KR20170091377A - Aroma candle container with lighting equipment using self-generation - Google Patents

Abstract

The present invention relates to an aroma soap container having an illuminating function through self-power generation. The aroma candle container includes a case having a cylindrical upper opening and an inner hollow formed therein, the case being filled with wicks and wax, A power generating unit for generating and supplying electricity using heat generated when the power generating unit is burned, a mounting unit formed at the lower portion of the casing to receive the casing and the power generating unit and having an inside space, And a light emitting portion for emitting light.

Description

[0001] The present invention relates to an aroma candle container containing a lighting function through self-

The present invention relates to an aroma candle bowl containing a lighting function through self-power generation, more specifically, a candle burns a wax filled in a container, and a smell is produced. A candle lamp is converted into electricity and used as a lighting function Which includes a self-generated illumination function.

Generally, aroma means fragrance or direction. It is made by processing the herb for convenient use. It is used to process essential oils extracted from flowers, leaves, stems, fruits and roots of plants with special efficacy.

Aroma scent mixes extracted essential oil with flammable solid which melts at suitable temperature such as paraffin or beeswax, and inserting core such as cotton in the center, and when we put light on the core, aroma scent dries, Psychological stability, and stress relief.

However, since most of the herbs are formed in the transparent container with the solid wax and the core, they are not so beautiful, and are used only for the purpose of directing the fragrance and are difficult to be used for decoration.

Korean Patent No. 10-0711221 for solving such a problem relates to a candle body, a candle body, a false-twist core fixed in the candle body, a light or heat transmission line wired along the combustible core in the candle body, A light or heat sensor which detects ignition light or heat of the wick; a sensor which is electrically connected to the sensor and is disposed inside the body of the candle, And a light emitting unit having a plurality of light sources emitting light by electric power, wherein the light emitting unit is provided with a light emission control section for alternately or repeatedly emitting a plurality of light sources to emit light.

However, in the case of the conventional art as described above, the LED irradiates the light from the lower part of the candle container to serve as a taillight. However, it is difficult to control the intensity of light generated from the LED, There was an inconvenience that it had to be replaced.

Korean Patent No. 10-0711221

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an aroma soap container having a lighting function by self-power generation, which can generate electricity using heat generated when a herb is burned, .

Another object of the present invention is to provide an aroma soap container including a lighting function by self-power generation in which heat generated from a candle is collected to heat a container containing a beverage so that a beverage formed inside the container is not cooled.

Another object of the present invention is to provide an aroma soap container including a lighting function by self-power generation which can be used as a mood, a sleeping light, and an illumination light by operating an LED without burning a herb with a rechargeable battery.

To achieve the above object, the present invention provides an aroma soap container including a lighting function through self-power generation, the casing having a cylindrical shape with an upper opening and an interior hollow, the case being filled with wicks and wax, A power generating part formed in the lower part of the case and configured to receive the case and the power generating part and having an inside space, And a light emitting portion for emitting light toward the light emitting portion.

In addition, the mounting portion of the aroma soap container including the illumination function through self-power generation according to the present invention may include an insertion groove formed into a taper so as to insert a case, and a case inserted or protruded according to the size of the case inserted into the insertion groove, And a socket made of an elastic body.

In addition, the power generating portion of the aroma soap container having the lighting function through self-power generation of the present invention includes a ventilation cap which is in close contact with an upper portion of the case and has a plurality of holes formed therein, A heat collecting device formed on the upper part of the ventilation cap and formed in a square shape so that the thermoelectric device can be attached thereto and collecting heat inside the case, a thermoelectric device attached to the upper side of the heat collecting device to receive heat from the heat collecting device, And a cooling device formed of at least one of a heat sink and a cooling fan coupled with the thermoelectric element to cool the thermoelectric element.

In addition, the light emitting unit of the aroma soap container including the lighting function through self-power generation of the present invention is formed in the mounting part, and the LED module is arranged on the circular PCB so as to irradiate light to the case at regular intervals. A storage battery for storing the generated electricity and supplying power to the LED module, the cooling fan, and the USB terminal; and a control device for changing the color of the light emitted from the LED module or controlling the intensity of the light.

In addition, the mounting portion of the aroma soap container including the lighting function through self-power generation of the present invention further includes a fixing base for fixing and supporting the position of the power generating portion. The height of the fixing portion can be adjusted to adjust the height of the power generating portion according to the height of the case. .

In addition, a USB terminal is formed on one side of the mounting portion of the aroma soap container including the illumination function through self-power generation of the present invention, so that auxiliary light for USB operation can be used in combination.

In order to solve the above-mentioned problems, an aroma soap container having a lighting function through self-power generation according to the present invention comprises a casing formed in a cylindrical shape with an upper portion opened and an interior hollow to fix a candle therein, A connecting portion formed at the lower portion of the connecting portion so as to supply or block the air required for the supersonic wave fixed to the case and connected to the upper portion of the mounting portion, A light emitting unit having an LED module formed thereon and a power generating unit formed on the connection unit and generating electricity by using heat generated when the wax is burned.

In addition, an exhaust port is formed above the connecting portion of the aroma soap container containing the lighting function through self-power generation according to the present invention, and the air inlet is formed at the lower portion thereof with an intake port. When the outer circumferential surface is rotated, So that oxygen can be supplied or cut off.

In addition, the electricity generating portion of the aroma soap container including the lighting function through the self-power generation of the present invention is formed in the upper part of the connection portion and is formed in a square shape so that the thermoelectric element can be attached thereto, And a cooling device formed of at least one of a heat sink and a cooling fan coupled to the thermoelectric element to cool the thermoelectric element, .

In addition, the mounting portion of the aroma soap container including the illumination function through self-power generation according to the present invention is formed into a hollow cylindrical shape so as to accommodate the case, and a spiral groove is formed through the outer peripheral surface to insert the lifting pin of the case A height adjuster coupled to the bevel gear of the rotary cylinder to rotate the rotary cylinder, and a straight line formed by a straight line into which the up / down pins of the case are inserted, And a cradle in which a groove is formed.

As described above, according to the aroma soap container including the lighting function through self-power generation according to the present invention, electricity can be produced by using heat generated when the herb is burned, so that there is no need to supply a separate power source .

