The invention relates to a modular refrigerator such as that described in DE 84 14 798 U1.
The modular refrigerator disclosed in DE 84 15 798 U1 consists of two replaceable lateral walls, a rear wall, a ceiling wall, a bottom wall and a front door which are fastened to one another by means of fastening and articulating means. The lateral walls, the rear wall, the ceiling wall and the bottom wall are each manufactured as a complete unit and form the housing of the refrigerator. A compressor, a condenser, a thermostat and a throttle valve of the refrigerator are all arranged on the rear wall. Electrical lines, whose ends are provided with a plug or plug coupling, extend through the walls. When the housing is assembled the electrical lines are connected together by means of the plugs and pug couplings in such a manner that a closed circuit is formed. The individual walls are then connected together and tightened one against the other with screws, for example. Projections of the electrical lines, the plugs and plug couplings are in this case received in suitable recesses in the walls in a concealed manner. The disadvantage of this design is that the joining of the individual walls and the contacting of the electrical lines are carried out separately.
The object of this invention is therefore to provide a modular refrigerator designed in such a manner that its assembly is simplified.
The object of the invention is achieved by a modular refrigerator comprising a first planar thermally insulated element, a second planar thermally insulated element and further planar thermally insulated elements which can be connected together and which can subsequently be detached from each other, and when connected, form a housing of the refrigerator, a refrigerant circuit which comprises an evaporator, a condenser and a compressor, a first electrical line arranged in the first planar element, a second electrical line arranged in the second planar thermally insulated element, and an electrical contact/counter-contact device by means of which both electric lines may be electrically connected, characterised in that the contact device is integrated in the first planar thermally insulated element and the counter-contact device is integrated in the second planar thermally insulate element in such a manner that the contact device automatically contacts the counter-contact device electrically during the mechanical connection of the first and second planar elements. The modular refrigerator according to the invention is provided, in particular, for being supplied in the unassembled condition, i.e. disassembled, to an end consumer, for example, so that this or these planar thermally insulated elements, which comprise two lateral elements, one bottom element, a ceiling element and a rear wall, for example, can be assembled together to form a functional refrigerator. However, planar thermally insulated elements may also be a combination of a lateral element and a ceiling element, for example, i.e. a planar thermally insulated element is part of the housing of the refrigerator. The individual planar thermally insulated elements may each comprise an inner lining and an outer lining which surround a cavity filled with a thermal insulation material. In addition to a mechanical connection of the planar thermally insulated elements it is also necessary to make electrical connections, e.g. an electrical line from the refrigeration control system to the refrigerant circuit. Because the contact device automatically contacts the counter-contact device during the mechanical connection of the two planar thermally insulated elements, i.e. the contact device automatically contacts the counter-contact device during the mechanical assembly of the housing, the required electrical connections are established during the mechanical assembly of the housing. Separate manual joining of the electrical contact/counter-contact device is therefore unnecessary, thereby simplifying the assembly of the housing.
According to variants of the refrigerator according to the invention the contact/counter-contact device is an electrical plug-socket device and/or the first or second planar thermally insulated element is the rear wall of the housing, the refrigerant circuit being arranged on the rear wall.
If the rear wall is to be designed particularly compactly, it may comprise a recess arranged in the lower region of the rear wall, in which recess the compressor is fastened. The size of the recess is preferably adapted to the spatial extensions of the compressor and preferably does not therefore extend throughout the width of the rear wall. To enable the compressor to discharge exhaust heat into the atmosphere surrounding the assembled refrigerator, the recess may be accessible from outside the housing.
If the electricity supply for the electronic components of the refrigerator derives from the rear wall, as is provided for according to a further variant of the refrigerator according to the invention, the cost of the electricity supply for the entire refrigerator can be minimised and the refrigerator can therefore be designed as compactly as possible.
To ensure that the refrigerator according to the invention has as few electrical connection points as possible, both the electricity supply for the electronic components and the electrical control signal from the electronic components to the refrigerant circuit can be supplied via the electrical contact/counter-contact device according to one embodiment.
If, according to a further variant of the refrigerator according to the invention, all the electronic components are combined to form a single electronic unit, the number of electrical lines is reduced. The electronic components comprise, for example, a temperature sensor, the temperature regulating electronics, a setting device for setting the theoretical temperature or a luminous device for illuminating the interior of the housing.
According to a variant of the refrigerator according to the invention the electronic unit is fastened to one inner side of the first or second planar thermally insulated element.
For example, in order to reduce the cost of laying the electrical lines, channel is integrated inside the housing for feeding through at least one of the two electrical lines according to a further variant of the refrigerator according to the invention. This channel may, for example, be in the form of an empty tube or may also be provided for establishing a refrigerant circuit connection. The channel is advantageously laid in the planar thermally-insulated element to which the electronic unit is also fastened. It is particularly advantage for one of the channel to lead to the electronic unit and the other end of the channel to the counter-contact device, so that both the electricity supply for the electronic unit and the electrical line for the electrical control signals transmitted by the electronic unit for the refrigerant circuit to be able to be conducted in the same channel. This provides a relatively clearly arranged and simple electrical line routing. It is also advantageous for the channel to run in the rear wall and for one of the channel to terminate at the electrical contact device so that the electricity supply for the electronic unit and the electrical line for the electrical control signals transmitted by the electronic unit for the refrigerant circuit again to be conducted in this channel.
An exemplary embodiment of a modular refrigerator according to the invention is shown by way of example in the diagrammatic figures below.
Both lateral walls 2 and 3, ceiling element 4, bottom element 5, rear wall 6 and door 7 are designed as planar thermally insulated elements and in the case of this exemplary embodiment each comprise an inner and an outer lining which surround a cavity filled with a thermal insulation material. In the case of this exemplary embodiment the thermal insulation material is an insulating foam 12.
Furthermore, the entire refrigerant circuit of refrigerator 1 is fastened to rear wall 6. The refrigerant circuit comprises essentially an evaporator 8, a condenser 9, lines connecting evaporator 8, condenser 9 and compressor 10, not shown in detail in the figures, and a refrigerant not shown in greater detail. Both evaporator 8 and condenser 9, which are tube-on-plate heat transmitters in this exemplary embodiment, are connected by foam to the insulating foam 12 of rear wall 6. In this case evaporator 8 is in heat conducting contact with inner lining 6a and condenser 9 is in heat conducting contact with outer lining 6b. This enables condenser 9 to discharge its heat relatively effectively to the air surrounding refrigerator 1 and evaporator 8 to cool relatively effectively the interior of housing G of refrigerator 1. It also makes it possible to arrange as much insulating foam 12 as possible to be arranged between evaporator 8 and condenser 9, which means that condenser 9 heats evaporator 8 as little as possible.
In this exemplary embodiment rear wall 6 comprises a recess 6c arranged in the lower region of rear wall 6, in which recess is fastened a compressor 10. Recess 6c is constructed so that it is accessible from outside housing G of refrigerator 1 so that compressor 10 is able to discharge its heat relatively effectively to the air surrounding housing G. In this exemplary embodiment recess 6c does not extend throughout the width of housing G. Compressor 10 is also supplied with electricity via a mains cable 13.
In this exemplary embodiment the refrigerant circuit is tested before delivery of the disassembled refrigerator 1 and is fully functional, i.e. refrigerator 1 is ready for operation as soon as it is assembled and connected to an electricity mains.
In this exemplary embodiment refrigerator 1 comprises another electronic unit 14 in which all the electronic components of refrigerator 1 are assembled. Electronic unit 14 is shown in greater detail in
In order to regulate the temperature of refrigerating appliance 1, electronic unit 14 is electrically connected to compressor 10 when refrigerator 1 is assembled. In this exemplary embodiment this electrical connection comprises an electrical line 30 which runs in a channel running in ceiling element 4 of refrigerator 1, which channel is in this exemplary embodiment an empty tube 31, an electrical line 32 which runs in a channel running in rear wall 6, which channel is in this exemplary embodiment an empty tube 33, and an electrical contact and counter-contact device, which in this exemplary embodiment is an electrical plug-socket device. Socket 34a of the plug-socket device is here fastened to ceiling element 4 and plug 34b of the plug-socket device is fastened to rear wall 6.
