CN221055305U - Ice discharging device for ice machine and ice machine - Google Patents

Abstract

The utility model provides an ice discharging device for an ice maker and the ice maker. The ice maker includes an ice making tub. The ice discharging device comprises a water tank and an ice discharging box. The upper part of the water tank is provided with an overflow port which is arranged above the ice outlet of the ice making barrel and is communicated with the ice outlet. The ice outlet box is arranged at the upper ice outlet of the ice making barrel, the ice outlet box is provided with a first ice outlet surface and a second ice outlet surface which are connected, the first ice outlet surface is arranged around the ice outlet, the second ice outlet surface is used for enabling ice cubes to be discharged out of the ice outlet box, at least part of the first ice outlet surface, which is close to the second ice outlet surface, is configured to be a first inclined surface, and the second ice outlet surface is configured to be a second inclined surface connected with the first inclined surface, so that the ice cubes are discharged at least through the first inclined surface and the second inclined surface. The structure can realize that ice cubes are not easy to accumulate in the ice outlet box, can be rapidly discharged, achieves the aim of enabling the ice cubes to be discharged outwards more smoothly, solves the problem of ice storage and blocking in the ice outlet box, enables the ice maker to make ice efficiently, and improves user experience.

Description

Ice discharging device for ice machine and ice machine

Technical Field

The utility model relates to the technical field of ice making, in particular to an ice discharging device for an ice maker and the ice maker.

Background

The existing granular ice making machine on the market has the phenomena of large ice storage and ice blockage of the ice outlet box, even more ice is not smoothly dropped to cause the phenomenon that the ice is stored in the ice outlet box more and the ice outlet box cover is blocked to be exploded, and the solution on the market is that the ice cubes on the ice outlet box are stirred by the stirring rod device to fall off, so that the stirring rod device is connected with the ice squeezing motor, the force is large, a certain danger exists, and the cost is increased. For example, chinese patent publication No. CN116242071a discloses an ice maker capable of efficiently and stably discharging ice, the ice making structure of the ice maker comprises an ice making core, a condenser pipe is wound on the surface of the ice making core, a spiral feeding shaft is arranged inside the ice making core, an ice poking rod is connected to the surface of the connecting end of the spiral feeding shaft, and therefore ice is discharged through the ice poking rod.

Disclosure of utility model

Aiming at the technical problems in the prior art, the utility model provides an ice discharging device for an ice machine and the ice machine, which improve the safety coefficient of the ice machine and the use experience of a user through the optimization of the structure.

The embodiment of the utility model provides an ice discharging device for an ice maker, the ice maker comprises an ice making barrel, and the ice discharging device comprises:

The upper part of the water tank is provided with an overflow port which is arranged above the ice outlet of the ice making barrel and is communicated with the ice outlet;

The ice discharging box is arranged at the upper ice discharging opening of the ice making barrel and is provided with a first ice discharging surface and a second ice discharging surface which are connected, the first ice discharging surface is arranged around the ice discharging opening, the second ice discharging surface is used for enabling ice cubes to be discharged out of the ice discharging box, at least part of the first ice discharging surface, which is close to the second ice discharging surface, is configured to be a first inclined surface, and the second ice discharging surface is configured to be a second inclined surface connected with the first inclined surface, so that the ice cubes are discharged at least through the first inclined surface and the second inclined surface. The structure can realize that ice cubes are not easy to accumulate in the ice outlet box, can be rapidly discharged, achieves the aim of enabling the ice cubes to be discharged outwards more smoothly, solves the problem of ice storage and blocking in the ice outlet box, enables the ice maker to make ice efficiently, and improves user experience.

In some embodiments, a portion of the first ice-out face remote from the second ice-out face is configured as a first plane, the first plane meets the first inclined face, and an area of the first plane is smaller than an area of the first inclined face. Therefore, ice cubes discharged from the upper ice outlet of the ice making barrel can be more discharged to the first inclined plane and move towards the direction where the second inclined plane is located through the guiding of the first inclined plane.

In some embodiments, an end of the first inclined surface that meets the first plane is configured as a high end of the first inclined surface, and a height of the high end of the first inclined surface is lower than a height of the first plane. Through setting up the difference in height for first inclined plane and first plane junction, can make the ice-cube fall down more fast by first plane, further improve ice efficiency.

