CN111778663A - Fabric resin treatment equipment - Google Patents

Abstract

The invention relates to the field of textiles, in particular to a fabric resin treatment device, wherein the fabric resin treatment can provide a plurality of excellent performances to the fabric, and can enable the fabric to obtain crease resistance, shrinkproof performance, non-ironing performance, durable ironing performance, flame resistance, good luster, comfortable hand feeling and other performances, the traditional treatment device is treated by a plurality of devices, the automation degree and the smooth process degree are too low, the device solves the problems, the fabric is placed in a vibration box filled with resin, the vibration box vibrates in a reciprocating mode to promote the resin to be fully impregnated into fabric fibers, the fabric passes through a rolling roller, a fabric channel and a conveying roller after impregnation is finished, a heating column is opened, the heating column dissipates heat to promote the resin to be condensed among the fabric fibers, the rolling roller and the conveying roller are controlled to rotate, the fabric slowly and slowly moves in a drying chamber, the fabric falls into a cleaning chamber after being dried, the resin residue is washed by reciprocating positive and negative rotation washing.

Description

Fabric resin treatment equipment

Technical Field

The invention relates to the field of spinning, in particular to a fabric resin treatment device.

Background

The resin treatment of the fabric can provide a plurality of excellent performances for the fabric, and the fabric can obtain the performances of crease resistance, shrinkproof performance, non-ironing performance, durable press ironing performance, flame resistance, good luster, comfortable hand feeling and the like.

Disclosure of Invention

The invention aims to provide fabric resin treatment equipment which can be used for better impregnating resin into fabrics by oscillation, rolling and drying the impregnated fabrics, and automatically dropping the dried fabrics into a cleaning chamber to clean resin residues.

The purpose of the invention is realized by the following technical scheme:

the utility model provides a fabric resin treatment facility, is including shaking the assembly, stoving assembly and washing assembly, stoving assembly, washing assembly all are connected with shaking the assembly, and stoving assembly is connected with washing assembly

As a further optimization of the technical scheme, the vibration assembly comprises a bottom plate, a motor shaft bracket, a motor shaft, a spring I, a vibration box, a belt wheel I, a belt I, a tension belt wheel, a belt wheel II, a tension belt wheel shaft, a tension belt wheel bracket, a sliding cylinder, a sliding column, a tension spring fixing plate, a vibration shaft bracket, an eccentric block, a friction block and a ball head friction column, wherein the motor is connected with the bottom plate, the motor is connected with the motor shaft, the motor shaft is rotatably connected with the motor shaft bracket, the motor shaft bracket is connected with the bottom plate, two ends of the spring I are respectively connected with the vibration box and the bottom plate, the motor shaft is connected with the belt wheel I, the belt wheel I is connected with the tension belt wheel and the belt wheel II through the belt I, the belt wheel is connected with the belt wheel shaft, the tension belt wheel shaft is rotatably connected, extension spring both ends are connected with tensioning band pulley support, extension spring fixed plate respectively, and the extension spring is in tensile state, and the traveller is connected with the extension spring fixed plate, and the extension spring fixed plate is connected with the bottom plate, and band pulley II is connected with the shock axle, vibrates the axle and vibrates the axle support rotation and be connected, vibrates the axle support and vibrate the case and be connected, vibrates the axle and is connected with the eccentric block, and six clutch blocks are connected with bottom plate, vibration case respectively, and three bulb friction post both ends are connected with six clutch block cooperations respectively.

