KR102211435B1 - Far-infrared radiation drying equipment - Google Patents

Abstract

The present invention relates to a far-infrared radiation drying apparatus, and the present invention relates to a far-infrared radiation drying apparatus for drying an object to be dried by radiating heat and far-infrared rays using electric energy supplied from the outside. It relates to a far-infrared radiation drying apparatus that reduces the temperature deviation of the far-infrared radiation radiated by control.
The present invention is a cell-type heating element that generates heat using electric energy, a heat insulating element located on the rear surface of the heating element to prevent heat generated from the heat generating element from being dispersed to the rear or left and right surfaces of the heating element, Located on the rear surface of the heating element, the far-infrared radiation reflecting film for reflecting the far-infrared rays together with the heat emitted from the heating element to the front, and the heating element, the heat insulating element and the far-infrared radiation reflecting film are wrapped around the heat emitted from the heating element and There is a technical feature of the primary far-infrared radiation film that radiates the far-infrared rays forward together.

Description

Far-infrared radiation drying equipment

The present invention relates to a far-infrared radiation drying apparatus that radiates heat and far-infrared rays using electric energy supplied from the outside to dry an object to be dried, and a far-infrared ray reduces the temperature deviation of the radiated far-infrared rays by controlling power to each of the cylindrical heating cores. It relates to a spin drying device.

The present invention is one of the most important processes in the production process that is produced, manufactured, manufactured, and processed across all industries, such as clothing, food, fiber, paper, agricultural products, painting, wood, grain, electronic parts, and drying for home appliances. It relates to the device.

Currently, the most commonly used drying device is a steam-type heating drying method using a boiler. Except for special drying, the energy source is mainly oil, and in addition, electricity and gas have been used as energy sources. These steam-type heating and drying methods incur enormous energy costs such as oil, electricity, and gas used as energy sources, and boiler facilities (compressors, air pipes, steam pipes, ductors, water pipes, water tanks, etc.) are installed or The equipment to which the device is attached has been used to dry the object for a long time.

1) Drying time has been taking a long time along with energy consumption,

2) It was not possible to freely adjust the moisture content desired for the moisture content.

3) Uniform and uniform drying of the object to be dried is impossible.

4) The material was frequently damaged, nutrients were destroyed, and

5) Difficulty sterilization treatment of dry matter, which leads to easily decay

6) There was a problem that uniform drying was difficult due to the variation in heating temperature.

In order to improve the above problems, infrared drying and far-infrared drying devices have been developed, but the energy source of most far-infrared drying devices uses oil to dry using a boiler, but as an auxiliary device, an auxiliary means only irradiating far-infrared rays with a low actual emissivity. The drying device of has been used.

In addition, a far-infrared drying device using only electricity was also developed, but the drying time as well as damage to the object to be dried and the destruction of nutrients was not significantly different compared to the conventional steam heating drying method, so there was no effect. There was a problem.

In Korea Patent Publication (2011-0094362) "Far Infrared Radiation Device", as shown in Fig. 11, it is a far-infrared radiating device that radiates far-infrared rays to an object to be heated using four planar heating elements. Compared with the past two planar heating elements, the temperature Although the deviation is small, there is still a temperature deviation of about 5 ~ 8℃, and it takes a long time to reach the drying temperature, resulting in a problem of lowering energy efficiency.

The present invention devised to solve the problems of the prior art as described above has an object to increase the drying effect by using less energy source.

In addition, there is an object of reducing the drying time and drying the object to be dried evenly.

In addition, there is an object to precisely control the temperature by controlling each of the heating elements.

In addition, there is an object to make the distribution of temperature heat generation uniform and to freely divide the heat concentration structure of a desired portion of the heating element.

The above object of the present invention is a cell-type heating element that generates heat using electric energy, and is located on the rear surface of the heating element to prevent heat generated from the heating element from being dispersed to the rear or left and right surfaces of the heating element. The heat insulation structure, located on the rear side of the heating structure, surrounds the far-infrared radiation reflective film and the heating structure, the heat insulation structure and the far-infrared radiation reflective film for reflecting the far-infrared rays together with the heat emitted from the heating structure to the front, and from the heating structure It is achieved by a primary far-infrared radiation film that radiates the far-infrared rays forward together with the emitted heat.

Therefore, since the present invention uses electricity as a heat source, there is an effect of reducing CO2 emissions compared to a drying apparatus using oil, gas, or the like as a heat source.

In addition, since the object to be dried can be quickly reached to an appropriate temperature for drying, there is an effect of shortening the drying time and saving energy.

