CN110986488A

CN110986488A - Formaldehyde adsorption particle drying equipment

Info

Publication number: CN110986488A
Application number: CN201911165203.5A
Authority: CN
Inventors: 张铭
Original assignee: Huzhou Wuxing Yimao Technology Development Co ltd
Current assignee: Huzhou Wuxing Yimao Technology Development Co ltd
Priority date: 2019-11-25
Filing date: 2019-11-25
Publication date: 2020-04-10

Abstract

The invention discloses formaldehyde adsorption particle drying equipment, which structurally comprises a feed hopper, a boiling drying device, an outer support, an air guide bent pipe, an air blower, a bottom frame, a discharge nozzle, a discharge inclined pipe and a motor, and has the following effects: boiling drying device mainly comprises flow state drying mechanism and wind pressure output mechanism, flow state drying mechanism and wind pressure output mechanism cooperate, the air current flow state boiling blowout structure that flow state drying mechanism and wind pressure output mechanism formed, can make the air after the heat conduction pole heating, form in the hot-blast entering inner tube, because the effect of wind pressure, the formaldehyde adsorbed particle forms the boiling state in the inner tube, and carry out extensive contact with the hot-air, take away along with the exhaust after the moisture content rapid evaporation, thereby can accomplish and carry out synchronous stoving to a large amount of formaldehyde adsorbed particles in short time, improve the production efficiency of formaldehyde adsorbed particle, reduce formaldehyde adsorbed particle manufacturing cost.

Description

Formaldehyde adsorption particle drying equipment

Technical Field

The invention relates to the field of formaldehyde cleaning, in particular to formaldehyde adsorption particle drying equipment.

Background

The formaldehyde adsorption particles are used for adsorbing formaldehyde, the formaldehyde adsorption particles contain a little moisture in the production process, the moisture can influence the formaldehyde adsorption effect of the formaldehyde adsorption particles and can reduce the service life of the formaldehyde adsorption particles, therefore, before the formaldehyde adsorption particles leave a factory, the formaldehyde adsorption particles need to be dried, the existing drying mode has a simple structure and a poor drying effect, which is not beneficial to synchronously drying a large amount of formaldehyde adsorption particles, after a large amount of formaldehyde adsorption particles are dried, the humidity detection procedure of the formaldehyde adsorption particles is often needed to be added, the production cost of the formaldehyde adsorption particles is improved, therefore, a formaldehyde adsorption particle drying device needs to be developed, the problems that the existing drying mode has a simple structure and a poor drying effect, and is not beneficial to synchronously drying a large amount of formaldehyde adsorption particles are solved, after a large amount of formaldehyde adsorption particles are dried, and the humidity detection process of the formaldehyde adsorption particles is also required to be added, so that the production cost of the formaldehyde adsorption particles is increased.

Summary of the invention

Aiming at the defects of the prior art, the invention is realized by the following technical scheme: a formaldehyde adsorption particle drying device structurally comprises a feeding hopper, a boiling drying device, an outer support, an air guide bent pipe, an air blower, an underframe, a discharging nozzle, a discharging inclined pipe and a motor, wherein the outer support is arranged at the top of the underframe and connected with the underframe, the boiling drying device is arranged at the top of the outer support and installed on the outer support, the discharging inclined pipe is arranged at the bottom of the boiling drying device and connected with the boiling drying device, the discharging nozzle is arranged at the rear end of the outer support and connected with the discharging inclined pipe, the air blower is arranged at the bottom of the outer support and installed on the outer support, the air guide bent pipe is arranged at the air outlet end of the air blower, the air blower is connected with the boiling drying device through the air guide bent pipe, the motor is arranged at the center of the outer support, the motor is matched with the boiling drying device, a feed hopper is arranged at the top of the boiling drying device, and the feed hopper is connected with the boiling drying device.

As the further optimization of this technical scheme, fluidized drying device constitute by flow state drying mechanism, wind pressure output mechanism, base, urceolus bottom be equipped with the base, base and urceolus connect, the inside flow state drying mechanism that is equipped with of urceolus, base below be equipped with wind pressure output mechanism, wind pressure output mechanism and the cooperation of flow state drying mechanism.

