CN110438695B

CN110438695B - High Wen Chongquan dyeing machine

Info

Publication number: CN110438695B
Application number: CN201910825922.9A
Authority: CN
Inventors: 郑永忠; 陈红军; 刘江坚; 杨凯
Original assignee: Sanji Precision Technology Guangdong Co ltd
Current assignee: Sanji Precision Technology Guangdong Co ltd
Priority date: 2019-09-03
Filing date: 2019-09-03
Publication date: 2024-02-09
Anticipated expiration: 2039-09-03
Also published as: CN110438695A

Abstract

The invention discloses a high Wen Chongquan dyeing machine which comprises a cylinder body, a water storage tank, a main pump and a heat exchanger, wherein fabrics in the cylinder body sequentially move circularly through a cloth lifting roller, a front water nozzle, a U-shaped cloth moving pipe, a rear water nozzle, a cloth swinging hopper and a cloth storage tank, the cloth lifting roller is arranged above the front water nozzle, the bottom of the cylinder body is communicated with the water storage tank, the top of the cylinder body is provided with a main pipeline, the water storage tank, the main pump, the heat exchanger and the main pipeline are sequentially communicated, the main pipeline is communicated with a first water inlet pipe and a second water inlet pipe, and the first water inlet pipe and the second water inlet pipe are respectively communicated with the front water nozzle and the rear water nozzle. The invention can improve the productivity while meeting the requirements of the dyeing process on the cycle period of the fabric, the low tension and the loading capacity of the light and thin fabric.

Description

High Wen Chongquan dyeing machine

Technical Field

The invention belongs to the field of dyeing machines, and particularly relates to a high Wen Chongquan dyeing machine.

Background

In order to increase the fabric loading capacity of the fabric storage tank, the current tank dyeing machine adopts a method of properly increasing the width of the fabric storage tank in the front-back and left-right directions so that the fabric can be stacked in the fabric storage tank more. This method can cause the fabrics to press against each other in the cloth storage tank, causing creases, especially in the case of highly compact knitted fabrics. Because the width about the cloth storage groove makes the fabric can exist certain contained angle with the leading ring when promoting the in-process, the bigger about the cloth storage groove width, the contained angle is bigger, and this contained angle can make fabric and leading ring produce the friction, causes the scratch phenomenon to the fabric. The larger the included angle, the more serious the scratch. The larger the included angle is, the larger the acting force of the cloth lifting roller on the fabric lifting is, so that the internal stress of the fabric is increased, and the dyeing quality of the fabric is reduced.

Disclosure of Invention

The invention aims to provide a high Wen Chongquan dyeing machine, which synchronously solves the technical problems of fabric loading capacity of a fabric storage tank and fabric dyeing quality.

According to one aspect of the invention, the high Wen Chongquan dyeing machine comprises a cylinder body, a water storage tank, a main pump and a heat exchanger, wherein fabrics in the cylinder body sequentially circulate through a cloth lifting roller, a front water nozzle, a U-shaped cloth moving pipe, a rear water nozzle, a cloth swinging hopper and a cloth storage tank, the cloth lifting roller is arranged above the front water nozzle, the bottom of the cylinder body is communicated with the water storage tank, the top of the cylinder body is provided with a main pipeline, the water storage tank, the main pump, the heat exchanger and the main pipeline are sequentially communicated, the main pipeline is communicated with a first water inlet pipe and a second water inlet pipe, and the first water inlet pipe and the second water inlet pipe are respectively communicated with the front water nozzle and the rear water nozzle.

The fabric is drawn by the cloth lifting roller, the front water nozzle and the rear water nozzle to do circular motion, the dye liquor in the water storage tank is pumped out by the main pump, and is sprayed out from the front water nozzle and the rear water nozzle respectively through the first water inlet pipe and the second water inlet pipe after passing through the heat exchanger, so that the dye liquor is continuously contacted with the fabric, and the dyeing process is completed.

The front water nozzle and the rear water nozzle respectively comprise a water inlet cavity, two nozzles and two water nozzles, the two nozzles are respectively communicated with the water inlet cavity, the first water inlet pipe and the second water inlet pipe are correspondingly communicated with the water inlet cavity, the two nozzles of the front water nozzle are respectively correspondingly communicated with the two nozzles of the rear water nozzle through a U-shaped cloth moving pipe, and the two nozzles of the rear water nozzle are respectively correspondingly connected with a cloth storage groove through a cloth swinging hopper. The inlet chamber makes two nozzles form disjunctor formula structure, because the dye liquor gets into two nozzles from the inlet chamber after, because the stock solution chamber in the nozzle is linked together, the dye liquor can form the pressure equalizing after carrying out effectual mixing in the stock solution chamber, has avoided the inhomogeneous phenomenon of dye liquor distribution.

