JPH02110297A - heat storage tank - Google Patents

Abstract

(57) [Abstract] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention is applicable to late-night power generation or cogeneration (
The present invention relates to a heat storage tank that stores heat using surplus power and surplus heat of a combined heat and power generation system.

[Prior Art] Conventionally, there is no suitable heat storage material for heat below 100°C and above 50°C, and water is generally used. Water can utilize latent heat for steam at temperatures above 100°C, but cannot utilize latent heat for temperatures below 100°C to room temperature. Thermal storage systems that use partial chemical compounds and hydrated salts are also considered to have issues such as overcooling, deterioration, and productivity.

On the other hand, water has a large specific heat, so even if Wi heat cannot be used, a relatively large amount of heat can be stored.For other substances, if latent heat is not used, the specific heat is small, so there is little heat storage.
It is not possible to obtain the effect as a heat storage tank.

[Problem to be solved by the invention] Salts, bricks, etc. can be used to store heat at high temperatures of several hundred degrees Celsius or higher, but since the temperature difference is large, sensible heat can also be used to store heat. On the other hand, at temperatures below 100°C, there is currently no serious use of anything other than wood.

Now, store warm water at 85°C in i, ooo, and heat it to 55°
Assuming that the heat is radiated to a temperature of C, the amount of heat released by hot water is 1 x 1,000 fLx :lO℃= :lO,0
00k cal.

If ethylene-vinyl acetate copolymer (hereinafter referred to as EVA) is used as a heat storage material, the latent heat of EVA will be 5
5 kcal/Jl from 85℃
55k cal x 1.0001 + 0.2 x for a temperature change of °C
1.000 sentences x 30℃ = 61,000k cal. In addition, 0, 2 (k c a 1 / l
'C) is the specific heat of EVA.

Therefore, if latent heat can be used, the amount of heat storage will be extremely large, even if the plastic has a small specific heat.

If we were to discover a material that has latent heat in the temperature range below 100°C and above 50°C, which is necessary as a primary heating medium for hot water supply and space heating, and create a heat storage tank using this material, it would be of great benefit. In particular, it is thought that the temperature that can be efficiently obtained with a heat pump is 60 to 80°C.

This invention was made in view of these points, and W.
It is an object of the present invention to provide a heat storage tank capable of storing heat at a temperature of less than 100°C and 50°C or more using J heat.

[Means for solving the problem] In this invention, the ethylene content is 65% to 94%.
A heat storage material of ethylene-vinyl acetate copolymer, ethylene-vinyl acrylate copolymer, ethylene-butyl acrylate copolymer, or ethylene-acrylic butyl copolymer is used as an ellipse with a volume change function of 2% or more. The heat storage tank is hermetically sealed in columnar or polygonal columnar capsules, immersed in brine as a heat transfer material, and alternately storing and dissipating heat by circulating the brine.

[Example] The melting point of ethylene-vinyl acetate copolymer (EVA) changes depending on the blending ratio of ethylene and vinyl acetate. For example, as shown in FIG. 6, when the amount of vinyl acetate is 14%, the melting point is 90°C, and when the amount of vinyl acetate is 30%, the melting point is 70°C. When the temperature of these EVA is lowered below the melting point, heat is generated as shown in FIG. That is, it is possible to utilize latent heat.

Therefore, by hermetically sealing these EVA in a metal or plastic capsule that does not melt at temperatures above the melting point of EVA, it becomes possible to utilize the latent heat generated when the temperature is lowered from a temperature above the melting point.

The capsule needs to have a structure that can easily absorb a volume change of 2% or more, taking into account the volume expansion of EVA due to temperature changes. (Expansion coefficient α of ethylene = 20x
Since the temperature is 10-510C, the volume increase is 0.02=2% assuming a temperature difference of 100C. ) To make the EVA inside the capsule store and release heat,
It may be helpful to immerse the capsules in brine and vary the temperature of the brine. This brine has a temperature range wider than the heat storage temperature of EVA of 50°C to 100°C, for example, 40°C to 100°C.
Liquid state at 110°C! ! It is necessary to maintain the

General heating brine can be used for this purpose.

The above is based on ethylene-vinyl acrylate copolymer (
EEA) or ethylene-methyl acrylate copolymer (EMA).

Similar examples include ethylene-butyl acrylate copolymer (EBA) and other ethylene-acrylic acid copolymers.

In addition, in the case of a warmer or a heat pump, it is economical from the point of view of efficiency to place the condenser of the heat pump in the liquid tank.

Hereinafter, the present invention will be described in detail based on the drawings. 1st
The figure is a side sectional view showing an example of the heat storage tank of the present invention.
The heat storage tank 10 is constructed by covering the periphery of a sealed liquid tank 4 with a heat insulating material 5. The liquid tank 4 is provided with inflow/outflow inlets 6 on the upper and lower left sides connected to a heater or a heat pump (not shown), and drain/inflow lowers connected to a radiator (not shown) are provided on the upper and lower right sides, respectively.

