JP3136330B2 - Heating / cooling method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heating and cooling method using a heating medium and a heating and cooling device. Here, the term heating / cooling device is a general heating device or cooling device, that is, a device for applying or removing heat.

[0002]

2. Description of the Related Art A cooling system using a refrigerant will be described below as an example of using a heat medium in a heating / cooling apparatus. A general flow diagram of a cooling system using a refrigerant is shown in FIG. The refrigerant cooled by the cooler 11 is stored in a refrigerant tank 12, and is introduced into a load 13 (a heat exchanger with a substance to be cooled or the like). Then, the heated refrigerant returns to the cooler 11.

If the load per hour and the cooling capacity of the cooler are the same and remain the same throughout the day, there is no problem as long as only a cooler suitable for the load is provided. However, the load usually fluctuates. If it fluctuates,
Even at the maximum load, the capacity of the cooler is adjusted to the maximum load so that the cooling can be performed appropriately. In this case, when the maximum load time is relatively short, for example, for one to two hours a day, a large cooler having a large capacity is required for the short time. Even if the total cooling capacity per day is sufficiently larger than the full load, a larger device is required if it cannot cope with the maximum load. And usually, it is used with reduced ability. Particularly, a cooling device for dehydrating city gas has a large problem. This is because the usage amount of city gas has a difference of more than 10 times at the peak amount in the evening from the minimum amount at night in the day. Introduction of such a large device that is unnecessary as a total capacity is very disadvantageous due to the problem of the installation area, the problem of the maximum contracted power, and the like.

[0004] Therefore, it is demanded that a cooler having a cooling capacity as small as possible can cover a daily load. Therefore, in the refrigerant tank provided in the circulation path of the heat medium,
It was devised to introduce a heat storage device. This is a substance that has a freezing point within the operating temperature of the heating medium.If the cooling capacity is excessive, it is solidified by that capacity, and when the cooling capacity is insufficient, the lack is compensated by the latent heat of solidification. is there.

[0005] According to this, it is not necessary to have a cooling device having the maximum load capability, and the size of the cooling device can be reduced.

[0006]

However, all the conventional heat storage devices are either fixed in position or installed in a spherical hard container filled with a heat storage agent. This has the following disadvantages.

FIG. 6 is a schematic view of a refrigerant tank 12 in which a number of heat storage tools 14 are introduced. In this example, the position of the spherical heat storage tool 14 is fixed by a net or the like. Now that there is room for cooling capacity, consider the process of cooling and solidifying the heat storage tool.
In this case, a heat medium having a low temperature enters from the inlet 15, and the temperature rises and is discharged from the outlet 16. The heat storage device 14 in the portion through which the low-temperature heat medium passes is cooled and solidified, but its path is relatively close to the bottom. This is because a heat medium having a lower temperature than the liquid in the tank is introduced. Then, since there is no movement as a whole, the vehicle passes through the route with emphasis. As a result, the heat medium is discharged without sufficient heat exchange, and the heat storage tool does not solidify sufficiently.

On the other hand, when the cooling capacity becomes insufficient, a high-temperature heat medium is introduced and passes through a relatively upper portion. This is because the heat medium having a high temperature is light, and the heat medium immediately proceeds upward near the entrance. Therefore, the heat medium passes above the solidified heat storage part, and the heat medium is discharged without being sufficiently exchanged (cooled). Of course, heat is exchanged for a long period of time, but when cooling must be performed rapidly, it may not be enough.

[0009] Furthermore, because of the spherical shape, it is conceivable that they gather at the flow portion and the flow becomes worse.

Although the cooling step has been described above, the same applies to a reverse heating device, and has the same drawbacks.

[0011]

In view of the above situation,
The inventor of the present invention has completed the method of the present invention as a result of earnest research, and the feature thereof is that a heat storage device for circulating a heat medium to a heating and cooling device and a load, and for storing heat during the circulation. A heating / cooling method having a heat medium retention tank containing the heat storage device, wherein the heat storage device comprises a flexible plastic container and a heat storage agent filled therein, and when 30% or more of the heat storage agent solidifies, the heat storage device expands. In this case, the specific gravity of the entire heat storage tool is adjusted to be equal to or less than the heat medium.

The heat medium may be any medium such as a refrigerant such as ethylene glycol or an aqueous solution thereof, or any other medium used as a medium for exchanging heat between a cooler and a load. Further, the heat medium storage tank is a container for storing a heat medium, and in the present invention is a container into which a heat storage tool is also introduced. The tank itself may be of any type and may be conventional.

