JP2021127892A - Ice machine - Google Patents

Abstract

To improve the cleanliness of an ice storage part in an ice machine.SOLUTION: An ice machine includes a cylindrical ice making body which cools water to make ice, an ice storage part which stores the ice, a rotor which rotates inside the ice making body and guides the ice toward the ice storage part, an ozone water supply part which supplies ozone water to the ice making body in a time other than ice making, and a control part which control the rotor when the ozone water is supplied to the ice making body by the ozone water supply part.SELECTED DRAWING: Figure 1

Description

The present invention relates to an ice machine.

Patent Document 1 describes an ice maker that generates ozone water using water stored in a water storage tank and cleans the inside of the water storage tank using the ozone water.

Japanese Unexamined Patent Publication No. 2014-9833

The ice maker described above is provided with a hopper (ice storage unit) for storing the produced ice. Since the inside of the ice storage section is where the ice comes into direct contact, there is a desire to improve cleanliness.

The present disclosure aims to improve the cleanliness of the ice storage section in an ice maker.

In order to achieve the above object, the ice maker in the present disclosure includes a tubular ice maker that cools water to produce ice, and a rotating body that rotates inside the ice maker and derives ice from the ice maker. , The ice storage section that stores the ice derived from the ice maker, the ozone water supply section that supplies ozone water to the ice maker, and the ozone water supply section that supplies ozone water to the ice maker at times other than ice making. , A control unit for rotating the rotating body.

According to the ice maker of the present disclosure, the cleanliness of the ice storage section can be improved.

It is a schematic diagram which shows the structure of the ice making machine which concerns on embodiment of this disclosure. It is a flowchart of the cleaning control executed by the control device shown in FIG.

Hereinafter, embodiments of the ice maker of the present disclosure will be described with reference to the drawings. FIG. 1 is a schematic view showing the configuration of the ice maker 1. In this specification, for convenience of explanation, the upper side and the lower side in FIG. 1 will be referred to as the upper side and the lower side of the ice maker 1, respectively, and the left side and the right side will be described as the left side and the right side of the ice maker 1 respectively. The ice machine 1 is an ice dispenser.

The ice machine 1 includes a refrigerant cycle unit 10, an ice making unit 20, a water storage tank 30 for storing water, an ozone water generating unit 40, a drain pan 50, and a control device 60. The control device 60 is an example of a “control unit”.

The refrigerant cycle unit 10 cools the water supplied from the water storage tank 30 by the refrigeration cycle to produce ice. The refrigerant cycle unit 10 includes a compressor 11, a condenser 12, an expansion valve 13, a cooler 14 (evaporator), and a refrigerant pipe 15 in which the refrigerant circulates in this order when the compressor 11 is driven during ice making. It constitutes a refrigeration cycle. The cooler 14 constitutes a part of the ice making section 20.

The ice making section 20 manufactures ice. The ice making section 20 includes a cooling cylinder 21, a cooler 14, an auger 22, a driving device 23, a hopper 24, a shutter 25, and a shooter 26. The cooling cylinder 21 is an example of an “ice maker”. The auger 22 is an example of a "rotating body". The hopper 24 is an example of an "ice storage section".

The cooling cylinder 21 is formed of stainless steel in a cylindrical shape. A tubular cooler 14 through which a refrigerant flows during ice making is wound around the outer circumference of the cooling cylinder 21. Inside the cooling cylinder 21, an auger 22 (rotary blade) is arranged coaxially with the cooling cylinder 21 and rotatably relative to the cooling cylinder 21.

The lower end of the auger 22 is rotatably supported by a lower bearing 22a. On the other hand, the upper end portion of the auger 22 is rotatably supported by the upper bearing 22b. The drive device 23 rotates the auger 22.

The hopper 24 stores the ice derived from the cooling cylinder 21. The hopper 24 is formed in a hollow box shape. The upper end (one end) of the cooling cylinder 21 is connected to the bottom surface of the hopper 24. Further, the upper bearing 22b is held at the bottom of the hopper 24. The upper bearing 22b is provided with a passage (not shown) that connects the inside of the cooling cylinder 21 and the inside of the hopper 24 and compresses the passing ice. Further, the hopper 24 is formed with a discharge port 24a for discharging the ice stored in the hopper 24.

