Abstract:
A refrigerating appliance includes a heat insulating housing and an inner chamber that is cooled by the circulation of cooling air. A hollow body extends in the inner chamber, defining a flow channel for the cooling air. Carriers for goods to be cooled are disposed in the inner chamber and are supported on the hollow body.

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
   This application is a continuation, under 35 U.S.C. § 120, of copending international application No. PCT/EP02/10209, filed Sep. 11, 2002, which designated the United States; this application also claims the priority, under 35 U.S.C. § 119, of German patent application No. 101 45 141.5, filed Sep. 13, 2001; the prior applications are herewith incorporated by reference in their entirety. 

   BACKGROUND OF THE INVENTION 
   Field of the Invention 
   The invention relates to a refrigerator having a thermally insulating housing and an internal area that is cooled by cooling air circulation and in which a hollow body extends that bounds a flow channel for the cooling air. 
   In conventional refrigerators of this type, the hollow body, which is also referred to as a multi-air-flow channel, is fitted centrally to the inner face of the refrigerator rear wall. This part, which can be seen by the user, is normally formed from an outer cover or sheath composed of a thermoplastic (SB, ABS) with an insulating part that is mounted in it in an interlocking and/or force-fitting manner. The sheath is attached to the rearward inner wall of the refrigerator by a screw connection and spacers on the foam side. Air channels are formed in the insulating part, in which cooling air is passed from the cold generator to the internal area of the refrigerator. The cooling air passes through openings in the insulating part and in the sheath into the internal area or cooling area. 
   Cooled item supports such as glass plates or gratings, on which the foods to be stored may be placed, are generally supported in conventional refrigerators on ribs that are integrally formed on the internal container of the refrigerator. It is also known for side depressions to be integrally formed in the walls of the internal container, in which connecting parts can be mounted, which are themselves used to support the cooled item supports. 
   Such a support has a number of disadvantages. Firstly, the ribs or depressions that are required to support the cooled item supports considerably complicate the molding of the internal container of the refrigerator that is normally produced by thermoforming a plastic panel. Specifically, to form the ribs or depressions, the mold must have so-called transverse slides that can be moved transversely with respect to a main forming direction (the depth direction of the internal container). These moving mold parts contribute considerably to the costs of the molds and increase the cost of their maintenance. Furthermore, their presence means that the original panel from which the internal container is formed is subjected to considerable stretching particularly in the areas that subsequently have to bear the load of the cooled item supports and of the cooled items located thereon so that the thickness of the original panel must be configured with a large safety margin to prevent the load from damaging the ribs or depressions during use of the refrigerator. 
   However, if damage nevertheless occurs, it is effectively uneconomic to repair such damage because the internal container of the refrigerator cannot be removed and replaced without, at the same time, damaging the insulating foam layer that surrounds it. 
   Furthermore, considerable effort is required by the user to clean such an internal container due to its uneven surfaces. 
   SUMMARY OF THE INVENTION 
   It is accordingly an object of the invention to provide a refrigerator with cooling air circulation that overcomes the hereinafore-mentioned disadvantages of the heretofore-known devices of this general type and that has an internal container formed by thermoforming using simple molds, and in which an original panel with thin walls may be used, and that can be cleaned easier by a user. 
   With the foregoing and other objects in view, there is provided, in accordance with the invention, a refrigerator, including a thermally insulating housing defining an internal area cooled by circulation of cooling air, a hollow body disposed in the internal area and bounding a flow channel for guiding the cooling air, and cooled item supports disposed in the internal area and supported on the hollow body. 
   Because, according to the invention, the cooled item supports that are disposed in the internal area of the refrigerator are supported on the hollow body, there is no need to form ribs, depressions, or other molding features for supporting the cooled item supports on the internal container of the refrigerator. Thus, it is possible to use simple, low-cost thermoforming molds. The absence of these molding features allows the use of original panels with thinner walls for forming the internal container so that material can be saved and costs can be reduced without this leading to any reduction in the robustness or life of the internal container. 
   The lack of molding features, furthermore, makes it possible to construct the walls of the internal container to be flat so that they can be cleaned quickly and effectively. 
