CN115142211A - Overflow dyeing machine capable of reducing fabric dyeing cylinder difference - Google Patents

Abstract

The utility model relates to a reduce overflow dyeing machine that surface fabric dyeing jar is poor relates to the technical field of printing and dyeing equipment, including the dyeing machine body, has seted up the feed inlet on the dyeing machine body, is located to rotate on the dyeing machine body that is close to feed inlet department and is provided with two and carries the cloth wheel, and two sections surface fabrics of different length are located two respectively and carry the cloth wheel after getting into the dyeing machine body, are provided with two sets of drive assembly that are used for driving two respectively and carry cloth wheel pivoted on the dyeing machine body. This application is through putting two sections surface fabrics of different length respectively to two cloth lifting wheel through the feed inlet on, two sets of drive assembly start control two cloth lifting wheel rotations respectively and carry the surface fabric to adjust the slew velocity that drive assembly drove two cloth lifting wheel according to the length of two sections surface fabrics and make two sections surface fabrics carry out the dyeing rate of dyeing unanimous in dyeing machine originally internally, thereby reduced the colour difference between the surface fabric of different length when making the surface fabric of different length dye in the dye liquor of same jar time.

Description

Overflow dyeing machine capable of reducing fabric dyeing cylinder difference

Technical Field

The application relates to the technical field of printing and dyeing equipment, in particular to an overflow dyeing machine capable of reducing fabric dyeing cylinder difference.

Background

The overflow dyeing machine is a dyeing device which has wide application in the intermittent dyeing and finishing engineering of fabrics, and especially plays an important role in the dyeing and finishing engineering of terylene and blended fabrics thereof.

In the related art, the fabric with the length exceeding the maximum dyed fabric length of the dyeing machine body needs to be divided into fabric sections with proper length and enter the overflow dyeing machine for dyeing in different batches due to the limitation of the length of the dyeing machine body. However, in the same color, the color of the fabric dyed in the dye liquor of the same specification in different vats generates certain color difference compared with the color of the fabric of the previous batch, the phenomenon is called vat difference, and the finished product quality of the fabric with the color and the specification is directly reduced if the vat difference is too large; and the fabrics with different lengths are placed in a cylinder for dyeing, so that the dyeing rate of the fabrics in the dye liquor is different due to the different lengths of the fabrics, thereby causing color difference among the fabrics with different lengths and generating adverse effect on the quality of the finished products of the fabrics with the color and the specification.

Disclosure of Invention

In order to reduce the color difference between fabrics with different lengths, the application provides an overflow dyeing machine for reducing the fabric dyeing cylinder difference.

The application provides a reduce overflow dyeing machine of surface fabric dyeing jar difference adopts following technical scheme:

the overflow dyeing machine comprises a dyeing machine body, wherein a feed inlet is formed in the dyeing machine body, two cloth lifting wheels are rotatably arranged on the dyeing machine body close to the feed inlet, two sections of fabrics with different lengths enter the dyeing machine body and are respectively arranged on the two cloth lifting wheels, and two groups of driving assemblies which are respectively used for driving the two cloth lifting wheels to rotate are arranged on the dyeing machine body.

By adopting the technical scheme, two sections of fabrics with different lengths are respectively placed on the two cloth lifting wheels through the feed inlet, the two groups of driving components are respectively started to control the two cloth lifting wheels to rotate to convey the fabrics, and the rotating speed of the driving components for driving the two cloth lifting wheels is adjusted according to the lengths of the two sections of fabrics, so that the dyeing rates of the two sections of fabrics dyed in the dyeing machine body are consistent, and the color difference between the fabrics with different lengths is reduced while the fabrics with different lengths are dyed in the dye liquor in the same vat time.

