CN116155059B

CN116155059B - Friction magneto-electricity micro-energy collection device for wax printing imitation

Info

Publication number: CN116155059B
Application number: CN202211655109.XA
Authority: CN
Inventors: 戚昕; 虞少波; 任世林; 潘鑫良; 王建森
Original assignee: Zhejiang Baofeng Printing & Dying Co ltd
Current assignee: Zhejiang Baofeng Printing & Dying Co ltd
Priority date: 2022-12-22
Filing date: 2022-12-22
Publication date: 2023-11-17
Anticipated expiration: 2042-12-22
Also published as: CN116155059A

Abstract

The invention provides a friction magneto-electricity micro-energy collection device for wax printing imitation, which relates to the field of wax printing imitation devices. The friction magneto-electricity micro-energy collection device for the wax printing is characterized in that a central shaft and an upper cross rod are arranged, cloth passes through the space between the central shaft and the upper cross rod, a plurality of friction blocks are arranged in the upper cross rod in a sliding mode, the friction blocks are provided with friction plates, magnet inserting pieces, iron blocks and conducting wires, static electricity is generated by friction between the iron blocks and the cloth, meanwhile, current is generated by cutting magnetic induction wires through the conducting wires, and the two electric energy is collected. Thereby achieving the effect of micro energy collection. And under the action of the electromagnet module, the iron block moves back and forth and plays a role in scraping the wool and cleaning the miscellaneous wool on the cloth.

Description

Friction magneto-electricity micro-energy collection device for wax printing imitation

Technical Field

The invention relates to the technical field of wax printing imitation printing devices, in particular to a friction magneto-electricity micro-energy collection device for wax printing imitation.

Background

In the textile printing industry, most of printing textiles are single-sided printing, and printing patterns are arranged on the front side and the back side of the fabric. The processing is generally carried out by adopting a wax printing imitation mode. The wax printing imitation printing is performed by the expression method and the printing of the pattern design. The printed fabric is generally made of pure cotton, cotton and hemp blended fabrics. The fabric after wax printing imitation is required to have a bright color and basically no front and back sides.

In the wax printing process, the miscellaneous hair on the fabric needs to be cleaned in advance, so that the phenomenon that the miscellaneous hair falls off in the printing and dyeing process to cause different or unclear pattern depth is avoided. For this purpose, it is necessary to remove the foreign hair and flock before printing.

In the process of cleaning the miscellaneous hair, the traditional mode needs to use rollers to continuously rub on the fabric, and the electronic motion caused by friction is enough to drive some small electronic parts to work, so that the micro energy sources are often not important enough and are wasted very. Therefore, a micro-electric energy collection mechanism is established to collect micro-electric energy generated by friction in the process of recovering the impurity-removed hair.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the invention provides a friction magneto-electricity micro-energy collection device for wax printing, which solves the problems in the background art.

(II) technical scheme

In order to achieve the above purpose, the invention is realized by the following technical scheme: the utility model provides a imitative friction magnetism electricity micro-energy collection device for wax printing polishes the cloth, includes the base, the base top is equipped with the cloth roller, and the base bottom is connected with the wind-up roll, the base left side central authorities department is seted up flutedly, is equipped with the axis in the recess, and the axis top is equipped with the top rail, and the axis below is equipped with the bottom rail, and the cloth passes the crack between top rail and the axis earlier, and then passes the crack between axis and the bottom rail.

The upper cross rod is provided with a sliding groove which is vertically communicated, a plurality of friction blocks are slidably matched in the sliding groove, an electromagnet module is arranged on one side, close to each other, of each friction block, a recess is formed in the upper side and the lower side of each friction block, a friction plate is arranged in each friction block recess, a plurality of magnet inserting sheets are inserted into each friction plate, magnetic poles between adjacent magnet inserting sheets are opposite, a plurality of through grooves are formed in each friction plate, and the through grooves are distributed between the adjacent magnet inserting sheets.

The magnet inserting piece is slidably matched with an iron block, a vertical wire is arranged on the iron block, the iron block moves back and forth to drive the wire to cut the magnetic induction wire, a storage battery is arranged at the top of the concave inner wall of the friction block, the wire and the iron block are respectively electrically connected with the storage battery, and the bottom of the iron block is in contact with cloth.

