Ice discharging device and ice maker
By introducing a dustproof and heat-insulating rotating door and a spiral rod structure into the ice maker, the problems of complex ice dispensing structure and ice jamming in existing ice makers have been solved, achieving efficient and clean ice transportation and storage.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GUANGDONG XINBAO ELECTRICAL APPLIANCES HLDG CO LTD
- Filing Date
- 2025-07-18
- Publication Date
- 2026-07-07
AI Technical Summary
Existing ice makers have complex ice dispensing structures, high costs, and are prone to ice jams or incomplete shut-off, causing the ice to melt and resulting in a poor user experience.
The dustproof and heat-insulating rotating door controls the opening and closing of the ice transport channel through a drive component. Combined with a spiral rod and ice guide plate, it improves ice dispensing efficiency and maintains the temperature and cleanliness of the ice through an insulation layer.
It prevents ice from getting stuck, improves ice dispensing efficiency, maintains the refrigeration effect of ice, avoids melting and contamination, and enhances the user experience.
Smart Images

Figure CN224470514U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of ice maker technology, and specifically to an ice dispensing device and an ice maker. Background Technology
[0002] Currently, there are various square ice makers on the market. When ice is needed, you can only pull out the ice box and use a spatula to scoop the ice into a juice cup or coffee cup. This results in a poor user experience. Moreover, frequently opening the ice box allows external contaminants to enter, and the spatula will also accumulate contaminants over time, inevitably contaminating the ice during use.
[0003] Utility model patent with publication number CN222783782U discloses an ice dispensing structure and an ice maker; it includes an ice storage chamber, an ice dispensing chamber, and an insulated cover. The ice dispensing chamber is connected to the ice storage chamber to form a first connecting channel. The insulated cover is rotatably connected to the ice storage chamber or the ice dispensing chamber to cover or open the first connecting channel. A dust cover is rotatably connected to the ice dispensing chamber. The insulated cover has a first connecting part extending into the ice dispensing chamber, and the dust cover has a second connecting part extending into the ice dispensing chamber. When the insulated cover is rotated open, the top wall of the first connecting part abuts against the bottom wall of the second connecting part, so that the dust cover rotates and opens with the insulated cover. The existing insulation cover has a complex structure, high cost, and inconvenient assembly. The insulation cover is opened by pushing it with ice, which then drives the dust cover to rotate and open. The insulation cover and dust cover will move under their own weight, which can easily cause ice to get stuck and result in poor ice dispensing. Furthermore, the insulation cover and dust cover are also closed by their own weight, which can easily lead to incomplete closure, causing the ice in the ice dispensing chamber to melt easily.
[0004] Therefore, there is still room for improvement and development in existing technologies. Utility Model Content
[0005] To address the problems of existing technologies, this utility model provides an ice dispensing device and an ice maker. When ice needs to be dispensed, the drive assembly drives the dustproof and heat-insulating rotating door to open the ice transport channel. Ice blocks in the ice storage chamber can enter the ice dispensing chamber through the ice transport channel and then be dispensed from the ice dispensing chamber. Under the action of the drive assembly driving the dustproof and heat-insulating rotating door, the dustproof and heat-insulating rotating door will not move on its own, thus preventing ice jamming and resulting in better ice dispensing effect. When making ice, the drive assembly drives the dustproof and heat-insulating rotating door to close the ice transport channel. Under the action of the drive assembly driving the dustproof and heat-insulating rotating door, the ice transport channel can be fully closed, so that the ice blocks stored in the ice storage chamber will not melt.
[0006] To achieve the above objectives, the technical solution applied in this utility model is as follows:
[0007] An ice dispensing device includes an ice-making box, which has an ice storage chamber and an ice receiving chamber, the ice receiving chamber being connected to the ice storage chamber; and an ice dispensing box, which has an ice dispensing chamber; the ice-making box and the ice dispensing box are fixedly connected to form an ice block transport channel, the ice block transport channel being connected to the ice storage chamber and the ice dispensing chamber; a dustproof and heat-insulating rotating door is movably installed in the ice block transport channel, the dustproof and heat-insulating rotating door being driven to rotate by a drive component to open or close the ice block transport channel. This configuration includes an ice storage chamber for storing ice, an ice dispensing chamber for dispensing ice, and a dustproof and heat-insulating rotating door for opening or closing the ice transport channel. When ice needs to be dispensed, the drive assembly activates the dustproof and heat-insulating rotating door to open the ice transport channel. Ice from the storage chamber can then enter the dispensing chamber and exit. The rotating door remains stationary, preventing ice from getting stuck and ensuring better dispensing efficiency. During ice making, the drive assembly activates the dustproof and heat-insulating rotating door to close the ice transport channel, effectively preventing the ice stored in the storage chamber from melting.
