (210). Holder (100) according to one of the preceding claims, wherein the first snap clip (4) is provided with a convexly curved radius (r4) in an end region (42) which faces the second frame part (2), and/or wherein the second snap bracket (5) is provided with a convexly curved radius (r5) in an end region (52) which faces the first frame part (1). Holder (100) according to any one of the preceding claims, additionally comprising: a securing element (8) with a connecting piece (80), which is connected to the first and/or the second frame part (1, 2) and projects beyond the first frame part (1) in relation to the holder transverse direction (C), and a locking piece (81) projecting from the connecting piece (80) in the same direction as the snap brackets (4, 5) from the frame parts (1, 2) with respect to the holder vertical direction (H); wherein the second snap bracket (5) is arranged between the locking piece (81) and the first snap bracket (4) with respect to the longitudinal direction (L) of the holder. Holder (100) after claim 6 , wherein the locking piece (81) has an edge (81A) which is oriented away from the first frame part (1) and runs inclined relative to the holder transverse direction (C) in the direction of the first frame part (1). Holder (100) according to one of the preceding claims, wherein the first frame part (1) and the second frame part (2) each have a shoulder (13, 23) projecting in the holder transverse direction (C) in a first end region (11, 21). Holder (100) after claim 8 , wherein the paragraphs (13, 23) are each provided with a slope. Holder (100) after claim 8 or 9 , wherein the first frame part (1) and the second frame part (2) are connected to one another in the first end region (11, 21) between the shoulder (13, 23) and one end (11A, 21A) by a bottom web (35). Holder (100) according to one of the preceding claims, wherein the first frame part (1) and the second frame part (2) are connected to one another in a second end region (12, 22) by an end web (9) extending in the holder transverse direction (C). . Evaporator assembly (200) for a refrigeration device (300), comprising: an evaporator (210) having an evaporator tube (211); a columnar sensor device (220), which is preferably designed to detect a temperature on the evaporator tube (211); and a holder (100) according to any one of the preceding claims; wherein the holder (100) is fixed to the pipe (211) of the evaporator (210) in such a way that the pipe (211) is positioned between the snap brackets (4, 5) and the frame parts (1, 2 ) is received and the snap brackets (4, 5) partially enclose the tube (211); and wherein the sensor device (220) is fixed between the tube (211) and the crossbar (3) with respect to the vertical direction (H) of the holder. Evaporator assembly (200) according to claim 12 , wherein the evaporator tube (211) has a recess (212) in which the sensor device (220) is arranged. Refrigeration appliance (300), in particular domestic refrigeration appliance, having: a refrigeration compartment (310) for accommodating refrigerated goods; and a refrigerant circuit (320) with an evaporator assembly (200). claim 12 or 13 , which is thermally coupled to the refrigeration compartment (310) to extract heat from the refrigeration compartment (310). Method (M) for fixing a columnar sensor device (220) to a tube (211) of an evaporator (210) by means of a holder (100) according to one of Claims 1 until 11 , comprising: positioning (M1) of the sensor device (220) in the holder (100) between the frame parts (1, 2) such that the sensor longitudinal axis (A220) is aligned along the holder longitudinal direction (L); Positioning (M2) of the holder (100) with the sensor device (220) arranged therein on the tube (211) in such a way that the holder longitudinal direction (L) is aligned transversely to the tube (211) and the tube (211) in relation to the holder longitudinal direction ( L) is arranged between the snap brackets (4, 5); and fixing (M3) the holder (100) to the tube (211) by rotating the holder (100) about an axis of rotation (A100) extending in the vertical direction (H) of the holder, so that the tube (211) is positioned between the snap brackets (4th , 5) and the frame parts (1, 2) engages or snaps.

Images