JP5456986B2 - Insulation - Google Patents

Description

  The present invention relates to a heat insulator, and more particularly to improvement of heat insulation of the heat insulator and prevention of dust generation.

Conventionally, for example, Patent Document 1 describes a mantle heater having a heat insulating member made of glass fiber mat, a bag-like cover member made of glass cloth that accommodates the heat insulating member, and a heating wire for heating. Yes. The glass cloth is preferably used as a bag-like cover member because it has excellent heat resistance that can withstand contact with a heating wire and its own dust generation property is low.
Japanese Patent No. 3177453

  However, since the glass cloth has a poor function of preventing the generation of dust from the heat insulating member covered by the glass cloth, it is impossible to use a heat insulating member having a dust generating property in the above prior art. Therefore, in the said prior art, there existed a limit in improving the heat insulation of a heat insulation member.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a heat insulator having improved heat insulation while effectively preventing dust generation.

  A heat insulator according to an embodiment of the present invention for solving the above problems includes a heat insulating layer, an outer bag made of a woven fabric of inorganic fibers that accommodates the heat insulating layer, and the heat insulating layer in the outer bag. And a dust-preventing layer made of an inorganic fiber non-woven fabric to be coated. ADVANTAGE OF THE INVENTION According to this invention, the heat insulating body which heat insulation improved while dust generation was prevented effectively can be provided.

  Moreover, it is good also as having the heat generating body for a heating arrange | positioned between the said dust prevention layer and the said exterior bag. In this way, it is possible to provide a heat insulator that can be used as a heater, in which heat generation is improved while dust generation is effectively prevented. Moreover, the said heat insulation layer is good also as consisting of a fiber body with which the airgel was filled. If it carries out like this, the heat insulation of a heat insulating body can be improved effectively.

  Below, the heat insulating body which concerns on one Embodiment of this invention is demonstrated. Note that the present invention is not limited to this embodiment.

  FIG. 1 is a perspective view showing an example of a member constituting one side of a heat insulator according to the present embodiment (hereinafter referred to as “the main heat insulator 1”). FIG. 2 is a plan view of an example of the heat insulator 1. FIG. 3 is a cross-sectional view of the heat insulator 1 taken along the line III-III shown in FIG.

  As shown in FIGS. 1 to 3, the heat insulator 1 includes a heat insulating layer 10 and an outer bag 20 that houses the heat insulating layer 10. As the heat insulating layer 10, an appropriate heat insulating material can be used according to the characteristics that the heat insulating body 1 should have, such as heat insulating properties, heat resistance, low dust generation properties, and flexibility.

  That is, for example, a heat insulating material having high heat insulating properties can be preferably used as compared with a heat insulating material made of inorganic fibers such as a glass fiber mat that has been conventionally used. Specifically, as the heat insulating layer 10, for example, a fiber body (aerogel fiber body) filled with airgel can be used.

  This airgel fiber body is a heat insulating material in which a fiber base material is filled with airgel. As the fiber base material constituting the airgel fiber body, for example, a fiber base material made of resin fibers such as polyethylene terephthalate (PET) fibers, carbon fibers, ceramic fibers such as silica fibers or alumina fibers can be used, and heat resistance The fiber base material which consists of an inorganic fiber excellent in can be used preferably.

  That is, as the fiber base material, an inorganic fiber woven fabric or non-woven fabric can be preferably used. By using a nonwoven fabric in which inorganic fibers are randomly oriented as the fiber substrate, the airgel can be effectively held between the inorganic fibers of the fiber substrate.

  Moreover, as inorganic fiber which comprises a fiber base material, ceramic fibers, such as an alumina fiber, can be used preferably, for example.

  As the airgel, for example, an airgel made of an inorganic material (inorganic airgel) or an airgel made of an organic material (organic airgel) can be used, and an inorganic airgel excellent in heat resistance can be preferably used. As the inorganic airgel, for example, silica airgel or alumina airgel can be used. In particular, by using silica airgel, the heat insulation property of the airgel fiber body can be effectively enhanced.

  Therefore, as an airgel fiber body, what filled the inorganic airgel in the nonwoven fabric of the inorganic fiber can be used preferably. Specifically, for example, an airgel fiber body in which silica airgel is filled in a nonwoven fabric of ceramic fibers can be preferably used.

  The ratio of the airgel and the fiber base contained in the airgel fiber body should be set as appropriate according to the characteristics (for example, heat insulation, heat resistance, low dust generation, flexibility) that the airgel fiber body should have. Can do.

