KR20200115869A - Photocatalyst Module for Attaching and Detaching to Wall Surface Fixed type Electric Lamp Equipped with Downward type Light Source - Google Patents

Abstract

According to a photocatalytic module detachable to a wall light with a downward light source of the present invention, the photocatalytic module detachable to the wall light with the downward light source includes: a light source unit that emits light of a specified wavelength (or wavelength band) using power and has a specified appearance; a socket unit supporting the light source unit inserted from below and supplying power to the light source unit; and a frame unit having a structure that is combined with the socket unit and fixed to the wall. The photocatalytic module includes: an attachment structure unit having a designated geometrical attachment area attachable to a designated light source area of the light source unit inserted to the socket unit from below and maintaining a state attached to the designated light source area of the light source unit by at least one of a structural feature and frictional force of the attachment area; a net structure unit including a net structure that transmits light of a specified wavelength (or wavelength band) emitted through the light source unit; and a photocatalytic material unit formed by coating a designated photocatalytic material on a designated air contact area among the attachment structure unit and the net structure unit.

Description

Photocatalyst Module for Attaching and Detaching to Wall Surface Fixed type Electric Lamp Equipped with Downward type Light Source}

The present invention provides the wall-type lamp while using the wall-type lamp by attaching and detaching it to a designated light source area of a light source unit having a designated shape (eg, a light bulb shape, a light tube shape, etc.) provided in a wall-type lamp fixed to the wall. It is to provide a photocatalytic module that purifies the air in space.

A photocatalyst is a material that promotes a designated chemical reaction by irradiating light in a designated wavelength band, and a representative photocatalyst material is titanium oxide (TiO2). Titanium oxide (TiO2) is used as a major raw material for white pigments, and when ultraviolet rays in the UV-A wavelength band are irradiated on such titanium oxide (TiO2), electrons in the valence band are excitation as conduction bands. ) And then restored to the valence band, a photocatalytic reaction that causes a strong oxidation or reduction reaction occurs. Accordingly, after manufacturing a photocatalytic filter containing a photocatalytic material such as titanium oxide (TiO2), the photocatalytic filter is irradiated with ultraviolet rays in the UV-A wavelength band while passing the air to decompose and purify various pollutants or dust in the air. The titanium oxide (TiO2) is mainly used for photocatalytic air purifiers and the like. Meanwhile, since such a photocatalytic air purifier is manufactured under conditions optimized for a photocatalytic reaction, the air purification efficiency is high, while the manufacturing cost is high.

Meanwhile, a method of purifying air while the fluorescent lamp is turned on by coating a photocatalytic material directly on a fluorescent lamp emitting ultraviolet rays has been proposed (Patent Publication No. 1999-0081038 (November 15, 1999)). However, this method is applicable only to some fluorescent lamps that emit ultraviolet rays in the UV-A wavelength band, and it has a problem that is difficult to apply to general lamps used as lighting, and air purification efficiency is also low due to little air flow around the fluorescent lamp. It has extremely low problems. In addition, titanium oxide (TiO2) is used as a main raw material for white pigments, as described above, and when such titanium oxide (TiO2) is directly coated on a fluorescent lamp, the brightness of the fluorescent lamp decreases, making it difficult to use as a lighting lamp. have.

Meanwhile, recently, a method of purifying the air while the fluorescent lamp is turned on has been proposed by fixing the fluorescent lamp protective cover formed with the photocatalytic coating layer by applying titanium oxide to the fluorescent lamp without directly coating the photocatalytic material ( Utility model registration notice No. 20-0341911 (02/03/2004). However, this method also has a problem applicable only to some fluorescent lamps that emit ultraviolet rays in the UV-A wavelength band, and the air purification efficiency is extremely low, and it has a problem that it is inconvenient to use as a lighting lamp because the brightness of the fluorescent lamp is reduced. .

An object of the present invention for solving the above problems is to emit light of a specified wavelength (or wavelength band) using a power source and support a light source unit having a specified appearance and the light source unit inserted from a downward direction. Attachable to the light source unit of a wall type lamp having a socket unit that supplies power and a frame unit having a structure that is coupled to the socket unit and fixed to the wall, and is attached to a designated light source area of the light source unit inserted from the lower direction of the socket unit An attachment structure having an attachment area of a designated geometry as possible and maintaining a state attached to a designated light source area of the light source unit by at least one of structural characteristics and frictional force of the attachment area, and a designated wavelength emitted through the light source unit (or A wall type having a top-down light source including a network structure including a network structure that transmits light of the wavelength band) and a photocatalytic material part formed by coating a designated photocatalytic material in a designated air contact area among the attachment structure and the network structure. It is to provide a photocatalytic module that is attached to and detached from the lamp.

Another object of the present invention is to provide a photocatalyst module detachable to a wall lamp having a top-down type light source that facilitates removal of the photocatalytic module by directly attaching the photocatalytic module to the light source of the wall lamp.

Another object of the present invention is to convective air around the photocatalytic module mounted on the light source unit of the wall lamp to maximize the photocatalytic response of the photocatalytic module mounted on the light source unit, which is attached to and detached from a wall lamp having a top-down type light source. To provide a photocatalytic module.

The photocatalyst module detachably attached to the wall lamp having a top-down type light source according to the present invention emits light of a specified wavelength (or wavelength band) using a power source, and a light source unit having a specified appearance and the light source unit inserted from a downward direction In the photocatalytic module detachable to the light source unit of a wall type lamp having a socket unit supporting and supplying power to the light source unit and a frame unit having a structure that is coupled to the socket unit and fixed to the wall surface, An attachment structure and the light source unit having a designated geometrical attachment area attachable to a designated light source area of the inserted light source unit and maintaining a state attached to the designated light source area of the light source unit by at least one of structural characteristics and frictional force of the attachment area A network structure unit including a network structure that transmits light of a specified wavelength (or wavelength band) emitted through and a photocatalytic material unit formed by coating a designated photocatalytic material in a designated air contact area among the attachment structure and the network structure unit. It features.

In the photocatalytic module detachably attached to a wall lamp having a top-down type light source according to the present invention, the wall type lamp induces light emitted through a light source inserted in the socket to diffuse into a specified range, and the upper region is Further comprising an open lampshade portion, wherein the air contact area includes a region in which heat generated during light emission of the light source unit flows in from a lower side direction of the lampshade unit and can contact air convectively in the direction of the open upper area of the lampshade unit It characterized in that it is made by doing.

In the photocatalytic module detachably attached to a wall lamp having a top-down type light source according to the present invention, the wall type lamp induces light emitted through a light source inserted in the socket to diffuse into a specified range, and the upper region is It further includes a closed lampshade, wherein the air contact area includes a region that is introduced from a lower side of the lampshade and can come into contact with air convectively flowing toward the other lower side of the lampshade.

In the photocatalytic module detachably attached to the wall lamp having a top-down type light source according to the present invention, the light source unit is characterized in that it comprises a light bulb shape.

In the photocatalytic module detachably attached to a wall lamp having a top-down type light source according to the present invention, the designated light source area of the light source unit is a light bulb area corresponding to a maximum diameter area based on a circular cross section of the light bulb type light source unit, and the light bulb type light source unit It is characterized in that it comprises at least one of a light bulb area including a predetermined distance from the maximum diameter area of the light source to the socket unit, and a total light bulb area of the light bulb type light source unit.

In the photocatalytic module detachably attached to the wall lamp having a top-down type light source according to the present invention, the geometric structure comprises: a diameter structure attachable to a designated light source area of a light bulb type light source unit inserted from a downward direction of the socket unit, and the light source unit It is characterized in that it comprises at least one of a curvature structure corresponding to a curvature of a light bulb in a designated light source area and a tilt structure attachable to a designated light source area of the light source unit.

In the photocatalytic module detachably attached to the wall lamp having a top-down type light source according to the present invention, the light source unit is characterized in that it comprises an external shape of a light tube structure.

In the photocatalytic module detachably attached to the wall lamp having a top-down type light source according to the present invention, the designated light source area of the light source unit is a partial light tube area of the light tube included in the light tube structure light source unit, and a light tube included in the light tube structure light source unit It characterized in that it comprises at least one of the entire light tube area of, a partial light tube area of two or more light tubes included in the light tube structure light source unit, and a total light tube area of two or more light tubes included in the light tube structure light source unit.

In the photocatalyst module detachably attached to the wall lamp having a top-down type light source according to the present invention, the geometric structure is a diameter that can be attached to a designated light source area formed in a light tube included in the light tube structure included in the light tube structure inserted in a downward direction of the socket part Structure, a multiple attachment structure capable of multiple attachment to two or more designated light source areas formed in a light tube included in the light tube structure light source unit, a linked attachment structure capable of being linked and attached to each designated light source area formed in two or more light tubes included in the light tube structure light source unit, It characterized in that it comprises at least one structure of the curvature structure corresponding to the specified light tube curvature of the cylindrical light tube.

In the photocatalyst module detachably attached to the wall lamp having a top-down type light source according to the present invention, the attachment area of the attachment structure includes a surface-treated area to increase frictional force with a designated light source area of the light source unit. It is characterized.

In the photocatalytic module detachable to the wall-type lamp having a top-down type light source according to the present invention, the attachment structure part comprises the network structure part.

In the photocatalytic module detachably attached to the wall lamp having a top-down type light source according to the present invention, the attachment structure includes a separate attachment structure connected to the network structure.

In the photocatalytic module detachably attached to the wall lamp having a top-down type light source according to the present invention, the network structure unit maintains a state spaced apart from the light source unit by a predetermined distance or more by an attachment structure attached to the light source unit. do.

In the photocatalyst module that is detachably attached to the wall lamp having a top-down type light source according to the present invention, the attachment structure comprises a material that does not deteriorate when exposed to light and heat of the light source for a specified period of time or longer. do.

In the photocatalyst module detachably attached to the wall lamp having a top-down type light source according to the present invention, the attachment structure unit includes a ductility that increases by more than a maximum cross-sectional size of the light source unit by an external force to be attached to a designated light source area of the light source unit. It is characterized by comprising a material having elasticity to return to the original state when the external force is removed.

In the photocatalytic module detachably attached to a wall-type lamp having a top-down type light source according to the present invention, the material having elasticity is characterized in that it provides elastic force for maintaining the frictional force.

In the photocatalyst module that is detachably attached to the wall lamp having a top-down type light source according to the present invention, the attachment structure unit is deformed by an external force to attach to a designated light source area of the light source unit, and then the external force is removed. It is characterized by comprising a material capable of maintaining a deformed state.

In the photocatalytic module detachably attached to the wall lamp having a top-down type light source according to the present invention, the photocatalytic material part is produced by coating photocatalytic material particles of 30 nm or less on the air contact area.

