CN216550978U - Automotive carpet production line - Google Patents

Abstract

The utility model relates to the technical field of automotive interior production, in particular to an automotive carpet production line which comprises a material moving mechanism, a feeding mechanism, a heating mechanism, an original carpet forming press, a composite forming press, a cooling compound machine, a turnover mechanism, a pulling mechanism, a material taking and transferring mechanism, an accessory assembling machine, a felt feeding machine and a water jet cutter, wherein the feeding mechanism places materials on the material moving mechanism, the material moving mechanism drives the materials to sequentially pass through the heating mechanism and the original carpet forming press, the felt is compounded by the felt feeding machine after the original carpet forming press finishes working, the materials are subjected to pressure maintaining forming by the composite forming press, then the materials are processed by the cooling compound machine, the materials are turned over by the turnover mechanism after being taken out, then the products are sent to the water jet cutter by the pulling mechanism, the materials are conveyed to the accessory assembling machine by the material taking and transferring mechanism after cutting, the whole operation flow is completed, therefore, the expenditure of labor cost is reduced, the efficiency is improved, and the potential safety hazard is reduced.

Description

Automotive carpet production line

Technical Field

The utility model relates to the technical field of automotive interior production, in particular to an automotive carpet production line.

Background

The automotive carpet is an interior trim part installed on a sheet metal of an automobile cab, has the functions of sound insulation, sound absorption, buffering and decoration, and is used for improving the comfort of vehicle driving. The automobile carpet commonly used in the market at present is mostly made of felts through compression molding. In the prior art, manual feeding is generally adopted when additional materials are added for composite forming during automobile carpet production, because the original carpet is hot when being fed into a press, the span of the press is large, manual operation cannot be achieved, the position of manual placement cannot be guaranteed, a large amount of human resources are required for material transportation and manual operation, meanwhile, potential safety hazards exist in high-temperature operation, and the main trend in the future is to replace manual operation with continuous improvement of labor cost after the material transportation and the manual operation are carried out.

SUMMERY OF THE UTILITY MODEL

In view of the above, there is a need to provide an automotive carpet production line.

In order to solve the problems of the prior art, the utility model adopts the technical scheme that:

the automobile carpet production line comprises a material moving mechanism, wherein a feeding mechanism, a heating mechanism, an original carpet forming press, a composite forming press and a cooling compound machine are sequentially arranged above the material moving mechanism along the working direction of the material moving mechanism, a turnover mechanism, a material pulling mechanism, a material taking and transferring mechanism and an accessory assembling machine are sequentially arranged at the tail end of the working direction of the material moving mechanism from right to left, a felt feeding machine is further arranged beside the composite forming press, and a water jet cutter position is arranged beside the material pulling mechanism.

Preferably, the heating mechanism comprises a first oven and a second oven, and the first oven and the second oven are sequentially arranged along the working direction of the material moving mechanism.

Preferably, the feeding mechanism comprises a rack, a stacking platform, a first material moving rack, a first lifting rack, a first slide rail, a first synchronous belt, a first driving motor, an air cylinder, a second slide rail and a first clamping jaw, the stacking platform is arranged beside the material moving mechanism, the rack stretches across the stacking platform and the material moving mechanism, the first slide rail is arranged on the rack in a horizontal state, the first material moving rack is slidably connected to the first slide rail, the moving direction of the first material moving rack is perpendicular to the working direction of the material moving mechanism, the first synchronous belt is horizontally arranged beside the first slide rail and parallel to the first slide rail, the first driving motor is fixedly connected to the rack, the first synchronous belt is in transmission connection with the first driving motor, the first material moving rack is fixedly connected with the first synchronous belt, the second slide rail is fixedly connected to the first material moving rack in a vertical state, the air cylinder is arranged beside the second slide rail in a vertical state, first crane slidable is located on the second slide rail and is located the bottom of first material moving frame, and first crane is connected with the cylinder transmission, and first clamping jaw fixed connection is in the bottom of first crane.

