CN221076861U - Ice making device for small ice making machine - Google Patents

Abstract

The utility model relates to the field of ice making, in particular to an ice making device for a small ice making machine, which comprises a frame, and an ice making and removing mechanism and an evaporator which are arranged on the frame, wherein the ice making and removing mechanism is connected with the evaporator; the evaporator comprises an ice-forming assembly, wherein the ice-forming assembly comprises a bracket and a plurality of rows of ice-forming grid grooves which are arranged side by side and are arranged on the bracket, and the top of each row of ice-forming grid grooves is provided with a current guide body; the water conservancy diversion body is equipped with concave cambered surface and the protruding cambered surface that links up mutually, protruding cambered surface is located into the notch top in ice tray groove, the width of concave cambered surface is from keeping away from protruding cambered surface one end to being close to protruding cambered surface one end and increase gradually, just concave cambered surface is from keeping away from protruding cambered surface one end to being close to protruding cambered surface one end slope setting. The utility model has high ice making efficiency and good ice making effect.

Description

Ice making device for small ice making machine

Technical Field

The utility model relates to the field of ice making, in particular to an ice making device for a small ice making machine.

Background

An ice maker is an apparatus for making ice particles or crushed ice. They are commonly used in businesses such as bars, restaurants, cold drink and supermarkets, and in refrigerators and freezers in homes. Is also an indispensable refrigeration device for entertainment and rest in hot summer. The existing household ice maker mainly comprises a bullet evaporator, a condenser, a shell, an axial flow fan, a water tank and other parts, wherein the bullet evaporator is partially soaked in water, is affected by a refrigeration system to be cooled and frozen locally, has low freezing efficiency and is small in freezing quantity; the shape and size of the ice is limited by the shape of the evaporator soaked in water, and the ice is generally large in thickness and uneven in size, and is not easy to de-ice, so that the ice making efficiency is low and the ice making effect is poor.

Disclosure of utility model

The utility model aims to solve the technical problem of providing an ice making device for a small ice making machine, which has high ice making efficiency and good ice making effect.

In order to solve the technical problems, the utility model provides an ice making device for a small ice machine, which comprises a frame, and an ice making and removing mechanism and an evaporator which are arranged on the frame, wherein the ice making and removing mechanism is connected with the evaporator;

The evaporator comprises an ice-forming assembly, wherein the ice-forming assembly comprises a bracket and a plurality of rows of ice-forming grid grooves which are arranged side by side and are arranged on the bracket, and the top of each row of ice-forming grid grooves is provided with a current guide body;

The water conservancy diversion body is equipped with concave cambered surface and the protruding cambered surface that links up mutually, protruding cambered surface is located into the notch top in ice tray groove, the width of concave cambered surface is from keeping away from protruding cambered surface one end to being close to protruding cambered surface one end and increase gradually, just concave cambered surface is from keeping away from protruding cambered surface one end to being close to protruding cambered surface one end slope setting.

As an improvement of the scheme, the width of the convex cambered surface is equal to the width of the notch of the ice-forming grid groove.

As an improvement of the scheme, the top wall and the bottom wall of the ice-forming grid groove are respectively provided with an inclined surface, and the inclined surfaces are downwards inclined and extend from the groove bottom to the groove opening.

As an improvement of the scheme, the frame is provided with an ice water separating seat which is arranged below the notch of the ice grid forming groove;

The ice water separating seat is provided with a plurality of ice particle guide plates which are arranged at intervals, and a water flow guide groove is enclosed between two adjacent ice particle guide plates and the ice water separating seat.

As an improvement of the scheme, the ice particle guide plates and the middle line positions of each row of ice grid grooves are arranged in a one-to-one correspondence mode.

As an improvement of the scheme, the ice water separating seat is provided with a diversion inclined plane, and the diversion inclined plane is arranged close to the ice grid forming groove.

As the improvement of above-mentioned scheme, the frozen water separation seat still is equipped with rivers baffle and water channel, form the rivers runner between rivers baffle and the water flow guide way, rivers runner and water channel intercommunication.

As an improvement of the scheme, the ice basket is arranged in front of the ice water separation seat.

As an improvement of the scheme, an ice particle sensor is arranged in the frame and is arranged above the blue port of the ice basket.

As an improvement of the scheme, the ice making and removing mechanism comprises a compressor, a condenser, a dry filter, a capillary tube and an electromagnetic valve, wherein the compressor, the condenser, the dry filter, the capillary tube and the evaporator are sequentially connected, and the electromagnetic valve is respectively connected with the compressor and the evaporator.

