CN114604691B - Chenille spinning energy-saving equipment - Google Patents

Abstract

The invention discloses chenille spinning energy-saving equipment, wherein a chenille spinning mechanism is arranged in an equipment bracket, a high-speed direct current brushless motor is fixed on the surface of the lower end of the equipment bracket at equal intervals, and a driving conical disc is connected with the upper end output end of the lower high-speed direct current brushless motor; comprising the following steps: the cross rod is connected to the upper end of the equipment bracket, and a transmission disc is arranged at the front end of the cross rod; the yarn pressing wheels are symmetrically arranged on the left side and the right side of the outer part of the mounting frame to control spinning guiding and conveying; the guide frame is fixedly arranged on the upper surface of the driving conical disc; and the fixing frame is embedded and fixedly arranged in the equipment bracket. This chenille spinning energy-saving equipment adopts novel structural design for this device adopts high-speed brushless DC motor control yarn drive to carry, and transmission speed is very fast, and the equipment maintenance of being convenient for, and weaving machine equipment has the protection architecture that prevents broken yarn simultaneously, and it can improve chenille weaving machine operation effect of using.

Description

Chenille spinning energy-saving equipment

Technical Field

The invention relates to the technical field of textile equipment, in particular to chenille spinning energy-saving equipment.

Background

Chenille is a flower yarn, soft in handfeel, strong in velvet sense of textile fabrics prepared by the chenille yarn, strong in heat preservation and decoration, at present, traditional chenille spinning machine equipment is basically driven by an alternating current induction machine, the transmission efficiency of an alternating current induction motor is low, and the yield of control yarn is low during use, so that the chenille spinning machine driven by the alternating current induction motor still has certain problems in the use process:

1. an alternating current induction motor is adopted to control yarn conveying in the existing part of chenille spinning machine, but the transmission efficiency of the alternating current induction motor is lower, and the energy efficiency of the spinning machine is improved by combining a belt and other complex speed regulating devices in the part of alternating current induction motor, so that the maintenance cost of the spinning machine is increased;

2. meanwhile, when the chenille spinning machine controls yarn conveying, the conveying speed of the chenille spinning machine has great influence on the conveying tension of the yarns, and when the conveying tension of the yarns is too high, the chenille spinning machine is easy to cause the situation of yarn breakage in spinning.

It is desirable to design a chenille spinning energy saving device for the above problems.

Disclosure of Invention

The invention aims to provide a chenille spinning energy-saving device, which aims to solve the problems that in the prior art, an alternating current induction motor is adopted to control yarn conveying in a part of chenille spinning machines, but the transmission efficiency of the alternating current induction motor is lower, and a part of alternating current induction motor is combined with a belt and other complex speed regulating devices to improve the energy efficiency of the spinning machine, so that the maintenance cost of the spinning machine is increased, meanwhile, the conveying speed of the chenille spinning machine has great influence on the conveying tension of yarns when the yarn conveying tension is controlled, and the spinning yarn breakage condition and the like are easily caused when the yarn conveying tension is overlarge.

In order to achieve the above purpose, the present invention provides the following technical solutions: the chenille spinning energy-saving device comprises a device bracket, a lower high-speed direct current brushless motor, a driving cone disc, a cross rod, a transmission disc, a mounting frame, an upper high-speed direct current brushless motor, a line pressing wheel, a tripod, an upper pressing ring, a lower pressing ring, a guide frame, a guide disc, a side hollow cylinder, a metal right-angle frame, a center hollow cylinder, a fixing frame, a tension detector, a detection rod, a detection disc, a miniature motor, a cam disc, a pushing rod, an upper adjusting rod, a lower adjusting rod, a sliding protection frame, a clamping block, a tension adjusting disc, a guide groove, a wire guide wheel, a stepping motor, a driving disc and a transmission belt, wherein the chenille spinning mechanism is arranged in the device bracket;

chenille spinning energy-saving equipment, still include:

the transverse rod is connected to the upper end of the equipment support, the transmission disc is arranged at the front end of the transverse rod, the installation frame is fixed in the equipment support, and the upper high-speed direct-current brushless motor is fixed in the middle of the upper surface of the installation frame;