The heat storage tool is a flexible plastic container filled with a heat storage agent. Flexibility is an essential requirement of the present invention, and it is necessary that the volume of the entire heat storage tool can be changed. Flexibility means the state of the filling inside,
A property that can be easily deformed by external pressure. As the material, polyethylene, polypropylene, and the like are inexpensive and suitable. The reason for making it deformable is that it can greatly reduce damage to the container due to expansion and contraction of the volume when the heat storage agent solidifies or melts, and that the deformation changes the volume of the container itself, resulting in a change in specific gravity as a whole This is to make the ups and downs. In addition, any shape may be used, but a shape having a thin portion and a thick portion such as a beer bottle or a mayonnaise container is preferable. According to this shape, the flow of the heat medium can be made smooth and blocking can be prevented.

[0014] The heat storage device may be any one as long as its weight can be adjusted by the above-mentioned container, but if not, a weight may be fixed or inserted. This is used for adjusting the specific gravity and for determining the position of the heat storage tool at rest (which one is down). Of course, not all regenerators need to be the same.

Next, the heat storage agent is filled in the plastic container, and performs heat balance by solidification and melting. This must have a freezing point within the operating temperature range of the heating medium. Further, when solidification is at least 30%, which is the maximum point of the present invention, it is necessary that the specific gravity of the heat medium to be used is not more than the specific gravity. When the heat storage agent is calculated as water, it is as follows. 3 heat storage containers
0 g, volume 30 cm ³ . The weight of the water is 500 g and the volume is 500 cm ³ . It has a weight of 20 g and a volume of 3 cm ³
Put the weight of. Therefore, the specific gravity of the whole is (30 + 500 + 20) / (30 + 500 + 3) = 1.032 It is assumed that this water is frozen by 30%. When the water freezes, the volume is 1.
093 times and the container expands with it, but its volume does not change. Total volume = 30 + 500 x 0.7 + (500 x 0.3 x 1.093) + 3 = 543.95 Total specific gravity = 550 / 543.95 = 1.011.

Therefore, the specific gravity of the heat medium is 1.032
In the following, when the heat storage agent is 1.011 or more, it sinks when the heat storage agent is in a liquid state and floats when 30% or more freezes. Since there are usually many having such specific gravity, it is not necessary to select a special one. For example, taking a refrigerant as an example, an aqueous solution of about 8% ethylene glycol may be used.

FIG. 1 is a graph showing how the specific gravity of the entire heat storage device decreases depending on the freezing rate of the heat storage agent (in this case, water). The specific gravity for all liquids is 1.032, and the specific gravity for all solidified is 0.949. Therefore, the specific gravity of this heat storage tool changes during this period. According to this graph, when the specific gravity of the heat medium is determined, it is also possible to determine what percentage or more of the heat storage agent solidifies and rises. For example, the specific gravity of the heat medium is 0.98
When nine are used, 50% or more of the whole should be frozen.

On the other hand, when the heat medium is determined, the calculation is performed in the opposite manner to determine what kind of heat storage agent should be filled, and how to make the weight. be able to. After all, according to the present invention, the specific gravity of the heat medium and the specific gravity of the heat storage agent when the liquid is solidified and the weight and volume of the weight, and what percentage of the weight should be adjusted when they are solidified, should be adjusted to meet the conditions. Become.

Of course, it is premised that the freezing point of the heat storage agent is within the operating temperature range of the heat medium. The operating temperature of the heating medium means a range between the maximum temperature and the minimum temperature of the heating medium. For example, in operation, when the refrigerant is cooled to -5 ° C by a cooler, and then cooled to -8 ° C by heat exchange with a load, and then cooled again to -5 ° C by a cooler, the temperature is between -5 ° C and 8 ° C. That is. In a solar heating apparatus using solar heat or the like that uses a heat medium (that is, the heat medium only circulates in a closed system), the temperature is generally about 10 to 70 ° C.

The heat storage agent need not be a pure substance but may be a mixture. For example, with water, ethylene glycol, etc.
The solidification point and specific gravity may be adjusted. In addition, in the case of a heating device, the solidification point becomes high, so that it may be selected from paraffin or the like.

The heat storage device of the present invention is not limited to a single-pass heat medium as described above. The heat storage device has a separate loop between the heating / cooling machine side and the load side. Any material such as those mixed in a tank may be used. In short, what is necessary is just to have a container through which the heat medium to be heated or cooled directly or indirectly by the heating / cooling machine passes.

[0022]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in more detail with reference to the embodiments shown in the drawings. FIG. 2 is a perspective view showing the heat storage device 1 of the present invention. This is a polyethylene container which is almost the same in shape as a beer bottle, and is filled with a heat storage agent having a freezing point of -5 ° C. The component of this heat storage agent is an aqueous solution of about 14% ethylene glycol. The expansion of the volume when solidified is slightly smaller, but not much different, than when all of the above is water.

