KR101747850B1 - Heating equipment - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a heating device that receives a satellite frequency and generates power to be used for a variety of clothes or thermal insulation through a heating process and can be easily controlled using a mobile device. A power generating unit for receiving a frequency to generate power, a heat exchanging unit for generating heat as a power source, a heat generating unit for receiving heat generated, and a circuit chip for various controls and driving; There is an effect that the temperature can be maintained through heat generation without using a separate battery.

Description

Heating equipment

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a heat generating device, and more particularly, to a heat generating device capable of generating heat using a power source generated by receiving a frequency without using a battery.

Generally, various types of heating devices have been proposed to maintain body temperature.

In particular, as electronic devices have become smaller and more robust in recent years, progress has been made to integrate electrical devices into clothes or other accessories that can be worn on a person's body. Some examples of such applications include clothing, including light emitting diodes, shoes including ski and snowboard boots heating devices, jackets with control panels for mobile phones or MP3 players, and continuous heart rate monitoring devices.

Such a technique requires that an electronic device has an energy source to operate. Such an energy source is typically a battery, the battery may be embedded in an electronic device, configured for one use, interchangeably configured, or rechargeable. Each of these current options has its drawbacks: the built-in battery makes the associated electronic device useless when the battery is discharged or damaged, the replaceable battery requires additional space and materials to accommodate the battery, This is because the battery requires additional material for the battery charger and connection plug. Consumers, especially athletes, are not ideal because they tend to require lighter apparel and equipment without additional power cords.

In addition, at the practical stage, it is difficult to escape the research stage because of the increase in the weight of the clothes due to the battery, the inaccuracy of the sensor measurement, and the availability of the collection information.

Thus, there is a need to have a wearable electronic device that does not contain a large battery, for example, that can generate its own energy.

Recently, a method of supplying electric energy wirelessly without contact is used. A wireless power receiving apparatus that receives energy wirelessly may be driven directly by the received wireless power, or may be powered by the charged power using the received wireless power, There was a definite problem.

Accordingly, there is a desperate need for a compact and simple-to-use heating device capable of generating power by generating power using a frequency that can be received without limitation in a region or a topography without using a separate battery.

1. Publication No. 10-2015-0032529 (Method and apparatus for periodically changing frequency in wireless power transmission) 2. Open No. 10-2015-0118254 (Outdoor sensing smart clothing with bio-signal using permanent conductive material) 3. Public number 10-2011-0082035 (foot-mounted sensor powered by foot-transceiver) 4. Publication No. 10-2015-0018734 (Wireless power receiving apparatus and method)

Accordingly, it is an object of the present invention to provide a heating device capable of receiving a frequency of a satellite regardless of its position and using the power source for heat generation.

Another object of the present invention is to make it easy to handle through miniaturization in a small circuit configuration, and to prevent the installation object from being restricted.

In addition, another object of the present invention is to improve the manufacturing diversity by forming the heating wire with various materials.

Another object of the present invention is to provide a method of reinforcing structural strength by a super elastic wire, which can be easily applied to objects such as hats, various clothes, cushions, shoes, blanket, gloves and socks.

Another object of the present invention is to prevent penetration and adherence of moisture or contaminants through the sheet, and to prevent diffusion even if ignition occurs.

In addition, another object of the present invention is to facilitate frequency reception control, heat generation control, and temperature control for a mobile communication device.

According to an aspect of the present invention, there is provided a power generating unit for receiving a frequency and generating power, a power generating unit connected to the power generating unit, A heat generating unit connected to the power generating unit and connected to the power generating unit to supply power to the heat generating unit and to control and drive the heat generating unit, The circuit chip connected to control the cutoff includes a communication unit for communication with the mobile communication device, a control unit for controlling the power generation unit and the heating unit, and a driving unit for driving the circuit. The control unit is connected to the communication unit, A power source of the power generating unit is charged with a battery when the heat generating unit is not operated And the heat generated by the heat receiving unit is transmitted to the heating line of the heat generating unit in a resistance manner by receiving the power generated by the frequency receiving by the power generating unit. Is controlled so as to control the temperature of the liquid.

As described above, the present invention receives the frequency of the satellite regardless of the position, and can use the power source for the heat generation purpose, so that the inconvenience of using a separate battery is eliminated.

In addition, it is easy to handle through miniaturization with a small circuit configuration, there is no limitation on the objects to be installed, and the heating line can be formed of various materials, thereby improving manufacturing diversity.

