CN110207485B - Alkali-free glass fiber processing technology - Google Patents

Abstract

The invention relates to the field of glass fiber processing, in particular to an alkali-free glass fiber processing technology, which comprises the following steps: communicating a water bath pipeline with a flow guide hole on an alkali-free glass fiber processing device, introducing a proper amount of water, and absorbing heat by using the water; drying the materials by a drying structure in the alkali-free glass fiber processing device, wherein the sealing structure controls the discharge of the materials; controlling the dried material to be discharged through a storage structure in the alkali-free glass fiber processing device; the driving structure is abutted against the drying structure, and the drying structure is driven to shake in a reciprocating manner through the driving structure, so that materials are effectively prevented from being accumulated in the drying structure, meanwhile, the heating area of the materials is increased due to the use of the drying structure, and the drying quality of the materials is greatly improved; the discharge of the material of the inside of structure control stoving structure is dried through accomodating structural seal structure, has improved the efficiency that the material was dried.

Description

Alkali-free glass fiber processing technology

Technical Field

The invention relates to the field of glass fiber processing, in particular to an alkali-free glass fiber processing technology.

Background

With the development and progress of the society and the rapid development of the glass fiber product industry, the consumption of glass fiber products is huge, the glass fiber alkali-free glass fiber processing device is widely used by workers, and a patent with application number of 201721643007.0 discloses a glass fiber alkali-free glass fiber processing device: the utility model discloses a glass fiber alkali-free glass fiber processingequipment, including the desiccator, drying machine top fixed mounting has the atomizer, the desiccator top is located the atomizer both sides and all is connected with hot air distributor, desiccator inner wall bottom is provided with the stirring pond, be provided with the motor shaft of being connected with the desiccator in the stirring pond, motor shaft one side is connected with the blade of arranging the inside equidistant of desiccator in, desiccator inner wall both sides are close to and all are connected with the arch on the motor shaft, protruding one end is connected with the through-hole, the desiccator both sides are first pipe of fixedly connected with and second pipe respectively, first pipe one end is kept away from desiccator one side and is connected with electric heater, the steam heater bottom is installed and is located the outside steam heater of desiccator, the steam heater bottom is connected with the conveying pipe through the delivery pump, conveying pipe top one side. Has the advantages that: convenient to use has effectually guaranteed the off-the-shelf stoving effect of glass fiber, avoids polluting simultaneously, and mark position precision is high.

However, in the conventional processing device for alkali-free glass fibers, granular glass fiber raw materials need to be dried before being stored, the contact area between the conventional dryer and the materials is small, the drying efficiency is low, the blanking is not convenient to control, the materials are easy to stack and block in the drying equipment, and the drying quality and the efficiency of the materials are further influenced.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides an alkali-free glass fiber processing technology, a driving structure is abutted against a drying structure, the drying structure is driven to shake back and forth by the driving structure, so that materials are effectively prevented from being accumulated in the drying structure, meanwhile, the heating area of the materials is increased by the use of the drying structure, so that the drying quality of the materials is greatly improved, a sealing structure is arranged on the drying structure, a sealing structure is arranged on a containing structure, so that the discharge of the materials in a storage box is conveniently controlled by the sealing structure on the drying structure, the discharge of the materials in the drying structure is controlled by the sealing structure on the containing structure, so that the discharge of the materials is more conveniently controlled, the material drying efficiency is greatly improved, and when the drying structure is abutted against a pressure relief structure, the pressure relief structure is used for damping and relieving pressure of the drying structure, and simultaneously cooling the driving structure.

The technical scheme adopted by the invention for solving the technical problems is as follows: an alkali-free glass fiber processing technology comprises the following steps:

s1: communicating a water bath pipeline with a flow guide hole on an alkali-free glass fiber processing device, introducing a proper amount of water, and absorbing heat by using the water;

s2: drying the materials by a drying structure in the alkali-free glass fiber processing device in the S1, and controlling the discharge of the materials by a sealing structure;

s3: controlling the dried material to be fed through a storage structure in the alkali-free glass fiber processing device in the S2;

the alkali-free glass fiber processing device in the method comprises eight guide rods, two support frames, a pressure relief structure, a storage box, a drying structure, a driving structure, a storage structure and a sealing structure; the storage structure for discharging materials and the storage box for storing materials are fixed at two ends through the support frame, and the storage box and the storage structure are detachably connected with the support frame; the drying structure for drying materials is arranged between the storage box and the accommodating structure, four guide rods with regular hexagonal cross sections are fixed on the drying structure, and the storage box is connected with the guide rods in a sliding manner;

