CN219010686U - Wheel inspection type dyeing machine - Google Patents

Abstract

The utility model discloses a round-robin type dyeing machine, which comprises a dyeing machine cylinder, a circulating water pump and a dyeing liquid circulating assembly, wherein at least two first dyeing bins and second dyeing bins which are independently arranged are arranged in the dyeing machine cylinder; the water outlet end of the circulating water pump is respectively communicated with the interiors of the first dyeing bin and the second dyeing bin. When the dyeing machine disclosed by the utility model is used for dyeing fabrics, the water consumption and the consumption of dyeing auxiliary agents are reduced, the sewage discharge is reduced, and the cost is reduced.

Description

Wheel inspection type dyeing machine

Technical Field

The utility model relates to the technical field of textile processing equipment, in particular to a round inspection dyeing machine.

Background

The traditional fabric dyeing machine, in particular to a multi-bin (tube) dyeing machine, is mainly characterized in that a plurality of bins (tubes) are operated simultaneously or are simultaneously supplied with dye liquor for spraying operation, so that certain water quantity is required to be ensured for the liquid level of each bin (tube), thereby consuming a large amount of water consumption and increasing the usage amount of auxiliary agents. Meanwhile, the power supply load required by the simultaneous operation of all the bins (pipes) is enough, the more the number of the bins (pipes) is, the more the water consumption and the auxiliary agent consumption are, and the cost is increased while the sewage discharge is increased.

As in the patent application No. 201420079641.6, a low bath ratio garment dyeing machine is disclosed, wherein the multi-bin rotary liner of the dyeing machine is a three-bin rotary liner. Firstly, filling clear water into the cylindrical machine shell, then installing the fabric on the cylindrical machine shell through a working door of a dyeing machine, starting a speed regulating motor after installing the fabric, and driving the three-bin rotary liner seat to rotate at a low speed by the speed regulating motor through a transmission belt, wherein the fabric turns over in the liner along with the rotation of the machine liner; and then the dye liquor enters a three-bin rotary liner for storing the fabrics through the screen plate to be mixed with the fabrics. As can be seen from the above disclosure, the three-bin rotary liner of the patent simultaneously operates to dye, which increases the usage amount of water and dyeing auxiliary agent, increases the cost and increases the discharge of sewage.

Disclosure of Invention

The utility model aims to provide a round-robin dyeing machine, which reduces water consumption and the consumption of dyeing auxiliary agents, reduces sewage discharge and reduces cost when dyeing fabrics.

The technical scheme is as follows:

the utility model provides a round-robin dyeing machine, including dyeing machine cylinder body, circulating water pump and dye liquor circulation subassembly, dyeing machine cylinder body is inside to be equipped with at least two first dyeing warehouses and the second dyeing warehouses that independently set up, dye liquor circulation subassembly includes first circulation branch pipe and second circulation branch pipe at least, first circulation branch pipe, second circulation branch pipe communicate with each other with the inboard bottom in first dyeing warehouses, second dyeing warehouses respectively, first circulation branch pipe, second circulation branch pipe link to each other with circulating water pump's water inlet end respectively, be provided with first water supply stop valve and second water supply stop valve on first circulation branch pipe, the second circulation branch pipe respectively; the water outlet end of the circulating water pump is respectively communicated with the interiors of the first dyeing bin and the second dyeing bin.

In an embodiment, the water circulation device further comprises a nozzle assembly, the nozzle assembly comprises a nozzle main pipe, a first nozzle branch pipe and a second nozzle branch pipe, the nozzle main pipe is connected with the water outlet end of the circulating water pump, one ends of the first nozzle branch pipe and the second nozzle branch pipe are respectively connected with the nozzle main pipe, the other ends of the first nozzle branch pipe and the second nozzle branch pipe are respectively connected with a first nozzle and a second nozzle, and a first nozzle stop valve and a second nozzle stop valve are respectively arranged on the first nozzle branch pipe and the second nozzle branch pipe.

In an embodiment, the dyeing bin body is also fixed with an automatic filter and a heat exchanger, the water outlet end of the circulating water pump is connected with the water inlet end of the automatic filter, the water outlet end of the automatic filter is connected with the water inlet end of the heat exchanger, and the water outlet end of the heat exchanger is connected with the nozzle main pipe.

