JPH01196498A - Regenerative container - Google Patents

Abstract

PURPOSE:To shorten the time for discharging the latent heat, to make it easy to separate the hot medium from the cooling fluid, and, moreover, to allow the containers to be piled when used by forming a hollow ring-shaped receptacle for seed crystals which is larger in diameter than the outer periphery of the main body of a regenerative container and by making the main body and the receptacle connected and communicate by a ring-shaped passageway. CONSTITUTION:The hollow disk-shaped main body 6 of a regenerative container and a hollow ring-shaped receptacle 7 for seed crystals whose inside diameter is larger than the main body are concentrically arranged substantially on a common plane and connected by a hollow ring-shaped passageway 8. The main body 6 of the regenerative container is packed with a regenerative material 2. At a part of the regenerative material a receptacle 7 for seed crystals is filled so that, upon cooling, the contents crystallize into seed crystals 4. The regenerative material 2 is in contact with seed crystals 4 at all points along its periphery and, when the heat is released, the crystals are allowed to grow by only short distances in the paths of their growth; therefore, the latent heat can be discharged in a short time. The regenerative containers can be joined in a pile by means of short cylindrical supporting rings 9.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to the structure of a heat storage container that houses a latent heat storage material.

[Prior art]

The heat storage container stores a latent heat storage material (eg, sodium sulfate decahydrate with a melting point of 30°C, sodium thiosulfate pentahydrate with a melting point of 48°C). When heat is applied or removed from the outer surface of the heat storage container via a heat medium, the latent heat storage material melts and
Shows large heat capacity upon solidification.

However, the aforementioned latent heat storage material exhibits a supercooling phenomenon during solidification and does not release latent heat at a desired temperature. In order to eliminate this drawback, a seed crystal accommodating part for storing a seed crystal is generally provided in a part of the heat storage container.

Figure 8 shows the latest known technology (
JP-A No. 60-33491).

A heat storage material 2 is housed in a hollow rectangular plate-shaped heat storage container 1. When this heat storage material 2 is heated, it melts and takes away the latent heat of fusion, and when it is cooled, it solidifies (crystallizes) and releases the latent heat of fusion.

Both ends of the U-shaped tube 5 are fixedly connected to the heat storage container 1 described above. In order to prevent the heat storage material inside this U-shaped tube 5 from melting, this U-shaped tube 5 is
The outer peripheral surface of the tube 5 is cooled.

Therefore, the heat storage material in the U-shaped tube 5 maintains a crystalline state, and the U-shaped tube 5 acts as a seed crystal storage section, storing the seed crystal 4 therein.

[Problem to be solved by the invention]

In the heat storage container (FIG. 8) according to the latest known technology, the contact points between the seed crystal 4 and the heat storage material 2 are points c and c' shown in the figure.
It's nearby. Therefore, when the heat storage material 2 solidifies while releasing latent heat, the crystals begin to grow from points C and C' and grow toward E near the left end of the figure.

However, as can be easily understood from Fig. 8, points c and c
The contact area between the seed crystal 4 and the heat storage material 2 near ' is small, and the distance between C and E is long. Therefore, it takes a long time for the crystal to grow, and latent heat cannot be dissipated quickly.

Furthermore, this heat storage container (Figure 8) is heated to absorb heat (heat storage).
When doing so, it is necessary to heat the area to the left of points c and c' in the figure and cool the area to the right of sincerity c and c' to prevent the seed crystal 4 from melting. In the structure (FIG. 8), it is not easy to separate the heating means (for example, high temperature liquid flow) and the cooling means (for example, cooling air) using the boundaries near points c and c'.

The present invention has been made in view of the above-mentioned circumstances, and provides a heat storage container that has a high latent heat release rate, is easy to partition between heating means and cooling means, and is easy to install a large number of heat storage containers in a narrow area. The purpose is to provide

[Means to solve the problem]

The heat storage container of the present invention created in order to achieve the above object has a heat storage container main body that stores a heat storage material formed into a hollow disk shape, and a hollow having an inner diameter larger than the outer circumference of the heat storage container main body. A ring-shaped seed crystal storage section is configured, and the heat storage container main body and the seed crystal storage section are arranged concentrically on substantially the same plane, and the outer periphery of the heat storage container main body and the inside of the seed crystal storage section are arranged concentrically. The surroundings are connected and communicated through an annular communication path.

[Effect]

According to the above configuration, (a) Since the seed crystal storage portion is provided facing the entire circumference of the M heating device body, the crystals grow from the outer circumference toward the center, and all of the heat storage material is The time it takes for the crystallization to finish is short. That is, latent heat can be released in a short period of time.

(b) Since the seed crystal storage section to be cooled is provided on the outer periphery of the heat accumulator body and is connected via an annular communication path, it is possible to The operation of cooling the crystal storage section is easy.

Moreover, since a large number of heat storage containers can be stacked and used via supporting apples, which will be explained later with reference to FIG. 2, the area required for installation is small.

〔Example〕

FIG. 1(A) and FIG. 1(B) show an embodiment of the heat storage container of the present invention, and FIG. B) is a cross-section taken along line BB in FIG. 1(A).

