HEAT INSULATING MATERIAL, ENGINE COMPRISING HEAT INSULATING MATERIAL, NANOPARTICLE DISPERSION LIQUID, AND PRODUCTION METHOD FOR HEAT INSULATING MATERIAL

Abstract

A heat insulating layer contains many hollow particles, a silicone-based resin binder, and silica nanoparticle. The percentage of the silica nanoparticles in the total amount of the resin binder and the silica nanoparticles is equal to or greater than 10% by volume and equal to or smaller than 55% by volume.

Claims

1. A heat insulating material containing many hollow particles, a silicone-based resin binder, and a nanoparticle, comprising: an inorganic nanoparticle as the nanoparticle, a percentage of the inorganic nanoparticle in a total amount of the resin binder and the inorganic nanoparticle being equal to or greater than 10% by volume and equal to or smaller than 55% by volume.

2. The heat insulating material of claim 1, wherein a surface of the inorganic nanoparticle is subjected to hydrophobization treatment.

3. The heat insulating material of claim 2, wherein the inorganic nanoparticle is a modified silica nanoparticle whose surface is modified with a phenyl group.

4. The heat insulating material of claim 1, wherein a number-average particle size of the hollow particles is equal to or smaller than 30 μm.

5. The heat insulating material of claim 1, wherein each hollow particle is an inorganic hollow particle.

6. An engine comprising: the heat insulating material of claim 1 on a surface forming a combustion chamber, a thickness of the heat insulating material is equal to or greater than 20 μm and equal to or smaller than 150 μm.

7. A nanoparticle dispersion liquid, a nanoparticle being dispersed in a reactive silicone-based resin solution, a percentage of the nanoparticle in a total amount of silicone-based resin and the nanoparticle upon reaction and curing of the resin solution being equal to or greater than 10% by volume and equal to or smaller than 55% by volume, and an HSP distance between the nanoparticle and the resin solution is equal to or smaller than 8.5 MPa.sup.0.5.

8. The nanoparticle dispersion liquid of claim 7, wherein the nanoparticle is a silica nanoparticle.

9. The nanoparticle dispersion liquid of claim 8, wherein a surface of the silica nanoparticle is modified with a phenyl group.

10. The nanoparticle dispersion liquid of claim 8, further comprising: toluene as a solvent of the resin solution.

11. The nanoparticle dispersion liquid of claim 10, wherein a blending amount of the toluene in the resin solution is equal to or greater than 30% by volume and equal to or smaller than 70% by volume.

12. The nanoparticle dispersion liquid of claim 7, further comprising: a hollow particle.

13. The nanoparticle dispersion liquid of claim 12, wherein a number-average particle size of the hollow particle is equal to or smaller than 30 μm.

14. The nanoparticle dispersion liquid of claim 12, wherein the hollow particle is an inorganic hollow particle.

15. A nanoparticle dispersion liquid production method, comprising: a resin solution preparation step of preparing a reactive silicone-based resin solution; and a dispersion step of dispersing a nanoparticle by addition of the nanoparticle to the resin solution, an HSP value of the resin solution being, at the resin solution preparation step, adjusted by addition of a solvent such that an HSP distance between the nanoparticle and the resin solution is equal to or smaller than 8.5 MPa.sup.0.5, a percentage of the nanoparticle in a total amount of silicone-based resin and the nanoparticle upon reaction and curing of the resin solution being, at the dispersion step, being equal to or greater than 10% by volume and equal to or smaller than 55% by volume.

16-24. (canceled)

25. A method for producing a heat insulating layer containing many hollow particles, a silicone-based resin binder, and a nanoparticle, comprising: a resin solution preparation step of preparing a reactive silicone-based resin solution for the binder; and a step of preparing particle dispersion liquid by addition of the hollow particles and the nanoparticle to the resin solution; a step of forming a coating layer from the particle dispersion liquid applied to a base material; and a step of forming the heat insulating layer by burning of the coating layer, an HSP value of the resin solution being, at the resin solution preparation step, adjusted by addition of a solvent such that an HSP distance between the nanoparticle and the resin solution is equal to or smaller than 8.5 MPa.sup.0.5.

