CN115821432A

CN115821432A - Cotton yarn weaving carding equipment

Info

Publication number: CN115821432A
Application number: CN202310036314.6A
Authority: CN
Inventors: 张立聘; 周大发; 罗永望
Original assignee: Cangnan Leisheng Textile Co ltd
Current assignee: Cangnan Leisheng Textile Co ltd
Priority date: 2023-01-08
Filing date: 2023-01-08
Publication date: 2023-03-21

Abstract

The invention discloses a cotton yarn textile carding device, belonging to the field of cotton yarn textile, comprising: a carding machine body; a bin disposed at the carding machine body feed delivery end; a gap is reserved between a discharge hole at the bottom end of the storage bin and a conveying belt at the feeding and conveying end of the carding machine body; the dispersion structure is arranged in the inner cavity of the stock bin; the servo motor is arranged outside the stock bin; wherein, the servo motor is used for controlling the bidirectional rotation of the disperser A and the disperser B on the dispersing structure. The invention has the advantages that the two-way rotation of the disperser A and the disperser B on the dispersing structure is utilized to stir the falling cotton materials to two sides in the storage bin, so that the cotton seedlings falling in a centralized manner are dispersed in the storage bin, the cotton materials discharged from the discharge port at the bottom end of the storage bin are dispersed and fall on the conveying belt at the feeding and conveying end of the carding machine body, the cotton materials conveyed into the carding machine body cannot be excessively centralized or accumulated, the cotton materials are dispersed continuously, and the labor is saved.

Description

Cotton yarn weaving carding equipment

Technical Field

The invention relates to the field of cotton yarn spinning, in particular to cotton yarn spinning carding equipment.

Background

The cotton yarn is made of cotton fiber through a spinning process, and is called cotton thread after being folded and processed. The cotton yarn needs to be combed after production before a finished product is rolled, so that the cotton yarn is prevented from being wound in the transmission process, and therefore, the cotton yarn is combed by using a cotton yarn carding machine.

"https:// www.douyin.com/search/% E6% A3%89% E7-BA-%B 1-E6-A2-B3-The-E7-90-86-E6-C-baimod id = 7019868168103941131532 & -publish \ time =0& -sort u type =0& -source = switch u tab & -type = video". A cotton yarn carding machine as disclosed in the above-mentioned website addresses, feeds cotton from a conveyor belt at the infeed end of the carding machine, after carding processing of the cotton yarn by the carding machine, forms a continuous cotton yarn output. However, the device has the following disadvantages in the actual use process:

when using above-mentioned device to carry out cotton yarn and combing, need the staff to disperse the cotton after sending into the cotton from the conveyer belt of carding machine feed end department, the cotton then that continuously sends needs the staff to disperse the cotton always, intensity of labour is bigger. In view of this, we propose a cotton yarn spinning carding machine.

Disclosure of Invention

1. Technical problem to be solved

The invention aims to provide cotton yarn spinning carding equipment to solve the problems in the background technology.

2. Technical scheme

A cotton yarn textile carding machine, comprising: a carding machine body; a bin disposed at the carding machine body feed delivery end; a gap is reserved between a discharge hole at the bottom end of the storage bin and a conveying belt at the feeding and conveying end of the carding machine body; the dispersion structure is arranged in the inner cavity of the storage bin; the servo motor is arranged outside the stock bin; wherein, the servo motor is used for controlling the bidirectional rotation of the disperser A and the disperser B on the dispersing structure.

Preferably, the silo comprises: the bin body is fixedly arranged at the feeding and conveying end of the carding machine body; the feeding channel is fixedly arranged in the middle of the top end of the bin body; the material baffle is fixedly arranged on the outer side of the discharge hole at the bottom end of the bin body; the bottom end of the striker plate is not contacted with a conveying belt of the feeding and conveying end of the carding machine body.

