KR102342890B1 - drier having equalizing air current distribution - Google Patents

Abstract

The present invention relates to a drier having uniform air current distribution, which allows drying air current to be guided upwards in concentration on only the direction of trays (100) without being spread in the direction outside the trays (100) at both side portions of the lower part of a chamber (10), in which the drying air current is circulated along flow paths (400, 400') formed between reflection plates (300) and an insulating plate (200), wherein the reflection plates (300) are installed to maintain a predetermined interval from the insulating plate (200) coupled to the inner side surface of the chamber (10). The present invention includes a turbo fan (100) installed at the central portion inside a duct (600) having a stepped structure of being installed at the upper side within the chamber (10) and having a flow passage (620) structure for moving the drying air current in a lateral direction. The present invention can perform a fine control operation for the drying air current, drying temperature and moisture contained in the drying air current, and perform uniform drying for an object to be dried without a drying speed difference between a central portion and an end portion of the object to be dried by concentrically raising the drying air current toward the trays (100) through cycle circulation.

Description

Dryer having equalizing air current distribution

The present invention relates to a dryer having a uniform airflow distribution, and more particularly, it is raised on trays through induction control of the drying airflow so that the dried object can be dried uniformly and effectively without a drying difference between the center and the edge of the building. It is about a dryer with a uniform airflow distribution that enables dry dried articles to be dried evenly.

A number of dryers for drying dry matter are on the market, and these existing dryers include drying materials on trays stacked on drying racks 20 and 30 like the dryer disclosed in the following prior art document registration patent (No. 10-1817233). It is dried only in the raised state. In particular, the trays 40 of FIG. 1 rotated together with the drying racks 20 and 30 in the dryer form an airflow in the centrifugal force direction during the rotation process. Of course, FIG. 1 is a diagram conceptually illustrating a shape in which the drying airflow moves in the direction of drawing the centrifugal force according to the influence of the centrifugal force appearing through the rotation of the trays 40 in the planar direction of the dryer.

Since this centrifugal force can have a huge effect on the movement of the drying airflow, the drying airflow does not move in the direction toward the trays 40 of FIG. will move to

In other words, since the drying air flow does not move toward the trays 40, the dried objects placed on the individual trays 40 cannot be dried evenly, and furthermore, the drying area of the drying material is not uniform, so the edge of the structure There is also a significant difference in drying between the central part and the central part, and there is even a phenomenon in which the edge part of the building burns black due to the drying difference.

The drying airflow cannot react sensitively to the action of the airflow because it is a gas. In particular, the rotating tray 40 and drying racks 20 and 30 are airflow directions that prevent the drying airflow from flowing in the direction of the trays 40 . Inevitably, it acts as an obstacle factor affecting ) (30) as a standard, it is inevitable to show a vortex flow that draws a centrifugal direction to the outside of the drying rack (20) (30).

Therefore, the drying air flow does not smoothly flow into the inside of the drying rack 20 (30) toward the drying material mounted on the trays 40, and only revolves around the outer periphery of the drying rack 20 (30), so that the drying product can be effectively dried. Not only that, it is also impossible to exhibit an even drying action.

Of course, since the drying air flow does not flow smoothly into the drying rack 20 ( 30 ), the buildings mounted on the trays 40 cannot be dried uniformly, and in particular, the edge of the building is larger than the center of the building. On the other hand, a phenomenon of drying and burning appears, whereas the central part of the structure is relatively less dry and does not dry out.

Therefore, there is an urgent need to develop a dryer capable of effectively controlling the direction of the dryer airflow in the dryer and uniformly and effectively drying the dried objects.

Patent Document 001: Registered Patent No. 10-1817233 (Registration Date 2018, 01, 04)

The present invention for solving the above problems provides a uniform airflow direction that can control and induce the airflow direction of the drying wind, which is the drying airflow, so that the entire area of the buildings can be dried evenly without a difference in drying speed between the central part and the edge part of the buildings put into the dryer. It aims to provide a dryer having an airflow distribution.

