CN107344390B - Sinusoidal cloth machine of colour mixture surface fabric - Google Patents

Abstract

The invention discloses a color-mixing fabric sine distributor, which comprises a rack and at least one group of machine components arranged on the rack, wherein the machine components comprise a receiving hopper component, a transition feeding component and a material guiding and distributing component which are connected in an up-down sequential material conveying manner; the transition feeding assembly is provided with a transition flat belt which is horizontally conveyed, and a discharge hole of the receiving hopper assembly is positioned right above the transition flat belt; the material guiding and distributing assembly comprises a material guiding hopper and an eccentric mechanism, the material guiding hopper comprises an upper hopper and a lower hopper, the upper hopper is fixedly arranged right below the corresponding discharging end of the transition flat belt, the lower hopper is movably hung below the upper hopper, and the eccentric mechanism is connected with the lower hopper to drive the lower hopper to swing. The color mixing brick has a simple structure and flexible and changeable forms, is specially used for manufacturing color mixing bricks with the fabrics in sine curve color pattern, and greatly simplifies and enriches the production and manufacturing of the fabrics of the color mixing bricks.

Description

Sinusoidal cloth machine of colour mixture surface fabric

Technical Field

The invention relates to the field of color mixing brick preparation, in particular to a sine cloth machine for color mixing fabrics.

Background

Along with the gradual improvement of living standard, people pay more attention to living environments, and higher requirements are also put forward on town construction and road environment beautification. The road is beautified and is not separated from the assistance of the colored floor tiles, the traditional colored floor tiles are single-colored, then the effect of the colored pattern floor tile road is achieved by regularly mixing and paving different single-colored floor tiles, and the pattern patterns spliced by the method are too rough and have limited patterns. The color pattern of individual color floor tiles has been improved to break through this bottleneck.

At present, color split floor tiles or colorful tiles mixed with various colors exist. The color pattern-dividing floor tile is a regular color tile with regular patterns formed by splicing more than two colors, the conventional manufacture of the regular color tile is necessary to prepare a mold with corresponding pattern grooves, and then the color-dividing floor tile is extremely complicated in manufacturing steps by sequentially filling the colors, so that each pattern needs to develop a mold and a process corresponding to each other, and the method is quite unfavorable for large-scale and high-efficiency production of enterprises. The colorful brick is an irregular color brick with gradual change colorful effect formed by splicing more than two colors, the mold is not required to be designed due to the irregular characteristic, and gradual change colorful is realized by randomly spreading different colors in the manufacturing process, so that the manufactured colorful brick has more decoration than the traditional monochromatic colorful brick, and the irregular characteristic of the colorful brick also determines that the colorful brick cannot meet the higher requirements of people on the colorful floor brick.

From the above, at present, there is a certain retardation for the production and preparation of the color-mixed floor tile, and the technology for preparing various regular pattern color tiles with simple manufacturing process and simple equipment is not researched and developed. In view of this, the present inventors have conducted intensive studies on the above problems and developed a fully automatic color mixing brick face fabric stirring station, thereby adaptively proposing a color mixing face fabric sine distributor.

Disclosure of Invention

The invention aims to provide a sine cloth machine for color-mixed fabrics, which has a simple structure and flexible and changeable forms, is specially used for manufacturing color-mixed bricks with the fabrics in sine curve color patterns, and greatly simplifies and enriches the production and manufacturing of the color-mixed brick fabrics.

In order to achieve the above object, the solution of the present invention is:

the sine distributor for the color-mixed fabric comprises a rack and at least one group of machine components arranged on the rack, wherein the machine components comprise a receiving hopper component, a transition feeding component and a material guiding and distributing component which are connected in an up-down sequential material conveying manner; the transition feeding assembly is provided with a transition flat belt which is horizontally conveyed, and a discharge hole of the receiving hopper assembly is positioned right above the transition flat belt; the material guiding and distributing assembly comprises a material guiding hopper and an eccentric mechanism, the material guiding hopper comprises an upper hopper and a lower hopper, the upper hopper is fixedly arranged right below the corresponding discharging end of the transition flat belt, the lower hopper is movably hung below the upper hopper, and the eccentric mechanism is connected with the lower hopper to drive the lower hopper to swing.

The machine assembly is provided with at least two groups of machine assemblies which are horizontally arranged side by side and the side by side direction is the output conveying direction of the color mixing fabric.

