JP5725442B2 - Heat shield tent - Google Patents

Description

  The present invention relates to heat countermeasures for tent warehouses, sunshade tents, outdoor tents and the like used outdoors.

  A light-transmitting tent sheet has been proposed in which an aluminum vapor deposition layer is provided on the outdoor side of a tent base fabric such as a polyester sheet, and a protective layer made of polyethylene is further provided on the outer side.

  There is a heat shield sheet in which a metal film layer made of aluminum is laminated on a tent base cloth made of a polyester fiber material with an infrared emissivity in the range of 0.1 to 0.5.

  There is a tent provided with an aluminum metal layer on the outdoor side of a base fabric made of knitted fabric and a urethane resin protective layer on the outdoor side.

From the outdoor side, a tent sheet in which a synthetic resin film, a base fabric, a metal film such as aluminum, and a synthetic resin coating curtain are integrally formed has been proposed.

Japanese Patent Laid-Open No. 11-36669 JP 2007-1079 A JP-A-6-134929 Japanese Utility Model Publication No. 56-14027

Therefore, there were the following problems.
There is an aluminum vapor deposition layer on the indoor side of the polyethylene sheet, and a three-layer structure with a polyester sheet base fabric on the indoor side, and there is a thermal barrier tent sheet that shields heat while transmitting light.
Transmitting sunlight is also transmitting heat, and it is basically difficult to produce a high heat shielding effect.
Furthermore, this light-transmitting heat-shielding tent sheet reflects most of the radiant heat from the outdoors. In other words, the light is also reflected outdoors, and there is a problem that it may affect an aircraft obstacle or an eye disorder of surrounding people.

  A thermal insulation sheet in which a metal film layer made of aluminum is laminated on a base fabric made of a polyester fiber material by a method such as vacuum deposition or sputtering has an infrared emissivity of about 0.1 to 0.5, which is a very low room temperature. It is basically difficult to significantly reduce

  There is a tent provided with an aluminum metal layer on the outdoor side of a base fabric made of knitted fabric and a urethane resin protective layer on the outdoor side. In this method, an aluminum metal layer is attached to the urethane-based resin layer, and the sheet is bonded to the base fabric with an adhesive. That is, the aluminum metal layer which is a radiant heat reflecting material is located between the surface layer material and the base fabric. That is, this structure does not sufficiently bring out the high reflection performance and low radiation performance, which are the original characteristics of radiant heat.

From the outdoor side, a tent sheet in which a synthetic resin film, a base fabric, a metal film such as aluminum, and a synthetic resin coating curtain are integrally formed has been proposed. The feature of this invention is that an aluminum metal film is formed on the back side of the base fabric, unlike the above-mentioned three. However, this aluminum metal film is formed by aluminum coating or vacuum deposition, and cannot be a uniform reflective layer. Furthermore, providing a polyester resin or acrylic resin layer on the indoor side, which is the radiation side, means that there is no air layer on the radiation side and cannot be a highly heat-insulating tent.
The present invention has been made to solve these problems.

Heat tent barrier of the present invention, the indoor side of the tent base fabric, a thermal material shield fitted with a material having high reflectance with respect to non-woven fabric or radiant heat on one side of the resin sheet, those unmoving fabric or a resin sheet The surface is attached so that the surface is the tent base cloth side, and the periphery of the nonwoven fabric or resin sheet is joined to the surface of the tent base cloth by an adhesive means, and the surface of the tent base cloth is between the nonwoven fabric or resin sheet and the tent base cloth. An air layer is provided.

The present invention is a pre-Symbol nonwoven fabric or a resin sheet, the further bonded to the tent base surface of the fabric with adhesive means, predetermined intervals between the front Stories and nonwoven fabric or a resin sheet and the tent base fabric A plurality of the air layers are formed on the surface.

The heat-shielding tent of the present invention has a heat-shielding material in which a material having high reflectance with respect to radiant heat is attached to one side of a woven fabric on the indoor side of the tent base fabric so that the woven fabric surface becomes the tent base fabric surface. Attaching , the periphery of the fabric is bonded to the surface of the tent base fabric by an adhesive means, and an air layer is provided between the fabric and the tent base fabric .

  According to the present invention, the woven fabric includes natural fibers and chemical fibers.

  In the present invention, the fabric is further joined to the surface of the tent base fabric by the bonding means, and a plurality of air layers are formed at predetermined intervals between the fabric and the tent base fabric. Features.

The heat-shielding tent of the present invention comprises a heat-shielding material in which a non-woven fabric or resin sheet is attached with a material having high reflectance with respect to radiant heat on the indoor side of the tent base fabric, and the non-woven fabric or resin sheet surface is the tent base. mounting such that the fabric surface, and the nonwoven fabric or a resin sheet, between the material of the high reflectivity for the radiation heat, further comprising other different resin sheet and the resin sheet, different from the non-woven fabric as another non-woven fabric is the tent base fabric surface, attached to the nonwoven fabric or a resin sheet, the periphery of the other nonwoven, bonded to the tent base surface of the fabric with adhesive means, and the other non-woven An air layer is provided between the tent base fabric and the tent base fabric .

Further, the heat shield tent of the present invention is a heat shield material in which a non-woven fabric or resin sheet is attached with a material having a high reflectivity with respect to radiant heat on the indoor side of the tent base fabric, and the nonwoven fabric or resin sheet surface is the tent. mounting such that the base cloth surface side, different from the resin sheet and the resin sheet is further attached to the nonwoven fabric or a resin sheet such that the tent base fabric surface, the periphery of the other resin sheet, It joins to the surface of the said tent base cloth with an adhesion | attachment means, and provides an air layer between the said other resin sheet and the said tent base cloth .

  In the present invention, the material having a high reflectance with respect to the radiant heat is a metal foil produced by rolling a metal plate.

  Further, the present invention is characterized in that an opening is provided in a material having a high reflectance with respect to the radiant heat.

  Further, the present invention is characterized in that a highly transmissive resin film is attached to the indoor side of a material having a high reflectance with respect to the radiant heat.

  The tent base fabric includes natural fibers, chemical fibers, and resin sheets.

  Attaching a material with high reflectivity to radiant heat, such as aluminum foil, which is only about 5 to 10 microns to a tent base fabric that has been used in the past, can produce a significant energy-saving effect associated with heat insulation. Is possible.

