JP4393275B2 - Ice temperature storage and ice temperature storage method - Google Patents

Description

  The present invention relates to an ice temperature storage for storing fresh food products in a temperature range of −3 ° C. to 0 ° C. in which fresh food products can be refrigerated and stored with good freshness. The present invention relates to an ice temperature storage and an ice temperature storage method that do not alter the quality of fresh food.

  For refrigerated storage of fresh food products, storage in the temperature range of −3 ° C. to 0 ° C., that is, in the ice temperature range is considered optimal. Preserving fresh food products in this temperature zone ensures that the fresh food products do not deteriorate over time and prevent microbial growth, thus maintaining the freshness, flavor and feel of the stored fresh food products. Will be. In addition, in this temperature range, the water in the fresh food product inner cells does not freeze, so the water volume does not increase, and the cell membrane and cell wall of the fresh food inner cells are not broken. It does not produce the drip found in fresh food such as meat.

Patent Document 1 proposes an ice temperature storage for maintaining a temperature range of an ice temperature range and preserving fresh food products.
FIG. 9 shows a schematic diagram of an ice temperature storage proposed in Patent Document 1.
The ice temperature storage proposed in Patent Document 1 includes an ice making machine (M) for producing fine ice, and a food storage (R) connected to the ice making machine (M) via a pipe.
The outer wall (O) of the food storage (R) has a heat insulating material, and prevents heat from being transferred from the outside air into the food storage (R). A first inner wall (W1) having a large number of openings is disposed along the outer wall (O) in the food storage (R). Fine ice produced by an ice making machine (M) is enclosed between the outer wall (O) and the first inner wall (W1).
A second inner wall (W2) is disposed further inside the space formed by the first inner wall (W1), and a plurality of air for circulating the air inside the food storage (R) is disposed on the second inner wall. A circulation hole is formed, and a circulation passage is formed between the first inner wall (W1) and the second inner wall (W2). A fan (F) for circulating air is disposed in the circulation passage.

  The ice temperature storage of the above structure is the ice temperature range by blowing cold air to the food in the food storage (R) by the fine ice laid on the inner wall of the food storage (R) and the air circulating in the food storage (R) The food is preserved at

JP-A-7-63458

A cold air flow type ice temperature storage like the above structure has the following problems.
First, the larger the food storage, the more difficult it is to maintain the ice temperature range, which is a narrow temperature zone of -3 ° C to 0 ° C inside the food storage. Therefore, it is very difficult to store a large amount of food with good freshness.
Next, since the cooling method is based on the convection of cold air, partial freezing occurs in a portion where the cold air directly hits, and in a portion where the cold air does not hit, the temperature becomes 0 ° C. or higher and a sufficient cooling preservation effect cannot be obtained. There is a problem. Accordingly, there is a problem that in the portion where the cold air is directly applied, the stored food becomes frozen and the freshness is lowered, and in the portion where the cold air is not applied, the portion is not cooled and rotten. Under supercooling, fruit and vegetable foods, in particular, can cause low-temperature damages that are dark or dent.
Moreover, since it is a structure which cools by introduce | transducing cold air, the problem that a foodstuff dries was unavoidable.
The present invention has been made in view of the above circumstances, and it is possible to accurately maintain the temperature in the ice temperature region throughout the food storage space even in a large food storage space, and the alteration of the stored food It is an object to provide an ice temperature storage and an ice temperature storage method capable of preventing the above.

The invention according to claim 1 is an ice maker that produces sherbet-like ice, a pipeline that feeds out sherbet-like ice produced by the ice maker, and a food that is connected to the pipeline and stores food. The storage space, the space surrounding the food is filled with sherbet-shaped ice sent from the pipeline , the pipeline receiving the sherbet-shaped ice produced by the ice making machine, the ice receiving tank, Connected to the supply pump, connected to the supply pump and communicated with the upper part of the food storage, a discharge pipe extending from the bottom of the food storage, connected to the discharge pipe, and discharged from the discharge pipe A circulation pump for circulating sherbet-shaped ice to the upper part of the food storage, and a shear fed from the circulation pump The Tsu bets like ice is ice temperature reservoir, characterized in that it consists of circulating pipe for guiding to the food storage top.
The invention according to claim 2 is the ice temperature storage according to claim 1 , wherein a differential pressure gauge for measuring a pressure loss in the circulation pipe is disposed in the middle of the circulation pipe path.
The invention according to claim 3 includes a branch pipe connected to the ice making machine in the middle of the circulation pipe path, and is arranged in the middle of the branch pipe path when a measured value of the differential pressure gauge becomes a predetermined value or less. The sherbet-shaped ice supplied with the desired IPF is converted into the sherbet-shaped ice provided with the desired IPF, and the sherbet-shaped ice provided with the desired IPF is fed into the food storage by the pipeline. The ice temperature storage according to claim 2 , wherein the ice temperature storage is supplied.
The invention according to claim 4 includes a branch pipe connected to the ice making machine in the middle of the circulation pipe path, and stops the circulation pump when a measured value of the differential pressure gauge becomes a predetermined value or more. The ice temperature storage according to claim 2, wherein a heater disposed in the pipeline is operated .

According to a fifth aspect of the present invention, there is provided a manufacturing process for manufacturing a sherbet-shaped ice, a supply process for supplying the sherbet-shaped ice manufactured in the manufacturing process to a food storage for storing food, and the food storage The sherbet-shaped ice supplied is composed of a circulation step of discharging from the bottom of the food storage and circulating to the top of the food storage. In the supply step, the sherbet-shaped ice supplied into the food storage is It meets the ambient space, in the circulation step, and differential pressure detecting step of measuring the pressure loss of the flow of sherbet ice circulating from the food storage bottom to the food reservoir top, sherbet-like ice in said food storage Comprising the step of replacing, when the pressure loss value detected in the differential pressure detecting step is less than or equal to a predetermined value, A step of switching a circulation path from the bottom of the food storage to the top of the food storage to a path from the bottom of the food storage to an ice making machine for producing sherbet-like ice; and from the sherbet-like ice supplied to the ice making machine to a desired An ice temperature storage method comprising the steps of producing a sherbet-like ice having an IPF and supplying a sherbet-like ice having the desired IPF from an ice making machine to the food storage.