The upper bucket comprises an upper half part and a lower half part, the lower half part is of a square cylindrical structure, and the upper half part is of a trapezoid cylindrical structure with a wide upper part and a narrow lower part; the lower hopper is a round hopper structure with a wide upper part and a narrow lower part; the discharge gate of last bucket bottom is less than the pan feeding mouth of lower bucket upper end to in the pan feeding mouth of lower bucket is stretched down to this bottom of going up the bucket under the natural state.

The outer side wall of the upper bucket is provided with two hanging shafts, and the lower bucket is movably hung on the two hanging shafts through a bearing piece.

The eccentric mechanism comprises a swing rod driving motor, an eccentric wheel and a swing rod; the eccentric wheel is arranged on the output shaft of the swing rod driving motor, one end of the swing rod is connected with the eccentric wheel, and the other end is connected with the lower bucket.

The receiving hopper assembly comprises a receiving hopper and an adjusting door mechanism; the receiving hopper is arranged right above the transition flat belt and takes the conveying direction of the transition flat belt as a reference direction; the upper end and the lower end of the receiving hopper are respectively provided with a feeding hole and a discharging hole, one side of the discharging hole, which corresponds to the direction facing the reference direction, is provided with an adjusting notch, an adjusting door mechanism is arranged on the side wall of the discharging hole, which corresponds to the direction facing the reference direction, and the adjusting door mechanism is provided with an adjusting plate which is covered on the adjusting notch and can be adjusted in an up-down moving way.

The adjusting notch is provided with a notch bottom which is arranged upwards, the notch bottom is of an arc-shaped surface structure with an upward arc-shaped bulge in the middle, and the lower end part of the adjusting plate is of an arc-shaped part which is matched with the arc-shaped surface structure of the notch bottom.

The adjusting door mechanism comprises an adjusting bolt, a fixed seat and a connecting seat; the fixing base is fixedly arranged on the side wall of the receiving hopper, the adjusting plate is arranged on the connecting base, and the connecting base is movably connected with the fixing base through an adjusting bolt.

The adjusting door mechanism further comprises two groups of limiting guide blocks, the two groups of limiting guide blocks are fixedly arranged on the side wall of the receiving hopper and correspondingly positioned on the left side and the right side of the adjusting plate, and the left side and the right side of the adjusting plate are movably embedded in guide grooves formed by the two groups of limiting guide blocks and the side wall of the receiving hopper respectively.

The transition feeding assembly comprises a mounting frame, a transmission shaft, a transition flat belt and a bevel gear variable frequency speed reducer; the transmission shaft is arranged on the mounting frame, the transition flat belt is transmitted and wound on the transmission shaft, and the transmission shaft is in transmission connection with the helical gear variable frequency speed reducer.

After the scheme is adopted, the color-mixed fabric sine distributor has the beneficial effects that compared with the prior art: the sinusoidal material distributor is arranged above the mixed color material output belt conveyor of the stirring station in the application of the sinusoidal material distributor for realizing the sinusoidal material distribution function of the mixed color material. In the work, according to the types of different colors of pigment needed by the color-mixed fabric, a corresponding group of machine components are applied, namely, different colors of pigment correspond to a group of machine components. After the pigment is received and stored by the receiving hopper component, the pigment is sent to the flat belt of the transition feeding component through the discharge hole of the receiving hopper component, the pigment is timely and properly sent to the guide hopper by the flat belt, and particularly, the pigment is sequentially sent to the lower hopper through the upper hopper, in the process, the lower hopper swings according to the set amplitude frequency under the drive of the eccentric mechanism, and the swinging direction is perpendicular to the output direction of the color mixing fabric output belt conveyor, so that the sinusoidal material distribution effect is realized. Different colors of pigment can be regularly and non-crossly overlapped on a mixed color fabric output belt conveyor or regularly overlapped according to a set pattern under different swinging settings of different machine components, so that various mixed color bricks with the fabrics in a sine curve color pattern can be simply manufactured.

Drawings

FIG. 1 is a front view of a sinusoidal cloth machine for color mixing fabrics of the present invention;

FIG. 2 is a side view of the sinusoidal cloth machine for color mixing fabrics of the present invention;

FIG. 3 is a front view of the machine assembly of the present invention;

FIG. 4 is a top view of the machine assembly of the present invention;

FIG. 5 is a front view of the guide hopper of the present invention;

FIG. 6 is a schematic view of an eccentric mechanism of the present invention;

FIG. 7 is a schematic view of an eccentric coupling portion of the eccentric mechanism of the present invention;

FIG. 8 is another schematic view of the eccentric connection of the eccentric mechanism of the present invention;

FIG. 9 is a front view of the transition feed assembly of the present invention;

FIG. 10 is a top view of the transition feed assembly of the present invention;

FIG. 11 is a front view of the receiving hopper assembly of the present invention;

fig. 12 is a side view of the receiving hopper assembly of the present invention.

