TWI585263B - Super permeation open fiber machine - Google Patents

Description

Ultra-permeability opener

The present invention relates to a fiber opening machine, and more particularly to a super permeable fiberizing machine for relaxing fibers of a cloth to facilitate dyeing and cleaning.

Dyeing on fibers with dyes is an important skill in the textile industry. Dyes can include oil soluble dyes as well as water soluble dyes. The oil-soluble dye is first emulsified and dissolved in water to produce an emulsion dye, and then the dyeing agent is dyed on the fibers of the cloth by a dyeing machine, and finally the emulsion which is not attached but remains on the cloth is dyed. The agent is cleaned.

However, the emulsion dyeing agent of the traditional dyeing machine is a vortex rope-like flow pattern, which causes the cloth to spin through the nozzle, causing the cloth to be curled, uneven dyeing, long dyeing time, and poor adhesion of the emulsion dye. And the emulsion dye which is not attached but remains on the cloth is not easily cleaned and the like.

Furthermore, the process of emulsification and dissolving the oil-soluble dye in water by stirring is easy to generate bubbles, and two problems are derived: first, some oil-soluble dyes are covered by bubbles and cannot be dissolved in water; The emulsion dye is disturbed by the bubbles and is not easily uniformly colored on the fibers of the cloth.

In fact, the manner of stirring is not easy to emulsify and dissolve the oil-soluble dye in water. Therefore, in general, a dispersant is added during the dyeing process to improve the effect of emulsification of the oil-soluble dye on water. However, the dispersant will increase the chemical oxygen demand of the wastewater (Chemical Oxygen Demand, abbreviated COD), causing environmental pollution. Moreover, bubbles are easily generated after the addition of the dispersant, and two problems with respect to the bubbles described in the preceding paragraph are generated.

In addition, in order to enable the emulsion dye to be uniformly dyed on the fibers of the cloth, a leveling agent is usually added. However, the leveling agent also increases the chemical oxygen demand of the wastewater, causing environmental pollution.

Further, the oil-soluble dye obtained by combining a plurality of molecules can be stirred into a small molecule combination by stirring, but the effect of emulsification of the oil-soluble dye of a small molecule combination in water is extremely poor. What is more serious is that the small molecule combination of each oil-soluble dye is very inconsistent, causing the particles of the emulsion dye to have different sizes, and the dyed fibers may cause problems such as color spots, color flowers, and uneven dyeing. The cost of the dyeing and finishing plant.

In addition, the finished dyed cloth usually has a relatively stiff feel, so the manufacturer will add an auxiliary agent that softens the cloth when the cloth is dyed, so that the cloth is soft to the touch. However, the softening auxiliary agent also increases the chemical oxygen demand of the wastewater, causing environmental pollution.

The main object of the present invention is to provide a super osmosis fiber-opening machine which can oscillate and smash the cloth during the process of dyeing the cloth, and can also oscillate the multi-molecule oil-soluble dye into a single molecule oil-soluble dye. The fiber of the cloth is beaten and slackened to be relaxed and can be dyed quickly and uniformly, and can reach a soft state of the hand. It is completely environmentally friendly without using a dispersing agent, a leveling agent and a soft auxiliary agent.

Another object of the present invention is to provide a super osmosis fiber-opening machine which can slap and smash the cloth during the cleaning process, and thoroughly wash the emulsion dye which is not adhered but remains on the cloth.

In order to achieve the foregoing objects, the present invention provides a super osmosis fiberizer comprising a body, at least one oscillator, and a weir device.

The body includes a first end portion, a fiber opening portion and a second end portion, the first end portion forming an inlet, the second end portion forming an outlet, and the fiber opening portion is disposed at the first and second ends Between the ends, a fiber opening space is defined, and the fiber opening space is connected between the inlet and the outlet, wherein the inlet is used for a liquid and a cloth to enter, and the liquid and the cloth pass through the fiber opening space. Then leave from the exit.

The oscillator is disposed in the fiber opening portion and generates a vibration wave transmitted to the liquid and transmitted to the cloth through the liquid, so that the liquid and the cloth are beaten by the vibration wave.

