KR20020051927A - Continuously and combiningly operable breadth expansion and vibration enhanced spray dyeing machine - Google Patents

Abstract

Widely spread, vibration-intensified spray dyeing system for continuous and connected work to process dyeing and other processes on fabrics. The dye and treatment agent are sprayed onto the fabric. The high speed air flow causes the fabric to vibrate violently to increase process effectiveness. The fabric can thus be subjected to continuous dyeing and other processing operations in a small amount in a short time.

Description

CONTINUOUSLY AND COMBININGLY OPERABLE BREADTH EXPANSION AND VIBRATION ENHANCED SPRAY DYEING MACHINE}

As used herein, the term continuous spray dyeing apparatus refers to a dyeing and processing apparatus that continuously dyes fabrics and provides other processes. The fabric is treated continuously and stretches substantially throughout the width direction. Liquid dyes and other textile treatment agents are brought into contact with the fabric in a micronized form by spray nozzle means arranged on the fabric. High velocity air steam is formed below the fabric to form a low pressure region that causes a pressure differential between the top and bottom of the unfolded fabric. The static pressure of the upper part of the fabric is greater than the lower pressure, so that the fabric is freely stretched in the width direction through the high-speed air steam, and the movement of the fabric may be periodically vibrated violently by irregular pressure.

This vibration provides energy for the dye, treatment or oxidizing gas that penetrates the fabric tissue to enhance the rate of absorption and diffusion of the dye into the fabric. Thus, high efficiency, low energy consumption, low solution ratio and low contamination can result in continuous dyeing and processing.

The invention relates in particular to the effect generated by the high velocity air steam formed by the tube guiding the cloth. This not only enhances the penetration and diffusion of the dye to speed up the dye when low temperature redox dyeing is performed, but also increases the penetration rate. When carrying out other processes, it provides a very efficient way to remove unintended dust or impurities from the fabric, thereby desizing, scouting, bleaching, soaping, reducing, enzymatically rinsing, Efficiently complete the relaxation and drying operations. Thus, the present invention can complete all dyeing and processing in a very short time compared to the conventional dyeing apparatus.

Conventional continuous dyeing devices are described as combining two or more devices having different functions of performing the dyeing process in a continuous manner. When dyeing, there are three steps: dye padding, development and fixation, and washing and drying operations. A general conventional continuous dyeing apparatus has been developed by improving the dye padding operation design. In order to achieve some operation, some designs go through a specific dyeing method in which each device is specifically combined. Thus, pretreatment operations are generally separated from dyeing operations in order to obtain the best manufacturing treatments due to the limitations of the plant environment. Referring to Figures 1 and 2, Figure 1 is a side view showing the combined structure of a conventional dye padding continuous dyeing device, Figure 2 is a side view of a conventional continuous spreading washing device. Referring to Figure 1, the combined structure is a dye padding device (A), steam or dryer (B), air oxidizing device (C), treatment padding device (D), steamer (E), washing machine (F) according to the manufacturing order ), A dehydrator (G) and a dryer (H). All the devices are connected in line and the fabric is pulled by the drive rollers and cloth guide shafts of each device so that they pass continuously through each device. The longitudinal and transverse directions of the fabric are pulled with great tension so that the fabric is treated in a continuous and widened state.

Thus, referring to FIG. 3A, the conventional continuous dyeing apparatus pulls the fabric past the dye padding device A so that the dye is absorbed by the driving roller A1 and the compression roller A2 in the dye padding device. Thus, the size of the contact surface between the two rollers directly affects the dye padding ratio, which affects the dyeing condition. In order to prevent color differences on both sides of the fabric, additionally pressure is applied to both sides of the dye padding roller so that the center of the pressure roller should be the peak standard so that the dye and the treatment agent are evenly distributed. 3B and 3C are side views of another general dye padding apparatus. The fabric past the dye padding device (A) passes directly through the steamer (B). This is different from the usual discontinuous dyeing apparatus. For example, a dyeing device in the form of an air flow or liquid blemish can similarly perform a continuous dye cycle and will dye at the same time. The fabric is passed through a steamer (B) or an air oxidizer (C) to allow dyes to develop and adhere. The advancing of the fabric is maintained by the cloth guide axis set B1. After the dye is fixed, the fabric is led to a washing machine (F) to remove the unfixed dye, remaining chemicals or other impurities. Typically the washer F has each unit F1, with several units connected in groups. The tubes are filled with a large amount of water. The dewatering compression roller F2 is mounted on the upper outer side of each shaft. The number depends on the process after dyeing. In conventional dye padding apparatuses and steamers, the process after dyeing includes operations such as re-oxidation, acid wash, neutralization, heat shower, soaping, heat shower and cold wash. Thus, most preferred are washers consisting of 7 to 9 tubes. After water washing and dehydration the fabric is led to a dryer (H) to dry. In general, a dryer consists of several drying tubes. After dye padding the fabric needs to be treated immediately with dye development and fixation so that the dye development and fixation treatment device is mounted immediately after the dye padding device.