A hollow disc-shaped heat storage container body 6 and a hollow annular seed crystal container 7 having a larger inner diameter are arranged concentrically on almost the same plane, and a hollow annular communication portion 8 is provided between the two. Connect by.

6a is the top surface of the hollow disc-shaped heat storage device main body 6.

This is a through pipe that penetrates the bottom surface and is fixed, and this through pipe reinforces the heat storage body 6 and expands its heat transfer area.

The heat storage material 2 is stored in the heat storage container main body 6.

A portion of this heat storage material fills the seed crystal container 7 and crystallizes into the seed crystal 4 when cooled.

As can be easily understood from FIG. 1(A), the heat storage material 2 is in contact with the seed crystal 4 around its entire circumference. The direction of crystal growth during heat dissipation is, for example, as shown by an arrow, and the distance of the crystal growth path is short. Therefore, latent heat can be released in a short time.

FIG. 2 is a vertical sectional view of a heat storage device constructed using the heat storage container (FIG. 1(B)) of the above embodiment.

The heat storage containers are stacked with short cylindrical support rings 9 interposed therebetween.

When the high-temperature heat medium is made to flow as shown by the arrow, a large number (5 in this example) of the heat storage bodies 6 are heated simultaneously, and since the heat medium (arrow D) is blocked by the support ring 9, no heat is generated. Do not heat the crystal container 7.

The seed crystal 4 is prevented from melting by flowing cooling air (or cooling water) having a temperature below the melting point of the heat storage material 2 while making contact with the seed crystal container 7 located outside the support ring 9 .

In Fig. 2, a portion of the high-temperature heat medium indicated by the arrow can flow between the heat storage container bodies 6 stacked vertically (for example, 5a
The height dimension of the support ring 9 is set so that a gap of n) is created.

FIGS. 3(A) and 3(B) show an embodiment different from the above example, and the differences from the previous example are as follows.

(i) A reinforcing plate 6b partitioning the central part of the penetrating vibro a.
has been established. According to this example, deformation of the heat storage container main body 6 due to expansion of the heat storage material is prevented.

(ii) A plurality of (four in this example) penetrating vibros c were provided around the penetrating vibro a. This makes the reinforcement even stronger and increases the heat transfer area. FIG. 4 is a vertical sectional view showing a state in which the heat storage containers of the above embodiment (FIG. 3) are stacked and installed.

FIG. 5 shows an enlarged detailed view of the 7th section surrounded by a chain line in FIG. 4.

A ring groove 6d is provided on the top surface of the lower heat storage container body 6-2, and an O-ring 1 is provided between it and the bottom surface of the upper heat storage container body 6-1.
0 is inserted. When sealed in this way, the fourth
The high temperature heat transfer medium arrow D' shown in the figure is completely cut off from the seed crystal container 7.

FIG. 6 shows a rubber backing 1 in place of the O-ring 10.
This is an example in which 1 is inserted. When used in this way, it is not necessary to provide the ring groove 1O, so the shape of the heat storage container main body 6 can be simplified.

FIG. 7 shows that an annular groove 6f is provided on the top surface of the heat storage container body 6, and an annular projection 6g is provided on the bottom surface of the heat storage container body 6 to fit them together, and a sealing material 12 is interposed between the two. This is an example. By fitting the annular groove and the annular protrusion in this manner, the effect of positioning the heat storage container main body 6 with respect to each other is achieved.

〔Effect of the invention〕

As explained above, when the heat storage container of the present invention is applied, the crystal growth distance is short and the time required for crystal growth is short, so latent heat is released in a short time.

Furthermore, the high temperature medium and the cooling fluid can be easily partitioned, and furthermore, they are suitable for stacking and use, and require a small installation area.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing an embodiment of the heat storage container of the present invention.
Figure (A) depicts a cross-section taken along the line AA in Figure CB), and Figure 2 is a vertical cross-sectional view showing the usage state of the above embodiment. FIG. 3 shows a different embodiment from the above, and FIG.
A B'-B' cross section of A) is drawn. FIG. 4 is a vertical sectional view showing the embodiment of FIG. 3 in use. FIG. 5 is an enlarged detailed view of section 7 shown in FIG. 4. FIGS. 6 and 7 are partially enlarged sectional views of embodiments different from those described above, and correspond to FIG. 5 in the previous example. FIG. 8 is an explanatory diagram of a known example of a heat storage container. 2... Heat storage material, 4... Seed crystal, 6... Heat storage container body, 7... Seed crystal container, 8... Communication portion, 9... Support ring. Patent Applicant: Hitachi Building Facilities Engineering Co., Ltd. Hitachi, Ltd. Tohoku Electric Power Co., Ltd. Representative Patent Attorney Tadashi Akimoto 1 other person No. I 8 Figure

Claims (1)

[Claims] 1. The heat storage container main body for storing the heat storage material is formed into a hollow disk shape, and a hollow annular seed crystal storage part having an inner diameter larger than the outer circumference of the heat storage container main body is formed, and the heat storage container main body described above and the seed crystal storage portion are arranged concentrically on substantially the same plane, and the outer peripheral side of the heat storage container main body portion and the inner peripheral side of the seed crystal storage portion are connected via an annular communication path,
A heat storage container characterized by being connected.