JP2010260760A - Titanium oxide and method for producing the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a titanium oxide material exhibiting photocatalytic activity by absorbing visible light, and a method for producing the same. <P>SOLUTION: The present titanium oxide material has a chemical composition of Ti<SB>2</SB>O<SB>3</SB>, an infrared absorption peak in the range of 900-925 cm<SP>-1</SP>of infrared absorption spectrum, and whose reflectance of light at 550 nm wavelength is ≤80%; that of light at 500 nm wavelength is ≤60%; that of light at 450 nm wavelength is ≤40%; and that of light at 400 nm is ≤30%, respectively. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a titanium oxide that can be suitably used as a photocatalyst and a method for producing the same.

  Titanium oxide has recently been in high demand as a photocatalyst and is produced by various production methods (for example, Japanese Patent Laid-Open No. 06-293519 (Patent Document 1), Japanese Patent Laid-Open No. 08-081233 (Patent Document 2). )).

  However, the titanium oxide disclosed in the above Japanese Patent Application Laid-Open No. 06-293519 (Patent Document 1) or Japanese Patent Application Laid-Open No. 08-08223 (Patent Document 2) is mainly composed of ultraviolet light (wavelength of wavelength smaller than 400 nm). ) Is absorbed, visible light (wavelength is 400 nm or more and 700 nm or less) is absorbed very little, and the photocatalytic activity is low under sunlight with a lot of visible light.

  Therefore, development of a titanium oxide that absorbs visible light and exhibits photocatalytic activity has been desired.

Japanese Patent Laid-Open No. 06-293519 Japanese Patent Application Laid-Open No. 08-081223

  An object of this invention is to provide the titanium oxide which absorbs visible light, and shows photocatalytic activity, and its manufacturing method.

The present invention, Ti ₂ has a chemical composition of O _3, having an infrared absorption peak in the range 900 cm ^-1 or more 925 cm ^-1 The following infrared absorption spectra, reflectance of light having a wavelength of 550nm is 80% or less, The titanium oxide has a reflectance of light having a wavelength of 500 nm of 60% or less, a reflectance of light having a wavelength of 450 nm of 40% or less, and a reflectance of light having a wavelength of 400 nm of 30% or less. Here, the titanium oxide according to the present invention may have an anatase type or rutile type crystal structure.

  The present invention also includes a step of adding an alkoxy group-containing liquid and a first hydrogen peroxide-containing aqueous liquid to titanium alkoxide to form titanium hydroxide, and a step of separating the titanium hydroxide from the mother liquor in a water-containing state. And a titanium compound-containing gel containing at least one of a titanium oxide and a hydroxide by causing the second hydrogen peroxide-containing aqueous liquid to undergo a self-thermal reaction with the separated water-containing titanium hydroxide. And a step of drying the titanium compound-containing gel to obtain a first titanium oxide.

  The present invention also includes a step of adding an alkoxy group-containing liquid and a first hydrogen peroxide-containing aqueous liquid to titanium alkoxide to form titanium hydroxide, and a step of separating the titanium hydroxide from the mother liquor in a water-containing state. And a titanium compound-containing gel containing at least one of a titanium oxide and a hydroxide by causing the second hydrogen peroxide-containing aqueous liquid to undergo a self-thermal reaction with the separated water-containing titanium hydroxide. And a titanium compound-containing liquid containing at least one of a titanium oxide and a hydroxide by causing the third hydrogen peroxide-containing aqueous liquid to self-react with the titanium compound-containing gel one or more times. And a step of drying the titanium compound-containing liquid to obtain a second titanium oxide.

  In the present invention, the “liquid” in the alkoxy group-containing liquid, the hydrogen peroxide-containing aqueous liquid, and the titanium compound-containing liquid includes not only a solution but also a suspension.

  ADVANTAGE OF THE INVENTION According to this invention, the titanium oxide which absorbs visible light and shows photocatalytic activity, and its manufacturing method can be provided.

It is a figure which shows IR spectrum of the 1st titanium oxide concerning this invention. It is a figure which shows the X-ray-diffraction peak of the 1st titanium oxide concerning this invention. It is a figure which shows the reflectance of the light with a wavelength of 400 nm-700 nm in the 1st titanium oxide concerning this invention. It is a figure which shows IR spectrum of the 2nd titanium oxide concerning this invention. It is a figure which shows the X-ray-diffraction peak of the 2nd titanium oxide concerning this invention. It is a flowchart which shows the manufacturing method of the titanium oxide concerning this invention.

(Embodiment 1)
An embodiment of such a titanium oxide to the present invention has a chemical composition of Ti ₂ O _3, having an infrared absorption peak in the range 900 cm ^-1 or more 925 cm ^-1 The following infrared absorption spectra, the wavelength of 550nm The reflectance of light is 80% or less, the reflectance of light having a wavelength of 500 nm is 60% or less, the reflectance of light having a wavelength of 450 nm is 40% or less, and the reflectance of light having a wavelength of 400 nm is 30% or less. The titanium oxide of the present embodiment can exhibit photocatalytic activity by absorbing at least light having a wavelength in the range of 400 nm to 550 nm among visible light. Details will be described below.

