JPH086171Y2 - Ice heat storage system - Google Patents

Description

[Detailed Description of the Invention] [Industrial field of application] The present invention relates to an ice heat storage system that stores ice produced by an ice maker in an ice storage tank to store heat.

[Conventional technology]

Since the power demand at night is much smaller than that at daytime, the use of night power is promoted by significantly discounting the night power charge.

For this reason, conventionally, night power is used to store heat at night,
This heat energy is used during the daytime for indoor air conditioning, refrigerators, and the like.

As such a heat storage system, conventionally, a harvested ice heat storage system has been known in which ice produced by an ice making machine is stored in an ice storage tank to store heat.

As such an ice heat storage system, for example, Showa 63
It is known that it is described in the REALIZE seminar text "Practice and future prospects of ice thermal storage air conditioning system" of the seminar held by Realize Co., Ltd. on April 21 and 22, 2014.

FIG. 4 shows an ice heat storage system described in this seminar text, and reference numeral 11 denotes an ice making unit.

A plurality of ice making plates 13 are vertically arranged in the ice making unit 11, and a freon gas flow passage 15 is formed in each of the ice making plates 13.

In addition, flow pipes 17 and 19 for CFC gas are connected to the flow passages 15 at the upper and lower ends of the ice making plate 13.

Below the ice making plate 13, a tray 21 having a discharge port is arranged. This discharge port communicates with an ice storage tank 23 arranged below the tray 21 through a communication pipe 25, and an ice breaker 27 is arranged in this communication pipe 25.

Further, a water sprinkling pipe 29 is arranged in the ice making unit 11 located above the ice making plate 13, and this water sprinkling pipe 29 is connected to a pipe 31 in which a pump 30 is arranged.
The lower end of is placed in the water 35 of the ice storage tank 23.

In such an ice heat storage system, in a process in which the water 35 sprinkled from the water sprinkling pipe 29 flows down the surface of the ice making plate 13, the CFC liquid flowing through the flow passage 15 of the ice making plate 13 evaporates, and a part of the flowing water is removed. Ice is applied to the surface of the ice making plate 13.

Then, when the ice 37 reaches a thickness of several mm, that is, after a certain period of time, high temperature CFC gas is sent to the flow passage 15 of the ice making plate 13 for several tens of seconds to heat the ice making plate 13, and FIG. As shown in, the ice 37 is separated from the ice making plate 13, dropped by gravity, crushed by the ice crusher 27, and an ice storage tank in which water 35 is stored.
Store ice 37 in 23 mixed with water 35. Water in this ice storage tank 35
Is supplied to a load such as an air conditioner and placed in this load for heat exchange.

In the ice heat storage system configured as described above, for example, it is possible to store heat energy by storing ice energy at night when the electricity rate is low, and use this heat energy for indoor cooling or a refrigerator during the daytime. Electric power can be effectively used.

However, in such a conventional ice heat storage system, since the water 35 and the ice 37 are mixed and stored in the ice storage tank 23 in which the water 35 is stored, the ice 37 and the water 35 coexist in the ice storage tank 23. However, there is a problem that it is very difficult to measure the amount of ice 37 in the ice storage tank 23.

Therefore, the ice storage tank that is cooled by the remaining ice 37
The amount of water 35 in 23, that is, the amount of residual heat storage is unknown,
There is a problem that it is very difficult to make an operation plan for the air conditioner or the like in response to a change in the amount of heat energy used due to the load of the air conditioner or the like.

In order to solve such a problem, the present applicant filed a patent application for an ice heat storage system on the same date as the utility model registration application.

FIG. 6 shows an ice heat storage system described in the specification of this patent application. In the figure, reference numeral 41 denotes an ice making machine for producing ice chips or crushed stones.

As the ice making machine 41, for example, a North Star ice making machine (trade name) is used.

Below this ice making machine 41, an ice storage tank 45 for storing the ice 43 produced by the ice making machine 41 is arranged, and at the lower part of this ice storage tank 45, a drain port 47 for draining cold water is formed. . The drain port 47 is always open.

Further, a sprinkler 48 is arranged in the upper part of the ice storage tank 45, and this sprinkler 48 has a large number of water spray nozzles 51 for spraying the ice 43 in the ice storage tank 45 on the lower surface of the water spray pipe 49. It is arranged and formed.

Below the ice storage tank 45, a water receiving tank 53 that receives cold water from the drainage port 47 of the ice storage tank 45 is arranged.

The water receiving tank 53 and the sprinkler 48, the cold water of the water receiving tank 53,
For example, they are connected by a cold water supply passage 57 for supplying to a load 55 such as an air conditioner, and the water that has undergone heat exchange in this load 55 is supplied to the sprinkler 48.

