JP2009002543A - Cold water supply device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cold water supply device capable of reducing costs, saving energy and improving efficiency. <P>SOLUTION: This cold water supply device comprises a storage tank 1 receiving the water, a water supply pipe 3 connected with the storage tank 1 and supplying the water into the storage tank 1, a cooling means 2 for making ice by freezing the water in the storage tank 1, and a heat generating conducting element 4 disposed in the storage tank 1 for generating and conducting heat. As the heat introduced into the storage tank 1 through the heat generating conducting element 4 melts the ice K of a peripheral area of the heat generating conducting element 4, a cooling water passage 5 is formed along the heat generating conducting element 4 inside of the ice K. The water supplied from the water supply pipe 3 is passed through the cooling water passage 5 and cooled. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a cold water supply apparatus that cools water and supplies cold water.

A conventional cold water supply device (see, for example, Patent Document 1) was introduced into a sealed ice heat storage chamber, a conditioning unit (cooler) including a refrigerant pipe disposed in the sealed ice heat storage chamber, and the sealed ice heat storage chamber. It consists of a pump that circulates water repeatedly. In the chilled water supply device of Patent Document 1, a refrigerant pipe is arranged in a sealed ice heat storage chamber, and ice is generated at an outer diameter portion of the refrigerant pipe by a cooler connected to the refrigerant pipe. Then, water is introduced into the sealed ice heat storage chamber and repeatedly circulated. In addition, cold water is taken out while melting ice by bringing water into contact with the ice generated on the outer diameter portion of the refrigerant pipe in the sealed ice heat storage chamber and performing heat exchange (heat radiation).
JP 2000-186838 A (pages 1 to 4, FIG. 1)

  In the cold water supply device of Patent Document 1, since water is constantly circulated after flowing water into the sealed ice storage room, electric power for moving the pump and the pump is required, the cost of the device is high, and electric energy There is much consumption.

  In addition, since heat generated by the operation of the pump or heat from the environment around the pump through the pump flows into the sealed ice storage chamber along with the circulating water, cooling that outputs cooling power to the sealed ice storage chamber The machine is required to have a large cooling capacity, and the adoption of a high-power cooling machine causes problems of high cost and high energy consumption.

  Furthermore, by introducing the refrigerant piping of the cooler into the ice heat storage chamber, the cooler becomes a dedicated machine for the cold water supply device, and the use of the cooler is limited.

  This invention is made | formed in view of the said actual condition, and makes it a subject to provide a low-cost, energy-saving, and highly efficient cold water supply apparatus.

  The cold water supply apparatus of the present invention includes a storage tank that stores water, a water supply pipe that is connected to the storage tank and supplies water into the storage tank, a cooling unit that freezes water in the storage tank to make ice, and a storage tank A heat generating conductive element that generates and conducts heat, and the heat introduced into the storage tank through the heat generating conductive element melts the ice in the area around the heat generating conductive element. A cooling water passage is formed inside the heat generation conductive element, and water supplied from the water supply pipe passes through the cooling water passage and is cooled.

  According to the cold water supply apparatus of the present invention, ice is formed in the storage tank by freezing the water in the storage tank via the cooling means. Further, the cold water supply device of the present invention includes the heat generation conductive element, so that the heat generated from the heat generation conductive element is transmitted to the ice produced in the storage tank, and the ice around the heat generation conductive element is transmitted. Can be melted. Between the heat generating conductive element and the unmelted ice, a melted ice space is continuously formed. For this reason, a cooling water channel (continuous space) through which water flows is formed along the heat-generating conductive element. Thereby, the water supplied into the storage tank from the water supply pipe passes through the cooling water channel formed inside the ice, and is cooled by heat exchange with the ice constituting the cooling water channel, thereby generating cold water. . Further, since the cooling water channel is formed inside the ice, the water passing through the cooling water channel has a large contact area with the ice, and the water can be cooled efficiently. Further, since the path of the cooling water channel is determined by the arrangement of the heat generation conductive elements, it is possible to optimize the formation of the cooling water channel by designing the heat generation conductive elements (path arrangement) and the heat capacity of the ice. In this way, the internal space (ice volume) of the storage tank can be effectively utilized by the arrangement (path, shape) of the heat generating conductive element, and a longer and more effective cooling water channel can be formed. Therefore, the cold water supply apparatus of this invention can cool water efficiently, and can produce | generate cold water. Further, in the cold water supply apparatus of the present invention, since the cooling water channel can be configured in the storage tank, a pump for constantly circulating water can be eliminated, which is advantageous in realizing cost reduction and energy saving of the apparatus.

  The cooling means of the cold water supply apparatus according to the present invention includes a heat exhaust unit that discharges heat generated when ice in the storage tank is made to ice, and the heat generation conductive element melts the ice in the storage tank. Electric heater, tap water heat supply unit for melting ice in the storage tank, air heat supply unit for melting ice in the storage tank, or cooling means for melting ice in the storage tank It is preferable that it is composed of at least one of the heat parts.

  According to the cold water supply apparatus of the present invention, by configuring the heat generation conductive element with an electric heater, it is possible to easily change from current (electric energy) to heat for melting ice in the storage tank. Moreover, the flow diameter of a cooling water channel etc. can also be adjusted by melting the ice in a storage tank by controlling the electric current (for example, current intensity, energization time) etc. of an electric heater. In addition, by configuring the heat generation conduction element with tap water heat supply unit or air heat supply unit, the heat of tap water or air becomes the energy to melt ice in the storage tank, and the amount of heat of tap water or air is reduced. Can be used. Furthermore, by configuring the heat generating conductive element with the exhaust heat portion of the cooling means, the exhaust heat generated by the cooling means can be effectively reused and recovered as energy for melting the ice in the storage tank. Therefore, energy efficiency can be realized and at the same time the efficiency of the refrigeration means can be improved.

  The water supply pipe of the cold water supply apparatus of the present invention includes a connection portion connected to the storage tank, and the connection portion is disposed in the storage tank in parallel with the heat generation conductive element, and the heat generated from the heat generation conductive element It is preferable that a freezing suppression space in which freezing of water is suppressed is formed. By disposing the connection portion of the water supply pipe in the storage tank in parallel with the heat generation conductive element, freezing of the water supply pipe supplying water into the storage tank can be suppressed. That is, the connection part of the water supply pipe is parallel to the heat generation conductive element, so that the heat generated from the heat generation conductive element is directly conducted to the connection part. Therefore, a freezing suppression space is formed inside the connecting portion, and the water inside the connecting portion is maintained substantially at or above the freezing temperature. For this reason, the connection part of water supply piping can suppress the freezing by the freezing state (below freezing temperature) inside a storage tank, and can prevent the water supply impossibility to the storage tank by freezing in a water supply piping beforehand.

  The cooling means of the cold water supply apparatus of the present invention includes a freezer, the storage tank is disposed in the freezer, and the water in the storage tank is frozen from the outer surface of the storage tank using the cold air in the freezer to make ice. Is preferred. The cooling means of the cold water supply apparatus of the present invention is provided with a freezer, so that it has a freezer function for stored items required for low-temperature storage such as food, and also functions as a water producing means (cold water generating means). Can do. That is, the cooling means of the cold water supply apparatus of the present invention can be used for various purposes such as a freezer at the same time, in addition to functioning for cold water cooling as cold water supply. Therefore, the cold water supply apparatus of the present invention improves the efficiency of the entire apparatus including the cooling means. Further, in the cold water supply apparatus of the present invention, the cooling means makes ice from the outer surface of the storage tank, so that it is not necessary to put the refrigerant piping of the cooling means into the storage tank, and a system for additional functions (freezer, refrigerator, etc.) Can be configured easily. Furthermore, it is possible to make ice using gas, liquid, or the like as a refrigerant, and the degree of freedom in cooling the water in the storage tank is high.