the rectangular array on the containing structure is fixedly provided with another four guide rods, and the guide rods with the sections in regular hexagonal structures are connected with the drying structure in a sliding manner; the driving structure for driving the drying structure to slide on the guide rod is abutted against the drying structure; the top of accomodating the structure be equipped with one be used for right drying structure carries out sealedly seal structure, drying structure is last be fixed with be used for right the storage box carries out another sealed structure, drying structure's both ends symmetry is equipped with two pressure release structure.

Specifically, the containing structure includes the conveyer trough, lower hopper and containing box, the containing box is located two between the support frame, the containing box with can dismantle the connection between the support frame, the bottom of containing box is equipped with the rectangle structure the conveyer trough, just be equipped with on the containing box lower hopper, lower hopper with contained angle between the bottom surface of containing box is less than 90, the storage box is located the support frame deviates from the one end of containing box.

Specifically, the stoving structure includes water conservancy diversion hole, stoving case, heat exchange tube and locker room, the rectangle structure the stoving case is located the storage box with between the containing box, the inside of stoving case is equipped with the locker room, the bottom of locker room is the quadrangular frustum of a prism structure, the inside of stoving case the inside of locker room is equipped with the S-shaped distribution the heat exchange tube, the cross-section of heat exchange tube is the annular structure that a semicircle and a plurality of zigzag are constituteed, the water conservancy diversion hole run through in the stoving case extends to the inside of heat exchange tube.

Specifically, seal structure includes uide bushing and sealing plug, one the uide bushing is fixed in the stoving case is close to the one end of storage box, and the other one the uide bushing is fixed in the containing box, on the stoving case the uide bushing with sliding connection between the storage box, on the containing box the uide bushing with sliding connection between the stoving case, be equipped with four prismatic table structures on the uide bushing the sealing plug, be equipped with four cross-sections on the containing box and be the regular hexagon structure the guide bar, on the containing box the guide bar with sliding connection between the stoving case, the stoving case deviates from the one end of containing box is equipped with four rectangle array distributions the guide bar, on the stoving case the guide bar with sliding connection between the storage box.

Specifically, the drive structure includes transmission shaft, belt pulley, two drive shafts, driving-disc, motor and gear, the motor is fixed in the inside of containing box, the transmission shaft through connection in the support frame with the containing box, the motor with all be equipped with on the transmission shaft the gear, two gear engagement, the bilateral symmetry of transmission shaft is equipped with two the belt pulley, two the drive shaft symmetry run through in the support frame, be equipped with in the drive shaft the belt pulley, it is same two on the support frame the winding has on the belt pulley the belt, the driving-disc is fixed in the drive shaft, the cross-section is oval the driving-disc with the stoving case is contradicted.

Specifically, pressure release structure includes the gasbag, resets circle, first check valve, second check valve and connecting pipe, two the gasbag is fixed in respectively the containing box with the stoving case, the inside of gasbag is equipped with the circle that resets, first check valve is fixed in the gasbag, the second check valve is fixed in the gasbag, the connecting pipe is fixed in the second check valve, the connecting pipe deviates from the one end of second check valve extends to the motor.

The invention has the beneficial effects that:

(1) according to the alkali-free glass fiber processing technology, the driving structure is abutted against the drying structure, and the drying structure is driven to shake in a reciprocating manner through the driving structure, so that materials are effectively prevented from being accumulated in the drying structure, meanwhile, the heating area of the materials is increased due to the use of the drying structure, and the drying quality of the materials is greatly improved.

(2) According to the alkali-free glass fiber processing technology, the sealing structure is arranged on the drying structure, the sealing structure is arranged on the containing structure, the discharging of materials in the storage box is convenient to control through the sealing structure on the drying structure, the discharging of the materials in the drying structure is controlled through the sealing structure on the containing structure, the discharging of the materials is further convenient to control, the material drying efficiency is greatly improved, and meanwhile when the drying structure is abutted against the pressure relief structure, the pressure relief structure is used for damping and relieving the pressure of the drying structure, and meanwhile, the driving structure is cooled.