As the further optimization of this technical scheme, flow state drying mechanism by top cap, jetting bull stick, strain the gas and go out fan housing, inner tube, stirring round bar, interior activity ring and constitute, the inner tube top be equipped with the top cap, top cap and inner tube swing joint, the top cap install at the urceolus top, top cap top central point put and be equipped with and strain the gas and go out the fan housing, strain the gas and go out fan housing and top cap connection, the inner tube inner wall on even equidistance distribute have the stirring round bar, inner tube central point put and be equipped with the jetting bull stick, the jetting bull stick install on the top cap perpendicularly, inner tube bottom be equipped with interior activity ring, interior activity ring and inner tube connect.

As a further optimization of the technical scheme, the blowing rotating rod consists of a heater, a connector, a blowing rod, a heat conducting rod and blowing holes, the blowing holes are uniformly and equidistantly distributed on the blowing rod, the blowing holes and the blowing rod are of an integrated structure, the top end of the blowing rod is provided with the connector, the connector is movably connected with the blowing rod, the connector is fixedly connected with the top cover, the heater is arranged at the top of the connector, the heat conducting rod is arranged at the center of the blowing rod, and the heat conducting rod penetrates through the connector and is connected with the heater.

As the further optimization of this technical scheme, wind pressure output mechanism constitute by inner fixed plate, guide housing, go up a ring section of thick bamboo, a lower ring section of thick bamboo, transmission wind pressure frame top be equipped with a ring section of thick bamboo, the interior circle of going up a ring section of thick bamboo on circle and be equipped with an inner fixed plate, inner fixed plate and a last ring section of thick bamboo connect, the inner fixed plate top be equipped with the guide housing, last ring section of thick bamboo outer lane and interior activity ring swing joint, last ring section of thick bamboo bottom be equipped with a lower ring section of thick bamboo, a lower ring section of thick bamboo and last ring section of thick bamboo connect.

As the further optimization of this technical scheme, transmission wind pressure frame constitute by branch, driving plate, wind ring, fresh air inlet, tuber pipe, driving plate central point put and be equipped with the tuber pipe, tuber pipe and driving plate connect, the tuber pipe both sides be equipped with branch, branch install perpendicularly on the driving plate, branch and base swing joint, the driving plate pass through branch and inner tube outer wall connection, driving plate below be equipped with the wind ring, wind ring and tuber pipe pass through the bearing and connect, the link evenly distributed of wind ring and tuber pipe have the fresh air inlet, fresh air inlet and tuber pipe structure as an organic whole.

Advantageous effects

The formaldehyde adsorption particle drying equipment disclosed by the invention is reasonable in design and strong in functionality, and has the following beneficial effects:

the boiling drying device mainly comprises a flow-state drying mechanism and a wind pressure output mechanism, wherein the flow-state drying mechanism is matched with the wind pressure output mechanism, and an airflow flow-state boiling ejection structure formed by the flow-state drying mechanism and the wind pressure output mechanism can ensure that air is heated by a heat conducting rod to form hot air to enter an inner barrel;

the inner cylinder and the blowing rod rotate under the driving torque generated by the motor, formaldehyde adsorption particles poured into the inner cylinder are repeatedly stirred by the stirring round rod arranged on the inner wall of the inner cylinder, so that the formaldehyde adsorption particles are suspended in the inner cylinder all the time, air sprayed by the blower enters the blowing rod along the air guide bent pipe, the air ring and the air pipe, and after the air is heated by the heat conduction rod, hot air is formed and sprayed out of blowing holes arranged on the surface of the rotating blowing rod at a high speed, so that each formaldehyde adsorption particle is fully contacted with the hot air, a boiling state is formed in the inner cylinder, and moisture is rapidly evaporated and then taken away from the air filtering and air outlet cover along with exhaust.

The movable structure formed by the inner movable ring, the upper ring cylinder and the inner fixed plate can enable the inner cylinder to stably rotate along the movable groove at the bottom of the top cover under the driving torque generated by the motor, and formaldehyde adsorption particles in the inner cylinder can be quickly concentrated by utilizing a hollow hemispherical structure formed by the guide cover through the guide cover, the upper ring cylinder and the lower ring cylinder, can efficiently flow into the upper ring cylinder and the lower ring cylinder along the guide cover, can slide downwards along the discharge inclined tube, and are finally discharged from the discharge nozzle in order.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic diagram showing a front view of a formaldehyde adsorbent particle drying apparatus according to the present invention;

FIG. 2 is a schematic sectional view of the fluidized drying apparatus according to the present invention;

FIG. 3 is a schematic cross-sectional view of a fluidized drying mechanism according to the present invention;

FIG. 4 is a schematic cross-sectional view of the blowing rotary rod of the present invention;

FIG. 5 is a schematic front view of the wind pressure output mechanism of the present invention;

fig. 6 is a front view of the driving wind pressure frame of the present invention.

