CN218909282U - Textile clothing cloth conveying device - Google Patents

Abstract

The utility model provides a textile clothing cloth conveying device, which comprises a conveying table, wherein the top end of the conveying table is connected with a conveying belt, and the upper surface of the conveying table is connected with a conveying mechanism; the conveying mechanism comprises a first feeding component connected to one end of the upper surface of the conveying table, a second pushing component connected to the other end of the upper surface of the conveying table, and a monitoring component arranged between the first feeding component and the second pushing component; the monitoring assembly comprises a flatness monitoring component connected to the upper surface of the conveying table, and a support frame arranged on one side of the flatness monitoring component and mounted on the upper surface of the conveying table, wherein an air cylinder is connected to the upper surface of the support frame, and a piston rod of the air cylinder extends to the inner part of the support frame and is connected with a cloth pushing roller. The utility model can rapidly flatten the textile clothing cloth, so as to facilitate rapid conveying of the cloth.

Description

Textile clothing cloth conveying device

Technical Field

The utility model mainly relates to the technical field of textile clothing processing, in particular to a textile clothing cloth conveying device.

Background

Before the textile fabric is rolled, the textile fabric is automatically conveyed by a conveying device in order to improve the rolling efficiency of the textile clothing fabric.

According to a textile fabric conveying device provided by patent document with application number of CN202010197465.6, the textile fabric conveying device comprises a conveyor, a winding roller is arranged on one side of the conveyor, the conveyor comprises a driving conveying roller, a driven conveying roller, a conveying belt and a conveying frame, a plurality of fixing components are arranged on the conveying belt at equal intervals, a water removing component, an ironing component and a leveling component are arranged above the conveying belt, the leveling component comprises a first driving roller and a second driving roller, the first driving roller and the second driving roller are in driving connection through a driving belt, the driving belt is in clearance arrangement with the conveying belt, an electric connecting piece is attached to the driving belt, the electric connecting piece is an electric connecting piece in a plurality of electric connection, and the electric connecting piece is connected with a static eliminator. The utility model is convenient for reducing the wrinkles on the cloth.

Above-mentioned cloth conveyor is in the transportation process, gets rid of the moisture on the water subassembly clearance cloth, carries out the stoving operation to the cloth, the storage of follow-up cloth of being convenient for, but traditional cloth conveyor carries and flattens the clothing cloth of weaving through the rotation of driving roller, and this mode piles up the cloth because of the fold of cloth in driving roller department easily to influence the rate of transport of cloth.

Disclosure of Invention

The utility model mainly provides a textile clothing cloth conveying device which is used for solving the technical problems in the background technology.

The technical scheme adopted for solving the technical problems is as follows:

the cloth conveying device for the textile clothing comprises a conveying table, wherein the top end of the conveying table is connected with a conveying belt, and the upper surface of the conveying table is connected with a conveying mechanism;

the conveying mechanism comprises a first feeding component connected to one end of the upper surface of the conveying table, a second pushing component connected to the other end of the upper surface of the conveying table, and a monitoring component arranged between the first feeding component and the second pushing component;

the monitoring assembly comprises a flatness monitoring component connected to the upper surface of the conveying table, and a support frame arranged on one side of the flatness monitoring component and mounted on the upper surface of the conveying table, wherein an air cylinder is connected to the upper surface of the support frame, and a piston rod of the air cylinder extends to the inner part of the support frame and is connected with a cloth pushing roller.

Further, a rotating shaft frame is arranged at one end of the piston rod of the air cylinder extending to the inside of the supporting frame, and the rotating shaft frame is connected with the cloth pushing roller in a rotating mode through a rotating shaft.

Further, the flatness monitoring component comprises a first photoelectric sensor arranged on the upper surface of the conveying table and a second photoelectric sensor arranged on the upper surface of the first photoelectric sensor.

Further, the first feeding assembly comprises first bearing frames which are arranged on the upper surface of the conveying table and are symmetrically arranged by taking the conveying belt as a central shaft, and a first feeding roller and a second feeding roller are sequentially connected between the two first bearing frames in a rotating mode from top to bottom.

Further, a moving aluminum cup is arranged in the first bearing frame and is coaxial with the first feeding roller, an electromagnet is inserted into one end of the moving aluminum cup, and the electromagnet is mounted in the first bearing frame.

Further, the second pushing component comprises a second bearing frame which is arranged on the upper surface of the conveying table and symmetrically arranged by taking the conveying belt as a central shaft, and a third feeding roller which is arranged between the two second bearing frames and sequentially arranged from top to bottom.