26. The heat insulating layer production method of claim 25, wherein a percentage of the nanoparticle in a total amount of the resin binder and the nanoparticle of the heat insulating layer is equal to or greater than 10% by volume and equal to or smaller than 55% by volume.

27. The heat insulating layer production method of claim 25, wherein a silica nanoparticle is contained as the nanoparticle.

28. The heat insulating layer production method of claim 27, wherein a surface of the silica nanoparticle is modified with a phenyl group.

29. The heat insulating layer production method of claim 27, wherein toluene is contained as the solvent.

30-35. (canceled)

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0089] FIG. 1 is a cross-sectional view of an engine as an application example of the present invention.

[0090] FIG. 2 is a cross-sectional view showing a heat insulating layer on a top surface of a piston of the engine.

[0091] FIG. 3 is a partially-enlarged cross-sectional view of the heat insulating layer.

[0092] FIG. 4 is a graph showing a relationship between a toluene blending amount and an HSP distance.

[0093] FIG. 5 is a graph showing the thermodecomposition start temperature (a heat generation peak position in DTA) of each binder with different silica nanoparticle blending amounts.

[0094] FIG. 6 is a graph showing the TG curve of each of binders with silica nanoparticle blending amounts of 40% by volume and 0% by volume.

[0095] FIG. 7 is a graph showing a relationship between the silica nanoparticle blending amount and a binder volume retention.

[0096] FIG. 8 is a graph showing volume retentions for “No Nanoparticles” and “Great Nanoparticle Blending Amount.”

[0097] FIG. 9 is a microscope image of the section of a heat insulating layer according to “Great Nanoparticle Blending Amount.”

[0098] FIG. 10 is a graph showing a relationship between the nanoparticle blending amount and a pencil hardness.

[0099] FIG. 11 is a graph showing a relationship between a nanoparticle size and a heat insulating layer surface hardness.

DETAILED DESCRIPTION

[0100] Hereinafter, an embodiment of the present invention will be described with reference to the drawings. The following description of a preferred embodiment is merely illustrative in nature and is not intended to limit the present invention and applications or uses thereof.

[0101] <Heat Insulating Material and Heat Insulating Layer>

[0102] A heat insulating material can be in a plate shape, a sheet shape, or other suitable shapes in accordance with a heat insulating target. A heat insulating layer is configured such that the heat insulating material is provided in the form of a layer on a surface of a base material as the heat insulating target. Hereinafter, the preferred embodiment will be described, but is not intended to limit the present invention.

[0103] In FIG. 1, 1 indicates an aluminum alloy piston of an engine as the base material on which the heat insulating layer is formed, 2 indicates a cylinder block, 3 indicates a cylinder head, 4 indicates an intake valve that opens/closes an intake port 5 of the cylinder head 3, 6 indicates an exhaust valve that opens/closes an exhaust port 7, and 8 indicates a fuel injection valve. A combustion chamber of the engine is formed by a top surface of the piston 1, the cylinder block 2, the cylinder head 3, and front surfaces (surfaces facing the combustion chamber) of umbrella portions of the intake and exhaust valves 4, 6. Defined above the top surface of the piston 1 is a cavity 9. Note that a spark plug is not shown.

[0104] As shown in FIG. 2, a heat insulating layer 11 is formed on the top surface of the piston 1. As shown in FIG. 3, the heat insulating layer 11 includes many hollow particles 12 made of inorganic oxide or ceramics and a silicone-based resin binder 13 holding the hollow particles 12 on the piston 1 and filling a portion among the hollow particles 12 to form the matrix of the heat insulating layer 11, and nanoparticles 14 are dispersed in the resin binder 13 (in FIG. 3, the nanoparticles 14 are indicated by points).