According to invention of Claim 1, the foodstuff accommodated in the food storage is wrapped in the sherbet-like ice which has fluidity | liquidity, and is cooled uniformly. In addition, since a certain temperature is maintained until the sherbet-like ice is completely solidified and completely melted, the temperature inside the food storage can be accurately measured even if a large-capacity food storage is used. Can be controlled.
Further , sherbet-like ice can be circulated from the bottom of the food storage toward the top, and the sherbet-like ice is prevented from consolidating in the food storage.
According to the second aspect of the present invention, the content (IPF) of the ice component in the circulating sherbet-like ice is detected by measuring the pressure loss of the circulating sherbet-like ice flow. It becomes possible to know the condition of the sherbet-like ice in the food storage.
According to the third aspect of the present invention, when the sherbet-like ice in the food storage becomes below the predetermined IPF, a part of the sherbet-like ice in the food storage is sent to the ice making machine, and the ice making machine is sent in The ice thus obtained is changed into a sherbet-like ice having a desired IPF, and the sherbet-like ice having the desired IPF is supplied again into the food storage, so that the IPF of the sherbet-like ice flowing in the ice temperature storage is kept constant. Can be in range.
According to the fourth aspect of the present invention, clogging of the circulation path of the sherbet-like ice can be detected by the differential pressure gauge, and the ice block that causes clogging can be melted by warming the pipeline with the heater. It becomes possible to prevent the problem of the circulation of the ice. As a result, it is possible to prevent the water component and ice component of the sherbet-like ice from being separated due to the circulation stop, and stable ice temperature storage becomes possible. Also, by stopping the circulation pump, the pipe can be prevented from bursting, and safe ice temperature storage becomes possible .

According to invention of Claim 5, the foodstuff accommodated in the food storage is wrapped in the sherbet-like ice which has fluidity | liquidity, and is cooled uniformly. In addition, since a certain temperature is maintained until the sherbet-like ice is completely solidified and completely melted, the temperature inside the food storage can be accurately measured even if a large-capacity food storage is used. Can be controlled. Further, sherbet-like ice can be circulated from the bottom of the food storage toward the top, and the sherbet-like ice is prevented from consolidating in the food storage.
In addition, by measuring the pressure loss of the circulating sherbet-like ice flow, it becomes possible to detect the content (IPF) of the ice component in the circulating sherbet-like ice, and in the food storage It becomes possible to know the state of the sherbet-like ice. Further, when the sherbet-like ice in the food storage becomes below a predetermined IPF, a part of the sherbet-like ice in the food storage is sent to the ice making machine, and the ice fed into the ice making machine is supplied with the desired IPF. Since the sherbet-like ice provided and the sherbet-like ice provided with the desired IPF are supplied again into the food storage, the IPF of the sherbet-like ice flowing in the ice temperature storage can be kept within a certain range.

Hereinafter, an embodiment of an ice temperature storage according to the present invention will be described with reference to the drawings. FIG. 1 is a schematic view of an ice temperature storage according to the present invention. FIG. 1A is a plan view of the ice temperature storage, FIG. 1B is a front view of the ice temperature storage, and FIG. 1C is a right side view of the ice temperature storage.
The ice temperature storage (1) according to the present invention connects an ice making machine (2) for producing sherbet-shaped ice, a food storage (3) for storing food, an ice making machine (2) and a food storage (3). And a pipeline (4) for supplying sherbet-shaped ice from the ice making machine (2) to the food storage (3).

The ice making machine (2) is connected to the refrigerant device (21) via a pipe, and the refrigerant is supplied to the ice making machine (2), whereby the ice making machine (2) is cooled and sherbet-like ice is produced. The
Here, the sherbet-like ice refers to ice having fluidity in which moisture and fine ice pieces are united. The fluidity of the sherbet-like ice is expressed by the content of fine ice components (hereinafter referred to as IPF) in the sherbet-like ice. When the IPF is 0%, the sherbet-like ice has no ice components at all. When the IPF is 100%, the sherbet-like ice is formed only by fine powdery snow-like ice pieces. Further, when the IPF is 50% or more, the sherbet-like ice becomes semi-solid and has almost no fluidity.
The sherbet-like ice according to the present invention is preferably composed of seawater whose salinity is adjusted to be higher than 0% and lower than 5%, and deep seawater collected at a depth of 200 m or more is used as the seawater. preferable.
The ice making machine (2) is not particularly limited as long as it can produce sherbet-like ice, but an ice making machine (2) having a structure shown in FIG. 2 can be exemplified.

FIG. 2 shows a schematic structure of the ice making machine (2).
The ice making machine (2) includes a substantially cylindrical drum body (201) partitioned into three sections, and the drum body (201) can be tilted in the vertical direction. The sections of the drum body (201) are an ice making part (202), a stirring part (203) and a transfer part (204) from the left in FIG.
A rotating shaft (205) passes through the inner central axis of the drum body (201). A scraper blade (251) for scraping off ice components adhering to the inner wall of the ice making part (202) is formed at a portion of the rotating shaft (205) located at the ice making part (202). A stirring blade (252) for stirring the sherbet-shaped ice fed from the ice making unit (202) is formed in a portion of the rotating shaft (205) positioned at the stirring unit (203). An auger screw (253) for feeding the sherbet-shaped ice fed from the stirring unit (203) to the ice take-out port (206) is formed in a portion located in the transfer unit (204) of the rotating shaft (205). .

A refrigerant passage (207) is provided on the outer periphery of the drum body (201), and the refrigerant passage (207) surrounding the ice making portion (202) is a first refrigerant passage (271), and the stirring portion (203) and the transfer portion (204). ) Surrounding the refrigerant passage (207) is a second refrigerant passage (272). The first refrigerant passage (271) and the second refrigerant passage (272) are divided by a partition wall (273) formed on the outer periphery of the drum body (201) near the boundary between the ice making part (202) and the stirring part (203). ing.
The first refrigerant passage (271) and the second refrigerant passage (272) are provided with refrigerant supply ports (274, 275), respectively, and the refrigerant supply ports (274, 275) are separate from the refrigerant device (21) shown in FIG. Connected to. Thus, the refrigerant is separately and independently supplied from the refrigerant device (21) to the first refrigerant passage (271) and the second refrigerant passage (272). The temperature of the refrigerant flowing through the second refrigerant passage (272) is set lower than the temperature of the refrigerant flowing through the first refrigerant passage (271).
The first refrigerant passage (271) and the second refrigerant passage (272) further include a refrigerant outlet (276, 277), and the refrigerant outlet (276, 277) and the refrigerant device (21) are connected to each other. The refrigerant that has passed through the refrigerant passage (271) and the second refrigerant passage (272) is separately circulated to the refrigerant device (21).