The present invention for the achievement of the above objects is a drying air stream descending along both sides in the chamber chamber 10 of the dryer, the trays 100 stacked on the rotary drying die 650 installed in the center of the chamber chamber 10 The intake port 610 and the flow passage 620 are formed together and spaced apart by a predetermined height to induce the upward movement to be concentrated in the central direction and to induce the elevated dry airflow to move in the lateral direction of the chamber chamber 10 . A duct 600 having a structure and a double shielding structure is installed in a structure to be shielded on the upper portion of the chamber chamber 10, and the turbofan 500 and the tray 100 are installed near the center of the flow passage 620. Through the combination of the through-holes 110 penetrating through the central portion of the drying air flow is concentrated and induced to the central portion of the trays 100 and rises, the turbofan 500 for rotation of the turbofan 500 A blower motor 510 having a rotation shaft coupled to the chamber chamber 10 is installed in the upper central portion of the duct 600 installed in the center of the upper portion, and adjacent to the blower motor 510 is the tray A driving motor providing power required for the rotation of 100 is installed, and the duct 600 is a dryer in which an upper mounting plate 601 portion and a lower shielding plate 602 portion are formed to be spaced apart by a predetermined height. an outdoor air hole 630 for controlling the inflow of outdoor air in the rear center of the mounting plate 601 corresponding to the rear center of the flow passage 620 for guiding the flow in the lateral direction; a suction port 610 formed in the central portion of the shielding plate 602 to pass the rising drying airflow toward the center of the trays 100; and the turbofan 500 axially installed in the vicinity of the center of the flow passage 620 for moving the dry air flow sucked in from the suction port 610 in the lateral direction in the chamber chamber 10 . It further includes, in any part of the upper rear surface in the chamber chamber 10, a pair of moisture drainage holes 900 for controlling moisture contained in the dry air stream by mixing the external air introduced from the external air hole 630. Further included, for the stacking installation of the tray 100, the tray 100 is formed of a tray with a structure of 0 to 9° from the bottom of the tray 100, and consists only of a polygonal rim structure for attaching the edge portion of the tray 100 ( 651)s; It is installed in a vertical bar structure from the outside of the tray tray 651, is coupled to the tray tray 651, and the tray 100 and the tray tray 651 through the power provided from the driving motor. The drying die 650 is rotated while including the; It includes, is installed in a vertical structure between the outside of the drying die 650 and the inside of the reflecting plate 300, is diffusely reflected in the direction of the trays 100, and is dried on the top of the trays 100 There is one feature in the dryer having a uniform airflow distribution further comprising a lamp (L).

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The through holes 110 have a structure penetrating through the central portion of the tray 100, the tray 100 is formed in a mesh or grill-type structure for even drying of the building material, and the outdoor air hole 630 is the It is located in the space between the intake ports 610 located at the upper and lower sides of the duct 600 and the outside air flowing in from the outside air hole 630 is mixed with the dry air flow of the rising air flow passing through the intake port 610 . There is one characteristic of the dryer having a uniform airflow distribution.

On the basis of the sensing signal of the humidity sensor 800, which is installed in the same structure as the aperture of the camera at any one side of the upper part of the chamber chamber 10 and the moisture contained in the rising dry air stream is higher than the reference value, it is detected based on the sensing signal of the humidity sensor 800. There is one feature in a dryer having a uniform airflow distribution that is further provided with a servo mechanism device 1000 for adjusting the diameter size of the hole 630 or the moisture drainage hole 900 .

In the servo mechanism device 1000, the motor 1100 is driven by the deviation signals while the detection values of the thermocouple 850 for detecting the temperature of the drying air flow are compared with the target value, and the outdoor air hole 630 or the exhaust There is one feature in a dryer having a uniform airflow distribution that is operated so that the temperature value of the drying airflow coincides with a target value by adjusting the diameter size of the wet hole 900 .

According to the present invention as described above, it is possible to precisely control the circulation cycling of the drying air flow flowing inside the chamber chamber of the dryer, thereby enabling the drying of the dried objects placed on the trays to be uniformly expected.

In addition, according to the present invention, for the even drying of the buildings placed on the trays, based on the measurement values of humidity and temperature for the drying airflow circulated in the chamber room, the rapid drying of the buildings is performed according to the precise control of the moisture drainage hole of the servo mechanism. Together with this, there is an effect that can prevent problems such as burning of buildings or excessive burning.

