CN113604894A

CN113604894A - Silk guide mechanism for tencel production

Info

Publication number: CN113604894A
Application number: CN202110937188.2A
Authority: CN
Inventors: 李超
Original assignee: Shaoxing Shunjia Textile Technology Co ltd
Current assignee: Shaoxing Shunjia Textile Technology Co ltd
Priority date: 2021-08-16
Filing date: 2021-08-16
Publication date: 2021-11-05

Abstract

The invention provides a silk guide mechanism for tencel production, which comprises a substrate and a transmission assembly, wherein the substrate is provided with a plurality of guide grooves; the silk guide mechanism for silk production provided by the invention has the advantages that the counter weight block is arranged on the supporting plate, so that the counter weight block downwards pulls the supporting plate, the supporting plate drives the pressing rod to rotate, the pressing rod presses the silk inside the transmission groove, the silk can be always positioned inside the transmission groove, the silk can be in close contact with the transmission disc, the silk can be conveyed when the transmission disc rotates, the problem that the silk is not in close contact with the transmission disc when the silk is conveyed is avoided, the silk is rubbed by the transmission disc to cause damage of the silk, the first motor is driven to downwards move by the pushing spring, the first motor drives the driving wheel to downwards move, the transmission belt is pushed by the driving wheel to keep tight, the phenomenon that the rotating speeds of the two rotating rods are inconsistent to cause stretching of the silk is avoided, easily causes influence on the quality of the tencel.

Description

Silk guide mechanism for tencel production

Technical Field

The invention relates to the technical field of tencel production, in particular to a thread guide mechanism for tencel production.

Background

Tencel, the name of science is lyocell fiber, commonly known as velveteen, use natural plant fiber as raw materials, have natural fiber and many fine properties of synthetic fiber concurrently, lyocell is green fiber, its raw materials are inexhaustible cellulose of the nature, the production run has no chemical reaction, the solvent used is non-toxic, "lyocell" fiber is with the pulp that can be regenerated and formed after smashing such as bamboo, wood, etc. as raw materials, advanced technology makes its solvent recovery reach 99.7%, not only energy-conservation, environmental protection, but also sustainable development.

In the production process of the tencel, the tencel is required to be guided from one production area to another so that the processing of the tencel can be continued.

Most of the existing yarn guide mechanisms adopt a plurality of motors to drive rotating shafts to convey tencel, and when the tencel is conveyed, the tencel is easily in poor contact with the rotating shafts, so that friction exists between the tencel and the rotating shafts, and the tencel is easily damaged, and the quality of the tencel is influenced.

Therefore, it is necessary to provide a thread guiding mechanism for tencel production to solve the above technical problems.

Disclosure of Invention

The invention provides a silk guide mechanism for tencel production, which solves the problem that friction between a tencel and a rotating shaft easily damages the tencel.

In order to solve the technical problem, the thread guide mechanism for tencel production provided by the invention comprises: the device comprises a substrate, a transmission assembly, a pressing assembly and a power assembly; the transmission assembly is fixed on the substrate and comprises a rotating rod, a transmission disc, a transmission groove, a belt pulley and a transmission belt; the pressing assembly is fixed on the base plate and comprises a supporting rod, a supporting plate, a pressing rod, a pulling rope and a balancing weight; wherein, the dwang with the base plate rotates to be connected, the transmission dish is fixed in on the dwang, the transmission groove is seted up in on the transmission dish, the belt pulley is fixed in the one end of dwang, the transmission band cup joint in the surface of belt pulley, the bracing piece is fixed in on the base plate, the backup pad with the bracing piece rotates to be connected, the suppression pole is fixed in the backup pad, it is fixed in to pull the rope in the backup pad, the balancing weight set up in the one end of pulling the rope.

Preferably, the base plate is the U-shaped, the dwang is provided with two altogether, two the dwang symmetric distribution is in the both sides of base plate to the structure on two dwangs is the same, two the belt pulley of dwang one end passes through the transmission band and connects.

Preferably, the transmission plate is provided with a plurality of transmission plates which are uniformly distributed on the surface of the rotating rod, the transmission groove is formed in the middle of the transmission plate, and the transmission grooves are arc-shaped.