In addition, since each heating element can be divided and controlled, there is an effect of increasing drying efficiency by intensively radiating heat to a desired portion of the object to be dried.

1 is a far-infrared radiation drying apparatus according to the present invention,
Figure 2 is a configuration diagram of a far-infrared primary radiation structure according to the present invention,
Figure 3 is an exploded perspective view of the far-infrared primary radiation structure according to the present invention,
Figure 4 is a configuration diagram of a heating element according to the present invention,
5 is a side view and a plan view of the heating heat core according to the present invention,
6 is an exploded perspective view of the heating element according to the present invention,
7 is an exemplary diagram of a 16-point division and an 8-point division of the heating heat core according to the present invention,
8 is an exemplary diagram of a 4-point division and 2-point division of a heating heat core according to the present invention,
9 is a conventional two-sided heating element and temperature measurement points,
10 is a temperature distribution table of temperature measurement points for each time of a conventional two-sided heating element,
11 is a conventional four-sided heating element and temperature measurement points,
12 is a temperature distribution table of temperature measurement points by time of a conventional four-sided heating element,
13 is a CELL type heating element and temperature measurement point of the present invention,
14 is a temperature distribution table of temperature measurement points for each time of the cell type heating element of the present invention,
15 is a table showing the temperature deviation of each heating element and a time table for reaching an appropriate temperature.

The terms or words used in the specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventor may appropriately define the concept of terms in order to describe his own invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention based on the principle that there is.

Accordingly, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all the technical spirit of the present invention, and thus various alternatives that can be used at the time of application It should be understood that there may be equivalents and variations.

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

1 is a far-infrared radiation drying apparatus according to the present invention. As shown in Fig. 1, the far-infrared radiation drying apparatus 10 has an inner space and is installed inside the body 100 and the body 100 having a rectangular box shape, and heat and far-infrared rays using electric energy supplied from the outside. In order to radiate the heat and far-infrared rays passing through the far-infrared primary radiation structure 200 and the far-infrared primary radiation structure 200 uniformly to the object to be dried, the heat distribution hole 2 is a structure that expands while downward at regular intervals. It consists of a dimensional infrared radiation film (300).

Further, the body 100 of the far-infrared radiation drying apparatus 10 further includes a blowing fan, an exhaust fan, and a cooling fan, not shown.

2 is a block diagram of a far-infrared radiation structure according to the present invention. As shown in FIG. 2, the far-infrared radiation component 200 is located at the rear of the cell-type heating component 220 that generates heat using electric energy and the heat generated by the heating component 220. Insulation component 240 to prevent dispersion to the rear or left and right sides of the heating component 220, located at the rear of the heating component 220, to reflect the far infrared rays together with the heat emitted from the heating component 220 to the front For the far-infrared radiation reflective film 250 and the heating element 220, the heat insulating element 240 and the far-infrared radiation reflective film 250 is wrapped and radiates the far-infrared rays forward together with the heat emitted from the heating element 220 ( 210).

3 is an exploded perspective view of a far-infrared radiation structure according to the present invention. As shown in Fig. 3, the heating element 220, the heat insulating element 240, the far-infrared radiation reflective film 250, and the heat insulating element 240 are formed by overlapping, and a primary far-infrared radiation film 210 is covered thereon. In addition, a rear cover 260 is located on the rear surface of the heat insulating component 240 located at the bottom of the far-infrared radiation reflective film 250 and a cooling duct 280 is located behind it. And, between the rear structure cover 260 and the cooling duct 280, an electric leakage insulation material 270 for blocking electric leakage is positioned.

4 is a configuration diagram of a heating element according to the present invention. As shown in FIG. 4, the CELL-type heating element 220 has at least one cylindrical heating heat core 221 that generates heat, and an electrical connection that supplies power to the heating heat core 221 using external electric energy. Terminal 230, the heating heat upper cover 222, which is located on the upper end of the heating heating core 221, made of mica or asbestos, and the heating heating intermediate cover 223 having at least one hole through which a cylindrical heating heating core can be inserted. ) And located at the bottom of the heating heat intermediate cover 223, and composed of a cover 224 under the heating heat made of mica or asbestos.

5 is a side view and a plan view of a heating heat core according to the present invention. As shown in FIG. 5, the heating heat core 221 has a cylindrical shape, and a nichrome wire 400 is wound in the horizontal or vertical direction around the heating heat core 221.

In addition, the nichrome wire 400 wound around the heating heat core 221 is a nichrome wire 400 adjacent to the nichrome wire 400 wound around the heating heat core 221 according to the position where the heating heat core 221 is disposed. The spacing of is equal or reduced.

