KR20230143107A - Wood dryer - Google Patents

Abstract

The present invention relates to a wood dryer, and more specifically, to form a standing wave by combining electromagnetic waves transmitted from an electromagnetic wave generator installed inside the drying chamber with a reflected wave generated by hitting a diffuser installed on the wall of the drying chamber, and generated by the standing wave. It relates to a wood dryer that removes moisture inside wood transported by a transfer means using heat.
According to the present invention, heat transfer is carried out evenly within the drying chamber, so that there is no difference in the drying state of the outside and inside of the wood, so that sparks or discharges do not occur in the wood during the drying process, and the wood is dried in a relatively short period of time, Deformation or damage can be reduced, and by installing an electromagnetic wave blocking unit to block electromagnetic waves from being emitted to the outside, it can provide the effect of minimizing the impact of electromagnetic waves on the human body of the drying process manager.

Description

Wood dryer{WOOD DRYER}

The present invention relates to a wood dryer, and more specifically, to form a standing wave by combining electromagnetic waves transmitted from an electromagnetic wave generator installed inside the drying chamber with a reflected wave generated by hitting a diffuser installed on the wall of the drying chamber, and generated by the standing wave. It relates to a wood dryer that removes moisture inside wood transported by a transfer means using heat.

In general, the moisture content of logs varies depending on the type of log and seasonal conditions at the time of cutting, but contains approximately 28 to 60% moisture. If a product is made using raw wood, the product will deform over time. Therefore, in order to use these logs for construction or furniture, etc., they must be dried.

Wood drying methods include natural drying and heat drying. Natural drying is a method of stacking wood in a drying area and drying it using atmospheric temperature, humidity, and wind. The facility cost is low and the work is relatively simple, but the drying time is high. It has the disadvantage of requiring a long time and a large drying area, and cannot be dried below the air moisture content.

On the other hand, hot air drying is a method of drying by artificially controlling drying conditions such as temperature, humidity, and wind speed in the drying room. It has the advantage of relatively short drying time and the ability to dry below the air moisture content.

Hot air drying heats the medium called air and dries the heated air through convection conduction, which transfers heat from the surface of the object to be dried, resulting in waste of energy due to surface heating and outflow of high-temperature air. In addition, when wood is dried using such a hot air drying device, the surface of the wood may crack due to the characteristics of the wood, or differences in drying conditions on the outside and inside of the wood may occur due to differences in heat transfer.

Moreover, as the thickness or diameter of the wood to be dried increases, drying becomes more difficult and severe drying defects occur during drying, lowering the yield. Immature wood containing moisture has very poor mechanical properties and is easily destroyed by drying stress generated during drying. In order to completely dry the inside of the wood, if it is dried by heat for a long period of time, the exterior of the wood will deform. There are problems such as this, and when dried with heat at a temperature low enough to not damage the exterior of the wood, it takes a lot of time for drying, and the treatment ability is significantly reduced.

In order to solve the above-described problem, the present invention attaches a diffuser made of aluminum or stainless steel inside the drying chamber, and the electromagnetic waves transmitted by the electromagnetic wave generator installed inside the drying chamber are reflected on the diffuser and have a small number of independent functions. The purpose is to provide a wood dryer that generates a reflected wave with a phase difference, forms a standing wave as the incident wave and the reflected wave with the phase difference travel without interfering with each other, and heat generated by the standing wave removes moisture inside the wood.

The present invention is a wood dryer that removes moisture contained within wood using heat generated by applying electromagnetic waves to wood (2), and includes a drying chamber (10) having an internal space for drying the wood (2) while transporting it. )and; an electromagnetic wave blocking unit 20 installed at the inlet or outlet of the drying chamber 10; A transfer means (30) installed to pass through the drying chamber (10) and the electromagnetic wave blocking unit (20) and consisting of one of a transfer roller or a conveyor belt to move the wood (2); a control device 40 that controls the drying chamber environment by inputting information about the wood 2; It includes a power supply unit 50 that supplies power to the drying chamber 10.

