JP2013092221A - Heat insulation sheet, and mixer drum cover for concrete mixer vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat insulation sheet that has a high heat insulation property, and to provide a mixer drum cover for a concrete mixer vehicle.SOLUTION: The heat insulation sheet 100 includes: a surface sheet 110 disposed on a surface; an aluminum sheet 120 provided with an aluminum film; and a cotton sheet 130. The aluminum sheet 120 is disposed between the surface sheet 110 and the cotton sheet 130, and has a plurality of holes for passing air contained in the cotton sheet 130 and water infiltrated into the cotton sheet 130 to the surface sheet 110 side.

Description

  The present invention relates to a heat insulating sheet and a mixer drum cover of a concrete mixer truck.

  There is a need for a technology that suppresses temperature changes inside cars and buildings. Patent Document 1 discloses a cooling sheet that uses a heat-absorbing sheet containing water to cover a vehicle and suppresses a temperature rise inside the vehicle by using vaporization heat.

JP 2003-314925 A

  Since it is necessary to supply the sheet with water, the sheet of Patent Document 1 is not suitable for use in a situation where water supply is difficult (for example, heat insulation of a building or the like). Although it is possible to use a heat insulating sheet that does not use water, such a sheet generally does not have a high heat insulating property, and the internal temperature change cannot be sufficiently suppressed under the strong sunlight in midsummer.

  This invention is made | formed in view of such a problem, and it aims at providing the heat insulation sheet with high heat insulation, and the mixer drum cover of a concrete mixer truck.

In order to achieve the above object, the heat insulating sheet according to the first aspect of the present invention is:
A surface sheet disposed on the surface;
An aluminum sheet provided with an aluminum film;
A cotton-like cotton sheet,
The aluminum sheet is disposed between the top sheet and the cotton sheet, and has a plurality of holes through which air contained in the cotton sheet and water that has entered the cotton sheet pass to the top sheet side. ,
It is characterized by that.

  The ratio of the area of the hole to the area of the aluminum sheet may be 30% or less.

  The ratio of the area of the hole to the area of the aluminum sheet may be 4% or less.

The area per one of the holes may be 20 mm ² or less.

The area per one of the holes may be 3.2 mm ² or less.

  You may provide the back surface sheet | seat arrange | positioned on the opposite side of the said surface sheet on both sides of the said aluminum sheet and the said cotton sheet.

In order to achieve the above object, the mixer drum cover according to the second aspect of the present invention comprises:
A heat insulating sheet according to the first aspect processed so as to be wound around the outer periphery of a mixer drum of a concrete mixer truck,
It is characterized by that.

  A heat insulating sheet with high heat insulating properties and a mixer drum cover for a concrete mixer truck can be provided.

It is a fragmentary sectional view of the heat insulation sheet concerning Embodiment 1. FIG. It is a figure which shows the aluminum sheet arrange | positioned at the heat insulation sheet, (A) is the surface view of an aluminum sheet, (B) is A-A 'partial sectional drawing, (C) is B-B' partial sectional drawing. It is a figure which shows the grid | lattice-like groove | channel formed in the surface of a heat insulation sheet. It is a figure which shows the modification of an aluminum sheet, (A) is a figure which shows the aluminum sheet which formed the aluminum film in the single side | surface of a film, (B) shows the aluminum sheet which pinched | interposed the aluminum film with two films FIG. It is a fragmentary sectional view of the surface sheet arrange | positioned on the surface of a heat insulation sheet. It is a figure which shows the wavy line-shaped groove | channel formed in the surface of a heat insulation sheet. It is a figure which shows a mode that a surface sheet, an aluminum sheet, a cotton sheet, and a back surface sheet are bonded together by the method of ultrasonic welding. It is a figure which shows a mode that the groove | channel was formed in the surface of a heat insulation sheet by connecting the recessed part formed in the case of ultrasonic welding. It is a figure which shows a mode that the bubble buffer sheet was affixed on the back surface of the heat insulation sheet. It is a right view of a concrete mixer truck when the mixer drum cover concerning Embodiment 2 is mounted | worn with the mixer drum of a concrete mixer truck. It is a left view of a concrete mixer truck when a mixer drum cover is attached to a mixer drum of a concrete mixer truck. It is an enlarged view of the eyelet part when the mixer drum cover is attached to the mixer drum. It is a perspective view of the experimental apparatus for verifying the heat insulation of a heat insulation sheet. It is sectional drawing of the experimental apparatus for verifying the heat insulation of a heat insulation sheet. It is a figure which shows the result of having verified the heat insulation of the heat insulation sheet using the experimental apparatus shown in FIG.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