[0008] The dustproof and heat-insulating rotating door has a straight plate structure, which is simple, low in cost, and easy to assemble. Compared with the existing technology, it eliminates the structure and cost of the dust cover, as well as the problem of ice getting stuck in the dust cover.
[0009] According to the above scheme, the ice-making box is provided with a first ice outlet, and the ice-discharging box is provided with an ice inlet, with the first ice outlet and the ice inlet fixedly connected; the dustproof and heat-insulating rotating door is hinged to the inner wall of the ice-discharging box, and the dustproof and heat-insulating rotating door is driven to rotate by a drive assembly to open or close the ice inlet. In this configuration, the dustproof and heat-insulating rotating door is hinged to the inner wall of the ice-discharging box via a pivot. When the ice inlet is open, the ice transport channel is in a connected state; when the ice inlet is closed, the ice transport channel is in a disconnected state.
[0010] Of course, the dustproof and heat-insulating rotating door can also be hinged to the inner wall of the ice box. The dustproof and heat-insulating rotating door is driven to rotate by the drive component to open or close the first ice outlet, achieving the same effect.
[0011] According to the above scheme, the driving component includes a second motor, a first connecting rod, and a second connecting rod. The second motor is fixed to the ice dispensing box. The first end of the first connecting rod is connected to the output end of the second motor, the second end of the first connecting rod is connected to the first end of the second connecting rod, and the second end of the second connecting rod is connected to the dustproof and heat-insulating rotating door. With this configuration, when the second motor is working, it drives the first connecting rod to move, which in turn drives the second connecting rod to move, which in turn drives the dustproof and heat-insulating rotating door to move, thereby opening or closing the first ice outlet.
[0012] The second motor is fixed to the outer wall of the ice dispenser; the first and second connecting rods are parallelogram connecting rods.
[0013] According to the above scheme, when the dustproof and heat-insulating rotating door closes the ice inlet, the outer edge of the door is tightly fitted against the inner wall of the ice inlet; an insulation layer is fixed on the dustproof and heat-insulating rotating door. This design ensures that when the dustproof and heat-insulating rotating door closes the ice inlet, the outer edge of the door is tightly fitted against the inner wall of the ice inlet, keeping the ice storage chamber sealed and preventing the ice stored inside from melting. Simultaneously, the dustproof and heat-insulating rotating door also serves as a dustproof barrier, preventing external dust from entering the ice storage chamber and contaminating the ice.
[0014] The use of an insulation layer fixed to the dustproof and heat-insulating rotating door improves the heat preservation effect of the ice in the ice storage cavity; the insulation layer is preferably foam.
[0015] According to the above scheme, the ice transport channel is equipped with an ice transport assembly, which includes a first motor and a screw rod. The first motor is fixed on the ice outlet box, the first end of the screw rod is connected to the output end of the first motor, and the second end of the screw rod passes through the ice inlet and the first ice outlet and is located in the ice storage cavity. The first motor is used to drive the screw rod to rotate, so as to transport the ice blocks in the ice storage cavity to the ice outlet cavity.
[0016] The bottom of the ice storage chamber is lower than the bottom of the ice outlet chamber. The spiral rod is inclined, with the higher end of the spiral rod connected to the output end of the first motor and the lower end rotatably located inside the ice storage chamber. The spiral rod includes a square spiral component, which allows for a larger contact surface with the ice block, thereby improving the ice outlet efficiency. The dustproof and heat-insulating rotating door is provided with a through hole to facilitate the passage of the spiral rod.
[0017] According to the above scheme, the ice dispensing box is provided with a second ice outlet, the ice inlet and the second ice outlet are connected, and an ice guide plate is provided between the ice inlet and the second ice outlet; the ice guide plate is inclined, with the higher end of the ice guide plate connected to the ice inlet and the lower end of the ice guide plate connected to the second ice outlet. With this arrangement, when ice enters the ice dispensing cavity through the ice inlet, the ice guide plate guides the ice to the second ice outlet, resulting in better ice dispensing and preventing ice from remaining in the ice dispensing cavity.