   In accordance with another feature of the invention, the hollow body is, preferably, disposed such that it is in contact with a first wall, preferably, the rear wall, of the internal area. In such a configuration, the flow channel for the cooling air may be bounded, on one hand, by the hollow body and, on the other hand, by the first wall. 
   Connecting bodies such as screws, rivets, or the like may be used to attach the hollow body to the first wall and are, preferably, each connected to a stiffening part that is disposed behind the first wall, in particular, in the case of a refrigerator with an internal container, an outer wall, and a foam layer (which is disposed between the internal container and the outer wall) on that face of the internal container that faces the foam. 
   Alternatively or in conjunction with the connecting body, it is also possible to provide at least one projection (which is disposed on a second wall adjacent to the first wall) for holding the hollow body. In such a case, the second wall may not only be a side wall but also, and, preferably, a top or bottom of the internal container. 
   One preferred way to attach the hollow body is to use at least two projections, one on the second wall and one on a third wall opposite the second wall, with at least one of these projections having a wedge-shaped cross-section with a steep face touching the hollow body, and an oblique face facing away from the hollow body. These projections allow the hollow body to be attached by latching by, first of all, pushing one end of the hollow body over the oblique face of the projection against the first wall, and, finally, by latching it in behind the steep face, simultaneously making contact with it and with the first wall. 
   In accordance with a further feature of the invention, these projections are, preferably, each formed integrally with their walls and, in particular, they may expediently be formed in one operation during the thermoforming of the internal container. 
   In accordance with an added feature of the invention, the hollow body is provided with a large number of holders that are disposed along at least one vertical line and in which suspension hooks on the cooled item supports engage. Such a configuration allows different numbers of cooled item supports to be fitted at different levels corresponding to the position of the holders, depending on the requirements of the user of the refrigerator. This way of holding the cooled item supports, in principle, allows the heights of the cooled item supports to be adjusted in finer steps than in the case of the prior art. 
   In accordance with an additional feature of the invention, there is provided a at least one vertical rail for attachment of the cooled item supports to the hollow body and the rail has at least one toothed latching strip and an opposing bearing strip that is oriented in the other direction to the latching strip. In a complementary manner with respect thereto, each cooled item support has a lever section with an end that can be supported on the teeth of the latching strip, and with an end that can be supported on the opposing bearing strip. The weight of the cooled item support and of any cooled items that may be located on it results in a lever moment being applied to this lever section, pushing each of its ends against the latching strip or the opposing bearing strip. By pivoting a cooled item support against the torque, a user can disengage the lever section from the latching strip and the opposing bearing strip and can vary its height along the rail. Such a configuration allows the height of the cooled item support to be adjusted extremely finely in steps that each correspond to the distance between the teeth on the latching strip. This distance may be from a few millimeters up to a centimeter, preferably, about 5 mm. 
   In accordance with yet another feature of the invention, the rail is formed by the boundary walls of an elongated cavity, which is connected to the internal area of the refrigerator by a slot. The latching strip is, then, expediently disposed on a face of the cavity facing away from the internal area. Such a rail configuration may be produced not only with particularly low weight but, at the same time, also such that it is particularly stiff when loaded. In particular, such a rail allows guide functions for the lever section on the cooled item support to be produced in a simple manner. 
   To make it possible for a user to remove cooled item supports and to install them as well, the slot, preferably, has a broadened section that is configured for a lever section of a cooled item support such as this to pass through. 
   In accordance with yet a further feature of the invention, the broadened section is, preferably, located at the upper end or lower end of the slot. 
   If the broadened section is disposed at the upper end of the slot, then, if the lever section is at the same level as a supporting surface for the cooled item support, it is possible for a problem to arise in that the lever section can be inserted but, because the supporting surface is abutting against the top of the internal area, the cooled item support cannot be pivoted sufficiently to allow it to be lowered to a desired height without the lever section being blocked on a tooth of the latching section. To avoid such a situation, the lever section is, expediently, disposed at such a distance above the supporting surface for the cooled item support that the top of the internal container does not impede pivoting of the cooled item support, as is necessary to prevent the lever section from engaging with the latching strip. 