(Embodiment 1)
The heat insulating sheet 100 according to the embodiment of the present invention is a multilayer structure sheet in which a plurality of sheets are stacked. By blocking infrared rays from the sun outside the object such as buildings, the temperature rise inside the object is suppressed.

  As shown in FIG. 1, the heat insulating sheet 100 includes a top sheet 110, an aluminum sheet 120, a cotton sheet 130, and a back sheet 140.

  The top sheet 110 is disposed on the surface of the heat insulating sheet 100, and protects the heat insulating sheet 100 from friction when ultraviolet rays or objects falling from the sun come into contact. The top sheet 110 is made of, for example, a woven fabric of polyester fiber that is resistant to friction and has a low ultraviolet transmittance.

  The aluminum sheet 120 is arrange | positioned between the surface sheet 110 and the cotton sheet 130, and suppresses that the infrared rays from the sun reach an object. For example, as shown in FIGS. 2B and 2C, the aluminum sheet 120 is an aluminum-deposited PET in which aluminum films (aluminum films 122 and 122) having high infrared reflectance are formed on both surfaces of a PET (Polyethylene Terephthalate) film 121. Consists of As shown in FIG. 2A, the aluminum sheet 120 has a plurality of circular holes opened at equal intervals.

  The cotton sheet 130 is a sheet for preventing the object from being heated by outside air heat or the like. The cotton sheet 130 is made of, for example, a nonwoven fabric in which polyester fibers are combined or entangled in a cotton shape. The cotton sheet 130 contains a large amount of air inside due to its nature. The air inside the cotton sheet 130 passes through holes formed in the aluminum sheet 120 and is supplied between the top sheet 110 and the aluminum sheet 120.

  The back sheet 140 is a sheet that is disposed on the back surface of the heat insulating sheet 100 and prevents the heat insulating sheet 100 from deteriorating due to friction when contacting the object. The back sheet 140 is disposed on the opposite side of the top sheet 110 with the aluminum sheet 120 and the cotton sheet 130 interposed therebetween. The back sheet 140 is made of, for example, a polypropylene fiber woven fabric or a polypropylene resin film that is resistant to friction.

  These four sheets (the front sheet 110, the aluminum sheet 120, the cotton sheet 130, and the back sheet 140) are sewn together with yarns of chemical fibers. Therefore, grooves are formed on both surfaces of the heat insulating sheet 100 along the stitches 150 as shown in FIG. The four sheets are sewn into a geometric pattern as shown in FIG. Here, the geometric pattern refers to a pattern made of a triangle, a rectangle, a rhombus, a polygon, a circle, or the like. By stitching the sheets into the geometric pattern, the heat insulating sheet 100 becomes strong against tension from any direction, the vertical direction and the horizontal direction.

  As described above, a groove having a geometric pattern is formed on the surface of the heat insulating sheet 100. For this reason, light falling from sunlight is diffusely reflected on the sheet surface, and the amount of infrared rays incident on the sheet is reduced. Moreover, since the infrared rays that have entered the sheet without being irregularly reflected are also reflected by the aluminum sheet 120, it is possible to prevent the object from being heated by infrared rays from the sun.