In an embodiment, the dye liquor circulation assembly further comprises a circulation main pipe, the first circulation branch pipe and the second circulation branch pipe are respectively connected with the circulation main pipe, and the circulation main pipe is connected with the water inlet end of the circulating water pump.

In an embodiment, the dyeing machine cylinder is further provided with a third dyeing bin which is independently arranged, the dyeing liquid circulation assembly further comprises a third circulation branch pipe, one end of the third circulation branch pipe is communicated with the bottom of the inner side of the third dyeing bin, the other end of the third circulation branch pipe is connected with the water inlet end of the circulating water pump, and a third water supply stop valve is arranged on the third circulation branch pipe.

In an embodiment, the inner bottoms of the first dyeing bin, the second dyeing bin and the third dyeing bin are respectively provided with a water level probe.

In an embodiment, the first dyeing bin, the second dyeing bin and the third dyeing bin are respectively provided with a cloth lifting wheel assembly and a cloth guide pipe, the cloth lifting wheel assemblies are positioned on one side of the cloth guide pipes, the fabric in the first dyeing bin and the second dyeing bin is conveyed to the cloth guide pipes through the cloth lifting wheel assemblies, and the first nozzles and the second nozzles are positioned at the cloth feeding ends of the cloth guide pipes.

In one embodiment, the dyeing machine cylinder is also provided with a left-right swing transmission mechanism, and the left-right swing transmission mechanism is connected with the cloth guide tube and the cloth groove.

In an embodiment, the left-right swing transmission mechanism comprises a transmission motor, a swing shaft and a swing cloth bucket, wherein the transmission motor is connected with the swing shaft, the swing cloth bucket is connected with the swing shaft, a feed inlet of the swing cloth bucket is connected with a cloth outlet end of the cloth guide pipe, and a discharge outlet of the swing cloth bucket is connected with the cloth groove.

In one embodiment, the heat exchanger comprises a shell, a medium inlet and a medium outlet which are arranged on the shell, a heat exchange cavity is arranged in the shell, a heat exchange tube is arranged in the heat exchange cavity, and the medium inlet and the medium outlet are respectively communicated with the inside of the heat exchange cavity.

The advantages and principles of the utility model are described below:

the round-robin type dyeing machine is provided with a dyeing machine cylinder body, a circulating water pump and a dyeing liquid circulating assembly, and at least two independent first dyeing bins and second dyeing bins are arranged inside the dyeing machine cylinder body. When the round-robin dyeing machine is used for dyeing, firstly, water and dye liquor are filled in a first dyeing bin, then a first water supply stop valve on a first circulating branch pipe is opened, and the dye liquor in the first dyeing bin is pumped by a circulating water pump to dye fabrics in the first dyeing bin. After the fabric in the first dyeing bin is dyed, the first water supply stop valve is closed, the second water supply stop valve is opened, and the circulating water pump pumps the dye liquor in the first dyeing bin to dye the fabric in the second dyeing bin. And after all the dye liquor in the first dyeing bin is pumped to the second dyeing bin, pumping the dye liquor in the second dyeing bin through a circulating water pump, and continuously dyeing the fabric in the second dyeing bin. After the dyeing of the fabrics in the second dyeing bin is finished, the second water supply stop valve is closed, the first water supply stop valve is opened at the same time, the dyeing of the new fabrics in the first dyeing bin is started, the reciprocating circulation is sequentially carried out, and the first dyeing bin and the second dyeing bin are repeatedly subjected to round-robin dyeing.

The utility model can reduce the water consumption and the consumption of dyeing auxiliary agents through the round-robin type dyeing, reduce the sewage discharge and the sewage treatment pressure, simultaneously reduce the cost, highlight the advantages of energy conservation and cost reduction, and have obvious economic benefit.