  Further, in the cold water supply apparatus of the present invention, since the storage tank is disposed in the freezer, the storage tank works as a cold storage material when the door of the freezer is opened and closed by taking in and out of the stored matter, and the temperature fluctuation (rise) in the freezer ) Can be suppressed, and the preservation state of the stored item in the freezer can be kept good.

  The freezer of the cold water supply apparatus of the present invention is provided in a partition section that partitions the first cold air passage that partitions the internal space of the freezer thermally and passes cold air to and from the outer surface of the storage tank. An opening / closing portion that opens and closes the first cold air passage and controls the passage of the cold air in the freezer to the first cold air passage, from the outer surface of the storage tank using the cold air that passes through the first cold air passage. It is preferable to freeze the water inside to make ice. In the cold water supply device of the present invention, by providing a partition part that thermally partitions the freezer interior space, the freezer space of the freezer and the first cold air passage for cooling the water (ice) in the storage tank are divided. be able to. That is, the first cold air passage is thermally blocked from the freezing space by the partition, and the temperature fluctuation in the freezer space due to the opening and closing of the freezer door hardly affects the temperature in the first cold air passage. Moreover, since the partition part is provided with an opening / closing part, the passage of the cold air to the first cold air passage is effectively controlled. That is, the flow of cold air is controlled in the first cold air passage, and the temperatures in the first cold air passage and the freezing space can be maintained. Moreover, the cold air for cooling the storage tank can be freely passed, and the water in the storage tank can be effectively made. For example, when opening the door of a freezer and putting stored goods in and out of the freezer, the open / close part is automatically closed so that the temperature of the freezing space in the freezer fluctuates. It is difficult for the temperature change to occur, and the influence of temperature fluctuations on the storage tank side can be effectively suppressed. Therefore, the ice in the storage tank is always maintained in a stable state (temperature), and a stable cooling water channel can be formed inside the ice. Moreover, since the water which flows through a cooling water channel is cooled by the stable flow volume and temperature, the stable cold water can be supplied. Thus, by dividing the internal space of the freezer into the freezing space and the first cold air passage via the partitioning portion and the opening / closing portion, the cold water supply device of this embodiment can function as a freezer and at the same time is stable. Cold water can also be supplied. Moreover, the cold water supply apparatus according to the present embodiment has the freezer function and the cold water cooling function at the same time, thereby improving the efficiency of the entire apparatus including the cooling means.

  Moreover, it is preferable that the heat generation conductive element of the cold water supply apparatus of the present invention generates heat only when water is cooled. As a result, the heat-generating conductive element generates heat and forms a cooling water channel every time cold water is required, which is advantageous for energy saving as compared with the case where heat is always generated.

  According to the cold water supply apparatus of the present invention, ice is formed in the storage tank by freezing the water in the storage tank via the cooling means. Further, the cold water supply device of the present invention includes the heat generation conductive element, so that the heat generated from the heat generation conductive element is transmitted to the ice produced in the storage tank, and the ice around the heat generation conductive element is transmitted. Can be melted. Between the heat generating conductive element and the unmelted ice, a melted ice space is continuously formed. For this reason, a cooling water channel (continuous space) through which water flows is formed along the heat-generating conductive element. Thereby, the water supplied into the storage tank from the water supply pipe passes through the cooling water channel formed inside the ice, and is cooled by heat exchange with the ice constituting the cooling water channel, thereby generating cold water. . Further, since the cooling water channel is formed inside the ice, the water passing through the cooling water channel has a large contact area with the ice, and the water can be cooled efficiently. Further, since the path of the cooling water channel is determined by the arrangement of the heat generation conductive elements, it is possible to optimize the formation of the cooling water channel by designing the heat generation conductive elements (path arrangement) and the heat capacity of the ice. In this manner, the inner space (ice volume) of the storage tank can be effectively used by arranging the (heat path, shape) of the heat generating conductive elements, and a longer and more effective cooling water channel can be formed. Therefore, the cold water supply apparatus of this invention can cool water efficiently, and can produce | generate cold water. Further, in the cold water supply apparatus of the present invention, since the cooling water channel can be configured in the storage tank, a pump for constantly circulating water can be eliminated, which is advantageous in realizing cost reduction and energy saving of the apparatus.

  The cold-water supply apparatus of this invention is demonstrated with reference to drawings.

(First embodiment)
The cold water supply apparatus according to this embodiment has a freezer (refrigerator) function.

  Specifically, as shown in FIG. 1, the cold water supply apparatus according to the present embodiment is mainly provided with a storage tank 1, a cooling means 2, a water supply pipe 3, and a heat generation conductive element 4 inside the freezer L. Yes. FIG. 1 shows the basic configuration of the cold water supply apparatus of this embodiment.

  As shown in FIG. 1, the freezer L includes a case portion 10. Further, in order to maintain the internal temperature of the freezer L, the case portion 10 is mainly composed of a heat insulating material 101. Thus, the heat insulating material 101 is arrange | positioned so that the freezer L may be covered. The case portion 10 includes an upper portion 10A, a lower portion 10B, a left portion 10C, a right portion 10D, a front portion 10E (shown in FIG. 2), and a rear portion 10F (shown in FIG. 2). A door (not shown) is provided at a predetermined position of the front side portion 10E, and a stored item (not shown) such as frozen food can be taken in and out of the freezer L.

  Moreover, as shown in FIG. 1, in the case part 10 of the freezer L, the storage tank 2 and the freezing space 202 which stores stored items, such as frozen food, are formed. In addition, the door of the freezer L faces the freezing space 202 so that opening and closing is possible.

  Hereinafter, the cooling means 2 and the freezing space 202 will be described.

  As shown in FIG. 1, a cooler 20 is provided on the left side portion 10 </ b> C of the case portion 10. The freezing space 202 is provided with partition plates 201A and 201B that partition the freezing space 202. The partition plate 201A is installed in parallel with the left side portion 10C, and the partition plate 201B is installed in parallel with the upper side portion 10A. That is, the partition plates 201A and 201B are connected perpendicularly to each other. As a result, a cold air passage 203A is formed between the left side portion 10C and the partition plate 201A, a cold air passage 203B is formed between the upper portion 10A and the partition plate 201B, and the cold air passages 203A and 203B are in communication.

  Further, as shown in FIG. 1, an opening 201D is formed between the partition plate 201A and the lower portion 10B of the case portion 10, and an opening 201C is formed between the partition plate 201B and the storage tank 1. Yes. Thus, the cold air passages 203A and 203B are communicated with the refrigeration space 202 through the openings 201C and 201D.

  Further, the heat exchange section 20A of the cooler 20 and the blower 22 are arranged in the cold air passage 203A. For this reason, the cool air generated by the heat exchanger 20A flows through the cool air passages 203A and 203B by the blower 22 and flows back into the freezing space 202 of the freezer L (flows in the direction of the arrow shown in FIG. 1).

  As can be understood from FIG. 1, the cold air formed in the heat exchange unit 20A of the cooler 20 passes through the opening 201C located in the vicinity of the storage tank 1 when returning to the freezing space 202 through the cold air passages 203A and 203B. Since it flows through the surface (102A) of the storage tank 1, the storage tank 1 can be cooled effectively.

  As described above, the cooling means 2 mainly includes the cooler 20, the blower 22, and the cool air passages 203A and 203B.

  Hereinafter, the storage tank 1 and its internal structure will be described.

  As shown in FIG. 1, the storage tank 1 is disposed inside the freezer L and is provided adjacent to the right side portion 10 </ b> D of the case portion 10. In addition, the tank case portion 102 of the storage tank 1 is formed of a metal having good thermal conductivity. For this reason, cold heat can be conducted to the inside of the storage tank 1 through the surface (side surface 102A) of the storage tank 1, and the inside (water) of the storage tank 1 is cooled (made ice) from the surface of the storage tank 1. Can do.

  FIG. 2 shows a cross section of the storage tank 1 of this embodiment. In addition, FIG. 2 shows the AA longitudinal cross-section of the storage tank 1 of the cold water supply apparatus shown in FIG.