Optionally, the driving assembly includes:

the rotating shaft is rotatably arranged on the dyeing machine body and is connected with the cloth lifting wheel;

the driving motor is arranged on the dyeing machine body;

a first drive wheel disposed on a drive motor output shaft;

the second driving wheel is arranged on the rotating shaft;

the transmission belt is sleeved on the first driving wheel and the second driving wheel;

and the controller is arranged on the dyeing machine body and is electrically connected with the driving motor.

Through adopting above-mentioned technical scheme, according to the length that gets into two sections surface fabrics in the dyeing machine, the staff sets for two driving motor's rotational speed through the controller, driving motor starts to drive first drive wheel and rotates, first drive wheel rotates and drives the drive belt and rotate, the drive belt rotates and drives the rotation of second drive wheel, the rotation of second drive wheel drives the pivot and rotates, the pivot rotates and drives the rotation of cloth lifting wheel to accomplish the drive work to cloth lifting wheel, and accomplish through control controller and carry the speed of the surface fabric to two cloth lifting wheels and adjust.

Optionally, a control box is arranged on the dyeing machine body, the two controllers are located in the control box, one side of the control box is in an open state, and a baffle used for shielding an opening of the control box is rotatably arranged on the control box.

By adopting the technical scheme, the control box is fixedly connected to the dyeing machine body, the two controllers are fixed in the control box, the controller in the control box can be adjusted by turning off the baffle, and after the operation is completed, the opening is blocked by the rotating baffle, so that the probability that the controller is polluted or damaged by water and dye liquor on the dyeing machine and the fabric exposed in the environment when the fabric in the dyeing machine is taken out is reduced, and the controller is ensured to be in a safe operation state.

Optionally, a locking component for locking a rotation position of the baffle when the baffle blocks the opening of the control box is arranged on the control box, and the locking component includes:

the locking plate is arranged on the baffle plate;

the locking block is rotatably arranged on the control box and provided with a locking hole for the locking plate to pass through;

the locking spring is arranged on the control box and connected with the locking block, when the baffle shields the opening of the control box, the locking plate penetrates through the locking hole, and the locking block is abutted against the baffle under the action of the locking spring.

Through adopting above-mentioned technical scheme, tensile locking spring drives the locking piece and removes, removes locking piece and lockplate and breaks away from, removes the lockplate and can drive the baffle and rotate, turns over the baffle and adjusts the controller parameter, adjusts the completion back, rotates the baffle and blocks the control box opening, loosens locking spring, and locking spring contracts back and drives the locking piece and support tightly on the baffle, and lockplate and locking hole grafting cooperation this moment to the completion is to the locking work of the rotational position of baffle.

Optionally, two separating rings are arranged on the dyeing machine body, which is located at the position, close to the feed inlet, of the two cloth lifting wheels, and the fabric passes through the separating rings and then bypasses the cloth lifting wheels.

By adopting the technical scheme, the two separating rings are respectively and fixedly connected to the dyeing machine body positioned at the feed inlet, and the fabric passes through the separating rings and then winds to the fabric lifting wheel when being dyed in the dyeing machine, so that the probability that the fabrics on the two fabric lifting wheels are wound together to be knotted when being dyed in the dyeing machine is reduced, and the normal conveying of the fabrics in the dyeing machine is ensured.

Optionally, the separating ring is detachably connected to the dyeing machine body through a connecting assembly, the connecting assembly includes:

the connecting pipe is arranged on the dyeing machine body and is in a vertical state;

the inserting rod is arranged on the separating ring and is vertically inserted into the connecting pipe downwards;

and the connecting screw rod is in threaded connection with the connecting pipe and horizontally penetrates through the side wall of the connecting pipe to be abutted against the insertion rod.