The titanium oxide of this embodiment has a chemical composition of Ti ₂ O ₃ . Here, the chemical composition ratio of titanium oxide, particularly the oxygen composition ratio, can be measured using an oxygen-nitrogen simultaneous analyzer or the like. Moreover, as will be described later, the titanium oxide of the present embodiment is red. At present, the following are known as typical titanium oxides. Titanium (II) oxide (TiO) is a black equiaxed crystal and is obtained by reducing TiO ₂ with carbon or hydrogen at about 2000 ° C. Titanium (III) oxide (Ti ₂ O ₃ ) is a black-purple rhombohedral or hexagonal crystal, has a corundum structure, and TiO ₂ is mixed at 1000 ° C. under a mixed gas stream of hydrogen and TiCl _4. Or by carbon reduction at 700 ° C. Titanium (IV) oxide (TiO ₂ ) is a colorless tetragonal crystal, and the powder appears white due to irregular reflection. With the transformation of Both are produced as minerals. The titanium oxide of this embodiment is red Ti ₂ O ₃ , and unlike conventional black-purple Ti ₂ O _3, it is not a mixture of conventional black TiO and colorless or white TiO ₂ .

Further, titanium oxide of this embodiment, with reference to FIGS. 1 and 4, having an infrared absorption peak in the range 900 cm ^-1 or more 925 cm ^-1 The following infrared absorption spectra. Infrared absorption peak appearing at 900 cm ^-1 or more 925 cm ^-1 in the range is assigned is unknown, the titanium oxide of the present embodiment are specific, unique to the titanium oxide of the present embodiment Ti This is considered to indicate a bonding mode of —O. Here, the infrared absorption spectrum in titanium oxide can be measured using an infrared spectrometer.

  In addition, referring to FIG. 3, the titanium oxide of the present embodiment has a reflectance of light with a wavelength of 550 nm of 80% or less, a reflectance of light with a wavelength of 500 nm of 60% or less, and a reflectance of light with a wavelength of 450 nm. The reflectance of light having a wavelength of 40% or less and a wavelength of 400 nm is 30% or less. For this reason, the titanium oxide of this embodiment can exhibit photocatalytic activity by absorbing at least part of light having a wavelength in the range of 400 nm to 550 nm among visible light. Here, the reflectance of light in the titanium oxide can be measured using a colorimeter.

  Further, the titanium oxide of the present embodiment is not particularly limited as long as it has photocatalytic activity, but it is preferably anatase type or rutile type with reference to FIGS. 2 and 5. This is because tetragonal crystal titanium oxide has three types of transformations, anatase type, rutile type and brookite type, and among these transformations, anatase type and rutile type show high catalytic activity.

(Embodiment 2)
In one embodiment of the method for producing a titanium oxide according to the present invention, referring to FIG. 6, the titanium hydroxide 12 is obtained by adding an alkoxy group-containing liquid and a first hydrogen peroxide-containing aqueous liquid to the titanium alkoxide 11. A second hydrogen peroxide-containing aqueous liquid is allowed to undergo a self-thermal reaction with the separated water-containing titanium hydroxide 12 and the step S1 of separating the titanium hydroxide from the mother liquor in a water-containing state. A step S3 of generating a titanium compound-containing gel 13 containing at least one of a titanium oxide and a hydroxide, and a step S11 of obtaining the first titanium oxide 31 by drying the titanium compound-containing gel 13 ,including. By this process, the titanium oxide of Embodiment 1 can be obtained efficiently in a short time. Details will be described below.

  The method for producing a titanium oxide of this embodiment includes a step S1 in which an alkoxy group-containing liquid and a first hydrogen peroxide-containing aqueous liquid are added to the titanium alkoxide 11 to generate a titanium hydroxide. By this process S1, the titanium alkoxide 11 is hydrolyzed efficiently in a short time, and the titanium hydroxide 12 is obtained.

In the step S1 of generating the titanium hydroxide, the titanium hydroxide can be hydrolyzed in the presence of the alkoxy group-containing liquid, whereby the titanium hydroxide can contain an alkoxy group. Here, coordination number of tetravalent Ti ions in the liquid is 6, in the Ti (OH) ₄ in a liquid, four of the six coordination sites of tetravalent Ti (titanium) ions the contains the OH group is considered that the remaining 2 thing oR group (alkoxy group) or OH ₂ enters. Further, by hydrolyzing the titanium alkoxide in the presence of hydrogen peroxide in the first hydrogen peroxide-containing aqueous liquid, the size of the aggregated particles in the liquid of the resulting titanium hydroxide is reduced (that is, the aggregated particles Can be made small in size.

  Here, although there is no restriction | limiting in particular as an alkoxy group of a titanium alkoxide, From a viewpoint with high reactivity, a C10 or less thing is preferable.

  The alkoxide group-containing liquid is not particularly limited as long as it is a liquid containing an alkoxy group. From the viewpoint of coordination with titanium alkoxide and titanium hydroxide, alcohols, polyhydric alcohols, ethers, esters Etc. are preferably used. Here, the alkoxy group preferably has 10 or less carbon atoms from the viewpoint of easy coordination to titanium alkoxide and titanium hydroxide.

  The first hydrogen peroxide-containing aqueous liquid is not particularly limited as long as it is a liquid containing hydrogen peroxide as a solute and water as a solvent, but from the viewpoint of promoting hydrolysis of titanium alkoxide, Is preferably used.

In the step S1 of generating the titanium hydroxide, the molar ratio OR _A / OR _M of the alkoxy group OR _A in the alkoxy group-containing liquid to the alkoxy group OR _M in the titanium alkoxide is 0.001 or more and 10 or less. Preferably, it is 0.01 or more and 5 or less. If the molar ratio OR _A / OR _M is less than 0.001, it is difficult for the titanium hydroxide to retain an alkoxy group, and if it is greater than 10, there are many useless alkoxy groups that do not coordinate to Ti (titanium). .