  As shown in FIG. 2, the heat generation conductive element 4 is disposed in the storage tank 1. In addition, the heat generation conductive element 4 of the present embodiment example includes a power source 40 and an electric heater 41 connected to the power source 40. In the present embodiment, the electric heater 41 connected to the power source 40 converts electric energy into heat and constitutes a heat source.

  The tank case portion 102 of the storage tank 1 includes a side surface 102A (shown in FIG. 1), 102B (shown in FIG. 1), 102E (shown in FIG. 2), 102F (shown in FIG. 2), and an upper surface 102C (FIGS. 1 and 2). And a lower surface 102D (shown in FIGS. 1 and 2).

  Further, as shown in FIG. 2, the side (upper and lower) surfaces (102B, 102C, 102D, 102E, and 102F) other than the side surface 102A of the tank case portion 102 are covered with the heat insulating material 101 and kept warm. . Note that the side surface 102A is cooled in contact with the cold air generated from the cooler 20, as described above. Further, since the tank case portion 102 is made of a metal having good thermal conductivity, the inside of the storage tank 1 can be cooled via the side surface 102A of the tank case portion 102.

  As shown in FIG. 2, an introduction portion 103 for introducing the electric heater 41 and the water supply pipe 3 into the tank case portion 102 is provided on the lower surface 102 </ b> D of the tank case portion 102. The introduction portion 103 is provided at a position near the side surface 102E side on the lower surface 102D. Further, on the upper surface 102C of the tank case portion 102, an electric heater 41 and a lead-out portion 104 for leading cold water are provided.

  Moreover, the electric heater 41 which comprises the heat generation conduction element 4 is arrange | positioned in the internal space 11 of the tank case part 102 so that it may meander (detour) as shown in FIG. Specifically, the electric heater 41 includes nine first to ninth continuous heat conducting portions 411, 412, 413, 414, 415, 416 that are equally arranged in the internal space 11 of the tank case portion 102. 417, 418, 419. That is, as shown in FIG. 2, the electric heater 41 is introduced into the internal space 11 of the tank case portion 102 via the introduction portion 103. The first heat conducting part 411 is arranged so as to be parallel to the lower surface 102D of the tank case part 102. Next, following the first heat conducting unit 411, a second heat conducting unit 412 is disposed at a position close to the side surface 102F so as to make an U-turn upward. Next, following the second heat conducting unit 412, the third heat conducting unit 413 is arranged so as to be parallel to the first heat conducting unit 411. Next, following the third heat conducting unit 413, a fourth heat conducting unit 414 is disposed at a position close to the side surface 102E so as to make a U-turn upward. Similarly, the fifth heat conduction part 415, the sixth heat conduction part 416, the seventh heat conduction part 417, the eighth heat conduction part 418, and the ninth heat conduction part 419 are continuously connected to the internal space of the tank case part 102, respectively. 11 and are finally led out through the deriving unit 104. In addition, the electric heater 41 is connected to the power supply 40 via the power supply terminal 400. In addition, based on the dimension of the tank case part 102, arrangement | positioning (distance between each, a U-turn direction, etc.) of a heat conductive part (411-419) can be optimized. Further, the number of the heat conducting portions (411 to 419) is not limited to nine, and can be set according to the actual dimensions of the tank case portion 102.

  As shown in FIG. 2, water is supplied from the water supply pipe 3 to the internal space 11 of the tank case portion 102 of the storage tank 1 through the introduction portion 103. The water level supplied and stored in the internal space 11 is a fixed position (volume) of the height (volume) of the tank case portion 102, for example, 7/10 to 10/10 of the volume of the internal space 11 of the tank case portion 102. Stopped when 9/10 is achieved. That is, in the internal space 11 of the tank case portion 102, a space (volume adjustment space 1101) where air exists is left above the space occupied by water. Thereby, when the water in the tank case part 102 of the storage tank 1 is cooled by the cooling means 4 to form ice, a necessary (expansion) adjustment volume (volume adjustment space 1101) corresponding to the expansion of the volume due to the solidification of water. Is prepared. Therefore, when making ice from water, the expansion of the volume of ice resulting from the bursting of the storage tank 1 can be coordinated. Therefore, it is possible to prevent the storage tank 1 from being ruptured due to the expansion of the volume.

  Further, as shown in FIG. 1 or FIG. 2, a pipe line 1031 is provided in the introduction part 103 of the tank case part 102. Further, the pipe 1031 is provided with a water supply pipe 3 for supplying water to the storage tank 1 and a drainage section 311 for discharging the water in the storage tank 1.

  The water supply pipe 3 is communicated with the pipe line 1031 via the three-way communication part 301. Further, the water supply pipe 3 is provided with a flow rate adjusting unit 302 (valve) for opening and closing the water supply pipe 3 and adjusting the flow rate. The drainage unit 311 is provided with a flow rate adjustment unit 312 (valve) for opening and closing the drainage unit 311 and adjusting the flow rate.

  Further, as shown in FIG. 1 or FIG. 2, a conduit 1041 is provided in the outlet portion 104 of the tank case portion 102. Further, the pipe 1041 is provided with a cold water outflow portion 6 for supplying cold water generated in the storage tank 1 to the outside. The cold water outflow unit 6 is provided with a flow rate adjusting unit 602 (valve) for opening and closing the cold water outflow unit and adjusting the flow rate.

  In addition, when the water stored in the storage tank 1 is discharged from the drainage unit 311, a check valve (a gas or liquid is allowed to flow in one direction in the pipe line 1041 to maintain the atmospheric pressure in the storage tank 1. Possible valve) 601 is provided. The check valve 601 is installed so that air flows from the outside to the inside of the storage tank 1, and the water stored in the storage tank 1 cannot flow out to the outside through the check valve 601. That is, when water is supplied into the storage tank 1 from the water supply pipe 3, when the storage tank 1 is full of water, the excess water (cold water) flows to the cold water outflow portion 6 via the pipe line 1041. . Water does not flow outside through the check valve 601. Further, when the water in the storage tank 1 is discharged from the storage tank 1 through the drainage unit 311, the external air passes through the check valve 601 as the water level in the storage tank 1 (cold water) decreases. Can flow into the storage tank 1. Therefore, the pressure in the storage tank 1 is maintained, and water can easily flow out downward.

  The introduction unit 103 is shown enlarged in FIG. FIG. 3 is an enlarged view of the introduction unit 103. As shown in FIG. 3, since the pipe line 1031 is covered with the heat insulating material 101, the inflow of cold heat by the cooling means 4 can be blocked. Accordingly, the (water) temperature in the pipe line 1031 is maintained at a temperature equal to or higher than the freezing temperature, and the water inside the pipe line 1031 can be maintained in a fluid state. Further, the pipe line 1031 includes a connection portion 3011 connected to the storage tank 1. In addition, since the pipe line 1031 constitutes a part of the water supply pipe line 3 of the present embodiment, the water supply pipe line 3 communicates with the storage tank 1 through the connection portion 3011.

  Specifically, as shown in FIG. 3, the pipe line 1031 communicates with the connection portion 3011 orthogonally. The connection portion 3011 is coaxially installed so as to surround the electric heater 41 of the heat generating conductive element 4. That is, the connection portion 3011 is a tubular member having a diameter larger than that of the electric heater 41 and is disposed in the storage tank 1 in parallel (coaxially) with the electric heater 41. For this reason, the freezing suppression space 300 is formed between the connection part 3011 and the electric heater 41. That is, since the connection part 3011 is arranged in parallel (coaxially) with the electric heater 41, the temperature inside the connection part 3011 is maintained at or above the substantially freezing temperature of water by the heat generated from the electric heater 41. Therefore, freezing of water in the connection part 3011 is suppressed. Thus, the water in the freezing suppression space 300 becomes difficult to freeze, and the water flowing in from the water supply pipe line 3 (pipe line 1031) can be supplied into the storage tank 1 via the connection part 3011.

