ICE SUPPLY DEVICE AND ICE MAKING SYSTEM

Abstract

An ice supply device includes an ice storage tank, a supply path, and a water flow path. The ice storage tank is configured to store sherbet ice. The sherbet ice may be taken out of the ice storage tank through the supply path. The water flow path joins the supply path. The water flow path is configured to carry flow of water there through.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This is a continuation of International Application No. PCT/JP2020/048749 filed. on Dec. 25, 2020, which claims priority to Japanese Patent Application No. 2019-237824, filed on Dec. 27, 2019 and PCT/2020/035080, filed on Sep. 16, 2020. The entire disclosures of these applications are incorporated by reference herein.

BACKGROUND

Technical Field

The present disclosure relates to an ice supply device and an ice making system.

Background Art

In order to refrigerate saltwater fish or the like, sherbet ice produced from salt water such as seawater may be used. The sherbet ice generated by an ice making device is stored in an ice storage tank and supplied to a user by a pump as needed.

When saltwater fish is refrigerated using sherbet ice, it is known that a temperature suitable for cold storage varies depending on a type and size of the fish. When the saltwater fish is refrigerated at a low temperature less than a temperature suitable for the saltwater fish to be refrigerated, the body of the saltwater fish may be frozen, and a commercial value of the fish may be greatly impaired.

Therefore, it has been proposed that a salinity of the sherbet ice is adjusted when the sherbet ice produced by the ice making device is supplied to a location of use (see, for example. Japanese Laid-Open Patent Publication No. 2008-281293). Note that there is a correlation between the temperature and the salinity of the sherbet ice, and the temperature can be indirectly adjusted by adjusting the salinity.

In a production apparatus for sherbet ice mixed with salt water disclosed in Japanese Laid-Open Patent Publication No. 2008-281293, fresh water is poured into an ice storage tank to adjust the salinity of the sherbet ice mixed with salt water in the ice storage tank, and the sherbet ice after the adjustment is taken out from the ice storage tank.

SUMMARY

An ice supply device in accordance with one aspect of the present disclosure includes an ice storage tank, a supply path, and a water flow path. The ice storage tank is configured to store sherbet ice. The sherbet ice may be taken out of the ice storage tank through the supply path. The water flow path joins the supply path. The water flow path is configured to carry flow of water therethrough.

An ice making system in accordance with one aspect of the present disclosure includes a refrigerant circuit that produces the sherbet ice and the ice supply device.

An ice making system in accordance with one aspect of the present disclosure includes an ice making device and the ice supply device.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an explanatory diagram of an ice making system according to Embodiment 1 of the present disclosure.

FIG. 2 is an explanatory diagram of an ice making machine in the ice making system illustrated in FIG. 1.

FIG. 3 is an explanatory diagram of an ice supply device including an ice storage tank in the ice making system illustrated in FIG. 1.

FIG. 4 is an explanatory diagram of a controller of the ice supply device illustrated in FIG. 3.

FIG. 5 is an explanatory plan view of an inside of the ice storage tank.

FIG. 6 is a flowchart of an example of control for adjusting a salinity of seawater in the ice storage tank.

FIG. 7 is an explanatory diagram of an ice making system according to Embodiment 2 of the present disclosure.

FIG. 8 is an explanatory diagram of a controller of the ice making system illustrated in FIG. 7.

FIG. 9 is a flowchart illustrating an example of water temperature control in a water tank.

FIG. 10 is a flowchart illustrating an example of control of a proportional control valve.

DETAILED DESCRIPTION OF EMBODIMENT(S)

An ice supply device and an ice making system of the present disclosure will be described in detail below with reference to the accompanying drawings. The present disclosure should not be limited to the following exemplification, but is intended to include any modification recited in the claims within meanings and a scope equivalent to the scope of the claims.

EMBODIMENT 1

FIG. 1 is an explanatory diagram of an ice making system S according to Embodiment 1 of the present disclosure. FIG. 2 is an explanatory diagram of an ice making machine 1 in the ice making system S illustrated in FIG. 1, and FIG. 3 is an explanatory diagram of an ice supply device C including an ice storage tank T in the ice making system S illustrated in FIG. 1.

The ice making system S includes an ice making device I and the ice supply device C. The ice making device I and the ice storage tank T which is a component of the ice supply device C are connected to each other by a pipe.

Ice Making Device I

The ice making device I produces sherbet ice from a medium to be cooled by exchanging heat with a refrigerant. In the present embodiment, seawater is used as the medium to be cooled, and the ice making device I produces fine ice using the seawater as a raw material, and returns sherbet ice mixed with seawater, in which the produced fine ice and the seawater are mixed, to the ice storage tank T. The sherbet ice is also referred to as slurry ice, ice slurry, slough ice, or liquid ice. As the medium to be cooled, for example, salt water containing salt in water can be used instead of seawater, The “water referred herein includes industrial water, tap water, and fresh water that are substantially free of salt.

The ice making device I includes a compressor 2, a heat source-side heat exchanger 3 (first heat exchanger), a four-way switching valve 4, a use-side expansion valve 5, a heat source-side expansion valve 6, an internal heat exchanger 7, and a receiver 8, in addition to the ice making machine 1 constituting a use-side heat exchanger (second heat exchanger). These devices are connected by a refrigerant pipe 96 to constitute a refrigerant circuit 95.

As illustrated in FIG. 1 and FIG. 2, the ice making machine 1 includes an evaporator 13 (second heat exchanger) including an inner pipe 11 and an outer pipe 12, and an ice scraper 14. The ice making machine 1 is a horizontal double pipe ice making machine in which axes of the inner pipe 11 and the outer pipe 12 are disposed horizontally. In the evaporator 13, liquid refrigerant passes through most of an annular space 24 between the inner pipe 11 and the outer pipe 12.

The inner pipe 11 is an element through which the seawater serving as the medium to be cooled passes. The inner pipe 11 is made of a metal material such as stainless steel or iron. The inner pipe 11 has a cylindrical shape, and is disposed in the outer pipe 12. Both ends of the inner pipe 11 are closed. In the inner pipe 11, the ice scraper 14 is disposed to scrape off ice produced on an inner peripheral surface of the inner pipe 11 and to disperse the ice into the seawater in the inner pipe 11. A seawater pipe 15 that supplies the seawater in the ice storage tank T into the inner pipe 11 is connected to one axial end of the inner pipe 11. A sherbet pipe 16 that returns the seawater from the inner pipe 11 to the ice storage tank T is connected to the other axial end of the inner pipe 11.

The outer pipe 12 has a cylindrical shape, and is made of a metal material such as stainless steel or iron as in the inner pipe 11. A plurality of (three in an illustrated example) refrigerant inlet pipes 17 branched downstream of the use-side expansion valve 5 are connected to a lower part of the outer pipe 12. A refrigerant outlet pipe 18 leading to the internal heat exchanger 7 is connected to an upper part of the outer pipe 12. In the present embodiment, three refrigerant inlet pipes 17 are provided, but the number of refrigerant inlet pipes 17 may be two or less or four or more. The number of refrigerant outlet pipes 18 is one, but may be two or more.

The ice scraper 14 includes a shaft 19, support bars 20, blades 21, and a motor 22. The shaft 19 has the other axial end that extends outward from a flange 23 provided at the other axial end of the inner pipe 11. The other axial end of the shaft 19 is connected to the motor 22 that drives the shaft 19. The support bars 20 are disposed upright on a peripheral surface of the shaft 19 at predetermined intervals, and the blades 21 are attached to distal ends of the support bars 20. Each of the blades 21 is, for example, a band plate-shaped member made of a synthetic resin. Each of the blades 21 has a tapered shape directed forward in a rotational direction.

