KR102619823B1 - Intelligent mattress structure for preventing electromagnetic wave and bacillus propagate and having bioactive function and control device thereof - Google Patents

Abstract

The present invention relates to an intelligent mattress structure that has an electromagnetic wave generation blocking function, a bacterial growth inhibiting function, and a bioactive function, and its control device. More specifically, it relates to an intelligent mattress structure and a control device thereof that are connected to a carbon fiber heating element and emit warmth, far-infrared rays, and negative ions from the carbon fiber heating element. A mattress including a negative ion sensor that detects negative ions flowing in from the carbon fiber heating element and a pollution level sensor that detects the level of pollution; Heat is generated by driving the electric heating structure, allowing warmth, far-infrared rays, and negative ions to flow into the mattress. It is manufactured in the form of a non-woven fabric that maintains a certain shape by applying or adsorbing a specific material to generate far-infrared rays and negative ions. A carbon fiber heating element containing a negative ion sensor; It is a structure in which electrodes are arranged, and electricity flows and generates heat while preventing the generation of electromagnetic waves. A plurality of heating wires are arranged in parallel and connected to the electrodes, so even if some heating wires are disconnected, the remaining heating wires continue to generate heat normally. Disclosed is an intelligent mattress structure that has a function of blocking electromagnetic waves, inhibits bacterial growth, and has a bioactive function. The present invention also provides a control unit for controlling the operation of an intelligent mattress structure that includes a mattress, a carbon fiber heating element, and an electric heating structure, has an electromagnetic wave generation blocking function and a bacterial growth inhibition function, and has a bioactive function; DB storing data necessary to control the warmth, far-infrared rays, and negative ions introduced into the mattress by the control unit; A blower drive unit configured to the carbon fiber heating element and driving a plurality of blowers to promote the inflow of warmth, far-infrared rays, and negative ions into the mattress; A pollution sensor that detects the pollution level of the mattress; A plurality of negative ion sensors that detect the amount of negative ions flowing into the mattress; Disclosed is an intelligent mattress structure having a bioactive function and a control device for the same, which includes a plurality of anion sensors that detect the amount of anions generated from the carbon fiber heating element.

Description

Intelligent mattress structure with electromagnetic wave generation blocking function, bacterial growth inhibition function, and bioactive function and its control device

The present invention relates to an intelligent mattress structure that has an electromagnetic wave generation blocking function, a bacterial growth inhibiting function, and a bioactive function, and a control device thereof.

In more detail, the present invention makes it possible to control the inflow of warmth, far-infrared rays, and negative ions into the mattress.

In general, a bed is a type of furniture for sleeping or resting. It does not require separate transportation or storage, but is installed in a fixed location, such as a bedroom, and is used. In particular, these beds Due to the advantage of being very convenient and easy to prepare for bed and make up the bedding after going to bed, it has become a necessity and is widely used in ordinary homes.

Meanwhile, recently, many functional improvement methods have been proposed to improve health using far-infrared rays, negative ions, or large amounts of oxygen. When the far-infrared rays are irradiated to the human body, the temperature of the deep subcutaneous layer increases, microvascular expansion, and blood circulation improves. It has effects such as stimulation, strengthening of metabolism, and improvement of tissue regeneration ability, and is excellent for gynecological diseases, nervous system diseases, and geriatric diseases. In particular, it is known to have the property of breaking down cholesterol lumps in blood vessels and blood. .

In addition, negative ions purify the blood through alkalization by increasing the ionization rate of mineral components such as calcium, sodium, or potassium in the blood, and generate substances called endorphins and enkephyrin, thereby increasing the ionization rate of calcium and sodium in the serum. It is known to not only purify blood, relieve fatigue, and restore physical strength, but also relieve pain by activating healthy cells in areas where there is strong pain, and has the effect of improving resistance to infection or regulating the autonomic nervous system. there is.

Recently, user demand for mattresses applying the above functionality is rapidly increasing, so continuous research and development is required to satisfy this.

Republic of Korea Patent Publication No. 10-2023-0067304 relates to a black alumina ceramic mattress having a far-infrared ray radiation function, comprising a far-infrared ray-radiating panel containing aluminum oxide (Al2O3), a colorant and germanium, and disposed at the lower part of the far-infrared ray-radiating panel. It may include a heat dissipation panel that generates heat when power is supplied, and a mattress frame disposed below the heat dissipation panel, wherein the far-infrared ray emitting panel has a brightness of at least 3 levels out of 10 brightness levels when processed in gray scale. It is configured to have a black or close-to-black color, so that it has a low light reflectance while having an excellent far-infrared radiation function. By optimizing detailed process conditions, it is possible to prevent sintering defects such as banding, cracks, and bubbles. can be minimized, and has improved production yield through multiple firing steps performed sequentially through a stepwise cooling process.

Republic of Korea Patent Registration No. 10-1465237 relates to a mattress that emits far-infrared rays and negative ions, and is composed of a plurality of springs to cushion the upper external force, and the spring is composed of either a bonnel spring or an independent spring. a spring assembly; A cushioning material located on the upper part of the spring assembly and made of at least one of memory foam, natural latex, chemical latex, sponge, and coconut palm to have a cushioning function; An apatite sheet located on the upper part of the cushion material and using apatite, a natural mineral processed into powder, or artificially synthesized apatite to emit far infrared rays and negative ions; It includes a cover located on the top of the apatite sheet and finishing the exterior, wherein the apatite sheet is spaced apart between the springs by a sheet fixing plate on the top of the cushion material or inside the spring assembly, and has a dispersion effect of far-infrared rays and negative ions. In order to enhance this, illite, which emits far-infrared rays and has a deodorizing effect, is added, and apatite and illite are composed at a weight ratio of 6:4. The mixture of apatite and illite can be molded into a sheet and used, or used as a sheet. It can be used by coating or spraying on the upper surface of the carbon sheet below, and is equipped with a carbon sheet on one side that promotes the emission of far-infrared rays and negative ions. By significantly improving the emission effect of far-infrared rays and negative ions, the user can use the large amount of energy emitted from the mattress. It is exposed to far-infrared rays and negative ions and allows you to get a good night's sleep.

Republic of Korea Patent Registration No. 10-1071367 relates to a mattress for a bed that emits hot and cold air and negative ions, comprising: a hot and cold wind generator equipped with a thermoelectric element and a blower that blows air cooled or heated by the thermoelectric element to the outside; A negative ion generator having a negative ion generator that generates negative ions and a blower that blows the negative ions generated by the negative ion generator to the outside, a control unit that controls the cold and hot air generator and the operation of the negative ion generator, and cold and hot air. Alternatively, a cold and hot wind negative ion generator consisting of a selection switch for selecting the generation of negative ions, a main body equipped with a blowing outlet, a blowing inlet, and a power supply, a mattress body with a built-in spring and surrounded by a ventilated shell, and the inside of the mattress body. A mattress consisting of a screen made of a breathable fiber material that is mounted across the front and rear ends and open on one side, and an air intake port mounted on one side and an air outlet mounted on the other side, which is mounted on the rear end of the mattress body and centered on the screen. And, it is composed of a connection pipe connecting the air intake and air outlet of the mattress with the blowing outlet and blowing inlet of the cold and hot air negative ion generator to circulate the cold and hot air and negative ions generated from the cold and hot air negative ion generator within the mattress, By supplying cold or warm air to the inside of the bed mattress, you can feel the effect of cooling or warming, and by supplying negative ions, it supplies refreshing air to the bedroom, creating a comfortable bedroom environment and encouraging a good night's sleep. By installing a screen inside the mattress, there is an advantage that hot and cold air and negative ions flowing into the mattress are evenly distributed without stagnation, and the speed of cold and hot air and negative ions flowing into the mattress can be adjusted, increasing user convenience.

Republic of Korea Patent Publication No. 10-2023-0067304 (published on May 16, 2023, name: Black alumina ceramic mattress with far-infrared radiation function) Republic of Korea Patent Registration No. 10-1465237 (registered on November 19, 2014, name: Mattress that emits far-infrared rays and negative ions) Republic of Korea Patent Registration No. 10-1071367 (registered on September 30, 2011, name: Bed mattress that emits hot and cold air and negative ions)

The purpose of the present invention is to have the function of blocking electromagnetic wave generation and inhibiting bacterial growth by activating the biorhythm by receiving the inflow of warmth, activating the biorhythm according to the inflow of far-infrared rays and negative ions, and suppressing the reproduction of bacteria such as mites. The purpose is to provide an intelligent mattress structure with functions and its control device.

Another object of the present invention is to treat the conductive wire connecting a plurality of heating wires to the electrode to prevent electromagnetic wave generation, thereby preventing the generation of harmful substances such as electromagnetic waves and generating heat, which has a function of blocking electromagnetic wave generation and inhibiting bacterial growth, and has a bioactive function. The aim is to provide an intelligent mattress structure and its control device.

Another object of the present invention is to connect a plurality of heating wires in parallel to conductive wires connected to electrodes to enable heating operation by the remaining heating wires even if some of the heating wires are disconnected, and to have the function of blocking electromagnetic wave generation and inhibiting bacterial growth. The aim is to provide an intelligent mattress structure with an active function and its control device.

Another object of the present invention is to provide an intelligent mattress structure with a bioactive function and a control device for blocking electromagnetic wave generation and inhibiting bacterial growth by connecting a switch for each of the plurality of heating wires so that only the necessary heating wires are supplied with power. I'm doing it.

Another object of the present invention is to provide an intelligent mattress structure and a control device thereof that have a bioactive function and have a function of blocking electromagnetic wave generation and inhibiting bacterial growth, allowing warmth, far-infrared rays and negative ions to be released to the place where the mattress is installed as needed. It is provided.

The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned can be clearly understood by those skilled in the art from the description below. There will be.

In order to achieve the above object, the intelligent mattress structure of the present invention has an electromagnetic wave generation blocking function, a bacterial growth inhibition function, and a bioactive function.

A mattress connected to a carbon fiber heating element to introduce warmth, far-infrared rays, and negative ions from the carbon fiber heating element, and including a negative ion sensor that detects negative ions flowing from the carbon fiber heating element, and a pollution level sensor that detects the level of pollution;

Heat is generated by driving the electric heating structure, allowing warmth, far-infrared rays, and negative ions to flow into the mattress. It is manufactured in the form of a non-woven fabric that maintains a certain shape by applying or adsorbing a specific material to generate far-infrared rays and negative ions. A carbon fiber heating element containing a negative ion sensor;

It is a structure in which electrodes are arranged, and electricity flows and generates heat while preventing the generation of electromagnetic waves. A plurality of heating wires are arranged in parallel and connected to the electrodes, so even if some heating wires are disconnected, the remaining heating wires continue to generate heat normally. It is characterized by

In the present invention, warmth, far-infrared rays, and negative ions are introduced into the mattress through a hose connecting the carbon fiber heating element and the mattress.

In the present invention, the carbon fiber heating element is characterized by a blower configured to promote the inflow of warmth, far-infrared rays, and negative ions into the mattress.

In the present invention, the through holes formed in the mattress and the carbon fiber heating element communicate with each other, so that warmth, far-infrared rays, and negative ions flow from the carbon fiber heating element into the mattress.

In order to achieve the above object, the intelligent mattress structure control device of the present invention has an electromagnetic wave generation blocking function, a bacterial growth inhibition function, and a bioactive function.

A control unit for controlling the operation of an intelligent mattress structure that includes a mattress, a carbon fiber heating element, and an electric heating structure, has an electromagnetic wave generation blocking function, a mite suppression function, and has a bioactive function;

DB storing data necessary to control the warmth, far-infrared rays, and negative ions introduced into the mattress by the control unit;

A blower drive unit configured to the carbon fiber heating element and driving a plurality of blowers to promote the inflow of warmth, far-infrared rays, and negative ions into the mattress;

A pollution sensor that detects the pollution level of the mattress;

A plurality of negative ion sensors that detect the amount of negative ions flowing into the mattress;

It is characterized by comprising a plurality of negative ion sensors that detect the amount of negative ions generated from the carbon fiber heating element.

In the present invention, the control unit

At the initial stage of electrode operation, the heating temperature of the carbon fiber heating element is relatively low, so all plural blowers are driven, but the wind strength is also increased to control warmth, far-infrared rays, and negative ions to flow into the mattress.

When the electrode drive is maintained for a certain period of time and the heating temperature in the carbon fiber heating element increases, multiple blowers are all driven or selectively driven. When all are driven, one blower strengthens the wind strength, while the other blower is driven. The blower is characterized by controlling the amount of warmth, far-infrared rays, and negative ions flowing into the mattress by weakening the intensity of the wind.

In the present invention, the control unit

If the electrode operation is maintained for a certain period of time and the heating temperature in the carbon fiber heating element increases, part of the warmth, far infrared ray and negative ion inflow passage connecting the mattress and the carbon fiber heating element is closed to control the inflow of warmth, far infrared rays and negative ions into the mattress. It is characterized by blocking.

According to the intelligent mattress structure and its control device having an electromagnetic wave generation blocking function, a bacterial growth inhibiting function, and a bioactive function of the present invention, it not only receives warmth and becomes warm, but also activates biological rhythm according to the inflow of far infrared rays and negative ions, It can inhibit the growth of bacteria such as mites.

In addition, the conductive wires that connect the plurality of heating wires to the electrodes are treated to prevent electromagnetic waves, preventing the generation of harmful substances and generating heat, so there is no harm to the human body.

In addition, since a plurality of heating wires are connected in parallel to the conductive wires connected to the electrodes, even if some heating wires are disconnected, heat generation operation by the remaining heating wires is possible, making maintenance and maintenance easy.

In addition, a switch is connected to each of the plurality of heating wires so that only the necessary heating wires are supplied with power, so the mattress can be used efficiently according to the user's wishes.

In addition, when necessary, warmth, far-infrared rays, and negative ions are released directly to the place where the mattress is installed. Even if it is not necessarily a mattress, warmth, far-infrared rays, and negative ions are released to the place where the mattress is installed, thereby heating a certain place and reducing the risk of staying in that place. It is possible to activate human biorhythms and suppress bacteria.

Other effects will be readily apparent to those skilled in the art from the description below.

Figure 1 is a diagram showing the configuration of an intelligent mattress structure that has an electromagnetic wave generation blocking function, a bacterial growth inhibition function, and a bioactive function according to an embodiment of the present invention.
Figure 2 is a diagram showing a hose connected to move warmth, far-infrared rays, and negative ions between the mattress and the carbon fiber heating element in Figure 1.
Figure 3 is a diagram showing the electrical connection between an electrode for generating negative ions and a carbon fiber heating element.
Figure 4 is a configuration diagram of the heat transfer structure.
Figure 5 is a structural diagram of two conductive wires bundled together to block electromagnetic waves.
Figure 6 is a structural diagram of blocking electromagnetic waves by using two separate conductive wires.
Figure 7 is a structural diagram of blocking electromagnetic waves by bundling two conductive wires according to another embodiment.
Figure 8 is an exemplary diagram showing the selective operation of the heating wire.
Figure 9 is a configuration diagram of an intelligent mattress structure control device having an electromagnetic wave generation blocking function, a bacterial growth inhibition function, and a bioactive function according to an embodiment of the present invention.
Figure 10 is an example of data stored in the DB of Figure 9.
Figure 11 is an operation flow chart of an intelligent mattress structure having an electromagnetic wave generation blocking function, a bacterial growth inhibition function, and a bioactive function according to an embodiment of the present invention.

Since the present invention can make various changes and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description.

However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

The terms used in the present invention are only used to describe specific embodiments and are not intended to limit the present invention.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the technical field to which the present invention pertains.

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

Figure 1 is a diagram showing the configuration of an intelligent mattress structure that has an electromagnetic wave generation blocking function, a bacterial growth inhibition function, and a bioactive function according to an embodiment of the present invention. Figure 2 is a diagram showing a hose connected to move warmth, far-infrared rays, and negative ions between the mattress and the carbon fiber heating element in Figure 1. Figure 3 is a diagram showing the electrical connection between an electrode for generating negative ions and a carbon fiber heating element. Figure 4 is a configuration diagram of the heat transfer structure. Figure 5 is a structural diagram of two conductive wires bundled together to block electromagnetic waves. Figure 6 is a structural diagram of blocking electromagnetic waves by using two separate conductive wires. Figure 7 is a structural diagram of blocking electromagnetic waves by bundling two conductive wires according to another embodiment. Figure 8 is an exemplary diagram showing the selective operation of the heating wire. Figure 9 is a configuration diagram of an intelligent mattress structure control device having an electromagnetic wave generation blocking function, a bacterial growth inhibition function, and a bioactive function according to the present invention. Figure 10 is an example of data stored in the DB of Figure 9. Figure 11 is an operation flow chart of an intelligent mattress structure that has an electromagnetic wave generation blocking function, a bacterial growth inhibition function, and a bioactive function according to the present invention.

As shown in Figure 1, the present invention may be configured to include a mattress 10, a carbon fiber heating element 20, and a heat transfer structure 40.

The mattress 10 is warmed by the warmth flowing in from the heating structure 40 and the carbon fiber heating element 20 located at the bottom, and the person using the mattress is warmed by the far infrared rays and negative ions flowing in from the carbon fiber heating element 20. It activates the biological rhythm and has the function of suppressing the proliferation of bacteria such as mites.

The mattress 10 maintains elasticity while maintaining a certain distance between the top and bottom through the spring 11, and is connected to the carbon fiber heating element 20 through the hoses 25 and 26, thereby providing heat and energy from the carbon fiber heating element 20. The carbon fiber heating element 20 is in communication with the through holes 12 and 13 formed on the left and right sides to allow far infrared rays and negative ions to flow into the space 14, and the through holes 21 and 22 formed in the carbon fiber heating element 20, respectively. Holes 15 (16) formed on the left and right sides of the upper surface to allow warmth, far-infrared rays, and negative ions to flow into the space 14 of the mattress 10, and to detect negative ions flowing into the space 14 of the mattress 10. Negative ion sensors 17 and 18 respectively configured on the left and right sides of the mattress 10, and a contamination sensor 19 configured on one side of the mattress 10 to detect the degree of contamination of the internal space 14 of the mattress 10. may include.

The carbon fiber heating element 20 generates heat by driving the heating structure 40 to allow warmth, far-infrared rays, and negative ions to flow into the mattress 10. A specific material is applied or adsorbed to generate far-infrared rays and negative ions to provide a constant It can be manufactured in the form of a non-woven fabric that maintains its shape, and the hoses 25 and 26 that introduce warmth, far-infrared rays and negative ions into the mattress 10 are connected, respectively, through holes 21 and 22, and a carbon fiber heating element 20. ) may include negative ion sensors 27 and 28 configured on the left and right sides respectively to detect negative ions in the internal space.

The internal space of the carbon fiber heating element 20 may be configured with blowers 31 and 32 that are driven to smoothly introduce warmth, far-infrared rays, and negative ions into the mattress 10. In the drawing, it is shown that two blowers are configured, but this is not necessarily limited to these.

In addition, the direction of the blower is variable, and may be driven to introduce a large amount of warmth, far-infrared rays, and negative ions toward the through holes 15, (16), (23) (24), and through holes 12 (12) (13 (21) (22). ) can also be driven to introduce a large amount of warmth, far-infrared rays, and negative ions.

The hoses 25 and 26 are made of an elastic material with a hollow interior, and their ends are formed larger than the size of the through holes 12, 13, 21 and 22, but have elasticity, so through holes 12 and 13. ) is smoothly inserted, and is fixed without falling out when connected between the mattress 10 and the carbon fiber heating element 20 for the inflow of warmth, far-infrared rays, and negative ions.

Meanwhile, in the structure of FIGS. 1 and 2, the carbon fiber heating element 20 is explained as being generated by a heat source generated from the heat transfer structure 40 and emitting warmth, far-infrared rays, and negative ions, but it is not necessarily limited to this structure. no.

That is, as shown in FIG. 3, it may be configured in the form of a carbon fiber-embedded quartz glass tube that can generate heat by being driven by an electric heat source.

This carbon fiber heating element 20 has the high strength, flexibility, and chemical stability of carbon fiber, so it can be used for a long time, and its improved durability further increases the quality of the product compared to existing metal heating elements, making it possible to continuously maintain a constant temperature. This is very beneficial in preventing safety accidents.

The heating structure 40 is a structure in which electrodes are arranged, and electricity flows and generates heat while preventing the generation of electromagnetic waves. As shown in FIG. 4, a plurality of heating wires 80 (electrodes) are arranged in parallel and connected to the electrodes. Even if some of the heating wires are disconnected, the remaining heating wires continue to generate heat normally.

The heating structure 40 is connected to each switch so that power is supplied or cut off according to the operation of the switch, and the switch is connected or disconnected under the control of the switch driver, thereby generating heat as power is supplied or cut off. At this time, all the heating wires 80 are driven at once to heat the entire surface of the carbon fiber heating element 20 evenly, thereby transferring heat to the entire surface of the mattress 10, or only some selected heating wires are driven to heat only some surfaces of the mattress 10. Heat can be transferred.

The heating structure 40 includes an electromagnetic wave blocking unit 90.

As shown in FIGS. 4 and 5, the electromagnetic wave blocking unit 90 may be configured as an integrated structure of the first conductive wire 5 and the second conductive wire 6. That is, two conductive wires 5 and 6 are combined into one bundle, and the outer circumferential surface is shielded with ferrite to form a structure.

At this time, an independent ground wire (not shown) is installed close to the outside of the ferrite in which the two conductive wires 5 and 6 are bundled and shielded, thereby establishing the wiring relationship of the electromagnetic wave blocking unit 90.

The ferrite is a widely used non-metallic (a type of ceramic) magnetic material. Its magnetization mechanism follows that of a ferrimagnetic material, and its characteristic is to prevent loss due to eddy currents. Therefore, such ferrite usually has the characteristic of selectively blocking the passage of electronic energy. It is used as a ferrite isolator.

In addition, it is a material that is applied to various commonly known fields such as ferrite rotors that rotate the electromagnetic wave polarization surface of the waveguide at an appropriate angle. Due to these material properties, when ferrite is applied to the electromagnetic wave blocking unit 90 of the present invention, it prevents radio waves from spreading. By changing the direction of the magnetic field, it is possible to sufficiently perform the function of neutralizing and attenuating harmful electromagnetic waves generated from the magnetic field.

The conductive wire shielding structure using the ferrite is basically in the form of a closed loop to shield magnetic flux from being emitted to the outside. If two conductive wires are tied together and connected continuously to be shielded, it can be implemented in various shapes such as circular or square. This is because if the ferrite shielding structure is formed discontinuously, that is, if there is a broken part, magnetic flux leaks to the outside.

The ferrite material may be composed of iron oxide (FeO, Fe2O3, Fe2O4, Fe3O4, etc.) and at least one metal. Metals used in combination with iron oxide include, for example, nickel (Ni), zinc (Zn), manganese (Mn), cobalt (Co), magnesium (Mg), aluminum (Al), barium (Ba), and copper. (Cu), iron (Fe), etc. are possible.

Meanwhile, although it is illustrated that the electromagnetic wave blocking unit 90 is composed of the first conductive wire 5 and the second conductive wire 6 as a bundle, it is not limited to this structure. For example, as shown in FIG. 6, an electromagnetic wave blocking portion made of ferrite may be formed to surround each conductive wire.

When current flows through the first conductive wire 5 and the second conductive wire 6 as power is supplied from the power source, a vibration change phenomenon occurs between the electrodes (+) and (-) due to the current flow in the same direction. A magnetic field is formed, and this magnetic field generates harmful electromagnetic waves that propagate to other areas of space according to electromagnetic radiation theory and the nature of waves.

Accordingly, in the process in which harmful electromagnetic waves are generated by forming a magnetic field as described above, the current flowing through the first conductive wire 5 and the second conductive wire 6 causes the electromagnetic wave blocking unit 90 shielded with ferrite. When passing, the ferrite acts as an inductance and changes the direction of the magnetic field propagating from the first conductive wire 5 and the second conductive wire 6. By changing the direction of the magnetic field, the ferrite neutralizes harmful electromagnetic waves, It attenuates.

At this time, the harmful electromagnetic waves that remain in a small amount after being neutralized and attenuated by the electromagnetic wave blocking unit 90 are emitted to the outside by being grounded by the ground wire and ground terminal, thereby completing the removal of the harmful electromagnetic waves.

As another embodiment for preventing the generation of electromagnetic waves, as shown in FIG. 7, the current flow direction of the electrode portion is close to the first conductive wire 5 and the second conductive wire 6, respectively, which supply power to the heating wire 80. and other conductive parts (7) and (8) through which current flows in a direction 180° different from each other, respectively, so as to cancel out electromagnetic waves generated from the first conductive wire (5) and the second conductive wire (6). You can.

The third conductive line 7 is configured to be parallel to the side of the first conductive line 3 forming the (+) electrode, and the fourth conductive line 8 is formed in parallel with the second conductive line 3 forming the (-) electrode. It is configured to be parallel to the side of the conductive line (6).

Therefore, both ends of the third conductive wire 7 are electrically connected to the power source so that the current flows in a direction 180° different from the current flow direction of the first conductive wire 5, thereby canceling out the magnetic field of the first conductive wire 5. Both ends of the fourth conductive wire (8) are electrically connected to a power source so that current flows in a direction 180° different from the current flow direction of the second conductive wire (6), so that the magnetic field of the second conductive wire (6) is generated. offset.

That is, since the directions of the magnetic fields formed in the first conductive wire (5), the third conductive wire (7), the second conductive wire (6), and the fourth conductive wire (8) are opposite to each other, the electromagnetic waves generated in the electrode part is canceled out.

Another embodiment having this effect is to block electromagnetic waves generated by the first conductive wire 5 and the second conductive wire 6 by the electromagnetic wave blocking unit 90 made of ferrite shown in FIGS. 3 to 6. At the same time, the remaining electromagnetic waves that may remain can be reliably removed by the third conductive line (7) and fourth conductive line (8).

In addition, electromagnetic waves are blocked even if one of the components does not operate normally, such as the effect of the ferrite material being halved or the third conductive wire (7) and fourth conductive wire (8) not acting due to external factors such as power failure. This is possible.

The heating wire 80 will be described using FIG. 4 as follows.

A plurality of heating wires 80 connected to each other through + and - electrodes are formed in parallel throughout the heating structure 40, and each switch (SW1 to SW6) is connected to each heating wire according to the control of the switching driver 150. It is designed to be connected or blocked. In other words, since a plurality of heating wires are connected in parallel, even if some heating wires are disconnected, the operation of the remaining heating wires is not affected. This is a configuration that allows the mattress user to stop the operation of some heating elements depending on which area they want to be warm. By doing this, the heating elements can be operated efficiently while reducing power consumption.

For example, as shown in FIG. 8, switch 1 (SW1) for turning on and off the heating wire at a position corresponding to the user's head 110, and a heating wire at a position corresponding to the user's torso 120 It can be divided into switches 2 and 3 (SW2 ~ SW3) for turning on and off, and switches 4 to 6 (SW4 ~ SW6) for turning on and off the heating wire at a position corresponding to the user's leg portion 130, and Only the switch corresponding to the desired part can be connected to generate heat.

Such an operation will be possible by configuring the operation panel of the control device to select switches 1 to 6. However, since selective driving of the heating wire 80 in this way affects the heating temperature of the carbon fiber heating element 20, it would be desirable to apply it according to the pollution detection result by the pollution sensor, which will be described later. That is, as a result of the detection by the pollution sensor 19, if the pollution level of the mattress does not exceed the standard value, it is determined that a large amount of far-infrared rays and negative ions do not need to be introduced into the mattress under the control of the control unit for a certain period of time, and is adjusted to the user's request. By operating only a few selected heating elements, mattress user satisfaction can be increased.

As shown in Figure 9, the intelligent mattress structure control device having an electromagnetic wave generation blocking function, a bacterial growth inhibition function, and a bioactive function according to an embodiment of the present invention includes a control unit 1, a DB 2, and a blower. A driving unit 3, a pollution level sensor 19 that detects the level of contamination in the space 14 of the mattress 10, a first negative ion sensor 17 that detects negative ions in the space 14 of the mattress 10, and a second negative ion sensor 17 that detects negative ions in the space 14 of the mattress 10. It may be configured to include 2 negative ion sensors 18, a third negative ion sensor 27 and a fourth negative ion sensor 28 that detect negative ions of the carbon fiber heating element 20, and a negative ion generator 20. The negative ion generator 20 is a carbon fiber heating element 20 configured to apply or adsorb far infrared rays and negative ion materials.

The control device shown in FIG. 9 is a control configuration for controlling far-infrared rays and negative ions to the mattress, and the configuration for controlling warmth, that is, the operation unit and switching driver described above with reference to FIG. 8, is omitted.

In the DB 2, as shown in FIG. 10, the heating temperature of the carbon fiber heating element 20 relative to the electrode driving time, that is, the driving time of the heating structure 40, and the carbon fiber heating element 20 according to the blower driving amount. Far infrared rays and negative ions flowing into the mattress 10, far infrared rays and negative ions flowing from the carbon fiber heating element 20 to the mattress 10 when the hoses 25 and 26 are connected between the mattress 10 and the carbon fiber heating element 20. Data on negative ion influx, etc. are stored and managed.

In addition, the DB 2 contains the amount of inflow of far-infrared rays and negative ions to remove contamination from the mattress 10, the heating temperature of the mattress 10 according to the electrode operation time, and the carbon fiber heating element 20 according to the blower driving amount. ) and the amount of warmth flowing into the mattress 10 from the carbon fiber heating element 20 when the hoses 25 and 26 are connected between the mattress 10 and the carbon fiber heating element 20. do.

Management of these data includes electrode operation time, whether the hoses 25 and 26 are connected between the mattress 10 and the carbon fiber heating element 20, and temperature, far-infrared rays and negative ions according to the operation time and blowing volume of the blowers 31 and 32. The amount of inflow into the mattress 10 is managed so that it interacts organically with each other, and is used to appropriately control the drive according to the user's request or the degree of contamination of the mattress 10.

In addition, whether both blowers 31 and 32 are driven, at what wind strength they are driven, the size of the through holes 15, 16, 23 and 24, and the hoses 25 and 26. ) are connected to the mattress 10, etc. are also managed so that they can interact organically.

For example, at the initial point of electrode operation, the heating temperature in the carbon fiber heating element 20 will be relatively low, so both blowers 31 and 32 are driven, but the wind strength is also increased and the hoses 25 and 26 are also installed on the mattress ( 10), it would be desirable to allow warmth, far-infrared rays, and negative ions to flow into the mattress 10 through all possible passages.

If the electrode operation is maintained for a certain period of time, the amount of warmth accumulated in the carbon fiber heating element 20 will increase and the heating temperature will be relatively high. In this case, all blowers 31 and 32 are driven or selectively driven, and when all are driven, In this case, one blower strengthens the wind strength, while the other blower weakens the wind strength, and the hoses 25 and 26 are directed to the place where the mattress 10 is installed instead of being connected to the mattress 10. Of course, this operation can be done based on the pollution detection result of the pollution level sensor, which will be explained later.

When the hoses 25 and 26 are passed through the place where the mattress 10 is installed as described above, some of the warmth, far-infrared rays, and negative ions are emitted directly to the place where the mattress is installed, instead of flowing into the internal space 14 of the mattress 10. As this happens, the area becomes warmer and biorhythms are activated by far-infrared rays and negative ions, while also suppressing bacterial growth in the area where the bed is installed. A temperature sensor may be configured as a means for detecting the heating temperature in the carbon fiber heating element 20.

Figure 11 is a diagram showing an example of controlling the operation according to the degree of contamination of the mattress. When the power is first turned on (S10) and the electrode is driven (S20), the heating wire generates heat and heat is transmitted to the carbon fiber heating element 20 located on the top. This is transmitted and the carbon fiber heating element 20 also generates heat (S30).

Next, as the carbon fiber heating element 20 generates heat, warmth, far-infrared rays, and negative ions are generated (S40), and the blowers 31 and 32 are controlled by the blower drive unit 3 that receives the control signal from the control unit 1. As the is driven, warmth, far-infrared rays, and negative ions flow into the mattress 10 (S50).

At this time, warmth, far-infrared rays, and negative ions naturally flow into the mattress 10 through the holes 15, 16, 23, and 24, and if the hoses 25, 26 are connected, the holes 12, 21 Warmth, far-infrared rays, and negative ions flow into the mattress 10 through the through holes 13 and 22, thereby increasing the temperature of the mattress 10. At the same time, the far-infrared rays and negative ions activate the biological rhythm of the person using the mattress, and kill bacteria. Inhibits reproduction.

While this operation is performed, the contamination level sensor 19 detects the contamination level of the mattress 10 and transmits it to the control unit 1. (S70)

The control unit 1 analyzes the pollution level of the mattress transmitted from the pollution level sensor 19, determines the amount of negative ions necessary to reduce the pollution level below the standard value, and controls the power so that the amount of negative ions can be generated (S80).