The drying chamber 10 includes an electromagnetic wave generator 11 installed inside the drying chamber 10 to transmit electromagnetic waves; One or more diffusers (12) installed on the wall of the drying chamber (10); a dielectric tube (13) installed inside the drying chamber (10) along the moving direction of the wood (2); a resistance value measurement pin 14 installed inside the drying chamber 10 to measure the electrical resistance inside the wood 2; It includes a ventilation device 15 installed outside the drying chamber 10 to discharge moisture generated inside the drying chamber 10 to the outside.

The electromagnetic wave blocking unit 20 includes an external lining 21 made of metal; an inner lining (22) installed inside the outer lining (21) and made of plastic; a water supply unit (23) for injecting water into the water circulation space (25) formed between the outer lining (21) and the inner lining (22); It includes a water discharge unit 24 that discharges water introduced into the water circulation space 25 to the outside, and the water circulating in the water circulation space 25 is formed in the inner space of the inner lining 22. It is characterized by blocking electromagnetic waves from being emitted to the outside.

The control device 40 includes an input unit 41 for inputting one or more information among the species, shape, moisture content, and movement speed of the wood 2; a memory 42 that stores information input to the input unit 41; an output unit 44 that displays information about the drying process of the wood 2; and a control unit 43 that controls to perform a drying process for the wood 2 based on the information input to the input unit 41, wherein the control unit 43 allows the task manager to use the input unit 41. The drying chamber environment is controlled according to the information about the wood 2 input through the drying chamber environment.

The diffuser 12 is made of either aluminum or stainless steel, and has a constant cross-sectional shape in the longitudinal direction, but is composed of a stepped structure that gradually lowers from the center at the highest height to the left and right, and the electromagnetic wave generator It is characterized in that the electromagnetic wave transmitted in (11) is reflected by hitting the diffuser 12, and the wavelength of the reflected wave forms a standing wave.

The diffuser 12 is installed one or more times on the wall of the drying chamber 10, and when installed at a corner, a diagonal plate is installed and attached thereto to eliminate mirror effect.

The ratio of the height of each staircase included in the staircase structure is characterized in that it is expressed as a sequence of decimal numbers.

The standing wave is an electromagnetic wave created by combining an electromagnetic wave transmitted from the electromagnetic wave generator 11 and a reflected wave generated when the electromagnetic wave hits the diffuser 12, and the standing wave heats the water molecules inside the wood 2. It is characterized in that it generates heat to remove moisture contained in the wood (2).

The resistance value measurement pin 14 measures the electrical resistance value of the wood 2 by directly contacting the wood 2 when installed inside the drying chamber 10, and the control device ( 40) calculates the moisture content of the wood 2 from the resistance value of the wood 2, and automatically controls the drying chamber 10 according to the moisture content, where the moisture content of the wood 2 is It is characterized by controlling to increase the output of electromagnetic waves when it is higher than the set value, and to lower the output of electromagnetic waves when the moisture content is lower than the set value.

The dielectric tube 13 has a cross-sectional shape of a square, an octagon, a circle, or an oval along the same longitudinal direction as the moving direction of the wood 2, and is installed inside the drying chamber 10 and transported to the internal space. It is characterized in that it allows the wood (2) to move as the means (30) passes through it, and blocks moisture and foreign substances generated during wood drying from directly contacting the diffuser (12).

The electromagnetic wave blocking unit 20 is installed at the entrance or exit of the drying chamber 10 and includes a sliding door 26 for blocking electromagnetic waves from being emitted to the outside. It is characterized in that it opens by moving up and down in proportion to the size of the wood (2) passing through the inlet or outlet.

