CN221146887U - Running water formula ice making subassembly - Google Patents

Abstract

The utility model discloses a running water type ice making assembly, which comprises: the ice making device comprises an ice making main body, wherein the front surface of the ice making main body is provided with an ice grid, the back surface of the ice making main body is provided with an evaporator, the ice making main body is provided with a water storage groove, the water storage groove is positioned above the ice grid, an overflow hole is formed in communication with the water storage groove, and water in the water storage groove flows into the ice grid through the overflow hole; when the ice cube storage device is used, water flows into the water storage tank, and when the water level in the water storage tank is higher than that of the overflow holes, water flows out of the plurality of overflow holes simultaneously and uniformly flows into the ice cubes to prepare ice cubes with uniform sizes; the water storage tank and the overflow hole are integrally formed on the ice making main body, so that the ice making device is simple in structure and does not need redundant installation steps.

Description

Running water formula ice making subassembly

Technical Field

The utility model relates to the technical field of ice making components, in particular to a running water type ice making component.

Background

An ice maker is a refrigeration mechanical device which cools water by an evaporator through a refrigerating system refrigerant to generate ice, and the ice is manufactured by adopting the refrigerating system and a water carrier through a certain device under the power-on state.

The running water type evaporator in the prior art on the current market distributes water to the ice grid in a water curtain pipe mode, such as Chinese patent number: 201920298526.0 discloses an ice making assembly of an ice maker, which comprises a water tank, an ice template, an evaporator, a water curtain pipe, an ice receiving box and a circulating water pump; the ice template is vertically arranged, and an ice grid is arranged on the front end face of the ice template; the evaporating pipe of the evaporator is arranged on the rear end face of the ice template; the water tank is located the top of ice template, and the cascade pipe is located between water tank and the ice template, is provided with a plurality of delivery ports on this cascade pipe, and a plurality of the delivery port is the one-to-one setting with the transversely arranged ice tray on the ice template, and during the use, the water in the water tank flows into the ice tray through the cascade pipe, carries out the heat exchange through the evaporimeter to make the ice-cube, but above-mentioned mode is very high to the technological requirement of cascade pipe, and the installation is also more complicated.

Disclosure of utility model

In view of this, the present utility model provides a flow-through ice making assembly.

In order to achieve the above purpose, the present utility model adopts the following technical scheme: a continuous-flow ice making assembly comprising: the ice making device comprises an ice making main body, wherein the front surface of the ice making main body is provided with an ice grid, the back surface of the ice making main body is provided with an evaporator, the ice making main body is provided with a water storage groove, the water storage groove is positioned above the ice grid, an overflow hole is formed in communication with the water storage groove, and water in the water storage groove flows into the ice grid through the overflow hole; when the ice cube storage device is used, water flows into the water storage tank, and when the water level in the water storage tank is higher than that of the overflow holes, water flows out of the plurality of overflow holes simultaneously and uniformly flows into the ice cubes to prepare ice cubes with uniform sizes; the water storage tank and the overflow hole are integrally formed on the ice making main body, so that the ice making device is simple in structure and does not need redundant installation steps.

As an alternative scheme of the utility model, the overflow holes are arranged on the front surface of the ice making main body, and a water spraying area is formed between the overflow holes and the ice grid; the utility model can ensure that water flows out from the overflow holes and flows into the water spraying area at the same time, and water can uniformly flow into the ice grid.

As an optional scheme of the utility model, the ice grids are transversely arranged and distributed on the ice making main body; the overflow holes are uniformly distributed on the front surface of the ice making main body; the water in the water storage tank can uniformly flow into the ice grid through the overflow holes and the water spraying area.

As an alternative scheme of the utility model, the overflow holes are arranged in a strip shape or in a long arc shape; the overflow holes are in one-to-one correspondence with the ice grids; the overflow holes are arranged in a strip shape or a long arc shape, so that the water yield of the overflow holes can be improved, the water flow area is increased, and the ice making efficiency is further improved.

As an alternative scheme of the utility model, the overflow holes are round holes, and diversion trenches are arranged between the overflow holes and the ice grids and distributed along the transverse arrangement direction of the ice grids; here is another structural style of overflow aperture, adopts circular shape overflow aperture also can reach the purpose of water simultaneously, and after the water flow from the overflow aperture flows into the guiding gutter, can flow to the ice tray through the guiding gutter, can increase the rivers area in the water spray zone, and rivers flow into the ice tray better, and then have increased ice making efficiency.

As an alternative scheme of the utility model, the ice making main body is provided with the area of the overflow hole which is concavely arranged to form a concave position, and the lower surface of the concave position is arranged in an arc shape to guide the fluid to flow to the diversion trench.

As an alternative scheme of the utility model, the ice making main body is provided with two rows of circular overflow holes which are transversely arranged; in this embodiment, the overflow holes are circular, so that the cross-sectional flow is smaller, and under the condition of high water injection speed in the water storage tank, the two rows of overflow holes can increase the water yield, and the overflow of the water storage tank is prevented.

As an alternative aspect of the present utility model, the ice-making body includes: an ice tray bracket and an ice tray; the water storage tank and the overflow hole are arranged on the ice tray bracket; the ice tray is provided with the ice grid.