In the figure: a feed hopper-1, a boiling drying device-2, a fluid state drying mechanism-21, a top cover-21 a, an injection rotating rod-21 b, a heater-21 b1, a joint-21 b2, an injection rod-21 b3, a heat conducting rod-21 b4, an injection hole-21 b5, a filtered air outlet hood-21 c, an inner cylinder-21 d, a stirring round rod-21 e, an inner movable ring-21 f, a wind pressure output mechanism-22, an inner fixed plate-22 a, a guide hood-22 b, an upper cylinder-22 c, a lower cylinder-22 d, a transmission wind pressure frame-22 e, a support rod-22 e1, a transmission disc-22 e2, a wind ring-22 e3, an air inlet hole-22 e4, an air pipe-22 e5, a base-23, an outer cylinder-24, an outer support-3, an air guide elbow-4, a heat exchanger, An air blower-5, a bottom frame-6, a discharge nozzle-7, a discharge inclined tube-8 and a motor-9.

Detailed Description

In order to make the technical means, the original characteristics, the achieved purposes and the effects of the invention easy to understand, the following description and the accompanying drawings further illustrate the preferred embodiments of the invention.

Example 1

Referring to fig. 1-4, the present invention provides an embodiment of a formaldehyde adsorbing particle drying apparatus:

referring to fig. 1, a formaldehyde adsorption particle drying device structurally comprises a feed hopper 1, a boiling drying device 2, an outer support 3, an air guide bent pipe 4, an air blower 5, an underframe 6, a discharge nozzle 7, a discharge inclined pipe 8 and a motor 9, wherein the top of the underframe 6 is provided with the outer support 3, the outer support 3 is connected with the underframe 6, the top of the outer support 3 is provided with the boiling drying device 2, the boiling drying device 2 is arranged on the outer support 3, the bottom of the boiling drying device 2 is provided with two parallel and equidistant discharge inclined pipes 8, the discharge inclined pipe 8 is connected with the boiling drying device 2, the rear end of the outer support 3 is provided with the discharge nozzle 7, the discharge nozzle 7 is connected with the discharge inclined pipes 8, the bottom of the outer support 3 is provided with two air blowers 5 in an axial symmetry structure, the air blowers 5 are arranged on the outer support 3, the air outlet end of the air blower 5 is provided with the air guide bent pipe 4, air-blower 5 connect with boiling drying device 2 through wind-guiding

return bend

4, 3 central point of outer support put and be equipped with motor 9, motor 9 and boiling drying device 2 cooperate, 2 tops of boiling drying device be equipped with feeder hopper 1, feeder hopper 1 and boiling drying device 2 connect.

Referring to fig. 2, the fluidized drying device 2 is composed of a fluidized drying mechanism 21, a wind pressure output mechanism 22, a base 23, and an outer cylinder 24, wherein the base 23 is disposed at the bottom of the outer cylinder 24, the base 23 is connected to the outer cylinder 24, the fluidized drying mechanism 21 is disposed in the outer cylinder 24, the wind pressure output mechanism 22 is disposed below the base 23, and the wind pressure output mechanism 22 is matched with the fluidized drying mechanism 21.

Referring to fig. 3, the fluid state drying mechanism 21 is composed of a top cover 21a, a blowing rotating rod 21b, an air filtering and air outlet cover 21c, an inner cylinder 21d, a stirring round rod 21e and an inner movable ring 21f, the top cover 21a is arranged at the top of the inner cylinder 21d, the top cover 21a is movably connected with the inner cylinder 21d, the top cover 21a is installed at the top of the outer cylinder 24, the air filtering and air outlet cover 21c is arranged at the center of the top cover 21a, the air filtering and air outlet cover 21c is connected with the top cover 21a, the stirring round rods 21e are uniformly distributed on the inner wall of the inner cylinder 21d at equal intervals, the blowing rotating rod 21b is arranged at the center of the inner cylinder 21d, the blowing rotating rod 21b is vertically installed on the top cover 21a, the inner movable ring 21f is arranged at the bottom of the inner cylinder 21d, and the inner movable ring 21 f.