In addition, according to the aroma soap container of the present invention, the heat generated from the candle is collected to heat the container containing the beverage, thereby preventing the beverage from being cooled inside the container.

In addition, according to the aroma soap container including the lighting function by self-power generation according to the present invention, the LED can be operated using a rechargeable battery even if the incense burner does not burn the incense so that the lamp can be used as a mood,

1 is a perspective view showing an outline of an aroma soap container including a lighting function through self-power generation according to a first embodiment;
FIG. 2 is a perspective view showing an interior structure of an aroma soap container including a lighting function by self-power generation according to the first embodiment. FIG.
FIG. 3 is a perspective view showing the construction of a power generation section of an aroma soap container including a lighting function through self-power generation according to the first embodiment. FIG.
FIG. 4 is a perspective view showing a configuration of a light emitting portion of an aroma soap container including a lighting function through self-power generation according to the first embodiment; FIG.
FIG. 5 is a perspective view illustrating a heating wire formed inside a double glass for heating a variable liquid of an aroma soap container having a lighting function through self-power generation according to the first embodiment; FIG.
FIG. 6 is a perspective view showing an outer appearance of an aroma soap container including a lighting function through self-power generation according to the second embodiment; FIG.
FIG. 7 is a perspective view showing a state in which an internal structure of an aroma soap container including a lighting function through self-power generation according to the second embodiment is seen. FIG.
FIG. 8 is a perspective view showing a configuration of a power generation section of an aroma soap container including a lighting function through self-power generation according to the second embodiment; FIG.
FIG. 9 is a perspective view showing a configuration of a light emitting portion of an aroma soap container including a lighting function through self-power generation according to the second embodiment; FIG.
FIG. 10 is a perspective view showing the outer shape of a mounting portion of an aroma soap container having a lighting function through self-power generation according to the second embodiment; FIG.
FIG. 11 is a perspective view illustrating a socket of an aroma soap container including a lighting function by self-power generation according to the second embodiment; FIG.
FIG. 12 is a perspective view showing a groove formed in a mounting portion for fixing a socket of an aroma soap container having a lighting function through self-power generation according to the second embodiment; FIG.
FIG. 13 is a perspective view showing an outer appearance of an aroma soap container including a lighting function through self-power generation according to the third embodiment; FIG.
FIG. 14 is a perspective view showing an interior structure of an aroma soap container including a lighting function by self-power generation according to the third embodiment. FIG.
15 is a perspective view showing a connecting portion of an aroma soap container including a lighting function through self-power generation according to the third embodiment;
16 is a perspective view showing a configuration of a power generation section of an aroma soap container including a lighting function through self-power generation according to the third embodiment;
17 is a perspective view showing in detail a mounting portion of an aroma soap container having a lighting function through self-power generation according to the third embodiment;
FIG. 18 is a perspective view showing a spring formed in a mounting portion of an aroma soap container having a lighting function through self-power generation according to the third embodiment; FIG.

Specific features and advantages of the present invention will be described in detail below with reference to the accompanying drawings. The detailed description of the functions and configurations of the present invention will be omitted if it is determined that the gist of the present invention may be unnecessarily blurred.

The present invention relates to an aroma soap container containing a lighting function through self-power generation, and more particularly, to an aroma soap container comprising a self-generated aroma wax filled with a candle, The present invention relates to an aroma soap container containing a lighting function.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view showing an outer shape of an aroma soap container including a lighting function through self-power generation according to the first embodiment. FIG.

As shown in FIG. 1, the aroma soap container including the lighting function through self-power generation according to the first embodiment is a case 100 (see FIG. 1) formed so as to fill the wax (not shown) A fire extinguishing cap 150 formed at an upper portion of the case 100 to block oxygen, dust and foreign substances flowing into the case 100; And a mounting portion 400 formed to support and fix the mounting portion 400.

The case 100 is made of a glass material and has a cylindrical shape with an empty interior and is open at its upper part to fill the wax 110. The outer surface of the case 100 is formed of a single- A liquid (not shown) having a color added thereto is sealed.

When the candle is burned in the case 100, the fire extinguishing cap 150 is separated from the case 100 so that oxygen is supplied from the outside, so that the combustion of the wax 110 can be smoothly performed, Is connected to the case 100, the supply of oxygen is cut off so that the candle inside the case 100 is turned off or dust or foreign matter does not flow from the outside.

The mounting portion 400 is formed to support the case 100, which is filled with wax (not shown), so as not to fall over the mounting portion 400. The inside of the mounting portion 400 is shaped to have an empty interior And a light emitting portion (not shown) to be described later is mounted inside.

FIG. 2 is a perspective view showing an interior structure of an aroma soap container including a lighting function through self-power generation according to the first embodiment. FIG.

As shown in FIG. 2, the aroma soap container having a lighting function through self-power generation according to the first embodiment is formed of a cylindrical double glass container, and the interior thereof is filled with wax 110, A mounting part 400 which is formed in a manner to be in contact with the lower part of the case 100 to receive the case 100 and in which the interior of the mounting part 400 is hollow and a mounting part 400, And a light emitting unit 300 formed inside the variable liquid 130 and irradiating light to the variable liquid 130.

The case 100 is formed of a transparent double glass container and the case 100 is filled with the aroma wax 110 and the wick 120 is formed in the center of the aroma wax 110 so as to hold a candle .

In addition, a variable liquid 130 having a hue is filled between the double glasses of the case 100, so that the light generated from the candle can be lightly emitted.

In this case, the variable liquid (130) is a liquid that is diluted with water in a reversible thion paint. When the temperature rises, the color changes and when the temperature lowers, the material returns to the original color. It is possible to give a variety of color changes.

Alternatively, the liquid may be filled with a liquid emitter or an optical fiber instead of the variable liquid 130 so that the liquid itself emits light. For this purpose, a fluorescent paint may be liquefied, or a diluent pigment may be diluted in the variable liquid 130, have.

The power generating unit 200 collects heat generated by burning the wax 110 in the case 100 using a thermoelectric element (not shown) to produce electricity. .

The mounting portion 400 is formed of a transparent glass material or plastic, and the inside of the mounting portion 400 is empty to accommodate the light emitting portion 300. The mounting portion 400 has a color such that the light emitting portion 300 mounted therein is not visible. It may be additive.

