KR102310103B1 - Far-infrared radiation lamp - Google Patents

Abstract

The present invention has a feature that an air pocket part is formed in a far-infrared radiation lamp to emit a large amount of far-infrared radiation when heated by a lamp and be used as a light. The far-infrared radiation lamp includes a main body, a lamp, a cover, and a breakage prevention net. A cover part provided on the lamp can be moved vertically in a vertical direction from a main body, so that a user can easily adjust far-infrared radiation from any location, thereby improving user satisfaction.

Description

Far-infrared radiation lamp

The present invention relates to a lamp for emitting far-infrared rays, and more particularly, to a lamp emitting a large amount of far-infrared rays beneficial to the human body by mixing ocher and minerals emitting far-infrared rays.

In general, bricks or tiles, which are fired products of clay on a flat surface, may be used for finishing the inner and outer walls of a building, and these bricks or tiles are fixed to the inner and outer walls of the building with mortar or adhesive.

Currently used indoor architectural tiles are used for some interior materials such as kitchens, bathrooms, and verandas, but they have developed mainly for design and practicality rather than hygienic aspects. is being presented

These tiles or bricks are mainly manufactured by mixing concrete or ceramics, and recently, a finishing material having a far-infrared radiation effect by mixing ocher is also used.

In the 'soil tile and manufacturing method thereof' of Patent Registration No. 0837850 (2008.06.05.), calcium hydroxide and loess are mixed with any one or more of elvan, illite, and tourmaline, and fly ash, diatomaceous earth, We propose a tile manufactured by a composition comprising any one or more components of volcanic ash and a component containing any one or more ore particles selected from the group of porcelain, pyrophyllite, and talc, and containing dyes and antibacterial agents on the surface.

Recently, efforts to manufacture finishing materials or building materials such as tiles using various natural materials are rapidly increasing, and in particular, materials containing beneficial minerals for the human body are being used in various ways.

The ocher is mainly used for beds or sofas, but examples used for lighting are extremely rare.

(Documentation) Patent Registration No. 0837850 (2008.06.05.)

In this embodiment, since the cover part provided in the electric lamp is movable vertically in the vertical direction in the main body part, the user can easily adjust the far-infrared radiation to be emitted from any position, so that the user's satisfaction with use is improved.

This embodiment intends to provide a far-infrared radiation lamp having an air pocket part so that a large amount of far-infrared rays from the lamp penetrate more into the human body.

The present embodiment intends to provide a far-infrared radiation lamp capable of radiating more far-infrared rays by changing the structure to minimize the loss of thermal energy along with the far-infrared radiation from the electric lamp.

In order to achieve the above object, the far-infrared radiation lamp according to an embodiment of the present invention includes a main body portion 50 provided with a first mounting portion 52 in a lower circumferential direction, and a socket S on the inner upper portion; a lamp (L) installed in the socket (S) and emitting far-infrared rays generated when power is applied to the outside; A second mounting unit 102 coupled to the first mounting unit 52 is provided, and an air pocket unit 110 formed to receive and store far-infrared thermal energy irradiated from the lamp (L), and the lamp (L). a cover unit 100 having a plurality of through-holes 120 through which far-infrared rays generated from are passed; and a breakage prevention net 200 attached to the lower surface of the cover part 100 to prevent damage, wherein the air pocket part 110 has an inlet part 111a opened on the upper surface of the cover part 100 . and first and second radially extending downwards of the cover part 100 so that thermal energy of the heated air introduced through the inlet part 111a is conducted to the lower surface of the cover part 100 . and auxiliary air pockets 111c and 111cc.

The first auxiliary air pocket portion 111c is spaced apart from each other on both left and right sides of the air pocket portion 110, and the second auxiliary air pocket portion 111cc is the first auxiliary air pocket portion 111c. ) extends relatively short from the center position on the left and right to the lower side.

The cover part 100 further includes a reflector 130 provided to reflect the far-infrared rays generated from the lamp L in the inner circumferential direction to the inner upper surface of the cover part 100 , the reflector 130 . is a body portion 132 formed in a left-right symmetrical form based on the insertion hole 131 formed in the center so that the socket (S) is inserted; a heat storage unit 134 for forming a predetermined space inside the body unit 132 to store heat energy generated from the lamp (L); It includes a round portion 136 that is repeatedly extended from the opposite surface facing the lamp (L) to reflect the heat and light irradiated from the lamp (L) at different angles toward the cover portion (100). .