The upper cross rod sliding groove is internally provided with an iron rod, the iron rod is parallel to the upper cross rod, the iron rod penetrates through the friction block and the electromagnet module, springs are connected to the front side and the rear side of the inner wall of the iron rod, the friction block positioned at the edge is connected with the springs, and the end part of the upper cross rod is provided with a tooth groove.

The electromagnet module comprises a shell, an electric coil, a singlechip, an electric push rod and a fixed block, wherein the iron rod penetrates through the shell, an iron sheet is arranged in the shell, the electric wire sleeve is sleeved outside the iron sheet, the singlechip is arranged at the top of the inner wall of the shell, the fixed block is arranged at the bottom of the inner wall of the shell, the fixed end of the electric push rod is arranged at the bottom of the singlechip, the movable end of the electric push rod is aligned to the fixed block, and a button cell is arranged in the shell and electrically connected with the electric push rod and the singlechip.

The L-shaped cavity is formed in the fixed block, the end part of the electric coil extends into the L-shaped cavity, two battery plates are arranged between the end parts of the electric coil in the L-shaped cavity, the two battery plates are arranged up and down, the movable end of the electric push rod is connected with a rubber rod, the rubber rod extends into the L-shaped cavity, one end of the rubber rod, far away from the electric push rod, is abutted against the inner wall of the L-shaped cavity to be bent upwards, the positive electrode and the negative electrode of the two battery plates are opposite, and the end part of the electric coil can be abutted with the battery plates.

A plastic rod is connected between the two battery plates, and one end, far away from the electric push rod, of the rubber rod is connected with the lowest battery plate.

Preferably, a gear driven by a motor is arranged at the top of the inner wall of the groove, and the gear is meshed with the tooth slot.

Preferably, the left side of the lower cross rod is provided with a cavity, the bottom of the inner wall of the groove is in a slope shape, and the cavity is used for collecting fallen batting.

Preferably, two vertical brackets are welded in the groove, a torque motor is fixedly arranged on the bracket, a transmission shaft of the torque motor is connected with the end part of the middle shaft, the end part of the upper cross rod is pivoted with the bracket, and the end part of the lower cross rod is connected with the bracket.

(III) beneficial effects

The invention provides a friction magneto-electricity micro-energy collection device for wax printing imitation. The beneficial effects are as follows:

1. the friction magneto-electricity micro-energy collection device for the wax printing is characterized in that a central shaft and an upper cross rod are arranged, cloth passes through the space between the central shaft and the upper cross rod, a plurality of friction blocks are arranged in the upper cross rod in a sliding mode, the friction blocks are provided with friction plates, magnet inserting pieces, iron blocks and conducting wires, static electricity is generated by friction between the iron blocks and the cloth, meanwhile, current is generated by cutting magnetic induction wires through the conducting wires, and the two electric energy is collected. Thereby achieving the effect of micro energy collection. And under the action of the electromagnet module, the iron block moves back and forth and plays a role in scraping the wool and cleaning the miscellaneous wool on the cloth.

Drawings

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

FIG. 2 is a schematic view of a partial structure of the present invention;

FIG. 3 is a schematic view of the upper cross bar structure of the present invention;

FIG. 4 is a schematic view of a friction block according to the present invention;

FIG. 5 is a cross-sectional view of the friction block structure of the present invention;

FIG. 6 is a schematic view of a friction plate according to the present invention;

FIG. 7 is an illustration of the electromagnet module structure of the present invention;

FIG. 8 is a schematic diagram of the internal structure of an electromagnet module according to the present invention;

fig. 9 is an enlarged view of the structure of fig. 8 a in accordance with the present invention.

In the figure: 1 base, 11 grooves, 12 brackets, 13 moment motors, 2 cloth rolls, 3 wind-up rolls, 4 gears, 5 center shafts, 6 upper cross bars, 61 iron bars, 62 springs, 63 tooth grooves, 7 lower cross bars, 71 cavities, 8 friction blocks, 81 friction plates, 82 magnet inserting sheets, 83 through grooves, 84 iron blocks, 85 wires, 86 storage batteries, 9 electromagnet modules, 91 iron sheets, 92 electric coils, 93 singlechips, 94 electric push rods, 10 fixing blocks, 101L cavities, 102 rubber bars and 103 battery plates.