In a normal ice making operation, the four-way switching valve 4 is maintained at a state indicated by a solid line in FIG. 1. High-temperature high-pressure gas refrigerant discharged from the compressor 2 flows through the four-way switching valve 4 into the heat source-side heat exchanger 3 functioning as a condenser, exchanges heat with air provided by the operation of the fan 10, and is condensed and liquefied. The liquefied refrigerant then flows into the use-side expansion valve 5 via the heat source-side expansion valve 6 in a fully open state, the receiver 8, and the internal heat exchanger 7. The refrigerant is decompressed to have a predetermined low pressure by the use-side expansion valve 5, and supplied through the refrigerant inlet pipe 17 into the annular space 24 between the inner pipe 11 and the outer pipe 12 that constitute the evaporator 13.

The refrigerant ejected into the annular space 24 exchanges heat with the seawater supplied into the inner pipe 11 to evaporate. The seawater containing fine ice produced by cooling by evaporation of the refrigerant flows out of the sherbet pipe 16 and returns to the ice storage tank T. The refrigerant gasifies by the evaporation in the ice making machine 1. Thereafter, the refrigerant is sucked into the compressor 2. At that time, if the refrigerant containing liquid enters the compressor 2 without being completely evaporated in the ice making machine 1, the compressor 2 may malfunction due to a sudden increase in pressure inside a compressor cylinder (liquid compression) and a decrease in viscosity of a refrigeration oil. Therefore, the low-pressure refrigerant that has left the ice making machine 1 to protect the compressor 2 exchanges heat with the high-pressure refrigerant that has passed through the receiver 8 in the internal heat exchanger 7, is heated, and returns to the compressor 2. The internal heat exchanger 7 is of a double pipe type. The low-pressure refrigerant from the ice making machine 1 exchanges heat with the high-pressure refrigerant when passing through the space between the inner pipe and the outer pipe of the internal heat exchanger 7. The refrigerant is thus heated and then returns to the compressor 2.

If the flow of the seawater is stagnated in the inner pipe 11 of the ice making machine 1, the ice is accumulated in the inner pipe 11 (ice accumulation) to hinder the operation of the ice making machine 1. In this case, a defrosting operation (a heating operation) is performed for melting the ice in the inner pipe 11. At this time, the four-way switching valve 4 is maintained at a state indicated by a broken line in FIG. 1. The compressor 2 discharges the high-temperature high-pressure gas refrigerant. The gas refrigerant flows into the annular space between the inner pipe 11 and the outer pipe 12 of the ice making machine 1 via the four-way switching valve 4 and the internal heat exchanger 7. The gas refrigerant exchanges heat with the ice-containing seawater in the inner pipe 11 to be condensed and liquefied. The liquefied refrigerant then flows into the heat source-side expansion valve 6 via the use-side expansion valve 5 in a fully open state, the internal heat exchanger 7, and the receiver 8. The heat source-side expansion valve 6 decompresses the liquefied refrigerant to a predetermined low pressure. Thereafter, the refrigerant flows into the heat source-side heat exchanger 3 functioning as an evaporator. During the defrosting operation, in the heat source-side heat exchanger 3 functioning as an evaporator, the refrigerant gasifies by exchanging heat with air provided by the operation of the fan 10. Thereafter, the refrigerant is sucked into the compressor 2.

Ice Supply Device C

As illustrated in FIG. 3, the ice supply device C is a device that supplies sherbet ice produced by the ice making device I to a user. The ice supply device C includes the ice storage tank T that stores sherbet ice, a supply path 31, and a water flow path 80 that joins the supply path 31 and through which water flows. The supply path 31 includes an on-off valve. By opening the on-off valve, sherbet ice is supplied to the user. In the present embodiment, the on-off valve is an electromagnetic valve 37, but may be a valve or the like manually opened by the user. The ice supply device C includes a controller 25 serving as a control unit. As illustrated in FIG. 4, the controller 25 includes a CPU 25a, a memory 25b such as a RAM and a ROM, and a transmission and reception unit 25c that performs transmission to and reception from external devices, sensors, and the like. The controller 25 achieves various kinds of control concerning an operation of the ice making system S, including operation control of the ice supply device C, in such a manner that the CPU 25a executes a computer program stored in the memory 25b. The controller 25 controls driving of drive units or actuators such as electromagnetic valves 37, 73, and 91, a proportional control valve 83, and pumps 32 and 38, which will be described later. In addition, the controller 25 receives detection signals from temperature sensors 84 and 92 and a water level sensor 33 by the transmission and reception unit 25c. The controller 25 is communicably connected to a control unit 27 of the ice making device I, controls an operation of the ice making device I via the control unit 27, and receives a signal from a sensor or the like of the ice making device I via the control unit 27. A main control unit of the ice making system S can be attached to the ice making device I.

The ice storage tank T is made of a metal material such as stainless steel or iron. The ice storage tank T has a rectangular cylindrical shape with a rectangular horizontal cross section. The ice storage tank T is a sealed container having a lid, but in FIG. 1 and FIG. 3, the lid is not illustrated in order to facilitate understanding of a configuration of an upper part of an inside of the ice storage tank T.

The pump 32 that transfers the seawater in the ice storage tank T into the inner pipe 11 of the ice making machine 1 by the seawater pipe 15 is disposed near a bottom of the inside of the ice storage tank T. By driving the pump 32 disposed near a bottom surface to transfer the seawater in the ice storage tank T into the inner pipe 11 of the ice making machine 1, it is possible to impart fluidity to the sherbet ice in the ice storage tank T.

The water level sensor 33 is provided in the ice storage tank T. On the basis of a detection signal from the water level sensor 33, the seawater is replenished and discharged as described later. The water level sensor 33 is detectable of a plurality of water levels in the ice storage tank T, and is disposed to he detectable of, for example, positions of 90%, 70%, 45%, 30%, and 25% of a height of the ice storage tank T from the bottom. As the water level sensor 33, a generally known sensor can be used. A discharge path 90 that discharges the seawater in the ice storage tank T is connected to near the bottom of the ice storage tank T. The discharge path 90 includes an electromagnetic valve 91.

The supply path 31 is a flow path or a passage for supplying sherbet ice produced by the ice making device I and stored in the ice storage tank T to the user. The supply path 31 has a supply port 39 that releases the sherbet ice taken out from the ice storage tank T at a downstream end. As the supply path 31, a pipe, a hose, or a combination thereof can be used. The pump 38 is disposed in the supply path 31, and the sherbet ice in the ice storage tank T can be sucked and taken out to outside by driving the pump 38.

A float 40 is a member that floats in the ice storage tank T apart from an inner wall 30 of the ice storage tank T. The float 40 in the present embodiment is a hollow body and can be made of a synthetic resin such as a vinyl chloride resin (PVC). The float 40 has a square shape in plan view and a substantially rhombic shape in side view. Specifically, an upper surface 40a of the float 40 has an upper inclined surface inclined from an outer edge toward a center of the float 40 so as to be away from a liquid level. Similarly, a bottom surface 40b of the float 40 has a lower inclined surface inclined from the outer edge toward the center of the float 40 so as to be away from the liquid level. A shape of the float 40 is not limited in the present disclosure, and a float having a circular shape in plan view, a float having a triangular shape, or a float having a polygonal shape having five or more sides can also be used. The upper surface and/or the bottom surface of the float 40 may be a flat surface instead of an inclined surface.