Drawings

Fig. 1 is a schematic structural view of a rotary dyeing machine of the present embodiment;

fig. 2 is another schematic structural view of the inspection dyeing machine of the present embodiment;

FIG. 3 is a schematic view of a structure of a rotary dyeing machine according to the present embodiment;

fig. 4 is a schematic structural view of a heat exchanger of the inspection dyeing machine of the present embodiment;

reference numerals illustrate:

1. a dyeing machine cylinder; 2. a circulating water pump; 3. a first dyeing bin; 4. a second dyeing bin; 5. a third dyeing bin; 6. a first circulation branch pipe; 7. a second circulation branch pipe; 8. a third circulation branch pipe; 9. a circulation main pipe; 10. a partition plate; 11. a first water supply shutoff valve; 12. a second water supply shutoff valve; 13. a third water supply shutoff valve; 14. a nozzle main pipe; 15. a first nozzle branch pipe; 16. a second nozzle branch pipe 16; 17. a third nozzle branch pipe; 18. a first nozzle shutoff valve; 19. a second nozzle shutoff valve 19; 20. a third nozzle shutoff valve; 21. a first nozzle; 22. a second nozzle; 23. a third nozzle; 24. a cloth lifting wheel assembly; 25. a cloth guide tube; 26. a drive motor; 27. a cloth swinging hopper; 28. a groove is arranged; 29. an automatic filter; 30. a heat exchanger; 31. a water level probe; 301. a housing; 302. a media inlet; 303. a medium outlet.

Detailed Description

In the description of the present utility model, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "middle," "inner," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate description of the present utility model and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first", "a second", etc. may explicitly or implicitly include one or more such feature. In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art in a specific case.

The preferred embodiments of the present utility model will be described in detail below with reference to the accompanying drawings so that the advantages and features of the present utility model can be more easily understood by those skilled in the art, thereby making clear and defining the scope of the present utility model.

As shown in fig. 1 to 3, the present embodiment discloses a round robin type dyeing machine, which comprises a dyeing machine cylinder 1, a circulating water pump 2 and a dyeing liquid circulating assembly. Wherein, the inside of the dyeing machine cylinder body 1 is provided with at least two first dyeing bins 3 and second dyeing bins 4 which are independently arranged. Preferably, the dyeing machine cylinder 1 is also provided with a third dyeing bin 5 which is arranged independently. The adjacent dyeing bins are separated into independent bins by a partition board 10.

The dye liquor circulation assembly at least comprises a first circulation branch pipe 6 and a second circulation branch pipe 7, and the first circulation branch pipe 6 and the second circulation branch pipe 7 are respectively communicated with the bottoms of the inner sides of the first dyeing bin 3 and the second dyeing bin 4. Preferably, the dyeing liquor circulation assembly further comprises a third circulation branch pipe 8, and one end of the third circulation branch pipe 8 is communicated with the inner bottom of the third dyeing bin 5. Further, the dye liquor circulation assembly further comprises a circulation main pipe 9, the first circulation branch pipe 6, the second circulation branch pipe 7 and the third circulation branch pipe 8 are respectively connected with the circulation main pipe 9, and the circulation main pipe 9 is connected with the water inlet end of the circulating water pump 2.

In order to control the dye solutions in the first dyeing bin 3, the second dyeing bin 4 and the third dyeing bin 5 respectively, the first circulation branch pipe 6 is provided with a first water supply stop valve 11, the second circulation branch pipe 7 is provided with a second water supply stop valve 12, and the third circulation branch pipe 8 is provided with a third water supply stop valve 13.

In order to dye the fabrics in the first dyeing bin 3, the second dyeing bin 4 and the third dyeing bin 5, the round-robin dyeing machine further comprises a nozzle assembly, and the fabrics are dyed through the dye liquor sprayed by the nozzle assembly. The nozzle assembly comprises a nozzle main 14, a first nozzle branch 15, a second nozzle branch 16 and a third nozzle branch 17. Wherein, the nozzle is responsible for 14 and is linked to the water outlet of circulating water pump 2, and the one end of first nozzle branch pipe 15, second nozzle branch pipe 16, third nozzle branch pipe 17 is responsible for 14 with the nozzle respectively. The first nozzle branch pipe 15, the second nozzle branch pipe 16, and the third nozzle branch pipe 17 are connected to the other ends thereof with a first nozzle 21, a second nozzle 22, and a third nozzle 23, respectively. The first nozzle branch pipe 15 is provided with a first nozzle stop valve 18, the second nozzle branch pipe 16 is provided with a second nozzle stop valve 19, and the third nozzle branch pipe 17 is provided with a third nozzle stop valve 20.

Further, the water level probes 31 are respectively arranged at the bottoms of the inner sides of the first dyeing bin 3, the second dyeing bin 4 and the third dyeing bin 5. The positions of the dye solutions in the first dyeing bin 3, the second dyeing bin 4 and the third dyeing bin 5 can be detected through the water level probe 31.