The water stored in the water storage tank 30 is supplied to the inside of the cooling cylinder 21 and cooled by the cooler 14, so that ice is generated on the inner peripheral surface of the cooling cylinder 21. This ice is scraped off by the auger 22 driven by rotation, and is transferred from the lower side to the upper side. Further, the ice is compressed as it passes through the passage of the upper bearing 22b, so that ice pieces are generated. This ice piece is led out and stored in the hopper 24.

The shutter 25 opens and closes the discharge port 24a of the hopper 24. When the discharge port 24a is opened by the shutter 25, the ice stored in the hopper 24 is discharged from the discharge port 24a. When the discharge port 24a is closed by the shutter 25, the discharge of ice stored in the hopper 24 is restricted. The shutter 25 is driven by the solenoid 25a.

The shooter 26 is formed in a tubular shape and guides the ice released from the discharge port 24a downward.

The water storage tank 30 includes a water supply unit 31, a tank unit 32, and a float switch 33. The water supply portion 31 and the tank portion 32 are integrally formed. The tank portion 32 is an example of a “tank”.

The water supply unit 31 supplies water to the tank unit 32. The water supply unit 31 is formed in a hollow box shape on the upper side of the tank unit 32. The first end of the first pipe 51 is connected to the upper wall of the water supply unit 31. A water pipe (not shown) is connected to the second end of the first pipe 51 via a water tap 51a. A normally closed type first solenoid valve 51b is arranged in the first pipe 51.

When the first solenoid valve 51b is energized and opened, the water in the water pipe is supplied into the water supply unit 31 via the first pipe 51. The energized state of the first solenoid valve 51b is controlled by the control device 60.

Further, an opening 31a is formed on the right side of the water supply unit 31 to communicate the inside and outside of the water supply unit 31. Further, the first end of the second pipe 52 communicating with the opening 31a is connected to the right side portion of the water supply portion 31. The second end of the second pipe 52 is connected to the fifth pipe 55, which will be described later. Further, on the bottom wall of the water supply unit 31, a lead-out unit 31b for leading the water supplied into the water supply unit 31 to the tank unit 32 is formed.

The tank unit 32 stores the water supplied from the water supply unit 31. The tank portion 32 is formed in a hollow box shape, and the first storage portion 32a and the second storage portion 32b are separated by a first weir portion 32a1 described later and are formed side by side in the left-right direction.

The first storage unit 32a is arranged below the water supply unit 31 and stores water derived from the water supply unit 31. A lead-out unit 31b of the water supply unit 31 is arranged on the upper wall on the side of the first storage unit 32a. A first weir portion 32a1 is formed on the side wall between the first storage portion 32a and the second storage portion 32b. When the water level of the first storage portion 32a becomes higher than the height of the first weir portion 32a1, the water stored in the first storage portion 32a gets over the first weir portion 32a1 and is led out to the second storage portion 32b.

The second storage unit 32b stores water derived from the first storage unit 32a. The first end of the third pipe 53 is connected to the bottom wall of the second storage portion 32b. The second end of the third pipe 53 is connected to the cooling cylinder 21 below the water storage tank 30 and the cooler 14.

Further, the first end of the fourth pipe 54 is connected to the cooling cylinder 21 at a position facing the second end of the third pipe 53. The second end of the fourth pipe 54 opens toward the drain pan 50. A normally closed type second solenoid valve 54a is arranged in the fourth pipe 54.

When the second solenoid valve 54a is energized and opened, the water stored in the second storage portion 32b flows through the third pipe 53, the cooling cylinder 21, and the fourth pipe 54, and the drain pan 50. Is discharged to. On the other hand, when the second solenoid valve 54a is in the closed state, since the second storage portion 32b and the cooling cylinder 21 are connected via the third pipe 53, the water level of the second storage portion 32b and the cooling cylinder 21 The water level is the same as. The energized state of the second solenoid valve 54a is controlled by the control device 60.

Further, the second storage portion 32b is provided with a second weir portion 32b1 and a drainage portion 32b2. The height of the second weir portion 32b1 is formed lower than the height of the first weir portion 32a1. The drainage portion 32b2 is an opening that opens upward at the height of the second weir portion 32b1. The first end of the fifth pipe 55 is connected to the drainage portion 32b2. The second end of the fifth pipe 55 opens toward the drain pan 50.

When the water level of the second storage portion 32b becomes higher than the height of the second weir portion 32b1, the water stored in the second storage portion 32b gets over the second weir portion 32b1 and flows out from the drainage portion 32b2. The water flowing out from the drainage portion 32b2 is led out to the drain pan 50 via the fifth pipe 55.