1 is a diagram conceptually illustrating a planar state of a dryer for indicating a fluid movement flow direction of a dryer stream in an existing dryer.
2 is a view three-dimensionally illustrating a dryer having a uniform airflow distribution according to an embodiment of the present invention.
FIG. 3 is a conceptual cross-sectional view for grasping the internal structure of the chamber chamber 10 while showing the front state of the chamber chamber 10 as a longitudinal cross-sectional structure for the chamber chamber 10 inside the housing shown in FIG. 2 .
4 is a view conceptually illustrating the direction of the dry air flow along with the inflow of outside air from the chamber chamber 10 as viewed from the planar direction of the chamber chamber 10 shown in FIGS. 2 and 3 .
5 is a view illustrating the structure of the duct 600 installed in the upper part of the chamber chamber 10 as viewed from different directions.
6 is a view conceptually illustrating the drying die 650 and the tray 651 required for the stacking installation method of the tray 100 in the chamber chamber 10.
FIG. 7 is a longitudinal cross-sectional structure of the chamber chamber 10 inside the housing shown in FIG. 2 , showing the front state of the chamber chamber 10, the flow of the dry air flow circulating in the chamber chamber 10 and irradiation of light It is a diagram conceptually showing the reflection direction along
8 is a view showing a state in which the diffuse reflection portion 310 shown in FIG. 7 is applied in, for example, a honeycomb structure.
9 is a diagram conceptually illustrating an operating mechanism of a servo mechanism for adjusting the diameter of the moisture drainage hole 900 shown in FIG. 3 and the outdoor air hole 630 shown in FIGS. 4 and 5 .

The present invention should be interpreted in a way that includes the scope of rights that reach the technical idea through various modified embodiments, only these embodiments make the publication of the present invention complete, and common knowledge in the technical field to which the present invention belongs It is provided to fully inform the possessor of the scope of the invention, and the present invention is only defined by the scope of the claims.

Moreover, the drawings attached to the present invention are attached as a way to help the understanding of the description of the present invention to the last, and the drawings attached to the present invention do not represent the technical idea of the present invention, The idea should not be understood as a limited interpretation by the accompanying drawings.

In the dryer having a uniform airflow distribution according to an embodiment of the present invention, for example, as shown in FIG. 2 , the exterior is made of a housing, and the inside of the housing is a chamber chamber 10 as shown in FIG. structure, and in the chamber chamber 10, a plurality of trays 100 for placing buildings may be installed in a stacked structure maintaining a predetermined interval, and around the side wall of the chamber chamber 10 It may be installed as a reflective plate 300 having a diffuse reflection structure that reflects the irradiated light in various directions.

Of course, a heat insulating plate 200 is installed around the side wall of the chamber chamber 10 in a structure that maintains a predetermined distance from the reflecting plate 300 installed along the side wall of the chamber chamber 10. The heat insulating plate 200 may exhibit an insulating effect so that the temperature of the drying air stream for drying the dried object mounted on the trays 100 is not affected by the temperature of the outside air. Dry air flow is a term with the same meaning as dry air, and may be used together in some cases.

In addition, flow paths 400 and 400' are formed between the heat insulating plate 200 and the reflection plate 300 as shown in FIG. It functions as a passage for the flow, but preferably serves as a passage through which the elevated dry air flow descends.

On the other hand, a turbofan 500 may be configured in the inner upper center of the chamber chamber 10 , and the turbofan 500 may be rotated by power provided from the blower motor 510 , and preferably It may be installed in the flow passage 620 corresponding to the inner side of the intake port 610 of the duct 600 shown in FIG.

The duct 600 may have a double shielding structure that maintains a predetermined separation space so as to have a flow passage 620 as shown in FIG. 5 . That is, it may be composed of a shielding plate 602 that is shielded from the upper portion in the chamber chamber 10 and a mounting plate 601 spaced apart from the shielding plate in a predetermined height direction. The blower motor 510 for providing power required for the rotation operation of the turbofan 500 may be installed in the central portion.

The turbofan 500 is an intake air for inducing the drying air flow descending along the flow paths 400 and 400 ′ configured inside the chamber chamber 10 to be concentrated in the center direction of the trays 100 and to be raised. function can be performed.