[0018] According to the above scheme, the ice receiving cavity is equipped with a third motor, an ice-making shell, and an ice-making mold. The ice-making mold is fixed to the inner wall of the ice receiving cavity, and an ice-pushing plate is provided on the outer wall of the ice-making shell. The third motor is used to drive the ice-making shell to rotate relative to the ice-making mold. When the third motor drives the ice-making shell to be above the ice-making mold, the ice blocks made by the ice-making mold can be detached into the ice storage cavity. When the third motor drives the ice-making shell to be below the ice-making mold, it is used to cooperate with the ice-making mold to make ice and to push the ice blocks in the ice receiving cavity into the ice storage cavity. In this way, by driving the ice-making shell to different positions with the third motor, different functions can be achieved.
[0019] Specifically, during ice making, the third motor drives the ice-making housing to be positioned below the ice-making mold. At this time, the ice-making housing is used to hold clean water and work with the ice-making mold to make ice. After ice making is completed, the third motor drives the ice-making housing to be positioned above the ice-making mold. At this time, the ice blocks made on the ice-making mold can be removed into the ice-receiving cavity. After the ice blocks are removed, the third motor drives the ice-making housing to be positioned below the ice-making mold again for making ice again. During the process of the third motor driving the ice-making housing to be positioned below the ice-making mold again, the ice-pushing plate on the outer wall of the ice-making housing can push the ice blocks in the ice-receiving cavity into the ice-storage cavity.
[0020] The ice receiving cavity is located on one side of the ice storage cavity.
[0021] According to the above scheme, the ice storage cavity is equipped with a high-level sensing component, which includes black infrared lamps and white infrared lamps located on both sides of the ice storage cavity, with the black and white infrared lamps positioned correspondingly. This configuration ensures that when the signal between the black and white infrared lamps is blocked by ice, it indicates that the ice level in the ice storage cavity has reached a high point, and ice production stops.
[0022] According to the above scheme, a sealing element is fixed at the connection between the ice-making box and the ice-dispensing box; an ice-making box cover is fixed on the ice-making box, and an ice-dispensing box cover is fixed on the ice-dispensing box.
[0023] The sealing element prevents water leakage at the connection between the ice maker 1 and the ice dispenser; when the dustproof and heat-insulating rotating door closes the ice transport channel, a relatively sealed heat-insulating space is formed under the enclosure of the dustproof and heat-insulating rotating door, the ice maker, and the top cover of the ice maker, allowing the ice to be stored in the ice maker for a longer time; the second motor is fixedly installed on the outer wall of the top cover of the ice dispenser.
[0024] The ice maker described in this utility model includes the ice dispensing device described above.
[0025] The beneficial effects of this utility model are:
[0026] This invention is designed so that when ice needs to be dispensed, the drive assembly drives the dustproof and heat-insulating rotating door to open the ice transport channel. Ice blocks in the ice storage chamber can enter the ice dispensing chamber through the ice transport channel and then be dispensed from the ice dispensing chamber. Under the action of the drive assembly driving the dustproof and heat-insulating rotating door, the dustproof and heat-insulating rotating door will not move on its own, so there will be no ice jamming, resulting in a better ice dispensing effect. When making ice, the drive assembly drives the dustproof and heat-insulating rotating door to close the ice transport channel. Under the action of the drive assembly driving the dustproof and heat-insulating rotating door, the ice transport channel can be fully closed, so that the ice blocks stored in the ice storage chamber will not melt. Attached Figure Description
[0027] Figure 1 This is an exploded view of the ice-discharging device of this utility model;
[0028] Figure 2 This is a top view of the ice-discharging device of this utility model.
[0029] Figure 3 yes Figure 2 Sectional view at position AA;
[0030] Figure 4 yes Figure 2 Sectional view of the BB position;
[0031] Figure 5 This is a diagram showing the state of the dustproof and heat-insulating rotating door with the ice inlet open.
[0032] Figure 6 yes Figure 5 Sectional view at the CC position;
[0033] Figure 7 This is a diagram of the ice storage cavity of this utility model in its fully loaded state;
[0034] Figure 8 This is a diagram showing the state of the dustproof and heat-insulating rotating door with the ice inlet open when the ice storage cavity of this utility model is fully loaded;
[0035] Figure 9 This is a diagram showing the state of an ice block being lifted by a spiral rod according to this utility model.