  Moreover, the heat insulation sheet 100 has the cotton sheet 130 with high heat insulation. Therefore, the heat transferred to the aluminum sheet 120 is also blocked by the cotton sheet 130, and the transfer of heat to the object is greatly suppressed. In addition, since an air layer is formed between the object and the heat insulating sheet 100 along the groove on the back surface as shown in FIG. 1, the slight heat that has passed through the cotton sheet 130 is also generated by this air layer. Blocked by. In addition, under conditions where the outside air temperature is low, such as in winter, it is necessary to confine heat inside the object, but the release of heat from the inside of the object is greatly suppressed by this groove.

  Thus, the heat insulating sheet 100 has a structure that makes it difficult for infrared rays and heat to pass therethrough. For this reason, the heat insulation sheet 100 can fully suppress the temperature change inside a target object.

  Moreover, since the polyester fiber strong against ultraviolet rays and friction is used for the surface sheet 110 arranged on the surface of the heat insulating sheet 100, it is assumed that the heat insulating sheet 100 is installed outdoors exposed to sunlight or friction. However, it can continue to be used without deterioration over a long period of time.

  Moreover, since the heat insulation sheet 100 is provided with the cotton sheet 130 with high heat insulation, the heat inside and outside the object can be efficiently blocked. Moreover, since the cotton has sound absorbing properties, the heat insulating sheet 100 can block sound from inside and outside of the object in addition to heat.

  The aluminum sheet 120 has a plurality of holes. Therefore, as shown in the below-mentioned Example, the heat insulation sheet 100 can exhibit high heat insulation compared with the case where the aluminum sheet 120 does not have a hole. Further, when the heat insulating sheet 100 is used outdoors, rainwater or the like may enter the heat insulating sheet 100 during use. Moisture that has entered inside stays in the cotton sheet 130 for a long period of time, and promotes deterioration of the heat insulating sheet 100. However, since the heat insulating sheet 100 according to the present embodiment has holes formed in the aluminum sheet 120, even if water enters the cotton sheet 130, the intruded water is absorbed into the top sheet 110 through the holes, or , Discharged through the needle hole, etc. As a result, moisture does not stay in the heat insulating sheet 100 for a long period of time, and deterioration of the heat insulating sheet 100 is suppressed.

  Note that a preferable range of the ratio of the hole area to the area of the aluminum sheet 120 (including the hole area) (hereinafter referred to as “opening ratio”) is 4% or less, and more desirably 2% to 4%. . In addition, when giving priority to the deterioration prevention of the heat insulation sheet 100, the aperture ratio of the aluminum sheet 120 may be 4% or more and 30% or less. Even if it is the aluminum sheet 120 of 30% or less of aperture ratio, the heat insulation sheet 100 can exhibit high heat insulation. The aperture ratio R is calculated by, for example, the following (Equation 1), where Sh is the area per hole, n is the number of holes per unit area of the aluminum sheet 120, and Sa is the unit area.

    R = (Sh × n × 100) ÷ Sa (Equation 1)

  Moreover, the suitable range of the magnitude | size of the hole opened in the aluminum sheet 120 is 2 mm or less in diameter, More preferably, it is 1 mm or less in diameter. In addition, when giving priority to the deterioration prevention of the heat insulation sheet 100, the size of the hole may be 3 mm or less or 5 mm or less. Even if the size of the hole is 3 mm or less or 5 mm or less, the heat insulating sheet 100 can exhibit high heat insulating properties.

The shape of the hole formed in the aluminum sheet 120 is not limited to a circle. It may be a polygon such as a triangle, a quadrangle, or a hexagon, or an arbitrary shape such as an ellipse. At this time, a preferable area per hole is 3.2 mm ² or less corresponding to the area of a circle having a diameter of 2 mm, more preferably about 0.8 mm ² or less corresponding to the area of a circle having a diameter of 1 mm. Good. In consideration of the loss of moisture that has entered the cotton sheet 130, it may be about 7.1 mm ² or less corresponding to the area of a circle with a diameter of 3 mm, and about 20 mm ² or less corresponding to the area of a circle with a diameter of 5 mm. .

