CN113265808B

CN113265808B - Non-woven fabric production and processing equipment

Info

Publication number: CN113265808B
Application number: CN202110825413.3A
Authority: CN
Inventors: 费建军
Original assignee: Nantong Rongrui Textile Co ltd
Current assignee: Nantong Rongrui Textile Co ltd
Priority date: 2021-07-21
Filing date: 2021-07-21
Publication date: 2021-10-08
Anticipated expiration: 2041-07-21
Also published as: CN113265808A

Abstract

The invention provides non-woven fabric production and processing equipment, relates to the technical field of non-woven fabric processing, and solves the problems that continuous tensioning drainage of non-woven fabrics cannot be realized in a linkage manner in a non-woven fabric conveying process through structural improvement, and front and back airflow jet type ventilation drying cannot be realized in the linkage manner of the non-woven fabrics. A non-woven fabric production and processing device comprises a base; the base is provided with a driving structure, and the base is also provided with an auxiliary structure. Because the two connecting pipes are welded with the spray pipe, and the spray pipe is positioned above the cloth; the outer wall of the spray pipe is provided with spray holes in an annular array shape, the spray holes in the annular array shape jointly form a gas diffusion structure of the spray pipe, and the spray pipe is in elastic contact with the cloth when the sliding plate reaches the maximum downward moving position, so that air-flow drying of the top surface of the cloth can be realized, and tensioned drainage of the cloth can also be realized through the spray pipe.

Description

Non-woven fabric production and processing equipment

Technical Field

The invention belongs to the technical field of non-woven fabric processing, and particularly relates to non-woven fabric production and processing equipment.

Background

With the rapid development of China, various industries are rapidly developed, particularly some manufacturing industries, such as: in the non-woven fabric industry, the non-woven fabric is widely applied to our lives, in order to meet the needs of people, the colors of the non-woven fabric are more and more, and the non-woven fabric needs to be dried after dyeing and sealing.

As in application No.: CN201922436197.4, a drying device for materials for non-woven fabric seal production and processing, which comprises a machine base, wherein the machine base is provided with the drying device, and the drying device is internally provided with a drying cavity, a shaping cavity and a cooling cavity; the drying cavity is internally provided with two guide roller supports, a damp clearing cover and a ceramic heating plate are arranged between the two guide roller supports, the damp clearing cover is arranged above the ceramic heating plate, the damp clearing cover is connected with a first fan at the upper end of the drying equipment through a pipeline, the first fan is connected with an electrostatic dust collection group, and the electrostatic dust collection group is provided with an exhaust pipe; three heating roller supports are arranged in the shaping cavity, an exhaust hood is arranged above the heating roller supports and fixed at the top of the shaping cavity, the exhaust hood is connected with a first fan through a pipeline, an air inlet hood is arranged on the bottom surface of the drying cavity, and the air inlet hood is connected with an air heating chamber in the machine base; the utility model discloses a setting of ceramic heating board and electromagnetic heating roller makes the controllability of non-woven fabrics to the temperature at the stoving in-process to the damage to the non-woven fabrics at the stoving in-process has been reduced.

The nonwoven fabric processing equipment similar to the above application has the following disadvantages:

the existing device is often realized the non-woven fabrics is dried through a plurality of electrical components and fan type heat abstractor when adding man-hour, has promoted the cost on the one hand, and on the other hand electrical component fault rate is higher, and can not realize the taut drainage of continuous type of non-woven fabrics through the linkage of structural improvement in non-woven fabrics transportation process, and positive and negative air current jet formula is taken a breath dry when can not realizing the linkage of non-woven fabrics simultaneously.

Therefore, in view of the above, research and improvement are made for the existing structure and defects, and a non-woven fabric production and processing device is provided, so as to achieve the purpose of higher practical value.

Disclosure of Invention

In order to solve the technical problems, the invention provides a non-woven fabric production and processing device, which aims to solve the problems that the existing device usually realizes non-woven fabric drying through a plurality of electrical elements and a fan type heat dissipation device during processing, on one hand, the manufacturing cost is improved, on the other hand, the failure rate of the electrical elements is high, the non-woven fabric cannot be continuously tensioned and drained in a linkage mode in the non-woven fabric conveying process through structural improvement, and meanwhile, front-back airflow jet type ventilation and drying can not be realized during linkage of the non-woven fabric.