In addition, in the center of the shielding plate 602, an intake port 610 for the passage of the rising dry air flow is formed, and in the rear central portion of the mounting plate 601, there is an outdoor air hole 630 through which outside air can be introduced. The turbofan 500 is installed in the central portion of the flow passage 620 that is formed to be spaced apart from the shielding plate 602 and the mounting plate 601 in the central direction of the trays 100 to collect the rising dry airflow. can lead to concentration.

Although not shown in the drawing, a driving motor may be further installed in the adjacent portion where the blower motor 510 is installed, and the rotating shaft of the driving motor is formed in a shaft structure at the upper center of the drying die 650 ( X) may be connected to a chain or a belt to provide rotational power necessary for rotation of the drying die 650 .

The duct 600 has an outside air hole 630 that allows outside air to flow into the chamber chamber 10 in the rear direction of the mounting plate 601 of the duct 600 in which the turbo fan 500 is installed. ) may be further formed. The above-mentioned outdoor air hole 630 may act as a factor for lowering the dry air flow in the chamber chamber 10 when it rises above a certain temperature.

The outdoor air hole 630 is a relationship that can be positioned as shown in FIGS. 3 and 7 in the space between the intake ports 610 positioned vertically above and below the duct 600, the outdoor air hole 630 . The outside air introduced from the inlet can be efficiently mixed with the dry air flow of the rising air flow passing through the intake port 610 , and proper temperature control of the drying air flow only by adjusting the holes for the intake port 610 and the outside air hole 630 . can be done precisely and easily. Of course, the temperature control of the drying air stream may be implemented, for example, through the servo mechanism 1000 to be described later.

On the other hand, the drying die 650 may be formed in a frame structure in which vertical poles from the outside of the trays 100 maintain a constant distance, as shown in FIGS. 3 and 6 , and the drying die 650 of FIG. While maintaining a constant height interval along the inside, the tray dies 651 may be combined in a horizontal or inclined structure of 1 to 9°.

These tray dies 651 are support for being seated in a structure in which the trays 100 are stacked, and have a polygonal rim structure suitable for the drying airflow to pass evenly in the direction of the trays 100 on which the building is placed. can

Accordingly, the trays 100 may be stacked in such a way that their edge portions are hung on top of the tray trays 651 .

The tray 100 is suitable for the mesh type or grill structure through which the rising dry air flow can pass evenly as shown in FIGS. 3 and 7 with reference to FIG. 6, and a passage hole 110 may be formed in the central portion thereof. . In particular, the passage hole 110 may perform a function of inducing the rising drying air flow to be concentrated only in the direction of the trays 100 by the suction power of the turbofan 500 and to rise.

The tray 100 having such a structure may be stacked in a state spanning over the tray tray dies 651 having a rim structure, and the drying die 650 of a vertical structure combined with the tray tray 651 is The shaft rod (X) formed in a shaft structure in the center of its upper end may be rotated through the power provided from the driving motor.

As the drying die 650 rotates, the trays 100 mounted on the tray dies 651 are also rotated, and the drying airflow and light irradiation and diffuse reflection in which the buildings mounted on the trays 100 rise. can be dried evenly.

On the other hand, in the flow paths 400 and 400 ′ formed between the heat insulating plate 200 and the reflective plate 300 , the dry air flow rising toward the upper portion of the chamber chamber 10 flows along both sides of the chamber chamber 10 . It serves as a passageway that allows it to descend.

That is, the upper portion of the chamber chamber 10, that is, the center of the turbofan 500 and the tray 100 installed as the central portion of the inner flow passage 620 of the duct 600 installed in the upper portion of the chamber chamber 10. According to the formation of the through holes 110 formed in the area, the dry air flow descends along both sides of the chamber chamber 10, then is concentrated in the direction of the trays 100 and rises, and then the internal flow passage of the duct 600 ( A circulation cycle is drawn in which it moves in both directions of the inner upper portion of the chamber chamber 10 through 620 , and descends again toward the flow passages 400 and 400 ′ formed in both inner portions of the chamber chamber 10 .

This dry airflow does not spread when the drying airflow rises with the cycle of descending and ascending, but is concentrated only in the direction of the trays 100 and can be raised. The whole area of the dried object can be dried evenly.