The light emitting part 300 is formed inside the mounting part 400 and is closely contacted to the lower part of the case 100 so as to irradiate light to the case 100. Even if the wick 120 is not lit, It is possible to use the electricity to generate mild light in the container to be used as a mood or sleeping.

A detailed description related to the light emitting unit 300 will be described later with reference to FIG.

A speaker (not shown) and a USB terminal (not shown) for data transmission are mounted on the outer circumferential surface of the mounting part 400 so as to output MP3, And the power is supplied from the battery 320 of FIG. 4 formed in the light emitting unit 300 to reproduce music.

The user can play music according to the mood when using the soap container with the mood light or sleeping, and can increase the psychological stability feeling by listening to the scent of fragrance and music. In addition to data transmission through USB terminal, The battery 320 can be charged through the power generation.

FIG. 3 is a perspective view showing a configuration of a power generation section of an aroma soap container including a lighting function through self-power generation according to the first embodiment. FIG.

As shown in FIG. 3, the power generation unit 200 of the aroma soap container having the lighting function through self-power generation according to the first embodiment can absorb heat generated by burning the wax 110 of FIG. 2 A heat collecting device 210 formed of a metallic material having a high thermal conductivity and formed of a donut-shaped circular network; a heat collecting device 210 formed in the same shape as the heat collecting device 210 on the heat collecting device 210 and receiving heat from the heat collecting device 210 And a cooling device 230 formed on at least one of a heat sink and a cooling fan formed on the thermoelectric element 220 to cool the thermoelectric element 220. [ do.

The thermoelectric element 220 is a device using a thermoelectric phenomenon, which is an energy conversion phenomenon that can convert heat into electricity or electricity. The thermoelectric element 220 applies heat to one side and generates heat And is cooled so as to be cooled so as to generate electricity.

As the temperature difference between the thermoelectric elements 220 increases, the electromotive force may become larger. Therefore, a heat collecting device is attached to one surface of the thermoelectric element 220 so that heat can be easily absorbed, and a cooling device is attached to the other surface to emit heat.

For this purpose, according to the present invention, there is provided a heat collecting device formed of copper or aluminum having high thermal conductivity so as to absorb the heat generated by burning the wax 110 and transmit the heat to the thermoelectric device 220 210 are attached.

The heat collecting device 210 is installed in the heat collecting device 220 so that the amount of heat transferred to the thermoelectric element 220 increases as the contact area with the thermoelectric element 220 increases, but the fragrance generated by burning the wax 110, It is preferable that it is formed in the form of

The cooling device 230 attached to the upper part of the thermoelectric element 220 is formed of at least one of a heat sink and a cooling fan. The heat sink is formed of copper or aluminum having a high thermal conductivity and has a plurality of Grooves should be formed.

When the cooling fan is used, air is pushed out of the case 100 of FIG. 2, so that the aroma of the aroma wax 110 burned in the case 100 spreads out to the outside, And the power of the cooling fan can be used without power supply by using the electromotive force generated from the thermoelectric element 220. [

Also, the heat sink and the cooling fan can be used in combination. In this case, since the cooling device is more efficient than using the single cooling device 230, a high electromotive force can be obtained.

Also, the electricity generated by the power generation unit 200 is connected to an electric wire so as to be stored in the battery 320 of FIG. 4, so that electricity can be stored.

4 is a perspective view showing a configuration of a light emitting portion of an aroma soap container including an illumination function through self-power generation according to the first embodiment.

As shown in FIG. 4, the light emitting unit 300 of the aroma soap container including the lighting function through the self-power generation according to the first embodiment is formed at the lower portion of the case 100 to irradiate the variable liquid 130 with light The LED modules 310 are disposed at regular intervals on the edges of the circular PCBs so as to be able to store electricity generated by the power generation unit 200 and supply power to the LED modules 310, A battery 320, and a controller 330 for changing the color of light emitted from the LED module 310 or adjusting the intensity of the light.

The LED module 310 is arranged at regular intervals on the edge of a PCB board formed in a circular shape so as to irradiate light to the variable liquid 130 formed between the double glasses of FIG. 2 and composed of white (white) The support base 350 is formed to be in close contact with the lower portion of the case 100. [

The light emitted from the LED is irradiated toward the variable liquid 130 in FIG. 2 and then passes through the variable liquid 130 to emit a gentle light according to the color of the variable liquid 130, .

The control unit 330 controls the voltage of the LEDs so that the light amount of the LEDs can be adjusted by being attached to the lower part of the LED module 310. When the LEDs disposed in the LED module 310 are red, The user may supply power only to LEDs of a desired color.

The battery 320 is a secondary battery that is used for storing electricity generated by the power generator 200 of FIG. 3 and can be used semi-permanently. The battery 320 may be a secondary battery that can be used semi-permanently. In order to smoothly charge the battery 320, A voltage regulator 340 is formed to generate electricity in the power generator 200 at a constant voltage and store the generated electricity in the battery 320.

2, a contact terminal (not shown) may be formed on a surface of the case 100 of FIG. 2 and the mounting portion 400 of FIG. 2 to allow electricity generated by the power generating unit 200 of FIG. 2 to be transmitted to the light emitting unit 300 (Not shown) are formed.

2, a contact terminal (not shown) is formed on the lower surface of the case 100 of FIG. 2 and the upper surface of the mounting portion 400 of FIG. 2 in order to send the electricity generated by the power generating portion 200 of FIG. 2 to the storage battery 320 The electricity generated by the power generating unit 200 can be sent to the storage battery 320 formed in the mounting unit 400 when the case 100 is mounted on the mounting unit 400.

In addition, since the case 100 may be rotated by the mounting part 400 and the contact terminals may not contact with each other, it is preferable to form contact terminals at the center of the lower surface of the case 100 and the center of the upper surface of the mounting part 400 .

In addition, in order to temporarily replace the battery 320 when the battery 320 is discharged, a detachable groove 360 for detachably attaching the battery 320 to the lower portion of the mounting portion 400 of FIG. 2 may be formed. A switch (not shown) may be formed in a part of the mount of FIG. 2 so that the brightness or color of the LED can be selected.

