KR20130053189A - Drier - Google Patents

Abstract

PURPOSE: A dryer is provided to independently supply dried hot air supplied in an independent drying room and to independently emit hot air emitted after drying without influencing dried goods in other drying rooms. CONSTITUTION: A dried hot air supplier (200) supplies dried hot air to a plurality of drying rooms (151, 152, 153). A path duct (510) circulates hot air emitted to entrances (511,512) from the drying rooms. A rear wall (500) and a front gate (300) include exits in which hot air flowed through the path duct are emitted. First and second heat exchangers (410, 430) heat-exchange waste hot air with external dried inhaled air emitted from the exits of the front gate and rear wall. An emission pipe (420) collects emitted waste hot air which is heat exchanged in first and second heat exchangers. A direction controller for air blast (422) supplies partial air to the dried hot air supplier and emits the rest of the air to outside. A guide tube (411) supplies external dried air which absorbes heat to the hot air supplier independently from exhaust waste hot air supplied to the hot air supplier by a direction controller for exhaust waste hot air.

Description

Dryer {Drier}

The present invention relates to a dryer.

Generally, a dryer is a device which embeds a to-be-dried thing in a drying chamber, and applies a drying hot air to a drying chamber, and performs drying.

Drying apparatuses are applied in various industries, and are produced and sold in various ways according to the respective fields of application.

For example, the agricultural and marine product dryers are for storing or drying various harvested agricultural and marine products, and Background Art Korean Laid-Open Patent Publication 2011-0070033 discloses a combined agricultural and aquatic product dryer.

Dryers are popular and are constantly being researched and developed to improve the quality of dried products and to reduce the drying cost by improving their function and composition.

The present invention constitutes a plurality of independent drying chambers in a drying space, and a structure in which the drying hot air supplied to the independent drying chamber and the hot air exhausted after drying are independently supplied and exhausted without affecting the dry items of the other drying chambers. By constructing a heat exchanger and a waste hot air exhaust blow direction controller on the top of the dryer, it is possible to shorten the drying time, improve the efficiency of the dryer and improve the quality of the building. In addition, by installing a far-infrared heating element directly under the dryer tray, it is to solve the problem of improving the quality and drying efficiency of the building.

According to the present invention,

A plurality of independent drying chambers on which the dry items are placed;

A dry hot air supply unit installed at a side of the plurality of drying chambers and supplying dry hot air to the plurality of drying chambers;

It is provided on the front and rear of the plurality of drying chambers, the inlet through which the hot air of the plurality of drying chambers are exhausted, a passage duct through which the hot air exhausted through the inlet flows and an outlet through which the hot air flows through the passage of the passage duct is discharged. Back walls and front doors;

Located between the first and second heat exchangers and the first and second heat exchangers in the upper portion of the drying chamber, the heat exchange with the waste hot air discharged from the outlet of the rear wall and the front door and the external dry suction air, A heat exchange part comprising an exhaust pipe collecting exhaust waste hot air heat exchanged in the second heat exchanger:

A waste hot air blowing direction controller for supplying some of the waste hot air collected in the exhaust pipe to the dry hot air supply unit according to temperature and moisture content, and discharging the remaining air to the outside;

Consists of a guide tube so that the external dry air absorbed heat in the first and second heat exchanger can always be supplied to the hot air air independently of the exhaust waste hot air supplied to the hot air supply by the exhaust waste hot air direction controller. do.

In addition, the far-infrared heating element made of a porous body is installed directly under the drying tray put into the plurality of drying chambers so that the far-infrared effect can be directly obtained:

A drying hot wind horizontal supply pipe installed below the plurality of drying chambers and configured to independently supply the drying hot air to each drying chamber;

The left and right vertical hot air supply pipes are installed in the horizontal supply pipe to supply dry hot air from the left and right sides.