According to the present invention as described above, moisture contained inside the wood transported by the transport means installed inside the drying chamber can be removed with heat generated by standing waves, and heat transfer is uniformly transmitted within the drying chamber to the outside of the wood. Since there is no difference in the drying state inside the wood, sparks or discharges do not occur in the wood during the drying process, and the wood can be dried in a relatively short time, providing the effect of reducing deformation or damage to the wood.

In addition, the present invention provides the effect of installing an electromagnetic wave blocking unit at the entrance or exit of the drying chamber to block electromagnetic waves from being emitted to the outside, thus minimizing the impact of electromagnetic waves on the human body of the manager working in the drying process.

Figure 1 is a diagram showing the overall structure of the wood dryer of the present invention.
Figure 2 is a perspective view of the wood dryer of the present invention.
Figure 3 is a perspective view of a drying chamber of the present invention.
Figure 4 is a cross-sectional view of the drying chamber of the present invention.
Figure 5 is a diagram showing a resistance value measuring pin for measuring the electrical resistance of wood moving in a drying chamber of the present invention.
Figure 6 is a diagram showing an example of installation of the diffuser of the present invention.
Figure 7 is a diagram showing electromagnetic wave reflection between the electromagnetic wave generator and the diffuser of the present invention.
Figure 8 is a diagram showing the generation of standing waves due to electromagnetic wave reflection by a plurality of diffusers.
Figure 9 is a perspective view of the electromagnetic wave blocking unit of the present invention.
Figure 10 is a cross-sectional view of the electromagnetic wave blocking unit of the present invention.
Figure 11 is a diagram showing the operation of the sliding door of the electromagnetic wave blocking unit of the present invention.
Figure 12 is a block diagram showing the configuration of the wood dryer of the present invention.

Hereinafter, the wood dryer of the present invention will be described in more detail with reference to the accompanying drawings showing preferred embodiments of the present invention. However, it should be understood that the invention may be implemented in many different forms and is not limited to the described embodiments.

1 is a view showing the overall structure of the wood dryer of the present invention, FIG. 2 is a perspective view of the wood dryer of the present invention, FIG. 3 is a perspective view of the drying chamber of the present invention, FIG. 4 is a cross-sectional view of the drying chamber of the present invention, FIG. 5 is a diagram showing a resistance value measuring pin for measuring the electrical resistance of wood moving in the drying chamber of the present invention, Figure 6 is a diagram showing an example of installation of the diffuser of the present invention, and Figure 7 is an electromagnetic wave generator of the present invention. A diagram showing electromagnetic wave reflection between and a diffuser, Figure 8 is a diagram showing a standing wave generated due to electromagnetic wave reflection by a plurality of diffusers, Figure 9 is a perspective view of the electromagnetic wave blocking unit of the present invention, and Figure 10 is an electromagnetic wave blocking unit of the present invention. Figure 11 is a cross-sectional view showing the operation of the sliding door of the electromagnetic wave blocking unit of the present invention, and Figure 12 is a block diagram showing the configuration of the wood dryer of the present invention.

The wood dryer of the present invention includes a drying chamber 10, an electromagnetic wave blocking unit 20, a transport means 30, a control device 40, and a power supply unit 50.

As shown in Figures 1, 2, and 12, the present invention is a wood dryer (1) that removes moisture contained within wood using heat generated by standing waves, and has an interior that dries the wood while transporting it. a drying chamber (10) having a space; An electromagnetic wave blocking unit (20) installed at the inlet or outlet of the drying chamber (10); A transfer means (30) installed to pass through the drying chamber (10) and the electromagnetic wave blocking unit (20) and consisting of one of a transfer roller or a conveyor belt to move the wood; A control device 40 that controls the environment of the drying chamber 10 by inputting information about the wood; A power supply unit 50 that supplies power to the drying chamber 10; Includes.