In some embodiments, the end of the second inclined surface connected with the first inclined surface is configured as a high-position end of the second inclined surface, the end of the first inclined surface connected with the second inclined surface is configured as a low-position end of the first inclined surface, and the high-position end of the second inclined surface is lower than the low-position end of the first inclined surface. Through setting up the difference in height for first inclined plane and second inclined plane junction, can make the ice-cube fall more fast when from first inclined plane to second inclined plane, further improve ice efficiency.

In some embodiments, the ice outlet box is provided with a water inlet, and the overflow port is communicated with the ice outlet of the ice making barrel through the water inlet, so that after water in the water tank exceeds the overflow port, the water can be discharged into the ice making barrel through the overflow port and the water inlet, and ice making of the ice making barrel is realized.

In some embodiments, the water inlet is provided on a side of the ice bank remote from the second ice-out surface such that water entering the ice bank can be evenly spread over the first ice-out surface.

In some embodiments, the height of the overflow port is higher than that of the water inlet, and the ice outlet device further comprises an overflow groove communicated with the water inlet and the overflow port respectively, and the groove bottom of the overflow groove is obliquely arranged. Through the inclined arrangement of the tank bottom of the overflow tank, the flow speed of water can be accelerated, so that the impact force of the water discharged from the overflow tank is larger, and the deicing speed is accelerated.

In some embodiments, the cavity bottom angle of the ice bank is configured as a tilt angle. Therefore, the ice pushing process in the ice box can be smoother, and quick ice discharging is facilitated.

In some embodiments, the ice bank further has an ice blocking plate formed by extending upward edges of the first and second ice-discharging surfaces. The ice baffle can limit the movement track of the ice cubes, and the ice cubes are prevented from falling out of the ice box.

The embodiment of the utility model also provides an ice maker, which comprises the ice discharging device for the ice maker. The structure can realize that ice cubes are not easy to accumulate in the ice outlet box, can be rapidly discharged, achieves the aim of enabling the ice cubes to be discharged outwards more smoothly, solves the problem of ice storage and blocking in the ice outlet box, enables the ice maker to make ice efficiently, and improves user experience.

Compared with the prior art, the embodiment of the utility model has the beneficial effects that: according to the utility model, at least part of the first ice outlet surface, which is close to the second ice outlet surface, is configured as the first inclined surface, and the second ice outlet surface is configured as the second inclined surface connected with the first inclined surface, so that ice cubes discharged from the ice outlet of the ice making barrel can be directly discharged outwards through the guidance of the first inclined surface and the second inclined surface, the ice cubes are not easy to be accumulated in the ice outlet box, but can be rapidly discharged, the aim of enabling the ice cubes to be discharged outwards more smoothly is achieved, the phenomenon of ice storage and ice blockage in the ice outlet box is solved, the ice making machine is enabled to make ice efficiently, and the user experience is improved. In addition, the utility model does not need to adopt electrical structures such as a motor, and the like, compared with the scheme in the prior art, the safety coefficient of the ice machine can be improved, and the manufacturing cost of products can be reduced.

Drawings

In the drawings, which are not necessarily drawn to scale, like numerals may describe similar components in different views. The accompanying drawings illustrate various embodiments by way of example in general and not by way of limitation, and together with the description and claims serve to explain the disclosed embodiments. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts. Such embodiments are illustrative and not intended to be exhaustive or exclusive of the present apparatus or method.

FIG. 1 is a front view of an ice discharge device for an ice maker according to an embodiment of the present utility model;

FIG. 2 is a top view of an ice discharge device for an ice maker according to an embodiment of the present utility model;

FIG. 3 is a schematic view showing a partial structure of an ice discharging device for an ice maker according to an embodiment of the present utility model;

FIG. 4 is a cross-sectional view taken along section A-A of FIG. 3;

Fig. 5 is a cross-sectional view of section B-B of fig. 3.

The reference numerals in the drawings denote components:

1-an ice making barrel; 2-a water tank; 21-overflow port; 3-discharging the ice box; 31-a water inlet; 32-an ice-blocking plate; 4-a first ice outlet surface; 41-a first incline; 42-a first plane; 5-a second ice outlet surface; 51-a second bevel; 6-overflow groove.

