阅读说明：本技术 一种黏胶纤维上油方法 (Viscose fiber oiling method ) 是由 高洁 于 2021-09-10 设计创作，主要内容包括：本发明属于纺织领域,尤其是涉及一种黏胶纤维上油方法。该方法是配合一种黏胶纤维上油装置进行的,该一种黏胶纤维上油装置包括机壳,机壳上固设有电机,电机的输出端在机壳内固定设有上油转轴,上油转轴上固设有上油滚筒,上油滚筒上设有上油滚筒上油机构,上油方法转轴的末端固设有主动齿轮,机壳内设有可转动的拨料转轴,拨料转轴上固设有拨料滚筒,拨料滚筒上设有拨料滚筒上油机构和拨料机构,拨料转轴的末端固设有从动齿轮,从动齿轮与主动齿轮可啮合传动,机壳在上油转轴的上方位置设有喂料机构,机壳在侧面设有可吹散纤维的吹气机构,机壳的下部设有可排出纤维的出料口。此方法可实现粘胶纤维的均匀上油。(The invention belongs to the field of textiles, and particularly relates to an oiling method for viscose fibers. The method is carried out by matching with a viscose fiber oiling device, the viscose fiber oiling device comprises a machine shell, a motor is fixedly arranged on the machine shell, an oiling rotating shaft is fixedly arranged at the output end of the motor in the machine shell, an oiling roller is fixedly arranged on the oiling rotating shaft, an oiling roller oiling mechanism is arranged on the oiling roller, a driving gear is fixedly arranged at the tail end of an oiling method rotating shaft, a rotatable material stirring rotating shaft is arranged in the machine shell, a material stirring roller is fixedly arranged on the material stirring rotating shaft, a material stirring roller oiling mechanism and a material stirring mechanism are arranged on the material stirring roller, a driven gear is fixedly arranged at the tail end of the material stirring rotating shaft and can be in meshed transmission with the driving gear, a feeding mechanism is arranged on the machine shell above the oiling rotating shaft, a blowing mechanism capable of blowing loose fibers is arranged on the side face of the machine shell, and a discharge port capable of discharging fibers is arranged at the lower portion of the machine shell. The method can realize uniform oiling of the viscose fibers.)

1. A viscose oiling method is carried out by matching with a viscose oiling device, the viscose oiling device comprises a machine shell (10), a motor (38) is fixedly arranged on the machine shell (10), an oiling rotating shaft (37) is fixedly arranged at the output end of the motor (38) in the machine shell (10), an oiling roller (35) is fixedly arranged on the oiling rotating shaft (37), a roller oil way (39) is arranged on the oiling roller (35), an oiling roller oiling mechanism is arranged on the oiling roller (35), a driving gear (62) is fixedly arranged at the tail end of the oiling method rotating shaft (37), a rotatable material stirring rotating shaft (31) is arranged in the machine shell (10), a material stirring roller (26) is fixedly arranged on the material stirring rotating shaft (31), a roller oil way (39) is arranged on the material stirring roller (26), a material stirring roller oiling mechanism and a material stirring mechanism are arranged on the material stirring roller (26), the tail end of the material poking rotating shaft (31) is fixedly provided with a driven gear (61), the driven gear (61) and the driving gear (62) can be in meshed transmission, a feeding mechanism is arranged above the upper oil rotating shaft (37) of the machine shell (10), a blowing mechanism capable of blowing loose fibers is arranged on the side face of the machine shell (10), and a discharge hole (34) capable of discharging fibers is formed in the lower portion of the machine shell (10).

2. The oiling roller oiling mechanism of the viscose fiber oiling method according to claim 1, which is characterized in that: six main sliding grooves (30) are uniformly formed in the oiling roller (35) according to sixty degrees, an oiling sliding block (36) capable of sliding in a reciprocating mode is arranged in each main sliding groove (30), each oiling sliding block (36) and a main spring (28) are connected between the corresponding oiling sliding blocks (30), a plurality of special-tooth bodies (32) are uniformly arranged on each oiling sliding block (36), a sliding block main oil way (27) capable of being communicated with the corresponding roller oil way (39) is formed in each main sliding groove (30) and each special-tooth body (32), a plurality of sliding block oil distribution ways (42) communicated with the corresponding sliding block main oil way (27) are formed in each special-tooth body (32), a connecting plate (29) matched with the corresponding sliding block oil distribution ways (42) is arranged on the oiling roller (35), an oiling small rotating shaft (41) is arranged at the tail end of each connecting plate (29), and a small oiling roller (44) capable of rotating oiling is arranged on each oiling small rotating shaft (41), an upper oil groove (43) is formed in the special-shaped gear body (32), and a connecting plate oil port (40) which can be communicated with the main oil way (27) of the sliding block is formed in each connecting plate (29).