The cover part 100 has a first screw thread 102a formed along a circumferential edge of the second mounting part 102 so as to be able to ascend or descend toward the ramp L, and the first mounting part 52 . A second screw thread 52a coupled to the first screw thread 102a is formed in the lamp (52a) to be screwed to each other, and the lamp ( It is characterized in that movement toward L) is made.

The main body portion 50 is characterized in that the auxiliary lamp 10 is provided in the inner circumferential direction to increase the surface temperature of the cover portion (100).

The present embodiments induce a convective flow of air through the air pocket inside the main body to reduce the temperature drop through heat transfer, thereby increasing the amount of far-infrared radiation emitted toward the user.

In the present embodiments, convection, circulation, and storage of the heated air inside the body part are possible, so that the temperature drop is minimized even when used for a long time, so the user's satisfaction is improved.

Embodiments of the present invention can be used in a jjimjilbang, an electric lamp, or a table lamp, so that a large amount of far-infrared radiation is emitted in a large amount to maximize the efficacy of far-infrared radiation.

1 is an exploded perspective view of a far-infrared radiation lamp according to an embodiment of the present invention.
Figure 2 is a cross-sectional view showing the coupling state of the body portion and the cover of the far-infrared radiation lamp according to an embodiment of the present invention.
Figure 3 is a cross-sectional view of the use state of the far-infrared radiation lamp according to an embodiment of the present invention.
4 is a view showing a state in which a light is installed in the main body according to an embodiment of the present invention.
5 is a view showing a body portion and a cover according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art can easily implement them.

The scope of the present invention should not be construed as being limited by the embodiments described herein.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the description of the embodiment, the same reference numerals are assigned to the same components, and in some cases, the descriptions of the same reference numerals will be omitted.

A far-infrared radiation lamp according to an embodiment of the present invention will be described with reference to the drawings.

1 to 4, the far-infrared radiation lamp 1 according to this embodiment uses clay or loess, which is an eco-friendly material, so that far-infrared rays and negative ions are emitted, so that it can be used harmlessly to the human body.

The far-infrared radiation lamp is provided with a first mounting part 52 in the lower circumferential direction, a body part 50 having a socket S on the inner upper part, and is installed in the socket S, and is generated when power is applied. A lamp (L) for emitting far-infrared radiation emitted to the outside, and a second mounting part (102) coupled to the first mounting part (52) are provided, and are formed to receive and store the thermal energy of the far-infrared rays irradiated from the lamp (L) The air pocket part 110 and the cover part 100 having a plurality of through-holes 120 through which the far-infrared rays generated from the lamp L pass, and the cover part 100 are attached to the lower surface of the cover part 100 to prevent damage. It includes a prevention net (200).

In addition, the air pocket unit 110 has an inlet portion 111a opened on the upper surface of the cover portion 100 and heat energy of the heated air introduced through the inlet portion 111a is transferred to the cover portion 100 . ) and the first and second auxiliary air pockets (111c, 111cc) extending radially toward the lower side of the cover part 100 so as to be conducted to the lower surface.

The body part 50 can be variously changed into a hemispherical shape or a semicircular shape, and in this embodiment, it is shown in a hemispherical shape.

The body part 50 may be formed by selecting any one or a plurality of clay, loess, kaolin, celadon, or white porcelain to emit, for example, far-infrared rays, and is not particularly limited to a specific material.

For example, the main body 50 is formed of a mineral such as clay or loess, and a mineral layer in which the far-infrared mineral (tourmaline and elvan, germanium, and feldspar) and the glaze are mixed is formed so that the far-infrared radiation is more easily radiated. The higher the temperature, the greater the far-infrared emissivity.

A lamp (L) is installed in the inner socket (S) of the main body portion (50), and the lamp (L) may be changed to various shapes in size or shape in addition to the shape shown in the drawings.