In the photocatalytic module detachably attached to the wall lamp having a top-down type light source according to the present invention, the photocatalytic material part is generated by coating a designated photocatalytic material after treatment with a designated primer in the air contact area. do.

In the photocatalytic module detachably attached to the wall lamp having a top-down type light source according to the present invention, the optical accumulator material part is generated by surface-treating a silicon (Si) component coating agent on the air contact area and then coating a designated photocatalytic material. It is characterized by being.

In the photocatalytic module detachably attached to a wall lamp having a top-down type light source according to the present invention, the photocatalytic material comprises a material by doping a designated metal element having conductivity in titanium oxide (TiO2). It is characterized.

In the photocatalytic module detachably attached to the wall lamp having a top-down type light source according to the present invention, the metal element is a time when energy is applied to titanium oxide (TiO2) to restore the electrons excited to the conduction band in the valence band. It characterized in that it performs a function of inducing a photocatalytic reaction through the light source unit by delaying.

In the photocatalyst module detachably attached to the wall lamp having a top-down type light source according to the present invention, the metal element is an electron excited by a conduction band in a valence band and a hole formed in the valence band when energy is applied to titanium oxide (TiO 2 ). It characterized in that it performs a function of inducing a photocatalytic reaction through the light source unit by breaking at least a part of the relationship therebetween.

According to the present invention, there is an advantage of purifying air in a space provided with the wall-type lamp while using the wall-type lamp by mounting a photocatalytic module on the light source part of the wall-type lamp.

According to the present invention, there is an advantage of facilitating the removal of the photocatalyst module by directly removing the photocatalyst module from the light source of the wall lamp.

According to the present invention, there is an advantage of maximizing the photocatalytic reaction of the photocatalytic module mounted on the light source unit by convective air around the photocatalytic module mounted on the light source unit of the wall lamp.

According to the present invention, there is an advantage of minimizing the decrease in brightness of the light source by mounting the photocatalytic module in a designated light bulb area of the light source unit excluding an area emitting light to be used as a lighting lamp among the areas of the light source unit of the wall lamp.

According to the present invention, there is an advantage of minimizing the decrease in brightness of the light source by thinly coating particles of a photocatalytic material of 30 nm or less in a designated air contact area of a photocatalytic module mounted on a light source of a wall lamp.

According to the present invention, a photocatalytic reaction of the photocatalytic material coated on the photocatalyst module is generated even when the light source unit of the wall lamp emits light in the ultraviolet wavelength band as well as a small amount or hardly. Regardless of the wavelength band, there is an advantage of purifying the surrounding air during use of the wall lamp.

1 is a block diagram showing the relationship between the wall lamp 100 and the photocatalytic module 130 according to an embodiment of the present invention.
2 is a block diagram showing the relationship between the wall lamp 100 and the photocatalytic module 130 according to an embodiment of the present invention.
3 is a diagram illustrating an embodiment of a photocatalytic module 130 according to an embodiment of the present invention.
4 is a block diagram showing the relationship between the wall lamp 100 and the photocatalytic module 130 according to the embodiment of the present invention.
5 is a block diagram showing the relationship between the wall lamp 100 and the photocatalytic module 130 according to an embodiment of the present invention.
6 is a diagram illustrating an embodiment of a photocatalytic module 130 according to an embodiment of the present invention.
7 is a view showing an embodiment of a process of manufacturing the photocatalytic module 130 according to the embodiment of the present invention.

Hereinafter, the operating principle of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. However, the drawings and the description to be described below are for a preferred implementation method among various methods for effectively describing the features of the present invention, and the present invention is not limited to the following drawings and description.

That is, the following examples correspond to examples of the preferred union form among the numerous examples of the present invention, and examples in which specific configurations are omitted from the following examples, or functions implemented in specific configurations are used as specific configurations. Dividing an embodiment, an embodiment incorporating functions implemented in two or more configurations into any one configuration, an embodiment in which the order of operation of a specific configuration is replaced, etc., all of the present inventions, even if not mentioned separately in the following examples. It is clearly stated that it belongs to the scope of the rights. Accordingly, it is clearly stated that various examples corresponding to a subset or a complementary set may be divided by retrospectively receiving the filing date of the present invention based on the following examples.

In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout the present invention.

As a result, the technical idea of the present invention is determined by the claims, and the following examples are a means for efficiently explaining the technical idea of the present invention to those of ordinary skill in the art to which the present invention belongs. Only.

1 is a block diagram showing the relationship between the wall lamp 100 and the photocatalytic module 130 according to the method of the present invention.

In more detail, the drawing 1 shows the wall lamp 100 while using the wall lamp 100 by attaching and detaching it to the designated light source area of the light source unit 105 provided in the wall lamp 100 fixed to the wall. As a side cross-sectional view of an embodiment of the photocatalytic module 130 for purifying the air in the provided space, those of ordinary skill in the technical field to which the present invention pertains, refer to and/or modify this Figure 1 Thus, various implementation methods for the relationship between the wall lamp 100 and the photocatalytic module 130 (for example, some components are omitted, subdivided, or combined implementation methods) can be inferred. It includes all the inferred implementation methods, and the technical features are not limited only by the implementation method shown in FIG. 1.

Referring to Fig. 1, the wall lamp 100 emits light of a specified wavelength (or wavelength band) using a power source, and a light source unit 105 having a specified appearance and the light source unit 105 inserted from a downward direction. ) To support and supply power to the light source unit 105, and the light emitted through the light source unit 105 inserted into the socket unit 110 to diffuse into a specified range, and the upper area is The open lampshade part 115, the frame part 120 having a structure that is fixed to the wall by being combined with at least one of the socket part 110 and the lampshade part 115, and the frame part 120 are attached to the wall surface. A power supply unit (not shown) that includes a fixing unit 125 for fixing, and applies external power to the socket unit 110 internally, and a switch unit (not shown) that processes on/off of the light source unit 105 Omit).

The light source unit 105 emits light of a specified wavelength using a power source or emits light of a specified wavelength band to emit light, or is a generic term for a component. Preferably, the light source unit 105 preferably includes an external shape of a light bulb. Meanwhile, according to another exemplary method of the present invention, it is obvious that the external shape of the light source unit 105 is not limited to a light bulb shape, and any shape other than the light bulb shape may be included in the scope of the present invention.

According to an exemplary method of the present invention, the light source unit 105 includes a light source (eg, a filament, a light emitting diode (LED), a light tube such as a fluorescent lamp, etc.) designated inside the external shape of a light bulb.

According to an exemplary embodiment of the present invention, the light source unit 105 emits light in a visible wavelength band to emit light, and may emit and emit light in some ultraviolet wavelength band or infrared wavelength band. Preferably, the light source unit 105 emits light in an ultraviolet wavelength band (eg, UV-A wavelength band, etc.) in addition to the visible light wavelength band to emit light. However, in the present invention, the wavelength (or wavelength band) of light emitted by the light source unit 105 is not limited to a specific wavelength (or wavelength band), and if the wavelength (or wavelength band) of the light source used for illumination, the present invention It can be defined as belonging to the scope of rights of

According to the implementation method of the present invention, the light source unit 105 attaches and detaches the photocatalytic module 130, and the photocatalytic module 130 includes a geometric structure previously designed to be detachable to the light source unit 105. Meanwhile, since the photocatalytic module 130 of the present invention is attached to and detached from the top-down light source unit 105 in the form of a top-down light bulb, the lamp having the light source unit 105 is not limited to the wall type lamp 100, and the wall type lamp 100 ) Other than the various types of lamps can also be included in the scope of the present invention.

The socket unit 110 is a generic term for a component that inserts and supports the light source unit 105 and supplies power to the light source unit 105. Preferably, it is preferable that the socket unit 110 inserts and supports the light source unit 105 in a downward direction (eg, a direction corresponding to the earth's gravity direction within a preset error (<90°)).

The lampshade part 115 is a generic term for a component that induces light emitted through the light source part 105 inserted in the socket part 110 to be diffused into a specified range. Preferably, the lampshade part 115 preferably includes a structure in which the upper region is open. On the other hand, in the case of some wall-type lamps 100, the lampshade portion 115 can be omitted, and the present invention clearly reveals that the embodiment in which the lampshade portion 115 is omitted may be included as a scope of rights. Meanwhile, according to another embodiment of the present invention, the lampshade portion 115 may include a structure in which the upper region is closed, and the present invention clearly reveals that this embodiment can also be included in the scope of the rights.

The frame part 120 is coupled to at least one of the socket part 110 and the lampshade part 115 and is combined with a fixing part 125 for fixing a wall surface, so that the light source part 105 and the socket part 110 and the lampshade It is a generic term for a component that positions the part 115 and the like at a certain height.

Referring to FIG. 1, the photocatalytic module 130 has an attachment area of a designated geometry that can be attached to a designated light source area of the light source unit 105 inserted in a downward direction of the socket unit 110, and An attachment structure 135 that maintains a state attached to a designated light source area of the light source unit 105 by at least one of structural characteristics and frictional force, and light of a designated wavelength (or wavelength band) emitted through the light source unit 105 A network structure unit 145 including a network structure that transmits light, and a photocatalytic material unit 140 formed by coating a designated photocatalytic material in a designated air contact area among the areas of the attachment structure unit 135 and the network structure unit 145. do. On the other hand, for convenience, FIG. 1 shows an embodiment in which the photocatalytic module 130 is attached to the light source unit 105 as illustrated in FIG. 3 to describe the technical characteristics of the photocatalytic module 130, but the photocatalyst according to the present invention It should be clearly noted that the geometry of the module 130 is not limited to the example of FIG. 3.

The attachment structure 135 includes an attachment area having a designated geometry that can be attached to a designated light source area of the light source unit 105 inserted in the downward direction of the socket unit 110. The light source unit 105 includes an external shape of a light bulb, and preferably, a designated light source area of the light source unit 105 is a light bulb area corresponding to a maximum diameter area based on a circular cross section of the light bulb shape light source unit 105, and the light bulb shape A light bulb area including a predetermined distance from the maximum diameter area of the light source unit 105 toward the socket unit 110 and at least one of the entire light bulb area of the light bulb-shaped light source unit 105 may be included. Meanwhile, when the designated light bulb area includes the entire light bulb area of the light bulb-shaped light source unit 105, the attachment structure 135 includes a certain number of light emitted from the light source unit 105 to be directly radiated to the outside (or It is preferable that the hole of the area) is formed.

According to an embodiment of the present invention, the geometrical structure attachable to the designated light source area includes a diameter structure attachable to the designated light source area of the bulb-shaped light source unit 105 inserted in the socket unit 110 from a downward direction, and the light source unit 105 ), a curvature structure corresponding to the curvature of the bulb of the designated light source region of the light source unit 105, and a tilt structure attachable to the designated light source region of the light source unit 105 may include at least one geometric structure.