  For existing tent base fabric, a heat shielding material bonded or welded with a polyester resin nonwoven fabric or resin sheet may be directly attached to the tent with double-sided tape or the like, and anyone can easily construct it.

  The heat shield tent of the present invention is a heat countermeasure and energy saving method that does not require any power.

  The heat shield tent of the present invention greatly improves the soundproofing effect such as rain sound.

  The heat shield tent of the present invention can be used in many fields such as an awning, an umbrella or a partition sheet.

It is sectional drawing of the heat insulation tent of this invention. It is a top view of the heat shield tent with an opening of the present invention. FIG. 2 is a cross-sectional view of the heat shield tent of the present invention in which a heat shield material using a polyester resin nonwoven fabric or a resin sheet is attached to the tent base fabric so as to have an air layer. It is sectional drawing of the heat insulation tent of this invention which attached the heat insulation material which used the textile fabric to a tent base fabric so that it might have an air layer. It is explanatory drawing at the time of seeing the experimental method of Example 1 from upper direction. It is explanatory drawing at the time of seeing the experimental method of Example 2 from upper direction. It is explanatory drawing which shows the structure of the heat-shielding material used by this invention. 6 is an explanatory diagram showing an experimental method of Example 3. FIG. FIG. 10 is an explanatory diagram showing an experimental method of Example 4. It is explanatory drawing at the time of seeing the experimental method of Example 5 from upper direction. It is explanatory drawing at the time of seeing the experimental method of Example 6 from upper direction. It is explanatory drawing which shows a test method of Example 7, and a mode that the operator is sticking the heat shielding material used by this invention on the wall and ceiling inside a tent warehouse. FIG. 10 is an explanatory diagram showing an experimental method of Example 8.

The best mode for carrying out the present invention will be described below.
Most of the radiant heat from the outside passes through the tent, which is light transmissive, enters the room, and supplies heat to the room. The remaining radiant heat that does not pass through is absorbed by the tent fabric and becomes conductive heat.
Also, conduction heat and convection heat from the outdoor atmosphere take the form of conduction heat and are absorbed by the tent fabric.
These conduction heats move inside the tent fabric to the indoor side, again take the three forms of conduction heat, convection heat, and radiant heat, are transmitted from the interior surface of the tent fabric to the room, and supply heat to the room.
In addition, if light is not transmitted because the tent fabric is thick or a metal plate is inserted, all of the movement in the tent fabric is conducted heat.

  As reported by many American institutions, 75% of the heat passing through buildings is radiant heat. Although the inside of the tent is slightly different from the building, the influence of radiant heat is considered to be very large. Therefore, preventing this radiant heat is also a major factor for the countermeasure against heat in the tent.

  As a method of preventing this radiant heat, it is known that the material 1 having a high reflectivity against the radiant heat, such as aluminum foil, is effective.

  From the law of conservation of energy, it is known that the sum of the reflectivity, emissivity, and transmittance of a material is 壱. In the present invention, since the material 1 that does not transmit radiant heat and has high reflectivity with respect to radiant heat is used, the transmittance is zero, and the sum of the reflectivity and the emissivity is low. That is, a material with a reflectivity of 98% has an emissivity of 2%, and a low emissivity means that the amount of heat supplied to the room is small.

In order to use the high reflectivity performance of the material 1 having high reflectivity against radiant heat, it is important to provide an air layer on the heat source side, and conversely, to use the low emissivity performance, radiation is required. It is most important to provide an air layer on the side.
That is, an air layer is required on either one of the materials 1 having high reflectivity with respect to radiant heat.

  As shown in FIG. 1, the present invention is a heat shielding tent in which a material 1 having high reflectivity against radiant heat, such as aluminum foil, is attached to the indoor side of a tent base fabric 2 made of natural fiber, chemical fiber, resin sheet or the like. is there. That is, the heat shielding tent 21 has a two-layer structure of the tent base fabric 2 and the material 1 having high reflectivity with respect to radiant heat from the outside.

  Moreover, the material 1 having a high reflectance with respect to radiant heat uses a metal foil obtained by rolling a metal plate, for example, an aluminum foil. That is, the entire tent has a structure provided with a uniform heat shield plate against heat.

  Since the material 1 having high reflectivity with respect to radiant heat does not transmit light, all the heat that moves in the tent base fabric 2 is considered to be conduction heat. The material 1 having a high reflectivity with respect to radiant heat generally has a concept of reflecting radiant heat, but this heat shield tent blocks conduction heat, and this discovery is the greatest point.

  Furthermore, in order to use the high reflection performance of the material 1 having a high reflectivity with respect to radiant heat, it is the conventional way of thinking that it is important to provide an air layer on the heat source side. However, the present invention is also characterized in that it does not have an air layer on the heat source side, and attaches the material 1 having high reflectivity to the radiant heat in close contact with the heat source side.

Since the material 1 having high reflectivity with respect to radiant heat does not transmit sunlight, the room is in a dark room. Therefore, when brightness is desired in the room, it is possible to provide the opening 4 in the material 1 having a high reflectivity with respect to radiant heat as shown in FIG. The shape, size, position, etc. of the opening 4 are free, there are few south surfaces with much solar radiation, and the north surface can be increased.
In addition, since there is a reflective material which is a material 1 having a high reflectivity with respect to radiant heat on the indoor side, there is an advantage that the number of indoor lighting fixtures can be reduced.

Further, as a method of making a heat-insulating tent with good heat insulation properties, as shown in FIG. 3, a heat-insulating material in which a non-woven fabric made of polyester resin or a resin sheet 6 or the like is attached to one side of a material 1 having high reflectivity against radiant heat is used as By attaching the surface of the non-woven fabric or the resin sheet 6 so as to be on the tent base fabric surface 2 side, a heat shield tent having high strength and high heat insulation can be obtained.
That is, the heat shielding tent has a three-layer structure including a tent base cloth 2, a polyester resin non-woven fabric or a resin sheet 6 and the like, and a material 1 having a high reflectivity with respect to radiant heat.

The tent base fabric 2 and the heat shielding material in which a non-woven fabric made of polyester resin or a resin sheet 6 or the like is attached to one side of the material 1 having high reflectivity with respect to radiant heat are fixed by bonding or welding 3, but the bonding or welding 3 parts are fixed. The air layer 5 can also be provided between both by performing partially rather than the whole surface. In the air layer 5 part, the heat insulating property is slightly improved compared to the close contact part, so that a larger effect can be produced as a whole.
Of course, in this case as well, if brightness is desired in the room, the opening 4 can be provided in the material 1 having a high reflectivity with respect to radiant heat as described above.

