KR101563327B1 - Structure preventing transformation for heat insulation device of storage tank and construction method - Google Patents

Abstract

The present invention relates to a deformation preventing structure for a heat insulation device of a thermal storage tank. The present invention comprises: a heat insulation material formed to cover an entire outer surface of a thermal storage tank; a heat reserving material formed to cover the entire outer surface of the heat insulation material; and a deformation preventing member coupled to the heat insulation material and the heat reserving material and arranged along the surface of a circumference of a thermal storage tank and wherein one side surface having a plurality of communication grooves is formed to face the thermal storage tank. The deformation preventing member installed toward the outside of the thermal storage tank is radially arranged along the outer circumferential surface of the upper side of the thermal storage tank to enable heat transmitted from the thermal storage tank to the heat reserving material to be moved to the inside of the deformation preventing member through the communication grooves to prevent heat from being transmitted to the heat insulation material so as to prevent, in advance, deformation of the heat insulation material due to heat of the thermal storage tank to minimize a heat loss of the thermal storage tank to have excellent heat efficiency.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a heat insulating tank,

The present invention relates to a deformation prevention structure for an adiabatic device of a thermal storage tank, and more particularly, to a deformation prevention structure for a heat storage tank, more specifically, a deformation preventing member in the form of a pipe is formed radially outwardly of the heat storage tank, To the deformation preventing member so that the deformation of the insulating member can be prevented more effectively by discharging the gas and the pressurized gas to the deformation preventing member smoothly.

Generally, in order to minimize heat emission along the surface of the heat storage tank, a heat insulating layer, a reinforcing material, a waterproof layer and a non-wetting concrete layer are formed in a heat storage tank as shown in Korean Patent Registration No. 10-0808221 and the heat storage layer and the waterproof layer And breakage of the heat storage tank can be prevented so that the heat efficiency of the heat storage tank can be maintained to be excellent.

However, even if a plurality of layers of heat insulating members are installed to increase the efficiency of thermal insulation of the heat storage tank, the heat transmitted to the surface of the heat storage tank is transferred to the heat insulating layer, There is a problem that the heat efficiency of the heat storage tank is lowered.

In order to minimize the deformation of the heat insulating layer and the reinforcing material provided in the heat storage tank by the heat stored in the heat storage tank, a plurality of layers such as a concrete and a heat insulating member for forming a heat insulating effect on the wall of the heat storage tank are formed. There is a problem in that the number of the insulating layers is easily peeled off because the releasing materials are not adhered to each other.

The deformation preventing structure of the heat storage tank according to the present invention is characterized in that the deformation preventing structure for the heat storage tank includes a heat insulating material formed on the outer surface of the heat storage tank, a heat insulating material formed on the outer surface of the heat insulating material, A deformation preventing member provided on the outer side of the heat storage tank is arranged radially along the upper outer circumferential surface of the heat storage tank so that the temperature of the heat storage tank The heat transferred from the heat storage tank to the heat insulating member is moved to the inside of the deformation preventing member through the flow passage formed in the deformation preventing member and is not transferred to the heat insulating material, thereby preventing the heat insulating material from being deformed by heat, And the thermal efficiency is excellent.

In the present invention, the deformation preventing member provided outside the heat storage tank is radially arranged along the upper outer circumferential surface of the heat storage tank so that the heat transmitted from the heat storage tank to the heat insulating material passes through the flow passage formed in the deformation preventing member, So that it is not transferred to the heat insulating material. Thus, the heat storage tanks are prevented from being deformed by the heat of the heat storage tanks, thereby minimizing the heat loss of the heat storage tanks.

The deformation preventing member located outside the heat storage tank is radially arranged while being arranged in the longitudinal direction of the pipe, so that the area where the deformation preventing member is in close contact with the heat insulating material or the like is widened to absorb more heat from the heat storage tank The heat transmitted to the heat insulating material is minimized to minimize the deformation of the heat insulating material and the heat transmitted to the deformation preventing member can be easily discharged to the outside.

