RU2405118C2 - Refrigerant apparatus without freezing on frost - Google Patents

Abstract

FIELD: personal use articles.

SUBSTANCE: refrigerant apparatus without freezing on frost contains the evaporator which is held on the carrier separating as a wall a vaporising chamber from the refrigerating chamber, an outlet for air to the air channel is made in the wall of the carrier, as well as a fan mounted on a hole for air with a vibration dampening. Behind the outlet for air of the carrier a fan is placed with a vane wheel and an engine that pulls air from the evaporation chamber and pumps it into the air channel. The fan is attached on the wall element of the air channel placed opposite the outlet for air. The wall element has a flat vertically oriented base. The vane wheel is located on the inner side of the base facing the carrier, and the engine is located on the outer side of the base. The wall element is mounted on the carrier with vibration dampening elements.

EFFECT: use of this invention enables to create a compact design with an easily mounted evaporator unit.

9 cl, 7 dwg

Description

Technical field

The present invention relates to a refrigeration apparatus without freezing frost (hereinafter referred to as a refrigeration apparatus) comprising an evaporation unit.

State of the art

Such an assembly typically comprises an evaporator, a case-type carrier, which delimits an evaporation chamber in the refrigerator body in which an air inlet and an air outlet are made to the evaporation chamber and in which the evaporator is located, and also includes a fan located at the carrier outlet to pump air from the carrier into the air channel through which air reaches the refrigerator compartment of the refrigerator.

In the known evaporation unit, the fan is mounted directly on the portion of the bearing wall in which the air outlet is made and which is connected to the rest of the wall by means of a flexible rubber tongue extending around the perimeter, and thereby has the ability to damp vibration. The rear wall of the air channel connected to the air outlet is fixed in the grooves of the rubber tongue.

The location of the fan on the vibrating portion of the bearing wall causes the fan motor to cover part of the cross section of the air outlet. In order to, however, obtain a sufficient free cross-section, the diameter of the air outlet must be made large. In addition, the weight of the fan exerts torque on the vibrating section, which contributes to the bias of the vibrating section and clamps the rubber tab. Flexible pliable rubber tongue complicates the fixation of the rear wall of the air channel.

Disclosure of invention

An object of the present invention is to provide an easily mounted evaporator assembly that would allow a compact design.

The problem is solved by the evaporator assembly containing the evaporator, the carrier body that surrounds the evaporator held on the carrier and separates the evaporation chamber from the refrigeration chamber by the wall, and a passage to the air channel is made in the wall of the carrier housing, as well as a fan mounted on the passage with vibration damping. In this case, the fan is fixed on the wall element of the air channel lying opposite the passage, and the wall element is fixed on the casing with the help of vibration damping elements. This type of arrangement of the fan allows you to keep the engine at a distance from the air passage, and thus the engine does not limit these openings, and the entire surface of the cross section of the passage is a useful surface. The dimensions of the passage can therefore be small.

The vibration damping elements are preferably buffers made of an elastically deformable material.

Such a buffer may have a groove around the perimeter, into which one of the parts, a wall element or carrier, is optionally engaged. Another part can, together with the buffer, form a plug-in connection from the pin and socket in such a way that the wall element or carrier, on the one hand, and the buffer, on the other hand, form a socket or pin, respectively, which engages in the socket.

In order to form an air channel having a substantially closed cross section, the first rib, which is protruding on the outside of the carrier, and the second rib, forming part of the wall element, preferably form a labyrinth seal.

In order to avoid undamped transmission of vibration from the wall element carrying the fan to the evaporator carrier, these two ribs surround each other preferably without touching each other.

The vibration damping elements are preferably connected to the wall element and / or to the carrier via a plug connection. In this case, at least the first of the vibration-damping elements must form in a state connected by a plug-in connection, the center of gravity for oscillation - preferably two vibration-damping elements form an axis - and during the oscillation determined by the center of gravity or axis, at least one other vibration damping element can be connected using a plug connection.

This other vibration damping element in the state connected by the plug connection is preferably fixed.

If the directions of the plug-in connection of the first vibration damping element and the other vibration damping element create a substantially right angle, then the other vibration damping element in the connected state prevents the first vibration damping element from disconnecting. Therefore, the protection of the first vibration damping element by fixing is not required.

Brief Description of the Drawings

Other features and advantages of the invention result from the following description of embodiments with reference to the accompanying figures. They show the following.

Figure 1: a schematic section along the upper region of a refrigeration apparatus, which is equipped with an evaporation unit according to the present invention.

Figure 2: axonometric projection of the carrier of the evaporation site and the wall element that carries the fan.

Figure 3: the housing and the wall element in a state connected to each other.

Figure 4: front view of a wall element according to the first embodiment.