The first mounting part 52 is coupled to the second mounting part 102 formed in the cover part 100 to be described later, and a more detailed description thereof will be given while describing the cover part 100 .

In this embodiment, the cover part 100 forms an air pocket part 110 on the inside of the cover part 100 so that the amount of far-infrared radiation radiated to the lower side of the cover part 100 is increased, and the air pocket part 110 has a predetermined amount. In a state in which air having a temperature of

In this case, when the user is positioned under the cover part 100, a large amount of far-infrared rays having a predetermined temperature may be radiated downward. In addition, since the external radiation amount of far-infrared radiation increases as the temperature of the cover part 100 increases, the amount of far-infrared radiation due to the temperature increase of the cover part 100 can be increased simultaneously with the thermal energy generated by the lamp L. .

To this end, in this embodiment, the air pocket part 110 is formed inside the cover part 100 , and the air pocket part 110 is a material (clay, ocher, white clay) emitting far infrared rays like the body part 50 . ) is made of

The cover part 100 may be formed with a plate-shaped heat transfer plate made of a metal or non-metal material such as aluminum or copper having excellent thermal conductivity on the upper surface or the lower surface, and is used without being limited to a specific material or shape.

The body part 100 has, for example, a through hole 120 formed based on a plan view, and the through hole 120 may be variously changed without being limited to the size and arrangement state shown in the drawings.

In addition, the main body 100 may be formed with an opening having a relatively larger diameter than the aforementioned through hole 120 at the center, and light and heat energy generated from the lamp L pass through the opening hole. Thus, it can be moved toward the face or neck of the user's upper half.

The cover part 100 is formed in a disk shape corresponding to the lower surface of the body part 50 as an example, but may be changed to another shape. The air pocket part 110 is formed to increase the amount of far-infrared radiation. For example, when heat is applied from the outside at a specific temperature to maximize the amount of far-infrared radiation, the loss of thermal energy is minimized so that the emissivity irradiated to the outside of the main body 50 is significantly increased; clay, loess, white clay, aluminum, copper or Similarly, since a material having a high heat transfer rate is used, the effect of far-infrared rays through the air pocket unit 110 can be improved.

The air pocket unit 110 is formed in any one of a spherical shape and an elliptical shape, but may be formed in another shape, and has a rounded inside shape so that air convection is stably made. In addition, when the body part 50 is manufactured, it may be inserted as a separate component or manufactured together in another way.

When the lamp L is operated, a convection phenomenon of air existing between the lamp L and the cover part 100 is caused as shown in the arrow direction. The cover part 100 may radiate a large amount of far-infrared rays to the outside as time elapses to be irradiated to the user's skin. In addition, the far-infrared rays induce a sterilization effect on harmful bacteria along with the user's blood circulation and waste product discharge, so that it can be used as an eco-friendly finishing material or tile.

The first auxiliary air pocket portion 111c according to the present embodiment is positioned on both left and right sides based on the drawing, and the second auxiliary air pocket portion 111cc is located between the left and right sides of the first auxiliary air pocket portion 111c according to the drawing. It extends relatively short toward the lower side.

When the lower surface of the main body 50 is heated to a predetermined temperature, the convection phenomenon is continuously performed as the temperature of the air inside the air pocket part 110 increases as time elapses.

When the air temperature rises in the air pocket part 110, the surface temperature on the lower surface of the cover part 100 does not fall due to the heat transfer phenomenon and is maintained at a predetermined temperature. It can emit far-infrared rays.

The air pocket part 110 serves as a kind of chamber, but may delay the temperature drop of the periphery of the air pocket part 100 and the cover part 50 due to convection and heat transfer phenomena.

The first auxiliary air pocket portion 111c corresponds to a kind of passage communicating with the air pocket portion 110, and provides a space through which heat circulating in the first auxiliary air pocket portion 111c can be introduced. .

In particular, since a plurality of first auxiliary air pocket portions 111c are radially disposed on the inner lower end portion 111b, the air heated to a predetermined temperature is continuously convectively circulated as shown by the arrow, and the air pocket portion 110 ), and by delaying the temperature drop for the cover part 100 as much as possible through heat transfer, it is possible to more stably emit a large amount of far-infrared rays.