   In accordance with yet an added feature of the invention, the slot extends along the side of the rail that is oriented substantially at right angles to the latching strip and/or to the opposing bearing strip. Such a configuration has the advantage that it is possible, simply by pivoting the cooled item support, to detach the lever section from the rail at the side so that cooled item supports can be installed and removed at any desired level in the internal area of the refrigerator between already existing cooled item supports, without it being necessary to remove adjacent cooled item supports for this purpose. 
   In accordance with yet an additional feature of the invention, the rail is a profiled element with a T-shaped cross-section. With such a rail, the latching strip and the opposing bearing strip are, preferably, disposed on surfaces of the transverse bar of the T-shaped cross-section that face away from one another. 
   In accordance with again another feature of the invention, the cooled item supports are each equipped with a locking lever that prevents inadvertent release or pivoting of the cooled item support. Such a locking lever may, expediently, have a locking finger that can be moved between a locked position, in which it rests on the latching strip or on the opposing bearing strip, and a released position. In the locked position, together with the ends of the lever section, the locking finger forms a third contact point between the cooled item support and the rail, preventing any pivoting movement of the cooled item support with respect to the rail. 
   As an alternative thereto, the hollow body may also be provided with a locking bar for locking the position of the cooled item supports. Such a locking bar allows all of the cooled item supports to be locked or released in one action. 
   In a complementary manner to the locking bar, the cooled item supports are, preferably, each provided with a vertically oriented contour, in particular, a groove, which can be engaged with the locking bar to lock the pivoting movement of the cooled item supports. 
   In accordance with again a further feature of the invention, the hollow body is, preferably, an extruded profile, in particular, is composed of metal, for example, aluminum or a fiber-reinforced plastic. Such a profile can be produced using tools that are simpler and cheaper than those for thermoforming a complicated shape, in particular, when moldings that can move in two or more directions have to be thermoformed. Furthermore, the use of the extruded profile results in a further cost advantage if a profile with the same cross-section is used in different models of refrigerators, in which case, for models whose internal containers are of different heights, it is sufficient to cut the profile to a suitable length for matching purposes, and there is no need for any adaptation of the profile whatsoever for different internal container widths. 
   In accordance with again an added feature of the invention, the hollow body has air passage openings and actuator-controlled closure shutters are fitted to the air passage openings for selectively closing the air passage openings. 
   With the objects of the invention in view, there is also provided a refrigerator, including a thermally insulating housing defining an internal area cooled by circulation of cooling air, a hollow body disposed in the internal area and bounding a flow channel for guiding the cooling air, cooled item supports disposed in the internal area and supported on the hollow body, the cooled item supports having suspension hooks, the hollow body having a plurality of holders disposed along at least one vertical line for holding the cooled item supports, and the suspension hooks engaging the holders to hold the cooled item supports in the internal area. 
   With the objects of the invention in view, there is also provided a refrigerator, including a thermally insulating housing defining an internal area cooled by circulation of cooling air, a hollow body disposed in the internal area and bounding a flow channel for guiding the cooling air, cooled item supports disposed in the internal area and supported on the hollow body, the hollow body having an elongated cavity with boundary walls defining at least one vertical rail for holding the cooled item supports, the rail having at least one toothed latching strip and an opposing bearing strip oriented opposite the latching strip, and each of the cooled item supports having a lever section with an end selectively supported on the latching strip and an end selectively supported on the bearing strip. 
   Other features that are considered as characteristic for the invention are set forth in the appended claims. 
   Although the invention is illustrated and described herein as embodied in a refrigerator with cooling air circulation, it is, nevertheless, not intended to be limited to the details shown because various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims. 
