KR20200030716A - Photocatalyst Module for Placing to Ceiling-Mounted type Electric Lamp Equipped with Downward Bulb type Light Source - Google Patents

Abstract

According to a photocatalyst module held in a ceiling type lamp having a light source in the form of a downward light bulb of the present invention, the photocatalyst module detachably held in a light source unit of a ceiling type lamp comprises: a light source unit which uses power to emit light in a predetermined wavelength (or wavelength band) and has an appearance of a light bulb; a socket unit which inserts the light source unit from a bottom, supports the same and supplies power to the light source unit; and a frame unit which has a structure coupling to the socket unit to be fixed on a ceiling. The present invention comprises: a holding structure unit which has a holding area capable of holding in a designated geometric structure in a designated light bulb area corresponding to an area between a minimum diameter and a maximum diameter based on a circular cross section of the light bulb form light source unit which is a light bulb shape inserted from a bottom to the socket unit, and maintains a state held in the designated light bulb area of the light bulb form light source unit by means of a relationship between a structural characteristics of the holding area and the gravity of the Earth; and a photocatalyst matter unit which is formed by coating a designated photocatalyst matter on a designated air contacting area among areas of the holding structure unit or by coating a designated photocatalyst matter on a designated air contacting areas among areas of a contact structure unit provided for being in contact with air in at least one side area of the holding structure unit. Accordingly, the present invention purifies air in a space where the ceiling type lamp is provided while the ceiling type lamp is used.

Description

Photocatalyst Module for Placing to Ceiling-Mounted type Electric Lamp Equipped with Downward Bulb type Light Source}

The present invention is to provide a photocatalyst module that purifies the air in a space provided with the ceiling lamp while using the ceiling lamp by removing it from a designated bulb region of a top down light bulb unit provided in a ceiling lamp fixed to the ceiling.

The photocatalyst is a material that irradiates light in a designated wavelength band to promote a designated chemical reaction, and a typical photocatalyst material is titanium oxide (TiO2). Titanium oxide (TiO2) is used as a main raw material for white pigments. When ultraviolet rays in the UV-A wavelength band are irradiated to these titanium oxides (TiO2), electrons in the valence band are excited as a conduction band. ), And then restored to the valence band again, a photocatalytic reaction that causes a strong oxidation reaction or a reduction reaction occurs. Accordingly, a photocatalyst filter including a photocatalytic material such as titanium oxide (TiO2) is produced, and then ultraviolet rays in the UV-A wavelength band are irradiated to the photocatalyst filter to pass through air and decompose and purify various contaminants or dust in the air. The titanium oxide (TiO2) is mainly used in photocatalyst air purifiers. On the other hand, since these photocatalyst air purifiers are manufactured under conditions optimized for photocatalytic reaction, air purification efficiency is high, while manufacturing costs are high.

Meanwhile, a method of purifying air while turning on a fluorescent lamp by coating a photocatalyst material directly on a fluorescent lamp that emits 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 has a problem that it is difficult to apply to general lamps used as lighting lamps. It has a very low problem. In addition, titanium oxide (TiO2) is used as the main raw material of the white pigment as described above. When this titanium oxide (TiO2) is directly coated on a fluorescent lamp, the brightness of the fluorescent lamp decreases, which causes inconvenience to use as a lighting lamp. have.

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

The 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 a light source unit having an external shape in the form of a light bulb, and the light source unit is inserted and supported in a downward direction. In the photocatalytic module that can be removed from the light source portion of the ceiling-type lamp having a socket portion for supplying power to the light source portion, and a frame portion having a structure fixed to the ceiling coupled to the socket portion, the light bulb inserted in the socket portion in the downward direction The light source portion of the light bulb type has a mounting area of a designated geometry structure that can be mounted in a designated light bulb area corresponding to an area between a minimum diameter and a maximum diameter based on a circular cross-section based on the shape of the light source part, and the relationship between the structural feature of the mounting area and the Earth's gravity A mounting structure for maintaining a mounted state in a designated bulb region, and the mounting structure A photocatalytic material formed by coating a designated photocatalytic material in a designated air contact region of a region or by coating a designated photocatalytic material in a designated air contact region of a region of a contact structure provided to contact air in at least one region of the mounting structure It is to provide a photocatalyst module mounted on a ceiling lamp having a top-down light bulb type light source including a portion.

Another object of the present invention is to provide a photocatalyst module mounted on a ceiling light fixture having a top-down light bulb type light source that facilitates removal of the photocatalyst module by removing the photocatalyst module directly from the light source of the ceiling light fixture.

Another object of the present invention, by convecting the air around the photocatalyst module mounted on the light source portion of the ceiling light fixture, the photocatalyst mounted on a ceiling light fixture with a top-down light bulb type light source to maximize the photocatalytic reaction of the photocatalyst module mounted on the light source portion In providing a module.

The photocatalyst module mounted on a ceiling lamp having a top-down light bulb type light source according to the present invention emits light of a designated wavelength (or wavelength band) by using a power source, and a light source unit having a light bulb shape appearance, and the light source unit from a downward direction. In the photocatalytic module that can be removed from the light source portion of the ceiling-type light fixture having a frame portion having a structure fixed to the ceiling and the socket portion for supplying power to the light source portion by inserting and supporting, wherein the socket portion It has a mounting area of a designated geometry structure that can be mounted in a designated light bulb area corresponding to an area between a minimum diameter and a maximum diameter based on a circular cross-section of the bulb-shaped light source unit inserted in the downward direction, and the relationship between the structural characteristics of the mounting area and the earth's gravity By maintaining the state mounted on the designated bulb region of the bulb-shaped light source unit A photocatalyst designated in a designated air contact region among regions of a contact structure portion formed by coating a designated photocatalytic material in a designated air contact region among regions of the tooth structure and the mounting structure or provided in contact with air in at least one region of the mounting structure It characterized in that it comprises a photocatalytic material portion formed by coating the material.

