KR20110053872A - Feet wrap having pad using flexible heating unit - Google Patents

Abstract

PURPOSE: A feet wrapper including a heating pad using a flexible heating element is provided to secure the excellent heat-insulating property of the feed wrapper by the electric stability of the flexible heating element. CONSTITUTION: A feet wrapper(10) including a heating pad comprises the following: an elastic band(15) and a band fixture(16) formed on the upper side of the feet wrapper for narrowing the upper side of the wrapper; the heating pad(30) installed on the wrapper; a controller(20) with a rechargeable power supply unit(26), connected to the heating pad for supplying electricity of the rechargeable power supply unit to the heating pad; and an inner skin and an outer skin sewed to form the wrapper. The heating pad is inserted in between the skins.

Description

Foot wrap having a heating pad by a flexible heating element {Feet wrap having pad using flexible heating unit}

The present invention relates to a foot wrapper used for the purpose of protecting the body temperature of a woman, a child, an elderly person or a patient, and more particularly, a combination of an elastic band and a fixing band is formed on an open top of the foot wrapper, and the heat wrapper has a heating mesh. Or a heating pad made of a heating element formed by an elastic heating wire or conductive twisted yarn, and the heating pad is portable and combines a controller with a built-in rechargeable power supply, and the heating pad is composed of a single type or a split type to wrap them. By inserting and forming a separate pocket in the end of the inner shell and the inner shell of the balsae, it is possible to effectively protect the body temperature as well as to protect the body temperature by heat bales that can generate heat in the winter or low temperature environment.

In general, when working or learning in the late autumn, winter, or low temperature when the temperature is low, the body will be more cold because it consumes a lot of body temperature from a relatively unprotected foot.

In addition, in the case of the foot, since peripheral blood vessels are not sufficiently developed, blood circulation is not evenly distributed, and the body part located farthest from the heart is not effective protection of body temperature in the existing thermal insulation type that only relies on socks. to be.

In particular, women, young children, or elderly people or patients with inconvenient activities, such as during normal sleep as well as during sleep or rest is very hot body heat consumption is set so that the higher temperature indoor heating will be set up because of excessive energy Consumption occurs.

Accordingly, to protect the body temperature by covering the feet with a blanket or wearing thick socks for the purpose of warming the feet as described above, these blankets and thick socks have more than the warmth and cold protection functions of the original materials. It is difficult to expect a more effective and urgent need for a product having excellent cold and warm insulation.

Accordingly, although a separate heating element has been attempted to be incorporated into a sock or a variety of pocket-shaped products, it has a heating function due to problems such as disconnection due to the breakdown of the existing heating element due to the characteristics of the bale that is frequently folded and unfolded. Insulation products are rarely produced or implemented in practice.

Moreover, the heating element applied to the above-mentioned thermal insulation product has excessive power consumption because it continuously provides power set by the user in addition to the problem of disconnection for bending and continuously operates and generates heat, and mostly uses household AC power. There are many restrictions on mobility. In particular, in places where it is impossible or inconvenient to use AC power, such as outdoors, it has a closed end that cannot operate the heating element as described above.

In addition, most heating elements supply power only at both ends of the heating element. When the width or length of the heating element becomes longer, the resistance value increases proportionally, resulting in an instantaneous voltage drop. Has the problem of falling.

In addition, due to voltage drop and decreasing amount of current, the local low temperature phenomenon occurs or the heat generation itself is not available due to the technical limitations such as difficult to use as a heating element. In addition, when the local high temperature phenomenon occurs, the insulation coating layer is destroyed, which may cause problems of safety accidents such as electric shock or fire.

The present invention is to solve the problems as described above, connecting the controller with a built-in rechargeable power supply to the heating pad made by embedding the main and auxiliary power lines in the heating element made of a flexible heating mesh or flexible heating wire or conductive twisted yarn, The heating pad is composed of a single type or a split type to be embedded in the foot wrapper of the open form or to form a pocket on the foot wrapper to insert,

It is an object of the present invention to provide a foot wrapper having a heating pad by a flexible heating element to produce excellent thermal insulation and cold protection due to the foot wrap due to the heating effect and electrical stability of the flexible heating pad.

The present invention for achieving the object as described above is provided with a foot-shaped balsae open top, and the upper side of the balsae opened by the elastic band and the band fastener on the upper side of the bales can be folded and narrowed in the form of wrinkles To ensure that

A separate heating pad is formed on the foot wrapper, and the heating pad is connected to a controller having a rechargeable power supply unit. The power of the rechargeable power supply unit is supplied to the heating pad by operation of the controller exposed from the foot wrapper having the heating pad. It is configured to be supplied.

According to the present invention, there is no fear of breakdown or damage due to disconnection without being hindered by movement by the thin, flexible and excellent elasticity heating pad, and if necessary, the heating pad of the desired part can be selectively operated. The efficiency of use is, of course, excellent in convenience, and the heat insulation pad of the baler itself adds heat to the heat shield, so it can perform a very good cold protection and body temperature protection, and the flexible heating element maintains an even distribution of voltage overall. By maintaining the heating temperature evenly, it is possible to prevent the current collision or voltage drop to prevent the error or deviation of the heating temperature during use, which has the effect of extending the service life.