Detailed Description

The embodiment of the invention provides a friction magneto-electricity micro-energy collection device for wax printing imitation, which is shown in figures 1-9, and is used for polishing cloth, and comprises a base 1, wherein a cloth roll 2 is fixedly arranged at the top of the base 1, and the cloth to be treated is wound on the cloth roll 2 in advance.

The bottom of the base 1 is fixedly provided with a wind-up roll 3, the center of the left side of the base 1 is provided with a groove 11, a central shaft 5 is pivoted in the groove 11, an upper cross bar 6 is arranged above the central shaft 5, a lower cross bar 7 is arranged below the central shaft 5, and cloth firstly passes through a gap between the upper cross bar 6 and the central shaft 5 and then passes through a gap between the central shaft 5 and the lower cross bar 7. The rotating shaft 5 rotates to pull the cloth to move. The processed cloth is wound on the wind-up roll 3.

The upper cross rod 6 is provided with a chute which is vertically communicated, a plurality of friction blocks 8 are slidably matched in the chute, an electromagnet module 9 is fixedly arranged on one side, close to each other, of each friction block 8, recesses are formed in the upper side and the lower side of each friction block 8, friction plates 81 are welded in the recesses of the friction blocks 8, a plurality of magnet inserting sheets 82 are fixedly inserted in the friction plates 81, magnetic poles between the adjacent magnet inserting sheets 82 are opposite, a plurality of through grooves 83 are formed in the friction plates 81, and the through grooves 83 are distributed between the adjacent magnet inserting sheets 82.

The magnet inserting piece 82 is slidably matched with an iron block 84, a vertical lead 85 is fixedly arranged on the iron block 84, the iron block 84 moves back and forth to drive the lead 85 to cut a magnetic induction line, and a storage battery 86 is fixedly arranged at the top of the concave inner wall of the friction block 8. The above-mentioned secondary batteries are classified into two types, one for absorbing alternating current and the other for absorbing direct current. Both ends of the lead 85 are electrically connected with the storage battery 86 absorbing the alternating current, and both ends of the iron block 84 are electrically connected with the storage battery 86 absorbing the direct current. The bottom of the iron block 84 is in contact with the cloth.

Working principle: the friction block 8 moves back and forth to sweep off the miscellaneous hair on the cloth. During the back and forth movement of the friction block 8, static electricity is generated by the back and forth movement of the iron block 8 in contact with the cloth, and tiny current is generated by the electronic movement caused by friction, and the current is direct current and is absorbed by one type of storage battery 86. At the same time, as the iron block 84 moves back and forth over the cloth, the wire 85 cuts the magnetically induced wire to produce a small alternating current that is absorbed by another type of battery 86.

The iron rod 61 is welded in the chute of the upper cross rod 6, the iron rod 61 is parallel to the upper cross rod 6, the iron rod 61 penetrates through the friction block 8 and the electromagnet module 9, the springs 62 are welded on the front side and the rear side of the inner wall of the iron rod 61, the friction block 8 positioned at the edge is welded with the springs 62, and the end part of the upper cross rod 6 is provided with the tooth slot 63.

The electromagnet module 9 comprises a shell, an electric coil 92, a single-chip microcomputer 93, an electric push rod 94 and a fixed block 10, wherein the iron rod 61 penetrates through the shell, an iron sheet 91 is welded in the shell, the electric coil 92 is sleeved outside the iron sheet 91, the single-chip microcomputer 93 is fixedly arranged at the top of the inner wall of the shell, the fixed block 10 is fixedly arranged at the bottom of the inner wall of the shell, the fixed end of the electric push rod 94 is fixedly arranged at the bottom of the single-chip microcomputer 93, the movable end of the electric push rod 94 is aligned with the fixed block 10, a button cell is fixedly arranged in the shell, and the button cell is electrically connected with the electric push rod 94 and the single-chip microcomputer 93.