A size of the float 40 is not limited in the present disclosure, but in a case where the float 40 having a square shape in plan view floats in the ice storage tank T having a rectangular inner wall in plan view, when a length (shorter length) of one side of the ice storage tank T is W, a length of one side of the float 40 having a square shape can be 0.3 W to 0.5 W, for example. In a case where the float 40 having a circular shape in a plan view floats in the ice storage tank T having a circular shape in a plan view, when D is an inner diameter of the ice storage tank T, an outer diameter of the float 40 having a circular shape can be set to 0.3 D to 0.5 D, for example.

An opening 41 vertically penetrating is formed at the center (center in plan view) of the float 40. The opening 41 has a circular shape in plan view. In the present embodiment, a distal end 34a of a hose 34 constituting a part of the supply path 31 is inserted into the opening 41 and fixed to the float 40. The hose 34 has a bellows portion 34b at a base of the distal end 34a. The bellows portion 34b can expand and contract by a predetermined distance along a longitudinal direction or an axial direction of the hose 34. An end of the bellows portion 34b opposite to the distal end 34a is connected to an enlarged diameter portion 35a at an end of a pipe 35 constituting the supply path 31. A position of the pipe 35 is fixed by a fixing tool (not illustrated).

One end of a chain 36 is fixed to each of four corners of the float 40 having a square shape. The other end of the chain 36 is locked to the inner wall 30 of the ice storage tank T. A length of each chain 36 is set to a length that allows vertical movement and horizontal movement within a certain range of the float 40. The float 40 can move up and down within a certain range by the presence of the bellows portion 34b. The presence of the chain 36 restricts horizontal movement of the float 40 beyond a certain range.

In the present embodiment, the pipe 35, the hose 34, and the opening 41 constitute the supply path 31. A distal end (opening edge) of the opening 41 of the float 40, which is a distal end of the supply path 31, functions as a takeout port 42 for sucking and taking out the sherbet ice stored in the ice storage tank T. The takeout port 42 is located on the bottom surface 40b of the float 40. In other words, the takeout port 42 is located below the liquid level of the sherbet ice stored in a tank body. A position of the takeout port 42 in a vertical direction is not limited in the present disclosure, but the size, shape, weight, and the like of the float 40 can be selected such that the takeout port 42 is positioned, for example, about 10 cm to 40 cm below a liquid level L of the sherbet ice.

Since ice has a specific gravity smaller than that of seawater, the ice moves upward by buoyancy. Thus, the sherbet ice near the liquid level in the ice storage tank T has an IPF higher than that of the sherbet ice near the bottom surface. In the present embodiment, since the takeout port 42 at the distal end of the supply path 31 is disposed not at a lower part or the center but at the upper part of the ice storage tank T in the vertical direction, it is possible to supply sherbet ice having a high IPF to the user. At this time, since the takeout port 42 at the distal end of the supply path 31 is disposed below the liquid level of the sherbet ice, it is possible to prevent air from being sucked from the takeout port 42 when the sherbet ice is sucked from the takeout port 42. Then, it is possible to prevent the pump 38 from being damaged by the sucked air.

Since the bottom surface 40b of the float 40 has the lower inclined surface inclined from the outer edge of the float 40 toward the takeout port 42 so as to he away from the liquid level, the air in the liquid around the takeout port 42 can be released upward along the inclined surface. It is therefore possible to further prevent the air from being sucked from the takeout port 42 at the distal end of the supply path 31.

The ice supply device C according to the present embodiment has a return flow path 50 that branches from the supply path 31 downstream of the pump 38 disposed in the supply path 31 and returns the sherbet ice to the ice storage tank T. The return flow path 50 is connected to the sherbet pipe 16 that returns seawater containing ice produced by the ice making machine 1 to the ice storage tank T. The return flow path 50 is provided with a safety valve 51. The safety valve 51 is opened when a pressure in the return flow path 50 is increased to exceed a predetermined pressure. The safety valve 51 also plays a role of opening and returning the sherbet ice into the ice storage tank T when the pressure in the return flow path 50 branched from the supply path 31 increases to exceed a predetermined pressure in a case where the pump 38 is driven even though the sherbet ice cannot be supplied from the supply port 39 due to a failure of the electromagnetic valve 37 provided in the supply path 31. The sherbet ice falls from a release port of a release pipe to be described later, which is disposed above the liquid level L of the sherbet ice stored in the ice storage tank T, and thus the sherbet ice near the liquid level can be disturbed. Further, it is possible to prevent the sherbet ice from being frozen, By opening the safety valve 51 to lower the pressure in the flow path of the sherbet ice, it is possible to avoid failure of the pump 38 due to excessive pressure.

Instead of the safety valve 51, an electromagnetic valve that is controllable to be opened and closed may be used. In this case, the electromagnetic valve is controlled by the CPU 25a of the controller 25 to be closed when the sherbet ice is being supplied to the user through the supply port 39 of the supply path 31, and is controlled to he open when the sherbet ice is not being supplied from the supply port 39 of the supply path 31. When the sherbet ice is not supplied, the sherbet ice can be returned into the ice storage tank T by operating the pump 38 and controlling the electromagnetic valve to be opened. This makes it possible to impart fluidity to the sherbet ice stored in the ice storage tank T and to prevent the sherbet ice from being frozen.

The pump 38 disposed in the supply path 31 functions as a pump for supplying the sherbet ice in the ice storage tank T to the user from the supply port 39, and can function as a pump for returning the sherbet ice taken out from the ice storage tank T to the ice storage tank T via the return flow path 50 branching from the supply path 31. A supply pump and a return pump for the sherbet ice can be shared.

By causing the CPU 25a of the controller 25 to interlock the operation of the pump 38 and opening and closing control of the electromagnetic valve that is controllable to be opened and closed, it is possible to prevent the sherbet ice from being frozen in the ice storage tank T. Specifically, the pump 38 is driven constantly or periodically while the ice making device I is operating, and the sherbet ice in the ice storage tank T can flow and circulate through the return flow path constantly or periodically. Thus, the sherbet ice near the liquid level is prevented from being frozen during ice making. The electromagnetic valve is controlled to be opened and closed by the CPU 25a of the controller 25 to be interlocked with the driving of the pump 38. By causing the sherbet ice in the ice storage tank T to flow and circulate through the return flow path constantly or periodically while the ice making device I is not operating, the sherbet ice in the ice storage tank T can be prevented from being frozen.

As illustrated in FIG. 5, a downstream end of the sherbet pipe 16 is branched into four branch pipes 60. A release pipe 61 is attached to a downstream end of each of the branch pipes 60. A plurality of (six in an example illustrated in FIG. 5) release ports 62 are formed on a lower surface of the release pipe 61. The branch pipes 60 and the release pipes 61 are disposed above the liquid level L of the sherbet ice stored in the ice storage tank T. By causing the sherbet ice to fall from the release port 62 located above the liquid level L of the sherbet ice, it is possible to impart fluidity to the sherbet ice near the liquid level. Further, the sherbet ice near the liquid level can be prevented from being frozen.

