KR102321065B1 - Apparatus for thermal comfort employing Light Emitting Diode - Google Patents

Abstract

The embodiment relates to an LED warmer.
Specifically, when such an LED warmer uses LED near-infrared rays to heat the human body, it synchronizes and corrects the LED near-infrared rays from the human body's thermal cycle natural vibration frequency according to the thermal natural vibration period of the human body, thereby emitting a comfortable state. It is characterized in that it is heated with a furnace.
Therefore, when using the near-infrared rays of the LED to heat the human body, the massage characteristics appear on its own from the thermal vibrations of the near-infrared rays, and the massage characteristics are exhibited in the human body to warm the body in a comfortable state.

Description

LED heater {Apparatus for thermal comfort employing Light Emitting Diode}

The content disclosed in the present specification relates to an LED warmer that heats a human body by emitting near-infrared rays from the LED when heating the human body.

Unless otherwise indicated herein, the material described in this section is not prior art to the claims of this application, and inclusion in this section is not an admission that it is prior art.

In general, LED near-infrared rays have grown into home care skin care devices until recently, helping many consumers to take care of their skin.

When such near-infrared rays are absorbed by a material like other infrared rays, energy of the absorbed near-infrared rays is converted into heat within the material.

Therefore, LED heaters using near-infrared rays of such LEDs have already been developed and known in Korea.

In case of looking at the related prior art in this background, the following patent documents are generally small enough to refer to the domestic prior art directly related as the related prior art by examining the prior art from the patent document. .

(Patent Document 1) KR200457622 Y1

For reference, the technology of Patent Document 1 is simply about a heater that appropriately gives a heating effect from the LED to near-infrared rays according to the arrangement shape of the LED when heating is performed.

On the other hand, the advantage of such an LED warmer is that it is highly efficient because heat is concentrated on the required part without increasing the ambient temperature, and it is a warmer that can be used comfortably even in midsummer because there is no ambient temperature.

That is, the advantage of the LED warmer is that it not only efficiently heats but also generates and maintains a comfortable environment by transferring energy to the object to be heated in the form of radiant energy.

In addition, it is not an invasive procedure that makes the skin look good on the surface in the process of skin recovery, but warm vibrations wake up cells and activate blood flow to make the skin healthy.

Therefore, the above-described vibrations of near-infrared rays, which show the effect of massage by themselves, can be utilized to provide more comfortable heating compared to the existing ones by using the advantages of the LED warmers.

The disclosed content is an LED that enables the body to heat up in a comfortable state by utilizing the fact that the massage characteristics appear on its own in the vibration of near-infrared rays when heating the human body using LED near-infrared rays. We would like to provide a heater.

The LED warmer according to the embodiment,

When heating the human body using the LED near-infrared rays, the LED near-infrared rays are synchronized and corrected from the natural vibration frequency of the human body's thermal cycle according to the thermal natural vibration period of the human body, so that the heat is provided in a comfortable state. do it with

According to the embodiments, when heating the human body using the near-infrared light of the LED, the characteristic of the massage itself appears in the thermal vibration of the near-infrared light, and the characteristic of the massage is exhibited in the human body to warm the body in a comfortable state. .

1 is a block diagram showing the configuration of an LED warmer according to an embodiment;
FIG. 2 is a flowchart sequentially illustrating the operation of the LED warmer of FIG. 1 according to an embodiment;

Advantages and features of the present disclosure, and methods of achieving them, will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings.

However, the present disclosure is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only the present embodiments allow the disclosure of the present disclosure to be complete, and are common in the technical field to which the present disclosure pertains. It is provided to fully inform those with knowledge of the scope of the invention, and the present disclosure is only defined by the scope of the claims. Like reference numerals refer to like elements throughout.

In describing the embodiments of the present disclosure, if it is determined that a detailed description of a well-known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. And the terms to be described later are terms defined in consideration of the functions in the embodiments of the present disclosure, which may vary according to intentions or customs of users and operators. Therefore, the definition should be made based on the content throughout this specification.

1 is a block diagram illustrating a configuration of an LED warmer according to an embodiment.

As shown in Fig. 1, the LED warmer includes a key signal input unit 101 that receives a heat driving command, a light emitting unit 103 that emits LED near-infrared rays, and an LED near-infrared emitting operation of the light emitting unit according to the warm driving command. It includes a control unit 102 for controlling. And, at this time, the LED warmer of one embodiment synchronizes and corrects the LED near-infrared rays from the thermal cycle natural vibration frequency of the human body according to the thermal natural vibration period of the human body when the controller 102 emits the LED near-infrared rays. Let it be warm.

When heating the human body, the key signal input unit 101 receives a preset heating operation command from a user's key manipulation and transmits it to the control unit 102, so that the human body is started to be heated.

When the heating is performed, the light emitting unit 103 emits near-infrared rays from the LED under the control of the control unit 102 to perform actual heating.