Referring to fig. 4, the blowing rotary rod 21b is composed of a heater 21b1, a connector 21b2, a blowing rod 21b3, a heat conducting rod 21b4 and blowing holes 21b5, the blowing holes 21b5 are uniformly and equidistantly distributed on the blowing rod 21b3, the blowing holes 21b5 and the blowing rod 21b3 are integrated, the connector 21b2 is arranged at the top end of the blowing rod 21b3, the connector 21b2 is movably connected with the blowing rod 21b3, the connector 21b2 is fixedly connected with the top cover 21a, the heater 21b1 is arranged at the top of the connector 21b2, and the heat conducting rod 21b4 is connected with the heater 21b1 through the connector 21b 2.

The stirring device also comprises stirring round rods 21e which are horizontally arranged on the inner wall of the inner cylinder 21d, and the stirring round rods 21e surround the inner ring of the inner cylinder 21d to form an annular structure and are sequentially arranged at equal intervals.

The blowing rod 21b3 is a hollow cylindrical structure, and a heat conducting rod 21b4 is arranged at the center of the blowing rod 21b 3.

When the formaldehyde adsorption device is used, the inner cylinder 21d and the blowing rod 21b3 perform rotary motion under the driving torque generated by the motor 9, formaldehyde adsorption particles poured into the inner cylinder 21d are repeatedly stirred through the stirring round rod 21e arranged on the inner wall of the inner cylinder 21d, the formaldehyde adsorption particles are always suspended in the inner cylinder 21d, air sprayed by the blower 5 enters the blowing rod 21b3 along the air guide bent pipe 4, the air ring 22e3 and the air pipe 22e5, after the air is heated by the heat guide rod 21b4, hot air is formed and is sprayed out at high speed from the blowing holes 21b5 arranged on the surface of the rotating blowing rod 21b3, each formaldehyde adsorption particle is fully contacted with the hot air, a boiling state is formed in the inner cylinder 21d, and moisture is rapidly evaporated and then taken away from the air filtering air outlet hood 21c along with exhaust.

Example 2

Referring to fig. 1-6, the present invention provides an embodiment of a formaldehyde adsorbing particle drying apparatus:

referring to fig. 1, a formaldehyde adsorption particle drying device structurally comprises a feed hopper 1, a boiling drying device 2, an outer support 3, an air guide bent pipe 4, an air blower 5, an underframe 6, a discharge nozzle 7, a discharge inclined pipe 8 and a motor 9, wherein the top of the underframe 6 is provided with the outer support 3, the outer support 3 is connected with the underframe 6, the top of the outer support 3 is provided with the boiling drying device 2, the boiling drying device 2 is arranged on the outer support 3, the bottom of the boiling drying device 2 is provided with two parallel and equidistant discharge inclined pipes 8, the discharge inclined pipe 8 is connected with the boiling drying device 2, the rear end of the outer support 3 is provided with the discharge nozzle 7, the discharge nozzle 7 is connected with the discharge inclined pipes 8, the bottom of the outer support 3 is provided with two air blowers 5 in an axial symmetry structure, the air blowers 5 are arranged on the outer support 3, the air outlet end of the air blower 5 is provided with the air guide bent pipe 4, the air blower 5 is connected with the boiling drying device 2 through the air guide bent pipe 4, the center of the outer support 3 is provided with a motor 9, and the motor 9 is matched with the boiling drying device 2.

Referring to fig. 5, the wind pressure output mechanism 22 is composed of an inner fixing plate 22a, a guide cover 22b, an upper ring cylinder 22c, a lower ring cylinder 22d, and a wind pressure transmission frame 22e, the upper ring cylinder 22c is disposed above the wind pressure transmission frame 22e, the inner fixing plate 22a is disposed on the inner ring of the upper ring cylinder 22c, the inner fixing plate 22a is connected with the upper ring cylinder 22c, the guide cover 22b is disposed on the top of the inner fixing plate 22a, the outer ring of the upper ring cylinder 22c is movably connected with an inner movable ring 21f, the lower ring cylinder 22d is disposed at the bottom of the upper ring cylinder 22c, the lower ring cylinder 22d is connected with the upper ring cylinder 22c, the upper ring cylinder 22c is connected with the inclined discharge pipe 8 through the lower ring cylinder 22d, and the electromagnetic valve is installed at the feeding end of the upper ring cylinder 22 c.

Referring to fig. 6, the wind pressure transmission frame 22e is composed of a supporting rod 22e1, a transmission disc 22e2, a wind ring 22e3, a wind inlet hole 22e4 and a wind pipe 22e5, the wind pipe 22e5 is arranged at the center of the transmission disc 22e2, the wind pipe 22e5 is connected with the transmission disc 22e2, two supporting rods 22e1 are arranged at two sides of the wind pipe 22e5 in an axisymmetrical structure, the supporting rod 22e1 is vertically arranged on the transmission disc 22e2, the supporting rod 22e1 is movably connected with the base 23, the transmission disc 22e2 is connected with the outer wall of the inner barrel 21d through the supporting rod 22e1, the wind ring 22e3 is arranged below the transmission disc 22e2, the wind ring 22e3 is connected with the wind pipe 22e5 through a bearing, the wind inlet holes 22e4 are uniformly distributed at the connecting end of the wind ring 22e3 and the wind pipe 22e5, and the wind inlet hole 22e4 is an integrated structure 5.

The guide cover 22b is a hollow semispherical structure and is connected with the inner fixing plate 22 a.

The top end of the air pipe 22e5 sequentially penetrates through the base 23, the inner fixing plate 22a and the guide hood 22b to be connected with the blowing rod 21b3, and the air pipe 22e5 is connected with the base 23, the inner fixing plate 22a and the guide hood 22b through bearings

The air ring 22e3 is connected with the blower 5 through the air guide bent pipe 4, and the bottom end of the air pipe 22e5 is in a closed structure and is connected with the motor 9.

When in use, the first movable structure formed by the inner movable ring 21f, the upper ring cylinder 22c and the inner fixed plate 22a can enable the inner cylinder 21d to stably rotate along the movable groove at the bottom of the top cover 21a under the driving torque generated by the motor 9, formaldehyde adsorption particles in the inner cylinder 21d can be quickly concentrated by the aid of the discharging structure formed by the guide cover 22b, the upper ring cylinder 22c and the lower ring cylinder 22d, the formaldehyde adsorption particles can efficiently flow into the upper ring cylinder 22c and the lower ring cylinder 22d along the guide cover 22b, and the formaldehyde adsorption particles can downwards slide along the discharging inclined pipe 8 and finally be sequentially discharged from the discharging nozzle 7.

The specific realization principle is as follows:

the boiling drying device 2 mainly comprises a fluid state drying mechanism 21 and an air pressure output mechanism 22, the fluid state drying mechanism 21 is matched with the air pressure output mechanism 22, an airflow fluid state boiling ejection structure formed by the fluid state drying mechanism 21 and the air pressure output mechanism 22 can enable air to form hot air to enter an inner cylinder 21d after being heated by a heat conducting rod 21b4, formaldehyde adsorption particles form a boiling state in the inner cylinder 21d under the action of air pressure and are in wide contact with hot air, moisture is quickly evaporated and then taken away along with exhaust, so that synchronous drying of a large number of formaldehyde adsorption particles can be completed in a short time, the production efficiency of the formaldehyde adsorption particles is improved, the production cost of the formaldehyde adsorption particles is reduced, because the inner cylinder 21d and the injection rod 21b3 perform rotary motion under the driving torque generated by a motor 9, and the stirring round rod 21e arranged on the inner wall of the inner cylinder 21d, the formaldehyde adsorption particles poured into the inner cylinder 21d are repeatedly stirred to enable the formaldehyde adsorption particles to be suspended in the inner cylinder 21d all the time, air sprayed by the blower 5 enters the blowing rod 21b3 along the air guide bent pipe 4, the air ring 22e3 and the air pipe 22e5, after the air is heated by the heat conduction rod 21b4, hot air is sprayed out from the blowing holes 21b5 arranged on the surface of the rotating blowing rod 21b3 at a high speed, each formaldehyde adsorption particle is fully contacted with the hot air, a boiling state is formed in the inner cylinder 21d, moisture is quickly evaporated and then taken away from the air filtering and air outlet hood 21c along with exhaust gas, because of a movable structure formed by the inner movable ring 21f, the upper cylinder 22c and the inner fixing plate 22a, the inner cylinder 21d can stably rotate along a movable groove at the bottom of the top cover 21a under the driving torque generated by the motor 9, and a discharging structure formed by the guide hood 22b, the upper cylinder 22c and the lower cylinder 22d, utilize the cavity half spherical structure that guide housing 22b formed, can concentrate the inside formaldehyde adsorbed particle of inner tube 21d fast, make formaldehyde adsorbed particle high-efficient inflow upper ring section of thick bamboo 22c and lower ring section of thick bamboo 22d along guide housing 22b to make formaldehyde adsorbed particle slide along arranging material pipe chute 8 downwards, discharge nozzle 7 is followed at last in proper order and is discharged.