The implementation of the utility model has the following beneficial effects:

The utility model relates to an ice-making assembly arranged on an evaporator of an ice-making device for a small ice-making machine, which comprises a plurality of rows of ice-making cells arranged side by side, wherein the top of each row of ice-making cells is provided with a current guide body, and water flows are uniformly paved on the notches of the corresponding ice-making cells through the current guide effect of the current guide bodies. Specifically, the water conservancy diversion body is equipped with concave cambered surface and the protruding cambered surface that links up mutually, and rivers fall to concave cambered surface, and the concave cambered surface of slope makes rivers produce certain kinetic energy to the protruding cambered surface is diffused on whole protruding cambered surface gradually through concave cambered surface, and the rivers flow to the notch in ice grid groove under the direction and the rectification effect of protruding cambered surface, form even rivers curtain on the notch. Therefore, in the process of refrigerating the evaporator by the ice making and removing mechanism, ice particles with uniform size can be formed in the ice forming grid groove, and the ice forming speed is high. In the process of heating the evaporator by the ice making and removing mechanism, the ice layer is uniformly paved on the ice forming grid grooves, so that the ice removing speed is high, and the ice particles in the ice forming grid grooves can be quickly separated from the ice forming grid grooves, and the ice removing speed is high. Therefore, the ice making efficiency is high and the ice making effect is good.

Drawings

Fig. 1 is a schematic view of the structure of an ice making device for a small-sized ice maker according to the present utility model;

FIG. 2 is a cross-sectional view of FIG. 1;

FIG. 3 is a schematic view of the internal ice making and removing mechanism of FIG. 1;

FIG. 4 is a schematic view of the structure of FIG. 3 at another angle;

FIG. 5 is a schematic view of the connection structure of the ice-forming assembly, the ice water dispenser and the ice basket of FIG. 1;

Fig. 6 is a schematic view of the ice-forming assembly of fig. 5.

Detailed Description

The present utility model will be described in further detail with reference to the accompanying drawings, for the purpose of making the objects, technical solutions and advantages of the present utility model more apparent. It is only stated that the terms of orientation such as up, down, left, right, front, back, inner, outer, etc. used in this document or the imminent present utility model, are used only with reference to the drawings of the present utility model, and are not meant to be limiting in any way.

Referring to fig. 1 to 6, the present utility model discloses an ice making device for a small-sized ice maker, which includes a frame 100, and an ice making and removing mechanism and an evaporator 1 mounted on the frame 100, the ice making and removing mechanism being connected to the evaporator 1.

The evaporator 1 comprises an ice-forming assembly, the ice-forming assembly comprises a bracket 11 and a plurality of rows of ice-forming cells 12 which are arranged side by side and are arranged on the bracket 11, and a current guide body 13 is arranged at the top of each row of ice-forming cells 12.

The flow guide body 13 is provided with a concave cambered surface 131 and a convex cambered surface 132 which are connected with each other, the convex cambered surface 132 is arranged above the notch of the ice tray forming groove 12, the width of the concave cambered surface 131 gradually increases from one end far away from the convex cambered surface 132 to one end close to the convex cambered surface 132, and the concave cambered surface 131 is obliquely arranged from one end far away from the convex cambered surface 132 to one end close to the convex cambered surface 132.

The utility model relates to an ice-making assembly arranged on an evaporator of an ice-making device for a small ice-making machine, which comprises a plurality of rows of ice-making cells arranged side by side, wherein the top of each row of ice-making cells is provided with a current guide body, and water flows are uniformly paved on the notches of the corresponding ice-making cells through the current guide effect of the current guide bodies. Specifically, the water conservancy diversion body is equipped with concave cambered surface and the protruding cambered surface that links up mutually, and rivers fall to concave cambered surface, and the concave cambered surface of slope makes rivers produce certain kinetic energy to the protruding cambered surface is diffused on whole protruding cambered surface gradually through concave cambered surface, and the rivers flow to the notch in ice grid groove under the direction and the rectification effect of protruding cambered surface, form even rivers curtain on the notch. Therefore, in the process of refrigerating the evaporator by the ice making and removing mechanism, ice particles with uniform size can be formed in the ice forming grid groove, and the ice forming speed is high. In the process of heating the evaporator by the ice making and removing mechanism, the ice layer is uniformly paved on the ice forming grid grooves, so that the ice removing speed is high, and the ice particles in the ice forming grid grooves can be quickly separated from the ice forming grid grooves, and the ice removing speed is high. Therefore, the ice making efficiency is high and the ice making effect is good.

