CN211060456U - Spray type ice cube maker - Google Patents

Abstract

A spray type ice cube maker comprises a shell, a refrigerating and heating device, an ice making unit and an ice taking device; a first clapboard and a second clapboard are arranged in the shell, the refrigerating and heating device is arranged on the top surface of the first clapboard, the ice making unit is arranged on the bottom surface of the first clapboard, and the ice taking device is arranged below the second clapboard; the bottom surface of the first partition plate is convexly provided with at least two installation convex strips, the ice making unit comprises an ice making plate connected with the bottom surface of the installation convex strips, a spraying assembly and a driving device, the first side of the spraying assembly is rotatably arranged relative to the ice making plate, the driving device is used for driving the spraying assembly to rotate, the top surface of the ice making plate is provided with a cooling pipe, the bottom surface of the ice making plate is provided with a plurality of ice grid grooves, the side surface of the spraying assembly, facing the ice making plate, is provided with a plurality of spraying ports, and the spraying assembly is internally provided with a; and a receiving groove is arranged outside the second side of the spraying assembly and is communicated with the ice taking device. The volume is small, and the ice blocks are not connected into a whole.

Description

Spray type ice cube maker

Technical Field

The utility model relates to an ice machine technical field, especially a fountain cube ice machine.

Background

The existing ice making machine is generally a pouring type ice making machine, that is, a water injection head is located above an ice making plate with a plurality of grooves, the water injection head injects water towards the ice making plate, a refrigerating device is arranged at the bottom of the ice making plate and used for quickly freezing water in the grooves into ice, and then the ice making plate is turned over, so that the ice making plate is downward with a plurality of grooves, and ice cubes fall into a collecting tank below after being slightly melted. Because the system ice board need overturn 180 degrees, consequently need reserve sufficient space and supply the system ice board upset, the collecting vat need be located under the system ice board simultaneously, also need occupy great space, just can avoid the ice-cube to drop to the outside in collecting vat, so make the volume of complete machine great. In addition, water may enter the gaps between the adjacent grooves to form gap ice cubes connecting the gaps between the plurality of grooves, so that at least a plurality of the collected ice cubes may be integrated, which is inconvenient for a user to use.

SUMMERY OF THE UTILITY MODEL

In view of the above, the present invention provides a small-sized spray-type ice cube maker, which can make ice cubes without connecting a plurality of ice cubes together, so as to solve the above-mentioned problems.

A spray type ice cube maker comprises a shell, a refrigerating and heating device, an ice making unit and an ice taking device, wherein the refrigerating and heating device, the ice making unit and the ice taking device are positioned in the shell; a first clapboard is horizontally arranged at a position close to the top in the shell, a second clapboard is horizontally arranged at a position close to the bottom, a refrigerating and heating device is arranged on the top surface of the first clapboard, an ice making unit is arranged on the bottom surface of the first clapboard, and an ice taking device is arranged below the second clapboard; the bottom surface of the first partition plate is convexly provided with at least two installation convex strips, the ice making unit comprises an ice making plate connected with the bottom surface of the installation convex strips, a spraying assembly and a driving device, the first side of the spraying assembly is rotatably arranged relative to the ice making plate, the driving device is used for driving the spraying assembly to rotate, the top surface of the ice making plate is provided with a cooling pipe, the bottom surface of the ice making plate is provided with a plurality of ice grid grooves, the side surface of the spraying assembly, facing the ice making plate, is provided with a plurality of spraying ports, and the spraying assembly is internally provided with a; and a receiving groove is arranged outside the second side of the spraying assembly and is communicated with the ice taking device.

Further, one end of the cooling pipe is provided with a liquid inlet, the other end of the cooling pipe is provided with a liquid outlet, the liquid inlet is arranged close to the first side of the spraying assembly, and the liquid outlet is arranged close to the second side of the spraying assembly.

Further, the first end and the second end of each installation sand grip all protrude downwards and are provided with the connection sand grip, the first through hole has been seted up to the bottom of connection sand grip, the position that system ice board is close to the connection sand grip all protrudes and is provided with first connecting arm, the second through hole has been seted up to the end of first connecting arm, the pivot passes the first through hole of connection sand grip and the second through hole of first connecting arm.

Furthermore, the first end of each installation convex strip is provided with a rotary installation seat in a downward protruding mode, a third through hole is formed in the rotary installation seat, the two ends of the first side of the spraying assembly are respectively provided with a second connecting arm in a protruding mode, the tail end of each second connecting arm is provided with a fourth through hole, and a second rotating shaft penetrates through the third through hole of the rotary installation seat and the fourth through hole of each second connecting arm.

