CN210486199U - Quantitative ice discharging device, ice maker and cold drink machine - Google Patents

Abstract

The utility model relates to a ration goes out ice device, ice machine and cold drink machine. This ration goes out ice device goes out ice unit including processing storehouse, frame, stirring unit and ration, the processing storehouse install in the frame, the processing storehouse is equipped with pan feeding mouth and discharge gate, the stirring unit install in the processing storehouse, the stirring unit is used for right ice-cube in the processing storehouse stirs, ration goes out ice unit including install in the first power supply of frame with install in push member in the processing storehouse, first power supply drive push member work, push member will stir ice-cube propelling movement extremely quantitatively after the discharge gate. The quantitative ice discharging device is fixed according to the pushing amount of the pushing piece for pushing the ice blocks each time, and the pushing times of the pushing piece are controlled through the first power source, so that quantitative ice discharging is realized.

Description

Quantitative ice discharging device, ice maker and cold drink machine

Technical Field

The utility model relates to a cold drink machinery technical field especially relates to a ration goes out ice device, ice machine and cold drink machine.

Background

The ice maker is a refrigeration mechanical device which cools water through an evaporator by a refrigeration system refrigerant to generate ice, and the manufactured cubed ice and bullet ice can be used for manufacturing other cold drinks of households or milk tea shops and the like. For example, ice cubes are often added to milk tea. However, ice cubes produced by conventional ice making machines tend to cake and form lumps due to their long shelf life. When the ice cubes need to be added, the hardened ice cubes are not easy to ice out or unstable in ice out.

SUMMERY OF THE UTILITY MODEL

Therefore, the quantitative ice discharging device, the ice maker and the cold drink machine are needed to solve the problem of unstable ice discharging, the quantitative ice discharging device is fixed according to the pushing amount of the pushing piece for pushing ice cubes each time, the pushing times of the pushing piece are controlled through the first power source, and therefore quantitative ice discharging is achieved, and the quantity of discharged ice is stable.

The utility model provides a ration goes out ice device, goes out ice unit including processing storehouse, frame, stirring unit and ration, processing storehouse install in the frame, processing storehouse is equipped with pan feeding mouth and discharge gate, the stirring unit install in the processing storehouse, the stirring unit is used for right ice-cube in the processing storehouse stirs, ration goes out ice unit including install in the first power supply of frame with install in push member in the processing storehouse, first power supply drive push member work, push member will stir ice-cube propelling movement extremely quantitatively after the discharge gate.

In the quantitative ice discharging device, ice blocks enter the processing bin through the feeding port and are stirred by the stirring unit to form small ice blocks meeting the use requirement, and the first power source drives the pushing piece to work and outputs the stirred ice blocks from the discharging port. The pushing amount of the pushing piece for pushing the ice cubes each time is fixed, and the pushing times of the pushing piece can be controlled by the first power source, so that the pushing total amount of the ice cubes is controlled, and quantitative ice discharging is achieved.

In one embodiment, the pushing member is an auger, the auger is rotatably mounted in the processing bin, and the first power source drives the auger to rotate.

In one embodiment, the first power source is a stepping motor, and the stepping motor can control the rotation times of the spiral propeller according to the received pulse signals.

In one embodiment, the quantitative ice discharging unit further comprises an ice discharging funnel mounted on the frame, and the ice discharging funnel is located below the discharging port.

In one embodiment, the quantitative ice discharging unit further comprises a second power source and a movable plate, the movable plate is movably mounted at the discharge port, the second power source is connected with the movable plate, and the second power source drives the movable plate to open or close the discharge port.

In one embodiment, the stirring unit comprises a third power source and a stirring paddle rotatably mounted in the processing bin, and the third power source is used for driving the stirring paddle to rotate.

In one embodiment, the feeding port, the stirring paddle and the pushing member are distributed from top to bottom.

In one embodiment, the number of the stirring paddles is two, the two stirring paddles are positioned on two sides of the pushing member, and the rotating directions of the two stirring paddles are opposite.

An ice maker comprises the quantitative ice discharging device. The big ice blocks formed into the plate enter the processing bin through the feeding port, are processed into small ice blocks by the stirring unit and are conveyed to the discharging port by the pushing member. Thus, the ice maker can stably discharge ice in a fixed amount

A cold drink machine, which comprises the quantitative ice discharging device. The cold drink machine can quantitatively add ice blocks into drinks to meet the ice consumption requirements of the drinks. Wherein, the cold drink machine can be a milk tea machine, a coffee machine or a dessert machine. When the quantitative ice discharging device is applied to a dessert machine, ice blocks can be quantitatively conveyed to sugar water, poplar nectar and the like.

Drawings

Fig. 1 is a schematic structural view of a quantitative ice discharging device according to an embodiment of the present invention;

FIG. 2 is a top view of FIG. 1;

fig. 3 is a left side view of fig. 2.