Specifically, the concave arc surface 131 is fan-shaped.

Preferably, the width of the convex arc surface 132 is equal to the width of the notch of the ice-forming groove 12, so that the water flow can cover the notch of the ice-forming groove, and the formed ice particles can completely fill the ice-forming groove, and the shape and the size of the ice particles are consistent with those of the ice-forming groove and uniform.

Preferably, as shown in fig. 6, the top wall and the bottom wall of the ice-forming cell 12 are provided with inclined surfaces 121, and the inclined surfaces 121 are arranged to extend downwards from the bottom of the cell to the notch. The inclined plane is arranged to enable the ice particles to be easily separated into ice grid grooves in the process of ice removal.

Preferably, as shown in fig. 2 and 6, a water spraying pipe 10 is disposed above the concave arc surface 131, water spraying holes (not shown in the drawings) are disposed on the water spraying pipe 10, and the water spraying holes and the concave arc surface 131 are disposed in one-to-one correspondence. The water flow flows to the convex cambered surface through the concave cambered surface and flows to the notch of the ice grid forming groove under the rectification action of the convex cambered surface.

Further, as shown in fig. 2 and 5, the frame 100 is provided with an ice separating seat 2, and the ice separating seat 2 is disposed below the notch of the ice tray 12. The ice and water can be automatically separated through the arrangement of the ice water separation seat, and the ice water is prevented from being mixed so as to accelerate the melting of the ice.

Specifically, the ice-water separation seat 2 is provided with a plurality of ice particle guide plates 21 which are arranged at intervals, and a water flow guide groove 22 is enclosed between two adjacent ice particle guide plates 21 and the ice-water separation seat 2. The ice particles in the ice-making grid groove fall onto the ice particle guide plate, so that the ice particles are ejected outwards. And water flows into the water flow guide groove along the groove edges of the ice-forming grooves to be collected, so that ice-water separation is realized.

Preferably, the ice particle guide plates 21 are arranged in one-to-one correspondence with the middle line positions of each row of ice grid grooves 12, so that the dropped ice particles can be ensured to accurately collide with the ice particle guide plates and pop up, and the falling into the water flow guide grooves and the blocking caused by the falling ice particles are avoided.

Preferably, the ice-water separation seat 2 is provided with a diversion inclined plane 26, and the diversion inclined plane 26 is arranged close to the ice-making cell 12. Under the guidance of the diversion inclined plane, the water flow smoothly and gently flows into the water flow guiding groove, and the noise can be effectively reduced.

Preferably, the ice-water separating seat 2 is further provided with a water flow baffle 23 and a water flow channel 24, a water flow channel 24 is formed between the water flow baffle 23 and the water flow guiding groove 22, and the water flow channel 24 is communicated with the water flow channel 25. The water flow baffle is arranged to prevent water from flowing out of the ice water separation seat, so that the flow limiting effect is achieved. Meanwhile, the water flow channel is arranged to enable water to be converged to the water flow channel along the water flow channel, and finally water is collected through the water flow channel and can be recycled.

Preferably, as shown in fig. 2 and 5, the present utility model further includes an ice basket 3, and the ice basket 3 is provided in front of the ice water dispenser 2. The ice basket can catch the ice particles ejected from the ice particle guide plate and plays a role in collecting the ice particles. More preferably, the blue mouth of the basket 3 has a height lower than the top of the water flow baffle 23. If the basket opening is too high, it may not be possible for ice particles to fall into the basket.

The ice basket 3 and the ice-water separating seat 2 are independent and are not communicated with each other. The water in the water flow guide groove 22, the water flow channel 24 and the water flow channel 25 all flow outside the ice basket 5 and cannot enter the ice basket 5, so that the water is prevented from contacting with the ice particles to accelerate the melting of the ice particles.

Preferably, as shown in fig. 2 and 5, an ice particle sensor 4 is disposed in the frame 100, and the ice particle sensor 4 is disposed above the blue mouth of the ice basket 3. The ice particle sensor 4 is preferably an infrared sensor. The ice particle sensor is used for sensing whether ice particles fall into ice blue or not, a user can know the ice making condition, and a sensing result is displayed on a display screen of the frame. More preferably, the height of the ice particle sensor 4 is lower than the height of the top of the ice particle guide plate 21. If the height of the ice particle sensor is too high, the ice particles may not be sensed.