In particular, the foot wrapper according to the present invention can be used effectively in the winter season by students studying in a chair for a long time, such as an examinee or a graduate student, including an outdoor worker or an indoor worker, the elderly elderly people or patients also protect or cold Effective use can be achieved for this purpose.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor may properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

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

1 is an overall configuration diagram of the balsa of the heating pad is formed in accordance with the present invention, Figure 2 is an overall view of the heating pad of the balsa in accordance with the present invention.

Foot wrapper 10 according to the present invention is made in the form of an open top pocket, it will be preferable to manufacture using a soft cotton fabric.

Such a bale 10 would be more ideal to fabricate the outer shell (11) made of a relatively tough nylon material and the inner skin 12 of the soft cotton fabric, the upper side of the open launcher 10 as a whole The elastic band 15 is inserted, and both ends of the elastic band 15 are exposed to the outside, thereby restraining both ends of these elastic bands 15 from separate band fixtures 16, thereby completing. At this time, the elastic band 15 is to be narrowed by folding the upper side of the open foot wrapper 10 in the form of wrinkles, pull the elastic band 15 in the state that the foot is inserted into the launcher 10 After the open upper side is narrowed, restraining the elastic band 15 pulled by the band fixture 16, the foot wrap 10 can be worn in close contact with the user's body.

In this case, the elastic band 15 and the band fixture 16 are often used as a means for narrowing the opening of the hat of the hooded jumper or the hat back of the training wear, or for the purpose of narrowing the sleeve or the bottom or the bottom of the jumper or jacket. The detailed description thereof will be omitted.

The foot wrap 10 made in this way is formed with a separate heating pad 30, the heating pad 30 as described above is connected to the controller 20 having a rechargeable power supply unit 26 of the controller 20 The heat is supplied while power is supplied from the rechargeable power supply unit 26 through the operation, and as the temperature of the heating pad 30 rises, the person using the foot wrap of the present invention feels warmth for the entire foot.

At this time, since the heating pad 30 may be formed as a single body or divided into a plurality of foot wrapper 10, which is limited to the position and number of the heating pad 30 according to the convenience and variety of the user or the manufacturer. Various variable applications will be possible without this.

Particularly, in the case of forming the heating pad 30 with respect to the foot wrapper 10, as shown in FIG. 3, in the case of the foot wrapper 10 formed of an overlap of the sheath 11 and the endothelial 12, the sheath ( 11) and the heating pad 30 may be positioned between the inner skin 12 so that the heating pad 30 may be fixed by sewing the outer skin 11 and the inner skin 12 and the outer skin 11. ) In the case of the foot wrapper 10 made of a single, as shown in Figure 4 in the state of sewing a separate pocket 13 in the desired position on the inner surface of the foot wrap 10 in the heating pad to the inside of the pocket 13 It is also possible to insert (30) to be used.

In addition, as a characteristic configuration in the present invention, the foot wrapper of the present invention forms a separate bag 14 on the outer surface of the foot wrapper 10 to put the controller 20 exposed outside to the inside of the bag 14. It is to be kept so that the simple management and processing for the controller 20 can be made.

The foot wrapper 10 of the present invention having the heating pad 30 as described above may include the heating pad 30 as a single entity corresponding to the whole foot wrapper 10 or as shown in FIG. 5. It may be formed in at least two divided forms with respect to the entire surface of the). At this time, when the heating pad 30 is in a split form, the heating pads 30 are connected in parallel to each other so that the heating pads 30 are connected to the controller 20. Since the power provided is delivered to each of the heating pad 30 at the same time it is possible to quickly and efficiently generate heat.

In addition, the heating pad 30 is formed in two or more divided forms, but these heating pads 30 have a connection structure by a general plug jack and a socket which can be separated and connected to each other, and the controller 20 It also has a connection structure of separation and coupling by AC adapter 27 or automobile cigar jack and plug jack and socket, so that the heating pad 30 in the position where heat is unnecessary is cut off the power supply through the separation of the plug jack. According to the convenience of the most efficient and can be adjusted to the appropriate heating state.

In particular, in the case of forming a separate pocket 13 sewn on the inner surface of the foot wrapper 10 may be used by inserting the heating pad 30 in the pocket 13, the pocket 13 In the case of separately forming the necessary parts of the user, as shown in Figure 6, the heating pad 30 having a corresponding size in each of the pockets 13 can be inserted or removed separately, so limited only to the necessary parts Of course, if the heating pad 30 is unnecessary, if the heating pad 30 is not necessary, all of the heating pads 30 can be removed from the pocket 13 and used for the purpose of a baler without heating means, which is very economical and reasonable.

Accordingly, the above heat generation as shown in FIG. 7 in a state where sufficient charge is made to the rechargeable power supply unit 26 inside the controller 20 by using a cigar jack in the AC adapter 27 or the vehicle. When the foot is inserted into the foot wrapper 10 having the pad 30, the controller 20 is operated so that the power of the rechargeable power supply unit 26 is supplied to the heating pad 30 so that the heating pad 30 is heated. Accordingly, the cold and warming of the entire foot of the user can be made. At this time, the foot wrapper 10 may be made to be used in size to be used for one foot to be worn on each foot or to be used to produce a size enough to put both feet at a time.

Hereinafter, the detailed configuration and operation of the controller and the heating pad for the balsa of the present invention will be described.