   The construction and method of operation of the invention, however, together with additional objects and advantages thereof, will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a cross-sectional view through an internal container of a refrigerator according to the invention with a hollow body mounted it and with a cooled item support that is suspended on the hollow body; 
       FIG. 2  is a fragmentary, enlarged cross-sectional view of a lower end of the hollow body of  FIG. 1  and its attachment to the internal container; 
       FIG. 3  is a fragmentary, enlarged cross-sectional view of an alternative embodiment of the lower end of the hollow body of  FIG. 1  and of its attachment to the internal container; 
       FIG. 4  is a perspective view of the hollow body of  FIG. 1  with a cooled item support fitted thereto; 
       FIG. 5  is a horizontal cross-sectional view through the hollow body of  FIG. 4 ; 
       FIG. 6  is a front elevational view of a second embodiment of an internal container of a refrigerator according to the invention with a hollow body installed therein and with a cooled item support suspended on the hollow body; 
       FIG. 7  is a horizontal cross-sectional view through a rearward area of the refrigerator of  FIG. 6  with the internal container and hollow body; 
       FIG. 8  is a fragmentary, enlarged, cross-sectional view of a side of the cooled item support and of its suspension on the hollow body of  FIG. 6 ; 
       FIG. 9  is a fragmentary, enlarged, cross-sectional view from above the cooled item support and the hollow body of  FIG. 8 ; 
       FIG. 10  is a fragmentary, enlarged, cross-sectional view of a side of an alternative embodiment of the cooled item support and of its suspension on the hollow body of  FIG. 8 ; 
       FIG. 11  is a fragmentary, enlarged, cross-sectional view from above the cooled item support and the hollow body of  FIG. 10 ; 
       FIG. 12  is a fragmentary, enlarged, partially cross-sectional and partially hidden view of the locking bar of  FIG. 11  and a method of operating the locking bar; 
       FIG. 13  is a fragmentary, enlarged, cross-sectional view from above another embodiment of the cooled item support and the hollow body according to the invention; 
       FIG. 14  is a fragmentary, enlarged, cross-sectional view of a side of the support and hollow body of  FIG. 13 ; 
       FIG. 15  is a fragmentary, enlarged, cross-sectional view from above a further embodiment of the cooled item support and the hollow body according to the invention; 
       FIG. 16  is a fragmentary, enlarged, cross-sectional view of a side of the support and hollow body of  FIG. 15 . 
   

   DESCRIPTION OF THE PREFERRED EMBODIMENTS 
   Referring now to the figures of the drawings in detail and first, particularly to  FIG. 1  thereof, there is shown a cross-section through an internal container  1  for a refrigerator according to the present invention. In the complete refrigerator, the internal container  1  is surrounded by an outer wall and an insulating foam layer that is enclosed between the outer wall and the internal container; such a design is known and will, therefore, not be described in detail. 
   A hollow body  2 , substantially formed from a fixed outer sheath  3  and a foam layer  4  that bounds a vertical flow channel  5  for the cooling air, extends over the entire height of the rear wall  6  of the internal container  1 . 
   The hollow body  2  is held on the rear wall  6  by projections  7  that are formed integrally with the bottom  8  or the top  9  of the internal container  1 . 
   As the enlarged detail in  FIG. 2  shows, the projections  7  have a wedge-shaped cross-section with an inclined face  10  and a steep face  11 , which is positioned such that the hollow body  2  is held in an interlocking manner between it and the rear wall  6 . 
   The hollow body  2  may be installed, for example, by inserting the hollow body  2  into the internal container  1  in an inclined position, such that the upper end of the hollow body  2 , first of all, touches the rear wall  6 . Pushing the lower end of the hollow body  2  in the depth direction of the internal container  1  results in its upper end sliding up on the rear wall and engaging behind the projection  7  from the top  9 ; at the same time, the lower end of the hollow body  2  slides over the inclined face  10  of the lower projection  7 , forcing the latter reversibly downwards, or reversibly bending the hollow body  2  itself, and, in the end, latching between the steep face  11  and the rear wall  6 . 
   As is shown in  FIG. 2 , the fixed outer sheath  3  of the hollow body  2  in each case extends around its ends, thus preventing the foam layer  4  in the interior of the hollow body  2  from being permanently deformed when the hollow body  2  is pushed over one of the projections  7 . 
   As  FIG. 3  shows, the hollow body  2  may alternatively also be mounted with the aid of a connecting body, such as a screw  12 , which extends through a hole in the rear wall  6  and engages with a stiffening part  13 , for example, a metal strip, which extends on the outer face of the internal container  1 , between it and the surrounding insulating foam layer. 
     FIG. 4  shows a perspective view of the hollow body  2 . Elongated holes  15 , which are intended for cooled item supports  16  to be hooked therein, one of which is shown by way of example in  FIG. 4 , are formed at regular intervals along two vertical lines on the front face  14  of the hollow body  2 . The cooled item support  16 , which is illustrated schematically in a simplified form, is formed from two supporting arms  17  configured to bear loads, for example, cut from steel sheet with an appropriate material thickness, each of which engages with a non-illustrated hook in one of the holes  15 , and a supporting plate  18  that is placed on the supporting arms  17  and is composed, for example, of safety glass. 
   Slots  19  that are disposed at different levels, in the present case run horizontally and are used as air outlet openings are also formed on the front face  14  of the hollow body  2  and, as is shown in the horizontal cross-section in  FIG. 5 , communicate with two vertical cooling air channels  5  that extend along the rear face of the hollow body  2  and are bounded on the one hand by its foam layer  4  and on the other hand by the rear wall  6  of the internal container. 
   Two large-area cutouts  20  on the front face  14  of the hollow body are covered with a transparent material, behind which is disposed a lighting device for illumination of the internal area. 
   Non-illustrated openings are provided in the rear wall  6  of the internal container  1  for the power supply for the lighting device to pass through and to supply cooling air to the channels  5 . These openings may also be integrally formed during the manufacture of the internal container. 
     FIG. 6  is a front view of the refrigerator, whose internal container  1 , which is used to line its internal area, is provided with a hollow body  2 , mounted on its rear wall, according to a second embodiment of the invention. In this embodiment, the hollow body  2  is an extruded profile composed of aluminum, which extends over the entire width of the rear wall and whose cross-section is shown in  FIG. 7 . The front view of the hollow body  2  is subdivided, from left to right in the figure, into a first vertical slot  21 , a first flow channel section  22 , a vertically running stepped-back section  22 . 1  that is covered by a transparent screen  23 , for example, composed of acryl glass, behind which is a lighting device  24  fitted to illuminate the internal area, a second flow channel section  25  and a second vertically running slot  26 . 
   As shown in the refinement in  FIG. 4 , slot-like outlet openings  19  are formed at different levels in the flow channel sections  22 ,  25 , through which cooling air can emerge from the flow channel located behind them into the internal area. 
   As is illustrated by way of example in the form of a dashed outline in  FIG. 6 , the flow of cooling air through the slots  19  can be controlled by disposing a covering shutter  29  behind each group of outlet slots  19 , which shutter  29  is opened or closed by an electrically driven actuator  30 , for example, a motor-driven threaded spindle, as a function of the climatic conditions measured in the internal area. As is shown in the cross section in  FIG. 7 , the actuators  30  are accommodated in vertical channels  31 ,  32  in the hollow body  2 , through which cable harnesses are also passed for the electrical supply to and control of the actuators  30  and of the lighting device  24 . 
   The cooled item support  16 , a front view of which is shown in  FIG. 6 , has two side supporting arms  33  with a supporting section  33 . 1  (see  FIGS. 8 and 9 ) with an at least approximately C-shaped cross-section, whose free end sections, which have a concave cross-section, face one another and hold a supporting surface composed of glass between them. Supporting sections  33 . 2  (see  FIGS. 8 and 9 ) are provided in the rearward area of the supporting arms  33  and engage through the slots  21 ,  26  in vertically elongated cavities  27 ,  28  that are located behind them and are in the form of holders, and whose boundary walls are used as guide elements for vertically adjustable suspension of the cooled item supports. The way in which the supporting arms  33  are suspended in these cavities  27 ,  28  is illustrated in detail in  FIGS. 8 and 9 . 
     FIG. 8  shows a side view of a supporting arm  33 , on one hand, in the form of solid lines, horizontally oriented, in a position anchored in the cavity  28 , and, on the other hand, in the form of dashed lines, in an unanchored position, pivoted with respect to the horizontal. 
   The supporting section  33 . 2  (which engages in the cavity  28 ) of the supporting arm  33  is lengthened upwards beyond the plane of the glass plate and is fitted with a lever section  34  that extends obliquely through the cavity  28  and, in its anchored position, engages by a first end  35  in a tooth intermediate space  36  between teeth  37  on a latching strip  38 , which extends along a surface of the cavity  28  facing the rear wall  6  of the internal container  1 . A second end  39  rests on an opposing bearing strip  40 , which forms an inner face of the cavity  28 , facing the internal area and adjacent to the slot  26 . The weight of the cooled item support and of any cooled items that may be located on it exerts a torque in the clockwise direction (with respect to  FIG. 8 ) on the lever section  34 , in each case pushing the ends  35 ,  39  of the lever section  34  against the respective surfaces  38 ,  40  facing them, and preventing the end  35  from being able to move out of the tooth intermediate space  36 . The end  35  cannot be removed from the tooth intermediate space  36  unless a user lifts the front end of the cooled item support so that it is moved to the position illustrated by the dashed lines. In such an orientation, the cooled item support can be moved freely in the vertical direction and can be moved to any desired height that corresponds to a space  36  between teeth. Because the distance between the teeth  37  of the latching strip  38  may be quite small, in the order of a few millimeters, the configuration allows the height of a cooled item support to be matched considerably more accurately to the respective user requirement than is possible, for example, with conventional configurations having ribs, which are formed on the side wall of the internal container, for supporting the cooled item support. 
   It is important to prevent the cooled item support from being pivoted upwards inadvertently so that it cannot slide out, for example, in the loaded state, if a user accidentally knocks it from underneath. For such a purpose, the left-hand supporting arm  33  in  FIG. 6  is equipped with a locking lever, whose operating section  41  can be seen in the front view in  FIG. 6 . The operating section  41  is connected to a locking finger  43  by a rod  42  (see  FIG. 8 ) that is parallel to the supporting arm  33  and is guided within it, and the locking finger  43  can be pivoted between a position in which it has no effect and a locked position, by pivoting the operating section  41 .  FIG. 8  shows the position in which the locking finger  43  has no effect and in which it is oriented vertically downwards and can be moved out of the cavity  28  through the slot  26  when the cooled item support is pivoted to the position shown by the dashed lines. In its locked position, the locking finger  43  is oriented horizontally, and its free end rests on the opposing bearing strip  40 , thus preventing the cooled item support from being pivoted. 
   To allow cooled item supports to be removed or to be hooked in additionally depending on the user&#39;s requirement, the two slots  21 ,  26  have respective broadened sections  44 ,  45  (see  FIG. 6 ) at their upper ends, whose sizes are such that the lever sections  34  of the right-hand and left-hand supporting arms  33  of a cooled item support can be moved through freely. Because, as is shown in  FIG. 8 , the two ends  35 ,  39  of the lever section  34  are located above the mounting level of the cooled item support as defined by the supporting arms  33 , it is possible to pivot the cooled item support sufficiently that it can be moved downwards to a desired height after insertion of the lever sections  34  of the two supporting arms into the cavities  27  and  28 , without the end  35  being stuck on a tooth  37  of the latching strip  38  in the process. 
     FIG. 9  shows a plan view of the cavity  27 , which is a mirror image of the cavity  28 .  FIG. 9  shows that, the latching strip  38  is in the form of a part that is separate from the rest of the hollow body  2  and is mounted in the cavity  27  retrospectively. 
   As can easily be seen, as an alternative to the refinement illustrated in  FIG. 8 , it would also be possible to fit the lever sections  34  substantially at the same level as the supporting arms  33 , or underneath them, while maintaining the inclined position between the ends  34 ,  39  of the lever sections  34 . Fitting out of the plane of the supporting arms has the advantage that effective locking is possible with the aid of a locking finger, such as the locking finger  43 , whose locked position is substantially at the same height as the supporting arms  33 . If a lever section were to be used underneath the plane of the supporting arms  33 , a locking finger, in order to be effective, would have to act in its locked position on the latching strip or on the outer face of the hollow body opposite the opposing bearing strip  40 . A broadened section of the slots  21 ,  26  would, then, have to be provided at the lower end of each of the slots in order to hook the cooled item supports in, and to unhook them. 