Furthermore, the driving device is a motor, a motor mounting seat is arranged at the position, away from the first side of the spraying assembly, of the bottom surface of the first partition plate or at the bottom surface of the second end of each mounting raised line in a downward protruding mode, the motor is arranged on the motor mounting seat, and an output shaft of the motor is connected with a connecting block; a connecting column is convexly arranged on the outer side of the spraying component close to the second side, the connecting block is connected with an extension arm, a limiting hole is formed in the first end of the extension arm, and the connecting block penetrates through the limiting hole; a spring is connected between the second end of the extension arm and the connecting column.

Furthermore, the second end of the extension arm is movably positioned at the outer side of the mounting convex strip, the side surface, far away from the second end, of the first end of the extension arm is provided with a trigger rod in a protruding mode, and the extension direction of the trigger rod is opposite to that of the extension arm; the installation sand grip is provided with first inductor and second inductor towards the lateral surface interval of extension arm.

Furthermore, a mounting groove is formed in the position, close to the connecting block, of the mounting convex strip, facing the outer side face of the extension arm, a first sensor is located in the mounting groove and facing one side of a first end of the mounting convex strip, a second sensor is located in the mounting groove and facing one side of a second end of the mounting convex strip, the first sensor and the second sensor are both micro switches, a triggering end of the first sensor is located on one side, facing the second end of the mounting convex strip, of the first sensor, and a triggering end of the first sensor is connected with a first triggering elastic sheet; the triggering end of the second sensor is positioned on one side of the second sensor, which faces the first end of the mounting convex strip, and is connected with a second triggering elastic sheet; the first triggering elastic sheet and the second triggering elastic sheet extend out of the mounting groove.

Further, the mounting groove has been seted up towards the lateral surface of extension arm and the position that is close to the connecting block to the installation sand grip, first inductor and second inductor are micro-gap switch, first inductor is located the mounting groove towards the one side of the first end of installation sand grip and the second end of the trigger end of first inductor towards the installation sand grip, the second inductor is located the mounting groove towards the one side of the second end of installation sand grip and the first end of the trigger end of second inductor towards the first end of installation sand grip, be provided with middle shell fragment between the trigger end of first inductor and the trigger end of second inductor, the first end of middle shell fragment is connected with the bottom of mounting groove, the second end stretches out in the mounting groove.

Further, an insulating layer is arranged on the inner surface of the ice taking device.

Furthermore, a quantitative ice outlet unit is arranged in the ice taking device and comprises a measuring cup, a baffle movably positioned above the measuring cup and a baffle driving unit used for driving the baffle to move.

Compared with the prior art, the spray type ice cube maker of the utility model comprises a shell, a refrigerating and heating device, an ice making unit and an ice taking device which are arranged in the shell; a first clapboard is horizontally arranged at a position close to the top in the shell, a second clapboard is horizontally arranged at a position close to the bottom, a refrigerating and heating device is arranged on the top surface of the first clapboard, an ice making unit is arranged on the bottom surface of the first clapboard, and an ice taking device is arranged below the second clapboard; the bottom surface of the first partition plate is convexly provided with at least two installation convex strips, the ice making unit comprises an ice making plate connected with the bottom surface of the installation convex strips, a spraying assembly and a driving device, the first side of the spraying assembly is rotatably arranged relative to the ice making plate, the driving device is used for driving the spraying assembly to rotate, the top surface of the ice making plate is provided with a cooling pipe, the bottom surface of the ice making plate is provided with a plurality of ice grid grooves, the side surface of the spraying assembly, facing the ice making plate, is provided with a plurality of spraying ports, and the spraying assembly is internally provided with a; and a receiving groove is arranged outside the second side of the spraying assembly and is communicated with the ice taking device. The volume is small, and the ice blocks are not connected into a whole.

Drawings

Embodiments of the present invention are described below with reference to the accompanying drawings, in which:

fig. 1 is a schematic perspective view of the spray-type ice cube maker according to the present invention.

Fig. 2 is a perspective view of the ice making plate of fig. 1 from a first perspective view.

Fig. 3 is a perspective view of the ice making plate of fig. 1 from a second perspective view.

Fig. 4 is an enlarged schematic view of a portion a in fig. 1.

Fig. 5 is a perspective view of fig. 4 with the motor, the motor mounting base, the connecting rod and the spring removed.

