TR201609916A2 - FREEZING DEVICE WITH A ICE UNIT PRODUCING TRANSPARENT ICE - Google Patents

Abstract

The present invention relates to a thermally insulated housing (1) comprising a freezer compartment (3); an ice tray (10) provided in the freezer compartment (3) and positioned with the plurality of ice chambers (12) facing sideways; the freezing device having an ice unit comprising a fluid supply member (20) extending in such a way as to allow fluid delivery on the ice tray (10), in particular a household refrigerator.

Description

DESCRIPTION FREEZER WITH AN ICE UNIT MAKING TRANSPARENT ICE The invention can be used with freezing devices with ice making unit, especially transparent ice. It concerns domestic refrigerators with a making system.

Ice pieces produced with ice units in refrigerators bubbles or accumulation of hard ions such as calcium that collects around it It has a cloudy appearance. Such pieces of ice are thrown into negatively affects the taste of liquids. In industrial-type ice machines, e.g. Vertical in freezer body to produce transparent ice with CN203561125U film by providing a slow flow of water from above to an ice tray positioned It is ensured that ice is formed in the form of ice and that it continues to increase.

In industrial ice machines, it is made of metal panel on which the ice unit is placed. A formed inner liner ensures that the vertically positioned ice tray is balanced. provides positioning.

Patent US6935124 is domestic type with a system for obtaining clear ice explains the refrigerator. refrigerator, a fresh food compartment and a It has a freezer compartment. Transparent ice making system lateral wall and a reservoir floor defining a fluid supply reservoir a fluid-conducted fluid discharge line with supply hopper, fluid supply one fluid per thousand including a fluid discharge line positioned above the reservoir The outlet chamber and at least one side wall extending from the chamber floor to the fluid supply chamber It contains multiple ice forming chambers, identified by A comeback along the upper opening, each ice forming chamber is with a liquid supply chamber and It has fluid conduction through an opening at the bottom of a few sidewalls.

A device comprising an evaporator and a plurality of ice forming fingers extending therefrom. multiple ice forming fingers on the evaporator plate pieces of ice extending into a number of ice forming chambers and freezing the water it is adapted.

The aim of the invention is to produce transparent ice with high ice production efficiency in freezing devices. unit is provided.

To achieve the aforementioned purpose, the invention includes a heat sink comprising a freezer compartment. insulated enclosure; multiple number of items provided in the freezer compartment and having an ice tray positioned with the ice bin facing sideways; ice tray comprising a fluid supply element extending over it to provide fluid conduction. A freezer device with an ice unit is, in particular, a household refrigerator. find it a preferred embodiment is the fluidized supply set under the The fluid supplied from the supply element is transparent in the corresponding ice chambers. multiple dispersing systems providing a fluid film for freezing in ice form contains a fluid container with a number of openings. fluid container, fluid by creating a buffer between the fluid supply element and the ice tray. to the ice tray against changes in the flow rate of the fluid coming from the supply element. It helps to achieve a laminar flow that regulates the flow and provides the film.

In a preferred embodiment of the invention, the fluid container is separated from the openings. It includes at least one separator arranged to separate the rooms. Like this fluid, fluid container without being affected by a slope that may occur in the installation It passes through all the openings provided between the separators.

Inclined mounting of the fluid container in applications without a separator some of the liquid supplied to the fluid container in the case of can accumulate, leaving some openings empty. In such a case, in the ice tray ice can be obtained only in the direction in which the fluid is supplied. Separators, ice tray a continuous film with flow across the openings in the fluid container provides the formation.

In a preferred embodiment of the invention, the fluid container is at least one bowl base facing the ice tray where it is stitched and openings are formed contains. The bottom of the hopper is to assemble the separator into the fluid container. makes it easier. The bottom of the chamber can be in the form of a planar plate or in an alternative embodiment, it may have a stepped, curved or curvilinear form.

In a preferred embodiment of the invention, the fluid supply element is placed in each chamber. it contains one outlet hole which is adjusted correspondingly. In this way, the fluid the supply element comes directly from the fluid supply element of each room. It provides direct filling with fluid.

In a preferred embodiment of the invention, the separator height fluid container is smaller than the circumferential wall height. In this way, the fluid container When the amount of fluid in it rises to fill a room, the separator It can be transferred to another room by hanging it.

In a preferred embodiment of the invention, the fluid container of the openings the position on the ice tray equidistant from the peripheral wall of the ice tray. is being done. In this way, the fluid coming out of each opening is transferred to the ice tray. the speed of the laminar flow is equal to each other and the laminar flow is not disturbed.