In the present embodiment, a downstream end of the seawater supply pipe 70 that supplies seawater to the ice storage tank T is connected to the sherbet pipe 16. The seawater sucked from a seawater acquisition port by a pump (not illustrated) joins the sherbet pipe 16 via a sterilization and filtration device 72 and the electromagnetic valve 73, and is supplied from the release ports 62 of the release pipes 61 to the ice storage tank T. The sterilization and filtration device 72 is a device for removing foreign substances contained in the seawater and sterilizing bacteria contained in the seawater. The seawater can be supplied to the ice storage tank T using the seawater supply pipe 70 on the basis of the detection signal of the water level sensor 33 described above.

The ice supply device C according to the present embodiment includes the water flow path 80 through which water flows and that joins the supply path 31 through which the sherbet ice is taken out of the ice storage tank T. The water flow path 80 joins the supply path 31 upstream of the pump 38 for sucking and taking out the sherbet ice from the ice storage tank T in a flow direction of the sherbet ice. As a result, the number of required pumps can be reduced to one from two. Instead of water, salt water containing salt in water can also be used.

In the present embodiment, an input unit 26 (see FIG. 4) communicably connected to the controller 25 is provided. The user can take out a desired amount of sherbet ice haying a desired salinity from the supply port 39 by inputting the salinity and the amount of sherbet ice to be taken out from the ice storage tank T.

In the present embodiment, the water stored in the water tank 81 is sucked by the pump 38 and joins the supply path 31 via the proportional control valve 83 as a flow rate regulating valve. In addition, a temperature sensor 84 as a first temperature sensor is provided downstream of a junction of the water flow path 80 and the supply path 31 and downstream of the pump 38 to detect a temperature of the sherbet ice. Since there is a correlation between the salinity and the temperature of the sherbet ice, by detecting the temperature of the sherbet ice by the temperature sensor 84, the salinity can be calculated from the detected temperature. This calculation can be performed by the CPU 25a of the controller 25. Then, an opening degree and/or an opening time of the proportional control valve 83 is adjusted by the CPU 25a of the controller 25 such that the calculated salinity becomes a target value on the basis of the calculated salinity, and thus the sherbet ice having a desired salinity can be obtained. For example, when the opening degree of the proportional control valve 83 is a full open degree, a flow rate of the sherbet ice flowing through the supply path 31 and a flow rate of the water flowing through the water flow path 80 are configured to be substantially equal. This configuration can set a concentration of the sherbet ice taken out from the electromagnetic valve 37 to about a half of a concentration of the sherbet ice stored in the ice storage tank T. For example, when the opening degree of the proportional control valve 83 is 50%, a ratio of the flow rate of the sherbet ice flowing through the supply path 31 and the flow rate of the water flowing through the water flow path 80 are two to one. It is therefore possible to set the concentration of the sherbet ice stored taken out from the electromagnetic valve 37 to about two thirds of the concentration of the sherbet ice stored in the ice storage tank T. When time for fully opening the proportional control valve 83 is about half of time for operating the pump 38, the concentration of the sherbet ice taken out from the electromagnetic valve 37 can be about two thirds of the concentration of the sherbet ice stored in the ice storage tank T. Instead of the temperature sensor 84, a concentration sensor 84 (first concentration sensor) that detects a salinity may be used. In this case, the opening degree and/or the opening time of the proportional control valve 83 can be adjusted by the controller 25 such that the salinity becomes a target value on the basis of the detected salinity.

In the present embodiment, the temperature sensor 92 as a second temperature sensor that detects the temperature of the sherbet ice in the ice storage tank T is disposed in the ice storage tank T. The salinity of the sherbet ice can be obtained by the CPU 25a of the controller 25 on the basis of the temperature of the seawater before the operation and the temperature of the sherbet ice after a start of the operation that are detected by the temperature sensor 92. The CPU 25a of the controller 25 changes the opening degree and/or the opening time of the proportional control valve 83 on the basis of the salinity to adjust the flow rate of water to join from the water flow path 80 to the supply path 31. Accordingly, a salinity of the sherbet ice supplied to a user can be adjusted. Note that it is also possible to use a concentration sensor 92 as a second concentration sensor instead of the temperature sensor 92 as the second temperature sensor. In this case, the CPU 25a of the controller 25 can obtain the concentration of the sherbet ice in the ice storage tank T by the concentration sensor 92.

Since there is a correlation between the salinity and the temperature of the sherbet ice, by detecting the temperature of the sherbet ice by the temperature sensor 92, the salinity can be calculated from the detected temperature by the CPU 25a of the controller 25. Then, when the calculated salinity is not within a predetermined range, the CPU 25a of the controller 25 prohibits an operation of taking out the sherbet ice in the ice storage tank T. When the salinity of the sherbet ice in the ice storage tank T is excessively low, the IPF of the sherbet ice is also low, and the sherbet ice is not sufficiently used as sherbet ice. By prohibiting the operation of taking out the sherbet ice in the ice storage tank when the detected salinity is not within the predetermined range, the sherbet ice in an insufficient state is prevented from being supplied to the user. Note that, in a case where the concentration sensor 92 as the second concentration sensor is used instead of the temperature sensor 92 as the second temperature sensor, the CPU 25a of the controller 25 prohibits the operation of taking out the sherbet ice in the ice storage tank T when the salinity of the sherbet ice detected by the concentration sensor 92 is not within the predetermined range.

In the present embodiment, the CPU 25a of the controller 25 controls the electromagnetic valve 91 and the electromagnetic valve 73 upon determination that the salinity calculated on the basis of the temperature detected by the temperature sensor 92 exceeds a predetermined value. Specifically, the CPU 25a of the controller 25 opens the electromagnetic valve 91 when the calculated salinity exceeds the predetermined value. As a result, the seawater in the ice storage tank T is discharged to outside via the discharge path 90. When a first predetermined condition is satisfied, the CPU 25a closes the electromagnetic valve 91 and then opens the electromagnetic valve 73 to supply the seawater to the ice storage tank T. When a second predetermined condition is satisfied, the CPU 25a closes the electromagnetic valve 73. In this manner, by discharging the seawater in the ice storage tank T and supplying the seawater to the ice storage tank T on the basis of the salinity of the seawater in the ice storage tank T, the salinity of the seawater in the ice storage tank T can be reduced to less than a predetermined value, and as a result, the ice making device I can be continuously operated. Accordingly, ice making efficiency of the ice making system S can be improved. As means for detecting the concentration of the seawater in the ice storage tank T, a salinity sensor can also be used.

The “predetermined value” described above is not limited in the present disclosure, but can be, for example, 7%. When the salinity of the sherbet ice in the ice storage tank T exceeds 7%, ice making in the ice making machine 1 becomes difficult and the ice making efficiency may decrease. The predetermined value can be appropriately set via an input unit (not illustrated) of the controller 25. The set predetermined value is stored in the memory 25b. The “first predetermined condition” and the “second predetermined condition” may be, for example, a decline in a water level as a division between water and ice to a certain position. Under the first predetermined condition, the CPU 25a of the controller 25 detects that the water level has declined to a first position by the water level sensor 33. As the first position, for example, a position of 45% of the height of the tank from the bottom can be selected from the plurality of water levels detected by the water level sensor 33. Since there is a possibility that the pump may be damaged if only ice is handled, when the water level declines to the first position, the water discharge is stopped and the water supply is started. Under the second predetermined condition, the CPU 25a of the controller 25 detects that the water level has risen to a second position by the water level sensor 33. As the second position, for example, a position of 90% of the height of the tank from the bottom can be selected from the plurality of water levels detected by the water level sensor 33. The first position and the second position can he appropriately set via an input unit (not illustrated) of the controller 25. The set first position and second position are stored in the memory 25b. In the present embodiment, as illustrated in FIG. 6, the following control flow is executed. The CPU 25a of the controller 25 detects the salinity of the sherbet ice in the ice storage tank T by the temperature sensor 92 disposed in the ice storage tank T (step S1). The CPU 25a of the controller 25 determines whether the salinity exceeds 7% (step S2), and advances the processing to step S3 upon determination that the salinity exceeds 7%. In step S3, the CPU 25a transmits a command to stop the operation of the ice making device I to the control unit 27 of the ice making device I. The CPU 25a opens the electromagnetic valve 91 provided in the discharge path 90 connected to the ice storage tank T (step S4). As a result, the seawater near the bottom surface of the ice storage tank T is discharged. The discharged seawater may contain some sherbet ice.