As shown in Figures 3 to 5, the drying chamber 10 is composed of a rectangular parallelepiped, the length of which is formed to correspond to the moving distance of the wood 2, and an electromagnetic wave generator 11, a diffuser 12, and a dielectric tube are inside. (13), a resistance value measurement pin (14), and a ventilation device (15).

The electromagnetic wave generator 11 is installed inside the drying chamber 10 and transmits electromagnetic waves, and the wavelength of the reflected wave generated when the transmitted electromagnetic wave is reflected by hitting the diffuser 12 forms a standing wave. Heat is generated to remove moisture from the wood (2).

The diffuser 12 is installed on one or more internal walls of the drying chamber 10, and is manufactured by extrusion molding from either aluminum or stainless steel. The cross-sectional shape of the diffuser 12 is constant in the longitudinal direction, but is composed of a stepped structure that gradually decreases from the center, which has the highest height, to the left and right. In addition, when the diffuser 12 is installed at a corner of the drying chamber 10, a diagonal plate is installed and attached thereon to eliminate the mirror effect.

The dielectric tube 13 is installed in a cross-sectional shape such as square, octagon, circular, or oval along the longitudinal direction (moving direction of the wood 2) inside the drying chamber 10, and is provided with a transfer means ( 30) is installed to allow the wood (2) to move along the longitudinal direction. In addition, it prevents moisture and foreign substances generated when drying the wood 2 from directly contacting the diffuser 12.

Since the dielectric tube 13 serves to support physical space while transmitting electromagnetic waves, a ferroelectric material is generally used. In the present invention, aluminum oxide (Al ₂ O ₃ ), a ferroelectric material with a high dielectric constant, is used, but glass with general ceramic properties may also be used.

The resistance value measuring pin 14 is installed inside the drying chamber 10 so that when information about the wood 2 is not entered into the input part of the control device 40, the task manager Information about the resistance can be measured using the resistance value measurement pin 14.

In the process of measuring the resistance value of the resistance value measurement pin 14, as shown in FIG. 5, there is a dielectric tube 13 installed in the drying chamber 10 along the moving direction of the wood 2, The wood 2 is transported by the transport means 30 installed inside the dielectric tube 13. The resistance value measurement pin 14 measures the electrical resistance value by directly contacting the wood 2 transported by the transfer means 30, and transmits the measured resistance value to the control device 40. Thus, the moisture content is calculated, and the drying chamber 10 can be automatically controlled according to the moisture content.

If the moisture content of the wood 2 measured by the resistance value measurement pin 14 is higher than the set value, the heating temperature of the wood can be increased by increasing the output of the electromagnetic waves. Conversely, when the moisture content is measured to be lower than the set value, the output of electromagnetic waves can be lowered to prevent the temperature from rising too much.

The ventilation device 15 is installed outside the drying chamber 10, and the installation interval is 1 m to 2 m. In the process of drying the wood 2, moisture generated inside the drying chamber 10 is discharged to the outside.

Figure 6 shows an example of installation of the diffuser 12 installed on the inner wall of the drying chamber 10. The diffuser 12 is composed of a staircase structure that gradually decreases from the center with the highest height to the left and right, and the ratio of the height of each step included in the staircase structure is expressed as a sequence of prime numbers, The width of each staircase is equal to the ratio of 1. Here, the prime number is defined as 'a number that has only 1 and itself as divisors among natural numbers greater than 1.' For example, 5 is a prime number because the only way to write the result of multiplying a number by 1Х5 or 5Х1 is to include the number itself.

In the present invention, the height ratio of the diffuser 12 is designed to have sizes of "3, 5, 7, 11, 13...", identical to the arrangement of prime numbers.