Adjacent cloth storage grooves are separated by a separation plate, so that the separated cloth storage grooves are formed. The bottom of each cloth storage groove tends to be gentle, so that the fabric can smoothly pass through the bottom of the cloth storage groove, and the accumulation marks of the fabric are reduced.

The two nozzles of the front water nozzle are respectively provided with a cloth guide ring, each cloth guide ring comprises a limiting seat and a cloth guide ring, each cloth guide ring is arranged in each limiting seat in a floating mode, each limiting seat is correspondingly fixed to one nozzle of the front water nozzle, and the fabric penetrates through each limiting seat and each cloth guide ring to move towards the cloth lifting roller. The cloth guide ring floats in the limit seat to strike the fabric, so that the phenomenon that the fabric is brought into the cloth lifting roller to cause winding and enters the nozzle to cause cloth blocking is avoided.

Each U-shaped cloth-moving pipe is internally provided with a front roller and a rear roller, drain pipes are arranged in the front roller and the rear roller, and the front roller and the rear roller are communicated with the drain pipes through gaps. After the fabrics are exchanged through the front water nozzle in the washing process, the fabrics are rolled through the front roller and the rear roller, and then are exchanged again through the rear water nozzle, so that the washing times and time can be effectively reduced, and the washing efficiency is greatly improved.

One end of each cloth swinging hopper is connected with a nozzle of the rear water nozzle through a lower support, the other end of each cloth swinging hopper is connected with a cloth storage groove, and each cloth swinging hopper is arranged on the cylinder body through an upper support. The upper support and the lower support play a role in supporting the cloth swinging hopper.

The upper support comprises a hanging bracket, a piston sleeve, a rotating rod and a mounting plate, one end of the hanging bracket is fixed on the cylinder body, the other end of the hanging bracket is fixed on the piston sleeve, the piston sleeve is sleeved with one end of the rotating rod, the rotating rod can rotate relative to the piston sleeve, the other end of the rotating rod is connected with the mounting plate, and the mounting plate is fixed on the cloth swinging hopper. When the cloth swinging hopper swings left and right, the rotating rod rotates along the piston sleeve.

The lower support comprises a pipe joint, a lower flange, an upper flange, a rotating shaft sleeve and a rotating sleeve, one end of the pipe joint is connected with one nozzle of the rear water nozzle, the other end of the pipe joint is fixed on the lower flange, the rotating shaft sleeve is sleeved and fixed on one end of the cloth swinging hopper, the rotating sleeve is sleeved and connected with the rotating shaft sleeve, the rotating shaft sleeve can rotate relative to the rotating sleeve, the lower flange and the upper flange are sleeved and connected with the rotating sleeve and the rotating shaft sleeve, and a sealing ring is arranged between the lower flange and the rotating shaft sleeve. When the cloth swinging hopper swings left and right, one end of the cloth swinging hopper rotates along the rotating sleeve through the rotating sleeve.

The invention can improve the productivity while meeting the requirements of the dyeing process on the cycle period of the fabric, the low tension and the loading capacity of the light and thin fabric.

Drawings

FIG. 1 is a schematic diagram of a high Wen Chongquan dyeing machine according to the present invention;

FIG. 2 is a schematic view of the high Wen Chongquan dyeing machine of FIG. 1 in the P-direction;

FIG. 3 is a schematic view of the Q-direction of the high Wen Chongquan dyeing machine of FIG. 1;

FIG. 4 is a schematic view of a cloth swinging hopper of the high Wen Chongquan dyeing machine shown in FIG. 1;

fig. 5 is a schematic view of the structure of the divided cloth storage tank of the high Wen Chongquan dyeing machine shown in fig. 1.

Detailed Description

The invention is described in further detail below with reference to the accompanying drawings.

As shown in fig. 1, the arrow direction is the direction in which the fabric 1 circulates in the cylinder 2. The high Wen Chongquan dyeing machine comprises a cylinder body 2, a water storage tank 2a, a main pump 3, a heat exchanger 4, a first water inlet pipe 5 and a second water inlet pipe 6, wherein a cloth guide ring 7, a cloth lifting roller 8, a front water nozzle 9, a U-shaped cloth moving pipe 10, a rear water nozzle 11, a cloth swinging hopper 12 and a cloth storage groove 13 are sequentially arranged in the cylinder body 2 along the movement direction of a fabric 1.