And, between the reflecting plate 300 and the drying die 650, the lamps L may be installed in a vertical rod-shaped structure, and near-infrared rays or halogen may be used for these lamps L.

In particular, the reflector 300 has through holes 300a in the lateral direction of the chamber chamber 10 so that the drying air flow descending along the flow paths 400 and 400 ′ can be exhausted toward the tray 100 . These through holes 300a are formed of diffuse reflection portions 310 having a diffuse reflection structure as shown in FIG. 7 suitable for the light irradiated from the opposite lamp L to be diffusely reflected in various directions toward the tray 100 again. can be

In particular, the diffuse reflection portion 310 has a structure that is inclined and protrudes from the formation point of the through holes 300a so that, when the light irradiated from the lamp L is incident, it can be diffusely reflected in various directions. It can also be formed with the same honeycomb structure.

On the other hand, a humidity sensor 800 and a thermocouple 850 may be further installed in any one portion of the chamber chamber 10, as shown in FIG. 9, and a pair of a pair of Moisture drainage holes 900 may be further installed, and the western mechanism device 1000 for adjusting the size of the diameter of the moisture drainage holes 900 based on the sensing of the humidity sensor 800 and the thermocouple 850 is provided. It can be installed in a more applicable manner.

Of course, this servo mechanism device 1000 can be applied to the outside air hole 630 formed in the rear portion of the mounting plate 601 of the duct 600 shown in FIG. 5 as well as the moisture drainage hole 900 . It may be applied to both the outdoor air hole 630 and the moisture drainage hole 900 depending on the environment of the , or may be applied to any one of these holes.

In particular, the outdoor air hole 630 and the moisture drainage hole 900 may have the same structure as the diaphragm applied to the camera to adjust the diameter, and the diaphragm structure of the outdoor air hole 630 and the moisture drainage hole 900 . The adjustment of the diameter based on the servo mechanism 1000 may be performed according to rotation control or reverse rotation control of the control gear ring 1200 as the servo mechanism device 1000 .

As shown in FIG. 9 , the servo mechanism device 1000 is rotated by being bitten by the adjustment gear ring 1200 and the adjustment gear ring 1200 , and the rotation induction ring 1300 and the rotation induction ring for rotating the adjustment gear ring 1200 . The motor 1100 may be configured to provide power required for rotation of the 1300 .

The humidity sensor 800 may detect when the moisture contained in the rising dry air stream is greater than or equal to a reference value, and the servo mechanism 1000 may be operated based on the sensed signal in this way.

Of course, the motor 1100 is driven by the deviation signals while the detected values of the thermocouple 850 for detecting the temperature of the drying airflow are compared with the target value, and the diameter size of the moisture drain hole 900 is adjusted to the drying airflow. It may be an Arduino-type servomotor suitable to be operated so that the temperature value of is matched with the target value.

The servo mechanism device 1000 can be applied to the outdoor air hole 630 according to the design environment, and by adjusting the diameter of the outdoor air hole 630 to control the amount of outside air flowing in, the controlled inflow outside air is adjusted. Skill is that when the temperature value of the dry air stream continuously rises above the target value, it can act as a factor for lowering the temperature.

In addition, the Arduino-type servomotor is continuously operated based on the signals sensed and detected from the humidity sensor 800 and the thermocouple 850, and It is possible to control the diameter size through execution control of a program installed in the MCU mounted on the board of the Arduino-based structure, and such a program is designed and executed by a coding method using, for example, a switch case conditional statement and a loop statement. can be controlled.

The switch case conditional statement used in the loop statement is implemented to read each value every 1 second and transmit data. To explain in detail, the temperature is measured according to the cycle that rotates every 1 second, transmits data, exits, and then returns to 1 again. At the second, the barometric pressure is measured, data is transmitted and exited, and when the second is reached, the altitude is measured and the data is transmitted and exited. ) to the MCU.

Of course, the period of time (eg: 1 second) may be a period made using the millis() function and the micros() function, and the program reflected in the thermocouple 850 is a function called 'millis()' and 'micros()' )' can be designed by coding using a function, and these functions represent the time that the thermocouple 850 of the Arduino board structure has started and operated so far in units of 'milliseconds' and 'microseconds', respectively. It is a function that can be given.