FIG. 5 is a perspective view showing a heating line formed inside a double glass for heating a variable liquid of an aroma soap container including a lighting function through self-power generation according to the first embodiment. FIG.

As shown in FIG. 5, a transparent heat line 140 is attached between the double glass of the case 100 of the aroma soap container having the lighting function through the self-power generation according to the first embodiment, Thereby supplying heat.

Since the temperature of the variable liquid 130 must be changed in order to change the hue of the variable liquid 130, a transparent heat line 140 is spirally installed between the double glasses of the case 100 in which the variable liquid 130 is formed to heat the variable liquid 130 do.

The heat lines 140 are installed at regular intervals to receive power from the power generation unit 200 of FIG. 2 or the storage battery 320 of FIG. 4 and generate heat to control the temperature of the variable liquid 130 formed between the double glasses So as to change the color.

The temperature of the heating wire 140 can be increased step by step and the voltage supplied to the heating wire 140 is controlled by the control device 330 of FIG. 4, so that the heating can be performed in a stepwise manner until a desired color is obtained .

The heat ray 140 is tightly wound around the lower portion of the case 100 so that the gap between the upper and lower portions of the heat ray 140 increases.

The temperature of the variable liquid 130 in the lower part is increased faster than the temperature of the variable liquid 130 in the upper part due to the heat line 140 tightly wound on the lower part of the case 100, ) Have different colors.

Accordingly, the gradation effect that the color changes from the lower part to the upper part of the variable liquid 130 can be exhibited, so that the appearance can be expressed beautifully and dynamically.

FIG. 6 is a perspective view showing an outer appearance of an aroma soap container including a lighting function through self-power generation according to a second embodiment, FIG. 7 is a perspective view showing an aroma soap container having a lighting function by self- Fig. 3 is a perspective view showing a state in which the inner structure is cut.

As shown in FIGS. 6 to 7, the aroma soap container having a lighting function through self-power generation according to the second embodiment is formed in a cylindrical shape with an upper opening and an inner hollow, A power generator 200 for generating and supplying electricity using heat generated when the wax 110 is burned and formed in the upper portion of the case 100; 100 which is formed in the lower part of the case 100 and is configured to receive the case 100 and the power generation part 200 and is hollow inside; (300).

The case 100 is made of a glass material having an open upper part and an empty interior. A wick 110 containing aroma is filled in the inside of the case 100 so that a candle can be burned. When the wax 110 is burnt, The core 120 and the wax 110 are refilled into the wax 110 or the case 100 filled with the wax 120 and the wax 110 are replaced.

The power generating unit 200 is closely attached to the upper part of the opened case 100 and is produced by using the heat of the candle generated when the wax 110 is burned in the case 100.

The mounting portion 400 is formed at the bottom of the case 100 to support and fix the case 100 so that the socket 470 can be used in accordance with the diameter of the case 100, And the height of the power generator 200 can be adjusted by fixing the position of the power generator 200 using the fixing table 460. [

The light emitting unit 300 stores electricity generated by the power generating unit 200 and is formed inside the mounting unit 400 and irradiates light toward the lower surface of the case 100 that is mounted on the mounting unit 400, The container can be used as sleeping light, taillight, decoration, etc.

FIG. 8 is a perspective view showing a configuration of a power generation section of an aroma soap container including an illumination function through self-power generation according to the second embodiment. FIG.

As shown in FIG. 8, the electricity generating unit 200 of the aroma soap container including the lighting function through self-power generation according to the second embodiment is closely attached to the upper part of the case 100 of FIG. 6, A ventilation cap 240 having an inner opening and a plurality of holes formed on a side thereof so as to allow air to flow in and a rectangular shape formed on an upper portion of the ventilation cap 240 so that the thermoelectric element 220 can be attached thereto A heat collecting device 210 for collecting heat inside the case 100 of FIG. 6; a thermoelectric element 220 attached to an upper side of the heat collecting device 210 to receive electricity from the heat collecting device 210 to produce electricity; And a cooling device 230 formed of a heat sink or a cooling fan coupled with the thermoelectric element 220 to cool the thermoelectric element 220.

The ventilation cap 240 is formed to be in close contact with the upper portion of the case 100 of FIG. 7 and is formed to open through the upper and lower portions. The lower and upper portions of the ventilation cap 240 have different diameters, do.

The upper portion of the ventilation cap 240 is formed to be smaller in diameter than the lower portion to collect heat generated inside the case 100 of FIG. 7, and a plurality of through holes are formed on the outer circumference of the case 100 ) To allow air to flow in.

An upper portion of the ventilation cap 240 is formed with a fixing hole 241 to be coupled with and fixed to the lower portion of the ventilation cap 240 and a rotation hole 242 formed on the outer circumference of the fixing hole 241 and rotatable along the outer peripheral surface of the fixing hole 241 .

A plurality of through holes are formed in the outer circumferential surface of the fixture 241 and the rotation hole 242 so as to supply oxygen to the inside of the case 100 of FIG. 7, and the size of the through- So that the inflow of air can be blocked.

Therefore, when the rotation hole 242 is rotated so that the through holes of the fixture 241 and the rotation hole 242 do not coincide with each other, the amount of air introduced into the case 100 is reduced So that the candle can be turned off.

The height of the fixture 241 is higher than that of the rotation hole 242 to prevent the rotation of the rotation hole 242 due to the weight of the heat collecting device 210 coupled to the upper part of the ventilation cap 240 .

The lower part of the heat collecting device 210 is coupled with a collecting network 211 which is conically shaped to spread heat toward the inside in order to collect heat generated inside the case 100 of FIG. It is possible to make the heat collection possible even if the height of the seconds is lowered.

The heat collecting device 210 is formed in a square shape so that the thermoelectric device 220 can be attached thereto. The heated air flows into the heat collecting device 210 and then transfers heat to the heat collecting device 210, As shown in FIG.

To this end, the lower part of the heat collecting device 210 is opened to make the interior of the heat collecting device 210 empty, and then the rectangular plates having different diameters are attached to the interior of the heat collecting device 210 at regular intervals.

The heated air generated inside the case 100 of Fig. 7 flows into the center of the rectangular plate formed in the heat collecting device 210, and then enters the upper direction, and then is returned to the lower portion through the space formed on both sides of the rectangular plate The heat is transferred to the heat collecting device 210.