Further, the first end of the sixth pipe 56 is connected to the fifth pipe 55. The second end of the sixth pipe 56 is connected to the bottom of the hopper 24. The water generated by melting the ice stored in the hopper 24 is led out to the drain pan 50 via the sixth pipe 56 and the fifth pipe 55.

The float switch 33 detects the water level of the second storage unit 32b. The water level detected by the float switch 33 (hereinafter referred to as the detected water level) is output to the control device 60. When the detected water level is equal to or lower than the first water level lower than the height of the second weir portion 32b1, the control device 60 energizes the first solenoid valve 51b. As a result, the first solenoid valve 51b is opened, so that water is supplied to the second storage unit 32b via the water supply unit 31 and the first storage unit 32a.

When the detected water level becomes higher than the second water level by supplying water to the second storage unit 32b, the control device 60 de-energizes the first solenoid valve 51b. As a result, the first solenoid valve 51b is closed, so that the water supply to the water supply unit 31 is stopped. The second water level is set to be higher than the first water level and lower than the height of the second weir portion 32b1. At the time of ice making, the water level of the second storage portion 32b is controlled to be between the first water level and the second water level.

The ozone water generation unit 40 generates ozone water using the water stored in the first storage unit 32a. The ozone water generation unit 40 includes a supply pipe 41, a pump 42, an ozone water generation device 43, and a third solenoid valve 44.

The supply pipe 41 is a pipe that connects the bottom portion of the first storage portion 32a and the upper wall of the second storage portion 32b. The supply pipe 41 supplies the water stored in the first storage unit 32a to the second storage unit 32b. In the supply pipe 41, the pump 42, the ozone water generator 43, the pipe joint 41a, and the third solenoid valve 44 are arranged in this order from the first storage unit 32a to the second storage unit 32b.

The pump 42 sends water from the first storage unit 32a to the second storage unit 32b. The pump 42 is controlled by the control device 60.

When the ozone water generator 43 is energized, the supplied water is electrolyzed to generate ozone water, and the ozone water is derived. When the pump 42 is driven, the ozone water generator 43 electrolyzes the water supplied from the first storage unit 32a to derive ozone water.

The concentration of ozone water generated by the ozone water generator 43 is controlled by the flow rate of water (flow rate per unit time) and the amount of energization (amount of energization per unit time). The flow rate is controlled by the driving amount of the pump 42. The amount of energization is controlled by the control device 60. The ozone water supplied from the ozone water generator 43 to the second storage unit 32b via the supply pipe 41 is stored in the second storage unit 32b.

The pipe joint 41a branches the ozone water derived from the ozone water generator 43 into the seventh pipe 57. The seventh pipe 57 connects the pipe joint 41a and the nozzle 57a, and supplies ozone water derived from the pipe joint 41a to the nozzle 57a. The nozzle 57a ejects ozone water toward the peripheral portion of the discharge port 24a.

The third solenoid valve 44 is a normally closed type solenoid valve. When the third solenoid valve 44 is energized and is in an open state, the pump 42 drives the ozone water generated by the ozone water generator 43 to the second storage unit 32b via the supply pipe 41. Derived. Further, in this case, the flow path resistance of the pipe joint 41a is set so that ozone water is suppressed from being led out to the seventh pipe 57 even when the pump 42 is driven.

When the third solenoid valve 44 is in a closed state due to non-energization, the derivation of ozone water from the third solenoid valve 44 to the second storage portion 32b is restricted. Further, in this case, by driving the pump 42, the ozone water generated by the ozone water generator 43 is led out to the seventh pipe 57.

The drain pan 50 receives the drainage and discharges it to the outside.

The control device 60 controls the ice machine 1 in an integrated manner. The control device 60 executes cleaning control for cleaning the inside of the hopper 24.

Next, the cleaning control executed by the control device 60 will be described with reference to the flowchart of FIG. Specifically, the cleaning control is a control in which ozone water is supplied to the cooling cylinder 21 to rotate the auger 22 at times other than during ice making. At times other than ice making, the drive of the compressor 11 is stopped and the circulation of the refrigerant is stopped. The washing control is started when the ice making is stopped and, for example, the washing switch (not shown) is turned on after the ice stored in the hopper 24 is discharged by the user.