Fig. 6 is a perspective view of fig. 5 with the extension arm removed.

Fig. 7 is an enlarged schematic view of a portion B in fig. 6.

Fig. 8 is a schematic view of a first inductor and a second inductor in another embodiment.

Detailed Description

The following describes in further detail specific embodiments of the present invention based on the drawings. It should be understood that the description herein of embodiments of the invention is not intended to limit the scope of the invention.

Referring to fig. 1, the spray-type ice cube maker according to the present invention includes a housing 10, a cooling and heating device 20 located in the housing 10, an ice making unit 30, and an ice fetching device 40.

A first partition plate 11 is horizontally arranged at a position close to the top in the casing 10, a second partition plate 12 is horizontally arranged at a position close to the bottom, the refrigerating and heating device 20 is arranged on the top surface of the first partition plate 11, the ice making unit 30 is arranged on the bottom surface of the first partition plate 11, and the ice taking device 40 is arranged below the second partition plate 12.

The cooling and heating device 20 includes a compressor, a water tank, etc., which are well known in the art and will not be described herein. The cooling and heating device 20 can perform cooling and reverse operation to perform heating.

At least two mounting convex strips 33 are protrudingly arranged on the bottom surface of the first clapboard 11, and the ice making unit 30 is connected with the bottom surfaces of the two mounting convex strips 33, so that a certain distance is kept between the ice making unit and the first clapboard 11, and heat dissipation and air circulation are facilitated.

The ice making unit 30 includes an ice making plate 31 connected to the mounting ribs 33, a shower assembly 32 rotatably provided with respect to the ice making plate 31, and a driving device for driving the shower assembly 32 to rotate.

Referring to fig. 2 and 3, the ice making plate 31 includes a box 311 having an opening at the bottom, a cooling tube 312 bent and distributed on the top surface of the box 311, and a plurality of ice grid grooves 313 arranged on the bottom surface of the box 311.

The cooling tube 312 has an inlet port 3121 at one end and an outlet port 3122 at the other end.

Referring to fig. 4 and fig. 1, the first end and the second end of each mounting protrusion 33 are respectively provided with a connecting protrusion 331 protruding downward, the bottom of the connecting protrusion 331 is provided with a first through hole, and a first rotating shaft 314 passes through the first through holes of the two connecting protrusions 331. The first connecting arm is protruded from the positions of the first side and the second side of the ice making plate 31 close to the connecting protrusion strip 331, the second through hole is opened at the end of the first connecting arm, and the rotating shaft 314 passes through the second through hole of the first connecting arm, thereby connecting the ice making plate 31 to the mounting protrusion strip 33.

The first end of each mounting convex strip 33 protrudes downwards to form a rotating mounting base 332, a third through hole is formed in the rotating mounting base 332, the second connecting arm 324 protrudes from each of the two ends of the first side of the spraying assembly 32, a fourth through hole is formed in the tail end of the second connecting arm 324, and a second rotating shaft 315 penetrates through the third through hole of the rotating mounting base 332 and the fourth through hole of the second connecting arm 324, so that the spraying assembly 32 is rotatably connected with the mounting convex strip 33 and can rotate relative to the ice making plate 31.

In other embodiments, the first side of the shower assembly 32 may also be rotatably coupled to the first side of the ice making plate 31. If the two ends of the first side of the ice making plate 31 extend outwards respectively, a third rotating shaft is arranged, the two ends of the first side of the spraying assembly 32 are provided with a third connecting arm in a protruding mode respectively, a fifth through hole is formed in the third connecting arm, and the third rotating shaft penetrates through the fifth through hole of the third connecting arm.

The side of the spraying assembly 32 facing the ice making plate 31 is provided with a plurality of spraying ports 321, the spraying assembly 32 is internally provided with a spraying pump connected with the plurality of spraying ports 321 through a water pipe, the spraying assembly 32 is also connected with a water tank through a water pipe, and the spraying pump is used for spraying water in the water tank upwards into the ice making plate 31 of the ice making plate 31 through the spraying ports 321. The spray assembly 32 also has a water collection box in which the spray pump is located, and the spray pump can also spray water out of the water collection box through the spray port 321.

The driving device is a motor 36, a motor mounting seat 35 is arranged at a position, away from the first side of the spraying assembly 32, of the bottom surface of the first partition plate 11 in a downward protruding mode, the motor 36 is arranged on the motor mounting seat 35, and an output shaft of the motor 36 is connected with a connecting block 37.