As a further optimization of the technical scheme, the drying assembly comprises a bevel gear I, a bevel gear II shaft bracket, a clutch box, an operating rod bracket, a clutch disc I, an output shaft, a sliding barrel, a ball groove, a clutch disc II, a shifting ball, a shifting bracket, a clutch operating rod, a belt wheel III, a belt II, a belt wheel IV shaft, a bracket I, a drying chamber support leg, a gear I, a gear II shaft, a rolling roller, a belt wheel V, a belt wheel III, a belt wheel VI shaft, a bracket II, a gear III, a gear IV shaft, a conveying roller, a fabric channel, a turntable shaft, a connecting rod I, a connecting rod II, a sliding shaft I, a door opening and closing bracket, a sliding shaft II, a sliding rail I, a sliding rail II, a heating column, a drying chamber door and a sliding, the bevel gear II is connected with a bevel gear II shaft, the bevel gear II shaft is connected with a bevel gear II shaft bracket and a clutch box in a rotating way, the bevel gear II shaft bracket and the clutch box are connected with a bottom plate, the bevel gear II shaft is connected with a clutch disc I, an output shaft is connected with the clutch box in a rotating way, the output shaft is connected with a sliding barrel in a sliding way, a ball groove is positioned on the sliding barrel, the sliding barrel is connected with the clutch disc II, a poking ball is connected with the ball groove in a sliding way, the ball groove is connected with a poking frame, the poking frame is connected with a clutch control lever, the clutch control lever is hinged with a control lever bracket, the control lever bracket is connected with the clutch box, the output shaft is connected with a belt wheel III, the belt wheel III is connected with a belt wheel IV through a belt II, the belt wheel IV is connected with a belt wheel IV shaft, the belt wheel IV shaft is connected, a gear I is meshed with a gear II, the gear II is connected with a gear II shaft, the gear II shaft is rotatably connected with a bracket I, a belt wheel IV shaft and a gear II shaft are respectively connected with two rolling rollers, the gear II shaft is connected with a belt wheel V, the belt wheel V is connected with a belt wheel VI through a belt III, the belt wheel VI is connected with a belt wheel VI shaft, the belt wheel VI shaft is rotatably connected with a bracket II, the bracket II is connected with a drying chamber, the belt wheel VI shaft is connected with a gear III, the gear III is meshed with a gear IV, the gear IV is connected with a gear IV shaft, the gear IV shaft is rotatably connected with a bracket II, the belt wheel VI shaft and the gear IV shaft are respectively connected with two conveying rollers, two fabric passages are respectively positioned at two sides of the drying chamber, a turntable is connected with a turntable shaft, the turntable and the turntable shaft are rotatably connected with the drying chamber, the turntable shaft is connected with a connecting rod I, and the, connecting rod II rotates with sliding shaft I to be connected, sliding shaft I rotates with two switch door supports to be connected, two switch door supports all are connected with the stoving room door, stoving room door and drying chamber clearance fit, two switch door supports are connected with two sliding shaft II respectively, two sliding shaft II respectively with I sliding connection of two slide rails, I both ends of sliding shaft respectively with two slide rails I, II sliding connection of two slide rails, two slide rails I, two slide rails II are located two slide rail boards respectively, two slide rail boards are connected with the drying chamber both sides wall respectively, the post that generates heat is connected with the drying chamber.

As a further optimization of the technical scheme, the cleaning assembly comprises a bevel gear III, a bevel gear IV shaft, a cleaning chamber, cleaning chamber support legs, a screen, a half-gear disc, straight gears, straight gear shafts and fan blades, wherein a motor shaft is connected with the bevel gear III, the bevel gear III is meshed with the bevel gear IV, the bevel gear IV is connected with the bevel gear IV shaft, the bevel gear IV shaft is connected with a bottom plate and the cleaning chamber, the screen is connected with the cleaning chamber in a sliding manner, the cleaning chamber is connected with the cleaning chamber support legs, the cleaning chamber support legs are connected with the bottom plate, the bevel gear IV shaft is connected with the half-gear disc, the half-gear disc is meshed with two straight gears, the two straight gears are respectively connected with the two straight gear shafts, the two straight gear shafts are rotationally connected with the cleaning chamber.

The fabric resin treatment equipment has the beneficial effects that: the method comprises the steps of putting a fabric into a vibration box filled with resin, enabling the vibration box to vibrate in a reciprocating mode to promote the resin to be fully impregnated into fabric fibers, enabling the fabric to pass through a rolling roller, a fabric channel and a conveying roller after impregnation is finished, starting a heating column, enabling the heating column to dissipate heat to promote the resin to condense among the fabric fibers, controlling the rolling roller and the conveying roller to rotate, enabling the fabric to slowly and slowly move in a drying chamber, enabling the fabric to fall into a cleaning chamber after being dried, and cleaning resin residues through reciprocating forward and reverse rotation cleaning.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

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

FIG. 2 is a first structural schematic diagram of the oscillating assembly 1 according to the present invention;

FIG. 3 is a schematic structural diagram of an oscillating assembly 1 according to the present invention;

FIG. 4 is a third schematic structural diagram of the oscillating assembly 1 of the present invention;