Description of the reference numerals

Color mixing fabric spreader 500:

excellent 50, a receiving hopper assembly 51, a transition feeding assembly 52, a material guiding and distributing assembly 53;

a receiving hopper 511, a feed inlet 5111, a discharge outlet 5112, an adjusting notch 5113, a baffle 5114,

the door adjusting mechanism 512, the adjusting plate 5121, the adjusting bolt 5122, the fixing base 5123,

a connection seat 5124 for limiting the guide block 5125;

the device comprises a mounting frame 521, a transmission shaft 522, a transition flat belt 523 and a helical gear variable frequency reducer 524;

an upper bucket 531, a lower bucket 532, and an eccentric mechanism 533;

an upper half 5311, a lower half 5312, a hanging shaft 5313, a connecting piece 5314,

the swing link connecting seat 5321, the swing link driving motor 5331, the eccentric wheel 5332 and the swing link 5333.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings and detailed description.

The scheme relates to a color-mixed fabric sine distributor 500, as shown in fig. 1-4, comprising a frame 50 and at least one group of machine components arranged on the frame 50. According to the types of different colors needed by the color-mixed fabric, a corresponding group of machine components are used, namely, each color corresponds to one group of machine components. Preferably, the machine assembly is provided with at least two sets of machine assemblies, and the at least two sets of machine assemblies are horizontally arranged side by side and the side by side direction is the output conveying direction of the color mixing fabric, namely the output conveying direction of the color mixing fabric bending belt conveyor 600 in fig. 2. In the specific example given, referring to fig. 1, the number of units is provided with three groups side by side.

The machine assembly comprises a receiving hopper assembly 51, a transition feeding assembly 52 and a material guiding and distributing assembly 53 which are connected in a material conveying mode in sequence. The transition feeding assembly 52 has a horizontal conveying flat belt 521, and the discharge port of the receiving hopper assembly 51 is located at a position directly above the transition flat belt 523, and the conveying direction of the transition flat belt 523 is terminated at its discharge end. The material guiding and distributing assembly 53 comprises a material guiding hopper and an eccentric mechanism 533, wherein the material guiding hopper comprises an upper hopper 531 and a lower hopper 532; the upper bucket 531 is fixedly arranged right below the corresponding discharging end of the transition flat belt 523, and the lower bucket 532 is movably hung below the upper bucket 531; the eccentric mechanism 533 and the lower bucket 532 are connected with each other, the lower bucket 532 is driven by the eccentric mechanism 533 to perform swinging motion, and the reciprocating swinging direction is perpendicular to the output conveying direction of the color mixing fabric bending belt conveyor 600.

The sinusoidal material distributor of the color-mixed material is arranged above the output belt conveyor 600 of the color-mixed material in the stirring station for realizing the sinusoidal material distribution function of the color-mixed material. In the work, according to the types of different colors of pigments needed by the color-mixed fabric, the machine components with corresponding groups are used. After each pigment is received and stored by the corresponding receiving hopper assembly 51, the pigment is sent to the transition flat belt 523 of the transition feeding assembly 52 through the discharge hole of the receiving hopper assembly, the transition flat belt 523 timely and properly sends the pigment into the guide hopper, and particularly, the pigment is sequentially sent to the lower hopper 532 through the upper hopper 531, in the process, the lower hopper 532 is driven by the eccentric mechanism 533 to controllably swing according to the set amplitude and frequency, and the swing direction is perpendicular to the output direction of the color mixing fabric output belt conveyor, so that the sinusoidal distribution effect is realized. Different corresponding required swinging effects can be set by controlling each color pigment through a corresponding machine assembly, so that the mixed color fabric bricks with various patterns of the sinusoidal color pattern can be simply manufactured by regularly and non-crossly overlapping cloth on a mixed color fabric output belt conveyor or regularly overlapping cloth according to the set pattern.