The outer side of the second side of the spray assembly 32, which is away from the first side, is provided with a connecting column 322 in a protruding manner.

Referring to fig. 5, the connection block 37 is connected to an extension arm 371, a position-limiting hole is formed at a first end of the extension arm 371, and the connection block 37 passes through the position-limiting hole. Thus, the connecting block 37 can drive the extension arm 371 to rotate together when rotating.

A spring 39 is connected between the second end of the extension arm 371 away from the connecting block 37 and the connecting column 322.

The second end of the extension arm 371 is movably located outside the mounting protrusion 33. The side of the first end of the extension arm 371 away from the second end is provided with a trigger bar 372 in a protruding way. The trigger lever 372 extends in a direction opposite to the extension arm 371.

When the motor 36 drives the connecting block 37 to rotate, the extension arm 371 rotates around the center of the connecting block 37 in a vertical plane, so that the spray assembly 32 is driven by the spring 39 to swing up and down in the vertical plane around the second rotating shaft 315, and the second side of the spray assembly 32 moves close to or away from the ice making plate 31. The spring 39 provides a resilient connection between the second side of the spray assembly 32 and the extension arm 371.

An inlet port 3121 is disposed proximate a first side of the spray assembly 32 and an outlet port 3122 is disposed proximate a second side of the spray assembly 32. Thus, when the cooling and heating device 20 performs heating operation, the ice blocks close to the first side of the spray assembly 32 are melted and fall off, and the ice blocks close to the second side of the spray assembly 32 are melted and fall off. After the ice cubes close to the first side of the spraying assembly 32 are melted and fall off, the second side of the spraying assembly 32 can move for a certain distance towards the ice making plate 31, so that the distance between the second side of the spraying assembly 32 and the ice making plate 31 is reduced, and when the ice cubes close to the second side of the spraying assembly 32 are melted and fall off, the falling distance is reduced, so that the spraying assembly 32 is prevented from being injured by smashing.

The first sensor 333 and the second sensor 334 are disposed on the outer side surface of the mounting convex strip 33 facing the extension arm 371 at intervals.

Referring to fig. 6 and 7, the mounting protrusion 33 faces the outer side surface of the extension arm 371 and is disposed at a position close to the connection block 37 to form a mounting groove 3301, and the first sensor 333 and the second sensor 334 are disposed in the mounting groove 3301 at an interval.

In the present embodiment, the first sensor 333 is located on the side of the mounting groove 3301 facing the first end of the mounting protrusion 33, and the second sensor 334 is located on the side of the mounting groove 3301 facing the second end of the mounting protrusion 33.

To save space, the second inductor 334 is disposed above the first inductor 333.

The first sensor 333 and the second sensor 334 are microswitches. The triggering end of the first sensor 333 is located at a side of the first sensor 333 facing the second end of the mounting protrusion 33, and the triggering end of the first sensor 333 is connected with a first triggering elastic sheet 3331; the trigger end of the second sensor 334 is located at one side of the second sensor 334 facing the first end of the mounting protrusion 33, and the trigger end of the second sensor 334 is connected with a second trigger spring 3341. The first triggering elastic piece 3331 and the second triggering elastic piece 3341 both extend out of the mounting groove 3301.

When the extension arm 371 upwards rotates to the middle of the mounting groove 3301 along the clockwise direction in fig. 7, the extension arm 371 abuts against the second triggering elastic sheet 3341 of the second sensor 334, so that the second triggering elastic sheet 3341 triggers the second sensor 334, and the second side of the spraying assembly 32 is close to the second side of the ice making plate 31.

When the extension arm 371 rotates downwards towards the spraying component 32 along the counterclockwise direction in fig. 7, the trigger rod 372 rotates upwards to the middle of the mounting groove 3301 along the counterclockwise direction in fig. 7, the trigger rod 372 abuts against the first trigger elastic sheet 3331 of the first sensor 333, so that the first trigger elastic sheet 3331 triggers the first sensor 333, and at the moment, the second side of the spraying component 32 opens relative to the ice making plate 31.

Referring to fig. 8, in another embodiment, the first sensor 333 and the second sensor 334 are disposed opposite to each other, that is, the trigger end of the first sensor 333 and the trigger end of the second sensor 334 are disposed opposite to each other, a middle spring plate 335 is disposed between the trigger end of the first sensor 333 and the trigger end of the second sensor 334, a first end of the middle spring plate 335 is connected to the bottom of the mounting groove 3301, and a second end of the middle spring plate extends out and is located outside the mounting groove 3301.