The invention relates to a non-woven fabric production and processing device, which is achieved by the following specific technical means:

a non-woven fabric production and processing device comprises a base; the base is provided with a driving structure, the base is also provided with an auxiliary structure, and the driving structure and the auxiliary structure are conveyed with cloth; the base is provided with an air supply structure, and the base is also provided with a shifting structure; the gas supply structure comprises two connecting pipes, a spray pipe and a spray hole, and the two connecting pipes are symmetrically welded on the sliding plate; a spray pipe is welded on the two connecting pipes and is positioned above the cloth; the outer wall of the spray pipe is provided with spray holes in an annular array shape, the spray holes in the annular array shape jointly form a gas diffusion structure of the spray pipe, and the spray pipe is in elastic contact with the cloth when the sliding plate reaches the maximum downward moving position, so that airflow type drying of the top surface of the cloth can be realized, and tensioning type drainage of the cloth can also be realized through the spray pipe.

Further, the base comprises a drying cover and an exhaust fan, the base is of a rectangular plate-shaped structure, the drying cover is fixedly connected to the base through bolts, and heating pipes are arranged in the drying cover; the top of the drying cover is provided with an air exhaust fan, and the air exhaust fan forms an air exhaust structure in the drying cover.

Furthermore, the base also comprises two fixed plates and two fixed bolts, the two fixed plates are symmetrically welded on the drying cover, and the two fixed plates are both in a rectangular plate structure; two fixing bolts are symmetrically inserted into each fixing plate, the bottom end faces of the fixing plates are not parallel and level with the bottom end face of the base, and the fixing plates form elastic anti-loosening structures of the fixing bolts.

Further, the driving structure comprises a roller A, a roller B and a gear A, the roller A is rotatably connected to the drying cover, and the gear A is mounted on the roller A; the roller B is also rotationally connected to the drying cover, a gear A is also arranged on the roller B, and the two gears A are meshed; the outer walls of the roller A and the roller B are in contact with the cloth, the rotating shaft of the roller A is connected with the driving motor, and the roller A and the roller B jointly form a friction driving type structure of the cloth.

Further, the auxiliary structure comprises a roller C, a roller D, a gear B and a belt wheel A, wherein the roller C is rotatably connected to the drying cover and is provided with the gear B; the roller D is also rotationally connected to the drying cover, a gear B is mounted on the roller D, and the two gears B are meshed; install band pulley A in roller C's the axis of rotation, and roller C and roller D's outer wall all contacts with the cloth to roller C and roller D have constituteed the auxiliary conveyor structure of cloth jointly.

Furthermore, the air supply structure comprises four sliding rods, a sliding plate, a baffle ring and an elastic piece, wherein the four sliding rods are welded on the top end face of the base, and the baffle ring is welded on the four sliding rods; the sliding plate is connected to the four sliding rods in a sliding mode, each sliding rod is sleeved with one elastic piece, and the four elastic pieces jointly form an elastic reset structure of the sliding plate.

Furthermore, the air supply structure also comprises air holes, wherein the air holes are arranged on the sliding plate in a rectangular array shape, the sliding plate is positioned below the cloth, and the air holes arranged in the rectangular array shape jointly form an airflow type drying structure of the cloth, so that the air holes are in a jet flow shape when the sliding plate reciprocates up and down, and the jet flow-shaped air flow can realize the quick drying of the cloth.

Furthermore, the air supply structure also comprises two stress blocks and a bulge, wherein the two stress blocks are symmetrically welded on the sliding plate; each stress block is welded with a bulge in a rectangular array shape, and the bulge is of a semi-cylindrical structure; the stirring structure comprises a rotating shaft, a stirring block and a belt wheel B, the rotating shaft is rotatably connected to the drying cover, the belt wheel B is mounted on the rotating shaft, and the belt wheel B is connected with the belt wheel A through a belt; two stirring blocks are mounted on the rotating shaft and are in elastic contact with the protrusions, and the rotating shaft and the stirring blocks jointly form a vibration type reciprocating stirring structure of the stress block, so that formation of continuous jet flow from the air holes can be realized.