In addition, one side surface and the other side surface of the deformation preventing member are coupled to the first and second coupling grooves respectively formed in the heat insulating material and the heat insulating material, and are firmly fixed to the heat insulating material and the heat insulating material, It is possible to prevent peeling and heat loss of the heat insulating material, the heat insulating material, and the like due to separation of the deformation preventing member.

The one side of the deformation preventing member is not in direct contact with the heat storage tank but is located inside the heat insulating material so that particles of the heat insulating material do not block the flow grooves of the deformation preventing member, The heat is smoothly transmitted to the deformation preventing member and is released to the outside.

In addition, since the plurality of flow grooves formed in the deformation preventing member are formed in an irregular shape or staggered rather than in a linear direction, the heat radiated from the heat storage tank can flow into the deformation preventing member more efficiently through the flow grooves, There is an advantage that heat is easily discharged to the outside through the member.

Further, an auxiliary insulating material is additionally provided between the heat insulating material and the heat insulating material, so that the heat emitted from the heat storage tank can be prevented from being transmitted to the heat insulating material more easily.

Further, by further forming a coating layer on the outer side of the heat insulating material or the deformation preventing member, it is possible to prevent breakage or heat loss of the heat insulating material, the heat insulating material, and the deformation preventing member.

In addition, since the structure of the heat insulating material, the heat insulating material, the deformation preventing member, and the like is simple, it can be easily installed in the existing heat storage tank, and the economical effect can be maximized easily.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a sectional view showing a deformation preventing structure of a heat insulating device of a heat storage tank according to the present invention. Fig.
2 to 4 are exploded perspective views showing the deformation preventing structure of the heat insulating device of the heat storage tank of the present invention.
5 is a perspective view showing a heat insulating material of a deformation preventing structure of the heat insulating device of the heat storage tank of the present invention.
6 is a perspective view showing a heat insulating material in a deformation preventing structure of the heat insulating device of the heat storage tank of the present invention.
FIG. 7 is a perspective view showing another embodiment of a heat insulating material in a deformation preventing structure for a heat insulating device of a heat storage tank according to the present invention. FIG.
8 is an exploded perspective view showing the use state of the auxiliary thermal insulator of the deformation preventing structure of the heat insulating device of the heat storage tank of the present invention.
9 is a perspective view showing a deformation preventing member of a deformation preventing structure for an adiabatic device of a heat storage tank of the present invention.
10 is a cross-sectional view showing another embodiment in which a coating layer of a deformation preventing structure is added to a heat insulating device of a heat storage tank of the present invention.
11 is a sectional view showing a first step of a method of constructing a deformation preventing structure for a heat insulating device of a heat storage tank according to the present invention.
12 and 13 are diagrams showing a second step of a method of constructing a deformation preventing structure for a heat insulating device of a heat storage tank according to the present invention.
14 and 15 are state diagrams showing a third step of a method of constructing a deformation preventing structure for a heat insulating device of a thermal storage tank according to the present invention.
16 is a state diagram showing a further step of a method of constructing a deformation preventing structure for a heat insulating device of a heat storage tank according to the present invention.

In order to achieve the above object, the present invention is as follows.

Hereinafter, the configuration of the present invention will be described in detail with reference to the accompanying drawings.

The deformation preventing structure 50 for the heat insulating device of the present invention comprises a heat insulating material 10, a heat insulating material 20 and a deformation preventing member 30 located outside the heat storage tank t in which heat is stored.

First, the heat storage tank t is used for storing heat inward, which is generally used at present, and a detailed description thereof will be omitted.

Further, since the upper portion of the heat storage tank (t) is formed in a dome shape, the heat storage effect can be enhanced, and a detailed description thereof will be omitted.

1 to 4, the heat insulating material 10 is adhered to the upper outer side surface of the heat storage tank t so as to minimize the heat dissipation from the heat stored in the heat storage tank t. .

Here, the heat insulating material 10 may be made of any material generally used at present, but it is preferable to use any one of mineral wool, glass wool, cerulean wool, and pearlite so as to exhibit the most excellent heat insulating effect .