Also, on the load 55 side of the circulation pump 59,
61 is branched from the cold water supply passage 57, and this hot water supply passage 61
Is connected to the sprinkler 48. Sprinkler rather than branch point
A cold water supply valve 63 and a bypass valve 65 are arranged in the cold water supply passage 57 and the hot water supply passage 61 on the 48 side, respectively.

Further, the water receiving tank 53 and the ice maker 41 are connected by a raw water supply passage 67 for supplying the water in the water receiving tank 53 to the ice maker 41, and the raw water pump 69 is connected to the raw water supply passage 67. Are arranged.

A water level gauge 71 that measures the water level in the water receiving tank 53 is arranged in the water receiving tank 53 that stores cold water. The water level gauge 71 is a water level W between the water level WL ₁ when 100% ice is stored in the ice storage tank 45 and the water level WL ₂ when the ice 43 in the ice storage tank 45 is completely thawed.
It is configured to measure L. This water level gauge 71 is connected to, for example, a monitor in a monitoring room that monitors the ice heat storage system, and measures the difference (WL ₂ −WL) between the water level WL ₂ and the water level WL when cold water is being supplied to the load 55. It is configured to calculate and represent.

In the ice heat storage system configured as described above, for example, the raw water pump 69 is started at night, and the raw water supply passage
The water in the water receiving tank 53 is supplied by the 67 to the ice making machine 41, and the ice making machine 41 produces chip-shaped and crushed stone-like ice 43.
43 is stored in the ice storage tank 45. When the water in the water receiving tank 53 falls according to the production amount of the ice 43 and reaches the predetermined water level WL ₁ , the raw material water pump 69 is stopped, whereby the ice heat storage is completed.

Next, for example, when the heat energy stored at night is taken out as cold water in the daytime, the cold water supply valve 63 is closed and the bypass valve 65 is opened, the circulation pump 59 is started, and the hot water supply flow is started. The hot water in the water receiving tank 53 is sprayed from the water spraying device 48 onto the ice 43 in the ice storage tank 45 through the path 61, and the hot water is cooled while passing through the ice 43 to be cold water. This cold water is the ice storage tank 45
The cold water in the water receiving tank 53 is stored in the water receiving tank 53 through the outlet 47 of the cold water, and the cold water supply valve 63 is opened to supply the cold water in the water receiving tank 53 to the load 55 through the cold water supply flow path 57, and the heat is exchanged in the load 55. Performed by.

Then, in the ice heat storage system configured as described above, the ice storage tank 45 in which the ice 43 is stored and the drain port 47 is formed is arranged below the ice making machine 41 that manufactures the ice 43, and the drain port is formed.
A water receiving tank 53 for receiving cold water from the 47 is arranged below the ice storage tank 45, and a water sprinkler 48 for spraying the ice 43 in the ice storage tank 45 is installed in the ice storage tank 45.
And the water receiving tank 53 and the ice maker 41 are placed inside the raw water supply passage 57.
The water receiving tank 53 and the sprinkler 48 are connected by the cold water supply flow path 57 via the load 55, and the water receiving tank 53 is provided with the water level gauge 71 for measuring the water level in the water receiving tank 53. Water level of the water receiving tank 53 when the ice 43 is not stored in the ice storing tank 45 WL ₂
And the water level in the water tank 53 when cold water is being supplied to the load 55.
By measuring WL and obtaining the difference (WL ₂ −WL), the amount of ice remaining in the ice storage tank 45 can be confirmed, and the remaining heat storage amount can be measured more reliably than before. it can.

This makes it easier than before to make an operation plan for the load 55 in response to changes in the amount of heat energy used by the load 55.

[Problems to be solved by the device]

However, in such an ice heat storage system, when the ice 43 in the ice storage tank 45 becomes less and becomes scattered, the water sprinkled from the water sprinkler 48 becomes iced as shown in FIG.
There was a problem that the sprinkled water was not cooled effectively because a state where the water flowed into the water receiving tank 53 from the drainage port 47 occurred without contacting with 43.

Then, there is a problem that the cooled water and the uncooled water are mixed and stored in the water receiving tank 53, and the cold water temperature in the water receiving tank 53 rises.

The present invention has been made to solve the above problems, and an object thereof is to provide an ice heat storage system that can use the ice in the ice storage tank to cool the sprinkled water to the end. And

[Means for solving the problem]

The ice heat storage system of the present invention is an ice maker that produces chip-shaped or crushed ice, and an ice storage tank that stores the ice produced by this ice maker and has a drain outlet formed at the bottom for draining cold water, A water receiving tank that receives cold water from the drainage port of this ice storage tank, a water sprinkling device that is disposed in the ice storage tank and sprays ice on the ice storage tank, and a load that supplies the cold water of the water receiving tank to a load. And a cold water supply flow path for supplying the heat-exchanged water to the water sprinkling device, the inner surface of the bottom of the ice storage tank, when the ice is now scattered in the ice storage tank,
A baffle for guiding the water sprinkled from the water sprinkler to the drainage port is arranged.