The heat shield tents 21, 31 and 41 are exposed to the wind and are in a state where their surfaces vibrate. When the material 1 having a high reflectivity with respect to radiant heat is integrated with the tent base fabric 2, the material 1 often receives a shearing force repeatedly due to wind.
Originally, since the material 1 having a high reflectivity with respect to radiant heat is plate-shaped, it is desirable to disperse this shearing force repeatedly applied. Therefore, as a method of dispersing the shearing force, a heat shield material in which a material 1 having high reflectivity with respect to radiant heat is attached to one side of a fabric 7 such as natural fiber or chemical fiber as shown in FIG. It was set as the heat insulation tent 51 attached so that the surface might become 2 surfaces of a tent base fabric.
That is, the tent base fabric 2, the woven fabric 7 such as natural fiber or chemical fiber, and the material 1 having a high reflectivity with respect to radiant heat and the heat shield tent 51 having a three-layer structure from the outside.

  If the material 1 having high reflectivity against radiant heat is attached to the surface of the fabric 7 such as natural fiber or chemical fiber, the material 1 having high reflectivity against radiant heat is highly pure and thin. The fabric 7 adheres closely to the fibers on the surface. That is, the surface of the heat insulating material using this woven fabric has irregularities, and the shearing force applied to the heat insulating material by the wind or the like is dispersed, so that a structure in which cracks do not easily occur can be obtained.

In addition, the tent base fabric 2 and the heat shielding material in which the material 1 having high reflectivity with respect to radiant heat is attached to the indoor side of the woven fabric 7 such as natural fiber or chemical fiber are fixed by bonding or welding 3, but are bonded or welded. The air layer 5 can be provided between the two parts by partially performing the three parts instead of the entire surface.
In the air layer 5 part, the heat insulating property is slightly improved compared to the close contact part, so that a larger effect can be produced as a whole.

  Of course, in this case as well, when brightness is desired in the room, the opening 4 can be provided in the material 1 having a high reflectivity with respect to radiant heat, as described above.

  The material 1 having a high reflectivity with respect to radiant heat is attached in contact with a column or roof frame of a tent warehouse. However, in the case where the support or the frame is made of metal such as a steel frame, there is a possibility that electrolytic corrosion will occur between the material 1 having a high reflectivity with respect to radiant heat. Therefore, as a countermeasure, a highly transmissive resin film 9 that efficiently transmits radiant heat can be attached to the indoor side of the material 1 having high reflectivity with respect to radiant heat.

The mechanism of the heat shield tent 21 will be described in detail.
In summer, conduction heat, convection heat and radiant heat from the outside are absorbed on the outer surface of the tent base fabric 2 and move through the tent base fabric 2 in the form of conduction heat, again from the indoor side of the tent base fabric 2 The heat is transferred into the room in three forms: conduction heat, convection heat and radiation heat.
Conductive heat moving through the tent base fabric 2 is conducted on the surface of the material 1 having high reflectivity with respect to radiant heat at the portion where the tent base fabric 2 and the material 1 with high reflectivity with respect to radiant heat are in close contact. Is blocked. Therefore, the heat radiated into the room from the material 1 having high reflectivity with respect to the radiant heat becomes a very small part. That is, the function of low radiation of the material 1 having high reflectivity with respect to radiant heat works effectively.
Further, the conduction heat blocked at the surface of the material 1 having a high reflectance with respect to the radiant heat is returned to the outdoor side of the tent base fabric 2. Accordingly, the outdoor temperature of the tent base fabric 2 is higher than the outdoor temperature of a normal tent.
However, according to Stefan-Boltzmann's law that the amount of heat radiated is proportional to the fourth power of the absolute temperature, it is radiated rapidly as the heat rises, and the outdoor side temperature of the tent base fabric 2 is significantly higher than usual. No.
The heat shielding tent of FIG. 3 has an air layer 5 between the tent base fabric 2 and a heat shielding material having a non-woven fabric made of polyester resin or a resin sheet 6 attached on one side of the material 1 having high reflectivity with respect to radiant heat. 41, the interior surface of the tent base fabric 2 takes three forms of conduction heat, convection heat, and radiant heat, and a polyester resin nonwoven fabric or resin sheet 6 or the like is applied to one surface of the material 1 having a high reflectivity with respect to the radiant heat. It is transmitted to the installed heat shield. However, a part of the radiant heat having the largest amount of heat is transmitted through the polyester resin nonwoven fabric or the resin sheet 6, reflected by the surface of the material 1 having a high reflectivity with respect to the radiant heat, and returned to the tent base fabric 2 again. Further, the radiant heat that is not transmitted is absorbed by the non-woven fabric made of polyester resin or the resin sheet 6 and becomes conductive heat, blocked by the surface of the material 1 having a high reflectivity with respect to the radiant heat, and returned to the tent base fabric 2 again.
This heat increases the temperature of the outdoor surface of the tent base fabric 2, but since it is radiated rapidly as described above, it does not become abnormally high.
In addition, since the space of the material 1 having a high reflectivity with respect to the tent base fabric 2 and the radiant heat is very small, almost no convection heat is generated, so this influence can be ignored.
As a result, the room temperature will not only drastically decrease, but the amount of radiant heat radiated from the material 1 having high reflectivity to the radiant heat will be greatly reduced, so the perceived temperature will change and the environment will be cooler than the actual room temperature. Can be made.

  In winter, the indoor heat is directed to the outdoor side, but since the material 1 having a high reflectivity with respect to the radiant heat is present on the indoor side, the radiant heat having the largest amount of heat is reflected and returned to the room. Therefore, if there is a heat source inside the tent, a warm environment can be maintained.

  The material 1 having high reflectivity with respect to radiant heat has the effect of increasing the surface temperature of the tent base fabric 2, and also has the effect of reducing the occurrence of condensation in winter.

The material 1 having a high reflectivity with respect to radiant heat is obtained by rolling a metal plate, and a thickness of about 5 to 10 microns is sufficient. However, in order to bring out high reflectivity performance, it is necessary to increase the purity of the material, and generally 99% or more is used.
However, the material 1 having a high reflectivity with respect to radiant heat is soft because of its high purity, and it is easy to be familiar with a fabric having flexibility such as a tent and is very easy to process.

  The tent base fabric 2 may be a commonly used tent base fabric and does not need to be newly produced.