In addition, a plurality of guide plates for guiding dry hot air to supply dry hot air to the left and right vertical supply pipes from the dry hot air supply unit are spaced apart from the bottom of the hot air supply unit at the bottom of the right dry hot air vertical supply pipe.

In addition, a collection space in which the waste hot air is collected so as to enter the waste hot air inlets formed on the rear wall and the front door (door) does not flow to the upper drying room after the drying of the drying chamber.

A guide plate is formed at the front door side of the collection space to secure a space for discharging waste hot wind, and a series of rectangular packing seats are formed at the front door of the guide plate, the front side of the horizontal hot air supply pipe, and the front side of the vertical hot air supply pipe. By smoothing the installed packing material and the pressing function to allow the plurality of drying chambers to act as independent drying spaces, all the drying materials are dried uniformly at the same time and the drying efficiency is increased.

That is, the guide plate is configured on the front door side of the collection space, and the packing material is installed on the front door so that the plurality of drying chambers can serve as independent drying spaces, and the packing material of the front door is formed of the guide plate. The front surface is in close contact with the front surface of the horizontal hot air supply pipe and the front surface of the vertical hot air supply pipe.

In addition, the drying hot air horizontal supply pipe has a porous through-hole through which dry hot air passes, and a heat insulating material is attached to the bottom of the horizontal hot water supply pipe.

In addition, the rear wall and the front door, as described above, prevent the waste hot air from flowing out or out of the drying chamber due to the gap between the front door and the rear wall and each drying room, and the 'dry hot air' and 'waste hot air' of each drying room are provided. By preventing the entry into other drying chambers, each drying chamber was able to act as an independent drying space, and rubber packing was installed on the contact plate to prevent the outflow when waste hot air from each drying chamber flows into the heat exchanger.

 In addition, inside the duct of the rear wall and the front door, a backflow prevention plate is installed to prevent the waste hot air of the lower drying chamber from flowing into the inlet of the plurality of drying chambers and prevent the flow back to the upper drying chamber entrance. The contact plate support of the duct (path room) may be deformed and the contact plate support is installed to prevent this.

In addition, the drying chamber is provided with a plurality of pedestals for supporting the tray for placing the object to be dried.

In addition, the plurality of pedestals are provided with a far infrared heating heater.

In addition, the far-infrared heat heater comprises: a structure consisting of a plurality of far-infrared radiating materials spaced apart from each other, and an insulator filled between the plurality of far-infrared radiating materials and having a plurality of openings; A structure consisting of a mesh-like far infrared radiation material pattern having a plurality of openings, and an insulator filled in the plurality of openings of the far infrared radiation material pattern and having a plurality of openings; One of a mesh-like far infrared emitting material structure having a plurality of openings.

The present invention constitutes a plurality of independent drying chambers in a drying space, and allows the drying hot air to be independently supplied to the independent drying chambers by horizontal supply pipes, and a waste hot air passage duct provided as exhaust inlets, passages, and outlets on the front and rear walls of the dryer. Exhaust Hot Air of Independent Drying Room The waste hot air is exhausted without affecting the dry items in other drying room, so that drying time can be shortened and all dry items can be dried at the same time, improving the quality of the building, reducing drying time and labor. It can be effective.

In addition, the present invention has a far-infrared heat generating heater in the movement path of the dry hot air, install a far-infrared heat generating heater having a porous structure that allows the hot air to pass through the lower part of the tray on which the object is placed, the flow of hot air smoothly While far-infrared rays can be directly radiated to the dry matter of the cultivation, there is an effect of doubling the quality and drying efficiency of the dry matter.

And, by configuring the heat exchanger and the exhaust waste hot air directional regulator on the drying chamber there is an effect of energy saving and shortening the drying time.