[Action]

In the ice heat storage system of the present invention, when the ice in the ice storage tank becomes less and becomes scattered, the water sprinkled from the water sprinkler is meandered by the baffle plate arranged on the inner surface of the bottom of the ice storage tank. During this meandering of water, the water is cooled by contact with ice.

〔Example〕

The present invention will now be described in detail with reference to an embodiment shown in the drawings.

FIG. 1 shows an ice heat storage system of the present invention. In the figure, reference numeral 81 indicates an ice making machine for producing ice chips or crushed stones.

As the ice making machine 81, for example, a North Star ice making machine (trade name) is used.

Below this ice making machine 81, an ice storage tank 85 for storing the ice 83 produced by the ice making machine 81 is arranged, and at the lower part of this ice storage tank 85, a drain port 87 for draining cold water is formed. . This drain port 87 is always open.

Further, a water sprinkler 88 is arranged in the upper part of the ice storage tank 85, and the water sprinkler 88 has a large number of water spray nozzles 91 for spraying the ice 83 in the ice storage tank 85 on the lower surface of the water spray pipe 89. Are arranged.

Below the ice storage tank 85, a water receiving tank 93 that receives cold water from the drain port 87 of the ice storage tank 85 is arranged.

The water receiving tank 93 and the sprinkler 88, the cold water of the water receiving tank 93,
For example, they are connected by a cold water supply flow path 97 for supplying to a load 95 such as an air conditioner, and the water that has undergone heat exchange in this load 95 is supplied to the sprinkler 88.

Also, on the load 95 side of the circulation pump 99,
101 is branched from the cold water supply passage 97, and this hot water supply passage 1
01 is connected to the sprinkler 88. A cold water supply valve 103 and a bypass valve 105 are respectively arranged in the cold water supply passage 97 and the hot water supply passage 101 on the sprinkler 88 side of the branch point.

Further, the water receiving tank 93 and the ice maker 81 are connected by a raw water supply passage 107 for supplying the water of the water receiving tank 93 to the ice maker 81, and the raw water pump 109 is connected to the raw water supply passage 107. Are arranged.

Further, in the water receiving tank 93 that stores cold water, a water level gauge 111 that measures the water level in the water receiving tank 93 is arranged. This water level meter 111 can measure the water level WL between the water level WL ₁ when 100% ice is stored in the ice storage tank 85 and the water level WL ₂ when the ice 83 in the ice storage tank 85 is completely thawed. Is configured. This water gauge 111
For example, it is connected to a monitor in a monitoring room that monitors the ice heat storage system, and the difference (WL ₂ −WL) between the water level WL ₂ and the water level WL when supplying cold water to the load 95 is calculated and expressed. It is configured.

The inner surface of the bottom of the ice storage tank 85 is an inclined bottom surface 113 that inclines downward toward the drainage port 87 in the center.
As shown in FIG. 1 and FIG. 2, when the ice 83 is scattered in the ice storage tank 85, the water sprayed from the water spray device 88 is meandered on the inclined bottom surface 113 of the A plurality of metal baffle plates 115 leading to the drainage port 87 are arranged.

These baffle plates 115 are formed by arranging a single metal plate in the vertical direction, and the inclined bottom surface 113 is formed by welding or the like.
It is stuck to.

In the ice heat storage system configured as described above, for example, the raw material water pump 109 is started at night, the water in the water receiving tank 93 is supplied to the ice making machine 81 by the raw material water supply passage 107, and the ice making machine 81 makes chips. -Shaped, crushed stone-shaped ice 83 is manufactured, and the ice 83 is stored in the ice storage tank 85. When the water in the water receiving tank 93 falls according to the production amount of the ice 83 and reaches the predetermined water level WL ₁ , the raw material water pump 109 is stopped, whereby the ice heat storage is completed.

Next, for example, when the thermal energy stored at night is taken out as cold water in the daytime, the cold water supply valve 103 is closed and the bypass valve 105 is opened, and the circulation pump 9
9, the hot water in the water receiving tank 93 is sprinkled on the ice 83 in the ice storage tank 85 from the water sprinkling device 88 by the hot water supply flow path 101, and the hot water is turned into the ice 83
It is cooled to cold water while passing through it. This cold water is stored in the water receiving tank 93 from the outlet 87 of the ice storage tank 85, and the cold water supply valve 10
By opening 3, cold water in the water receiving tank 93 is supplied to the load 95 via the cold water supply passage 97, and heat is exchanged in the load 95.

Then, in the ice heat storage system configured as described above, when the ice 83 in the ice storage tank 85 becomes less and becomes scattered, due to the baffle 115 arranged on the inclined bottom surface 113 of the ice storage tank 85, The water sprinkled from the sprinkler 88 meanders, as shown in FIG. 3, and contacts the ice 83 during the meandering of the water to cool the water.