The molar ratio HP _A / OR _M of the hydrogen peroxide HP _A in the first hydrogen peroxide-containing aqueous liquid to the alkoxy group OR _M in the titanium alkoxide is preferably 0.001 or more and 20 or less. It is more preferable that the number is 0.01 or more and 10 or less. When the molar ratio HP _A / OR _M is less than 0.001, the titanium alkoxide is not sufficiently hydrolyzed, and the production of titanium hydroxide is reduced.

  The initial temperature for hydrolyzing the titanium alkoxide by adding the alkoxy group-containing liquid and the first hydrogen peroxide-containing aqueous liquid to the titanium alkoxide is not particularly limited, but is 263 K (−10 ° C.) or higher and 373 K (100 ° C.). ) Is preferable, and 273 K (0 ° C.) or more and 323 K (50 ° C.) or less is more preferable. If the initial hydrolysis temperature is less than 263K, the titanium alkoxide is solidified to reduce the reactivity, and if it is greater than 373K, hydrogen peroxide is decomposed.

  Moreover, the manufacturing method of the titanium oxide of this embodiment is equipped with process S2 which isolate | separates the titanium hydroxide 12 from a mother liquid in a water-containing state. Titanium hydroxide can be isolated by this separation step. Here, the titanium hydroxide is separated from the mother liquor in a water-containing state in order to keep the alkoxy group contained in the titanium hydroxide. The method for separating the titanium hydroxide from the mother liquor is not particularly limited, and various methods such as filtration and centrifugation can be used. It is also preferable to purify the separated titanium hydroxide by washing it with pure water, distilled water, ion exchange water or the like.

  In addition, the titanium oxide production method of the present embodiment causes the separated water-containing titanium hydroxide 12 to self-react with the second hydrogen peroxide-containing aqueous liquid, whereby the titanium oxide and the hydroxide are oxidized. Step S3 of generating a titanium compound-containing gel 13 containing at least one of the objects is provided. By this process, the titanium compound-containing gel 13 can be obtained efficiently in a short time. Such a titanium compound-containing gel 13 has not been specified in its chemical composition and structure, but contains at least one of titanium hydroxide and oxide. Here, the self-thermal reaction refers to a reaction that occurs due to self-heating of a plurality of chemical species.

  The autothermal reaction of the present embodiment occurs, for example, by adding the second hydrogen peroxide-containing aqueous liquid at a specific initial temperature to the separated water-containing titanium hydroxide 12. Moreover, the molar ratio of the hydrogen peroxide in the 2nd hydrogen peroxide containing aqueous liquid with respect to the hydroxyl group in a titanium hydroxide is enlarged, and titanium oxide is contained by accelerating the oxidation of a titanium hydroxide. A titanium oxide-containing gel (titanium compound-containing gel) is obtained.

  Here, the second hydrogen peroxide-containing aqueous liquid is not particularly limited as long as it is a liquid containing hydrogen peroxide as a solute and water as a solvent, like the first hydrogen peroxide-containing aqueous liquid. From the viewpoint of promoting oxidation of the hydroxide and suppressing an increase in the reaction temperature, hydrogen peroxide is preferably used.

In the step S3 of generating the titanium compound-containing gel 13, the molar ratio HP _B / OH _M of the hydrogen peroxide HP _B in the second hydrogen peroxide-containing aqueous liquid to the hydroxyl group OH _M in the titanium hydroxide 12 is 0. It is preferably 0.001 or more and 20 or less, and more preferably 0.01 or more and 10 or less. When the molar ratio HP _B / OH _M is smaller than 0.001, the reaction time becomes longer, and when it is larger than 20, a rapid reaction occurs.

  In addition, the initial temperature at which the second hydrogen peroxide-containing aqueous liquid is added to the titanium hydroxide to initiate a self-thermal reaction between the titanium hydroxide and the second hydrogen peroxide-containing aqueous liquid is 273 K (0 ° C. ) To 573 K (300 ° C.) or less, preferably 293 K (20 ° C.) to 473 K (200 ° C.), more preferably 300 K (27 ° C.) to 315 K (42 ° C.). If the initial temperature of the self-heating reaction is less than 273K, the self-heating reaction is difficult to occur, and if it is greater than 573K, the aqueous liquid is rapidly lost and a rapid reaction occurs.

  Moreover, the manufacturing method of the titanium oxide of this embodiment is equipped with process S11 which dries the titanium compound containing gel 13. FIG. Through this process, the liquid component of the titanium compound-containing gel 13 is evaporated, and the first titanium oxide 31 is obtained. The first titanium oxide includes titanium oxide crystals formed in the step of drying the titanium compound-containing gel 13.

  In this embodiment, it is preferable to perform the process of drying a titanium compound containing gel in the state which does not boil the liquid component in a titanium compound containing gel. By gently evaporating the liquid component in the titanium compound-containing gel without boiling, the formation of titanium oxide (titanium compound) crystals in the drying process is not hindered, and the titanium oxide (titanium) has a high crystallization rate. Compound) is obtained.

  Here, the state where the liquid component in the titanium compound-containing gel is not boiled refers to a state where the atmospheric pressure during drying of the titanium compound-containing gel is higher than the vapor pressure of the liquid component. In addition, from the viewpoint of promoting the drying of the titanium compound-containing gel, it is preferable that the difference between the atmospheric pressure during the drying of the titanium compound-containing gel and the vapor pressure of the liquid component is small.