As shown in FIG. 8, the controller 20 of the heating pad according to the present invention includes a selection button unit 21, a time setting unit 22, and a temperature setting unit 23, and the time setting unit 22. And the central processing unit 24 in a state in which the temperature setting unit 23 is connected with the power supplied from the separate rechargeable power supply unit 26, the temperature and power adjusted by the time setting unit 22 and the temperature setting unit 23. The power is delivered to the heating pad 30 with an intermittent time. In addition, the time, temperature and state of charge set as described above can be confirmed through a separate display unit 25.

Here, the rechargeable power supply unit 26 is composed of a low-voltage direct current rechargeable battery or supercapacitor, etc., by using an AC adapter 27 or the like to accumulate power through household AC power or by using a cigar jack in an automobile or the like. It is to use the stored power in the state of power storage, but the foot pad 10 combined with the heating pad 30 due to the rechargeable power supply unit 26 will not interfere with the movement, so in the end as well as outdoors very convenient Use is done.

That is, the controller 20 controls the power provided from the rechargeable power supply unit 26 and transmits the power to the heating pad 30. The controller 20 includes a selection button unit 21 and The time setting part 22, the temperature setting part 23, the central processing part 24, and the display part 25 are formed, and the rechargeable power supply part 26 is integrated.

Accordingly, when the power on, off, time setting and temperature setting are performed through the selection button unit 21, the central processing unit 24, which receives such a signal, generates power suitable for the set value as described above. At the same time, the display unit 25 displays the set time or temperature, displays the remaining battery capacity of the rechargeable power supply unit 26, and the battery voltage. It will display the status of being charged or completed. The display unit 25 may include an LED, a liquid crystal display, and the like.

Therefore, when the operation sequence for the heating pad formed in the bale of the present invention using the controller 20 as described above, first to set the heating temperature for the heating pad 30 by pressing the select button 21. For example, each time a specific button constituting the selection button unit 21 is sequentially pressed, the heating temperature is set in the order of low temperature, medium temperature, medium temperature, high temperature, ultra high temperature, low temperature, and the like. The furnace can be selected and the selected temperature range can be confirmed by LED lighting on the display unit 25.

In addition, by pressing a specific button constituting the selection button unit 21 is adjusted for the interruption time of the power, the supply time and the interruption time of the power applied to the heating pad 30 is 1 ~ 40 If freely adjusted within the range of minutes to have the temperature set in the temperature setting section 23 and the process of applying power and cut off set in the time setting section 22 is to be repeated continuously.

In particular, the control of the heating temperature in the temperature setting unit 23 as described above is made by varying the amount of current applied to the heating pad 30 in accordance with the operation of the selection button unit 21, the heating pad 30 ), When the overheat cut-off part 33 by bimetal is additionally formed, the power is automatically cut off due to the physical properties of the bimetal when overheated beyond a desired set temperature range, so that a fire or burn may be caused by overheating. You can prevent accidents.

In particular, in operating the heating pad 30 made of a single or multiple heating elements 40 by using the rechargeable power supply unit 26 by the low-voltage DC rechargeable battery, the control operation of the rechargeable power supply unit 26 by the storage battery and the control operation. For various electronic circuits, it is preferable to adopt a structure in which a rechargeable battery and an electronic circuit are fixed together in one case, and a circuit is formed on a board to allow a temperature to be adjusted in multiple stages. Press the switch by (21) once, low temperature, twice press the middle temperature, three times the middle temperature, four times the high temperature, five times the ultra high temperature. Can also be cut off and flowed at regular intervals (e.g. after the first 20 minutes However, after that, the board is connected to the rechargeable battery by making terminals that can be energized and cut off at 10-minute intervals) and then connected to the rechargeable battery.

The rechargeable battery constituting the rechargeable power supply unit 26 should be replaceable, and the inside of the case may include a substrate designed with the above-described temperature controller function, and if the rechargeable battery is a lithium ion-based rechargeable battery, an explosion-proof circuit may be included at the same time. It would be desirable to make.

In addition, the outside of the case to create a power groove that can be used by plugging in the power cord connected to the waterproof jack is pulled out of the heating pad (30), and can also be used by plugging in the AC adapter (27) used to charge the rechargeable battery, If you plug the adapter jack into the above power groove without removing the rechargeable battery, it will be charged immediately.If you plug in the waterproof jack, it will make a structure to supply the current to the heat generating part. Control temperature and attach power on / off switch on the outside of the case to turn off the power

Accordingly, the rechargeable power supply unit and the time and temperature control unit are integrally embedded in one case and separately separated from each other to form a heating pad 30 in which the heating element 40 and the overheat cutoff unit 33 are combined. Power supply groove (connector) attached to the (20) will be the most ideal form to be able to use the power jack attached to the heating pad (30).

The heating pad 30 that generates power by being supplied by the controller 20 is manufactured by applying various types of heating means known in the art, such as a flexible heating mesh or a flexible heating wire, to the heating means as described above. As shown in FIG. 9, the heat generating pad 30 is formed by the heat storage carrier 31 at the top thereof, the heat generator 40 at the bottom thereof, and the heat insulation 32 at the bottom thereof, so that they are sewn together. Is adhesively fixed.