Detailed Description

The present utility model will be described in detail below with reference to the drawings and detailed description to enable those skilled in the art to better understand the technical scheme of the present utility model.

The embodiment of the utility model provides an ice outlet device for an ice maker. As shown in fig. 1 to 5, the ice maker includes an ice making tub 1. The ice discharging device comprises a water tank 2 and an ice discharging box 3. An overflow port 21 is formed at the upper part of the water tank 2, and the overflow port 21 is arranged above the ice outlet of the ice making barrel 1 and is communicated with the ice outlet. The ice outlet box 3 is arranged at the upper ice outlet of the ice making barrel 1, the ice outlet box 3 is provided with a first ice outlet surface 4 and a second ice outlet surface 5 which are connected, the first ice outlet surface 4 is arranged around the ice outlet, the second ice outlet surface 5 is used for discharging ice cubes out of the ice outlet box 3, at least part of the first ice outlet surface 4, which is close to the second ice outlet surface 5, is configured to be a first inclined surface 41, and the second ice outlet surface 5 is configured to be a second inclined surface 51 connected with the first inclined surface 41, so that ice cubes are discharged at least through the first inclined surface 41 and the second inclined surface 51. Among them, the first and second inclined surfaces 41 and 51 may be understood as being used to gradually move downward the ice cubes discharged from the ice outlet of the ice making bucket 1, i.e., the first and second inclined surfaces 41 and 51 are used to gradually guide the ice cubes downward.

The arrow direction shown in fig. 1 and 2 is the water flow direction. The water supply port communicated with the ice making barrel 1 is formed at the lower part of the water tank 2, the water tank 2 provides water for the ice making barrel 1 through the water supply port, ice cubes made by the ice making barrel 1 are discharged from the upper opening of the ice making barrel 1, and the upper opening of the ice making barrel 1 is the ice outlet of the ice making barrel 1. When the ice making barrel 1 fails or the ice making barrel 1 is finished, the ice making barrel 1 needs to be subjected to ice melting treatment, and at the moment, water in the water tank 2 can be discharged to an ice outlet of the ice making barrel 1 through an overflow port 21 at the upper part of the water tank 2, so that the water enters the ice making barrel 1 from the ice outlet of the ice making barrel 1, and the aim of melting ice is fulfilled.

Alternatively, the ice bank 3 has a notch communicating up and down with the ice outlet of the ice making barrel 1, around which the first ice discharging surface 4 is disposed, and ice cubes discharged from the notch can be discharged from the first slope 41 through the first ice discharging surface 4 toward the second slope 51 to be discharged through the second slope 51.

Alternatively, the angle between the first inclined surface 41 and the horizontal plane may be smaller than the angle between the second inclined surface 51 and the horizontal plane.

According to the utility model, at least part of the first ice outlet surface 4 close to the second ice outlet surface 5 is configured as the first inclined surface 41, and the second ice outlet surface 5 is configured as the second inclined surface 51 connected with the first inclined surface 41, so that ice cubes discharged from the ice outlet of the ice making barrel 1 can be directly discharged outwards through the guidance of the first inclined surface 41 and the second inclined surface 51, the ice cubes are not easy to be accumulated in the ice outlet box 3, but can be rapidly discharged, the aim of enabling the ice cubes to be discharged outwards more smoothly is fulfilled, the phenomenon of ice storage and ice blockage in the ice outlet box 3 is solved, the ice making machine is enabled to make ice efficiently, and the user experience is improved. In addition, the utility model does not need to adopt electrical structures such as a motor, and the like, compared with the scheme in the prior art, the safety coefficient of the ice machine can be improved, and the manufacturing cost of products can be reduced.

In some embodiments, as shown in fig. 3 and 5, a portion of the first ice-making surface 4 remote from the second ice-making surface 5 is configured as a first plane 42, the first plane 42 meets the first inclined surface 41, and an area of the first plane 42 is smaller than an area of the first inclined surface 41. In this way, the ice cubes discharged from the upper ice outlet of the ice making bucket 1 can be more discharged to the first slope 41, and guided by the first slope 41 to move in the direction of the second slope 51.