3. The stirring roller oiling mechanism of the viscose fiber oiling method according to claim 1, which is characterized in that: six main sliding grooves (30) are uniformly formed in the material shifting roller (26) according to sixty degrees, a material shifting sliding block (25) capable of sliding in a reciprocating mode is arranged in each main sliding groove (30), a main spring (28) is connected between each oiling sliding block (36) and each main sliding groove (30), a plurality of special-shaped tooth bodies (32) are uniformly arranged on each material shifting sliding block (25), a sliding block main oil way (27) capable of being communicated with the roller oil way (39) is formed in each main sliding groove (30) and each special-shaped tooth body (32), a plurality of sliding block oil distributing ways (42) communicated with the sliding block main oil way (27) are formed in each main sliding groove (30), a connecting plate (29) matched with each sliding block oil distributing way (42) is arranged on each oiling roller (35), an oiling small rotating shaft (41) is arranged at the tail end of each connecting plate (29), a rotatable oiling small roller (44) capable of oiling is arranged on each oiling small rotating shaft (41), an upper oil groove (43) is formed in the special-shaped gear body (32), a connecting plate oil port (40) which can be communicated with the main oil way (27) of the sliding block is formed in each connecting plate (29), and the material stirring roller (26) can be meshed with the upper oil sliding block (36).

4. The material shifting mechanism of the viscose fiber oiling method according to claim 1, which is characterized in that: a material shifting rod rotating groove (54) is formed in the material shifting sliding block (25), a material shifting rotating shaft (49) capable of rotating freely is arranged in the material shifting rod rotating groove (54), a torsion spring (51) is arranged at the lower end of the material shifting rotating shaft (49), a material shifting rod (48) is fixedly arranged at the upper end of the material shifting rotating shaft (49), a material shifting round head (47) is fixedly arranged at the upper end of the material shifting rotating shaft (49), a material shifting rod rope groove (50) is formed in the material shifting rotating shaft (49), a material shifting rope (46) is wound on the material shifting rod rope groove (50), a material shifting oil way (55) is formed in the material shifting sliding block (25), a material shifting sliding groove (45) is formed in the material shifting sliding block (25), a material shifting sliding block (53) capable of plugging the material shifting oil way (55) at any position and capable of sliding in a reciprocating manner under the influence of the material shifting oil way (55) is arranged in the material shifting sliding groove (45), the material shifting sliding block (53) is fixedly connected with the material shifting rope (46).

5. The oiling roller oiling mechanism of the viscose fiber oiling method according to claim 4, which is characterized in that: dial material slider (25) and be equipped with concave arc bearing (57), be equipped with in concave arc bearing (57) but free rotation's concave arc pole (58), concave arc frame (59) have set firmly on concave arc pole (58), be equipped with concave arc pivot (60) on concave arc frame (59), but be equipped with free rotation on concave arc pivot (60) and avoid dial material rope (46) with dial concave arc cylinder (52) that material grooving (56) contacted.

6. The feeding mechanism of the viscose fiber oiling method according to claim 1, which is characterized in that: the feeding device is characterized in that a feeding port (13) is formed in the machine shell (10), input machine frames (11) are arranged on two sides of the feeding port (13), each input machine frame (11) is provided with an input swing groove (12), each input machine frame (11) is provided with an input rotating shaft (16) in the input swing groove (12), each input rotating shaft (16) is provided with an input swing rod (14), each input swing rod (14) is provided with an input rotating shaft (16) at the tail end, each input rotating shaft (16) is provided with an input roller (15), and an input spring (17) capable of being tightened is arranged between the input swing rod (14) and the input machine frame (11).