  The method for reducing the difference between the atmospheric pressure during drying and the vapor pressure of the liquid component is not particularly limited. For example, a method for reducing the atmospheric pressure during drying (a reduced pressure drying method), a method during drying, A method of increasing the atmospheric pressure and increasing the drying temperature (high pressure drying method) can be used. The liquid component in the titanium compound-containing gel includes alcohols that are alkoxy group-containing liquids and hydrogen peroxide water that is a hydrogen peroxide-containing aqueous liquid. The alcohols and water have a minimum azeotropic point. Therefore, the difference between the atmospheric pressure during drying and the vapor pressure of the liquid component can be reduced.

  Here, the drying conditions of the titanium compound-containing gel are not particularly limited as long as the liquid components in the titanium compound-containing gel are not boiled. For example, in the reduced-pressure drying method, for example, conditions of a drying temperature of 193 K (−80 ° C.) to 373 K (100 ° C.) at an atmospheric pressure of 1 Pa to 100 kPa are preferably used.

(Embodiment 3)
In another embodiment of the method for producing a titanium oxide according to the present invention, referring to FIG. 6, the titanium hydroxide is added with an alkoxy group-containing liquid and a first hydrogen peroxide-containing aqueous liquid to form titanium hydroxide. 12, a step S 2 of separating the titanium hydroxide 12 from the mother liquor in a hydrated state, and a second hydrogen peroxide-containing aqueous liquid is self-heated into the separated hydrated titanium hydroxide 12. A third hydrogen peroxide-containing aqueous liquid is applied to the titanium compound-containing gel 13 once in the step S3 of generating a titanium compound-containing gel 13 containing at least one of titanium oxide and hydroxide by reacting. Step S4 for producing a titanium compound-containing liquid 14 containing at least one of a titanium oxide and a hydroxide by self-thermal reaction as described above, It includes a step S21 of obtaining a second titanium oxide 41 a liquid 14 is dried, a. By this process, the titanium oxide of Embodiment 1 can be obtained efficiently in a short time. Details will be described below.

  In the titanium oxide production method of the present embodiment, the step S1 for producing the same titanium hydroxide 12 as the titanium oxide production method of the second embodiment and the titanium hydroxide 12 are separated from the mother liquor in a water-containing state. Step S2 and Step S3 for generating the titanium compound-containing gel 13 are provided.

  Further, in the method for producing a titanium oxide according to the present embodiment, the titanium compound-containing liquid 14 is generated by causing the titanium compound-containing gel 13 to self-react with the third hydrogen peroxide-containing aqueous liquid one or more times. including. By this step, a titanium compound-containing liquid containing at least one of titanium oxide and hydroxide is obtained. Here, the self-thermal reaction refers to a reaction caused by self-heating of a plurality of chemical species, as in the self-thermal reaction in the second embodiment.

  The autothermal reaction of the present embodiment occurs, for example, by adding a third hydrogen peroxide-containing aqueous liquid to the titanium compound-containing gel 13 at a specific initial temperature. In the autothermal reaction of the present embodiment, the size of the aggregated particles of the titanium compound in the aqueous liquid is small due to the action of hydrogen peroxide in the third hydrogen peroxide-containing aqueous liquid (that is, the particle size of the aggregated particles). And the titanium compound-containing gel is dispersed or dissolved in the aqueous liquid. Here, it is preferable that the third hydrogen peroxide-containing aqueous liquid has a higher hydrogen peroxide content than the second hydrogen peroxide-containing aqueous liquid.

  In the present embodiment, the number of autothermal reactions required to uniformly disperse or dissolve the titanium compound-containing gel 13 in the third hydrogen peroxide-containing aqueous liquid is at least twice. By adding the first hydrogen peroxide-containing aqueous liquid to the titanium compound-containing gel 13, the first self-heat reaction occurs, and by adding the second hydrogen peroxide-containing aqueous liquid, the second self-heat reaction occurs. And the kth autothermal reaction occurs by adding the kth (k ≧ 2) hydrogen peroxide-containing aqueous liquid. In this way, the hydrogen peroxide-containing aqueous liquid can be self-heated one or more times with the titanium compound-containing gel. Here, it is preferable that the kth hydrogen peroxide-containing aqueous liquid increases the hydrogen peroxide content as compared with the k-1th hydrogen peroxide-containing aqueous liquid.

Also, by increasing the molar ratio HP _C / OH _G of hydrogen peroxide HP _C of the third hydrogen peroxide-containing aqueous liquid to the hydroxyl group OH _G needed to coordinate to the titanium of the titanium compound-containing gel, titanium By promoting the oxidation of the compound-containing gel, a titanium compound-containing liquid containing a titanium oxide is obtained. Here, the “hydroxyl group necessary for coordination to a titanium atom” refers to a number of hydroxyl groups equal to the valence of the titanium atom.

  Here, the third hydrogen peroxide-containing aqueous liquid is not particularly limited as long as it is a liquid containing hydrogen peroxide as a solute and water as a solvent, like the first and second hydrogen peroxide-containing aqueous liquids. However, hydrogen peroxide is preferably used from the viewpoint of promoting oxidation of the titanium compound-containing gel and refinement of the aggregated particles and suppressing an increase in the reaction temperature.