Thus, in the ice heat storage system configured as described above, the water sprinkled from the sprinkler 88 when the ice is scattered in the inside of the bottom of the ice storage tank 85. Since the baffle plate 115 that guides the drainage port 87 while meandering is arranged, when the ice 83 in the ice storage tank 85 decreases and becomes scattered, the baffle plate arranged on the inclined bottom surface 113 of the ice storage tank 85. The water sprinkled from the sprinkler 88 is meandered by the 115, and the water is cooled by coming into contact with the ice 83 during the meandering of the water, and the ice 83 in the ice storage tank 85 is finally cooled to cool the sprinkled water. Therefore, even if the ice 83 becomes scattered, the cold water temperature in the water receiving tank 53 can be maintained at a low temperature, and the load 95
The control corresponding to can be performed.

In addition, in the ice heat storage system configured as described above,
Below the ice making machine 81 that produces the ice 83, an ice storage tank 85 that stores the ice 83 and has a drain port 87 is arranged, and a water receiving tank 93 that receives cold water from the drain port 87 is located below the ice storage tank 85. Placed in
A sprinkler 88 for sprinkling water on the ice 83 in the ice storage tank 85 is arranged in the ice storage tank 85, the water receiving tank 93 and the ice maker 81 are connected by the raw water supply flow path 107, and the water receiving tank 93 and the water sprinkling device 88 are connected. Are connected by a cold water supply flow path 97 via a load 55, and the water receiving tank 93 is connected to this water receiving tank.
Since the water level gauge 111 for measuring the water level in 93 is arranged, the water level WL _{2 in} the water receiving tank 93 when the ice 83 is not stored in the ice storage tank 85
And the water level in the receiving tank 93 when supplying cold water to the load 95.
By measuring WL and obtaining the difference (WL ₂ −WL), the amount of ice remaining in the ice storage tank 85 can be confirmed, and the remaining heat storage amount can be measured more reliably than before. it can.

This makes it easier than before to make an operation plan for the load 95 in response to changes in the amount of heat energy used by the load 95.

In the above embodiment, an example in which the baffle plate 115 is arranged on the inclined bottom surface 113 of the ice storage tank 85 has been described, but the present invention is not limited to the above embodiment, and the bottom surface of the ice storage tank is made flat. Even if it is formed and a baffle plate is arranged on this flat bottom surface, it is possible to obtain substantially the same effect as in the above embodiment.

[Effect of device]

In the ice heat storage system of the present invention, on the inner surface of the bottom of the ice storage tank,
When ice is scattered in this ice storage tank, a baffle that guides the water sprinkled from the sprinkler device to the drain port is arranged, so the ice in the ice storage tank decreases and When present, the baffle placed on the inner surface of the bottom of the ice storage tank meanders the water sprinkled from the sprinkler, and the water is cooled by contacting the ice during the meandering of the water. The ice inside can be used to cool the sprinkled water until the end.

[Brief description of drawings]

FIG. 1 is an explanatory view showing an embodiment of the ice heat storage system according to the present invention. FIG. 2 is an explanatory view showing a state where ice is scattered in the ice storage tank of FIG. FIG. 3 is a plan view showing the baffle plate of FIG. 1 and its vicinity. FIG. 4 is an explanatory view showing a state where ice is manufactured in the conventional harvest-type ice heat storage system. FIG. 5 is an explanatory view showing a state where ice is separated from the ice making plate and stored in the ice storage tank in the ice heat storage system of FIG. FIG. 6 is an explanatory diagram showing an ice heat storage system for which a patent application was filed by the applicant on the same date. FIG. 7 is a plan view showing a state where ice is scattered around the drainage port of the ice storage tank of FIG. 6 and its vicinity. [Explanation of symbols for main parts] 81 …… ice maker 83 …… ice 85 …… ice storage tank 87 …… drain port 88 …… sprinkler 93 …… water receiving tank 97 …… cold water supply channel 115 …… obstruction Board.

Claims (1)

[Scope of utility model registration request] Claim: What is claimed is: 1. An ice maker for producing chip-shaped or crushed ice, an ice storage tank for storing the ice produced by the ice maker, and a drain outlet for discharging cold water to the bottom, and the ice storage. A water receiving tank that receives cold water from the drainage port of the tank, a water sprinkling device that is arranged in the ice storage tank and sprays ice in the ice storage tank, and the cold water of the water receiving tank is supplied to a load and heat exchange is performed at this load. A cold water supply flow path for supplying the water to the sprinkler, the inner surface of the bottom of the ice storage tank, when the ice is scattered in the ice storage tank, from the sprinkler An ice heat storage system comprising a baffle arranged to meander the sprinkled water to the drainage port.