In the photocatalyst module mounted on a ceiling lamp having a top-down light bulb type light source according to the present invention, the ceiling lamp is induced to spread light emitted through a light source unit inserted in the socket into a specified range and open an upper region Further comprising a lampshade portion, the air contact area, including a region that can be in contact with the air flowing in the direction of the lower side of the lampshade by the heat generated during light emission of the light source unit convected toward the open upper region of the lampshade It is characterized by being made.

In the photocatalytic module mounted on a ceiling lamp having a top-down light bulb type light source according to the present invention, the mounting structure is a geometry structure that is not exposed to the open upper region of the lamp shade, and is not exposed to the lower side region of the lamp shade It characterized in that it further comprises at least one of the geometry.

In the photocatalyst module mounted on a ceiling lamp having a top-down light bulb type light source according to the present invention, the geometry is greater than a minimum diameter and smaller than a maximum diameter based on a circular cross-section based on a circular cross-section of the bulb type light source inserted in the socket portion from below. At least one of a diameter structure that can be mounted in a specified bulb region of a diameter range, a curvature structure corresponding to a specified bulb curvature between the minimum diameter and a maximum diameter, and a tilt structure for mounting in a designated bulb region between the minimum and maximum diameters. It is characterized by comprising a structure.

In the photocatalyst module mounted on a ceiling lamp having a top-down light bulb type light source according to the present invention, the mounting area is characterized in that it comprises a surface-treated area to increase the frictional force with the designated light bulb area of the light source unit .

In the photocatalytic module mounted on a ceiling lamp having a top-down light bulb type light source according to the present invention, the mounting structure is characterized in that it comprises a transparent material that transmits light from the light source.

In the photocatalytic module mounted on a ceiling lamp having a top-down light bulb type light source according to the present invention, the mounting structure is characterized in that it comprises a material that does not deteriorate in a state exposed for more than a specified period of time to light and heat of the light source unit do.

In the photocatalyst module mounted on a ceiling light fixture having a top-down light bulb type light source according to the present invention, the contact structure portion comprises at least one structure of a bead structure or a pin structure for maximizing the contact area of air Is done.

In the photocatalytic module mounted on a ceiling lamp having a top-down light bulb type light source according to the present invention, the contact structure portion is characterized in that it comprises a transparent material that transmits light from the light source portion.

In the photocatalytic module mounted on a ceiling light fixture having a top-down light bulb type light source according to the present invention, the contact structure is characterized in that it comprises a material that does not deteriorate in a state exposed for more than a specified period of time to light and heat of the light source part do.

In the photocatalyst module mounted on a ceiling light fixture having a top-down light bulb type light source according to the present invention, the mounting structure portion comprises a hinge portion that opens or narrows a designated portion over a specified interval to be mounted on the light source portion Is done.

In the photocatalyst module mounted on a ceiling light fixture having a top-down light bulb type light source according to the present invention, the mounting structure portion is provided with or connected to an elastic part that applies a force in a direction to narrow the gap between the parts opened by the hinge part Is done.

In the photocatalytic module mounted on a ceiling light fixture having a top-down light bulb type light source according to the present invention, the mounting structure portion further comprises an opening and closing portion corresponding to a portion that is widened or narrowed over a specified distance by the hinge portion Is done.

In the photocatalyst module mounted on a ceiling light fixture having a top-down light bulb type light source according to the present invention, the light is emitted from the light source part by being provided or bound at one side of the mounting structure part mounted on the designated light bulb area of the light source part It characterized in that it further comprises a power generating unit for generating power and a fan unit for operating based on the power generated through the power generating unit to generate pressure for flowing air around the photocatalytic material unit.

In the photocatalytic module mounted on a ceiling lamp having a top-down light bulb type light source according to the present invention, the fan unit blocks the light emitted from the light source unit from being reflected by the rotation of the fan for generating the pressure, or the fan It characterized in that it further comprises a blocking portion for blocking so as not to form a shadow corresponding to the rotation of.

In the photocatalytic module mounted on a ceiling lamp having a top-down light bulb type light source according to the present invention, the photocatalytic material portion is produced by coating particles of photocatalytic material of 30 nm or less in the air contact area.

In the photocatalyst module mounted on a ceiling light fixture having a top-down light bulb type light source according to the present invention, the photocatalyst material part is produced by coating a designated photocatalyst material after treatment with a designated primer in the air contact area do.

In the photocatalytic module mounted on a ceiling light fixture having a top-down light bulb type light source according to the present invention, the photocatalytic material portion is produced by coating a specified photocatalytic material after surface treatment with a silicon (Si) -based coating agent in the air contact area It is characterized by being.

In the photocatalytic module mounted on a ceiling lamp having a top-down light bulb type light source according to the present invention, the photocatalytic material is made of a material containing a material by doping (Doping) a designated metal element having conductivity in titanium oxide (TiO2) It is characterized by.

In the photocatalyst module mounted on a ceiling light fixture having a top-down light bulb type light source according to the present invention, the metal element is applied with energy to titanium oxide (TiO2) to restore the original excited electrons from the valence band to the conduction band. It is characterized by performing a function of inducing a photocatalytic reaction through the light source unit by delaying.