Thus, a conventional continuous dyeing apparatus is constructed by connecting several different apparatuses together for continuous dyeing and processing. The dye padding device A, which is used to dye and treat the fabric substantially, has the problem of making the fabric without light contact or folding it in a straight line dyed in a straight line. The longitudinal tension is greater than 1.5 kg F (per centimeter) in addition to the transverse pull by the device for pulling the fabric to allow the fabric to be fully stretched for dyeing and processing. Thus, while conventional continuous dyeing apparatus can only dye and process tatting fabrics, the problem present in knit or stretch fabrics cannot be solved now. Moreover, in the dyeing process by the dye padding apparatus, although a small amount of liquid dyeing can be made, the dyeing process cannot yet be performed at once. When dye development and fixation are carried out in a steamer, it is not possible to continuously supply dyes at the same time, so that the fabric cannot get dark color. When the fabric is washed, a large amount of water is needed for washing. The above-mentioned continuous dyeing apparatus requires a great deal of improvement and modification for the new environmental protection dyeing apparatus.

Referring to FIG. 4, there is shown another spray dyeing apparatus having a widening, vibrating enhanced dyeing operation developed by the inventor of the present invention. This is described in Taiwan patent 098,316 and US patent 5,775,136 and PCT WO98 / 49383. The present invention is an improved invention derived from these technical ideas and features.

Referring to Figures 4 and 6, Figure 4 is a side view of a spray dyeing apparatus having a dyeing operation is expanded width and reinforced reinforced, Figure 6 is a side view showing the structure of a continuous spray dyeing apparatus according to the present invention. The air guiding nozzle design part is almost identical in concept and structure. However, the application of the air guide nozzle in the present invention is different from the conventional invention. The advantages are described for the convenience of the test procedure. The big difference is that in previous cases the discontinuous dyeing device could only perform a small amount of staining and work; The continuous spray dyeing apparatus of the present invention can not only continuously perform operations in the treatment tank but also be connected to other apparatuses to perform operations such as dyeing, treating agent absorption, steam dye development, air dye development, dye fixing, washing and drying. Can finish continuously. In order to facilitate absorption or to increase production rates, treatment vessels can optionally be added to obtain the required quality and production rate. Therefore, in view of the drawbacks of the discontinuous spray dyeing apparatus with expanded width and vibration enhanced dyeing operation and the above-mentioned general continuous dyeing apparatus, the application technology of the air guiding nozzle should be improved for a better environmental protection dyeing method. . Accordingly, the present invention provides another mass-produced continuous dyeing apparatus.

The present invention relates to a spray dyeing device (hereinafter referred to as a " continuous spray dyeing device ") that has been expanded and vibrated to enhance continuous and connecting work so as to maintain continuous spray dyeing and to be efficient in treating the device.

The drawings show an embodiment in which examples of various advantages and objects of the present invention can be seen.

1 is a side view showing the combined structure of a conventional padding type continuous dyeing apparatus,

Figure 2 is a side view showing the structure of a conventional continuous widening washing machine,

3a to 3c is a side view showing the structure of a conventional dyeing padding device,

4 is a view showing another spray dyeing apparatus for carrying out widened and enhanced vibration dyeing described in Taiwan Patent 098,316 and US Patent 5,775,136 and PCT WO98.49383,

5 is a side view showing the structure of the continuous spray dyeing apparatus according to the present invention,

6 is a side view showing the structure of the continuous spray dyeing apparatus according to the present invention and its use state,

7 is a cross-sectional view taken along the line X-X 'of the continuous spray dyeing apparatus according to the present invention,

8 is a cross-sectional view taken along the line Y-Y 'of the continuous dyeing apparatus according to the present invention,

9 is a side view showing still another structure of the continuous spray dyeing apparatus according to the present invention and its use state.