As an optional scheme of the utility model, the front surface of the ice tray support is provided with an inner cavity, and the ice tray is embedded and installed on the ice tray support.

The other beneficial technical effects of the utility model are embodied in the specific embodiments.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required to be used in the embodiments or the description of the prior art will be briefly described below, and it is obvious that the drawings in the following description are only embodiments of the present utility model, and that other drawings can be obtained according to the provided drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of embodiment 1 of a continuous-flow ice making assembly of the present utility model;

FIG. 2 is a schematic cross-sectional view of embodiment 1 of a continuous-flow ice making assembly of the present utility model;

FIG. 3 is a schematic view of example 2 of a continuous-flow ice making assembly according to the utility model.

Reference numerals illustrate:

An ice-making body 100; an ice tray 101; a water reservoir 102; a water inlet 1021; an overflow aperture 103; a diversion trench 104; the concave position 105; a lower surface 1051; a water shower area 106; a tray support 110; an ice tray 120; an evaporator 200.

Detailed Description

The invention will now be described in further detail with reference to the accompanying drawings. The drawings are simplified schematic representations which merely illustrate the basic structure of the invention and therefore show only the structures which are relevant to the invention.

Example 1

A flow-through ice making assembly, as shown in fig. 1 and 2, comprising: the ice making device comprises an ice making main body 100, wherein an ice grid 101 is arranged on the front surface of the ice making main body 100, an evaporator 200 is arranged on the back surface of the ice making main body 100, a water storage tank 102 is arranged on the ice grid 101, an overflow hole 103 is formed in communication with the water storage tank 102, and water in the water storage tank 102 flows into the ice grid 101 through the overflow hole 103.

Specifically, the ice tray support 110 and the ice tray 120, the ice tray 120 may be fixedly mounted on the ice tray support 110, or may be separately and limitedly mounted on the ice tray support 110;

The water storage tank 102 and the overflow hole 103 are arranged on the ice tray support 110, and the ice tray 101 is arranged on the ice tray 120.

The water storage tank 102 is provided with a water inlet 1021, and an external water supply assembly is connected with the water storage tank 102 through the water inlet 1021 and supplies water into the water storage tank 102;

When the water level in the water storage tank 102 is higher than the height of the overflow hole 103 in use, water in the water storage tank 102 flows out through the overflow hole 103 and uniformly flows into the ice tray 101; in the evaporation coil of the evaporator 200, the cooling liquid circulates to absorb the heat of the water in the ice tray 101, so that the water in the ice tray 101 continuously releases the heat and slowly condenses into ice blocks, thereby achieving the purposes of fast ice making and uniform size of the ice blocks.

In the embodiment, the water storage tank 102 is adopted to replace the traditional water curtain pipe, the water storage tank 102 is directly formed on the ice tray bracket 110, the structure is simple, and the assembly steps of products are reduced; and the overflow holes 103 automatically correspond to the ice trays 101 after the ice tray 120 is installed.

In an alternative embodiment, the tray 120 is detachably mounted to the tray support 110.

The front of the ice tray support 110 is provided with an inner cavity, the ice tray 120 is embedded and installed in the inner cavity of the ice tray support 110, and is locked through a limiting piece, after ice making is completed, the limiting piece is unlocked, the whole ice tray 120 can be taken out, and ice cubes can be taken out.

Further, the evaporator 200 has an evaporation coil uniformly arranged on the back surface of the tray support 110, and exchanges heat with the tray 120 through the back surface of the tray support 110;

the evaporator 200 may be welded to the back of the tray support 110.

To enhance heat exchange efficiency, a layer of heat conducting glue may be provided between the tray support 110 and the evaporation coil.

In an alternative embodiment, the overflow hole 103 is disposed on the front surface of the ice making body 100, and a water spraying area 106 is formed between the overflow hole 103 and the ice tray 101;

As shown in fig. 1, the water inlet 1021 is arranged on the right side of the water storage tank 102, when water flows in from the water inlet 1021, the water flows from the right side to the left side so as to fully distribute the bottom of the water storage tank 102, when the water level is higher than the overflow hole 103, the water flows out from the overflow hole 103 and flows downwards along the water spraying area 106, and finally flows into the ice grid 101.

Further, the ice trays 101 are arranged and distributed transversely on the ice making main body 100; the overflow holes 103 are uniformly distributed on the front surface of the ice making body 100.

As further shown in fig. 1, three rows of ice trays 101 are arranged and distributed on the ice tray 120, and the overflow holes 103 are opposite to the upper side of the ice trays 101, and the area between the overflow holes 103 and the ice trays 101 forms the water spraying area 106.

Further, the overflow holes 103 are arranged in a strip shape or the overflow holes 103 are arranged in a long arc shape, and the overflow holes 103 are in one-to-one correspondence with the ice grids 101, so as shown in fig. 1, when water flows out from the overflow holes 103, the water flows out along the strip-shaped overflow holes 103, the water flow area of the water flowing through the water spraying area 106 is large, and meanwhile, the water flow area flowing into the ice grids 101 is large, so that the contact area between the water flow and the ice grids 101 is increased, and the ice making efficiency is further increased.