In addition, it can be easily applied to objects such as hats, various clothes, cushions, shoes, blanket, gloves, socks and so on. It is reinforced by super elastic wire to prevent disconnection and deformation of heating wire, It is possible to prevent penetration and adherence of contaminants and to prevent diffusion even if ignition occurs.

In addition, there is an effect that frequency reception control, heat generation control, and temperature control can be easily performed for a mobile communication device.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic diagram of a heating device according to the present invention,
2 is a block diagram showing a heating device according to the present invention;
FIG. 3 is an exemplary block diagram of a temperature sensor, a battery, a thermoelectric element, and an amplifier formed in the heat generating device according to the present invention,
FIG. 4 is a perspective view showing a heat generating part formed on a sheet according to the present invention,
5A is a plan view showing a heat generating pattern formed on a heat generating portion according to the present invention,
FIG. 5B is a plan view of a sheet of a heat generating portion according to the present invention,
FIG. 6 is an exploded perspective view of a heat generating unit according to the present invention,
7 is an assembled perspective view of FIG. 6,
8 is an exemplary view showing a heat generating unit according to the present invention installed on an object by a sewing method;
9 is a view showing an example in which a heat generating part according to the present invention is installed on an object by an adhesive method;
10 is a view illustrating an example in which a heat generating unit according to the present invention is installed on an object by a Velcro tape method;
11 is an exemplary diagram showing an application executed for controlling the heat generating apparatus according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

1 to 10, a heat generating apparatus according to the present invention is a heat generating apparatus. The heat generating apparatus includes a power generating unit 10 receiving a frequency of an artificial satellite 11 to generate power, a heat exchanging unit 20, a heating unit 30 that generates heat by receiving the generated heat, and a circuit chip 40 for various controls and driving.

First, the heating device 100 forms a power generator 10 receiving a frequency and generating power.

The frequency received by the power generator 10 may be transmitted from the satellite 11 or the mobile communication device. The frequency may be a high frequency band used for portable communication or a TV, or a general frequency (general rectifier) It can be configured as one of a plurality.

The power generating unit 10 may include one or both of a band switch diode, a pin diode, a see-saw diode for detection, a show diode, a zener diode, a fast recovery rectifier diode, a high speed rectifier diode, a general rectifier diode, Can be mixed and configured.

At this time, the power generating unit 10 selects one to be interlocked with the used frequency, and one of a band switch diode, a pin diode, and a see-saw diode for detection is used for a high frequency band, and a show diode, a Zener diode, Rectifier diodes, high-speed rectifier diodes, general rectifier diodes, and switching diodes.

In the present invention, the power generating unit 10 uses a zener (constant voltage) diode or a switching diode that can receive a general-purpose frequency band. The power generating unit 10 sets a specific frequency band, A constant voltage is generated by the Zener effect.

The heat exchanging unit 20 receives power from the power generating unit 10 and generates heat by generating heat from a power source connected to the power generating unit 10. [ It can be configured in the form of a resistor.

Here, an example in which the power generation unit 10 can be implemented by adding another configuration will be described.

1. A power generating unit 10 is connected to a heat generating unit 30 by connecting a thermoelectric element 70. The thermoelectric element 70 is supplied with power and is heated at one side, The heat generating surface can be configured to be directed toward the human body to enable the heat generating function to be performed.

2. An amplifying unit 80 is connected to the power generating unit 10 to supply the amplified power to the heat exchanging unit 20. The amplifier 80 amplifies the voltage generated by the power generating unit 10, (30) to generate a voltage higher than the voltage of the power generating unit (10).

3. The power generator 10 is connected to the rechargeable battery 60 so that the rechargeable battery 60 is charged when the frequency of the rechargeable battery 60 is not operated while the frequency is continuously received, The power source of the power source 60 is used.

The heat generating unit 30 is connected to the heat exchanging unit 20 and receives heat to form an exothermic unit 30 on the object 200 requiring heat.

The heating portion 30 may be formed of one of lithium, carbon, copper, silver, and aluminum on one side of the sheet 31 to form a heating line 32. The heating line 32 is formed of a soft material to form a coating layer 33 to protect the heating line 32 from wrinkling or folding due to external force.

A heating pattern 34 may be formed in the form of a thin film on the sheet 31 around the heating line 32 or a thermal diffusion pattern may be formed on the surface of the sheet 31 by using one of lithium, Layer 31a is formed so as to enlarge the heat dissipation area and actively correspond to the shape change.