Referring to fig. 8 and 9, an L-shaped cavity 101 is formed in the fixing block 10, the end part of the electric coil 92 extends into the L-shaped cavity 101, two battery plates 103 are arranged between the end parts of the electric coil 92 in the L-shaped cavity 101, the two battery plates 103 are arranged up and down, a rubber rod 102 is fixedly bonded at the movable end of the electric push rod 94, the rubber rod 102 extends into the L-shaped cavity 101, one end of the rubber rod 102, far away from the electric push rod 94, is abutted against the inner wall of the L-shaped cavity 101 and is bent upwards, the positive and negative poles of the two battery plates 103 are opposite, and the end parts of the electric coil 92 can be abutted against the battery plates 103.

A plastic rod is fixedly bonded between the two battery plates 103, and one end, far away from the electric push rod 94, of the rubber rod 102 is highly bonded with the lowest battery plate 103.

Working principle: the uppermost panel 103 in the initial state is abutted with the end of the electric coil 92. The whole circuit is communicated with the electromagnet module 9 to generate a magnetic field. When the direction of the magnetic field of the electromagnetic module 9 needs to be changed, the electric push rod 94 is controlled to extend to push the rubber rod 102 into the L-shaped cavity 101, so that the battery plate 103 is lifted, the uppermost battery plate 103 is far away from the end of the electric coil 92, and the lowermost battery plate 103 is in butt joint with the end of the electric coil 92.

The positive and negative poles of the two battery plates are opposite, so that the magnetic field direction is changed, and the magnetic pole direction of the electromagnet module 9 is realized. So that the friction blocks 8 are close to each other or far away from each other.

The top of the inner wall of the groove 11 is provided with a gear 4 driven by a motor, and the gear 4 is meshed with the tooth groove 63.

The upper cross bar is half embedded in the base 1, and the motor is used for driving the gear 4 to rotate, so that the whole upper cross bar 6 is driven to rotate. Because static electricity is generated by friction, the batting is adsorbed on the surface of the upper cross rod 6, and the batting is contacted with the base 1 through the rotation of the upper cross rod 6, so that the batting is scraped.

The left side of the lower cross bar 7 is provided with a cavity 71, the bottom of the inner wall of the groove 11 is in a slope shape, and the cavity 71 is used for collecting fallen batting. The scraped flock falls on the bottom of the inner wall of the groove 11 and slides into the lower cross bar 7.

Two vertical brackets 12 are welded in the groove 11, a torque motor 13 is fixedly arranged on the brackets 12, a transmission shaft of the torque motor 13 is connected with the end part of the middle shaft 5, the end part of the upper cross rod 6 is pivoted with the brackets 12, and the end part of the lower cross rod 7 is fixedly arranged with the brackets 12.

In summary, the friction magneto-electricity micro-energy collection device for wax printing is provided with the center shaft 5 and the upper cross rod 6, cloth passes through the center shaft and the upper cross rod, a plurality of friction blocks 8 are arranged in the upper cross rod 6 in a sliding mode, the friction blocks 8 are provided with friction plates 81, magnet inserting sheets 82, iron blocks 84 and conducting wires 85, static electricity is generated by friction between the iron blocks 84 and the cloth, meanwhile, the conducting wires 85 cut magnetic induction lines to generate current, and the two electric energy are collected. Thereby achieving the effect of micro energy collection. And under the action of the electromagnet module 9, the iron block 84 moves back and forth to simultaneously play a role in scraping the wool and cleaning the miscellaneous wool on the cloth.