1 is a schematic perspective view of a dryer according to the present invention
2a and 2b is a schematic perspective view for explaining the configuration of the dryer according to the present invention
3a to 3d are schematic different perspective views for explaining the configuration of the dryer front door and the rear wall according to the present invention
Figure 4 is a perspective view for explaining the heat exchanger and the exhaust blower and the blowing direction regulator of the dryer according to the invention.
5a to 5c are schematic diagrams for explaining the operating principle of the exhaust blow regulator of the dryer according to the present invention;
6A is a cross-sectional view of the AB of FIG. 1, and FIG. 6B is a cross-sectional view of the CD of FIG. 1.
7 is a schematic view of a horizontal hot pipe.
Figure 8a is a schematic cross-sectional view for explaining the drying hot air movement path of the dryer according to the present invention
Figure 8b is a schematic cross-sectional view for explaining the drying hot air movement path of the dryer according to the present invention
9A to 9C are schematic views for explaining the structure of a far-infrared heat heater applied to the present invention.

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

In this process, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms specifically defined in consideration of the structure and operation of the present invention may vary depending on the intention or custom of the user, the operator. Definitions of these terms should be based on the content of this specification.

Figure 1 is a schematic perspective view of a dryer according to the present invention, Figure 2a is a front perspective view, Figure 2b is a schematic perspective view for explaining the configuration of the dryer according to the invention on the back wall side.

As shown in FIG. 1, the dryer of the present invention has a front door 100 at the front, a rear wall 500 at the rear, and a hot air supply unit 200 and a hot air supply unit at the right side of the inner drying chamber 100. There is a controller 250, the heat exchanger 400 consisting of the first, second heat exchanger (410, 430) and the exhaust pipe 420 in the upper portion and the exhaust amount regulator 422 for adjusting the waste hot air exhaust amount on the right side.

2A and 2B are detailed views of the present invention, the dryer according to the present invention includes a plurality of drying chambers (151, 152, 153) in which the object is placed;

 A plurality of drying hot air horizontal supply pipes (101, 102, 103) installed below the plurality of drying chambers (151, 152, 153) to supply hot air upwardly to the plurality of drying chambers (151, 152, 153); Left and right vertical air supply pipe (90) and rainwater direct supply pipe (80) for supplying dry hot air to the plurality of horizontal supply pipe (101, 102, 103) on the left and right of the horizontal hot air supply pipe (101, 102, 103):

A first hot air inlet plate 161 for supplying dry hot air to the rainwater supply pipe 80, a bottom horizontal heat supply pipe 91 and a third hot air inlet plate for supplying dry hot air to the left vertical supply pipe 90 ( 163) and a second hot air inlet plate 162 for supplying dry hot air to the lowermost horizontal heat supply pipe 101:

A hot air supply unit 200 including the hot air inflow plate 161, 162, 163, a heat transfer heater 220 for heating air to supply drying hot air, and a blower 210 for flowing the heated air to a drying chamber; ;

A collection space (113, 114, 115) in which the waste hot air gathers to enter the waste hot air inlets formed on the rear wall and the front door without drying the waste hot air after the drying above the plurality of drying chambers and the horizontal supply pipe;

Guide plates (110, 111, 112) on the front door 300 side of the collection space (113, 114, 115) to secure the waste hot air discharge space, to prevent the encroachment of the collection space due to overloading of the dry to the tray, the guide plate ( A packing material 320 installed in the front door 300 and a crimping function are configured by forming a series of rectangular packing seats including a front surface of the 110, 111 and 112, a front surface of the horizontal hot air supply pipes 101, 102 and 103, and a front surface of the vertical hot air supply pipes 90 and 80. Make it smooth.

In addition, a plurality of pedestals (123) for supporting the drying tray 10 is put into the plurality of drying chamber (151, 152, 153); Far infrared ray heating element 600 is installed horizontally with the pedestals 123 to enable direct irradiation of far-infrared rays which can improve the drying quality of the dry matter of the tray and smooth the flow of drying hot air. ) Is installed.

