CN111006484A

CN111006484A - Energy-saving drying device for processing LED lamp tube

Info

Publication number: CN111006484A
Application number: CN201911308203.6A
Authority: CN
Inventors: 李志聪
Original assignee: Zhaoqing Xiaofanren Technology Co ltd
Current assignee: Zhaoqing Xiaofanren Technology Co ltd
Priority date: 2019-12-18
Filing date: 2019-12-18
Publication date: 2020-04-14

Abstract

The invention relates to an energy-saving drying device for processing an LED lamp tube, which comprises a main body, an air inlet pipe and an air outlet pipe, wherein the main body is in a cuboid shape, the air inlet pipe and the air outlet pipe are both vertical to the top of the main body, the air outlet pipe is arranged at the top of the main body, the air inlet pipe is arranged at the bottom of the main body and is communicated with the air outlet pipe through the main body, an air exhaust device is arranged in the air outlet pipe, a heating mechanism is arranged in the main body, an energy-saving mechanism is arranged in the air inlet pipe, the heating mechanism comprises a transmission shaft, a first bearing, a rotating ring, an inner gear, a power assembly and two heating assemblies, each heating assembly comprises a through hole, a heating rod, a rotating shaft, a second bearing, a rotating gear and at least two loading rings, and the energy, moreover, the energy-saving function is realized through the energy-saving mechanism.

Description

Energy-saving drying device for processing LED lamp tube

Technical Field

The invention relates to the field of lighting fixture processing, in particular to an energy-saving drying device for processing an LED lamp tube.

Background

An LED, i.e., a light emitting diode, is a semiconductor diode that can convert electrical energy into light energy, and is essential for an oven in the production process of the LED, such as baking of an LED support, sintering after dispensing, drying and aging experiments of a lamp tube, and the like.

The most level of current LED oven bracket is fixed arranges, great space has been occupied, can not adjust the distance between each bracket wantonly, make the inner space of oven can not obtain abundant effectual utilization, and cause the stoving inhomogeneous easily, moreover, the drying process in, for the sake of convenience with the toxic gas that the drying process produced, the circulation of air in can making the oven, and when outside air admission oven, can make the temperature in the oven reduce, thereby the required power of oven heating has been increased, energy-conservation is reduced.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: in order to overcome the defects of the prior art, an energy-saving drying device for processing an LED lamp tube is provided.

The technical scheme adopted by the invention for solving the technical problems is as follows: an energy-saving drying device for processing an LED lamp tube comprises a main body, an air inlet pipe and an air outlet pipe, wherein the main body is cuboid, the air inlet pipe and the air outlet pipe are both vertical to the top of the main body, the air outlet pipe is arranged at the top of the main body, the air inlet pipe is arranged at the bottom of the main body, the air inlet pipe is communicated with the air outlet pipe through the main body, an air exhaust device is arranged in the air outlet pipe, a heating mechanism is arranged in the main body, and an energy-saving mechanism is arranged in the;

the heating mechanism comprises a transmission shaft, a first bearing, a rotating ring, an inner gear, a power assembly and two heating assemblies, the transmission shaft is coaxially arranged with the air outlet pipe, the top of the main body is provided with an installation hole, the transmission shaft penetrates through the installation hole and is in sliding and sealing connection with the inner wall of the installation hole, the inner ring of the first bearing is installed on the transmission shaft, the outer ring of the first bearing is fixedly connected with the top of the main body, the rotating ring and the inner gear are coaxially arranged with the transmission shaft, the transmission shaft penetrates through the rotating ring and is fixedly connected with the rotating ring, the inner gear is positioned on one side of the rotating ring, which is far away from the air inlet pipe, the inner gear is fixedly connected with the top in the main body, the heating assemblies are circumferentially and uniformly distributed by taking the axis of the transmission shaft as a;