The density of an airgel fiber body can be made into the range of 20-500 kg / m < ³ >, for example, Preferably it can be set as the range of 100-300 kg / m < ³ >.

  Such an airgel fiber body has excellent heat insulating properties because air convection in the airgel fiber body is effectively prevented by the micropores in the airgel filling the voids between the fibers.

  Specifically, the thermal conductivity of the airgel fiber body at 25 ° C. can be, for example, 0.024 W / m · K or less, preferably 0.020 W / m · K or less, and more preferably. May be 0.018 W / m · K or less.

  The thermal conductivity of the airgel fiber body at 80 ° C. can be, for example, 0.035 W / m · K or less, preferably 0.027 W / m · K or less, more preferably 0. 0.025 W / m · K or less.

  Thus, since an airgel fiber body has the outstanding heat insulation, it can reduce in thickness, maintaining sufficient heat insulation. Specifically, the thickness of the airgel fiber body can be, for example, in the range of 1 to 100 mm, preferably in the range of 1 to 50 mm, and more preferably in the range of 1 to 20 mm. And even more preferably in the range of 1-10 mm. By reducing the thickness of the heat insulating layer 10, the flexibility of the heat insulating layer 10 can be improved.

  Moreover, as the heat insulation layer 10, the compression molding body of a nanoparticle can also be used, for example. This compression-molded body is a heat-insulating structure that can be produced by compression-molding nanoparticles.

As a nanoparticle which comprises a compression molding body, the thing whose average diameter of the primary particle is the range of 1-100 nm can be used, for example. The average diameter of the primary particles of the nanoparticles can be preferably in the range of 1 to 50 nm, more preferably in the range of 1 to 25 nm, still more preferably in the range of 1 to 15 nm. Particularly preferably, it can be in the range of 1 to 10 nm. In addition, this average diameter is expressed by the formula “D = 6 / () when the true density (g / m ³ ) of the nanoparticles is“ a ”and the specific surface area (m ² / g) of the nanoparticles is“ S ”. a × S) ”is a converted particle diameter D (m). For example, since the true density of silica is 2.2 × 10 ⁶ m ² / g, the average diameter (converted particle diameter) of silica nanoparticles having a specific surface area of 300 m ² / g is calculated to be about 9 nm.

  Moreover, as a nanoparticle, the nanoparticle (inorganic nanoparticle) which consists of an inorganic material excellent in heat resistance can be used preferably. As the inorganic nanoparticles, for example, nanoparticles made of a metal oxide such as silica, alumina, titanium oxide or the like can be preferably used.

  Especially, the heat insulation of a compression molding body can be effectively improved by using the nanoparticle (silica nanoparticle) which consists of silica. As silica nanoparticles, dry silica (so-called fumed silica) produced by a gas phase method or wet silica produced by a liquid phase method can be preferably used.

  The compression molded body can further contain a fiber material in addition to the nanoparticles. By including a fiber material, the compression-molded body can have excellent flexibility without being accompanied by a decrease in heat insulation due to formation of cracks or the like even during deformation such as bending.

  As this fiber material, a fiber (inorganic fiber) made of an inorganic material having excellent heat resistance can be preferably used. As the inorganic fiber, for example, glass fiber or ceramic fiber such as alumina fiber can be used.

  The exterior bag 20 in which the heat insulation layer 10 is accommodated is a bag-like body made of a woven fabric of inorganic fibers. As inorganic fiber which comprises the exterior bag 20, ceramic fibers, such as glass fiber, a silica fiber, an alumina fiber, a silica alumina fiber, can be used preferably, for example. In addition, as the woven fabric of inorganic fibers, those having a fluororesin coating can be preferably used.

  Since the exterior bag 20 is composed of inorganic fibers, it has excellent heat resistance, and since it is composed of woven fabric, its own dust generation property is low.

  One of the characteristic features of the present invention is that, as shown in FIGS. 1 to 3, the heat insulator 1 having the heat insulating layer 10 and the outer bag 20 as described above is included in the outer bag 20. It is the point which further has the dust generation prevention layer 30 which coat | covers the heat insulation layer 10. FIG.

  The dust generation preventing layer 30 is made of an inorganic fiber nonwoven fabric. And the dust generation prevention layer 30 is arrange | positioned in the exterior bag 20 so that the whole surface of the heat insulation layer 10 may be covered. That is, the dust generation preventing layer 30 is a bag-like body that houses the heat insulating layer 10 and is housed in the exterior bag 20.

  As the inorganic fibers constituting the dust generation preventing layer 30, for example, glass fibers, ceramic fibers such as silica fibers, alumina fibers, and silica alumina fibers can be preferably used.