A seawater supply port (221) is formed at the lower end of the ice making unit (202). The seawater supply port (221) is connected to a replenishment tank (209) that stores seawater. Thereby, seawater can be supplied into the ice making unit (202).
The ice making unit (202) includes an air supply port (222) for supplying air into the ice making unit (202).

  The ice making machine (2) further includes a control unit for controlling the opening / closing of a valve for controlling the flow rate of seawater into the ice making machine (2) and the rotational speed of the rotating shaft (205), and the internal temperature of the ice making machine (2). A temperature sensor for measuring the temperature is provided. Moreover, the control part is provided with a timer, and can measure the inflow amount of seawater into the ice making machine (2) by opening the valve for controlling the inflow amount of seawater and measuring time by the timer.

In the ice making machine (2) having the above structure, first, the control unit opens a valve arranged in a path connecting the replenishing tank (209) and the seawater supply port (221). Thereby, seawater is supplied in the ice making part (202). The seawater supply amount is measured by the opening degree of the valve and the seawater supply time measured by a timer.
Seawater supplied to the ice making section (202) is cooled by the refrigerant flowing through the first refrigerant passage (271), and adheres to the inner wall surface of the ice making section (202) as an ice layer. The ice layer formed on the inner wall surface of the ice making part (202) by the rotation of the rotating shaft (205) is scraped off by the scraping blade (251). At this time, air is supplied from the air supply port (222), and the air adheres around the scraped fine ice pieces to prevent the ice pieces and seawater from being separated. If the drum body (201) is inclined upward in the downstream direction, the supplied air flows toward the downstream process, and exhibits the effect of preventing separation of ice pieces and seawater over the entire drum body. It becomes possible to do.

The sherbet-like ice formed by the ice making unit (202) is sent to the stirring unit (203) as the seawater is supplied.
Here, since the refrigerant flowing through the second refrigerant passage (272) has a lower temperature than the refrigerant flowing through the first refrigerant passage (271), the sherbet-shaped ice is further cooled. Here, the IPF of the sherbet-like ice further increases. The volume of the sherbet-like ice increases as the IPF increases, and this increased amount of sherbet-like ice is sent to the ice take-out port (206) by the auger screw (253).

Here, the IPF of the sherbet-like ice is the refrigerant temperature, the refrigerant flow rate flowing through the first refrigerant passage (271) and the second refrigerant passage (272), the rotational speed of the rotary shaft (205), or into the ice making machine (2). The amount of seawater is appropriately adjusted.
In the present embodiment, the IPF of the sherbet-like ice produced is preferably less than 40%. When the IPF is 40% or more, the food storage (3) corner of the pipeline (4), the valve or pump inlet provided in the pipeline (4), the bent pipe or throttle in the pipeline (4) The sherbet-like ice is consolidated in the pipe, and the sherbet-like ice is supplied to the food storage (3), the sherbet-like ice is circulated inside the food storage (3), or the sherbet from the food storage (3). Will cause problems in the discharge of ice. Furthermore, the IPF of the sherbet-like ice is preferably 30% or less. If the IPF is 30% or less, since it has high fluidity, clogging in the pipeline (4) of the ice temperature storage (1) can be surely prevented, and the temperature change caused by the transfer of heat is further increased. It will be reduced.

The sherbet-shaped ice produced as described above is supplied to the food storage (3) by the pipeline (4).
As shown in FIG. 1, the food storage (3) is divided into a plurality of sections (31) (FIG. 1 shows an example divided into four sections). Each compartment (31) is provided with a supply port (32) for introducing sherbet-like ice therein, and each supply port (32) is connected to the pipeline (2).
A mesh cage (33) of a mesh container is attached to each compartment (32). The net cage (33) may be made of a flexible material such as a string as long as it is a net-like body having a plurality of openings, or may be made of a material that is not easily deformed such as a metal. In the example shown in FIG. 1, a mesh screen (33) formed from a plastic resin is shown. By forming the mesh cage (33) from the plastic resin, the mesh mesh (33) has an appropriate degree of flexibility, so that the food contained in the mesh cage (33) is less likely to be damaged, and corrosion such as rust occurs. It becomes difficult.

1 has a cross-sectional shape substantially equal to the cross-sectional shape defined by the inner wall surface of each compartment (31) formed in the food storage (3), and the net cage (33) is a food product. The storage (3) can be freely inserted into and removed from each compartment. Moreover, it is preferable that an appropriate space is formed between the bottom surface of each section (31) and the net cage (33). As will be described later, since the discharge port (34) for discharging the sherbet-like ice is provided on the bottom surface of each compartment (31), the food contained in the net cage (33) is formed by forming a space. It is possible to prevent the flow of the sherbet-like ice in the vicinity of the discharge port (34).
As will be described later, the bottom surface of each compartment (31) forms a tapered space (35) that narrows downward, but the bottom of the net cage (33) is attached to the food storage (3). At the same time, it is made to coincide with the upper end surface of the taper space (35).
The size of the mesh of the mesh basket (33) is not particularly limited as long as it is smaller than the size of the food contained in the mesh basket (33).
In addition, a lid can be attached to the upper surface of the food storage (3) (not shown), and the food storage (3) can be sealed after the mesh basket (33) is accommodated in the food storage (3). To do.

Each section (31) shown in FIG. 1 has a substantially rectangular cross section in plan view, but the cross-sectional shape is not particularly limited to the example shown in FIG. 1, and a desired shape such as a circle or an ellipse can be adopted as appropriate. It is.
In the example shown in FIG. 1, each section (31) extends downward from the food storage space (36) and the rectangular parallelepiped-shaped food storage space (36) extending from the upper surface of the food storage (3). It consists of a pyramid-shaped taper space (35) that narrows downward.
At the lower end of the taper space (35), there is provided a discharge port (34) that can discharge the sherbet-like ice supplied to the food storage (3).
In addition, it is preferable that a heat insulating material is arrange | positioned in the outer wall surface of a food storage (3), an inner wall surface, or a wall. By disposing the heat insulating material, it is possible to block the inflow of heat from the outside of the food storage (3), and it is possible to maintain the ice temperature region in the food storage (3) for a long time.