the yarn pressing wheels are symmetrically arranged on the left side and the right side of the outer part of the mounting frame to control guiding and conveying of spinning, a tripod is arranged at the middle position of the front end of the mounting frame, an upper pressing ring and a lower pressing ring are rotatably connected to the two sides of the front surface of the mounting frame, and spinning is wound between the upper pressing ring and the lower pressing ring to control guiding and conveying of the spinning;

the guide frame is fixedly arranged on the upper surface of the driving conical disc;

the fixing frame is embedded and fixedly arranged in the equipment bracket, and the fixing frame is correspondingly arranged at the positions of the right upper ends of the two groups of driving cone discs;

the wire wheel is symmetrically installed at two outer sides of the installation frame in a rotating mode, the wire wheel corresponds to the wire pressing wheel in an upper-lower fit mode, the stepping motor is fixedly installed on the bottom face of the installation frame, driving discs are installed at the side face output end of the stepping motor and the side face transmission end of the wire wheel, and meanwhile a transmission belt is installed on the outer portions of the upper driving disc and the lower driving disc in a sleeved mode.

Preferably, the yarn of the outside transmission of drive awl dish passes through leading truck, lower clamping ring, goes up clamping ring line ball wheel and transmits to the outside of driving disk, and 2 drive awl dishes that drive mechanism on 3 driving disks, the mounting bracket and the lower extreme correspond constitute a weaving drive unit group to weaving unit group is arranged in equipment support medium-distance replication, and this partial structure is convenient for control yarn direction is carried.

Preferably, the tripod is arranged between the upper pressing ring and the lower pressing ring on the left side and the right side, two groups of spinning yarns are arranged in the tripod in a penetrating mode, the upper pressing ring and the lower pressing ring are correspondingly distributed up and down, and the directional transmission of the yarns can be controlled under the guiding action of the upper pressing ring and the lower pressing ring.

Preferably, the guide frame is by direction disc, the hollow section of thick bamboo of avris, metal right angle frame and central hollow section of thick bamboo, direction disc fixed mounting is in the upper surface of drive awl dish, the hollow section of thick bamboo of avris runs through and installs in the avris internal position of direction disc, metal right angle frame fixed mounting is in the upper surface of direction disc, the hollow section of thick bamboo fixed mounting in the upper end avris position of metal right angle frame, and the yarn that the guide frame can control drive awl dish transmission is upwards guided transmission.

Preferably, two ends of the metal right-angle frame are respectively fixed with the side hollow cylinder and the center hollow cylinder, the center hollow cylinder is correspondingly arranged at the center position of the upper end of the guide disc, and the inside of the center hollow cylinder and the inside of the side hollow cylinder are communicated with chenille spinning to control the guiding and conveying of the chenille spinning, so that yarns penetrate through the inside of the side hollow cylinder and the inside of the center hollow cylinder, and the yarns led out from the side of the driving cone disc are conveyed to the upper center position.

Preferably, the side of the fixing frame is also provided with a tension detector and a micro motor:

the tension detector is fixedly arranged in the middle of the front side surface of the fixing frame, detection rods are symmetrically arranged on two sides of the outer part of the tension detector, and a detection disc is rotatably arranged in the detection rods;

the miniature motor is fixedly installed at the back position of the fixing frame, the front end output end of the miniature motor is connected with a cam disc, two sides of the cam disc are mutually connected with an upper adjusting rod and a lower adjusting rod through pushing rods, meanwhile, sliding protection frames are fixedly installed on the side sides of the upper adjusting rod and the side sides of the lower adjusting rod, and tension adjusting discs are rotatably installed in the sliding protection frames.

Preferably, the two ends of the cam disc are symmetrically provided with 2 groups of pushing rods, two sides of one pushing rod at one end are respectively connected with the cam disc and the upper adjusting rod in a rotating way, two sides of the pushing rod at the other end are respectively connected with the cam disc and the lower adjusting rod in a rotating way, and when the cam disc is controlled to rotate, the pushing rods at the two sides can be controlled to correspondingly rotate.

