RU2338134C2 - Refrigerator with internal space separated in sections - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: refrigerating unit with internal space of heat-insulating casing divided into several chambers, in which at least one of chambers is separated from remaining part of internal space with door, which is held with latch in closed position, which is formed from elastically deformed element and element that deforms elastically deformed element. Elastically deformed element is formed with section of door or casing wall. Application of this device makes it possible to manufacture refrigerator that is cheap in production and simple in assembly.

EFFECT: creation of refrigerator that is cheap and simple in assembly.

12 cl, 8 dwg

Description

Technical field

The present invention relates to a refrigerating apparatus with an internal space divided into several chambers, in particular to a combined refrigerator-freezer or freezer, in which a door is hung at the inlet of at least one chamber separating the chamber from the rest of the internal space.

State of the art

Such a refrigeration apparatus is known from DE-8903459 U. In it, the door of the freezer is held in a closed position by a latch.

The latch of this known refrigeration apparatus has an elastically deformable element in the form of a capsule, from which a ball protrudes, which can be pressed to overcome the resistance of the spring installed in the capsule, and an element used to deform the elastically deformable element, having the form of a protrusion on the door of the freezer, which when opened and closed the ball presses the door. In order to install the capsule on the inner cavity, it is necessary to form a recess in it, into which the capsule can be inserted and in which the capsule will hold firmly.

Disclosure of invention

An object of the present invention is to provide a refrigeration apparatus with an interior space divided into several chambers and at least one chamber with a hinged door, inexpensive to manufacture and easy to assemble.

The problem is solved in the refrigerator with the features of paragraph 1 of the claims. If the elastically deformable element according to the invention is formed by a wall section of the housing or door, then the elastic element can be discarded as a separate structural element, and the number of parts required when assembling the refrigeration apparatus will be reduced.

According to a first embodiment, the resiliently deformable element is part of the internal cavity of the refrigeration apparatus, and the internal cavity is preferably integral. Such a wall section can be made elastically deformable if heat-insulating filler with which the walls of the body are filled is removed from the elastically deformable section of the wall, in the area of the elastically deformable element, the heat insulating filler of the body is removed.

According to a second embodiment, an elastically deformable element can be formed on the door, and a deforming element can be formed on the inner cavity of the housing.

The deforming element in this embodiment is attached to the internal cavity, preferably as a separate structural element; this allows you to perform this element from a material that is more resistant to abrasion than the inner container itself.

Preferably, the deforming element is in the form of a plug that is inserted into a recess in the housing, in particular in the internal cavity of the housing.

The elastically deformable element is preferably a portion of the door wall facing the deforming element. Preferably, there is a cavity behind the door wall in the region of the elastically deformable element, into which the elastically deformable element can be elastically pressed when the door is opened and closed.

The elastic deformable element is easily realized in the boundary zone between the front and rear shell, which are parts of the door wall, and the shells are closed in the region of the elastically deformable element

Opposite edge zones of the inner and outer shells may limit the groove to accommodate the shaped seal. The cavity is preferably part of such a groove defined by the anterior and posterior membranes.

If the outer wall has a handle made separately from the door leaf, that is, a grip that the user can take to open or close the door, it is desirable that an elastically deformable element is formed on the grip (handle). In the event that repair is required due to wear of the elastically deformable element, then in this case it will be sufficient only to replace the handle, while the remaining parts of the door will remain operational. In addition, this makes it possible to minimize wear due to abrasion if the handle is made of a more wear-resistant material than the rest of the door.

Preferably a deformable element, i.e. the latch is installed on the side surface of the door farthest from the axis of rotation (i.e., opposite the axis of rotation). However, it is also possible to install a latch on a side surface of a door that is cross-relative to the pivot axis, but for this to be securely fixed, two latches would generally be required on opposing side surfaces.