At this time, the heat storage transfer material 31 is made by adding a cotton fabric to the upper part of the fabric made of Techno thermo, and the Techno thermo is a combination of a light energy absorbing heat generating yarn and a W-section yarn. It is a new material that realizes higher heat retention by manufacturing, and it has better heat retention than ordinary fabrics even in cloudy weather, where light energy is not active, and it prevents heat from leaking to the outside as it is a material with low thermal conductivity compared to conventional heat storage function yarns. There is a fabric. Accordingly, the heat storage transfer member 31 prevents heat from leaking by the heating element 40, thereby minimizing heat loss due to heat dissipation, and the cotton fabric has a soft touch, thereby making it more comfortable.

In addition, the heat insulator 32 is made of fiber glass silica pads, and fiber glass silica pads are commonly referred to as space suit materials, but they can withstand thousands of degrees Celsius and are oriented in one direction. It is widely known as a material having a function of completely blocking heat conduction, wherein the heat insulator 32 blocks heat from the heat generating body 40 in an unnecessary direction and at the same time the heat is directed toward the human body. Since it can be transmitted intact, it is possible to produce more efficient heat generation characteristics by blocking the release of unnecessary heat.

The flexible heating pad 30 made as described above is very effective because the heat generating action of the heating element 40 located between the heat storage carrier 31 and the heat insulator 32 can be evenly and effectively diffused and conducted.

Here, for the purpose of improving elasticity, durability, chemical resistance, insulation, and waterproofness of the heating pad 30, as shown in FIGS. 10 and 11, the upper and lower surfaces of the heating element 40, respectively As the heat generating pads 30 are formed by attaching and forming the surface sheets 45 and 45 ', the heating pads 30 are elastic or durable due to the material properties of the surface sheets 45 and 45'. Various physical properties such as waterproofness or insulation are greatly improved.

In more detail, the heating element 40 having the power line is placed on the first surface sheet 45, and the second surface sheet 45 ′ is sequentially placed on the upper surface of the heating element 40. Then, when the surface sheets 45, 45 'are pressurized by a high-pressure press device, the surface sheets 45, 45' are thermally melted with each other and the surface sheets 45, 45 'are divided. At the same time, the heating pad 30 is completed while the heating element 40 is embedded with the power line between the surface sheets 45 and 45 '.

In this case, when a separate adhesive sheet 46, such as a plastic sheet, is inserted between the surface sheets 45 and 45 'to be heat-compressed, the vinyl sheet adhesive sheet 46 has a very low melting point. It has the advantage that can be used for the surface sheets 45, 45 'of various materials having a higher melting point than the vinyl paper.

That is, when the surface sheets 45 and 45 'are used as nonwoven fabrics or woven papers, the surface sheets 45 and 45' made of nonwoven fabrics and woven papers, as well as the soft touch, of the heating pad 30 are used. It is to improve durability without affecting ductility, and when the surface sheets 45 and 45 'are used as waterproof fabrics such as neoprene, the entire heating pad 30 is waterproof. Therefore, it is possible to prevent a short circuit or electric shock to the heating pad.

In addition, when the surface sheets 45 and 45 ′ are used as spandex having excellent elasticity, the heating pad 30 may have more elasticity, so that the heating sheet 30 may have a greater elasticity. Continuous and safe use can be made without difficulty from various pressures and loads applied.

The heating element 40 for constituting the heating pad 30 may be made of a conductive mesh 41 in the form of a mesh or the flexible heating wire 44 in the form of a wire, and the conductive mesh 41 may be used. In case of), it can be said that it has flexibility for a large area, and in the case of the flexible heating wire 44, it has an advantage that it can be effectively used in various fields due to its excellent elasticity.

That is, the heating element 40 is the entire surface of the core material 41a woven in the form of weft and warp or string and blade using fiber yarn or soft synthetic resin or rubber yarn as shown in Figs. A conductive coating layer 41b formed of a conductive composition on the surface, and an insulating layer 41c formed by coating or coating an insulator made of liquid silicone rubber or the like on the surface of the conductive coating layer 41b. ), The conductive coating layer 41b made of a conductive composition generates heat by applying power to the conductive mesh 41 so that the overall temperature rise of the heating element 40 is achieved.

In particular, the core 41a woven as described above is impregnated in the conductive composition or the conductive composition is coated or coated on the surface of the core 41a to form the coating layer 41b by the conductive composition. Here, the conductive composition is made by mixing the liquid silicone rubber and the conductive carbon black. Preferably, the liquid silicone rubber and the conductive carbon black may be ideally mixed in a mass ratio of 100: 1 to 15.

In this way, the conductive mesh 41 on which the core 41a, the coating layer 41b, and the insulating layer 41c are formed is connected to a power line for applying power to the coating layer 41b to complete the heating element 40. Could be.

At this time, the power supply line is provided at regular intervals between the main power supply lines 42 and 42 'which are arranged side by side at both ends of the conductive mesh 41 and these main power supply lines 42 and 42'. Comprising an auxiliary power line 43, 43 'is arranged, the main power line 42, 42' and the auxiliary power line 43, 43 'is a coating layer 41b and the conductive composition Since the electrical connection state is maintained, when the power is applied to these main power lines 42 and 42 'and the auxiliary power lines 43 and 43', the coating layer 41b becomes energized and the coating layer 41b. The self acts as a resistor to perform a heat generating action by the resistance.

Particularly, the auxiliary power lines 43 and 43 'are applicable to various numbers according to the width or length of the conductive mesh 41. In the case where the conductive mesh 41 is wide or long, the auxiliary power source is long. The number of lines 43 and 43 'should be increased proportionally so that the distance between power lines is not too far.