The heat collecting device 210 and the fusing net 211 are made of copper or aluminum having a high thermal conductivity so that heat transfer to the thermoelectric device 220 is performed well.

The thermoelectric element 220 is a device using thermoelectric conversion, which is an energy conversion phenomenon that can convert heat into electricity or electricity, and uses a Hebeck effect in which an electromotive force is generated by a temperature difference. On one side, a heat collecting device 210 is attached And the cooling device 230 is attached to the other surface for cooling.

The cooling device 230 is attached to the other surface of the thermoelectric element 220 to form a circular or aluminum material having a high thermal conductivity so as to discharge the heat transmitted from the thermoelectric element 220 to the outside, A plurality of grooves and concavities and convexities are formed to widen the area in contact with the substrate.

The inside of the cooling device 230 is opened to be coupled with the thermoelectric element 220 attached to the heat collecting device 210. The heat collecting device 210 and the thermoelectric element 220 are inserted into the thermoelectric element 220 Is coupled to the cooling device 230. [

At this time, a fixing guide 232 for fixing the thermoelectric element 220 is formed on the inner surface of the cooling device 230, and the thermoelectric element 220 is fixed via the fixing guide 232 .

The upper part of the cooling device 230 is coupled with a pedestal (not shown) to form a flat upper surface. A container containing a mug or a beverage is placed on the pedestal to transfer heat radiated from the cooling device 230, The cooling performance of the cooling device 230 may be enhanced by transmitting heat to the beverage container.

A first fixing groove 231 is formed in a lower portion of the cooling device 230 to fix the cooling device 230. The fixing groove 460 of the first fixing groove 231 is inserted into the cooling device 230 Can be fixed and supported.

9 is a perspective view showing a configuration of a light emitting portion of an aroma soap container including a lighting function through self-power generation according to the second embodiment.

9, the light emitting unit 300 of the aroma soap container having the illumination function through self-power generation according to the second embodiment is formed inside the mounting unit 400 of FIG. 7, The LED module 310 has LEDs arranged at regular intervals on the circular PCB so that light can be irradiated to the LED module 310, the cooling fan, and the USB terminal A battery 320 for supplying electric power to the LED module 430 and a control unit 330 for changing the color of the light emitted from the LED module 310 or adjusting the intensity of the light.

The LED module 310 is arranged in a circular shape with circular LEDs having different diameters at regular intervals on the circular PCB board so that the range of light irradiation is changed according to the size of the case 100 of FIG. The support unit 350 supports the LED module 310 so that the LED module 310 is positioned above the mounting unit 400 and is separated from the lower portion of the mounting unit 400 of FIG.

The light generated from the LED module 310 passes through the case 100 and the socket 470 of FIG. 7, and the light is poured so that the light can be used as a mood or sleeping. The socket 470 is made of transparent plastic or glass It should be made of material so that light can be transmitted.

The control unit 330 controls the voltage of the LEDs so that the light amount of the LEDs can be adjusted by being attached to the lower part of the LED module 310. When the LEDs disposed in the LED module 310 are red, The user may supply power only to LEDs of a desired color.

The battery 320 is a secondary battery that is used for storing electricity generated by the power generator 200 shown in FIG. 7 and can be used semi-permanently. The battery 320 needs to be used as a side surface of the battery 320 to smoothly charge the battery 320. A voltage regulator 340 is formed to generate electricity in the power generator 200 at a constant voltage and store the generated electricity in the battery 320.

10 is a perspective view showing the outline of the mounting portion of the aroma soap container having the lighting function through self-power generation according to the second embodiment.

As shown in FIG. 10, the mounting portion 400 of the aroma soap container including the lighting function through self-power generation according to the present invention further includes a fixing table 460 for fixing and supporting the position of the power generator 200 And the length of the fixing table 460 is adjustable so that the height of the power generator 200 can be adjusted according to the height of the case 100 of FIG.

In addition, a USB terminal 430 is formed on one side of the mounting part 400, and auxiliary light 370, which is operated as a USB, can be used in combination.

The mounting portion 400 is formed in a cylindrical shape and has a space for accommodating the device therein. The charging terminal 410 is formed on a circumferential surface of the mounting portion 400 to supply external power. The light emitting portion 300 of FIG. A control button 420 formed on a circumferential surface so as to control brightness, color, and pattern of light irradiated from the light emitting unit 300, and a light emitting hole (not shown) for inserting the LED so that the light emitting unit 300 of FIG. 450, a fixing table 460 formed to mount and fix the power generating unit 200 of FIG. 8, and a USB terminal formed to supply power to the external device.

The fixing table 460 is inserted into the first fixing groove 231 of the cooling device 230 formed in the power generating unit 200 of FIG. 8 to fix the power generating unit 200 so as not to move, The height of the power generator 200 of FIG. 7 can be adjusted according to the size of the power generator 200.

A groove (not shown) is formed on the inner side of the fixing table 460 so that the height of the fixing table 460 can be adjusted. A latch (not shown) When the fixing table 460 is inserted into the interior of the fixing table 460,

A terminal (not shown) connected to the cable of the thermoelectric element 220 is formed on the fixing table 460 of FIG. 7 so that the electricity generated by the power generator 200 of FIG. 7 can be transmitted to the light emitting unit 300 And the terminals are connected to the storage battery 320 formed in the mounting portion 400 of FIG.

In addition, a power terminal is formed on the outer circumferential surface of the mounting part 400 so that the battery 320 can be temporarily used when the battery 320 is discharged, and the user can adjust the brightness, color, A control button 420 is provided to allow selection.

The control button 420 can adjust the brightness, color, and pattern of light emitted from the light emitting unit 300 of FIG. 9, and when the diameter of the case 100 of FIG. 7 is small, Only the arranged LEDs are operated, and when the diameter is large, the LEDs formed on the outside can be selectively operated.

The light emitting hole 450 is formed in a shape corresponding to the LED formed on the LED module 310 as a hole formed for transmitting light irradiated from the LED module 310 of FIG. 9 to the outside of the mount 400.

Therefore, the LED module 310 of FIG. 9 can emit light to the outside through the light emitting hole 450, and the light emitting hole 450 can be changed according to the quantity and shape of the LED formed on the LED module 310 .

