WO2011124448A2

WO2011124448A2 - Refrigeration device having an illuminating unit

Info

Publication number: WO2011124448A2
Application number: PCT/EP2011/053876
Authority: WO
Inventors: Christoph Becke; Gerd Wilsdorf
Original assignee: BSH Bosch und Siemens Hausgeräte GmbH
Priority date: 2010-04-09
Filing date: 2011-03-15
Publication date: 2011-10-13
Also published as: WO2011124448A3; EP2556314A2; DE102010003826A1; CN102834683A

Abstract

The invention relates to a refrigeration device comprising an inner space (3) enclosed by a heat insulating body (1) and a door (2), the heat insulating body (1) having a layer made of insulation material (4), which is delimited from the inner space (3) by a deep-drawn inner container (5), and further comprising at least one illuminating unit (7) for illuminating the inner space. The refrigeration device is characterized in that the deep-drawn inner container (5) has at least one thin-walled, translucent area, and an illuminating unit (7) is arranged in the area of a thin-walled, translucent area on the side of the inner container (5) which faces away from the inner space.

Description

Refrigerating appliance with lighting device

The present invention relates to a refrigerator, in particular a domestic refrigerator, with an enclosed by a heat-insulating body and a door interior and at least one illumination device for illuminating the interior.

Refrigeration appliances such as household refrigerators or freezers are conventionally provided with interior lighting, which is either at least partially recessed or projecting on one of the inner walls of the device, usually on the ceiling surface or one of the side walls attached. In most cases, the illumination device consists of a lamp which comprises a single light bulb as the light source. However, by various built-in parts in the device, such as storage trays or pull-out boxes, but also by introduced food, which act as light barriers, large parts of the device by the light emitted by the lamp is not or only inadequately achieved. By the above conventional incandescent lighting, therefore, only uneven illumination of the interior of the device is possible.

Furthermore, the incandescent lighting actually converts only a small fraction of its electrical power consumption into light output; By far the greater part of the power consumption is converted into heat, which undesirably heats the interior space and has to be dissipated.

In addition, the installation of the illumination device takes place from the inside of the container. The inner container of the refrigerator, which limits the interior space against the insulating layer in the body, is generally produced in one piece from a thermoformed plastic element. In order to guide the wiring of the illumination device from the insulation layer into the interior, the inner container must be punched or milled. As a result, the inner container is no longer completely closed. Over a longer period of time, moisture can penetrate the insulation layer of the device via the sealing point.

The document DE 103 39 904 describes a refrigerator with an interior lighting, which comprises at least one organic light-emitting diode (OLED). These For example, the diode can also be integrated in an inner wall of the refrigeration appliance, ie at least one OLED can be located in the wall of the cavity filled with insulating material facing the interior of the appliance. The OLED consists of a substrate, an electrode, one or a plurality of organic layers and a counter electrode. However, this invention assumes that both the substrate and the electrode are transparent. In addition, the inner container of the refrigerator is formed in this document by a plurality of housing plates, ie, the inner container of the device is composed of five separate housing plates, and therefore can not be inexpensively made from a deep-drawn element. This structure also has the disadvantage that through the seals between the housing plates with time condensation can penetrate into the cavity filled with insulating material.

The present invention is therefore based on the object to provide a refrigerator with a lighting device that ensures a uniform illumination of the interior of the device, occupies little space, the interior can not be heated and manufactured inexpensively.

The object is achieved by a refrigeration device having the features of claim 1. The refrigeration device according to the invention has a deep-drawn inner container, which limits the refrigerator interior against the insulating layer in the body. This inner container is deep-drawn so that at least one thin-walled, translucent region is created. Translucency means translucent, but not transparent. The translucent area is perceived by the user as a matt, milky surface which is advantageous in that the lighting unit and possibly the insulation layer are not exactly recognizable to the user.