In addition, the hot air flowing into the inlet (311, 312), the inlet (311, 312) is installed on the front of the plurality of drying chamber (151, 152, 153), the waste hot air collected in the collection space (113, 114) of the plurality of drying chamber (151, 152, 153). The front door is provided with a hot air passage duct 310 composed of a passage through which the circulation flows and the hot air flowing into the heat exchanger 410 is discharged to the heat exchanger 410, and a packing structure 320 capable of packing between the front door and the drying chamber. 300;

As shown in FIG. 2B, the inlet 511 and 512 are installed at the rear of the plurality of drying chambers 151, 152 and 153 and the waste hot air collected in the collection spaces 113 and 114 of the plurality of drying chambers 151, 152 and 153 and the inlets 511 and 512. Hot air passage duct 510 consisting of a passage through which the waste hot air flows and a hot air flowed through the passage to the heat exchanger 430, and a packing structure 520 for packing the rear wall and the drying chamber. Is provided with a back wall 500 is provided. Meanwhile, the waste hot air collected in the collection space 115 of the uppermost drying chamber 153 among the plurality of drying regions 151, 152, 153 is exhausted directly from the top to the inlet of the heat exchanger 410, 430 without passing through the front door and the rear wall. 314,514.

The first and second heat exchangers 410 and 430 are disposed above the drying chamber to exchange heat with the waste hot air discharged from the outlets 313 and 513 of the rear wall 500 and the front door 300 and the external dry suction air. A heat exchanger (400) positioned between an inlet and the first and second heat exchangers, the exhaust pipe (420) collecting exhaust waste hot air heat exchanged in the first and second heat exchangers;

The waste hot air directional controller for supplying the waste hot air collected in the exhaust pipe 420 to the dry hot air supply unit to an exhaust blower 421 to the dry hot air supply unit according to the temperature and the amount of moisture, and the remaining air to be discharged to the outside ( 422);

Guide pipes 411 and 412 which allow external dry air absorbing heat from the first and second heat exchangers to always be independently supplied to the hot air blowing unit regardless of the discharge waste hot air supplied to the hot air supply unit by the discharge waste hot air direction controller. It is composed of

Therefore, in the dryer according to the present invention, the hot hot air supplied to the left and right hot air vertical supply pipes 90 and 80 by the dry hot air guide plate is supplied with the dry hot air heated by the heat transfer heater 220 in the dry hot air supply unit 200. The heat is supplied to the hot air horizontal supply pipe (115, 114, 113), the hot air supplied to the plurality of drying chambers (151, 152, 153) as a horizontal pipe and the heat generated from the far-infrared heating element (600) installed in the plurality of pedestals in the plurality of drying chambers. The dry items placed in the plurality of drying chambers 151, 152, 153 are dried. At this time, the dryer of the present invention can increase the dry quality of the dry matter, because the far infrared heat of the far infrared heating element 600 is directly irradiated from the lower and upper portion of the dry matter, and dried alone in accordance with the required dry heat amount of the dry matter. Drying may be carried out or mixed with a hot air heater.

In addition, the dryer of the present invention is composed of a plurality of drying chambers, unlike the drying chamber structure of the conventional dryer, and configured to receive fresh hot wind and far infrared heat without moisture supplied from the horizontal hot air supply pipes 101, 102, 103 for each drying chamber independently, By constructing the waste hot air dried in each drying room through the front door and the back wall instead of passing through to the upper drying room, it is possible to simultaneously and uniformly dry the dry items in an independent space, which shortens the drying time and The non-uniform drying of the building helps to solve the labor input problem of changing the position of the tray during the drying process.

The packing function of the packing structures 320 and 520 installed on the front door and the rear wall described above is a structure which ensures the function as an independent drying space of the plurality of drying chambers described above, and the front door 300 and the rear wall 520 and each drying chamber. The gap between the 151, 152 and 153 prevents the waste hot air from flowing out or out of the drying chamber without entering the duct passages of the front door 300 and the rear wall 520, and the 'dry hot air' and 'closure' of each drying chamber. It prevents the 'hot air' from flowing into other drying chambers so that each drying chamber can serve as an independent drying space.