Meanwhile, the geometric structure of the attachment structure 135 may further include at least one of a geometric structure that is not exposed to an open upper area of the lampshade and a geometric structure that is not exposed to a lower side area of the lampshade.

According to an exemplary embodiment of the present invention, the attachment area of the attachment structure 135 may include a surface-treated area to increase the frictional force of the light source unit 105 with a designated light bulb area.

According to an embodiment of the present invention, the attachment structure 135 may include the network structure 145. For example, when the attachment structure 135 and the network structure 145 are integrated, both the attachment structure 135 and the net structure 145 may be attached to the light source unit 105.

According to an exemplary method of the present invention, the attachment structure 135 may include a separate attachment structure connected to the network structure 145. For example, the attachment structure 135 and the net structure 145 are separately configured, so that only the attachment structure 135 is attached to the light source unit 105, and the net structure unit 145 is not attached to the light source unit 105, but at a predetermined interval. You can maintain a more separated state.

According to an exemplary method of the present invention, the network structure part 145 may maintain a state spaced apart from the light source part 105 by a predetermined distance or more by the attachment structure part 135 attached to the light source part 105.

According to an exemplary method of the present invention, the attachment structure 135 includes a transparent material that transmits light from the light source unit 105. Accordingly, the light emitted by the light source unit 105 may pass through the attachment structure 135 and reach the photocatalyst material unit.

According to an embodiment of the present invention, the attachment structure 135 includes light emitted from the light source unit 105 and heat generated during light emission of the light source unit 105 (e.g., at least 25°C or more and a maximum of about 300°C. It is desirable to include a material that does not deteriorate even when exposed for a long period of time for longer than the period specified in heat). Preferably, the attachment structure 135 includes a material that does not deteriorate in transparency even when exposed to light and heat of the light source unit 105 for a long period of time. For example, the attachment structure 135 is processed to be transparent and includes a material processed to have durability against light and heat (e.g., PE (Poly Ethylene), nylon, CPI (Clearance Poly Imide), Teflon, etc.) can do.

According to the first material embodiment of the present invention, the attachment structure 135 has a specified range of ductility that extends without being damaged to a specified range by an external force, and a specified range of elasticity to return to its original state when the external force is removed. It may contain a material having Preferably, the attachment structure 135 is attached to the designated light source area of the light source unit 105 by an external force, so that the ductility increases by more than the maximum sectional area size of the light source unit 105 and the external force is removed. It may contain a material having elasticity to return. On the other hand, in this case, the geometric structure attachable to the designated light source area includes a diameter smaller than or equal to the minimum diameter based on the circular cross section of the designated light source area of the light source unit 105 in a state where no external force is applied. It includes at least one of a diameter structure attachable to the designated light source area of 105, a curvature structure corresponding to the designated light bulb curvature of the designated light source area, and a tilt structure attachable to the designated light source area of the light source unit 105 can do. Meanwhile, the elastic material may provide an elastic force for maintaining the frictional force required to attach the photocatalytic module 130 to a designated light bulb area of the light source unit 105.

According to the second material embodiment of the present invention, the attachment structure 135 is deformed by an external force to be attached to a designated light source area of the light source unit 105 and then maintains the deformed state while the external force is removed. It may contain possible materials.

According to the third material embodiment of the present invention, the attachment structure 135 may include a material that at least partially combines the first to second material embodiments.

According to the implementation method of the present invention, the attachment structure 135 may include an air contact area of a designated area for contacting air in a designated area of the surface area, and in this case, the designated air contact of the attachment structure 135 The photocatalytic material part 140 may be formed by coating a photocatalytic material designated on the region. Meanwhile, the air contact area is introduced from the lower side of the lampshade 115 by heat generated during light emission of the light source unit 105 and contacts air convectively in the direction of the open upper area of the lampshade unit 115 It may include possible areas.

The photocatalytic material part 140 is a generic term for a component formed by coating a designated photocatalytic material on a designated air contact area, and is preferably formed by coating a designated photocatalytic material on a designated air contact area among the areas of the attachment structure 135. . Here, the photocatalyst material includes titanium oxide (TiO2).

According to an exemplary method of the present invention, the photocatalytic material part 140 may be formed by coating a photocatalytic material particle of 30 nm or less in a designated air contact area of the attachment structure 135. According to the present invention, no matter how transparent the material of the attachment structure 135 is, since titanium oxide (TiO2) contained in the photocatalytic material is an opaque material used as a raw material for a white pigment, the photocatalytic material is coated. Even in a state where the photocatalytic module 130 is attached to the light source unit 105, in order to minimize the reduction in brightness of light by the photocatalytic material, the photocatalytic material should be thinly coated on the designated air contact area. It is preferable that the size of the photocatalytic material particles is 30 nm or less.

According to the implementation method of the present invention, the photocatalytic material part 140 does not damage the transparency of the attachment structure 135 or the contact structure in a designated air contact area of the attachment structure 135 (or minimizes transparency damage). In addition, after treatment with a designated primer so that the photocatalytic material is easily coated on the air contact area, it may be generated by coating a designated photocatalytic material on the primer-treated air contact area.

According to the implementation method of the present invention, the photocatalytic material part 140 may be produced by surface-treating a transparent silicon (Si)-based coating agent on a designated air contact area of the attachment structure part 135 and then coating a designated photocatalytic material. . Here, the silicon (Si) component is used as a raw material for transparent glass, as well as a material that is safe for photocatalytic reaction of titanium oxide (TiO2), so if the coating agent of the silicon (Si) component does not damage the transparency of the air contact area In addition, it is possible to prevent the photocatalytic material from causing a catalytic reaction to the attachment structure 135 or the material of the contact structure, as well as treatment so that the photocatalytic material stably maintains a coating state in the air contact area.

On the other hand, titanium oxide (TiO2) contained in the photocatalytic material is activated in the UV-A wavelength band (for example, 315 to 400 nm wavelength band), and the light source unit 105 is not a light source for photocatalytic reaction, but a conventional illumination Since it includes a light source for the UV-A wavelength band, or even if the UV-A wavelength band is radiated, a small amount may be emitted. Accordingly, according to the method of the present invention, the photocatalytic material has conductivity in titanium oxide (TiO2) in order to induce a photocatalytic reaction even if the light in the UV-A wavelength band is not emitted from the light source unit 105 or a small amount is radiated. It can be manufactured in the form of a material doped with a designated metal element.

The photocatalytic reaction of the photocatalytic material occurs through the process of restoring the electrons excitation from the valence band to the conduction band by applying light energy to titanium oxide (TiO2) to its original state. On the other hand, normally, electrons excited to the conduction band in the valence band are restored to the valence band in a time period of about 10^-6 seconds. No reaction may occur. On the other hand, when light in the UV-A wavelength band is applied to titanium oxide (TiO2), the electrons excited in the valence band are restored to the valence band slower than the 10^-6 seconds, thereby causing a photocatalytic reaction.

Meanwhile, according to the embodiment of the present invention, the photocatalytic material may be prepared by doping titanium oxide (TiO2) with a designated metal element having conductivity. In this case, the metal element doped with titanium oxide (TiO2) is titanium oxide ( Light energy is applied to TiO2) to delay (e.g., delay a 10^-3 second time period) the time (Life Time) at which the excited electrons are restored to their original state in the valence band and/or the conduction band in the valence band. Breaking at least some of the relationship between the electrons excited by the valence band and the holes formed in the valence band (e.g., the electrons excited by the conduction band in the valence band become free electrons and move to the metal element, so that the valence band The relationship between the electron excited by the conduction band at and the hole formed in the valence band is broken. In this case, the electron restored to the valence band in the conduction band may be an electron other than the excited electron, and through this process, the conduction band in the valence band The time for restoring the excited electrons to the original state is delayed), so that the light source unit 105 of a wavelength band other than a specific wavelength band (eg, UV-A wavelength band) designated for the photocatalytic reaction of the titanium oxide (TiO 2) It is also possible to perform the function of inducing a photocatalytic reaction through. According to the implementation method of the present invention, the metal element may include metal elements having various conductivity, such as gold (Au), silver (Ag), copper (Cu), aluminum (Al), etc., preferably silver (Ag) It may contain elements.

2 is a block diagram showing the relationship between the wall lamp 100 and the photocatalytic module 130 according to the method of the present invention.

In more detail, Figure 2 shows the wall lamp 100 while using the wall lamp 100 by attaching and detaching it to the designated light source area of the light source unit 105 provided in the wall lamp 100 fixed to the wall. As a side cross-sectional view of an embodiment of the photocatalytic module 130 that purifies the air in the provided space, those of ordinary skill in the art to which the present invention pertains, refer to and/or modify this Figure 2 Thus, various implementation methods for the relationship between the wall lamp 100 and the photocatalytic module 130 (for example, some components are omitted, subdivided, or combined implementation methods) can be inferred. It includes all the inferred implementation methods, and the technical features are not limited only by the implementation method shown in FIG. 2.

Referring to FIG. 2, the wall lamp 100 emits light of a specified wavelength (or wavelength band) using a power source, and a light source unit 105 having a specified appearance and the light source unit 105 inserted from a downward direction. ) To support and supply power to the light source unit 105, and the light emitted through the light source unit 105 inserted into the socket unit 110 to diffuse into a specified range, and the upper area is A frame part 120 having a structure that is fixed to the wall by being coupled to at least one of the closed lampshade part 115, the socket part 110 and the lampshade part 115, and the frame part 120 on the wall. A power supply unit (not shown) that includes a fixing unit 125 for fixing, and applies external power to the socket unit 110 internally, and a switch unit (not shown) that processes on/off of the light source unit 105 Omit).

The light source unit 105 emits light of a specified wavelength using a power source or emits light of a specified wavelength band to emit light, or is a generic term for a component. Preferably, the light source unit 105 preferably includes an external shape of a light bulb. Meanwhile, according to another exemplary method of the present invention, it is obvious that the external shape of the light source unit 105 is not limited to a light bulb shape, and any shape other than the light bulb shape may be included in the scope of the present invention.

According to an exemplary method of the present invention, the light source unit 105 includes a light source (eg, a filament, a light emitting diode (LED), a light tube such as a fluorescent lamp, etc.) designated inside the external shape of a light bulb.