  Next, the operation of the cold water supply apparatus of this embodiment will be described.

  (1) First, as shown in FIG. 2, water is supplied into the storage tank 1 through the water supply pipe 3 by opening the flow rate adjusting means 302 and 602. When the water in the storage tank 1 fills the internal space 11 of the storage tank 1, it flows out through the cold water outflow part 6. At this time, the flow rate adjusting means 302 is closed. That is, when the water in the storage tank 1 becomes full, the excess water is discarded by the cold water outflow part 6.

  (2) Next, the flow rate adjusting means 312 of the drainage unit 311 is opened for several seconds, and the water that is full in the storage tank 1 is discharged through the drainage unit 311 with a predetermined volume (water amount). Thereby, a volume adjustment space 1101 is formed above the storage tank 1. The predetermined volume can be 1/10 to 3/10 of the total volume of the internal space 11 of the storage tank 1.

  (3) Next, the cold air flows through the side surface 102A of the storage tank 1 via the cold air passages 203A and 203B while the set temperature of the freezing space 202 of the freezer L is maintained by the cold air (cold heat) from the cooling means 2. Therefore, cold heat is conducted into the storage tank 1 through the side surface 102A, and the water in the storage tank 1 is made into ice.

  (4) Then, the power supply 40 is turned on, the electric heater 41 generates heat, and the ice K around the electric heater 41 is melted to form the cooling water channel 5. FIG. 4 shows a cross section of the peripheral area when the electric heater 41 generates heat. As shown in FIG. 4, the heat generated from the electric heater 41 constituting the heat-generating conductive element 4 melts the ice K in the surrounding area to form a tubular cooling water channel 5 with the electric heater 41 as the central axis. Is done. That is, the cooling water channel 5 is formed along the length direction of the electric heater 41 while being covered with the ice K. Further, as shown in FIG. 2, since the electric heater 41 is arranged in the internal space 11 of the storage tank 1 so as to meander (detour) inside the ice K, the cooling water channel 5 is also arranged in the electric heater 41. It is formed to meander (detour) along (route).

  (5) Next, water is supplied into the storage tank 1 through the water supply pipe 3 by opening the flow rate adjusting means 302 and 602 again. At this time, the supplied water flows into the cooling water channel 5 and rises while meandering (bypassing) along the cooling water channel 5 while contacting the ice K and melting the ice K (while exchanging heat). . Then, the cooled water (cold water) passes through the cooling water channel 5 and reaches the volume control space 1101. Further, the cold water stored in the volume control space 1101 is supplied to the user via the cold water outlet 104 and the cold water outlet 6.

  (6) After the cold water is discharged, the storage tank 1 is almost full of water that becomes the next ice. And it returns to the process of (2) and the process of (2)-(6) is repeated and cold water is supplied.

  Moreover, since the freezing space 202 is provided adjacent to the storage tank 1 in the freezer L, the storage tank 1 in which the inside is made of ice can function as a cold storage material in the freezing space 202 of the freezer L. it can. That is, when the door of the freezer L is opened and stored items such as foods are taken in and out of the freezing space 202, the temperature in the freezing space 202 partially rises, but the storage tank 1 functions as a cold storage material to As an auxiliary cooling means of means 2, it is possible to suppress an increase in the temperature of stored items previously contained in the freezing space 202 of the freezer L, or to reduce energy consumption of the cooling means 2.

  Further, in the cold water supply apparatus of the present embodiment, when the internal volume of the storage tank 1 is formed to be about 1 liter, the water temperature is changed from the raw water (water flowing into the storage tank 1 from the water supply pipe 3) having a water temperature of 25 ° C. Up to about 4 liters of cold water (cold water flowing out to the outside through the cold water outflow part 6) of 15 ° C. or less can be supplied. The supply rate of cold water is about 2 liters / minute. It should be noted that the internal volume of the storage tank 1 and the supply rate of cold water can be optimized based on the temperature of raw water actually used. For example, when the supply amount of cold water is large, the cooling water passage 5 formed in the ice K can be set longer by increasing the internal volume of the storage tank 1. In addition, a longer cooling water channel 5 can be configured by improving the occupation ratio of the heat generating conductive element 4 to the unit volume of ice inside the storage tank 1.

  Thus, according to the cold water supply apparatus of this embodiment, ice K is formed in the storage tank 1 by freezing the water in the storage tank 1 via the cooling means 2. Further, by providing the heat generation conductive element 4 in the storage tank 1, heat generated from the heat generation conductive element 4 is transmitted to the ice K made in the storage tank 1, and the heat generation conductive element 4 (electric heater 41). ) Around the ice K can be melted. Between the heat-generating conductive element 4 (electric heater 41) and the unmelted ice K, a melted ice space is continuously formed. For this reason, the cooling water channel 5 (continuous space) through which water flows is formed along the heat generating conductive element 4 (electric heater 41). As a result, the water supplied from the water supply pipe 3 into the storage tank 1 passes through the cooling water channel 5 formed inside the ice K, and is cooled by heat exchange with the ice K constituting the cooling water channel 5. Can be formed. Further, since the cooling water channel 5 is formed inside the ice K, the water passing through the cooling water channel 5 has a large contact area with the ice K, and can cool the water efficiently. Moreover, since the path | route of the cooling water channel 5 is decided by arrangement | positioning of the heat generation conduction element 4 (electric heater 41, the heat conduction parts 411-419), the heat generation conduction element 4 (electric heater 41, the heat conduction parts 411-419). It is possible to optimize the cooling water channel 5 according to the design (path arrangement) of the above and the heat capacity of the ice K. In the present embodiment, the heat generating conductive element 4 (electric heater 41, heat conductive portions 411 to 419) is arranged in the storage tank 1 so as to meander (bypass), thereby generating the heat generating conductive element (electric heater 41, The meandering (bypass) cooling water channel 5 along the heat conducting portions 411 to 419) can be formed, and the effective cooling water channel 5 can be formed in the limited internal space 11 of the storage tank 1. In this way, the internal space 11 (ice volume) of the storage tank 1 is effectively utilized by the arrangement (path, shape) of the heat generating conductive element 4 (electric heater 41, heat conductive portions 411 to 419), An effective cooling water channel 5 can be formed. Therefore, the cold water supply apparatus according to the embodiment can efficiently cool water and generate cold water. Moreover, in the cold water supply apparatus of the present embodiment, the cooling water channel 5 can be configured in the storage tank 1, so that a pump for constantly circulating water can be eliminated, and the apparatus can be reduced in cost and energy saving. It is advantageous.

  In addition, by configuring the heat generating and conducting element 4 with the electric heater 41, it is possible to easily change from current (electric energy) to heat for melting the ice K in the storage tank 1. Further, the flow diameter of the cooling water channel 5 can be adjusted by melting the ice K in the storage tank 1 by controlling the current of the electric heater 41 (for example, current intensity, energization time).

  Moreover, in the cold water supply apparatus of the present embodiment, the storage tank 1 is arranged in the storage tank 1 (introduction section 103) in parallel with the heat generation conductive element 4 (electric heater 41) by arranging the connection portion 3011 of the water supply pipe 3. Freezing of the water supply pipe 3 (connection portion 3011) for supplying water into the inside 1 can be suppressed. That is, the connection part 3011 of the water supply pipe 3 is parallel to the heat generation conductive element 4 (electric heater 41), so that heat generated from the heat generation conductive element 4 (electric heater 41) is directly conducted to the connection part 3011. The Therefore, the freezing suppression space 300 is formed inside the connection part 3011, and the water inside the connection part 3011 is maintained substantially at or above the freezing temperature. For this reason, the connection part 3011 of the water supply pipe 3 is suppressed from freezing due to the refrigeration state (freezing temperature or lower) inside the storage tank 1, and the water supply pipe 3 (connection part 3011) is brought into the storage tank 1 due to freezing. Inability to supply water can be prevented.