FIG. 3 is a schematic diagram of the route of the pipeline (4).
The pipeline (4) includes an ice receiving tank (41) disposed immediately below the ice making machine (2), a supply pump (42) connected to the ice receiving tank (41) via a pipe, a supply pipe (42), Connected and extended from a supply pipe (43) for guiding the sherbet-shaped ice fed from the supply pipe (42) to the upper part of the food storage (3) and a discharge port (34) formed on the bottom of the food storage (3). A discharge pipe (44) to be installed, a circulation pump (45) for circulating the sherbet-like ice discharged through the discharge pipe (44) to the upper part of the food storage (3), and a sherbet-like shape fed from the circulation pump (45) It consists of a circulation pipe (46) for guiding the ice to the upper part of the food storage (3). Moreover, the circulation pipe (46) has a branch pipe (47) that branches along the route and is connected to the ice making machine (2). Further, the circulation pipe (46) is provided with a differential pressure gauge (48) for measuring the pressure loss of the sherbet-like ice flowing in the circulation pipe (46) on the way.

The ice receiving tank (41) is disposed directly under the ice making machine (2). The sherbet-like ice produced by the ice making machine (2) is received by the ice receiving tank (41). The bottom part of the ice receiving tank (41) is formed in a tapered shape that narrows downward, and a pipe extends at the lower end of the tapered bottom part and is connected to the supply pump (42). Since the bottom of the ice receiving tank (41) is formed in a tapered shape, sherbet-like ice can be prevented from accumulating in the inner corner of the ice receiving tank (41), and the sherbet manufactured by the ice making machine (2). The ice in the form will be sequentially sent to the supply pump (42).
A drain valve (411) is disposed at the right end in FIG. 3 of the pipe extending from the ice receiving tank (41), so that water can be appropriately drained from the ice receiving tank (41).

The sherbet-shaped ice sent from the ice receiving tank (41) to the supply pump (42) is guided to the upper part of the food storage (3) by the supply pipe (43).
The supply pipe (43) branches according to the number of compartments (31) formed in the food storage (3), and is connected to the supply port (32) provided in each compartment (see FIG. 1).
Thus, the sherbet-shaped ice sent out by the supply pump (42) is supplied to each section (31) formed in the food storage (3).
The sherbet-shaped ice supplied into the compartment (31) enters the mesh cage (33) disposed in the compartment (31) and fills the surrounding space of the food stored in the mesh cage (33). , Make the food temperature ice temperature. Therefore, the whole food is uniformly heated to ice temperature, there are no temperature spots, and it is possible to surely prevent the food such as partial freezing, high-temperature alteration or low-temperature damage, and to keep the temperature of the whole food reliably.

A discharge pipe (44) extends from a discharge port (34) provided at the bottom of the food storage (3). The discharge pipe (44) is connected to the circulation pump (45). Further, a drain valve (441) is attached to the left end of the discharge pipe (44) in FIG. 3 so that water can be appropriately drained from the food storage (3).
A circulation pipe (46) extends from the circulation pump (45). The circulation pipe (46) guides the sherbet-shaped ice delivered from the circulation pump (45) upward, and is connected to the supply pipe (43) near the upper part of the food storage (3).
Thus, the sherbet-like ice discharged from the bottom surface of the food storage (3) reaches the circulation pump (45) through the discharge pipe (44), and is sent upward by the circulation pump (45). ) To the inside of the supply pipe (43) and follow the path of circulation into the food storage (3) again.

In the present invention, the sherbet-like ice made of seawater that is preferably used is separated from the ice component and the water component when left in a stationary state for a long time, and the fine ice pieces are solidified and solidified to form a large mass Forming ice pieces.
Like the present invention, the food storage (3) is connected to the discharge pipe (44) extending from the bottom, the circulation pump (45) connected to the discharge pipe (44), the circulation pump (45) and the supply pipe (43). By constructing a circulation path constituted by the circulation pipe (46), the sherbet-like ice supplied in the food storage (3) can be made to flow, and the sherbet-like ice in the food storage (3) The separation phenomenon between the water component and the ice component of ice can be prevented. Therefore, the ice in the food storage (3) can always be kept in a sherbet state in which fine ice components and water components are united and the food stored in the food storage (3) is stored at ice temperature. Make sure you do.

A differential pressure gauge (48) is disposed in the middle path of the circulation pipe (46). The differential pressure gauge (48) measures the pressure loss of the sherbet-like ice flowing in the circulation pipe (46).
FIG. 4 shows the relationship between pressure loss in the flow of IPF and sherbet-like ice. In FIG. 4, λs is a pipe friction coefficient when sherbet-shaped ice made of seawater is flowed into the pipe, λw is a pipe friction coefficient when seawater is flowed into the pipe, and in FIG. 4, λs and λw The ratio is taken on the vertical axis. In FIG. 4, the IPF is taken on the horizontal axis. FIG. 4 shows the change in the ratio of λs and λw with the change in IPF, which means that the pressure loss increases as the ratio of λs and λw increases.
As shown in FIG. 4, as the IPF of the sherbet-like ice increases, the pressure loss increases proportionally. Therefore, the IPF of the sherbet-like ice flowing in the circulation pipe (46) is detected by arranging the differential pressure gauge (48) and measuring the pressure loss of the sherbet-like ice flowing in the circulation pipe (46). It becomes possible. As described above, since the circulation path of the sherbet-like ice is formed around the food storage (3), the food storage (3) is measured by measuring the pressure loss of the sherbet-like ice flowing through the circulation pipe (46). It becomes possible to accurately detect the IPF of the sherbet-like ice inside.

As shown in FIG. 3, the circulation pipe (46) branches in the middle of the path, and the branch pipe (47) extends from the branch point. The branch pipe (47) is connected to the ice making machine (2).
Thereby, the sherbet-like ice flowing through the circulation pipe (46) can be flowed toward the ice making machine (2).

The suitable operation form using the structure of the said pipeline (4) is shown.
The sherbet-like ice circulates from the food storage (3) through the discharge pipe (44), the circulation pump (45), the circulation pipe (46), the supply pipe (43), and the food storage (3). By this circulation, separation of the water component and ice component of the sherbet-like ice in the food storage (3) is prevented, and the temperature in the food storage (3) is maintained in the ice temperature region.
As time elapses, the temperature of the sherbet-like ice flowing through the food storage (3) and the circulation path gradually rises due to the outside air, and the ice component of the sherbet-like ice dissolves while the water component increases. The IPF of the sherbet-like ice is lowered by reducing the ice component and increasing the water component. The IPF of the sherbet-like ice is detected by a differential pressure gauge (48) installed on the circulation pipe (46). That is, when the IPF of the sherbet-like ice is lowered, the pressure loss of the sherbet-like ice flowing in the circulation pipe (46) is lowered, so that the measured value indicated by the differential pressure gauge (48) is reduced.
As shown in FIG. 3, the differential pressure gauge (48) is connected to the control panel, and the measured value of the differential pressure gauge (48) is sent to the control panel. When the differential pressure gauge (48) sends a signal indicating a pressure loss value lower than a predetermined threshold value to the control board, the control board sends a signal to a valve (431) installed near the upper end of the circulation pipe (46). The valve (431) is closed. Then, the control panel sends a signal to the valve (471) so as to open the valve (471) installed in the branch pipe (47).
In this way, the circulation path of the sherbet-shaped ice around the food storage (3) is switched to the path from the food storage (3) to the ice making machine (2).