Example 2

The difference between this embodiment 2 and embodiment 1 is that, as shown in fig. 3, the overflow hole 103 is configured as a circular hole, and a diversion trench 104 is added between the overflow hole 103 and the ice tray 101, and the diversion trench 104 is distributed along the transverse arrangement direction of the ice tray 101; when in use, the water in the overflow hole 103 flows into the diversion trench 104, then flows into the ice tray 101 through the diversion trench 104 and the water spraying area 106, and absorbs the heat of the water through the cooling liquid in the evaporator 200, so that the water in the ice tray 101 is formed into ice cubes.

Further, the ice making body 100 is concavely disposed in the area where the overflow hole 103 is disposed, so as to form a concave portion 105, and a lower surface 1051 of the concave portion 105 is arcuately disposed, so as to guide the fluid to flow toward the diversion trench 104; when in use, after the water level in the water storage tank 102 reaches the overflow hole 103, the water flows out of the overflow hole 103 and uniformly flows to the ice tray 101 under the guidance of the diversion trench 104;

Further, the water spraying area 106 is formed between the diversion trench 104 and the ice tray 101, that is, the water flows out from the overflow hole 103 and uniformly flows through the water spraying area 106 under the guidance of the diversion trench 104 to flow to the ice tray 101, so that the water passing area is increased, and the ice making efficiency is improved.

Further, two rows of circular overflow holes 103 are arranged on the ice making main body 100, and because the overflow holes 103 are circular and small in shape, insufficient flow rate is easy to occur, for example, when the water storage tank 102 is used for supplementing water, the water supplementing speed is high, the water flowing speed of the overflow holes 103 is low, the water flowing speed in the water storage tank 102 is high, and two rows of overflow holes 103 are arranged to prevent the water storage tank 102 from overflowing; alternatively, the water output can be increased by discharging water through the two rows of overflow holes 103 during the continuous water replenishment process of the water storage tank 102.

In addition, in the above embodiments 1 and 2, the water inlet 1021 of the water storage tank 102 may be connected to an external water supply assembly, which may be a combination of a water tank and a water pump;

A water receiving tank can be arranged at the bottom of the ice making main body 100, and the water receiving tank is connected with the water storage tank 102 through a backflow pipeline, so that the dripped water is backflow to the water storage tank 102 for recycling.

The running water type ice making assembly solves the problem of uneven water flow distribution of the ice grid 101 for a user, improves the user experience of the ice maker, and simultaneously eliminates the traditional water curtain pipe structure by arranging the water storage groove 102 on the ice tray support 110, reduces assembly steps and can realize that a plurality of overflow holes discharge water simultaneously.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present utility model. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the utility model. Thus, the present utility model is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (9)

1. A continuous-flow ice making assembly comprising: the ice making machine comprises an ice making main body (100), wherein an ice grid (101) is arranged on the front side of the ice making main body (100), and an evaporator (200) is arranged on the back side of the ice making main body, and is characterized in that: the ice making main body (100) is provided with a water storage groove (102), the water storage groove (102) is positioned above the ice grid (101), an overflow hole (103) is formed in the water storage groove (102) in a communicated mode, and water in the water storage groove (102) flows into the ice grid (101) through the overflow hole (103).

2. The flow-through ice making assembly of claim 1, wherein: the overflow hole (103) is arranged on the front surface of the ice making main body (100), and a water spraying area (106) is formed between the overflow hole (103) and the ice grid (101).

3. A continuous-flow ice making assembly according to claim 2, wherein: the ice grids (101) are transversely arranged and distributed on the ice making main body (100); the overflow holes (103) are uniformly distributed on the front surface of the ice making main body (100).

4. A continuous-flow ice making assembly according to claim 3, wherein: the overflow holes (103) are arranged in a strip shape or the overflow holes (103) are arranged in a long arc shape; the overflow holes (103) are in one-to-one correspondence with the ice grids (101).

5. A continuous-flow ice making assembly according to claim 2, wherein: the overflow holes (103) are round holes, guide grooves (104) are arranged between the overflow holes (103) and the ice grids (101), and the guide grooves (104) are distributed along the transverse arrangement direction of the ice grids (101).

6. The continuous-flow ice making assembly of claim 5, wherein: the ice making main body (100) is provided with an overflow hole (103) in a concave manner to form a concave position (105), and the lower surface (1051) of the concave position (105) is arranged in an arc shape to guide fluid to flow to the diversion trench (104).

7. The continuous-flow ice making assembly of claim 5, wherein: two rows of circular overflow holes (103) which are transversely arranged are arranged on the ice making main body (100).

8. A continuous-flow ice making assembly according to any one of claims 1-7, wherein: the ice-making body (100) includes: an ice tray holder (110) and an ice tray (120); the water storage groove (102) and the overflow hole (103) are arranged on the ice tray bracket (110); the ice tray (120) is provided with the ice grid (101).

9. The flow-through ice making assembly of claim 8, wherein: the front of the ice tray support (110) is provided with an inner cavity, and the ice tray (120) is embedded and installed on the ice tray support (110).