  Further, the arrangement of the holes formed in the aluminum sheet 120 is not limited to equal intervals. The interval between the holes may be changed at random.

  Further, the structure of the aluminum sheet is not limited to the structure shown in FIG. 2B. For example, as shown in FIG. 4A, the aluminum film 122 may be formed on one side of the PET film 121. Good. Further, as shown in FIG. 4B, a structure in which an aluminum film 122 is sandwiched between PET films 121 or the like may be used.

  In order to prevent rainwater from penetrating into the inner layer of the heat insulating sheet 100, an acrylic resin waterproof film 111 is formed on the back surface side of the top sheet 110 (inner layer side of the heat insulating sheet 100) as shown in FIG. It may be. By forming the waterproof film 111, peeling of the aluminum film from the aluminum sheet 120 due to infiltration of rainwater is suppressed, so that the heat insulating sheet 100 can maintain high heat insulating properties over a long period of time. Moreover, since the waterproof film 111 is formed on the back surface side of the top sheet 110, the waterproof film 111 is not peeled off from the surface of the top sheet 110 when an object contacts the surface of the top sheet 110. Therefore, the heat insulation sheet 100 can maintain high waterproofness for a long period of time.

  In addition, when the waterproof film 111 is formed on the surface side of the heat insulating sheet 100, the waterproof film 111 causes a chemical reaction with dust, dust, or the like attached to the surface of the surface sheet 110, and stains or coloring that cannot be cleaned on the sheet surface. generate. Dirt and coloring generated on the surface of the surface sheet 110 make it easy to absorb outside heat, and lower the reflection function of the surface sheet such as infrared rays. However, in this embodiment, since the waterproof film 111 is formed on the back surface side of the top sheet 110, the waterproof film 111 does not cause uncleanable stains or coloring on the surface of the top sheet 110. In addition, when the waterproof film 111 is formed on the surface side, it is difficult to wash the heat insulating sheet 100 with water. This is because the water adhering to the surface of the top sheet 110 becomes polka dots due to the water repellent function of the waterproof film 111 and is immediately detached from the sheet surface. However, since the heat insulation sheet 100 of this embodiment does not have the waterproof film 111 on the surface, the surface of the surface sheet 110 can be easily washed with water by utilizing the water absorption of the woven fabric. Therefore, even if dust or dirt adheres to the surface of the surface sheet 110, the reflection function of the surface sheet 110 can be easily recovered by washing the surface of the surface sheet 110 with water.

  The waterproof film 111 is not limited to an acrylic resin, and may be a fluorine compound or the like. Since the fluorine compound is extremely stable and does not deteriorate for a long time, the waterproof property of the heat insulating sheet 100 can be maintained for a longer time.

  Moreover, in the above-mentioned embodiment, although the groove | channel was formed in the grid | lattice form on the surface of the heat insulation sheet 100, you may form a groove | channel in a wavy line shape, as shown in FIG. When rainwater adheres to the surface of the heat insulating sheet 100, water droplets easily fall along the wavy lines, so that the surface of the heat insulating sheet 100 is not excessively cooled by the heat of vaporization.

  Moreover, the top sheet 110, the aluminum sheet 120, the cotton sheet 130, and the back sheet 140 may be bonded together by high frequency welding or ultrasonic welding. Here, the high-frequency welding refers to a method in which a target object is caused to generate heat from the inside by causing a potential movement at an atomic or molecular level in the target object by the electric field action of high-frequency energy. Further, ultrasonic welding refers to a method in which an object is melted and bonded by heat by ultrasonic vibration. For example, as shown in FIG. 7, a part of the heat insulating sheet 100 may be pressurized from both sides of the sheet, and an electromagnetic wave or ultrasonic vibration may be applied to the pressurized part, so that the pressurized part is melted with heat and bonded. .