The operation after this path switching will be described using the ice making machine (2) shown in FIG.
The sherbet-like ice discharged from the bottom of the food storage (3) flows through the circulation pipe (46) by the circulation pump (45). Here, as described above, the valve (431) of the circulation pipe (46) is closed, while the valve (471) of the branch pipe (47) is open, so that the sherbet-like shape flowing in the circulation pipe (46) is formed. The ice is guided to the branch pipe (47). Since the branch pipe (47) is connected to the ice making machine (2), the sherbet-shaped ice guided in the branch pipe (47) reaches the ice making machine (2).
The branch pipe (47) is connected to the seawater supply port (221) of the ice making machine (2), so that sherbet-like ice flowing through the branch pipe (47) is placed in the ice making section (202) of the ice making machine (2). Supplied.
The refrigerant device (21) and the ice making machine (2) are operated, and the sherbet-like ice supplied from the branch pipe (47) is supercooled in the ice making machine (2), so that the sherbet-like ice having a desired IPF is obtained. Manufactured.

The sherbet-shaped ice produced by the ice making machine (2) is brought from the ice take-out port (206) of the ice making machine (2) to the ice receiving tank (41). When the ice making machine (2) produces a predetermined amount of sherbet-like ice, the control panel sends a signal to the valve (431) to open the valve (431) of the circulation pipe (46), and the branch pipe (47) A signal is sent to valve (471) to close the valve and an actuation signal is sent to supply pump (42).
The sherbet-shaped ice in the ice receiving tank (41) is urged into the supply pipe (43) by the operation of the supply pump (42), and flows into each section of the food storage (3) from the supply pipe (43).
In this way, by sending a part of the sherbet-like ice flowing through the food storage (3) to the ice maker (2) and repeating the operation of feeding the sherbet-like ice having a high IPF from the ice maker (2) as appropriate, The IPF in the food storage (3) is stored within a certain range, and the temperature in the food storage (3) can be accurately maintained at the ice temperature.

FIG. 5 shows the temperature characteristics of the sherbet-like ice and the relationship between the salinity and the temperature of the sherbet-like ice. Fig. 5 shows the results of testing semi-solid sherbet-like ice at room temperature and examining its temperature change and flow state, and the results of testing for sherbet-like ice made from seawater with different salinity concentrations. is there.
The semi-solid sherbet-like ice gradually becomes fluid as the ice component of the sherbet-like ice dissolves over time. In this process, the temperature of the sherbet-like ice rises with time.
When the IPF falls below 50% and the sherbet-like ice comes to have fluidity, the temperature rise stops and becomes a substantially constant temperature regardless of the passage of time. This constant temperature is maintained until all the ice components of the sherbet-like ice melt and the sherbet-like ice becomes seawater.
After sherbet-like ice becomes seawater, the temperature starts to rise again.
Therefore, when the IPF is less than 50% and greater than 0%, the sherbet-like ice can maintain a constant temperature. As described above, the maximum IPF for flowing in the pipeline (4) is less than 40%, and when the IPF exceeds 40%, sherbet-like ice is solidified in the pipeline (4). It is not possible to obtain a good circulation. Further, the minimum value of IPF used in the present invention is preferably 10% or more. This is because if the IPF is less than 10%, the temperature starts to rise in a short time and the ice temperature cannot be kept stable.

In the test shown in FIG. 5, sherbet-shaped ice made from seawater with a salinity of 1%, 2%, 3.4%, 5% and 6% was used. As shown in FIG. 5, as the salinity concentration increases, the temperature in a constant temperature range from when sherbet-like ice begins to have fluidity until it becomes completely seawater decreases. This means that a desired constant temperature can be obtained by adjusting the salinity of seawater that becomes sherbet-like ice.
The condensation temperature of intracellular moisture in many fresh foods is -3 ° C to 0 ° C. When fresh food is stored at a temperature of -3 ° C or lower, the moisture in the fresh food cells freezes and the volume of the moisture is When it becomes large, the cell membrane or cell wall is destroyed, and when this fresh food is returned to room temperature, the internal components of the cell flow out and the freshness is lowered. Moreover, when it is 0 degreeC or more, problems, such as high temperature alteration or miscellaneous bacteria reproduction, will arise. Therefore, it is preferable that the optimum temperature for storing fresh food is an ice temperature range of −3 ° C. or higher and lower than 0 ° C.
As shown in FIG. 5, the salinity concentration of seawater for stabilizing at such an ice temperature range of −3 ° C. or more and less than 0 ° C. is in the range of higher than 0% and lower than 5%. This salinity concentration range is the optimum concentration band in the present invention.

FIG. 6 is a flowchart of ice temperature storage using the ice temperature storage according to the present invention.
First, the salt concentration of the seawater used is adjusted. As described above, the salinity concentration is preferably adjusted to be higher than 0% and not higher than 5%. Thereby, the stable temperature of -3 degreeC to 0 degreeC optimal for food preservation | save can be brought in in a food storage (3).
The seawater whose salt concentration is adjusted is supplied to the replenishment tank (209) of the ice making machine (2).

In the manufacturing process subsequent to the salt concentration adjustment process shown in FIG. 6, sherbet-shaped ice is manufactured.
The seawater supplied to the supply tank (209) is supercooled in the ice making machine (2) by the refrigerant sent from the refrigerant device (21) as described above, and becomes sherbet-like ice. The IPF of the sherbet-like ice produced is adjusted by the temperature or flow rate of the refrigerant from the refrigerant device (21), the rotational speed of the rotary shaft (205) of the ice making machine (2), and the like. The range of the IPF to be adjusted is preferably 10% or more and less than 40% as described above.