Figure 5: axonometric view of the rubber buffer.

6: fragment of a wall element according to the second variant of implementation.

7: view of the wall element without a fan, view from the rear side.

The implementation of the invention

Figure 1 shows a schematic section along the upper region of a refrigerator according to the present invention. The refrigeration apparatus has a housing 1 and a door 2, which are implemented, as usual, in the form of hollow bodies filled with a heat-insulating layer 3 of foam material. The inner space of the housing 1 is also divided by means of a heat-insulating separation wall 4 into the evaporation chamber 5 and the refrigeration compartment 6. The separation wall 4 is formed by the base of the housing type carrier 7 for the evaporation assembly on which the known plate evaporator 8 is mounted by itself. The carrier 7 is mounted at a distance from the ceiling of the housing 1 and together with the side walls of the housing limits the evaporation chamber 5. The carrier 7 also has an inlet 9 for air on its side facing doors 2, and an air outlet 10 on its side facing the rear wall of the housing 1. In the rear region of the evaporation chamber 5, behind the outlet 10 of the carrier 7, there is a fan 11 with a paddle wheel 12 and an engine 13 that draws air from the evaporator chamber 5 and pumps it into the air channel 14.

In an exemplary sectional view of FIG. 1, the air channel 14 passes only through the partition wall 4 and flows into the refrigerating compartment 6 lying directly below it. Alternatively, the air channel 14 can also be provided inside the rear wall of the housing 1 and provided with many through holes to the refrigerating compartment 6, through which cold air flowing in the air channel 14 is evenly distributed along the height of the refrigeration compartment 6. Further, a valve can be provided in the air channel 14 that supplies a flow of cold air different branches of the air duct 14 to choose one of several branches of the refrigerating appliance, such as refrigerating compartment 6 and not shown in the freezer compartment.

Figure 2 shows in axonometric projection the carrier 7, made essentially of plastic by injection molding, and mounted on it a cup-shaped wall element 15. In the rear wall 16 of the carrier 7, which is essentially flat, there is a round outlet 10. Concentric in relation to the hole 10 from the rear wall 16 is separated by a rib 17, curved in the form of an arc of a circle. The wall element 15 has, both in the figure and in the mounted state, a flat, vertically oriented base 18 and spaced apart from the base 18 at a right angle, extending along a circular arc rib 19, which in the assembled state of Fig. 3 of the carrier 7 and the wall element 15 covers with a small gap the rib 17 of the carrier 7. Also in the mounted state, neither the front edge of the rib 19 touches the rear wall 16 nor the rear edge of the rib 17 touches the base 18. The connection between the carrier 7 and the wall element 15 in the mounted housing oyanii thereby occurs solely through the upper and lower rubber buffers 20 or 21, and thus expelled straight undamped vibration transfer motor 13 mounted on the wall element 15 on the carrier 7.

The rubber buffers 20, 21 have the same appearance as shown in FIG. 5 in a perspective view. They have one, essentially cylindrical, body with an axially extending hole 22 and with an outer groove 23 adjacent to the end of the cylinder extending around the perimeter, as well as one supporting flange 24 connected to the groove 23.

The two upper rubber buffers 20 are inserted into the holes of the rear wall 16, and thus, the rear wall 16 is engaged with the perimeter groove 23 of the rubber buffers 20. The opening 22 of the buffers 20 is oriented horizontally. The lower buffers 21 are arranged with a vertically oriented hole at two corners 25 having an L-shaped cross section that are spaced apart from the rib 19 of the wall element 15, close to its lower edge. A horizontal cornice of the carrier 7 extends under the corners 25, on which two vertical pins 27 are made. One of the pins 27 is closed in FIG. 2 by the wall element 15. The installation of the wall element 15 on the carrier 7 is due to the fact that the lower rubber buffers 21 are slightly inclined at first located wall element 15 are mounted on top of the pins 27. Due to the gap between the pins 27 and the holes 22 into which they enter, and / or because of the flexibility of the rubber buffers 21, the wall element 15 is made to rotate around a horizontal axis, sewing through two pins 27, and rotates around this axis in a vertical position in which two sleeves 28, which are made on the brackets 29 protruding in the upper region of the wall element 15. With their help, the rubber buffers fixed on the rear wall are unbent 20. In this 3, the support flanges 24 of the rubber buffers 20 hold the sleeves 28 at a distance from the rear wall 16.

Due to the engagement of the upper rubber buffers 20 in the sleeves 28, the lower rubber buffers 21 can no longer disconnect from the pins 27 without being locked with them. To fix the sleeves 28 on the rubber buffers 20, the diameters of the sleeves 28 and the buffers 20 can be adjusted to each other so that the sleeves 28 are mounted on the buffers 20 with a friction closure. It is also acceptable for the sleeves 28 to be provided on their inner surfaces with ribs (not shown in the figures) extending in the axial direction, which when pressed in, are pressed into the material of the buffers 20, or provided with hooks like fishing hooks on the inner surfaces of the sleeves 28.