7. The air blowing mechanism of the viscose fiber oiling method according to claim 1, which is characterized in that: the improved air sealing device is characterized in that an air inlet (33) is formed in the casing (10), the casing (10) is provided with a communicating hole, the air inlet (33) is used for exhausting the air casing (19), an air outlet (18) capable of blowing fibers uniformly is formed in the air exhausting casing (19), an air sealing plate (20) is arranged in the air exhausting casing (19), an air sealing block (24) is arranged in the air exhausting casing (19), an air sealing sliding groove (23) is formed in the air sealing block (24), the air sealing sliding groove (23) is internally provided with a sliding body, the air sealing sliding block (21) is withdrawn under the action of air flow blown in from the air inlet (33) and is aligned with a gap in the air sealing plate (20), and an air sealing spring (22) is connected between the air sealing sliding groove (23).

Technical Field

The invention belongs to the field of textiles, and particularly relates to an oiling method for viscose fibers.

Background

Viscose fiber is one of viscose fiber, viscose filament and artificial fiber for short. Viscose is the main variety of artificial fiber and the second largest chemical fiber in China. In the post-treatment of production, oiling treatment is needed. However, the prior art lacks a method and a tool for uniformly oiling the viscose fibers, so that the method for oiling the viscose fibers uniformly is designed.

Disclosure of Invention

The invention aims to provide an oiling method for viscose fibers, aiming at the problems in the prior art.

In order to achieve the purpose, the invention adopts the following technical scheme: a viscose fiber oiling method is carried out by matching with a viscose fiber oiling device, the viscose fiber oiling device comprises a shell, a motor is fixedly arranged on the shell, an oiling rotating shaft is fixedly arranged at the output end of the motor in the shell, an oiling roller is fixedly arranged on the oiling rotating shaft, a roller oil circuit is arranged on the oiling roller, an oiling roller oiling mechanism is arranged on the oiling roller, a driving gear is fixedly arranged at the tail end of the oiling method rotating shaft, a rotatable material shifting rotating shaft is arranged in the shell, a material shifting roller is fixedly arranged on the material shifting rotating shaft, a roller oil circuit is arranged on the material shifting roller, a material shifting roller oiling mechanism and a material shifting mechanism are arranged on the material shifting roller, a driven gear is fixedly arranged at the tail end of the material shifting rotating shaft, the driven gear and the driving gear can be meshed for transmission, a feeding mechanism is arranged at the position of the shell above the oiling rotating shaft, the side surface of the shell is provided with an air blowing mechanism capable of blowing fibers, and the lower part of the shell is provided with a discharge hole capable of discharging the fibers.

Preferably, six main chutes are evenly seted up according to sixty degrees on the oiling roller, be equipped with the slider that oils of reciprocating sliding in the main chute, the slider that oils with be connected with main spring between the main chute, evenly be equipped with a plurality of special tooth bodies on the slider that oils, main chute seted up can with the slider major oil way of cylinder oil way UNICOM, main chute and every set up on the special tooth body a plurality of with the slider major oil way of slider major oil way looks UNICOM divides the oil circuit, be equipped with on the oiling roller with slider divides oil circuit matched with connecting plate, the end of connecting plate is equipped with the little pivot of oiling, be equipped with the rotatable oiling small drum that oils on the little pivot of oiling, the last oil groove of having seted up on the special tooth body, every but the connecting plate has seted up UNICOM the connecting plate of slider major oil way.

Preferably, six main sliding chutes are uniformly arranged on the material poking roller according to sixty degrees, material poking sliding blocks capable of sliding in a reciprocating manner are arranged in the main sliding chutes, a main spring is connected between the oiling sliding block and the main sliding chute, a plurality of special-shaped tooth bodies are uniformly arranged on the material shifting sliding block, the main chute is provided with a main slide block oil circuit which can be communicated with the roller oil circuit, the main chute and each special-shaped gear body are provided with a plurality of slide block oil distribution circuits which are communicated with the main slide block oil circuit, the oiling roller is provided with a connecting plate matched with the sliding block oil distribution circuit, the tail end of the connecting plate is provided with a small oiling rotating shaft, the oiling small rotating shaft is provided with a rotatable oiling small roller, the special-shaped gear body is provided with an oil groove and each connecting plate is provided with a connecting plate oil port which can be communicated with the main oil way of the sliding block, and the material shifting roller can be meshed with the oiling sliding block.