In step S4, to produce a titanium compound-containing liquid, the molar ratio of hydrogen peroxide HP _C of the third hydrogen peroxide-containing aqueous liquid to the hydroxyl group OH _G needed to coordinate the titanium atom of the titanium compound-containing gel HP _C / OH _G is preferably 0.001 or more and 20 or less, more preferably 0.01 to 10. When the molar ratio is less than 0.001, the reaction time is long, and when it is more than 20, a rapid reaction occurs.

  The initial temperature at which the third hydrogen peroxide-containing aqueous liquid is added to the titanium compound-containing gel to initiate the self-thermal reaction is preferably 273 K (0 ° C.) or higher and 573 K (300 ° C.) or lower, preferably 293 K (20 ° C.) or higher. 493K (200 ° C.) or less is more preferable, and 300 K (27 ° C.) or more and 315 K (42 ° C.) or less is particularly preferable. If the initial temperature of the self-heating reaction is less than 273K, the self-heating reaction is difficult to occur, and if it is greater than 573K, the aqueous liquid is rapidly lost and a rapid reaction occurs.

  The titanium compound-containing liquid obtained in this way is so-called both for ceramics, metals, other inorganic materials such as hydrophilic base materials, and resins, other organic materials such as lipophilic base materials. It can be applied thinly with a uniform thickness without causing repelling. This is considered to be due to the fact that an alkoxy group, which is a functional group having both hydrophilic and lipophilic properties, is contained in the titanium compound-containing liquid. That is, the alkoxy group contained in the water-containing titanium hydroxide is also contained in the titanium compound-containing gel obtained by the reaction between the titanium hydroxide and the second hydrogen peroxide-containing aqueous liquid. The contained alkoxy group is considered to be contained in the titanium compound-containing liquid obtained by the reaction between the titanium compound-containing gel and the third hydrogen peroxide-containing aqueous liquid.

  Moreover, the manufacturing method of the titanium oxide of this embodiment is equipped with process S21 which dries the titanium compound containing liquid 14. FIG. Through this process, the liquid component of the titanium compound-containing liquid 14 is evaporated, and the second titanium oxide 41 is obtained. The second titanium oxide includes titanium oxide crystals formed in the step of drying the titanium compound-containing liquid 14.

  Here, in the titanium compound-containing liquid 14, due to the action of hydrogen peroxide in the third hydrogen peroxide-containing aqueous liquid, the size of the aggregated particles of the titanium compound in the titanium compound-containing liquid is in the titanium compound-containing gel. This is considered to be smaller than the size of the aggregated particles of the titanium compound.

  In the present embodiment, the step of drying the titanium compound-containing liquid is preferably performed in a state where the liquid components in the titanium compound-containing liquid are not boiled. By gently evaporating the liquid component in the titanium compound-containing liquid without boiling, the formation of titanium oxide (titanium compound) crystals in the drying process is not hindered, and the titanium oxide (titanium) has a high crystallization rate. Compound) is obtained.

  Here, the state where the liquid component in the titanium compound-containing liquid is not boiled refers to a state where the atmospheric pressure during drying of the titanium compound-containing liquid is higher than the vapor pressure of the liquid component. Further, from the viewpoint of promoting the drying of the titanium compound-containing liquid, it is preferable that the difference between the atmospheric pressure during the drying of the titanium compound-containing liquid and the vapor pressure of the liquid component is small.

  The method for reducing the difference between the atmospheric pressure during drying and the vapor pressure of the liquid component is not particularly limited, and the same method as in the second embodiment can be used. Here, the drying condition of the titanium compound-containing liquid is not particularly limited as long as the liquid component in the titanium compound-containing liquid is not boiled. For example, in the reduced-pressure drying method, a drying temperature of 193 K (−80 ° C.) to 373 K (100 ° C.) is preferably used at an atmospheric pressure of 1 Pa to 100 kPa.

  Here, an example of a method for producing a titanium oxide film (titanium oxide film) according to the present invention is based on a paint containing a titanium compound-containing liquid 14 obtained in this embodiment with reference to FIG. And a step S32 of drying the paint applied to the base material. Through this process, the liquid component of the paint containing the titanium compound-containing liquid 14 applied to the base material is evaporated, and a second titanium oxide film 42 (titanium oxide film) is obtained. The titanium oxide film includes a titanium oxide crystal formed in the step of drying the titanium compound-containing liquid 14 contained in the paint.

  The coating material containing the titanium compound-containing liquid 14 thus obtained, as is apparent from the description of the titanium compound-containing liquid 14 in the present embodiment, a base material having a hydrophilic surface such as ceramics, metal, and other inorganic materials, and Titanium compound-containing liquid contained in paint can be applied thinly at a uniform thickness without causing the so-called repellency to any of the lipophilic base materials such as resins and other organic materials. . By drying the titanium compound-containing liquid film having a uniform thickness, a second titanium oxide film 42 having a uniform thickness can be obtained.

  Here, the paint containing the titanium compound-containing liquid 14 refers to a paint containing the titanium compound-containing liquid 14 capable of forming the titanium oxide film 42. Such a coating material may be composed of the titanium compound-containing liquid 14, but prevents the aggregation of the titanium compound in the coating material during coating and drying, thereby forming a uniform titanium oxide film 42 with a small thickness. From the viewpoint, in addition to the titanium compound-containing liquid, any of a titanium compound aggregation inhibitor and a dilution solvent may be included. Here, as the titanium compound aggregation inhibitor, those that dissolve in an arbitrary ratio in the solvent of the paint and have a higher boiling point than the solvent of the paint are preferably used. For example, when the titanium compound-containing liquid is an aqueous liquid, the titanium compound aggregation inhibitor is preferably one that dissolves in water at an arbitrary ratio and has a higher boiling point than water, such as propylene glycol, ethylene glycol, diethylene glycol, etc. Is preferred. Further, as the dilution solvent, a solvent that dissolves in an arbitrary ratio in the solvent of the paint is preferably used. For example, when the titanium compound-containing liquid is an aqueous liquid, those that dissolve in water at an arbitrary ratio are preferable, and for example, water, methyl alcohol, ethyl alcohol, isopropyl alcohol, and the like are preferable.