6 is an exploded perspective view of a heating element according to the present invention. As shown in FIG. 6, the heating element 220 has a cylindrical heating heating core 221 that generates heat using external electric energy and a heating heating core upper cover 222 surrounding the heating heating core 221. ), a heat generating heat core middle cover 223 and a heat generating heat core cover underneath.

In addition, the cylindrical heat generating heat core 220 has a parallel structure in a plurality of horizontal and vertical plurality, and preferably, a parallel structure of four horizontally and four vertically is preferable.

Power can be controlled to each of the 16 heating heating cores 220, and the heating heating core 220 has a nichrome wire 400 wound in any one or more of a horizontal direction or a vertical direction, and the heating element 220 It is more preferable that the distance between the nichrome wires 400 adjacent to each other is the same or variably narrower than the same distance as the distance from the center to the outer shell increases.

Alternatively, in the cylindrical heating heat core 221, the nichrome wire 400 is wound in one or more of a horizontal direction or a vertical direction, and the neighboring nichrome wire 400 is further away from the center of the heating element 220 to the outer shell. ) Has the characteristic that the spacing between them is the same or variably wider than the same spacing.

In addition, although the shape of the heating heat core 221 is preferably a cylindrical shape, it may be configured in various shapes such as a square pillar and a pentagonal pillar.

7 is an exemplary diagram of a 16-point division and an 8-point division of the heating core according to the present invention. As shown in FIG. 7, the heating heat core 221 can be separated into 16 points and controlled, (a) is a layout diagram of the heating heat core, and (b) is a heating heat core 221 in a 16-point division method. Is divided, and (c) and (d) is a method of dividing the heating heat core 221 into 8 points.

8 is an exemplary diagram of a 4-point division and a 2-point division of the heating core according to the present invention. As shown in FIG. 8, (a) is a method in which the heating heat core 221 is divided by 4 points, and (b) and (c) is a method in which the heating heat core 221 is divided by 2 points. As described above, in the present invention, the heating heat cores 221 are arranged by 4 horizontally and 4 vertically and divided into 2 points, 4 points, 8 points, and 16 points to control the temperature, thereby enabling precise control.

9 is a conventional two-sided planar heating element and temperature measurement points, and FIG. 10 is a temperature distribution table of a temperature measurement point by time of a conventional two-sided planar heating element. In the case of the two-sided planar heating element of the conventional far-infrared ray drying device as shown in FIG. 9, the temperature measurement points are measured at 5 minutes, 15, 25 minutes, 35 minutes, and 1 hour 35 minutes, respectively, in FIG. Appears as As shown in Fig. 10, when the appropriate drying temperature is 135 to 145°C, in the case of the two-sided planar heating element structure, the drying temperature reached the appropriate drying temperature after 1 hour and 35 minutes, but the minimum temperature between the temperature measurement points was 131 ℃, and the maximum temperature was 147 ℃ in zone 2.

11 is a conventional four-sided planar heating element and temperature measurement points, and FIG. 12 is a temperature distribution table of a temperature measurement point by time of a conventional four-sided planar heating element. In the case of the four-sided planar heating element of the conventional far-infrared ray drying apparatus as shown in FIG. 11, the temperature measurement points are measured at 5 minutes, 15, 25 minutes, 35 minutes, and 1 hour 35 minutes, respectively, in FIG. Appears as As shown in Fig. 12, when the appropriate drying temperature is 135 to 145°C, in the case of the four-sided heating element structure, the drying temperature reached the appropriate drying temperature after 1 hour and 35 minutes, but the minimum temperature between the temperature measurement points was 131 ℃, and the maximum temperature was 137℃ in zone 1 and zone 2.

13 is a CELL-type heating element and temperature measurement points of the present invention, and FIG. 14 is a temperature distribution table of a temperature measurement point by time of the CELL-type heating element of the present invention. In the case of the CELL type heating element of the present invention as shown in FIG. 13, when the temperature is measured at 5 minutes, 15, 25 minutes, 35 minutes, and 1 hour at the temperature measurement point, it appears as in FIG. 14. As shown in Fig. 14, when the appropriate drying temperature is 135 to 145°C, in the case of the cell type heating element of the present invention, the appropriate drying temperature was reached in 1 hour, and the minimum temperature between the temperature measurement points was in zones 2 and 7 It was 142℃, and the maximum temperature was 145℃ in Zone 5.