In a preferred embodiment of the invention, the fluid container, the ice tray peripheral extends along the wall. The fluid container is pre-warmed along the ice tray. so that it can provide fluid throughout the ice tray from the specified points. The fluid velocity can be minimized without creating turbulence. Choice In one embodiment, the fluid supply element is in the form of a hollow tube.

The pipe form can be supplied easily and the fluid pressure can be adjusted to other geometries. It is possible to transport it efficiently throughout the freezer with less reduction than is happening.

A preferred embodiment of the invention is that the fluid container has openings, fluid a water that is indirectly supplied by the overflow from the supply element. Includes leash room. The overflow chamber, for example located in the fluid container by supplying water indirectly to a neighboring room, When the fluid is supplied due to the fact that it is above the fluid container by ensuring that air bubbles that may occur are thrown out, It directs the fluid that will produce transparent ice.

In a preferred embodiment of the invention, the ice tray is in the freezer compartment. extends in depth. Thus, the side-facing ice tray is transverse to the cabinet. It is placed in such a way that it occupies the least space in the direction.

In a preferred embodiment of the invention, the fluid supply element is the fluid It is connected to the container by snap-fit. Thus, the fluid supply element, It is easily mounted in the fluid container.

An eV device realized to achieve the aim of this invention is given in the attached figures. shown and from these figures; Figure 1 - A freezer containing a representative embodiment of a clear ice unit It is a front perspective view of the refrigerator with compartment.

Figure 2 - A representative configuration of the clear ice unit in the mounting situation rear perspective display.

Figure 3 - is the front perspective view of the transparent ice unit in Figure 2.

Figure 4 - Top perspective view of the transparent ice unit in Figure 2.

Figure 5 - A representative image of a fluid container for the clear buZ unit. from the rear part of the configuration where the fluid supply element is connected perspective assembly display.

Figure 6 - Fluid supply element of fluid container shown in Figure 5 It is a rear perspective view in disassembled condition.

Figure 7 - In the assembly state of the fluid container shown in Figure 5, a is the cross-sectional representation on the axis passing through the opening.

Figure 8 - An assembly condition of the fluid container shown in Figure 5 It is the cross-section representation on the axis passing through the separator.

Figure 9 - representation of the fluid supply element for the transparent ice unit of the invention It is a side view of a configuration.

Figure 10 - Figure Sate is a side view of the fluid container shown.

The parts in the figures are numbered one by one and the corresponding numbers are given below. 1 Enclosure 2 Refrigerator compartments 3 freezer compartments 4 Drawers ice container 12 Ice bin 14 Guide extension 16 Perimeter wall Fluid supply person 21 Introduction 22 Entry Announcement 23 Covers 24 Cover tlansi locking recess 26 Exit hole 27 Transport profiles fluid container 31 Rooms 32 Front wall 33 Hopper base 34 Back wall separator 351 ledge 352 Slots 36 Water overflow tank 37 Holder piece 38 openness 381 flat protrusion 39 Locking Timagi 40 Body 41 Base 42 First support extension 44 Second support extension 45 Installation part 46 Bed part 47 baffle plate 0L Base angle In the figure, there is a refrigerator compartment (2) in the upper part and a freezer in the lower part. heat-insulating enclosure (l) perspective of a domestic refrigerator with compartment (3) is displayed as. The heat-insulated enclosure (l) has a closable door (in the figure). (not shown) in a cabinet structure accessible by Housing (1) inner lining It is a plastic panel. The freezer compartment (3) is located on the floor (41) of the frozen products. There is a drawer (4) where it is stored. Ice in the upper part of the drawer (4) container (5) is provided. The ice bin (5) should have its short edge so that it occupies the least space from the front. an open top box that extends transversely and the long side extends in the depth direction is in the form. A vertical ice tray (10) in the open upper part of the ice cabinet (5) is fixed. The ice tray (10) has a matrix structure and is side-facing rows of ice. It has chambers (12).