  In addition, as shown in FIG. 8, the groove | channel on the surface of the heat insulation sheet 100 may be formed by connecting the recessed part 160 formed in both surfaces of a sheet | seat at the time of high frequency welding or ultrasonic welding. Unlike sewing sheets together, there is no need to make a needle hole in the surface of the heat insulating sheet 100, so rainwater will not enter through the needle hole. As a result, the waterproofness of the heat insulating sheet 100 can be further improved.

  The top sheet 110, the aluminum sheet 120, the cotton sheet 130, and the back sheet 140 may contain a thermoplastic resin such as polyester, polypropylene, polyethylene, polyvinyl chloride, or polystyrene. Since the sheet is easily melted by heat, the adhesive strength of the sheet is further increased when the sheets are bonded by high frequency welding or ultrasonic welding.

  The method of bonding the top sheet 110, the aluminum sheet 120, the cotton sheet 130, and the back sheet 140 is not limited to stitching or ultrasonic welding. Bonding may be performed using an adhesive, or may be performed by directly applying heat to the sheet instead of electromagnetic waves or ultrasonic waves.

  Further, a plurality of fine fibers protrude from the surface of the back sheet 140 by, for example, penetrating or planting fine fibers having an average diameter of 1 to 1000 nm on the back sheet 140, and the fine fibers are entangled with the cotton sheet 130. Thus, the back sheet 140 and the cotton sheet 130 may be bonded together like a so-called surface fastener. The back sheet 140 is a part that is in direct contact with the object and easily peels off from the heat insulating sheet 100. In addition to stitching and ultrasonic welding, the back sheet 140 is bonded to the cotton sheet 130 and the back sheet 140 using this method. By placing, the peeling of the back sheet 140 from the heat insulating sheet 100 can be significantly suppressed. Moreover, if this fine fiber is also protruded on the surface on the side in contact with the object, when the heat insulating sheet 100 is installed on the object, the fine fiber is interposed between the back sheet 140 and the object. It plays a role and can suppress deterioration of the back sheet 140 due to friction with the object.

  The order in which these sheets are stacked is not limited to the order of “surface sheet 110, aluminum sheet 120, cotton sheet 130, and back sheet 140”. The order of the aluminum sheet 120 and the cotton sheet 130 may be changed to be “surface sheet 110, cotton sheet 130, aluminum sheet 120, back sheet 140”, or the aluminum sheet 120 may be added between the cotton sheet 130 and the back sheet 140. “Top sheet 110, aluminum sheet 120, cotton sheet 130, aluminum sheet 120, back sheet 140” may be used. By providing the aluminum sheet 120 between the cotton sheet 130 and the back sheet 140, the infrared rays emitted from the object can be reflected before reaching the cotton sheet 130. Therefore, in the situation where the outside air temperature is low, such as in winter, the infrared rays emitted from the object can be immediately reflected on the object, so that the object can be efficiently kept warm.

  In addition, as shown in FIG. 9, a bubble cushioning sheet 170 may be further bonded to the heat insulating sheet 100. Here, the bubble cushioning sheet is a sheet in which two resin sheets are bonded together, and is a sheet in which air is enclosed in a plurality of cylindrical protrusions 171 formed on one of the two sheets. Say. Since the thermal conductivity of air that does not move, so-called dead air, is extremely low, the heat insulating sheet 100 can further enhance the heat insulating property by including the bubble buffering sheet 170.

  Note that carbon dioxide gas, argon gas, krypton gas, xenon gas, or the like may be enclosed in the protrusion 171 in addition to air. Since these gases have a lower thermal conductivity than air, the heat insulating property of the heat insulating sheet 100 can be further improved.

(Embodiment 2)
Hereinafter, the mixer drum cover of the concrete mixer truck using the heat insulating sheet 100 will be described. As shown in FIG. 10, the mixer drum cover 200 is a cover obtained by processing the heat insulating sheet 100 into a shape that can be wound around a mixer drum of a concrete mixer truck. As shown in FIG. 11, the mixer drum cover 200 includes a cover part 210 and an eyelet part 220.