Preferably, the tension adjusting disc is rotatably installed in the sliding protective frame, two groups of tension adjusting discs are correspondingly arranged up and down, detection discs are correspondingly arranged between the two groups of tension adjusting discs, meanwhile, chenille spinning yarns are distributed on the outer windings of the upper group of tension adjusting discs and the lower group of tension adjusting discs and the outer windings of the detection discs in a winding mode to detect and adjust the conveying tension of the chenille spinning yarns, the yarns are distributed on the side positions of the tension adjusting discs and the side positions of the detection discs in a winding mode, and the tension of yarn transmission can be detected and adjusted.

Preferably, the side of the sliding protection frame is in penetrating sliding connection with the fixing frame, a clamping block is fixedly embedded on the inner side of the sliding protection frame, the sliding protection frame can be controlled to transversely move under the action of the transmission structure, and the sliding protection frame can adjust the corresponding positions between the upper tension adjusting disc and the lower tension adjusting disc, so that the tension of the transmission yarn is adjusted.

Preferably, the outside of tension adjustment disk has seted up the guide way, and the guide way cross-section is circular arc structure, and the position of guide way corresponds each other with the circular slot position of the inside seting up of fixture block, is convenient for carry the yarn direction through guide way and fixture block.

Compared with the prior art, the invention has the beneficial effects that: this chenille spinning energy-saving equipment adopts novel structural design for adopt down high-speed DC brushless motor control yarn in this chenille spinning machine to carry, it can be great improvement weaving efficiency, is provided with in the spinning machine simultaneously and prevents broken yarn protection architecture, its specific content is as follows:

1. the chenille spinning energy-saving equipment is provided with a high-speed spinning mechanism, wherein a lower high-speed direct current brushless motor and an upper high-speed direct current brushless motor are adopted in the chenille spinning machine to control yarn transmission, so that the yarn transmission efficiency can be greatly improved, and meanwhile, yarns are wound and arranged among a tension adjusting disc, a lower compression ring, an upper compression ring and a crimping wheel, so that the directional yarn transmission can be controlled, and the spinning is assisted;

2. this chenille spinning energy-saving equipment is provided with broken yarn protection architecture, the spinning winding distributes between upper and lower tension adjustment dish and detection dish, at the in-process of yarn weaving transmission, under the inductive action of detection dish, it can detect the yarn tension of transmission in real time, when the yarn tension of detection surpassed the scope of normal transmission, through induction mechanism control micro motor drive this moment, the cam dish correspondence of micro motor control side rotates, the push rod rotation of cam dish control both sides promotes regulation pole and lower regulation pole lateral shifting respectively, thereby the tension adjustment dish correspondence position of upper and lower both sides is adjusted, be convenient for regulate and control the tension of transmission yarn, tighten the fracture when avoiding the yarn transmission, realize certain broken yarn guard action.

Drawings

FIG. 1 is a schematic diagram of the overall frontal structure of the present invention;

FIG. 2 is a schematic diagram of the overall side structure of the present invention;

FIG. 3 is a schematic diagram of the front structure of the driving cone disc of the present invention;

FIG. 4 is a schematic view of the structure of the guide frame of the present invention;

FIG. 5 is a schematic diagram of the front view of the tripod of the present invention;

FIG. 6 is a schematic diagram of the front view of the stepping motor according to the present invention;

FIG. 7 is a schematic diagram of the front view of the fixing frame of the present invention;

FIG. 8 is a schematic top view of a tension disc of the present invention;

fig. 9 is a schematic view of the structure of the cam plate of the present invention.

In the figure: 1. an equipment rack; 2. a lower high-speed DC brushless motor; 3. driving the conical disc; 4. a cross bar; 5. a drive plate; 6. a mounting frame; 7. the upper high-speed direct current brushless motor; 8. a wire pressing wheel; 9. a tripod; 10. a pressing ring is arranged; 11. a lower pressing ring; 12. a guide frame; 121. a guide disc; 122. a side hollow cylinder; 123. a metal right angle frame; 124. a central hollow cylinder; 13. a fixing frame; 14. a tension detector; 15. a detection rod; 16. a detection disc; 17. a micro motor; 18. a cam plate; 19. a push rod; 20. an upper adjusting rod; 21. a lower adjusting rod; 22. a sliding protective frame; 221. a clamping block; 23. a tension adjusting disc; 24. a guide groove; 25. a wire guide wheel; 26. a stepping motor; 27. a drive plate; 28. a drive belt.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-9, the present invention provides a technical solution: the chenille spinning energy-saving device is characterized in that a chenille spinning mechanism is arranged in a device bracket 1, a lower high-speed direct current brushless motor 2 is fixed on the lower end surface of the device bracket 1 at equal intervals, and a driving cone disc 3 is connected to the upper end output end of the lower high-speed direct current brushless motor 2;

a chenille spinning energy saving device comprising:

the cross rod 4 is connected to the upper end of the equipment bracket 1, the front end of the cross rod 4 is provided with a transmission disc 5, the inside of the equipment bracket 1 is fixedly provided with a mounting frame 6, and the middle position of the upper surface of the mounting frame 6 is fixedly provided with an upper high-speed direct current brushless motor 7;

the yarn pressing wheels 8 are symmetrically arranged on the left side and the right side of the outer part of the mounting frame 6 to control spinning guiding and conveying, a tripod 9 is arranged in the middle of the front end of the mounting frame 6, an upper pressing ring 10 and a lower pressing ring 11 are rotatably connected on two sides of the front surface of the mounting frame 6, and spinning guiding and conveying is controlled by winding between the upper pressing ring 10 and the lower pressing ring 11;

a guide frame 12 fixedly installed on the upper surface of the driving cone 3;

the fixing frame 13 is embedded and fixedly arranged in the equipment bracket 1, and the fixing frame 13 is correspondingly arranged at the right upper end positions of the two groups of driving cone discs 3;

the wire wheel 25 is symmetrically and rotatably arranged at two outer side positions of the mounting frame 6, the wire wheel 25 is correspondingly attached to the wire pressing wheel 8 up and down, the stepping motor 26 is fixedly arranged on the bottom surface of the mounting frame 6, the driving discs 27 are respectively arranged at the side output end of the stepping motor 26 and the side transmission end of the wire wheel 25, and meanwhile, the driving belt 28 is sleeved outside the upper driving disc 27 and the lower driving disc 27.

In the embodiment, yarns transmitted from the outside of the driving cone disc 3 are transmitted to the outside of the driving disc 5 through the guide frame 12, the lower pressing ring 11 and the pressing wheel 8 of the upper pressing ring 10, the driving mechanisms on the 3 driving discs 5 and the mounting frame 6 and the 2 driving cone discs 3 corresponding to the lower end form a spinning driving unit group, and the spinning unit groups are arranged in a medium-distance replication manner in the equipment bracket 1 (a plurality of groups of spinning unit groups can be replicated according to the spinning requirement and are arranged in the equipment bracket 1); the tripod 9 is arranged between an upper press ring 10 and a lower press ring 11 on the left side and the right side, two groups of spinning yarns are arranged in the tripod 9 in a penetrating way, and the upper press ring 10 and the lower press ring 11 are correspondingly distributed up and down; the guide frame 12 comprises a guide disc 121, a side hollow cylinder 122, a metal right-angle frame 123 and a central hollow cylinder 124, wherein the guide disc 121 is fixedly arranged on the upper surface of the driving conical disc 3, the side hollow cylinder 122 is penetratingly arranged at the inner side position of the side of the guide disc 121, the metal right-angle frame 123 is fixedly arranged on the upper surface of the guide disc 121, and the central hollow cylinder 124 is fixedly arranged at the side position of the upper end of the metal right-angle frame 123; the two ends of the metal right-angle frame 123 are respectively fixed with the side hollow cylinder 122 and the center hollow cylinder 124, the center hollow cylinder 124 is correspondingly arranged at the center position of the upper end of the guide disc 121, and the inside of the center hollow cylinder 124 and the side hollow cylinder 122 are communicated with chenille spinning to control the guide conveying thereof;

the yarn drum is controlled to rotate through the lower high-speed direct current brushless motor 2 and the upper high-speed direct current brushless motor 7 so as to control yarn conveying, yarns are wound outside the driving conical disc 3 and are outwards discharged, the discharged yarns penetrate through the inside of the side hollow drum 122 and the center hollow drum 124, the center hollow drum 124 is correspondingly arranged at the position right above the driving conical disc 3, the directional conveying of the yarns is controlled through the guided side hollow drum 122 and the center hollow drum 124 in the process of driving the conical disc 3 to rotate the yarn protection, the yarns are led out through the center hollow drum 124 and then sequentially wound on the tension adjusting disc 23, the detecting disc 16, the tripod 9, the lower pressing ring 11, the upper pressing ring 10 and the pressing wire wheel 8 for guiding conveying, the yarns for guiding conveying are finally contacted with the outside the driving disc 5, the yarns of each group are respectively driven through the upper high-speed direct current brushless motor 7, the transmission efficiency is high, and the speed is controlled without using belts and other structures.

The side of the fixing frame 13 is also provided with a tension detector 14 and a micro motor 17: the tension detector 14 is fixedly arranged in the middle of the front side surface of the fixed frame 13, detection rods 15 are symmetrically arranged on two sides of the outer part of the tension detector 14, and a detection disc 16 is rotatably arranged in the detection rods 15; the micro motor 17 is fixedly arranged at the back position of the fixed frame 13, the front end output end of the micro motor 17 is connected with the cam disc 18, both sides of the cam disc 18 are mutually connected with the upper adjusting rod 20 and the lower adjusting rod 21 through the pushing rod 19, meanwhile, the side sides of the upper adjusting rod 20 and the lower adjusting rod 21 are fixedly provided with the sliding protection frame 22, and the inside of the sliding protection frame 22 is rotatably provided with the tension adjusting disc 23; the pushing rods 19 are symmetrically provided with 2 groups at two ends of the cam plate 18, two sides of one pushing rod 19 are respectively and rotatably connected with the cam plate 18 and the upper adjusting rod 20, and two sides of the other pushing rod 19 are respectively and rotatably connected with the cam plate 18 and the lower adjusting rod 21; the tension adjusting discs 23 are rotatably arranged in the sliding protective frame 22, two groups of tension adjusting discs 23 are correspondingly arranged up and down, the detection discs 16 are correspondingly arranged between the two groups of tension adjusting discs 23, and meanwhile chenille spinning yarns are wound and distributed outside the upper group of tension adjusting discs 23 and the lower group of tension adjusting discs 16 to detect and adjust the conveying tension of the chenille spinning yarns; the side surface of the sliding protection frame 22 is connected with the fixing frame 13 in a penetrating and sliding way, and a clamping block 221 is embedded and fixed on the inner side surface of the sliding protection frame 22; the outside of the tension adjusting disc 23 is provided with a guide groove 24, the section of the guide groove 24 is in an arc-shaped structure, and the position of the guide groove 24 corresponds to the position of a round groove formed in the clamping block 221;

the yarn winding is arranged between the upper tension adjusting disk 23 and the lower tension adjusting disk 23, the middle side of the upper tension adjusting disk 23 and the lower tension adjusting disk 23 is correspondingly provided with a detection disk 16, when the yarn is in the process of directional transmission, the tension of yarn transmission can be detected in real time through the contact of the detection disk 16 and the yarn, and detected data is transmitted to the tension detecting instrument 14, if the detected data is in the normal range of yarn transmission, the device controls the yarn to be normally transmitted, if the detected data exceeds the normal range of yarn transmission (the tension detecting instrument 14 is electrically connected with a controller, the controller is electrically connected with a micro motor 17 which controls the rotation of the cam disk 18, the micro motor 17 is controlled to drive and run according to the detected data of the tension detecting instrument 14), the controller controls the micro motor 17 to drive and control the cam disk 18 to rotate, the push rods 19 on two sides are correspondingly rotated, the push rods 19 push the slide protecting frames 22 connected on the sides in the process of rotation, the back surfaces of the slide protecting frames 22 are connected with the inner penetrating sliding of the fixing frames 13 under the push force of the push rods 19, the slide protecting frames 22 penetrate the side protecting frames 13 in the normal range, the tension of the two sides of the sliding protecting frames is controlled by the push rods 19, the tension protecting frames are controlled by the micro motor 17 to move in the opposite directions, the tension is controlled by the tension of the micro motor 17, the tension is controlled to be prevented from moving in the opposite directions when the tension is transmitted to the yarn transmission is detected, the tension is controlled to be in the opposite directions, the tension is controlled, the tension is prevented from being transmitted, and the tension is adjusted, and the yarn is in the yarn transmission is in the proper condition, and the tension is cut and is in the opposite direction, and the tension is transmitted to the yarn transmission is in the tension transmission and the yarn is in the transmission and the tension is cut and is in the opposite side and is in the transmission. Improving the application effect of the textile machine.