According to an exemplary embodiment of the present invention, the light source unit 105 emits light in a visible wavelength band to emit light, and may emit and emit light in some ultraviolet wavelength band or infrared wavelength band. Preferably, the light source unit 105 emits light in an ultraviolet wavelength band (eg, UV-A wavelength band, etc.) in addition to the visible light wavelength band to emit light. However, in the present invention, the wavelength (or wavelength band) of light emitted by the light source unit 105 is not limited to a specific wavelength (or wavelength band), and if the wavelength (or wavelength band) of the light source used for illumination, the present invention It can be defined as belonging to the scope of rights of

According to the implementation method of the present invention, the light source unit 105 attaches and detaches the photocatalytic module 130, and the photocatalytic module 130 includes a geometric structure previously designed to be detachable to the light source unit 105. Meanwhile, since the photocatalytic module 130 of the present invention is attached to and detached from the top-down light source unit 105 in the form of a top-down light bulb, the lamp having the light source unit 105 is not limited to the wall type lamp 100, and the wall type lamp 100 ) Other than the various types of lamps can also be included in the scope of the present invention.

The socket unit 110 is a generic term for a component that inserts and supports the light source unit 105 and supplies power to the light source unit 105. Preferably, it is preferable that the socket unit 110 inserts and supports the light source unit 105 in a downward direction (eg, a direction corresponding to the earth's gravity direction within a preset error (<90°)).

The lampshade part 115 is a generic term for a component that induces light emitted through the light source part 105 inserted in the socket part 110 to be diffused into a specified range. Preferably, the lampshade part 115 preferably includes a structure in which the upper region is closed. On the other hand, in the case of some wall-type lamps 100, the lampshade portion 115 can be omitted, and the present invention clearly reveals that the embodiment in which the lampshade portion 115 is omitted may be included as a scope of rights. On the other hand, according to another embodiment of the present invention, it is possible for the lampshade part 115 to include a structure in which the upper region is open, and the present invention clearly reveals that this embodiment can also be included in the scope of the rights.

The frame part 120 is coupled to at least one of the socket part 110 and the lampshade part 115 and is combined with a fixing part 125 for fixing a wall surface, so that the light source part 105 and the socket part 110 and the lampshade It is a generic term for a component that positions the part 115 and the like at a certain height.

Referring to FIG. 2, the photocatalytic module 130 has an attachment area of a designated geometry that can be attached to a designated light source area of the light source unit 105 inserted from a downward direction of the socket unit 110, and An attachment structure 135 that maintains a state attached to a designated light source area of the light source unit 105 by at least one of structural characteristics and frictional force, and light of a designated wavelength (or wavelength band) emitted through the light source unit 105 A network structure unit 145 including a network structure that transmits light, and a photocatalytic material unit 140 formed by coating a designated photocatalytic material in a designated air contact area among the areas of the attachment structure unit 135 and the network structure unit 145. do. On the other hand, for convenience, Fig. 2 shows an embodiment in which the photocatalytic module 130 is attached to the light source unit 105 as in the example of Fig. 3 and describes the technical characteristics of the photocatalytic module 130, but the photocatalyst according to the present invention It should be clearly noted that the geometry of the module 130 is not limited to the example of FIG. 3.

The attachment structure 135 includes an attachment area having a designated geometry that can be attached to a designated light source area of the light source unit 105 inserted in the downward direction of the socket unit 110. The light source unit 105 includes an external shape of a light bulb, and preferably, the designated light source area of the light bulb type light source unit 105 is a light bulb area corresponding to a maximum diameter area based on a circular cross section of the light bulb type light source unit 105, the It may include at least one of a bulb region including a predetermined distance from the maximum diameter region of the bulb-shaped light source unit 105 toward the socket unit 110 and the entire bulb region of the bulb-shaped light source unit 105. Meanwhile, when the designated light bulb area includes the entire light bulb area of the light bulb-shaped light source unit 105, the attachment structure 135 includes a certain number of light emitted from the light source unit 105 to be directly radiated to the outside (or It is preferable that the hole of the area) is formed.

According to an embodiment of the present invention, the geometrical structure attachable to the designated light source area includes a diameter structure attachable to the designated light source area of the bulb-shaped light source unit 105 inserted in the socket unit 110 from a downward direction, and the light source unit 105 ), a curvature structure corresponding to the curvature of the bulb of the designated light source region of the light source unit 105, and a tilt structure attachable to the designated light source region of the light source unit 105 may include at least one geometric structure.

Meanwhile, the geometric structure of the attachment structure 135 may further include at least one of geometric structures that are not exposed to the lower side area of the lampshade.

According to an exemplary embodiment of the present invention, the attachment area of the attachment structure 135 may include a surface-treated area to increase the frictional force of the light source unit 105 with a designated light bulb area.

According to an embodiment of the present invention, the attachment structure 135 may include the network structure 145. For example, when the attachment structure 135 and the network structure 145 are integrated, both the attachment structure 135 and the net structure 145 may be attached to the light source unit 105.

According to an exemplary method of the present invention, the attachment structure 135 may include a separate attachment structure connected to the network structure 145. For example, the attachment structure 135 and the net structure 145 are separately configured, so that only the attachment structure 135 is attached to the light source unit 105, and the net structure unit 145 is not attached to the light source unit 105, but at a predetermined interval. You can maintain a more separated state.

According to an exemplary method of the present invention, the network structure part 145 may maintain a state spaced apart from the light source part 105 by a predetermined distance or more by the attachment structure part 135 attached to the light source part 105.

According to an exemplary method of the present invention, the attachment structure 135 includes a transparent material that transmits light from the light source unit 105. Accordingly, the light emitted by the light source unit 105 may pass through the attachment structure 135 and reach the photocatalyst material unit.

According to an embodiment of the present invention, the attachment structure 135 includes light emitted from the light source unit 105 and heat generated during light emission of the light source unit 105 (e.g., at least 25°C or more and a maximum of about 300°C. It is desirable to include a material that does not deteriorate even when exposed for a long period of time for longer than the period specified in heat). Preferably, the attachment structure 135 includes a material that does not deteriorate in transparency even when exposed to light and heat of the light source unit 105 for a long period of time. For example, the attachment structure 135 is processed to be transparent and includes a material processed to have durability against light and heat (e.g., PE (Poly Ethylene), nylon, CPI (Clearance Poly Imide), Teflon, etc.) can do.

According to the first material embodiment of the present invention, the attachment structure 135 has a specified range of ductility that extends without being damaged to a specified range by an external force, and a specified range of elasticity to return to its original state when the external force is removed. It may contain a material having Preferably, the attachment structure 135 is attached to the designated light source area of the light source unit 105 by an external force, so that the ductility increases by more than the maximum sectional area size of the light source unit 105 and the external force is removed. It may contain a material having elasticity to return. On the other hand, in this case, the geometric structure attachable to the designated light source area includes a diameter smaller than or equal to the minimum diameter based on the circular cross section of the designated light source area of the light source unit 105 in a state where no external force is applied. It includes at least one of a diameter structure attachable to the designated light source area of 105, a curvature structure corresponding to the designated light bulb curvature of the designated light source area, and a tilt structure attachable to the designated light source area of the light source unit 105 can do. Meanwhile, the elastic material may provide an elastic force for maintaining the frictional force required to attach the photocatalytic module 130 to a designated light bulb area of the light source unit 105.

According to the second material embodiment of the present invention, the attachment structure 135 is deformed by an external force to be attached to a designated light source area of the light source unit 105 and then maintains the deformed state while the external force is removed. It may contain possible materials.

According to the third material embodiment of the present invention, the attachment structure 135 may include a material that at least partially combines the first to second material embodiments.

According to the implementation method of the present invention, the attachment structure 135 may include an air contact area of a designated area for contacting air in a designated area of the surface area, and in this case, the designated air contact of the attachment structure 135 The photocatalytic material part 140 may be formed by coating a photocatalytic material designated on the region. Meanwhile, the air contact area may include an area that is introduced from the lower side of the lampshade 115 and can contact air convectively flowing in the lower side of the lampshade 115.

The photocatalytic material part 140 is a generic term for a component formed by coating a designated photocatalytic material on a designated air contact area, and is preferably formed by coating a designated photocatalytic material on a designated air contact area among the areas of the attachment structure 135. . Here, the photocatalyst material includes titanium oxide (TiO2).

According to an exemplary method of the present invention, the photocatalytic material part 140 may be formed by coating a photocatalytic material particle of 30 nm or less in a designated air contact area of the attachment structure 135. According to the present invention, no matter how transparent the material of the attachment structure 135 is, since titanium oxide (TiO2) contained in the photocatalytic material is an opaque material used as a raw material for a white pigment, the photocatalytic material is coated. Even in a state where the photocatalytic module 130 is attached to the light source unit 105, in order to minimize the reduction in brightness of light by the photocatalytic material, the photocatalytic material should be thinly coated on the designated air contact area. It is preferable that the size of the photocatalytic material particles is 30 nm or less.

According to the implementation method of the present invention, the photocatalytic material part 140 does not damage the transparency of the attachment structure 135 or the contact structure in a designated air contact area of the attachment structure 135 (or minimizes transparency damage). In addition, after treatment with a designated primer so that the photocatalytic material is easily coated on the air contact area, it may be generated by coating a designated photocatalytic material on the primer-treated air contact area.

According to the implementation method of the present invention, the photocatalytic material part 140 may be produced by surface-treating a transparent silicon (Si)-based coating agent on a designated air contact area of the attachment structure part 135 and then coating a designated photocatalytic material. . Here, the silicon (Si) component is used as a raw material for transparent glass, as well as a material that is safe for photocatalytic reaction of titanium oxide (TiO2), so if the coating agent of the silicon (Si) component does not damage the transparency of the air contact area In addition, it is possible to prevent the photocatalytic material from causing a catalytic reaction to the attachment structure 135 or the material of the contact structure, as well as treatment so that the photocatalytic material stably maintains a coating state in the air contact area.

On the other hand, titanium oxide (TiO2) contained in the photocatalytic material is activated in the UV-A wavelength band (for example, 315 to 400 nm wavelength band), and the light source unit 105 is not a light source for photocatalytic reaction, but a conventional illumination Since it includes a light source for the UV-A wavelength band, or even if the UV-A wavelength band is radiated, a small amount may be emitted. Accordingly, according to the method of the present invention, the photocatalytic material has conductivity in titanium oxide (TiO2) in order to induce a photocatalytic reaction even if the light in the UV-A wavelength band is not emitted from the light source unit 105 or a small amount is radiated. It can be manufactured in the form of a material doped with a designated metal element.

The photocatalytic reaction of the photocatalytic material occurs through the process of restoring the electrons excitation from the valence band to the conduction band by applying light energy to titanium oxide (TiO2) to its original state. On the other hand, normally, electrons excited to the conduction band in the valence band are restored to the valence band in a time period of about 10^-6 seconds. No reaction may occur. On the other hand, when light in the UV-A wavelength band is applied to titanium oxide (TiO2), the electrons excited in the valence band are restored to the valence band slower than the 10^-6 seconds, thereby causing a photocatalytic reaction.