the heating assembly comprises a through hole, heating rods, a rotating shaft, a second bearing, a rotating gear and at least two carrying rings, wherein the heating rods and the rotating shaft are parallel to the transmission shaft, the heating rods are fixed on one side of the rotating ring, which is far away from the internal gear, the rotating shaft is positioned between the two heating rods, the through hole is formed in the rotating ring, the second bearing is positioned in the through hole, the outer ring of the second bearing is fixed on the inner wall of the rotating ring, the inner ring of the second bearing is installed on the rotating shaft, the rotating gear is installed at the top end of the rotating shaft and is meshed with the internal gear, the carrying rings are coaxially arranged with the rotating shaft, the carrying rings are positioned on one side of the rotating ring, which is close to the air inlet pipe, the carrying rings are uniformly distributed along the axis of;

the energy-saving mechanism comprises fan blades, a third bearing, a friction ring, a friction disc, a connecting shaft, a power disc and three transmission assemblies, wherein the friction ring, the friction disc, the connecting shaft and the power disc are all arranged coaxially with the transmission shaft, the power disc is arranged at the bottom end of the transmission shaft, the diameter of the connecting shaft is smaller than the inner diameter of the air inlet pipe and equal to the inner diameter of the friction ring, the outer diameter of the friction ring is larger than the outer diameter of the air inlet pipe, the diameter of the friction disc is larger than the diameter of the connecting shaft, the friction ring is attached to the bottom inside the main body and is in sealing connection with the bottom inside the main body, the friction disc is positioned between the friction ring and the power disc, gaps are arranged between the power disc and the friction ring, the connecting shaft penetrates through the friction ring, the connecting shaft is in sliding and sealing, the flabellum and third bearing all are located the intake pipe, the inner circle of third bearing is installed on the connecting axle, the outer lane of third bearing is fixed on the inner wall of intake pipe, drive assembly uses the axis of transmission shaft as central circumference evenly distributed between friction ring and power disc, the power disc passes through drive assembly and is connected with the friction ring.

Preferably, in order to realize rotation and movement of the friction ring, the transmission assembly comprises a sliding block, a guide rod, a connecting rod, a spring and two fixing blocks, the axis of the guide rod is perpendicular to and intersected with the axis of the transmission shaft, two ends of the guide rod are fixed on the friction ring through the two fixing blocks, the sliding block is sleeved on the sliding block and is hinged to the power disc through the connecting rod, the distance between one end, close to the power disc, of the connecting rod and the axis of the transmission shaft is smaller than the distance between the other end of the connecting rod and the axis of the transmission shaft, the sliding block is abutted against the fixing block, close to the axis of the transmission shaft, and the sliding block is connected.

Preferably, the guide bar is coated with a lubricating oil in order to reduce friction between the guide bar and the slider.

Preferably, the slider is made of rubber for achieving buffering and vibration reduction.

Preferably, in order to improve the heating effect, the friction ring is coated with heat-conducting silica gel.

Preferably, in order to drive the transmission shaft to rotate, the power assembly comprises a driving motor, a driving gear and a driven gear, the driving motor is fixed on the main body, the driving motor is in transmission connection with the driving gear, the driven gear is installed on the transmission shaft, and the driving gear is meshed with the driven gear.

Preferably, the drive motor is a servo motor in order to increase the drive force of the drive motor.

Preferably, in order to prolong the service life of the main body, the main body is provided with an anti-corrosion zinc coating.

Preferably, in order to facilitate the installation of the transmission shaft, chamfers are arranged at both ends of the transmission shaft.

Preferably, in order to reduce friction between the drive shaft and the drive shaft, an inner wall of the mounting hole is coated with a sealing grease.

The energy-saving drying device for processing the LED lamp tube has the advantages that the function of heating and drying devices is realized through the heating structure, compared with the existing heating mechanism, the heating mechanism is higher in heating uniformity through the rotation and revolution modes of the carrying ring, and further realizes the energy-saving function through the energy-saving mechanism.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic structural diagram of an energy-saving drying device for LED lamp tube processing according to the present invention;

FIG. 2 is an enlarged view of portion A of FIG. 1;

FIG. 3 is a schematic structural diagram of an energy-saving mechanism of the energy-saving drying device for processing LED lamp tubes of the present invention;