The present invention provides a continuous spray dyeing apparatus that allows fabrics to be floated, stretched out and vibrated violently by high speed air flows in dyeing and other processing operations to complete the fixation in a short time.

The present invention also provides wide spread continuous spray dyeing and processing for interwoven fabrics of other stretch fabrics. Moreover, the present invention provides a continuous spray dyeing apparatus which can be connected to other apparatuses to achieve a continuous process, which can be freely deformed, adjusted, unrolled or reduced depending on the manufacturing process, thus achieving economical dyeing and processing operations. Can be.

In addition, the present invention provides a continuous spray dyeing apparatus in which the fabric is similarly processed in each area in such a way that the fabrics are folded together. In each zone, the fabric is pulled by a wheel that pulls one cloth. Thus, the tension on the fabric can be minimized and the problem of bad soft touch of the fabric processed by the original padding continuous dyeing apparatus can be improved.

Furthermore, the present invention provides a continuous spray dyeing apparatus capable of providing a general dispersing and reactive dye with a low temperature reducing dye solution under the condition that nitrogen gas is introduced into an upstream treatment tank and also performing a spray dyeing operation. As the fabric passes through the next treatment bath, the reducing dye liquor can be oxidized by spraying a large amount of clear air with an air guiding nozzle to improve the dye.

In addition, the present invention provides a continuous spray dyeing apparatus in which a high speed air stream is provided to the bottom surface of the fabric so that the fabric periodically vibrates vigorously as the fabric passes each treatment tank. Thus, the dyeing, treating agent or refining air can quickly pass through the fabric to aid in the shaking, making small amounts of dyeing and processing very effective.

Another object of the present invention is to provide a continuous spray dyeing apparatus which sprays high speed air containing a large amount of water or dyes released from an air guiding nozzle when washing or dyeing a tightly woven fabric. The treated fabric can thus be dyed on both sides and the impurities remaining in the fabric can be quickly released into the water.

Thus, the present invention can perform rapid washing and enhanced dyeing. Another purpose of the present invention is to improve the practical removal of impurities present in the fabric so that operations such as desizing, scouring, bleaching, soaping and cleaning can be processed quickly. It is to provide a continuous spray dyeing apparatus which provides a small amount and high-speed concentrated dyeing by periodic vigorous shaking.

The present invention thus provides a very efficient cleaning effect on the fabric being dyed. Moreover, the present invention provides a continuous spray dyeing apparatus for drying fabrics through drying and heat through air guiding nozzles, as well as dyeing and other wet type processing operations, which can introduce external cold air at low temperatures. Can be.

In order to achieve the above object, the continuous spray dyeing apparatus provided by the present invention has a treatment tank connected to perform similar dyeing, and the treatment tank is designed with the same concept and structure. The treatment tank is fabric storage tank, fabric guide tube, air guide nozzle, fabric pull wheel, blast machine, dye pump, fabric weaving device, air heater, dye heater, air cooling inlet, discharge outlet, nitrogen inlet, steam Inlets, air filters, dye filters, pipes connecting each component, and controllers for each device.

Each before and after end of the treatment seconds of the continuous spray dyeing apparatus according to the present invention is composed of the left and right walls of the treatment tank to form a passage, left and right sides and a wide passage in parallel so that the fabric enters and expands in a widthwise manner. The fabric reservoir may be provided upstream of the reinforcement passage adjacent the bottom of the vessel so that the fabric may be folded and stacked with the required medicine. The fabric thus reduces its speed of movement so that the tension is dispersed in subsequent operations. A fabric guide tube is formed downstream of the passage. An air guide nozzle divided into one or a plurality of parts is formed along the passage direction in the cross-sectional direction of the side wall under the fabric guide tube. These nozzles are piped to the brass apparatus for introducing and discharging compressed air. One or more dye nozzles are provided in the fabric guide tube and piped to a dye pump for guiding and releasing the dye or treatment to the surface of the fabric. A dynamic fabric dragging wheel is provided below the outlet outlet downstream of the fabric to allow the fabric in the fabric loading tank to be dragged through the fabric guide. The fabric may proceed continuously to the next treatment bath to perform another treatment operation. Thus, when dyeing and other processing operations are performed, the fabric is brought into full contact with the fine dye particles that are discharged through the dye nozzle to achieve a small amount of dyeing. When the fabric is in contact with the dye, the fabric is subjected to periodic violent vibrations by the high velocity air stream ejected from the air guiding nozzles. Thus, the dye and chemical or reoxidation gas have the necessary energy to penetrate the fabric. The rate at which the dye is absorbed into the fabric and the rate of diffusion are enhanced so that continuous dyeing and processing operations can be performed with high efficiency, low energy, low bath rate and low contamination.