Moreover, the millis() function and micros() function indicate the time after the thermocouple 850, which is based on the Arduino structure, operates, and since the sensor value must be measured for a long time, the millis() function and micros() function Variables used with functions need to be specified in unsinged long format.

If the int type is specified instead of the unsinged long type, an error may occur in the measurement of the sensor value of the thermocouple 850 soon after, because the range that the int type can represent is limited. Therefore, in order to prevent an error in measuring the sensor value of the thermocouple 850, the unsinged long type, which is a more extensive type than the range that the int type can represent, should be specified.

An operation process for the dryer having a uniform airflow distribution according to an embodiment of the present invention may be described below.

Any part of the upper part of the duct 600 installed in the upper part in the chamber chamber 10 after the buildings are placed on the stacked trays 100 while maintaining a predetermined interval in a vertical structure in the center of the chamber chamber 10 . With the power of the driving motor installed above, the tray 100 including the drying die 650 and the tray tray 651 may be rotated at a slow speed.

At this time, in the lamps (L) installed in a vertical rod-type structure between the reflector 300 and the drying dies 650, light irradiated from near-infrared or halogen is irradiated toward the tray 100, and the building is dried. become dry

Of course, at this time, since the peripheral portion of the through holes 300a formed in the reflection plate 300 is formed of the diffuse reflection portions 310 having a structure suitable for diffuse reflection, the light incident irradiated from the opposite side is shown in FIGS. 7 and 8 . As shown in the above, the diffuse reflection portions 310 may be reflected in the form of diffusely reflected light in various directions toward the tray 100 again.

For various diffuse reflection of light, for example, the diffuse reflection portion 310 may be formed in a honeycomb structure as shown in FIG. 8 , but is not limited to such a honeycomb structure.

In addition, at this time, a part of the drying air flow through the through holes 300a formed in the reflecting plate 300 is exhausted in the lateral direction of the trays 100 as shown in FIG. However, another part of the dry air flow descends along the flow passages 400 and 400 ′ formed between the insulating plate 200 and the reflective plate 300 and rises toward the trays 100 to dry the dry matter. .

The descending dry air flow is generated by the strong suction force according to the combination of the suction of the turbofan 500 installed in the central portion of the duct 10 and the through hole 110 formed in the center of the tray 100, ) are concentrated in the central direction and can rise.

That is, since the drying airflow is concentrated in the central direction of the trays 100 and shows a flow of upward movement passing through, an even drying effect of the dried material mounted on the trays 100 can be expected. This drying airflow shows an upward airflow concentrated in the center direction of the trays 100 without problems such as a centrifugal vortex phenomenon occurring through the rotation of the drying racks 20 and 30 in the existing dryer.

In this way, the dry air flow rising toward the center of the tray 100 is sucked through the intake port 610 of the duct 600 as shown in FIG. 5, and then the duct shown in FIGS. 3 and 7 in the turbo fan 500 ( It may be moved laterally in the chamber chamber 10 through the flow passage 620 of the 600 .

In this way, the dry air flow moved in the upper inner direction in the chamber chamber 10 descends again along the flow paths 400 and 400 ′ formed in both side directions in the chamber chamber 10 , and then again in the tray 100 . ) and draws a circular cycle that rises in the direction toward the center.

Of course, at this time, the drying air flow descending along the flow passages 400 and 400 ′ formed in both side directions in the chamber chamber 10 is also through the through holes 300a formed in the reflecting plate 300 in the lateral direction of the trays 100 . It is moved to and can be dried.

As such, in the chamber chamber 10 , the dry air flow descends from both side wall sides of the chamber chamber 10 , and is concentrated in the central direction of the trays 100 located in the center of the chamber chamber 10 . As a result, the dried products mounted on the trays 100 can be dried evenly.