The first auxiliary air pocket portion 111c is located on the left and right sides based on the drawing, and the second auxiliary air pocket portion 111cc is located between the first auxiliary air pocket portions 111c adjacent to the left and right sides (based on the drawing). The upwardly extended extension length is relatively short. The reason why the auxiliary air pocket part 111cc is extended in this way is that it is shortened in consideration of the thickness of the body part 50 .

In the first and second auxiliary air pockets 111c and 111cc, some air does not easily escape after it is introduced by convection and stays there, so air heated to a specific temperature can be trapped, so that the cover 50 is It is more advantageous for emitting a large amount of far-infrared rays to the outside by preventing a sudden temperature drop after the temperature is raised.

In particular, in the present embodiment, as the heated air stays in the first and second auxiliary air pockets 111c and 111cc, the rate at which the surface temperature of the cover part 100 decreases may be reduced.

In the present embodiment, the first and second diameter reduction portions 111c1 and 111cc1 having reduced diameters are formed in the connection portions connected to the first and second auxiliary air pocket portions 111c and 111cc in the air pocket portion 110 .

The first and second diameter reduction portions 111c1 and 111cc1 are formed after the convection-moving air along the inner circumferential surface of the air pocket portion 110 formed in a spherical shape flows into the first and second auxiliary air pocket portions 111c and 111cc. It is formed to induce the amount of re-emission to the

Therefore, in the spherical air pocket part 110, convective circulation of the heated air is continuously made on the inner peripheral surface, and some air flows into and stays in the first and second auxiliary air pocket parts 111c and 111cc. It is possible to prevent the temperature drop of the entire cover part 100 and continuously radiate far-infrared rays.

In this case, the cover part 50 can minimize the temperature drop due to surface heat loss, and induce heating and convection of air through the air pocket part 110 to increase the emissivity.

In the present embodiment, when the air pocket part 110 is cut in a longitudinal section and viewed from the side, the inlet part 111a opened on the upper surface is opened in the upper side structure, and the inner side of the lower light structure based on the inlet part 111a. The first and second auxiliary airs are formed in the form of a downward light that widens toward the lower end 111b, and extend from the inner lower end 111b toward the lower surface of the cover 100 by a predetermined length. Pocket portions 111c and 111cc are provided.

The reason that the air pocket part 110 is formed in a downward light shape is to have a structure in which the temperature of the lower surface of the cover part 100 does not drop, so that even when heated to the same temperature, more far-infrared rays are emitted to the outside. .

For example, the cover part 100 has a structure shown in a cross-sectional view and is formed of a mineral such as clay or loess, and a far-infrared mineral (tourmaline, elvan, germanium, and feldspar) components and glaze so that the far-infrared rays are more easily radiated on the lower surface. Since the mixed mineral layer 101 is formed, the higher the temperature of the upper surface, the higher the far-infrared emissivity.

To this end, the cover part 50 is formed in the form of a downward-facing light in which the inlet part 111a of the air pocket part 110 is opened with a small area, and it becomes wider toward the inner lower end part 111b. Temperature maintenance by continuous convective movement of heat is maintained, and the movement of heat dissipation is reduced relative to the lower surface of the cover part 100 corresponding to the outside of the inlet part 111a, so that heat loss can be minimized. .

For example, when the lower surface of the cover part 100 is heated to a predetermined temperature, the air temperature inside the air pocket part 110 rises. is reduced, and the convection phenomenon in the air pocket part 110 is continuously made.

When the air temperature rises in the air pocket unit 110, the surface temperature of the cover unit 100 does not drop due to the heat transfer phenomenon and is maintained at a predetermined temperature. can do it

The cover part 100 is provided with a reflector 130 provided to reflect the far-infrared rays generated from the lamp L in the inner circumferential direction to the inner upper surface of the cover part 100 .

The reflector 130 includes a body portion 132 formed in a symmetrical shape from left to right with respect to an insertion hole 131 formed in the center so that the socket S is inserted, and the body so that thermal energy generated from the lamp L is stored. The heat storage unit 134 forming a predetermined space inside the unit 132, and the heat and light irradiated from the lamp L by repeatedly extending in a round from the opposite surface facing the lamp L It includes a round portion 136 that reflects at different angles toward the cover portion 100 .