Meanwhile, according to the embodiment of the present invention, the photocatalytic material may be prepared by doping titanium oxide (TiO2) with a designated metal element having conductivity. In this case, the metal element doped with titanium oxide (TiO2) is titanium oxide ( Light energy is applied to TiO2) to delay (e.g., delay a 10^-3 second time period) the time (Life Time) at which the excited electrons are restored to their original state in the valence band and/or the conduction band in the valence band. Breaking at least some of the relationship between the electrons excited by the valence band and the holes formed in the valence band (e.g., the electrons excited by the conduction band in the valence band become free electrons and move to the metal element, so that the valence band The relationship between the electron excited by the conduction band at and the hole formed in the valence band is broken. In this case, the electron restored to the valence band in the conduction band may be an electron other than the excited electron, and through this process, the conduction band in the valence band The time for restoring the excited electrons to the original state is delayed), so that the light source unit 105 of a wavelength band other than a specific wavelength band (eg, UV-A wavelength band) designated for the photocatalytic reaction of the titanium oxide (TiO 2) It is also possible to perform the function of inducing a photocatalytic reaction through. According to the implementation method of the present invention, the metal element may include metal elements having various conductivity, such as gold (Au), silver (Ag), copper (Cu), aluminum (Al), etc., preferably silver (Ag) It may contain elements.

3 is a diagram illustrating an embodiment of a photocatalytic module 130 according to an embodiment of the present invention.

In more detail, FIG. 3 is an attachment structure including a material having elasticity to return to its original state when the external force is removed and the ductility that increases by an external force by more than the maximum cross-sectional size of the light bulb included in the light source unit 105 ( 135) is illustrated in a side cross-sectional view of the photocatalytic module 130 attached to the designated light bulb area of the light source unit 105 through frictional force generated by the elasticity, and the technical field to which the present invention belongs In the case of those of ordinary skill in the art, various embodiments of implementing the photocatalytic module 130 may be inferred by referring to and/or modifying this Figure 3, but the present invention includes all the inferred embodiments. It is made, and the technical features are not limited only to the embodiment illustrated in FIG. 3.

Referring to the embodiment of FIG. 3, the photocatalytic module 130 exhibits ductility that increases by more than the maximum cross-sectional area of the light bulb included in the light source unit 105 due to an external force, and elasticity to return to its original state when the external force is removed. A frictional force is provided to attach the photocatalyst module 130 to a designated light bulb area of the light source unit 105 by elasticity of the material of the attachment structure 135, including an attachment structure 135 made of a material.

Meanwhile, an attachment area attached to a designated light bulb area of the light source unit 105 is formed inside the attachment structure 135, and a designated photocatalytic material is coated on the air contact area formed outside the attachment structure 135 to form a photocatalytic material. Form part 140.

4 is a block diagram showing the relationship between the wall lamp 100 and the photocatalytic module 130 according to the method of the present invention.

In more detail, Figure 4 shows the wall lamp 100 while using the wall lamp 100 by attaching and detaching it to the designated light source area of the light source unit 105 provided in the wall lamp 100 fixed to the wall. As a side cross-sectional view of an embodiment of the photocatalytic module 130 for purifying air in the provided space, those of ordinary skill in the art to which the present invention pertains, refer to Figure 4 and/or modify Thus, various implementation methods for the relationship between the wall lamp 100 and the photocatalytic module 130 (for example, some components are omitted, subdivided, or combined implementation methods) can be inferred. It includes all the inferred implementation methods, and the technical features are not limited only by the implementation method shown in FIG. 4.

Referring to Fig. 4, the wall lamp 100 emits light of a specified wavelength (or wavelength band) using a power source, and a light source unit 105 having a specified appearance and the light source unit 105 inserted from a downward direction. ) To support and supply power to the light source unit 105, and the light emitted through the light source unit 105 inserted into the socket unit 110 to diffuse into a specified range, and the upper area is The open lampshade part 115, the frame part 120 having a structure that is fixed to the wall by being combined with at least one of the socket part 110 and the lampshade part 115, and the frame part 120 are attached to the wall surface. A power supply unit (not shown) that includes a fixing unit 125 for fixing, and applies external power to the socket unit 110 internally, and a switch unit (not shown) that processes on/off of the light source unit 105 Omit).

The light source unit 105 emits light of a specified wavelength using a power source or emits light of a specified wavelength band to emit light, or is a generic term for a component. Preferably, the light source unit 105 preferably includes a light tube structure. On the other hand, according to another embodiment of the present invention, the external shape of the light source unit 105 is not limited to the light tube structure, it is clearly revealed that any form other than the light tube structure may be included in the scope of the present invention.

According to an exemplary method of the present invention, the light source unit 105 includes a light source that emits light of a specified wavelength (or wavelength band) inside the tube structure.

According to an exemplary embodiment of the present invention, the light source unit 105 emits light in a visible wavelength band to emit light, and may emit and emit light in some ultraviolet wavelength band or infrared wavelength band. Preferably, the light source unit 105 emits light in an ultraviolet wavelength band (eg, UV-A wavelength band, etc.) in addition to the visible light wavelength band to emit light. However, in the present invention, the wavelength (or wavelength band) of light emitted by the light source unit 105 is not limited to a specific wavelength (or wavelength band), and if the wavelength (or wavelength band) of the light source used for illumination, the present invention It can be defined as belonging to the scope of rights of

According to the implementation method of the present invention, the light source unit 105 attaches and detaches the photocatalytic module 130, and the photocatalytic module 130 includes a geometric structure previously designed to be detachable to the light source unit 105. On the other hand, since the photocatalytic module 130 of the present invention is attached to and detached from the light source unit 105 having a top-down light tube structure, the lamp having the light source unit 105 is not limited to the wall type lamp 100, and the wall type lamp 100 ) Other than the various types of lamps can also be included in the scope of the present invention.

The socket unit 110 is a generic term for a component that inserts and supports the light source unit 105 and supplies power to the light source unit 105. Preferably, it is preferable that the socket unit 110 inserts and supports the light source unit 105 in a downward direction (eg, a direction corresponding to the earth's gravity direction within a preset error (<90°)).

The lampshade part 115 is a generic term for a component that induces light emitted through the light source part 105 inserted in the socket part 110 to be diffused into a specified range. Preferably, the lampshade part 115 preferably includes a structure in which the upper region is open. On the other hand, in the case of some wall-type lamps 100, the lampshade portion 115 can be omitted, and the present invention clearly reveals that the embodiment in which the lampshade portion 115 is omitted may be included as a scope of rights. Meanwhile, according to another embodiment of the present invention, the lampshade portion 115 may include a structure in which the upper region is closed, and the present invention clearly reveals that this embodiment can also be included in the scope of the rights.

The frame part 120 is coupled to at least one of the socket part 110 and the lampshade part 115 and is combined with a fixing part 125 for fixing a wall surface, so that the light source part 105 and the socket part 110 and the lampshade It is a generic term for a component that positions the part 115 and the like at a certain height.

Referring to FIG. 4, the photocatalytic module 130 has an attachment area of a designated geometry that can be attached to a designated light source area of the light source unit 105 inserted from a downward direction of the socket unit 110, and An attachment structure 135 that maintains a state attached to a designated light source area of the light source unit 105 by at least one of structural characteristics and frictional force, and light of a designated wavelength (or wavelength band) emitted through the light source unit 105 A network structure unit 145 including a network structure that transmits light, and a photocatalytic material unit 140 formed by coating a designated photocatalytic material in a designated air contact area among the areas of the attachment structure unit 135 and the network structure unit 145. do. On the other hand, for convenience, FIG. 4 illustrates an embodiment in which the photocatalytic module 130 is attached to the light source unit 105 as illustrated in FIG. 6 to describe the technical characteristics of the photocatalytic module 130, but the photocatalyst according to the invention It is obvious that the geometry of the module 130 is not limited to the example of FIG. 6.

The attachment structure 135 includes an attachment area having a designated geometry that can be attached to a designated light source area of the light source unit 105 inserted in the downward direction of the socket unit 110. The light source unit 105 includes an external shape of a light tube structure, and preferably, a designated light source area of the light source unit 105 is a partial light tube area of a light tube included in the light tube structure light source unit 105, and the light tube structure light source unit 105 At least one of the entire light tube area of the light tube included in the light tube, some light tube areas of two or more light tubes included in the light tube structure light source unit 105, and the total light tube area of two or more light tubes included in the light tube structure light source unit 105 It can include areas. On the other hand, when the designated light source area includes the entire light tube area of the light tube structure light source unit 105, the attachment structure 135 includes a certain number of light emitted from the light source unit 105 to be directly radiated to the outside (or It is preferable that the hole of the area) is formed.

According to the implementation method of the present invention, the geometric structure attachable to a designated light source area has a diameter structure attachable to a designated light source area formed in a light tube included in the socket part 110 in a downward direction. (For example, when the photocatalytic module 130 is attached to a single light tube, etc.), a multiple attachment structure capable of multiple attachment to two or more designated light source regions formed in a light tube included in the light tube structure light source unit 105, the light tube structure light source unit ( 105), a linkage attachment structure that can be linked and attached to each designated light source area formed in two or more light tubes included in), a curvature structure corresponding to the designated light tube curvature of a cylindrical light tube (for example, a photocatalytic module 130 is attached to any one light tube It may include at least one geometric structure of the case where light from the attached light tube is irradiated or the light tube is attached to one light tube and is irradiated with light from a plurality of light tubes.

Meanwhile, the geometric structure of the attachment structure 135 may further include at least one of a geometric structure that is not exposed to an open upper area of the lampshade and a geometric structure that is not exposed to a lower side area of the lampshade.

According to an exemplary embodiment of the present invention, the attachment area of the attachment structure 135 may include a surface-treated area to increase the frictional force of the light source unit 105 with a designated light tube area.

According to an embodiment of the present invention, the attachment structure 135 may include the network structure 145. For example, when the attachment structure 135 and the network structure 145 are integrated, both the attachment structure 135 and the net structure 145 may be attached to the light source unit 105.

According to an exemplary method of the present invention, the attachment structure 135 may include a separate attachment structure connected to the network structure 145. For example, the attachment structure 135 and the net structure 145 are separately configured, so that only the attachment structure 135 is attached to the light source unit 105, and the net structure unit 145 is not attached to the light source unit 105, but at a predetermined interval. You can maintain a more separated state.

According to an exemplary method of the present invention, the network structure part 145 may maintain a state spaced apart from the light source part 105 by a predetermined distance or more by the attachment structure part 135 attached to the light source part 105.

According to an exemplary method of the present invention, the attachment structure 135 includes a transparent material that transmits light from the light source unit 105. Accordingly, the light emitted by the light source unit 105 may pass through the attachment structure 135 and reach the photocatalyst material unit.

