KR200448667Y1 - heater - Google Patents

Abstract

The present invention is a high heat efficiency and does not require a preheating time, and relates to a heater device that allows the heater device to operate normally stably by preventing the coil-like heating element from expanding due to heat generation and falling down. The heater device according to the present invention is at least one heating element made of a coil form; A heating element driver supplying driving power to the heating element; An apparatus driver for driving a motor to generate a rotational force; Mechanism unit for connecting any one side of the both ends of the heating element and the rotary shaft of the mechanism drive unit; And a control module for controlling the heating element driving unit and the mechanism driving unit to operate in conjunction with each other, so that the heating element is rotated at the same time as the heating element so as to prevent the heating element from sagging even if the heating element is expanded by the heating.

Heating element, rotation

Description

Heater device

The present invention relates to a heater device, and more particularly to a heater device that prevents the heating element from sagging downward even if it is expanded by heat.

An air curtain device is mainly installed in an entrance door, and the air curtain device discharges air in the front vertical direction of the entrance to form a blocking film that blocks the interior and the outside as air, thereby maintaining the indoor temperature even when the door is opened. It can be kept constant and prevents heat loss caused by intrusion of outside air due to opening and closing of the door.

The air curtain device is suitable for a place where a lot of people go in and out of the cooling and heating effect, and effectively prevents dust, insects, odors, etc. from entering the interior.

The air curtain device is used to install a lot in the door of the place, such as banks, restaurants. The air curtain device uses a heater therein, and heat generated from the heater is converted into hot air by the operation of the motor and discharged to the outside.

1A and 1B are photographs and internal structure diagrams of a heater widely used in an air curtain apparatus according to the related art. The conventional heater 10 shown in FIG. 1 is disposed in the support pipe 16, the power terminals 14 and 22 connected to both ends of the support pipe 16, and the support pipe 16. Nichrome wire 18 for dissipating heat, magnesium oxide 20 filling the inside of the support pipe 16 on which the nichrome wire 18 is disposed, and a heat dissipation fin surrounding the outer circumferential surface of the support pipe 16 in a coil form ( 22). Referring to the operation of the conventional heater having the above-described structure, when power is supplied through the power supply terminals 14 and 22, the nichrome wire 18 in the support pipe 16 generates heat, and the nichrome wire 18 Heat generated from the heat is sequentially transferred to the magnesium oxide 20, the support pipe 16, and the heat dissipation fin 22, thereby finally generating heat. At this time, the heat emitted from the heat radiation fins 22 is converted into hot air by a blowing fan or the like and transmitted to the outside.

The conventional heater operating as described above has a complicated structure. In addition, since the conventional heater has a plurality of heat transfer media for transferring heat from the nichrome wire, which is a heating element, preheating is required until the temperature of the heat radiating fin, which is the final heat transfer medium, becomes hot enough to generate hot air. This is a problem that takes a lot. In addition, the conventional heater has a problem that the motor must be further driven for a certain time to completely remove the latent heat of the heat transfer medium and the heat radiation fin even after the operation is completed.

The present invention is to solve the above-mentioned problems of the prior art, the heating element is directly exposed to the air to increase the thermal efficiency and at the same time shorten the preheating and cooling time, the heating element is heated at the same time and rotates the heating element It is an object of the present invention to provide a heater device that enables the heater device to operate normally stably by preventing the heating element from sagging downward even when the heat is expanded by heat generation.

The heater device according to the present invention is at least one heating element made of a coil form; A heating element driver supplying driving power to the heating element; An apparatus driver for driving a motor to generate a rotational force; Mechanism unit for connecting any one side of the both ends of the heating element and the rotary shaft of the mechanism drive unit; And a control module for controlling the heating element driving unit and the mechanism driving unit to operate in conjunction with each other, wherein the heating element is rotated at the same time as the heating element so as to prevent the heating element from sagging even if the heating element is expanded by the heating.

The present invention is configured so that the heating element is directly exposed to the air to increase the thermal efficiency and at the same time to shorten the preheating and cooling time, and the heating element is heated and rotates at the same time so that the heating element is not stretched to the lower side even if the heating element is expanded by the heating. As a result, the heater device can be stably operated normally.

The present invention is configured so that the heating element is directly exposed to the air to increase the thermal efficiency and at the same time to shorten the preheating and cooling time, and the heating element is heated and rotates at the same time so that the heating element is not stretched to the lower side even if the heating element is expanded by the heating. This allows the heater unit to operate stably in normal operation.

The configuration of the heater device according to the preferred embodiment of the present invention described above will be described in detail with reference to FIG. 2.

The heater device includes a control module 100, a user interface unit 102, a heating element driving unit 104, a heating element 106, a mechanism driving unit 108, and a mechanism unit 110.

The control module 100 provides the heating unit driving unit 104 with the heating element driving unit 104 or the driving stop command at the same time as the user operation through the user interface unit 102, and provides the driving or driving stop command to the mechanical drive unit 108. . That is, the control module 100 controls the heating element driver 104 and the mechanism driver 108 to be interlocked.

The user interface unit 102 includes keys for commanding on or off, and provides a signal according to the key input to the control module 100.

The heating element driving unit 104 supplies driving power to the heating element 106 according to a control command of the control module 100, or stops driving by blocking the supply of driving power to the heating element 106.

The heating element 106 generates heat when driving power is supplied from the heating element driver 104.

The mechanism unit 110 supports both ends of the heating element 106, and connects the rotary shaft of the instrument driving unit 108 with the heating element 106.