Drawings

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

FIG. 1 is a flow diagram of a process of the present invention;

FIG. 2 is a schematic view of the overall structure of an alkali-free glass fiber processing apparatus according to a preferred embodiment of the present invention;

FIG. 3 is a schematic view of a connection structure between the drying structure and the driving structure shown in FIG. 2;

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

FIG. 5 is an enlarged view of the portion B shown in FIG. 3;

FIG. 6 is a schematic view of a connection structure between the driving structure and the storage box shown in FIG. 4;

fig. 7 is a schematic view of the connection structure of the driving shaft and the driving disc shown in fig. 3.

In the figure: 1. guide bar, 2, support frame, 3, pressure release structure, 31, gasbag, 32, reset circle, 33, first check valve, 34, second check valve, 35, connecting pipe, 4, storage box, 5, stoving structure, 51, water conservancy diversion hole, 52, stoving case, 53, heat exchange tube, 54, locker room, 6, drive structure, 61, transmission shaft, 62, belt, 63, belt pulley, 64, drive shaft, 65, driving-disc, 66, motor, 67, gear, 7, accomodate the structure, 71, the transport tank, 72, lower hopper, 73, accomodate the case, 8, seal structure, 81, uide bushing, 82, the sealing plug.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

As shown in fig. 1-7, the alkali-free glass fiber processing process of the present invention comprises the following steps:

s1: communicating a water bath pipeline with a flow guide hole on an alkali-free glass fiber processing device, introducing a proper amount of water, and absorbing heat by using the water;

s2: drying the materials by a drying structure in the alkali-free glass fiber processing device in the S1, and controlling the discharge of the materials by a sealing structure;

s3: controlling the dried material to be fed through a storage structure in the alkali-free glass fiber processing device in the S2;

the alkali-free glass fiber processing device in the method comprises eight guide rods 1, two support frames 2, a pressure relief structure 3, a storage box 4, a drying structure 5, a driving structure 6, a storage structure 7 and a sealing structure 8; the containing structure 7 for discharging materials and the two ends of the storage box 4 for storing materials are fixed through the support frame 2, and the storage box 4 and the containing structure 7 are detachably connected with the support frame 2; the drying structure 5 for drying materials is arranged between the storage box 4 and the accommodating structure 7, four guide rods 1 with regular hexagonal cross sections are fixed on the drying structure 5, and the storage box 4 is connected with the guide rods 1 in a sliding manner;

the other four guide rods 1 are fixed on the storage structure 7 in a rectangular array, and the guide rods 1 with the sections in regular hexagonal structures are connected with the drying structure 5 in a sliding manner; the driving structure 6 for driving the drying structure 5 to slide on the guide rod 1 is abutted against the drying structure 5; it is right to accomodate structure 7's top be equipped with one be used for drying structure 5 seals seal structure 8, it is right to be fixed with on drying structure 5 be used for storage box 4 carries out another sealed seal structure 8, drying structure 5's both ends symmetry is equipped with two pressure release structure 3.

Specifically, the containing structure 7 comprises a carrying groove 71, a discharging hopper 72 and a containing box 73, the containing box 73 is arranged between the two support frames 2, the containing box 73 is detachably connected with the support frames 2, the carrying groove 71 with a rectangular structure is arranged at the bottom end of the containing box 73, the discharging hopper 72 is arranged on the containing box 73, an included angle between the discharging hopper 72 and the bottom surface of the containing box 73 is smaller than 90 degrees, and the storage box 4 is arranged at one end of each support frame 2, which is far away from the containing box 73; the arrangement of the carrying grooves 71 is convenient for being matched with a forklift to carry the device, and meanwhile, the included angle between the bottom surfaces of the blanking hopper 72 and the containing box 73 is smaller than 90 degrees, so that the materials are effectively prevented from being blocked in the blanking hopper 72.