The heat insulating material 10 is adhered to the heat storage tank t through a bonding member such as an adhesive agent (not shown in the figure), a coupling member (not shown in the drawing) such as bolts, pins, It is self-explanatory and the detailed explanation is omitted.

In addition, the heat insulating material 10 can be used in various forms depending on the purpose of the user such as liquid or solid form.

Meanwhile, as shown in FIGS. 1 to 4, the heat insulating material 20 is positioned outside the heat insulating material 10, so that the heat stored in the heat storage tank t is formed more smoothly.

Here, the heat insulating material 20 is fixedly coupled to the heat insulating material 10 or the heat storage tank t through a bonding member, a joining member, a heat welding or the like which are generally used as the heat insulating member 10.

The heat insulating material 20 may be any material that exhibits generally excellent effects at present, but is used as an example of polyurethane in order to exhibit a more excellent warming effect.

5 to 7, a first coupling groove 11 is formed in the heat insulating material 10 so that the deformation preventing member 30 can be easily coupled to the heat insulating material 10 and the heat insulating material 20 And a second coupling groove 21 is formed in the heat insulating material 20.

In addition, the first engaging groove 11 and the second engaging groove 21 may be formed in various shapes. In the present invention, the first engaging groove 11 and the second engaging groove 21 may be radially formed.

This is to allow the heat radiated from the heat storage tank (t) to smoothly flow into the deformation preventing member (30) and to be discharged to the outside.

In addition, the insulating material 20 may be used in various forms depending on the purpose of the user such as liquid or solid form.

When the heat insulating material 20 is formed in a solid form, the second joining recess 21 is formed inside the heat insulating material 20 as shown in FIG. 6, The deformation preventing member 30 is formed to be coupled.

Alternatively, if the heat insulating material 20 is formed in a liquid form, the deformation preventing member 30 is joined to the first coupling groove 11 of the heat insulating material 10, The heat insulating material 20 is sprayed to cure the heat insulating material 20 so that the heat insulating material 20 is separated from the plurality of second joining recesses 21 as shown in FIG.

In addition, as shown in FIG. 8, in order to more smoothly block the heat transmitted from the heat storage tank t and the heat insulating material 10 to the heat insulating material 20, the heat insulating material 10, A heat insulating material k may be additionally formed.

Here, the auxiliary insulating material (k) may be any material which is generally used as a heat insulating material at present, but may be selected from a cereal wool or the like for higher heat insulating effect.

The auxiliary heat insulating material k may be formed on the entire surface of the heat insulating material 10, but it may be installed separately at a certain point depending on the temperature of the heat emitted from the heat storage tank t.

In addition, the auxiliary heat insulating material (k) can be fixed to the heat insulating material (20) through an adhesive member, a joining member, a heat welding or the like.

In addition, when the auxiliary thermal insulating material k is formed between the heat insulating material 10 and the thermal insulating material 20, the thermal insulating material k is firmly fixed to the thermal insulating material 10 and the thermal insulating material 20, The insertion groove m to which the auxiliary heat insulating material k is coupled may be formed only in one of the heat insulating material 10 and the heat insulating material 20. The deformation preventing member 30 may be formed on the heat insulating material 10 and the heat insulating material 20 The first joining recess 11 of the heat insulating material 10 and the second joining recess 21 of the heat insulating material 20 may be formed on both the heat insulating material 10 and the heat insulating material 20 have.

9, the deformation preventing member 30 is positioned between the heat insulating material 10 and the heat insulating material 20 and is arranged along the circumferential surface of the heat storage tank t to form a plurality of flow grooves 31, Is formed so as to face the heat storage tank (t).

The direction of the side surface a of the deformation preventing member 30 is connected to the first coupling groove 11 formed on the heat insulating material 10 and the other side surface b of the deformation preventing member 30 is connected to the second coupling groove 21).

4 or 9, when one side (a) of the deformation preventing member 30 is engaged with the first engaging groove 11 of the heat insulating material 10, the outer side of the heat insulating material 10 The height h1 of the first engaging groove 11 formed in the heat insulating material 10 is set to 70 mm or less relative to the height h2 of the deformation preventing member 30 so that the other side b of the deformation preventing member 30 is protruded. %.