Preferably, the material pulling mechanism of the viscose fiber oiling method according to the claim is characterized in that: the material poking device is characterized in that a material poking rod rotating groove is formed in the material poking slide block, a material poking rotating shaft capable of rotating freely is arranged in the material poking rod rotating groove, a torsion spring is arranged at the lower end of the material poking rotating shaft, a material poking rod is fixedly arranged at the upper end of the material poking rotating shaft, a material poking round head is fixedly arranged at the upper end of the material poking rotating shaft, a material poking rod rope groove is formed in the material poking rotating shaft, a material poking rope is wound on the material poking rod rope groove, a material poking oil path is formed in the material poking slide block, a material poking slide groove is formed in the material poking slide block, a material poking slide block capable of plugging the material poking oil path at any position and capable of sliding back and forth under the influence of the material poking oil path is arranged in the material poking slide block, and the material poking slide block is fixedly connected with the material poking rope.

Preferably, the material shifting sliding block is provided with a concave arc bearing, a concave arc rod capable of rotating freely is arranged in the concave arc bearing, a concave arc rack is fixedly arranged on the concave arc rod, a concave arc rotating shaft is arranged on the concave arc rack, and a concave arc roller capable of rotating freely and capable of avoiding the contact between the material shifting rope and the material shifting rope groove is arranged on the concave arc rotating shaft.

Preferably, the casing is provided with a feeding port, the casing is provided with input frames on two sides of the feeding port, each input frame is provided with an input swing slot, each input frame is provided with an input rotating shaft in the input swing slot, each input rotating shaft is provided with an input swing rod, the tail end of each input swing rod is provided with an input rotating shaft, each input rotating shaft is provided with an input roller, and a tightenable input spring is arranged between each input swing rod and the input frame.

Preferably, the air inlet has been seted up on the casing, be equipped with the UNICOM on the casing the air inlet casing of giving vent to anger, it can evenly blow the gas outlet that looses with the fibre to be equipped with on the casing of giving vent to anger, be equipped with in the casing of giving vent to anger and seal the gas board, be equipped with in the gas board and seal the gas spout, be equipped with slidable and cancel under the effect of the air current that the air inlet insufflated right seal the gas slider of breach on the gas board, seal the gas slider with it is equipped with and seals the gas spring to seal to connect between the gas spout.

Has the advantages that:

the invention provides a viscose fiber oiling method through improvement, and compared with the prior art, the viscose fiber oiling method has the following improvements and advantages:

1. the fiber bundles can be combed and separated through the mutual matching of the material poking roller, the oiling roller and the special-shaped tooth bodies.

2. The uniform oiling can be realized through the mutual matching of the roller oil circuit, the connecting plate oil port, the small oiling rotating shaft, the sliding block oil distribution circuit, the upper oil groove and the small oiling roller.

3. Through the cooperation of the material shifting sliding groove, the material shifting rope, the material shifting round head, the material shifting rod, the material shifting rotating shaft, the material shifting rod rope groove, the torsion spring and the auxiliary mechanism thereof, the separation treatment of a plurality of fiber positions can be realized.

Drawings

FIG. 1 is a front cross-sectional view of the design;

FIG. 2 is a top view of the present design;

FIG. 3 is a cross-sectional view taken at A-A of FIG. 1;

FIG. 4 is an enlarged view of a portion of FIG. 1 at B;

FIG. 5 is a cross-sectional view taken at C-C of FIG. 3;

FIG. 6 is an enlarged view of a portion of FIG. 3 at D;

FIG. 7 is an enlarged view of a portion of FIG. 5 at E;

FIG. 8 is a cross-sectional view taken at F-F of FIG. 7;

fig. 9 is a sectional view at G-G in fig. 7.

In the figure, a machine shell 10, an input frame 11, an input swing slot 12, a feeding port 13, an input swing rod 14, an input roller 15, an input rotating shaft 16, an input spring 17, an air outlet 18, an air outlet shell 19, an air sealing plate 20, an air sealing slide block 21, an air sealing spring 22, an air sealing chute 23, an air sealing block 24, a material shifting slide block 25, a material shifting roller 26, a slide block main oil way 27, a main spring 28, a connecting plate 29, a main chute 30, a material shifting rotating shaft 31, a special gear body 32, an air inlet 33, a material outlet 34, an oiling roller 35, an oiling slide block 36, an oiling rotating shaft 37, a motor 38, a roller oil way 39, a connecting plate oil port 40, an oiling small rotating shaft 41, a slide block oil distributing way 42, an oiling groove 43, an oiling small roller 44, a material shifting chute 45, a material shifting rope 46, a material shifting round head 47, a material shifting rod 48, a material shifting rotating shaft 49, a material shifting rod rope groove 50, a torsion spring 51, a concave arc roller 52, a material shifting slide block 53, a material shifting rod rotating groove 54, The material poking oil path 55, the material poking rope groove 56, the concave arc bearing 57, the concave arc rod 58, the concave arc frame 59, the concave arc rotating shaft 60, the driven gear 61 and the driving gear 62.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