Next, in step S5, the CPU 25a determines whether the water level detected by the water level sensor 33 has declined to a water level lower than the first predetermined condition. Upon determination that the water level has declined to the water level lower than the first predetermined condition in step S5, the CPU 25a advances the processing to step S6 and closes the electromagnetic valve 91 in step S6. Next, the CPU 25a opens the electromagnetic valve 73 (step S7). As a result, the seawater (having a salinity of about 3.5%) is supplied into the ice storage tank T. Next, in step S8, the CPU 25a determines whether the water level detected by the water level sensor 33 has risen to a water level higher than the second predetermined condition. Upon determination that the water level has risen to a water level higher than the second predetermined condition in step S8, the CPU 25a advances the processing to step S9 and closes the electromagnetic valve 73 in step S9. Thereafter, in step S10, the CPU 25a transmits a command to start the operation of the ice making device I to the control unit of the ice making device I. The processing returns to step S1 after execution of step S10, and the CPU 25a of the controller 25 detects the salinity of the sherbet ice in the ice storage tank T by the temperature sensor 92 disposed in the ice storage tank T. By repeating such steps S1 to S10, the ice making device I can be continuously operated. A target salinity in the ice storage tank T can be set to, for example, 3.5% to 7%. By performing such control, the ice making device I can be continuously operated.

When the salinity of the seawater in the ice storage tank T detected by the temperature sensor 92 exceeds a predetermined value, the CPU 25a of the controller 25 may control the electromagnetic valve 91 of the discharge path 90 and the electromagnetic valve 73 of the seawater supply pipe 70 such that the salinity of the seawater in the ice storage tank T becomes the target salinity. The control in this case can be performed as follows. The CPU 25a of the controller 25 recognizes the salinity of seawater supplied from the seawater supply pipe 70. The CPU 25a of the controller 25 can control the electromagnetic valve 91 and the electromagnetic valve 73 such that the salinity when salt water having different concentrations is mixed in the ice storage tank T becomes the target salinity by calculating an amount of seawater discharged from the ice storage tank T and an amount of seawater supplied from the seawater supply pipe 70 when the salinity of the seawater in the ice storage tank T becomes a predetermined value. In this case, the first predetermined condition can be the amount of seawater discharged from the ice storage tank T, and the second predetermined condition can be the amount of seawater supplied from the seawater supply pipe 70.

Water is supplied to the water tank 81 via a control valve 86. A float switch 87 is disposed in the water tank 81, and the control valve 86 is controlled to open and close on the basis of a detection signal from the float switch 87 to start and stop the supply of water to the water tank 81.

Action and Effects of Embodiment 1

In the production apparatus disclosed in ENT LITERATURE 1, the fresh water is poured into the ice storage tank storing the produced sherbet ice to adjust the salinity of the sherbet ice, and thus only sherbet ice having a certain specific salinity can be obtained. When it is desired to refrigerate different types of saltwater fish, it is therefore difficult to adjust the salinity of the sherbet ice to a salinity suitable for the saltwater fish. An object of the present disclosure is to provide an ice supply device and an ice making system capable of adjusting a salinity of sherbet ice supplied to a user.

In Embodiment 1 (embodiment of the ice supply device), the water flow path 80 through which water flows joins the supply path 31 through which the sherbet ice is taken out of the ice storage tank T. As a result, the salinity of the sherbet ice supplied to the user can be easily adjusted by adjusting the flow rate of water to join the supply path 31. When, for example, sherbet ice for refrigerating different types of saltwater fish is required after a predetermined amount of sherbet ice is supplied to the user, the salinity of the sherbet ice can be adjusted only by adjusting the flow rate of water from the water flow path 80 to join to the supply path 31, which improves usability of the ice supply device C.

In Embodiment 1, the pump 38 is disposed downstream of the junction where the water flow path 80 joins the supply path 31 in the flow direction of the sherbet ice. By arranging the pump 38 downstream of the junction in the flow direction of the sherbet ice, one pump allows the sherbet ice and water to flow.

In Embodiment 1, the proportional control valve 83 is disposed in the water flow path 80, and the opening degree and/or the opening time of the proportional control valve 83 are controlled by the CPU 25a of the controller 25 such that the salinity of the sherbet ice after joining becomes a target value. The salinity of the sherbet ice after joining can he adjusted only by controlling the opening degree and/or the opening time of the proportional control valve 83 provided in the water flow path 80.

In Embodiment 1, the temperature sensor 84 that detects the temperature of the sherbet ice is provided downstream of the junction of the supply path 31 and the water flow path 80 in the flow direction of the sherbet ice, and the CPU 25a of the controller 25 controls the opening degree and/or the opening time of the proportional control valve 83 such that the detected temperature becomes a target value. The salinity of the sherbet ice after joining can be adjusted by controlling the proportional control valve 83 using the temperature by detected the temperature sensor 84. In this case, since there is a correlation between the salinity and the temperature of the sherbet ice, the salinity of the sherbet ice can be calculated from the temperature detected by the temperature sensor 84.

In Embodiment 1, the temperature sensor 92 is disposed in the ice storage tank T, and on the basis of the temperature of the seawater before the operation and the temperature of the sherbet ice after the start of the operation that are detected by the temperature sensor 92, the salinity of the sherbet ice is calculated by the CPU 25a of the controller 25. Then, on the basis of the calculated salinity, the salinity of the sherbet ice supplied to the user can be adjusted by adjusting the flow rate of water to join the supply path 31 from the water flow path 80.

In Embodiment 1, the temperature sensor 92 detects the temperature of the sherbet ice, and the CPU 25a of the controller 25 calculates the salinity from the detected temperature. Then, when the calculated salinity is not within a predetermined range, the CPU 25a of the controller 25 prohibits an operation of taking out the sherbet ice in the ice storage tank T. When the salinity of the sherbet ice in the ice storage tank T is excessively low, the IPF of the sherbet ice is also low, and the sherbet ice is not sufficiently used as sherbet ice. By prohibiting the operation of taking out the sherbet ice in the ice storage tank when the detected salinity is not within the predetermined range, the sherbet ice in an insufficient state is prevented from being supplied to the user.

In Embodiment 1, the input unit 26 communicably connected to the controller 25 is provided, the user can take out a desired amount of sherbet ice having a desired salinity from the supply port 39 by inputting the salinity and the amount of sherbet ice to be taken out from the ice storage tank T.