FIG. 4 is an enlarged view of portion B of FIG. 3;

in the figure: 1. the main body comprises a main body, 2 parts of an air inlet pipe, 3 parts of an air outlet pipe, 4 parts of a transmission shaft, 5 parts of a first bearing, 6 parts of a rotating ring, 7 parts of an internal gear, 8 parts of a heating rod, 9 parts of a rotating shaft, 10 parts of a second bearing, 11 parts of a rotating gear, 12 parts of a carrying ring, 13 parts of fan blades, 14 parts of a third bearing, 15 parts of a friction ring, 16 parts of a friction disc, 17 parts of a connecting shaft, 18 parts of a power disc, 19 parts of a sliding block, 20 parts of a guide rod, 21 parts of a connecting rod, 22 parts of a spring, 23 parts of a fixed block, 24 parts of a.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.

As shown in fig. 1-2, an energy-saving drying device for processing an LED lamp tube comprises a main body 1, an air inlet tube 2 and an air outlet tube 3, wherein the main body 1 is rectangular, the air inlet tube 2 and the air outlet tube 3 are both perpendicular to the top of the main body 1, the air outlet tube 3 is arranged at the top of the main body 1, the air inlet tube 2 is arranged at the bottom of the main body 1, the air inlet tube 2 is communicated with the air outlet tube 3 through the main body 1, an air extractor is arranged in the air outlet tube 3, a heating mechanism is arranged in the main body 1, and an energy-saving mechanism is arranged in the;

the heating mechanism comprises a transmission shaft 4, a first bearing 5, a rotating ring 6, an internal gear 7, a power assembly and two heating assemblies, the transmission shaft 4 and the air outlet pipe 3 are coaxially arranged, the top of the main body 1 is provided with a mounting hole, the transmission shaft 4 penetrates through the mounting hole and is in sliding and sealing connection with the inner wall of the mounting hole, the inner ring of the first bearing 5 is arranged on the transmission shaft 4, the outer ring of the first bearing 5 is fixedly connected with the top of the main body 1, the rotating ring 6 and the internal gear 7 are coaxially arranged with the transmission shaft 4, the transmission shaft 4 passes through the rotating ring 6 and is fixedly connected with the rotating ring, the internal gear 7 is positioned on one side of the rotating ring 6 far away from the air inlet pipe 2, the internal gear 7 is fixedly connected with the top part in the main body 1, the heating components are circumferentially and uniformly distributed by taking the axis of the transmission shaft 4 as a center, and the power components are arranged at the top of the main body 1 and are in transmission connection with the transmission shaft 4;

the heating component comprises a through hole, a heating rod 8, a rotating shaft 9, a second bearing 10, a rotating gear 11 and at least two carrying rings 12, the heating rod 8 and the rotating shaft 9 are both parallel to the transmission shaft 4, the heating rod 8 is fixed on one side of the rotating ring 6 far away from the internal gear 7, the rotating shaft 9 is positioned between the two heating rods 8, the through hole is arranged on the rotating ring 6, the second bearing 10 is positioned in the through hole, the outer ring of the second bearing 10 is fixed on the inner wall of the rotating ring 6, the inner ring of the second bearing 10 is arranged on the rotating shaft 9, the rotating gear 11 is arranged at the top end of the rotating shaft 9 and is meshed with the internal gear 7, the carrying ring 12 is coaxially arranged with the rotating shaft 9, the carrying ring 12 is positioned on one side of the rotating ring 6 close to the air inlet pipe 2, the carrying rings 12 are uniformly distributed along the axis of the rotating shaft 9, and the rotating shaft 9 penetrates through the carrying ring 12 and is fixedly connected with the carrying ring 12;

the device that will be used for making the LED fluorescent tube is placed on carrying thing ring 12, it produces the heat to lead to the fact through 8 circular telegrams of heating rod, and simultaneously, make transmission shaft 4 rotate under first bearing 5's supporting role through power component, transmission shaft 4's rotation drives swivel becket 6 and rotates, swivel becket 6's rotation drives the hot plate and realizes synchronous rotation, swivel becket 6's rotation still makes axis of rotation 9 drive through second bearing 10 and carries thing ring 12 and realize synchronous rotation, rotation through the hot plate, can improve the degree of consistency of heating in main part 1, and simultaneously, axis of rotation 9's rotation drives rotating gear 11 and rotates on internal gear 7, thereby make axis of rotation 9 drive and carry thing ring 12 production rotation, further improve the degree of consistency of device heating.