[0036] Figure 10 This is a diagram showing the ice discharge state of the ice discharge cavity of this utility model;
[0037] Figure 11 yes Figure 2 Sectional view of the DD position in the middle;
[0038] Figure 12 This is a diagram showing the ice-removing state of the ice-making mold of this utility model;
[0039] Figure 13 This is a diagram showing the ice-dispensing state of the ice-making shell of this utility model;
[0040] In the picture:
[0041] 1. Ice container; 2. Ice container lid; 3. First motor; 4. Screw rod; 6. Dustproof and heat-insulating rotating door; 7. Insulation layer; 8. Second motor; 91. First connecting rod; 92. Second connecting rod; 10. Third motor; 11. Ice container shell; 111. Ice-pulling plate; 12. Ice mold; 130. First ice outlet; 131. Ice storage cavity; 132. Ice receiving cavity; 14. Sealing element; 15. Ice container outlet; 150. Ice inlet; 151. Ice outlet cavity; 152. Ice guide plate; 153. Second ice outlet; 16. Ice container lid; 17. Black infrared lamp; 18. White infrared lamp. Detailed Implementation
[0042] The technical solution of this utility model will be described below with reference to the accompanying drawings and embodiments.
[0043] like Figures 1 to 13 As shown, the ice dispensing device of this utility model includes an ice-making box 1, which has an ice storage cavity 131 and an ice receiving cavity 132, and the ice receiving cavity 132 is connected to the ice storage cavity 131; an ice dispensing box 15, which has an ice dispensing cavity 151; the ice-making box 1 and the ice dispensing box 15 are fixedly connected to form an ice block transport channel, which connects the ice storage cavity 131 and the ice dispensing cavity 151; a dustproof and heat-insulating rotating door 6 is movably provided in the ice block transport channel, and the dustproof and heat-insulating rotating door 6 is driven to rotate by a drive component to open or close the ice block transport channel. In this configuration, the ice storage chamber 131 is used to store ice, the ice outlet chamber 151 is used to dispense ice, and the dustproof and heat-insulating rotating door 6 is used to open or close the ice transport channel. When ice needs to be dispensed, the dustproof and heat-insulating rotating door 6 is driven by the drive component to open the ice transport channel. The ice in the ice storage chamber 131 can enter the ice outlet chamber 151 through the ice transport channel and then be dispensed from the ice outlet chamber 151. Under the action of the drive component driving the dustproof and heat-insulating rotating door 6, the dustproof and heat-insulating rotating door 6 will not move on its own, so there will be no ice jamming, resulting in a better ice dispensing effect. When making ice, the drive component drives the dustproof and heat-insulating rotating door 6 to close the ice transport channel. Under the action of the drive component driving the dustproof and heat-insulating rotating door 6, the ice transport channel can be fully closed, so that the ice stored in the ice storage chamber 131 will not melt.
[0044] The dustproof and heat-insulating rotating door 6 has a straight plate structure, which is simple, low in cost, and easy to assemble. Compared with the existing technology, it eliminates the structure and cost of the dust cover, as well as the problem of ice getting stuck in the dust cover.
[0045] Furthermore, the ice-making box 1 is provided with a first ice outlet 130, and the ice-discharging box 15 is provided with an ice inlet 150. The first ice outlet 130 and the ice inlet 150 are fixedly connected. The dustproof and heat-insulating rotating door 6 is hinged to the inner wall of the ice-discharging box 15. The dustproof and heat-insulating rotating door 6 is driven to rotate by a drive assembly to open or close the ice inlet 150. In this configuration, the dustproof and heat-insulating rotating door 6 is hinged to the inner wall of the ice-discharging box 15 via a pivot. When the ice inlet 150 is open, the ice transport channel is in a connected state; when the ice inlet 150 is closed, the ice transport channel is in a disconnected state.
[0046] Of course, the dustproof and heat-insulating rotating door 6 can also be hinged to the inner wall of the ice box 1. The dustproof and heat-insulating rotating door 6 is driven to rotate by the drive component to open or close the first ice outlet 130, achieving the same effect.