The upper bucket 531 and the lower bucket 532 are combined to form the upper bucket 531, the upper bucket 531 is fixedly arranged, the lower bucket 532 is driven by the eccentric mechanism 533 to swing while the upper bucket 531 is used for receiving the pigment, the pigment falling out of the lower bucket 532 is discharged in a single pendulum mode, the belt for receiving the pigment is matched with the belt to perform linear motion perpendicular to the swinging direction of the belt, sinusoidal cloth can be obtained, and the lower bucket 532 is applied to the manufacture of mixed color fabrics to achieve the tile cloth effect of the sinusoidal cloth. By controlling the amplitude and frequency of the simple pendulum of the lower bucket 532, the density of the cloth sinusoid can be controlled.

As shown in fig. 5, the guide hopper is designed into an upper hopper 531 and a lower hopper 532, the matching of the two parts is very critical, in order to improve the matching degree of the receiving materials, the discharge hole at the bottom end of the upper hopper 531 is designed to be smaller than the feed inlet at the upper end of the lower hopper 532, and the bottom end of the upper hopper 531 extends downwards into the feed inlet of the lower hopper 532 in a natural state. Even when the swing width of the lower bucket 532 is large, the coloring material in the upper bucket 531 can be smoothly fed into the lower bucket 532 and timely participate in the cloth, and the uniformity of the sinusoidal cloth can be enhanced.

Further, the upper bucket 531 is designed to have an upper half 5311 and a lower half 5312, and the lower half 5312 has a square tubular structure, and the upper half 5312 has a trapezoidal tubular structure with a wide upper part and a narrow lower part. The lower bucket 532 has a circular bucket structure with a wide upper part and a narrow lower part. This facilitates the upper hopper 531 to receive the fed color material, and then to uniformly, smoothly and reliably guide the color material into the lower hopper 532.

Preferably, the lower bucket 532 is movably hung on the upper bucket 431. Specifically, the outer wall of the upper bucket 531 is provided with two hanging shafts 5311, and the lower bucket 532 is movably hung on the two hanging shafts 5311 through a bearing member. In addition, in order to facilitate the fixing and mounting effect of the upper bucket 531, the bucket edge of the upper bucket 531 is provided with a connecting piece 5314 in an outward turned manner, and in a specific embodiment, the connecting piece 5314 is provided with three pieces surrounded by three sides. The upper bucket 531 and the related bracket are locked and fixed by the connecting sheet 5314.

Preferably, as shown in fig. 6-8, the eccentric mechanism 533 includes a swing link driving motor 5331, an eccentric 5332, and a swing link 5333. The swing rod driving motor 5331 is fixedly arranged on the motor mounting seat 5334, the eccentric wheel 5332 is arranged on the output shaft of the swing rod driving motor 5331, one end of the swing rod 5333 is connected with the eccentric wheel 5332, and the other end is connected with the lower bucket 532. Specifically, a swing link connection base 5321 is disposed on a side wall of the lower bucket 532, and the other end of the swing link 5333 is connected to the swing link connection base 5321 through a matched connection plate. The swing rod driving motor 5331 drives the eccentric wheel 5332 to rotate, then drives the swing rod 5333 to swing back and forth, and finally drives the lower bucket 532 to swing back and forth.

Preferably, the transition feeding assembly 52, as shown in fig. 9-10, includes a mounting frame 521, a transmission shaft 522, a transition flat belt 523, and a helical gear variable frequency reducer 524. The transmission shaft 522 is rotatably installed on the installation frame 521, the transition flat belt 523 is transmitted and wound on the transmission shaft 522, and the transmission shaft 522 and the helical gear variable frequency reducer 524 are in transmission connection with each other through a gear mechanism. In operation, the helical gear variable frequency speed reducer 524 drives the transmission shaft 522 to controllably rotate in a variable frequency manner, so that the transition flat belt 523 can be driven to controllably output pigment in a variable frequency manner according to feeding requirements.

The receiving hopper assembly 51 is shown in fig. 11-12 and includes a receiving hopper 511 and an adjustment gate mechanism 512. The receiving hopper 511 is provided directly above the transition flat belt and is oriented with respect to the conveying direction of the transition flat belt. The upper and lower ends of the receiving hopper 511 are respectively provided with a feeding hole 5111 and a discharging hole 5112, the discharging hole 5112 and the transition flat belt are arranged in an up-down adjacent mode, and a discharging gap is reserved between the discharging hole 5112 and the transition flat belt. An adjusting notch 5113 is formed on one side of the discharge port 5112, which corresponds to the reference direction (left side in fig. 12). An adjusting gate mechanism 512 is installed on a sidewall of the discharge port 5112 facing to one side correspondingly to the reference, the adjusting gate mechanism 512 has an adjusting plate 5121, and the adjusting plate 5121 is covered on the adjusting notch 5113 and is provided with an adjustable up-and-down movement.