As shown in FIG. 7, the electromagnetic wave transmitted from the electromagnetic wave generator, which is an incident wave, strikes the diffuser 12 and forms a reflected wave that is different in phase from the incident wave. The incident wave and the reflected wave proceed independently of each other without interference or fusion, forming a standing wave. And heat is generated by the standing wave. In other words, the water molecules contained inside the wood rotate and vibrate due to standing waves and collide with adjacent water molecules. Because water molecules have polarity, their movement is caused by electromagnetic waves whose polarity changes over time. As water molecules vibrate and collide due to standing waves, the temperature rises, thereby generating heat in the wood. The heat generated as standing waves move water molecules removes moisture from the wood inside the drying chamber.

Electromagnetic waves generated by the electromagnetic wave generator 11 and penetrating the inside of the drying chamber 10 have a constant frequency and amplitude. However, the direction changes as it hits the diffuser 12 installed on the wall and is reflected. When electromagnetic waves generated from the same electromagnetic wave generator 11 are reflected by a plurality of diffusers 12 having different heights and returned, a phase difference occurs as they are reflected by the diffusers 12 having different heights. A phase difference occurs as the time and distance at which each electromagnetic wave is reflected varies.

FIG. 8 shows electromagnetic waves with a phase difference (θ) traveling in the same space as they are reflected by diffusers 12 having different heights.

If the height of the diffuser 12 is constant, the frequency or output of the electromagnetic wave changes as the generated electromagnetic wave and the reflected electromagnetic wave interfere or merge. However, when electromagnetic waves are reflected using the diffuser 12 having a small height ratio as in the present invention, the reflected electromagnetic waves do not interfere with each other and exist independently, forming a standing wave inside the drying chamber 10.

Also, when a considerably large number of diffusers 12 are used as in the present invention and the number of height changes of each diffuser 12 is increased, the number of standing waves with a phase difference increases, resulting in a fairly uniform electromagnetic wave within the space. is formed Since the ratio of the height of the diffuser 12 for each reflected wave follows a decimal sequence, the phase difference also becomes a function of decimals. In other words, the presence of multiple standing waves with a phase difference with a small number of functions independent of frequency can heat the space uniformly, and uniform drying is possible by uniformly heating the inside of the wood that occupies a three-dimensional space.

In addition, as multiple standing waves that change polarity in the same form are generated, uniform polarity is formed within the space. Because of this, electric sparks that may occur when metal enters the electromagnetic wave oven do not occur in the wood dryer of the present invention. In other words, since there is no electrical potential difference or only a very small difference occurs at each location within the space, a discharge (spark) due to a sudden potential difference does not occur even if a metal is located.

Meanwhile, as shown in FIG. 1, a plurality of transport rollers 31 are installed in the transport means 30 for continuously transporting and supplying the wood 2 to be dried. The transport roller 31 rotates along a rotation axis arranged perpendicular to the transport direction of the timber 2 and transports the timber 2 forward.

As described above, a conveyor belt may be installed on the transport means 30 to transport the wood 2 placed above.

As shown in FIGS. 9 to 11, the electromagnetic wave blocking unit 20 is installed at the inlet or outlet of the drying chamber, and includes an external lining 21, an internal lining 22, a water supply unit 23, and a water discharge unit. (24), water circulation space (25), sliding door (26), and internal space of the inner lining (27).

The outer lining 21 is made of metal, and the inner lining 22 is installed inside the outer lining 21 and is made of plastic. It includes a water supply unit 23 that injects water into the water circulation space 25 formed between the outer lining 21 and the inner lining 22, and supplies water into the water circulation space 25. It includes a water discharge unit 24 that discharges to the outside.

Here, the water circulating in the water circulation space 25 serves to block the electromagnetic waves from being emitted to the outside. In addition, it includes a sliding door 26 to again block electromagnetic waves from being emitted to the outside, and the sliding door 26 can move up and down depending on the size of the wood. When the wood 2 moved by the transport means 30 is large or high in height, the sliding door 26 opens relatively large, and when the wood 2 is small in size or low in height, the sliding door 26 opens relatively small.

