JPH0783590A - Heat accumulating device utilizing latent heat - Google Patents

Abstract

PURPOSE:To perform an effective prevention of deterioration by a method wherein polyacetal which is most effective as heat accumulative material utiliz ing latent heat in view of a crystal temperature and an heat radiating amount is selected, a predetermined thermal medium is combined with this polyacetal and then the heat accumulative material is immersed when the thermal medium is directly contacted with it. CONSTITUTION:A heat accumulative device 1 selects polyacetal as a heat accumulative material 3 and stores it in a container 2. As thermal medium, silicone oil dehydrated under vacuum is used. Deterioration of the heat accumulative material is prevented by selecting such a combination as above. The thermal medium heated with a heater 5 passes through a pipe passage 4, stores heat in the heat accumulative material, passes its heat to another pipe passage 4 and heat is radiated from a radiator 6.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat storage device using a heat storage material for storing heat by utilizing latent heat and a heat medium for transferring heat energy.

[0002]

2. Description of the Related Art A heat storage device utilizing latent heat generally stores a heat storage material in a heat storage tank, in which a high temperature fluid is made to flow into the heat storage tank, and a low temperature fluid is made to flow in to extract the stored energy. Heat is exchanged between the heat storage material and the fluid, and the latent heat that is stored and radiated by the phase change of melting and solidification of the heat storage material is used to store and radiate.

As an example of such a heat storage device, Japanese Patent Laid-Open No. 59-59-
The one disclosed in Japanese Patent No. 134498 is known.

The heat storage device according to the above publication has a capsule filled with shape-stabilized polyethylene and a fluid heat medium,
It consists of a steam accumulator housed in a high-pressure water tank. The shape-stabilized polyethylene is in the form of pellets or round bars, and is subjected to shape-stabilization treatment so as not to fluidize even when it is melted by heat.

The shape stabilizing treatment is carried out by various methods such as surface modification by irradiation with electron beam or gamma ray, chemical treatment with a crosslinking agent to form crosslinks, and the like.
As a fluid heat medium, water or ethylene glycol,
Alternatively, silicon-based oil or the like is used.

[0006]

In the conventional heat storage device described above, a capsule containing shape-stabilized polyethylene provided as a heat storage material and a fluid heat medium filled therein is used as a heat storage device in the heat storage device. It is used in formations in direct contact with steam, which is the heat transfer medium that serves to transfer and transfer energy.

However, when polyethylene itself melts when latent heat is utilized due to phase change of polyethylene, the surface cannot be stabilized and maintained, so the surface is modified, and even if it comes into direct contact with steam, which is a heat medium, this The surface portion acts as a kind of wall, does not melt, and does not directly contribute to the utilization of latent heat.

In a heat storage device utilizing latent heat, it is desirable that all of the heat storage materials contribute to heat storage if the heating medium is in direct contact with the heat storage material and the heat is directly exchanged. Deterioration is accelerated. Therefore inevitably problem must be provided some walls between the heat storage material and the heat medium is generated.

On the other hand, in the conventional heat storage material utilizing latent heat described above, even if high density polyethylene having a high crystallization temperature is used,
The melting point is about 135 ° C., the latent heat amount is about 200 J / g, the crystallization temperature is about 110 ° C., and the heat radiation amount is about 190 J / g.

If the crystallization temperature of this heat storage material is higher, the range of utilization equipment can be further expanded and waste heat can be used more effectively. For example, in addition to the use of heat for heating or hot water supply, which has been conventionally performed with a hot water type, it is also possible to use cooling using an absorption refrigerator. Therefore, a heat storage material that has a high crystallization temperature and can store heat at a higher temperature is needed.

Further, in the conventional heat storage material, the surface of the heat storage material is coated with a heat-resistant resin or has a fluidity that causes the surface to swell in order to prevent mutual fixation and nodulation even if the temperature exceeds the melting point during heat storage. Although it is stored in a capsule together with the heat medium, the amount of heat stored is reduced by coating and the manufacturing cost and labor increase.

Further, as the material used as the heat medium, ethylene glycol is generally mentioned, but there is a problem that ethylene glycol cannot be used in the range of heating temperature of 180 ° C. from the viewpoint of heat resistance.

For this reason, it is necessary to select the optimum one from the other heat mediums. In that case, not only whether or not there is heat resistance in the above temperature range but also the heat medium is in direct contact with the heat medium so that the heat medium is directly contacted. It is also necessary to consider whether it does not accelerate the deterioration of the. To deteriorate the heat storage material,
The water content in the heat medium and dissolved oxygen are related, and the deterioration rate further increases in the high temperature molten state. Therefore, there is also a problem that the heat medium must be selected after considering these problems.