See FIG. 5 and FIG. 8. 5 is a side view showing the structure of a continuous spray dyeing apparatus according to the present invention; 8 is a cross-sectional view taken along the line Y-Y 'of the continuous spray dyeing apparatus according to the present invention. Continuous spray dyeing apparatus according to the present invention is a treatment tank (1), inlet passage 101, outlet passage 102, fabric loading tank (4), fabric guide passage (5), air guide nozzle 51, reflection Action base 52, air circulation passage 63, fabric dragging wheel 3, brest device 6, air filter 602, dye pump 7, dye nozzle 71, fabric wiggling device 8 ), Fabric transmitter (2), air heater (601), dye heater (702), fuel filter (701), liquefied gas circulation guide plate (53), purge air inlet (65), outlet outlet (66), nitrogen inlet 641, stream inlet 642, water inlet 74, water nozzle 721, spray nozzle 722, valve 103, outlet fabric wiggling device 11, valve 103, on outlet fabric Gling apparatus 11 and dye fusion circulation 54.

See Figures 5, 6, 7, 8 and 9. The treatment tank 1 has the same shape and shape on the front and back sides so as to be connected conveniently. An inlet passage 101 is provided over the sidewall upstream of the treatment vessel passage, while an outlet passage 102 is formed over the sidewall downstream of the treatment vessel. The left and right side surfaces of each passageway in the treatment tank 1 and the left and right side walls of the passage are formed in parallel passages having a width opening and closing portion so that the fabric 2 passes through the treatment tank 2 in a shape of widening width. do. The downstream end 402 in the lower treatment tank 2 is located lower than the stream end 401. They form an inclined surface at a small angle so that the circulating liquid quickly gathers at the lowest position and returns to the dye reservoir via the circulation pump 17. The fabric reservoir 4 is provided upstream of the passage of the treatment tank 1. The lower part of the reservoir 4 is composed of a liquefied gas separation net plate 41.

The fabric guide tube 5 is formed in the passage downstream part of the processing tank 1. One or more dye nozzles 71 are provided on the upper side wall in the passage of the fabric guide tube 5. The air discharge pipe 62 and the fabric guide pipe 5 on the outer portion of the lower passage so that the lower wall of the fabric guide pipe 5 and the top wall of the air discharge pipe 62 have a common wall 52. Provided in the same direction. The common wall 52 (also known as the reflective base 52) is provided with one or a plurality of air guide nozzles 51 which are partially separated along the end passage of the cavity wall 52. The upstream end of the highway wall 52 is connected to the fabric reservoir 4 long liquid gas separation network plate 41. The downstream end of the fraud cavity wall 52 is connected to the outlet passageway 102. The cavity wall 52 thus forms an angle of inclination with the upstream end lower than the downstream end. A fabric dragging wheel 3 is provided below the outlet passageway 102. The fabric wiggling device 8 is provided below the fabric dragging wheel 3 in the upstream direction. The fabric wiggling device 8 is connected to the wiggling plate via a power transmission device to shake the fabric longitudinally. The cavity wall 52 extends at the connection portion between the cavity wall 52 and the liquid gas separation network plate 41 to form a dye circulation guide plate 53. One or more dye fusion circulation sections 54 are provided downstream of the dye circulation guide plate 53. The air circulation passage 63 is formed between the circulation portion 54 and the passage. Thus, the circulating dye from the cavity wall 52 does not mix with the air stream circulated as it passes through the fusion circulation.

On the left and right walls downstream and in the passage of the treatment tank 1, a hidden breast machine 6 is provided below the air vent tube 62. The hidden breast device 6 is provided with a flow cylinder 64 at the inlet end. The inner space of the floor cylinder is formed by the air filter 602. The outlet of the brest device 6 is connected to the air discharge pipe 62.