An outer sheet 35 impregnated with a water repellent antifouling agent or a nonflammable material is attached to both outer surfaces of the sheet 31 and the edges of the sheet 31 and the outer sheet 35 are bonded can do.

At this time, the water-repellent antifouling agent may include one or more water-repellent antifoaming agents such as hydrophobic materials having hydrophobicity, fluorooxy-alkoxy compounds, waxes containing aliphatic components, and florine, silane, Or polymerized.

The non-combustible material may be composed of inorganic hydroxide of aluminum hydroxide, magnesium hydroxide, or a mixture thereof.

The perforation hole 37 may be formed in the seat 31 and the outer sheet 35 so as to be sewn on the object 200 formed of one of a hat, various clothes, a cushion, a shoe, a blanket, An adhesive sheet 38 may be attached to the outer sheet 35 so as to be adhered to an object 200 formed of one of a hat, various clothes, a cushion, a shoe, a blanket, a glove and a sock, A velcro tape 39 may be formed on the object 200 to be attached to the object 200 formed of one of a hat, various clothes, a cushion, a shoe, a blanket, a glove and a sock.

At this time, the object 200 may be composed of various mechanisms, devices, and the like that must maintain the temperature.

The adhesive sheet 38 is adhered and fixed to the object 200 after removing the release paper 38a. The Velcro tape 39 is composed of a Velcro tape 39a and an arm Velcro tape 39b, 200 and the outer sheet 35, respectively.

In addition, a wire 36 made of a super-elastic shape memory alloy is provided on the outer surface of the seat 31 or on the inner surface of the outer sheet 35 in lateral and longitudinal directions to reinforce strength against external force, It can be configured to be restored to the original state.

The temperature sensor 30 may be connected to the circuit chip 40 so as to transmit the temperature data to the mobile communication device 90 after the temperature sensor 50 for checking the temperature of the heat is installed. (50) is composed of a thermocouple, a temperature-resisting resistor, and a thermistor suitable for downsizing. A thermocouple, a temperature-resisting resistor, and a thermistor are briefly described as follows.

1. When the two types of metals are combined, the thermocouple flows between the two metals when the temperatures at both ends of the junction are different from each other. In this case, the temperature difference between the two contacts is determined by the current. The platinum-platinum rhodium, chromel- , Iron-vigorous tantalum, copper-constantan, and the like.

2. The RTD is obtained by measuring the resistance by measuring the electrical resistance of the metal or semiconductor according to the temperature, and measuring the temperature. The resistance element may be composed of a metal wire such as platinum, copper, or nickel.

3. The thermistor is a semiconductor device that has a property that the electric resistance value decreases sensitively when the temperature rises. It is formed by sintering metal oxides such as manganese, nickel, cobalt, iron, copper and titanium. And the measurement range may be configured to have a sensitivity of about -50 to 300 ° C.

The circuit chip 40 is connected to the power generating unit 10 to control and drive the heating unit 30. The circuit chip 40 includes a communication unit 90 for communication with the mobile communication device 90, A control unit 42 for controlling the power generating unit 10 and the heating unit 30 and a driving unit 43 for driving the driving unit 41, And a charge switching unit 45 for switching the power source of the power generating unit 10 to be charged by the battery 60 when the heat generating unit 30 is not operating.

In this case, the charge switching unit 45 can set the driving time through the application of the mobile communication device 90. If the non-driving time of the heat switching unit 20 exceeds the predetermined time, the switching operation of the charge switching unit 45 So that the battery 60 is charged with the power of the power generating unit 10.

The mobile communication device 90 can be configured to be able to drive and temperature control the circuit chip 40 by installing an application.

That is, the heat generating device 100 is connected to the heat generating unit 30 through the circuit chip 40 so that the heat of the heat exchanging unit 20, which is operated by receiving power from the power receiving unit 10, .

The operation and effect of the present invention constructed as described above will be described below.

As shown in FIGS. 1 to 11, in order to use the heating device 100, a frequency to be used is selected and a power supply generating unit 10 is selected after setting a use band.

The power generating unit 10 is connected to the heat exchanging unit 20 and the heating unit 30 in order and the circuit chip 40 is installed to be interlocked between the power generating unit 10 and the heat exchanging unit 20 Thereby completing the assembly of the heating device 100.

Here, the thermoelectric element 70 may be connected to the heat generating unit 30 to receive power from the power generating unit 10, if necessary, and the battery 60 may be connected to the power generating unit 10 And the amplifier 80 can be connected to amplify the power of the power generating unit 10, so that the power generating unit 10 can be variously manufactured according to the use conditions.