Figure 4 is a perspective view of the side of the wall element 15 facing the carrier 7, depicting a blade wheel 12. The blade wheel 12 has a circular base 30 near the base 18 of the wall element 15, from which a plurality of blades 31 are spaced. By rotating the blade wheel 12, air is introduced into the direction of the axis of the blade wheel 12 through the air outlet 10 is accelerated radially outward and flows through the open lower side of the wall element 15.

6 is a perspective view of a portion of a wall element 15 according to a second embodiment of the invention. Instead of the sleeve 28, the bracket 29 is provided with a pin 32, which is oriented so that when the wall element 15 is rotated around the axis defined by the lower rubber buffers 21, to the rear wall 16, engage with the holes 22 of the upper rubber buffers 20, go through them and with a thickened free end, engage on the inside of the rubber buffers 20, inside the carrier 7. The trunnion 32 may, as shown in the figure, have a cut so that it is easier to pass through the hole 22, but due to the flexibility of the rubber buffers 20 beats.

7 is a perspective view of the wall element 15 from the rear wall side, without a fan 11. There is a U-shaped bracket 33 on the outside of the base 18, the rigidity of which is reinforced by ribs 34 spaced horizontally. Open upward groove 35 in the bracket 33 carries a bearing 36, which serves to suspend the motor shaft 13. At the base 18 of the wall element 15 there is a wedge-shaped groove 37, tapering in the direction of the center of the base 18. At the lower end of the groove 37, in the center of the base 18, there is a second bearing 38 for the engine 13. When assembling the evaporator assembly, two bearings 36, 38 are first mounted on the shaft of the engine 13, and then the front section of the shaft with the bearing 38 is inserted into the upper region of the groove 37. Due to the fact that the engine 13 now moves with bearings and 36, 38 down, bearings 36, 38 fall into their positions shown in Fig.7, and the engine 13 is held between them. Next, the blade wheel 12 is mounted on a section of the shaft protruding beyond the inner side of the base 18.

Claims (9)

1. A refrigeration apparatus without freezing frost, containing an evaporator (8) that is held on a carrier (7) that separates the evaporation chamber (5) from the refrigeration chamber by the wall (16), and an outlet is made in the wall (16) of the carrier (7) ( 10) for air to the air duct (14), as well as containing a fan (11) mounted on the air outlet (10) with vibration damping, characterized in that a fan is located behind the outlet (10) for the carrier air (7) (11) with a paddle wheel (12) and an engine (13) that draws draws air from the evaporation chamber (5) and pumps it into the air channel (14), moreover, the fan (11) is mounted on the wall element (15) of the air channel (14) lying opposite the air outlet (10), and the wall element (15 ) has a flat vertically oriented base (18), and the blade wheel (12) is located on the inner side of the base (18) facing the carrier (7), and the engine (13) is located on the outside of the base (18), and the wall element (15 ) mounted on the carrier (7) using vibration damping elements (20 , 21). 2. The refrigeration apparatus according to claim 1, characterized in that the vibration damping elements (20, 21) are buffers made of an elastically deformable material. 3. The refrigeration apparatus according to claim 2, characterized in that at least one of the buffers (20, 21) has a groove (23) around the perimeter, into which the wall element (15) or carrier (7) enters with engagement, and also the fact that the wall element (15) or the carrier (7), on the one hand, and the buffer (20, 21), on the other hand, form a socket (28) or a pin (27), respectively, which engages in the socket. 4. The refrigeration apparatus according to claim 1, characterized in that the first rib (17), which is made protruding on the outside of the carrier (7), and the second rib (19), forming part of the wall element (15), preferably form a labyrinth seal of air channel (14). 5. The refrigeration apparatus according to claim 4, characterized in that one of the two fins (17, 19) surrounds the other without contacting each other. 6. The refrigerator according to one of claims 1 to 5, characterized in that the vibration damping elements (20, 21) are connected to the wall element (15) and / or to the carrier (7) using a plug connection. 7. Refrigeration apparatus according to claim 6, characterized in that at least the first of the vibration-damping elements (21) forms a center of gravity for oscillation in the state of the plug-in connection, during which at least the second vibration-damping element (20 ) can be connected using a plug connection. 8. The refrigeration apparatus according to claim 7, characterized in that the second vibration damping element (20) is preferably fixed in the state of the plug connection. 9. The refrigerator according to claim 7, characterized in that the directions of the plug connection of the first and second vibration damping elements (20, 21) create a substantially right angle.

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