Therefore, the flexible heating element 40 can be manufactured by adding or subtracting the number of the auxiliary power lines 43 and 43 'as described above, so that the resistance value of the place where the actual power is supplied even if the length of the heating element is long or wide is increased. It is kept substantially constant so that voltage drop does not occur at all, and current distribution is uniform, thereby preventing local heating or local low temperature phenomenon.

In addition, the main power lines 42 and 42 'and the auxiliary power lines 43 and 43' are to be connected so that powers of different polarities are sequentially applied alternately, and the polarities of neighboring power lines are the same. In this case, since energization will not be made, these main power lines 42, 42 'and auxiliary power lines 43, 43' are positive or negative so that power of different polarities can be applied between adjacent power lines. When the separate connection to the power supply unit of the heating element 40 is applied evenly and stable heat is made.

In addition, when a heating element is to be made according to a specific voltage, the grid gap of the conductive mesh 41 is adjusted according to the voltage to be used to adjust the installation interval of the auxiliary power lines 43 and 43 '. . In other words, in order to make a low voltage heating element, the voltage drop occurs at a small resistance value due to the low supply voltage, and the mesh size of the mesh is made very small, and a plurality of auxiliary power lines 43, 43 'are installed. However, while the gap is tight and the voltage to be used is applied, the insulating layer 41c (which may be formed by forming an insulating layer by the liquid silicone rubber on the surface of the coating layer or by overlaying a separate coating material, if necessary) This is done by creating the optimal grid size and spacing between the power supply lines that produce the best heat without breaking.

On the other hand, in order to make a high-voltage heating mesh, the grid size of the conductive mesh 41 may be increased and the spacing of the auxiliary power lines 43 and 43 'may be increased. At this time, the grid size of the mesh should be adjusted so that the insulation between the horizontal and vertical lines between the grids of the mesh does not break due to the occurrence of corona. The spacing of the supply lines can also be made wider at the maximum distance where no voltage drop occurs.

In addition, in the construction of the heating element 40, the main heating means may be manufactured using the flexible heating wire 44 as shown in FIGS. 14 and 15, wherein the flexible heating wire 44 is a stretchable heat conductive material. Elasticity in which heat conduction is also performed on the surfaces of the flexible core member 44a and the conductive coil wire 44b in a state where the conductive coil wire 44b made of carbon fiber yarn is wound on the surface of the elastic core member 44a made of silicone resin. The stretchable insulating material 44c made of silicone resin is covered and formed. Accordingly, when power is applied to the conductive coil wire 44b of the flexible heating wire 44, the conductive coil wire 44b serves as a resistor to generate heat, and eventually the temperature rise of the flexible heating wire 44 is increased. Of course, the heat generation to the entire heating element 40 through the heat conduction will occur.

In this way, a separate power line for applying power to the conductive coil wire 44b is connected to the flexible heating wire 44 formed by the flexible core material 44a, the conductive coil wire 44b, and the elastic insulating material 44c. By forming it will be able to complete the desired heating element (40).

At this time, the power supply line is provided at regular intervals between the main power supply lines 42 and 42 'which are arranged side by side at both ends of the stretchable heating line 44 and these main power supply lines 42 and 42'. The main power lines 42 and 42 'and the auxiliary power lines 43 and 43' are electrically connected to the conductive coating line 44b. Since the connection state is maintained, when power is applied to the main power lines 42 and 42 'and the auxiliary power lines 43 and 43', the conductive coil lines 44b become energized and the conductive coil lines ( 44b) itself is to act as a resistor to perform the exothermic action by the resistance.

Particularly, the auxiliary power lines 43 and 43 'may be applied to various numbers according to the total length of the flexible heating line 44. When the length of the flexible heating line 44 is long, the auxiliary power line 43 43 ') should be increased proportionally so that the distance between power lines is not too far apart.

Therefore, the heating element 40 can be manufactured by adding or subtracting the number of the auxiliary power lines 43 and 43 'as described above, so that the resistance value of the actual power supply is substantially constant, no matter how long the heating element is. Not only does the voltage drop occur at all, but the current distribution is uniform, thereby preventing local heating or local low temperature.

In addition, the main power lines 42 and 42 'and the auxiliary power lines 43 and 43' are to be connected so that powers of different polarities are sequentially applied alternately, and the polarities of neighboring power lines are the same. In this case, since energization will not occur, the main power lines 42 and 42 'and the auxiliary power lines 43 and 43' are positive or negative so that power of different polarities can be applied between adjacent power lines. When the separate connection to the power supply of the stretchable heating element 40 is applied evenly and stably generated heat from the applied power.

In addition, when the heating element is to be made according to a specific voltage, the length of the flexible heating wire 44 may be adjusted according to the voltage to be used to adjust the installation interval of the auxiliary power lines 43 and 43 'installed therein. That is, in order to make a low voltage heating element, a plurality of auxiliary power lines 43 and 43 'are provided for the flexible heating line 44, considering that a voltage drop occurs at a small resistance value due to a low supply voltage. By narrowing the spacing and applying the voltage to be used, it is necessary to create an optimum spacing of the power supply line that produces the best heat without destroying the insulation.

On the other hand, in order to make a high voltage heating element, the spacing of the auxiliary power lines 43 and 43 'may be wider with respect to the entire length of the flexible heating line 44. At this time, the spacing of the auxiliary power lines 43, 43 'is to be made wider to the maximum distance that the voltage drop does not occur.