[0047] Furthermore, the drive assembly includes a second motor 8, a first connecting rod 91, and a second connecting rod 92. The second motor 8 is fixed to the ice dispensing box 15. The first end of the first connecting rod 91 is connected to the output end of the second motor 8, the second end of the first connecting rod 91 is connected to the first end of the second connecting rod 92, and the second end of the second connecting rod 92 is connected to the dustproof and heat-insulating rotating door 6. With this configuration, when the second motor 8 is working, it drives the first connecting rod 91 to move, the first connecting rod 91 drives the second connecting rod 92 to move, and the second connecting rod 92 drives the dustproof and heat-insulating rotating door 6 to move, thereby opening or closing the first ice dispensing port 130.
[0048] The second motor 8 is fixed to the outer wall of the ice dispensing box 15; wherein, as shown in the figure Figure 1 As shown, the first link 91 and the second link 92 are parallelogram links.
[0049] Furthermore, when the dustproof and heat-insulating rotating door 6 closes the ice inlet 150, the outer edge of the dustproof and heat-insulating rotating door 6 is tightly fitted with the inner wall of the ice inlet 150; an insulation layer 7 is fixed on the dustproof and heat-insulating rotating door 6. This configuration ensures that when the dustproof and heat-insulating rotating door 6 closes the ice inlet 150, the outer edge of the dustproof and heat-insulating rotating door 6 is tightly fitted with the inner wall of the ice inlet 150, keeping the ice storage cavity 131 in a sealed state, preventing the ice stored in the ice storage cavity 131 from melting; simultaneously, the dustproof and heat-insulating rotating door 6 also serves a dustproof function, preventing external dust from entering the ice storage cavity 131 and contaminating the ice.
[0050] The insulation layer 7 is fixed on the dustproof and heat-insulating rotating door 6, which can better keep the ice in the ice storage cavity 131 warm; the insulation layer 7 is preferably foam.
[0051] Furthermore, the ice transport channel is equipped with an ice transport assembly, which includes a first motor 3 and a screw rod 4. The first motor 3 is fixed to the ice outlet box 15. The first end of the screw rod 4 is connected to the output end of the first motor 3, and the second end of the screw rod 4 passes through the ice inlet 150 and the first ice outlet 130 and is located in the ice storage cavity 131. The first motor 3 is used to drive the screw rod 4 to rotate, so as to transport the ice in the ice storage cavity 131 to the ice outlet cavity 151.
[0052] The bottom of the ice storage chamber 131 is lower than the bottom of the ice outlet chamber 151. The spiral rod 4 is inclined, with the higher end of the spiral rod 4 connected to the output end of the first motor 3 and the lower end rotatably located inside the ice storage chamber 131. The spiral rod 4 includes a square spiral component, which can have a larger contact surface with the ice block, thereby enabling higher ice dispensing efficiency. The dustproof and heat-insulating rotating door 6 is provided with a through hole to facilitate the passage of the spiral rod 4.
[0053] Furthermore, the ice dispensing box 15 is provided with a second ice dispensing port 153, and the ice inlet 150 and the second ice dispensing port 153 are connected, with an ice guide plate 152 provided between the ice inlet 150 and the second ice dispensing port 153; the ice guide plate 152 is inclined, with the higher end of the ice guide plate 152 connected to the ice inlet 150 and the lower end of the ice guide plate 152 connected to the second ice dispensing port 153. With this configuration, when ice enters the ice dispensing cavity 151 through the ice inlet 150, the ice is guided to the second ice dispensing port 153 by the ice guide plate 152, resulting in better ice dispensing and preventing ice from remaining in the ice dispensing cavity 151.
[0054] Furthermore, the ice receiving cavity 132 is equipped with a third motor 10, an ice-making shell 11, and an ice-making mold 12. The ice-making mold 12 is fixed to the inner wall of the ice receiving cavity 132, and an ice-pushing plate 111 is provided on the outer wall of the ice-making shell 11. The third motor 10 is used to drive the ice-making shell 11 to rotate relative to the ice-making mold 12. When the third motor 10 drives the ice-making shell 11 to be above the ice-making mold 12, the ice blocks made by the ice-making mold 12 can be detached into the ice storage cavity 131. When the third motor 10 drives the ice-making shell 11 to be below the ice-making mold 12, it is used to cooperate with the ice-making mold 12 to make ice and to push the ice blocks in the ice receiving cavity 132 into the ice storage cavity 131. In this way, by driving the ice-making shell 11 to different positions by the third motor 10, different functions can be achieved.