The thin-walled, translucent area of the inner container is created by the material weakening during deep drawing. Preferably, the translucent region has a material thickness (wall thickness) of 0.2 to 0.8 mm. This wall thickness causes the translucent areas of the inner container have a matte, milky surface. According to the invention, at least one illumination device for illuminating the interior is provided in the region of the thin-walled, translucent region. This Lighting device is located on the side facing away from the interior of the inner container, ie in the insulating layer of the heat-insulating body or between the insulating layer and the inner container wall. This makes it possible to illuminate the interior of the refrigerator partially or horizontally. Advantageously, the wiring of the lighting device in the heat-insulating body.

An advantage of the refrigerator according to the invention is the homogeneous and completely closed inner container. There are no components in which the bulb is captured, in the interior. The smooth container wall is interrupted by no additional parts, there are no edges and joints. In addition, the inner container for the cabling need not be punched or milled.

In addition, the present invention better protects the isolation of the refrigerator from moisture by the completely closed inner container. Since there are no sealing points, the insulation of the refrigeration device remains intact longer. The life cycle of the refrigeration appliance is extended. In addition, a cleaning of the inner container is much easier. With no corners and edges and seams between different materials, the inner container is more hygienic and easier to keep clean. Soiling can be recognized at first glance and easily removed. In addition, the lighting device is no longer visible part and can be produced more cheaply. A previously indispensable light coverage is no longer necessary.

The design of the light surface can adapt to the respective inner container design, since no complex housing parts need to be manufactured, but only the lighting elements are adapted.

Furthermore, the lighting device does not heat the interior and allows a uniform illumination of the interior. The at least one thin-walled, translucent region is preferably located on the side walls of the inner container, but may also be located on the rear wall, the bottom surface or the ceiling surface of the inner container. In one embodiment, at least one side wall of the deep-drawn inner container is thin-walled and transparent. Luzent. Alternatively, the entire inner container can consist of translucent areas, for example, by being made of a deep-drawn board, preferably made of polystyrene, which is processed extremely thin-walled.

The illumination device backlit preferably about 1/5 to 2/3 of the surface of the inner container in order to achieve a uniform and sufficient illumination of the refrigeration device interior. Advantageously, the lighting device is maintenance-free and has, for example, as lighting means. at least one LED on. A maintenance-free lighting device is necessary because the lighting device between the heat-insulating body and deep-drawn inner container, i. in the insulation layer. An exchange of the bulb is therefore difficult.

The lighting device can illuminate the refrigeration device interior partially or over a large area. Partial illumination can be achieved by single LEDs. If several LEDs are arranged next to one another, surface illumination can be achieved.

In one embodiment, the illumination device has at least one light guide. Light guides are, for example, optical waveguides, glass fibers, polymeric optical fibers or other light-conducting components made of plastic as well as fiber optic components. The lighting device may preferably have an optical waveguide (FO) or a lightguide cable (LLK). FO or LLK are made of optical fibers or partially assembled, fitted with connectors and cables for transmission of light. Depending on the application, the optical fibers used, in which the radiation is propagated, consist of mineral glass (usually silica glass or quartz glass), or organic glass (plastic). The light source used for the optical fiber is, for example, LEDs. Preferably, the illumination device has at least one bundle of a plurality of light guides, each starting from a central light source and distributing the light from this light source, ending at various points distributed over the thin-walled, transparent region of the deep-drawn inner container.

The refrigerator according to the invention is also easy with regard to the installation. The lighting device is on the side facing away from the interior of the inner container appropriate. The power supply of the illumination source is advantageously also already laid within the heat-insulating body. Subsequently, the cavity of the heat-insulating body between the inner wall and outer wall is filled with insulation material.

The deep-drawn inner container can be made of thermoplastics, such as polyethylene terephthalate, polystyrene or polypropylene. In a preferred embodiment, the inner container is made of polystyrene. Polystyrene is particularly suitable because of its high degree of stretching.

Further embodiments and advantages of the present invention will be explained below with reference to an embodiment of the present invention. Showing:

1 shows a schematic, horizontal section through an inventive refrigeration device. and

Figure 2 is a schematic partial view of the inner container with light guide.