When the height h1 of the first engaging groove 11 is equal to the height h2 of the deformation preventing member 30, the one side surface (a) of the deformation preventing member 30 is directly connected to the heat storage tank the heat stored in the heat storage tank t is directly transmitted to the deformation preventing member 30 and is diverted to the outside through the deformation preventing member 30 so that heat loss occurs in the heat storage tank t The height h1 of the first engaging groove 11 is set to be at most 70% with respect to the height h2 of the deformation preventing member 30 in order to prevent the thermal efficiency from being lowered. The deformation preventing member 30 is inserted into the inside of the heat insulating material 10 without the side surface (a) being in close contact with the heat storage tank (t).

The other side b of the deformation preventing member 30 protrudes from the second joining recess 21 of the heat insulating material 20 while the other side b of the deformation preventing member 30 protrudes outside the heat insulating member 10. [ So that the deformation preventing member 30 is not easily separated from the heat insulating material 10 and the heat insulating material 20. [

The reason why the one side surface a formed with the flow grooves 31 of the deformation preventing member 30 is located inside the first engaging groove 11 of the heat insulating material 10 is that the heat insulating material 10 is installed The particles of the heat insulating material 20 can flow into the flow grooves 31 formed in the deformation preventing member 30 to close the flow grooves 31 when the heat insulating material 20 is formed in a liquid form, In order to prevent the particles of the heat insulating material 20 from flowing into the flow grooves 31 by locating the flow grooves 31 of the preventing member 30 in the first engaging grooves 11 of the heat insulating material 10 will be.

The deformation preventing member 30 is formed in a pipe shape so as to be formed along the outer peripheral surface of the heat storage tank t and the heat insulating material 10 so that the heat introduced into the deformation preventing member 30 penetrates So that it can be easily discharged in the lateral direction.

When the flow channel 31 is formed on one side surface (a) of the deformation preventing member 30, it is preferable that the flow channel groove 31 is formed not to be formed in a straight line but to be irregular or located at a staggered position.

This is because the upper part of the heat storage tank t is generally in the form of a dome so that the heat discharged to the upper side of the heat storage tank t spreads out in a radial form while a plurality of the flow grooves 31 extend in a straight line The heat that has passed through the heat insulating material 10 can be easily adhered to the heat insulating material 10 or the like with a wider area than the deformation preventing member 30 The flow grooves 31 are arranged irregularly or staggeredly.

It is also preferable that the deformation preventing members 30 are arranged radially when they are arranged outside the heat storage tank t.

This is because when the deformation preventing member 30 is arranged in a radial direction, the area of the thermal storage tank t and the heat insulating material 10 closely contacting with each other is widened so that the heat that has passed through the heat insulating material 10 can be efficiently transferred to the deformation preventing member 30 And at the same time the heat transmitted to the heat insulating material 20 is minimized so that the heat insulating material 20 is deformed by heat to minimize heat loss due to deformation of the heat insulating material 20 and decrease in thermal efficiency .

When the deformation preventing member 30 is coupled to the heat insulating material 10 and the heat insulating material 20 and is fixed to the heat storage tank t and the heat insulating material 10 and the heat insulating material 20, It can be fixed or combined through heat fusion or the like. Therefore, detailed description will be omitted.

10, a coating layer 40 made of a synthetic resin material such as polypropylene may be further formed on the outside of the heat insulating material 20 and the deformation preventing member 30.

It should be noted that the coating layer 40 may be fixedly bonded to the heat insulating material 10, the heat insulating material 20, and the deformation preventing member 30 through an adhesive member, a bonding member, Is omitted.

The coating layer 40 is formed on the outer side of the heat insulating material 20 and the deformation preventing member 30 so as to prevent the thermal insulating material 20 and the deformation preventing member 30 from being damaged by an external impact, And the detailed description thereof will be omitted.

A construction method according to a preferred embodiment of the present invention having the above-described construction will be described as follows.