As shown in fig. 3, the energy saving mechanism includes fan blades 13, a third bearing 14, a friction ring 15, a friction disc 16, a connecting shaft 17, a power disc 18 and three transmission components, the friction ring 15, the friction disc 16, the connecting shaft 17 and the power disc 18 are all coaxially arranged with the transmission shaft 4, the power disc 18 is installed at the bottom end of the transmission shaft 4, the diameter of the connecting shaft 17 is smaller than the inner diameter of the air inlet pipe 2 and equal to the inner diameter of the friction ring 15, the outer diameter of the friction ring 15 is larger than the outer diameter of the air inlet pipe 2, the diameter of the friction disc 16 is larger than the diameter of the connecting shaft 17, the friction ring 15 is attached to and hermetically connected with the bottom inside the main body 1, the friction disc 16 is located between the friction ring 15 and the power disc 18, gaps are arranged between the power disc 18 and the friction ring 15 and the friction disc 16, the connecting shaft 17 penetrates through the friction ring 15, the friction disc 16 is installed on the top end of the connecting shaft 17, the fan blades 13 are installed at the bottom end of the connecting shaft 17, the fan blades 13 and the third bearing 14 are both located in the air inlet pipe 2, the inner ring of the third bearing 14 is installed on the connecting shaft 17, the outer ring of the third bearing 14 is fixed on the inner wall of the air inlet pipe 2, the transmission assemblies are circumferentially and uniformly distributed between the friction ring 15 and the power disc 18 by taking the axis of the transmission shaft 4 as the center, and the power disc 18 is connected with the friction ring 15 through the transmission assemblies.

The power disc 18 is driven to rotate during the rotation of the transmission shaft 4, the friction ring 15 is driven to synchronously rotate by the rotation of the power disc 18 through the transmission assembly, meanwhile, the rotation of the friction ring 15 generates centrifugal force, the transmission assembly drives the friction ring 15 to be attached to the friction disc 16 through the centrifugal force and generates a gap between the friction ring 15 and the bottom of the main body 1, namely, a gap is generated between the friction ring 15 and the air inlet pipe 2, meanwhile, air in the main body 1 is exhausted from the air outlet pipe 3 through an air exhaust device, air outside the main body 1 is conveyed into the main body 1 from the air inlet pipe 2, the fan blades 13 drive the connecting shaft 17 to rotate under the supporting action of the third bearing 14 through air flow, the connecting shaft 17 rotates and drives the friction disc 16 and the friction ring 15 to reversely rotate, so that the friction force between the friction ring 15 and the friction disc 16 can be improved, and the heat generated, the heat is transferred into the main body 1 again, and energy conservation is realized.

As shown in fig. 4, the transmission assembly includes a sliding block 19, a guide rod 20, a connecting rod 21, a spring 22 and two fixing blocks 23, the axis of the guide rod 20 is perpendicular to and intersects with the axis of the transmission shaft 4, two ends of the guide rod 20 are fixed on the friction ring 15 through the two fixing blocks 23, the sliding block 19 is sleeved on the sliding block 19, the sliding block 19 is hinged to the power disc 18 through the connecting rod 21, the distance between one end of the connecting rod 21 close to the power disc 18 and the axis of the transmission shaft 4 is smaller than the distance between the other end of the connecting rod 21 and the axis of the transmission shaft 4, the sliding block 19 abuts against the fixing block 23 close to the axis of the transmission shaft 4, and the sliding block 19 is connected to the fixing block.