The device is disposed in the fiber opening space and licks the cloth.

According to a preferred embodiment, the fiber opening portion includes an oscillating region, the oscillating region is connected to the first end, and the fiber opening space includes an oscillating space, the oscillating space is located in the oscillating region and communicates with the inlet, the oscillating The device is disposed in the oscillation zone. The super-osmosis fiber-opening machine further includes a plurality of oscillators, wherein a part of the oscillator is disposed outside the top of the oscillating region and is defined as a first oscillator, and another portion of the oscillator is disposed outside the bottom of the oscillating region and Defined as a second oscillator, the first oscillators and the second oscillators are staggered with each other. The first oscillators are arranged in a plurality of rows, the first oscillators of the same row are arranged at intervals, the second oscillators are arranged in a plurality of rows, and the second oscillators of the same row are arranged at intervals, wherein the plurality of rows are first The oscillators respectively correspond to the plurality of second oscillators, and each of the first oscillators and the corresponding one of the second oscillators are staggered with each other. The first oscillators of different rows are staggered with each other, and the second oscillators of different rows are staggered with each other. Each of the first oscillators and each of the second oscillators are arranged in a direction perpendicular to an axis of the body. The fiber opening portion includes a crepe area and a crepe area, and the garnish area is disposed between the oscillating area and the crepe area, the splicing area is connected to the second end, and the fiber opening space comprises a a cloth space and a cloth space, the cloth space is located in the cloth area and is connected between the oscillation space and the cloth space, and the cloth space is located in the cloth area and communicates with the outlet, the device Including a fabric structure and a cloth The structure has a portion of the draping structure located in the oscillating space and another portion located in the crepe space, the draping structure being disposed in the crepe space.

According to a preferred embodiment, the first and second ends of the body are respectively coupled to the two ends of a dyeing machine, and the liquid and the cloth are moved in the dyeing machine, and the oscillator provides 10,000 times per minute to 50,000 times of vibration, the liquid and the cloth are cycled every two minutes, so that the vibration beats the liquid and the cloth 30,000 times per minute, and the liquid is beaten by the vibration wave and the cloth in 2.5 hours. 450,000 times.

According to a preferred embodiment, the liquid is a mixture of water and oil-soluble dye or a cleaning liquid.

The effect of the invention is that in the process of dyeing the cloth, the cloth is oscillated and beaten, and the oil-soluble dye formed by combining the multi-molecules in the liquid is also oscillated into a single molecule oil-soluble dye to make the cloth The fibers are beaten and slackened to be dyed quickly and evenly, and can be softened to the touch. They are completely environmentally friendly without dispersing agents, leveling agents and softening auxiliary agents. Again. In addition, during the cleaning process, the cloth is swayed and smashed, and the emulsion dye which is not attached but remains on the cloth is thoroughly washed.

1‧‧‧dyeding machine

2‧‧‧Liquid

3‧‧‧ cloth

10‧‧‧ Ontology

11‧‧‧ First end

111‧‧‧ Entrance

113‧‧‧First pipe fittings

1131‧‧‧ first end

1133‧‧‧ second end

115‧‧‧First joint

13‧‧‧Defiance Department

131‧‧‧Open space

1311‧‧‧Oscillating space

1313‧‧‧搓布空间

1315‧‧‧揉布空间空间

133‧‧‧Oscillation zone

135‧‧‧搓布区

137‧‧‧揉布区

15‧‧‧second end

151‧‧‧Export

153‧‧‧Second pipe fittings

1531‧‧‧ first end

1535‧‧‧ second end

155‧‧‧second joint

20‧‧‧Oscillator

201‧‧‧Vibration

21, 21'‧‧‧ first oscillator

23, 23'‧‧‧ second oscillator

30‧‧‧搓揉 device

31‧‧‧搓 fabric structure

311‧‧‧ first board

3111‧‧‧First perforation

313‧‧‧Second plate

3131‧‧‧Second perforation

33‧‧‧揉布结构

331‧‧‧ first board

333‧‧‧Second plate

θ 1‧‧‧ acute angle

θ 2‧‧‧ obtuse angle

Figure 1 is a perspective view of a super osmosis fiber opening machine of the present invention.