[0105] The thickness (hereinafter referred to as a “film thickness”) of the heat insulating layer 11 is, for example, equal to or greater than 20 μm and equal to or smaller than 150 μm and preferably equal to or greater than 40 μm and equal to or smaller than 100 μm. As the hollow particle 12, one having a μm-order particle size smaller than the film thickness of the heat insulating layer 11 is used. Preferably, the hollow particle 12 has an average particle size of equal to or smaller than 30 μm, for example. For example, a hollow particle with an average particle size of equal to or smaller than 10 μm can be preferably employed. The average particle size of the nanoparticle 14 is preferably equal to or smaller than 500 nm, more preferably equal to or greater than 1 nm and equal to or smaller than 200 nm, and much more preferably equal to or greater than 1 nm and equal to or smaller than 120 nm.

[0106] Note that the above-described numeric value range is a preferred range in a case where the heat insulating layer 11 is provided on the surface forming the combustion chamber of the engine, and is not limitative. In a case where the heat insulating layer is provided on, e.g., equipment other than the surface forming the combustion chamber, the particle size of the hollow particle 12 and the film thickness of the heat insulating layer 11 can be further decreased or increased.

[0107] Preferably, an inorganic hollow particle is employed as the hollow particle 12, and a ceramic-based hollow particle containing a Si-based oxide component (e.g., silica) or an Al-based oxide component (e.g., alumina) such as a glass balloon, a glass bubble, a fly ash balloon, a shirasu balloon, a silica balloon, or an aluminosilicate balloon is employed. The hollow rate of the hollow particle is preferably equal to or greater than 60% by volume and more preferably equal to or greater than 70% by volume.

[0108] As the resin binder 13, silicone-based resin containing three-dimensional polymer with a high degree of branching and represented by methylsilicone-based resin and methylphenyl silicone-based resin can be preferably used, for example. Specific examples of the silicone-based resin may include polyalkylphenylsiloxane.

[0109] As the nanoparticle 14, an inorganic nanoparticle made of an inorganic compound such as zirconia, alumina, silica, or titania, a metal nanoparticle such as Ti, Zr, or Al, etc. can be employed, and particularly, a silica nanoparticle whose surface is modified with a phenyl group can be preferably employed. The nanoparticle may be hollow or solid.

[0110] The blending amount (the percentage of the nanoparticles 14 in the total amount of the resin binder 13 and the nanoparticles 14 after burning, the same also applies below) of the nanoparticles 14 is preferably equal to or greater than 10% by volume and equal to or smaller than 55% by volume. The blending amount (the percentage of the hollow particles 12 in the heat insulating layer 11 after burning, the same also applies below) of the hollow particles 12 can be adjusted in accordance with, e.g., heat insulating properties required for the heat insulating layer. The blending amount of the hollow particles 12 can be, for example, equal to or greater than 30% by volume and equal to or smaller than 60% by volume. Such a blending amount is more preferably equal to or greater than 40% by volume and equal to or smaller than 55% by volume.

[0111] <Production of Heat Insulating Layer>

[0112] The above-described heat insulating layer can be produced by a method described below. This production method includes a nanoparticle dispersion liquid preparation step, the coating step of coating the base material with nanoparticle dispersion liquid to form a coating layer, and a burning step of burning the coating layer to form the heat insulating layer.

[0113] (Preparation of Nanoparticle Dispersion Liquid)

[0114] This step includes the step of preparing a reactive silicone-based resin solution for the binder and the step of dispersing the nanoparticles in the resin solution.

[0115] Resin Solution Preparation

[0116] At this step, a solvent is added to a raw material resin solution (the reactive silicone-based resin solution) such that an HSP distance between the nanoparticle and the reactive silicone-based resin solution is equal to or smaller than 8.5 MPa.sup.0.5, and in this manner, the HSP value of the resin solution is adjusted. In this manner, the binder reactive silicone-based resin solution to be provided for the next dispersion step is obtained.