  The material 1 and the tent base cloth 2 that have high reflectivity with respect to radiant heat may be bonded, welded 3 or double-sided tape, and the bonding method does not matter.

Example 1
Radiation heat is irradiated to the thermal insulation tent 61 and the thermal insulation tent 71 attached with aluminum foil foil, and the tent base cloth 2 of the conventional base cloth, which is not processed anything, by the far infrared heater 13, and the back surface temperature of the tent base cloth is measured. To do. The tent fabric is all on the heat source side, and the aluminum foil is on the opposite side of the heat source.
The thickness of the aluminum foil foil was 10 microns.

[Heat insulation test]
A 1 kilowatt far-infrared heater 13 was set in a room temperature of 26 ° C. and a humidity of 61%. Then, three test specimens were placed at a location 20 cm away from the far infrared heater 13.
In FIG. 5 for explaining the case where the experimental method of the embodiment is viewed from above, the first sheet is the tent base cloth 2 that is commercially available. The second sheet is a heat shield tent 61 in which an aluminum foil foil, which is a material 1 having a high reflectivity with respect to radiant heat, is attached to the entire back surface of the tent base fabric 2 (opposite to the heat irradiation side) with an adhesive 19. is there. The adhesive 19 serves as an adhesive means. Further, the third sheet is a heat shield tent 71 having a slight air layer 5 at the center by attaching only the periphery of the aluminum foil foil to the back side of the tent base fabric 2 with the adhesive 19.
Then, the far infrared heater 13 was irradiated, and the far infrared heater 13 side temperature of the first commercially available tent base fabric 2 was heated from room temperature to 90 ° C.
In the following table, the back surface temperature of the first tent base fabric 2 is “1. Back surface temperature”, the back surface temperature of the second heat shield tent is “2. The backside temperature of the thermal tent is indicated by “3. Backside temperature”.

[result]

[Discussion]
(1) When the first sheet, which is a commercially available tent base cloth 2, increases the irradiation side surface temperature, the heat is immediately transmitted to the back surface (inside the room). It can also be seen that when the surface temperature on the irradiation side of the tent base fabric 2 is 90 ° C., “1. Back surface temperature” is as high as 109 ° C. and 19 ° C. That is, when the temperatures of both surfaces of the tent base fabric 2 are compared, the radiation side temperature on the back side is higher than the heat irradiation side temperature.
(2) When the “1. back surface temperature” of the first tent base fabric 2 is 109 ° C., the “2. back surface temperature” of the second heat shield tent 61 to which the aluminum foil foil is adhered and stuck is 32. The temperature difference became 72.6 ° C. at 0.8 ° C. It can be seen that the heat shielding effect by the aluminum foil foil is very large.
(3) In addition, by attaching the adhesive 19 only around the aluminum foil foil, the “3. Back surface temperature” of the third heat shield tent 71 having a slight air layer at the center is 33.0 ° C. Thus, a temperature drop of 76.0 ° C. was observed as compared with 109 ° C., which is “1. Back surface temperature” of the first tent base fabric 2.
(4) “2. Back surface temperature” of the second heat shield tent 61 in which the aluminum foil foil is entirely bonded to the tent base cloth 2 and the third heat shield tent 71 provided with the air layer 5 in the center. With "3. Back surface temperature", it can be estimated that the third sheet with an air layer has a higher heat shielding effect.

(Example 2)
A heat shielding material 12 shown in FIG. 7 (a) in which a non-woven fabric 8 made of a polyester resin is pasted on an aluminum foil foil, which is a material 1 having high reflectivity against radiant heat, and a conventional tent that is not processed at all. The base fabric 2 is irradiated with radiant heat, and the back surface temperature of the tent base fabric 2 is measured. The tent base fabric 2 is all located on the heat source side, and the aluminum foil foil is located on the side opposite to the heat source.

[Heat insulation test]
A 1 kilowatt far-infrared heater 13 was set at a room temperature of 26 ° C. and a humidity of 66%. Then, three test specimens were placed at a location 20 cm away from the far infrared heater 13.
In FIG. 6 illustrating the case where the experimental method of the embodiment is viewed from above, the thickness of the heat shield 12 is 0.1 millimeter.
The first sheet is the same as the tent base cloth 2 that is commercially available. In the second sheet, the heat shielding material 12 was placed on the back side of the tent base fabric 2 (opposite to the heat irradiation side) so that the polyester resin nonwoven fabric 8 side was the tent base fabric 2 side, and the entire surface was adhered with an adhesive 19. This is a heat shield tent 81. Furthermore, the third sheet is a heat-shielding tent in which the heat-insulating material 12 has the polyester resin nonwoven fabric 8 side facing the tent and only the periphery is attached with an adhesive 19 to provide a slight air layer 5 at the center. 91.
Then, the far-infrared heater 13 was irradiated, and the irradiation side temperature of the first tent base cloth 2 was heated from room temperature to 90 ° C.
In the table below, the back surface temperature of the first tent base fabric is “4. Back surface temperature”, and the back surface temperature of the second heat shield tent 81 is “5. Back surface temperature”. The back surface temperature of the thermal tent 91 is indicated by “6. Back surface temperature”.

[result]

[Discussion]
(1) When the irradiation side surface temperature of the first tent base fabric 2 is 90 ° C., it is understood that “4. Back surface temperature” of the tent is as high as 107 ° C. and 17 ° C. That is, when the temperatures of both surfaces of the tent base fabric 2 are compared, the radiation side temperature on the back side is higher than the heat irradiation side temperature.
(2) When “4. Back surface temperature” of the first tent base cloth 2 is 107 ° C., “5. It can be seen that the temperature is 33.3 ° C. and the temperature is lowered by 73.7 ° C.
(3) Also, when “4. Back surface temperature” of the first tent base fabric 2 is 107 ° C., the heat shield 12 is attached to the periphery with an adhesive 19 and the air shield 5 is provided at the center. It can be seen that “6. Back surface temperature” of the tent 91 was 33.9 ° C., which was also decreased by 73.1 ° C.
(4) In this experiment, there is not much difference between “5. Back surface temperature” of the heat shield tent 81 and “6. Back surface temperature” of the heat shield tent 91, and in this test, the heat shield effect due to the presence or absence of the air layer 5. It was not possible to confirm the difference.