By adopting the technical scheme, when the size of the fabric changes, the size of the partition ring needs to be changed according to the size of the fabric, the connecting screw rod is screwed to be separated from the connecting pipe, the inserting rod is moved to drive the partition ring to move, the inserting rod is moved to take down the partition ring for changing, the inserting rod on the changed partition ring is inserted into the connecting pipe and the height of the partition ring is adjusted, after the adjustment is completed, the connecting screw rod is moved to penetrate through the side wall of the connecting pipe and the connecting screw rod is screwed to be tightly abutted on the inserting rod, the replacement work of the partition ring is completed, and the adaptation range of the partition ring to different sizes of fabrics is expanded through the adjustment of the height of the partition ring.

Optionally, the dyeing machine body is provided with a limiting ring, the limiting ring is located below the two separating rings, and the fabric on the two fabric lifting wheels passes through the limiting ring from the cylinder bottom to the top and then respectively passes through the two separating rings.

By adopting the technical scheme, the limiting ring is fixedly connected to the dyeing machine body below the two separating rings, and the two sections of fabrics penetrate into the two separating rings respectively after penetrating through the limiting ring, so that the fabrics cannot interfere with the connecting pipe, the inserting rod and the connecting screw before penetrating into the separating rings, and the probability that the connecting screw and the connecting pipe are corroded due to pollution and difficult to disassemble due to the fact that dye liquor and water on the fabrics fall into the connecting screw and the connecting pipe is reduced.

Optionally, the spacing ring is detachably connected to the two connecting pipes through a fixing component, the fixing component includes:

the two fixing rods are arranged on the limiting ring and are respectively positioned on two sides of the limiting ring close to the two connecting pipes;

the fixing piece is arranged on the fixing rod, and an oblong hole horizontally penetrating through the thickness of the fixing piece is formed in the fixing piece;

the fixing screw is in threaded connection with the connecting pipe, penetrates through the overlong circular hole, and the head of the fixing screw abuts against the fixing piece.

Through adopting the above technical scheme, when the size of surface fabric changes, need change the size of spacing ring according to the size of surface fabric size, twist and move clamping screw and break away from with the connecting pipe, clamping screw breaks away from with the stationary blade when breaking away from with the connecting pipe, it drives the dead lever and removes to remove the stationary blade, the dead lever removes and drives the spacing ring and shifts out the dyeing machine body, change the spacing ring, the spacing ring after removing the change removes to between two connecting pipes, the stationary blade on removing two dead levers is contradicted with the connecting pipe lateral wall, twist clamping screw and pass the overlength and connecting pipe threaded connection and the head supports tightly on the stationary blade, thereby accomplish the change work of spacing ring, the dyeing machine body is to the spacing work of not unidimensional cloth.

Optionally, the cloth lifting wheel is in a hollow state, a plurality of water dripping holes communicated with the inside of the cloth lifting wheel are uniformly distributed on the wheel surface of the cloth lifting wheel, and an anti-skid pad is arranged on the wheel surface of the cloth lifting wheel.

By adopting the technical scheme, the cloth lifting wheel is arranged to be hollow, a plurality of water dripping holes communicated with the inside of the cloth lifting wheel are formed in the cloth lifting wheel, and the non-slip mat is laid on the wheel surface, so that the probability that the fabric slips on the cloth lifting wheel due to accumulation of water on the fabric is reduced, the friction force between the cloth lifting wheel and the fabric is improved, and the fabric conveying effect of the cloth lifting wheel is ensured.

Optionally, both ends of the cloth lifting wheel are provided with baffle discs, and the diameters of the baffle discs are larger than the diameter of the cloth lifting wheel.

By adopting the technical scheme, the blocking discs are fixedly connected to the two ends of the cloth lifting wheel to block the fabric on the cloth lifting wheel, so that the probability that the fabric on the cloth lifting wheel moves to the adjacent cloth lifting wheel due to position deviation is reduced, and the probability that two sections of cloth generate color difference due to the change of dyeing rate caused by the fact that the fabric moves to the adjacent cloth lifting wheel is reduced.