In addition, the present invention by installing the heat pipe portion 400 in the upper part of the dryer 'dry hot air' dried in the plurality of drying room is introduced into the inlet of the front door and the rear wall, the outlet through the duct passage of the front door and the rear wall exit By being exhausted into the heat exchanger, the low temperature external suction air for drying is heated by heat exchange with 'waste hot air' to supply the dry hot air supply to the dry hot air supply, thereby reducing drying cost and increasing efficiency. At this time, the exhaust blower 421 installed in the heat exchange unit is installed to facilitate the discharge of the waste hot air because the flow resistance is generated when the waste hot air passes through the front door, the rear wall, and the heat integrator, and the exhaust blow direction controller 422 is dried. According to the degree of moisture of the waste hot air in the process by discharging all the outside or by sending a portion back to the heat supply unit 200 to configure the function to recycle to reduce the drying cost doubled.

3A to 3D are schematic perspective views for explaining the configuration of the dryer front door and the rear wall according to the present invention.

3A is a structure of the waste hot air duct passage 310 of the front door, and FIG. 3B is a structure of the waste hot air duct passage 510 of the rear wall.

The waste hot air duct passages of the front door and the rear wall have the same structure except for the packing structure as shown in FIGS. 3A and 3B. The exterior of the front door and the rear wall have the inlet (311, 312, 511, 512) through which the waste hot air flows and the passage ducts through which the waste hot air flows. Outlets 313 and 513 are formed to discharge the waste hot air to the heat integrators 410 and 430. A packing structure 320 is installed in the drying chamber contact plate 314 of the front door and the packing of the drying room contact plate 514 of the rear wall. Seat 540 is fixed to the packing seat of the drying chamber and the adhesive material, Figure 3c is an internal structure and Figure 3d is a waste heat to the drying chamber of the upper floor while the waste hot air of the lower floor rises in the duct passage 301 in the EF cross-sectional view of Figure 3a. In order to prevent the inflow of the waste hot air backflow prevention plate (350,550), and the packing structure 320 of the drying chamber contact plate (314,514) in the process of pressing with the packing seat of the drying chamber deformation of the drying chamber contact plate (314,514) Prevent this from happening It was placed in contact with the support plate (370, 570). In addition, the cover plate (330,530) and the outer frame (350.550) of the front door and the rear wall is composed of a heat insulating material.

Figure 4 is a perspective view for explaining the heat exchange unit and the exhaust blow direction controller of the dryer according to the present invention, Figures 5a to 5c is a schematic diagram for explaining the operating principle of the exhaust blow regulator of the dryer according to the present invention.

As shown, the dryer of the present invention, the heat exchange unit 400 is the waste hot air (450,451) and the external suction air for drying 440 discharged from the outlets (313,513) of the front door 300 and the rear wall (500) First and second heat exchangers 410 and 430 are installed so as to exchange heat with each other, and are positioned between the first and second heat exchangers 410 and 430, and heat exchange in the first and second heat exchangers 410 and 430. The exhaust pipe 420 collects the waste hot air 452 and discharges it to the outside, and guide pipes 411 and 412 for guiding the external external suction air 441 and 442 heated by heat exchange to flow into the hot air supply unit 200. In addition, an exhaust blower 412 is installed in the exhaust pipe 420 so that the dry waste hot air passes through the front door duct passage 301 and the rear wall duct passage 501 to pass the first and second heat exchangers, thereby increasing the flow resistance. As a result, smooth waste hot air is exhausted.

And it is installed in front of the exhaust blower 412 to discharge the waste hot air from the exhaust blower 412 from the outside in accordance with the degree of moisture to the outside or to send a portion back to the heat supply unit 200 to recycle to reduce the drying cost An exhaust blowing direction controller 422 that can function is configured.

That is, Figures 5a to 5c is a schematic diagram for explaining the operating principle of the exhaust blow direction controller 422 according to the present invention. In the early stage of the drying process, the exhaust waste hot air contains a lot of moisture, so that the entire amount of waste hot air must be discharged to the outside while blocking the inflow of the waste waste hot air to the dry hot air supply unit 200 at the lower side of the blowing direction controller as shown in FIG. The blowing direction controller 422 is adjusted by operating the blowing amount adjusting lever 423 so as to completely exhaust the whole amount to the outside, and as shown in FIG. 5B, the blowing amount adjusting lever 423 is set at a predetermined angle according to the degree of moisture of the waste heat. By adjusting the blowing direction controller 422, a part of the exhaust hot air is discharged to the outside and a part of the exhaust hot air flows into the dry hot air supply unit 200 to be recycled. In addition, in the latter half of the drying section with less moisture in the waste hot air during the drying process, the exhaust blow direction controller 422 blocks the exhaust waste hot air discharged to the outside and transfers all the heat-exchanged air to the dry hot air supply unit 200. Supply to allow complete recirculation to reduce drying costs.

6A is a cross-sectional view taken along the line A-B of FIG. 1, and FIG. 6B is a cross-sectional view taken along the line C-D of FIG. 1.

6a is a cross-sectional structure having a heat exchanger at the top and 6b is a cross-sectional structure having an exhaust pipe 420 at the top. 6A and 6B are identical in structure except for the upper portion. As shown in the drawing, the dry hot air supply unit 200 includes a blower 210 and an electric heater 220 in a predetermined space, and heats the air drawn by the blower with an electric heat heater to dry the hot air for drying the plurality of drying chambers 151. 152, 153). At this time, the drying air flowing into the blower 210 is configured to combine the two types of air to be supplied to the heat transfer heater 220, one of the heat exchanger (drying air flowing out of the dryer as shown in Figure 6a) 410, 430 is the air heated by absorbing the heat of the waste hot air, the other is the dried waste hot air (exhaust hot air) from the drying chamber through the front door and the rear wall duct passage (310, 510) as shown in Figure 6b The exhaust blower 421 is configured to be collected in the exhaust pipe 420 by passing through the air 410, and the air to send some or all of the waste hot air to the blower 210 by the exhaust blow controller 422 according to the temperature and the amount of moisture. to be.

The air collected in the heat supply unit is heated by the heat transfer heater 220 and the drying hot air is supplied to the plurality of drying chambers 151, 152, and 153 by the blower 210. And hot air vertical supply pipes 90 and 80 on the left and right sides of the hot air vertical supply pipes 153 to supply the hot air vertical feed pipes 90 and 80 to the left and right sides through the hot air guide plates 161 and 162. Is supplied to the hot air horizontal supply pipes (101, 102, 103) from the left and right, and the hot air supplied to the horizontal heat supply pipe is discharged to the upper side of the tray to be supplied to each drying chamber. Meanwhile, the guide plate “163” is installed to supply dry hot air to the lowermost horizontal heat supply pipe 104. Further, the far infrared heating element 600 is disposed directly below a drying tray installed in a plurality of drying chambers 151, 152, and 153. By installing the irradiated far infrared heat from the upper and lower parts of the dry matter contained in the tray, the sterilization of the dried matter and the drying of the inside and the outside of the dried product can be seen at the same time, and the far infrared can be directly irradiated to increase the drying efficiency. have.

7 is a perspective view of the hot air horizontal supply pipe (101, 102, 103) structure. The hot air horizontal supply pipe has a rectangular duct shape, and the upper plate is composed of a perforated plate 71 so as to uniformly supply hot air to the dry matter of the tray. The lower plate 73, the lower outer surface was composed of a reflective insulating material (74). The reflective insulating material 74 is a hot waste hot air in the exhaust pipe 72 as the space is collected in the bottom of the horizontal supply pipe (101, 102, 103), that is, the bottom plate 73, the bottom when the hot air passes through the vent pipe 72 It functions to prevent the influence of drying hot air.