Preferably, move material mechanism and include support frame and two girders that are the horizontality and place, all be provided with centre gripping subassembly, first slider, chain and first rotary actuator on two girders, two chains are located the lateral wall of two girders respectively, and two first sliders are fixed connection respectively on two chains, and two centre gripping subassemblies are fixed connection respectively on two first sliders, and two first rotary actuators are located the lateral wall of two girders respectively, and two chains are connected with two first rotary actuator transmissions respectively.

Preferably, the material moving mechanism is further provided with a second rotary driver and a plurality of lifting assemblies, all the lifting assemblies are arranged at equal intervals along the length direction of the girders, all the lifting assemblies comprise two lead screws, two second sliding blocks and two third sliding rails, the two lead screws are respectively positioned beside the two girders in a vertical state, the two third sliding rails are respectively positioned beside the two lead screws in a vertical state, the two second sliding blocks are respectively connected to the two third sliding rails in a sliding manner, and the two screw rods penetrate through the two second sliding blocks, the two screw rods are respectively in threaded fit with the two second sliding blocks, connecting frames in one-to-one correspondence to the number of the lifting assemblies are arranged at the bottoms of the two girders, all the connecting frames are respectively and fixedly connected to the second sliding blocks, the second rotary driver is positioned at the bottoms of the two girders, and all the screw rods are in transmission connection with the second rotary driver.

Preferably, the felt feeding machine comprises a felt feeding frame, a fourth sliding rail, a second driving motor, a second synchronous belt, a second material moving frame, a third driving motor, a gear, a rack, a fifth sliding rail, a second lifting frame and a second clamping jaw, the felt feeding frame is located beside the composite forming press, the fourth sliding rail is located above the felt feeding frame in a horizontal state, the second material moving frame is slidably located on the fourth sliding rail, the second synchronous belt is located beside the fourth sliding rail and arranged in parallel with the fourth sliding rail, the second material moving frame is fixedly connected to the second synchronous belt, the second driving motor is fixedly connected to the frame, an output shaft of the second driving motor is in transmission connection with the second synchronous belt, the fifth sliding rail is located on the second material moving frame in a vertical state, the second lifting frame is slidably located on the fifth sliding rail, the rack is fixedly connected to the top end of the second lifting frame in a vertical state, the gear is located the second and moves the work or material rest and the gear is connected with the rack meshing, and third driving motor is located the second and moves the work or material rest, and third driving motor's output shaft and gear fixed connection, second clamping jaw fixed connection are in the bottom of second crane.

Compared with the prior art, the beneficial effect of this application is:

1. this application moves the material through the mode of needling through feed mechanism and carries and place on moving material mechanism, it removes to drive the material through moving material mechanism, loop through heating mechanism and former blanket forming press, go through the felt material loading machine with the felt complex after former blanket forming press work is accomplished, carry out the pressurize shaping to the material through compound forming press, it processes to it through the cooling compounding machine after the shaping, the material is taken out the back and is carried out the turn-ups to the material through tilting mechanism, send the product to water sword cutting machine department by drawing material mechanism again, carry the accessory assemblage machine with the material through getting material and moving mechanism after accomplishing the cutting, thereby accomplish whole operation flow, from this reduce human cost's expenditure, reduce the potential safety hazard.

2. This application loops through first oven and second oven through moving material mechanism, and first oven preheats the material, carries out the secondary heating to the material through the second oven to reach the required heating degree of material, thereby accomplish the heating to the material

3. This application drives first clamping jaw through the horizontal direction removal of first work or material rest and the vertical motion's of first crane cooperation and gets to the material clamp to accomplish automatic feeding's operation, reduce human cost's expenditure from this, reduce staff's intensity of labour.

4. This application drives the chain through first rotary actuator and rotates, drives first slider through the chain and removes to the operation that the material was moved is accomplished in the removal that drives the centre gripping subassembly, and the second reduces human cost's expenditure from this, reduces staff's intensity of labour.