In the description of the present invention, it should be noted that the terms "inside", "below", and the like refer to orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention conventionally place when used, and are used only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

As shown in FIGS. 1 and 2, a viscose oiling method is performed by matching with a viscose oiling device, which comprises a housing 10, a motor 38 is fixedly arranged on the housing 10, an oiling rotating shaft 37 is fixedly arranged at the output end of the motor 38 in the housing 10, an oiling roller 35 is fixedly arranged on the oiling rotating shaft 37, a roller oil circuit 39 is arranged on the oiling roller 35, an oiling roller oiling mechanism is arranged on the oiling roller 35, a driving gear 62 is fixedly arranged at the tail end of the oiling method rotating shaft 37, a rotatable material shifting rotating shaft 31 is arranged in the housing 10, a material shifting roller 26 is fixedly arranged on the material shifting rotating shaft 31, a roller oil circuit 39 is arranged on the material shifting roller 26, a material shifting roller oiling mechanism and a material shifting mechanism are arranged on the material shifting roller 26, a driven gear 61 is fixedly arranged at the tail end of the material shifting rotating shaft 31, the driven gear 61 and the driving gear 62 can be meshed for transmission, a feeding mechanism is arranged at a position above the oiling rotating shaft 37 on the housing 10, the casing 10 is provided with an air blowing mechanism for blowing fibers at a side surface thereof, and a discharge port 34 for discharging the fibers is provided at a lower portion of the casing 10.

As shown in fig. 1, fig. 3, fig. 4, and fig. 6, six main chutes 30 are uniformly provided on the oiling roller 35 according to sixty degrees, an oiling slider 36 capable of sliding back and forth is provided in the main chute 30, a main spring 28 is connected between the oiling slider 36 and the main chute 30, a plurality of different tooth bodies 32 are uniformly provided on the oiling slider 36, a slider main oil path 27 capable of communicating with the roller oil path 39 is provided on the main chute 30, a plurality of slider branch oil paths 42 communicating with the slider main oil path 27 are provided on the main chute 30 and each different tooth body 32, a connecting plate 29 matching with the slider branch oil paths 42 is provided on the oiling roller 35, an oiling small rotating shaft 41 is provided at the end of the connecting plate 29, a small oiling roller 44 capable of rotating oiling is provided on the oiling small rotating shaft 41, an oiling oil groove 43 is provided on the different tooth body 32, and a connecting plate 40 of communicating the slider main oil path 27 is provided on each connecting plate 29.

As shown in the figures 1 and 3, respectively, fig. 4 and 6 show that six main chutes 30 are uniformly formed in the material shifting roller 26 according to sixty degrees, the material shifting slider 25 capable of sliding back and forth is arranged in the main chute 30, a main spring 28 is connected between the upper oil slider 36 and the main chute 30, a plurality of special-shaped teeth 32 are uniformly arranged on the material shifting slider 25, a main slider oil path 27 capable of communicating with the roller oil path 39 is formed in the main chute 30, a plurality of main slider oil distributing paths 42 communicated with the main slider oil path 27 are formed in the main chute 30 and each special-shaped teeth 32, a connecting plate 29 matched with the main slider oil distributing paths 42 is arranged on the upper oil roller 35, an upper oil small rotating shaft 41 is arranged at the tail end of the connecting plate 29, a small upper oil roller 44 capable of rotating to oil is arranged on the upper oil small rotating shaft 41, an upper oil groove 43 is formed in the special-shaped teeth 32, a connecting plate 40 capable of communicating with the main slider oil path 27 is formed in each connecting plate 29, and the material shifting roller 26 can be meshed with the upper oil slider 36.