In the photocatalytic module mounted on a ceiling lamp having a top-down light bulb type light source according to the present invention, the metal element is applied with energy to titanium oxide (TiO2) and excited by a conduction band in a valence band and holes formed in the valence band It is characterized in that it performs a function of inducing a photocatalytic reaction through the light source unit by at least partially cutting off the relationship between them.

According to the present invention, the photocatalyst module is mounted on the light source portion of the ceiling-type light fixture, and there is an advantage of purifying air in a space provided with the ceiling-type light fixture while using the ceiling-type light fixture.

According to the present invention, there is an advantage that facilitates the removal of the photocatalyst module by removing the photocatalyst module directly to the light source portion of the ceiling type 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 convecting air to the periphery of the photocatalytic module mounted on the light source unit of the ceiling light.

According to the present invention, there is an advantage of minimizing the decrease in brightness of the light source unit by mounting a photocatalyst module in a designated bulb region of the light source unit except for a region emitting light to be used as an illumination lamp among the regions of the light source unit of the ceiling type lamp.

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

According to the present invention, the light source portion of the ceiling type lamp emits light in the ultraviolet wavelength band as well as a small amount or hardly emits light to generate a photocatalytic reaction of the photocatalytic material coated on the photocatalyst module to generate the type or wavelength of the light source unit. There is an advantage of purifying the surrounding air during use of the ceiling lamp regardless of the band.

1 is a block diagram showing a relationship between a ceiling light fixture 100 and a photocatalytic module 130 according to an embodiment of the present invention.
2 is a diagram illustrating an embodiment of the photocatalytic module 130 according to an embodiment of the present invention.
3A and 3B are diagrams illustrating another embodiment of the photocatalytic module 130 according to the method of the present invention.
4 is a view showing an embodiment of a process for manufacturing a photocatalytic module 130 according to an embodiment of the present invention. A view showing an embodiment of a process for manufacturing a module 130.

Hereinafter, an operation 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 shown below and the following description are for preferred implementation methods among various methods for effectively describing the features of the present invention, and the present invention is not limited only to the following drawings and description.

That is, the following embodiments correspond to the preferred embodiment of the union type among the numerous embodiments of the present invention, and the specific embodiments are omitted from the specific embodiments, or the functions implemented in the specific structures are specified. The embodiments of dividing, or the embodiment of integrating the functions implemented in two or more configurations into any one configuration, the embodiment of replacing the operation sequence of a specific configuration, etc. are all of the present invention, even if not specifically mentioned in the following embodiments. It is clear that it falls within the scope of rights. Accordingly, it is clearly stated that various embodiments corresponding to a subset or a subset can be divided by retroactively filing the filing date of the present invention.

In addition, in the following description of the present invention, when it is determined that detailed descriptions of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, detailed descriptions 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 a user's or operator's intention or practice. Therefore, the definition should be made based on the overall contents of the present invention.

As a result, the technical spirit of the present invention is determined by the claims, and the following examples are one means for efficiently explaining the technical spirit of the present invention to those skilled in the art to which the present invention pertains. That's it.

1 is a block diagram showing the relationship between the ceiling type light 100 and the photocatalytic module 130 according to an embodiment of the present invention.

In more detail, FIG. 1 shows the ceiling lamp 100 while using the ceiling lamp 100 by detaching it from a designated bulb area of the top-down bulb type light source unit 105 provided in the ceiling lamp 100 fixed to the ceiling. As a side cross-sectional view of an embodiment of the photocatalytic module 130 for purifying air in a space provided with, if the person having ordinary knowledge in the art to which the present invention belongs, refer to FIG. 1 and / or By modifying the ceiling type lamp 100 and the photocatalytic module 130, a variety of implementation methods (for example, some components may be omitted, subdivided, or combined implementation methods) may be inferred, but the present invention It is made including all the inferred implementation methods, and its technical characteristics are not limited to only the implementation methods illustrated in FIG. 1.

Referring to FIG. 1, the ceiling type light 100 emits light of a specified wavelength (or wavelength band) by using a power source, and has a light source unit 105 having an external shape in the form of a light bulb, and the light source unit 105 in a downward direction. It is inserted to support the socket portion 110 for supplying power to the light source portion 105, and the light emitted through the light source portion 105 inserted in the socket portion 110 is induced to diffuse to a specified range, and the upper region It includes a frame portion 120 having a structure fixed to the ceiling by being coupled to at least one of the opened lampshade portion 115 and the socket portion 110 and the lampshade portion 115, and internally receives external power. It includes a power supply unit (not shown) supplied to the socket unit 110 and a switch unit (not shown) for processing on / off of the light source unit 105.

The light source unit 105 emits light of a designated wavelength by using a power source or emits light of a designated wavelength band or emits light, or is a general term for a component. Preferably, the light source unit 105 preferably includes an external shape in the form of a light bulb. 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 a light bulb shape, and it is clearly revealed that any shape other than the light bulb shape can be included in the scope of the present invention.

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

According to an embodiment of the present invention, the light source unit 105 emits and emits light in the visible wavelength band, and may emit and emit light in some ultraviolet wavelength bands or light in the infrared wavelength band. Preferably, the light source unit 105 emits and emits light in the ultraviolet wavelength band (eg, UV-A wavelength band, etc.) in addition to the visible light wavelength band. However, in the present invention, the wavelength (or wavelength band) of the 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 as illumination, the present invention It can be defined as belonging to the scope of rights.