The cloth lifting roller 8 is arranged above the front water nozzle 9, and a large-diameter and large-wrap-angle driving roller is arranged in the cloth lifting roller 8, so that the lifting force of the cloth lifting roller 8 is improved, the relative sliding of the cloth 1 is reduced, and the holding force of the cloth lifting roller 8 is effectively increased.

The bottom intercommunication of cylinder body 2 has aqua storage tank 2, and the top of cylinder body 2 is equipped with trunk line 14, and aqua storage tank 2a, main pump 3, heat exchanger 4, trunk line 14 communicate in proper order, and trunk line 14 communicates has first inlet tube 5, second inlet tube 6.

As shown in fig. 1 and 2, the arrow direction in fig. 2 is the water flow direction. The front water nozzle 9 and the rear water nozzle 11 respectively comprise a water inlet cavity 15 and two nozzles 16, the two nozzles 16 are respectively communicated with the water inlet cavity 15, the first water inlet pipe 5 and the second water inlet pipe 6 are correspondingly communicated with the water inlet cavity 15, the two nozzles 16 of the front water nozzle 9 are respectively correspondingly communicated with the two nozzles 16 of the rear water nozzle 11 through a U-shaped cloth walking pipe 10, and the two nozzles 16 of the rear water nozzle 11 are respectively correspondingly connected with a cloth storage groove 13 through a cloth swinging hopper 12.

The fabric 1 is fed through a working door 17 of the cylinder body 2, the fabric 1 is drawn to circularly move by utilizing the cloth lifting roller 8, the two nozzles 16 of the front water nozzle 9 and the two nozzles 16 of the rear water nozzle 11, meanwhile, the dye liquor in the water storage tank 2a is pumped out through the main pump 3, respectively enters the water inlet cavity 15 of the front water nozzle 9 and the water inlet cavity 15 of the rear water nozzle 11 through the first water inlet pipe 5 and the second water inlet pipe 6 after passing through the heat exchanger 4, and is sprayed out from the water outlet 18 of the nozzles 16, so that the dyeing process is continuously contacted with the fabric 1, and the fabric is finished.

As shown in fig. 1 and 5, adjacent cloth storage slots 13 are separated by a partition plate 38, thereby forming partitioned narrow cloth storage slots. The bottom of each cloth storage groove 13 is flattened, as shown by the flattened section 39 in fig. 1, and the flattened section 39 makes the fabric pass through the bottom of the cloth storage groove 13 smoothly, and reduces fabric accumulation marks. The separated cloth storage groove is equivalent to being divided into two small cloth storage grooves. Under the condition of the same load, the load in the small cloth storage groove is only half of that in the original cloth storage groove, the reduction of the load can effectively improve the mutual extrusion state of the fabrics in the cloth storage groove, and the crease is reduced; under the condition of the same load, the width of the cloth groove in the small cloth storage groove is only half of that of the original cloth storage groove, the included angle between the cloth and the cloth guide ring is effectively reduced when the cloth passes through the cloth guide ring in the lifting process, the abrasion of the cloth can be effectively reduced, the internal stress of the cloth is reduced, and uneven dyeing caused by uneven shrinkage due to the fact that the internal stress of the filament fabric is larger can be particularly avoided, so that the dyeing quality is improved.

As shown in fig. 1 and 2, the water inlet cavity 15 enables the two nozzles 16 to form a combined nozzle structure, and after the dye liquor enters the two nozzles 16 from the water inlet cavity 15, the liquid storage cavities 19 of the two nozzles 16 are communicated, so that before the dye liquor is sprayed out from the water outlets 18 of the two nozzles 16, the dye liquor can be effectively mixed in the liquid storage cavities 19 to form uniform pressure, the uneven distribution phenomenon of the dye liquor is greatly reduced, and the phenomenon that the dyeing degree of fabrics in a plurality of cloth storage grooves or separated cloth storage grooves is different is effectively avoided.