In some other embodiments, the first ice-discharging surface 4 may not have the first plane 42, that is, the first inclined surface 41 is configured as the whole of the first ice-discharging surface 4, so as to better guide the ice cubes discharged from the ice-discharging opening.

In some embodiments, an end of the first inclined surface 41 that meets the first flat surface 42 is configured as a high end of the first inclined surface 41, and a height of the high end of the first inclined surface 41 is lower than a height of the first flat surface 42. By providing a height difference at the junction of the first inclined surface 41 and the first plane 42, ice cubes can fall down from the first plane 42 more quickly, and ice discharging efficiency is further improved.

The above-mentioned height is understood to be the height of the ice maker at the position where the ice discharging device is in a normal operation state, i.e., the horizontal height of the first inclined surface 41 and the first flat surface 42 with respect to the horizontal plane in the normal operation state.

In some embodiments, as shown in fig. 3 and 4, an end of the second inclined surface 51, which is connected to the first inclined surface 41, is configured as a high end of the second inclined surface 51, an end of the first inclined surface 41, which is connected to the second inclined surface 51, is configured as a low end of the first inclined surface 41, and a height of the high end of the second inclined surface 51 is lower than a height of the low end of the first inclined surface 41. By providing the difference in height at the junction of the first inclined surface 41 and the second inclined surface 51, ice cubes can fall down more quickly from the first inclined surface 41 to the second inclined surface 51, and ice discharging efficiency is further improved.

Alternatively, the first inclined surface 41 and the second inclined surface 51 may be connected by a riser, where the height of the riser is the difference between the high end of the second inclined surface 51 and the low end of the first inclined surface 41.

In some embodiments, as shown in fig. 1 to 3, the water inlet 31 is provided on the ice-making box 3, and the overflow port 21 is communicated with the ice outlet of the ice-making barrel 1 through the water inlet 31, so that after the water in the water tank 2 exceeds the overflow port 21, the water can be discharged into the ice-making barrel 1 through the overflow port 21 and the water inlet 31, so that the ice is made into the ice-making barrel 1, and other ice-making structures are not required to be provided for the ice-making barrel 1, so that the structural design is more reasonable.

Alternatively, the water inlet 31 may be one or more, and the water inlets 31 may be reasonably distributed so that water can uniformly flow to the first ice surface 4 and flow into the ice making barrel 1.

In some embodiments, as shown in fig. 1 to 3, the water inlet 31 is provided at a side of the ice bank 3 remote from the second ice-discharging surface 5, so that water entering the ice bank 3 can uniformly spread over the first ice-discharging surface 4.

Alternatively, the opening of the water inlet 31 may be inclined downward to facilitate the water discharged from the water inlet 31 to be directly discharged onto the first ice surface 4 and into the ice making bucket 1.

In some embodiments, as shown in fig. 1, the height of the overflow port 21 is higher than the height of the water inlet port 31, and the ice discharging device further comprises an overflow groove 6 respectively communicated with the water inlet port 31 and the overflow port 21, and the bottom of the overflow groove 6 is obliquely arranged. Through the inclined arrangement of the bottom of the overflow groove 6, the flow speed of water can be increased, so that the impact force of the water discharged from the overflow groove 6 is larger, and the deicing speed is increased.

Alternatively, both ends of the overflow tank 6 may be welded to the overflow port 21 and the water inlet 31, respectively, or may be detachably connected, which is not particularly limited in the present application.

In some embodiments, the bottom angle of the cavity of the ice bank 3 is configured as a tilt angle. Therefore, the ice pushing process in the ice box 3 can be smoother, and quick ice discharging is facilitated.

Optionally, the above-mentioned inclination angle is specifically configured as an inclination rounded angle.

In some embodiments, as shown in fig. 2 and 3, the ice bank 3 further has an ice blocking plate 32 formed by extending upward edges of the first ice-discharging surface 4 and the second ice-discharging surface 5. The ice baffle 32 can limit the movement track of the ice cubes, and prevent the ice cubes from falling out of the ice bin 3.