Furthermore, the air supply structure also comprises a frame body, the frame body is a rectangular frame-shaped structure, the frame body is welded on the bottom end face of the sliding plate, and the frame body forms an air flow collecting structure for air outlet.

Compared with the prior art, the invention has the following beneficial effects:

through auxiliary structure, the cooperation setting of structure and toggle structure of supplying gas, when toggle structure rotates, can realize the continuous air-flowing type drying of cloth positive and negative, and can also realize the taut drainage of cloth, specifically as follows: firstly, the sliding plate is connected to the four sliding rods in a sliding manner, each sliding rod is sleeved with an elastic piece, and the four elastic pieces jointly form an elastic reset structure of the sliding plate; the air holes are arranged on the sliding plate in a rectangular array shape, the sliding plate is positioned below the cloth, and the air holes arranged in the rectangular array shape jointly form an airflow type drying structure of the cloth, so that the air holes are in a jet flow shape when the sliding plate reciprocates up and down, and the jet flow-shaped airflow can realize the quick drying of the cloth; secondly, the rotating shaft is rotatably connected to the drying cover, a belt wheel B is mounted on the rotating shaft, and the belt wheel B is connected with the belt wheel A through a belt; two stirring blocks are arranged on the rotating shaft, the stirring blocks are in elastic contact with the protrusions, and the rotating shaft and the stirring blocks jointly form a vibration type reciprocating stirring structure of the stress block, so that the formation of continuous jet flow discharged from the air holes can be realized; thirdly, the frame body is of a rectangular frame structure, is welded on the bottom end surface of the sliding plate and forms an air flow collecting structure from the air holes; fifthly, a spray pipe is welded on the two connecting pipes and is positioned above the cloth; the outer wall of the spray pipe is provided with spray holes in an annular array shape, the spray holes in the annular array shape jointly form a gas diffusion structure of the spray pipe, and the spray pipe is in elastic contact with the cloth when the sliding plate reaches the maximum downward moving position, so that air-flow drying of the top surface of the cloth can be realized, and tensioned drainage of the cloth can also be realized through the spray pipe.

Drawings

Fig. 1 is a schematic axial view of the present invention.

Fig. 2 is a schematic axial view of the drying hood of the present invention with the drying hood removed.

Fig. 3 is a schematic axial view of the invention in the other direction of fig. 2.

Fig. 4 is an enlarged schematic view of fig. 3 a according to the present invention.

Fig. 5 is an enlarged view of the structure of fig. 3B according to the present invention.

Fig. 6 is an enlarged schematic axial view of the air supply structure of the present invention.

Fig. 7 is a schematic axial view of the invention in the other direction from fig. 6.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a base; 101. a drying cover; 102. a fixing plate; 103. fixing the bolt; 104. an air extracting fan; 2. a drive structure; 201. a roller A; 202. a roller B; 203. a gear A; 3. an auxiliary structure; 301. a roller C; 302. a roller D; 303. a gear B; 304. a pulley A; 4. an air supply structure; 401. a slide bar; 402. a sliding plate; 40201. air holes; 403. a baffle ring; 404. an elastic member; 405. a stress block; 406. a protrusion; 407. a frame body; 408. a connecting pipe; 409. a nozzle; 410. spraying a hole; 5. a toggle structure; 501. a rotating shaft; 502. a shifting block; 503. a belt pulley B; 6. and (4) distributing.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 7:

the invention provides non-woven fabric production and processing equipment, which comprises a base 1; a driving structure 2 is arranged on the base 1, an auxiliary structure 3 is also arranged on the base 1, and cloth 6 is conveyed on the driving structure 2 and the auxiliary structure 3; the base 1 is provided with an air supply structure 4, and the base 1 is also provided with a shifting structure 5; referring to fig. 3, the air supply structure 4 includes two connection pipes 408, a nozzle 409 and a nozzle 410, and the two connection pipes 408 are symmetrically welded to the sliding plate 402; a spray pipe 409 is welded on the two connecting pipes 408, and the spray pipe 409 is positioned above the cloth 6; the outer wall of the spray pipe 409 is provided with the spray holes 410 in an annular array, the spray holes 410 in the annular array form a gas diffusion structure of the spray pipe 409, and when the sliding plate 402 reaches the maximum downward moving position, the spray pipe 409 is in elastic contact with the cloth 6, so that the airflow drying of the top surface of the cloth 6 can be realized, and the tensioning type drainage of the cloth 6 can be realized through the spray pipe 409.

Referring to fig. 1, the base 1 includes a drying cover 101 and a suction fan 104, the base 1 is a rectangular plate-shaped structure, the drying cover 101 is fixedly connected to the base 1 through bolts, and a heating pipe is arranged in the drying cover 101; the top of the drying hood 101 is provided with a suction fan 104, and the suction fan 104 constitutes a suction structure for the gas in the drying hood 101.

Referring to fig. 1, the base 1 further includes two fixing plates 102 and two fixing bolts 103, the two fixing plates 102 are symmetrically welded to the drying hood 101, and both the two fixing plates 102 are in a rectangular plate-shaped structure; two fixing bolts 103 are symmetrically inserted into each fixing plate 102, the bottom end face of each fixing plate 102 is not parallel to the bottom end face of the base 1, and the fixing plates 102 form an elastic anti-loosening structure of the fixing bolts 103.

Referring to fig. 3, the driving structure 2 includes a roller a201, a roller B202 and a gear a203, the roller a201 is rotatably connected to the drying hood 101, and the gear a203 is mounted on the roller a 201; the roller B202 is also rotationally connected to the drying cover 101, a gear A203 is also arranged on the roller B202, and the two gears A203 are meshed; the outer walls of the roller A201 and the roller B202 are both in contact with the cloth 6, the rotating shaft of the roller A201 is connected with a driving motor, and the roller A201 and the roller B202 jointly form a friction driving type structure of the cloth 6.

Referring to fig. 3, the auxiliary structure 3 includes a roller C301, a roller D302, a gear B303 and a pulley a304, the roller C301 is rotatably connected to the drying cover 101, and the gear B303 is mounted on the roller C301; the roller D302 is also rotatably connected to the drying cover 101, a gear B303 is arranged on the roller D302, and the two gears B303 are meshed; the rotating shaft of the roller C301 is provided with a belt wheel A304, the outer walls of the roller C301 and the roller D302 are both contacted with the cloth 6, and the roller C301 and the roller D302 jointly form an auxiliary conveying structure of the cloth 6.

Referring to fig. 3 and 4, the air feeding structure 4 includes four sliding rods 401, four sliding plates 402, a baffle ring 403 and an elastic member 404, the number of the sliding rods 401 is four, the four sliding rods 401 are welded on the top end surface of the base 1, and the baffle ring 403 is welded on the four sliding rods 401; the sliding plate 402 is slidably connected to the four sliding rods 401, and each sliding rod 401 is sleeved with an elastic member 404, and the four elastic members 404 form an elastic reset structure of the sliding plate 402.

Referring to fig. 6, the air supply structure 4 further includes air holes 40201, the air holes 40201 are arranged on the sliding plate 402 in a rectangular array, the sliding plate 402 is located below the cloth 6, and the air holes 40201 arranged in the rectangular array form together to form an air flow type drying structure for the cloth 6, so that when the sliding plate 402 reciprocates up and down, the air holes 40201 are in a jet flow shape, and the jet flow type air flow can realize rapid drying of the cloth 6.

Referring to fig. 6, the air feeding structure 4 further includes two force receiving blocks 405 and a protrusion 406, the two force receiving blocks 405 are provided, and the two force receiving blocks 405 are symmetrically welded to the sliding plate 402; each stress block 405 is welded with a bulge 406 in a rectangular array shape, and the bulge 406 is of a semi-cylindrical structure; referring to fig. 3, the toggle structure 5 includes a rotating shaft 501, a toggle block 502 and a pulley B503, the rotating shaft 501 is rotatably connected to the drying hood 101, the pulley B503 is mounted on the rotating shaft 501, and the pulley B503 is connected to the pulley a304 through a belt; two toggle blocks 502 are mounted on the rotating shaft 501, the toggle blocks 502 are in elastic contact with the protrusions 406, and the rotating shaft 501 and the toggle blocks 502 jointly form a vibration type reciprocating toggle structure of the stress block 405, so that the formation of continuous jet flow from the air holes 40201 can be realized.