According to an embodiment of the present invention, the light source unit 105 removes the photocatalytic module 130, and the photocatalytic module 130 is manufactured to include a geometric structure previously designed to be detachable from the light source unit 105. . On the other hand, since the photocatalyst module 130 of the present invention is removed from the light source unit 105 in the form of a top-down light bulb, the light fixture provided with the light source unit 105 is not limited to the ceiling lamp 100, and the ceiling lamp 100 In addition, it is clearly revealed that various types of lamps may 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, the socket portion 110 is preferably inserted and supported in the downward direction (for example, a direction corresponding to the direction of the earth's gravity 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 diffuse into a designated range. Preferably, the lampshade portion 115 preferably includes a structure in which the upper region is opened. On the other hand, in the case of some ceiling-type lamps 100, it is possible to omit the lampshade portion 115, and the present invention clearly discloses that embodiments in which the lampshade portion 115 is omitted may also be included in the scope of rights. On the other hand, according to another embodiment of the present invention, the lampshade portion 115 is possible to include a structure in which the upper region is closed, and the present invention clearly discloses that such an embodiment can also be included in the scope of rights.

The frame part 120 is a component part coupled to at least one of the socket part 110 and the lampshade part 115 to fix the light source part 105 and the socket part 110 and the lampshade part 115 to the ceiling. It is a generic term.

Referring to FIG. 1, the photocatalytic module 130 is assigned to a designated light bulb area corresponding to a region between a minimum diameter and a maximum diameter based on a circular cross-section of the light bulb unit 105 inserted in the downward direction in the socket portion 110. A mounting structure 135 having a mounting area of a designated geometry that can be mounted, and maintaining a mounted state in a designated light bulb area of the light bulb type light source 105 by a relationship between structural characteristics of the mounting area and earth gravity, Designated among areas of the contact structure 145 formed by coating a designated photocatalytic material in a designated air contact area among the areas of the mounting structure 135 or provided to contact air in at least one area of the mounting structure 135 And a photocatalytic material portion 140 formed by coating a designated photocatalytic material in the air contact area. On the other hand, for convenience, FIG. 1 shows an embodiment in which the photocatalytic module 130 as illustrated in FIG. 2 is mounted on the light source unit 105 to describe technical features of the photocatalyst module 130, but the photocatalyst according to the present invention It is clear that the geometry of the module 130 is not limited to the example in FIG. 2.

The mounting structure 135 is a designated light bulb corresponding to the area of the light bulb between the minimum diameter and the maximum diameter based on the circular cross-section of the bulb-shaped light source unit 105 inserted in the downward direction in the socket portion 110 in the horizontal direction. Includes a mounting area of a specified geometry that can be mounted in the area.

According to an embodiment of the present invention, the geometric structure that can be mounted in a designated bulb region is a diameter range larger than a minimum diameter and smaller than a maximum diameter based on a circular cross-section of the bulb-shaped light source unit 105 inserted in the downward direction in the socket portion 110. Geometry of at least one of a diameter structure that can be mounted on a designated bulb region, a curvature structure corresponding to a specified bulb curvature between the minimum diameter and a maximum diameter, and a tilt structure for mounting on a designated bulb region between the minimum and maximum diameters Structure.

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

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

According to an embodiment of the present invention, the mounting structure 135 is preferably made of a transparent material that transmits light from the light source unit 105. Accordingly, the light emitted from the light source unit 105 and radiated may pass through the interior of the mounting structure 135 to reach the photocatalytic material unit 140.

According to an embodiment of the present invention, the mounting structure 135 includes light emitted from the light source unit 105 and heat generated during light emission of the light source unit 105 (for example, at least 25 ° C or more and up to 300 ° C or more) It is preferable to include a material that does not deteriorate even after being exposed for a long period of time over a specified period of time. Preferably, the mounting structure 135 preferably includes a material that does not fall in transparency even when exposed to light and heat of the light source unit 105 for a long time. For example, the mounting structure 135 is transparently processed and includes a material processed to be durable against light and heat (eg, Poly Ethylene (PE), Nylon, Clearance Poly Imide (CPI), Teflon, etc.) can do.

According to an embodiment of the present invention, the mounting structure 135 is a material having a specified range of ductility that increases without damage to a specified range by an external force and elasticity of a specified range to return to the original state when the external force is removed. It may include. Preferably, the mounting structure 135 includes a material having a ductility that extends beyond the maximum cross-sectional area of the light bulb included in the light source unit 105 by external force and an elastic material to return to the original state when the external force is removed. You can.

According to an embodiment of the present invention, the mounting structure 135 may include a material that maintains the design strength of a specified range (for example, a range that maintains the rigidity of the specified range) before or during light emission of the light source unit 105. You can. Preferably, the mounting structure 135 has a predetermined range of design intensity to maintain a pre-designed geometric structure at room temperature (for example, 25 ° C), heat generated during light emission of the light source unit 105 (for example, It may contain materials that do not deteriorate (e.g., do not become soft) and maintain a specified range of design strength, even under prolonged exposure over a specified period of time (at least 25 ° C and up to 300 ° C). have.

According to an embodiment of the present invention, the mounting structure 135 may include an air contact area of a designated area for contacting air in a designated area of the surface area, in this case, the designated air contact of the mounting structure 135 The photocatalytic material portion 140 may be formed by coating the photocatalytic material designated in the region. On the other hand, the air contact area is in contact with air convecting toward the open upper area of the lampshade 115 by flowing in the downward side direction of the lampshade 115 by heat generated during light emission of the light source unit 105. Possible areas can be included.

Meanwhile, when the photocatalytic material part 140 is formed in a designated area of the surface area of the mounting structure 135, the mounting structure 135 includes a bead structure for maximizing the contact area of air as illustrated in FIG. However, the present invention is not limited thereby.