Further, the second pushing component further comprises a motor which is arranged on one side surface of the second bearing frame and is coaxially arranged with the third feeding roller.

Compared with the prior art, the utility model has the beneficial effects that:

firstly, the utility model can carry out rapid flattening on the cloth of the textile clothing so as to facilitate rapid conveying of the cloth, and specifically comprises the following steps: the piston rod of the cylinder drives the rotating shaft frame to descend, and the rotating shaft frame drives the cloth pushing roller to descend so as to press the textile clothing cloth on the conveying belt, so that the textile clothing cloth is kept in full contact with the cloth pushing roller and the conveying belt, when the textile clothing cloth has folds, the folds of the cloth arch due to the contact with the cloth pushing roller, and the cloth passing through the cloth pushing roller is flattened.

Secondly, the utility model uses the magnetic field formed after the electromagnet is electrified to attract the moving aluminum cup inserted into the electromagnet, and the moving aluminum cup and the first feeding roller are coaxially arranged, so that the rotation of the first feeding roller is slowed down, the friction force between the first feeding roller and the cloth of the textile clothing is increased, the movement of one end of the cloth is slowed down, the other end of the cloth is convenient to accelerate the conveying, and the arched cloth is quickly leveled.

The utility model will be explained in detail below with reference to the drawings and specific embodiments.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is an enlarged view of the structure of the area A in FIG. 1;

FIG. 3 is an isometric view of the present utility model;

fig. 4 is a cross-sectional view of a first bearing frame of the present utility model.

In the figure: 10. a conveying table; 20. a conveyor belt; 30. a conveying mechanism; 31. a first feed assembly; 311. a first bearing bracket; 312. a first feed roller; 313. a second feed roller; 314. a moving aluminum cup; 315. an electromagnet; 32. the second pushing component; 321. a second bearing frame; 322. a third feed roller; 323. a motor; 33. a monitoring component; 331. a flatness monitoring part; 3311. a first photosensor; 3312. a second photosensor; 332. a support frame; 333. a cylinder; 334. a cloth pushing roller.

Detailed Description

In order that the utility model may be more fully understood, a more particular description of the utility model will be rendered by reference to the appended drawings, in which several embodiments of the utility model are illustrated, but which may be embodied in different forms and are not limited to the embodiments described herein, which are, on the contrary, provided to provide a more thorough and complete disclosure of the utility model.

It will be understood that when an element is referred to as being "mounted" on another element, it can be directly on the other element or intervening elements may be present, and when an element is referred to as being "connected" to the other element, it may be directly connected to the other element or intervening elements may also be present, the terms "vertical", "horizontal", "left", "right" and the like are used herein for the purpose of illustration only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs, and the terms used herein in this description of the utility model are for the purpose of describing particular embodiments only and are not intended to be limiting of the utility model, with the term "and/or" as used herein including any and all combinations of one or more of the associated listed items.

1-4, a fabric conveying device for textile clothing includes a conveying table 10, wherein a conveying belt 20 is connected to the top end of the conveying table 10, and a conveying mechanism 30 is connected to the upper surface of the conveying table 10;

the conveying mechanism 30 comprises a first feeding assembly 31 connected to one end of the upper surface of the conveying table 10, a second pushing assembly 32 connected to the other end of the upper surface of the conveying table 10, and a monitoring assembly 33 arranged between the first feeding assembly 31 and the second pushing assembly 32;

the monitoring assembly 33 comprises a flatness monitoring component 331 connected to the upper surface of the conveying table 10, and a supporting frame 332 arranged on one side of the flatness monitoring component 331 and mounted on the upper surface of the conveying table 10, an air cylinder 333 is connected to the upper surface of the supporting frame 332, and a piston rod of the air cylinder 333 extends to the inner portion of the supporting frame 332 and is connected with a cloth pushing roller 334.