  Such a dust generation preventing layer 30 can effectively prevent dust generation from the heat insulator 1. That is, since the nonwoven fabric constituting the dust generation preventing layer 30 is configured by three-dimensionally intertwining randomly oriented inorganic fibers, it effectively captures dust generated from the heat insulating layer 10 in the outer bag 20. can do.

  Further, when the dust generation preventing layer 30 is disposed in direct contact with the surface of the heat insulating layer 10, dust is generated from the outer surface of the heat insulating layer 10 in contact with the dust generation preventing layer 30. Can be effectively prevented.

  Therefore, in the heat insulating body 1, it is possible to effectively prevent the dust generated from the heat insulating layer 10 from leaking out of the dust preventing layer 30 by housing the heat insulating layer 10 in the dust preventing layer 30. Can be prevented.

  As shown in FIGS. 1 to 3, the heat insulator 1 includes a heat insulating layer 10, two inorganic fiber nonwoven fabrics 31 and 32 that constitute the dust generation preventing layer 30, and two inorganic fibers that constitute the outer bag 20. It can manufacture from the woven fabrics 21 and 21.

  That is, first, one heat insulating layer 10 formed into a sheet shape is sandwiched between one nonwoven fabric 31 and the other nonwoven fabric 32. And the outer peripheral part 31a of the one nonwoven fabric 31 and the outer peripheral part 32a of the other nonwoven fabric 32 which overlap each other are stitched with inorganic fiber yarn (for example, glass fiber yarn) to cover the heat insulating layer 10 The dust generation prevention layer 30 is formed.

  Next, the dust generation preventing layer 30 containing the heat insulating layer 10 is sandwiched between one woven fabric 21 and the other woven fabric 22. Then, the outer peripheral portion 21a of one woven fabric 21 and the outer peripheral portion 22a of the other woven fabric 22, which are overlapped with each other, are stitched with an inorganic fiber yarn (for example, glass fiber yarn), and the dust generation prevention layer 30 is formed. The outer bag 20 to be covered is formed.

  Thus, the heat insulator 1 can have the heat insulating layer 10 having excellent heat insulating properties such as an airgel fiber body while having the outer bag 20 made of a woven fabric of inorganic fibers, and the dust generation preventing layer 30. It is possible to effectively prevent the dust generation derived from the heat insulating layer 10. Therefore, this heat insulation body 1 can be preferably used as a heat insulating material constructed in a semiconductor, liquid crystal, or electronic component manufacturing apparatus, for example.

  FIG. 4 shows an example of the heat insulation structure 2 constructed so that the heat insulator 1 covers the outer periphery of the pipe 100 to be insulated. The pipe 100 is a pipe for transporting a heated fluid connected to a manufacturing apparatus such as a semiconductor. Since this heat insulator 1 can have excellent heat insulation, heat resistance, low dust generation and flexibility, for example, even in a thin pipe 100 having an outer diameter in the range of 6 to 25 mm. It can arrange | position appropriately along the outer periphery of.

  In FIG. 5, about the other side surface of this heat insulator 1, the cross section similar to FIG. 3 is shown. As shown in FIG. 5, the heat insulator 1 further includes a heating element 40 for heating disposed between the dust generation prevention layer 30 and the outer bag 20. In this example, the heating element 40 is a heating wire that generates heat when energized.

  The heating element 40 is attached to a support layer 50 made of a woven fabric of inorganic fibers, which is disposed between the dust generation prevention layer 30 and the outer bag 20. As inorganic fiber which comprises this support layer 50, ceramic fibers, such as glass fiber, a silica fiber, an alumina fiber, a silica alumina fiber, can be used preferably, for example.

  And the heat generating body 40 which consists of a heating wire is sewn on the support layer 50 by inorganic fiber yarns, such as a glass fiber yarn. Further, the support layer 50 may be sewn to the exterior bag 20 with inorganic fiber yarns such as glass fiber yarns.

  The heating element 40 of the heat insulator 1 can heat the object through the outer bag 20. That is, as shown in FIG. 4, when covering the outer periphery of the pipe with the heat insulator 1, the heat insulator 1 is arranged so that the heating element 40 is arranged along the outer periphery of the pipe via the outer bag 20. Install. Specifically, in this case, the outer surface of the pipe, the outer bag 20 of the main heat insulating body 1, the heating element 40, the dust generation preventing layer 30, and the heat insulating layer 10 are sequentially laminated toward the radially outer side of the pipe. It becomes.

  In FIG. 6, about the other side surface of this heat insulation body 1, the cross section similar to FIG. 3 is shown. As shown in FIG. 6, the heat insulator 1 has a heating element 40 disposed between the dust generation prevention layer 30 and the outer bag 20.