In addition, in the construction of the heating element 40, the main heating means may be manufactured using the conductive twisted yarn 47 as shown in FIGS. 16 and 17. The conductive twisted yarn 47 may be made of non-combustible materials. The conductive layer 47b was formed by coating a conductive composition made of a mixture of liquid silicone rubber and carbon black on the surface of the screening 47a formed by joining several strands of glass fibers having durability and not absorbing moisture. In this state, the insulating layer 47c made of stretchable silicone resin is coated on the surface of the conductive layer 47b.

When the conductive twisted yarn 47 is applied with power from both ends, heat is generated while the conductive layer 47b plays a role of a resistor, and eventually, heat from the conductive layer 47b is insulated from the insulating layer 47c. While conducting through the heating element 40 is to perform the heating action.

In this way, the conductive twisted yarn 47 made of the screening 47a made of glass fiber, the conductive layer 47b made of carbon black, and the insulating layer 47c made of silicone rubber is woven together in the form of a weft and an inclined yarn. In this case, the method of weaving the net by the conductive twisted yarn 47 is a conductive cross that crosses each other by combining a plain weave and a plain weave, not tricot or knitted. The point of contact between the twisted yarns 47 is to be naturally produced. Accordingly, as the power is applied to the conductive twisted yarn 47 as described above, the heating element 40 by the conductive twisted yarn 47 performs a heat action.

At this time, as a means for applying power to the conductive twisted yarn 47, main power lines 42 (42 ') and these main power lines (parallel) disposed at both ends of the conductive twisted yarn 47 in parallel with each other ( 42 and 42 ', which are composed of auxiliary power lines 43 and 43' which are arranged at regular intervals between the main power lines 42 and 42 'and the auxiliary power line 43 ( 43 'maintains electrical connection with the conductive layer 47b of the conductive twisted yarn 47, so that power is supplied to these main power lines 42, 42' and auxiliary power lines 43, 43 '. In this case, the conductive twisted yarn 47 is in an energized state and at the same time, the conductive layer 47b itself performs a role of a resistor to perform a heat generating action by resistance.

Here, the main power lines 42 and 42 'and the auxiliary power lines 43 and 43' may be suitable for supplying a stable power supply using a braided electrode formed by braiding a conductive wire. In addition, as a method of connecting or fixing the main power supply lines 42 and 42 'and the auxiliary power supply lines 43 and 43' by the conductive twisted yarn 47, they are connected to each other using separate weaving yarns. It would be more preferable to be able to maintain a stable ground state without being separated or separated.

In particular, the auxiliary power lines 43, 43 'can be applied in various numbers according to the total length of the conductive twisted yarn 47, when the length of the conductive twisted yarn 47 is long or wide The number of auxiliary power lines 43 and 43 'should be increased proportionally so that the distance between power lines is not too far.

Therefore, the heating element 40 can be manufactured by adding or subtracting the number of the auxiliary power lines 43 and 43 'as described above, so that the resistance value of the actual power supply is substantially constant, no matter how long the heating element is. Not only does the voltage drop occur at all, but the current distribution is uniform, thereby preventing local heating or local low temperature.

The main power lines 42 and 42 'and the auxiliary power lines 43 and 43' applied to the heating element made of the conductive twisted yarn 47 are connected so that power of different polarities is alternately sequentially applied. If the polarities of the power lines adjacent to each other are the same, the energization will not occur, so that the main power lines 42 and 42 'and the auxiliary power supply are applied so that powers of different polarities can be applied between power lines adjacent to each other. When the lines 43 and 43 'are respectively connected to the power source of the positive electrode or the negative electrode, the heating element 40 is evenly and stably generated from the applied power source.

In addition, when the heating element is to be made according to a specific voltage, the length of the conductive twisted yarn 47 is adjusted according to the voltage to be used to adjust the installation interval of the auxiliary power lines 43 and 43 '. . That is, in order to make a low voltage heating element, a plurality of auxiliary power lines 43 and 43 'are provided for the conductive twisted yarn 47 in consideration of the fact that the voltage drop occurs at a small resistance value due to the low supply voltage. By narrowing the gap and applying the voltage to be used, it is necessary to create an optimum gap of the power supply line that generates the best heat without destroying the insulation.

On the other hand, in order to make a high voltage heating element, the spacing of the auxiliary power lines 43 and 43 'with respect to the entire length of the conductive twisted yarn 47 may be arranged. At this time, the spacing of the auxiliary power lines 43, 43 'is to be made wider to the maximum distance that the voltage drop does not occur.

Such a foot wrapper of the present invention, the heating pad 30 formed on the foot wrap 10 is formed by dividing at least two or more with respect to the entire area of the foot wrap 10, each of the heating pad ( As the 30 is configured to be separately connected by the controller 20 described above, the power consumption of the power supply unit 26 can be greatly reduced through individual control of each of the heating pads 30.

That is, when the foot wrap 10 having the respective heating pads 30 divided as described above is used for the first time, power is supplied to all the heating pads 30 divided as described above for a set time. After the simultaneous heating is performed, when the set heat generation time ends, the power supply is cut off for all the heating pads 30, and at the same time, the power is individually applied or cut off for each of the heating pads 30 to generate all the heating pads 30. The heating pads 30 connected to the sequential heating or the designated object or set form repeatedly perform the heating operation and the stopping operation in turn.