When the extension arm 371 rotates upwards to the middle of the mounting groove 3301 along the clockwise direction in fig. 8, the extension arm 371 abuts against the middle spring piece 335, so that the middle spring piece 335 triggers the second sensor 334; when the extension arm 371 rotates downwards towards the spray assembly 32 along the counterclockwise direction in fig. 7, the trigger rod 372 rotates upwards to the middle of the mounting groove 3301 along the counterclockwise direction in fig. 7, and the trigger rod 372 abuts against the middle spring plate 335, so that the middle spring plate 335 triggers the first sensor 333.

The refrigerating and heating device 20, the spray pump, the first sensor 333 and the second sensor 334 are all connected with a controller, when the second sensor 334 senses the extension arm 371, the controller controls the spray pump to spray and controls the refrigerating and heating device 20 to refrigerate, so that ice cubes are made in the ice grid groove 313; when the first sensor 333 senses the extension arm 371, the controller controls the cooling and heating device 20 to perform a heating operation, so that the ice cubes in the ice grid groove 313 start to melt and are separated from the ice making plate 31, and the ice cubes separated from the ice making plate 31 fall onto the spraying unit 32 and slide along the surface of the spraying unit 32.

Referring to fig. 1, a receiving groove 34 is formed outside the second side of the shower assembly 32, the receiving groove 34 is in communication with the ice picker 40, and the receiving groove 34 receives ice cubes slid from the surface of the shower assembly 32 and transfers the ice cubes to the ice picker 40. The inner surface of the ice-taking device 40 is provided with an insulating layer for maintaining the temperature of the ice cubes, so that the ice cubes can be stored conveniently. The ice-fetching device 40 is also provided with a quantitative ice-outputting unit, such as a measuring cup, a baffle movably positioned above the measuring cup, and a baffle driving unit for driving the baffle to move. The ice taking device 40 is provided with an ice taking port 41 and a turnover cover which is rotatably arranged at the ice taking port 41, and the measuring cup is arranged at the ice taking port 41.

Compared with the prior art, the spray type ice cube maker of the utility model comprises a shell 10, a refrigerating and heating device 20, an ice making unit 30 and an ice taking device 40 which are arranged in the shell 10; a first clapboard 11 is horizontally arranged at a position close to the top in the shell 10, a second clapboard 12 is horizontally arranged at a position close to the bottom, the refrigerating and heating device 20 is arranged on the top surface of the first clapboard 11, the ice making unit 30 is arranged on the bottom surface of the first clapboard 11, and the ice taking device 40 is arranged below the second clapboard 12; the bottom surface of the first partition plate 11 is convexly provided with at least two mounting convex strips 33, the ice making unit 30 comprises an ice making plate 31 connected with the bottom surface of the mounting convex strips 33, a spraying assembly 32 with a first side rotatably arranged relative to the ice making plate 31 and a driving device for driving the spraying assembly 32 to rotate, the top surface of the ice making plate 31 is distributed with cooling pipes 312, the bottom surface is provided with a plurality of ice grid grooves 313, the side surface of the spraying assembly 32 facing the ice making plate 31 is provided with a plurality of spraying ports 321, and the spraying assembly 32 is internally provided with a spraying pump for spraying water from the spraying ports 321; the spray assembly 32 is provided with a receiving groove 34 on the outside of the second side, and the receiving groove 34 is in communication with an ice harvesting device 40. The volume is small, and the ice blocks are not connected into a whole.

The above description is only for the preferred embodiment of the present invention and should not be construed as limiting the scope of the present invention, and any modification, equivalent replacement or improvement within the spirit of the present invention is encompassed by the claims of the present invention.

Claims (10)

1. The utility model provides a fountain cube ice machine which characterized in that: comprises a shell, a refrigerating and heating device, an ice making unit and an ice taking device which are positioned in the shell; a first clapboard is horizontally arranged at a position close to the top in the shell, a second clapboard is horizontally arranged at a position close to the bottom, a refrigerating and heating device is arranged on the top surface of the first clapboard, an ice making unit is arranged on the bottom surface of the first clapboard, and an ice taking device is arranged below the second clapboard; the bottom surface of the first partition plate is convexly provided with at least two installation convex strips, the ice making unit comprises an ice making plate connected with the bottom surface of the installation convex strips, a spraying assembly and a driving device, the first side of the spraying assembly is rotatably arranged relative to the ice making plate, the driving device is used for driving the spraying assembly to rotate, the top surface of the ice making plate is provided with a cooling pipe, the bottom surface of the ice making plate is provided with a plurality of ice grid grooves, the side surface of the spraying assembly, facing the ice making plate, is provided with a plurality of spraying ports, and the spraying assembly is internally provided with a; and a receiving groove is arranged outside the second side of the spraying assembly and is communicated with the ice taking device.