The adjusting notch 5113 is of a side opening structure facing the reference to one side, so that the specific position is designed to realize the purpose of discharging adjustable through the cooperation of the receiving hopper and the transition flat belt. The opening of the notch 5113 is controlled and regulated by the regulating plate 5121 of the regulating gate mechanism 512, so that the effective control of the quantity and speed of the discharge from the receiving hopper to the transition flat belt is realized, the effect of preventing the blockage of the discharge port is also brought, and the sequential transition buffering and conveying of the pigment conveying are greatly facilitated.

Preferably, the adjusting notch 5113 has a notch bottom disposed upward, the notch bottom has an arc surface structure with an arc-shaped protrusion upward in the middle, and the lower end of the corresponding adjusting plate 5121 has an arc portion adapted to the arc surface structure of the notch bottom. This arc structural design makes in the adjustment process more smooth and easy effective, and the ejection of compact is smooth controllable more.

Preferably, in order to facilitate the effective cooperation between the adjusting plate 5121 and the adjusting notch 5113, the receiving hopper 511 is designed as a square hopper structure formed by splicing four side plates, and the adjusting plate 5121 is in a flat plate structure attached to a corresponding side plate.

The preferred embodiment of the door adjusting mechanism 512 includes an adjusting bolt 5122, a fixing base 5123 and a connecting base 5124. The fixing seat 5123 is fixedly installed on the side wall of the receiving hopper 511, the adjusting plate 5121 is installed on the connecting seat 5124, the connecting seat 5124 is movably connected with the fixing seat 5123 through an adjusting bolt 5122, specifically, one end of the adjusting bolt 5122 is fixedly locked on the connecting seat 5124, and the other end of the adjusting bolt 5122 is adjustably locked with the fixing seat 5123 through a threaded nut. When the adjustment plate 5121 is to be adjusted up and down, the adjustment bolt 5122 is simply moved up and down by unscrewing the nut.

Preferably, in order to facilitate the stability of the up-and-down adjustment of the adjustment plate 5121, the adjustment door mechanism 512 further includes two sets of limit guide blocks 5125 for performing a limit guiding function on the adjustment plate 5121. Specifically, two sets of limiting guide blocks 5125 are fixedly installed on the side wall of the receiving hopper 511 and are correspondingly located at the left and right sides of the adjusting plate 5121, the two sets of limiting guide blocks 5125 and the side wall of the receiving hopper 511 form guide grooves, and the left and right sides of the adjusting plate 5121 are movably embedded in the guide grooves respectively.

Preferably, in order to facilitate the effective cooperation between the discharge port 5112 and the transition flat belt and ensure the effective conveyance of the colorant, two symmetrically arranged baffles 5114 extending along the reference direction are disposed at the discharge port 5112 of the receiving hopper 511, and the lower end of the two baffles 5114 is lower than the discharge port 5112, where the lower portion forms a guard structure between the discharge port 5112 and the transition flat belt. The two baffles 5114 are provided with a protection extension part which extends towards one side of the reference direction, and the protection extension part plays a role in continuously protecting the output section of the transition flat belt.

The foregoing description is only of the preferred embodiments of the present invention, and all equivalent changes and modifications that come within the scope of the following claims are intended to be embraced therein.

Claims (9)