The control device 60 discharges the water stored in the second storage unit 32b in S10. Specifically, the control device 60 energizes the second solenoid valve 54a for a first predetermined time. The first predetermined time is set to a time during which all the water stored in the second storage unit 32b and the cooling cylinder 21 is discharged.

When the second solenoid valve 54a is opened for the first predetermined time, the water stored in the second storage portion 32b and the cooling cylinder 21 is brought into the drain pan 50 via the third pipe 53 and the fourth pipe 54. It is discharged.

Subsequently, the control device 60 supplies ozone water to the cooling cylinder 21 in S11. Specifically, the control device 60 generates ozone water until the water level of the second storage unit 32b reaches the second water level. First, the control device 60 closes the second solenoid valve 54a and opens the first solenoid valve 51b and the third solenoid valve 44. Further, the control device 60 drives the pump 42 to energize the ozone water generator 43.

At this time, the control device 60 controls the pump 42 and the ozone water generator 43 so that the ozone concentration of the ozone water becomes a predetermined concentration. The predetermined concentration is a concentration at which the ozone gas generated from the ozone water generated by the ozone water generator 43 can sufficiently sterilize the inside of the hopper 24.

Further, the first solenoid valve 51b controls the flow rate of the water discharged to the first storage unit 32a so that the water stored in the first storage unit 32a is not led out to the second storage unit 32b. In other words, the control device 60 controls the first solenoid valve 51b so that the water in the first storage portion 32a does not flow beyond the first weir portion 32a1 into the second storage portion 32b from the first pipe 51 to the first. The flow rate of water discharged to the storage unit 32a is adjusted. At this time, the pump 42 continues to be driven to supply water to the ozone water generator 43.

As a result, ozone water is generated by the ozone water generation unit 40 from the water stored in the first storage unit 32a, and the ozone water is led out to the second storage unit 32b. When the water level of the second storage unit 32b rises and the detected water level reaches the second water level, the control device 60 stops the generation of ozone water. Specifically, the control device 60 closes the first solenoid valve 51b and the third solenoid valve 44. Further, the control device 60 stops energization of the pump 42 and the ozone water generator 43.

As a result, ozone water having a predetermined concentration is stored in the second storage unit 32b up to the second water level. At this time, since the second solenoid valve 54a is in the closed state, ozone water having a predetermined concentration is supplied to the cooling cylinder 21 from the second storage unit 32b via the third pipe 53. The water level of the cooling cylinder 21 is the same as the second water level of the second storage portion 32b.

Subsequently, the control device 60 rotates the auger 22 for a second predetermined time in S12.

As a result, the ozone water stored in the cooling cylinder 21 is agitated and degassed to generate ozone gas. This ozone gas flows from the cooling cylinder 21 into the hopper 24 through the passage of the upper bearing 22b through which ice passes. The ozone gas that has flowed into the hopper 24 cleans the inside of the hopper 24. The second predetermined time is set to a time during which ozone in ozone water is sufficiently degassed. The first pipe 51, the first solenoid valve 51b, the ozone water generator 40, the water storage tank 30, the third pipe 53, the fourth pipe 54, the second solenoid valve 54a, and the third solenoid valve 44 are attached to the cooling cylinder 21. It constitutes an ozone water supply unit that supplies ozone water.

When the water level of the second storage unit 32b is equal to or lower than the second water level, the space above the ozone water surface of the second storage unit 32b and the inside of the hopper 24 are connected via the fifth pipe 55 and the sixth pipe 56. Is connected. As a result, the ozone gas generated by degassing the ozone water stored in the second storage unit 32b flows into the hopper 24 via the fifth pipe 55 and the sixth pipe 56 to clean the inside of the hopper 24. .. The space above the surface of the ozone water in the second storage portion 32b is an example of "a portion of the tank above the surface of the ozone water". The fifth pipe 55 and the sixth pipe 56 are examples of “connecting pipes”.

According to the present embodiment, the ice maker 1 includes a tubular cooling cylinder 21 that cools water to produce ice, and an auger 22 that rotates inside the cooling cylinder 21 and derives ice from the cooling cylinder 21. , A hopper 24 for storing ice derived from the cooling cylinder 21, an ozone water supply unit for supplying ozone water to the cooling cylinder 21, and an ozone water supply unit for supplying ozone water to the cooling cylinder 21 at times other than ice making. It is provided with a control device 60 that supplies and rotates the auger 22.