15 is a table showing temperature deviations of each heating element and a time table for reaching an appropriate temperature. As shown in FIG. 15, in the case of the conventional two-sided planar heating element, the time required to reach the appropriate temperature was 1 hour and 35 minutes, and the temperature deviation was large, ranging from 6 to 16°C. And, in the case of the conventional four-sided planar heating element, the time required to reach the appropriate temperature was 1 hour and 35 minutes, and the temperature deviation was 5 to 8°C. Although the deviation between the minimum and maximum temperatures in the temperature measurement section was small, it took a long time to reach the appropriate temperature. On the other hand, in the case of the CELL type heating element according to the present invention, the appropriate temperature was reached in 1 hour, and the temperature deviation of the temperature measurement area was also the least, at 3 to 5°C.

Although the present invention has been shown and described with a preferred embodiment as described above, it is not limited to the above-described embodiment, and within the scope of the spirit of the present invention, to those of ordinary skill in the art. Various changes and modifications will be possible.

10: far-infrared radiation drying device 100: body
200: far-infrared radiation construct 300: secondary far-infrared radiation film
210: primary far-infrared radiation film 220: heating element
221: heating heat core 222: heating heat top cover
223: middle cover of heating heat 224: cover under heating heat
230: electrical connection terminal 240: insulation structure
245: insulation gasket 250: far-infrared radiation reflective film
260: rear structure cover 270: electrical leakage insulation material
280: cooling duct 400: nichrome wire

Claims (10)

A heating element that generates heat using electric energy;
A heat insulating structure located on the rear surface of the heating element;
In the far-infrared radiation structure of a far-infrared radiation drying apparatus for drying an object to be dried through far-infrared radiation including a far-infrared radiation reflecting film for reflecting the far-infrared radiation together with the heat emitted from the heating element,
The far-infrared radiation component
CELL type heating element;
A heat insulation component located on the rear surface of the heating component to prevent heat generated by the heating component from being dispersed to the rear surface or left and right surfaces of the heating component;
A far-infrared radiation reflective film located on the rear surface of the heating element and configured to reflect far-infrared rays to the front surface together with the heat emitted from the heating element; And
Comprising a primary far-infrared radiation film surrounding the heating element, the heat insulating element, and the far-infrared radiation reflective film, and radiating the far-infrared rays forward together with heat emitted from the heating element,
The CELL-type heating element includes one or more cylindrical heating heat cores generating heat;
An electrical connection terminal for supplying power to the heating heat core using external electrical energy;
It is located on the upper end of the heating heat core, the heating heat top cover made of mica or asbestos;
A heating heat intermediate cover having at least one hole through which the cylindrical heating heat core can be inserted; And
It is located at the lower end of the middle cover of the heating heat, and includes a cover under the heating heat made of mica or asbestos,
In the cylindrical heating heat core, the nichrome wire is wound in one or more of a horizontal direction or a vertical direction,
The cylindrical heating heating core is a far-infrared radiation drying apparatus, characterized in that it is capable of controlling power to each of the cylindrical heating heating cores
The method of claim 1,
The far-infrared radiation component
A cooling duct for cooling heat transferred to an inner wall surface of the far-infrared radiation drying device on the rear surface of the heating element;
Electrical leakage insulating material for blocking electrical leakage between the heating element and the cooling duct
Far-infrared radiation drying apparatus comprising a further comprising.
delete The method of claim 1,
The cylindrical heating heat core has a parallel structure in a plurality of horizontally and vertically, and a far-infrared radiation drying apparatus capable of controlling power to each of the cylindrical heating heating cores.
The method of claim 4,
When the heat generating heat core has a parallel structure of 4 horizontally and 4 vertically, a power supply is connected to one heating heating core by one contact, and power is controlled by dividing it into 16 points.
The method of claim 4,
When the heat generating heat core has a parallel structure of 4 horizontally and 4 vertically, a power source is connected to two heating heat cores by one contact and divided into 8 points to control power.
The method of claim 4,
When the heat generating heat core has a parallel structure of 4 horizontally and 4 vertically, a power supply is connected to each of the four heating cores by one contact, and power control is possible by dividing it into 4 points.
The method of claim 4,
When the heat generating heat cores have a parallel structure of 4 horizontally and 4 vertically, a power supply is connected to each of the eight heating heating cores by one contact, and power is controlled by dividing it into two points.
The method of claim 1,
The cylindrical heating heat core is far-infrared radiation, characterized in that the distance between the adjacent nichrome wires is the same or variably narrower than the same distance as the distance from the center of the heating element to the outside Drying device.
The method of claim 1,
The cylindrical heating heat core is far-infrared radiation, characterized in that the distance between the nichrome wires adjacent to each other is the same or variably wider than the same distance as the distance from the center of the heating element increases Drying device.

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