  The support layer 50 to which the heating element 40 is sewn is formed as a bag-like body that houses the dust generation prevention layer 30. In other words, in the present heat insulating body 1, the dust generation preventing layer 30 that accommodates the heat insulating layer 10 is doubly covered with the support layer 50 made of a woven fabric of inorganic fibers and the exterior bag 20.

  Next, specific examples of the heat insulator 1 will be described.

[Example]
In the examples, the dust generation property of the heat insulator 1 was evaluated.

  As the heat insulating layer 10, an airgel fiber body (Pyrogel 6650, Aspen Aerogels Inc.) formed by filling a fiber base material, which is a nonwoven fabric of silica fibers, with silica airgel was used. As the exterior bag 20, a bag-like body formed of a glass cloth (glass fiber woven fabric) having a thickness of 0.5 mm was used. As the dust generation preventing layer 30, a bag-like body formed from a glass fiber mat (glass fiber nonwoven fabric) having a thickness of 5 mm was used.

  And as this heat insulation body 1, the heat insulation layer 10 in which the heat insulation layer 10 was accommodated in the dust prevention layer 30, and the said dust generation prevention layer 30 was accommodated in the exterior bag 20 was manufactured. In addition, a heat insulator (heat insulator X) having the same structure as that of the heat insulator 1 (that is, a structure in which the heat insulating layer 10 is directly covered with the outer bag 20) except that the dust generation preventing layer 30 is not provided was also manufactured.

  The dust generation properties of these two types of heat insulators A and X were evaluated. In the evaluation of dust generation, first, a vibrating device (BALL VIBRATORS, Exen Corporation) equipped with a sample table that can be vibrated in a clean chamber with a predetermined volume and a particle counter (KC-22B, Ontec Corporation). ) And were installed.

  Then, one of the two types of heat insulators A and X was placed on the sample stage of the vibration device, and then the vibration of the sample stage was started. Next, after the sample stage was vibrated for 1 minute, the vibration was stopped, and the number of fine particles generated in the chamber was measured by a particle counter for 1 minute. As a comparative example, the number of fine particles was similarly measured without placing anything on the sample stage.

FIG. 7 shows the evaluation results of dust generation. In FIG. 7, the horizontal axis indicates the size (diameter) of the measured fine particles, and the vertical axis indicates the number of particles of each size (number / 300 cm ³ ) measured in 300 cm ³ air in the chamber. . In FIG. 7, a white bar graph shows the result of the comparative example, a black bar graph shows the result of the heat insulator X, and a hatched bar graph shows the result of the heat insulator A.

  As shown in FIG. 7, for the thermal insulator X that does not have the dust generation prevention layer 30, significantly more fine particles were detected than in the comparative example, and fine particles having a size not detected in the comparative example were also detected.

  On the other hand, the number of fine particles detected for the thermal insulation A having the dust generation preventing layer 30 was almost the same as that of the comparative example. That is, it was confirmed that the heat insulator A has the dust prevention layer 30 to prevent dust generation.

It is a perspective view which shows an example of the member which comprises this about one side surface of the heat insulating body which concerns on one Embodiment of this invention. It is a top view about an example of a heat insulator concerning one embodiment of the present invention. It is sectional drawing of the heat insulating body cut | disconnected by the III-III line | wire shown in FIG. It is a perspective view about an example of the heat insulation structure concerning one embodiment of the present invention. It is sectional drawing about the other side surface of the heat insulating body which concerns on one Embodiment of this invention. It is sectional drawing about the other side surface of the heat insulating body which concerns on one Embodiment of this invention. It is explanatory drawing which shows an example of the result of having evaluated the dust generation property of the heat insulating body which concerns on one Embodiment of this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Heat insulation body, 2 Heat insulation structure, 10 Heat insulation layer, 20 Exterior bag, 21,22 Woven fabric of inorganic fiber, 30 Dust prevention layer, 31, 32 Nonwoven fabric of inorganic fiber, 40 Heat generating body, 50 Support layer.

Claims (2)

A heat insulating layer made of a fibrous body filled with airgel;
An exterior bag made of a woven fabric of glass fiber or ceramic fiber , containing the heat insulating layer;
A dust-preventing layer that is a bag-like body made of a nonwoven fabric of inorganic fibers that covers the entire surface of the heat insulating layer in the exterior bag;
A heat insulator characterized by comprising: The heat insulator according to claim 1, further comprising a heating element that is disposed between the dust-preventing layer and the exterior bag.

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