In order to dye the fabric, in this embodiment, a cloth lifting wheel assembly 24 and a cloth guide tube 25 are respectively arranged in the first dyeing bin 3, the second dyeing bin 4 and the third dyeing bin 5, the cloth lifting wheel assembly 24 is located at one side of the cloth guide tube 25, and the fabric in the first dyeing bin 3 and the second dyeing bin 4 is conveyed to the cloth guide tube 25 through the cloth lifting wheel assembly 24. The first nozzle 21 in the first dyeing bin 3 is positioned at the cloth feeding end of the cloth guide tube 25, the second nozzle 22 in the second dyeing bin 4 is also positioned at the cloth feeding end of the cloth guide tube 25, and the third nozzle 23 in the third dyeing bin 5 is also positioned at the cloth feeding end of the cloth guide tube 25. The fabric is fed into the cloth guide 25 by the cloth lifting wheel assembly 24 while dyeing, and the fabric is dyed by the dye solution sprayed from the nozzle while passing through the cloth guide 25.

The dyeing machine cylinder body 1 is also provided with a left-right swing transmission mechanism which is connected with the cloth guide tube 25 and the cloth groove 28. The fabric enters the left-right swing transmission mechanism after passing through the cloth guide tube 25, and then enters the cloth groove 28 through the left-right swing transmission mechanism.

The fabric can swing left and right when passing through the left and right swinging transmission mechanism. Preferably, the left-right swing transmission mechanism comprises a transmission motor 26, a swing shaft and a cloth swinging hopper 27, wherein the transmission motor 26 is connected with the swing shaft, the cloth swinging hopper 27 is connected with the swing shaft, and the transmission motor 26 can drive the cloth swinging hopper 27 to swing left and right through the swing shaft. The feed inlet of the cloth swinging hopper 27 is connected with the cloth outlet end of the cloth guide tube 25, and the discharge outlet of the cloth swinging hopper 27 is connected with the cloth groove 28.

The fabric enters the cloth swinging hopper 27 of the left-right swinging transmission mechanism to swing left and right after passing through the cloth guide pipe 25, and the fabric is continuously transposed left and right in the swinging process, so that crease marks can be reduced, and the fabric can be stacked in the cloth groove 28 left and right after coming out of the cloth swinging hopper 27.

Further, in this embodiment, an automatic filter 29 and a heat exchanger 30 are further fixed on the chromosome, the water outlet end of the circulating water pump 2 is connected to the water inlet end of the automatic filter 29, the water outlet end of the automatic filter 29 is connected to the water inlet end of the heat exchanger 30, and the water outlet end of the heat exchanger 30 is connected to the nozzle main pipe 14. The dye liquor pumped by the circulating water pump 2 is filtered by an automatic filter 29 and heated by a heat exchanger 30, and then is sent to different dyeing bins for dyeing.

Preferably, as shown in fig. 4, the heat exchanger 30 of the present embodiment includes a housing 301, and a medium inlet 302 and a medium outlet 303 disposed on the housing 301, wherein a heat exchange cavity is disposed in the housing 301, a heat exchange tube is disposed in the heat exchange cavity, and the medium inlet 302 and the medium outlet 303 are respectively communicated with the interior of the heat exchange cavity. Dye liquor enters through the medium inlet 302 and flows out of the medium outlet 303 after being heated in the heat exchange cavity.

The cloth lifting wheel assembly 24 of the embodiment is any cloth lifting wheel assembly 24 on the market at present, and can realize the conveying of fabrics. The automatic filter 29 of this embodiment is any filter currently available in the market, and can be used for filtering dye liquor.