5. This application drives the rising or the decline of girder through the link to satisfy different processing operation demands, reduce human cost's expenditure from this, reduce staff's intensity of labour.

6. This application drives the second clamping jaw through the horizontal direction removal of second work or material rest and the vertical motion's of second crane cooperation and gets to the material clamp to accomplish the material loading subassembly of felt, thereby reduce human cost's expenditure from this, reduce staff's intensity of labour.

Drawings

FIG. 1 is a side view of the entirety of the present application;

FIG. 2 is a top view of the entirety of the present application;

FIG. 3 is a perspective view of the present application in its entirety;

FIG. 4 is an enlarged view at A in FIG. 1 of the present application;

FIG. 5 is an enlarged view at B in FIG. 1 of the present application;

FIG. 6 is an enlarged view at C of FIG. 2 of the present application;

FIG. 7 is an enlarged view at D of FIG. 3 of the present application;

FIG. 8 is an enlarged view at E in FIG. 3 of the present application;

FIG. 9 is an enlarged view at F of FIG. 3 of the present application;

the reference numbers in the figures are:

1-a material moving mechanism; 1 a-a girder; 1 b-a clamping assembly; 1 c-a first slider; 1c 1-chain; 1 d-a lifting assembly; 1d 1-lead screw; 1d2 — second slider; 1d 3-third slide; 1d 4-link;

2-a feeding mechanism; 2 a-a frame; 2 b-a stockpiling platform; 2 c-a first material moving frame; 2c1 — first slide rail; 2c2 — first timing belt; 2c3 — first drive motor; 2 d-a first lifting frame; 2d 1-cylinder; 2d2 — second slide; 2 e-a first jaw;

3-a heating mechanism; 3 a-a first oven; 3 b-a second oven;

4-original blanket forming press;

5-a composite forming press; 5 a-felt feeding machine; 5a 1-felt feeding frame; 5a2 — a second drive motor; 5a 3-second timing belt; 5a4 — a second transfer rack; 5a5 — a third drive motor; 5a 6-second crane; 5a7 — second jaw; 5a 8-gear; 5a 9-rack; 5a 10-fourth slide rail; 5a 11-fifth slide rail;

6-cooling the compound machine;

7-turning over mechanism;

8-a material pulling mechanism; 8 a-water jet cutter station;

9-material taking and transferring mechanism;

10-accessory assembling machine.

Detailed Description

For further understanding of the features and technical means of the present invention, as well as the specific objects and functions attained by the present invention, the present invention will be described in further detail with reference to the accompanying drawings and detailed description.

As shown in fig. 1-9, the present application provides: the automobile carpet production line comprises a material moving mechanism 1, wherein a feeding mechanism 2, a heating mechanism 3, an original carpet forming press 4, a composite forming press 5 and a cooling compound machine 6 are sequentially arranged above the material moving mechanism 1 along the working direction of the material moving mechanism, a turnover mechanism 7, a material pulling mechanism 8, a material taking and transferring mechanism 9 and an accessory assembling machine 10 are sequentially arranged at the tail end of the working direction of the material moving mechanism 1 from right to left, a felt feeding machine 5a is further arranged beside the composite forming press 5, and a water jet cutter position 8a is arranged beside the material pulling mechanism 8.

Based on above-mentioned embodiment, the technical problem that this application wanted to solve adopts artifical material loading, because former blanket all is hot when sending into the press, and the big manual work of span of press can not stretch out the hand operation moreover, and the position of manual work placing can not guarantee yet, and material handling and manual work need drop into a large amount of manpower resources, and high temperature operation has the potential safety hazard simultaneously. Therefore, the material is transferred and placed on the material moving mechanism 1 through the material loading mechanism 2 in a needling mode, the material is driven to move through the material moving mechanism 1 and sequentially passes through the heating mechanism 3 and the original carpet forming press 4, the felt is compounded by the felt feeding machine 5a after the original carpet forming press 4 finishes working, the material is subjected to pressure maintaining forming by the compound forming press 5 and then processed by the cooling compound machine 6, the material is turned over by the turning mechanism 7 after being taken out, then the product is sent to the water jet cutting machine by the material pulling mechanism 8, and the material is sent to the accessory assembling machine 10 through the material transferring mechanism 9 after being cut, so that the whole operation flow is finished, the expenditure of labor cost is reduced, and potential safety hazards are reduced.