In Figure 2, the ice unit is mounted on the back wall of the freezer compartment (3). shown in perspective from the back. Ice tray (10) fully upright position and the ice bins (12) are on a body (40) with the side facing is fixed. The body (40) supports the ice tray (10) on two opposite sides. a first support extension 42 and a second support in the columnar structure, respectively extension (44). First and second support extensions (42, 44) It is in the form of a panel fixed to the ice tray (10) from the sides. Ice tray (10) in a triangular-like form from the lower lateral wall to the base (41) the guide extensions (14) extend. Guide extensions (14) first and second support extension (42, 44) with bottom part of ice tray (10) same as base (41) is in the plane. The guide extensions (14) face the ice tray (10) in the upright position. It forms a support leg in a way that prevents it from tipping correctly. Ice a circumferential wall (16) of the tray (10) and the frame-like structure of the ice bins. (12) limits it from the outermost parts. The upper part of the circumferential wall (16), it is adjacent to the lower edge of an inclined baffle plate 47 . Orientation The plate (47) has a structure with corrugation-like sequential grooves. A fluid container (30) in an open-top box structure is the upper part of the ice tray (10). extends from end to end. The fluid container (30) is placed in the freezer compartment. (3) a front wall (32) facing its open mouth and an opposite rear wall (34) It forms a pool between them. A fluid supply in a hollow tube structure member (20) is provided between the front wall (32) and the rear wall (34). Fluid The adjoining end of the supply member (20) to the front wall (32) is formed into a blind plug-like It is closed with a lid (23) and a rectangular lid tlance (24). is surrounded. The cover flange (24) is a gradual bent portion of the front wall (32) is mounted inside. On the other hand, the fluid supply element (20) is mounted on the rear wall. (34) has a rectangular inlet flange circumferentially enclosing an inlet (21) close to it. (22) has. The lower part of the inlet (21) pipe, which is outside of the inlet flange (22) a U-shaped opening in the middle of the upper edge of the second support extension (44). the cut-out fits into the bearing portion 46 containing the seat 352. Hook a mounting part (45) in the structure from the rear side adjacent to the bearing part (46) It extends posteriorly, joined to the second support extension 44.

Figure 3 shows the perspective from the front of the ice unit. First support mounting part in a panel structure adjacent to the extension (42) from the bottom of the rear edge (45) is located. The body (40) rests on the mounting part (45). the freezer compartment (3) is attached to its inner lining. Perimeter wall (16) bottom grooves on the inclined baffle plate (47) adjacent to its edge A film is added to each ice chamber (12) of the water supplied from the fluid container (30). It allows it to flow over the peripheral wall (16) in a way that forms the form.

In Figure 4, the fluid container (30) is seen from above. On a hopper bottom (33) sequential openings (38) are provided. Total water flow from openings (38) The flow rate is stable as a film on the upper surface of the inclined baffle plate (47) high enough to provide a flow. On the other hand, the inclined baffle plate After (47) the ice tray (10) film flow on the surfaces of the ice bins (12) It will create a healthy contact between cold surfaces and running water. it is of such a low value. In this direction; according to the capacity of the ice unit Although the number of ice bins (12) can be changed, per 100 g of ice The total water flow rate to be provided is 0.8-1.2 L/min. is in the range.

The above-mentioned water flow rate, with the number of columns in the ice chamber (12) being “n” stable and homogeneous water on the inclined surface, provided that the intervals are provided. number of openings (38) in the fluid container (30) structure to allow flow = 2 x (n-l). The diameters of the opening (38) are equivalent to 100 g of ice in the number of holes in question. per 0.8-1.2 L/min. It is adjusted to provide flow rate in the range of can be differentiated. With separators (35) placed in the fluid container (30) The minimum number of rooms (31) in the form of a partitioned pool = (1/2) X (n-l), must be in the range of maximum = (2/3) x (n-l). Room (31) preferably in pool form There must be at least 3 openings (38) per head. Alternatively, laminar in film form The ice making speed parameters required for the flow are with reference to this specification. also available from the combined document U86935124.

The fluid container (30) is a sump base (33) extended and divided into chambers (31) it has the structure of a pool with sequential openings (38). Fluid supply element (20) extends through the fluid container (30). Fluid supply element (20) provided on the hopper bottom (33), close to the inlet flange (22). a retainer (37) snaps the fluid supply element (20) into the fluid it attaches to the container (30). Fluid supply element (20) along its length sewn into the chamber floor (33) partitioning the openings (38) into the chambers (31) It fits into the slots (352) in the appropriate form on the upper part of the separators (35).

As shown in Figures 5 and 6, the fluid supply element (20) is located in the inlet flange. (22) the locking recess (25) formed in the form of a cut on the upper corners and the fluid corresponding locking tabs (39) at the top of the container (30) by stretching the inlet flange (22) into a plug-in connection, removable has. A water overflow tank (36) closes to the inlet (21) for the fluid container. (30) was created on. The water overflow tank (36) is located in the bottom of the tank (33). It is in a section that does not have an opening (38). Hopper base (33) shown in figure 7 it has a base angle (Ot). Base angle (Herb) spaced below the hopper bottom (33) It allows it to extend parallel with the guide plate (47), which is available as a guide.