First, as shown in Fig. 11, the heat insulating material 10 is formed on the upper outer side surface of the heat storage tank t by a method such as an adhesive member, a joining member, and a heat welding method.

Here, the heat insulating material 10 may be formed in various forms depending on the purpose of the user, such as a solid state or a liquid state.

The heat insulating material 10 is formed with a first engaging groove 11 in which the entire thickness of the heat insulating material 10 is not penetrated but partly opened.

The first engagement groove 11, which is partially opened, is positioned so as to face upward without being directed in the direction of the heat storage tank t.

In addition, the first engagement groove 11 formed in the heat insulating material 10 is formed radially with reference to the center point of the upper side of the heat storage tank t. (S10)

12, a pipe-shaped deformation preventing member 30 is inserted into the first engaging groove 11 formed radially with respect to the center point of the upper side of the heat storage tank t, 11).

Here, one side (a) of the deformation preventing member (30) is connected to the first coupling groove (11) of the heat insulating material (10) while facing the heat storage tank (t).

In addition, the flow grooves 31 are formed in the one side surface (a), and the flow grooves 31 are located inside the heat insulator 10.

13, when the deformation preventing member 30 is coupled to the first coupling groove 11 of the heat insulating material 10, the height of the first coupling groove 11 of the heat insulating material 10 b1 of the deformation preventing member 30 are protruded at a predetermined interval from the heat insulating material 10 because the h1 of the deformation preventing member 30 is only up to 70% with respect to the height h2 of the deformation preventing member 30. S20 )

Then, the heat insulating material 20 formed in a liquid or solid form is formed on the upper side of the heat insulating material 10. The other side surface b of the deformation preventing member 30, which protrudes partly from the heat insulating material 10, 20 are coupled to each other.

14, when the heat insulating material 20 is formed in a solid form, the heat insulating material 20 is first inserted into the heat insulating material 20 to which the other side b of the deformation preventing member 30 is coupled. The second joining recess 21 of the heat insulating material 20 is inserted into the other side b of the deformation preventing member 30 so that the heat insulating material 10 and the deformation preventing member 30 The heat insulating material 20 may be formed on the outer side of the heat insulating member 20.

Alternatively, as shown in FIG. 15, when the heat insulating material 20 is formed into a liquid form and sprayed to the outside of the heat insulating material 10 and the deformation preventing member 30, The second engaging groove 21 is automatically formed in the heat insulating material 20 by the other side b of the preventing member 30. [

When the heat insulating material 20 is formed in a liquid state, the flow grooves 31 of the deformation preventing member 30 are located inside the heat insulating material 10 and are clogged, 31 to prevent the clogging of the flow grooves 31 due to the heat insulating material 20. [0050] As shown in FIG.

When the one side surface a of the deformation preventing member 30 is coupled to the first coupling groove 11 of the heat insulating material 10 as described above, the other side surface b of the deformation preventing member 30 is connected to the second coupling groove 21 of the heat insulating material 20. [ The heat insulating material 10, the heat insulating material 20, and the deformation preventing member 30 are firmly fixed to each other and are not easily separated.

The other side b of the deformation preventing member 30 may be connected to the heat insulating material 20 according to the purpose of the user when the heat insulating material 20 is joined to the other side b of the deformation preventing member 30. [ Or may be coupled to form the same plane as the heat insulating material 20. (S30)

16, when the heat insulating material 10 and the deformation preventing member 30 and the heat insulating material 20 are formed on the upper side of the heat storage tank t, the heat insulating material 10 and the heat insulating material 20 A supplementary thermal insulation material (k) of various materials may be additionally formed to enhance the thermal insulation effect and the thermal insulation effect on the thermal storage tank (t).

The auxiliary insulating material k may be formed on the entire surface of the heat insulating material 10 but may be formed only at a certain point depending on the temperature at which the heat is dissipated in the heat storage tank t.

This is because the upper portion of the heat storage tank t is formed in a dome shape, and the temperature of the heat stored in the heat storage tank t can be variously transmitted according to a certain point.