[0117] The above-described raw material resin solution may be of a one-component/addition-curing type or a dehydration condensation curing type, and the one-component/addition-curing type can be preferably used. As the solvent, e.g., toluene or xylene can be preferably used as long the HSP value of the reactive silicone-based resin solution can be adjusted such that the above-described HSP distance decreases.

[0118] The blending amount of the solvent varies to some extend depending on the HSP value of each of the raw material resin solution, the nanoparticle, and the solvent, but the above-described HSP distance can be close to equal to or smaller than 8.5 MPa.sup.0.5 as long as the blending amount of the solvent in the reactive silicone-based resin solution is equal to or greater than about 30% by volume and equal to or smaller than about 70% by volume.

[0119] Dispersion of Nanoparticles

[0120] The nanoparticles are added to the reactive silicone-based resin solution whose HSP value has been adjusted by addition of the solvent as described above, and by agitation, the nanoparticle dispersion liquid is prepared. The blending amount of the nanoparticles is set such that the percentage of the nanoparticles in the total amount of the silicone-based resin and the nanoparticles upon reaction and curing of the above-described resin solution is equal to or greater than 10% by volume and equal to or smaller than 55% by volume.

[0121] The nanoparticles may be added to the resin solution and the resultant may be agitated, and by further addition of the hollow particles and agitation, the nanoparticle dispersion liquid containing the hollow particles may be prepared. The blending amount of the hollow particles can be adjusted in accordance with the required heat insulating properties. Such a blending amount can be, for example, equal to or greater than 30% by volume and equal to or smaller than 60% by volume.

[0122] The obtained nanoparticle dispersion liquid can be stored until production of the heat insulating material etc. The HSP distance between the nanoparticle and the reactive silicone-based resin solution decreases to equal to or smaller than 8.5 MPa.sup.0.5 as described above, and therefore, a nanoparticle dispersion state in such a resin solution is maintained even during storage.

[0123] (Coating with Nanoparticle Dispersion Liquid)

[0124] In the case of a nanoparticle dispersion liquid containing no hollow particles described above, the coating layer is formed in such a manner that the base material is coated with a mixture of the nanoparticle dispersion liquid and the hollow particles, and in the case of a nanoparticle dispersion liquid to which the above-described hollow particles have been added in advance, the coating layer is formed in such a manner that the base material is directly coated with such dispersion liquid. Such coating can be performed using a spray. Coating may be performed using a brush or a spatula. Upon such coating, the viscosity of the nanoparticle dispersion liquid can be adjusted to a viscosity suitable for coating by addition of the solvent.

[0125] (Burning of Coating Layer)

[0126] The coating layer on the base material is dried and burnt, and in this manner, the heat insulating layer is formed. That is, by such burning, the reactive silicone-based resin is cured, and the heat insulating layer containing the hollow particles and the nanoparticles is obtained. Burning can be performed in such a manner that the coating layer is heated at a temperature of about 100° C. to about 200° C. for several minutes to several hours.

[0127] <Case of Production of Heat Insulating Material>

[0128] In the case of the nanoparticle dispersion liquid containing no hollow particles described above, an item in an intended heat insulating material shape is molded using the mixture of the nanoparticle dispersion liquid and the hollow particles, and the heat insulating material is obtained in such a manner that the obtained item is dried and burnt.

[0129] In the case of the nanoparticle dispersion liquid containing the above-described hollow particles, an item in an intended heat insulating material shape is molded using such nanoparticle dispersion liquid, and the heat insulating material is obtained in such a manner that the obtained item is dried and burnt.