  Moreover, in the cold water supply apparatus of the present embodiment, the cooling means 2 has a freezer function for stored items required for low temperature storage such as food, and also functions as a water refrigerating means for the cold water supply apparatus. Can do. That is, the cooling means 2 of the cold water supply apparatus according to the present embodiment can be used for various purposes such as a freezer at the same time, in addition to functioning for making cold water supply. Therefore, the efficiency of the whole apparatus including the cooling means 2 is improved in the cold water supply apparatus of this embodiment.

  Moreover, in the cold water supply apparatus of the present embodiment, the cooling means 2 makes ice from the outer surface (102A) of the storage tank 1, so that it is not necessary to put the refrigerant piping of the cooling means 2 into the storage tank 1, and Function (freezer, refrigerator, etc.) system can be easily configured. Furthermore, it is possible to make ice using gas, liquid or the like as a refrigerant, and the degree of freedom of the cooling method for the water in the storage tank 1 is high.

  Moreover, in the cold water supply apparatus of this embodiment, since the storage tank 1 is disposed in the freezer L, the storage tank 1 (internal ice K) is stored cold when the door of the freezer L is opened and closed by taking in and out stored items. It functions as a material, can suppress temperature fluctuation (increase) in the freezer L (freezer space 202), and can keep the preservation state of foods in the freezer L (freezer space 202) in good condition.

  Moreover, in the cold water supply apparatus of the present embodiment, the heat generation conductive element 4 can generate heat only when water is cooled. Thereby, whenever the cold water is required, the heat generating conductive element 4 generates heat to form the cooling water channel 5, which is advantageous for energy saving as compared with the case where heat is always generated.

(Second Embodiment)
This embodiment is basically the same as the configuration of the first embodiment. Hereinafter, a different part from the first embodiment will be described. Note that portions similar to those in the first embodiment are described using the same reference numerals.

  FIG. 5 shows a cold water supply apparatus according to this embodiment. As shown in FIG. 5, the cold water supply apparatus according to the present embodiment is a modified embodiment in which a partition portion 25 is provided and deformed inside the freezer L shown in the first embodiment.

  Specifically, the partition part 25 is installed in the freezer L so as to partition the first cold air passage 24 between the storage tank 1 and the freezing space 202. That is, as shown in FIG. 5, the partition portion 25 is installed in parallel to the side surface 102 </ b> A of the storage tank 1. Accordingly, the first cold air passage 24 is defined between the side surface 25B of the partition portion 25 and the side surface 102A of the storage tank 1. Further, the side surface 25 </ b> A of the partition portion 25 faces the frozen space 202.

  The partition part 25 is comprised from the plate-shaped heat insulating material 101. FIG. In addition, the partition part 25 has an opening / closing part 23 </ b> A formed at an end connected to the upper part 10 </ b> A of the case part 10, and an opening / closing part 23 </ b> B formed at an end connected to the lower part 10 </ b> B. That is, opening / closing parts 23 </ b> A and 23 </ b> B for opening and closing the first cold air passage 24 are provided at both ends of the first cold air passage 24.

  The partition plate 201B is disposed so as to be orthogonal to the partition portion 25, and an opening 201C is formed between the partition plate 201B and the partition portion 25. Further, the partition plate 201 </ b> C is provided in parallel to the lower side portion 10 </ b> B and is disposed so as to be orthogonal to the partition portion 25. One end of the partition plate 201C is connected to the partition portion 25, and the other end forms an opening 201D together with the partition plate 201A. A cold air passage 203C is formed between the partition plate 201C and the lower portion 10B.

  As described above, when the open / close portions 23A and 23B are in the closed state, the cold air generated from the cooling means 2 flows into the freezing space 202 through the cold air passages 203A and 203B and the opening 201C, and the stored items in the freezing space 202 are stored. Can be cooled. After the cold air passes through the freezing space 202, it flows through the opening 201D to the cooling means 2 and is regenerated.

  When the open / close portions 23A and 23B are in the open state, the cold air generated from the cooling means 2 flows into the freezing space 202 through the cold air passages 203A and 203B and the opening 201C, and at the same time, the cold air passages 203A and 203B are opened and closed. It flows into the 1st cold wind path 24 via the part 23A, and the inside (water) of the storage tank 1 can be frozen from the side surface 102A of the storage tank 1. After passing through the first cold air passage 24, the cold air flows into the cooling means 2 through the opening / closing portion 23B and the cold air passages 203C and 203A and is regenerated.

  Thus, in the cold water supply apparatus of the present embodiment, by providing the partition portion 25 that thermally partitions the internal space of the freezer L, the freezing space 202 of the freezer L and the water (ice) in the storage tank 1 are supplied. It can divide | segment into the 1st cold wind path 24 for cooling. That is, the first cold air passage 24 is thermally blocked from the freezing space 202 by the partition portion 25, and the temperature fluctuation in the inside (freezing space 202) due to opening / closing of the door of the freezer L is the temperature in the first cold air passage 24. It becomes difficult to affect. Moreover, since the partition part 25 is provided with the opening / closing parts 23 </ b> A and 23 </ b> B, the passage of the cold air to the first cold air passage 24 is effectively controlled. That is, the flow of cold air is controlled in the first cold air passage 24, and the temperatures in the first cold air passage 24 and the freezing space 202 can be maintained. Moreover, the cold air for cooling the storage tank 1 can be freely passed through, and the water in the storage tank 1 can be effectively made. For example, when the door of the freezer L is opened and stored items such as foods are taken in and out of the freezer L (freezer space 202), the open / close portions 23A and 23B are automatically controlled to be closed, thereby freezing in the freezer L. Even if the temperature of the space 202 fluctuates, a temperature change in the first cold air passage 24 hardly occurs, and the influence of the temperature fluctuation on the storage tank 1 side can be effectively suppressed. Therefore, the ice K in the storage tank 1 is always maintained in a stable state (temperature), and the stable cooling water channel 5 can be formed inside the ice K. Moreover, since the water which flows through the cooling water channel 5 is cooled by the stable flow volume and temperature, the stable cold water can be supplied. Thus, by dividing the internal space of the freezer L into the freezing space 202 and the first cold air passage 24 via the partition portion 25 and the opening / closing portions 23A and 23B, the cold water supply device of the present embodiment can be used as a freezer. At the same time it can function, it can also supply stable cold water. Moreover, the cold water supply apparatus of the present embodiment example has the freezer function and the cold water cooling function at the same time, so that the efficiency of the entire apparatus including the cooling means 2 is improved.

(Third embodiment)
This embodiment is basically the same as the configuration of the first embodiment. Hereinafter, a different part from the first embodiment will be described. Note that portions similar to those in the first embodiment are described using the same reference numerals.

  FIG. 6 shows a longitudinal section (similar to the AA position shown in FIG. 1) of the storage tank 1 of the cold water supply apparatus of this embodiment. As shown in FIG. 6, the cold water supply apparatus of this embodiment example has the same configuration as that of the first embodiment example except that it differs with respect to the heat generation conductive element 4. That is, in the present embodiment, the heat source of the heat generation conductive element 4 is air existing outside, and the cooling water channel is formed by melting the ice in the storage tank 1 using the heat of the air. 5 is a form example.

  Specifically, as shown in FIG. 6, the heat generation conductive element 4 is arranged in the storage tank 1 of the present embodiment. The heat generation conductive element 4 of the present embodiment example includes a heat generation source 40A and a circulating heat medium pipe 41A connected to the heat generation source 40A. In addition, the heat generation source 40A and the circulating heat medium pipe 41A of the present embodiment constitute an air heat supply unit of the cold water supply apparatus of the present invention. Further, the circulating heat medium pipe 41A is made of a metal having good thermal conductivity. Inside the circulating heat medium pipe 41A, a heat medium flows, and heat is moved through the heat medium. An example of the heat medium used in this embodiment is a non-freezing heat medium (antifreeze) such as ethylene glycol.