The USB terminal 430 is connected to the USB terminal 430 such as the auxiliary light 370 shown in FIG. 6 to supply electric power to the usable device. do.

The auxiliary light 370 of FIG. 6 can be read through the USB terminal 430 at night to charge the smartphone discharged in the outdoors.

FIG. 11 is a perspective view illustrating a socket of an aroma soap container including a lighting function through self-power generation according to the second embodiment. FIG. 12 is a perspective view illustrating a lighting function through self- Fig. 6 is a perspective view showing a groove formed in a mounting portion for fixing a socket of an aromatic scented candle container.

11 to 12, the mounting portion 400 of the aroma soap container, which includes the lighting function through self-power generation according to the second embodiment, And a fixture 473 which is inserted or protruded according to the size of the case 100 of FIG. 1 inserted into the insertion groove 472 to press and fix the case 100 of FIG. 1 and an elastic body 474). ≪ / RTI >

The socket 470 is formed with an insertion groove 472 so that the case 100 of FIG. 7 can be inserted therein. The insertion groove is tapered to have a smaller diameter as it goes from the upper portion to the lower portion. Even if the size is slightly larger than the bottom diameter of the insertion groove 472.

When the case 100 of FIG. 1 having a smaller diameter than the insertion groove 472 is inserted into the socket 470, the latch 473 is formed so as to press the case so that the case 100 of FIG. do.

The fixing member 473 protrudes into the insertion groove 472 and is inserted into the socket 473 when the case 100 of FIG. 1 is inserted and is protruded by the elastic body 474 so that the case 100 of FIG. So that it can be pressed and fixed.

The lower portion of the socket 470 is formed with a fixing protrusion 471 protruding from the lower portion of the socket 470 so as to prevent the socket 470 from detaching or rotating after being coupled to the mounting portion 400. The upper portion of the mounting portion 400 is fixed The light emitting hole 450 is formed so as to penetrate from the upper part to the light emitting hole 450 in a size corresponding to the projection 471. The light emitting hole 450 is formed in a circumferential direction by a height of the fixing protrusion 471, Shaped second fixing groove 440 is formed.

Are formed on both inner side surfaces of the mounting portion 400 of the second fixing groove 440 and are formed in different directions.

The fixing protrusion 471 formed on the socket 470 can be brought into close contact with the light emitting hole 450 formed in the mounting part 400 by the second fixing groove 440 of the mounting part 400, The socket 470 can be fixed to the mounting part 400 by rotating the socket 470 in the circumferential direction along the second fixing groove 440 after being closely contacted with the mounting part 400, The case 100 of FIG.

FIG. 13 is a perspective view showing an outer appearance of an aroma soap container having a lighting function through self-power generation according to the third embodiment, FIG. 14 is a perspective view showing an aroma soap container having a lighting function through self- Fig. 3 is a perspective view showing a state in which the inner structure is cut.

As shown in FIGS. 13 to 14, the aroma soap container including the lighting function through self-power generation according to the third embodiment is formed in a cylindrical shape with an upper opening and an interior hollow, A mounting part 400 formed to mount the case 100 and to move the case 100 upward or downward and a mounting part 400 coupled to the upper part of the mounting part 400 to mount the case 100, A light emitting unit 300 having an LED module 310 formed on a lower portion of the connection unit 500 and capable of irradiating light, And a power generation unit 200 formed on the connection unit 500 and generating electricity using heat generated when the wax 110 is burned.

The case 100 is formed inside the mounting part 400 and has a conical fixing pin 160 protruding from its inner center so as to fix the candle composed of the wax 110 and the wick 120, When the wax 110 is melted and the position of the flame is lowered as the candle is burned due to the ascending or descending of the connection part 500 by the connection part 500 by the connection part 500, .

The connection part 500 is formed on the upper part of the mounting part 400 and is threadedly coupled to the mounting part 400. A light emitting part 300 capable of irradiating light is formed in the lower part of the connection part 500, Even if it is not turned on, the light can be irradiated.

A transparent tube 540 having upper and lower openings is formed at the center of the connection part 500. Light generated by the candle is irradiated to the surroundings through the transparent tube 540 and the user can check the state of the candle .

The transparent tube 540 is formed to be inserted into the upper side of the connection part 500, so that the transparent tube 540 can be pushed up when igniting the candle and then ignited.

The power generating unit 200 is electrically connected to the light emitting unit 300 by using the heat of the candle which is formed on the upper portion of the connection unit 500 and is fixed to the case 100.

FIG. 15 is a perspective view showing a connection part 500 of an aroma soap container including a lighting function through self-power generation according to the third embodiment.

As shown in FIG. 15, an exhaust port 511 is formed above the connecting part 500 of the aroma soap container including the lighting function through self-power generation according to the third embodiment, and an air inlet port 521. The intake port 521 is formed in a double shape so that when the outer circumferential surface is rotated, the intake port 521 is opened or closed to supply or block oxygen.

The connection part 500 is formed with an upper cylinder 510 and a lower cylinder 520 spaced apart from each other through which the inside is pierced and a handle 530 is disposed on both sides of the upper cylinder 510 and the lower cylinder 520 And the two cylinders are fixed.

14 is inserted between the upper cylinder 510 and the lower cylinder 520 of the connection part 500 and inserted into the upper cylinder 510. The transparent tube 540 is inserted into the upper cylinder 510, When the transparent tube 540 of FIG. 14 is pushed up toward the upper cylinder 510 in a state where it is stationary, a space is formed between the transparent tube 540 and the lower cylinder 520 of FIG. 14 It becomes possible to ignite a fire in the wick 120 of FIG. 14 formed inside.

An exhaust port 511 is formed in the upper cylinder 510 of the connection part 500 so that carbon dioxide and fragrance generated in the connection part 500 can be discharged through the exhaust port 511. The lower cylinder 520 Is formed with an intake port 521 for supplying oxygen necessary for combustion.

At this time, the inlet port 521 formed in the lower cylinder 520 is formed to be two inward and outward in the same size and quantity, and the outer side is formed so as to be rotatable so that the inlet port 521 formed on the outer side is rotated, The size can be changed to control the amount of oxygen introduced.

