KR100655857B1 - F.I.R. Drying system using far infrared rays and preheating and exhaust air - Google Patents

Abstract

Disclosed are a continuous far-infrared drying apparatus using a dehumidifying exhaust gas using a far infrared radiator and a dehumidifying device and preheating air. Drying apparatus according to the present invention includes a drying chamber, a transfer unit and a blowing system. The drying chamber has an input hopper and an outlet and has a plurality of chambers formed in multiple stages while communicating in a zigzag form from the input hopper to the outlet. In each of these chambers a transfer part is arranged. The transfer part has drive shafts arranged horizontally on both sides of each chamber, and a chain sprocket is mounted on the outer circumferential surface of the drive shaft. At this time, a belt-type far infrared radiator is fastened and rotated to the chain sprocket facing each other. In addition, a power supply shaft equipped with a power supply sprocket for supplying electricity to the belt type far infrared radiator is disposed inside the belt type far infrared radiator. On the other hand, in the blowing system, suction ducts are formed in the upper and lower parts of the drying chamber, and an internal blower is connected to the suction duct, and the inner blower is connected to the downwind pipes and the side blower tubes formed on the upper and side surfaces of the respective chambers. In addition, on one side or the other side of each chamber, a blowing fan for transferring the preheating of the lower chamber to the upper chamber is mounted.

Description

Continuous far infrared drying device using dehumidification exhaust and preheating air using far infrared radiator and dehumidifier {F.I.R. Drying system using far infrared rays and preheating and exhaust air}

1 is a cross-sectional view schematically showing a drying apparatus according to the present invention,

2 is a schematic cross-sectional view of a drying apparatus according to another embodiment.

<Explanation of symbols for the main parts of the drawings>

100: drying apparatus 110: drying chamber

112: inlet hopper 114: outlet

116: Chamber 118: Building Guide

130: transfer unit 132: drive shaft

134: chain sprocket 136: power supply shaft

138: power supply sprocket 140: insulation

142: brush 144: drum pulley

146: mesh network belt 150: air blowing system

152: suction duct 154: first dehumidifier

156: internal blower 158: downward blower

160: side blower 162: blowing fan

164: second dehumidifier 180: plate-type far infrared radiator

190: belt type far infrared radiator

The present invention relates to a drying apparatus, and more particularly, to a continuous far infrared drying apparatus using a far-infrared radiator capable of producing high quality agricultural and marine products and food using a far-infrared radiator and a dehumidification exhauster and a preheating air using a dehumidifying apparatus.

In general, the method of drying the harvested agricultural and marine products or foods include conventional methods (natural drying) and using fossil fuels such as oil. The conventional method is a method of drying in a natural state exposed to sunlight, and has the advantage of being able to receive a high price due to excellent merchandise by maintaining excellent quality of agricultural and aquatic products, but most of them have difficulty in quality control and are restricted in terms of climate and space utilization. Have.

Drying method using fossil fuel such as oil is the most widely used method of drying by generating hot air by heat generated by burning fuel, but it is the most widely used method. It is difficult to produce high-quality products because it is long and the quality of the agricultural and marine products and other products are exposed at high temperatures for a long time.

Far infrared rays, on the other hand, are radiant energy emitted from ceramic materials and the like and are radiated when heated by another heat source. Therefore, it can be used to radiate far infrared rays by coating or forming heating far-infrared radiation ceramics on the surface of heat-resistant material in the form of plate, tube, lamp or coating according to various heat treatment characteristics, and heating the far-infrared radiation ceramics using electricity or other fuel. Has the characteristics.

Therefore, there is an urgent need for a method for drying agricultural and marine products and foods with economical and high-quality products by using a supply system of far-infrared rays, dehumidification exhaust, and preheating air radiated from such ceramics.

The present invention has been made to meet the above necessity, an object of the present invention by irradiating and drying the two-way far-infrared radiant heat to the dried goods zigzag moved to the bottom of the multi-stage along the belt in the drying chamber, high-quality agricultural and marine products and food It is to provide a continuous far-infrared drying apparatus using a dehumidification exhaust and preheating air using a far-infrared radiator and a dehumidification apparatus capable of producing a.

Another object of the present invention is to dehumidify the hot and humid humid air to dry the dry matter to blow the dry air to the dry again, the ventilation system that can lift the upper part by dehumidifying the humid air in the drying chamber consisting of a multi-stage It can reduce drying time, reduce energy consumption, and dehumidification exhaust and preheating using far-infrared radiator and dehumidifier that can prevent environmental pollution caused by using fossil fuel by using eco-friendly electric energy source. It is to provide a continuous far infrared drying apparatus using air.