Meanwhile, according to an embodiment of the present invention, the mounting structure 135 may include a contact structure 145 for contacting air in at least one region. In this case, the contact structure portion 145 includes at least a portion of the area (or the entire region) including an air contact area over a designated area for contacting air, and preferably, a designated air contact area among the areas of the contact structure part 145 The photocatalytic material portion 140 may be coated to form the photocatalytic material portion 140. On the other hand, the air contact area is in contact with air convecting toward the open upper area of the lampshade 115 by flowing in the downward side direction of the lampshade 115 by heat generated during light emission of the light source unit 105. Possible areas can be included.

According to the method of the present invention, the contact structure 145 may include at least one of a bead structure and a fin structure for maximizing the contact area of air. However, the shape of the contact structure portion 145 is not limited to a bead structure or a pin structure, and if the configuration portion of the components constituting the photocatalyst module 130 forms an air contact area above the designated area, the photocatalyst material is coated. It may be defined as the contact structure 145.

According to an embodiment of the present invention, the contact structure portion 145 preferably includes a transparent material that transmits light from the light source portion 105. Thus, the light emitted from the light source unit 105 and radiated can pass through the interior of the mounting structure 135 and the contact structure 145 to reach the photocatalytic material part coated on the air contact area.

According to an embodiment of the present invention, the contact structure 145 includes a material that does not deteriorate even when exposed to light generated by the light source unit 105 and heat generated during light emission of the light source unit 105 for a period of time or longer. It is desirable to do. Preferably, the contact structure portion 145 preferably includes a material that does not fall in transparency even when exposed to light and heat of the light source portion 105 for a long time.

On the other hand, if the mounting structure 135 is a material that maintains the design strength of a specified range (for example, a range that maintains the rigidity of the specified range), the photocatalytic module 130 is designated to be mounted on the light source unit 105 It includes a hinge portion 150 to open or narrow the portion over a specified distance, the elastic portion 155 for applying a force in a direction to narrow the gap between the portions opened by the hinge portion 150, and the hinge portion 150 ) May further include one or more components of the opening / closing part 160 corresponding to a part that is widened or narrowed over a distance specified by).

The hinge portion 150 of the portion corresponding to the mounting structure 135 (or a combination of the mounting structure 135 and the contact structure 145), the photocatalytic module 130, the designated light bulb area of the light source unit 105 A hinge function for opening or narrowing a designated portion over a specified interval to mount the gate, and the opening / closing unit 160 corresponds to a designated portion that is widened or narrowed through the hinge 150.

The elastic portion 155 narrows the gap between the open portions of the hinge portion 150 when the opening and closing portions 160 are opened at regular intervals based on the hinge portion 150 by an external force and then the external force is removed. It is a generic term for a component that performs a function of applying a force in a direction. Preferably, the elastic portion 155 may include a metallic elastic material such as a spring or a spring, or may include various non-metallic elastic materials. Meanwhile, according to another exemplary embodiment of the present invention, when the clasp function or the locking function capable of maintaining the open and narrowed state in the opening / closing part 160 is included, the elastic part 155 can be omitted. It is not limited.

The opening / closing part 160 is a generic term for a designated part that is widened or narrowed through the hinge part 150. Preferably, the opening / closing part 160 may include a clasp function or a locking function capable of maintaining an open and narrowed state based on the hinge part 150. Meanwhile, when the clasp function or the locking function is included in the opening / closing part 160, the elastic part 155 may be omitted, and the present invention is not limited thereto.

On the other hand, the photocatalyst module 130 is provided on one side of the mounting structure 135 mounted on the designated light bulb area of the light source unit 105 or is bound to generate light by irradiating light emitted from the light source unit 105 Further comprising a power generation unit 165, and a fan unit 170 operating on the basis of the power generated through the power generation unit 165 to generate pressure for flowing air around the photocatalytic material unit 140, According to an embodiment, the fan unit 170 blocks the light emitted from the light source unit 105 from being reflected by the rotation of the fan for generating the pressure, or blocks the shadow from the rotation of the fan from being formed. A blocking part (not shown) may be further included.

The power generation unit 165 is a generic term for a component that generates power (eg, a power source capable of operating the fan unit 170) using light emitted and emitted through the light source unit 105 without a separate external power supply. Preferably, the power generation unit 165 is provided on one side of the mounting structure 135 mounted on the designated light bulb area of the light source unit 105 or is bound to a panel irradiated with light emitted from the light source unit 105 (illustrated) And omitted) and a generator (not shown) for generating power by using the light irradiated on the panel, and may further include a converter for converting the generated power to a designated operating power according to an implementation method.

The fan unit 170 is a generic name of a component unit that generates pressure for flowing air around the photocatalytic material unit 140 using power generated by the power generation unit 165 as an operating power source. Preferably, the fan unit 170 includes a motor (not shown) that rotates using the power generated through the power generation unit 165 and a fan (not shown) that rotates to generate pressure by receiving the rotational force of the motor. In addition, a body (not shown) for transmitting the pressure generated by the rotation of the fan in a specific direction may be further included.

According to an embodiment of the present invention, the fan unit 170 blocks light emitted from the light source unit 105 from being repeatedly reflected while changing a reflection angle by rotation of the fan, and / or the light source unit 105 It may further include a blocking portion to block the light emitted from the repetitively formed while changing the shadow formation position by the rotation of the fan. On the other hand, the blocking unit is implemented in the form of a separate component provided in the fan unit 170, and / or using the arrangement relationship between the body of the fan unit 170 and the light source of the fan and the light source unit 105, the fan unit The body of 170 may be designed and manufactured to perform the function of the blocking portion.