Therefore, if the holes of the inner air inlet 521 and the outer air inlet 521 are rotated so as not to coincide with each other in order to extinguish the ignited candles inside, the supply of oxygen is blocked and the candle can be extinguished.

The LED module 310 is formed on the outer circumferential surface of the lower cylinder 520 formed at the lower part of the connection part 500 to form a light emitting part 300 capable of emitting light. Electricity generated through the power generation unit 200 can be supplied to irradiate light.

A battery (not shown) capable of storing generated electricity is formed in the handle 530 so that light can be irradiated through the LED module 310 even if the candle is not ignited.

FIG. 16 is a perspective view showing a configuration of a power generation unit 200 of an aroma soap container including an illumination function through self-power generation according to the third embodiment.

As shown in FIG. 16, the electricity generating unit 200 of the aroma soap container including the lighting function through self-power generation according to the third embodiment is formed on the connecting part 500 and the thermoelectric element 220 is attached A heat collecting device 210 which is formed in a quadrangular shape so as to collect the heat inside the case 100 and which is attached to the upper side of the heat collecting device 210 to receive heat from the heat collecting device 210, And a cooling device 230 formed of at least one of a heat sink and a cooling fan coupled to the thermoelectric element 220 to cool the thermoelectric element 220.

The heat collecting device 210 is coupled with a collecting network 211 which is widely spread toward the inside of the connecting part 500 of FIG. 14 in a conical shape in order to collect the heat generated in the case 100 mounted in the case 100 of FIG. And the length of the collection pipe 211 should correspond to the distance between the heat collecting device 210 and the candle so that the heat can be transferred to the heat collecting device 210.

The heat collecting device 210 is formed in a square shape so that the thermoelectric device 220 can be attached thereto. The heated air flows into the heat collecting device 210 and then transfers heat to the heat collecting device 210, As shown in FIG.

To this end, the lower part of the heat collecting device 210 is opened to make the interior of the heat collecting device 210 empty, and then the rectangular plates having different diameters are attached to the interior of the heat collecting device 210 at regular intervals.

14, the heated air generated in the connection part 500 of FIG. 14 flows into the center of the rectangular plate formed in the heat collecting device 210, enters the upper direction, The heat is transmitted to the heat collecting device 210 while exiting through the space formed on both sides of the plate.

At this time, the heat collecting device 210 and the heat sink 211 need to be formed of copper or aluminum material having a high thermal conductivity so that heat transfer to the thermoelectric device 220 is performed well.

The thermoelectric element 220 is a device using thermoelectric conversion, which is an energy conversion phenomenon that can convert heat into electricity or electricity, and uses a Hebeck effect in which an electromotive force is generated by a temperature difference. On one side, a heat collecting device 210 is attached And the cooling device 230 is attached to the other surface for cooling.

The cooling device 230 is attached to the other surface of the thermoelectric element 220 to form a circular or aluminum material having a high thermal conductivity so as to discharge the heat transmitted from the thermoelectric element 220 to the outside, A plurality of grooves and concavities and convexities are formed to widen the area in contact with the substrate.

The inside of the cooling device 230 is opened to be coupled with the thermoelectric element 220 attached to the heat collecting device 210. The heat collecting device 210 and the thermoelectric element 220 are inserted into the thermoelectric element 220 Is coupled to the cooling device 230. [

At this time, a fixing guide 232 for fixing the thermoelectric element 220 is formed on the inner surface of the cooling device 230, and the thermoelectric element 220 is fixed via the fixing guide 232 .

17 is a perspective view showing in detail a mounting portion 400 of an aroma soap container including an illumination function through self-power generation according to the third embodiment.

As shown in FIG. 17, the mounting portion 400 of the aroma soap container having the lighting function through self-power generation according to the third embodiment is formed into an empty cylindrical shape so as to accommodate the case 100 A spiral groove 491 penetrating the outer circumferential surface is formed to insert the lifting pin 170 of the case 100 and a rotary cylinder 490 rotatable through the bevel gear 493 is provided at a lower portion of the rotary cylinder 490, A height adjuster 492 coupled to the bevel gear 493 so as to rotate the rotary cylinder 490 and a straight line 490 which receives the rotary cylinder 490 and has an inner side on which a line up and down pin 170 of the case 100 is inserted (480) formed with a straight groove (481) formed by a straight line.

The holder 480 is internally hollow and has an open top to accommodate the rotary cylinder 490 and the case 100. The upper portion of the holder 480 is provided with a screw thread Respectively.

The holder 480 is formed on both sides of the inside of the holder 480 with grooves formed in a straight line so that the elevating and lowering pins 170 formed on both sides of the case 100 can be inserted and the rotary cylinder 490 can be rotated A through hole 482 is formed so that the height adjuster 492 can be inserted.

The rotary cylinder 490 is hollow and has an open top so as to receive the case 100. A spiral groove 491 is formed on the outer circumferential surface of the rotary cylinder 490 so as to penetrate to the inside and form a spiral.

The lifting pins 170 formed on both sides of the case 100 are inserted into the linear grooves 481 of the mounting table 480 through the spiral grooves 491. Bevel gears 493 And is rotated by the height adjuster 492 in place.

The height adjuster 492 engages with the bevel gear 493 of the rotary cylinder 490 to rotate the rotary cylinder 490 in the cradle 480 through the rotational force of the height adjuster 492, The lifting pin 170 of the case 100 existing in the case 100 is inserted into the straight groove 481 of the mount table 480 so that the case 100 does not rotate even when the rotary cylinder 490 rotates, So that it can be raised or lowered upward.

Therefore, even if the height of the candle mounted in the case 100 is reduced while the height thereof is reduced, the height adjuster 492 can be rotated to raise the case 100 toward the connection portion 500 of FIG. 14, The power generation unit 200 can continuously generate electricity while being burned.

In addition, since the holder 480 can be detached, it is possible to replace the burned candle, and the height of the candle to be mounted on the case 100 is not limited, so that various candles can be mounted on the case 100 and used.

FIG. 18 is a perspective view showing a spring formed in a mounting portion of an aroma soap container including a lighting function through self-power generation according to the third embodiment. FIG.