As shown in fig. 1-3, further: the heating mechanism 3 comprises a first oven 3a and a second oven 3b, and the first oven 3a and the second oven 3b are sequentially arranged along the working direction of the material moving mechanism 1.

Based on the above embodiments, the technical problem that the present application intends to solve is that the heating mechanism 3 heats the material. For this reason, this application loops through first oven 3a and second oven 3b through moving material mechanism 1, and first oven 3a preheats the material, carries out the secondary heating to the material through second oven 3b to reach the required heating degree of material, thereby accomplish the heating to the material

As shown in fig. 3, 5 and 7, further:

the feeding mechanism 2 comprises a rack 2a, a material stacking platform 2b, a first material moving rack 2c, a first lifting rack 2d, a first slide rail 2c1, a first synchronous belt 2c2, a first driving motor 2c3, an air cylinder 2d1, a second slide rail 2d2 and a first clamping jaw 2e, wherein the material stacking platform 2b is arranged at the side of the material moving mechanism 1, the rack 2a stretches across the material stacking platform 2b and the material moving mechanism 1, the first slide rail 2c1 is horizontally arranged on the rack 2a, the first material moving rack 2c is slidably connected to the first slide rail 2c1, the moving direction of the first material moving rack 2c is perpendicular to the working direction of the material moving mechanism 1, the first synchronous belt 2c2 is horizontally arranged at the side of the first slide rail 2c1 and parallel to the first slide rail 2c3, the first synchronous belt 2c2 is fixedly connected to the rack 2a, the first synchronous belt 2c 8628 is connected to the first driving motor 2c3, and the first synchronous belt 2 is fixedly connected to the first synchronous belt 862 c2, second slide rail 2d2 is vertical state fixed connection on first frame 2c that moves, and cylinder 2d1 is the side that vertical state lies in second slide rail 2d2, and first crane 2d slidable lies in second slide rail 2d2 and lies in the bottom of first frame 2c that moves, and first crane 2d is connected with cylinder 2d1 transmission, and first clamping jaw 2e fixed connection is in the bottom of first crane 2 d.

Based on the above embodiment, the technical problem that this application wants to solve is that feed mechanism 2 places the material on moving material mechanism 1. Therefore, the material is stacked through the material stacking platform 2b, when the material needs to be clamped, the first synchronous belt 2c2 is driven to rotate by the first driving motor 2c3, the first material moving frame 2c is driven to move along the direction of the first slide rail 2c1 by the first synchronous belt 2c2, so as to drive the first clamping jaw 2e to come above the material, at the moment, the cylinder 2d1 is started, the first lifting frame 2d is driven to move along the direction of the second slide rail 2d2 by the output shaft of the cylinder 2d1, the first clamping jaw 2e is driven to clamp the material on the material stacking platform 2b by the movement of the first clamping jaw 2d, the first driving motor 2c3 drives the first material moving frame 2c to move to the material moving mechanism 1, the first lifting frame 2d1 is driven by the first cylinder 2d1, so as to place the material on the material moving mechanism 1 by the first clamping jaw 2e, therefore, the automatic feeding operation is completed, the expenditure of labor cost is reduced, and the labor intensity of workers is reduced.