The reflector 130 plays a role of concentrating the thermal energy generated by the lamp L on the cover part 100, and raises the surface temperature of the cover part 100 to a higher temperature so that a large amount of far-infrared radiation is emitted for a long time. It can be kept more stable.

In this embodiment, the heat energy transmitted from the lamp L through the reflector 130 toward the upper surface of the cover 100 together with the heat energy irradiated from the lamp L to the cover 100 is reflected to make the short By allowing it to rise rapidly to a high temperature within a time, it is possible to achieve the operation of the lamp (L) and the emission of a large amount of far-infrared rays.

The heat storage unit 134 is formed in a hollow state, and air or gas may be injected therein. The heat storage unit 134 provides a space in which heat energy generated by the lamp L and heat energy are stored by the reflector 130's own heat transfer.

The heat storage unit 134 is provided with a heat transfer fin 134a having one end connected to an inner surface of a round portion 136 , which will be described later, and the other end extending toward the heat storage unit 134 by a predetermined length.

The heat transfer fins 134a receive heat through the heat storage unit 134 or the round unit 136 to store thermal energy, and discharge heat toward the heat storage unit 134 to prevent temperature drop.

The round part 136 extends repeatedly toward the inside and outside of the heat storage part 134 with a predetermined curvature, and increases the contact area with the thermal energy irradiated from the lamp L to increase the amount of thermal energy can be stored.

2 to 3, the cover part 100 according to the present embodiment is a first along the circumferential edge of the second mounting part 102 so as to be able to ascend or descend toward the ramp (L). A thread 102a is formed. In addition, a second screw thread 52a coupled to the first screw thread 102a is formed in the first mounting part 52 to be screwed to each other, and the cover part 100 is rotated in a clockwise or counterclockwise direction. Movement toward the ramp (L) is made according to the degree of rotation.

The first mounting part 52 extends upward from a position spaced apart by a predetermined height from the lowermost end of the body part 50, and extends vertically in the circumferential direction for stable installation with the cover part 100. A magnet (M) is provided.

The magnet (M) maintains a state of temporary contact using magnetic force so as not to fall downward when the user installs the cover part 100 on the first mounting part 52, thereby preventing damage due to the fall of the cover part 100. can be prevented

To this end, the cover part 100 is provided with a contact member 104 in the circumferential direction in order to be temporarily contacted by the magnetic force of the magnet (M). Steel is used for the contact member 104 to be in contact with the magnet M, but it may be possible to use other materials that can be contacted by magnetic force.

When the contact member 104 contacts the magnet M, the cover part 100 does not fall from the body part 50 and maintains a contact state. When the user rotates the cover part 100 clockwise, the first screw thread 102a and the second screw thread 52a are engaged with each other, so that the cover part 100 is stably installed in the body part 50 .

When the user continues to rotate the cover part 100 in a clockwise direction, the vertical separation distance between the lamp L and the cover part 100 is shortened, so that the surface temperature of the cover part 100 rises faster, A large amount of far-infrared rays can be more radiated toward the lower side.

In this embodiment, a reflective part 140 inclined toward the cover part 100 is formed on the round part 136 , and the reflective part 140 emits far-infrared rays irradiated from the lamp L to the cover part 100 . The far-infrared rays can always be left toward the surface of the cover part 100 by reflecting it to the upper surface (based on the drawing) of the .

In this case, the surface temperature of the cover part 100 is raised in the shortest time, and high-temperature heat is formed in the air pocket part 100 described above, so that a large amount of far-infrared rays is radiated toward the user.

Therefore, the user can turn on the far-infrared radiation lamp and feel the far-infrared radiation through the skin or hair within a short time, improving satisfaction.

Referring to the accompanying FIG. 3 , the auxiliary lamp 10 is provided in the inner circumferential direction in order to increase the surface temperature of the cover part 100 in the body part 50 according to the present embodiment.

The auxiliary lamp 10 has a smaller size than the above-described lamp L, and the first mounting part 52 described above along the inner circumferential direction of the body part 50 to prevent the temperature drop of the cover part 100 . A plurality is disposed on the upper side of the.