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

1. Friction magneto-electricity micro-energy collection device is used in imitative wax printing polishes cloth, including base (1), its characterized in that: the cloth winding machine is characterized in that a cloth roller (2) is arranged at the top of the base (1), a winding roller (3) is connected to the bottom of the base (1), a groove (11) is formed in the center of the left side of the base (1), a middle shaft (5) is arranged in the groove (11), an upper cross rod (6) is arranged above the middle shaft (5), a lower cross rod (7) is arranged below the middle shaft (5), cloth firstly passes through a gap between the upper cross rod (6) and the middle shaft (5) and then passes through a gap between the middle shaft (5) and the lower cross rod (7);

the upper cross rod (6) is provided with a chute which is vertically communicated, a plurality of friction blocks (8) are slidably matched in the chute, an electromagnet module (9) is arranged on one side, close to each other, of each friction block (8), recesses are formed in the upper side and the lower side of each friction block (8), friction plates (81) are arranged in the recesses of each friction block (8), a plurality of magnet inserting sheets (82) are inserted in the recesses of each friction block (81), magnetic poles between the adjacent magnet inserting sheets (82) are opposite, a plurality of through grooves (83) are formed in each friction plate (81), and the through grooves (83) are distributed among the adjacent magnet inserting sheets (82);

an iron block (84) is slidably matched with the magnet inserting piece (82), a vertical wire (85) is arranged on the iron block (84), the iron block (84) moves back and forth to drive the wire (85) to cut a magnetic induction wire, a storage battery (86) is arranged at the top of the concave inner wall of the friction block (8), the wire (85) and the iron block (84) are respectively electrically connected with the storage battery (86), and the bottom of the iron block (84) is in contact with cloth;

an iron rod (61) is arranged in the chute of the upper cross rod (6), the iron rod (61) is parallel to the upper cross rod (6), the iron rod (61) penetrates through the friction block (8) and the electromagnet module (9), springs (62) are connected to the front side and the rear side of the inner wall of the iron rod (61), the friction block (8) positioned at the edge is connected with the springs (62), and tooth grooves (63) are formed in the end part of the upper cross rod (6);

the electromagnet module (9) comprises a shell, an electric coil (92), a single-chip microcomputer (93), an electric push rod (94) and a fixed block (10), wherein the iron rod (61) penetrates through the shell, an iron sheet (91) is arranged in the shell, the electric coil (92) is sleeved outside the iron sheet (91), the single-chip microcomputer (93) is arranged at the top of the inner wall of the shell, the fixed block (10) is arranged at the bottom of the inner wall of the shell, the fixed end of the electric push rod (94) is arranged at the bottom of the single-chip microcomputer (93), the movable end of the electric push rod (94) is aligned to the fixed block (10), and a button battery is arranged in the shell and is electrically connected with the electric push rod (94) and the single-chip microcomputer (93);

an L-shaped cavity (101) is formed in the fixed block (10), the end part of the electric coil (92) stretches into the L-shaped cavity (101), two battery plates (103) are arranged in the L-shaped cavity (101) and between the end parts of the electric coil (92), the two battery plates (103) are arranged up and down, the movable end of the electric push rod (94) is connected with a rubber rod (102), the rubber rod (102) stretches into the L-shaped cavity (101), one end, far away from the electric push rod (94), of the rubber rod (102) is abutted against the inner wall of the L-shaped cavity (101) to be bent upwards, the positive electrode and the negative electrode of the two battery plates (103) are opposite, and the end part of the electric coil (92) can be abutted with the battery plates (103);

a plastic rod is connected between the two battery plates (103), and one end, far away from the electric push rod (94), of the rubber rod (102) is connected with the lowest battery plate (103).

2. The friction magneto-electricity micro-energy collection device for wax printing imitation according to claim 1, wherein the friction magneto-electricity micro-energy collection device is characterized in that: the top of the inner wall of the groove (11) is provided with a gear (4) driven by a motor, and the gear (4) is meshed with the tooth groove (63).

3. The friction magneto-electricity micro-energy collection device for wax printing imitation according to claim 2, wherein the friction magneto-electricity micro-energy collection device is characterized in that: the left side of the lower cross rod (7) is provided with a cavity (71), the bottom of the inner wall of the groove (11) is in a slope shape, and the cavity (71) is used for collecting and falling into the batting.

4. A friction magneto-electricity micro energy collection device for wax printing imitation according to claim 3, wherein: two vertical supports (12) are welded in the groove (11), a torque motor (13) is fixedly installed on the supports (12), a transmission shaft of the torque motor (13) is connected with the end part of the center shaft (5), the end part of the upper cross rod (6) is pivoted with the supports (12), and the end part of the lower cross rod (7) is connected with the supports (12).