[0055] Specifically, during ice making, the third motor 10 drives the ice-making housing 11 to be positioned below the ice-making mold 12. At this time, the ice-making housing 11 is used to hold water and cooperate with the ice-making mold 12 to make ice. After ice making is completed, the third motor 10 drives the ice-making housing 11 to be positioned above the ice-making mold 12. At this time, the ice blocks made on the ice-making mold 12 can be removed into the ice-receiving cavity 132. After the ice is removed, the third motor 10 drives the ice-making housing 11 to be positioned below the ice-making mold 12 again for making ice again. During the process of the third motor 10 driving the ice-making housing 11 to be positioned below the ice-making mold 12 again, the ice-pushing plate 111 on the outer wall of the ice-making housing 11 can push the ice blocks in the ice-receiving cavity 132 into the ice-storage cavity 131.
[0056] The ice receiving cavity 132 is located on one side of the ice storage cavity 131.
[0057] Furthermore, the ice storage cavity 131 is equipped with a high-level sensing component, which includes a black infrared lamp 17 and a white infrared lamp 18 located on both sides of the ice storage cavity 131, with the black infrared lamp 17 and white infrared lamp 18 being correspondingly arranged. This arrangement allows ice to be blocked when the signal between the black infrared lamp 17 and the white infrared lamp 18 is blocked by ice, indicating that the ice in the ice storage cavity 131 has reached a high level or is full, thus stopping ice making; conversely, when the signal between the black infrared lamp 17 and the white infrared lamp 18 remains in communication, it indicates that the ice in the ice storage cavity 131 has not reached a high level, thus continuing ice making.
[0058] Furthermore, a sealing element 14 is fixed at the connection between the ice-making box 1 and the ice-dispensing box 15; an ice-making box cover 2 is fixed on the ice-making box 1, and an ice-dispensing box cover 16 is fixed on the ice-dispensing box 15.
[0059] The sealing element 14 prevents water leakage at the connection between the ice-making box 1 and the ice-dispensing box 15; when the dustproof and heat-insulating rotating door 6 closes the ice transport channel, a relatively sealed heat-insulating space is formed under the enclosure of the dustproof and heat-insulating rotating door 6, the ice-making box 1, and the ice-making box cover 2, allowing the ice to be stored in the ice-making box 1 for a longer time; the second motor 8 is fixedly installed on the outer wall of the ice-dispensing box cover 16.
[0060] The ice maker described in this utility model includes the ice dispensing device described above.
[0061] The working principle of this utility model:
[0062] After the ice blocks are formed in the ice-making mold 12, the third motor 10 drives the ice-making housing 11 to rotate above the ice-making mold 12 to avoid the ice removal space. After the ice blocks are demolded from the ice-making mold 12, they fall into the ice-receiving cavity 132. Then, the third motor 10 drives the ice-making housing 11 to rotate below the ice-making mold 12. During the rotation, the ice-pushing plate 111 on the ice-making housing 11 can push the ice blocks in the ice-receiving cavity 132 into the ice-storage cavity 131. When the ice blocks in the ice-storage cavity 131 reach the high position or are full, the signal between the black infrared lamp 17 and the white infrared lamp 18 is blocked by the ice blocks, stopping ice making. At this time, the user can operate the ice-making system. The machine's control panel dispenses ice. When dispensing ice, the second motor 8 drives the connecting rod 9 to rotate, which in turn drives the dustproof and heat-insulating rotating door 6 to open the ice inlet 150, thus connecting the ice transport channel. At this time, the first motor 3 drives the screw rod 4 to rotate, which in turn drives the ice in the ice storage chamber 131 to climb upwards. When the ice climbs to the ice inlet 150, since the dustproof and heat-insulating rotating door 6 is in the open ice inlet 150 state, the ice, under its own weight and the pressure of the ice behind it, is guided from the ice inlet 150 through the ice guide plate 152 to the second ice outlet 153, thus dispensing ice into the juice cup or coffee cup.
[0063] The embodiments of the present utility model have been described above with reference to the accompanying drawings. However, the present utility model is not limited to the specific embodiments described above. The specific embodiments described above are merely illustrative and not restrictive. Those skilled in the art can make many other forms under the guidance of the present utility model without departing from the spirit and scope of the claims, and all of these forms are within the scope of protection of the present utility model.