100. The ice making machine comprises a processing bin, 101, a feeding port, 102, a discharging port, 103, a guide plate, 200, a rack, 300, a stirring unit, 310, a third power source, 320, a stirring paddle, 410, a first power source, 420, a pushing member, 430, an ice discharging hopper, 440, a second power source, 450 and a movable plate.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. In contrast, when an element is referred to as being "directly on" another element, there are no intervening elements present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only. In the present invention, the terms "first", "second" and "third" do not denote any particular quantity or order, but are merely used to distinguish names.

Example one

Referring to fig. 1 to 3, a quantitative ice discharging apparatus includes a processing bin 100, a frame 200, a stirring unit 300, and a quantitative ice discharging unit. The processing bin 100 is mounted on the rack 200, the processing bin 100 is provided with a feeding port 101 and a discharging port 102, the stirring unit 300 is mounted in the processing bin 100, the stirring unit 300 is used for stirring ice cubes in the processing bin 100, the quantitative ice discharging unit comprises a first power source 410 mounted on the rack 200 and a pushing member 420 mounted in the processing bin 100, the first power source 410 drives the pushing member 420 to work, and the pushing member 420 quantitatively pushes the stirred ice cubes to the discharging port 102.

In the quantitative ice discharging device, ice cubes enter the processing bin 100 through the feeding port 101 and are stirred by the stirring unit 300 to form small ice cubes which are satisfactory to use, and the first power source 410 drives the pushing member 420 to work to discharge the stirred ice cubes from the discharging port 102. The pushing amount of the pushing member 420 for pushing the ice cubes each time is fixed, and the first power source 410 can control the pushing times of the pushing member 420, so that the total pushing amount of the ice cubes is controlled, quantitative ice discharging is realized, and the output amount of the ice cubes is stable.

Alternatively, the first power source 410 may drive the pusher 420 to rotate, flip, or translate. The pusher 420 may be an auger, a bucket with a fixed capacity, or a scraping cartridge with a fixed capacity. For example, the first power source 410 drives the bucket to tumble such that the bucket fixedly scoops a quantity of ice from the interior of the processing bin 100 to the discharge port 102 at a time. For another example, the first power source 410 drives the scraping box to linearly reciprocate, so that the scraping box fixedly takes a certain amount of ice at a time and translates to the discharging hole 102.

Specifically, referring to fig. 1 to 3, the pushing member 420 is an auger, the auger is rotatably mounted in the processing bin 100, and the first power source 410 drives the auger to rotate. The pushing amount is fixed every time the screw propeller rotates for one circle, so that the ice blocks can be quantitatively output.

Further, the first power source 410 is a stepper motor. The stepping motor can control the rotation times of the spiral propeller according to the received pulse signals. So, through pulse control can accurate control screw propeller's rotation number of times, and then the output of control ice-cube.

Wherein, the first power source 410 can also be selected as a cylinder, a cylinder or other types of motors. The first power source 410 may be connected to the pusher 420 by a chain drive, a link drive, or a gear drive. Fig. 1-3 show the first power source 410 connected to the pusher 420 by a chain drive.

Specifically, referring to fig. 1, the quantitative ice discharging unit further includes an ice discharging hopper 430 installed on the frame 200. The ice outlet funnel 430 is located below the discharge hole 102, and a container such as a cup can be placed at the bottom of the ice outlet funnel 430. The ice hopper 430 serves as a guide for guiding the ice cubes discharged from the discharge hole 102 into a container located therebelow.

Specifically, referring to fig. 1, the quantitative ice discharging unit further includes a second power source 440 and a movable plate 450. The movable plate 450 is movably installed at the discharge port 102, the second power source 440 is connected to the movable plate 450, and the second power source 440 drives the movable plate 450 to open or close the discharge port 102. The second power source 440 may be a pen-shaped cylinder, which is mounted on the frame 200 and connected to the movable plate 450 to drive the movable plate 450 to turn over, thereby closing or opening the discharge hole 102. When ice needs to be discharged, the second power source 440 drives the movable plate 450 to move, the discharge hole 102 is opened, and the ice blocks fall into the ice discharge hopper 430, so that quantitative ice discharge is realized.

In one embodiment, referring to fig. 1-3, the blending unit 300 includes a third power source 310 and a blending paddle 320 rotatably mounted in the processing bin 100. The third power source 310 is used for driving the stirring paddle 320 to rotate, so that the stirring paddle 320 stirs the ice cubes during the rotation process, and the ice cubes are processed into small ice cubes meeting the use requirement.

Wherein, the feeding port 101, the stirring paddle 320 and the pushing member 420 are distributed from top to bottom. Therefore, the ice cubes enter the processing bin 100 from the feeding port 101, are automatically stirred by the stirring paddle 320 under the action of gravity, fall onto the pushing member 420, and are pushed to the discharging port 102.

Specifically, referring to fig. 1, the processing bin 100 is provided with guide plates along the circumferential sides of the feeding port 101, the guide plates being inclined toward the middle of the processing bin 100 so that the ice cubes can be collectively dropped into the middle of the processing bin 100.