Preferably, the supporting plate is connected with the base plate in a sliding mode, the supporting plate and the transmission disc are not located on the same horizontal plane, the number of the pressing rods is two, the two pressing rods are symmetrically distributed on one side of the two rotating rods, and the two pressing rods are identical in structure.

Preferably, the pressing rod is not in contact with the transmission disc, the pulling rope is fixed on the upper portion of the middle of the supporting plate, and the pulling rope is connected with the balancing weight through a connecting piece.

Preferably, the power assembly comprises a mounting plate, a lifting rod, a fixed disc, a pushing spring, a first motor and a driving wheel.

Preferably, the mounting panel is fixed in on the base plate, the lifter with mounting panel sliding connection to the lifter is square pole, the fixed disk is fixed in the one end of lifter, the mounting panel is located the middle part of base plate.

Preferably, the pushing spring is located the mounting panel with between the fixed disk, first motor with the one end fixed connection of lifter, the action wheel is fixed in the output of first motor to the action wheel with the transmission band contact.

Preferably, the base plate is fixedly connected with a reciprocating assembly, and the reciprocating assembly comprises a fixing plate, a second motor, a transmission rod, a sliding frame, a lifting plate and a transmission hole.

Preferably, the fixed plate is fixed on the base plate, the second motor is fixed on the fixed plate, the transmission rod is fixed at the output end of the second motor, the lifting plate is connected with the base plate in a sliding manner, the transmission hole is formed in the lifting plate, the sliding frame is fixed at one end of the lifting plate, one end of the transmission rod is located in the sliding frame, and the transmission rod is connected with the sliding frame in a sliding manner.

Compared with the related art, the silk guide mechanism for tencel production provided by the invention has the following beneficial effects:

the invention provides a silk guide mechanism for silk production, which is characterized in that a support plate is provided with a balancing weight, the balancing weight pulls the support plate downwards, the support plate drives a pressing rod to rotate, the pressing rod presses the silk in a transmission groove, the silk can be always positioned in the transmission groove, the silk can be in close contact with a transmission disc, the silk can be conveyed when the transmission disc rotates, the problem that the silk is not in close contact with the transmission disc when the silk is conveyed is avoided, the transmission disc rubs the silk to cause damage to the silk, a first motor is driven to move downwards by a pushing spring, a driving wheel is driven to move downwards by the first motor, the transmission belt is pushed by the driving wheel to keep tight, the phenomenon that the rotation speeds of two rotating rods are not consistent all the time to cause stretching of the silk is avoided, easily causes influence on the quality of the tencel.

Drawings

FIG. 1 is a schematic structural view of a first embodiment of a thread guiding mechanism for tencel production provided by the present invention;

FIG. 2 is a perspective view of the substrate shown in FIG. 1;

fig. 3 is a schematic structural diagram of a second embodiment of a silk guide mechanism for tencel production provided by the invention.

Reference numbers in the figures:

1. a substrate, a first electrode and a second electrode,

2. a transmission component 21, a rotating rod 22, a transmission disc 23, a transmission groove 24, a belt pulley 25 and a transmission belt,

3. a pressing component 31, a support rod 32, a support plate 33, a pressing rod 34, a pulling rope 35 and a balancing weight,

4. a power component 41, a mounting plate 42, a lifting rod 43, a fixed disc 44, a pushing spring 45, a first motor 46 and a driving wheel,

5. the reciprocating assembly 51, the fixing plate 52, the second motor 53, the transmission rod 54, the sliding frame 55, the lifting plate 56 and the transmission hole.

Detailed Description

The invention is further described with reference to the following figures and embodiments.

First embodiment

Please refer to fig. 1 and fig. 2 in combination, wherein fig. 1 is a schematic structural diagram of a thread guiding mechanism for tencel production according to a first embodiment of the present invention; fig. 2 is a perspective view of the substrate shown in fig. 1. A silk guide mechanism for tencel production comprises: the device comprises a base plate 1, a transmission assembly 2, a pressing assembly 3 and a power assembly 4; the transmission assembly 2 is fixed on the substrate 1, and the transmission assembly 2 comprises a rotating rod 21, a transmission disc 22, a transmission groove 23, a belt pulley 24 and a transmission belt 25; the pressing component 3 is fixed on the base plate 1, and the pressing component 3 comprises a support rod 31, a support plate 32, a pressing rod 33, a pulling rope 34 and a balancing weight 35; wherein, dwang 21 with base plate 1 rotates to be connected, transmission dish 22 is fixed in on the dwang 21, transmission groove 23 sets up in on the transmission dish 22, belt pulley 24 is fixed in the one end of dwang 21, transmission band 25 cup joint in belt pulley 24's surface, bracing piece 31 is fixed in on the base plate 1, backup pad 32 with bracing piece 31 rotates to be connected, suppression pole 33 is fixed in on the backup pad 32, it is fixed in to pull rope 34 in the backup pad 32, balancing weight 35 set up in the one end of pulling rope 34.