The photocatalytic material unit 140 is a generic term for a component formed by coating a designated photocatalytic material on a designated air contact area, preferably formed by coating a designated photocatalytic material on a designated air contact area of the area of the mounting structure 135 And / or is formed by coating a designated photocatalytic material in a designated air contact area of the area of the contact structure 145 provided to contact air to at least one area of the mounting structure 135. Here, the photocatalytic material is made of titanium oxide (TiO2).

According to the method of the present invention, the photocatalytic material portion 140 is 30nm or less photocatalytic material particles in the designated air contact area of the mounting structure 135 and / or the designated air contact area of the contact structure 145 It can be produced by coating. According to the present invention, no matter how transparent the material of the mounting structure 135 is, since the titanium oxide (TiO2) contained in the photocatalyst material is an opaque material used as a raw material for a white pigment, the photocatalyst material is coated. The photocatalytic material must be thinly coated on the designated air contact area to minimize the decrease in light intensity by the photocatalytic material even when the photocatalyst module 130 is mounted on the light source unit 105, and for this purpose, the photocatalyst material must be coated thinly on the designated air contact area It is preferable that the size of the photocatalytic material particles to be made is 30 nm or less.

According to an exemplary embodiment of the present invention, the photocatalytic material unit 140 may include the mounting structure 135 or the designated air contact area of the mounting structure 135 and / or the designated air contact area of the contact structure 145. A photocatalyst material designated in the primer-treated air contact area after a primer treatment designated so that the photocatalytic material is easily coated on the air contact area while preventing the transparency of the contact structure portion 145 from being damaged (or minimize the transparency loss) It can be produced by coating.

According to the method of the present invention, the photocatalytic material portion 140 is made of a silicon (Si) component that is transparent to the designated air contact region of the mounting structure 135 and / or the designated air contact region of the contact structure 145. It can be produced by coating the designated photocatalytic material after surface treatment of the coating agent. Here, since the silicon (Si) component is used as a raw material for transparent glass, and is a material that is safe for photocatalytic reaction of titanium oxide (TiO2), the coating agent of the silicon (Si) component does not damage the transparency of the air contact area. In addition, the photocatalytic material is treated to maintain a stable coating state on the air contact area, and the photocatalytic material can also be blocked from generating a catalytic reaction on the material of the mounting structure 135 or the contact structure 145. have.

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

The photocatalytic reaction of the photocatalytic material occurs through the process of restoring the electrons excited from the valence band to the conduction band by applying light energy to titanium oxide (TiO2). On the other hand, electrons excited by the conduction band in the valence band are normally restored to the valence band in a time period of about 10 ^ -6 seconds. Thus, when the electrons are excited and restored in the valence band in the time period of 10 ^ -6 seconds, a sufficient photocatalyst is restored. The reaction may not occur. On the other hand, when light in the UV-A wavelength band is applied to titanium oxide (TiO2), the electrons excited by the conduction band in the valence band are restored to the valence band slower than the 10 ^ -6 second, resulting in a photocatalytic reaction.

On the other hand, according to the method of the present invention, the photocatalytic material may be prepared by doping a designated metal element having conductivity to titanium oxide (TiO2), in which case the metal element doped in the titanium oxide (TiO2) is titanium oxide (TiO2) TiO2) is applied to light energy to delay the life of the electrons excited from the valence band to the conduction band (Life Time), and / or delay the conduction band from the valence band Breaks at least some of the relationship between the electrons excited with and the holes formed in the valence band (for example, the electrons excited by the conduction band in the valence band are freely electromagnetized and move to the metal element) In the case, the relationship between the electrons excited by the conduction band and the hole formed in the valence band is broken. Other electrons may be other electrons, and a specific wavelength band designated for the photocatalytic reaction of the titanium oxide (TiO2) (for example, a time during which the electrons excited from the valence band to the conduction band is restored to its original state is delayed) (for example, , UV-A wavelength band) can also perform a function of inducing a photocatalytic reaction through the light source unit 105 of a wavelength band other than that. According to the method of the present invention, the metal element may include various metal elements having conductivity, such as gold (Au), silver (Ag), copper (Cu), aluminum (Al), and preferably silver (Ag). It may contain elements.

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

In more detail, FIG. 2 illustrates a simple embodiment in a plan view in cross section of the photocatalytic module 130 including a mounting structure 135 which is detached from a light source unit 105 in a top-down light bulb shape in the form of a bead, Any person having 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 2, but the present invention is inferred. It is made including all embodiments, and the technical features are not limited to only the embodiment illustrated in FIG. 2.

Referring to the embodiment of FIG. 2, the photocatalyst module 130 increases the ductility that extends beyond the maximum cross-sectional area of the light bulb included in the light source unit 105 by external force and returns elasticity to return to the original state when the external force is removed. A specified number of beads are produced in the form of a ball through a connecting thread of a material having a material, and the set of beads of the specified number sewn by the connecting thread and the connecting thread is a light bulb type light source unit inserted in a downward direction of the socket unit 110. The designated geometry is mountable in a designated bulb region corresponding to a region between the minimum and maximum diameters based on the circular cross-section of 105.

On the other hand, one side of the beads sewn by the connecting thread is formed with a mounting area mounted on a designated light bulb area of the light source unit 105, and a designated photocatalytic material is coated on the designated air contact area of the beads to form a photocatalytic material unit 140. To form.

3A and 3B are diagrams illustrating another embodiment of the photocatalytic module 130 according to the method of the present invention.