In the present invention, polyacetal having a large crystal temperature and a large amount of heat radiation is selected as a heat storage material so as to be advantageous in terms of heat storage and heat radiation, while paying attention to various problems occurring in the conventional heat storage device. A heat medium that is used in combination with this to transfer and receive heat energy to and from the heat storage material does not promote deterioration of the heat storage material, and yet has sufficient heat resistance at a heating temperature of 180 ° C. when used as a heat storage device. An object of the present invention is to provide a heat storage device that selects a heat medium to have and prevents deterioration of the heat storage material.

[0015]

As a means for solving the above problems, the present invention uses polyacetal as a heat storage material in a heat storage tank, and uses a vacuum as a heat medium for transmitting or receiving heat energy to the heat storage material. This is a heat storage device that uses latent heat by directly contacting the heat storage material after the dehydration treatment.

In this heat storage device, silicon oil can be selected and combined as the heat medium. In this case, the heat medium obtained by subjecting the heat medium to dehydration may be filled with N ₂ gas or other insoluble gas.

In any case, it is preferable that the heat medium contains an adsorbent for formaldehyde, which is a low-molecular-weight component produced by thermal decomposition and deterioration of polyacetal.

[0018]

In the heat storage device of the present invention having the above structure, polyacetal is used as the heat storage material. Polyacetal is more advantageous than polyethylene (HDPE) or the like in terms of crystallization temperature and heat radiation amount, and is suitable as a heat storage material.

Therefore, when polyacetal is used as the heat storage material, it is desirable that the heat medium that directly contacts the heat storage material does not deteriorate the heat storage material. Therefore, at least vacuum is applied to the heat medium to perform a dehydration treatment, and the heat medium is brought into direct contact with the heat storage material.

Furthermore, since the operating temperature of the heat storage device is 180 ° C., heat resistance at this temperature is also required. In that case, as the heat medium, it is desired that the heat resistance and the weight change of the heat storage material polyacetal due to the immersion are as small as possible. Silicon-based oil was selected as the heat medium that satisfies these conditions.

Further, the deterioration of the heat accumulating material polyacetal largely includes oxidative deterioration and thermal decomposition deterioration, and is related to water and dissolved oxygen in the heat medium, and further deteriorates at high temperature and in a molten state. Therefore, for the oxidative deterioration, the heat accumulating material polyacetal can be prevented from deteriorating by filling the inside of the system with N ₂ gas or an inert gas after subjecting the heat medium to dehydration treatment.

However, although the thermal decomposition deterioration can be suppressed, it cannot be completely prevented, so that decomposition products of the heat accumulating material polyacetal are generated.

The decomposition products of the heat accumulating material polyacetal are mainly formaldehyde HCOH, and when this is oxidized, formic acid HCOOH is formed. Since the heat storage material polyacetal promotes the decomposition of the polymer by the acid, it is necessary to prevent the decomposition and deterioration by removing the decomposition products with an adsorbent. Melamine can be used as an example of an adsorbent.

[0024]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows an example of use of the heat storage device. The heat storage device 1 used here has a heat storage material 3 enclosed in a closed container 2.

This device is connected to a heater 5 and a radiator 6 via a valved line 4 as shown in the figure. Then, the heat medium in the tube is heated by the heater 5, and the heated heat medium is passed through the heat accumulator 1 by opening the valve 7 on the heater side.
Allow the heat to be stored sufficiently. After that, the valve 7 is closed and the valve 8 on the radiator side is opened to warm the heat medium, and the heat is radiated from the radiator 6.

As the heat storage material 3 used in the heat storage device described above, it is preferable to select a material having a crystallization temperature as high as possible. Therefore, regarding polyacetal copolymer, polyacetal homopolymer, polyvinylidene fluoride polymer, 11 nylon polymer, 12 nylon polymer, ethylene vinyl alcohol copolymer, and high density polyethylene (HDPE), their melting points,
The amount of latent heat, the crystallization temperature, and the amount of heat released were examined.

The polyacetal copolymer used for this measurement is DURACON M-25 (manufactured by Polyplastics Co.).

The polyacetal homopolymer is Delrin 1
00 (manufactured by DuPont), polyvinylidene fluoride polymer is Kiner 460 (manufactured by Mitsubishi Yuka), 11 nylon polymer is Rilsan BESNOTL (manufactured by Toray),
12 nylon polymer is 3024 NUX (made by Ube),
Ethylene vinyl alcohol copolymer is Eval EP-
E (made by Kuraray), HDPE is Shorex 500
3 W (manufactured by Showa Denko) was used.

Table 1 collectively shows the measurement results.

[0030]

[Table 1]

As can be seen from the measurement results, polyacetal copolymer, polyacetal homopolymer, polyvinylidene fluoride polymer, 11 nylon polymer, 12
Nylon polymer and ethylene vinyl alcohol copolymer have higher crystallization temperature than HDPE.

Moreover, the polyacetal copolymer or the homopolymer has the largest heat radiation amount, as can be seen immediately by comparing the heat radiation values. Therefore, it can be seen that polyacetal is most advantageous as the heat storage material.