3 is a schematic plan view of a first embodiment of a lighting device;

Fig. 4 is a schematic plan view of a second embodiment of a lighting device.

1 shows a diagrammatic, horizontal section through a chewing apparatus according to the invention, here a refrigerator, with a heat-insulating body 1 which is composed of an outer skin 6, an insulating layer 4 and an inner container 5 (also called "inner liner"). The deep-drawn inner container 5 limits the heat-insulating body 1 to the interior. The heat-insulating body 1 and a door 2 surround the interior 3 of the refrigerator. On the side facing away from the interior of the deep-drawn inner container 5, the illumination device 7 is attached. The illumination device 7 is behind a thin-walled, translucent area 15 an orderly. The illumination device 7 backlit the translucent region 15, as a result of which the interior 3 of the refrigerator is illuminated.

2 shows a partial view of the refrigerator from FIG. 1. The lighting device 7 is arranged on the side of the insulating layer 4 or the side of the inner container 5 facing away from the interior. The illumination device 7 is composed of a light source 8, for example an LED, and at least one bundle of light guides 9, so that a planar illumination of the interior of the device is possible. The wiring 10 of the illumination device 7 takes place in the insulation layer 4 of the heat-insulating body 1.

3 shows a schematic plan view of a thin-walled, translucent region 15 of an inner container 5, with a lighting device 7 mounted thereon. This is composed here of four light sources, for example LEDs. From each light source 8 radiate several light guides 9, which distribute the light over a larger area and thus ensure that the translucent area 15 is backlit over a large area.

Another embodiment of such a planar illumination is shown in Fig. 4. Again, a plan view of the insulating material facing side of a thin-walled portion 15 of an inner container 5 is shown. At or in the vicinity of this area is a matrix of a larger number of smaller lamps 8, for example LEDs, arranged. For example, 10-100 LEDs together may form a lighting device 7. These are interconnected by current-carrying cables 1 1, which open into the power supply cable 10 routed through the insulation layer 4.

It may be advantageous not to mount the illumination device 7 or its luminous means 8 directly on the inner container 5, but to place a thin layer of a light-scattering material between them. This layer can either be applied to the inner container (on the inside or outside). Alternatively, a thin layer, for example of a Glaserfaser- or plastic fabric between the bulbs 8 and the thin-walled portion 15 of the inner container 5 are laid.

Claims

PATENT CLAIMS

Refrigeration appliance, in particular household refrigeration appliance, with an interior (3) enclosed by a heat-insulating body (1) and a door (2), the heat-insulating body (1) having a layer of insulating material (4) which passes through to the interior (3). a deep-drawn inner container (5), and with at least one lighting device (7) for illuminating the interior, characterized in that the deep-drawn inner container (5) has at least one thin-walled, translucent area, and wherein in the area of a thin-walled, translucent area a Lighting device (7) is arranged on the side of the inner container (5) facing away from the interior.

Refrigeration appliance according to claim 1, wherein at least one side wall of the deep-drawn inner container (5) is thin-walled and translucent.

Refrigeration appliance according to one of the preceding claims, wherein the thin-walled, translucent areas of the deep-drawn inner container (5) have a material thickness of 0.2 to 0.8 mm.

Refrigeration appliance according to one of the preceding claims, wherein the thin-walled, translucent areas backlit by a lighting device (7) take up approximately 1/5 to 2/3 of the area of the inner container (5).

Refrigeration appliance according to one of the preceding claims, wherein the lighting device (7) comprises maintenance-free lamps.

Refrigeration appliance according to one of the preceding claims, wherein the lighting device

(7) comprises at least one light guide. Refrigeration appliance according to one of the preceding claims, wherein the cabling of the lighting device is arranged in the heat-insulating body (1).

8. Refrigeration device according to one of the preceding claims, wherein the deep-drawn inner container (5) is made of polystyrene.