  The heat generation source 40 </ b> A includes a radiator (heat radiator) 72 and a blower 71 that supplies hot air of air to the radiator 72. Further, the circulating heat medium pipe 41A includes an external pipe 400A, and the radiator 72 is disposed in the external pipe 400 of the circulating heat medium pipe 41A.

  As shown in FIG. 6, the circulating heat medium conduit 41 </ b> A is arranged in the internal space 11 of the tank case portion 102 so as to meander (detour). Specifically, the circulating heat medium pipe line 41 </ b> A includes first to ninth nine continuous tubular heat conducting parts 411, 412, 413, and 414 that are equally arranged in the internal space 11 of the tank case part 102. 415, 416, 417, 418, 419. That is, as shown in FIG. 6, the circulating heat medium pipe 41 </ b> A is introduced into the internal space 11 of the tank case part 102 via the introduction part 103. The first heat conducting part 411 is arranged so as to be parallel to the lower surface 102D of the tank case part 102. Next, following the first heat conducting unit 411, a second heat conducting unit 412 is disposed at a position close to the side surface 102F so as to make an U-turn upward. Next, following the second heat conducting unit 412, the third heat conducting unit 413 is arranged so as to be parallel to the first heat conducting unit 411. Next, following the third heat conducting unit 413, a fourth heat conducting unit 414 is disposed at a position close to the side surface 102E so as to make a U-turn upward. Similarly, the fifth heat conduction part 415, the sixth heat conduction part 416, the seventh heat conduction part 417, the eighth heat conduction part 418, and the ninth heat conduction part 419 are continuously connected to the internal space of the tank case part 102, respectively. 11 and are finally led out through the deriving unit 104. Further, the circulating heat medium pipe 41A is connected to the radiator 72 via the external pipe 400A. Further, the external pipe line 400A is provided with a pump P that circulates the heat medium inside the pipe line.

  Next, the operation of the cold water supply apparatus of this embodiment using the heat of air by the air heat supply unit will be described.

  (1) First, water is supplied into the storage tank 1 through the water supply pipe 3 by opening the flow rate adjusting means 302 and 602 (see FIG. 6). When the water in the storage tank 1 fills the internal space 11 of the storage tank 1, it flows out through the cold water outflow part 6. At this time, the flow rate adjusting means 302 is closed. That is, when the water in the storage tank 1 becomes full, the excess water is discarded by the cold water outflow part 6.

  (2) Next (see FIG. 6), the flow rate adjusting means 312 of the drainage unit 311 is opened for several seconds, and the water that has become full in the storage tank 1 is discharged through the drainage unit 311 in a predetermined volume (water volume). Is done. Thereby, a volume adjustment space 1101 is formed above the storage tank 1. The predetermined volume can be 1/10 to 3/10 of the total volume of the internal space 11 of the storage tank 1.

  (3) Next (see FIG. 1), while the set temperature of the freezing space 202 of the freezer L is maintained by the cold air (cold heat) from the cooling means 2, the cold air is stored in the storage tank 1 via the cold air passages 203A and 203B. Flowing on the side surface 102A. Therefore, cold heat is conducted into the storage tank 1 through the side surface 102A, and the water in the storage tank 1 is made into ice.

  (4) Then (see FIG. 6), the heat generation source 40A is operated, and the heat of the air is conducted to the heat medium in the circulation heat medium pipe 41A by the radiator 72 through the circulation heat medium pipe 41A. Furthermore, heat flows into the storage tank 1 along the circulating heat medium pipe line 41A via the heat medium. Therefore, the ice K in the peripheral area of the circulating heat medium pipe 41 </ b> A is melted by heat, and the cooling water path 5 is configured. A cross section of the cooling water channel 5 is shown in FIG. As described above, the cooling water passage 5 is formed along the length direction of the circulating heat medium pipe passage 41 </ b> A in a state covered with the ice K. Further, as shown in FIG. 6, the circulating heat medium pipe 41 </ b> A is disposed in the internal space 11 of the storage tank 1 so as to meander (detour) inside the ice K, so that the cooling water path 5 also circulates heat. It is formed so as to meander (detour) along the arrangement (path) of the medium pipe path 41A.

  (5) Next (see FIG. 6), by opening the flow rate adjusting means 302 and 602 again, water is supplied into the storage tank 1 via the water supply pipe 3. At this time, the supplied water flows into the cooling water channel 5 and rises while meandering (bypassing) along the cooling water channel 5 while contacting the ice K and melting the ice K (while exchanging heat). . Then, the cooled water (cold water) passes through the cooling water channel 5 and reaches the volume control space 1101. Further, the cold water stored in the volume control space 1101 is supplied to the user via the cold water outlet 104 and the cold water outlet 6.

  (6) After the cold water flows out, the storage tank 1 is full of water that will become the next ice. And it returns to the process of (2) and the process of (2)-(6) is repeated and cold water is supplied.

  As described above, in this embodiment, the heat generation conduction element 4 is configured by the air heat supply unit (the heat generation source 40A, the circulation heat medium pipe 41A), so that the heat of the air is the ice in the storage tank 1. It becomes the energy to melt K, and the amount of heat that air has can be used. Therefore, energy saving can be realized.

(Fourth embodiment)
This embodiment is basically the same as the configuration of the third embodiment. Hereinafter, a different part from the third embodiment will be described. Note that portions similar to those in the third embodiment are described using the same reference numerals.

  FIG. 7 shows a longitudinal section (similar to the position AA shown in FIG. 1) of the storage tank 1 of the cold water supply apparatus of this embodiment. As shown in FIG. 7, the cold water supply apparatus of the present embodiment has the same configuration as that of the third embodiment, except that the heat generation conductive element 4 is different.

  That is, in this embodiment, what constitutes the heat source of the heat generating and conducting element 4 includes the exhaust heat of the cooling means 2 in addition to the heat of air. The cooling water channel 5 can be effectively formed by melting the ice K in the storage tank 1 using the heat of the air and the exhaust heat of the cooling means 2.

  Specifically, as shown in FIG. 7, the heat generation conductive element 4 is arranged in the storage tank 1 of the present embodiment. The heat generation conductive element 4 of the present embodiment example includes a heat generation source 40A, a circulating heat medium pipe 41A connected to the heat generation source 40A, and an exhaust heat section 20B of the cooling means 2. In addition, the exhaust heat part 20B of the cooling means 2 is thermally connected to the circulating heat medium pipe 41A.

  The heat generation source 40A and the circulation heat medium pipe 41A of the present embodiment constitute an air heat supply unit of the cold water supply apparatus of the present invention.

  Further, as shown in FIG. 7, the circulating heat medium pipe 41 </ b> A includes pipes 621, 623, 625, and 626. The heat generation source 40A includes a radiator (heat radiator) 72 and a blower 71 that supplies hot air of air to the radiator 72, and is further thermally connected to the exhaust heat unit 20B of the cooler 20 (see FIG. 1). ing.

  Further, the circulating heat medium pipe 41A is made of a metal having good thermal conductivity. Inside the circulating heat medium pipe 41A, a heat medium flows, and heat is moved through the heat medium. In addition, as a heat medium used for this embodiment, the heat medium (antifreeze liquid) which does not freeze like ethylene glycol etc. can be illustrated.

  The radiator 72 is disposed in the pipe line 623, and the exhaust heat unit 20 </ b> B of the cooler 20 is disposed in thermal contact with the pipe line 624. The pipes 623 and 624 form a closed circuit W (→ 622 → 623 → 624 → 625 → 622 →) by the three-way communication portions 622 and 624. Further, a pipe line 621 is connected to the three-way communication part 622, and a pipe line 626 is connected to the three-way communication part 624. In this way, the exhaust heat unit 20B that generates heat (discharges from the cooling means 2) and the radiator 72 are arranged in the closed circuit W, and the closed circuit W is further arranged in the circulating heat medium pipe 41A.