[0130] <Specific Example of Resin Solution Preparation>

[0131] Next, the resin solution preparation step will be described based on a specific example where toluene is used as the solvent. The HSP values of the used raw material resin solution, the silica nanoparticles as the nanoparticles whose surfaces have been modified with the phenyl group, and toluene are as in Table 1. In the HSP section of Table 1, δD is an energy term derived from dispersion force between molecules, δP is an energy term derived from polar force between molecules, δH is an energy term derived from hydrogen bonding force between molecules, and the unit thereof is MP.sup.0.5. RO is an interaction radius (in units of MPa.sup.0.5).

TABLE-US-00001 TABLE 1 Interaction HSP δD δP δH Radius Nanoparticles 19.0 8.4 11.3 7.0 Raw Material 24.8 10.2 10.8 18.3 Resin Solution Toluene 18.0 1.4 2.0

[0132] Supposing that the HSP value of the raw material resin solution is δD1, δP1, and δH1, the HSP value of the silica nanoparticle is δD2, δP2, and δH2, and the HSP distance (in units of MPa.sup.0.5) between the raw material resin solution and the nanoparticle is Ra, (Ra).sup.2=4×(δD.sub.2−δD.sub.1).sup.2+(δP.sub.2−δP.sub.1).sup.2+(δH.sub.2−δH.sub.1).sup.2 is satisfied. According to Table 1, the HSP distance (Ra) between the raw material resin solution and the silica nanoparticle is 11.8 MPa.sup.0.5.

[0133] The HSP value (δD, δP, δH) of the reactive silicone-based resin solution obtained by addition of toluene to the raw material resin solution can be obtained as the arithmetic average of the HSP values of the raw material resin solution and toluene from the volume ratio thereof. The HSP value (δD, δP, δH) of the reactive silicone-based resin solution and the HSP distance between such a resin solution and toluene for various toluene blending amounts (% by volume) are as in Table 2. FIG. 4 shows, by a graph, a relationship between the toluene blending amount and the HSP distance.

TABLE-US-00002 TABLE 2 HSP HSP δD δP δH Distance Ra   0 vol % 24.8 10.2 10.8 11.8  10 vol % 24.1 9.4 10.0 10.4  20 vol % 23.5 8.5 9.1 9.2  30 vol % 22.8 7.6 8.2 8.2  40 vol % 22.1 6.7 7.3 7.6  50 vol % 21.4 5.8 6.4 7.3  60 vol % 20.7 4.9 5.5 7.6  70 vol % 20.0 4.1 4.7 8.2  80 vol % 19.4 3.2 3.8 9.2  90 vol % 18.7 2.3 2.9 10.4 100 vol % 18.0 1.4 2.0 11.8

[0134] According to Table 2 and FIG. 4, it shows that as long as the toluene blending amount is equal to or greater than about 30% by volume and equal to or smaller than about 70% by volume in this case, the HSP distance between the reactive silicone-based resin solution and the silica nanoparticle is equal to or smaller than 8.5 MPa.sup.0.5 and favorable dispersibility of the silica nanoparticles in the above-described resin solution is exhibited accordingly.

[0135] <Advantages of Great Nanoparticle Blending Amount>

[0136] (Heat Resistance; TG-DTA)

[0137] For a plurality of nanoparticle-containing binders (with no hollow particles) obtained in such a manner that the silica nanoparticles are dispersed in different blending amounts in the silicone-based resin, heat resistance was evaluated by thermogravimeter-differential thermal analysis (TG-DTA). The silicone-based resin is of the addition-curing type. The silica nanoparticle is of a phenyl group modified type with an average particle size of 100 nm.

[0138] FIG. 5 shows the thermodecomposition start temperature (a heat generation peak position in the DTA) of each nanoparticle-containing binder (after burning). According to this figure, the thermodecomposition start temperature increases as the blending amount of the silica nanoparticles increases. It shows that when the blending amount of the silica nanoparticles reaches equal to or greater than 10% by volume, the thermodecomposition start temperature increases as compared to the binder with a zero silica nanoparticle blending amount. When such a blending amount reaches equal to or greater than 20% by volume, the thermodecomposition start temperature increases as compared to the binder with the zero silica nanoparticle blending amount by about 50° C.