As described in the continuous spray dyeing apparatus, the fabric pulled and crushed by the fabric dragging wheel 3 and stored in the fabric reservoir 4 is stored in the cavity wall 52 under the fabric guide tube 5 ( Through the face of the reflective base 52). The dye or treatment agent in the reservoir 9 is compressed by the dye pump 7 to be sprayed onto the top surface of the fabric and passes through a transfer pipe 72, a filter 701 and a heat exchanger 702 to the fabric. Enter the dye nozzle 71 in the guide tube (5). Thus, when processing a dyeing or other process, the fabric (2) is expelled from the air guide nozzle 51 so that the entire width is expanded by the high-flow air flow discharged to flow through the fabric guide tube (5) Will be pulled. The fabric 2 is covered with scattered dye and fine particles of the treatment agent ejected from the dye nozzle 71 on top of the fabric guide tube 5. Dyeing is achieved by penetration of the dye from the top side to the bottom. The lower surface of the fabric 2 is provided with a high velocity air stream exiting from the plurality of divided air guide nozzles 51 in series to form a flotation force on the fabric. The air flow creates a pressure difference between the upper and lower surfaces of the fabric 2 such that the lower side is lower in pressure by the higher velocity air flow while the upper side is higher in pressure by the slower air flow. Thus, the upper and lower air streams act to cause the fabric to shake periodically. The upper air stream with the higher pressure acts to release the air stream on the left and right sides under the fabric 2. As it passes through the fabric guide tube 5, the fabric not only vibrates violently periodically but also completely unfolds continuously in the width direction. The dye and solution not absorbed in the fabric 2 are recovered by the dye circulation pump 17 to the dye reservoir 9 or flow back to the treatment tank 1 downstream for respray. If in the washing process, the solution is exchanged.

The gas section is connected to the brest device 6 by means of an air circulation flow cylinder 64 (additional circulation pipes and transmission pipes must be fitted if a hidden brest device is not fitted) and the air in the bath is connected to the brest device 6. And is sent to the air discharge pipe 62 via the air filter 602 and the heat exchanger 601 via the transmission pipe. The air is thus discharged by the air guide nozzle 51 along the upper surface of the reflective base 52 in the upstream direction of the fabric guide tube 5. The air flow has an opposite direction to the movement of the fabric 2. The fabric 2 has a stable movement because the friction between the fabric dragging wheel 3 and the fabric is greater than the force caused by the air flow. Therefore, the fabric dragging wheel 3 should have a greater pulling force than the force generated by the air flow in order for the fabric to proceed stably. In fact, the fabric 2 in the treatment tank 1 can have movement in the same direction as the air flow which facilitates dyeing. The difference between staining in which the movement has the same direction and staining in which the movement has the opposite direction is not significant. In operation, however, the opposite direction of movement provides more stability with respect to the movement of the fabric 2 than in the same direction. In other words, the same direction of movement is less suitable for discontinuous dyeing apparatus, which has been described in detail in the previous patent of the same inventor and further explanation is omitted here. Basically, in the area of continuous and discontinuous dyeing, there is a big difference in the requirements of the speed of the weaving. The reason is that depending on the process as the fabric 2 passes through each device, the treatment relates to a continuous dyeing device, and therefore the speed of the fabric 2 for complete dyeing and better quality under limited conditions and time. It is desirable to lower the. When the fabric 2 and the air flow are in the opposite direction, the speed of the fabric 2 can be completely controlled by the fabric dragging wheel 3. Therefore, simultaneous purpose is not a problem in operation. The energy of the air discharged from the air guiding nozzle 51 may be totally converted into energy necessary for the vibration of the fabric 2. In addition, another object is that most contaminants are removed along the air stream and the circulating solution in the dyeing or impurity treatment process. In addition, a cleaning nozzle 721 is provided at an upstream end in the air discharge pipe 62 and connected to the high pressure washing pump or the water tank by the transmission pipe 74. Another transfer pipe 73 is formed in the transfer pipe 74 and connected to the dye transfer pipe 72. The reverse control valve opens and closes the valve, particularly when washing or dyeing drab fabrics, either water or a mixture of water and dyes. Is provided to each pipeline to control the emissions. The discharged solution is discharged and mixed in the air flow direction in the air discharge pipe 62 so that a large amount of water or dye discharged from the air guide nozzle 51 can contact the fabric 2. This allows impurities or treatments to remain in the fabric 2 to diffuse rapidly into the water. If the fabric 2 is dyed on both sides, another steam pipe can be provided to the transfer pipe 74 so that the reverse control valve 641 can directly provide the required temperature to the treatment tank 1.