2 is a perspective view of another perspective view of the super osmosis fiber opening machine of the present invention.

Figure 3 is a top perspective view of the super osmosis fiber opener of the present invention

Figure 4 is a cross-sectional view of the super-permeability opener of the present invention.

Fig. 5 is a schematic view showing the opening, dyeing or washing of the super-permeability opening machine of the present invention.

The embodiments of the present invention will be described in more detail below with reference to the drawings and the <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt;

1 to FIG. 5, FIG. 1 is a perspective view of a super osmosis fiber opening machine of the present invention; FIG. 2 is a perspective view of another perspective view of the super osmosis fiber opening machine of the present invention; FIG. 4 is a cross-sectional view of the super-permeability opening machine of the present invention; FIG. 5 is a schematic view showing the opening, dyeing or cleaning of the super-permeability opening machine of the present invention. The present invention provides a super osmosis fiberizer comprising a body 10, at least one oscillator 20, and a tampering device 30.

The body 10 includes a first end portion 11 , a fiber opening portion 13 and a second end portion 15 . The first end portion 11 of the body 10 defines an inlet 111. The second end portion 15 of the body 10 defines an outlet 151. The first and second ends 11 and 15 of the body 10 are respectively coupled to a dyeing machine 1. The two ends are shown in Figure 5. The fiber opening portion 13 is disposed between the first and second end portions 11 and 15 and defines a fiber opening space 131. The fiber opening space 131 communicates with the inlet port 111 and the outlet port 151. The inlet 111 is used for a liquid 2 and a cloth 3 to enter from the dyeing machine 1. The liquid 2 and the cloth 3 pass through the fiber opening space 131, and then exit from the outlet 151, and return to the dyeing machine 1 . More specifically, the first end portion 11 of the body 10 includes a first tube member 113 and a first joint 115. The first tube member 113 includes a first end 1131 and a second end 1133. The first joint 115 The second end 1133 of the first tube member 113 is connected to the fiber opening portion 13 as shown in FIG. 4 and FIG. 5, and is connected to the outer side wall of the first end 1131 of the first tube member 113 and connected to one end of the dyeing machine 1. Show. The top of the second end 1133 of the first tube member 113 extends downward to the fiber opening portion 13. The entire bottom portion of the first tube member 113 is horizontal. The inlet portion 111 extends through the first tube member 113, as shown in FIG. Show. The second end portion 15 of the body 10 includes a second tube member 153 and a second joint 155. The second tube member 153 includes a first end 1531 and a second end 1535. The second joint 155 is disposed on the second end. The outer side wall of the first end 1531 of the second pipe member 153 is connected to the other end of the dyeing machine 1. The second end 1533 of the second pipe member 153 is connected to the fiber opening portion 13, as shown in FIGS. 4 and 5. Where the second tube The top of the second end 1533 of the piece 153 extends downward to the fiber opening portion 13. The entire bottom portion of the second tube member 153 is stepped, and the outlet 151 extends through the second tube member 153 as shown in FIG. The fiber opening portion 13 includes an oscillating region 133, a diaper region 135 and a diaper region 137. The oscillating region 133 is connected to the second end 1133 of the first tube member 113 of the first end portion 11. The oscillating region 133 is disposed between the oscillating region 133 and the stencil region 137. The splicing region 137 is connected to the second end 1533 of the second tubular member 153 of the second end portion 15. The fiber opening space 131 includes an oscillating space 1311, a crepe space 1313, and a crepe space 1315. The oscillating space 1311 is located in the oscillating region 133 and communicates with the inlet 111. The crepe space 1313 is located in the crepe area 135 and communicates between the oscillating space 1311 and the crepe space 1315. The cloth space 1315 is located in the cloth area 137 and communicates with the outlet 151. The length direction of the fiber opening portion 13 is parallel to an axis of the body 10. The width direction of the fiber opening portion 13 is perpendicular to the axis of the body 10. The top of the cloth region 135 is from the top of the oscillation region 133. Up and toward the second end portion 15 extends to the top of the draping region 137, and the oscillating region 133, the draping region 135, and the bottom of the draping region 137 are located at the same horizontal plane. In other words, the distance between the top and bottom of the oscillating region 133 is smaller than the distance between the top and the bottom of the lands 137. The distance between the top and bottom of the lands 135 is from the oscillating region 133. The direction of the area 137 gradually becomes larger. Referring to FIG. 5, the liquid 2 sequentially passes through the inlet 111 of the first end portion 11, the oscillating space 1311 of the fiber opening space 131, the crepe space 1313, the crepe space 1315, and the exit of the second end portion 15. 151 flows and then returns to the dyeing machine 1. Preferably, the flow rate of the liquid 2 is six hundred meters per minute. The cloth 3 is moved in the flow direction of the liquid 2, so that it is sequentially passed through the inlet 111 of the first end portion 11, the oscillating space 1311 of the fiber opening space 131, and the crepe space 1313 as with the liquid 2. It flows with the cloth space 1315 and the outlet 151 of the second end portion 15, and then returns to the dyeing machine 1. Preferably, the liquid 2 and the cloth 3 are cycled every two minutes. The so-called "cycle every two minutes" means that the liquid 2 and the cloth 3 pass through the body 10, enter the dyeing machine 1, and then return. To the body 10, it is a cycle, and the overall time is two minutes. its The dyeing machine 1 is a conventional structure, so the detailed structure of the dyeing machine 1 will not be described here, but only shown in Fig. 5, which will be described first.