Referring to fig. 6 and 7, the air feeding structure 4 further includes a frame 407, the frame 407 is a rectangular frame structure, the frame 407 is welded to the bottom end surface of the sliding plate 402, and the frame 407 constitutes an air flow collecting structure from the air hole 40201.

The specific use mode and function of the embodiment are as follows:

when the roller A201 rotates, firstly, the roller B202 is also rotatably connected to the drying cover 101, a gear A203 is also arranged on the roller B202, and the two gears A203 are meshed; the outer walls of the roller A201 and the roller B202 are both contacted with the cloth 6, the rotating shaft of the roller A201 is connected with a driving motor, the roller A201 and the roller B202 jointly form a friction driving type structure of the cloth 6, and the auxiliary structure 3 is also in a rotating state under the friction of the cloth 6;

during drying, firstly, the sliding plate 402 is connected to the four sliding rods 401 in a sliding manner, each sliding rod 401 is sleeved with one elastic piece 404, and the four elastic pieces 404 jointly form an elastic reset structure of the sliding plate 402; the air holes 40201 are arranged on the sliding plate 402 in a rectangular array shape, the sliding plate 402 is positioned below the cloth 6, and the air holes 40201 arranged in the rectangular array shape jointly form an airflow type drying structure of the cloth 6, so that when the sliding plate 402 reciprocates up and down, the air holes 40201 are in a jet flow shape, and the jet flow-shaped airflow can realize the rapid drying of the cloth 6; secondly, the rotating shaft 501 is rotatably connected to the drying cover 101, a belt wheel B503 is mounted on the rotating shaft 501, and the belt wheel B503 is connected with the belt wheel A304 through a belt; two toggle blocks 502 are mounted on the rotating shaft 501, the toggle blocks 502 are in elastic contact with the protrusions 406, and the rotating shaft 501 and the toggle blocks 502 jointly form a vibration type reciprocating toggle structure of the stress block 405, so that continuous jet flow from the air holes 40201 can be formed; thirdly, the frame 407 is a rectangular frame-shaped structure, the frame 407 is welded to the bottom end surface of the sliding plate 402, and the frame 407 forms an air flow collecting structure from the air hole 40201; fifthly, as the two connecting pipes 408 are welded with the spraying pipe 409, and the spraying pipe 409 is positioned above the cloth 6; the outer wall of the spray pipe 409 is provided with the spray holes 410 in an annular array, the spray holes 410 in the annular array form a gas diffusion structure of the spray pipe 409, and when the sliding plate 402 reaches the maximum downward moving position, the spray pipe 409 is in elastic contact with the cloth 6, so that the airflow drying of the top surface of the cloth 6 can be realized, and the tensioning type drainage of the cloth 6 can be realized through the spray pipe 409.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims

1. The utility model provides a non-woven fabrics production and processing equipment which characterized in that: comprises a base (1); the cloth feeding device is characterized in that a driving structure (2) is arranged on the base (1), an auxiliary structure (3) is further arranged on the base (1), and cloth (6) is conveyed on the driving structure (2) and the auxiliary structure (3); the base (1) is provided with an air supply structure (4), and the base (1) is also provided with a shifting structure (5); the driving structure (2) comprises a roller A (201), a roller B (202) and a gear A (203), the roller A (201) is rotatably connected to the drying cover (101), and the gear A (203) is installed on the roller A (201); the roller B (202) is also rotatably connected to the drying cover (101), a gear A (203) is also arranged on the roller B (202), and the two gears A (203) are meshed; the outer walls of the roller A (201) and the roller B (202) are both in contact with the cloth (6), the rotating shaft of the roller A (201) is connected with a driving motor, and the roller A (201) and the roller B (202) jointly form a friction driving type structure of the cloth (6); the auxiliary structure (3) comprises a roller C (301), a roller D (302), a gear B (303) and a belt wheel A (304), the roller C (301) is rotatably connected to the drying cover (101), and the gear B (303) is mounted on the roller C (301); the roller D (302) is also rotatably connected to the drying cover (101), a gear B (303) is mounted on the roller D (302), and the two gears B (303) are meshed; a belt wheel A (304) is mounted on a rotating shaft of the roller C (301), outer walls of the roller C (301) and the roller D (302) are in contact with the cloth (6), and the roller C (301) and the roller D (302) jointly form an auxiliary conveying structure of the cloth (6); the air feeding structure (4) comprises four sliding rods (401), a sliding plate (402), baffle rings (403) and elastic pieces (404), wherein the number of the sliding rods (401) is four, the four sliding rods (401) are all welded on the top end face of the base (1), and the baffle rings (403) are all welded on the four sliding rods (401); the sliding plate (402) is connected to the four sliding rods (401) in a sliding mode, each sliding rod (401) is sleeved with one elastic piece (404), and the four elastic pieces (404) jointly form an elastic reset structure of the sliding plate (402); the air supply structure (4) further comprises air holes (40201), the air holes (40201) are arranged on the sliding plate (402) in a rectangular array shape, the sliding plate (402) is positioned below the cloth (6), and the air holes (40201) arranged in the rectangular array shape jointly form an air flow type drying structure of the cloth (6); the air feeding structure (4) further comprises two stress blocks (405) and a protrusion (406), the two stress blocks (405) are arranged, and the two stress blocks (405) are symmetrically welded on the sliding plate (402); each stress block (405) is welded with bulges (406) in a rectangular array shape, and the bulges (406) are in a semi-cylindrical structure; the toggle structure (5) comprises a rotating shaft (501), a toggle block (502) and a belt wheel B (503), the rotating shaft (501) is rotatably connected to the drying cover (101), the rotating shaft (501) is provided with the belt wheel B (503), and the belt wheel B (503) is connected with the belt wheel A (304) through a belt; two toggle blocks (502) are mounted on the rotating shaft (501), the toggle blocks (502) are in elastic contact with the protrusions (406), and the rotating shaft (501) and the toggle blocks (502) jointly form a vibration type reciprocating toggle structure of the stress block (405); the air supply structure (4) further comprises a frame body (407), the frame body (407) is a rectangular frame-shaped structure, the frame body (407) is welded to the bottom end face of the sliding plate (402), and the frame body (407) forms an air flow collecting structure from the air holes (40201); the air supply structure (4) comprises two connecting pipes (408), two spray pipes (409) and two spray holes (410), and the two connecting pipes (408) are symmetrically welded on the sliding plate (402); a spray pipe (409) is welded on the two connecting pipes (408), and the spray pipe (409) is positioned above the cloth (6); the outer wall of the spray pipe (409) is provided with spray holes (410) in an annular array shape, the spray holes (410) in the annular array shape jointly form a gas diffusion structure of the spray pipe (409), and when the sliding plate (402) reaches the maximum downward moving position, the spray pipe (409) is in elastic contact with the cloth (6).

2. The nonwoven fabric production and processing apparatus of claim 1, wherein: the base (1) comprises a drying cover (101) and an air exhaust fan (104), the base (1) is of a rectangular plate-shaped structure, the drying cover (101) is fixedly connected to the base (1) through bolts, and heating pipes are arranged in the drying cover (101); and a suction fan (104) is installed at the top of the drying cover (101), and the suction fan (104) forms a gas suction structure in the drying cover (101).

3. The nonwoven fabric production and processing apparatus of claim 1, wherein: the base (1) further comprises two fixing plates (102) and two fixing bolts (103), the two fixing plates (102) are symmetrically welded on the drying cover (101), and the two fixing plates (102) are both rectangular plate-shaped structures; two fixing bolts (103) are symmetrically inserted into each fixing plate (102), the bottom end face of each fixing plate (102) is not flush with the bottom end face of the base (1), and the fixing plates (102) form an elastic anti-loosening structure of the fixing bolts (103).