In more detail, FIGS. 3A and 3B include a mounting structure 135 removed from the light source unit 105 in the form of a light bulb, and a photocatalytic material unit 140 coated on a designated air contact area, the hinge unit 150, As an example of a planar cross-sectional view of the photocatalytic module 130 including the elastic part 155 and the opening and closing part 160, as well as the power generation part 165 and the fan part 170, the present invention belongs to Those of ordinary skill in the art will be able to deduce various embodiments of implementing the photocatalytic module 130 by referring to and / or modifying the drawings 3a and 3b, but the present invention provides all It is made to include the embodiment, the technical features are not limited to only the embodiments illustrated in Figures 3a and 3b.

Referring to the embodiment of FIG. 3A, the photocatalytic module 130 has a mounting area of a designated geometry structure that can be mounted in a designated light bulb area corresponding to an area between a minimum diameter and a maximum diameter based on a circular cross-section of the light bulb type light source unit 105, By the relationship between the structural characteristics of the mounting area and the earth's gravity, the mounting structure 135 maintaining the mounted state in the designated light bulb area of the light bulb type light source 105 and the designated air among the areas of the mounting structure 135 Formed by coating the photocatalytic material designated in the contact area, or formed by coating the designated photocatalytic material in the designated air contact area among the areas of the contact structure 145 provided for contacting air to at least one area of the mounting structure 135 It includes a photocatalytic material portion 140.

On the other hand, the photocatalytic module 130 according to the embodiment of this figure 3a is a part designated to be mounted on the light source unit 105 (for example, a portion corresponding to the opening / closing unit 160) is spread over a specified interval as illustrated in the example of FIG. It may include a hinge portion 150 to be narrowed.

On the other hand, the photocatalytic module 130 according to the embodiment of this figure 3a further includes an elastic part 155 that applies a force in a direction to narrow the gap between the open portions by the hinge 150, as illustrated in Figure 3b, or And / or an opening / closing part 160 corresponding to a part that is widened or narrowed more than a gap specified by the hinge part 150.

On the other hand, the photocatalytic module 130 according to the embodiment of the figure 3a is provided on one side of the mounting structure 135 mounted on the designated light bulb area of the light source section 105 or is bound to emit light emitted from the light source section 105. The generation unit 165 for generating the designated power under irradiation and a fan unit 170 operating based on the power generated through the generation unit 165 to generate pressure for flowing air around the photocatalytic material unit 140 ) May be further included. On the other hand, at least one of the power generation unit 165 and the fan unit 170 may be provided in a plurality of two, thereby the present invention is not limited.

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

In more detail, FIG. 4 shows an embodiment of a process of manufacturing a photocatalytic module 130 mountable in a designated light bulb area corresponding to a region between a minimum diameter and a maximum diameter based on a circular cross-section of the light bulb type light source unit 105. However, a person having ordinary knowledge in the technical field to which the present invention pertains may refer to this figure 4 and / or modify it to infer various embodiments of the manufacturing process of the photocatalytic module 130. It is made including all the inferred embodiments, and the technical features are not limited to only the embodiments illustrated in FIG. 4.

Referring to Figure 4, each of the structural parts constituting the photocatalytic module 130 according to a pre-designed design structure for manufacturing the photocatalytic module 130 (eg, mounting structure 135, contact structure 145, mounting structure ( 135) and one or more structural parts of the combination of the contact structure part 145, and a hinge part 150, an elastic part 155, an opening / closing part 160, and a power generation part provided in the photocatalytic module 130 according to an implementation method ( 165) and one or more designated structures, such as one or more of the fan parts 170) 400, and a primer designated in the designated air contact area of the mounted structure 135 and / or the contact structure 145 among the fabricated / prepared structures After the treatment and / or the silicon (Si) -based coating agent treatment (405), the primer treatment and / or coating agent curing process is treated (410).

When the primer treatment and / or coating agent treatment for the designated air contact area of the mounting structure 135 and / or the contact structure 145 is cured, the mounting structure 135 cured after the primer treatment and / or coating agent treatment And / or coating the designated photocatalytic material to the designated air contact area of the contact structure 145 (415), followed by thermal drying (420).

When the photocatalytic material designated in the designated air contact area of the mounting structure 135 and / or the contact structure 145 is coated and thermally dried, each structure is cut and / or combined according to a designated design structure to form a bulb type light source unit ( 105) to manufacture a photocatalytic module 130 that can be mounted (425).

100: ceiling lamp 105: light source unit
110: socket 115: lamp shade
120: frame portion
130: photocatalytic module 135: mounting structure
140: photocatalytic material portion 145: contact structure portion
150: hinge portion 155: elastic portion
160: opening and closing unit 165: power generation unit
170: fan unit

Claims (21)