The rotation of power disc 18 passes through connecting rod 21, slider 19, guide arm 20 and fixed block 23 in proper order and drives friction ring 15 and rotate, and, slider 19 moves towards keeping away from transmission shaft 4 axis direction under the effect of centrifugal force, and make the distance between power disc 18 and friction ring 15 reduce, make spring 22 compress simultaneously, after power disc 18 stops rotating, make slider 19 restore to the throne under the elastic action of spring 22, thereby make friction ring 15 restore to the throne, still played the function of sealed intake pipe 2 through friction ring 15, the protectiveness has been improved.

Preferably, the guide rod 20 is coated with a lubricating oil in order to reduce the frictional force between the guide rod 20 and the slider 19.

The lubricating oil has the function of reducing the friction force between the guide rod 20 and the sliding block 19, and the moving fluency of the sliding block 19 is improved.

Preferably, the material of the slider 19 is rubber for achieving cushioning and vibration reduction.

The rubber is soft, so that the impact force generated when the sliding block 19 abuts against the fixed block 23 can be reduced, and the buffering and vibration reduction are realized.

Preferably, in order to improve the heating effect, the friction ring 15 is coated with heat conductive silicone.

The function of the heat-conducting silica gel is to improve the heat-conducting capacity of the friction ring 15 and prolong the heating effect.

Preferably, in order to drive the transmission shaft 4 to rotate, the power assembly comprises a driving motor 24, a driving gear 25 and a driven gear 26, the driving motor 24 is fixed on the main body 1, the driving motor 24 is in transmission connection with the driving gear 25, the driven gear 26 is installed on the transmission shaft 4, and the driving gear 25 is meshed with the driven gear 26.

The driving motor 24 is started, so that the driving gear 25 drives the driven gear 26 to rotate, and the rotation of the driven gear 26 drives the transmission shaft 4 to rotate, thereby realizing the function of driving the transmission shaft 4 to rotate.

Preferably, the driving motor 24 is a servo motor in order to increase the driving force of the driving motor 24.

The servo motor has a characteristic of strong overload capability, so that the driving force of the driving motor 24 can be improved.

Preferably, in order to prolong the service life of the main body 1, the main body 1 is provided with an anti-corrosion zinc coating.

The function of anticorrosive galvanizing coat is to promote the rust-resistant ability of main part 1, prolongs the life of main part 1.

Preferably, in order to facilitate the installation of the transmission shaft 4, both ends of the transmission shaft 4 are provided with chamfers.

The chamfer angle is used for reducing the caliber of the transmission shaft 4 when the transmission shaft passes through the mounting hole, and the effect of convenient mounting is achieved.

Preferably, in order to reduce the frictional force between the drive shaft 4 and the drive shaft 4, the inner wall of the mounting hole is coated with a sealing grease.

The sealing grease has the function of reducing the friction force between the transmission shaft 4 and improving the sealing property.

The device for manufacturing the LED lamp tube is placed on the object carrying ring 12, heat is generated by electrifying the heating rod 8, meanwhile, the driving motor 24 is started, the driving gear 25 drives the driven gear 26 to rotate, the driven gear 26 rotates to drive the transmission shaft 4 to rotate under the supporting effect of the first bearing 5, the transmission shaft 4 rotates to drive the rotating ring 6 to rotate, the rotating ring 6 rotates to drive the heating plate to synchronously rotate, the rotating ring 6 also rotates to drive the object carrying ring 12 to synchronously rotate through the rotating shaft 9 through the second bearing 10, the uniformity of heating in the main body 1 can be improved through the rotation of the heating plate, meanwhile, the rotating gear 11 is driven by the rotating shaft 9 to rotate on the inner gear 7, the rotating shaft 9 drives the object carrying ring 12 to rotate, the uniformity of heating of the device is further improved, the power disc 18 is driven to rotate during the rotation of the transmission shaft 4, the rotation of the power disc 18 sequentially passes through, The slide block 19, the guide rod 20 and the fixed block 23 drive the friction ring 15 to rotate, the slide block 19 moves in the direction away from the axis of the transmission shaft 4 under the action of centrifugal force, the distance between the power disc 18 and the friction ring 15 is reduced, the spring 22 is compressed, the movement of the friction ring 15 enables the moving ring to be attached to the friction disc 16 and a gap is formed between the friction ring 15 and the bottom of the main body 1, namely a gap is formed between the friction ring 15 and the air inlet pipe 2, air in the main body 1 is exhausted from the air outlet pipe 3 through an air exhaust device, air outside the main body 1 is conveyed into the main body 1 from the air inlet pipe 2, the fan blades 13 drive the connecting shaft 17 to rotate under the supporting action of the third bearing 14 through air flow, the rotation of the connecting shaft 17 drives the friction disc 16 and the friction ring 15 to rotate in the opposite direction, so that the friction force between the friction ring 15 and the friction disc 16 can be improved, and further, the heat is transmitted to the main body 1 again, energy conservation is achieved, after the power disc 18 stops rotating, the sliding block 19 is reset under the elastic action of the spring 22, the friction ring 15 is reset, the function of sealing the air inlet pipe 2 is achieved through the friction ring 15, and the protection performance is improved.