In the supplying step, sherbet-like ice is supplied into the food storage (3) via the pipeline (4). Here, a net basket (33) containing a desired food is disposed in each compartment (31) in the food storage (3).
The sherbet-shaped ice produced by the ice making machine (2) is received by the ice receiving tank (41) of the pipeline (4), and is urged by the supply pump (42) to the supply pipe (43) to supply the supply pipe (43). To the food storage (3).
The sherbet-shaped ice supplied to the food storage (3) enters the mesh basket (33), uniformly wraps the entire surface of the food stored in the mesh basket (33), and sets the temperature of the food to the ice temperature. . After a certain amount of sherbet ice is supplied to the food storage (3), the circulation process is started.
The valve (432) provided in the supply pipe (43) is closed by the control panel immediately before the circulation process is started. The control panel also sends a signal to the supply pump (42) to stop the supply pump (42).

In the circulation process, the control panel sends a signal to the circulation pump (45) to operate the circulation pump (45). The sherbet-like ice is discharged from the bottom of the food storage (3), and is brought back to the upper part of the food storage (3) by the circulation pump (45), and the sherbet-like ice in the food storage (3) flows. . Thereby, the sherbet-shaped ice in the food storage (3) does not solidify, and the food stored in the food storage (3) is not damaged.
During the circulation process, the differential pressure gauge (48) measures the pressure loss of the sherbet ice flowing in the circulation pipe (46) when the delivery amount of the sherbet ice from the circulation pump (46) becomes constant. The IPF of sherbet-like ice in the food storage (3) can be detected. The value of the pressure loss measured by the differential pressure gauge (48) is sent to the control panel and compared with a threshold value input in advance to the control panel. A circulation process is performed while the measured value of the pressure loss is equal to or greater than the threshold value.
The threshold value may be a pressure loss value when the IPF of the sherbet-like ice flowing through the circulation pipe (46) becomes 10%, for example.
As shown in FIG. 5, the temperature of the sherbet-like ice is kept substantially constant until all the ice components inside the sherbet-like ice are melted, so that the inside of the food storage (3) is kept during the circulation process. The ice temperature is kept stable.

When the pressure loss value of the differential pressure gauge (48) becomes equal to or less than the threshold value, the replacement process is started.
When the differential pressure gauge (48) sends a pressure loss value below the threshold value to the control panel, the control panel closes the valve (431) disposed in the circulation pipe (46) and is disposed in the branch pipe (47). A signal is sent to each valve (431, 471) to open the valve (471), and each valve is operated. In this way, while the circulation path is blocked, a sherbet-like ice flow path from the food storage (3) to the ice making machine (2) is formed.
Thereafter, the sherbet-like ice flows from the bottom of the food storage (3) to the ice making machine (2), and becomes sherbet-like ice having a predetermined IPF in the ice making machine (2). And the sherbet-like ice reaches from the ice making machine (2) to the ice receiving tank.
A predetermined amount of sherbet-shaped ice is sent from the food storage (3) to the ice maker (2), and is made into sherbet-shaped ice having a predetermined IPF by the ice maker (2) and received by the ice receiving tank (41). Then, the control panel opens the valve (431) of the circulation pipe (46) and closes the valve (471) of the branch pipe (47). The control panel also stops the supply pump (42). Thereafter, the control panel operates the supply pump (42) and opens the valve (432) provided in the supply pipe (43), and the sherbet-like ice received by the ice receiving tank (41) is again fed to the food storage (3). To supply.
Thereafter, a circulation process is started, and a replacement process is appropriately performed according to the IPF of the flowing sherbet-like ice.

The ice temperature storage according to the present invention can be variously modified.
For example, by disposing the ice making machine (2), the pipeline (4), and the food storage (3) on a pedestal on which the vehicle can be mounted, the ice temperature can be stored even during transportation by the vehicle.
In the above example, the threshold value corresponding to the lower limit value of the IPF for the sherbet-like ice is input to the control panel. However, the threshold value corresponding to the upper limit value may be further set. Thereby, it becomes possible to detect clogging in the pipeline (4) of the ice temperature storage (1). For example, the corner of the food storage (3) of the pipeline (4), the inlet of a valve or pump provided in the pipeline (4), the bent pipe or throttle pipe in the pipeline (4), etc. A heater is installed in the part where ice is likely to consolidate. When the sherbet-like ice circulation path is clogged, the differential pressure gauge (48) shows a high pressure loss value, so it is possible to determine whether clogging has occurred in the circulation path by appropriately setting an upper limit threshold. It becomes. When the pressure loss value from the differential pressure gauge (48) exceeds the upper threshold, the control panel temporarily stops the circulation pump (45) and temporarily operates the heater to consolidate the sherbet-like ice. By heating the easy portion, clogging in the pipeline (4) is eliminated, and it becomes possible to prevent the quality of the food from being deteriorated due to the problem of circulation of the sherbet-like ice.
Alternatively, the control panel may collect pressure loss value data from the differential pressure gauge (48) for a certain period of time to calculate the rate of change of the pressure loss value. Based on the rate of change of the pressure loss value, a method may be employed in which the time during which the IPF is considered to be within a predetermined range is calculated, and the circulation pump (45) is stopped within the calculated time. . According to this method, it is not necessary to always operate the circulation pump (45), and the power consumption can be reduced.

In the above example, the ice receiving tank (41) that receives and temporarily stores the sherbet-like ice produced by the ice making machine (2) is used. Instead, an ice storage as shown in FIG. 7 is used. Also good.
FIG. 7 shows the ice storage, FIG. 7 (a) is a longitudinal sectional view of the ice storage, and FIG. 7 (b) is a view of the inside of the ice storage from above.
The ice storage (5) has an ice storage chamber (51) for storing the sherbet-shaped ice produced by the ice making machine (2), and a sherbet-like ice produced by the ice making machine (2) in the ice storage chamber (51). And a delivery path (53) for sending sherbet-like ice to the pipeline (4) of the ice temperature storage (1).

The introduction path (52) introduces the ice receiving part (521) that receives the ice from the ice making machine (2) and the sherbet-like ice accommodated in the ice receiving part (521) into the ice storage chamber (51). A pump (522) and an introduction pipe (523) for guiding sherbet-shaped ice sent from the introduction pump (522) to the upper surface of the ice storage chamber (521).
The sherbet-like ice produced by the ice making machine (2) is brought into the ice storage chamber (51) through the introduction path (52). A drain valve (524) for draining water is attached to the introduction pump (522).