A light source unit that emits light of a specified wavelength (or wavelength band) by using a power source and has an external shape in the form of a light bulb, a socket unit for inserting and supporting the light source unit in a downward direction, and supplying power to the light source unit, and the socket unit In the photocatalytic module that can be removed from the light source portion of the ceiling-type light fixture having a frame portion having a structure fixed to the ceiling is coupled,
A light-emitting portion inserted in a downward direction from the socket portion has a mounting area of a designated geometry that can be mounted in a designated light bulb area corresponding to a region between a minimum diameter and a maximum diameter based on a circular cross-section, and has structural features and earth gravity of the mounting area. A mounting structure unit that maintains a mounted state on a designated light bulb area of the light bulb type light source unit by a relationship therebetween; And
It is formed by coating a designated photocatalytic material in a designated air contact area among the areas of the mounting structure or coating a designated photocatalytic material in a designated air contact area among areas of a contact structure provided to contact air in at least one area of the mounting structure. The photocatalytic material portion formed by; a photocatalyst module mounted on a ceiling light fixture having a top-down light bulb type light source comprising a.
According to claim 1,
The ceiling-type lamp, the light emitted through the light source portion inserted in the socket portion induces to diffuse to a specified range and further includes a lampshade portion with an open upper area,
The air contact area, the top-down light bulb characterized in that it comprises a region that can be brought into contact with the air convecting in the direction of the open upper region of the lampshade portion by the heat generated during the light emission of the light source portion from the lower side of the lampshade portion A photocatalyst module mounted on a ceiling lamp with a form light source.
According to claim 2, The mounting structure,
Geometry structure not exposed to the open upper area of the lampshade,
A photocatalyst module mounted on a ceiling light fixture having a top-down light bulb type light source, further comprising at least one geometric structure that is not exposed to the lower side region of the lampshade.
The method of claim 1, wherein the geometric structure,
A diameter structure that can be mounted in a designated bulb region of a diameter range larger than a minimum diameter and smaller than a maximum diameter based on a circular cross-section of the bulb-shaped light source portion inserted from the socket portion in a downward direction
A curvature structure corresponding to a specified precursor curvature between the minimum diameter and the maximum diameter,
A photocatalyst module mounted on a ceiling light fixture with a top-down light bulb type light source, characterized in that it comprises at least one structure of a tilting structure for mounting in a designated bulb region between the minimum diameter and the maximum diameter.
The method of claim 1, wherein the mounting area,
A photocatalyst module mounted on a ceiling lamp with a top-down light bulb type light source, characterized in that it comprises a surface-treated area to increase the frictional force with the designated light bulb area of the light source unit.
According to claim 1, wherein the mounting structure,
A photocatalyst module mounted on a ceiling lamp having a top-down light bulb type light source, comprising a transparent material that transmits light from the light source unit.
According to claim 1, wherein the mounting structure,
A photocatalyst module mounted on a ceiling light fixture with a top-down light bulb type light source, characterized in that it comprises a material that does not deteriorate in a state of being exposed to light and heat of the light source part for a period of time or more.
The method of claim 1, wherein the contact structure,
A photocatalyst module mounted on a ceiling light fixture having a top-down light bulb type light source, comprising at least one of a bead structure and a fin structure for maximizing the contact area of air.
The contact structure according to claim 1 or 8,
A photocatalyst module mounted on a ceiling lamp having a top-down light bulb type light source, comprising a transparent material that transmits light from the light source unit.
The contact structure according to claim 1 or 8,
A photocatalyst module mounted on a ceiling light fixture with a top-down light bulb type light source, characterized in that it comprises a material that does not deteriorate in a state of being exposed to light and heat of the light source part for a period of time or more.
According to claim 1, wherein the mounting structure,
A photocatalyst module mounted on a ceiling light fixture having a top-down light bulb type light source, comprising a hinge portion that opens or narrows a designated portion over a specified distance to be mounted on the light source portion.
The method of claim 11, wherein the mounting structure,
A photocatalyst module mounted on a ceiling light fixture having a top-down light bulb type light source, characterized in that it is provided with or connected to an elastic part that exerts a force in a direction to narrow the gap between the parts opened by the hinge part.
The method of claim 11, wherein the mounting structure,
A photocatalyst module mounted on a ceiling light fixture having a top-down light bulb type light source, further comprising an opening / closing portion corresponding to a portion that is widened or narrowed over a gap specified by the hinge portion.
According to claim 1,
A power generation unit provided on one side of the mounting structure mounted on the designated light bulb area of the light source unit or bound to generate a designated power by receiving light emitted from the light source unit;
A photocatalyst mounted on a ceiling light fixture having a top-down light bulb type light source, further comprising a fan unit that operates based on the power generated through the power generation unit to generate a pressure for flowing air around the photocatalyst material unit. module.
15. The method of claim 14, The fan unit,
A top-down light bulb shape further comprising a blocking unit that blocks light emitted from the light source unit from being reflected by rotation of the fan for generating the pressure or blocks a shadow corresponding to the rotation of the fan from being formed. A photocatalyst module mounted on a ceiling lamp with a light source.
According to claim 1, wherein the photocatalytic material portion,
A photocatalyst module mounted on a ceiling light fixture with a top-down light bulb type light source, characterized in that it is produced by coating particles of photocatalytic material of 30 nm or less in the air contact area.
According to claim 1, wherein the photocatalytic material portion,
A photocatalyst module mounted on a ceiling light fixture having a top-down light bulb type light source, characterized in that it is produced by coating a designated photocatalyst material after treatment with a designated primer in the air contact area.
According to claim 1, wherein the photocatalytic material portion,
A photocatalyst module mounted on a ceiling light fixture with a top-down light bulb type light source, characterized in that it is produced by surface-treating a coating agent of silicon (Si) component in the air contact area and coating a designated photocatalyst material.
The method of claim 1, wherein the photocatalytic material,
A photocatalyst module mounted on a ceiling light fixture with a top-down light bulb type light source, characterized in that it comprises a material by doping a designated metal element having conductivity in titanium oxide (TiO2).
The method of claim 19, wherein the metal element,
It is equipped with a top-down light bulb type light source, characterized in that it performs a function of inducing a photocatalytic reaction through the light source unit by delaying the time when electrons excited from the valence band to the conduction band are restored to their original state by applying energy to titanium oxide (TiO2). A photocatalyst module mounted on a ceiling lamp.
The method of claim 19, wherein the metal element,
A top-down light bulb characterized by performing a function of inducing a photocatalytic reaction through the light source unit by at least partially breaking a relationship between electrons excited from a valence band to a conduction band and holes formed in the valence band by applying energy to titanium oxide (TiO2) A photocatalyst module mounted on a ceiling lamp with a form light source.

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