The sliding door 26 serves as an entrance through which the wood 2 is input or discharged. The wood 2 introduced through the sliding door 26 of the electromagnetic wave blocking unit 20 installed at the entrance of the drying chamber passes through the internal space 27 of the inner lining and is introduced into the drying chamber 10. Likewise, the wood that has been completely dried in the drying chamber passes through the inner space 27 of the inner lining and is discharged through the sliding door 26 of the electromagnetic wave blocking unit 20 installed at the outlet of the drying chamber. In this way, the electromagnetic wave blocking unit 20 blocks electromagnetic waves that may be generated during the drying process, thereby providing the effect of minimizing the impact of electromagnetic waves on the worker's human body.

Referring to FIG. 11, the work manager includes a control device 40 that controls the environment of the drying chamber 10 by inputting information about the wood, and a power supply unit 50 that supplies power to the drying chamber 10.

The control device 40 includes an input unit 41, a memory 42, a control unit 43, and an output unit 44.

The input unit 41 allows the task manager to input one or more information among the species, shape, moisture content, and movement speed of the wood 2, and the memory 42 stores the information input to the input unit 41. do. The control unit 43 performs a drying process and controls the environment of the drying chamber 10 according to the information about the wood based on the information input by the operation manager to the input unit 41, and the output unit 44 Displays information about the drying process of the wood.

When explaining the drying process of the wood (2) through the wood dryer (1) of the present invention with reference to the attached drawings, the wood (2) is separated from the electromagnetic wave blocking unit (20) by the transport means (30). When passing through and being transferred to the drying chamber 10, the electromagnetic wave transmitted from the electromagnetic wave generator 11 is synthesized with the reflected wave hitting the diffuser 12 to form a new wavelength, a standing wave, and the heat generated by the standing wave is After removing the moisture inside the wood 2, the wood 2, which has completed electromagnetic wave blocking and drying, is discharged through the electromagnetic wave blocking unit 20 and then inputted into another process or released as a finished product.

The wood dried in this way prevents sparks or discharges from occurring in the wood during the drying process, reduces deformation or damage to the wood by drying the wood in a relatively short time, and heat transfer is uniformly transmitted within the drying chamber. This can provide the effect that there is no difference in the dry state of the exterior and interior of the wood.

Although the preferred embodiments of the present invention have been described with reference to the accompanying drawings, the technical configuration of the present invention described above can be changed to other specific forms by those skilled in the art without changing the technical idea or essential features of the present invention. You will be able to understand that this can be implemented. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the claims described later rather than the detailed description above, and the meaning and scope of the claims and All changes or modified forms derived from the equivalent concept should be construed as falling within the scope of the present invention.

1: Wood dryer 2: Wood
10: drying chamber 11: electromagnetic wave generator
12: diffuser 13: dielectric tube
14: Resistance value measurement pin 15: Ventilation device
20: electromagnetic wave blocking part 21: external lining
22: inner lining 23: water supply part
24: water discharge unit 25: water circulation space
26: sliding door 27: inner space of inner lining
30: transfer means 31: transfer roller
40: control device 41: input unit
42: memory 43: control unit
44: output unit 50: power unit

Claims (11)