FIG. 3 is a view similar to FIG. 5, in which the heat storage tool of FIG. It can be seen that many heat storage tools 14 are located below. Since the heat medium having a low temperature is introduced from the inlet, most of the heat medium contacts the heat storage device and short-circuits to the outlet.

Next, the amount of heat will be described. Needless to say, since the freezing point of the heat storage agent is -5 ° C., the freezing point of the refrigerant in the piping is lower than that. Right here,
This cooling condition is assumed as follows. Cooling capacity: 100,000 kcal / h Load Peak: 200,000 kcal / h (3.2 hours) Normal: 50,000 kcal / h (20.8 hours) Liquid coagulation heat: 80 kcal / kg

The peak 3.2 hours is 100,000 kcal / h
Capacity is insufficient, so the amount of negative heat is 100,000 × 3.2 = 32
0,000 required. Therefore, 320,000 divided by 80 = 4,000 kg of liquid is required. Then, the heat storage agent that has already solidified is melted, thereby absorbing the amount of heat.

At the end of the peak time, the load is 50,000 kcal
/ H, the capacity of the cooler becomes excessive. With this excess capacity, the heat storage agent of the heat storage tool is recondensed. In this example, 320,000 / 50,000 = 6.4 hours. Therefore, the vehicle is operated at full capacity for 6.4 hours regardless of the load, and after that, the capacity is reduced by half to 50,000
Kcal / h operation is sufficient. In this way, the capacity of the cooler may be 100,000 kcal / h even though the maximum load is 200,000 kcal / h.

The flow of the refrigerant may be controlled by controlling the load and the amount to the bypass provided in the refrigerant tank. This can be done while watching the temperature at each point. The present invention is a heat storage device, and the driving method and the like need not be special. Further, all the heat storage tools to be put in the tank need not be the heat storage tools of the present invention.

In the state shown in FIG. 3, if the cooler 11 has sufficient capacity, the heat storage device 14 gradually solidifies and starts to float from the time when it solidifies by about 30% or more. FIG. 4 shows a state where almost all the heat storage tools are floating. In this state, if the capacity of the cooler is insufficient, the inlet temperature increases, the temperature of the introduced heat medium increases, and the heat medium moves upward immediately after entering the container. Since a large number of heat storage tools exist near the position, the heat is taken away by the solidified heat storage tool and the heat storage tool is cooled. This not only compensates for the insufficient cooling capacity, but also allows for sufficient heat exchange without the short path of the heat medium as described above.

In the above embodiment, an example using a cooler has been described, but this is exactly the same for the heating device (heating and cooling are reversed, and the positions of the inlet and outlet are also reversed).

[0030]

According to the heating and cooling method of the present invention, the following effects can be obtained. The maximum capacity of the heating / cooling machine can be reduced. It can be easily and quickly implemented on existing plants. Since blocking of the heat storage tool does not occur, no stress is applied to the refrigerant tank, and a conventional one can be used. The heat storage container itself is easily manufactured and inexpensive. In addition, the fillers therein are also inexpensive. Since the heat storage tool floats and sinks, not only there is no short path of the flow, but also because of the stirring effect, heat exchange is performed efficiently and quickly. Therefore, when the capacity of the cooler is insufficient, it can be promptly compensated.

[Brief description of the drawings]

FIG. 1 is a graph showing an example of the specific gravity of the heat storage device of the present invention.

FIG. 2 is a perspective view showing an example of the heat storage device of the present invention.

FIG. 3 is a schematic flow sheet illustrating the method of the present invention.

FIG. 4 is a schematic flow sheet illustrating the method of the present invention.

FIG. 5 is a schematic flow sheet showing a conventional example.

FIG. 6 is a schematic flow sheet showing a conventional example.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 11 Cooler 12 Refrigerant tank 13 Load 14 Heat storage device 15 Inlet 16 Outlet

────────────────────────────────────────────────── ─── Continued on the front page (72) Minoru Yamada, Inventor Cosmo Engineering Co., Ltd. 1-20-19 Shimanouchi, Chuo-ku, Osaka-shi (58) Field surveyed (Int. Cl. ⁷ , DB name) F28D 20 / 00 C09K 5/00 101 C09K 5/06

Claims (1)

(57) [Claims] 1. A heating / cooling method comprising circulating a heat medium to a heating / cooling device and a load, and having a heat medium retention tank including a heat storage tool for storing heat during the circulation. It comprises a flexible plastic container and a heat storage agent filled therein, and when 30% or more of the heat storage agent solidifies,
A heating and cooling method characterized by adjusting the specific gravity of the entire heat storage device to be less than or equal to the heat medium by expansion.