Base plate 1 is the U-shaped, dwang 21 is provided with two altogether, two dwang 21 symmetric distribution is in the both sides of base plate 1 to the structure on two dwang 21 is the same, two the belt pulley 24 of dwang 21 one end passes through transmission band 25 and connects.

The two rotating levers 21 are structured such that the tencel is conveyed from both sides of the substrate 1, and the two rotating levers 21 are connected by a conveying belt 25 so that the two rotating levers 21 can be rotated in synchronization.

The transmission discs 22 are arranged in a plurality, the transmission discs 22 are uniformly distributed on the surface of the rotating rod 21, the transmission grooves 23 are formed in the middle of the transmission discs 22, and the transmission grooves 23 are arc-shaped.

Multiple transfer trays 22 may simultaneously transport multiple sets of produced tencel.

The supporting plate 32 is slidably connected to the base plate 1, the supporting plate 32 is not located on the same horizontal plane as the transfer tray 22, two pressing rods 33 are provided, the two pressing rods 33 are symmetrically distributed on one side of the two rotating rods 21, and the two pressing rods 33 have the same structure.

The pressing rod 33 presses the tencel so that the tencel can be in close contact with the transmission disc 22, and the transmission disc 22 can move along with the tencel when rotating.

The pressing rod 33 is not in contact with the transmission disc 22, the pulling rope 34 is fixed on the upper middle part of the supporting plate 32, and the pulling rope 34 is connected with the balancing weight 35 through a connecting piece.

The connecting piece between balancing weight 35 and the pulling rope 34 can adopt hook, buckle for can change balancing weight 35 as required, change the balancing weight 35 of different weight.

The power assembly 4 comprises a mounting plate 41, a lifting rod 42, a fixed disc 43, a pushing spring 44, a first motor 45 and a driving wheel 46.

The first motor 45 is powered by an external power source, and a control switch is provided between the external power source and the first motor 45.

The mounting panel 41 is fixed in on the base plate 1, the lifter 42 with mounting panel 41 sliding connection to lifter 42 is square pole, fixed disk 43 is fixed in the one end of lifter 42, mounting panel 41 is located the middle part of base plate 1.

The square-shaped lift pins 42 allow the lift pins 42 to move only up and down inside the mounting plate 41.

The push spring 44 is located between the mounting plate 41 and the fixed disk 43, the first motor 45 is fixedly connected with one end of the lifting rod 42, the driving wheel 46 is fixed at the output end of the first motor 45, and the driving wheel 46 is in contact with the transmission belt 25.

The driving wheel 46 rotates to drive the transmission belt 25 to rotate synchronously, and the pushing spring 44 pushes the first motor 45, so that the first motor 45 can drive the driving wheel 46 to move downwards, so that the driving wheel 46 pulls the transmission belt 25, and the transmission belt 25 is kept in a tight state.

The working principle of the silk guide mechanism for producing the tencel provided by the invention is as follows:

upwards rotating the support plate 32, the support plate 32 upwards rotates to drive the pressing rod 33 to upwards move, then placing the tencel inside the transmission grooves 23 on the two rotating rods 21, then loosening the support plate 32, downwards pulling the support plate 32 by the balancing weight 35, the support plate 32 downwards rotates to drive the pressing rod 33 to rotate, so that the pressing rod 33 presses the tencel, so that the tencel can be positioned inside the transmission grooves 23 and is in close contact with the transmission disc 22, then the output end of the first motor 45 is controlled to rotate by the control switch, the output end of the first motor 45 rotates to drive the driving wheel 46 to rotate, the driving wheel 46 rotates to drive the transmission belt 25 to rotate, the transmission belt 25 rotates to drive the belt pulley 24 to rotate, the belt pulley 24 rotates to drive the rotating rod 21 to rotate, the rotating rod 21 rotates to drive the transmission disc 22 to rotate, so that the transmission disc 22 drives the tencel to move, in the transmission process, the fixed disc 43 is pushed downwards by the pushing spring 44, the downward movement of the fixed disc 43 drives the lifting rod 42 to move downwards, the downward movement of the lifting rod 42 drives the first motor 45 to move downwards, the downward movement of the first motor 45 drives the driving wheel 46 to move downwards, and the downward movement of the driving wheel 46 can drive the driving wheel 46 to pull the transmission belt 25, so that the transmission belt 25 is kept in a tight state.