In order to achieve the object of the present invention as described above, the present invention,

An input hopper and an outlet formed at one upper part and one lower part, a plurality of chambers formed in multiple stages while communicating in a zigzag form from the input hopper to the discharge port, and a plate-like far-infrared radiator disposed above the uppermost chamber of each chamber, A drying chamber having a dry guide mounted on the communicating portion of the chamber;

A pair of horizontally arranged to face each other on both sides of each chamber, the drive shaft is equipped with a chain sprocket on the outer circumferential surface, the belt type far infrared radiator is fastened and rotated to the respective chain sprocket facing each other, and each belt type far infrared radiator A transport unit having a power supply shaft equipped with a power supply sprocket on the outer circumferential surface to be in close contact with the belt-type far infrared radiator, and transporting the object to be discharged from the input hopper to the discharge port along each chamber to irradiate and dry in both directions; And

A suction duct disposed at the top and bottom of the drying chamber and connected with the first dehumidifier, a pair of internal blowers connected to each suction duct, and connected to a pair of internal blowers mounted on the upper and side surfaces of each chamber Far-infrared radiator and dehumidifier using a blower system having a downward blower fan and a side blower fan, and a blower fan mounted on one side or the other side of each chamber and a blower fan to transfer the preheating to the upper chamber. Provided is a continuous far infrared drying apparatus using dehumidification exhaust and preheated air.

With reference to the accompanying drawings will be described a continuous far infrared drying apparatus using a dehumidifying exhaust and preheating air using a far infrared radiator and a dehumidifying apparatus according to a preferred embodiment of the present invention.

1 is a cross-sectional view schematically showing a drying apparatus according to the present invention, and FIG. 2 is a cross-sectional view schematically showing a drying apparatus according to another embodiment.

Referring to FIG. 1, the continuous far-infrared drying apparatus 100 using the dehumidifying exhaust gas and the preheating air using the far infrared radiator and the dehumidifying apparatus according to the present invention comprises a drying chamber 110, a conveying unit 130, and a blowing system 150. .

Drying chamber 110 is formed with an input hopper 112 for injecting the dry matter on one side on the upper surface, the discharged to dry to be discharged to the outside is dried to be injected into the input hopper 112 on the one side of the drying chamber 110 to the outside 114 is formed. The interior of the drying chamber 110 is formed with a plurality of chambers 116 continuously formed at regular intervals from the top to the bottom. At this time, one side of the chamber 116 located at the top end is in communication with the input hopper 112, one side of the chamber 116 located at the bottom end is in communication with the outlet 114. Preferably, the other side of the chamber 116 located at the top is in communication with the other side of the chamber 116 in the adjacent lower part, and continues to communicate in a zigzag shape. More preferably, the communicating portion between each chamber 116 is equipped with a dry guide 118 at an angle toward the inside of the drying chamber 110. On the other hand, the plate-like far-infrared radiator 180 is mounted on an upper surface of the drying chamber 110, that is, the upper surface of the chamber 116 located at the uppermost end. One side of the radiator 180 is connected with a conventional external power source (not shown) in a conventional manner. That is, the external power source and the radiator 180 are electrically connected through the normal connection terminal. At this time, the plate-like far-infrared radiator 180 is formed with elvan, ocher and ceramic layers to emit far-infrared rays by the heat source. In the drying chamber 110 formed as described above, a transfer part 130 for moving the object from the input hopper 112 to the discharge port 114 is disposed.

The conveying unit includes a drive shaft 132, a belt type far infrared radiator 135, a power supply shaft 136, and a brush 142. A pair of drive shafts 132 are horizontally disposed on both sides of each chamber 116 to face each other, and a chain sprocket 134 is mounted on each drive shaft 132. At this time, the belt type far infrared radiator 135 is fastened to the pair of chain sprockets 134 facing each other. Like the belt-type far infrared emitter 135, like the plate-like far infrared emitter 180, the elvan, ocher and ceramic layers are formed to emit far infrared rays by a heat source. On the other hand, a power supply shaft 136 having the same shape as the drive shaft 132 is mounted inside each belt type far infrared radiator 135, and a power supply sprocket 138 is mounted on each power supply shaft 136. . The power supply sprocket 138 is mounted in close contact with the belt type far infrared emitter 135 to supply electricity to the belt type far infrared radiator 135 that is rotated. Preferably, when the power supply sprocket 138 supplies electricity to the belt type far infrared emitter 135, far infrared rays are radiated from the belt type far infrared radiator 135. At this time, each drive shaft 132 is coated with an insulating material 140 on the contact surface with each chain sprocket 134 so that the current flowing in the belt-type far infrared emitter 135 does not pass to the outside.
The power supply sprocket 138 is a common metal sprocket having a tooth form a conductor, and the power supply shaft 136 mounted inside the power supply sprocket 138 is also a conductor capable of supplying power. Therefore, when a normal external power (not shown) at one end of the power supply shaft 136 is connected to the power supply by a conventional method such as a connection terminal and the power is supplied, electricity applied to the power supply shaft 136 is supplied to the power supply sprocket Electricity is supplied to the belt-type far-infrared radiator 135 which rotates through the tooth of 138. The far-infrared radiator 135 is also a conductor, and since it is formed with elvan or ocher or ceramic layers therein, it is far-infrared by heat source. Will be radiated.