According to an embodiment of the present invention, the attachment structure 135 includes light emitted from the light source unit 105 and heat generated during light emission of the light source unit 105 (e.g., at least 25°C or more and a maximum of about 300°C. It is desirable to include a material that does not deteriorate even when exposed for a long period of time for longer than the period specified in heat). Preferably, the attachment structure 135 includes a material that does not deteriorate in transparency even when exposed to light and heat of the light source unit 105 for a long period of time. For example, the attachment structure 135 is processed to be transparent and includes a material processed to have durability against light and heat (e.g., PE (Poly Ethylene), nylon, CPI (Clearance Poly Imide), Teflon, etc.) can do.

According to the first material embodiment of the present invention, the attachment structure 135 has a specified range of ductility that extends without being damaged to a specified range by an external force, and a specified range of elasticity to return to its original state when the external force is removed. It may contain a material having Preferably, the attachment structure 135 is attached to the designated light source area of the light source unit 105 by an external force, so that the ductility increases by more than the maximum sectional area size of the light source unit 105 and the external force is removed. It may contain a material having elasticity to return. On the other hand, in this case, the geometric structure attachable to the designated light source area includes a diameter smaller than or equal to the minimum diameter based on the circular cross section of the designated light source area of the light source unit 105 in a state where no external force is applied. It includes at least one of a diameter structure attachable to the designated light source area of 105, a curvature structure corresponding to the designated light bulb curvature of the designated light source area, and a tilt structure attachable to the designated light source area of the light source unit 105 can do. Meanwhile, the elastic material may provide an elastic force for maintaining the frictional force required to attach the photocatalytic module 130 to a designated light bulb area of the light source unit 105.

According to the second material embodiment of the present invention, the attachment structure 135 is deformed by an external force to be attached to a designated light source area of the light source unit 105 and then maintains the deformed state while the external force is removed. It may contain possible materials.

According to the third material embodiment of the present invention, the attachment structure 135 may include a material that at least partially combines the first to second material embodiments.

According to the implementation method of the present invention, the attachment structure 135 may include an air contact area of a designated area for contacting air in a designated area of the surface area, and in this case, the designated air contact of the attachment structure 135 The photocatalytic material part 140 may be formed by coating a photocatalytic material designated on the region. Meanwhile, the air contact area is introduced from the lower side of the lampshade 115 by heat generated during light emission of the light source unit 105 and contacts air convectively in the direction of the open upper area of the lampshade unit 115 It may include possible areas.

The photocatalytic material part 140 is a generic term for a component formed by coating a designated photocatalytic material on a designated air contact area, and is preferably formed by coating a designated photocatalytic material on a designated air contact area among the areas of the attachment structure 135. . Here, the photocatalyst material includes titanium oxide (TiO2).

According to an exemplary method of the present invention, the photocatalytic material part 140 may be formed by coating a photocatalytic material particle of 30 nm or less in a designated air contact area of the attachment structure 135. According to the present invention, no matter how transparent the material of the attachment structure 135 is, since titanium oxide (TiO2) contained in the photocatalytic material is an opaque material used as a raw material for a white pigment, the photocatalytic material is coated. Even in a state where the photocatalytic module 130 is attached to the light source unit 105, in order to minimize the reduction in brightness of light by the photocatalytic material, the photocatalytic material should be thinly coated on the designated air contact area. It is preferable that the size of the photocatalytic material particles is 30 nm or less.

According to the implementation method of the present invention, the photocatalytic material part 140 does not damage the transparency of the attachment structure 135 or the contact structure in a designated air contact area of the attachment structure 135 (or minimizes transparency damage). In addition, after treatment with a designated primer so that the photocatalytic material is easily coated on the air contact area, it may be generated by coating a designated photocatalytic material on the primer-treated air contact area.

According to the implementation method of the present invention, the photocatalytic material part 140 may be produced by surface-treating a transparent silicon (Si)-based coating agent on a designated air contact area of the attachment structure part 135 and then coating a designated photocatalytic material. . Here, the silicon (Si) component is used as a raw material for transparent glass, as well as a material that is safe for photocatalytic reaction of titanium oxide (TiO2), so if the coating agent of the silicon (Si) component does not damage the transparency of the air contact area In addition, it is possible to prevent the photocatalytic material from causing a catalytic reaction to the attachment structure 135 or the material of the contact structure, as well as treatment so that the photocatalytic material stably maintains a coating state in the air contact area.

On the other hand, titanium oxide (TiO2) contained in the photocatalytic material is activated in the UV-A wavelength band (for example, 315 to 400 nm wavelength band), and the light source unit 105 is not a light source for photocatalytic reaction, but a conventional illumination Since it includes a light source for the UV-A wavelength band, or even if the UV-A wavelength band is radiated, a small amount may be emitted. Accordingly, according to the method of the present invention, the photocatalytic material has conductivity in titanium oxide (TiO2) in order to induce a photocatalytic reaction even if the light in the UV-A wavelength band is not emitted from the light source unit 105 or a small amount is radiated. It can be manufactured in the form of a material doped with a designated metal element.

The photocatalytic reaction of the photocatalytic material occurs through the process of restoring the electrons excitation from the valence band to the conduction band by applying light energy to titanium oxide (TiO2) to its original state. On the other hand, normally, electrons excited to the conduction band in the valence band are restored to the valence band in a time period of about 10^-6 seconds. No reaction may occur. On the other hand, when light in the UV-A wavelength band is applied to titanium oxide (TiO2), the electrons excited in the valence band are restored to the valence band slower than the 10^-6 seconds, thereby causing a photocatalytic reaction.

Meanwhile, according to the embodiment of the present invention, the photocatalytic material may be prepared by doping titanium oxide (TiO2) with a designated metal element having conductivity. In this case, the metal element doped with titanium oxide (TiO2) is titanium oxide ( Light energy is applied to TiO2) to delay (e.g., delay a 10^-3 second time period) the time (Life Time) at which the excited electrons are restored to their original state in the valence band and/or the conduction band in the valence band. Breaking at least some of the relationship between the electrons excited by the valence band and the holes formed in the valence band (e.g., the electrons excited by the conduction band in the valence band become free electrons and move to the metal element, so that the valence band The relationship between the electron excited by the conduction band at and the hole formed in the valence band is broken. In this case, the electron restored to the valence band in the conduction band may be an electron other than the excited electron, and through this process, the conduction band in the valence band The time for restoring the excited electrons to the original state is delayed), so that the light source unit 105 of a wavelength band other than a specific wavelength band (eg, UV-A wavelength band) designated for the photocatalytic reaction of the titanium oxide (TiO 2) It is also possible to perform the function of inducing a photocatalytic reaction through. According to the implementation method of the present invention, the metal element may include metal elements having various conductivity, such as gold (Au), silver (Ag), copper (Cu), aluminum (Al), etc., preferably silver (Ag) It may contain elements.

5 is a block diagram showing the relationship between the wall lamp 100 and the photocatalytic module 130 according to an embodiment of the present invention.

In more detail, the drawing 5 shows the wall lamp 100 while using the wall lamp 100 by attaching and detaching it to the designated light tube area of the light source unit 105 provided in the wall lamp 100 fixed to the wall. As a side cross-sectional view of an embodiment of the photocatalytic module 130 for purifying the air in the provided space, those of ordinary skill in the art to which the present invention pertains, refer to and/or modify this Figure 5 Thus, various implementation methods for the relationship between the wall lamp 100 and the photocatalytic module 130 (for example, some components are omitted, subdivided, or combined implementation methods) can be inferred. It includes all the inferred implementation methods, and the technical features are not limited only by the implementation method shown in FIG. 5.

Referring to FIG. 5, the wall lamp 100 emits light of a specified wavelength (or wavelength band) by using a power source, and a light source unit 105 having a specified appearance and the light source unit 105 inserted from a downward direction. ) To support and supply power to the light source unit 105, and the light emitted through the light source unit 105 inserted into the socket unit 110 to diffuse into a specified range, and the upper area is A frame part 120 having a structure that is fixed to the wall by being coupled to at least one of the closed lampshade part 115, the socket part 110 and the lampshade part 115, and the frame part 120 on the wall. A power supply unit (not shown) that includes a fixing unit 125 for fixing, and applies external power to the socket unit 110 internally, and a switch unit (not shown) that processes on/off of the light source unit 105 Omit).

The light source unit 105 emits light of a specified wavelength using a power source or emits light of a specified wavelength band to emit light, or is a generic term for a component. Preferably, the light source unit 105 preferably includes a light tube structure. On the other hand, according to another embodiment of the present invention, the external shape of the light source unit 105 is not limited to the light tube structure, it is clearly revealed that any form other than the light tube structure may be included in the scope of the present invention.

According to an exemplary method of the present invention, the light source unit 105 includes a light source that emits light of a specified wavelength (or wavelength band) inside the tube structure.

According to an exemplary embodiment of the present invention, the light source unit 105 emits light in a visible wavelength band to emit light, and may emit and emit light in some ultraviolet wavelength band or infrared wavelength band. Preferably, the light source unit 105 emits light in an ultraviolet wavelength band (eg, UV-A wavelength band, etc.) in addition to the visible light wavelength band to emit light. However, in the present invention, the wavelength (or wavelength band) of light emitted by the light source unit 105 is not limited to a specific wavelength (or wavelength band), and if the wavelength (or wavelength band) of the light source used for illumination, the present invention It can be defined as belonging to the scope of rights of

According to the implementation method of the present invention, the light source unit 105 attaches and detaches the photocatalytic module 130, and the photocatalytic module 130 includes a geometric structure previously designed to be detachable to the light source unit 105. On the other hand, since the photocatalytic module 130 of the present invention is attached to and detached from the light source unit 105 having a top-down light tube structure, the lamp having the light source unit 105 is not limited to the wall type lamp 100, and the wall type lamp 100 ) Other than the various types of lamps can also be included in the scope of the present invention.

The socket unit 110 is a generic term for a component that inserts and supports the light source unit 105 and supplies power to the light source unit 105. Preferably, it is preferable that the socket unit 110 inserts and supports the light source unit 105 in a downward direction (eg, a direction corresponding to the earth's gravity direction within a preset error (<90°)).

The lampshade part 115 is a generic term for a component that induces light emitted through the light source part 105 inserted in the socket part 110 to be diffused into a specified range. Preferably, the lampshade part 115 preferably includes a structure in which the upper region is closed. On the other hand, in the case of some wall-type lamps 100, the lampshade portion 115 can be omitted, and the present invention clearly reveals that the embodiment in which the lampshade portion 115 is omitted may be included as a scope of rights. On the other hand, according to another embodiment of the present invention, it is possible for the lampshade part 115 to include a structure in which the upper region is open, and the present invention clearly reveals that this embodiment can also be included in the scope of the rights.