In this exemplary embodiment empty tube 33 is lathered in insulating foam 12 of rear wall 6 and empty tube 31 is lathered in the insulating foam of ceiling element 4. The one end of empty tube 31 integrated in ceiling element 4 leads to electronic unit 14, and the other end of empty tube 31 leads to socket 34a. The one end of empty tube 33 integrated in rear wall 6 leads to recess 6c and the other end of empty tube 33 leads to plug 34b. Electrical line 30 running in empty tube 31 electrically connects electronic unit 14 to socket 34a, electrical line 32 running in empty tube 33 connects compressor 10 electrically to plug 34b, and plug 34b and socket 34a are designed so that when assembled, electronic unit 14 is electrically connected to compressor 10 so that electronic unit 14 activates compressor 10 according to the set theoretical temperature and the actual temperature measured with temperature sensor 15.
An electricity supply provided for electronic unit 14, in the form of electrical lines 35 and 36, which are also laid in empty tubes 31 and 33 and are connected to one another by means of the plug-socket device. Power supply 37 required for establishing the low voltage is secured in recess 6c of rear wall 6 in this exemplary embodiment.
The assembly of refrigerator 1 is now explained in more detail in the following with reference to
In this exemplary embodiment furniture fittings 40 each comprise a metal pin 40a, which is provided with a thread 40b. In this exemplary embodiment thread 40b is screwed into holes 41 predrilled into rear wall 6 with a screwdriver, not shown. One of metal pins 40a′ is shown in
After metal pins 40a have been screwed into rear wall 6, bottom element 5, which in this exemplary embodiment comprises predrilled holes 42 corresponding to metal pins 40a, are fitted to rear wall 6 in the direction of arrows 43 so that metal pins 40a screwed in rear wall 6 are inserted into holes 42 of bottom element 5 corresponding to them. Metal pins 40a are then provided with lock nuts 40c, by means of the screwdriver, so that rear wall 6 and bottom element 5 are fixedly connected to one another, as shown in
After bottom element 5 and rear wall 6 have been fixedly connected to one another by means of furniture fittings 40, further metal pins 40a are screwed into rear wall 6 in holes predrilled for this purpose. These screwed metal pins 40a are shown in
Finally, in order to assembly housing G fully both lateral walls 2 and 3 are also connected to furniture fittings 40, rear wall 6, ceiling element 4 and bottom element 5. The fully assembled housing G is shown in
Moreover, two further fittings 70 and 71 are each screwed with two screws 72 to the lower side of housing G. One of fittings 71 is provided with a pin 73 to which door 7 of refrigerator 1 can be pivotably fastened. As illustrated in
A further fitting 80 is then screwed on with screws 81 to the upper side of housing G, as can be seen in
In this exemplary embodiment evaporator 8 and condenser 9 are essentially identical tube-on-plate heat transmitters. In particular, different tube-on-plate heat transmitters may also be used for evaporator 8 and condenser 9. Other types of heat transmitters are also conceivable for evaporator 8 and condenser 9. In particular, a roll-bond evaporator is suitable.
Number | Date | Country | Kind |
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10 2004 052 622 | Oct 2004 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2005/055128 | 10/10/2005 | WO | 00 | 4/27/2007 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2006/045694 | 5/4/2006 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3349220 | Kinney | Oct 1967 | A |
5921095 | Lee et al. | Jul 1999 | A |
6071015 | Erbse et al. | Jun 2000 | A |
20060144058 | Kentner et al. | Jul 2006 | A1 |
Number | Date | Country |
---|---|---|
84 15 798 | Sep 1985 | DE |
7-294097 | Nov 1995 | JP |
2002-228345 | Aug 2002 | JP |
WO2004062444 | Jul 2004 | WO |
Number | Date | Country | |
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20090064700 A1 | Mar 2009 | US |