When a heat driving command is input by the key signal input unit 101 , the control unit 102 controls the LED near-infrared emission operation of the light emitting unit 103 to heat the human body. At this time, the control unit 102 synchronizes and corrects the LED near-infrared rays from the natural vibration frequency of the human body's thermal cycle according to the thermal natural vibration period of the human body when heated according to the LED near-infrared emission. make it warm. Therefore, when heating the human body using the near-infrared light of the LED, the massage characteristic of applying a certain stimulus on its own appears from the thermal vibration of the near-infrared infrared light, and the characteristic of the massage is exhibited in the human body to warm the body in a comfortable state. . In this case, in one embodiment, the above-described natural vibration frequency of thermal circulation of the human body is defined by indicating a unique vibration frequency generated from thermal circulation motion flowing along the human body when the human body is normally active.

Additionally, the configuration of the light emitting unit 103 according to an embodiment applied to the LED warmer of FIG. 1 will be described in detail as follows.

First, the light emitting unit 103 according to an embodiment is composed of an LED and an electrode when near-infrared rays are emitted from the LED.

For example, when the electrodes are heated to the human body, they emit near-infrared rays from a plurality of LEDs installed at the same distance from each other according to a control signal of the controller 102 to heat the electrode.

At this time, when the near-infrared rays are emitted, the plurality of LEDs emit near-infrared rays from a matrix shape in which the LEDs are arranged horizontally and vertically, so that the heat by the near-infrared rays becomes effective heat for the human body or the like.

And, when near-infrared rays are generated around the LED, it conducts the light source from the center and extends to other parts.

Preferably, when the electrode is installed in this way, the distance from each other of the plurality of electrodes is set to be the same according to the self-effective heating area characteristic of the LED, so that the heating by the LED near-infrared rays becomes the effective heating.

Therefore, when near-infrared rays from LEDs are transmitted through the subcutaneous fat layer without any damage, only light energy is transmitted to the inside of the body to promote collagen remodeling and nerve regeneration.

FIG. 2 is a flowchart sequentially illustrating the operation of the LED warmer of FIG. 1 according to an embodiment.

As shown in FIG. 2 , when the LED warmer according to an exemplary embodiment heats the human body, it receives a preset heat driving command from the user's key manipulation to initiate heating (S201).

And, when such a heat driving command is input, the near-infrared emission operation of the LED is controlled to heat the human body (S202).

In this case, when heated using LED near-infrared rays, the LED near-infrared rays are synchronized and corrected from the human body's thermal cycle natural vibration frequency according to the heat natural vibration period of the human body, so that they are emitted in a comfortable state.

For example, when heated using LED near-infrared rays, according to the thermal natural vibration period of the human body, the LED near-infrared rays are thermally synchronized and weighted from the human body's thermal cycle natural vibration frequency, so that they are heated in a comfortable state.

In a comfortable state according to such an embodiment, when looking at the fact that the vibration of LED near-infrared rays exhibits the characteristics of massage itself while having thermal vibration characteristics, and that it is transmitted to the object in the form of radiant energy rather than other heating methods, it will occur

In addition, the vibration of LED near-infrared rays is not an invasive treatment principle that makes the skin look good in the process of skin recovery, but a form of vibration such as a massage of a warm kind of constant stimulation, which wakes up cells and activates blood flow to make the skin healthy.

Therefore, when heating the human body using the near-infrared rays of the LED, the characteristic of a massage that applies a certain stimulus by itself appears from the thermal vibration of the near-infrared rays, and the characteristic of the massage is exhibited in the human body to warm the body in a comfortable state. will do

Therefore, when the near-infrared rays of the LED are emitted through this, heat is generated in the human body in a comfortable state, thereby obtaining an effect similar to receiving a massage and heating the LED (S203).

As described above, in one embodiment, when heating the human body using the near-infrared light of the LED, the LED near-infrared is synchronized and corrected from the natural vibrational frequency of the human body's thermal cycle according to the thermal natural vibration period of the human body. Let it be warm.

Therefore, when using the near-infrared light of the LED to heat the human body, the massage characteristic of applying a certain stimulus by itself appears from the thermal vibration of the near-infrared light, and the characteristic of the massage is exerted in the human body to provide a comfortable state. warm up

On the other hand, in one embodiment, in addition to heat in such a comfortable state, LED near-infrared light can be performed more smoothly considering that it is mainly used for people with pain such as neuralgia.

For this purpose, the advantages of the LED warmer are used as described above. The advantage of the LED warmer is that it not only efficiently heats but also maintains a comfortable environment by transferring energy to the object to be heated in the form of radiant energy.

Therefore, the above-described vibration of near-infrared rays, which shows the effect of massage, which is a characteristic of near-infrared rays, is utilized to provide more comfortable heating by well exhibiting the advantages of such LED heaters.