Example 1
1-1. Production of Titanium Compound-Containing Gel 100 g of titanium isopropoxide (titanium alkoxide), 171 g of isopropyl alcohol (alkoxy group-containing liquid) and 25 g of 35% by mass of hydrogen peroxide (first hydrogen peroxide-containing aqueous liquid) Was added and mixed for 1 minute, whereby titanium isopropoxide was vigorously hydrolyzed to obtain a yellow slurry of titanium hydroxide. Wherein the molar ratio OR _A / OR _M isopropoxy group (alkoxy group) OR _A isopropyl alcohol to isopropoxy group (alkoxy group) OR _M in titanium isopropoxide was 2.0, titanium isopropoxide The molar ratio HP _A / OR _M of hydrogen peroxide HP _{A in} an aqueous liquid containing 35% by weight of hydrogen peroxide (first hydrogen peroxide-containing aqueous liquid) with respect to the isopropoxy group (alkoxy group) OR _M therein is 0. The ambient temperature was 293 K (20 ° C.).

  Next, the slurry-like titanium hydroxide was filtered off in a water-containing state to obtain a yellow paste-like titanium hydroxide.

Next, 544 g of 35% by mass of hydrogen peroxide (second hydrogen peroxide-containing aqueous liquid) is added to the obtained paste-like titanium hydroxide at an initial temperature of 300 K (27 ° C.) for 20 seconds. When subjected to thermal reaction, a titanium compound-containing gel containing titanium oxide and titanium hydroxide was obtained. Here, hydrogen peroxide HP 35% by weight of hydrogen peroxide containing aqueous liquid (the second hydrogen peroxide containing aqueous liquid) in to the hydroxyl group OH _M needed to coordinate the titanium atoms in the titanium hydroxide the molar ratio HP _B / OH _M of _B was 4.0. In addition, since the titanium atom in a titanium hydroxide is tetravalent, the hydroxyl group required for coordinating to 1 mol titanium atom is 4 mol.

  Thus, in this example, a titanium compound-containing gel was obtained from titanium isopropoxide in 10 minutes. The production time of the titanium compound-containing gel of this example was reduced to about 1/4320 time compared to the conventional method that required 720 hours to obtain a titanium compound-containing liquid from titanium isopropoxide.

1-2. Production of first titanium oxide 1-1. The titanium compound-containing gel obtained in (1) was dried for 30 minutes at an atmospheric pressure of 51 kPa and a drying temperature of 355 K (82 ° C.) using a freeze vacuum drying apparatus (DF-01H manufactured by Nippon Vacuum Technology Co., Ltd.). An oxide was obtained. The production time of the first titanium oxide of this example was shortened to about 1/10 of the conventional method that required 5 hours to obtain titanium oxide from the titanium compound-containing liquid.

1-3. Physical Properties of First Titanium Oxide The first titanium oxide thus obtained has a red color, and the oxygen composition ratio was analyzed using an oxygen-nitrogen simultaneous analyzer (TR-436 manufactured by LECO). It had a composition of Ti ₂ O ₃ .

Moreover, when the IR spectrum of this first titanium oxide powder was measured using a Fourier transform IR (infrared) absorption spectrum measuring apparatus (JIR-7000, manufactured by JEOL Ltd.), the IR shown in FIG. A spectrum was obtained. This IR spectrum, characteristic IR absorption peaks of titanium oxide of the present invention appeared to 912cm ^-1 in a range of 900 cm ^-1 or more 925 cm ^-1 or less.

  Further, the powder of the first titanium oxide was subjected to powder X-ray diffraction using an X-ray diffractometer (XPELT-PRO manufactured by PANALYTICAL), and the X-ray diffraction peak shown in FIG. 3 was obtained. . From the analysis of half width and pattern of multiple X-ray diffraction peaks, this first titanium oxide contains 61% of anatase-type crystals, 8% of rutile-type crystals, and 31% of non-crystals. It was. Therefore, this first titanium oxide is considered to have photocatalytic activity.

Moreover, the reflectance of the light of the wavelength of 400 nm-700 nm in this 1st titanium oxide powder was measured using the colorimeter (Color-Eye3100 by Macbeth Co.). At this time, for comparison, a white titanium oxide (TiO _2, anatase, manufactured by Ishihara Sangyo Kaisha, Ltd. ST-01) was measured reflectance of light having a wavelength of 400nm~700nm in powder. These results are shown in FIG. In FIG. 3, R indicates the reflectance curve for the white titanium oxide, and S indicates the reflectance curve for the red first titanium oxide.