In summary, the present application includes at least one of the following beneficial technical effects:

1. two sections of fabrics with different lengths are respectively placed on the two cloth lifting wheels through the feed inlet, the two groups of driving assemblies are respectively started to control the two cloth lifting wheels to rotate to convey the fabrics, and the rotating speed of the driving assemblies for driving the two cloth lifting wheels is adjusted according to the lengths of the two sections of fabrics, so that the dyeing rates of the two sections of fabrics for dyeing in the dyeing machine body are consistent, and the color difference between the fabrics with different lengths is reduced while the fabrics with different lengths are dyed in the dye solution in the same cylinder;

2. according to the length of two sections of fabrics entering the dyeing machine, a worker sets the rotating speed of two driving motors through a controller, the driving motors are started to drive a first driving wheel to rotate, the first driving wheel rotates to drive a driving belt to rotate, the driving belt rotates to drive a second driving wheel to rotate, the second driving wheel rotates to drive a rotating shaft to rotate, and the rotating shaft rotates to drive a cloth lifting wheel to rotate, so that the driving work of the cloth lifting wheel is completed, and the conveying speed of the fabrics on the two cloth lifting wheels is adjusted through controlling the controller;

3. through spacing ring fixed connection on the dyeing machine body of two spacer ring below, two sections surface fabrics all penetrate two spacer rings respectively after penetrating in the spacing ring to make the surface fabric can not interfere with connecting pipe, peg graft pole and connecting screw before penetrating the spacer ring, reduced the dye liquor on the surface fabric and water fall to make connecting screw and connecting pipe pollute the corrosion and be difficult to the probability of dismantling in connecting screw and the connecting pipe.

Drawings

FIG. 1 is a schematic perspective view of the present application;

FIG. 2 is a schematic structural view of the cloth lifting wheel and drive assembly of the present application, with the side wall of the dyeing machine body cut away;

FIG. 3 is a schematic structural view of a control box, a controller and a locking assembly of the present application;

fig. 4 is an enlarged schematic view of a portion a in fig. 1.

Reference numerals: 1. a dyeing machine body; 11. a feed inlet; 12. a cloth lifting wheel; 13. a water dripping hole; 14. a non-slip mat; 15. a catch plate; 16. a control box; 17. a baffle plate; 18. a spacer ring; 19. a limiting ring; 2. a drive assembly; 21. a rotating shaft; 22. a drive motor; 23. a first drive wheel; 24. a second drive wheel; 25. a transmission belt; 26. a controller; 3. a locking assembly; 31. a locking plate; 32. a locking block; 33. a locking spring; 34. a locking hole; 4. a connecting assembly; 41. a connecting pipe; 42. a plug rod; 43. connecting a screw rod; 5. a fixing assembly; 51. fixing the rod; 52. a fixing sheet; 53. fixing the screw rod; 54. an oblong hole.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

The embodiment of the application discloses an overflow dyeing machine for reducing fabric dyeing cylinder difference.

Referring to fig. 1, the overflow dyeing machine for reducing the fabric dyeing vat difference comprises a dyeing machine body 1, wherein one end of the dyeing machine body 1 is provided with a feed inlet 11, one side of two opposite inner side walls inside the dyeing machine body 1, which are close to the feed inlet 11, is respectively and rotatably connected with a cloth lifting wheel 12, and the axis directions of the two cloth lifting wheels 12 are overlapped. Two groups of driving components 2 which are respectively used for driving the two cloth lifting wheels 12 to rotate are arranged on the dyeing machine body 1.

Referring to fig. 2, the cloth lifting wheel 12 is hollow, and water dripping holes 13 communicated with the inside of the cloth lifting wheel 12 are radially and uniformly distributed on the wheel surface of the cloth lifting wheel 12. The outer wheel surface of the cloth lifting wheel 12 is fixedly connected with an anti-skid pad 14. The two ends of the cloth lifting wheel 12 are fixedly connected with baffle discs 15 with the diameter larger than that of the cloth lifting wheel 12.