Specifically, referring to fig. 1 and 2, a rotating shaft frame 3331 is mounted at one end of the piston rod of the air cylinder 333 extending into the support frame 332, and the rotating shaft frame 3331 is rotatably connected with the cloth pushing roller 334 through a rotating shaft;

the flatness monitoring part 331 includes a first photosensor 3311 mounted on the upper surface of the conveying table 10, and a second photosensor 3312 mounted on the upper surface of the first photosensor 3311;

further, the rotating shaft frame 3331 is driven to descend by the piston rod of the air cylinder 333, the cloth pushing roller 334 is driven to descend by the rotating shaft frame 3331 so as to press the textile clothing cloth on the conveying belt 20, and the sufficient contact between the textile clothing cloth and the cloth pushing roller 334 and the conveying belt 20 is kept, so that when the textile clothing cloth has wrinkles thereon, the wrinkles of the cloth arch due to the contact with the cloth pushing roller 334;

further, whether the cloth of the textile garment passes through is monitored by the first photoelectric sensor 3311, whether the cloth of the textile garment passes through is monitored by the second photoelectric sensor 3312 from the upper side of the first photoelectric sensor 3311, a photoelectric induction door is formed by the cooperation of the first photoelectric sensor 3311 and the second photoelectric sensor 3312, whether the arched cloth exists near the cloth pushing roller 334 is monitored, and whether the posture of the cloth of the textile garment needs to be adjusted is judged by a controller connected with the first photoelectric sensor 3311 and the second photoelectric sensor 3312.

Specifically, referring to fig. 3 and 4, the first feeding assembly 31 includes a first bearing frame 311 installed on the upper surface of the conveying table 10 and symmetrically disposed about the conveying belt 20 as a central axis, and a first feeding roller 312 and a second feeding roller 313 are sequentially rotatably connected between the two first bearing frames 311 from top to bottom;

a moving aluminum cup 314 is arranged in the first bearing frame 311, the moving aluminum cup 314 and the first feeding roller 312 are coaxially arranged, an electromagnet 315 is inserted into one end of the moving aluminum cup 314, and the electromagnet 315 is mounted in the first bearing frame 311;

further, after the fabric of the textile garment passes through the gap between the first feeding roller 312 and the second feeding roller 313, the fabric in the gap is pushed to move by synchronous rotation of the first feeding roller 312 and the second feeding roller 313;

further, the magnetic field formed after the electromagnet 315 is electrified is used for attracting the moving aluminum cup 314 inserted into the electromagnet 315, and the moving aluminum cup 314 and the first feeding roller 312 are coaxially arranged, so that the rotation of the first feeding roller 312 is slowed down, the friction between the first feeding roller 312 and the cloth of the textile clothing is increased, the movement of one end of the cloth is slowed down, the other end of the cloth is convenient for accelerating the conveying, and the arched cloth is quickly leveled.

Specifically, referring to fig. 3 and 4, the second pushing assembly 32 includes a second bearing frame 321 installed on the upper surface of the conveying table 10 and symmetrically disposed about the conveying belt 20 as a central axis, and a third feeding roller 322 disposed between the two second bearing frames 321 and sequentially disposed from top to bottom;

the second pushing assembly 32 further includes a motor 323 disposed on one side surface of the second bearing frame 321 and coaxially disposed with the third feeding roller 322;

further, the third feeding rollers 322 are supported by the second bearing frame 321, and cloth passing through a gap between the two third feeding rollers 322 is conveyed by synchronous rotation of the two third feeding rollers 322;

further, the third feeding roller 322 is driven to rotate by the motor 323, and when the controller connected with the first photoelectric sensor 3311 and the second photoelectric sensor 3312 judges that an electric signal of cloth air supply is received, the motor 323 connected with the controller is controlled to work in time.

The specific operation mode of the utility model is as follows:

when the fabric is required to be conveyed so as to be wound by the winding roller, after the fabric is led to pass through the first feeding component 31, the monitoring component 33 and the second pushing component 32 in sequence and then is connected with the winding roller, the third feeding roller 322 is driven to rotate by the motor 323, when the controller connected with the first photoelectric sensor 3311 and the second photoelectric sensor 3312 judges that an electric signal for supplying air to the fabric is received, the motor 323 connected with the first photoelectric sensor 3311 and the second photoelectric sensor 3312 is controlled to work in time, the motor drives the second feeding roller 313 connected with the output shaft of the second photoelectric sensor 3312 to rotate, and under the friction effect between the fabric and the first feeding roller 312, the first feeding roller 312 and the second feeding roller 313 synchronously rotate so as to push the fabric in the gap to move;

the rotating shaft frame 3331 is driven to descend by the piston rod of the air cylinder 333, the cloth pushing roller 334 is driven to descend by the rotating shaft frame 3331 so as to press the textile clothing cloth on the conveying belt 20, and the sufficient contact between the textile clothing cloth and the cloth pushing roller 334 and the conveying belt 20 is kept, so that when the textile clothing cloth has folds on the cloth, the folds of the cloth arch due to the contact with the cloth pushing roller 334, and the cloth passing through the cloth pushing roller 334 is flattened;