The at least one oscillator 20 is disposed in the fiber opening portion 13 and generates a vibration wave 201. The vibration wave 201 is transmitted to the liquid 2 and transmitted to the cloth 3 through the liquid 2, so that the liquid 2 and the cloth 3 are vibrated. Wave 201 beat. In this embodiment, the super-osmotic fiber opening machine further includes a plurality of oscillators 20, wherein a part of the oscillator is disposed outside the top of the oscillating region 133 and is defined as the first oscillator 21, 21', and the other portion The oscillator is disposed outside the bottom of the oscillating region 133 and is defined as a second oscillator 23, 23', and the first oscillators 21, 21' and the second oscillators 23, 23' are staggered with each other. Preferably, the first oscillators 21, 21' are arranged in a plurality of rows, the first oscillators 21, 21' of the same row are spaced apart from each other, and the second oscillators 23, 23' are arranged in a plurality of rows, the same The second oscillators 23, 23' of the row are spaced apart from each other, wherein the plurality of rows of first oscillators 21, 21' respectively correspond to the plurality of rows of second oscillators 23, 23', each row of first oscillators 21, 21' and Corresponding one of the rows of second oscillators 23, 23' is staggered with each other, as shown in FIG. Preferably, the different rows of first oscillators 21, 21' are staggered with each other. As shown in FIGS. 1 and 3, the different rows of second oscillators 23, 23' are staggered with each other, as shown in FIGS. 2 and 3. Show. Each of the first oscillators 21, 21' and each of the second oscillators 23, 23' are arranged along the width direction of the fiber opening portion 13 (i.e., the direction perpendicular to the axis of the body 10). . The oscillators 20, including the first and second oscillators 21, 21', 23, 23', provide oscillating waves 201 of 10,000 to 50,000 times per minute, the liquid 2 and the cloth 3 every two minutes. The cycle was repeated once, and the vibration wave 201 struck the liquid 2 and the cloth 33,000 times per minute, and beat the liquid 2 and the cloth 350,000 times in 2.5 hours. The oscillators 20, including the first and second oscillators 21, 21', 23, 23', may be an electric ceramic oscillator or other types of oscillators, and are not particularly limited. The electric ceramic oscillator is characterized in that it oscillates about 10,000 to 50,000 times per minute.