When the fabric 2 enters the next treatment tank 1, the operation of the wiggling plate 8 allows the fabric 2 to fall into the fabric reservoir 4 and fold well. In order to facilitate the inspection procedure, the effect generated in the fabric guide tube is described in more detail below.

According to Bernoulli's law, a space with a higher velocity liquid gas stream has a lower pressure. Thus, when a high speed air stream is formed below the fabric 2 as described above, the pressure under the fabric 2 is lower than the pressure in the vicinity by the low speed air flow. The fabric 2 is pulled in the direction of the high velocity air flow region by the pressure difference and gravity 8. So friction is closely related to high velocity airflow while the fabric 2 is increased to obtain the best energy from the airflow. So whenever the fabric 2 is close to the mainstream of a high velocity air stream, it cannot be pulled by the air stream and run forward. Since the mainstream of the high velocity air flow has a greater kinetic energy, the forward moving fabric 2 is continuously suspended and moved over a flat wall to prevent friction between the fabric 2 and the pipe wall. Whenever the fabric is forced into the mainstream of the high velocity air stream, the fabric 2 generates the highest pressure and force to move quickly away from the mainstream region. The generation of the peak pressure results from the conversion of kinetic energy into pressure energy with respect to resistance. This is affected by the reflection of the flat reflecting base 52 and by the same phase as the other peaks so that other peak pressures are generated immediately. This highest pressure is generated continuously in the fabric 2 periodically along the fabric guide tube 5. Thus, some parts of the fabric 2 may have periodic vibrations. The vibration frequency is determined by the mass of the fabric 2 as well as the momentum of the air flow. Thus, in the dyeing or processing process, the opening width of the air guide nozzle 51 and the output of the breast apparatus can control the vibration frequency. The occurrence of the periodic vibrations is the result of work performed by large amounts of energy. Each vibration not only loosens the fabric structure of the fabric 2 so that the dye can have a circulation passage, but also allows the dye to obtain the energy necessary to penetrate the fabric structure. This further enhances the rate and diffusion rate at which the dye is absorbed into the fabric. Thus, the fabric can have tension and relaxation effects through periodic violent vibrations, in order to obtain additionally small amounts of high concentration, high efficiency, low energy consumption, low basing rate and low staining in the dyeing process. At the same time, impurities on the fabric can be effectively removed to quickly complete processing such as dishing, scouring, branching, reducing, enzymatic treatment, soaping, washing. Thus, the present invention can perform dyeing and other process treatments in a remarkably short time.

The present invention is not limited to the above-described embodiments, and the present invention can be variously modified without departing from the technical spirit of the present invention. Accordingly, the present invention is not limited by the following claims in order to facilitate technical and practical advances.

Claims (7)