The ice storage chamber (51) has a substantially cylindrical shape, and the bottom surface of the ice storage chamber (51) is formed in a tapered shape that narrows downward.
A rotating shaft (511) is disposed along the central axis of the ice storage chamber (51). A plurality of crushing bars (512) extend from the rotating shaft (511) in the radial direction of the ice storage chamber (51). The crushing bar (512) extends at a different height, and exhibits a crushing effect and a stirring effect on sherbet-like ice, which will be described later, throughout the ice storage chamber (51). A wing portion (513), which is a wing-shaped rod, is disposed at the lower end of the rotating shaft (511). The wing (513) facilitates the discharge of sherbet-like ice from the ice storage chamber (51). The upper end of the rotating shaft (511) is connected to a motor (514) disposed on the upper surface of the ice storage chamber (51). The motor (514) is connected to the above-described control panel, and sends a load signal of the motor (514) applied when the rotating shaft (511) rotates to the control panel.
A baffle stick (515) extends from the inner wall surface of the ice storage chamber (51) toward the center of the cross section of the ice storage chamber (51). A plurality of baffle bars (515) are arranged in the axial direction of the storage chamber (51) by changing the height so as not to interfere with the crushing bar (512) when the rotating shaft (511) rotates. The baffle stick (515) facilitates crushing of sherbet-like ice, which will be described later.
The refrigerant from the refrigerant device (21) of the ice temperature storage (1) can flow into the wall of the ice storage chamber (51), and the inside of the ice storage chamber (51) is kept at a low temperature. In addition, a temperature sensor (516) extends from the inner wall of the ice storage chamber (51), and the temperature inside the ice storage chamber (51) can be measured. The temperature sensor (516) is connected to the control panel, and sends a signal of the temperature inside the ice storage chamber (51) to the control panel. The control panel adjusts the refrigerant flow rate and refrigerant temperature from the refrigerant device (21) according to the signal from the temperature sensor (516). Thereby, the inside of the ice storage chamber (51) is kept at a constant low temperature.

As described above, sherbet-like ice made from seawater is easily separated into a water component and an ice component when placed in a stationary state.
While storing the sherbet-like ice in the ice storage chamber (51), the sherbet-like ice is placed in a stationary state. At this time, the sherbet-like ice is separated into a water component and an ice component, and the ice component floats above the ice storage chamber (51). As a result, an ice layer is formed upward and a water layer is formed downward in the ice storage chamber (51). In the ice layer above the ice storage chamber (51), fine ice pieces accumulate and these ice pieces consolidate to form a large ice mass. As shown in FIG. 7, the crushing rod (512) extends to the vicinity of the inner wall of the ice storage chamber (51), and the baffle rod (515) extends to the vicinity of the rotating shaft (511). Above, wrap the crushing bar (512) and the baffle bar (515).
In this state, when the motor (514) is operated and the rotating shaft (511) is rotated, the ice block tries to rotate together with the rotating shaft (511). On the other hand, the baffle rod (515) opposes the rotational force, and as a result, a shearing force is generated inside the ice block, and the ice block is crushed. After the ice block is crushed into fine ice pieces, the crushing rod (512) stirs the inside of the ice storage chamber (51) with the rotation of the rotating shaft (511), and the fine ice pieces inside the ice storage chamber (512) again. A sherbet-like ice is formed in which water and water components are mixed together.
As shown in FIG. 4, since the fluidity of the sherbet-like ice is related to the IPF, the IPF of the sherbet-like ice inside the ice storage chamber (51) is detected by measuring the load applied to the rotating shaft (511). It becomes possible to do.
After the sherbet-like ice inside the ice storage chamber (51) becomes a predetermined IPF, the valve (531) of the delivery path (53) disposed below the ice storage chamber (51) is opened, and the ice storage chamber (51) The sherbet-shaped ice inside is sent to the delivery path (53).
Since the bottom of the ice storage chamber (51) is formed in a tapered shape that narrows downward, the sherbet-like ice is smoothly discharged from the bottom of the ice storage chamber (51).

The delivery path (53) is connected to a delivery pump (532) connected to the bottom of the ice storage chamber (51) and a delivery pump (532), and from a delivery pipe (533) for sending sherbet-like ice to the ice temperature storage (1). Become. In the pipeline (4) shown in FIGS. 1 and 3, the supply pump (42) corresponds to the delivery pump (532), and the supply pipe (43) corresponds to the delivery pipe (53). The delivery pipe (533) is connected to the food storage (3) and connected to the circulation pipe (46) in the same manner as the pipeline (4) shown in FIGS.
The delivery pipe (53) branches in the middle of the path, one being a pipe (534) connected to the food storage (3) and the other being a pipe (535) connected to the upper part of the ice storage chamber (51). Thus, by providing the pipe (535) connected to the ice storage chamber (51), the sherbet-like ice can be circulated around the ice storage chamber (51).
Switching between the pipe (534) connected to the food storage (3) and the pipe (535) connected to the ice storage chamber (51) is a valve (536) provided on the pipe (534) connected to the food storage (3). And a valve (537) provided on a pipe (535) connected to the ice storage chamber (51).
Through the delivery path constructed in this manner, sherbet-shaped ice is sent from the ice storage chamber (51) to the food storage (3).

An ice temperature storage method using the ice storage (5) configured as described above will be described.
In the same manner as described above, the salinity of the seawater produced in the sherbet-like ice is adjusted in the salt concentration adjustment step. Thereafter, in the production process, sherbet-like ice is produced by the ice making machine (2). In the supplying step, the sherbet-like ice produced by the ice making machine (2) is sent to the ice storage (5). A predetermined amount of sherbet-shaped ice is sent from the ice storage (5), and the supply process is completed. Thereafter, the ice making machine (2) continues to produce sherbet-like ice, and when a predetermined amount of sherbet-like ice is stored in the ice storage (5), the operation of the ice making machine (2) is stopped.
Thereafter, the circulation process is performed in the same manner as described above, and during the circulation process, the pressure loss of the sherbet-like ice flowing in the circulation pipe (46) is measured by the differential pressure gauge (48), and is determined from a predetermined threshold value. When the pressure loss is low, the replacement process is started.

