EP1305559A1

EP1305559A1 - Refrigeration device

Info

Publication number: EP1305559A1
Application number: EP01951688A
Authority: EP
Inventors: Walter Woldenberg; Thomas Kranz
Original assignee: BSH Bosch und Siemens Hausgeraete GmbH
Current assignee: BSH Hausgeraete GmbH
Priority date: 2000-07-20
Filing date: 2001-07-17
Publication date: 2003-05-02
Anticipated expiration: 2021-07-17
Also published as: CN1232788C; WO2002008676A1; ATE310217T1; PL362504A1; DE50108100D1; US6644044B2; US20030110783A1; ES2252256T3; EP1305559B1; PL198312B1; CN1443294A; BR0112536A; EP1305559B8; DE20012619U1

Abstract

A multi-temperature refrigerator, of which the evaporators serving for cooling the compartments of different temperature can be activated separately through a 3/2-way solenoid valve, the solenoid valve being followed, for lowering the pressure of the refrigerant in relation to the respective evaporator, by a throttle line includes a marking on the throttle for mounting the line in a correct position on the solenoid valve. The invention forms the marking for the throttle lines with a separate component that can be applied to the throttle line positively and/or nonpositively.

Description

The refrigerator

The invention relates to a refrigeration device with a heat-insulating housing, within which at least two refrigeration compartments of different temperatures are provided, the evaporators of which can be controlled separately from one another by at least one control element, with each of the evaporator inflow on the inflow side being preceded by a throttle line which is forcibly circulated by a refrigerant compressor and serves to reduce the pressure , of which at least one is equipped with an identifier for its correct position assignment to the control element.

In multi-temperature zone refrigerators, it is known to use 3/2-way solenoid valves to act on the evaporators assigned to the individual refrigeration compartments, to which so-called capillary tubes are installed in order to reduce the pressure of the refrigerant forcedly circulated by a refrigerant compressor. In order to connect the capillary tubes in the correct position with the outputs of the 3/2 way solenoid valve, IDs have so far been used on the capillary tubes in the form of color markings and wavy shape of the capillary tube. This type of labeling of the capillary tubes has shown that after the manufacturing process of the refrigerator due to the previous manufacturing process, the labeling for the correct connection of the capillary tube to the solenoid valve is so far beyond recognition that a clear assignment of the respective capillary tube to the correct one Output of the solenoid valve is no longer possible for a production employee.

The invention has for its object to improve the disadvantages inherent in the prior art with simple design measures. This object is achieved according to the invention in that the identifier is formed by a separate component that is positively and / or non-positively applied to the throttle line.

By marking the invention according to the example as 3/2

An identifying element is provided for the directional solenoid valve of the control element facing the control element, which ensures a permanent, easily visualizable and thus direct assignment of the throttle line end sections to the respective outlet of the solenoid valve even after a production run. As a result, a production employee can quickly and accurately mount the cable ends in the correct position. In addition, such identification of the throttle line is both insensitive to temperature influences and deformations occurring on the throttle lines designed as capillary tubes during the production run of the refrigeration device. In this respect, permanent identification of the throttle line is provided, which makes it possible to handle a refrigeration device in its manufacturing process without any special precautionary measures that take the labeling into account.

A component used to identify the throttle lines can be provided particularly cost-effectively if, according to a preferred embodiment of the

The object of the invention is that the component is designed as a commercially available standard component. The use of a commercially available standard component consequently avoids costly in-house developments for a component for marking the throttle line.

The component is particularly simple to attach to the throttle line designed as a capillary tube if, according to a next advantageous embodiment of the object of the invention, it is provided that the component is provided on the circumferential surface of the throttle line, at least in sections, on its circumference.

The throttle line end sections to be connected on the output side to the multi-way solenoid valve are particularly clearly distinguishable if, according to a further preferred embodiment of the object of the invention, it is provided that the component engages around the throttle line in a pipe-like manner in the fastening state. Through the clear visual identification of the connection section of the Throttle lines are not only much easier for the connection work for the production personnel, but also significantly reduce the time required for the correct assignment.

The commercially available component for identifying the throttle lines can be attached particularly inexpensively and quickly, positionally securely and in a manner that is easy to manufacture if, according to a next preferred embodiment of the object of the invention, it is provided that the component is designed as a commercially available standard crimping part.

In a particularly simple manner, with several throttles designed as capillary tubes, a positionally reliable assignment to the connections of the multi-way solenoid valve is ensured if, according to a last preferred embodiment of the subject matter of the invention, it is provided that each of the throttle lines is marked, the number of lines serving for identification Components per throttle line is different.

The invention is explained in the following description using the example of a three-temperature zone refrigerator. Show it:

1 is a three-temperature household cooling device with, thermally separated compartments of different temperature, cooled in a cooling capacity adapted by an evaporator, spatial in front view,

Fig. 2 in a simplified schematic representation of the refrigeration system of the cooling device with the evaporators arranged therein and equipped on the inflow side with a throttle device and

3 a section of one of the capillary tubes

Throttle devices with an identification applied on the jacket side, in a spatial view from above. 1, a three-temperature household cooling device 10 with a heat-insulating housing 11 is shown. The housing 11 serves to accommodate three heat-insulating cold compartments 13, 14, 15, each of which can be closed by a separate door 15, 16, 17. Of the cold compartments 12 to 14, the overhead compartment that can be closed with the door 15 is designed as a freezer compartment, the middle compartment 13, to which the door 16 is assigned, is designed as a normal refrigeration compartment, while the underlying refrigeration compartment 14 serves as a cellar compartment and can be locked with the door 17. The different temperatures in the individual refrigeration compartments 12 to 14 are maintained with a refrigeration system 18 shown in simplified form in FIG. 2.