The working steps of the round-robin dyeing machine of the embodiment are as follows:

firstly, water and dye liquor are filled in the first dyeing bin 3, then the first water supply stop valve 11 and the first nozzle 21 stop valve 18 are opened, the circulating water pump 2 pumps the dye liquor in the first dyeing bin 3, and the dye liquor enters the first nozzle 21 through the first nozzle stop valve 18 after passing through the automatic filter 29 and the heat exchanger 30. The cloth lifting wheel assembly 24 in the first dyeing bin 3 drives the fabric to be sent to the cloth guide tube 25, the fabric is dyed by the dyeing sprayed by the first nozzle 21, and the dyeing liquid returns to the first dyeing bin 3 for circulation along with the fabric. After the dye liquor and the fabric in the first dyeing bin 3 are circulated for a certain process time, the first nozzle stop valve 18 is closed, the cloth lifting wheel assembly 24 of the first dyeing bin 3 is closed, and meanwhile, the second nozzle stop valve 19 is opened, and the cloth lifting wheel assembly 24 of the second dyeing bin 4 is opened. The circulating water pump 2 pumps the dye liquor in the first dyeing bin 3 and sends the dye liquor to the second nozzle 22 through the second nozzle stop valve 19 to be sprayed out, and the cloth lifting wheel assembly 24 drives the fabric to dye in the second dyeing bin 4.

When the second dyeing bin 4 starts to dye, the dye liquid in the first dyeing bin 3 is pumped to the second dyeing bin 4. When the water level probe 31 in the first dyeing bin 3 detects that the dye liquor in the first dyeing bin 3 is completely extracted, the first water supply stop valve 11 is closed, and the circulating water pump 2 starts to extract the dye liquor in the second dyeing bin 4 by opening the second water supply stop valve 12, so that the dye liquor starts to circularly dye in the second dyeing bin 4. After the dye liquor and the fabric in the second dyeing bin 4 circulate to a certain process time, the second nozzle stop valve 19 and the cloth lifting wheel assembly 24 of the second dyeing bin 4 are closed, and the third nozzle stop valve 20 and the cloth lifting wheel assembly 24 of the third dyeing bin 5 are opened.

The circulating water pump 2 pumps the dye liquor in the second dyeing bin 4 and conveys the dye liquor to the third nozzle 23 of the third dyeing bin 5 for dyeing, and the cloth lifting wheel assembly 24 of the third dyeing bin 5 drives the fabric to be dyed. When the third dyeing bin 5 is used for dyeing, the dye liquor in the second dyeing bin 4 is pumped to the third dyeing bin 5, and when the water level probe 31 in the second dyeing bin 4 detects that the dye liquor in the second dyeing bin 4 is not available, the second water supply stop valve 12 is closed, the third water supply stop valve 13 is opened, and the dye liquor starts to circularly dye in the third dyeing bin 5.

After the dye liquor and the fabric in the third dyeing bin 5 circulate between certain processes, the third nozzle stop valve 20 is closed, the cloth lifting wheel assembly 24 of the third dyeing bin 5 is closed, the first nozzle stop valve 18 is opened, the cloth lifting wheel assembly 24 of the first dyeing bin 3 is opened, and the dye liquor is sent into the first dyeing bin 3 through the first nozzle stop valve 18 to dye new fabrics. When the first dyeing bin 3 performs dyeing, the dyeing liquid of the third dyeing bin 5 is pumped into the first dyeing bin 3. When the water level probe 31 in the third dyeing bin 5 detects that the dye liquor in the third dyeing bin 5 is completely extracted, the third water supply stop valve 13 is closed, the first water supply stop valve 11 is opened at the same time, and the dye liquor is circularly dyed in the first dyeing bin 3 again.

The first dyeing bin 3, the second dyeing bin 4 and the third dyeing bin 5 in this embodiment are used for dyeing in a circulating and alternating manner, and when one of the dyeing bins is used for dyeing, the fabrics in the other two dyeing bins are in a dye liquor absorption stage, so that the dye liquor effect is guaranteed. Compared with the traditional three-bin dyeing machine, the embodiment only needs one third of the dyeing liquid and water consumption of the traditional three-bin dyeing machine, and only one third of the electricity consumption of the traditional three-bin dyeing machine. The water consumption and the consumption of the dye liquor are reduced, so that the sewage discharge and the sewage treatment pressure are reduced, the advantages of energy conservation and cost reduction are highlighted, and the method has very obvious economic benefits.

In the above description, the present embodiment is described with only three dyeing bins, and in other embodiments, the round-robin dyeing machine is not limited to three dyeing bins, but may be four, five, six, etc.

The embodiments of the present utility model are not limited thereto, and the present utility model may be modified, substituted or combined in various other forms without departing from the basic technical spirit of the present utility model, which falls within the scope of the claims, according to the above-described aspects of the present utility model, using the general knowledge and conventional means of the art.