The transfer part 130 formed as described above is rotated such that a dry object introduced into the input hopper 112 is discharged to the discharge port 114 while forming a zigzag shape through the communication portion of each chamber 116. At this time, the object to be passed to the lower chamber 116 is passed to the next step by the dry guide 118 formed in the communication portion, the chamber 116 on the opposite side of the dry guide 118 has a belt-type far infrared emitter ( Each of the brushes 142 for removing the residues on the upper surface of the 135 is mounted.

In addition, the transfer unit 130 may use a mesh net belt in place of the belt-type far infrared radiator 135. As shown in FIG. 2, the transfer unit 130 includes a driving shaft 132, a mesh net belt 146, a brush 142, and a plate-like far-infrared radiator 180. A pair of drive shafts 132 are mounted on both sides of each chamber 116 so as to face each other, and a drum pulley 144 is mounted on each drive shaft 132. At this time, mesh mesh belt 146 is wound around drum-type pulley 144 facing each other, and brush 142 is mounted in chamber 116 on the opposite side of object guide 118. In addition, a plate-like far-infrared radiator 180 is disposed inside each mesh net belt 146.
Each of the far-infrared radiator 180 is electrically connected at one end through a conventional external power source and a connection terminal, not shown as in the above-described embodiment, and also in the elvan, loess and ceramic layers as in the previous embodiment. Therefore, when the power source connected to the external power source is applied to each far-infrared radiator 180, each plate-like far infrared radiator 180 radiates far infrared rays by the applied heat source.

Meanwhile, the blowing system 150 includes a suction duct 152, an internal blower 156, and a blowing fan 162. The suction duct 152 is disposed on the upper and lower portions of the drying chamber 110, that is, the upper surface of the upper chamber 116 and the lower surface of the lower chamber 116. Each of the suction ducts 152 is connected to an internal blower 156 disposed below the drying chamber 110, and the internal blower 156 is a downward blower tube 158 formed on the upper and side surfaces of each chamber 116. And it is connected to the side blower tube 160 to blow the preheated dry air in a direction perpendicular to the conveying direction of the object to facilitate dehumidification from the object to be dried. At this time, the air sucked into the suction duct 152 is the first dehumidifier 154 disposed on the upper surface of the drying chamber 110 to remove the moisture by removing the high-temperature humid humid air of the input hopper 112 side suction duct (152) flows into the interior.
1 and 2, the downwind pipe 158 connected to the inner blower 156 blows the preheated dry air blown from the inner blower 156 to the bottom of the downwind blower 158 through a hole in the lower portion of the belt. Air is blown at right angles from the top to the construction object coming from the type | mold far-infrared radiator 135 or the mesh net belt 146, and the side blower tube 160 connected with the internal blower 156 is preheated from the internal blower 156. The dry air is blown through the side hole blowing tube 160 side hole to blow air to the object to be dried at right angles from the side, and the side blowing fan 162 serves to smoothly blow.

In addition, a blower fan 162 is installed on one side or the other side of each chamber 116 in order to prevent heat loss of the dry air. At this time, each blowing fan 162 is equipped with a second dehumidifier 164 to dehumidify the humid air generated in the lower chamber 116. The blower fans 162 thus formed are pulled up from the bottom to the top while dehumidifying the hot and humid humid air generated in each chamber 116.

Hereinafter, the state of use of the continuous far-infrared drying apparatus 100 using the dehumidifying exhaust gas and the preheating air using the far infrared radiator and the dehumidifying apparatus formed as described above will be briefly described.

First, when the object to be dried is introduced into the input hopper 112, it is placed on top of the belt-type far infrared emitter 135 or the mesh net belt 146. At this time, the far-infrared radiated from the belt-like far-infrared radiator 135 or the plate-infrared radiator 180 disposed above the drying chamber 110 and the far-infrared radiated from the plate-like far-infrared radiator 180 disposed inside the mesh net belt 146. The dry matter is first dried by the far-infrared rays emitted from. Preferably, the far-infrared radiant heat radiated from the plate-like far-infrared radiator 180 disposed inside the belt-type far infrared radiator 135 or the mesh net belt 146 together with the transfer is irradiated upward, and at the same time the drying chamber 110 Far-infrared radiant heat is irradiated to the object from the plate-like far infrared radiator 180 disposed on the upper side to be dried in a bidirectional far-infrared irradiation method. On the other hand, in the lower chamber 116, the far-infrared radiation of the belt-type far infrared emitter 135 is irradiated in the up and down directions, or the plate-like far-infrared radiator 180 disposed inside the mesh net belt 146 is upper and lower. Far-infrared rays are irradiated in the direction, and the dry matters of the dry matters are second, third, fourth, etc. by the two-way far-infrared irradiation method, and high-quality dry matters are discharged to the outlet 114. At this time, the internal blower 156 that sucks the dehumidified dry air from the suction duct 152 to blow the air blower to the downwind duct 158 and the lateral blower 160 mounted in the respective chambers 116 is more effective and improves the thermal efficiency. Blow dry air in a direction perpendicular to the transported object. In addition, the blower fan 162 mounted on one side or the other side of each chamber 116 sucks and dehumidifies the humid air in the lower chamber 116 and pulls it up to the upper chamber 116.