Figure 8a is a schematic cross-sectional view for explaining a drying hot air movement path of the dryer according to the present invention. 8B is a schematic cross-sectional view for describing a waste hot wind moving path of the dryer according to the present invention.

In FIG. 8A, the arrow indicates the moving direction of the drying hot air. As shown in FIG. 8A, the external air preheated by the heat exchanger supplied to the heat portion and some waste hot air air are heated to the heat transfer heater 220 by the blower 210, and the heated air is heated by the guide plates 161, 162 and 163. It is supplied to the vertical supply pipe (90, 80), the drying hot air is supplied to the horizontal supply (101, 102, 103) by the left and right vertical supply pipe (90, 80) from the left and right, the horizontal supply (101, 102, 103) The drying hot air moves to the left and right while passing through the dry matters of the tray, and the drying hot air absorbed moisture while passing through the dry matter becomes waste hot air and collects in the waste hot air collection spaces 113, 114, and 115.

At this time, the far-infrared heat generating heaters 600 installed on the pedestal 123 on which the tray is placed are installed between the upper and lower sides of the tray, thereby drying the dry object together with the drying hot air. In addition, the structure of the far-infrared heating element may be a porous body or a plurality of passages so that the dry hot air can pass through the dry matter contained in the trays.

 8B is a cross-sectional view for describing a waste hot wind moving path of the dryer of the present invention.

Arrow direction in the figure indicates the movement direction of the waste hot air.

In the above technique, the waste hot air flows into the waste hot air inlets 311, 312, 511, and 512 formed in the front door 300 and the rear wall 500 in the state of gathering the waste hot air collection spaces 113, 114, and 115. Ascending through the duct path 310 is discharged to the first and second heat exchangers (410, 430) through the waste hot air outlet (313, 513). At this time, the waste hot air of the collection space 115 of the uppermost layer is directly introduced into the first and second heat exchangers 410 and 430 through the upper spaces 314 and 514 without entering the front door and the rear wall. In addition, when the waste hot air from the lower layers 311 and 511 rises, it may be introduced into the drying chamber of the upper layer, thereby preventing the countercurrent phenomenon by installing the backflow preventing plates 360 and 560. And the waste hot air passing through the heat exchanger is preheated by the heat exchange dry air coming from the outside is collected in the exhaust pipe (420).

9A to 9C are schematic views for explaining the structure of a far-infrared heat heater applied to the present invention.

Far infrared heating heater applied to the present invention, first, as shown in Figure 9a, a plurality of far-infrared heat generating materials 615a, 615b, 615c spaced apart from each other; The plurality of far-infrared heat generating materials 615a, 615b, and 615c may be filled between the insulator 610 having a plurality of openings 611.

In addition, as shown in Fig. 9b, the mesh-like far-infrared heat generating material pattern 620 having a plurality of openings; The graphite pattern 620 may be implemented to have a structure including an insulator 610 filled in a plurality of openings and having a plurality of openings 611.

In addition, as shown in Figure 9c, it may be implemented as a mesh-like far-infrared heat generating material structure 650 having a plurality of openings (651).

In this case, electrodes 710 and 720 are connected to both ends of the plurality of far-infrared heat generating materials 615a, 615b and 615c of FIG. 9A, and the graphite pattern 62 and the graphite rod structure 650 of FIG. 9B.

Although embodiments according to the present invention have been described above, these are merely exemplary, and those skilled in the art will understand that various modifications and equivalent embodiments of the present invention are possible therefrom. Accordingly, the true scope of the present invention should be determined by the following claims.