The heating unit 30 may be formed as a thin film on the sheet 31 so that the heating unit 32 may be appropriately formed in accordance with the area and the shape of the object 200. In order to improve the durability, To form the coating layer 33. The coating layer 33 is formed to have excellent heat resistance and flexibility to ensure free movement.

After the outer sheet 35 is disposed on both sides of the sheet 31, the edges of the sheet 31 and the outer sheet 35 are integrated by an adhesive or a heat bonding method.

A wire 36 is formed in a mesh form between the sheet 31 and the outer sheet 35 to reinforce the structural strength of the wire 36 by the ability of the superelastic shape memory alloy to support the wire 36, There is a feature that can maintain the state.

Thereafter, the heating unit 30 is attached to the object 200 by one or two methods of sewing through the perforation hole 37, using an adhesive sheet 38, or attaching a velcro tape 39 .

The temperature sensor 50 is inserted into the seat 31 and the outer sheet 35 and the temperature sensor 50 is connected to the circuit chip 40 to check the heat generation temperature in real time It is easy to control temperature.

Next, the heating device 100 receives the frequency of the satellite 11 or the like from the power generating unit 10 and generates a constant voltage by operating the application of the mobile communication device 90, The control unit 42 controls the power to be transmitted to the heat exchanging unit 20 and generates heat by driving the heat exchanging unit 20 through the driving unit 43. The heat generated in the heat exchanging unit 20 is heat- The heat is transmitted along the heating line 32 of the heat exchanger 30 to generate heat.

At this time, the position tracking unit 44 of the circuit chip 40 transmits the information through the communication unit 41 to display the geographical position on the satellite 11 or the mobile communication device 90, If the heat exchange unit 20 is not driven for a predetermined period of time, the charge switching unit 45 charges the battery 60 connected to the power generating unit 10, The power source of the power source 60 can be used.

The heating device 100 may be configured to allow the user to receive and operate the power generator 10 through the application of the mobile communication device 90 and the operation information of the heat exchanger 20, Real-time temperature information using the sensor 50 can be easily grasped, so that it is possible to wirelessly control the operation with the circuit chip 40, thereby increasing convenience.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, Various changes and modifications may be made by those skilled in the art.

10: Power generating unit 11: Satellite
20: heat exchanging part 30:
31: sheet 31a: thermal diffusion layer
32: Heating line 33: Coating layer
34: heating pattern 35: outer sheet
36: wire 37: perforated hole
38: Adhesive sheet 39: Velcro tape
40: circuit chip 41:
42: control unit 43:
44: position tracking unit 45: charge switching unit
50: Temperature sensor 60: Battery
70: thermoelectric element 80: amplifier
90: mobile communication device 100: heating device
200: object

Claims (14)

A power generating unit 10 for receiving a frequency and generating a power source and forming at least one heat exchanging unit 20 connected to the power generating unit 10 to generate a resistance by a power source to be supplied, (30) connected to the heat source (20) and installed on an object (200) requiring heat generation, the heat generating line (32) receiving heat and generating heat,
The circuit chip 40 connected to the power generating unit 10 to receive power and to control and supply power to the heat exchanging unit 20 for controlling and driving the heat generating unit 30 is connected to the mobile communication device A control unit 42 for controlling the power generation unit 10 and the heating unit 30 and a driving unit 43 for driving the communication unit 41 for communicating with the communication unit 41, And a charge switching unit 45 for switching the power source of the power generating unit 10 to be charged by the battery 60 during non-operation of the heat generating unit 30 Forming,
The circuit of the circuit chip 40 is connected to the heat generating line 32 of the heat generating unit 30 by receiving the power generated by the frequency receiving in the power generating unit 10 and transmitting heat generated in the heat exchanging unit 20 in a resistance- And controls the operation of the heat exchange unit (20) through the configuration. delete delete The heat generating part (30) according to claim 1, wherein a heating line (32) is formed of lithium or carbon on one side of the sheet (31)
Wherein the heating line (32) comprises a coating layer (33) made of a soft material. The method of claim 4, wherein a heat generating pattern (34) is formed on the sheet (31) in the form of a thin film around the heating line (32)
Wherein the surface of the sheet (31) is made of lithium or carbon to form a thermal diffusion layer (31a). delete delete delete delete delete delete delete delete delete

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