As described above, the continuous far infrared drying device using the far infrared radiator and the dehumidification exhaust and the preheating air using the dehumidifying apparatus according to the present invention is equipped with a belt type far infrared radiator and a plate type far infrared radiator radiating far infrared rays, and using a dehumidifying apparatus. By introducing dehumidifying air into the drying room by injecting the drying air into the drying room, the up and side blower system can be used to shorten the drying time of the building in the drying room, reduce the energy consumption, and be an environmentally friendly electric energy source. By using it, there is an advantage to not only prevent the environmental pollution caused by the use of fossil fuels, but also to obtain high quality agricultural products and foods.

In addition, the continuous far-infrared drying apparatus using the dehumidifying exhaust air and the preheating air using the far-infrared radiator and the dehumidifying apparatus according to the present invention, by mounting a blowing fan including a dehumidifying apparatus on one side or the other side of each chamber formed inside the drying chamber, The dehumidified air can be used to dehumidify and be pulled upwards in the reverse order, which has the advantage of high thermal efficiency. Also, the drying efficiency can be increased by blowing in the downward and lateral directions inside each chamber by using an internal blower.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art can be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims You will understand.

Claims (5)

An input hopper and an outlet formed in one upper part and one lower part, a plurality of chambers formed in multiple stages while communicating in a zigzag form from the input hopper to the discharge hole, and a plate-like far-infrared radiator disposed above the uppermost chamber of each chamber; A drying chamber having a dry guide mounted on a communicating portion of each chamber; A pair of horizontally arranged to face each other on both sides of the chamber and a drive shaft equipped with a chain sprocket on an outer circumferential surface thereof, a belt-type far infrared radiator fastened to each of the chain sprockets facing each other, and the respective belt type The inner part of the far infrared radiator has a power supply shaft equipped with a power supply sprocket on the outer circumferential surface so as to be in close contact with the belt-type far infrared radiator. ; And A pair of suction ducts disposed on the upper and lower portions of the drying chamber and connected with a first dehumidifier, a pair of internal blowers connected to the respective suction ducts, and mounted on the upper and side surfaces of the respective chambers; A blower system having a down blower tube and a side blower tube connected to the inner blower, and a blowing fan mounted on one side or the other side of each chamber together with a second dehumidifier to transfer preheat to the upper chamber, Brushes are mounted on opposite sides of the respective chambers so as to face the respective building guides, and each drive shaft is coated with an insulating material on a contact surface with a chain sprocket, and the belt-type far infrared emitters are made of elvan or ocher and ceramic layers. Continuous far-infrared drying apparatus using the dehumidification exhaust and preheating air using the far-infrared radiator and the dehumidifier characterized in that it is formed. An input hopper and an outlet formed in one upper part and one lower part, a plurality of chambers formed in multiple stages while communicating in a zigzag form from the input hopper to the discharge hole, and a plate-like far-infrared radiator disposed above the uppermost chamber of each chamber; A drying chamber having a dry guide mounted on a communicating portion of each chamber; A pair of mounting shafts facing each other on both sides of the respective chambers, a drive shaft having a drum pulley mounted on an outer circumferential surface thereof, a mesh mesh belt wound around each drum type pulley facing each other, and a mesh mesh belt of the respective mesh mesh belts. A conveying portion formed of a plate-like far-infrared radiator arranged inside; And a pair of suction ducts disposed on the upper and lower portions of the drying chamber and connected to a first dehumidifier, a pair of internal blowers connected to the respective suction ducts, and mounted on the upper and side surfaces of the respective chambers. A blower system having a down blower tube and a side blower tube connected to the inner blower of the blower, and a blower fan mounted on one side or the other side of the respective chambers and a blower fan to transfer the preheating to the upper chamber. Each chamber is equipped with a brush on the opposite side to face the respective dry guide, the plate-like far infrared radiator is characterized in that the lamellar or loess and ceramic layers are formed, dehumidifying exhaust and preheating using a dehumidifier Continuous far infrared drying device using air. delete delete delete

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