Working principle: when the device is used, according to the structures shown in fig. 1-9, yarn conveying is controlled through the lower high-speed direct current brushless motor 2 and the upper high-speed direct current brushless motor 7, the independent conveying structure can control yarn conveying more stably and rapidly, and when a local lower high-speed direct current brushless motor fails, only the motor at the position is required to be independently maintained, so that equipment maintenance cost is reduced;

simultaneously, the yarn is guided and conveyed between the upper tension adjusting disk 23 and the lower tension adjusting disk 23 under the guiding conveying action of the guide frame 12, yarn upper end limiting is arranged between the lower compression ring 11 and the upper compression ring 10, yarn is wound between the compression ring 8 and the guide wire wheel 25 and conveyed upwards (the driving disk 27 of the side output end is controlled to rotate by the operation stepping motor 26, the driving disk 27 drives the driving disk 27 and the guide wire wheel 25 corresponding to the upper end to rotate under the driving action of the driving belt 28, the rotating guide wire wheel 25 can assist yarn conveying), the yarn is finally contacted and connected to the outside of the driving disk 5, the part structure can control the yarn to be conveyed stably according to a certain path, the yarns on two sides are prevented from being wound with each other in the conveying process, meanwhile, the tension on two sides is detected in real time through the detection disk 16, when the yarn conveying tension is detected to be normal, the equipment normally operates and conveys, when the yarn conveying tension is detected to exceed the numerical value of a normal range, the tension detector 14 transmits detected data to a connected controller at the moment, the time, the micro motor 17 electrically connected with the driving disk 17 is controlled by the controller to rotate correspondingly by the driving disk 17, the micro motor 17 drives the two sides 18 to rotate correspondingly, the rotating shafts 19 corresponding to the driving disk 18 to the two sides to move correspondingly, and the two sides of the guide wire frame 18 are pushed by the opposite to move correspondingly, and the tension adjusting frame 22 moves correspondingly to the tension adjusting lever 22 to move in the direction of the opposite directions when the two protective frames are moved in the direction, and the opposite directions are prevented from moving in the direction, and the protective frame 22 is moved to move in the direction and the opposite to the tension is in the direction and the normal direction.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The chenille spinning energy-saving device is characterized in that a chenille spinning mechanism is arranged in a device bracket (1), a lower high-speed direct current brushless motor (2) is fixed on the lower end surface of the device bracket (1) at equal intervals, and a driving conical disc (3) is connected to the upper end output end of the lower high-speed direct current brushless motor (2);

characterized by comprising the following steps:

the transverse rod (4) is connected to the upper end of the equipment support (1), the front end of the transverse rod (4) is provided with a transmission disc (5), an installation frame (6) is fixed in the equipment support (1), and an upper high-speed direct current brushless motor (7) is fixed in the middle of the upper surface of the installation frame (6);

the yarn pressing wheels (8) are symmetrically arranged on the left side and the right side of the outside of the mounting frame (6) to control guiding and conveying of spinning yarn, a tripod (9) is arranged at the middle position of the front end of the mounting frame (6), an upper pressing ring (10) and a lower pressing ring (11) are rotatably connected to the two sides of the front surface of the mounting frame (6), and spinning yarn is wound between the upper pressing ring (10) and the lower pressing ring (11) to control guiding and conveying of the spinning yarn;

the guide frame (12) is fixedly arranged on the upper surface of the driving conical disc (3);

the fixing frame (13) is embedded and fixedly arranged in the equipment bracket (1), and the fixing frame (13) is correspondingly arranged at the positions of the right upper ends of the two groups of driving conical discs (3);

the wire guide wheels (25) are symmetrically and rotatably arranged at two outer side positions of the mounting frame (6), the wire guide wheels (25) are correspondingly attached to the wire pressing wheels (8) up and down, a stepping motor (26) is fixedly arranged on the bottom surface of the mounting frame (6), driving discs (27) are arranged at the side output end of the stepping motor (26) and the side transmission end of the wire guide wheels (25), and a transmission belt (28) is sleeved outside the upper driving disc and the lower driving disc (27);