(Example 3)
Next, as shown in FIG. 8, the tent model 10 and the tent model 20 are manufactured and placed outside the room, and the tent model 10 and the heat shield material 22 of the heat shield tent with the heat shield material 22 attached are not attached. The room temperature of the tent model 20 is measured. The entrance / exit 12 of the tent model 10 and the tent model 20 is always open.

[Heat insulation test]
Conventionally, a base fabric is used for the tent model 10 and the tent model 20, and the thickness is 0.5 mm. The size of the tent model 10 and the tent model 20 is 400 W × 500 D × 350 Hmm. As shown in FIG. 7B, the heat shielding material is between a resin sheet made of polyester or the like and a material 1 having a high reflectivity with respect to radiant heat. Another resin sheet 28 made of polyethylene terephthalate or the like is provided, and the nonwoven fabric 27 is attached to the resin sheet made of polyester or the like so that the non-woven fabric 27 is on the tent base cloth 2 side. A heat shield 22 having a highly permeable resin film 9 attached to the indoor side is used.
In Example 3, a polyester resin non-woven fabric or a resin sheet in the resin sheet 6 is a resin sheet made of polyester, and the other resin sheet 28 is a resin sheet made of polyethylene terephthalate. Further, an aluminum foil is used for the material 1 having a high reflectance with respect to radiant heat.
In FIG. 8, the tent model 10 has the non-woven fabric 27 side of the 0.1 mm heat shielding material 22 adhered to the entire back surface of the tent base fabric 2 with the adhesive 19 on the back side (the side opposite to the heat irradiation side). On the other hand, the tent model 20 is only the tent base fabric 2. The tent model 10 and the tent model 20 are located at a height of 100 mm from the floor.
In the following table, the surface temperature of the tent model 20 of FIG. 8 without the heat shielding material 22 is a, and the temperature in the tent model 20 is b.
Similarly, the surface temperature of the tent model 10 in FIG. 8 to which the heat shield 22 is attached is indicated by c, and the temperature inside the tent model 10 is indicated by d. Furthermore, the outside air temperature in Example 3 is indicated by e.
Note that the following “result (first experiment)” and “result (second experiment)” are based on the experiment performed under the same conditions described above, but the dates of the experiment are different.

[Result (first experiment)]

[Discussion]
(1) The weighted average temperature of the temperature b in the tent model 20 without the heat shield 22 is 37.0 ° C. On the other hand, the weighted average temperature of the temperature d in the tent model 10 with the heat shielding material 22 is 32.5 ° C. Therefore, the weighted average temperature of the temperature d in the tent model 10 with the heat shield 22 attached is 4.5% on average than the weighted average temperature of the temperature b within the tent model 20 without the heat shield 22 attached. It can be seen that the temperature is low. Therefore, it can be seen that the heat shielding material 22 has a heat shielding effect. In addition, the average outside temperature at this time was 30.8 degreeC.
(2) The surface temperature a of the tent model 20 without the heat shielding material 22 and the surface temperature c of the tent model 10 with the heat shielding material 22 fluctuate greatly. This is considered to be a wind effect.
(3) Although the temperature b in the tent model 20 without the heat shield 22 is greatly influenced by wind or the like, the temperature d in the tent model 10 with the heat shield 22 is relatively stable. I understand that. Further, after 13:55, the temperature d in the tent model 10 with the heat shielding material 22 pasted is lower than the outside temperature e.
(4) At 12:40, the temperature b in the tent model 20 without the heat shield 22 was the highest at 40.3 ° C. However, at 12:40, the temperature d in the tent model 10 with the heat shield 22 attached is 34.6 ° C., which is 5 in comparison with the temperature b in the tent model 20 without the heat shield 22 attached. It can be seen that it is as low as 7 ° C.
Moreover, since the temperature d in the tent model 10 to which the heat shielding material 22 is attached is 34.6 ° C., it is 4.2 ° C. higher than the outside air temperature e of 30.4 ° C. at 12:40. On the other hand, the temperature b in the tent model 20 without the heat shielding material 22 attached at the same time is 40.3 ° C., so that it is 9.9 ° C. higher than the outside temperature e of 30.4 ° C. . Therefore, it can be seen that the heat shielding material 22 has a heat shielding effect.

[Result (second experiment)]

[Discussion]
(1) The weighted average temperature of the temperature b in the tent model 20 to which the heat shielding material 22 is not attached is 40.3 ° C. On the other hand, the weighted average temperature of the temperature d in the tent model 10 to which the heat shielding material 22 is stuck is 35.9 ° C. Therefore, the weighted average temperature of the temperature d in the tent model 10 with the heat shield 22 attached is 4.4 ° C. higher than the weighted average temperature of the temperature b in the tent model 20 without the heat shield 22 attached. It turns out that it is low. Therefore, it can be seen that the heat shielding material 22 has a heat shielding effect. In addition, the average outside temperature at this time was 33.1 degreeC.
(2) Even if the temperature changes in the tent model 10 and the tent model 20 are observed, the temperature b in the tent model 20 without the heat shield 22 is changed at a high temperature of 31.2 ° C. to 43.8 ° C. On the other hand, it can be seen that the temperature d in the tent model 10 with the heat shield 22 attached is stable at a relatively low temperature of 29.0 ° C. to 38.4 ° C.
(3) The temperature d in the tent model 10 to which the heat shielding material 22 is pasted is approximately the same as the outside air temperature e from about 14:25.
(4) The maximum temperature b in the tent model 20 without the heat shield 22 is 43.8 ° C. (13:55), whereas the temperature b in the tent model 10 with the heat shield 22 is applied. The maximum value of the temperature d was 38.4 ° C. (13:55) and 5.4 ° C. was low.

Example 4
Next, as shown in FIG. 9, the tent model 10 and the tent model 20 are manufactured and placed outside the room, and the thermal barrier tent model 10 of the thermal barrier tent with the thermal barrier 22 attached is not attached. The room temperature of the tent model 20 is measured. The entrance / exit 12 of the tent model 10 is always sealed.