  Referring to FIG. 3, white titanium oxide only slightly reduced the reflectance of light having a wavelength of less than 450 nm, and light having a wavelength of 450 nm or more exhibited a high reflectance of about 80%. In contrast, the first titanium oxide has a high reflectance of light with a wavelength of 600 nm to 700 nm, which is about 85 to 90%. However, as the wavelength decreases from 600 nm to 400 nm, the reflectance of light with that wavelength increases. Reduced. Specifically, the reflectance of light having a wavelength of 550 nm is about 75%, the reflectance of light having a wavelength of 500 nm is about 55%, the reflectance of light having a wavelength of 450 nm is about 35%, and light having a wavelength of 400 nm. The reflectance of was about 25%. That is, the reflectance of light having a wavelength of 550 nm is 80% or less, the reflectance of light having a wavelength of 500 nm is 60% or less, the reflectance of light having a wavelength of 450 nm is 40% or less, and the reflectance of light having a wavelength of 400 nm. Was 30% or less. Thus, it can be seen that the first titanium oxide exhibits a red color when the reflectance of light having a wavelength of 550 nm or less is small, that is, light having a wavelength of 550 nm or less is largely absorbed. The conventional white titanium oxide absorbs light having a wavelength of approximately 450 nm or less and exhibits photocatalytic activity, whereas the red first titanium oxide absorbs light having a wavelength of approximately 550 nm or less and exhibits photocatalytic activity. It is thought that it shows.

(Example 2)
2-1. Production of titanium compound-containing liquid 1-1. By adding 1088 g of 35% by mass of hydrogen peroxide (third hydrogen peroxide-containing aqueous liquid) at an initial temperature of 300 K (27 ° C.) to the titanium compound-containing gel obtained in (1) above, and causing a self-thermal reaction for 40 seconds. A titanium compound-containing liquid containing titanium oxide and hydroxide was obtained. Here, hydrogen peroxide HP _C in 35% by weight of hydrogen peroxide containing aqueous liquid to the hydroxyl group OH _G needed to coordinate the titanium atom of the titanium compound in the gel (the third hydrogen peroxide-containing aqueous liquids) the molar ratio of HP _C / OH _G was 8.0. In addition, since the titanium atom in a titanium compound gel is tetravalent, the hydroxyl group required to coordinate to 1 mol titanium atom is 4 mol. However, in the titanium compound-containing liquid, the titanium compound was not uniformly dispersed or dissolved in the liquid.

Therefore, 1360 g of 35% by mass of hydrogen peroxide (third hydrogen peroxide-containing aqueous liquid) was further added to the titanium compound-containing liquid at an initial temperature of 300 K (27 ° C.), and a self-thermal reaction was performed for 1 minute. . Here, hydrogen peroxide HP _C in 35% by weight of hydrogen peroxide containing aqueous liquid to the hydroxyl group OH _G needed to coordinate the titanium atom of the titanium compound in the gel (the third hydrogen peroxide-containing aqueous liquids) The molar ratio of HP _C / OH _G was 10.0. Thus, 35 mass% hydrogen peroxide solution (third hydrogen peroxide-containing aqueous liquid) was subjected to a self-thermal reaction twice with the titanium compound-containing gel. Thus, a titanium compound-containing liquid in which the titanium compound was uniformly dispersed or dissolved in the liquid was obtained.

  Thus, in this example, a titanium compound-containing liquid was obtained from the titanium compound-containing gel in 10 minutes. That is, a titanium compound-containing liquid was obtained from titanium isopropoxide in 20 minutes. The production time of the titanium compound-containing liquid of this example was shortened to about 1/2160 compared to the conventional method that required 720 hours to obtain the titanium compound-containing liquid from titanium isopropoxide.

2-2. Production of second titanium compound 2-1. The titanium compound-containing liquid obtained in (1) was dried for 4 hours at an atmospheric pressure of 51 kPa and a drying temperature of 355 K (82 ° C.) using a freezing vacuum drying apparatus (DF-01H manufactured by Nippon Vacuum Technology Co., Ltd.). An oxide was obtained. The production time of the second titanium oxide of this example was shortened to about 4/5 compared with the conventional method that required 5 hours to obtain titanium oxide from the titanium compound-containing liquid.

2-3. Second titanium oxide obtained in this way the physical properties of the second titanium oxide, like the first titanium compound, was red titanium oxide having a chemical composition of Ti ₂ O _3.

Further, an IR (infrared) spectrum shown in FIG. 4 was obtained for the second titanium oxide powder. In IR spectra of the second titanium oxide, as in the case of IR spectrum of the first titanium oxide shown in Figure 1, of the present invention to 912cm ^-1 in a range of 900 cm ^-1 or more 925 cm ^-1 or less An IR absorption peak peculiar to titanium oxide appeared. Further, 1714 cm ^-1 of the IR spectrum of the first titanium oxide (FIG. ^{1), 1619cm -1, 1532cm -1} , so as to correspond to each of the IR absorption peak of 1438cm ^-1 and 1026cm ^-1, the second titanium 1707 cm ^-1 in IR spectrum of the oxide (Fig. ^{4), 1619cm -1, 1525cm -1} , IR absorption peak of 1418cm ^-1 and 1026cm ^-1 appeared. On the other hand, the IR spectrum of the first titanium oxide (FIG. 1) is appeared broad large absorption peak P in 3393Cm ^-1, the IR spectrum of the second titanium oxide (FIG. 4) is the absorption peak P A corresponding absorption peak did not appear. Thus, the second titanium oxide has the same color and the first titanium oxide (red) and chemical composition (Ti ₂ O _3), the crystal structure will be described later as a separate, substantially the same Ti-O It is considered that the titanium oxide has a bonding mode of

  Moreover, the X-ray diffraction peak shown in FIG. 5 was obtained for the second titanium oxide powder. From the analysis of half widths and patterns of a plurality of X-ray diffraction peaks, the second titanium oxide contained anatase-type crystals with a probability of 54% and non-crystals with a probability of 46%. Therefore, this second titanium oxide is also considered to have photocatalytic activity. Here, the crystal structure of the second titanium oxide was slightly different from the first crystal structure. It is unclear whether this difference is due to the difference between the titanium compound-containing gel and the titanium compound-containing liquid or the difference that occurs during drying.