1. A sinusoidal cloth machine of colour mixture surface fabric, its characterized in that: the device comprises a frame and at least one group of machine components arranged on the frame, wherein the machine components comprise a receiving hopper component, a transition feeding component and a material guiding and distributing component which are connected in sequence in an up-down conveying manner; the transition feeding assembly is provided with a transition flat belt which is horizontally conveyed, and a discharge hole of the receiving hopper assembly is positioned right above the transition flat belt; the material guiding and distributing assembly comprises a material guiding hopper and an eccentric mechanism, the material guiding hopper comprises an upper hopper and a lower hopper, the upper hopper is fixedly arranged right below the corresponding discharging end of the transition flat belt, the lower hopper is movably hung below the upper hopper, and the eccentric mechanism is connected with the lower hopper to drive the lower hopper to swing; the machine assembly is provided with at least two groups of machine assemblies which are horizontally arranged side by side, and the side by side direction is the output conveying direction of the color mixing fabric; in the work, according to the types of different colors of pigments needed by the color-mixed fabric, the machine components with corresponding groups are used; each pigment is fed and stored by the corresponding receiving hopper assembly and then is fed onto a transition flat belt of the transition feeding assembly through a discharge hole of the transition flat belt, the pigment is fed into the guide hopper in proper time and in proper quantity by the transition flat belt, and is particularly fed into the lower hopper sequentially by the upper hopper, in the process, the lower hopper is driven by the eccentric mechanism to controllably swing according to the set amplitude and frequency, and the swing direction is perpendicular to the output direction of the color mixing fabric output belt conveyor, so that the sinusoidal material distribution effect is realized; different swing effects required by each color pigment can be set through corresponding machine assembly control, so that the regular non-crossed overlapped cloth or the regular overlapped cloth according to the set flower type pattern on the mixed color fabric output belt conveyor can be realized.

2. The sinusoidal distributor for color mixing fabrics as defined in claim 1, wherein: the upper bucket comprises an upper half part and a lower half part, the lower half part is of a square cylindrical structure, and the upper half part is of a trapezoid cylindrical structure with a wide upper part and a narrow lower part; the lower hopper is a round hopper structure with a wide upper part and a narrow lower part; the discharge gate of last bucket bottom is less than the pan feeding mouth of lower bucket upper end to in the pan feeding mouth of lower bucket is stretched down to this bottom of going up the bucket under the natural state.

3. A mixed color fabric sine distributor as claimed in claim 1 or 2, wherein: the outer side wall of the upper bucket is provided with two hanging shafts, and the lower bucket is movably hung on the two hanging shafts through a bearing piece.

4. The sinusoidal distributor for color mixing fabrics as defined in claim 1, wherein: the eccentric mechanism comprises a swing rod driving motor, an eccentric wheel and a swing rod; the eccentric wheel is arranged on the output shaft of the swing rod driving motor, one end of the swing rod is connected with the eccentric wheel, and the other end is connected with the lower bucket.

5. The sinusoidal distributor for color mixing fabrics as defined in claim 1, wherein: the receiving hopper assembly comprises a receiving hopper and an adjusting door mechanism; the receiving hopper is arranged right above the transition flat belt and takes the conveying direction of the transition flat belt as a reference direction; the upper end and the lower end of the receiving hopper are respectively provided with a feeding hole and a discharging hole, one side of the discharging hole, which corresponds to the direction facing the reference direction, is provided with an adjusting notch, an adjusting door mechanism is arranged on the side wall of the discharging hole, which corresponds to the direction facing the reference direction, and the adjusting door mechanism is provided with an adjusting plate which is covered on the adjusting notch and can be adjusted in an up-down moving way.

6. The sinusoidal distributor for mixed color fabrics according to claim 5, wherein: the adjusting notch is provided with a notch bottom which is arranged upwards, the notch bottom is of an arc-shaped surface structure with an upward arc-shaped bulge in the middle, and the lower end part of the adjusting plate is of an arc-shaped part which is matched with the arc-shaped surface structure of the notch bottom.

7. The sinusoidal distributor for mixed color fabrics according to claim 5, wherein: the adjusting door mechanism comprises an adjusting bolt, a fixed seat and a connecting seat; the fixing base is fixedly arranged on the side wall of the receiving hopper, the adjusting plate is arranged on the connecting base, and the connecting base is movably connected with the fixing base through an adjusting bolt.

8. A mixed color fabric sine distributor as claimed in claim 5 or 7, wherein: the adjusting door mechanism further comprises two groups of limiting guide blocks, the two groups of limiting guide blocks are fixedly arranged on the side wall of the receiving hopper and correspondingly positioned on the left side and the right side of the adjusting plate, and the left side and the right side of the adjusting plate are movably embedded in guide grooves formed by the two groups of limiting guide blocks and the side wall of the receiving hopper respectively.

9. The sinusoidal distributor for color mixing fabrics as defined in claim 1, wherein: the transition feeding assembly comprises a mounting frame, a transmission shaft, a transition flat belt and a bevel gear variable frequency speed reducer; the transmission shaft is arranged on the mounting frame, the transition flat belt is transmitted and wound on the transmission shaft, and the transmission shaft is in transmission connection with the helical gear variable frequency speed reducer.

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