Compared with the prior art, this an energy-saving drying device for LED fluorescent tube processing has realized the function of heating and stoving device through heating structure, compares with current heating mechanism, and this heating mechanism is through carrying the rotation and the mode of revolution of thing ring 12, and the degree of consistency of heating is higher, not only, has still realized energy-conserving function through energy-conserving mechanism, compares with current energy-conserving mechanism, and this energy-conserving mechanism has still improved the protective capability, and the practicality is stronger.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims

1. An energy-saving drying device for processing an LED lamp tube comprises a main body (1), an air inlet pipe (2) and an air outlet pipe (3), wherein the main body (1) is cuboid in shape, the air inlet pipe (2) and the air outlet pipe (3) are both vertical to the top of the main body (1), the air outlet pipe (3) is arranged at the top of the main body (1), the air inlet pipe (2) is arranged at the bottom of the main body (1), the air inlet pipe (2) is communicated with the air outlet pipe (3) through the main body (1), and an air exhaust device is arranged in the air outlet pipe (3), and the energy-saving drying device is characterized in that a heating mechanism is arranged in the main body (1), and an energy-saving mechanism is arranged in;

the heating mechanism comprises a transmission shaft (4), a first bearing (5), a rotating ring (6), an internal gear (7), a power assembly and two heating assemblies, the transmission shaft (4) is coaxially arranged with an air outlet pipe (3), a mounting hole is formed in the top of the main body (1), the transmission shaft (4) penetrates through the mounting hole and slides and is in sealing connection with the inner wall of the mounting hole, the inner ring of the first bearing (5) is installed on the transmission shaft (4), the outer ring of the first bearing (5) is fixedly connected with the top of the main body (1), the rotating ring (6) and the internal gear (7) are coaxially arranged with the transmission shaft (4), the transmission shaft (4) penetrates through the rotating ring (6) and is fixedly connected with the rotating shaft, the internal gear (7) is positioned on one side of the rotating ring (6) far away from the air inlet pipe (2), the internal gear (7) is fixedly connected with the top of the main body (1), the heating components are circumferentially and uniformly distributed by taking the axis of the transmission shaft (4) as a center, and the power components are arranged at the top of the main body (1) and are in transmission connection with the transmission shaft (4);

the heating assembly comprises a through hole, heating rods (8), a rotating shaft (9), a second bearing (10), a rotating gear (11) and at least two object carrying rings (12), wherein the heating rods (8) and the rotating shaft (9) are parallel to a transmission shaft (4), the heating rods (8) are fixed on one side of the rotating ring (6) far away from an inner gear (7), the rotating shaft (9) is positioned between the two heating rods (8), the through hole is formed in the rotating ring (6), the second bearing (10) is positioned in the through hole, an outer ring of the second bearing (10) is fixed on the inner wall of the rotating ring (6), an inner ring of the second bearing (10) is installed on the rotating shaft (9), the rotating gear (11) is installed at the top end of the rotating shaft (9) and meshed with the inner gear (7), the object carrying rings (12) and the rotating shaft (9) are coaxially arranged, the carrying ring (12) is positioned on one side, close to the air inlet pipe (2), of the rotating ring (6), the carrying ring (12) is uniformly distributed along the axis of the rotating shaft (9), and the rotating shaft (9) penetrates through the carrying ring (12) and is fixedly connected with the carrying ring (12);