Specifically, referring to fig. 2 and 3, the stirring paddles 320 are two, two stirring paddles 320 are located at both sides of the pushing member 420, and the rotation directions of the two stirring paddles 320 are opposite, so that the two stirring paddles 320 do not squeeze the pushing member 420 during the process of stirring ice cubes.

Further, the number of the third power sources 310 corresponds to the number of the paddles 320. The third power source 310 controls the rotation of the respective stirring paddles 320, without interfering with each other. The processing bin 100 is mounted above the frame 200. The first power source 410 and the third power source 310 are arranged in the rack 200 side by side, so that the layout is reasonable, and the space is saved.

The two paddles 320 are located above the pushing member 420 and located at two sides of the pushing member 420. The paddles 320 and the pusher 420 are staggered to avoid interference. The two paddles 320 have a space therebetween, the space forming a first stirring area, and the pusher 420 is located below the first stirring area. During the stirring process of the stirring unit 300, the main processing area of the two stirring paddles 320 is the first stirring area, so that the processed small ice cubes automatically fall onto the pushing member 420, and the subsequent ice cubes are conveniently output. A second stirring zone is formed between one of the paddles 320 and the adjacent sidewall of the processing chamber 100, and a third stirring zone is formed between the other paddle 320 and the adjacent sidewall of the processing chamber 100. The ice cubes processed in the second stirring area and the third stirring area fall to two sides of the processing bin 100, and are also conveyed to the middle of the processing bin 100 under the rotation of the stack and the stirring paddle 320, and then are pushed to the discharging port 102 by the pushing member 420.

The paddle 320 includes a shaft and a protruding rod mounted on the shaft. The two ends of the rotating shaft are rotatably mounted on the processing bin 100 through bearings. The protruding pole is a plurality of, and a plurality of protruding poles set up on the pivot at interval.

Example two

The ice blocks stored in the conventional ice maker for a long time may be formed into blocks, and the output or the amount of the discharged ice is not easily controlled.

The utility model also provides an ice maker's technical scheme. The ice maker comprises the quantitative ice discharging device. An ice maker is a refrigeration machine that produces ice by cooling water through an evaporator with a refrigerant in a refrigeration system. The big ice cubes formed into the plate enter the processing bin 100 through the feeding port 101, and are processed into small ice cubes by the stirring unit 300, and then are conveyed to the discharging port 102 by the pushing member 420. Thus, the ice maker can stably discharge ice in a fixed amount.

EXAMPLE III

The utility model also provides a technical proposal of the cold drink machine. The cold drink machine comprises the quantitative ice discharging device. Therefore, the cold drink machine can quantitatively add ice blocks into drinks to meet the ice consumption requirement of the drinks. Wherein, the cold drink machine can be a milk tea machine, a coffee machine or a dessert machine. When the quantitative ice discharging device is applied to a dessert machine, ice blocks can be quantitatively conveyed to sugar water, poplar nectar and the like.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. A quantitative ice discharging device is characterized by comprising: processing storehouse, frame, stirring unit and ration go out the ice unit, the processing storehouse install in the frame, the processing storehouse is equipped with pan feeding mouth and discharge gate, the stirring unit install in the processing storehouse, the stirring unit is used for right the ice-cube in the processing storehouse stirs, the ration goes out the ice unit including install in the first power supply of frame with install in push member in the processing storehouse, first power supply drive push member work, push member will stir the ice-cube after the propelling movement to quantificationally the discharge gate.

2. The quantitative ice discharging device according to claim 1, wherein the pushing member is an auger rotatably mounted in the processing bin, and the first power source drives the auger to rotate.

3. The quantitative ice discharging device according to claim 2, wherein the first power source is a stepping motor, and the stepping motor controls the number of rotations of the screw propeller according to the received pulse signal.

4. The quantitative ice discharging device according to claim 1, wherein the quantitative ice discharging unit further comprises an ice discharging funnel mounted on the frame, and the ice discharging funnel is located below the discharging hole.

5. The quantitative ice discharging device according to claim 4, wherein the quantitative ice discharging unit further comprises a second power source and a movable plate, the movable plate is movably mounted at the discharge port, the second power source is connected with the movable plate, and the second power source drives the movable plate to open or close the discharge port.

6. The quantitative ice discharging device according to any one of claims 1 to 5, wherein the stirring unit comprises a third power source and a stirring paddle rotatably mounted in the processing bin, and the third power source is used for driving the stirring paddle to rotate.

7. The device of claim 6, wherein the inlet, the paddle, and the pusher are distributed from top to bottom.

8. The quantitative ice discharging device of claim 6, wherein the number of the stirring paddles is two, two stirring paddles are located at two sides of the pushing member, and the rotation directions of the two stirring paddles are opposite.

9. An ice maker, wherein said ice maker comprises a metered ice dispensing apparatus as claimed in any one of claims 1 to 8.

10. A cooler characterized in that it comprises a metered ice dispensing device as claimed in any one of claims 1 to 8.

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