The elastic deforming element does not have to be in direct contact with the deforming element. For example, a protective part may be placed in the contact area between the elastically deformable element and the deforming element in order to minimize abrasion of these elements. An elastic deformable element can also be formed by a hinge of the door itself or mounted on it.

Other features and advantages of the invention arise from the following description of examples of implementation with reference to the accompanying drawings,

where figure 1 is a view of a refrigerator with a separated freezer, to which the present invention is applicable;

FIG. 2 is a schematic sectional view of a door according to a first embodiment of the invention; FIG.

figure 3 is an enlarged section of the upper edge of the door and the adjacent portion of the housing of the refrigeration unit with the door closed;

figure 4 is a partial perspective view of a modified version of the door of figure 2;

5 is a schematic sectional view of the lower corner of a door leaf according to a second embodiment of the invention;

6 is a section through a part of the body and door of the freezer of a two-temperature refrigerating cabinet according to a third embodiment of the invention;

Fig.7 is a variant of Fig.6; and

Fig. 8 is a partial sectional view of a freezer according to a fourth embodiment of the invention.

The implementation of the invention

Shown in figure 1 in a perspective projection in front of a two-temperature refrigeration apparatus 10 has a heat-insulating casing 12 with an external door 11 connected to it, pivoting around a vertical axis. The inner space of the housing 12 is divided by a heat-insulating horizontal partition 14 into a refrigerator 13 and a freezer 15. On the inner container of the housing 12 at the height of the partition 14 a freezer door 16 is fastened, turning on a horizontal axis and shown here in an open horizontal position; in the closed position, it substantially hermetically closes the front side of the freezer 15.

Figure 2 shows a schematic section of a door 16 of the freezer in a vertical closed position. The door 16 of the freezer consists of an outer shell 17 facing the outer door 22, and an inner shell 18 facing the inner cavity of the freezer 15, which are in contact with each other at the edges and surround the inner space, filled mainly with heat-insulating foam 19. At the upper edge the outer shell 17 is formed by a recess 20 for gripping. On top, it is limited by an elongated shelf 21 of the outer shell 17, as well as a gripper 22, which, like the shell 17, 18, is made in the form of an integral part by injection molding. The horizontal shelf 23 of the gripper 22 is attached to the shelf 21 by fixing or gluing. The vertical shelf 24, for which the user is comfortable to grasp and pull, passes in front of the recess 20 to capture vertically downward from the horizontal shelf 23. The step 25 on the upper side of the horizontal shelf 23 is part of a latch that locks the door leaf 16 in a vertical position.

The second part of the latch, as can be seen from figure 3, is formed by a protrusion 26, mounted on the inner cavity of the housing 12. The protrusion is a part of the tube 27 of a rigid, abrasion-resistant polymeric material, the base part of which with a geometric and frictional closure enters the recess 28 on the upper wall of the inner cavity of the housing 12. In the depicted position of the door leaf 16, the protrusion 26 enters the ledge 25 on the horizontal shelf 23 of the capture 22. The opposite shelf 21 protruding inward horizontal edge 29 of the outer shell 17 under holds the horizontal shelf 23 under the ledge 25. The edge 30 of the shelf 23 shown in FIG. 3 to the left of the ledge 25 is not supported by the edge 29, so that when the door is opened and closed under the pressure of the protrusion 26, it can be fed down and squeezed out into the groove 31, which is a flexible shaped gasket 32 for sealing the gap between the door leaf 16 and the frame. A narrow slit 33 extends from the bottom of the groove 31 between the horizontal edge 29 of the outer shell and the edge of the inner shell 18. This slit 33 allows the horizontal edge 29 to also slightly feed down when the protrusion 26 passes through the edge portion 30.

The horizontal shelf 23 is attached over a large surface to the shelf 21 and the edge 29 of the outer shell 17, for example by gluing or pinching on the outer ends of the shelf 21 and the edge 29. This allows the user to facilitate the release of the latch when opening the door so that it does not only pull the vertical shelf 24 capture 22 horizontally forward (figure 4 to the right), but at the same time pulls the vertical shelf 24 up, lowering the edge section 30.