monitoring whether cloth of the textile clothing passes through the first photoelectric sensor 3311, monitoring whether cloth of the textile clothing passes through the second photoelectric sensor 3312 from the upper side of the first photoelectric sensor 3311, forming a photoelectric induction door through the cooperation of the first photoelectric sensor 3311 and the second photoelectric sensor 3312, and monitoring whether arched cloth exists near the cloth pushing roller 334 so as to judge whether the posture of the cloth of the textile clothing needs to be adjusted or not through a controller connected with the first photoelectric sensor 3311 and the second photoelectric sensor 3312;

the magnetic field formed after the electromagnet 315 is electrified is used for attracting the moving aluminum cup 314 inserted into the electromagnet 315, and the moving aluminum cup 314 and the first feeding roller 312 are coaxially arranged, so that the rotation of the first feeding roller 312 is slowed down, the friction between the first feeding roller 312 and the cloth of the textile clothing is increased, the movement of one end of the cloth is slowed down, the other end of the cloth is convenient for accelerating the conveying, and the arched cloth is quickly leveled.

While the utility model has been described above with reference to the accompanying drawings, it will be apparent that the utility model is not limited to the embodiments described above, but is intended to be within the scope of the utility model, as long as such insubstantial modifications are made by the method concepts and technical solutions of the utility model, or the concepts and technical solutions of the utility model are applied directly to other occasions without any modifications.

Claims (7)

1. The cloth conveying device for the textile clothing comprises a conveying table (10), and is characterized in that the top end of the conveying table (10) is connected with a conveying belt (20), and the upper surface of the conveying table (10) is connected with a conveying mechanism (30);

the conveying mechanism (30) comprises a first feeding assembly (31) connected to one end of the upper surface of the conveying table (10), a second pushing assembly (32) connected to the other end of the upper surface of the conveying table (10), and a monitoring assembly (33) arranged between the first feeding assembly (31) and the second pushing assembly (32);

the monitoring assembly (33) comprises a flatness monitoring component (331) connected to the upper surface of the conveying table (10), and a supporting frame (332) arranged on one side of the flatness monitoring component (331) and mounted on the upper surface of the conveying table (10), an air cylinder (333) is connected to the upper surface of the supporting frame (332), and a piston rod of the air cylinder (333) extends to the inner portion of the supporting frame (332) and is connected with a cloth pushing roller (334).

2. The cloth conveying device for textile clothing according to claim 1, wherein a rotating shaft frame (3331) is mounted at one end of a piston rod of the air cylinder (333) extending to the inside of the supporting frame (332), and the rotating shaft frame (3331) is rotatably connected with the cloth pushing roller (334) through a rotating shaft.

3. A textile garment material transporting device according to claim 1, wherein said flatness monitoring means (331) comprises a first photosensor (3311) mounted to an upper surface of said transporting table (10), and a second photosensor (3312) mounted to an upper surface of said first photosensor (3311).

4. The cloth conveying device for textile clothing according to claim 1, wherein the first feeding assembly (31) comprises first bearing frames (311) which are installed on the upper surface of the conveying table (10) and are symmetrically arranged by taking the conveying belt (20) as a central axis, and a first feeding roller (312) and a second feeding roller (313) are sequentially connected between the two first bearing frames (311) in a rotating mode from top to bottom.

5. The cloth conveying device for textile clothing according to claim 4, wherein a moving aluminum cup (314) is arranged in the first bearing frame (311), the moving aluminum cup (314) and the first feeding roller (312) are coaxially arranged, an electromagnet (315) is inserted into one end of the moving aluminum cup (314), and the electromagnet (315) is mounted in the first bearing frame (311).

6. The cloth conveying device for textile clothing according to claim 1, wherein the second pushing assembly (32) comprises a second bearing frame (321) which is installed on the upper surface of the conveying table (10) and is symmetrically arranged by taking the conveying belt (20) as a central axis, and a third feeding roller (322) which is arranged between the two second bearing frames (321) and is sequentially arranged from top to bottom.

7. A textile garment material transporting device according to claim 6, wherein said second pushing assembly (32) further comprises a motor (323) provided on a side surface of said second bearing frame (321) and coaxially arranged with said third feed roller (322).

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