Preferably, the dispersion structure comprises: a transmission assembly; the disperser A is arranged at the driving end of the transmission assembly; a disperser B arranged at the driven end of the transmission assembly; the driving end of the transmission assembly is driven by the servo motor to rotate, and the driven end of the transmission assembly is matched with the driving end of the transmission assembly to rotate, so that the bidirectional rotating material dispersing of the disperser A and the disperser B is realized.

Preferably, the transmission assembly comprises: a housing; the connecting roller A is rotatably arranged on the outer side of the shell through a sealing bearing; one end of the connecting roller A, which is far away from the shell, is connected with an output shaft of the output end of the servo motor; the bevel gear A is sleeved at one end of the connecting roller A, which is positioned in the shell; the connecting roller B is rotatably arranged on the inner side of the shell through a sealing bearing; one end of the connecting roller B, which is far away from the shell, is rotatably connected with the inner side wall of the shell through a rotating shaft; the bevel gear B is sleeved at one end of the connecting roller B in the shell; the bevel gear C is rotatably arranged on the inner top wall of the shell through a sealing bearing; the bevel gear A, the bevel gear C and the bevel gear B are sequentially connected in a meshed manner.

Preferably, the disperser a comprises: the sleeve A is sleeved at one end of the connecting roller A, which is positioned outside the shell; the dispersing blades A are fixedly arranged on the circumferential surface of the outer wall of the sleeve A in an annular array; the disperser B comprises: the sleeve B is sleeved at one end, outside the shell, of the connecting roller B; and the dispersing blades B are fixedly arranged on the circumferential surface of the outer wall of the sleeve B in an annular array.

Preferably, a plurality of the dispersing blades a and B are successively shortened along the outer walls of the sleeve a and the sleeve B, respectively.

Preferably, the side edges of the dispersing blades A and B are respectively arranged into an arc shape, and the arc surfaces of the dispersing blades A and B are opposite.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

(1) According to the invention, through the arrangement of the dispersing structure, the disperser A and the disperser B on the dispersing structure rotate in different directions respectively by utilizing the bidirectional rotation of the disperser A and the disperser B, so that the falling cotton materials are stirred towards two sides of the storage bin, and the concentrated falling cotton seedlings are dispersed in the storage bin, so that the cotton materials discharged from the discharge port at the bottom end of the storage bin are dispersed and fall on the conveying belt at the feeding and conveying end of the carding machine body, and the cotton materials conveyed into the carding machine body cannot be concentrated or accumulated too much, and are dispersed continuously, so that the labor is saved. The problem of need the staff with the cotton dispersion after sending into the cotton from the conveyer belt of carding machine feed end department, the cotton then needs the staff to disperse the cotton always of continuous sending, intensity of labour is great is solved.

(2) According to the invention, the dispersing blades A and the dispersing blades B are arranged, and the falling cotton materials are contacted by the dispersing blades A and the dispersing blades B with sequentially shortened lengths, so that the cotton materials are dispersed at different distances, the plane area of the inner cavity of the storage bin can be covered, and the falling cotton materials are prevented from being dispersed towards the same area. The opposite arc surfaces of the dispersing leaves A and the dispersing leaves B are arranged to ensure that the dispersing leaves A and the dispersing leaves B contact cotton materials and reduce the cotton materials from hanging on the dispersing leaves A and the dispersing leaves B when the cotton materials are dispersed.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of a cross-sectional connection structure of a storage bin according to the present invention;

FIG. 3 is a schematic view of the dispersion structure of the present invention;

FIG. 4 is a schematic view of a sectional connection structure of the cartridge body of the present invention;

the numbering in the figures illustrates:

1. a carding machine body; 2. a storage bin; 3. a servo motor; 4. a dispersed structure;

201. a feed channel; 202. a bin body; 203. a striker plate;

401. a transmission assembly; 402. a sleeve A; 403. dispersing leaves A; 404. dispersing leaves B; 405. a sleeve B;

4011. a housing; 4012. sealing the bearing; 4013. a rotating shaft; 4014. a connecting roller B; 4015. a bevel gear B; 4016. a bevel gear C; 4017. a bevel gear A; 4018. roller a is attached.