Figure 4 shows in perspective projection the upper part of the door 16 according to an alternative embodiment of the invention. The upper part of the outer shell 17 is visible with a grip recess 20 partially covered by a grip 22. A longitudinal slit 34 is formed on the horizontal flange 23 of the grip 22, and a flat thickening 35 is formed between the slit 34 and the trailing edge of the shelf 23. The shelf 23 is not supported under the thickening 35. Owing to this and the presence of a slit 34, the bending of the thickening 35 in the longitudinal direction of gripping is facilitated when, when the door is opened and closed, the protrusion 26 slides along the thickening 35. The slot 34 or the abrupt break of the thickening 35 adjacent to it play the role of a ledge to which, when the door is closed, ledge 26 of the frame.

Of course, the elastic deformation of the door leaf necessary to move from the open position to the closed and vice versa should not be limited to the side of the door 16 facing the protrusion 26. Certain additional flexibility can be created due to the elastic deformability of the shells 17, 18 themselves.

Another possibility of making the door elastically deformable is shown in FIG. A deep-drawn blind hole 37 is formed on the left side surface 36 of the door. A cylindrical pivot pin 39 is inserted into the inner part 38 of the blind hole with a geometrical closure. The diameter of the adjacent outer portion 40 of the blind hole gradually increases towards the side surface 36. The free end protruding from the blind hole 37 the pivot pin 39 can rotate in a recess in the side wall of the internal cavity of the housing 12. The opposite lower right corner of the door 16 has a similar design th. The upper edge portion of this door 16 may, for example, be of the same construction as in FIG. 3, however, in this embodiment, the edge portion 30 may be rigid. When opening and closing this door 16, the door 16, as a whole, is pushed down. The outwardly expanding portions 40 allow the pivot pin 39 to easily rotate around an axis perpendicular to the plane of the figure, and the blind holes 37 are simultaneously elastically deformed. After the latch is released or locked, the pivot pins 39 resiliently restore their parallel orientation.

6 illustrates a third embodiment of the refrigerator according to the invention by means of a partial section showing the upper edge of the freezing chamber door 16 and the ceiling portion of the inner cavity 41 opposite this upper edge. In the illustrated closed and latched position of the freezer door 16, there are two inclined surfaces extending from the protrusions 42 and 43 on the upper side of the door 16 and respectively on the inner cavity 41, are adjacent to each other. Both protrusions 42, 43 are respectively formed as integral parts of the outer wall of the door 16 of the freezer and the inner cavity 41. The door 16 of the freezer is completely filled with heat-insulating foam 19. A flat bowl 44 is glued on the back of the inner cavity 41 facing the door 16 43. When the refrigerator is filled with insulating foam 45 during the assembly of the refrigerator, the bowl 44 does not allow the insulating foam to pass into the space behind the protrusion 43, due to which, when opening and closing the door 16, the protrusion 43 with the surrounding area the walls of the inner cavity 41 can bend back under the pressure of the protrusion 42.

An improvement of this embodiment is shown in FIG. The door 16 is identical to the door shown in Fig.6. Instead of the protrusion 43 on the inner cavity 41 against the protrusion 42 of the door 16 there is a flat cavity 46, in which the buffer element 47 is placed, replacing the protrusion 43 of Fig.6. The advantage of this change is that when deep drawing the inner cavity 41, the depression 46 is easier to manufacture than the protrusion 43, which, after deep drawing, makes it difficult to remove the punch of the exhaust stamp from the inner cavity. In addition, the buffer element, in contrast to the protrusion inseparable from the internal cavity, can easily be replaced if it is worn by friction against the protrusion 42 on the door 16.