As shown in fig. 3, 8 and 9, further:

move material mechanism 1 and include two girders 1a that are the horizontality and place, all be provided with clamping component 1b on two girders 1a, first slider 1c, chain 1c1 and first rotary actuator, two chains 1c1 are located two girders 1 a's lateral wall respectively, two first sliders 1c are fixed connection respectively on two chains 1c1, two clamping component 1b are fixed connection respectively on two first sliders 1c, two first rotary actuator are located two girders 1 a's lateral wall respectively, two chains 1c1 are connected with two first rotary actuator transmissions respectively.

Based on the above embodiment, the technical problem that this application wants to solve is that material moving mechanism 1 presss from both sides the transport to the material. For this reason, this application all is provided with centre gripping subassembly 1b on through two girders 1a, can effectually carry out centre gripping simultaneously to the both ends of material, drive the material and remove along girder 1 a's length direction in the centre gripping, drive two chains 1c1 rotations respectively through playing two first rotary actuator simultaneously, thereby it removes to drive first slider 1c along girder 1 a's length direction through chain 1c 1's rotation, thereby drive centre gripping subassembly 1 b's removal, thereby accomplish the operation of moving the material, first rotary actuator is preferred servo motor, reduce human cost's expenditure from this, reduce staff's intensity of labour.

As shown in fig. 3 and 9, further:

the material moving mechanism 1 is further provided with a second rotary driver and a plurality of lifting components 1d, all the lifting components 1d are equidistantly arranged along the length direction of the girders 1a, all the lifting components 1d comprise two lead screws 1d1, two second sliding blocks 1d2 and two third sliding rails 1d3, the two lead screws 1d1 are vertically arranged at the sides of the two girders 1a respectively, the two third sliding rails 1d3 are vertically arranged at the sides of the two lead screws 1d1 respectively, the two second sliding blocks 1d2 are slidably connected to the two third sliding rails 1d3 respectively, the two lead screws 1d1 penetrate through the two second sliding blocks 1d2, the two lead screws 1d1 are in threaded fit with the two second sliding blocks 1d2 respectively, the bottoms of the two girders 1a are provided with connecting frames 1d4 corresponding to the lifting components 1d in number one by one, all the connecting frames 1d4 are fixedly connected to the second sliding blocks 1d2 respectively, the second rotary drivers are arranged at the bottoms of the two girders 1a, and all the screw rods 1d1 are in transmission connection with the second rotary drivers.

Based on the above embodiments, the technical problem that the present application intends to solve is to adjust the heights of two girders 1a through a lifting mechanism, so as to match the requirements of different processing operations. For this reason, this application drives all lead screws 1d1 through second rotary actuator and rotates, thereby can adjust two girder 1 a's height in step, lead screw 1d 1's rotation has driven the removal of the second slider 1d2 rather than screw-thread fit, make second slider 1d2 move along the direction of third slide rail 1d3, thereby drive link 1d 4's removal through the removal of second slider 1d2, thereby drive girder 1 a's rising or decline through link 1d4, thereby satisfy different processing operation demands, reduce the expenditure of human cost from this, reduce staff's intensity of labour.

As shown in fig. 2-4 and 6, further:

the felt feeding machine 5a comprises a felt feeding frame 5a1, a fourth sliding rail 5a10, a second driving motor 5a2, a second synchronous belt 5a3, a second feeding frame 5a4, a third driving motor 5a5, a gear 5a8, a rack 5a9, a fifth sliding rail 5a11, a second lifting frame 5a6 and a second clamping jaw 5a7, the felt feeding frame 5a1 is located beside the composite forming press 5, the fourth sliding rail 5a10 is horizontally located above the felt feeding frame 5a1, the second feeding frame 4 is slidably located on the fourth sliding rail 5a10, the second synchronous belt 5a3 is located beside and parallel to the fourth sliding rail 5a10, the second feeding frame 5a4 is fixedly connected to the second synchronous belt 3875 a3, the second driving motor 5a2 is fixedly connected to the rack 2a, an output shaft of the second driving motor 5a2 is connected to the second synchronous belt 4975 a 5475 a, and the second synchronous belt 6855 a is vertically connected to the second synchronous belt 6855 a, the second lifting frame 5a6 is slidably located on the fifth sliding rail 5a11, the rack 5a9 is vertically and fixedly connected to the top end of the second lifting frame 5a6, the gear 5a8 is located on the second material moving frame 5a4, the gear 5a8 is meshed with the rack 5a9, the third driving motor 5a5 is located on the second material moving frame 5a4, the output shaft of the third driving motor 5a5 is fixedly connected with the gear 5a8, and the second clamping jaw 5a7 is fixedly connected to the bottom of the second lifting frame 5a 6.