Specifically, the drying structure 5 includes a diversion hole 51, a drying box 52, a heat exchange tube 53 and a storage chamber 54, the drying box 52 with a rectangular structure is arranged between the storage box 4 and the storage box 73, the storage chamber 54 is arranged inside the drying box 52, the bottom end of the storage chamber 54 is of a quadrangular frustum structure, the heat exchange tube 53 distributed in an S shape is arranged inside the storage chamber 54 inside the drying box 52, the cross section of the heat exchange tube 53 is of an annular structure formed by a semicircle and a plurality of sawteeth, and the diversion hole 51 penetrates through the drying box 52 and extends to the inside of the heat exchange tube 53; at first with the water bath pipeline be connected to water conservancy diversion hole 51, make the water bath pipeline with heat exchange tube 53 switches on, then the heat transfer water source is followed water conservancy diversion hole 51 gets into the inside of heat exchange tube 53, it is right the inside material of stoving case 52 is dried, simultaneously the cross-section of heat exchange tube 53 is the annular structure that a semicircle and a plurality of zigzags are constituteed, and the effectual material that prevents is in paste on the heat exchange tube 53, increased simultaneously with the area of contact of material, simultaneously heat exchange tube 53S-shaped distributes, further improvement drying efficiency and quality.

Specifically, the sealing structure 8 includes a guiding sleeve 81 and a sealing plug 82, one guiding sleeve 81 is fixed at one end of the drying box 52 close to the storage box 4, the other guide sleeve 81 is fixed on the containing box 73, the guide sleeve 81 on the drying box 52 is connected with the storage box 4 in a sliding way, the guide sleeve 81 on the containing box 73 is connected with the drying box 52 in a sliding way, the guide sleeve 81 is provided with the sealing plug 82 with a quadrangular frustum pyramid structure, the containing box 73 is provided with four guide rods 1 with regular hexagonal cross sections, the guide rods 1 on the containing box 73 are connected with the drying box 52 in a sliding manner, one end of the drying box 52, which is far away from the containing box 73, is provided with four guide rods 1 distributed in a rectangular array, and the guide rods 1 on the drying box 52 are connected with the storage box 4 in a sliding manner; the driving structure 6 abuts against the drying box 52, when the driving structure 6 drives the drying box 52 to slide in a direction away from the storage box 73, the guiding sleeve 81 on the drying box 52 slides with the storage box 4, the guiding sleeve 81 pushes the sealing plug 82 to abut against the storage box 4, sealing the storage box 4, meanwhile, the sealing plug 82 on the storage box 73 does not abut against the drying box 52, so that the material inside the drying box 52 is discharged from the guiding sleeve 81 through the discharging hopper 72, when the driving structure 6 drives the drying box 52 to move in a direction close to the storage box 73, the drying box 52 and the storage box 4 both slide with the guiding rod 1, the guiding sleeve 81 on the drying box 52 drives the sealing plug 82 not to abut against the storage box 4, so that the material enters the inside of the drying box 52 from the inside of the storage box 4, sealing plug 82 on containing box 73 contradicts stoving case 52, and then right hopper 72 seals down, and then is convenient for control the interpolation and the emission of material, and then has improved drying efficiency greatly, simultaneously guide bar 1 is regular hexagon structure, and then has avoided stoving case 52 misplaces, and then has improved driven stability can greatly.

Specifically, the driving structure 6 includes a transmission shaft 61, a belt 62, a belt pulley 63, two driving shafts 64, a driving disc 65, a motor 66 and a gear 67, the motor 66 is fixed inside the storage box 73, the transmission shaft 61 is connected to the support frame 2 and the storage box 73 in a penetrating manner, the gear 67 is arranged on each of the motor 66 and the transmission shaft 61, the two gears 67 are engaged, the two belt pulleys 63 are symmetrically arranged at two ends of the transmission shaft 61, the two driving shafts 64 are symmetrically connected to the support frame 2 in a penetrating manner, the belt pulley 63 is arranged on each driving shaft 64, the belt 62 is wound on the two belt pulleys 63 on the same support frame 2, the driving disc 65 is fixed on the driving shafts 64, and the driving disc 65 with an elliptical cross section is abutted to the drying box 52; the power line of the motor 66 is connected with a control line box, the motor 66 rotates, the gear 67 on the motor 66 drives the gear 67 on the transmission shaft 61 to rotate, the belt pulley 63 on the transmission shaft 61 drives the belt pulley 63 on the driving shaft 64 to rotate through the belt 62, the driving shaft 64 drives the driving disc 65 to rotate, the driving disc 65 is abutted against the drying box 52, so that the storage box 4 slides along with the guide rod 1, and the drying box 52 slides along with the guide rod 1.