Claims (10)

1. The rotary inspection type dyeing machine is characterized by comprising a dyeing machine cylinder body, a circulating water pump and a dyeing liquid circulating assembly, wherein at least two first dyeing bins and second dyeing bins which are independently arranged are arranged in the dyeing machine cylinder body, the dyeing liquid circulating assembly at least comprises a first circulating branch pipe and a second circulating branch pipe, the first circulating branch pipe and the second circulating branch pipe are respectively communicated with the bottoms of the inner sides of the first dyeing bins and the second dyeing bins, the first circulating branch pipe and the second circulating branch pipe are respectively connected with the water inlet end of the circulating water pump, and a first water supply stop valve and a second water supply stop valve are respectively arranged on the first circulating branch pipe and the second circulating branch pipe; the water outlet end of the circulating water pump is respectively communicated with the interiors of the first dyeing bin and the second dyeing bin.

2. The rotary dyeing machine according to claim 1, further comprising a nozzle assembly, wherein the nozzle assembly comprises a nozzle main pipe, a first nozzle branch pipe and a second nozzle branch pipe, the nozzle main pipe is connected with the water outlet end of the circulating water pump, one ends of the first nozzle branch pipe and the second nozzle branch pipe are respectively connected with the nozzle main pipe, the other ends of the first nozzle branch pipe and the second nozzle branch pipe are respectively connected with a first nozzle and a second nozzle, and a first nozzle stop valve and a second nozzle stop valve are respectively arranged on the first nozzle branch pipe and the second nozzle branch pipe.

3. The rotary dyeing machine according to claim 2, wherein the dyeing bin body is further fixed with an automatic filter and a heat exchanger, the water outlet end of the circulating water pump is connected with the water inlet end of the automatic filter, the water outlet end of the automatic filter is connected with the water inlet end of the heat exchanger, and the water outlet end of the heat exchanger is connected with the nozzle main pipe.

4. The rotary inspection dyeing machine according to claim 1, wherein the dyeing liquid circulation assembly further comprises a circulation main pipe, the first circulation branch pipe and the second circulation branch pipe are respectively connected with the circulation main pipe, and the circulation main pipe is connected with the water inlet end of the circulation water pump.

5. The rotary inspection dyeing machine according to any one of claims 1 to 4, wherein a third dyeing bin is further arranged on the dyeing machine cylinder body, the dyeing liquid circulation assembly further comprises a third circulation branch pipe, one end of the third circulation branch pipe is communicated with the inner bottom of the third dyeing bin, the other end of the third circulation branch pipe is connected with the water inlet end of the circulating water pump, and a third water supply stop valve is arranged on the third circulation branch pipe.

6. The rotary dyeing machine according to claim 5, wherein the water level probes are respectively arranged at the bottoms of the inner sides of the first dyeing bin, the second dyeing bin and the third dyeing bin.

7. The rotary inspection dyeing machine according to claim 5, wherein the first dyeing bin, the second dyeing bin and the third dyeing bin are respectively provided with a cloth lifting wheel assembly and a cloth guide pipe, the cloth lifting wheel assemblies are positioned on one side of the cloth guide pipes, the fabric in the first dyeing bin and the second dyeing bin is conveyed to the cloth guide pipes through the cloth lifting wheel assemblies, and the first nozzle and the second nozzle are positioned at the cloth feeding ends of the cloth guide pipes.

8. The rotary inspection dyeing machine according to claim 7, wherein the cylinder body of the dyeing machine is further provided with a left-right swing transmission mechanism, and the left-right swing transmission mechanism is connected with the cloth guide tube and the cloth groove.

9. The wheel inspection dyeing machine according to claim 8, wherein the left-right swing transmission mechanism comprises a transmission motor, a swing shaft and a cloth swinging hopper, the transmission motor is connected with the swing shaft, the cloth swinging hopper is connected with the swing shaft, a feed inlet of the cloth swinging hopper is connected with a cloth outlet end of the cloth guide pipe, and a discharge outlet of the cloth swinging hopper is connected with the cloth groove.

10. A rotary dyeing machine according to claim 3, wherein the heat exchanger comprises a housing, a medium inlet and a medium outlet on the housing, a heat exchange chamber is arranged in the housing, heat exchange tubes are arranged in the heat exchange chamber, and the medium inlet and the medium outlet are respectively communicated with the inside of the heat exchange chamber.

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