Detailed Description

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Referring to fig. 1-4, the present invention provides a technical solution:

a cotton yarn textile carding machine, comprising:

a carding machine body 1; the bin 2 is arranged at the feeding and conveying end of the carding machine body 1; wherein a gap is reserved between a discharge port at the bottom end of the storage bin 2 and a conveying belt at the feeding and conveying end of the carding machine body 1; the dispersion structure 4 is arranged in the inner cavity of the stock bin 2; the servo motor 3 is arranged outside the stock bin 2; wherein, the servo motor 3 is used for controlling the bidirectional rotation of the disperser A and the disperser B on the dispersing structure 4. According to the invention, the dispersing structure 4 is arranged, and the disperser A and the disperser B on the dispersing structure 4 rotate in different directions respectively by utilizing the bidirectional rotation of the disperser A and the disperser B, so that the falling cotton materials are shifted to two sides in the bin 2, and the cotton seedlings falling in a concentrated manner are dispersed in the bin 2, so that the cotton materials discharged from the discharge port at the bottom end of the bin 2 are dispersed and fall on the conveying belt at the feeding and conveying end of the carding machine body 1, the cotton materials conveyed into the carding machine body 1 are not excessively concentrated or accumulated, the cotton materials are dispersed continuously, and the labor is saved. The problem of need the staff with the cotton dispersion after sending into the cotton from the conveyer belt of carding machine feed end department, the cotton then needs the staff to disperse the cotton always of continuous sending, intensity of labour is great is solved.

Specifically, the bunker 2 includes:

the bin body 202 is fixedly arranged at the feeding conveying end of the carding machine body 1; the feeding channel 201 is fixedly arranged in the middle of the top end of the bin body 202; the material baffle plate 203 is fixedly arranged outside the discharge hole at the bottom end of the bin body 202; wherein, the striker plate 203 inclines towards the feeding and conveying end of the carding machine body 1, and the bottom end of the striker plate 203 is not contacted with the conveying belt at the feeding and conveying end of the carding machine body 1. The inlet of the feeding channel 201 is connected with an external cotton conveying pipeline through a flange, cotton entering the bin body 202 from the feeding channel 201 falls down from the middle of the bin body 202 to contact the dispersing structure 4, and dispersed fabric is discharged along a discharge port at the bottom end of the bin body 202 and falls on a conveying belt at the feeding conveying end of the carding machine body 1 and conveyed into the carding machine body 1 for carding operation.

Further, the dispersing structure 4 includes:

a drive assembly 401; a disperser A arranged at the active end of the transmission assembly 401; disperser B, arrange at driven end of drive assembly 401; wherein, the drive end of drive assembly 401 is driven through servo motor 3 and is rotated, and the driven end of drive assembly 401 cooperates the drive end of drive assembly 401 and rotates, realizes the two-way rotation material dispersion of deconcentrator A and deconcentrator B. Carding machine body 1 during operation, servo motor 3 circular telegram is started, the output shaft of 3 delivery ends of servo motor drives transmission assembly 401 drive end and rotates along with the pointer, then deconcentrator A rotates along with transmission assembly 401 drive end, under the effect of the built-in gear train of transmission assembly 401, transmission assembly 401 driven end cooperation transmission assembly 401 drive end anticlockwise rotation, then deconcentrator B anticlockwise rotation, cause deconcentrator A along with deconcentrator B rotate towards different directions respectively, with the cotton of whereabouts towards the inside both sides dispersion of feed bin 2, and then realize the purpose of the interior cotton intensive dispersion of feed bin 2.