2. The spray cube ice maker of claim 1, wherein: one end of the cooling pipe is provided with a liquid inlet, the other end of the cooling pipe is provided with a liquid outlet, the liquid inlet is arranged close to the first side of the spraying assembly, and the liquid outlet is arranged close to the second side of the spraying assembly.

3. The spray cube ice maker of claim 1, wherein: the first end and the second end of each installation sand grip all stand out downwards and are provided with the connection sand grip, and first through-hole has been seted up to the bottom of connection sand grip, and the position that the system ice board is close to the connection sand grip all stands out and is provided with first connecting arm, and the second through-hole has been seted up to the end of first connecting arm, and the pivot passes the first through-hole of connection sand grip and the second through-hole of first connecting arm.

4. The spray cube ice maker of claim 1, wherein: the first end of each installation convex strip is provided with a rotary installation seat in a downward protruding mode, a third through hole is formed in the rotary installation seat, the two ends of the first side of the spraying assembly are respectively provided with a second connecting arm in a protruding mode, the tail end of each second connecting arm is provided with a fourth through hole, and a second rotating shaft penetrates through the third through hole of the rotary installation seat and the fourth through hole of each second connecting arm.

5. The spray cube ice maker of claim 1, wherein: the driving device is a motor, a motor mounting seat is arranged at the position, away from the first side of the spraying assembly, of the bottom surface of the first partition plate or at the bottom surface of the second end of each mounting raised line in a downward protruding mode, the motor is arranged on the motor mounting seat, and an output shaft of the motor is connected with a connecting block; a connecting column is convexly arranged on the outer side of the spraying component close to the second side, the connecting block is connected with an extension arm, a limiting hole is formed in the first end of the extension arm, and the connecting block penetrates through the limiting hole; a spring is connected between the second end of the extension arm and the connecting column.

6. The spray cube ice maker of claim 5, wherein: the second end of the extension arm is movably positioned on the outer side of the mounting convex strip, the side surface, far away from the second end, of the first end of the extension arm is provided with a trigger rod in a protruding mode, and the extension direction of the trigger rod is opposite to that of the extension arm; the installation sand grip is provided with first inductor and second inductor towards the lateral surface interval of extension arm.

7. The spray cube ice maker of claim 6, wherein: the installation convex strip is provided with a mounting groove towards the outer side surface of the extension arm and close to the position of the connecting block, the first sensor is positioned in the mounting groove and faces one side of the first end of the installation convex strip, the second sensor is positioned in the mounting groove and faces one side of the second end of the installation convex strip, the first sensor and the second sensor are both microswitches, the triggering end of the first sensor is positioned at one side of the first sensor facing the second end of the installation convex strip, and the triggering end of the first sensor is connected with a first triggering elastic sheet; the triggering end of the second sensor is positioned on one side of the second sensor, which faces the first end of the mounting convex strip, and is connected with a second triggering elastic sheet; the first triggering elastic sheet and the second triggering elastic sheet extend out of the mounting groove.

8. The spray cube ice maker of claim 6, wherein: the mounting groove has been seted up towards the lateral surface of extension arm and the position that is close to the connecting block to the installation sand grip, first inductor and second inductor are micro-gap switch, first inductor is located the mounting groove towards the one side of the first end of installation sand grip and the second end of the trigger end of first inductor towards the installation sand grip, the second inductor is located the mounting groove towards the first end of one side of the second end of installation sand grip and the trigger end of second inductor towards the installation sand grip, be provided with middle shell fragment between the trigger end of first inductor and the trigger end of second inductor, the first end of middle shell fragment is connected with the bottom of mounting groove, the second end stretches out in the mounting groove.

9. The spray cube ice maker of claim 1, wherein: and the inner surface of the ice taking device is provided with a heat insulation layer.

10. The spray cube ice maker of claim 1, wherein: the ice taking device is internally provided with a quantitative ice outlet unit, and the quantitative ice outlet unit comprises a measuring cup, a baffle movably positioned above the measuring cup and a baffle driving unit used for driving the baffle to move.

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