[Heat insulation test]
For the tent model 10 and the tent model 20, a conventional base fabric is used, and the thickness is 0.5 mm. The size of the tent model 10 and the tent model 20 is 400 W × 500 D × 350 Hmm. The heat shielding material 22 is used as in the second embodiment.
In FIG. 9, the tent model 10 has the non-woven fabric 27 side of the 0.1 mm heat shielding material 22 adhered to the back side of the tent base fabric 2 (the side opposite to the heat irradiation side) with the adhesive 19. On the other hand, the tent model 20 is only the tent base fabric 2. The tent model 10 and the tent model 20 are located at a height of 100 mm from the floor.
In the following table, the surface temperature of the tent model 20 of FIG. 9 without the heat shielding material 22 is a, and the temperature in the tent model 20 is b.
Similarly, the surface temperature of the tent model 10 of FIG. 9 to which the heat shielding material 22 is stuck is indicated by c, and the temperature inside the tent model 10 is indicated by d. Furthermore, the outside air temperature in Example 3 is indicated by e.

[result]

[Discussion]
(1) The weighted average temperature of the temperature b in the tent model 20 without the heat shield 22 is 42.1 ° C. On the other hand, the weighted average temperature of the temperature d in the tent model 10 to which the heat shielding material 22 is stuck is 36.6 ° C. Therefore, the weighted average temperature of the temperature d in the tent model 10 with the heat shield 22 attached is 5.5 ° C. lower than the weighted average temperature of the temperature b in the tent model 20 without the heat shield 22 attached. Become. Therefore, it can be seen that, compared with the results of Example 3, the entrance / exit 12 of the tent model 10 and the tent model 20 is more effectively shielded than when it is always sealed, compared to when it is always opened.
(2) At 11:55, the temperature b in the tent model 20 without the heat shield 22 was 47.1 ° C., the highest temperature. On the other hand, the temperature d in the tent model 10 with the heat shield 22 attached at the same time was 40.0 ° C., and the outside temperature e was 33.3 ° C. Therefore, it can be seen that the temperature d in the tent model 10 to which the heat shielding material 22 is stuck is 7.1 ° C. lower than the temperature b in the tent model 20 to which the heat shielding material 22 is not stuck. Therefore, it can be seen that the heat shielding material 22 has a heat shielding effect.
(3) Although the surface temperature a of the tent model 20 and the surface temperature c of the tent model 10 fluctuate greatly due to the wind, the temperature b in the tent model 20 without the heat shielding material 22 is It can be seen that the surface temperature changes in a sensitive manner in conjunction with the temperature change.
(4) The heat shield tent 10 and the heat shield tent 20 are not air-conditioned indoors and are sealed, so that the temperature d in the tent model 10 with the heat shield 22 attached is kept warm after 13:25. The situation is changing and the temperature is almost the same as the outside temperature e. However, even though the temperature d in the tent model 10 with the heat shielding material 22 and the outside air temperature e are substantially the same, the tent model 10 with the heat shielding material 22 has a higher radiation amount of electromagnetic waves. It can be considered that the inside of the tent model 10 to which the heat material 22 is stuck feels quite cool as the temperature of experience.

(Example 5)
Next, based on FIG. 10 which explains the case where the experimental method of the embodiment is viewed from above, the heat shielding material 22 is completely adhered to the indoor side of the tent base cloth 2 which is a tent cloth using a conventional base cloth. The performance is verified by measuring the temperature difference between the case and the case of bonding with a partial air layer.

[Heat insulation test]
The heat shield material 22 is used as the heat shield material. Here, the heat shielding material 22 is a non-woven fabric made of polyester resin or a resin sheet made of polyester, out of the non-woven fabric 27, and another resin sheet made of polyethylene terephthalate on the resin sheet made of polyester. 28, a 7 μm thick aluminum foil, which is a material 1 having a high reflectivity with respect to radiant heat, and a highly transmissive resin film 9 are attached in this order.
Here, the reflectance of the heat shield 22 is 0.95.
As shown in FIG. 10, a far-infrared heater (1000 W / m ² ) 13 in an environment having a reflection temperature of 20.0 ° C., an atmospheric temperature, an external optical temperature, an external optical system transmittance of 1 and a humidity of 50%. Three test specimens were lined up at a distance of 1 m from and irradiated under the same conditions. The irradiation temperature is 60 ° C. Each test body is partitioned by a partition plate 23.
Here, the test specimen SP-1 is a heat shielding tent 101 in which the heat shielding material 22 is adhered to the tent base fabric 2 with the adhesive 19 which is an adhesion means to be completely adhered.
In the test body SP-2, only the periphery of the nonwoven fabric 27 of the heat shielding material 22 is adhered to the tent base fabric 2 with the adhesive 19, and the air layer 5 is interposed between the tent base fabric 2 and the nonwoven fabric 27 of the heat shielding material 22. This is a heat shield tent 111 provided.
The test body SP-3 uses only the tent base fabric 2.

[result]
As a result of measuring the back surface temperature of each specimen (SP-1 and SP-2 are the sides on which the heat shielding material 22 is pasted, SP-3 is the opposite side of the surface to be irradiated), the specimen SP-1 is 32.7. C., specimen SP-2 was 31.5.degree. C. and specimen SP-3 was 49.7.degree.

[Discussion]
(1) The specimens SP-1 and SP-2 to which the heat shield 22 is attached have the back surface temperatures of 32.7 ° C. and 31.5 ° C., respectively, whereas the specimen SP to which the heat shield 22 is not attached. The back surface temperature of -3 was 49.7 ° C. Therefore, the back surface temperatures of SP-1 and SP-2 were 17.0 ° C. and 18.2 ° C. lower than the back surface temperature of SP-3, respectively. Therefore, SP-1 of the heat-shielding tent 101 and SP-2 of the heat-shielding tent 111, which are test bodies to which the heat-shielding material 22 is pasted, are higher in heat shield than the test body SP-3 to which the heat-shielding material 22 is not pasted. It turns out that it has an effect.
(2) The specimen SP-2 in which the air layer 5 is provided and the heat shielding material 22 is pasted on the tent base cloth 2 has a back surface temperature higher than that of SP-1 in which the heat shielding material 22 is entirely bonded to the tent base cloth 2. Was 1.2 ° C. lower. It is not the tent base cloth 2 that adheres the heat shield 22 but the other material because the temperature when the air shield 5 is provided and the heat shield 22 is applied is lower than the temperature of the heat shield 22 bonded to the entire surface. However, the same tendency is shown. Therefore, it is considered that the heat shielding effect is enhanced by providing the air layer 5 due to the improvement of heat insulation.

(Example 6)
Next, based on FIG. 11 which explains the case where the experimental method of the embodiment is viewed from above, a heat shield as a heat shield for agriculture is provided on the indoor side of the tent base fabric 2 which is a tent fabric using a conventional base fabric. The performance is verified by measuring the temperature difference between the case where the material 32 is completely adhered and the case where a part of the air layer is provided and bonded.