(Example 3)
3-1. Production of titanium compound film 2-1. 5% by mass of the titanium compound-containing liquid (liquid in which the titanium compound is uniformly dispersed or dissolved) obtained in 1 above, 1% by mass of propylene glycol as a titanium compound aggregation inhibitor, and 94% by mass as a diluting solvent Was added and uniformly mixed and dispersed to prepare a paint containing a titanium compound-containing liquid.

Using a spray gun, the paint is applied to a part of the surface of the glass plate and the acrylic resin plate to a uniform thickness (weight per unit area: 60 g / m ² ), and 3 at an ambient temperature of 353 K (80 ° C.). Let dry for hours. Here, the glass plate was left in the air for 7 days in advance and the surface thereof was in a water-repellent state. Thus, a glass plate and an acrylic resin plate coated with a coating containing a titanium compound-containing liquid on a part of the surface, and a fluorescent lamp with a 32 type ultraviolet absorbing film from a distance of 10 cm from the surface of the plate (FHF32EX manufactured by Toshiba Lighting & Technology Corporation). -N · NU-MS) was irradiated for 2 hours. The light of such a fluorescent lamp with an ultraviolet absorbing film has an emission spectrum in the range of 400 nm to 700 nm, and emission peak wavelengths appear at 440 nm, 490 nm, 550 nm, 590 nm and 620 nm. After the light irradiation, the surfaces of the glass plate and the acrylic resin plate were washed with water, and the hydrophilicity of the surface was evaluated. In the evaluation of the hydrophilicity of the surface, the glass plate and the acrylic resin plate were set up vertically, and the water droplets that did not remain on the surface were washed hydrophilic, and the water droplets that remained on the surface were water repellency. The results are summarized in Table 1.

  Referring to Table 1, in both the glass plate and the acrylic resin plate, the surface on which the coating containing the titanium compound-containing liquid was not applied was water-repellent, whereas the coating containing the titanium compound-containing liquid was applied. The finished surface was hydrophilic. This is because the titanium compound-containing liquid contained in the paint applied to the glass plate and the acrylic resin plate is dried to form a titanium oxide film (this is considered to be a second titanium oxide film from the above result). It is considered that the surfaces of the glass plate and the acrylic resin plate are made hydrophilic by the photocatalytic activity of the titanium compound film (second titanium oxide film) by irradiation with light having a wavelength of 400 nm to 700 nm.

  It should be understood that the embodiments and examples disclosed herein are illustrative and non-restrictive in every respect. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  11 titanium alkoxide, 12 titanium hydroxide, 13 titanium compound-containing gel, 14 titanium compound-containing liquid, 31 first titanium oxide, 41 second titanium oxide, 42 second titanium oxide film, S1 titanium Step of generating hydroxide, step of separating S2 titanium hydroxide from the mother liquor in a water-containing state, step of generating S3 titanium compound-containing gel, step of generating S4 titanium compound-containing liquid, and drying of S11 titanium compound-containing gel S21, drying the S21 titanium compound-containing liquid, S31 applying the paint containing the titanium compound-containing liquid to the base material, and S32 drying the paint applied to the base material.

Claims (4)

Having a chemical composition of Ti ₂ O ₃ ,
Having an infrared absorption peak in the range 900 cm ^-1 or more 925 cm ^-1 The following infrared absorption spectra,
The reflectance of light having a wavelength of 550 nm is 80% or less, the reflectance of light having a wavelength of 500 nm is 60% or less, the reflectance of light having a wavelength of 450 nm is 40% or less, and the reflectance of light having a wavelength of 400 nm is 30% or less. A certain titanium oxide.   The titanium oxide according to claim 1, which has an anatase type or rutile type crystal structure. Adding an alkoxy group-containing liquid and a first hydrogen peroxide-containing aqueous liquid to titanium alkoxide to produce titanium hydroxide;
Separating the titanium hydroxide from the mother liquor in a water-containing state;
A titanium compound-containing gel containing at least one of a titanium oxide and a hydroxide is obtained by subjecting the separated water-containing titanium hydroxide to an autothermal reaction with a second hydrogen peroxide-containing aqueous liquid. A step of generating,
Drying the titanium compound-containing gel to obtain a first titanium oxide. Adding an alkoxy group-containing liquid and a first hydrogen peroxide-containing aqueous liquid to titanium alkoxide to produce titanium hydroxide;
Separating the titanium hydroxide from the mother liquor in a water-containing state;
A titanium compound containing at least one of the titanium hydroxide and the titanium oxide by causing the second hydrogen peroxide-containing aqueous liquid to undergo a self-thermal reaction with the separated water-containing titanium hydroxide. Forming a gel;
Generating a titanium compound-containing liquid containing at least one of an oxide of titanium and a hydroxide by causing the third hydrogen peroxide-containing aqueous liquid to self-react with the titanium compound-containing gel one or more times; ,
Drying the titanium compound-containing liquid to obtain a second titanium oxide.

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