The cymbal device 30 is disposed in the fiber opening space 131 and smashes the cloth 3. In the present embodiment, the cymbal device 30 includes a crepe structure 31 and a crepe structure 33. A portion of the draping structure 31 is located in the oscillating space 1311, and another portion is located in the crepe space 1313. The crepe structure 33 is provided in the crepe space 1315. More specifically, the crepe structure 31 protrudes from the inner side of the bottom of the oscillating region 133 and the inner side of the bottom of the crepe region 135, and the crepe structure 33 protrudes from the inner side of the top of the crepe region 137. Preferably, the fabric structure 31 has a dome shape and includes a first board body 311 and a second board body 313. The first board body 311 has a first end and a second end, and the second board body The 313 has a first end and a second end. The first end of the first plate 311 abuts against the inner side of the bottom of the oscillating area 133, and the second end of the first plate 311 is connected to the second plate 313. The first end of the second plate 313 abuts against the inner side of the bottom of the crepe area 135. The junction of the first and second plates 311 and 313 of the fabric structure 31 is an acute angle θ 1 (that is, less than ninety degrees). Preferably, the angle of the acute angle θ 1 is 70 degrees. Wherein the connection between the first and second plates 311 and 313 of the fabric structure 31 is at the boundary between the oscillation space 1311 and the cloth space 1313, so the first plate body 311 of the cloth structure 31 is located. The oscillating space 1311, the second plate 313 of the draping structure 31 is located in the crepe space 1313. The first plate body 311 of the cloth structure 31 forms a plurality of first through holes 3111, and the second plate body 313 of the cloth structure 31 forms a plurality of second holes 3131. In other embodiments, the crepe structure 31 may also be completely within the crepe space 1313 or a portion thereof may be located in the crepe space 1315. The fabric structure 33 has a dome shape and includes a first plate body 331 and a second plate body 333. The first plate body 331 has a first end and a second end, and the second plate body 333 has a first The first end of the first plate body 331 and the second end of the second plate body 333 abut against the top inner side of the draping area 137, and the second end of the first plate body 331 The end is connected to the first end of the second plate body 333. The junction of the first and second plates 331, 333 of the draping structure 33 is an obtuse angle θ 2 (that is, greater than ninety degrees). Preferably, the angle of the obtuse angle θ 2 is 100 degrees.

Referring to FIG. 5, when the super osmosis fiber opener of the present invention is combined with the dyeing machine 1 for dyeing, the liquid 2 is a mixture of water and oil-soluble dye. The oscillators 20 (including the first and second oscillators 21, 21', 23, 23') are activated, and the oscillators 20 are transmitted from the top and bottom of the oscillation region 133 of the body 10 (including the first and second The oscillating wave 201 of 10,000 to 50,000 times per minute provided by the oscillator 21, 21', 23, 23') taps the liquid 2 located in the oscillating space 1311 and is transmitted through the liquid 2 to the oscillating space 1311. Inside the cloth 3. Thereby, the oil-soluble dye in the liquid 2 is oscillated into a small molecule combination from the original multi-molecule combination, and is easily emulsified and dissolved in water to obtain an emulsion dye. Next, the emulsifying dye enters the crepe space 1315, and a portion of the emulsion dye passes through the first and second perforations 3111, 3131. The cloth 3 located in the oscillating space 1311 rubs into the connection between the first and second plates 311 and 313 of the draping structure 31 during the process of entering the crepe space 1313 along with the flow of the emulsified dye. And then, as the flow of the emulsion dye enters the crepe space 1315, it is rubbed to the joint of the first and second plates 331, 333 of the crepe structure 33. Finally, the emulsion dye and the cloth 3 are cycled once every two minutes to cause the vibration wave 201 to beat the emulsion dye and the cloth 33,000 times per minute, and beat the emulsion in 2.5 hours. Dye and the cloth for 450,000 times. The cloth 3 is beaten and smashed in an environment where the temperature rises. Thereby, the fibers of the cloth 3 can be beaten and smashed to completely relax the bottom to achieve the effect of "opening", and the oil-soluble dye combined with the small molecules in the emulsion dye is further oscillated into a single The oil-soluble dye of the molecule can be completely emulsified and dissolved in water, the particles are very fine and uniform, and the bubbles in the emulsion dye are also completely refined by the vibration wave 201 without affecting the emulsification of the oil-soluble dye in the water. The effect is that the fiber of the cloth 3 can be dyed quickly and uniformly by the emulsion dyeing agent, and the problems of color spots, color flowers and uneven dyeing are not caused, the dyeing heat preservation time is shortened, work efficiency is improved, and no dispersion is required at all. Agent and leveling agent, saving the cost of dyeing and finishing plant, reducing the discharge of chemical oxygen demand of sewage, reducing environmental pollution, environmental protection, and improving the competitiveness of dyeing and finishing plants.