  A pump P is installed in the pipeline 624. The pipe 621 is provided with a flow rate adjusting means 621A (valve) for opening and closing the pipe and adjusting the flow rate. A check valve 626A is installed in the pipe line 626, and the heat medium in the pipe line 626 is set to flow in the direction D1 (shown in FIG. 7).

In the state where the flow rate adjusting means 621A is closed, when the pump P is operated, the heat medium in the closed circuit W flows so as to circulate in the direction D2 (shown in FIG. 7), and from the exhaust heat unit 20B and the radiator 72. Heat can be accumulated while circulating. That is, when the cold water is not supplied, the heat medium having heat as a standby state is accommodated in the closed circuit W and does not flow into the storage tank 1.
When the flow rate adjusting means 621A is switched to the open state, the heat medium flows in the order of the pipe lines 625 and 621 (D3 direction, shown in FIG. 7) by the pump P. Furthermore, after flowing through the inside of the storage tank 1 along the circulating heat medium pipe 41 </ b> A, it is returned to the exhaust heat unit 20 </ b> B through the pipe 626 and regenerated. In this way, the heat medium flows so as to circulate along the directions D1 and D3 in the circulation heat medium pipe 41A. That is, when supplying cold water, the heat medium having heat as an operating state is released from the closed circuit W and flows into the storage tank 1 to melt the ice to form the cooling water channel 5. .

  Next, the operation of the cold water supply apparatus of the present embodiment using the heat of air and the exhaust heat of the cooling means 2 will be described.

  (1) First, (see FIG. 7), by opening the flow rate adjusting means 302, 602, water is supplied into the storage tank 1 via the water supply pipe 3. When the water in the storage tank 1 fills the internal space 11 of the storage tank 1, it flows out through the cold water outflow part 6. At this time, the flow rate adjusting means 302 is closed. That is, when the water in the storage tank 1 becomes full, the excess water is discarded by the cold water outflow part 6.

  (2) Next (see FIG. 7), the flow rate adjusting means 312 of the drainage unit 311 is opened for several seconds, and the water that has become full in the storage tank 1 is discharged through the drainage unit 311 in a predetermined volume (water amount). Is done. Thereby, a volume adjustment space 1101 is formed above the storage tank 1. The predetermined volume can be 1/10 to 3/10 of the total volume of the internal space 11 of the storage tank 1.

  (3) Next (see FIG. 1), while the set temperature of the freezing space 202 of the freezer L is maintained by the cold air (cold heat) from the cooling means 2, the cold air is stored in the storage tank 1 via the cold air passages 203A and 203B. Flowing on the side surface 102A. Therefore, cold heat is conducted into the storage tank 1 through the side surface 102A, and the water in the storage tank 1 is made into ice.

  (4) Then (see FIG. 7), the flow rate adjusting means 621A is set to the open state (switched from the standby state to the operating state), and the heat medium stored in the closed circuit W and having heat is a circulating heat medium pipe. It flows into the storage tank 1 through the path 41A. Therefore, the ice K in the peripheral area of the circulating heat medium pipe 41 </ b> A is melted by heat, and the cooling water path 5 is configured.

  (5) Next (see FIG. 7), by simultaneously opening the flow rate adjusting means 302 and 602 again, water is supplied into the storage tank 1 via the water supply pipe 3. At this time, the supplied water flows into the cooling water channel 5 and rises while meandering (bypassing) along the cooling water channel 5 while contacting the ice K and melting the ice K (while exchanging heat). . Then, the cooled water (cold water) passes through the cooling water channel 5 and reaches the volume control space 1101. Further, the cold water stored in the volume control space 1101 is supplied to the user via the cold water outlet 104 and the cold water outlet 6.

  (6) After the cold water is discharged, the storage tank 1 is almost full of water that becomes the next ice. And it returns to the process of (2) and the process of (2)-(6) is repeated and cold water is supplied. Further, by closing the flow rate adjusting means 621A, the heat medium is switched to a standby state in which heat is accumulated while circulating in the closed circuit W.

  As described above, in this embodiment, the heat generation conduction element 4 is configured by the air heat supply unit (the heat generation source 40A, the circulation heat medium pipe 41A), so that the heat of the air is the ice in the storage tank 1. It becomes energy that melts K, and the amount of heat that air has can be used. Furthermore, by configuring the heat generating conductive element 4 with the exhaust heat part 20B of the cooling means 2, the exhaust heat generated by the cooling means 2 can be reused and recovered as energy for melting the ice K. Therefore, the efficiency of the cooling means 2 can be improved while realizing energy saving.

(Fifth embodiment)
This embodiment is basically the same as the configuration of the third embodiment. Hereinafter, a different part from the third embodiment will be described. Note that portions similar to those in the third embodiment are described using the same reference numerals.

  FIG. 8 shows a longitudinal section (similar to the AA position shown in FIG. 1) of the storage tank 1 of the cold water supply apparatus of this embodiment. As shown in FIG. 8, the cold water supply device of the present embodiment has the same configuration as that of the third embodiment except that the heat generation conductive element 4 is different.

  That is, in this embodiment, what constitutes the heat source of the heat generating conductive element 4 is constituted by the heat of tap water. The cooling water channel 5 can be effectively formed by melting the ice K in the storage tank 1 using the heat of the tap water.

  Specifically, as shown in FIG. 8, the heat generation conductive element 4 is arranged in the storage tank 1 of the present embodiment. The heat generation conductive element 4 of the present embodiment example includes a heat generation source 40B and a heat medium pipe 41B connected to the heat generation source 40B.

  In addition, the heat generation source 40B and the heat medium pipe 41B of the present embodiment constitute a tap water heat supply unit of the cold water supply apparatus of the present invention. The heat medium pipe 41B is made of a metal having good heat conductivity. A heat medium flows in the heat medium pipe 41B, and heat is transferred through the heat medium. In addition, the tap water from the feed water piping 3 is directly utilized as a heat medium used for this embodiment.

  As shown in FIG. 8, the heat medium pipe 41 </ b> B includes pipes 631 and 314. The pipe line 631 is in communication with the outlet unit 104 side. The pipe line 414 communicates with the introduction unit 103 side.

  The pipe line 631 is provided with a flow rate adjusting means 631A (valve) for opening and closing the pipe line and adjusting the flow rate. Furthermore, a pipe line 633 communicating with the atmosphere is provided above the pipe line 631 connected to the derivation unit 104, and communicates with the pipe line 631 via the three-way communication unit 632. The three-way communication portion 632 is disposed in the pipe line 631 between the flow rate adjusting means 631A and the outlet portion 104. The pipe 633 is provided with a flow rate adjusting means 633A (valve) for opening and closing the pipe and adjusting the flow rate.

  The pipe 314 is provided with a flow rate adjusting means 314A (valve) for opening and closing the pipe and adjusting the flow rate. Further, the downstream side of the pipe 314 is communicated with the drainage part 311 via the three-way communication part 313. Note that the three-way communication portion 313 is disposed on the downstream side of the flow rate adjusting means 312.

  Thus, the heat generation source 40 </ b> B of the present embodiment example includes the water supply pipe 3. That is, tap water is supplied from the water supply pipe 3, and the heat of the tap water is conducted to the inside of the storage tank 1 through the heat medium pipe 41B. The tap water that has worked to form the cooling water channel 5 in the storage tank 1 and exchanged heat is discharged to the drainage unit 311 through the pipe 314.

  Further, the heat medium pipe 41B of the present embodiment example is similar to the circulation heat medium pipe 41A (see FIG. 6) of the third embodiment example, and the internal space of the tank case portion 102 is meandering (detouring). 11 is arranged.