As shown in FIG. 18, the mounting portion 400 of the aroma soap container having a lighting function through self-power generation according to the present invention includes a case 100 having a cylindrical shape, And a spring 483 formed at a lower portion of the case 100 and adapted to automatically adjust the height of the case 100 according to the weight of the case 100. [ .

The candle to be fixed to the case 100 may be burned in the wax and the overall height may be lowered and the candle may be burned inside the candle holder 480 so that light generated in the candle may not be irradiated to the outside.

A spring 483 is formed between the case 100 and the mount 480 so that the spring 483 is compressed according to the weight of the candle fixed to the case 100 so that even if the user does not adjust the height, The light can be formed to emit light to the outside through the transparent tube.

The spring 483 is in the form of a coil so that when the weight of the candle fixed to the case 100 is heavy, the spring 483 is compressed and the case 100 is lowered. When the candle is burnt, The case 100 can be raised due to the restoring force so that combustion can be performed at the same position.

As described above, according to the aroma soap container including the lighting function by the self-power generation according to the present invention, electricity can be produced using heat generated when the incense burns, so that no separate power source is supplied, The heat generated is collected to heat the container containing the beverage so that the beverage formed in the inside of the container is not cooled, and even if the herb is not burned, the LED can be used as a mood,

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken as a limitation of the scope of the present invention. Or modify it. The scope of the invention should, therefore, be construed in light of the claims set forth to cover many of such variations.

100: Case 110: Wax
120: Wick 130: Variable liquid
140: heat line 150: digestion cap
160: Fixing pin 170: Up / down pin
200: power generator 210: heat collecting device
211: heat sink 220: thermoelectric element
230: cooling device 231: first fixing groove
232: fixed guide 240: ventilation cap
241: fixture 242:
300: light emitting unit 310: LED module
320: Battery 330: Control device
340: regulator 350: support
360: detachable groove 370: auxiliary illumination
400: mounting part 410: charging terminal
420: Control button 430: USB terminal
440: second fixing groove 450: light emitting hole
460: Fixture 470: Socket
471: Fixing projection 472: Insertion groove
473: fastener 474: elastic body
480: Cradle 481: Straight groove
482: through hole 490: rotating cylinder
491: Spiral groove 492: Height adjuster
493: Bevel gear 500: Connection
510: upper cylinder 511: exhaust port
520: lower cylinder 521: intake port
530: handle 540: transparent tube
550: Retaining ring

Claims (10)

A casing having an upper portion opened in a cylindrical shape and formed so as to be hollow inside and filled with wicks and wax therein;
A power generator for generating and supplying electricity using heat generated when the wax is burned;
A mounting portion formed at a lower portion of the case and configured to receive the case and the power generation portion, the mounting portion being hollow inside;
And a light emitting portion formed in the mounting portion and irradiating light toward the container.
Aroma herb vessel containing self-generated lighting function.
The method according to claim 1,
The mounting portion includes an insertion groove formed in a tapered shape to allow insertion of the case,
And a socket made of an elastic material and inserted into or protruding from the insertion groove in accordance with the size of the case inserted into the insertion groove to press and fix the case.
Aroma herb vessel containing self-generated lighting function.
The method according to claim 1,
The power-
A ventilation cap which is in close contact with an upper portion of the case and has an inner opening to allow air to flow into the case and a plurality of holes at a side thereof;
A collecting device formed on a top of the ventilation cap and formed in a square shape so that a thermoelectric element can be attached thereto and collecting the heat inside the case;
A thermoelectric element attached to an upper side of the heat collecting device to receive heat from the heat collecting device to produce electricity;
And a cooling device formed of at least one of a heat sink and a cooling fan for cooling the thermoelectric device by being coupled with the thermoelectric device
Aroma herb vessel containing self-generated lighting function.
The method according to claim 1,
The light-
An LED module formed in the mounting part and having LEDs arranged at regular intervals on a circular PCB so as to irradiate light to the case;
A battery for storing electricity generated by the power generation unit and supplying power to the LED module, the cooling fan, and the USB terminal;
And a control device for changing the color of the light emitted from the LED module or adjusting the intensity of the light.
Aroma herb vessel containing self-generated lighting function.
The method according to claim 1,
And the height of the power generator can be adjusted according to the height of the case by adjusting the length of the fixing table,
Aroma herb vessel containing self-generated lighting function.
The method according to claim 1,
And a USB terminal is formed on one side of the stationary part, so that auxiliary light which is operated by USB can be used in combination.
Aroma herb vessel containing self-generated lighting function.
A case formed in a cylindrical shape so that an upper portion thereof is opened and an inner portion thereof is hollow so as to fix a candle therein;
A mounting portion formed to mount the case and move the case upward or downward;
A connecting portion coupled to an upper portion of the mounting portion and configured to be hollow inside to supply or block the air required for the seconds fixed to the case;
A light emitting unit formed at a lower portion of the connection unit and having an LED module for irradiating light;
And a power generating part formed on the connection part and generating electricity using heat generated when the wax is burned
Aroma herb vessel containing self-generated lighting function.
8. The method of claim 7,
Wherein the exhaust port is formed at an upper portion of the connection portion and the exhaust port is formed at a lower portion thereof with an intake port through which the air is introduced. The intake port is formed in a double structure,
Aroma herb vessel containing self-generated lighting function.
8. The method of claim 7,
The power-
A heat collecting device formed on an upper portion of the connection portion and formed in a square shape so that a thermoelectric element can be attached thereto and collecting heat inside the case;
A thermoelectric element attached to an upper side of the heat collecting device to receive heat from the heat collecting device to produce electricity;
And a cooling device formed of at least one of a heat sink and a cooling fan for cooling the thermoelectric device by being coupled with the thermoelectric device
Aroma herb vessel containing self-generated lighting function.
8. The method of claim 7,
The mounting portion
A rotating cylinder formed in a hollow cylindrical shape so as to receive the case and formed with a spiral groove penetrating the outer circumferential surface so as to insert a lifting pin of the case and rotated through a bevel gear at a lower portion;
A height adjuster coupled to the bevel gear of the rotating cylinder to rotate the rotating cylinder;
And a cradle receiving the rotating cylinder and having a linear groove formed in a straight line into which the ascending and descending pins of the case are inserted,
Aroma herb vessel containing self-generated lighting function.

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