In the refrigeration system 18 shown in FIG. 2, the electronic control device and its signal and control lines have been omitted for the sake of simplicity. The refrigeration system 18 has a compressor 19, which is followed by a condenser 20 and a dryer 21 on the pressure side in series connection. The dryer 21 is connected on the discharge side to a first, electrically operated 3/2 way solenoid valve 22, which is fluidically coupled with one of its outputs to the input of a second similar 3/2 way solenoid valve 23, forming a series connection between these two. Due to the still free outputs of the valve units arranged in series with one another and designed as electromagnetically operated 3/2 way valves, three different ones are available

Refrigeration circuits I, II and III are formed, which can be acted upon with refrigerant. The 3/2 way solenoid valves 22 and 23 are part of the refrigerant circuits I, II and III and serve as control elements for the refrigerant supply to the respective refrigeration circuit, whereby they divert the refrigerant flow arriving from the condenser 20 via the dryer cartridge 21 into one of the circuits. Each of the outputs of the 3/2 way solenoid valves, which represent the entrance to the refrigeration circuits I to III, is immediately followed by an evaporator, with a first evaporator 24 in the refrigeration circuit I for cooling the freezer compartment 12 and a second one in the refrigeration circuit III Evaporator 25 for maintaining the temperature in the normal cooling compartment 13 and a last evaporator 26 located in the cooling circuit II serves to cool the cellar compartment 14. A throttle element 27, 28 and 29 is provided between the inputs of the evaporators 24 to 26 and the outputs of the 3/2 way solenoid valves 22 and 23, which serve as inputs for the cooling circuits I to III. In the present case, each of these throttle elements 27 to 29 is designed as a capillary tube which is wound in a spiral-like manner and which is used to lower the pressure of the refrigerant coming from the condenser 20 to the respective working pressure of the respectively assigned evaporator 24 to 26 is used.

As can be seen in particular from FIG. 3, the throttle elements 27 to 29 designed as capillary tubes (here the capillary tube 27 is shown as an example) are provided on their jacket side 30 with a commercially available component 31 serving as an identifier. The components 31 provided for identifying the individual capillary tubes serve to indicate the correct assignment to the outputs of the solenoid valves 22 and 23 for controlling the individual evaporators 24 to 26. For identifying the assignment of the capillary tubes to the

The outputs of the solenoid valves 22 and 23 are, for example, the capillary tube 27 introduced into the cooling circuit I with a component 31, the capillary tube 28 introduced into the cooling circuit II with two components 31, and the capillary tube 29 introduced into the cooling circuit III with three components 31. In the present case, the components 31 are designed as standard grimp parts and encompass the jacket side 30 of the capillary tubes 27 to 29 over a defined length in a tube-like manner. The components 31 arranged on the jacket side of the throttle lines 27 to 29 designed as a capillary tube are positively and non-positively fixed on the jacket side 30, the components 31 designed as commercially available crimping parts being fastened by their deformation in the manner of a tube. Due to the tube-like shape of the components 31, the inside encloses the jacket side 30 of the throttle lines 27 to 29, the free ends of the components 31 facing each other after the tube-like shape being at least slightly buried in the jacket wall of the throttle lines 27 to 29 for fastening them. In this way, the components 31 are held non-slip on the jacket wall of the throttle lines 27 to 29.

Due to the type of identification of the throttle lines 27 to 29 on the basis of the components 31 on the one hand and their positive and non-positive attachment on the other hand, an identifier is provided on the throttle lines 27 to 29, which is also securely positioned on the throttle lines 27 to during the production run of a refrigeration device 29 is set. This considerably simplifies the assignment of the individual throttle lines 27 to 29 to the corresponding outputs of the solenoid valves 22 and 23 for the production personnel. It goes without saying that in addition to the exemplary number of components 31 provided for identifying the throttle lines 27 to 29, other numerical assignments of the components 31 to distinguish the throttle lines 27 to 29 and their assignment to the outputs of the solenoid valves 22 and 23 are also possible.

Claims

claims

1.Refrigeration device with a heat-insulating housing, in which at least two refrigeration compartments of different temperatures are provided, the evaporators of which can be controlled separately from one another by at least one control element, each of the evaporators on the inflow side being connected upstream of a throttle line which is forcibly circulated by a refrigerant compressor and serves to reduce the pressure which at least one is equipped with an identifier for its correct position assignment to the control element, characterized in that the identifier is formed by a separate component (31) applied to the throttle line (27, 28, 29) in a positive and / or non-positive manner.

2. Refrigerating appliance according to claim 1, characterized in that the component (31) is designed as a commercially available standard component.

3. Refrigerating appliance according to claim 1 or 2, characterized in that the component (31) on the outer surface (30) of the throttle line (27, 28, 29) is provided at least in sections.

4. Refrigerating appliance according to one of claims 1 to 3, characterized in that the component (31) in the attached state surrounds the throttle line (27, 28, 29) in a tube-like manner.

5. Refrigerating appliance according to one of claims 1 to 4, characterized in that the component (31) is designed as a commercially available standard crimping part.

6. Refrigerating appliance according to one of claims 1 to 5, characterized in that each of the throttle lines (27, 28, 29) is characterized, the number of components used for identification (31) per throttle line (27, 28, 29) is different ,