Accordingly, since the initial heat is generated for the entire balsa 10 by supplying power to the entire heating pad 30 at the time of initial use, the rapid heating action is performed, and then the individual heating pads separated only for individually set time periods ( 30) Only the blinking sequentially can reduce the power consumption significantly. In this case, as the heating pad 30 blinks as described above, a temperature drop may occur in a short-circuit state of the power supply, but the heating pad 30 in the state embedded in the bale 10 is balsa 10 The warmth will be maintained for a predetermined time due to its thermal insulation and latent heat characteristics of the heating pad 30, so that the heating effect may be sufficiently obtained even if the heating pad 30 is sequentially flashed as described above.

Accordingly, when the power is applied to all of the heating pads 30 as described above, the power consumption of the rechargeable power supply unit 26 is large, so that the heating pads 30 may be used only for 3 to 4 hours. As the intermittent operation is sequentially performed, the usage time for the rechargeable power supply unit 26 is increased by two to three times or more. Therefore, more effective use can be made when a long time work or activity in the open air is required.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the present invention as defined by the appended claims. Examples should be understood.

1 is an overall configuration diagram of a balsa formed with a heating pad according to the present invention

Figure 2 is an overall view of the heating pad of the balsa according to the invention

Figure 3 is an enlarged cross-sectional view of the heating pad portion of the balsa according to the present invention.

Figure 4 is an enlarged cross-sectional view showing another embodiment of the heating pad portion of the balsa according to the present invention.

5 is another embodiment of the balsa according to the present invention

Figure 6 is another embodiment of the balsa according to the present invention

7 is a state diagram used in the balsae according to the present invention

8 is a controller configuration and connection diagram of a heating pad according to the present invention

9 is another embodiment of the heating element of the heating pad according to the present invention;

10 is another embodiment of the heating element of the heating pad according to the present invention;

FIG. 11 is a partially enlarged view of the heating element according to FIG. 10. FIG.

12 is a block diagram of an internal heating element of the heating pad according to the present invention;

FIG. 13 is an enlarged view of a portion “A” of the heating mesh of FIG. 12; FIG.

14 is another configuration diagram of the internal heating element of the heating pad according to the present invention;

FIG. 15 is an enlarged view of a portion “A” of the flexible heating wire according to FIG. 14.

16 is another configuration diagram of an internal heating element of the heating pad according to the present invention;

FIG. 17 is an enlarged view of a portion “A” of the conductive twisted yarn of FIG. 16. FIG.

18 is a diagram illustrating a separate control connection for a heating pad divided according to the present invention

Explanation of symbols on the main parts of the drawings

10: footwrap 11: shell

12: endothelial 13: pocket

14: pocket 15: elastic band

16: band fixture

20: controller 21: selection button

22: time setting section 23: temperature setting section

24: central processing unit 25: display unit

26: rechargeable power supply unit 27: AC adapter

30: heating pad 31: heat storage carrier

32: insulator 33: overheat cut off

40: heating element 41: conductive mesh

41a: core material 41b: conductive coating layer

41c: Insulation layer 42,42 ': Main power line

43,43 ': Auxiliary power cable 44: Flexible heating wire

44a: flexible core material 44b: conductive coil wire

44c: elastic insulation coating

45,45 ': Surface sheet 46: Adhesive sheet

47: conductive twisted yarn 47a: screening

47b: conductive layer 47c: insulating layer

Claims (21)