The frame part 120 is coupled to at least one of the socket part 110 and the lampshade part 115 and is combined with a fixing part 125 for fixing a wall surface, so that the light source part 105 and the socket part 110 and the lampshade It is a generic term for a component that positions the part 115 and the like at a certain height.

Referring to FIG. 5, the photocatalytic module 130 has an attachment area of a designated geometry that can be attached to a designated light source area of the light source unit 105 inserted from a downward direction of the socket unit 110, and An attachment structure 135 that maintains a state attached to a designated light source area of the light source unit 105 by at least one of structural characteristics and frictional force, and light of a designated wavelength (or wavelength band) emitted through the light source unit 105 A network structure unit 145 including a network structure that transmits light, and a photocatalytic material unit 140 formed by coating a designated photocatalytic material in a designated air contact area among the areas of the attachment structure unit 135 and the network structure unit 145. do. On the other hand, for convenience, FIG. 5 illustrates an embodiment in which the photocatalytic module 130 is attached to the light source unit 105 as illustrated in FIG. 6 to explain the technical characteristics of the photocatalytic module 130, but the photocatalyst according to the present invention It should be clearly noted that the geometry of the module 130 is not limited to the example of FIG. 6.

The attachment structure 135 includes an attachment area having a designated geometry that can be attached to a designated light source area of the light source unit 105 inserted in the downward direction of the socket unit 110. The light source unit 105 includes an external shape of a light tube structure, and preferably, a designated light source area of the light source unit 105 is a partial light tube area of a light tube included in the light tube structure light source unit 105, and the light tube structure light source unit 105 At least one of the entire light tube area of the light tube included in the light tube, some light tube areas of two or more light tubes included in the light tube structure light source unit 105, and the total light tube area of two or more light tubes included in the light tube structure light source unit 105 It can include areas. Meanwhile, when the designated light tube area includes the entire light tube area of the light tube structure light source unit 105, the attachment structure unit 135 includes a certain number of light emitted from the light source unit 105 to be directly radiated to the outside (or It is preferable that the hole of the area) is formed.

According to the implementation method of the present invention, the geometric structure attachable to a designated light source area has a diameter structure attachable to a designated light source area formed in a light tube included in the socket part 110 in a downward direction. (For example, when the photocatalytic module 130 is attached to a single light tube, etc.), a multiple attachment structure capable of multiple attachment to two or more designated light source regions formed in a light tube included in the light tube structure light source unit 105, the light tube structure light source unit ( 105), a linkage attachment structure that can be linked and attached to each designated light source area formed in two or more light tubes included in), a curvature structure corresponding to the designated light tube curvature of a cylindrical light tube (for example, a photocatalytic module 130 is attached to any one light tube It may include at least one geometric structure of the case where light from the attached light tube is irradiated or the light tube is attached to one light tube and is irradiated with light from a plurality of light tubes.

Meanwhile, the geometric structure of the attachment structure 135 may further include at least one of geometric structures that are not exposed to the lower side area of the lampshade.

According to an exemplary embodiment of the present invention, the attachment area of the attachment structure 135 may include a surface-treated area to increase the frictional force of the light source unit 105 with a designated light tube area.

According to an embodiment of the present invention, the attachment structure 135 may include the network structure 145. For example, when the attachment structure 135 and the network structure 145 are integrated, both the attachment structure 135 and the net structure 145 may be attached to the light source unit 105.

According to an exemplary method of the present invention, the attachment structure 135 may include a separate attachment structure connected to the network structure 145. For example, the attachment structure 135 and the net structure 145 are separately configured, so that only the attachment structure 135 is attached to the light source unit 105, and the net structure unit 145 is not attached to the light source unit 105, but at a predetermined interval. You can maintain a more separated state.

According to an exemplary method of the present invention, the network structure part 145 may maintain a state spaced apart from the light source part 105 by a predetermined distance or more by the attachment structure part 135 attached to the light source part 105.

According to an exemplary method of the present invention, the attachment structure 135 includes a transparent material that transmits light from the light source unit 105. Accordingly, the light emitted by the light source unit 105 may pass through the attachment structure 135 and reach the photocatalyst material unit.

According to an embodiment of the present invention, the attachment structure 135 includes light emitted from the light source unit 105 and heat generated during light emission of the light source unit 105 (e.g., at least 25°C or more and a maximum of about 300°C. It is desirable to include a material that does not deteriorate even when exposed for a long period of time for longer than the period specified in heat). Preferably, the attachment structure 135 includes a material that does not deteriorate in transparency even when exposed to light and heat of the light source unit 105 for a long period of time. For example, the attachment structure 135 is processed to be transparent and includes a material processed to have durability against light and heat (e.g., PE (Poly Ethylene), nylon, CPI (Clearance Poly Imide), Teflon, etc.) can do.

According to the first material embodiment of the present invention, the attachment structure 135 has a specified range of ductility that extends without being damaged to a specified range by an external force, and a specified range of elasticity to return to its original state when the external force is removed. It may contain a material having Preferably, the attachment structure 135 is attached to the designated light source area of the light source unit 105 by an external force, so that the ductility increases by more than the maximum sectional area size of the light source unit 105 and the external force is removed. It may contain a material having elasticity to return. On the other hand, in this case, the geometric structure attachable to the designated light source area includes a diameter smaller than or equal to the minimum diameter based on the circular cross section of the designated light source area of the light source unit 105 in a state where no external force is applied. It includes at least one of a diameter structure attachable to the designated light source area of 105, a curvature structure corresponding to the designated light bulb curvature of the designated light source area, and a tilt structure attachable to the designated light source area of the light source unit 105 can do. Meanwhile, the elastic material may provide an elastic force for maintaining the frictional force required to attach the photocatalytic module 130 to a designated light bulb area of the light source unit 105.

According to the second material embodiment of the present invention, the attachment structure 135 is deformed by an external force to be attached to a designated light source area of the light source unit 105 and then maintains the deformed state while the external force is removed. It may contain possible materials.

According to the third material embodiment of the present invention, the attachment structure 135 may include a material that at least partially combines the first to second material embodiments.

According to the implementation method of the present invention, the attachment structure 135 may include an air contact area of a designated area for contacting air in a designated area of the surface area, and in this case, the designated air contact of the attachment structure 135 The photocatalytic material part 140 may be formed by coating a photocatalytic material designated on the region. Meanwhile, the air contact area may include an area that is introduced from the lower side of the lampshade 115 and can contact air convectively flowing in the lower side of the lampshade 115.

The photocatalytic material part 140 is a generic term for a component formed by coating a designated photocatalytic material on a designated air contact area, and is preferably formed by coating a designated photocatalytic material on a designated air contact area among the areas of the attachment structure 135. . Here, the photocatalyst material includes titanium oxide (TiO2).

According to an exemplary method of the present invention, the photocatalytic material part 140 may be formed by coating a photocatalytic material particle of 30 nm or less in a designated air contact area of the attachment structure 135. According to the present invention, no matter how transparent the material of the attachment structure 135 is, since titanium oxide (TiO2) contained in the photocatalytic material is an opaque material used as a raw material for a white pigment, the photocatalytic material is coated. Even in a state where the photocatalytic module 130 is attached to the light source unit 105, in order to minimize the reduction in brightness of light by the photocatalytic material, the photocatalytic material should be thinly coated on the designated air contact area. It is preferable that the size of the photocatalytic material particles is 30 nm or less.

According to the implementation method of the present invention, the photocatalytic material part 140 does not damage the transparency of the attachment structure 135 or the contact structure in a designated air contact area of the attachment structure 135 (or minimizes transparency damage). In addition, after treatment with a designated primer so that the photocatalytic material is easily coated on the air contact area, it may be generated by coating a designated photocatalytic material on the primer-treated air contact area.

According to the implementation method of the present invention, the photocatalytic material part 140 may be produced by surface-treating a transparent silicon (Si)-based coating agent on a designated air contact area of the attachment structure part 135 and then coating a designated photocatalytic material. . Here, the silicon (Si) component is used as a raw material for transparent glass, as well as a material that is safe for photocatalytic reaction of titanium oxide (TiO2), so if the coating agent of the silicon (Si) component does not damage the transparency of the air contact area In addition, it is possible to prevent the photocatalytic material from causing a catalytic reaction to the attachment structure 135 or the material of the contact structure, as well as treatment so that the photocatalytic material stably maintains a coating state in the air contact area.

On the other hand, titanium oxide (TiO2) contained in the photocatalytic material is activated in the UV-A wavelength band (for example, 315 to 400 nm wavelength band), and the light source unit 105 is not a light source for photocatalytic reaction, but a conventional illumination Since it includes a light source for the UV-A wavelength band, or even if the UV-A wavelength band is radiated, a small amount may be emitted. Accordingly, according to the method of the present invention, the photocatalytic material has conductivity in titanium oxide (TiO2) in order to induce a photocatalytic reaction even if the light in the UV-A wavelength band is not emitted from the light source unit 105 or a small amount is radiated. It can be manufactured in the form of a material doped with a designated metal element.

The photocatalytic reaction of the photocatalytic material occurs through the process of restoring the electrons excitation from the valence band to the conduction band by applying light energy to titanium oxide (TiO2) to its original state. On the other hand, normally, electrons excited to the conduction band in the valence band are restored to the valence band in a time period of about 10^-6 seconds. No reaction may occur. On the other hand, when light in the UV-A wavelength band is applied to titanium oxide (TiO2), the electrons excited in the valence band are restored to the valence band slower than the 10^-6 seconds, thereby causing a photocatalytic reaction.

Meanwhile, according to the embodiment of the present invention, the photocatalytic material may be prepared by doping titanium oxide (TiO2) with a designated metal element having conductivity. In this case, the metal element doped with titanium oxide (TiO2) is titanium oxide ( Light energy is applied to TiO2) to delay (e.g., delay a 10^-3 second time period) the time (Life Time) at which the excited electrons are restored to their original state in the valence band and/or the conduction band in the valence band. Breaking at least some of the relationship between the electrons excited by the valence band and the holes formed in the valence band (e.g., the electrons excited by the conduction band in the valence band become free electrons and move to the metal element, so that the valence band The relationship between the electron excited by the conduction band at and the hole formed in the valence band is broken. In this case, the electron restored to the valence band in the conduction band may be an electron other than the excited electron, and through this process, the conduction band in the valence band The time for restoring the excited electrons to the original state is delayed), so that the light source unit 105 of a wavelength band other than a specific wavelength band (eg, UV-A wavelength band) designated for the photocatalytic reaction of the titanium oxide (TiO 2) It is also possible to perform the function of inducing a photocatalytic reaction through. According to the implementation method of the present invention, the metal element may include metal elements having various conductivity, such as gold (Au), silver (Ag), copper (Cu), aluminum (Al), etc., preferably silver (Ag) It may contain elements.