Referring to fig. 1 and 2, the driving assembly 2 includes a rotation shaft 21, a driving motor 22, a first driving wheel 23, a second driving wheel 24, and a transmission belt 25. The rotating shaft 21 is rotatably connected to the dyeing machine body 1 and horizontally penetrates through the dyeing machine body 1, and one end, located inside the dyeing machine body 1, of the rotating shaft 21 is fixedly connected with the cloth lifting wheel 12. The driving motor 22 is fixedly connected to the upper surface of the dying machine body 1. The first drive wheel 23 is fixedly connected to the output shaft of the drive motor 22. The second driving wheel 24 is fixedly connected to one end of the rotating shaft 21 which penetrates out of the dyeing machine body 1. The transmission belt 25 is fitted over the first driving wheel 23 and the second driving wheel 24.

Referring to fig. 1 and 3, the drive assembly 2 further includes a controller 26. The outer side wall of one side of the dyeing machine body 1 is fixedly connected with a control box 16, and the side wall of one side, far away from the dyeing machine body 1, of the control box 16 is in an open state.

Referring to fig. 2 and 3, the controller 26 is fixedly attached to an inner sidewall of the control box 16 on a side opposite to the opening and electrically connected to the driving motor 22.

Referring to fig. 2 and 3, the controller 26 controls the driving motor 22 to rotate, the driving motor 22 rotates to drive the first driving wheel 23 to rotate, the first driving wheel 23 rotates to drive the transmission belt 25 to move, the transmission belt 25 moves to drive the second driving wheel 24 to rotate, the second driving wheel 24 rotates to drive the rotating shaft 21 to rotate, the rotating shaft 21 rotates to drive the cloth lifting wheel 12 to rotate, and the cloth lifting wheel 12 rotates to convey the fabric.

Referring to fig. 1 and 3, a baffle 17 capable of shielding the opening is rotatably connected to an outer side wall of the control box 16 on the side where the opening is opened. The control box 16 is provided with a locking assembly 3 for locking the position of the baffle 17 when the baffle 17 blocks the opening of the control box 16, and the locking assembly 3 comprises a locking plate 31, a locking block 32 and a locking spring 33.

Referring to fig. 1 and 3, a locking plate 31 is fixedly attached to a side wall of the shutter 17 on a side away from a rotation point of the shutter 17. The locking block 32 is rotatably connected to the side wall of the control box 16 far away from the rotation position of the baffle 17, and a locking hole 34 horizontally penetrating through the locking block 32 is formed in the side wall of the locking block 32 near the baffle 17. One end of the locking spring 33 is fixedly connected to a side wall of the control box 16 far away from the rotation position of the baffle 17, and the other end of the locking spring 33 is fixedly connected to a side wall of the locking block 32 near the control box 16. When the baffle 17 blocks the opening of the control box 16, the locking plate 31 is in inserted fit with the locking hole 34 on the locking block 32, and the locking block 32 is abutted against the side wall of the baffle 17 under the action of the restoring retraction force of the locking spring 33.

Referring to fig. 1 and 3, the locking spring 33 is stretched to move the locking block 32 to be separated from the locking plate 31, the movable baffle 17 opens the opening of the control box 16, the parameters of the controller 26 are adjusted according to the length of two sections of fabric placed in the dyeing machine body 1, after the adjustment is completed, the movable baffle 17 closes the opening of the control box 16, the locking block 32 is released, the locking spring 33 retracts to drive the locking block 32 to move towards the baffle 17, the locking plate 31 penetrates through the locking hole 34, and the locking block 32 abuts against the side wall of the baffle 17.

With reference to fig. 1 and 4, two separating rings 18 are removably connected to the dying machine body 1 at the feed inlet 11 by means of two sets of connecting members 4. Two separating rings 18 are respectively arranged on one side of the two cloth lifting wheels 12 close to the discharge hole. The fabric passes through the divider ring 18 and then wraps around the lifting wheel 12.