[0139] FIG. 6 shows the TG curves of the binder with the zero silica nanoparticle blending amount and the binder with a silica nanoparticle blending amount of 40% by volume. At a silica nanoparticle blending amount of 40% by volume, a weight retention is 94.8% at a temperature of 500° C. and 92.7% even at 1000° C.

[0140] As described above, it shows that a great silica nanoparticle blending amount is effective for improving the heat resistance of the heat insulating material.

[0141] (Heat Resistance; Volume Retention)

[0142] For each of nanoparticle-containing binders (with no hollow particles) with phenyl-group modified type silica nanoparticle blending amounts of 1% by volume, 4% by volume, 10% by volume, and 40% by volume, the heat insulating layer was formed on the blasted surface of the aluminum alloy base material by the above-described production method. Such a heat insulating layer was detached from the base material, and the volume retention when a thermal load for holding a temperature of 430° C. for six hours is provided was measured. A temperature of 430° C. is a temperature at which an organic component in the binder is decomposed.

[0143] The results are shown in FIG. 7. For the binder with a silica nanoparticle blending amount of 40% by volume, a volume shrinkage amount is about the half of that of the binder with 1% by volume.

[0144] For “No Nanoparticles” and “Great Nanoparticle Blending Amount” shown in Table 3, the heat insulating layer was produced by a method similar to that of the above-described nanoparticle-containing binder and was detached from the base material, and thereafter, each volume retention was measured by a similar method. The hollow particle is an aluminosilicate fine balloon with an average particle size of 5 μm, the resin binder is addition-curing type silicone resin, and the nanoparticle is a phenyl group modified type silica nanoparticle with an average particle size of 100 nm. The numeric values in the table show the blending amounts after burning. For “Great Nanoparticle Blending Amount,” the blending amount of the silica nanoparticles, i.e., the percentage of the silica nanoparticles in the total amount of the resin binder and the silica nanoparticles after burning, is 40% by volume.

TABLE-US-00003 TABLE 3 Hollow Particles Binder Nanoparticles No Nanoparticles 50 vol % 50 vol %  0 vol % Great Nanoparticle 50 vol % 30 vol % 20 vol % Blending Amount

[0145] The volume retention measurement results are shown in FIG. 8. “Great Nanoparticle Blending Amount” shows a higher volume retention than that for “No Nanoparticles” by 10% or more.

[0146] As described above, it shows that a great silica nanoparticle blending amount is effective for improving the heat resistance of the heat insulating material.

[0147] FIG. 9 shows a scanning electron microscope (SEM) image of the section of the heat insulating layer according to “Great Nanoparticle Blending Amount.” According to such an image, no hollow particle damage and no void are shown.

[0148] (Heat Resistance; Relationship between Nanoparticle Blending Amount and Heat Insulating Layer Surface Hardness)

[0149] For “No Nanoparticles” and “Great Nanoparticle Blending Amount” of Table 3, the surface of the heat insulating layer (a thickness of 50 μm), which is obtained by the above-described production method, on the base material was polished. For each heat insulating layer, heating treatment was performed, in which the temperature of the heat insulating layer is increased to 500° C. from a room temperature over one hour and the heat insulating layer is cooled to the room temperature after having been held at 500° C. for six hours. The pencil hardness (the scratch hardness) of the heat insulating layer before and after such heating treatment was checked. The results are shown in Table 4.

TABLE-US-00004 TABLE 4 Great Nanoparticle No Nanoparticles Blending Amount Before Heating Pencil Hardness 5B to 6B Pencil Hardness HB Treatment After Heating Pencil Hardness 2H Pencil Hardness 8H Treatment

[0150] According to Table 4, “Great Nanoparticle Blending Amount” shows a significantly-higher pencil hardness before and after heating than that for “No Nanoparticles.”