6 is a diagram illustrating an embodiment of the photocatalytic module 130 according to the method of the present invention.

In more detail, FIG. 6 shows the ductility that increases by more than the cross-sectional area of the cross-sectional structure of a plurality of light tubes included in the light source unit 105 by an external force and the space between the light tubes and the external force is removed. A simple cross-sectional plan view of the photocatalyst module 130 attached to the designated light tube area of the light source unit 105 through the frictional force generated by the elasticity using the attachment structure 135 including the elastic material to be returned As an example, a person of ordinary skill in the art to which the present invention pertains may infer various embodiments of implementing the photocatalytic module 130 by referring to and/or modifying this Figure 6, The present invention includes all the inferred embodiments, and the technical features thereof are not limited to the embodiments illustrated in FIG. 6.

Referring to the embodiment of Fig. 6, the photocatalyst module 130 increases the ductility and the external force by an external force that is greater than the cross-sectional area of a combination of the cross-sectional area between the cross-section of the light tube and the space between the light tube on the cross-sectional structure of the plurality of light tubes included in the light source unit 105. It includes an attachment structure 135 made of a material having elasticity to return to its original state when removed, and the photocatalyst module 130 is transferred to the light source unit 105 by elasticity of the material of the attachment structure 135 A frictional force is provided to attach to the designated light tube area of

Meanwhile, an attachment region attached to a designated light tube area of the light source unit 105 is formed inside the attachment structure 135, and a designated photocatalytic material is coated on the air contact area formed outside the attachment structure 135 to form a photocatalytic material. Form part 140.

7 is a view showing an embodiment of a process of manufacturing the photocatalytic module 130 according to the embodiment of the present invention.

In more detail, FIG. 7 shows an embodiment of a process of manufacturing the photocatalytic module 130 attachable to a designated light source area of the light source unit 105 having a designated shape (eg, a light bulb or a light tube, etc.). Those of ordinary skill in the relevant technical field will be able to infer various embodiments of the manufacturing process of the photocatalytic module 130 by referring to and/or modifying this Figure 7, but the present invention The embodiments are included, and the technical features are not limited only to the embodiments illustrated in FIG. 7.

Referring to FIG. 7, each of the structural parts constituting the photocatalytic module 130 according to the design structure previously designed to manufacture the photocatalytic module 130 (e.g., the attachment structure 135, the network structure 145, the attachment structure ( 135) and one or more structures of the combination of the network structure 145), etc.), and the designated air contact of the attachment structure 135 and/or the network structure 145 among the fabricated/prepared structures After performing a designated primer treatment on the region and/or a silicon (Si) component coating (705), a step of curing the primer treatment and/or the coating agent treatment (710).

When the primer treatment and/or the coating agent treatment for the designated air contact area of the attachment structure 135 and/or the network structure 145 is cured, the attachment structure 135 cured after the primer treatment and/or coating agent treatment And/or after coating a designated photocatalytic material on a designated air contact area of the network structure 145 (715), a heat drying process is performed (720).

When the photocatalytic material designated in the designated air contact area of the attachment structure 135 and/or the network structure 145 is coated and then thermally dried, each structure part is cut and/or combined according to the designated design structure to form a designated light source part. The photocatalytic module 130 attachable to the 105 is manufactured (725).

100: wall lamp
105: light source
110: socket
115: lampshade
120: frame part
125: fixed part
130: photocatalytic module
135: attachment structure
140: photocatalytic material part
145: network structure

Claims (23)

A light source unit that emits light of a specified wavelength (or wavelength band) using a power source and has a specified appearance, a socket unit supporting the light source unit inserted from a downward direction and supplying power to the light source unit, and the socket unit In the photocatalytic module detachable to the light source part of a wall type lamp having a frame part having a structure fixed to the wall,
Has a designated geometrical attachment area that can be attached to a designated light source area of the light source unit inserted in the downward direction of the socket unit, and maintains a state attached to the designated light source area of the light source unit by at least one of structural characteristics and frictional force of the attachment area Attaching structure to make;
A network structure unit including a network structure that transmits light of a specified wavelength (or wavelength band) emitted through the light source unit; And
A photocatalytic module detachably attached to a wall lamp having a top-down type light source comprising a; a photocatalytic material part formed by coating a designated photocatalytic material on a designated air contact area among regions of the attachment structure and the network structure.
The method of claim 1,
The wall-type lamp further includes a lampshade portion with an upper region open and inducing light emitted through a light source portion inserted into the socket portion to be diffused to a specified range,
The air contact area includes an area that is introduced from the lower side of the lampshade by heat generated during light emission of the light source unit and can come into contact with air convectively in the direction of the open upper area of the lampshade. A photocatalytic module that is attached to and detached from a wall lamp equipped with a light source.
The method of claim 1,
The wall lamp further includes a lampshade part in which light emitted through the light source part inserted in the socket part is diffused to a specified range and the upper region is closed,
The air contact area includes an area that is introduced from one side of the lower side of the lampshade and can come into contact with air convectively toward the other side of the lower side of the lampshade. Photocatalyst module that is detachable.
The method of claim 1, wherein the light source unit,
A photocatalytic module detachable from a wall type lamp having a top-down type light source, characterized in that it includes a light bulb-shaped exterior.
The method of claim 4, wherein the designated light source area of the light source unit,
A light bulb area corresponding to a maximum diameter area based on a circular cross section of the light bulb-shaped light source unit,
A light bulb area including a predetermined distance from the maximum diameter area of the light bulb-shaped light source unit toward the socket unit,
A photocatalyst module detachable from a wall type lamp having a top-down type light source, comprising at least one of the entire bulb areas of the bulb type light source unit.
The method of claim 4, wherein the geometric structure,
A diameter structure that can be attached to a designated light source area of the light bulb-shaped light source unit inserted in the downward direction of the socket unit,
A curvature structure corresponding to a curvature of a bulb in a designated light source area of the light source unit,
A photocatalytic module detachable from a wall lamp having a top-down type light source, comprising at least one of an inclination structure attachable to a designated light source area of the light source unit.
The method of claim 1, wherein the light source unit,
A photocatalytic module detachably attached to a wall type lamp having a top-down type light source, characterized in that it comprises an external shape of a light tube structure.
The method of claim 7, wherein the designated light source area of the light source unit,
A partial light tube area of the light tube included in the light tube structure light source unit,
The entire light tube area of the light tube included in the light tube structure light source unit,
A partial light tube region of at least two light tubes included in the light tube structure light source unit,
A photocatalyst module detachable from a wall lamp having a top-down type light source, comprising at least one of the entire light tube areas of two or more light tubes included in the light tube structure light source unit.
The method of claim 7, wherein the geometric structure,
A diameter structure attachable to a designated light source area formed in a light tube included in the light tube structure included in the light source unit, inserted from a downward direction of the socket unit,
A multiple attachment structure capable of multiple attachments to two or more designated light source areas formed in a light tube included in the light tube structure light source unit,
Linkage attachment structure capable of linking and attaching to each designated light source area formed in two or more light tubes included in the light tube structure light source unit,
A photocatalytic module detachable from a wall lamp having a top-down type light source, characterized in that it comprises at least one of a curvature structure corresponding to a specified light tube curvature of a cylindrical light tube.
The method of claim 1, wherein the attachment region of the attachment structure comprises:
A photocatalytic module detachable from a wall type lamp having a top-down type light source, comprising a surface-treated area to increase frictional force with a designated light source area of the light source unit.
The method of claim 1, wherein the attachment structure,
A photocatalyst module detachable from a wall lamp having a top-down type light source, comprising the network structure.
The method of claim 1, wherein the attachment structure,
A photocatalytic module detachable from a wall type lamp having a top-down type light source, comprising a separate attachment structure connected to the network structure.
The method of claim 1 or 12, wherein the network structure,
A photocatalytic module detachable from a wall lamp having a top-down type light source, characterized in that maintaining a state spaced apart from the light source unit by a predetermined distance or more by an attachment structure attached to the light source unit.
The method of claim 1, wherein the attachment structure,
A photocatalytic module detachable from a wall lamp having a top-down type light source, comprising a material that does not deteriorate when exposed to light and heat of the light source unit for more than a specified period.
The method of claim 1, wherein the attachment structure,
Top-down form, characterized in that it comprises a ductility that extends by an external force by an external force to be attached to a designated light source area of the light source unit, and a material having elasticity to return to its original state when the external force is removed A photocatalytic module that is attached to and detached from a wall lamp equipped with a light source.
The method of claim 15, wherein the material having elasticity,
A photocatalytic module detachably attached to a wall lamp having a top-down type light source, characterized in that it provides an elastic force for maintaining the frictional force.
The method of claim 1, wherein the attachment structure,
Detachable to a wall type lamp having a top-down type light source, characterized in that it comprises a material capable of maintaining the deformed state in a state in which the external force is removed after being deformed by an external force in order to be attached to the designated light source area of the light source unit Photocatalytic module.
The method of claim 1, wherein the optical storage material unit,
A photocatalytic module detachably attached to a wall lamp having a top-down type light source, characterized in that produced by coating a photocatalytic material particle of 30 nm or less on the air contact area.
The method of claim 1, wherein the optical storage material unit,
A photocatalyst module detachable from a wall lamp having a top-down type light source, characterized in that it is generated by coating a designated photocatalytic material after treatment with a designated primer on the air contact area.
The method of claim 1, wherein the optical storage material unit,
A photocatalyst module detachable from a wall lamp having a top-down type light source, characterized in that it is produced by surface-treating a silicon (Si) component coating agent on the air contact area and then coating a designated photocatalytic material.
The method of claim 1, wherein the photocatalytic material,
A photocatalytic module that is attached to and detached from a wall lamp having a top-down type light source, characterized in that it contains a material by doping a designated metal element having conductivity in titanium oxide (TiO2).
The method of claim 21, wherein the metal element,
It has a top-down type light source, characterized in that it performs a function of inducing a photocatalytic reaction through the light source unit by delaying a time for restoring the electrons excited from the valence band to the conduction band by applying energy to the titanium oxide (TiO2) to its original state. A photocatalytic module that is attached to and detached from a wall lamp.
The method of claim 21, wherein the metal element,
A top-down form, characterized in that it performs a function of inducing a photocatalytic reaction through the light source by breaking at least a part of the relationship between the electrons excited in the conduction band in the valence band and the holes formed in the valence band by applying energy to titanium oxide (TiO2) A photocatalytic module that is attached to and detached from a wall lamp equipped with a light source.

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