As shown in fig. 1, 3, 5, 7 and 8, a material-shifting rod rotating groove 54 is formed on the material-shifting slider 25, a material-shifting rotating shaft 49 capable of rotating freely is arranged in the material-shifting rod rotating groove 54, a torsion spring 51 is arranged at the lower end of the material-shifting rotating shaft 49, a material-shifting rod 48 is fixedly arranged at the upper end of the material-shifting rotating shaft 49, a material-shifting round head 47 is fixedly arranged at the upper end of the material-shifting rotating shaft 49, a material-shifting rod rope groove 50 is formed on the material-shifting rotating shaft 49, a material-shifting rope 46 is wound on the material-shifting rod rope groove 50, a material-shifting oil path 55 is formed on the material-shifting slider 25, a material-shifting sliding chute 45 is formed on the material-shifting slider 25, a material-shifting rope 46 is formed on the material-shifting slider 25, a material-shifting slider 53 capable of blocking the material-shifting oil path 55 at any position and capable of sliding back and forth and back under the influence of the material-shifting oil path 55 is arranged in the material-shifting slider 45, and the material-shifting slider 53 is fixedly connected with the material-shifting rope 46.

As shown in fig. 9, the material-shifting slider 25 is provided with a concave arc bearing 57, a concave arc rod 58 capable of freely rotating is arranged in the concave arc bearing 57, a concave arc frame 59 is fixedly arranged on the concave arc rod 58, a concave arc rotating shaft 60 is arranged on the concave arc frame 59, and a concave arc roller 52 capable of freely rotating and preventing the material-shifting rope 46 from contacting with the material-shifting rope groove 56 is arranged on the concave arc rotating shaft 60.

As shown in fig. 1, a feeding port 13 is formed in a casing 10, input frames 11 are arranged on two sides of the feeding port 13 of the casing 10, an input swing slot 12 is formed in each input frame 11, an input rotating shaft 16 is arranged in each input swing slot 12 of each input frame 11, an input swing rod 14 is arranged on each input rotating shaft 16, an input rotating shaft 16 is arranged at the tail end of each input swing rod 14, an input roller 15 is arranged on each input rotating shaft 16, and a lockable input spring 17 is arranged between each input swing rod 14 and the input frame 11.

As shown in fig. 1, an air inlet 33 is provided on the case 10, an air outlet housing 19 communicating with the air inlet 33 is provided on the case 10, an air outlet 18 capable of blowing fibers uniformly is provided on the air outlet housing 19, an air sealing plate 20 is provided in the air outlet housing 19, an air sealing block 24 is provided in the air outlet housing 19, an air sealing chute 23 is provided in the air sealing block 24, an air sealing slider 21 which can slide and cancel a gap on the air sealing plate 20 under the action of an air flow blown in by the air inlet 33 is provided in the air sealing chute 23, and an air sealing spring 22 is provided between the air sealing slider 21 and the air sealing chute 23.

Initial position: the material shifting oil path 55 is not filled with hydraulic oil, and the material shifting slide block 53 is positioned at the extending end of the material shifting chute 45.

The oiling method for viscose fibers comprises the following specific steps:

the first step is as follows: and blowing the air flow. The fiber fed from the feed port 13 is nipped by the feed roller 15, uniformly blown off by the air flow blown from the air outlet 18, and enters between the kick-out roller 26 and the oiling roller 35.

The second step is that: carding and separating fibers, starting a motor 38, driving a material shifting roller 26 and an oiling roller 35 to rotate along with the motor, driving a material shifting slide block 25 and an oiling slide block 36 to drive special-shaped tooth bodies 32 on the material shifting slide block and the oiling slide block to mesh, and carding and separating the fibers by the material shifting slide block 25 and the oiling slide block 36 in the meshing process.

The third step: and (4) stirring and dispersing. Along with the rotation of the material shifting roller 26 and the oiling roller 35, hydraulic oil is input into the material shifting oil circuit 55, the hydraulic oil drives the material shifting slider 53 to slide, the material shifting slider 53 drives the material shifting rope 46 to displace, the material shifting rope 46 drives the material shifting rotating shaft 49 to rotate, and then the material shifting rod 48 is driven to shift, so that the uniform dispersion of fibers is realized.

The fourth step: brushing and oiling. With the rotation of the material shifting roller 26 and the oiling roller 35, the material shifting slider 25 and the oiling slider 36 are pressed back to the main chute 30, the connecting plate 29 drives the oiling small rotating shaft 41 and the oiling small roller 44 to extend out, the roller oil path 39, the slider main oil path 27 and the slider branch oil path 42 are communicated, oil is sprayed out, and the rotating oiling small roller 44 is driven to rotate.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.