Fluid supply element (20) lined outlet holes (26) perpendicular to base angle (01) it is positioned at an angle with respect to the ground plane. So exit The turbulence created by the pressure of the water sprayed from the holes (26) directly access to the openings (38) is prevented. The sprayed water is first deposited in the bottom of the hopper. (33) hits the far part of the openings (38) and from there, thanks to the base angle (or) it proceeds to the opening (38) by being directed. The water sprayed during the advance vortex formation near the opening (38) is prevented. Exit As water from the holes (26) flows through the bottom angle (1) and the bowl bottom (33) It has a laminar flow character.

As seen in Figure Side, fluid supply element (20) separator (35) upper In the form of an arc that wraps the pipe between two opposing projections (351) on the it sits on a housing (352). Inverted u in fluid supply element (20) There is a transport profile (27) in the form. Transport profile (27) to separator (35) sits over protrusion (351).

Figure 9 shows a hollow tube with fluid supply element 20 .

In the continuation of the entrance (21) of the pipe, in the lower part, they are angled to each other with respect to the vertical axis. There are exit holes (26) arranged in a distance. Exit holes (26) in pairs according to the corresponding rooms (31) in the lower parts of the settlement. are grouped. In Figure 101, the fluid container (30) is shown from the side. Spicy A flat protrusion (381) surrounds the openings (38) on the bottom of the hopper base (33) it wraps around.

The mains water coming from the inlet (21) of the fluid supply element (20), the outlet It is filled into the fluid container (30) by flowing through the holes (26). Exit holes (26) fill the corresponding rooms (31) independently of each other.

Even if the fluid container (30) is angled on the horizontal axis, the separators (35) it prevents the passage to the neighboring room (31). Openings (38) from hopper bottom (38) The fluid flows through the baffle plate (47) and drains from there to form a it is filled into the ice chamber (12) in a film-forming manner. Thanks to laminar flow no air bubbles are formed in the fluid that fills the ice chamber (12) and The frozen fluid solidifies, forming transparent ice. Fluid supply person (20) can supply mains water directly to the fluid container (30) as well as with the help of another element to which it relates, for example, food coloring or It can also provide a different beverage in freezable liquid form.

Claims (11)

REQUESTS l - A fluid container (30) with a plurality of openings (38) set under the fluid supply element (20) and providing a fluid film to freeze the fluid supplied from the fluid supply element (29) in the form of transparent ice in the corresponding ice chambers (12). Heat-insulated enclosure (1) comprising a freezer compartment (3); an ice tray (10) provided in the freezer compartment (3) and positioned with a plurality of ice bins (12) facing sideways; Freezing device, especially a household refrigerator, with a transparent ice unit, characterized by a fluid supply element (20) that extends over the ice tray (10) in such a way as to provide fluid conduction. 2- A freezing device according to claim 1.6, comprising at least one separator (35) of the fluid container (30) whose openings (38) are arranged to separate the separate rooms (31). 3- A freezing device according to claim 2, wherein the fluid container (30) includes at least one chamber bottom (33) facing the ice tray (10) where the separator (35) is erected and openings (38) are formed. 4- A freezer device according to claim 2 or 3, wherein the fluid supply element (20) includes one outlet opening (26) corresponding to each chamber (31). 5- A freezing device according to Claim 2-4, the height of the separator (35) being less than the height of the fluid container (30) peripheral wall (16). 6- A freezing device according to any one of the preceding claims, the position of the openings (38) above the fluid container (30) configured at an equal distance from the peripheral wall (16) of the ice tray (10). 7. A freezing device according to any one of the preceding claims, where the fluid container (30) extends along the peripheral wall (16) of the ice tray (10). 8- A freezing device according to any one of the preceding claims, wherein the fluid supply element (20) is in the form of a hollow tube. 9. A freezing device according to any one of the preceding claims, comprising a water overflow chamber (36) where the fluid container (30) indirectly supplies the fluids to the openings (38) with the fluid overflow from the fluid supply element (20). 10- A freezing device according to any one of the preceding claims, with the ice tray (10) extending deep within the freezer compartment (3). 11. A freezing device according to any one of the preceding claims, where the fluid supply element (20) is snap-fit connected to the fluid container (30).