The embodiment of the utility model also provides an ice maker, which comprises the ice discharging device for the ice maker. The ice maker adopting the ice discharging device is characterized in that at least part of the first ice discharging surface 4, which is close to the second ice discharging surface 5, is configured as the first inclined surface 41, and the second ice discharging surface 5 is configured as the second inclined surface 51 which is connected with the first inclined surface 41, so that ice cubes discharged from the ice discharging port of the ice making barrel 1 can be directly discharged outwards through the guidance of the first inclined surface 41 and the second inclined surface 51, the ice cubes are not easy to be accumulated in the ice discharging box 3, the ice cubes can be rapidly discharged, the aim of enabling the ice cubes to be discharged outwards more smoothly is fulfilled, the phenomenon of ice storage and ice blockage in the ice discharging box 3 is solved, the ice maker is enabled to make ice efficiently, and the user experience is improved. In addition, the utility model does not need to adopt electrical structures such as a motor, and the like, compared with the scheme in the prior art, the safety coefficient of the ice machine can be improved, and the manufacturing cost of products can be reduced.

The above embodiments are merely exemplary embodiments of the present utility model and are not intended to limit the present utility model. Various modifications and equivalent arrangements of this utility model will occur to those skilled in the art, and are intended to be within the spirit and scope of the utility model.

Claims (10)

1. An ice-out device for an ice-making machine comprising an ice-making bucket (1), characterized in that it comprises:

The upper part of the water tank (2) is provided with an overflow port (21), and the overflow port (21) is arranged above the ice outlet of the ice making barrel (1) and is communicated with the ice outlet;

The ice discharging box (3) is arranged at the upper ice discharging opening of the ice making barrel (1), the ice discharging box (3) is provided with a first ice discharging surface (4) and a second ice discharging surface (5) which are connected, the first ice discharging surface (4) is arranged around the ice discharging opening, the second ice discharging surface (5) is used for enabling ice cubes to be discharged out of the ice discharging box (3), at least part of the first ice discharging surface (4) close to the second ice discharging surface (5) is configured to be a first inclined surface (41), and the second ice discharging surface (5) is configured to be a second inclined surface (51) connected with the first inclined surface (41) so that the ice cubes can be discharged out at least through the first inclined surface (41) and the second inclined surface (51).

2. Ice-making device for an ice-making machine according to claim 1, characterized in that the portion of the first ice-making surface (4) remote from the second ice-making surface (5) is configured as a first plane (42), the first plane (42) being contiguous with the first inclined surface (41), and the area of the first plane (42) being smaller than the area of the first inclined surface (41).

3. Ice-discharging device for an ice-making machine according to claim 2, characterized in that the end of the first inclined surface (41) which meets the first plane (42) is configured as the high end of the first inclined surface (41), the high end of the first inclined surface (41) having a lower height than the first plane (42).

4. The ice discharging device for an ice maker according to claim 1, wherein an end of the second inclined surface (51) contacting the first inclined surface (41) is configured as a high end of the second inclined surface (51), an end of the first inclined surface (41) contacting the second inclined surface (51) is configured as a low end of the first inclined surface (41), and a height of the high end of the second inclined surface (51) is lower than a height of the low end of the first inclined surface (41).

5. Ice-making device according to claim 1, characterized in that the ice-making box (3) is provided with a water inlet (31), and the overflow port (21) communicates with the ice outlet of the ice-making barrel (1) through the water inlet (31).

6. Ice-outlet device for an ice-making machine according to claim 5, characterised in that the water inlet (31) is arranged on the ice-outlet housing (3) on the side remote from the second ice-outlet surface (5).

7. Ice-making device for an ice-making machine according to claim 5 or 6, characterized in that the overflow opening (21) is higher than the water inlet opening (31), and in that it further comprises an overflow channel (6) communicating with the water inlet opening (31) and the overflow opening (21), respectively, the channel bottom of the overflow channel (6) being arranged obliquely.

8. Ice-making device for an ice-making machine according to claim 1, characterized in that the bottom angle of the inner cavity of the ice-making housing (3) is configured as an oblique angle.

9. Ice-making device for an ice-making machine according to claim 1, characterised in that the ice-making housing (3) also has an ice-stop plate (32) formed by the upward extension of the edges of the first ice-making face (4) and the second ice-making face (5).

10. An ice maker, characterized by comprising an ice-out device for an ice maker as claimed in any one of claims 1 to 9.