As shown in fig. 1 and 5, two nozzles 16 of the front water nozzle 9 are respectively provided with a cloth guide ring 7, the cloth guide ring 7 comprises a limit seat 20 and a cloth guide ring 21, the cloth guide ring 21 is floatingly arranged in the limit seat 20, the limit seat 20 is correspondingly fixed on one nozzle 16 of the front water nozzle 9, and the fabric 1 moves towards the cloth lifting roller 8 through the limit seat 20 and the cloth guide ring 21. The floating cloth guide ring 7 is arranged in the limit seat 20 so as to enable the cloth guide ring to move within a certain range. Before the fabric 1 brings other fabrics into the cloth lifting roller 8, the floating cloth guide ring 7 can make irregular movement in a certain range in the lifting process of the fabric 1, and the movement and the impact of the fabric 1 can effectively beat the fabric brought along with the fabric 1, so that the phenomenon that the fabric 1 is brought into the cloth lifting roller 8 to cause winding and enters the nozzle 16 to cause cloth blocking is avoided.

As shown in fig. 1 and 3, each U-shaped cloth-running pipe 10 is internally provided with a front roller 22 and a rear roller 23, the front roller 22 and the rear roller 23 are internally provided with a drain pipe 24, and the front roller 22 and the rear roller 23 are communicated with the drain pipe 24 through a gap 25. During water washing, the fabric 1 passes through the two nozzles 16 of the front water nozzle 9, and sewage generated after the fabric 1 exchanges with clean water is discharged through the gaps 25 of the front roller 22 and the rear roller 23 and the drain pipe 24; when the fabric 1 enters the U-shaped cloth-moving pipe 10, the front roller 22 and the rear roller 23 roll water, so that sewage carried in the fabric 1 is effectively separated from the fabric 1 and is discharged through the gaps 25 of the front roller 22 and the rear roller 23 and the drain pipe 24; the fabric 1 passes through the two nozzles 16 of the rear water nozzle 11, and the sewage generated after the fabric 1 is exchanged with the clean water again is discharged through the gaps 25 of the front roller 22 and the rear roller 23 and the drain pipe 24. Therefore, the fabric 1 is exchanged through the front water nozzle 9 in the washing process, is rolled through the front roller 22 and the rear roller 23, and is exchanged again through the rear water nozzle 11, so that the washing times and time are effectively reduced, and the washing efficiency is greatly improved.

As shown in fig. 1 and 4, one end of each cloth swinging hopper 12 is connected with one nozzle 16 of the rear water nozzle 11 through a lower support 36, the other end of each cloth swinging hopper 12 is connected with one cloth storage groove 13, and each cloth swinging hopper 12 is mounted on the cylinder body 1 through an upper support 37. The upper support 37 comprises a hanging bracket 26, a piston sleeve 27, a rotating rod 28 and a mounting plate 29, one end of the hanging bracket 26 is fixed on the cylinder body 1, the other end of the hanging bracket 16 is fixed on the piston sleeve 27, the piston sleeve 27 is sleeved with one end of the rotating rod 28, the rotating rod 28 can rotate relative to the piston sleeve 27, the other end of the rotating rod 28 is connected with the mounting plate 29, and the mounting plate 29 is fixed on the cloth swinging hopper 12. The lower support 36 comprises a pipe joint 30, a lower flange 31, an upper flange 32, a rotating shaft sleeve 33 and a rotating sleeve 34, one end of the pipe joint 30 is connected with one nozzle 16 of the rear water nozzle 11, the other end of the pipe joint 30 is fixed on the lower flange 31, the rotating shaft sleeve 33 is sleeved on one end of the cloth swinging hopper 12, the rotating sleeve 34 is sleeved on the rotating shaft sleeve 33, the lower flange 31 and the upper flange 32 are sleeved on the rotating sleeve 34 and the rotating shaft sleeve 33, and a sealing ring 35 is arranged between the lower flange 31 and the rotating shaft sleeve 33. After the fabric 1 is sprayed out through the cloth swinging hopper 12, the fabric 1 is orderly stacked by adopting the left and right swinging of the cloth swinging hopper 12, so that the running condition is effectively improved. When the cloth swinging hopper 12 swings left and right, the upper support 37 and the lower support 36 play a role in supporting the rotation of the cloth swinging hopper 12: the rotating rod 28 rotates along the piston sleeve 27, and one end of the cloth swinging hopper 12 rotates along the rotating sleeve 34 through the rotating sleeve 33, so that the stability of the left and right swinging of the cloth swinging hopper 12 is ensured.

What has been described above is merely some embodiments of the present invention. It will be apparent to those skilled in the art that various modifications and improvements can be made without departing from the spirit of the invention.