The auxiliary lamp 10 is used for two purposes: for the purpose of illuminance reinforcement, and for raising the temperature of the cover part 100 because the lamp L is a far-infrared lamp, not a conventional incandescent bulb or LED bulb. .

In this case, the illuminance at the lower position of the cover part 100 can be secured, so that the user's satisfaction is improved.

In the present embodiment, a breakage prevention net 200 is provided to prevent damage to the main body 50, and the breakage prevention net 200 is formed in a mesh type.

The anti-damage net 200 may be attached to any one or both of the upper surface or the lower surface of the main body 50, and may be positioned without being limited to a particular position.

Since the breakage prevention net 200 is formed in a mesh shape, it is more advantageous to improve durability.

Since the breakage prevention net is made of a mesh in the form of a grid, it is possible to prevent damage during use by stably supporting it even when an external force is applied from any direction.

As shown in FIG. 5 , the body part 50 and the cover part 100 according to another embodiment of the present invention are respectively coupled to the first mounting part 52 and the second mounting part 102 differently from the above-described embodiment. A coupling hole is formed for the , and coupling through a separate coupling member (not shown) may also be possible.

In this case, the body part 50 and the cover part 100 may be assembled by aligning the positions of the first mounting part 52 and the second mounting part 102 with each other and inserting the coupling member into the coupling hole.

As such, the present invention is not limited to the described embodiments, and it is apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Accordingly, it should be said that such modifications or variations shall fall within the scope of the claims of the present invention.

50: body part
52: first mounting part
L: lamp
100: cover part
110: air pocket part
111a: inlet part
111c, 111cc: first and second auxiliary air pockets
130: reflector
134: heat storage
136: Round Part
200: anti-vandal net

Claims (5)

The first mounting portion 52 is provided in the lower circumferential direction, the body portion 50 is provided with a socket (S) on the inner upper portion;
a lamp (L) installed in the socket (S) and emitting far-infrared rays generated when power is applied to the outside;
A second mounting unit 102 coupled to the first mounting unit 52 is provided, and an air pocket unit 110 formed to receive and store far-infrared thermal energy irradiated from the lamp (L), and the lamp (L). a cover unit 100 having a plurality of through-holes 120 through which far-infrared rays generated from are passed; and
It includes a damage prevention net 200 attached to the lower surface of the cover part 100 to prevent damage,
The air pocket 110 includes an inlet 111a opened on the upper surface of the cover 100 and thermal energy of the heated air introduced through the inlet 111a is transferred to the cover 100 . and the first and second auxiliary air pockets (111c, 111cc) extending radially toward the lower side of the cover part 100 so as to be conducted to the lower surface of the
The cover part 100 further includes a reflector 130 provided to reflect the far-infrared rays generated from the lamp L in the inner circumferential direction to the inner upper surface of the cover part 100,
The first auxiliary air pocket portion 111c is spaced apart from each other on both left and right sides of the air pocket portion 110, and the second auxiliary air pocket portion 111cc is the first auxiliary air pocket portion 111c. ) extends relatively short from the central position on the left and right to the bottom,
The reflector 130 includes a body 132 formed in a symmetrical shape with respect to an insertion hole 131 formed in the center so that the socket S is inserted, and the heat energy generated by the lamp L is stored. The heat storage unit 134 forming a predetermined space inside the body 132 and the heat and light irradiated from the lamp L are repeatedly extended in a round shape from the opposite surface facing the lamp L. A far-infrared radiation lamp including a round part 136 for reflecting at different angles toward the cover part 100 . delete delete The method according to claim 1,
The cover part 100 has a first screw thread (102a) formed along the circumferential edge of the second mounting part 102 so as to be able to ascend or descend toward the ramp (L),
A second screw thread 52a coupled to the first screw thread 102a is formed on the first mounting part 52 to be screwed to each other, and the cover part 100 rotates in a clockwise or counterclockwise direction. A far-infrared radiation lamp that moves toward the lamp (L) according to the degree of being. The method according to claim 1,
A far-infrared radiation lamp, characterized in that the main body (50) is provided with an auxiliary lamp (10) in the inner circumferential direction to increase the surface temperature of the cover part (100).

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