Also, in the liquid tank 4, E
A large number of capsules 2 filled with VA, EEA or HMA heat storage material are inserted, and the temperature range is from -10°C to 100°C.
Brine 3, which is in a liquid state in a temperature range of C or higher, is injected so as to fully immerse the capsule 2.

Therefore, by heating the capsule 2 via the brine 3 with a heater or a heat pump on the left side (not shown), heat is stored by heating, for example, EVA in the capsule 2. On the other hand, heat can be radiated by circulating the brine 3 through a radiator (not shown) on the right side. By doing this alternately, it plays the role of a heat storage.

Example 1 EVA with an ethylene content of 75% is used as a heat storage material. At this time, latent heat is generated at a temperature of 70° C. or lower, and heat can be stored. As the brine, alcohol, ethylene glycol, or water mixed with these antifreeze solutions can be used. If the operating temperature range of the heat storage device is 80°C or less, FRP (glass fiber reinforced plastic) is used in the liquid tank 4.
It is possible to use a tank. Capsule 2 will be made of plastic. The latent heat is 45 to 50 kcal per liter of EVA.

Example 2 Perfluorocarbon is used as brine. If the heat storage material is EVA containing ethylene (15%), Wi heat will be 55 to 60 kcal/l at 60 to 85°C. As the liquid tank 4, a metal water tank is used.

On the other hand, whether it is the shape of capsule 2 or the length of the column is 3 of the width
It is desirable that it be at least four times as large.

Various cross-sectional shapes can be considered, or the expected maximum value of the volume change of the heat storage material (expansion coefficient is maximum 20 x 10-6/'C)2
The capsule must be able to absorb a sufficient amount of %.

Specific examples of capsules used in this invention will be described below. FIG. 2 shows a cross section of a long cylindrical capsule 11 that is 1.375 times longer than its major or minor axis. When the perfect circle 12 has the same outer circumference length, the volume ratio is 1.039, which is about a 4% increase in volume.

Figure 3 is an example of a capsule 13 with a hexagonal cross section whose vertex has a rounded radius of 1/10 of the side length.If this is a perfect circle 14 with the same outer circumference length, the volume ratio is 1.061.
It is.

Similarly, if the rounded cross section of the rectangular prism 15 shown in FIG. 4 is a perfect circle 16 with the same outer circumferential length, the volume ratio is 1.075.

Furthermore, in the case where the outer periphery is configured in a wave shape as shown in Fig. 5,
2 by slightly changing the external shape as shown by the broken line 18.
% volume change is obtained, and there is always a gap between capsules, which is convenient for brine distribution. The capsule of the present invention is constructed by forming metal or plastic columnar bodies with various cross-sectional shapes, and enclosing EVA, EEA, or HMA therein.

[Effect of the invention] As explained above, the heat storage tank of the present invention.

(By encapsulating a heat storage material made of DEVA, EEA, or EMA, it can be used as a heat storage material that is stable even above its melting point.

■By making the capsule columnar with an oval cross section or a polygonal cross section (including a polygonal shape with a deformed outer periphery), it is possible to absorb volumetric expansion of 2% or more of the enclosed heat storage material with a margin, allowing long-term heat retention. It is possible to manufacture capsules without fatigue through cycles at low cost.

Further, by forming the columnar shape, the occupation rate in the liquid tank can be increased.

e) By separating the heat storage material and the brine as the heat transfer material, it is possible to utilize the phase change of the heat storage material from solid to liquid.

■In columnar capsules with a corrugated outer periphery, there are gaps between the capsules, allowing brine to penetrate.
There is no need for spacers or other measures, and an economical heat storage tank can be formed.

[Brief explanation of drawings]

FIG. 1 is a sectional view of a heat storage tank showing an embodiment of the present invention. 2 to 5 are diagrams showing the cross-sectional shape of the capsule. FIG. 6 is a glass showing the relationship between the melting point of EVA and the amount of ethylene. FIG. 7 is a graph showing the relationship between heat generation and temperature of EVA. 1 ... 2 ... φ 3 ... 4 ... 5 ... Heat storage material metal or plastic capsule brine liquid tank ItlTZS layer

Claims (1)

[Claims] A heat storage material of ethylene-vinyl acetate copolymer, ethylene-vinyl acrylate copolymer, ethylene-butyl acrylate copolymer or ethylene-acrylic butyl copolymer with an ethylene content of 65% to 94%, The capsules are hermetically sealed in long cylindrical or polygonal cylindrical capsules that have a volume change function of more than %, and these capsules are immersed in brine as a heat transfer material, and heat storage and heat radiation are alternately repeated by the circulation of the brine. A heat storage tank characterized by: