KR101793309B1 - Heat Generating Glove Capable of preventing Electromagnetic Wave from Generating - Google Patents

Abstract

The present invention relates to a heating glove using a method for preventing generation of electromagnetic waves of a heating product for DC power supply including a heating element, a temperature sensor, a temperature control device (artificial intelligence IC), an ON / OFF switch function (FET IC) , The power supply is turned off when the temperature of the heating element reaches the preset off temperature. If the temperature of the heating element is lowered and the temperature of the heating element is lowered to the predetermined temperature, the battery is turned on to supply power to the battery In order to generate the electromagnetic wave near to zero level, it is attached to the heating element, and a predetermined resistance value is set to the temperature sensor corresponding to the on / off set temperature on a one-to-one basis and the heating element and power on / The generated electromagnetic waves are generated at almost zero level so that they can be maintained for at least 30 seconds for a certain period of time even when the applied voltage is changed. The heating element is sewed along the outline of all the fingers while extending from one side of the heating glove and the jack exposed at one end of the heating element is formed on the back side of the heating glove And is embedded in the pocket portion.

Description

TECHNICAL FIELD [0001] The present invention relates to a heat generating glove capable of preventing generation of electromagnetic waves,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heating glove capable of preventing the generation of electromagnetic waves in a direct current power source (including a battery), and in the conventional PWM temperature control method, The on / off temperature of the temperature control device is set differently for each temperature setting step for the purpose of lengthening the on-off period of the heat generating glove heat generator. The upper limit temperature (off temperature) and the lower limit temperature (on temperature) The present invention relates to a heat-generating glove capable of preventing generation of electromagnetic waves so that an on / off period of an occurring power source is longer than that of a conventional power source so that an electromagnetic wave is generated below a reference level.

BACKGROUND ART [0002] Heat generators (e.g., heating vests, heat-generating mats, etc.) that heat by using a battery are currently in the market. This allows users to wear the existing outerwear to maintain a temperature of about 34 degrees Celsius or more at a temperature of about 3 to 4 hours depending on the capacity of the battery (about 3 V to 24 V) so that they can withstand cold weather, It is used as a product.

Such conventional heat-generating products usually include a built-in heating pad member (for example, a structure in which carbon fibers or electric wires are connected to generate a direct current or an AC power through a battery to generate heat) Battery power is used as the power source, and a large-area heating element such as a mat uses a DC converter (adapter) and a temperature controller.

On the other hand, since the battery power is DC, the electromagnetic wave is not generated, but the temperature is continuously increased and the heat ray and the heating element are damaged. In addition, the probability of the image to be burned (especially, low temperature image) is very high and the battery usage time is also uniformly short The need to regulate the temperature of the exothermic product (or heating element) by regulating the output of the battery. Therefore, as a typical conventional method, a PWM (Pulse Width Modulation) control method in which the temperature ratio is adjusted by adjusting the duty ratio of the power on / off time is commonly used.

However, when the PWM method is used, the on / off period must be shortened for effective temperature control to generate electromagnetic waves every power on / off cycle. Therefore, there is a problem that electromagnetic waves per unit time of measurement occur more frequently than the EMF certification reference value.

On the other hand, as a prior art in this field, it is disclosed in the description of a heat glove (Korea Utility Model Registration No. 20-0457487, registered on Dec. 15, 2011). However, this technology has only added the ability to generate heat, but the contents of temperature control and electromagnetic wave prevention have not been disclosed at all.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a DC power source for reducing the generation of electromagnetic waves by increasing the on-off period of the battery compared to the conventional PWM method. And a heat-generating glove capable of preventing the generation of electromagnetic waves in the heating element.

It is still another object of the present invention to provide a heating glove capable of preventing the generation of electromagnetic waves by preventing the generation of electromagnetic waves by setting the on-off temperature of the temperature control apparatus in each step differently.

According to a preferred embodiment of the present invention,

A heating glove comprising a heating element, a temperature sensor, a temperature control device, an ON / OFF switch device, and a battery, wherein the heating element is powered by a method for preventing generation of electromagnetic waves, The control unit controls the battery so that the power supply is turned on by sending a battery on signal when the temperature of the heating element is lowered to a predetermined temperature, and the pocket unit is provided in the back of the heating glove. The heating element is sewed along the outline of all the fingers while extending from one side of the heating glove. The jack exposed at one end of the heating element is a heating glove built in a pocket portion formed on the back of the heating glove,
In order to generate the electromagnetic wave near to zero level, it is attached to the heating element, and the predetermined resistance value is set to the temperature sensor corresponding to the on / off setting temperature one by one and the heating element and the power on / Generated electromagnetic waves at almost zero level so that they can be maintained for at least 30 seconds,
The battery is operated at an off temperature and a lower temperature for each step set in the battery or controller and then repeatedly turned on or off at an upper limit temperature and a lower limit temperature by a predetermined step after at least 30 seconds. Possible heating gloves are provided.

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As described above, according to the heating glove capable of preventing the generation of electromagnetic waves according to the present invention, the on-off period of the battery is longer than that of the conventional PWM method, thereby preventing the generation of electromagnetic waves.

Further, according to the present invention, the on-off temperature of the temperature control device is set differently for each step, thereby preventing the generation of electromagnetic waves.

1 to 4 are views showing a heating element sewn in a heating glove capable of preventing electromagnetic waves according to the present invention.
5 to 9 are views showing a heating element in the form of a lead wire connected in parallel to a carbon fiber woven fabric among heating elements sewn in a heating glove capable of preventing electromagnetic waves according to the present invention.
10 to 12 are views showing the shape of a heating element to be sewn in a heating glove capable of preventing generation of electromagnetic waves according to the present invention.
13 and 14 are schematic perspective views of a heating glove capable of preventing electromagnetic waves according to the present invention.

Hereinafter, a heat-generating glove capable of preventing electromagnetic waves according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Referring to Figure 1,

In a heating glove capable of preventing the generation of electromagnetic waves,

When the heating area is 15 cm 2, the power consumption of 0.43 W to 0.53 W per hour is required to generate heat of 34 ° C to 70 ° C at a voltage of 3.7V. The heating pad used in the heating glove is 34 ° C ~ 50 ° C. It is necessary to set the power on / off cycle required for the electromagnetic wave to be much lower than the EMF certification standard 30 seconds or more, and the resistance value of the heating element (pad) area should be 28? To 32 ?.

In order to generate the same temperature under the same conditions, the resistance value decreases at the same rate according to the exothermic area increasing ratio.

The area of the heat body can be combined as the result of the width x length. However, when considering the heat generation region and the sewing space, the width of one side (vertical) of the heat pad is 1.5 cm to 3 cm.

The heating area increases only by the horizontal value because the height (2.5cm) is fixed.

However, when operated by 24v power supply (for motorcycle), when heat gap is 0.3cm, high heat is generated and the heat gap is large and the work is complicated.

The length of the heating line refers to the length between the shortest (3 cm in length) and the longest (0.3 cm in length) that can fit into the area of the heating element (3 cm in length x Ncm in width) and will be described with reference to Fig.

In FIG. 1, the heating pad area is 75 cm 2 (50 x 2.5 cm), and the heat ray (red) length is 50 cm (without heating wire spacing). Hot wire (red): 1

On the other hand, according to FIG. 2, there are two hot wires, FIG. 3 shows three wires, and FIG. 4 shows four wires. The heat-generating area and the resistance value thereof are shown in Tables 1 to 12 below.

The following ratios are established for the heat generation line (Ω / 1m) that can meet the heat generation area, the resistance value, and the length of the heating line for the heat generation area to satisfy the heat generation area and the heat generation temperature.

Heating area Resistance value: Heating line length = 100cm Heat resistance value: 100cm

Therefore, 100 cm hot wire resistance value = heat generating area resistance value * 100 / heating wire length

The standard of the heating line to be used is based on that it can be produced or purchased based on Ω / 1m.

A heating element designed to operate with a 3.7V supply can also be operated with a 5V or 7.4V supply, where the reference is based on power consumption (W).

Due to the characteristics of the product, the power of the heating pad area is the same, so the resistance value of the heating area varies depending on the operating voltage.

Tables 1 to 4 show the results when using one to four stranded hot wire using a 3.7V battery voltage.

Tables 5 to 8 show the results when using one to four stranded hot wire using a 7.4V battery voltage.

Tables 9 to 12 show the results of using one to four stranded hot wire using 11.1 V battery voltage.

On the other hand, the length of the heating element varies depending on the length and the length. However, when the heating wire (wire) is the same in the same area, the length of the heating wire inserted is the same.

A heat plate (heating element) designed to operate with a 3.7V power supply can be operated at 5V or 7.4V, but the criterion can be used within a range not exceeding twice the maximum value of the appropriate power consumption (W) range If it exceeds this range, the heat of heating (heating element) may be heated due to the difficulty of temperature control, and heat and hot plate may be ignited. Also, the temperature ON / OFF period is shortened and the amount of generated electromagnetic waves also increases.

Conversely, a heating element designed for a 7.4V power supply can be used as a 5V power supply in some cases. In this case, it should not fall below 0.5 times the minimum value of the optimum power consumption (W). If it exceeds this range, .

1 to 4, a heating glove capable of preventing electromagnetic waves from being connected through a series-connected wire, and a wire for connecting an electrode to a carbon fiber fabric woven carbon yarn spaced apart at a predetermined interval The heating pad (heating element) connected in parallel is shown in FIGS. 5 to 9.

5 to 9,

DC voltage (battery) at 3.7V, 5V, 7.4V, 11.1V, and 22.2V

(Ω), the number of carbon atoms in a specified heating element (length), the number of carbon atoms in a carbonaceous material The interval is displayed.

The operation of the heat-generating glove capable of preventing the generation of electromagnetic waves according to the present invention will be described.

When the power is applied to the heating element (heating pad) by turning on the switch in the heating device for DC power including the heating element, the temperature sensor, the temperature control device (artificial intelligent IC), the ON / OFF switch function (FET IC) When the temperature reaches the preset off temperature (artificial intelligence IC input), the artificial intelligence IC sends an OFF signal to the FET IC to turn off the power supply. As a result, the temperature of the heating element is lowered, When using a battery (including a DC power regulator) designed to turn on the power supply by sending a signal to the FET IC, it is necessary to apply the on / off Set the specified resistance value of the temperature sensor corresponding to one set temperature and set the heating element and power on / off period for a certain time (at least 30 seconds) Or more.

The on / off setting temperature of the DC power source driven by the temperature sensor attached to the heating element varies depending on the temperature adjusting step set in the battery or the regulator (for direct current power supply). The upper limit temperature (the temperature at which the power is turned off) The temperature (the temperature at which the power is turned on) is set.

In addition, generation of electromagnetic waves in a heating glove using a regulator (for DC power supply) is prevented or minimized (almost zero level).

A battery and a regulator (including a temperature sensor having a resistance value corresponding to a specific temperature (and an artificial intelligence IC recognizing these resistance values and a FET IC functioning as a switch for turning the power on and off) ) Is used to prevent the generation of electromagnetic waves in the heating element.

Based on the on / off setting temperature and the resistance value corresponding to each step inputted to the temperature control device (artificial intelligent IC), the power on / off cycle of each step exceeds the predetermined time (at least 30 seconds) Zero level.

It is operated at the off temperature and the on temperature for each stage set in the battery or the regulator (for DC power source), and after a certain time (depending on the site of use and skin close contact) Repeat on / off at the upper and lower temperatures.

And is optimized for each operating voltage according to the heating area of the heating element and the corresponding heating line length.

It is designed to use a carbon body-wired heating element among other heating elements optimized for the operating voltage, as another voltage (upper voltage). Even in this case, the on / off period of the heating element is not changed, so that generation of electromagnetic waves is prevented or occurs at almost zero level.

When using 3.7v for 7.4v, connect the wire with 1.5cm × 2 (1.5cm × 2).

In case of using 3.7v for 11.1v, increase it to 1.5cm × 3 (1.5cm × 3) for connection.

10 and 11 are views showing a heating element in the form of a series lead wire.

As described above, the heating element is arranged along the rim of all the fingers of the heating glove and is sewn inward.

12 is a view showing a heating element in the form of a parallel carbon fiber weave.

As described above, the heating elements are arranged at regular intervals (parallel to the carbon yarn) in a woven fabric composed of a carbon yarn and a general yarn.

In FIGS. 10 to 12, a jack portion connected to a battery (not shown) is connected to the battery by being formed in the female type.

13 and 14 are views showing an example of a heating glove capable of preventing electromagnetic waves according to the present invention.

Reference numeral 30 denotes a sewing line. The heating elements of Figs. 10 to 12 are built in (sewed) inside the sewing line 30. Fig.

Reference numerals 42 and 44 denote power supply lines and jacks. The jack 44 is connected to a battery (not shown, but may be a female type), battery (not shown, temperature control device and temperature setting button), and is installed in the pocket of the heating glove.

The power line 42 is connected to the heating element shown in Figs.

30: Bleeding line
42: Power line
44: Jack

Claims (7)

A heating glove comprising a heating element, a temperature sensor, a temperature control device, an ON / OFF switch device, and a battery, wherein the heating element is powered by a method for preventing generation of electromagnetic waves, The control unit controls the battery so that the power supply is turned on by sending a battery on signal when the temperature of the heating element is lowered to a predetermined temperature, and the pocket unit is provided in the back of the heating glove. The heating element is sewed along the outline of all the fingers while extending from one side of the heating glove. The jack exposed at one end of the heating element is a heating glove built in a pocket portion formed on the back of the heating glove,
In order to generate the electromagnetic wave near to zero level, it is attached to the heating element, and the predetermined resistance value is set to the temperature sensor corresponding to the on / off setting temperature one by one and the heating element and the power on / Generated electromagnetic waves at almost zero level so that they can be maintained for at least 30 seconds,
The battery is operated at an off temperature and a lower temperature for each step set in the battery or controller and then repeatedly turned on or off at an upper limit temperature and a lower limit temperature by a predetermined step after at least 30 seconds. Possible fever gloves. The method according to claim 1,
The on / off setting temperature of the DC power source driven using the temperature sensor attached to the heating element varies depending on the temperature adjusting step set in the battery or the controller. In each step, the upper limit temperature (the power is turned off) and the lower limit temperature a temperature at which the electromagnetic wave is turned on is set.
The method according to claim 1,
A temperature sensor having a resistance value corresponding to a specific temperature, a temperature control device for recognizing the resistance values, and an on / off switch device for switching on / off the power based on the temperature sensor. Possible fever gloves.
The method according to claim 1, wherein the power on / off cycle for each step is set to a predetermined time, at least 30 seconds or more, based on the on / off set temperature for each step input to the temperature control device and the corresponding resistance value Heat gloves that can prevent the generation of electromagnetic waves.
delete The method according to claim 1,
Characterized in that it is differently determined according to the operating voltage according to the heating area of the heating element and the corresponding heating wire length.
The method according to claim 1,
It can be used as a different voltage (upper voltage), and in this case, the on / off period of the heating element is not changed, so that electromagnetic waves are prevented from being generated.

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