Claims
1. An ice-discharging device, characterized in that, include: An ice-making box (1) is provided with an ice storage cavity (131) and an ice receiving cavity (132) inside the ice-making box (1), and the ice receiving cavity (132) is connected to the ice storage cavity (131); An ice dispensing box (15) is provided with an ice dispensing cavity (151); The ice-making box (1) and the ice-discharging box (15) are fixedly connected and form an ice transport channel, which connects the ice storage cavity (131) and the ice discharge cavity (151). The ice transport channel is equipped with a dustproof and heat-insulating rotating door (6), which is driven to rotate by a drive assembly to open or close the ice transport channel.
2. The ice-discharging device according to claim 1, characterized in that: The ice box (1) is provided with a first ice outlet (130), and the ice box (15) is provided with an ice inlet (150). The first ice outlet (130) and the ice inlet (150) are fixedly connected. The dustproof and heat-insulating rotating door (6) is hinged to the inner wall of the ice box (15). The dustproof and heat-insulating rotating door (6) is driven to rotate by a drive assembly to open or close the ice inlet (150).
3. The ice-discharging device according to claim 2, characterized in that: The drive assembly includes a second motor (8), a first connecting rod (91) and a second connecting rod (92). The second motor (8) is fixed on the ice box (15). The first end of the first connecting rod (91) is connected to the output end of the second motor (8). The second end of the first connecting rod (91) is connected to the first end of the second connecting rod (92). The second end of the second connecting rod (92) is connected to the dustproof and heat-insulating rotating door (6).
4. An ice-discharging device according to claim 3, characterized in that: When the dustproof and heat-insulating rotating door (6) closes the ice inlet (150), the outer edge of the dustproof and heat-insulating rotating door (6) is tightly fitted with the inner wall of the ice inlet (150); a heat-insulating layer (7) is fixed on the dustproof and heat-insulating rotating door (6).
5. An ice-discharging device according to claim 2, characterized in that: The ice transport channel is equipped with an ice transport assembly, which includes a first motor (3) and a screw rod (4). The first motor (3) is fixed on the ice outlet box (15). The first end of the screw rod (4) is connected to the output end of the first motor (3). The second end of the screw rod (4) passes through the ice inlet (150) and the first ice outlet (130) and is located in the ice storage cavity (131). The first motor (3) is used to drive the screw rod (4) to rotate, so as to transport the ice in the ice storage cavity (131) to the ice outlet cavity (151).
6. An ice-discharging device according to claim 2, characterized in that: The ice box (15) is provided with a second ice outlet (153), the ice inlet (150) and the second ice outlet (153) are connected, and an ice guide plate (152) is provided between the ice inlet (150) and the second ice outlet (153); the ice guide plate (152) is inclined, the higher end of the ice guide plate (152) is connected to the ice inlet (150), and the lower end of the ice guide plate (152) is connected to the second ice outlet (153).
7. An ice-discharging device according to claim 2, characterized in that: The ice receiving cavity (132) is equipped with a third motor (10), an ice-making shell (11), and an ice-making mold (12). The ice-making mold (12) is fixed on the inner wall of the ice receiving cavity (132), and an ice-pushing plate (111) is provided on the outer wall of the ice-making shell (11). The third motor (10) is used to drive the ice-making shell (11) to rotate relative to the ice-making mold (12). When the third motor (10) drives the ice-making shell (11) to be above the ice-making mold (12), the ice blocks made by the ice-making mold (12) can be removed into the ice storage cavity (131). When the third motor (10) drives the ice-making shell (11) to be below the ice-making mold (12), it is used to cooperate with the ice-making mold (12) to make ice and to use the ice-pushing plate (111) to push the ice blocks in the ice receiving cavity (132) into the ice storage cavity (131).
8. An ice-discharging device according to claim 2, characterized in that: The ice storage cavity (131) is equipped with a high-position sensing component, which includes a black infrared lamp (17) and a white infrared lamp (18) located on both sides of the ice storage cavity (131), and the black infrared lamp (17) and the white infrared lamp (18) are arranged accordingly.
9. An ice-discharging device according to claim 2, characterized in that: A sealing element (14) is fixed at the connection between the ice-making box (1) and the ice-dispensing box (15); an ice-making box cover (2) is fixed on the ice-making box (1), and an ice-dispensing box cover (16) is fixed on the ice-dispensing box (15).
10. An ice maker, characterized in that: Includes the ice-discharging device according to any one of claims 1-9.