Next, silicon oil is selected as the heat medium. When selecting a heat medium for accumulating the heat accumulating material polyacetal, ethylene glycol, which is a commonly used heat medium, is unsuitable from the heating temperature range.
It was also found that diphenyl-based oil is not suitable for heating at 200 ° C. because of its large evaporation amount. Therefore, a comparison was made between silicon-based oil and alkylbenzene-based oil. In the case of alkylbenzene-based oil, the heat storage material polyacetal was reduced by about 50% (weight) after 150 hours, so it was considered unsuitable and the weight loss was small. Select silicone oil. Fig. 2 shows the experimental results of the weight reduction of the heat storage material polyacetal for the alkylbenzene oil and the silicon oil.

From the above-mentioned test results, it was found that when polyacetal is used as the heat storage material, the silicone oil is the most suitable as the heat medium at present, but at the same time, it was found that the heat storage material was slightly eluted in the heat medium. This is because electron beam irradiation breaks the bonds between the molecules of the heat storage material to generate formaldehyde HCOH, which is a low molecular weight component.

Next, when polyacetal was selected as the heat storage material, the deterioration in air and N ₂ gas was examined to determine the atmosphere in the heat storage device. When comparing the deterioration in air of the heat storage material polyacetal and the deterioration in N ₂ gas, for example, comparing the weight residual ratio after 50 minutes at the measurement temperature of 240 ° C., N in the air is 29%.
It becomes 94.2% in ₂ gas. This is T
It is the result of measuring the weight residual amount of the heat storage material polyacetal at each temperature using G (thermal balance). Therefore, it is found that the heat storage material is preferably used in N ₂ gas or other inert gas.

<Conditions> Measurement temperature: 240, 260, 280, 300 ° C. Measurement time: 1 hour Measurement atmosphere: N ₂ gas or air

[0037]

[Table 2]

The above measurement results are shown in FIGS.

Formaldehyde HCOH, which is a low molecular weight component of the heat accumulating material polyacetal, becomes HCOOH formic acid when oxidized (2HCOH + O ₂ → 2HCOO).
H). Since the heat storage material polyacetal is accelerated in decomposition by acid, it is necessary to prevent or remove the oxidation of formaldehyde, which is a low molecular weight component. Therefore, the formaldehyde adsorbent was added to silicon-based oil in the atmosphere of the heat storage device in N ₂ gas or other inert gas to prevent deterioration of the heat storage material due to low molecular weight components. Storage,
In a heat radiation test, melamine was added to silicone oil.

[0040]

[Chemical 1]

Due to the effect of adsorbing the low molecular weight component formaldehyde of the heat accumulating material polyacetal generated by the thermal decomposition deterioration, the pipe clogging due to the polyacetal low molecular weight component formaldehyde at the time of cooling, which was a problem in system operation, was introduced. And so on.

[0042]

[Effect] As described in detail above, in the heat storage device using polyacetal as the heat storage material, it is possible to prevent the heat storage material from deteriorating by vacuuming the heat medium and subjecting it to dehydration treatment.

The use of silicon oil as the heat medium is effective for a heat storage device using polyacetal as the heat storage material, and is also preferable from the viewpoint of heat resistance. further,
Degradation of the heat storage material can be effectively prevented by subjecting the heat medium to a vacuum dehydration treatment in its fluid system and using one filled with N ₂ gas or other inert gas.

Even when silicone oil is used as a heat medium, low-molecular-weight component of polyacetal, formaldehyde, is generated by thermal decomposition. However, when an adsorbent is put in the heat medium, formaldehyde is adsorbed, which causes problems in system operation. It is possible to alleviate pipe clogging and the like due to the low molecular weight component formaldehyde.

[Brief description of drawings]

FIG. 1 is a sectional view of a heat storage device according to an embodiment.

FIG. 2 is a diagram for explaining selection of silicon-based oil.

FIG. 3 is a diagram showing a change over time in the residual weight ratio in N ₂ gas.

FIG. 4 is a diagram showing the change over time in the residual weight ratio in air.

[Explanation of symbols]

 1 Heat Storage Device 2 Closed Container 3 Heat Storage Material 4 Pipeline 5 Heater 6 Radiator

Claims (4)

[Claims] 1. A polyacetal is used as a heat storage material in a heat storage tank, and a heat medium for transferring or receiving heat energy to the heat storage material is dehydrated by vacuum so that it directly contacts the heat storage material. Heat storage device that utilizes the latent heat. 2. The heat storage device using latent heat according to claim 1, wherein silicon oil is selected as the heat medium. 3. The dehydrated heat medium is treated with N ₂
The heat storage device using latent heat according to claim 1 or 2, which is filled with a gas or another inert gas. 4. The heat storage device using latent heat according to claim 1, wherein the heat medium contains an adsorbent for low-molecular-weight component formaldehyde, which is generated by thermal decomposition deterioration of polyacetal.