The buffer element 47 itself can be rigid, and all forced deformation when opening and closing the door 16 is transmitted to the internal cavity 41, but it can also be made of elastic material that will perceive part of this deformation, thereby unloading the internal cavity 41.

In another modification, not shown in the drawings, the inner cavity 41 in the area covered by the bowl 44 is completely flat, and the protrusion, which interacts with the protrusion 42 on the door 16, is formed on a buffer element glued across the surface to the inner cavity against the bowl 44.

On Fig as a fourth variant of the invention shows a partial section of a freezer. Its internal space is divided by horizontally arranged evaporators 51 into several compartments 52, each of which is closed by a door 53. Since the individual compartments 52 do not need to be isolated from each other, the doors 53 are only simple walls and do not have heat insulating filler. Each of them leans back to the side wall of the internal cavity. Each door has a horizontal upper surface 54, from which the protrusion 55 extends upward. The protrusion 55 of the uppermost door 53 interacts with the downward protrusion 56 on the inner cavity. In this case, the protrusion 56 of the inner cavity can be a rigid and deforming way to act on the protrusion 55 on the door, as in the implementation examples described with reference to figures 1-4, or, on the contrary, the protrusion 55 on the door can be rigid and deform the protrusion 56 on the inner cavity, as in the examples of implementation in FIGS. 6 and 7. Of course, the protrusions 55, 56 can be simultaneously elastically deformable, so that each of them can act in a deforming manner on the opposite protrusion.

The edges of the evaporators on the door side are inserted into plastic strips 57, on the lower side of which there are protrusions similar to the protrusion 56 of the internal cavity, which, when interacting with the protrusions 55 of the doors 53 located below them, form latches.

Claims (12)

1. A refrigerator with an interior space of a heat-insulating casing divided into several chambers (13, 15, 52), in which at least one of the chambers (15, 52) is separated from the rest of the interior by a door (16, 53), which is closed the position is held by a latch formed from an elastically deformable element (30, 35, 38, 43, 55, 56) and a deforming elastically deformable element (42, 55, 56), characterized in that the elastically deformable element (30, 35, 38, 43, 55 , 56) is formed by a section of the wall of the door (16, 53) or the body. 2. The refrigeration apparatus according to claim 1, characterized in that the elastically deformable element (43) is formed on the inner cavity (41) of the housing, and the deforming element (43) on the door (16). 3. The refrigeration apparatus according to claim 2, characterized in that in the area of the elastically deformable element (43), the heat-insulating filler (45) of the housing is removed. 4. The refrigeration apparatus according to claim 1, characterized in that the elastically deformable element (30, 35, 38) is formed on the door (16), and the deforming element (27) is formed on the inner cavity of the housing. 5. The refrigeration apparatus according to claim 4, characterized in that the deforming element is formed by a plug (27), which is inserted into the recess (28) of the internal cavity. 6. The refrigerator according to claim 4 or 5, characterized in that the elastically deformable element is a portion (30, 35) of the door wall (16) facing the deforming element (27). 7. The refrigerator according to claim 6, characterized in that there is a cavity (31) behind the door wall (16) in the region of the elastically deformable element (30). 8. The refrigerator according to one of claims 4, 5, 7, characterized in that the wall of the door (16) consists of a front (17) and a back (18) shells closing in the region of an elastically deformable element (30). 9. The refrigeration apparatus according to claim 7, characterized in that the cavity (31) is part of a groove (31) bounded by the front and rear shell (17, 18) containing the shaped seal (32). 10. The refrigerator according to one of claims 4, 5, 7, 9, characterized in that there is a grip (22) in the door wall (16) and that an elastically deformable element (30, 35) is formed on the grip (22). 11. The refrigeration apparatus according to one of claims 1 to 5, characterized in that the elastically deformable element (30, 35) is located on the side surface of the door that is far from the axis of rotation (16). 12. The refrigeration apparatus according to one of claims 1 to 5, characterized in that the elastically deformable element (38) is located on the hinge of the door (16).

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