Referring to fig. 1 and 4, the connection assembly 4 includes a connection pipe 41, a bayonet rod 42, and a connection screw 43. The connecting pipe 41 is fixedly connected to the inner bottom wall of the feed inlet 11 of the dyeing machine body 1 and is in a vertical state. The insertion rod 42 is fixedly connected to the outer circumferential surface of the spacer ring 18 and is inserted vertically downward into the connection pipe 41. The connecting screw 43 is connected with the connecting pipe 41 by screw thread and horizontally passes through the side wall of the connecting pipe 41 to abut against the outer side wall of the inserting rod 42.

Referring to fig. 1 and 4, the two connecting pipes 41 are detachably connected with the limiting rings 19 through the fixing assemblies 5, and the limiting rings 19 are positioned below the middle of the two separating rings 18. The fixing assembly 5 includes two fixing rods 51, a fixing piece 52, and a fixing screw 53. One ends of the two fixing rods 51 are fixedly connected to the outer annular surfaces of the two ends of the limiting ring 19 respectively. A securing plate 52 is fixedly attached to an end of the securing rod 51 remote from the spacer ring 18. An oblong hole 54 horizontally penetrating the thickness of the fixing plate 52 is formed in the fixing plate 52. The fixing screw 53 horizontally passes through the long circular hole 54 and is threadedly coupled to the connection pipe 41.

The working principle of the embodiment of the application is as follows:

two sections of fabrics with different lengths are respectively wound on the two cloth lifting wheels 12 through the two separating rings 18, parameters of the controller 26 are adjusted according to the lengths of the two sections of fabrics, the controller 26 controls the driving motor 22 to start to drive the first driving wheel 23 to rotate, the first driving wheel 23 rotates to drive the driving belt 25 to rotate, the driving belt 25 rotates to drive the second driving wheel 24 to rotate, the second driving wheel 24 rotates to drive the cloth lifting wheels 12 to rotate, and the cloth lifting wheels 12 rotate to convey the fabrics to dye; in the dyeing process, one end of the fabric which is firstly input into the dyeing machine body 1 penetrates through the limiting ring 19 to be knotted with the tail end of the fabric.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: equivalent changes in structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (10)

1. The utility model provides a reduce overflow dyeing machine of surface fabric dyeing jar difference which characterized in that: the cloth lifting mechanism comprises a dyeing machine body (1), wherein a feed port (11) is formed in the dyeing machine body (1), two cloth lifting wheels (12) are arranged on the dyeing machine body (1) close to the feed port (11) in a rotating mode, two sections of fabrics with different lengths enter the dyeing machine body (1) and then are respectively arranged on the two cloth lifting wheels (12), and two groups of driving assemblies (2) which are respectively used for driving the two cloth lifting wheels (12) to rotate are arranged on the dyeing machine body (1).

2. An overflow dyeing machine for reducing the difference between the dyeing vats of fabrics according to claim 1, characterized in that: the drive assembly (2) comprises:

the rotating shaft (21), the rotating shaft (21) is rotatably arranged on the dyeing machine body (1) and is connected with the cloth lifting wheel (12);

a drive motor (22), said drive motor (22) being arranged on the dying machine body (1);

a first drive wheel (23), the first drive wheel (23) being provided on an output shaft of the drive motor (22);

a second drive wheel (24), the second drive wheel (24) being provided on the rotating shaft (21);

the transmission belt (25), the said transmission belt (25) is set up on the first driving wheel (23) and second driving wheel (24);

a controller (26), said controller (26) being arranged on the dying machine body (1) and being electrically connected with the drive motor (22).

3. An overflow dyeing machine for reducing the vat difference in dyeing fabrics as claimed in claim 2, characterized in that: the dyeing machine is characterized in that a control box (16) is arranged on the dyeing machine body (1), the two controllers (26) are located in the control box (16), one side of the control box (16) is in an open state, and a baffle (17) used for shielding an opening of the control box (16) is rotatably arranged on the control box (16).