Claims (12)

A plurality of drying chambers in which the dry items are placed;
A dry hot air supply unit installed at side surfaces of the plurality of drying chambers and supplying dry hot air to the plurality of drying chambers;
A rear wall provided at the front and rear surfaces of the plurality of drying chambers, the inlet through which hot air of the drying chamber is exhausted, a passage duct through which hot air exhausted through the inlet flows, and an outlet through which hot air of the passage duct is discharged; Front door;
A first heat exchanger and a second heat exchanger disposed at an upper portion of the drying chamber and configured to heat exchange the waste hot air and the external dry suction air discharged from the outlets of the rear wall and the front door, and between the first and second heat exchangers. A heat exchange part configured of an exhaust pipe collecting exhaust waste hot air heat exchanged in the second heat exchanger;
And a waste hot air blowing direction controller for supplying some of the waste hot air collected in the exhaust pipe to the dry hot air supply unit according to temperature and moisture content, and discharging the remaining air to the outside.
The method according to claim 1,
It further includes a guide tube for allowing the external dry air absorbed heat in the first and second heat exchanger to be independently supplied to the hot air air portion irrespective of the exhaust waste hot air supplied to the hot air supply by the exhaust waste hot air direction controller. Configured by the dryer.
The method according to claim 2,
Far infrared ray heating element made of a porous body so that it is installed under the drying tray that is put into the plurality of drying chambers so that the far infrared effect can be directly obtained:
A drying hot wind horizontal supply pipe installed below the plurality of drying chambers and configured to supply dry hot air to each of the plurality of drying chambers independently:
And a left and right vertical hot air supply pipe configured to supply dry hot air to the horizontal supply pipe from left and right sides.
The method according to claim 3,
And a plurality of guide plates for guiding dry hot air so as to supply dry hot air to the left and right vertical supply pipes from the dry hot air supply part, spaced apart from the bottom of the hot air supply part at the bottom of the right dry hot air vertical supply pipe.
The method according to claim 3,
And a collection space in which the waste hot air gathers to enter the waste hot air inlets formed on the rear wall and the front door without drying the waste hot air into the upper drying chamber after drying.
The method according to claim 5,
The guide plate is configured on the front door side of the vowel space,
In order for the plurality of drying chambers to serve as independent drying spaces,
Packing material is installed in the front door,
The packing material of the front door,
A front surface of the guide plate, the dryer is in close contact with the front surface of the horizontal hot air supply pipe and the vertical hot air supply pipe.
The method according to claim 3,
In the upper part of the dry hot air supply pipe is formed through holes through which the dry hot air can pass,
And a heat insulating material having a flat plate structure attached to a lower portion of the dry hot air supply pipe.

The method according to claim 1,
The gap between the front door and the rear wall and each drying chamber prevents waste hot air from flowing out of the drying chamber,
The front door and the rear wall is provided with a rubber packing to prevent the outflow to the outside when the waste hot air from the respective drying chambers flow into the heat exchanger.
The method according to claim 1,
Inside the duct of the rear wall and the front door, a backflow prevention plate is installed to prevent the waste hot air of the lower drying chamber from flowing back into the inlet of the upper drying chamber.
And the front door is provided with a contact plate support for preventing the deformation of the contact plate of the duct when the front door is compressed with the drying chamber.
The method according to claim 1,
And a plurality of pedestals for supporting a tray for placing the object on each of the plurality of drying chambers.
The method of claim 10,
A dryer equipped with a far-infrared heat heater in the plurality of pedestals.
The method of claim 11,
The far infrared heating heater,
A structure comprising a plurality of far-infrared radiating materials spaced apart from each other, and an insulator filled between the plurality of far-infrared radiating materials and having a plurality of openings; A structure consisting of a mesh-like far infrared radiation material pattern having a plurality of openings, and an insulator filled in the plurality of openings of the far infrared radiation material pattern and having a plurality of openings; A dryer comprising one of a mesh-shaped far infrared emitting material structure having a plurality of openings.

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