Claims

1. The high Wen Chongquan dyeing machine is characterized by comprising a cylinder body (2), a water storage tank (2 a), a main pump (3) and a heat exchanger (4), wherein a fabric (1) in the cylinder body (2) is sequentially communicated with a cloth lifting roller (8), a front water nozzle (9), a U-shaped cloth moving pipe (10), a rear water nozzle (11), a cloth swinging hopper (12) and a cloth storage tank (13), the cloth lifting roller (8) is arranged above the front water nozzle (9), the bottom of the cylinder body (2) is communicated with the water storage tank (2 a), the top of the cylinder body (2) is provided with a main pipe (14), the water storage tank (2 a), the main pump (3), the heat exchanger (4) and the main pipe (14) are sequentially communicated, the main pipe (14) is communicated with a first water inlet pipe (5) and a second water inlet pipe (6), the first water inlet pipe (5) and the second water inlet pipe (6) are respectively communicated with the front water nozzle (9) and the rear water nozzle (11), the front water nozzle (9) and the rear water nozzle (11) respectively comprise a water inlet cavity (15) and two nozzles (16), the water inlet cavity (15) are correspondingly communicated with the first water inlet pipe (15), two nozzles (16) of preceding water nozzle (9) correspond two nozzles (16) of intercommunication back water nozzle (11) through a U-shaped cloth pipe (10) respectively, two nozzles (16) of back water nozzle (11) correspond through a pendulum cloth fill (12) respectively and connect a cloth storage tank (13), inlet chamber (15) make two nozzles (16) form disjunctor formula nozzle structure, effectively avoid the difference to appear in the dyeing degree in a plurality of cloth storage tanks or the divided cloth storage tank's fabric, each U-shaped cloth pipe (10) are built-in has preceding roll (22) and back roll (23), preceding roll (22), back roll (23) all are built-in drain pipe (24), preceding roll (22), back roll (23) all are through gap (25) intercommunication drain pipe (24).

2. A high Wen Chongquan dyeing machine according to claim 1, characterized in that adjacent cloth storage tanks (13) are separated by a partition plate (38), the bottom of each cloth storage tank (13) being gentle.

3. The high Wen Chongquan dyeing machine according to claim 2, wherein the two nozzles (16) of the front water nozzle (9) are respectively provided with a cloth guide ring (7), the cloth guide rings (7) comprise a limit seat (20) and a cloth guide ring (21), the cloth guide ring (21) is floatingly arranged in the limit seat (20), the limit seat (20) is correspondingly fixed on one nozzle (16) of the front water nozzle (9), and the fabric (1) moves towards the cloth lifting roller (8) through the limit seat (20) and the cloth guide ring (21).

4. A high Wen Chongquan dyeing machine according to claim 1 or 3, characterized in that one end of each cloth swinging hopper (12) is connected with one nozzle (16) of the rear water nozzle (11) through a lower support (36), the other end of each cloth swinging hopper (12) is connected with a cloth storage groove (13), and each cloth swinging hopper (12) is mounted on the cylinder (2) through an upper support (37).

5. The high Wen Chongquan dyeing machine according to claim 4, characterized in that the upper support (37) comprises a hanger (26), a piston sleeve (27), a rotating rod (28) and a mounting plate (29), one end of the hanger (26) is fixed on the cylinder (2), the other end of the hanger (26) is fixed on the piston sleeve (27), the piston sleeve (27) is sleeved with one end of the rotating rod (28), the rotating rod (28) can rotate relative to the piston sleeve (27), the other end of the rotating rod (28) is connected with the mounting plate (29), and the mounting plate (29) is fixed on the cloth swinging hopper (12).

6. The high Wen Chongquan dyeing machine according to claim 4, wherein the lower support (36) comprises a pipe joint (30), a lower flange (31), an upper flange (32), a rotating shaft sleeve (33) and a rotating sleeve (34), one end of the pipe joint (30) is connected with one nozzle (16) of the rear water nozzle (11), the other end of the pipe joint (30) is fixed on the lower flange (31), the rotating shaft sleeve (33) is sleeved and fixed on one end of the cloth swinging hopper (12), the rotating sleeve (34) is sleeved on the rotating shaft sleeve (33), the rotating shaft sleeve (33) can rotate relative to the rotating sleeve (34), the lower flange (31), the upper flange (32) are sleeved on the rotating sleeve (34) and the rotating shaft sleeve (33), and a sealing ring (35) is arranged between the lower flange (31) and the rotating shaft sleeve (33).