Based on the above-mentioned embodiment, the technical problem that this application wants to solve is that felt material loading machine 5a removes and presss from both sides the felt. For this purpose, the second driving motor 5a2 drives the second synchronous belt 5a3 to rotate, so that the second synchronous belt 5a3 drives the second material moving rack 5a4 fixedly connected with the second synchronous belt to move, so that the second material moving rack 5a4 moves along the direction of the fourth sliding rail 5a10, so as to drive the second clamping jaw 5a7 to move horizontally, meanwhile, the third driving motor 5a5 drives the gear 5a8 fixedly connected with the third driving motor, so that the gear 5a8 drives the rack 5a9 engaged with the second driving rack to move, the rack 5a9 drives the second lifting rack 5a6 to move, so that the second lifting rack 5a6 moves along the direction of the fifth sliding rail 5a11, so as to drive the second clamping jaw 7 at the bottom of the second lifting rack 5a6 to clamp the material, and the second lifting rack 5a6 drives the second clamping jaw 7 to clamp the material through the horizontal movement of the second lifting rack 5a 375 a and the vertical movement of the second lifting rack 5a6, thereby completing the feeding assembly of the felt, thereby reducing the expenditure of labor cost and reducing the labor intensity of workers.

The above examples, which are intended to represent only one or more embodiments of the present invention, are described in greater detail and with greater particularity, and are not to be construed as limiting the scope of the utility model. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (6)

1. The automobile carpet production line comprises a material moving mechanism (1) and is characterized in that a feeding mechanism (2), a heating mechanism (3), an original carpet forming press (4), a composite forming press (5) and a cooling compound machine (6) are sequentially arranged above the material moving mechanism (1) along the working direction of the material moving mechanism, a turnover mechanism (7), a material pulling mechanism (8), a material taking and transferring mechanism (9) and an accessory assembling machine (10) are sequentially arranged at the tail end of the working direction of the material moving mechanism (1) from right to left, a felt feeding machine (5a) is further arranged beside the composite forming press (5), and a water jet cutter position (8a) is arranged beside the material pulling mechanism (8).

2. The automotive carpet production line according to claim 1, characterized in that the heating mechanism (3) comprises a first oven (3a) and a second oven (3b), and the first oven (3a) and the second oven (3b) are arranged in sequence along the working direction of the material moving mechanism (1).

3. The automotive carpet production line according to claim 1, characterized in that the feeding mechanism (2) comprises a machine frame (2a), a material stacking platform (2b), a first material moving frame (2c), a first lifting frame (2d), a first slide rail (2c1), a first synchronous belt (2c2), a first driving motor (2c3), an air cylinder (2d1), a second slide rail (2d2) and a first clamping jaw (2e), the material stacking platform (2b) is arranged beside the material moving mechanism (1), the machine frame (2a) spans the material stacking platform (2b) and the material moving mechanism (1), the first slide rail (2c1) is arranged on the machine frame (2a) in a horizontal state, the first material moving frame (2c) is connected to the first slide rail (2c1) in a sliding manner, the moving direction of the first material moving frame (2c) is perpendicular to the working direction of the material moving mechanism (1), the first synchronous belt (2c2) is arranged on the first slide rail (1) in a horizontal direction and parallel to the first slide rail (2c), first driving motor (2c3) fixed connection is in frame (2a), first synchronous belt (2c2) is connected with first driving motor (2c3) transmission, first work or material rest (2c) and first synchronous belt (2c2) fixed connection, second slide rail (2d2) are vertical state fixed connection in first work or material rest (2c), cylinder (2d1) are the side that vertical state lies in second slide rail (2d2), first crane (2d) slidable lies in on second slide rail (2d2) and lies in the bottom of first work or material rest (2c), first crane (2d) is connected with cylinder (2d1) transmission, first clamping jaw (2e) fixed connection is in the bottom of first crane (2 d).