Specifically, the control unit synchronizes and reduces the LED near-infrared rays from the natural vibration frequency of pain for a number of different types of pain, such as neuralgia, muscle pain, etc. make it possible

So, in addition to the heat in the above-mentioned comfortable state, the LED near-infrared light is performed more smoothly considering that it is mainly used for people with pain such as neuralgia.

On the other hand, another embodiment provides a malfunction diagnosis according to the heat in the above-described comfortable state by diagnosing a failure based on the thermal characteristic of the LED warmer when heating is performed in such a comfortable state.

For this, it has the following configuration.

First, the control unit,

a) When heated in a comfortable state, if the temperature of the LED exceeds the preset standard temperature, it is processed normally, and if it is below the standard temperature, abnormalities that substantially affect the near-infrared heating of the LED are detected.

b) In this case, the above abnormality is determined by the LED that is expected to fail frequently, and the human body caused by the person who heats the LED if it is not such an LED.

c) And, at this time, by estimating whether the LED is an abnormal person with the following [Equation 1], the estimated value (Xt, a value indicating how much the current LED element affects the heat) is preliminarily If the value is greater than the set value, the LED is determined as an abnormality, and if it is less than the set value, the human body is systematically sequentially determined as an abnormality.
[Equation 1]
Xt = γ1Xt-1 + γ2Xt-2 + ... + γpXt-p + ζt - δt-1ζt-1 - ... - δqζt-q
(Here, Xt is the degree to which the current LED affects whether there is an abnormality, Xt-n is the degree to which the current LED's surface cleanliness and environmental factors including surface temperature affect the abnormality by environmental factors, and γ is the LED environmental factor itself. ζt is the error between the moving average value of Xt and the current value of Xt, and ζt-n is the error between the moving average value of Xt-n and the current value of Xt-n. , δ is the degree to which the error (ζ) affects the LED)

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d) And, at this time, this moving average section may be different for each part, i.e., LED. For example, in the case of a fast-wearing LED, the moving average section is set short, and in the case of a late-wearing LED, the moving average section is set long. do.

More specifically, the moving average section of [Equation 1] is equal to the moving average section value calculated according to [Equation 2] below from the preset reference moving average section value when the current wear level of the LED in use is less than the preset value. Set the shortened by subtracting it.

On the other hand, the moving average section of [Equation 1] is extended by adding the moving average section value calculated according to [Equation 2] below from the reference moving average section value when the current wear level of the LED being used is larger than a preset value. set

[Equation 2]

Moving average section = [{(Current wear level - preset wear level)/preset unit wear difference value} × preset unit moving average section]

101: key signal input unit 102: control unit
103: light emitting part

Claims (3)

In the LED warmer that emits near-infrared rays from the LED to heat the human body,
a key signal input unit configured to receive a preset heat driving command from a user's key manipulation to perform heating when heating the human body;
a light emitting unit for heating by emitting near-infrared rays from the LED when the heating is performed; and
and a control unit for controlling the LED near-infrared emitting operation of the light emitting unit to heat the human body when a heat driving command is input by the key signal input unit,
When the control unit becomes warm according to the emission of the near-infrared LED, the LED near-infrared is synchronized and corrected from the natural vibration frequency of the human body according to the heat natural vibration period of the human body,

The control unit is
When heating, by synchronizing and emitting the near-infrared rays from the natural frequencies of pain for a number of different types of pain, thereby heating,

The control unit is
a) When performing the heating, if the temperature of the LED exceeds the preset standard temperature, it is treated normally, and if it is below the temperature of the LED, abnormalities that substantially affect the near-infrared heating of the LED are detected,
b) The above-mentioned abnormality is an LED or a human body,
c) A person who is above the above
By estimating whether the LED is an abnormal person with the following [Equation 1], if the estimated value (Xt, a value indicating how much the current LED element affects the heat) is greater than or equal to a preset value, the LED is determined as an abnormality, and if it is less than, the human body is systematically sequentially determined as an abnormality,
[Equation 1]
Xt = γ1Xt-1 + γ2Xt-2 + ... + γpXt-p + ζt - δt-1ζt-1 - ... - δqζt-q
(Here, Xt is the degree to which the current LED affects whether there is an abnormality, Xt-n is the degree to which the current LED's surface cleanliness and environmental factors including the surface temperature affect the abnormality by environmental factors, and γ is the LED environmental factor itself. ζt is the error between the moving average value of Xt and the current value of Xt, and ζt-n is the error between the moving average value of Xt-n and the current value of Xt-n. , δ is the degree to which the error (ζ) affects the LED)
d) The moving average section of [Equation 1] is,
When the current wear level of the LED in use is less than the preset value, the preset reference moving average section value is reduced by subtracting the moving average section value calculated according to [Equation 2] below, and when it is large, the reference moving average section value setting the height by adding as much as the moving average section value calculated according to [Equation 2] below; LED heater featuring
[Equation 2]
Moving average section = [{(current wear level - preset wear level)/preset unit wear difference value} × preset unit moving average section] delete delete

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