  The cover part 210 is a cover for preventing the mixer drum from being heated by sunlight or outside air heat, and is formed by cutting the heat insulating sheet 100 so as to be wound around the mixer drum. In addition, about description of the heat insulation sheet 100, since it is the same as Embodiment 1, it abbreviate | omits.

  The eyelet part 220 is a metal ring formed at both ends of the cover part 210, and is used to fix the mixer drum cover 200 to the mixer drum with a rope. As shown in FIG. 12, the mixer drum cover 200 is fixed to the mixer drum by alternately passing a rope through the eyelet portion 220.

  Kneaded concrete is gradually cured by heat. Therefore, once the concrete is mixed in the concrete manufacturing factory, the concrete must be transported to the construction site in a short time. In particular, in midsummer and other high temperatures, the hardening of the concrete is further promoted by the heat of the mixer drum that has become hot due to sunlight and outside air heat, so the concrete can be transported to the construction site in a shorter time. Must-have. However, since the mixer drum cover 200 of the present embodiment can block sunlight and outside air heat by the heat insulating sheet 100, the temperature rise of the mixer drum can be suppressed. Therefore, since the hardening of the concrete is not promoted by the heat of the mixer drum, the concrete can be transported for a longer time (that is, farther) even under high temperature conditions.

The heat insulating property of the heat insulating sheet was verified using the experimental apparatus shown in FIG.
First, a heat insulating sheet (sample A) in which no holes are formed in the aluminum sheet, nine heat insulating sheets (samples B1 to 9) in which the diameter and opening ratio of the holes are changed, and a heat insulating sheet that does not use the aluminum sheet ( Sample C) was prepared. Table 1 shows the aperture ratio and the hole diameter of each sample. The configurations of Samples B1 to B9 are the same as those in Embodiment 1 except for the size of the holes and the aperture ratio. That is, samples B1 to 9 are a surface sheet composed of a woven fabric of polyester fibers, an aluminum sheet composed of aluminum-deposited PET having an aluminum film formed on both sides, and a cotton sheet composed of a nonwoven fabric of polyester fibers, , And a back sheet composed of polypropylene fiber woven fabric. Sample A has the same configuration as samples B1 to 9 except that the aluminum sheet is not perforated, and sample C has a configuration in which the aluminum sheet is removed from samples B1 to 9.

Each of these 11 samples was set in the experimental apparatus 300 shown in FIG.
As shown in FIG. 14, the experimental apparatus 300 includes heat-insulating cylinders 310 and 320 that are open on one side, an incandescent bulb 330 that is installed in the cylinder 310 and serves as a heat source, and a thermometer 341 that measures the temperature of the incandescent bulb 330. And thermometers 342 and 343 for measuring the surface temperatures of the front and back surfaces of the heat insulating sheet. Each sample is set so that the cylinder 310 side is a top sheet and the cylinder 320 side is a back sheet.

  Each sample was sandwiched between the openings of the cylinders 310 and 320, and the incandescent lamp 330 was turned on. And when the heat source temperature (temperature measured by the thermometer 341) reaches 90 ° C., 95 ° C., 100 ° C., 105 ° C., 110 ° C. from the normal temperature (about 25 ° C.), the front and back surfaces of each sample A temperature difference (a temperature difference measured by the thermometer 342 and the thermometer 343) was measured. The measurement results are shown in Table 2. Moreover, the graph of a measurement result when heat-source temperature reaches 110 degreeC is shown in FIG.