While there have been shown and described what are at present considered the fundamental principles of the invention, the essential features and advantages thereof, it will be understood by those skilled in the art that the present invention is not limited by the embodiments described above, which are merely illustrative of the principles of the invention, but rather, is capable of numerous changes and modifications in various forms without departing from the spirit or essential characteristics thereof, and it is intended that the invention be limited not by the foregoing descriptions, but rather by the appended claims and their equivalents.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims

1. The utility model provides a formaldehyde adsorption particle drying equipment, its structure includes feeder hopper (1), boiling drying device (2), outer support (3), wind-guiding return bend (4), air-blower (5), chassis (6), discharge nozzle (7), row material pipe chute (8), motor (9), its characterized in that:

chassis (6) top be equipped with outer support (3), outer support (3) top be equipped with boiling drying device (2), boiling drying device (2) bottom be equipped with row material pipe chute (8), outer support (3) rear end be equipped with discharge nozzle (7), outer support (3) bottom be equipped with air-blower (5), air-blower (5) air-out end be equipped with wind-guiding return bend (4), outer support (3) central point put and be equipped with motor (9), boiling drying device (2) top be equipped with feeder hopper (1).

2. The formaldehyde adsorption particle drying apparatus of claim 1, wherein: boiling drying device (2) constitute by flow state drying mechanism (21), wind pressure output mechanism (22), base (23), urceolus (24) bottom be equipped with base (23), urceolus (24) inside be equipped with flow state drying mechanism (21), base (23) below be equipped with wind pressure output mechanism (22).

3. The formaldehyde adsorption particle drying apparatus of claim 2, wherein: flow state drying mechanism (21) by top cap (21a), jetting bull stick (21b), strain the gas and go out fan housing (21c), inner tube (21d), stirring round bar (21e), interior activity ring (21f) and constitute, inner tube (21d) top be equipped with top cap (21a), top cap (21a) top be equipped with and strain gas and go out fan housing (21c), inner tube (21d) inner wall on be equipped with stirring round bar (21e), inner tube (21d) central point put and be equipped with jetting bull stick (21b), inner tube (21d) bottom be equipped with interior activity ring (21 f).

4. The formaldehyde adsorption particle drying apparatus of claim 3, wherein: the blowing rotating rod (21b) consists of a heater (21b1), a joint (21b2), a blowing rod (21b3), a heat-conducting rod (21b4) and a blowing hole (21b5), wherein the blowing hole (21b5) is formed in the blowing rod (21b3), the joint (21b2) is arranged at the top end of the blowing rod (21b3), the heater (21b1) is arranged at the top of the joint (21b2), and the heat-conducting rod (21b4) is arranged at the center of the blowing rod (21b 3).

5. The formaldehyde adsorption particle drying apparatus of claim 2, wherein: wind pressure output mechanism (22) by interior fixed plate (22a), guide housing (22b), go up a ring section of thick bamboo (22c), down a ring section of thick bamboo (22d), transmission wind pressure frame (22e) constitute, transmission wind pressure frame (22e) top be equipped with a ring section of thick bamboo (22c), last ring section of thick bamboo (22c) circle in and be equipped with interior fixed plate (22a), interior fixed plate (22a) top be equipped with guide housing (22b), last ring section of thick bamboo (22c) bottom be equipped with down a ring section of thick bamboo (22 d).

6. The formaldehyde adsorption particle drying apparatus of claim 5, wherein: drive wind pressure frame (22e) constitute by branch (22e1), driving disc (22e2), wind ring (22e3), air inlet (22e4), tuber pipe (22e5), driving disc (22e2) central point put and be equipped with tuber pipe (22e5), tuber pipe (22e5) both sides be equipped with branch (22e1), driving disc (22e2) below be equipped with wind ring (22e3), the link of wind ring (22e3) and tuber pipe (22e5) be equipped with air inlet (22e 4).