[Heat insulation test]
As the heat shield material, a heat shield material 32 which is an agricultural heat shield material is used. Here, as shown in FIG. 7C, the heat shielding material 32 is a polyester resin nonwoven fabric or a resin made of polyester or the like among the resin sheet 6 on one surface of another resin sheet 28 made of polyethylene terephthalate or the like. A sheet is attached, and further, a material 1 having a high reflectance with respect to radiant heat and a highly transmissive resin film 9 are attached to a resin sheet made of polyester or the like in this order. In Example 6, polyethylene terephthalate is used for the other resin sheet 28, and a resin sheet made of polyester is used for the non-woven fabric made of polyester resin or the resin sheet in the resin sheet 6. Further, a 7 μm thick aluminum foil is used for the material 1 having a high reflectivity with respect to radiant heat. Here, the reflectance of the heat shield 32 is 0.95.
As shown in FIG. 11, a far-infrared heater (1000 W / m ² ) 13 in an environment having a reflection temperature of 20.0 ° C., an atmospheric temperature, an external optical temperature, an external optical system transmittance of 1 and a humidity of 50%. Three test specimens were lined up at a distance of 1 m from and irradiated under the same conditions. The irradiation temperature is 60 ° C. Each test body is partitioned by a partition plate 23.
Here, the test body SP-4 is a heat shield tent 121 in which the heat shield 32 is adhered to the entire surface of the tent base fabric 2 with the adhesive 19 and completely adhered.
The test body SP-5 was bonded to the tent base fabric 2 only around the other resin sheet 28 of the heat shield 32 with the adhesive 19, and the tent base fabric 2 and the other resin sheet 28 of the heat shield 32 were This is a heat shield tent 131 provided with an air layer 5 therebetween.
Only the tent base fabric 2 is used for the test body SP-6.

[result]
As a result of measuring the back surface temperature of each test body (SP-4 and SP-5 are the sides on which the heat shielding material 32 is pasted, SP-3 is the opposite side of the irradiated surface), the test body SP-4 is 29.9. C., Specimen SP-5 was 26.9.degree. C., and Specimen SP-6 was 51.0.degree.

[Discussion]
(1) The specimens SP-4 and SP-5 with the heat shield 32 attached thereon have back surface temperatures of 29.9 ° C. and 26.9 ° C., respectively, whereas the specimen SP without the heat shield 32 attached. The back surface temperature of −6 was 51.0 ° C. Therefore, the back surface temperatures of SP-4 and SP-5 were 21.1 ° C. and 24.1 ° C. lower than the back surface temperature of SP-6, respectively. Therefore, SP-4 of the heat-shielding tent 121 and SP-5 of the heat-shielding tent 131, which are test bodies to which the heat-shielding material 32 is stuck, have a higher heat-shielding effect than the specimen SP-6 to which the heat-shielding material 32 is not stuck. It can be seen that
(2) The specimen SP-5 in which the heat shielding material 32 is provided on the tent base cloth 2 with the air layer 5 provided thereon is opposite to the back surface of SP-4 in which the heat shielding material 32 is entirely bonded to the tent base cloth 2. The temperature was 3.0 ° C lower. It is not the tent base cloth 2 that adheres the heat shield 32 but the other material, because the temperature of the air shield 5 and the heat shield 32 attached is lower than that of the entire surface of the heat shield 32. However, the same tendency is shown. Therefore, it is considered that the heat shielding effect is enhanced by providing the air layer 5 due to the improvement of heat insulation.
(3) Compared with the heat shield 22 of Example 5, the temperature of SP-4 and SP-5 with the heat shield 32 is lower than SP-1 and SP-2 with the heat shield 22 attached. Therefore, it can be seen that the heat shielding effect of the heat shielding material 32 is higher than that of the heat shielding material 22.

(Example 7)
Next, on the indoor side of the tent base fabric 2 used in the actual tent warehouse 14, the temperature difference between when the heat shield 22 is attached to the wall 16 and the ceiling 17 and when it is not attached is measured to verify the performance. To do.

[Heat insulation test]
FIG. 12 shows a situation where the worker 15 actually attaches the heat shielding material 22 to the wall 16 and the ceiling 17 inside the tent warehouse 14. That is, the eyelet 4 is attached around the heat insulating material 22, and the heat insulating material 22 is tied to the tent frame 25 by the string 26 so as to be along the wall 16 and the ceiling 17. Here, the heat shield 22 and the wall 16 and the ceiling 17 inside the tent warehouse 14 are not bonded. Therefore, a gap is formed between the heat shield 22 and the wall 16 and the ceiling 17 inside the tent warehouse 14.
The weather on the day of the verification in Example 7 is clear and the outside air temperature is 26 ° C., but the air conditioner is effective inside the tent warehouse 14.
Here, in FIG. 12, the temperature of the ceiling 17a to which the heat shield 22 of the tent warehouse 14 is not attached is represented by (A).
The temperature of the wall 16a of the tent warehouse 14 to which the heat shield 22 is not attached is represented by (b).
The temperature of the ceiling 17b of the tent warehouse 14 to which the heat shield 22 is attached is represented by (c).
The temperature of the wall 16b of the tent warehouse 14 to which the heat shield 22 is attached is represented by (d).
The above (a), (b), (c) and (d) represent the temperature inside the tent warehouse 14.
Furthermore, the temperature outside the warehouse at the location where the heat shield 22 is attached to the wall 16 inside the tent warehouse 14 (eg, the temperature on the back side of 16b) and the heat shield 22 on the wall 16 inside the tent warehouse 14. The temperature on the outside of the warehouse at the place where the slab was not attached (example: temperature on the back side of 16a) was also measured.

[result]
(A) was 27.5 ° C. and (B) was 34.0 ° C. (C) was 25.0 ° C, and (D) was 25.6 ° C.
On the other hand, the temperature on the outside of the warehouse where the heat shield 22 was attached to the wall 16 inside the tent warehouse 14 was 30.1 ° C. Further, the temperature on the outside of the warehouse where the heat shield 22 was not attached to the wall 17 inside the tent warehouse 14 was 27.8 ° C.