Chamber Room (10) Tray (100)
Through hole (110)
Insulation plate (200) Reflector plate (300)
Through hole (300a) diffuse reflection part (310)
Euro (400) (400') Turbofan (500)
Blower motor (510)
Duct (600) Mounting Plate (601)
Shield (602) Intake (610)
Flow passage (620) Outdoor air hole (630)
Drying Die(650) Tracing Die(651)
Lamp (L)
Humidity Sensor(800) Thermocouple(850)
Damp hole (900) Servo mechanism device (1000)
Motor(1100) Adjustable Gearing(1200)
Rotation Induction Ring (1300)

Claims (9)

delete delete delete delete delete Inducing the drying air flow that descends along both sides in the chamber chamber 10 of the dryer to rise so as to be concentrated in the central direction of the trays 100 stacked on the rotary drying die 650 installed in the center of the chamber chamber 10, In order to induce the elevated dry airflow to move in the lateral direction of the chamber chamber 10, the duct 600, which is a structure spaced apart by a predetermined height and has a double shielding structure, is formed with an intake port 610 and a flow passage 620 together. It is installed in a shielded structure on the upper portion of the chamber chamber 10,
Through a combination of the turbofan 500 installed near the center of the flow passage 620 and the passage holes 110 penetrating through the central portion of the trays 100, the drying air flow is directed to the central portion of the trays 100. Concentrated, induced and elevated,
In order to rotate the turbofan 500, a blower motor 510 having a rotation shaft coupled to the turbofan 500 is installed in the upper central portion of the duct 600 in the chamber chamber 10. A driving motor that provides power necessary for rotation of the tray 100 is chukseol, and in a region adjacent to the blower motor 510,
In the duct 600, the upper mounting plate 601 portion and the lower shielding plate 602 portion are formed to be spaced apart by a predetermined height, and at the rear center of the flow passage 620 for guiding the rising dry airflow to the side. an outdoor air hole 630 for controlling the inflow of outdoor air in the center of the rear of the corresponding mounting plate 601; a suction port 610 formed in the central portion of the shielding plate 602 to pass the rising drying airflow toward the center of the trays 100; and the turbofan 500 axially installed in the vicinity of the center of the flow passage 620 for moving the drying airflow sucked from the suction port 610 in the lateral direction in the chamber chamber 10 . further comprising,
A pair of moisture drainage holes 900 are further included in any part of the upper rear surface of the chamber chamber 10 for evaporating moisture contained in the dry air stream by mixing the external air introduced from the external air hole 630,
For the stacking installation of the trays 100, tray dies 651 made of only a polygonal rim structure for attaching the edge portions of the trays 100 to a structure of 0 to 9° from the bottom of the trays 100;
It is installed in a vertical bar structure from the outside of the tray tray 651, is coupled to the tray tray 651, and the tray 100 and the tray tray 651 through the power provided from the driving motor. The drying die 650 is rotated while including the;
including,
A lamp (L) that is installed in a vertical structure between the outside of the drying die 650 and the inside of the reflecting plate 300, is diffusely reflected in the direction of the trays 100, and dries the building mounted on the trays 100. Dryer having a uniform airflow distribution, characterized in that it further comprises. 7. The method of claim 6,
The through holes 110 have a structure penetrating through the central portion of the tray 100, the tray 100 is formed in a mesh or grill-type structure for even drying of the building material, and the outdoor air hole 630 is the It is located in the space between the intake ports 610 located at the upper and lower sides of the duct 600 and the outside air flowing in from the outside air hole 630 is mixed with the dry air flow of the rising air flow passing through the intake port 610 . A dryer having a uniform airflow distribution, characterized in that it becomes. 7. The method of claim 6,
On the basis of the sensing signal of the humidity sensor 800, which is installed in the same structure as the aperture of the camera at any one side of the upper part of the chamber chamber 10 and the moisture contained in the rising dry air stream is higher than the reference value, it is detected based on the sensing signal of the humidity sensor 800. A dryer having a uniform airflow distribution, characterized in that the servo mechanism device (1000) for adjusting the diameter size of the hole (630) or the moisture drainage hole (900) is further provided. 9. The method of claim 8,
In the servo mechanism device 1000, the motor 1100 is driven by the deviation signals while the detection values of the thermocouple 850 for detecting the temperature of the drying air flow are compared with the target value, and the outdoor air hole 630 or the exhaust A dryer having a uniform airflow distribution, characterized in that it is operated so that the temperature value of the drying airflow coincides with a target value by adjusting the diameter size of the wet hole (900).

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