An upper portion of the foot wrapper 10 having an open pocket shape is formed on the upper side of the foot wrapper 10 by the elastic band 15 and the band stopper 10 opened by the band stopper 16. So that you can lose A separate heating pad 30 is formed on the bale 10 as described above, and the heating pad 30 is connected to the controller 20 having the rechargeable power supply unit 26, and the heating pad 30 is connected to the heating pad 30. Foot wrapper having a heating pad by a flexible heating element, characterized in that the power supply of the rechargeable power supply unit 26 is configured to be supplied to the heating pad (30) by the operation of the controller 20 exposed from the foot wrap having a. The method of claim 1, Foot wrapper 10 is made of the outer shell 11 and the inner shell 12 is sewn, and between the outer shell 11 and the inner shell 12, the heating pad 30 is characterized in that the flexible heating element characterized in that the configuration is configured Foot wrap with a heating pad. The method of claim 1, Foot wrapper having a heating pad by a flexible heating element, characterized in that by forming a separate pocket (13) on the inner surface of the foot wrapper 10 is configured to insert the heating pad (30) into the pocket (13). The method of claim 1, The foot wrapper 10 has a heating pad having a heating pad by a flexible heating element, characterized in that a separate pocket 14 is formed on an outer surface thereof so that the controller 20 exposed to the outside can be inserted and stored in the pocket 14. The method of claim 1, The heating pad 30 is formed of at least two or more divided parts with respect to the entire surface of the foot wrapper 10, and each of the heating pads 30 is connected in parallel by a plug jack and a socket structure that can be separated and connected to each other. , Foot pad having a heating pad by a flexible heating element, characterized in that the power generating pad 30 corresponding to the unnecessary position is configured to cut off the power consumption. The method of claim 1, The controller 20 has a time setting section 22 and a temperature setting section 23 which are variable by the selection button section 21, and is connected to the time setting section 22 and the temperature setting section 23. 24 has a set temperature and intermittent time to supply power to the heating pad 30, The display unit 25 connected to the central processing unit 24 allows the power to be applied, the set operating time, the set temperature, the remaining power, the voltage for the power source, and the state of charge. Rechargeable power supply unit 26 of the foot wrap having a heating pad by a flexible heating element, characterized in that configured to be supplied to the heating pad 30 through the central processing unit 24 by charging the power supplied from the AC adapter 27 . The method of claim 1, The heating pad 30 is a foot wrap having a heating pad by a flexible heating element, characterized in that the heating element 40 is built between the upper and lower surface sheets 45, 45 '. The method of claim 7, wherein The surface sheets 45 and 45 'are fused to each other by inserting the adhesive sheet 46 between the surface sheets 45 and 45' and fusion of the adhesive sheet 46 by heat pressing. Foot wrapper having a heating pad by a flexible heating element characterized in that. The method of claim 7, wherein Surface sheet 45 (45 ') is a foot wrapper having a heating pad by a flexible heating element, characterized in that consisting of one selected from neoprene (neoprene) or spandex (spandex). The method of claim 1, The heating pad 30 is a balsa wrapper having a heating pad by a flexible heating element, characterized in that the heating element 40 is built between the upper heat storage transfer member 31 and the lower heat insulator (32). The method of claim 10, The heat accumulator 31 is a foot wrapper having a heating pad by a flexible heating element, characterized in that the fabric is formed in close contact with the upper surface of the Techno thermo fabric. The method of claim 10, Insulator 32, foot wrappers having a heating pad by a flexible heating element, characterized in that composed of fiber glass silica pad (fiber glass silica pad). The method of claim 1, The heating pad 30 has a heat generating body 40 embedded between the top and bottom surface sheets 45 and 45 ′, and a heat storage carrier 31 is formed on the top surface of the top surface sheet 45. Foot wrapper having a heating pad by a flexible heating element, characterized in that the bottom surface of the lower surface sheet 45 'is formed by a heat insulator (32). The method according to any one of claims 7, 10 and 13, The heating element 40 is equally disposed between the main power lines 42 and 42 'and the main power lines 42 and 42' which are arranged side by side at both ends of the conductive mesh 41 in a lattice form. Comprised of auxiliary power lines 43, 43 'arranged at intervals, the main power lines 42, 42' and the auxiliary power lines 43, 43 'are connected so that different polarities are sequentially applied alternately. Foot wrapper having a heating pad by a flexible heating element, characterized in that configured. 15. The method of claim 14, The conductive mesh 41 forms a coating layer 41b made of a conductive composition in which liquid silicon rubber and carbon black are mixed on the surface of the core material 41a in the form of a lattice, and an insulating layer (on the surface of the coating layer 41b). A foot wrapper having a heating pad by a flexible heating element, which is formed by forming 41c). The method according to any one of claims 7, 10 and 13, The heating element 40 is disposed between the main power lines 42 and 42 'and the main power lines 42 and 42' which are arranged in parallel with each other at both ends of the flexible heating line 44 which are arranged side by side. Is composed of auxiliary power lines 43, 43 'evenly arranged in connection with the flexible heating line 41, and alternately with the main power lines 42, 42' and the auxiliary power lines 43, 43 '. Foot wrapper having a heating pad by a flexible heating element, characterized in that configured to connect so that different polarities are sequentially applied. The method of claim 16, The stretchable heating wire 44 winds and forms the conductive coil wire 44b on the surface of the stretchable core material 44a, and coats the stretchable insulating material 44c on the outer surface of the stretchable core material 44a and the conductive coil wire 44b. Foot wrapper having a heating pad by a flexible heating element, characterized in that made by. The method according to any one of claims 7, 10 and 13, The heating element 40 is formed by weaving the conductive twisted yarns 47 in a warp shape with the weft yarns, and on both sides of the woven conductive twisted yarns 47 side by side to connect the ends of the conductive twisted yarns 47 to each other. The auxiliary power supply line 43 disposed at equal intervals to form a contact with the conductive twisted yarn 47 between the main power supply lines 42 and 42 'and the main power supply lines 42 and 42'. (43 ') by the flexible heating element, characterized in that it is configured to connect different polarities sequentially applied to the main power line 42, 42' and the auxiliary power line (43, 43 ') in turn. Foot wrapper with heating pad. The method of claim 18, The conductive twisted yarn 47 forms a conductive layer 47b made of a conductive composition in which liquid silicone rubber and carbon black are mixed on the surface of the screening 47a in which glass fibers are joined, and the surface of the conductive layer 47b. The foot wrapper having a heating pad by a flexible heating element, characterized in that formed by forming an insulating layer (47c) of the liquid silicone rubber. The method according to any one of claims 7, 10 and 13, A heating wrapper having a heating pad by a flexible heating element, characterized in that the heating element (40) is equipped with an overheat blocking portion (33) by bimetal. The method of claim 1, The heating pads 30 are formed in a divided form on the entire surface of the foot wrapper 10, and each of the divided heating pads 30 is individually connected to each of the controllers 20, and the controller It is configured to extend the use time due to the reduction of power consumption for the rechargeable power supply unit 26 of the controller 20 as the intermittent power supply to each heating pad 30 through the individual control of the (20). Foot wrapper having a heating pad by a flexible heating element characterized in that.

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