4. The automotive carpet production line according to claim 1, characterized in that the material moving mechanism (1) comprises two girders (1a) placed in a horizontal state, each of the two girders (1a) is provided with a clamping component (1b), a first sliding block (1c), a chain (1c1) and a first rotary driver, the two chains (1c1) are respectively located on the side walls of the two girders (1a), the two first sliding blocks (1c) are respectively and fixedly connected to the two chains (1c1), the two clamping components (1b) are respectively and fixedly connected to the two first sliding blocks (1c), the two first rotary drivers are respectively located on the side walls of the two girders (1a), and the two chains (1c1) are respectively in transmission connection with the two first rotary drivers.

5. The automotive carpet production line according to claim 4, characterized in that the material moving mechanism (1) is further provided with a second rotary driver and a plurality of lifting components (1d), all the lifting components (1d) are equidistantly arranged along the length direction of the crossbeam (1a), all the lifting components (1d) comprise two lead screws (1d1), two second sliders (1d2) and two third slide rails (1d3), both the lead screws (1d1) are vertically arranged at the sides of the two crossbeams (1a), both the third slide rails (1d3) are vertically arranged at the sides of the two lead screws (1d1), both the second sliders (1d2) are slidably connected to the two third slide rails (1d3), and both the lead screws (1d1) penetrate through the two second sliders (1d2), both the two lead screws (1d1) are respectively in threaded fit with both the second sliders (1d2), the bottom of two girder (1a) all is provided with link (1d4) with lifting unit (1d) quantity one-to-one, and all link (1d4) are fixed connection respectively on second slider (1d2), and the second rotary actuator is located the bottom of two girder (1a), and all lead screws (1d1) all are connected with the transmission of second rotary actuator.

6. The automotive carpet production line according to claim 3, characterized in that the felt feeder (5a) comprises a felt feeding rack (5a1), a fourth slide rail (5a10), a second driving motor (5a2), a second synchronous belt (5a3), a second feeding rack (5a4), a third driving motor (5a5), a gear (5a8), a rack (5a9), a fifth slide rail (5a11), a second lifting rack (5a6) and a second clamping jaw (5a7), the felt feeding rack (5a1) is located at the side of the composite forming press (5), the fourth slide rail (5a10) is located above the felt feeding rack (5a1) in a horizontal state, the second feeding rack (5a4) is slidably located on the fourth slide rail (5a10), the second synchronous belt (5a3) is located at the side of the fourth slide rail (5a10) and is arranged in parallel to the second feeding rack (5a4), and the second synchronous belt (5a 8242) is fixedly connected to the second feeding rack (3), the second driving motor (5a2) is fixedly connected to the rack (2a), an output shaft of the second driving motor (5a2) is in transmission connection with a second synchronous belt (5a3), the fifth sliding rail (5a11) is located on the second material moving frame (5a4) in a vertical state, the second lifting frame (5a6) is slidably located on the fifth sliding rail (5a11), the rack (5a9) is fixedly connected to the top end of the second lifting frame (5a6) in a vertical state, the gear (5a8) is located on the second material moving frame (5a4) and the gear (5a8) is in meshing connection with the rack (5a9), the third driving motor (5a5) is located on the second material moving frame (5a4), an output shaft of the third driving motor (5a5) is fixedly connected with the gear (5a8), and the second clamping jaw (5a7) is fixedly connected to the bottom of the second lifting frame (5a 6).

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