the supporting plate 32 is provided with the balancing weight 35, so that the supporting plate 32 is pulled downwards by the balancing weight 35, the supporting plate 32 drives the pressing rod 33 to rotate, the pressing rod 33 presses the tencel inside the transmission groove 23, the tencel can be always positioned inside the transmission groove 23, the tencel can be in close contact with the transmission disc 22, the tencel can be conveyed when the transmission disc 22 rotates, the problem that the tencel is not in close contact with the transmission disc 22 when the tencel is transmitted is avoided, the transmission disc 22 rubs the tencel to cause damage to the tencel is avoided, the first motor 45 is driven by the pushing spring 44 to move downwards, the first motor 45 drives the driving wheel 46 to move downwards, the transmission belt 25 is pushed by the driving wheel 46, the transmission belt 25 is kept tight all the time, the problem that the rotating speeds of the two rotating rods 21 are inconsistent to cause stretching of the tencel is avoided, easily causes influence on the quality of the tencel.

Second embodiment

Referring to fig. 3, a second embodiment of the present application provides another type of silk guide mechanism for silk production based on the silk guide mechanism provided in the first embodiment of the present application. The second embodiment is only the preferred mode of the first embodiment, and the implementation of the second embodiment does not affect the implementation of the first embodiment alone.

Specifically, the difference of the silk thread production guide mechanism provided by the second embodiment of the present application lies in that the silk thread production guide mechanism, a reciprocating assembly 5 is fixedly connected to the base plate 1, and the reciprocating assembly 5 includes a fixing plate 51, a second motor 52, a transmission rod 53, a sliding frame 54, a lifting plate 55, and a transmission hole 56.

One side of the substrate 1 is provided with a winding device of the tencel, the motor drives the collecting cylinder to rotate, the collection of the tencel is completed, an external power supply provides power for the second motor 52, a control switch is arranged between the external power supply and the second motor 52, the second motor 52 adopts a stepping motor, and the rotating speed of the second motor 52 can be adjusted.

The fixing plate 51 is fixed on the substrate 1, the second motor 52 is fixed on the fixing plate 51, the transmission rod 53 is fixed at the output end of the second motor 52, the lifting plate 55 is slidably connected with the substrate 1, the transmission hole 56 is formed in the lifting plate 55, the sliding frame 54 is fixed at one end of the lifting plate 55, one end of the transmission rod 53 is located inside the sliding frame 54, and the transmission rod 53 is slidably connected with the sliding frame 54.

The connection position of the base plate 1 and the lifting plate 55 adopts a square groove, so that the lifting plate 55 can only move up and down when pushed by the transmission rod 53, and the sliding frame 54 is connected with the lifting plate 55, so that the transmission rod 53 can drive the sliding frame 54 to move up and down when rotating.

The working principle is as follows:

when it is required to wind the tencel, the tencel penetrates through the transmission hole 56, then the output end of the second motor 52 is controlled to rotate by the control switch, the output end of the second motor 52 rotates to drive the transmission rod 53 to rotate, the transmission rod 53 rotates to drive the sliding frame 54 to move up and down, the sliding frame 54 moves up and down to drive the lifting plate 55 to move up and down, the lifting plate 55 moves up and down to drive the transmission hole 56 to move up and down, the transmission hole 56 moves up and down to drive the tencel to move up and down, and therefore the tencel can be uniformly wound on the surface of the collecting cylinder.