As shown in fig. 2-4, the ice making and removing mechanism comprises a compressor 5, a condenser 6, a dry filter 7, a capillary tube 8 and an electromagnetic valve 9, wherein the compressor 5, the condenser 6, the dry filter 7, the capillary tube 8 and the evaporator 1 are sequentially connected, and the electromagnetic valve 9 is respectively connected with the compressor 5 and the evaporator 1.

When making ice, the electromagnetic valve 9 is closed, and high-pressure gas is sequentially delivered to the condenser 6, the dry filter 7, the capillary tube 8 and the evaporator 1 through the compressor 5, so that water flow on the ice-forming grid groove 12 gradually forms ice particles. When the ice is removed, the electromagnetic valve 9 is opened, high-pressure gas flows to the electromagnetic valve 9 through the compressor 5 and is conveyed to the evaporator 1, so that thinner ice blocks on the ice-making grooves 12 are melted, for example: the ice blocks at the edges of the ice-forming cells make the ice particles in the ice-forming cells 12 separate from the ice-forming cells 12 under the action of gravity, fall onto the ice particle guide plates 21 and rebound out, and finally fall into the ice basket 3 for collection. The water obtained by melting ice blocks falls into the water flow guide groove 22 under the guide of the guide inclined plane 26, converges in the water flow channel 24, and finally flows out of the ice water separation seat 2 through the water flow channel 25 and is collected.

It should be noted that the ice making and removing mechanism realizes refrigeration and heating, and adopts the structure of the prior art, which is not described in detail here.

In summary, the utility model provides an ice making device for a small ice making machine, which has high ice making efficiency and good ice making effect.

While the foregoing is directed to the preferred embodiments of the present utility model, it will be appreciated by those skilled in the art that changes and modifications may be made without departing from the principles of the utility model, such changes and modifications are also intended to be within the scope of the utility model.

Claims (10)

1. An ice making device for a small ice making machine is characterized by comprising a frame, and an ice making and removing mechanism and an evaporator which are arranged on the frame, wherein the ice making and removing mechanism is connected with the evaporator;

The evaporator comprises an ice-forming assembly, wherein the ice-forming assembly comprises a bracket and a plurality of rows of ice-forming grid grooves which are arranged side by side and are arranged on the bracket, and the top of each row of ice-forming grid grooves is provided with a current guide body;

The water conservancy diversion body is equipped with concave cambered surface and the protruding cambered surface that links up mutually, protruding cambered surface is located into the notch top in ice tray groove, the width of concave cambered surface is from keeping away from protruding cambered surface one end to being close to protruding cambered surface one end and increase gradually, just concave cambered surface is from keeping away from protruding cambered surface one end to being close to protruding cambered surface one end slope setting.

2. The ice making apparatus for a small-sized ice maker as claimed in claim 1, wherein the width of the convex arc surface is equal to the width of the notch of the ice-making cell.

3. The ice making apparatus for a small ice maker as claimed in claim 1, wherein the top wall and the bottom wall of the ice-forming cells are each provided with a slope which is provided to extend obliquely downward from the bottom of the cell to the notch.

4. The ice-making device for a small-sized ice maker as claimed in claim 1, wherein the frame is provided with an ice water separating seat, and the ice water separating seat is provided below a notch of the ice tray;

The ice water separating seat is provided with a plurality of ice particle guide plates which are arranged at intervals, and a water flow guide groove is enclosed between two adjacent ice particle guide plates and the ice water separating seat.

5. The ice-making device for a small-sized ice maker as claimed in claim 4, wherein the ice particle guide plates are disposed in one-to-one correspondence with the intermediate line positions of the ice tray grooves of each row.

6. The ice-making device for a small-sized ice maker as recited in claim 4, wherein said ice-water separation housing is provided with a guide slope, said guide slope being disposed adjacent to the ice-making cells.

7. The ice-making device for a small-sized ice maker as claimed in claim 4, wherein said ice-water separating seat is further provided with a water flow baffle and a water flow passage, a water flow passage is formed between said water flow baffle and said water flow guide groove, and said water flow passage are communicated.

8. The ice-making device for a small-sized ice maker as recited in claim 7, further comprising an ice basket provided in front of the ice water dispenser.

9. The ice making apparatus for a small ice maker of claim 8, wherein an ice particle sensor is provided in said housing, said ice particle sensor being provided above a blue mouth of said ice basket.

10. The ice making apparatus for a small ice making machine according to any one of claims 1 to 9, wherein said ice making/removing mechanism comprises a compressor, a condenser, a dry filter, a capillary tube and an electromagnetic valve, said compressor, condenser, dry filter, capillary tube and evaporator being connected in this order, said electromagnetic valve being connected to the compressor and evaporator, respectively.