4. An overflow dyeing machine for reducing the vat difference in dyeing fabrics as claimed in claim 3, characterized in that: the control box (16) is provided with a locking component (3) for locking the rotation position of the baffle plate (17) when the baffle plate (17) shields the opening of the control box (16), and the locking component (3) comprises:

a lock plate (31), the lock plate (31) being provided on the baffle plate (17);

the locking block (32) is rotatably arranged on the control box (16), and a locking hole (34) for the locking plate (31) to pass through is formed in the locking block (32);

the locking spring (33), locking spring (33) set up on control box (16) and be connected with locking block (32), when baffle (17) sheltered from control box (16) opening, locking hole (34) are passed in locking plate (31), locking block (32) support tightly on baffle (17) under locking spring (33) effect.

5. An overflow dyeing machine for reducing the vat difference in dyeing fabrics as claimed in claim 1, characterized in that: two separating rings (18) are arranged on the dyeing machine body (1) which is positioned at the positions of the two cloth lifting wheels (12) close to the feed port (11), and the fabric passes through the separating rings (18) and then bypasses the cloth lifting wheels (12).

6. An overflow dyeing machine for reducing the vat difference in dyeing fabrics as claimed in claim 5, characterized in that: the separating ring (18) is detachably connected to the dyeing machine body (1) by a connecting assembly (4), the connecting assembly (4) comprising:

a connecting pipe (41), wherein the connecting pipe (41) is arranged on the dyeing machine body (1) and is in a vertical state;

the plug rod (42) is arranged on the separation ring (18) and vertically inserted downwards into the connecting pipe (41);

the connecting screw rod (43), the connecting screw rod (43) is in threaded connection with the connecting pipe (41) and horizontally penetrates through the side wall of the connecting pipe (41) to abut against the inserting rod (42).

7. An overflow dyeing machine for reducing the vat difference in dyeing fabrics as claimed in claim 6, characterized in that: the dyeing machine body (1) is provided with a limiting ring (19), the limiting ring (19) is positioned below the two separating rings (18), and the fabric on the two cloth lifting wheels (12) passes through the limiting ring (19) from the cylinder bottom upwards and then respectively passes through the two separating rings (18).

8. An overflow dyeing machine for reducing the vat difference in dyeing fabrics as claimed in claim 7, characterized in that: spacing ring (19) can dismantle through fixed subassembly (5) and connect on two connecting pipes (41), fixed subassembly (5) include:

the two fixing rods (51) are arranged on the limiting ring (19) and are respectively positioned on two sides, close to the two connecting pipes (41), of the limiting ring (19);

the fixing plate (52), the said fixing plate (52) is set up on the dead lever (51), offer the long round hole (54) horizontally and perforating the thickness of the fixing plate (52) on the said fixing plate (52);

the fixing screw rod (53) is in threaded connection with the connecting pipe (41), the fixing screw rod (53) penetrates through the long circular hole (54), and the head of the fixing screw rod abuts against the fixing piece (52).

9. An overflow dyeing machine for reducing the vat difference in dyeing fabrics as claimed in claim 1, characterized in that: the cloth lifting wheel (12) is in a hollow state, a plurality of water dripping holes (13) communicated with the inside of the cloth lifting wheel (12) are radially and uniformly distributed on the wheel surface of the cloth lifting wheel (12), and an anti-skid pad (14) is arranged on the wheel surface of the cloth lifting wheel (12).

10. An overflow dyeing machine for reducing the vat difference in dyeing fabrics as claimed in claim 1, characterized in that: the cloth lifting wheel is characterized in that two ends of the cloth lifting wheel (12) are respectively provided with a baffle disc (15), and the diameter of each baffle disc (15) is larger than that of the cloth lifting wheel (12).

Images