Has the advantages that:

the output end of the second motor 52 rotates to drive the transmission rod 53 to rotate, so that the transmission rod 53 drives the sliding frame 54 to move up and down, the sliding frame 54 drives the lifting plate 55 to move up and down, the lifting plate 55 can drive the transmission hole 56 to move up and down by moving up and down, and then the tencel in the transmission hole 56 can be driven to move up and down, and the tencel can be uniformly wound on the surface of the collecting cylinder.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. A silk production seal wire mechanism, its characterized in that includes:

the device comprises a base plate (1), a transmission assembly (2), a pressing assembly (3) and a power assembly (4);

the transmission assembly (2) is fixed on the substrate (1), and the transmission assembly (2) comprises a rotating rod (21), a transmission disc (22), a transmission groove (23), a belt pulley (24) and a transmission belt (25); the pressing component (3) is fixed on the base plate (1), and the pressing component (3) comprises a supporting rod (31), a supporting plate (32), a pressing rod (33), a pulling rope (34) and a balancing weight (35);

wherein, dwang (21) with base plate (1) rotates to be connected, transmission dish (22) are fixed in on dwang (21), transmission groove (23) are seted up in on transmission dish (22), belt pulley (24) are fixed in the one end of dwang (21), transmission band (25) cup joint in the surface of belt pulley (24), bracing piece (31) are fixed in on base plate (1), backup pad (32) with bracing piece (31) rotate to be connected, suppression pole (33) are fixed in on backup pad (32), it is fixed in to pull rope (34) on backup pad (32), balancing weight (35) set up in pull the one end of rope (34).

2. The silk production guide wire mechanism of claim 1, characterized in that the base plate (1) is U-shaped, the two rotating rods (21) are arranged, the two rotating rods (21) are symmetrically distributed on two sides of the base plate (1), the two rotating rods (21) have the same structure, and the belt pulleys (24) at one ends of the two rotating rods (21) are connected through a transmission belt (25).

3. The silk production guide wire mechanism of claim 1, characterized in that the transmission disc (22) is provided with a plurality of transmission discs, the transmission discs (22) are uniformly distributed on the surface of the rotating rod (21), the transmission grooves (23) are arranged in the middle of the transmission discs (22), and the transmission grooves (23) are all arc-shaped.

4. Tencel production guide mechanism according to claim 1, characterized in that the support plate (32) is slidably connected to the base plate (1) and the support plate (32) is not in the same horizontal plane as the transport plate (22), the pressing rods (33) are provided in two, the two pressing rods (33) are symmetrically distributed on one side of the two rotating rods (21), and the two pressing rods (33) have the same structure.

5. The silk guide mechanism of claim 1, characterized in that the pressing rod (33) is not in contact with the transmission disc (22), the pulling rope (34) is fixed on the middle of the supporting plate (32) and the pulling rope (34) is connected with the balancing weight (35) through a connecting piece.

6. Tencel production guide mechanism according to claim 1, wherein the power assembly (4) comprises a mounting plate (41), a lifting rod (42), a fixed plate (43), a push spring (44), a first motor (45) and a driving wheel (46).

7. The silk production guide wire mechanism of claim 6, characterized in that the mounting plate (41) is fixed on the base plate (1), the lifting rod (42) is connected with the mounting plate (41) in a sliding manner, the lifting rod (42) is a square rod, the fixing disc (43) is fixed at one end of the lifting rod (42), and the mounting plate (41) is located in the middle of the base plate (1).

8. The silk production guide wire mechanism of claim 6, characterized in that the pushing spring (44) is located between the mounting plate (41) and the fixed disc (43), the first motor (45) is fixedly connected with one end of the lifting rod (42), the driving wheel (46) is fixed at the output end of the first motor (45), and the driving wheel (46) is in contact with the transmission belt (25).

9. The silk production guide wire mechanism of claim 1, characterized in that a reciprocating component (5) is fixedly connected to the base plate (1), and the reciprocating component (5) comprises a fixing plate (51), a second motor (52), a transmission rod (53), a sliding frame (54), a lifting plate (55) and a transmission hole (56).

10. The silk production guide wire mechanism of claim 9, wherein the fixing plate (51) is fixed on the base plate (1), the second motor (52) is fixed on the fixing plate (51), the transmission rod (53) is fixed on the output end of the second motor (52), the lifting plate (55) is connected with the base plate (1) in a sliding manner, the transmission hole (56) is formed in the lifting plate (55), the sliding frame (54) is fixed at one end of the lifting plate (55), one end of the transmission rod (53) is positioned inside the sliding frame (54), and the transmission rod (53) is connected with the sliding frame (54) in a sliding manner.