[Discussion]
(1) The temperature (c) of the ceiling 17b to which the heat shield 22 is attached is 2.5 ° C. lower than the temperature (b) of the ceiling 17a to which the heat shield 22 is not attached. On the other hand, the temperature (d) of the wall 16b to which the heat shield 22 was attached was 8.4 ° C. lower than the temperature (b) of the wall 16a to which the heat shield 22 was not attached. Therefore, it can be seen that the heat shielding material 22 has a heat shielding effect.
(2) Regarding the temperature outside the warehouse of the wall 16 of the tent warehouse 14, when the heat shield 22 is attached inside the wall 16, the radiant heat is reflected outside without entering. Therefore, the temperature outside the warehouse where the heat shield 22 is attached to the wall 16 inside the tent warehouse 14 is the outside of the warehouse where the heat shield 22 is not attached to the wall 16 inside the tent warehouse 14. It is 2.3 ° C. higher than the temperature of

(Example 8)
Next, in FIG. 13, the tent model 30 and the tent model 40 are manufactured using the tent base cloth 2 that is the same tent fabric as the tent warehouse 14, placed outside, and the tent model 30 with the heat shielding material 22 attached thereto. The room temperature of the tent model 40 without the heat shield 22 is measured.

[Heat insulation test]
The size of the tent model 30 and the tent model 40 is 600 W × 900 D × 600 Hmm. The heat shield material 22 is used as the heat shield material.
In FIG. 13, the tent model 30 has the heat shielding material 22 bonded to the entire surface with the adhesive 19 on the back side (the side opposite to the heat irradiation side) of the tent base fabric 2. On the other hand, the tent model 40 is only the tent base cloth 2 without attaching the heat shield 22. The tent model 30 and the tent model 40 were installed on the tent warehouse 14 side, and the internal temperature data of the tent model 30 and the tent model 40 were taken for 12 days, respectively.

[result]
During the day when the sun is out, the internal temperature of the tent model 30 with the heat shield 22 attached was nearly 10 ° C. lower than the internal temperature of the tent model 40 without the heat shield 22 attached.

[Discussion]
(1) From the above results, it has become clear that the heat shielding effect of the heat shielding material 22 is high. The measurement of Example 8 was performed from September to October. If the temperature in midsummer is high, the reflection of radiant heat by the material 1 having high reflectivity with respect to the radiant heat and the penetration of conduction heat into the room. It is considered that a higher heat shielding effect can be obtained by prevention.
(2) This time, measurement was performed using the tent base fabric 2 which is a tent material. However, if the material is more likely to be a heat source such as a steel plate or cement plate, a higher heat shielding effect can be obtained. Think.

1 Highly reflective material for radiant heat 2 Tent base fabric 3 Adhesion or welding 4 Opening
5 Air layer 6 Non-woven fabric or resin sheet made of polyester resin 7 Woven fabric 8 Non-woven fabric made of polyester resin 9 High permeability resin film 10, 20, 30, 40 Tent model 11 Entrance / exit 12, 22, 32 Heat shield 13 Far infrared heater 14 Tent warehouse 15 Worker 16 Wall 16a Wall 16b Wall 17 Ceiling 17a Ceiling 17b Ceiling 18 Model 19 Adhesive 21, 31, 41, 51, 61, 71, 81, 91, 101, 111,
121, 131 Heat-shielding tent 23 Partition plate 24 Eyelet 25 Tent frame 26 String 27 Non-woven fabric 28 Resin sheet

Claims (11)

Install a heat shield with a high-reflectance material against radiant heat on one side of the nonwoven fabric or resin sheet on the indoor side of the tent base fabric so that the nonwoven fabric or resin sheet surface is on the tent base fabric surface side. ,
A heat shield tent , wherein the periphery of the nonwoven fabric or resin sheet is bonded to the surface of the tent base cloth by an adhesive means, and an air layer is provided between the nonwoven fabric or resin sheet and the tent base cloth . The non-woven fabric or resin sheet is further bonded to the surface of the tent base cloth by the bonding means, and a plurality of air layers are formed at predetermined intervals between the non-woven fabric or resin sheet and the tent base cloth. The heat shield tent according to claim 1. Install a heat shield with a high-reflectance material against radiant heat on one side of the fabric on the interior side of the tent fabric so that the fabric surface becomes the surface of the tent fabric and bond the surroundings of the fabric A heat-shielding tent which is bonded to the surface of the tent base fabric by means and an air layer is provided between the woven fabric and the tent base fabric . The heat-shielding tent according to claim 3, wherein the fabric includes natural fibers and chemical fibers . Claims the fabric, said further bonded to the tent base surface of the fabric with adhesive means, wherein a plurality of said air layer is formed at predetermined intervals between the tent base fabric and the fabric The thermal insulation tent of Claim 3 or Claim 4. Install a heat shield with a high-reflectance material against radiant heat on one side of the nonwoven fabric or resin sheet on the indoor side of the tent base fabric so that the nonwoven fabric or resin sheet surface is on the tent base fabric surface side. ,
Further provided with another resin sheet different from the resin sheet between the nonwoven fabric or the resin sheet and a material having high reflectivity with respect to the radiant heat, the other nonwoven fabric different from the nonwoven fabric is the tent base cloth surface Attached to the nonwoven fabric or resin sheet,
A heat shield tent , wherein the periphery of the other nonwoven fabric is bonded to the surface of the tent base fabric by an adhesive means, and an air layer is provided between the other nonwoven fabric and the tent base fabric . Install a heat shield with a high-reflectance material against radiant heat on one side of the nonwoven fabric or resin sheet on the indoor side of the tent base fabric so that the nonwoven fabric or resin sheet surface is on the tent base fabric surface side. ,
It is further attached to the nonwoven fabric or resin sheet so that another resin sheet different from the resin sheet is on the tent base fabric surface side,
A heat shield tent , wherein the periphery of the other resin sheet is bonded to the surface of the tent base cloth by an adhesive means, and an air layer is provided between the other resin sheet and the tent base cloth . The heat shield tent according to any one of claims 1 to 7, wherein the material having a high reflectance with respect to the radiant heat is a metal foil produced by rolling a metal plate . The heat shielding tent according to any one of claims 1 to 8, wherein an opening is provided in a material having high reflectivity with respect to the radiant heat. The heat- shielding tent according to any one of claims 1 to 9, wherein a highly transmissive resin film is further installed on the indoor side of a material having a high reflectivity with respect to the radiant heat. The said tent base fabric contains a natural fiber, a chemical fiber, and a resin sheet, The heat insulation tent of any one of Claims 1-10 characterized by the above-mentioned.