the guide frame (12) is composed of a guide disc (121), a side hollow cylinder (122), a metal right-angle frame (123) and a central hollow cylinder (124), wherein the guide disc (121) is fixedly arranged on the upper surface of the driving conical disc (3), the side hollow cylinder (122) is arranged at the inner side position of the side of the guide disc (121) in a penetrating way, the metal right-angle frame (123) is fixedly arranged on the upper surface of the guide disc (121), and the central hollow cylinder (124) is fixedly arranged at the side position of the upper end of the metal right-angle frame (123);

the side of the fixing frame (13) is also provided with a tension detector (14) and a micro motor (17):

the tension detector (14) is fixedly arranged in the middle of the front side surface of the fixed frame (13), detection rods (15) are symmetrically arranged on two sides of the outer part of the tension detector (14), and a detection disc (16) is rotatably arranged in the detection rods (15);

the miniature motor (17) is fixedly installed at the back position of the fixed frame (13), the front end output end of the miniature motor (17) is connected with a cam disc (18), two sides of the cam disc (18) are mutually connected with an upper adjusting rod (20) and a lower adjusting rod (21) through pushing rods (19), meanwhile, sliding protection frames (22) are fixedly installed on the side sides of the upper adjusting rod (20) and the lower adjusting rod (21), and tension adjusting discs (23) are rotatably installed in the sliding protection frames (22).

2. A chenille spinning energy saving device according to claim 1, characterized in that: yarn of drive awl dish (3) outside transmission passes through leading truck (12), lower clamping ring (11), goes up clamping ring (10), line ball wheel (8) and transmits to the outside of driving dish (5), and 2 drive awl dishes (3) that drive mechanism on 3 driving dishes (5), mounting bracket (6) and the lower extreme correspond constitute a weaving drive unit group to weaving drive unit group is in equipment support (1) medium-distance replication range.

3. A chenille spinning energy saving device according to claim 1, characterized in that: the tripod (9) is arranged between an upper pressing ring (10) and a lower pressing ring (11) on the left side and the right side, two groups of spinning yarns are arranged in the tripod (9) in a penetrating mode, and the upper pressing ring (10) and the lower pressing ring (11) are distributed correspondingly up and down.

4. A chenille spinning energy saving device according to claim 1, characterized in that: the two ends of the metal right-angle frame (123) are respectively fixed with the side hollow cylinder (122) and the center hollow cylinder (124), the center hollow cylinder (124) is correspondingly arranged at the center position of the upper end of the guide disc (121), and the inside of the center hollow cylinder (124) and the inside of the side hollow cylinder (122) are communicated with chenille spinning and control the guide conveying of spinning.

5. A chenille spinning energy saving device according to claim 1, characterized in that: the two ends of the cam disc (18) of the pushing rod (19) are symmetrically provided with 2 groups, two sides of the pushing rod (19) at one end are respectively in rotary connection with the cam disc (18) and the upper adjusting rod (20), and two sides of the pushing rod (19) at the other end are respectively in rotary connection with the cam disc (18) and the lower adjusting rod (21).

6. A chenille spinning energy saving device according to claim 1, characterized in that: the tension adjusting disc (23) is rotatably arranged in the sliding protective frame (22), two groups of tension adjusting discs (23) are correspondingly arranged up and down, a detection disc (16) is correspondingly arranged between the two groups of tension adjusting discs (23), and meanwhile chenille yarns are distributed by winding the outer parts of the upper group of tension adjusting discs (23) and the lower group of tension adjusting discs (16) and the outer parts of the detection discs (16) and are detected and adjusted.

7. A chenille spinning energy saving device according to claim 6, characterized in that: the side face of the sliding protection frame (22) is connected with the fixing frame (13) in a penetrating and sliding mode, and a clamping block (221) is fixedly embedded into the inner side face of the sliding protection frame (22).

8. A chenille spinning energy saving device according to claim 7, characterized in that: the outside of tension adjusting disk (23) has seted up guide way (24), and guide way (24) cross-section is circular-arc structure, and guide way (24) position and fixture block (221) inside circular slot position of seting up are corresponding each other.