the energy-saving mechanism comprises fan blades (13), a third bearing (14), a friction ring (15), a friction disc (16), a connecting shaft (17), a power disc (18) and three transmission assemblies, wherein the friction ring (15), the friction disc (16), the connecting shaft (17) and the power disc (18) are coaxially arranged with the transmission shaft (4), the power disc (18) is installed at the bottom end of the transmission shaft (4), the diameter of the connecting shaft (17) is smaller than the inner diameter of the air inlet pipe (2) and equal to the inner diameter of the friction ring (15), the outer diameter of the friction ring (15) is larger than the outer diameter of the air inlet pipe (2), the diameter of the friction disc (16) is larger than the diameter of the connecting shaft (17), the friction ring (15) is attached to the bottom in the main body (1) and is in sealing connection with the bottom in the main body (1), the friction disc (16) is located between the friction ring (15) and the power disc (18), gaps are formed between the power disc (18), friction ring (15) is passed in connecting axle (17), the inner wall slip and sealing connection of connecting axle (17) and friction ring (15), the top at connecting axle (17) is installed in friction disc (16), the bottom at connecting axle (17) is installed in flabellum (13), flabellum (13) and third bearing (14) all are located intake pipe (2), the inner circle of third bearing (14) is installed on connecting axle (17), the outer lane of third bearing (14) is fixed on the inner wall of intake pipe (2), transmission assembly uses the axis of transmission shaft (4) to be center circumference evenly distributed between friction ring (15) and power dish (18), power dish (18) are connected with friction ring (15) through transmission assembly.

2. The energy-saving drying device for processing the LED lamp tube as claimed in claim 1, wherein the transmission assembly comprises a sliding block (19), a guide rod (20), a connecting rod (21), a spring (22) and two fixing blocks (23), the axis of the guide rod (20) is perpendicular to and intersected with the axis of the transmission shaft (4), two ends of the guide rod (20) are fixed on the friction ring (15) through the two fixing blocks (23), the sliding block (19) is sleeved on the sliding block (19), the sliding block (19) is hinged with the power disc (18) through the connecting rod (21), the distance between one end of the connecting rod (21) close to the power disc (18) and the axis of the transmission shaft (4) is smaller than the distance between the other end of the connecting rod (21) and the axis of the transmission shaft (4), and the sliding block (19) abuts against the fixing block (23) close to the axis of the transmission shaft (4), the sliding block (19) is connected with a fixed block (23) far away from the axis of the transmission shaft (4) through a spring (22).

3. The energy-saving drying device for processing the LED lamp tube as claimed in claim 2, wherein the guide rod (20) is coated with lubricating oil.

4. The energy-saving drying device for processing the LED lamp tube as claimed in claim 2, wherein the slider (19) is made of rubber.

5. The energy-saving drying device for processing the LED lamp tube as claimed in claim 1, wherein the friction ring (15) is coated with heat-conducting silica gel.

6. The energy-saving drying device for processing the LED lamp tube as claimed in claim 1, wherein the power assembly comprises a driving motor (24), a driving gear (25) and a driven gear (26), the driving motor (24) is fixed on the main body (1), the driving motor (24) is in transmission connection with the driving gear (25), the driven gear (26) is installed on the transmission shaft (4), and the driving gear (25) is meshed with the driven gear (26).

7. The energy-saving drying device for processing the LED lamp tube as claimed in claim 6, wherein the driving motor (24) is a servo motor.

8. The energy-saving drying device for processing the LED lamp tube as claimed in claim 1, wherein the main body (1) is provided with an anti-corrosion zinc coating.

9. The energy-saving drying device for processing the LED lamp tube as claimed in claim 1, wherein both ends of the transmission shaft (4) are provided with chamfers.

10. The energy-saving drying device for processing LED lamp tubes as claimed in claim 1, wherein the inner wall of the mounting hole is coated with sealing grease.