One or more connectable treatment baths having a wide cross-sectional area such that the fabric is dyed or otherwise processed in series; An inlet passage formed in an upper end portion of an upstream sidewall of the treatment tank; An outlet passage formed in an upper end portion of a downstream sidewall of the treatment tank; A dynamic fabric dragging wheel formed in each said inlet and outlet passageway; A fabric reservoir formed under an inlet passage upstream of the passage in the treatment tank; A fabric guide tube formed so as to have an inclination angle between the fabric reservoir and the outlet passage in a downstream portion of the treatment tank with a downstream end thereof higher than an upstream end; The dye pump and the treatment liquid discharged toward the fabric is formed on the upper side wall of the fabric guide tube so as to be ejected by ejecting the fine particles to a large area of the fabric and the dye pump and the pipe through the pipe through which the dye or treatment liquid is discharged; One or a plurality of dye nozzles connected; One or a plurality of partially separated air guide nozzles formed along a passage in a cross section of the lower sidewall of the fabric guide tube such that the upstream air guide nozzle and the downstream air guide nozzle are separated apart; A reflecting base formed in a downstream direction of each of the air guide nozzles so as to be discharged by being guided to the air guide nozzles and connected to the brest device via a pipe; Under the action of the reflective base, the discharged high velocity air stream flows along the upper surface of the reflective base such that the lower fabric pressure is lowered by the high velocity air stream and the upper pressure is higher by the lower velocity air stream. Running upstream below the fabric, the top and bottom air flows interact to allow the fabric to pass through the fabric guide tube so that the width is fully extended and with periodic violent vibration, the fabric penetrates into the fabric structure. So that the pressure conversion and gravity are continuously pushed into the mainstream region of the high velocity air stream so that the energy conversion rate is increased closely related to the high velocity air flow so that the maximum energy can be obtained from the air stream. Low tensile, low energy consumption, low bassing rate and In order to achieve an environment that maintains constant color and processing, impurities in the fabric can be dished, scored, bleached, reduced in order to achieve additional high concentrations, high efficiency, low energy consumption, low bassing rates and low staining in the dyeing process. Process, such as enzymatic treatment, soaping, washing, etc., is effectively removed to ensure a quick termination of the process, while a continuous, connectable width and vibration can be applied to allow the fabric to have tension and relaxation through periodic intense vibrations. Enhanced spray dyeing device. The liquid gas circulation guide plate of claim 1, further comprising a dragging type liquid gas circulation guide plate and a separate liquid gas circulation passage between the fabric guide tube and the fabric reservoir. A downstream portion of the liquid gas circulation guide plate separately forms an arc circulation to form one or a plurality of liquid fusion pipes, and an air flow under the fabric is circulated to pass through the mesh under the fabric reservoir to pass through the air circulation passage. Liquid is passed through the fusion pipe along the liquid gas circulation guide plate by the dragging and pressure difference of the dragging type liquid gas circulation guide plate, and the potential to return to the breast via the lower sidewall of the treatment tank. So that the passageway A continuous and connectable wide spread and vibration-enhanced spray dyeing device formed between said liquid fusion pipes and consequently a split liquid gas circulation is formed within said treatment tank. The apparatus of claim 1, further comprising a spray nozzle device comprising a passage pipe having one or a plurality of nozzles in the air discharge passage; Dye, water, or vapor along the manufacturing process allows the air or discharge path to flow through the manufacturing process so that the exiting liquid or gas is mixed with the air stream to allow the air guiding nozzle to release a high velocity air stream containing a large amount of dye liquid, water or steam The other end of the passage pipe, guided by a nozzle in the chamber, is connected to the steam transfer pipe and the control valve mounted to each of the pipes via a dye transfer pipe, a compression pump or a water tank, and through the pipes. Wide spreading and vibration enhanced spray dyeing device. The fabric wiggling device according to claim 1, further comprising a weigling plate provided under a dynamic fabric dragging wheel in an upstream passage of the treatment tank and including a wiggling plate, a transmission shaft, a drive rod, and a drive at one end of the wiggling plate; ; The wiggling plate extends outward of the jaw wall so that the wiggling plate reciprocates in the longitudinal axis so that the fabric can be folded as desired and falls into the fabric reservoir, and the end of the wiggling plate is connected to the driving unit. A spray dyeing apparatus, the width of which is continuous and connectable, which is fixed to the left and right sidewalls by the transmission shaft, and which is enhanced in vibration. 2. The air inlet of claim 1, further comprising: an air inlet and an outlet outlet provided in the breast device inlet passageway; A hot air exhaust outlet and a nitrogen (inert gas) inlet provided on the sidewall of the treatment tank; And a treatment liquid circulation outlet at the bottom of the treatment tank; And a control valve provided at each of the inlets and outlets so that the continuous or connectable width and vibration-enhanced spray dyeing device in which air supply or delivery to the treatment tank can be arbitrarily controlled according to a manufacturing process. The spray dyeing of claim 1, further comprising a heat exchanger and a filter connected to the dye transfer or circulation passage and the air transfer or circulation passage respectively forming a passage. Device. 2. The apparatus of claim 1, further comprising a water nozzle provided in said treatment tank, said water nozzle being provided in a corner that is easily contaminated so that, when each dyeing process is completed, water is guided to the nozzle to be discharged toward the contaminated wall. Spray dyeing device with continuous and wide spread and vibration-enhanced connection to the high pressure pump via pipes.