Specifically, the pressure relief structure 3 includes an air bag 31, a reset ring 32, a first one-way valve 33, a second one-way valve 34 and a connecting pipe 35, the two air bags 31 are respectively fixed to the storage box 73 and the drying box 52, the reset ring 32 is arranged inside the air bag 31, the first one-way valve 33 is fixed to the air bag 31, the second one-way valve 34 is fixed to the air bag 31, the connecting pipe 35 is fixed to the second one-way valve 34, and one end of the connecting pipe 35, which is away from the second one-way valve 34, extends to the motor 66; when the drying box 52 collides with the storage box 4 against the air bag 31 or the drying box 52 collides with the storage box 73 against the air bag 31, the air bag 31 is extruded and deformed, air is discharged from the air bag 31 through the second one-way valve 34, passes through the connecting pipe 35, and then cools the motor 66, and meanwhile, the air bag 31 relieves the pressure of the drying box 52, the storage box 4 and the storage box 73, when the air bag 31 does not collide, the resetting ring 32 pushes the air bag 31 to reset, and the air enters the air bag 31 from the first one-way valve 33.

When the drying box is used, firstly, the water bath pipeline is connected to the flow guide hole 51, so that the water bath pipeline is communicated with the heat exchange pipe 53, then a heat exchange water source enters the inside of the heat exchange pipe 53 from the flow guide hole 51 to dry materials in the drying box 52, meanwhile, the cross section of the heat exchange pipe 53 is of an annular structure consisting of a semicircle and a plurality of sawteeth, the materials are effectively prevented from being stuck on the heat exchange pipe 53, meanwhile, the contact area with the materials is increased, and meanwhile, the heat exchange pipe 53 is distributed in an S shape, so that the drying efficiency and the drying quality are further improved; the power cord of the motor 66 is connected with the control wire box, the motor 66 rotates, the gear 67 on the motor 66 drives the gear 67 on the transmission shaft 61 to rotate, the belt pulley 63 on the transmission shaft 61 drives the belt pulley 63 on the driving shaft 64 to rotate through the belt 62, the driving shaft 64 drives the driving disc 65 to rotate, the driving disc 65 abuts against the drying box 52, so that the storage box 4 slides with the guide rod 1, the drying box 52 slides with the guide rod 1, when the driving structure 6 drives the drying box 52 to slide along the direction departing from the containing box 73, the guide sleeve 81 on the drying box 52 slides with the storage box 4, the guide sleeve 81 pushes the sealing plug 82 to abut against the storage box 4, so as to seal the storage box 4, meanwhile, the sealing plug 82 on the containing box 73 does not abut against the drying box 52, so that the materials in the drying box 52 are discharged from the guide sleeve 81 through the discharging hopper 72, when the driving structure, the drying box 52 and the storage box 4 both slide with the guide rod 1, the guide sleeve 81 on the drying box 52 drives the sealing plug 82 not to collide with the storage box 4, so that materials enter the drying box 52 from the inside of the storage box 4, the sealing plug 82 on the storage box 73 collides with the drying box 52, and the discharging hopper 72 is further sealed, so that the addition and the discharge of the materials are conveniently controlled, and further, the drying efficiency is greatly improved, meanwhile, the guide rod 1 is of a regular hexagon structure, so that the dislocation of the drying box 52 is avoided, and further, the stability of transmission is greatly improved; when the drying box 52 and the storage box 4 collide with the air bag 31 or the drying box 52 and the storage box 73 collide with the air bag 31, the air bag 31 is extruded and deformed, air is discharged from the air bag 31 through the second one-way valve 34, passes through the connecting pipe 35, and then cools the motor 66, meanwhile, the air bag 31 decompresses the drying box 52, the storage box 4 and the storage box 73, when the air bag 31 does not collide, the restoring ring 32 pushes the air bag 31 to restore, and the air enters the air bag 31 from the first one-way valve 33.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the embodiments and descriptions given above are only illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (2)

1. An alkali-free glass fiber processing technology is characterized by comprising the following steps:

s1: communicating a water bath pipeline with a flow guide hole on an alkali-free glass fiber processing device, introducing a proper amount of water, and absorbing heat by using the water;

s2: drying the materials by a drying structure in the alkali-free glass fiber processing device in the S1, and controlling the discharge of the materials by a sealing structure;

s3: controlling the dried material to be fed through a storage structure in the alkali-free glass fiber processing device in the S2;