In other words, the electrode operation time is increased to allow negative ions to continue to be generated, and since the amount of negative ions in the mattress 10 is detected in real time by the negative ion sensors 17 and 18, the control unit 1 continues to operate the electrode so that the amount of negative ions detected in real time reaches the target value. It is to drive it. Of course, even at this time, the control unit 1 analyzes the pollution level detected by the pollution level sensor 19 and analyzes in real time whether the pollution level is lowered.

As described above, in the detailed description of the present invention, preferred embodiments of the present invention have been described, but this is an illustrative description of the best embodiment of the present invention and does not limit the present invention. In addition, it goes without saying that anyone skilled in the art of the present invention can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

Accordingly, the scope of the present invention is not limited to the above-described embodiments, but may be implemented in various forms of embodiments within the scope of the appended claims. In addition, it is considered to be within the scope of the claims of the present invention to the extent that anyone skilled in the art can make modifications without departing from the gist of the invention claimed in the claims.

1: Control unit 2: DB
3: Blower driving unit 5. 6, 7, 8: Conductive wire
10: mattress 11: spring
12, 13, 15, 16, 21, 22, 23, 24: through hole 14: mattress space
17. 18, 27, 28: Negative ion sensor 19: Pollution sensor
20: carbon fiber heating element 31, 32: blower
40: heating structure 80: heating wire
90: Electromagnetic wave blocking unit 150: Switching driving unit

Claims (7)

A mattress connected to a carbon fiber heating element to introduce warmth, far-infrared rays, and negative ions from the carbon fiber heating element, and including a negative ion sensor that detects negative ions flowing from the carbon fiber heating element, and a pollution level sensor that detects the level of pollution;
Heat is generated by driving the electric heating structure, allowing warmth, far-infrared rays, and negative ions to flow into the mattress. It is manufactured to maintain a certain shape by applying or adsorbing a specific material to generate far-infrared rays and negative ions, and detects the negative ions generated. A carbon fiber heating element containing a sensor;
It is a structure in which electrodes are arranged, and electricity flows and generates heat while preventing the generation of electromagnetic waves. A plurality of heating wires are arranged in parallel and connected to the electrodes, so even if some heating wires are disconnected, the remaining heating wires continue to generate heat normally. Characterized by
The mattress and the carbon fiber heating element each have holes formed in communication with each other, so that warmth, far-infrared rays, and negative ions flow from the carbon fiber heating element into the mattress. It is an intelligent mattress that has an electromagnetic wave generation blocking function, a bacterial growth inhibition function, and a bioactive function. struct.
In claim 1,
An intelligent mattress structure that has a function of blocking electromagnetic wave generation and inhibiting bacterial growth, and has a bioactive function, characterized in that the warmth, far-infrared rays, and negative ions flow into the mattress through a hose connecting the carbon fiber heating element and the mattress. In claim 1,
The carbon fiber heating element is an intelligent mattress structure that has a function of blocking electromagnetic wave generation and inhibiting bacterial growth, and has a bioactive function, characterized in that it is configured with a plurality of blowers to promote the inflow of warmth, far-infrared rays, and negative ions into the mattress.
delete A control unit for controlling the operation of an intelligent mattress structure that includes a mattress, a carbon fiber heating element, and an electric heating structure, has an electromagnetic wave generation blocking function, a bacterial growth inhibition function, and has a bioactive function;
DB storing data necessary to control the warmth, far-infrared rays, and negative ions introduced into the mattress by the control unit;
A blower drive unit configured to the carbon fiber heating element and driving a plurality of blowers to promote the inflow of warmth, far-infrared rays, and negative ions into the mattress;
A pollution sensor that detects the pollution level of the mattress;
A plurality of negative ion sensors that detect the amount of negative ions flowing into the mattress;
Characterized by comprising a plurality of negative ion sensors that detect the amount of negative ions generated from the carbon fiber heating element,
The control unit
At the initial stage of electrode operation, the heating temperature of the carbon fiber heating element is relatively low, so all plural blowers are driven, but the wind strength is also increased to control warmth, far-infrared rays, and negative ions to flow into the mattress.
When the electrode drive is maintained for a certain period of time and the heating temperature in the carbon fiber heating element increases, multiple blowers are all driven or driven selectively. When all are driven, one blower strengthens the wind strength, while the other blower is driven. The blower controls the amount of warmth, far-infrared rays, and negative ions flowing into the mattress by reducing the intensity of the wind. It is an intelligent mattress structure control device that has an electromagnetic wave blocking function, a bacterial growth inhibition function, and a bioactive function.
delete In claim 5,
The control unit
If the electrode operation is maintained for a certain period of time and the heating temperature in the carbon fiber heating element becomes relatively high, part of the warmth, far infrared rays, and negative ion inflow passage connecting the mattress and the carbon fiber heating element is closed to control the inflow of warmth, far infrared rays, and negative ions into the mattress. An intelligent mattress structure control device that has an electromagnetic wave generation blocking function, a bacterial growth inhibition function, and a bioactive function.

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