Still further, the transmission assembly 401 includes:

a housing 4011; a connecting roller a4018 rotatably provided outside the casing 4011 through a seal bearing 4012; one end of the connecting roller A4018 departing from the shell 4011 is connected with an output shaft of the output end of the servo motor 3; the bevel gear A4017 is sleeved at one end, located in the shell 4011, of the connecting roller A4018; a connecting roller B4014 rotatably provided inside the casing 4011 through a seal bearing 4012; one end of the connecting roller B4014, which is far away from the shell 4011, is rotatably connected with the inner side wall of the shell 4011 through a rotating shaft 4013; a bevel gear B4015 sleeved at one end of the connecting roller B4014 in the shell 4011; a bevel gear C4016 rotatably arranged on the inner top wall of the shell 4011 through a seal bearing 4012; wherein, bevel gear A4017, bevel gear C4016 and bevel gear B4015 are engaged and connected in sequence. An output shaft at the conveying end of the servo motor 3 drives the connecting roller A4018 to rotate clockwise, the bevel gear A4017 rotates clockwise, the bevel gear C4016 meshed with the bevel gear A4017 is connected with the bevel gear C4016 to rotate along with the bevel gear C4016, and the bevel gear B4015 meshed with the bevel gear C4016 rotates along with the bevel gear C4016 counterclockwise, so that the cotton material is dispersed by the disperser A and the disperser B which rotate in different directions respectively. And the top of the shell 4011 is set to be a triangular structure, and the tip of the triangular structure faces upwards, so that falling materials are dispersed.

Further, the disperser a includes:

the sleeve A402 is sleeved at one end of the connecting roller A4018 outside the shell 4011; seven dispersing blades A403 which are fixedly arranged on the circumferential surface of the outer wall of the sleeve A402 in an annular array; the disperser B comprises: a sleeve B405, sleeved at one end of the connecting roller B4014 outside the housing 4011; seven dispersing blades B404 are fixedly arranged on the circumferential surface of the outer wall of the sleeve B405 in an annular array. The sleeve a402 rotates clockwise with the joining roller a4018, and the seven dispersing blades a403 rotate clockwise; the sleeve B405 rotates counterclockwise with the connecting roller B4014, and the seven dispersing blades B404 rotate counterclockwise, and the falling cotton is dispersed by the dispersing blades a403 and B404 having different rotation directions.

It is worth noting that the seven dispersing lobes a403 and B404 are successively shorter along the outer wall of the sleeve a402 and B405, respectively. According to the invention, the dispersing blades A403 and B404 are arranged, and the falling cotton materials are contacted by the dispersing blades A403 and B404 with sequentially shortened lengths, so that the cotton materials are dispersed at different distances, the plane area of the inner cavity of the bin 2 can be covered, and the falling cotton materials are prevented from being dispersed towards the same area.

It is noted that the side edges of the dispersing blades a403 and B404 are respectively arranged in an arc shape, and the arc surfaces of the dispersing blades a403 and B404 are opposite. According to the invention, the dispersing leaves A403 and the dispersing leaves B404 are arranged, and the arc surfaces of the dispersing leaves A403 and the dispersing leaves B404 which are opposite are arranged, so that the cotton hanging on the dispersing leaves A403 and the dispersing leaves B404 is reduced when the dispersing leaves A403 and the dispersing leaves B404 contact the cotton and disperse the cotton.

The working principle is as follows: when cotton materials are combed, an inlet of a feeding channel 201 is connected with an external cotton material conveying pipeline through a flange, a carding machine body 1 starts to work, a servo motor 3 is electrified to start, an output shaft at a conveying end of the servo motor 3 drives a connecting roller A4018 to rotate clockwise, a bevel gear A4017 rotates clockwise, a bevel gear B4015 which is meshed with the bevel gear A4017 and connected with the bevel gear C4016 rotates along with the bevel gear C4016, a sleeve A402 rotates clockwise along with the connecting roller A4018, and seven dispersing blades A403 rotate clockwise; the sleeve B405 rotates counterclockwise along with the connecting roller B4014, the seven dispersing blades B404 rotate counterclockwise, cotton materials entering the bin body 202 from the feeding channel 201 fall from the middle of the bin body 202 to contact with the dispersing blades a403 and the dispersing blades B404, and the falling cotton materials are dispersed by the dispersing blades a403 and the dispersing blades B404 which rotate in different directions. The dispersed fabric is discharged from a discharge port at the bottom end of the bin body 202 and falls on a conveying belt at the feeding and conveying end of the carding machine body 1, and the dispersed fabric is conveyed into the carding machine body 1 for carding operation.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It should be understood by those skilled in the art that the present invention is not limited to the above embodiments, and the above embodiments and descriptions are only preferred examples of the present invention and are not intended to limit the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the present invention, which fall within the scope of the claimed invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. A cotton yarn textile carding machine, characterised by comprising:

a carding machine body (1);

a silo (2) arranged at the feed delivery end of the carding machine body (1);

a gap is reserved between a discharge hole at the bottom end of the storage bin (2) and a conveying belt at the feeding conveying end of the carding machine body (1);

the dispersion structure (4) is arranged in the inner cavity of the stock bin (2);

the servo motor (3) is arranged outside the stock bin (2);

the servo motor (3) is used for controlling the bidirectional rotation of the disperser A and the disperser B on the dispersing structure (4).

2. A cotton yarn textile carding machine as claimed in claim 1, characterised in that said magazine (2) comprises:

the bin body (202) is fixedly arranged at the feeding and conveying end of the carding machine body (1);

the feeding channel (201) is fixedly arranged in the middle of the top end of the bin body (202);

the material baffle (203) is fixedly arranged outside the discharge hole at the bottom end of the bin body (202);

the bottom end of the striker plate (203) is not in contact with a conveying belt at the feeding conveying end of the carding machine body (1).

3. A cotton yarn textile carding machine as claimed in claim 1, characterised in that said dispersing structure (4) comprises:

a transmission assembly (401);

a disperser A arranged at the active end of the transmission assembly (401);

a disperser B arranged at a driven end of the transmission assembly (401);

the driving end of the transmission assembly (401) is driven by the servo motor (3) to rotate, and the driven end of the transmission assembly (401) is matched with the driving end of the transmission assembly (401) to rotate, so that the bidirectional rotating material dispersing of the disperser A and the disperser B is realized.

4. A cotton yarn textile carding machine as claimed in claim 3, characterised in that said transmission assembly (401) comprises:

a housing (4011);

a connecting roller A (4018) rotatably provided outside the casing (4011) via a seal bearing (4012);

one end of the connecting roller A (4018) departing from the shell (4011) is connected with an output shaft of the output end of the servo motor (3);

the bevel gear A (4017) is sleeved at one end, located in the shell (4011), of the connecting roller A (4018);

a connecting roller B (4014) rotatably provided inside the casing (4011) via a seal bearing (4012);

one end of the connecting roller B (4014) departing from the shell (4011) is rotatably connected with the inner side wall of the shell (4011) through a rotating shaft (4013);

the bevel gear B (4015) is sleeved at one end, located in the shell (4011), of the connecting roller B (4014);

the bevel gear C (4016) is rotatably arranged on the inner top wall of the shell (4011) through a seal bearing (4012);

the bevel gear A (4017), the bevel gear C (4016) and the bevel gear B (4015) are sequentially connected in a meshed manner.

5. A cotton yarn textile carding machine as in claim 4, wherein said disperser A comprises:

the sleeve A (402) is sleeved at one end, outside the shell (4011), of the connecting roller A (4018);

the dispersing blades A (403) are fixedly arranged on the circumferential surface of the outer wall of the sleeve A (402) in an annular array;

the disperser B comprises:

the sleeve B (405) is sleeved at one end, outside the shell (4011), of the connecting roller B (4014);

and the dispersing blades B (404) are fixedly arranged on the circumferential surface of the outer wall of the sleeve B (405) in an annular array.

6. A cotton yarn textile carding machine, as claimed in claim 5, in which: a plurality of the dispersing blades A (403) and B (404) are sequentially shortened along the outer walls of the sleeve A (402) and the sleeve B (405), respectively.

7. A cotton yarn textile carding machine, as claimed in claim 5, in which: the side edges of the dispersing leaves A (403) and B (404) are respectively arranged into an arc shape, and the arc surfaces of the dispersing leaves A (403) and B (404) are opposite.