When the auxiliary heat insulating material k is located between the heat insulating material 10 and the heat insulating material 20, the heat insulating material 10 may be installed only at one of the heat insulating material 10 and the heat insulating material 20, And the auxiliary insulating material (k) is coupled to the formed insertion groove (m).

Therefore, by forming the auxiliary heat insulating material (k) only in a portion where a high temperature is transmitted, it is possible to prevent the heat from being radiated to the outside or the heat to be transmitted to the heat insulating material (20) And to increase the heat insulation effect.

In addition, when the auxiliary thermal insulating material k is formed between the heat insulating material 10 and the heat insulating material 20, a portion where the auxiliary thermal insulating material k and the deformation preventing member 30 overlap may occur. The portion where the auxiliary thermal insulator k overlaps the deformation preventing member 30 may be cut so that the auxiliary thermal insulating material k and the deformation preventing member 30 are not overlapped.

The reason why the auxiliary thermal insulating material k is cut when the auxiliary thermal insulating material k and the deformation preventing member 30 are overlapped is that the deformation preventing member 30 flows into the deformation preventing member 30 Since the heat is blocked by the auxiliary heat insulating material k and can be transmitted to the heat insulating material 20 without being diverted to the outside, the deformation preventing member 30 is not cut. (S35)

On the other hand, after the heat insulating material 10, the heat insulating material 20, the deformation preventing member 30 and the heat insulating material k are formed on the outer side of the heat storage tank t as described above, a coating layer of synthetic resin such as polypropylene (40).

Here, the coating layer 40 is generally used for preventing breakage and deformation of the heat insulating material 10, the heat insulating material 20, the deformation preventing member 30 and the heat insulating material k, and a detailed description thereof will be omitted. (S40)

After the heat insulating material 10, the heat insulating material 20 and the deformation preventing member 30, the heat insulating material k and the coating layer 40 are formed on the upper side of the heat storage tank t as described above, And the heat is stored in the heat storage tank (t).

Then, a part of the heat stored in the heat storage tank t is transmitted to the outside through the upper surface.

When heat transferred to the outside through the upper side of the heat storage tank t is partially blocked by the heat insulating material 10 and remains in the heat storage tank t, another part of the heat is transferred to the heat insulating material 10.

The heat transferred to the heat insulating material 10 is transferred to the heat insulating material 20 or the deformation preventing member 30 which is in contact with the heat insulating material 10. The heat insulating material 10 is transferred to the deformation preventing member 30 having a relatively high thermal conductivity, Heat is transferred to the heat exchanger.

One side of the deformation preventing member 30 is coupled to the first engaging groove 11 of the heat insulating member 10 so that the deformation preventing member 30 is closer to the heat accumulating tank t than the heat insulating member 20. [ So that the heat radiated from the heat storage tank t is moved to the deformation preventing member 30 earlier than the heat insulating member 20. [

The deformation preventing member 30 is formed with a flow groove 31 at one side of the deformation preventing member 30 so that the heat transmitted to the heat insulating material 10 can be easily transferred to the deformation preventing member 30 through the flow groove 31, So that the heat transmitted through the heat insulating material 10 to the heat insulating material 20 is minimized.

In addition, the flow grooves 31 adjacent to each other in the plurality of flow grooves 31 formed in the deformation preventing member 30 are not arranged in a linear direction but arranged irregularly or staggered, So that a larger amount of heat can be introduced into the deformation preventing member 30 through the flow grooves 31.

The deformation preventing member 30 is arranged radially with respect to the center point of the upper side of the heat storage tank t so that the contact area between the heat storage tank t and the heat insulating material 10 becomes wider, The heat is smoothly introduced into the deformation preventing member 30 in a larger amount.

The heat transferred to the heat storage tank t and the heat insulating material 10 by the plurality of flow grooves 31 formed in the deformation preventing member 30 and the deformation preventing member 30 radially arranged is transmitted to the deformation preventing member 30 is absorbed as much as possible so that the heat transmitted to the heat insulating material 20 is minimized to prevent breakage or deformation of the heat insulating material 20 by heat so as to prevent the heat insulating effect or the heat insulating effect of the heat storage tank t from being lowered .