     FIGS. 10 to 12  illustrate another possible way to protect the cooled item supports  16  against inadvertent pivoting. In the case of the end section of the supporting arm  33  as shown in  FIG. 10 , which engages in the cavity  28 , a groove  47  that is indicated by a dashed line and faces away from the viewer extends exactly vertically when the lever section  34  is correctly engaged on the latching strip  38 , that is to say, when the end  35  engages in a space between the teeth of the latching strip  38 . A locking bar  48  in the form of a rod extending substantially over the entire length of the cavity . 28  on a side wall of the cavity  28  opposite the groove  47  can be moved between a position in which it has no effect, as shown in  FIG. 11 , and a locked position, in which the locking bar  48  engages in the grooves  47  in all of the supporting arms that engage in the cavity  28 . 
   A mechanism having two wheels  50 , which are coupled by a belt  49  or in some other suitable manner, as shown schematically in  FIG. 12 , may be used to move the locking bar  48  between the position in which it has no effect and the locked position.  FIG. 12  shows the locking bar  48  in the position in which it has no effect, standing on the bottom  51  of the cavity  28 . The rod is connected to the wheels  50  through two eccentric pins  52  such that it can rotate; one of the wheels  50  is connected through an opening in the front face of the hollow body  2  to a control knob  53  in the internal area of the refrigerator. Rotation of the control knob  53  in the counter clockwise direction raises the locking bar  48  and pushes it to the left in the perspective shown in  FIG. 12  so that it engages in the grooves  47  in the supporting arms  33 . The locked position is reached as soon as the locking bar  48  comes to rest on the bottom  51  again. 
   If only one of the cooled item supports is not positioned correctly, so that its groove  47  is not exactly vertical, the locking bar  48  cannot engage in the locked position, and the control knob  53  returns to the illustrated position in which it has no effect on being released. This immediately warns a user when the action of hooking in the cooled item supports that is carried out is not secure. 
     FIG. 13  shows a plan view of two rails for guiding and holding the lever section  34  of a supporting arm  33  according to a modified refinement. As in the case of  FIGS. 8 and 9 , the rails are in the form of an elongated vertical cavity  54 ,  55 , with a latching strip  38  on a side facing the rear wall  6  of the refrigerator, and with an opposing bearing strip  40  on a side facing the internal area. A slot  56  extends over a side wall of the cavity  54 ,  55  that is oriented at right angles to the latching strip  38  and to the opposing bearing strip  40 . The cavities  54 ,  55  are each disposed on the side edges of the hollow body  2 . Their outlines are not approximately mirror images of the cavities  27 ,  28 , but are exactly identical. 
   The lever section  34  of the supporting arm  33  that engages in the cavity  54  has a first end  35  that rests on a step (which is in the form of a sawtooth) on the latching strip  38  (in other words: it engages in a space between two teeth), and a second end  39 , which rests on the opposing bearing strip  40 . By pivoting the supporting arms  33  in the counter-clockwise direction, the lever sections  34  can be moved to a position in which they extend substantially vertically and can be pushed out of the cavities  54 ,  55  at the side (downwards in  FIG. 13 ), after which it is possible to remove the entire cooled item support. 
   Although not described specifically, it is, of course, also possible for the cooled item support of  FIGS. 13 and 14  to be equipped with a locking lever as shown in  FIGS. 6 and 8 , or with the locking bar as described with reference to  FIGS. 10 to 12 . 
     FIGS. 15 and 16  show a further refinement of a rail  57  for suspension of cooled item supports and of a cooled item support matched thereto. The rail  57 , which is, once again, formed integrally with the hollow body  2  as an extruded profile, has a T-shaped cross-section with the toothed latching strip  38  disposed on a surface of the transverse bar  58  of the T-shaped cross-section facing the internal area or the cooled item support  16 . The opposing bearing strip extends on the rear face of the transverse support  59 . In such a case, the lever section  34  is formed from a point  59  that projects downwards from the supporting arm  34  and engages in a space between the teeth of the latching strip  38 , and two hooks  60 , which are angled obliquely upwards, clasp the transverse support  58  and rest on its rear opposing bearing strip  40 .