In Embodiment 1, the supply path 31 includes the takeout port 42 for taking out the sherbet ice in the ice storage tank T, and the takeout port 42 is disposed below the liquid level L of the sherbet ice in the ice storage tank T by a predetermined distance. Since fine ice constituting the sherbet ice has a specific gravity smaller than that of seawater, the ice moves upward by buoyancy. Thus, the sherbet ice near the liquid level in the ice storage tank T has an IPF higher than that of the sherbet ice near the bottom surface. By taking out the sherbet ice near the liquid level by the takeout port 42 disposed below the liquid level L of the sherbet ice in the ice storage tank T by a predetermined distance, the sherbet ice having a high IPF can be supplied to the user.

In Embodiment 1 (embodiment of the ice making system), the water flow path 80 through which water flows joins the supply path 31 through which the sherbet ice is taken out of the ice storage tank T. As a result, the salinity of the sherbet ice supplied to the user can be easily adjusted by adjusting the flow rate of water to join the supply path 31. When, for example, sherbet ice for refrigerating different types of saltwater fish is required after a predetermined amount of sherbet ice is supplied to the user, the salinity of the sherbet ice can be easily adjusted only by adjusting the flow rate of water from the water flow path 80 to join to the supply path 31, which improves usability of the ice making system S.

EMBODIMENT 2

FIG. 7 is an explanatory diagram of an ice making system according to Embodiment 2 of the present disclosure. FIG. 8 is an explanatory diagram of a controller of the ice making system illustrated in FIG. 7.

The ice making system S according to the present embodiment includes the ice making device I and the ice supply device C as in Embodiment 1. The ice making system S according to the present embodiment further includes a cooling apparatus 100 and a temperature sensor (third temperature sensor) 103. The cooling apparatus 100 cools water flowing through the water flow path 80. The third temperature sensor 103 detects a temperature of the water cooled by the cooling apparatus 100.

The cooling apparatus 100 and the third temperature sensor 103 according to the present embodiment are disposed in the water tank 81 that is a component of the ice supply device C. The cooling apparatus 100 includes a heat exchanger (third heat exchanger). Hereinafter, the heat exchanger constituting the cooling apparatus 100 is also referred to as a cooling heat exchanger 100. The cooling heat exchanger 100 is inserted into the water tank 81 to exchange heat with water in the water tank 81. The cooling heat exchanger 100 can adopt, for example, a configuration in which a heat transfer tube through which a refrigerant flows is wound in a coil shape.

The cooling heat exchanger 100 according to the present embodiment is supplied with the refrigerant used in the ice making device I. As in Embodiment 1, the ice making device I includes the ice making machine 1 constituting the use-side heat exchanger (second heat exchanger), the compressor 2, the heat source-side heat exchanger 3 (first heat exchanger), the four-way switching valve 4, the use-side expansion valve 5, the heat source-side expansion valve 6, the internal heat exchanger 7, and the receiver 8. These devices are connected by a refrigerant pipe 96 to constitute a refrigerant circuit 95.

A first branch pipe 97 branches from a refrigerant pipe 96a between an outflow portion 3a of the liquid refrigerant in the heat source-side heat exchanger 3 and the use-side expansion valve 5, specifically, from the refrigerant pipe 96a between the receiver 8 and the internal heat exchanger 7. A second branch pipe 98 branches from a refrigerant pipe 96b between an outflow portion 1a of a gas refrigerant in the ice making machine 1 and a suction portion 2a of a gas refrigerant of the compressor 2, specifically, from the refrigerant pipe 96b between the internal heat exchanger 7 and the four-way switching valve 4. The first branch pipe 97 is connected to a refrigerant inlet 100a of the cooling heat exchanger 100. The second branch pipe 98 is connected to a refrigerant outlet 100b of the cooling heat exchanger 100.

The refrigerant having dissipated heat in the heat source-side heat exchanger 3 passes through the heat source-side expansion valve 6 and the receiver 8, branches from the refrigerant pipe 96a to the first branch pipe 97, and flows into the cooling heat exchanger 100. The refrigerant having passed through the cooling heat exchanger 100 passes through the second branch pipe 98, joins the refrigerant pipe 96b, passes through the four-way switching valve 4, and is sucked into the compressor 2. The cooling heat exchanger 100 is provided in the refrigerant circuit 95 in parallel with the ice making machine 1.

The first branch pipe 97 is provided with a cooling expansion valve 101 that decompresses the refrigerant. The liquid refrigerant flowing through the first branch pipe 97 is decompressed by the cooling expansion valve 101 to become a low-temperature low-pressure gas-liquid two-phase refrigerant, and is supplied to the cooling heat exchanger 100. The cooling heat exchanger 100 causes heat exchange between the water in the water tank 81 and the refrigerant. By this heat exchange, the refrigerant absorbs heat from the water in the water tank 81 and evaporates, and the water in the water tank 81 is cooled.

The cooling expansion valve 101 is opened to supply the refrigerant to the cooling heat exchanger 100, and is closed to stop supplying the refrigerant to the cooling heat exchanger 100. Thus, the cooling expansion valve 101 functions as a control valve that controls the flow of the refrigerant to the cooling heat exchanger 100. The cooling expansion valve 101 opens and closes on the basis of the temperature detected by the third temperature sensor 103. Specifically, when the temperature detected by the third temperature sensor 103 exceeds a predetermined upper limit temperature T_th1, the cooling expansion valve 101 is opened to cool the water in the water tank 81. Specifically, when the temperature detected by the third temperature sensor 103 exceeds a predetermined lower limit temperature T_th2, the cooling expansion valve 101 is closed to stop cooling the water in the water tank 81. The upper limit temperature T_th1 can be set to a temperature at which the sherbet ice having joined the water in the supply path 31 does not excessively melt. For example, the upper limit temperature T_th1 can be set to 5° C. The lower limit temperature T_th2 can be set to a temperature at which the water in the water tank 81 does not freeze. For example, the lower limit temperature T_th2 can be set to 2° C. By setting the lower limit temperature T_th2 to a temperature at which the water does not freeze, the sherbet ice and water can be prevented from being unable to join together.

The third temperature sensor 103 is disposed in a lower part of the water tank 81 (below a center of the water tank 81 in the vertical direction). Thus, a lower temperature of the water in the water tank 81 can be detected. The third temperature sensor 103 is preferably disposed below the cooling heat exchanger 100. The third temperature sensor 103 is more preferably disposed near a bottom surface of the water tank 81.

The second branch pipe 98 is provided with a fifth temperature sensor 105. The fifth temperature sensor 105 detects a temperature of the refrigerant having passed through the cooling heat exchanger 100. When the cooling expansion valve 101 is open, an opening deuce of the cooling expansion valve 101 is adjusted such that a degree of superheating of the refrigerant obtained using a detection result of the fifth temperature sensor 105 becomes a predetermined set value.

An opening and closing operation of the cooling expansion valve 101 is controlled by the control unit (second control unit) 27 of the ice making device I. As the controller 25 of the ice supply device C, the control unit 27 includes a CPU 27a, a memory 27b such as a RAM and a ROM, and a transmission and reception unit 27c that performs transmission to and reception from external devices, sensors, and the like. The control unit 27 achieves various kinds of control concerning the operation of the ice making system S, including the operation control of the ice making device I, in such a manner that the CPU 27a executes a computer program stored in the memory 27b. The control unit 27 controls driving of the compressor 2, the four-way switching valve 4, the expansion valves 5, 6, and 101, and the like. The control unit 27 receives a detection signal from the fifth temperature sensor 105 or the like through the transmission and reception unit 27c. The control unit 27 is communicably connected to the controller 25 of the ice supply device C, and acquires detection results of the temperature sensors 103 and 104 and the like received by the controller 25.