[0151] As in Table 3, the pencil hardness (the scratch hardness) of the heat insulating layer before and after the above-described heating treatment was also checked for each case where the blending amount of the hollow particles is fixed to 50% by volume and the blending amount of the phenyl-group modified type silica nanoparticles with an average particle size of 100 nm is 10% by volume, 20% by volume, 30% by volume, 50% by volume, and 60% by volume. The results are shown as a graph in FIG. 10 in combination with the cases of nanoparticle blending amounts of 0% by volume and 40% by volume. For the case of employing an alumina nanoparticle with an average particle size of 100 nm as the nanoparticle and the case of employing a zirconia nanoparticle with an average particle size of 100 nm as the silica nanoparticle, a relationship between the nanoparticle blending amount and the scratch hardness of the heat insulating layer after the above-described heating treatment was also checked. The results are shown in FIG. 10 in combination with the case of the silica nanoparticles. As in the silica nanoparticle, a nanoparticle whose surface is modified with a phenyl group by hydrophobization treatment was used as any of the alumina nanoparticle and the zirconia nanoparticle.

[0152] According to FIG. 10, any of silica, alumina, and zirconia shows an increasing pencil hardness as the nanoparticle blending amount increases, and shows a peak pencil hardness at a nanoparticle blending amount of 50% by volume. As in the case of the silica nanoparticle, the cases of the alumina nanoparticle and the zirconia nanoparticle also show a high scratch hardness after heating to 500° C. Note that the case of 60% by volume is that a film formation failure has occurred in association with an increase in the viscosity of the particle dispersion liquid.

[0153] As described above, it shows that a great silica nanoparticle blending amount is effective for improving the hardness and heat resistance of the heat insulating material.

[0154] (Heat Resistance; Relationship between Nanoparticle Size and Heat Insulating Layer Surface Hardness)

[0155] Phenyl group modified type silica nanoparticles with different average particle sizes were prepared, the heat insulating layer was formed on the surface of the base material by the above-described production method by means of each type of nanoparticle, and the pencil hardness (the scratch hardness) of the heat insulating layer before and after the above-described heating treatment was checked. As in the case of Table 3, the hollow particle is an aluminosilicate fine balloon with an average particle size of 5 μm and the resin binder is addition-curing type silicone resin. The hollow particle blending amount is 50% by volume, the resin binder blending amount is 30% by volume, and the nanoparticle blending amount is 20% by volume. That is, the percentage of the silica nanoparticles in the total amount of the resin binder and the silica nanoparticles after burning is 40% by volume.

[0156] The results are shown in FIG. 11. According to this figure, when the silica nanoparticle average particle size is equal to or smaller than 500 nm, the scratch hardness after heating to 500° C. is about 8H regardless of the average particle size, and almost no influence of the average particle size is observed. The scratch hardness before heating is also about HB, and almost no influence of the average particle size is observed. On the other hand, when the average particle size is 1000 nm, voids are observed in the heat insulating layer, and the scratch hardness after heating to 500° C. is greatly degraded. Thus, the nanoparticle preferably has an average particle size of equal to or smaller than 500 nm, for example.

[0157] Note that the heat insulating layer according to the present invention is applied to the top surface of the piston 1 in the above-described embodiment, but the present invention is not limited to this configuration and the heat insulating layer may be formed on other surfaces forming the combustion chamber of the engine, such as the lower surface of the cylinder head 3. Further, the present invention is not limited to the engine, and is also applicable to other types of industrial equipment and consumer equipment for which heat insulation is required.

LIST OF REFERENCE CHARACTERS

[0158] 1 Piston (Base Material) [0159] 11 Heat Insulating Layer [0160] 12 Hollow Particle [0161] 13 Resin Binder [0162] 14 Nanoparticle