The heat absorbed by the deformation preventing member 30 is quickly and smoothly discharged through the penetrated portion of the deformation preventing member 30 formed in a pipe shape, It is possible to minimize the deformation of the heat insulating material 20 by the heat transmitted to the deformation preventing member 30. [

The auxiliary heat insulating material k is formed between the heat insulating material 10 and the heat insulating material 20 at the portion where the temperature of the heat is highest even if the temperature of the heat transmitted to each point is different according to the shape of the heat storage tank t, The heat transmitted to the heat insulating material 20 by the auxiliary heat insulating material k is minimized and the heat dissipated to the outside of the heat storage tank t is minimized to reduce the heat insulating effect and the heat insulating effect of the heat storage tank t It is possible to minimize the occurrence of the problem.

Although the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is obvious to those who have knowledge of.

10: Insulation
11: first engaging groove
20: Insulation
21: second engaging groove
30: deformation preventing member
40: Coating layer
t: storage tank
50: Deformation prevention structure for insulation device of heat storage tank

Claims (12)

(10) in which a first engagement groove (11) partially opened to the outer surface of the heat storage tank (t) is radially formed;
A heat insulating material 20 having a second coupling groove 21 radially formed on an outer surface of the heat insulating material 10;
A side surface a is coupled to the first engagement groove 11 of the heat insulating material 10 while being radially arranged along the circumferential surface of the heat storage tank t and the second engagement groove 21 of the heat insulating material 20, A deformation preventing member 30 in the form of a pipe having one side surface a formed with a plurality of flow grooves 31 staggered to face the heat storage tank t, Deformation preventive structure for heat insulator of storage tank with characteristics.
The heat insulating structure according to claim 1, wherein the heat insulating material (10) is selected from any one of mineral wool, glass wool, ceramic wool, and pearlite.
delete The hinge according to claim 1, characterized in that the height (h1) of the first engaging groove (11) formed in the heat insulating material (10) is formed to be at most 70% with respect to the height (h2) Deformation preventive structure for insulation device in a storage tank.
The heat insulating structure according to claim 1, wherein the heat insulating material (20) is made of polyurethane.
The heat insulating material (10) according to claim 1, further comprising an auxiliary heat insulating material (k) between the heat insulating material (10) and the heat insulating material (20) (m) to which the heat insulating tank (k) is coupled.
delete The heat insulating structure of a thermal storage tank according to claim 1, further comprising a coating layer (40) formed outside the heat insulating material (20) or the deformation preventing member (30).
A method of constructing a deformation preventive structure for a heat insulating material installed in a heat storage tank for storing heat, a heat insulating material, and a heat storage tank for a heat storage tank for constructing a deformation preventing member,
A step (S10) of covering the entire outer surface of the heat storage tank with a heat insulating material formed by radially forming the first engagement groove;
A second step of arranging the deformation preventing member in a radial direction along the outer circumferential surface of the heat storage tank while coupling one side of the deformation preventing member formed in a pipe shape in the first coupling groove formed radially to the heat insulating member and having the flow grooves formed in the lower side S20);
And a third step (S30) of arranging the heat insulating material on the outside of the heat insulating material and the deformation preventing member and fixing the second insulating groove formed on the heat insulating material so as to be coupled to the other side of the deformation preventing member. Of the deformation preventing structure.
The heat storage tank according to claim 9, characterized in that, when the deformation preventing member is engaged with the second coupling groove of the heat insulating material in the second step (S20), the other side surface of the deformation preventing member protrudes to the outside of the heat insulating material A method of constructing a deformation preventing structure for an adiabatic device.
The heat storage tank according to claim 9, further comprising a step (S35) of forming an auxiliary insulating material between the heat insulating material and the heat insulating material when the heat insulating material is formed in the heat storage tank, Of the deformation preventing structure.
The method according to claim 9, further comprising a fourth step (S40) of coating a coating layer on the outer side of the heat insulating material and the deformation preventing member after the third step (S30) A method of constructing a deformation preventing structure.

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