The water flow path 80 is provided with a fourth temperature sensor 104. The fourth temperature sensor 104 detects the temperature of water immediately before joining the supply path 31. When the temperature of the water joining the supply path 31 is high, the sherbet ice after joining is easily melted, and there is a possibility that the salinity of the sherbet ice decreases and the temperature rapidly increases. Therefore, the temperature of the water before joining is detected by the fourth temperature sensor 104, and the opening degree of the proportional control valve 83 is adjusted on the basis of the detection result. The opening degree of the proportional control valve 83 is adjusted by the controller 25 as in Embodiment 1.

Water Temperature Control in Water Tank

FIG. 9 is a flowchart illustrating an example of water temperature control in the water tank.

The control unit 27 cools the water in the water tank 81 in accordance with a procedure illustrated in FIG. 9 and maintains a water temperature within a predetermined range. The control unit 27 first acquires a water temperature T by receiving a detection signal from the third temperature sensor 103 in the water tank 81 (step S11).

Next, the control unit 27 determines whether the water temperature T exceeds the predetermined upper limit temperature T_th1 (step S12). The upper limit temperature T_th1 can be set to 5° C. as described above. When a determination in step S12 is positive (YES), the control unit 27 performs control to open the cooling expansion valve 101 in order to cool the water in the water tank 81 (step S13).

When the determination in step S12 is negative (NO), the control unit 27 further determines whether the water temperature T is lower than the predetermined lower limit temperature T_th2 (step S14). The lower limit temperature T_th2 can be set to 2° C. as described above. When a determination in step S14 is positive (YES), the control unit 27 performs control to close the cooling expansion valve 101 (step S15). Specifically, the control unit 27 closes the cooling expansion valve 101 when the cooling expansion valve 101 is open, and maintains a dosed state when the cooling expansion valve 101 is closed. As a result, cooling of the water in the water tank 81 is stopped.

When the determination in step S14 is negative (NO), the control unit 27 maintains an open or close state of the cooling expansion valve 101 (step S16). Specifically, the control unit 27 maintains an open state when the cooling expansion valve 101 is open, and maintains a closed state when the cooling expansion valve 101 is closed.

The control unit 27 can maintain the temperature of the water in the water tank 81 within a predetermined range from T_th1 to T_th2 by repeating the above procedure.

Control of Proportional Control Valve

The controller 25 according to the present embodiment adjusts the opening degree of the proportional control valve 83 in accordance with the temperature of the water flowing through the water flow path 80. Specifically, the controller 25 obtains an amount of water to join the sherbet ice in the ice storage tank T from the temperature (salinity) of the sherbet ice in the ice storage tank T, the temperature (salinity) of the sherbet ice that the user wants to take out, and the temperature of the water to join the sherbet ice, and adjusts the opening degree of the proportional control valve 83.

For example, when the sherbet ice in the ice storage tank T is at −3° C. and the sherbet ice at −1.5° C. as a set temperature is taken out, the controller 25 makes the opening degree of the proportional control valve 83 different between when the temperature of the water flowing through the water flow path 80 is 2° C. and when the temperature is 5° C. Specifically, the controller 25 makes the opening degree of the proportional control valve 83 smaller when the water temperature is 5° C. than when the water temperature is 2° C.

Assuming that the opening degree of the proportional control valve 83 is the same between when the temperature of the water is 2° C. and when the temperature of the water is 5° C., the IPF of the sherbet ice changes more greatly and the temperature of the sherbet ice reaches the set temperature more quickly when the water at 5° C. joins than when the water at 2° C. joins. Therefore, there is a high possibility that the temperature of the sherbet ice exceeds the set temperature.

When the water temperature is 5° C., the controller 25 according to the present embodiment makes the opening degree of the proportional control valve 83 smaller than the opening degree when the water temperature is 2° C. to decrease the change in the IPF and increase the time to reach the set temperature. It is therefore possible to prevent the temperature of the sherbet ice from exceeding the set temperature.

In the present embodiment, since the water temperature in the water tank 81 is controlled to 2° C. to 5° C., the controller 25 sets the lowest 2° C. as a “reference temperature” and sets the opening degree of the proportional control valve 83 at this time as a “reference opening degree”. When the water temperature exceeds the reference temperature, the controller 25 operates the opening degree of the proportional control valve 83 from the reference opening degree in a closing direction. The controller 25 is configured to operate the opening degree of the proportional control valve 83 to be larger in the closing direction as the temperature of water in excess of the reference temperature increases.

FIG. 10 is a flowchart illustrating an example of the control of the proportional control valve.

The controller 25 controls the opening degree of the proportional control valve by, a procedure illustrated in FIG. 10 to adjust the temperature of the sherbet ice to the set temperature. The controller 25 first acquires the water temperature by receiving a detection signal from the fourth temperature sensor 104 in the water flow path 80 (step S21).

Next, the controller 25 calculates a difference between the water temperature and a reference temperature (for example, 2° C.) (step S22). Then, the controller 25 calculates an operation amount (closing amount) of the proportional control valve 83 from the reference opening degree using the difference (step S23).

Next, the controller 25 operates the proportional control valve 83 in accordance with the calculated operation amount to join the water from the water flow path 80 to the supply path 31 (step S24).

Action and Effects of Embodiment 2

The ice supply device C and the ice making system S according to Embodiment 2 have the following action and effects in addition to the action and effects in Embodiment 1.

In the ice supply device C according to Embodiment 2, the cooled water flows in the water flow path 80. It is therefore possible to prevent the sherbet ice from being melted by the joined water and to supply the sherbet ice having a high IPF to the user.

In Embodiment 2, the ice supply device C includes the cooling apparatus 100 that cools the water flowing through the water flow path 80. It is therefore possible to prevent the sherbet ice from being melted by the joined water and to supply the sherbet ice having a high IPF to the user.

The ice making system S according to Embodiment 2 includes the refrigerant circuit 95 that produces sherbet ice and the ice supply device C. Thus, the sherbet ice produced by the refrigerant circuit 95 can be stored in the ice storage tank T, and water can join to the supply path 31 through which the sherbet ice is taken out of the ice storage tank T. Accordingly, a salinity of the sherbet ice supplied to a user can be adjusted.

In Embodiment 2, the refrigerant circuit 95 includes the compressor 2, the heat source-side heat exchanger (first heat exchanger) 3 that dissipates heat from the refrigerant compressed by the compressor 2, and the ice making machine 1 which is the use-side heat exchanger (second heat exchanger) that exchanges heat between the refrigerant having dissipated heat in the heat source-side heat exchanger 3 and a medium to he cooled serving as a raw material of sherbet ice to cool the medium to he cooled. Therefore, the medium to be cooled can be cooled by the refrigerant flowing through the refrigerant circuit 95 to produce sherbet ice.

In Embodiment 2, the refrigerant circuit 95 further includes the cooling heat exchanger (third heat exchanger) 100 that exchanges heat between the refrigerant having dissipated heat in the heat source-side heat exchanger 3 and water to be flowed through the water flow path 80 to cool the water. Therefore, the water flowing through the water flow path 80 can be cooled using the refrigerant of the refrigerant circuit 95 that produces the sherbet ice.

In Embodiment 2, the water tank 81 that stores water cooled by the cooling heat exchanger 100 is further provided. Therefore, the cooled water can he stably supplied to the supply path 31.