Furthermore, the first oscillators 21, 21' are disposed outside the top of the oscillating region 133, and the second oscillators 23, 23' are disposed outside the bottom of the oscillating region 133. The first oscillators 21 are provided. 21' and the second oscillators 23, 23' are staggered with each other. Thereby, the vibration waves 201 of the first and second oscillators 21, 21', 23, and 23' can oscillate the liquid 2 and the cloth 3 passing through the oscillation space 1311 with "no dead angle". In particular, "the first oscillators 21, 21' of the same row are spaced apart from each other, and the second oscillators 23, 23' of the same row are spaced apart from each other, and the plurality of first oscillators 21, 21' respectively correspond to the second oscillation of the plurality of rows 23, 23', each row of the first oscillator 21, 21' and the corresponding one of the second oscillators 23, 23' are staggered with each other, the technical characteristics of the non-dead angle oscillation flapping range is large, the effect More obvious. In addition, the technical characteristics of "the first oscillators 21, 21' of different rows are staggered with each other, and the second oscillators 23, 23' of different rows are staggered with each other", the range of the oscillations without the dead angle is the largest, and the effect is the most Significant.

Further, the vibration wave 201 of the first and second oscillators 21, 21', 23, and 23' can oscillate and oscillate the liquid 2 and the cloth 3" passing through the oscillation space 1311 in a "no dead angle" oscillation. The body 10 as a whole exhibits a "long" technical feature, so that the liquid 2 can smoothly pass through the fiber opening space 131 without generating a vortex-like flow pattern. Thereby, all the fibers such as the warp yarn and the weft yarn of the cloth 3 can pass through the fiber opening space 131 in a flat and unfolded state, thereby enhancing the effect of the tapping and licking of the cloth 3, and making the fibers of the cloth 3 more slack. The fibers of the cloth 3 achieve the effect of being dyed more quickly and more uniformly by the emulsion dye.

Moreover, the first and second through holes 3111 and 3131 of the first and second plates 311 and 313 of the draping structure 31 can improve the smoothness of the flow of the liquid 2, so that the cloth 3 can pass through the opening more smoothly. The space 131 further enhances the effect of the cloth 3 being beaten and twisted, and further improves the degree of slack of the fibers of the cloth 3, so that the fibers of the cloth 3 are more quickly and uniformly dyed by the emulsion dye.

It is worth mentioning that after the cloth 3 is beaten and smashed, it can reach the soft state of the hand, and it is completely unnecessary to add a soft auxiliary agent, reduce the discharge of chemical oxygen demand of the sewage, and reduce environmental pollution.

Referring to FIG. 5, when the super osmosis fiberizer of the present invention is applied to cleaning, the liquid is a cleaning liquid, preferably, the cleaning liquid is clean water, and in the manner described in paragraph [0020] of the specification. The present invention is operated to clean an emulsion dye which is not attached but remains on the finished dyed cloth 3. Thereby, after the cloth 3 is beaten and twisted, since the fibers of the cloth 3 can be completely loosened and completely opened, the water can completely wash the emulsion dye which is not adhered but remains on the cloth 3.

The above is only a preferred embodiment for explaining the present invention, and is not intended to limit the present invention in any way, and any modifications or alterations to the present invention made in the spirit of the same invention. All should still be included in the scope of the intention of the present invention.