the alkali-free glass fiber processing device in the method comprises eight guide rods (1), two support frames (2), a pressure relief structure (3), a storage box (4), a drying structure (5), a driving structure (6), a storage structure (7) and a sealing structure (8); the containing structure (7) for discharging materials and the two ends of the storage box (4) for storing materials are fixed through the support frame (2), and the storage box (4) and the containing structure (7) are detachably connected with the support frame (2); the drying structure (5) for drying materials is arranged between the storage box (4) and the accommodating structure (7), four guide rods (1) with regular hexagonal sections are fixed on the drying structure (5) in a rectangular array mode, and the storage box (4) is connected with the guide rods (1) in a sliding mode;

the other four guide rods (1) are fixed on the storage structure (7) in a rectangular array mode, and the guide rods (1) with the sections being in regular hexagonal structures are connected with the drying structure (5) in a sliding mode; the driving structure (6) for driving the drying structure (5) to slide on the guide rod (1) is abutted against the drying structure (5); the top end of the accommodating structure (7) is provided with a sealing structure (8) for sealing the drying structure (5), the drying structure (5) is fixedly provided with another sealing structure (8) for sealing the storage box (4), and two ends of the drying structure (5) are symmetrically provided with two pressure relief structures (3);

the containing structure (7) comprises a carrying groove (71), a blanking hopper (72) and a containing box (73), the containing box (73) is arranged between the two support frames (2), the containing box (73) is detachably connected with the support frames (2), the carrying groove (71) with a rectangular structure is arranged at the bottom end of the containing box (73), the blanking hopper (72) is arranged on the containing box (73), an included angle between the blanking hopper (72) and the bottom surface of the containing box (73) is smaller than 90 degrees, and the storage box (4) is arranged at one end, away from the containing box (73), of the support frame (2);

the drying structure (5) comprises a flow guide hole (51), a drying box (52), a heat exchange pipe (53) and a storage chamber (54), the drying box (52) with a rectangular structure is arranged between the storage box (4) and the storage box (73), the storage chamber (54) is arranged in the drying box (52), the bottom end of the storage chamber (54) is of a quadrangular frustum structure, the heat exchange pipe (53) distributed in an S shape is arranged in the storage chamber (54) in the drying box (52), the cross section of the heat exchange pipe (53) is of an annular structure consisting of a semicircle and a plurality of sawteeth, and the flow guide hole (51) penetrates through the drying box (52) and extends to the inside of the heat exchange pipe (53);

the sealing structure (8) comprises a guide sleeve (81) and a sealing plug (82), one guide sleeve (81) is fixed at one end, close to the storage box (4), of the drying box (52), the other guide sleeve (81) is fixed at the storage box (73), the guide sleeve (81) on the drying box (52) is in sliding connection with the storage box (4), the guide sleeve (81) on the storage box (73) is in sliding connection with the drying box (52), the sealing plug (82) of a quadrangular frustum structure is arranged on the guide sleeve (81), four guide rods (1) with regular hexagonal cross sections are arranged on the storage box (73), the guide rods (1) on the storage box (73) are in sliding connection with the drying box (52), and one end, away from the storage box (73), of the drying box (52) is provided with four guide rods (1) distributed in a rectangular array, the guide rod (1) on the drying box (52) is connected with the storage box (4) in a sliding way;

drive structure (6) includes transmission shaft (61), belt (62), belt pulley (63), two drive shafts (64), driving-disc (65), motor (66) and gear (67), motor (66) are fixed in the inside of containing box (73), transmission shaft (61) through connection in support frame (2) with containing box (73), motor (66) with all be equipped with on transmission shaft (61) gear (67), two gear (67) meshing, the both ends symmetry of transmission shaft (61) is equipped with two belt pulley (63), two driving shaft (64) symmetry run through in support frame (2), be equipped with on drive shaft (64) belt pulley (63), it is same two on support frame (2) belt pulley (63) go up to twine belt (62), driving-disc (65) are fixed in driving-disc (64), the driving disk (65) with an oval cross section is abutted against the drying box (52).

2. The alkali-free glass fiber processing process according to claim 1, wherein: pressure relief structure (3) are including gasbag (31), reset ring (32), first check valve (33), second check valve (34) and connecting pipe (35), two gasbag (31) are fixed in respectively containing box (73) with stoving case (52), the inside of gasbag (31) is equipped with reset ring (32), first check valve (33) are fixed in gasbag (31), second check valve (34) are fixed in gasbag (31), connecting pipe (35) are fixed in second check valve (34), connecting pipe (35) deviate from the one end of second check valve (34) extends to motor (66).

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