In the case of the heat insulating sheets (samples B1 and B2) having an opening ratio of 1% and 3%, it was found that the heat insulating property higher than that of the heat insulating sheet (sample A) having no holes in the aluminum sheet was exhibited. In particular, it was found that a heat insulating sheet (sample B2) having an aperture ratio of 3% exhibits high heat insulating properties. This is because the air contained in the cotton sheet 130 is supplied between the top sheet 110 and the aluminum sheet 120 through the holes, and as a result, the air is slightly retained between the top sheet 110 and the aluminum sheet 120, and the aluminum sheet It is considered that 120 sticks to the top sheet 110 tightly, and as a result, the heat of the top sheet 110 is hardly transmitted to the aluminum sheet 120.
On the other hand, it was found that in the case of the heat insulating sheet (sample B3) having an aperture ratio of 5%, the heat insulating property is lower than that of the heat insulating sheet (sample A) having no holes in the aluminum sheet. This is considered to be because the infrared reflection efficiency of the aluminum sheet is lowered due to the increase in the aperture ratio, and as a result, the heat insulation property of the heat insulation sheet is lowered beyond the increase in heat insulation property due to the retention of air.
Therefore, the preferable range of the opening ratio of the holes in the aluminum sheet is 4% or less, more desirably 2 to 4%.

  Moreover, it turns out that the heat insulation sheet (sample C) with an aperture ratio of 30% or less shows a higher heat insulation property with the heat insulation sheet (samples B1 to B9) with an aperture ratio of 30% or less and a heat insulation sheet without an aluminum sheet (sample C). It was. Therefore, considering the loss of moisture that has entered the cotton sheet, a sufficiently high heat insulating property can be obtained even when the aperture ratio is set to 4% to 30%.

In addition, in the heat insulating sheet (samples B1 to B9) having a hole diameter of 5 mm or less and the heat insulating sheet (sample C) having no aluminum sheet, the heat insulating sheet having a hole diameter of 5 mm or less is higher in heat insulation. It was found that Therefore, even if the size of the hole in the aluminum sheet is 5 mm or less (about 20 mm ² or less in area), sufficiently high heat insulation can be obtained.

In addition, with a heat insulating sheet (samples B1 to B3) having a hole diameter of 1 mm and a heat insulating sheet (samples B4 to B9) having a hole diameter of 3 mm and 5 mm, the heat insulating sheet having a diameter of 1 mm may exhibit higher heat insulating properties. I understood. Therefore, a preferable hole size in the aluminum sheet is 2 mm or less in diameter (about 3.2 mm ² or less in area), more preferably 1 mm (about 0.8 mm ² in area) or less.

DESCRIPTION OF SYMBOLS 100 Thermal insulation sheet 110 Top surface sheet 111 Waterproof film 120 Aluminum sheet 121 Film 122 Aluminum film 130 Cotton sheet 140 Back surface sheet 150 Seam 160 Recess 170 Bubble buffer sheet 171 Protrusion 200 Mixer drum cover 210 Cover part 220 Eyelet part 300 Experimental apparatus 310, 320 Cylinder 330 Incandescent bulb 341-343 Thermometer

Claims (7)

A surface sheet disposed on the surface;
An aluminum sheet provided with an aluminum film;
A cotton-like cotton sheet,
The aluminum sheet is disposed between the top sheet and the cotton sheet, and has a plurality of holes through which air contained in the cotton sheet and water that has entered the cotton sheet pass to the top sheet side. ,
A heat insulating sheet characterized by that. The ratio of the area of the hole to the area of the aluminum sheet is 30% or less,
The heat insulating sheet according to claim 1. The ratio of the area of the hole to the area of the aluminum sheet is 4% or less,
The heat insulation sheet according to claim 1 or 2, wherein The area per one of the holes is 20 mm ² or less,
The heat insulating sheet according to any one of claims 1 to 3, wherein the heat insulating sheet is provided. The area per one of the holes is 3.2 mm ² or less.
The heat insulation sheet according to any one of claims 1 to 4, wherein the heat insulation sheet is provided. A back sheet disposed on the opposite side of the top sheet across the aluminum sheet and the cotton sheet,
The heat insulation sheet according to any one of claims 1 to 5, wherein The heat insulating sheet according to any one of claims 1 to 6, wherein the heat insulating sheet is processed so as to be wound around an outer periphery of a mixer drum of a concrete mixer truck.
A mixer drum cover characterized by that.