According to this, the ozone water supplied to the cooling cylinder 21 is agitated by the rotation of the auger 22 by the cleaning control, and ozone gas is generated. This ozone gas flows into the hopper 24 from the cooling cylinder 21 to sterilize the inside of the hopper 24. Therefore, the ice machine 1 can improve the cleanliness of the hopper 24.

Further, the upper end of the cooling cylinder 21 is connected to the bottom surface of the hopper 24.

According to this, the ozone gas generated in the cooling cylinder 21 surely flows into the hopper 24.

Further, in the ice machine 1, the fifth pipe 55 and the sixth pipe connecting the tank part 32 for storing ozone water, the space above the water surface of the ozone water in the second storage part 32b of the tank part 32, and the hopper 24 are provided. 56 and is further provided.

According to this, when ozone water is stored in the tank portion 32 (second storage portion 32b), the ozone gas in the space above the water surface of the ozone water in the second storage portion 32b is the fifth pipe 55 and the fifth pipe 55. 6 It flows into the hopper 24 through the pipe 56. Therefore, the ice machine 1 can further improve the cleanliness of the hopper 24.

Although the ice maker 1 according to one or more aspects has been described above based on the embodiment, the present invention is not limited to this embodiment. As long as the gist of the present invention is not deviated, various modifications that can be conceived by those skilled in the art are applied to the present embodiment, and a form constructed by combining components in different embodiments is also within the scope of one or more embodiments. May be included within.

In the above-described embodiment, the tank unit 32 includes the first storage unit 32a and the second storage unit 32b, but instead, the tank unit 32 may include only the second storage unit 32b. In this case, water is supplied from the water supply unit 31 to the second storage unit 32b. Further, in this case, the ozone water generation unit 40 generates ozone water using the water stored in the second storage unit 32b.

In the above-described embodiment, the ozone water is generated by the ozone water generation unit 40, but instead, a pair of electrodes (not shown) are arranged in the second storage unit 32b to generate ozone water. You may. When the pair of electrodes are energized, the water stored in the second storage unit 32b is electrolyzed to generate ozone water.

Further, in the above-described embodiment, in the cleaning control, ozone water is supplied to the cooling cylinder 21 to the same water level as the second water level of the second storage unit 32b, but instead of this, the second storage unit 32b Ozone water may be supplied to the cooling cylinder 21 up to a predetermined water level higher than the second water level of the above. Specifically, in the cleaning control, the amount of ozone water generated is adjusted so that the water level of the second storage portion 32b becomes the height of the second weir portion 32b1 which is higher than the second water level. That is, the predetermined water level is the same as the height of the second weir portion 32b1.

In this way, the control device 60 supplies ozone water to the cooling cylinder 21 to a predetermined water level at times other than during ice making. The predetermined water level is set higher than the water level at which water is supplied to the cooling cylinder 21 during ice making.

According to this, the predetermined water level of the cooling cylinder 21 at the time of cleaning control is higher than the water level of the cooling cylinder 21 at the time of ice making. Therefore, in the cleaning control, ozone gas more reliably flows into the hopper 24.

The present invention is widely available in ice machines.

1 Ice maker 20 Ice maker 21 Cooling cylinder (ice maker)
22 auger (rotating body)
24 Hoppa (ice storage section)
30 Water storage tank 32 Tank section (tank)
32a 1st storage 32b 2nd storage 40 Ozone water generator 43 Ozone water generator 50 Drain pan 51 1st pipe 53 3rd pipe 54 4th pipe 55 5th pipe (connection pipe)
56 6th pipe (connection pipe)
60 Control device (control unit)

Claims (4)

A tubular ice maker that cools water to produce ice,
A rotating body that rotates inside the ice making body and derives the ice from the ice making body,
An ice storage unit that stores the ice derived from the ice maker,
An ozone water supply unit that supplies ozone water to the ice maker,
An ice maker including a control unit that supplies the ozone water to the ice maker by the ozone water supply unit to rotate the rotating body at times other than during ice making. The ice maker according to claim 1, wherein the ice maker has one end connected to the bottom surface of the ice storage section. The control unit supplies the ozone water to the ice maker to a predetermined water level by the ozone water supply unit at a time other than the time of ice making.
The ice maker according to claim 1 or 2, wherein the predetermined water level is set higher than the water level at which the water is supplied to the ice maker at the time of ice making. The tank for storing ozone water and
The ice maker according to any one of claims 1 to 3, further comprising a portion of the tank above the surface of the ozone water and a connecting pipe connecting the ice storage portion.

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