In Embodiment 2, provided are the third temperature sensor 103 that detects the temperature of the water in the water tank 81, the cooling expansion valve (control valve) 101 that controls the flow of the refrigerant in the cooling heat exchanger 100, and the control unit (second control unit) 27 that controls the operation of the cooling expansion valve 101 on the basis of the temperature detected by the third temperature sensor 103. Thus, the temperature of the water in the water tank 81 can be controlled appropriately.

In Embodiment 2, the third temperature sensor 103 is disposed in a lower part of the inside of the water tank 81. Therefore, a temperature as low as possible of the water stored in the water tank 81 can be detected, and by controlling the operation of the cooling expansion valve 101 on the basis of this temperature, it is possible to prevent the water in the water tank 81 from being cooled more than necessary (frozen).

OTHER MODIFICATIONS

The present disclosure should not be limited to the embodiments described above, and can be variously modified within the scope of the claims.

For example, in the embodiments, the ice storage tank has a rectangular cylindrical shape having a rectangular horizontal cross section, but the present disclosure is not limited thereto. The ice storage tank may he a tank having a cylindrical shape with a circular horizontal cross section, or a tank having a polygonal horizontal cross section.

Instead of the evaporator according to the embodiments, for example, an evaporator in which a refrigerant is ejected by a nozzle into the annular space between the inner pipe and the outer pipe can be used.

Further, in the embodiments, the horizontal double pipe ice making machine in which the axes of the inner pipe and the outer pipe are disposed horizontally is exemplified as the ice making machine. However, the configuration of the ice making machine is not limited in the present disclosure, and ice making machines having various shapes and structures, such as a vertical double pipe ice making machine in which the axes of the inner pipe and the outer pipe are disposed vertically can be adopted.

In the embodiments, the adjustment of the salinity and the amount of the sherbet ice supplied to the user, which are input to the input unit 26, is not illustrated. However, for example, the salinity of the sherbet ice can be adjusted by controlling the opening degree of the proportional control valve 83 to set a value detected by the first temperature sensor 84 to a temperature corresponding to the target salinity. The supply amount of sherbet ice can be adjusted by providing a sensor (not illustrated) capable of measuring a flow rate near the electromagnetic valve 37 and by opening the electromagnetic valve 37 for a time until a target amount of sherbet ice is supplied.

In Embodiment 2, the cooling heat exchanger as the cooling apparatus may be disposed outside the water tank. In this case, a water circuit that draws water from the water tank by a pump to circulate can he provided, and the cooling heat exchanger can be provided in the water circuit.

In Embodiment 2, the cooling heat exchanger as the cooling apparatus may be provided in a refrigerant circuit other than the refrigerant circuit in the ice making device. The cooling apparatus need not use a refrigerant.

In Embodiment 2, the water temperature is detected by the temperature sensor provided in the water flow path for the control of the proportional control valve, but the water temperature may be detected by the temperature sensor in the water tank. However, the proportional control valve can be controlled more accurately by detecting the water temperature immediately before joining the supply path by the temperature sensor provided in the water flow path.

In Embodiment 2, the control of the proportional control valve may be feedback control based on the temperature or salinity of the sherbet ice after joining to the water.

In Embodiment 2, a temperature sensor may be provided not only in the lower part but also in the upper part of the water tank.

In Embodiment 2, the temperature range of the water in the water tank is exemplified as 2° C. to 5° C., but may be a temperature range different from this temperature range.

Claims

1. An ice supply device comprising:

an ice storage tank configured to store sherbet ice;

a supply path through which sherbet ice may be taken out of the ice storage tank; and

a water flow path that joins the supply path, the water flow path being configured to carry flow of water therethrough.

2. The ice supply device according to claim 1, further comprising:

a pump disposed downstream of a junction at which the water flow path joins the supply path in a flow direction of the sherbet ice.

3. The ice supply device according to claim 1, further comprising:

a flow rate regulating valve provided in the water flow path; and

a. control unit configured to control the flow rate regulating valve to control a salinity of the sherbet ice after joining the flow of water to become a target value.

4. The ice supply device according to claim 3, further comprising:

one of a first temperature sensor arranged to detect a temperature of the sherbet ice and a first concentration sensor arranged to detect a salinity of the sherbet ice downstream of the junction in the flow direction of the sherbet ice,

the control unit being configured to control the flow rate regulating valve so that the temperature detected by the first temperature sensor or the salinity detected by the first concentration sensor becomes a target value.

5. The ice supply device according to claim 3, further comprising:

a first temperature sensor arranged to detect a temperature of the sherbet ice downstream of the junction in the flow direction of the sherbet ice,

the control unit being configured to calculate a salinity from the temperature detected by the first temperature sensor and control the flow rate regulating valve so that the salinity calculated becomes a target value.

6. The ice supply device according to claim 3, wherein

the control unit is configured to control at least one of an opening degree and an opening time of the flow rate regulating valve.

7. The ice supply device according to claim 3, further comprising:

a second concentration sensor arranged to detect a salinity of the sherbet ice in the ice storage tank, wherein

the control unit prohibits an operation of taking out the sherbet ice in the ice storage tank when the salinity detected by the second concentration sensor is not within a predetermined range.

8. The ice supply device according to claim 1, further comprising:

a second temperature sensor arranged to detect a temperature of sherbet ice in the ice storage tank; and

a salinity calculation unit configured to calculate a salinity of the sherbet ice based on a temperature of a medium to be cooled supplied to the ice storage tank, the temperature of the medium to be cooled being detected by the second temperature sensor before an operation of an ice making device, and a temperature of the sherbet ice stored in the ice storage tank, the temperature of the sherbet ice being detected by the second temperature sensor after a start of the operation of the ice making device.

9. The ice supply device according to claim 1, further comprising

an input unit configured to receive a salinity and an amount of the sherbet ice taken out from the ice storage tank.

10. The ice supply device according to claim 1, wherein

the supply path includes a takeout port through which the sherbet ice in the ice storage tank is taken out, the takeout port being disposed in the ice storage tank, and

the takeout port is disposed below a liquid level of the sherbet ice in the ice storage tank by a predetermined distance.

11. The ice supply device according to claim 1, wherein

the water is cooled water that flows through the water flow path.

12. The ice supply device according to claim 1 further comprising:

a cooling apparatus configured to cool the water that flows through the water flow path.

13. An ice making system including the ice supply device according to claim 1, the ice making system further comprising:

a refrigerant circuit that produces the sherbet ice.

14. The ice making system according to claim 13, wherein

the refrigerant circuit includes a compressor, a first heat exchanger configured to dissipate heat from a refrigerant compressed by the compressor, and a second heat exchanger configured to exchange heat between the refrigerant having dissipated heat in the first heat exchanger and a medium to be cooled serving as a raw material of the sherbet ice and cool the medium to be cooled.

15. The ice making system according to claim 14, wherein

the refrigerant circuit further includes a third heat exchanger configured to exchange heat between the refrigerant having dissipated heat in the first heat exchanger and the flow of water through the water flow path and cool the water.

16. The ice making system according to claim 15, further comprising:

a water tank that stores the water cooled by the third heat exchanger.

17. The ice making system according to claim 16, further comprising:

a third temperature sensor arranged to detect a temperature of the water in the water tank;

a control valve configured to control a flow of the refrigerant in the third heat exchanger; and

a second control unit configured to control an operation of the control valve based on the temperature detected by the third temperature sensor.

18. The ice making system according to claim 17, wherein

the third temperature sensor is disposed in a lower part of an inside of the water tank.

19. An ice making system including the ice supply device according to claim 1, the ice making system thither comprising:

an ice making device.