  As described above, when the flow rate adjusting means 631A and 315 are switched to the open state, the tap water (heat medium) flows into the storage tank 1 through the pipe line 631. Then, it flows out of the storage tank 1 through the pipe 314 and is discharged. That is, the heat of the tap water (heat medium) flows into the storage tank 1, so that the cooling water channel 5 can be formed by melting the ice K around the heat medium pipe 41 </ b> B.

  In addition, when the water stored in the storage tank 1 is discharged from the drainage unit 311, a check valve (a gas or liquid is allowed to flow in one direction in the pipe line 1041 to maintain the atmospheric pressure in the storage tank 1. Possible valve) 601 is provided. The check valve 601 is installed so that air flows from the outside to the inside of the storage tank 1, and the water stored in the storage tank 1 cannot flow out to the outside through the check valve 601. That is, when water is supplied into the storage tank 1 from the water supply pipe 3, when the storage tank 1 is full of water, the excess water (cold water) flows to the cold water outflow portion 6 via the pipe line 1041. . Water does not flow outside through the check valve 601. Further, when the water in the storage tank 1 is discharged from the storage tank 1 through the drainage unit 311, the external air passes through the check valve 601 as the water level in the storage tank 1 (cold water) decreases. Can flow into the storage tank 1. Therefore, the pressure in the storage tank 1 is maintained, and water can easily flow out downward.

  Next, operation | movement of the cold water supply apparatus of the example of this embodiment using the heat of the tap water by a tap water heat supply part is demonstrated.

  (1) First, water is supplied into the storage tank 1 through the water supply pipe 3 by opening the flow rate adjusting means 302 and 602 (see FIG. 8). When the water in the storage tank 1 fills the internal space 11 of the storage tank 1, it flows out through the cold water outflow part 6. At this time, the flow rate adjusting means 302 is closed. That is, when the water in the storage tank 1 becomes full, the excess water is discarded by the cold water outflow part 6.

  (2) Next (see FIG. 8), the flow rate adjusting means 312 of the drainage unit 311 is opened for several seconds, and the water that has become full in the storage tank 1 is discharged through the drainage unit 311 in a predetermined volume (water amount). Is done. Thereby, a volume adjustment space 1101 is formed above the storage tank 1. The predetermined volume can be 1/10 to 3/10 of the total volume of the internal space 11 of the storage tank 1.

  (3) Next (see FIG. 8), while the set temperature of the freezing space 202 of the freezer L is maintained by the cold air (cold heat) from the cooling means 2, the cold air is stored in the storage tank 1 via the cold air passages 203A and 203B. Flowing on the side surface 102A. Therefore, cold heat is conducted into the storage tank 1 through the side surface 102A, and the water in the storage tank 1 is made into ice.

  (4) Then (see FIG. 8), the flow rate adjusting means 631A and 315 are set to the open state, and the tap water flows from the water supply pipe 3 to the storage tank 1 via the pipe line 631. The heat of the tap water is conducted into the storage tank 1 through the heat medium pipe 41B. Therefore, the ice K in the peripheral area of the heat medium pipe 41B is melted by heat, and the cooling water path 5 is configured.

  (5) Next (see FIG. 8), by opening the flow rate adjusting means 302, 602 again, water is supplied into the storage tank 1 via the water supply pipe 3 (pipe line 1031). At this time, the supplied water flows into the cooling water channel 5 and rises while meandering (bypassing) along the cooling water channel 5 while contacting the ice K and melting the ice K (while exchanging heat). . Then, the cooled water (cold water) passes through the cooling water channel 5 and reaches the volume control space 1101. Further, the cold water stored in the volume control space 1101 is supplied to the user via the cold water outlet 104 and the cold water outlet 6.

  (6) Further, by closing the flow rate adjusting means 631A and opening the flow rate adjusting means 633A and 315, air flows from the pipe line 633 to the heat medium pipe line 41B. The tap water flowing through the heat medium pipe 41B and constituting the heat medium flows out to the drainage section 311 side through the pipe 314. Thereby, in the standby state of the cold water supply device, the tap water (heat medium) in the heat medium pipe line 41B is discharged (exhausted), thereby preventing the heat medium pipe line 41B from freezing.

  (7) After the cold water is discharged, the storage tank 1 is almost full of water that becomes the next ice. And it returns to the process of (2) and the process of (2)-(6) is repeated and cold water is supplied.

  Thus, in the present embodiment, the heat generation conductive element 4 is configured by the tap water heat supply unit, so that the heat of the tap water becomes energy for melting ice, and the amount of heat of the tap water can be used. it can. Therefore, energy saving can be realized.

  The cold water supply apparatus of the present invention can be used in fields such as drinking water and cooling water.

It is a conceptual diagram (side sectional view) of the cold water supply apparatus in the first embodiment of the present invention. It is AA sectional drawing (longitudinal sectional view) shown in FIG. 1 of the cold water supply apparatus in the first embodiment of the present invention. It is an enlarged view of the introducing | transducing part of the cold water supply apparatus in 1st Example of this invention. It is a cross-sectional conceptual diagram of the cooling water channel of the cold water supply apparatus in the first embodiment of the present invention. It is a longitudinal cross-sectional view of the cold water supply apparatus in the 2nd Example of this invention. It is a longitudinal cross-sectional view of the cold water supply apparatus in the 3rd Embodiment of this invention. It is a longitudinal cross-sectional view of the cold water supply apparatus in the 4th Example of this invention. It is a longitudinal cross-sectional view of the cold water supply apparatus in the 5th Example of this invention.

Explanation of symbols

1: Storage tank 2: Cooling means 3: Water supply piping
4: Heat generation conductive element 5: Cooling channel K: Ice (Ice made water)
41: Electric heater 40A, 40B: Heat generation source 41A: Circulating heat medium conduit 41B: Heat medium conduit 20B: Waste heat section 3011: Connection section 300: Freezing suppression space L: Freezer 102A: Outer surface (storage tank)
23A, 23B: Opening / closing section 24: First cold air passage 25: Partition section

Claims (6)

A storage tank for storing water;
A water supply pipe connected to the storage tank and supplying water into the storage tank;
Cooling means for freezing water in the storage tank to make ice,
A heat generating conductive element provided in the storage tank for generating and conducting heat, and
The heat introduced into the storage tank through the heat generating conductive element melts the ice in the peripheral area of the heat generating conductive element, thereby forming a cooling channel along the heat generating conductive element inside the ice. The water supplied from the water supply pipe is cooled by passing through the cooling water channel. The cooling means includes a heat exhaust unit that discharges heat generated when the water in the storage tank is iced to the outside.
The heat generation conduction element includes an electric heater for melting the ice in the storage tank, a tap water heat supply unit for melting the ice in the storage tank, and an air for melting the ice in the storage tank. The chilled water supply device according to claim 1, wherein the chilled water supply device comprises at least one of a heat supply unit or the exhaust heat unit of the cooling means for melting ice in the storage tank. The water supply pipe includes a connection portion connected to the storage tank,
The connection portion is disposed in the storage tank in parallel with the heat generation conductive element, and a freezing suppression space in which freezing of water is suppressed is formed inside by the heat generated from the heat generation conductive element. The chilled water supply device according to claim 1, wherein: The cooling means includes a freezer,
The said storage tank is arrange | positioned in the said freezer, The water in the said storage tank is frozen from the outer surface of the said storage tank using the cold air in the said freezer, and ice-making is characterized by the above-mentioned. The cold water supply apparatus of any one of Claims. The freezer
A partition that thermally partitions the internal space of the freezer and partitions a first cold air passage through which cool air passes between the outer surface of the storage tank;
An opening / closing part provided in the partition part, for opening and closing the first cold air passage, and for controlling the passage of the cold air in the freezer to the first cold air passage;
5. The cold water supply apparatus according to claim 4, wherein the water in the storage tank is frozen from the outer surface of the storage tank by using cold air passing through the first cold air passage.   The cold-water supply device according to claim 1, wherein the heat-generating conductive element generates the heat only when the water is cooled.

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