In the replacement step, the valves (431, 471) are operated to switch the sherbet-like ice flow path in the same manner as described above. Thereby, the sherbet-like ice discharged from the food storage (3) is sent to the replenishment tank (209) of the ice making machine (2).
When the replacement process starts, the control panel operates the motor (514) of the ice storage (5). As described above, the sherbet-shaped ice stored in the ice storage chamber (51) and separated into the water component and the ice component is crushed and agitated by the rotation of the motor (514), and the water component and the ice component are separated again. It becomes a sherbet-like ice. It is detected from the load signal from the motor (514) whether the sherbet-like ice in the ice storage (514) has a desired IPF.
When the sherbet-like ice reaches the desired IPF, a valve (531) disposed near the bottom of the ice storage chamber (51) is opened by a signal from the control panel, and the ice storage (5) to the food storage (3) The sherbet-like ice flow path leading to is opened, and the sherbet-like ice is sent to the food storage (3) through the delivery path (53).
The ice making machine (2) replenishes the amount of seawater replaced in the replacement process from the replenishment tank (209), manufactures sherbet-shaped ice from the replenished seawater, and the manufactured sherbet-shaped ice is stored in an ice storage as needed. Sent to (5).

  In the method as described above, the ice storage (5) can produce sherbet-like ice having a desired IPF simply by crushing and stirring the sherbet-like ice separated into the water component and the ice component. Therefore, a large amount of sherbet-like ice having a desired IPF can be made relatively quickly. This makes it possible to replace a large amount of sherbet-like ice. In addition, the replacement process can be performed without depending on the production capacity of the ice making machine (2).

By using the ice storage (5) as described above, it is possible to replace a large amount of sherbet-like ice, and thus it is possible to construct an ice temperature storage (1) as shown in FIG.
FIG. 8 is a configuration diagram of an ice temperature storage capable of storing a large amount of food at an ice temperature.
The ice temperature storage (1) shown in FIG. 8 includes one ice making machine (2), one ice storage (5), and a plurality of food storages (3). The configuration of the sherbet-like ice channel connecting the ice making machine (2), the ice storage (5) and the food storage (3) to each other is the same as described above, but from the ice storage (5) to a plurality of food storages (3 ) Is different in that it is branched and connected.
As described above, since the ice storage (5) can supply a large amount of sherbet-like ice at a time, by using the ice storage (5), sherbet-like ice can be simultaneously applied to a plurality of food storages (3). It is possible to perform the replacement process. Therefore, it becomes possible to store food in a plurality of food storages (3), and efficiently store ice temperature for a large amount of food.

  The present invention is suitably applied to an ice temperature storage for storing foods at an ice temperature of -3 ° C to 0 ° C.

It is the schematic of the ice temperature storage which concerns on this invention. (A) is a top view of an ice temperature storage, (b) is a front view of an ice temperature storage, (c) is a right side view of an ice temperature storage. 1 is a schematic structural diagram of an ice making machine according to the present invention. It is a schematic diagram of the path | route of the pipeline of the ice temperature storage which concerns on this invention. It is a figure which shows the relationship of the pressure loss in the flow of IPF and a sherbet-like ice. It is a figure which shows the relationship between the temperature characteristic and salt concentration of sherbet-like ice, and the temperature of sherbet-like ice. It is a flowchart of the ice temperature storage using the ice temperature storage which concerns on this invention. It is a figure which shows the ice storage used for the ice temperature storage which concerns on this invention. (A) is the longitudinal cross-sectional view of an ice storage, (b) is the figure which looked at the ice storage chamber of the ice storage from the upper direction. It is a block diagram of the ice temperature storage which can store a lot of foods at ice temperature. It is a figure which shows the conventional ice temperature storage.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Ice temperature storage 2 ... Ice maker 3 ... Food storage 33 ... Net cage 4 ... Pipeline 41 ... Ice receiving tank 42 ... .... Supply pump 43 ... Supply pipe 44 ... Discharge pipe 45 ... Circulation pump 46 ... Circulation pipe 47 ... Branch pipe 48 ... Differential pressure gauge

Claims (5)

An ice machine that produces sherbet-shaped ice;
A pipeline for delivering sherbet-like ice produced by the ice making machine;
It is connected to the pipeline and consists of a food storage where food is stored,
The food surrounding space is filled with sherbet-shaped ice sent from the pipeline,
The pipeline is an ice receiving tank for storing sherbet-like ice produced by the ice making machine,
A supply pump connected to the ice receiving tank;
A supply pipe connected to the supply pump and communicating with the upper part of the food storage;
A discharge pipe extending from the bottom of the food storage;
A circulation pump connected to the discharge pipe and circulating the sherbet-like ice discharged from the discharge pipe to the upper part of the food storage;
An ice temperature storage, comprising a circulation pipe for guiding sherbet-shaped ice fed from the circulation pump to the upper part of the food storage.   The ice temperature storage according to claim 1, wherein a differential pressure gauge for measuring a pressure loss in the circulation pipe is disposed in the circulation pipe path. A branch pipe connected to the ice making machine in the middle of the circulation pipe path,
When the measured value of the differential pressure gauge becomes a predetermined value or less, a valve arranged in the middle of the branch pipe path is opened,
The ice maker makes the sherbet-like ice supplied from the branch pipe into a sherbet-like ice having a desired IPF,
The ice temperature storage according to claim 2, wherein sherbet-like ice having the desired IPF is supplied into the food storage by the pipeline. A branch pipe connected to the ice making machine in the middle of the circulation pipe path,
When the measured value of the differential pressure gauge becomes a predetermined value or more,
While stopping the circulation pump,
The ice temperature storage according to claim 2, wherein a heater disposed in the pipeline is operated. A manufacturing process for manufacturing sherbet-shaped ice;
Supplying the sherbet-shaped ice produced in the production process to a food storage for storing food;
The sherbet-shaped ice supplied in the food storage is composed of a circulation step of discharging from the bottom of the food storage and circulating to the top of the food storage,
In the supplying step, sherbet ice supplied within said food storage is less than the space around the food product,
In the circulation step, a differential pressure detection step of measuring a pressure loss of a sherbet-like ice flow circulating from the bottom of the food storage to the top of the food storage;
Comprising a replacement step of replacing the sherbet-shaped ice in the food storage,
When the pressure loss value detected in the differential pressure detecting step is equal to or less than a predetermined value, the replacement step has a circulation path from the bottom of the food storage to the top of the food storage, and sherbet-like ice from the bottom of the food storage Switching to the path to the ice machine that manufactures
Producing sherbet-like ice with a desired IPF from sherbet-like ice supplied to the ice making machine;
An ice temperature storage method comprising the step of supplying sherbet-like ice having the desired IPF from an ice maker to the food storage .

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