10‧‧‧ Ontology

11‧‧‧ First end

111‧‧‧ Entrance

113‧‧‧First pipe fittings

115‧‧‧First joint

13‧‧‧Defiance Department

133‧‧‧Oscillation zone

135‧‧‧搓布区

137‧‧‧揉布区

15‧‧‧second end

153‧‧‧Second pipe fittings

155‧‧‧second joint

21, 21'‧‧‧ first oscillator

Claims (10)

A super-permeability fiber-opening machine comprising: a body comprising a first end portion, a fiber opening portion and a second end portion, the first end portion forming an inlet, the second end portion forming an outlet, the opening The fiber portion is disposed between the first and second end portions and encloses an open fiber space, wherein the fiber opening space is connected between the inlet and the outlet, wherein the inlet is used for entering a liquid and a cloth. The liquid and the cloth pass through the fiber opening space and then exit from the outlet; at least one oscillator is disposed at the fiber opening portion and generates a vibration wave, the vibration wave is transmitted to the liquid and transmitted to the cloth through the liquid, so that The liquid and the cloth are beaten by the vibration wave; and a device is disposed in the fiber opening space and the cloth is rubbed. The ultra-permeability fiber-opening machine of claim 1, wherein the fiber opening portion includes an oscillating region, the oscillating region is connected to the first end portion, and the fiber opening space comprises an oscillating space, wherein the oscillating space is located The oscillating region is in communication with the inlet, and the oscillator is disposed in the oscillating region. The super-osmosis fiber-opening machine according to claim 2, further comprising a plurality of oscillators, wherein a part of the oscillator is disposed outside the top of the oscillating region and is defined as a first oscillator, and the other portion is oscillated The device is disposed outside the bottom of the oscillating region and is defined as a second oscillator, and the first oscillator and the second oscillator are staggered with each other. The super-osmosis fiber-opening machine according to claim 3, wherein the first oscillators are arranged in a plurality of rows, the first oscillators of the same row are arranged at intervals, and the second oscillators are arranged in a plurality of rows. The second row of the same oscillator in each other Arranged in intervals, wherein the plurality of first oscillators respectively correspond to the plurality of second oscillators, and each of the first oscillators and the corresponding one of the second oscillators are staggered with each other. The super-osmosis fiber-opening machine of claim 4, wherein the first oscillators of different rows are staggered with each other, and the second oscillators of different rows are staggered with each other. The super-osmosis fiber-opening machine of claim 4, wherein each row of the first oscillator and each row of the second oscillator are arranged along a direction perpendicular to an axis of the body. The ultra-permeability fiber-opening machine of claim 2, wherein the fiber opening portion comprises a crepe area and a crepe area, and the garnish area is disposed between the oscillating area and the crepe area, The fabric opening area is connected to the second end portion, and the fiber opening space comprises a crepe space and a crepe space, wherein the crepe space is located in the draping area and is connected between the oscillating space and the crepe space, the 揉The cloth space is located in the cloth area and communicates with the outlet, the device comprises a crepe structure and a crepe structure, a part of the woven structure is located in the oscillating space, and the other part is located in the crepe space. The crepe structure is disposed in the crepe space. The super osmosis fiber-opening machine according to any one of claims 1 to 7, wherein the first and second ends of the body are respectively coupled to the two ends of a dyeing machine, and the liquid and the cloth are moved by In the dyeing machine, the oscillator provides tens of thousands to 50,000 vibrations per minute, and the liquid and the cloth are cycled every two minutes, so that the vibration wave beats the liquid and the cloth 30,000 times per minute. The liquid was beaten by the vibration wave and the cloth was forty-five thousand times in 2.5 hours. The super osmosis fiber-opening machine according to any one of claims 1 to 7, wherein the liquid is a mixture of water and an oil-soluble dye or a cleaning liquid. The super osmosis fiber opening machine of claim 8, wherein the liquid is a mixture of water and an oil-soluble dye or a cleaning liquid.