A wood dryer that removes moisture contained within wood using heat generated by applying electromagnetic waves to wood (2),
a drying chamber (10) having an internal space for drying the wood (2) while transporting it;
an electromagnetic wave blocking unit 20 installed at the inlet or outlet of the drying chamber 10;
A transfer means (30) installed to pass through the drying chamber (10) and the electromagnetic wave blocking unit (20) and consisting of one of a transfer roller or a conveyor belt to move the wood (2);
a control device 40 that controls the drying chamber environment by inputting information about the wood 2;
A wood dryer including a power supply unit (50) that supplies power to the drying chamber (10). According to paragraph 1,
The drying chamber 10,
an electromagnetic wave generator 11 installed inside the drying chamber 10 to transmit electromagnetic waves;
One or more diffusers (12) installed on the wall of the drying chamber (10);
a dielectric tube (13) installed inside the drying chamber (10) along the moving direction of the wood (2);
a resistance value measurement pin 14 installed inside the drying chamber 10 to measure the electrical resistance inside the wood 2;
A wood dryer comprising: a ventilation device (15) installed outside the drying chamber (10) to discharge moisture generated inside the drying chamber (10) to the outside. According to paragraph 1,
The electromagnetic wave blocking unit 20,
an outer lining (21) made of metal;
an inner lining (22) installed inside the outer lining (21) and made of plastic;
a water supply unit (23) for injecting water into the water circulation space (25) formed between the outer lining (21) and the inner lining (22);
It includes a water discharge unit 24 that discharges water introduced into the water circulation space 25 to the outside,
A wood dryer, characterized in that the water circulating in the water circulation space (25) blocks electromagnetic waves formed in the inner space of the inner lining (22) from being emitted to the outside. According to paragraph 1,
The control device 40,
an input unit 41 for inputting one or more information among the tree species, shape, moisture content, and movement speed of the wood 2;
a memory 42 that stores information input to the input unit 41;
an output unit 44 that displays information about the drying process of the wood 2;
It includes a control unit 43 that controls to perform a drying process for the wood 2 based on the information input to the input unit 41,
The control unit (43) is a wood dryer, characterized in that the drying chamber environment is controlled according to the information about the wood (2) input by the operation manager through the input unit (41). According to paragraph 2,
The diffuser 12 is,
Made of either aluminum or stainless steel,
The cross-sectional shape is constant in the longitudinal direction, but is composed of a stepped structure that gradually decreases from the center, which is the highest, to the left and right.
A wood dryer, characterized in that the wavelength of the reflected wave generated when the electromagnetic wave transmitted from the electromagnetic wave generator (11) is reflected by hitting the diffuser (12) forms a standing wave. According to paragraph 2,
The diffuser 12 is,
A wood dryer, which is installed on the wall of the drying chamber (10) in one or more pieces, and when installed at a corner, a diagonal plate is installed and attached thereto to eliminate the mirror effect. According to clause 5,
A wood dryer, characterized in that the ratio of the height of each staircase included in the staircase structure is expressed as a sequence of decimal numbers. According to clause 5,
The standing wave is,
An electromagnetic wave created by combining an electromagnetic wave transmitted from the electromagnetic wave generator 11 and a reflected wave generated when the electromagnetic wave hits the diffuser 12,
A wood dryer, characterized in that the standing wave generates heat while heating water molecules inside the wood (2) to remove moisture contained in the wood (2). According to paragraph 2,
The resistance value measurement pin 14 is,
Measure the electrical resistance value of the wood (2) by directly contacting the wood (2) while installed inside the drying chamber (10),
The control device 40 calculates the moisture content of the wood 2 from the resistance value of the wood 2, and automatically controls the drying chamber 10 according to the moisture content, wherein the wood 2 A wood dryer, characterized in that it is controlled to increase the output of electromagnetic waves when the moisture content is higher than the set value, and to lower the output of electromagnetic waves when the moisture content is lower than the set value. According to paragraph 2,
The dielectric tube 13 is,
It has a cross-sectional shape of a square, an octagon, a circle, or an oval along the same longitudinal direction as the moving direction of the wood (2), and is installed inside the drying chamber (10) while the transport means (30) passes through the internal space. A wood dryer, characterized in that it allows the wood (2) to move and prevents moisture and foreign substances generated during wood drying from directly contacting the diffuser (12). According to paragraph 3,
The electromagnetic wave blocking unit 20,
It is installed at the inlet or outlet of the drying chamber 10, and includes a sliding door 26 to block electromagnetic waves from being emitted to the outside, and the sliding door 26 is configured to block the wood passing through the inlet or outlet. 2) A wood dryer, characterized in that it opens by moving up and down in proportion to the size of the wood.