The instrument driving unit 108 is provided with a motor to drive the motor under the control of the control module 100, the one end of the rotary shaft of the motor and the heating element 106 is connected through the mechanism unit 110 Accordingly, the heating element 106 is rotated by the rotational force of the motor.

The structure of the heating element 106 and the mechanism unit 110 will be described further with reference to FIG. 3.

The heating element 106 is embedded in the outer housing A of the heater device, and at both ends of the heating element 106 supports the heating element 106 and is connected to the outer housing A and the mechanism driver 108. The first and second connecting members (B1, B2) are provided for.

The first connection member B1 connects the rotary shaft of the mechanism driving unit 108 and one end of the heating element 106. The second connection member B2 connects the other end of the heating element 106 to the connection groove C of the outer housing A.

When the rotating shaft of the motor rotates according to the driving of the mechanism driving unit 108, a rotational force is also applied to the heating element 106 by the first connection part B1 connected to the rotating shaft, thereby driving the driving mechanism 108. Accordingly, the heating element 106 is rotated.

The heating element 106 is connected to a nichrome wire in the form of a coil, and emits heat when power is applied from the outside through the power supply terminal.

Generally, the heating element mainly uses nichrome wire. The nichrome wire is an alloy containing about 15 to 20% of chromium in nickel, and is mainly used as a heating wire to generate heat when electricity is applied, and the electrical resistivity is 95 to 120 μm. Cm. In other words, the electrical resistivity is a resistance value generated by the material itself when the current is energized, and the larger the resistance, the higher the amount of heat. The nichrome wire having such a property is a very excellent material.

4 is a perspective view showing the heat generator 106 separately according to the present invention. As shown in FIG. 4, the shape of the coil of the heating element 106 according to the present invention is preferably wound repeatedly in a polygonal shape in which corners and angles exist, such as a triangle. By constructing the shape of the coil of the heating element 106 of the present invention in a polygon, it is possible to have a force by the shape of the coil, as a result it is possible to prevent the phenomenon that the coil is drooping and fall.

On the other hand, Figure 5 is a perspective view showing another embodiment of the heating element 106 according to the present invention by way of example. As shown in FIG. 5, the coil may be configured in a circular shape.

The nichrome wire material used as the heating element has a problem that the wire diameter becomes thin and broken when it is used for a long time by oxidation with oxygen in the atmosphere in a hotly heated state. In order to solve the problem of the heating element, the heating element according to the present invention is coated on the surface, thereby preventing the oxidation phenomenon of the nichrome wire constituting the heating element and to achieve electrical insulation. The heating element according to a preferred embodiment of the present invention is heat-treated at 1200 ℃ for about 3 hours, thereby forming a film formed of a predetermined material on the surface.

The operation of the heater device according to the preferred embodiment of the present invention described above will be described.

The control module 100 of the heater device provides a driving command to the heating element driving unit 104 and the mechanism driving unit 108 when an on command is input through the user interface unit 102. The heating element driver 104 supplies driving power to the heating element 106 under the control of the control module 100, and the instrument driving unit 108 drives the motor under the control of the control module 100.

Accordingly, the heating element 106 rotates while performing heat generation, and continues to rotate even when the heating element 106 is expanded by heat, so that the expanded heating element 106 does not sag downward.

On the other hand, the control module 100 of the heater device provides a driving stop command to the heating element driving unit 104 and the mechanism driving unit 108 when the OFF command is input through the user interface unit 102. The heating element driving unit 104 cuts off the supply of driving power to the heating element 106 under the control of the control module 1000, and the mechanism driving unit 108 stops driving the motor to rotate the heating element 106. Stop.

The heater device according to the preferred embodiment of the present invention described above is employed as a heater of the air curtain device.

In addition, in the above-described preferred embodiment of the present invention, only one heating element is illustrated, but the heating element may be provided with one or more. In this case, a plurality of gears and the like are further provided to provide rotational force to each heating element.

The present invention has been described above with reference to preferred embodiments thereof, but this is merely an example and is not intended to limit the present invention, and those skilled in the art to which the present invention belongs do not depart from the essential characteristics of the present invention. It will be appreciated that various modifications not illustrated above are possible in the scope. And differences related to such modifications and applications will have to be construed as being included in the scope of the invention as defined in the appended claims.

1 is a block diagram of a heater device according to the prior art.

2 is a block diagram of a heater device according to a preferred embodiment of the present invention.

3 is a structural diagram of a mechanism and a heating unit according to a preferred embodiment of the present invention.

4 and 5 is a detailed structural diagram of a heat generating unit according to a preferred embodiment of the present invention.

Claims (5)

One or more heating elements formed in a coil form; A heating element driver supplying driving power to the heating element; An apparatus driver for driving a motor to generate a rotational force; Mechanism unit for connecting any one side of the both ends of the heating element and the rotary shaft of the mechanism drive unit; Control module for controlling the heating element drive unit and the mechanism drive unit to operate in conjunction Including, the heater is generated and rotates at the same time the heater is characterized in that the heating element is not stretched down even if the heating element is expanded by the heat. The heater device according to claim 1, wherein the coil shape of the heating element is repeated in a polygonal shape. The heater device according to claim 1, wherein the coil shape of the heating element is repeated in a circular shape. The heater apparatus according to claim 1, wherein the heating element is heat-treated for a predetermined time at a temperature of 1000 ° C. or more. The heater device according to any one of claims 1 to 4, wherein the heater device is used as a heater of an air curtain device.

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