FIG. 5 is a partial cross-sectional view of the oscillating assembly 1 of the present invention;

FIG. 6 is a first schematic structural diagram of the drying assembly 2 of the present invention;

FIG. 7 is a second schematic structural view of the drying assembly 2 of the present invention;

FIG. 8 is a third schematic structural view of the drying assembly 2 of the present invention;

FIG. 9 is a fourth schematic structural view of the drying assembly 2 of the present invention;

FIG. 10 is a partial cross-sectional view of the drying assembly 2 of the present invention;

FIG. 11 is a schematic structural diagram of a drying assembly 2 according to the present invention;

fig. 12 is a sixth schematic structural view of the drying assembly 2 of the present invention;

fig. 13 is a seventh structural schematic view of the drying assembly 2 of the present invention;

fig. 14 is an eighth schematic structural view of the drying assembly 2 of the present invention;

fig. 15 is a schematic structural diagram nine of the drying assembly 2 of the present invention;

FIG. 16 is a first schematic view of the structure of the cleaning assembly 3 of the present invention;

FIG. 17 is a second schematic structural view of the cleaning assembly 3 of the present invention;

fig. 18 is a third schematic structural view of the cleaning assembly 3 of the present invention.

In the figure: an oscillating assembly 1; a bottom plate 1-1; a motor 1-2; motor shaft support 1-3; 1-4 of a motor shaft; 1-5 parts of a spring I; 1-6 of a vibration box; 1-7 belt wheels; 1-8 parts of a belt I; tensioning belt wheels 1-9; 1-10 belt wheels; tensioning belt wheels 1-11; tensioning belt wheel brackets 1-12; 1-13 of a slide cylinder; 1-14 of a sliding column; 1-15 of a tension spring; a tension spring fixing plate 1-16; oscillating shafts 1-17; oscillating shaft supports 1-18; eccentric blocks 1-19; 1-20 parts of friction block; 1-21 parts of a ball head friction column; drying the combined body 2; a bevel gear I2-1; a bevel gear II 2-2; 2-3 of a bevel gear II; 2-4 shaft supports of a bevel gear II; 2-5 of a clutch box; a joystick mount 2-6; 2-7 parts of a clutch disc; 2-8 parts of an output shaft; 2-9 parts of a slide cylinder; 2-10 parts of ball grooves; 2-11 parts of a clutch disc; 2-12 of ball poking; 2-13 of a poking frame; clutch operating rods 2-14; 2-15 of belt wheel III; 2-16 parts of a belt II; belt pulleys IV 2-17; 2-18 of belt wheel IV shaft; 2-19 of a bracket I; 2-20 parts of a drying chamber; drying chamber support legs 2-21; 2-22 parts of a gear I; gears II 2-23; 2-24 of a gear II shaft; 2-25 of rolling roller; pulleys V2-26; belts III 2 to 27; a pulley VI 2-28; 2-29 of a belt wheel VI shaft; 2-30 parts of a bracket II; gears III 2 to 31; 2-32 parts of a gear IV; 2-33 parts of gear IV shaft; conveying rollers 2-34; fabric channels 2-35; 2-36 of a rotary table; turntable shafts 2-37; 2-38 of a connecting rod; a connecting rod II 2-39; 2-40 parts of a sliding shaft I; a door opening and closing bracket 2-41; 2-42 of a sliding shaft; 2-43 of a slide rail; sliding rails II 2-44; 2-45 parts of heating column; drying chamber doors 2-46; 2-47 of slide rail plates; a cleaning assembly 3; bevel gears III 3-1; bevel gears IV 3-2; a bevel gear IV shaft 3-3; 3-4 of a cleaning chamber; 3-5 parts of a cleaning chamber support leg; 3-6 of a screen mesh; 3-7 parts of a half gear disc; 3-8 parts of straight gears; 3-9 parts of a straight gear shaft; and 3-10 parts of fan blades.

Detailed Description

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

The fixed connection in the device is realized by fixing in modes of welding, thread fixing and the like, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to achieve axial fixation of the bearing and achieve rotation; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail, and the sliding groove or the guide rail is generally in a step shape, so that the sliding block is prevented from falling off in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.

The first embodiment is as follows:

the present embodiment is described below with reference to fig. 1 to 18, and a fabric resin treatment apparatus includes an oscillating assembly 1, a drying assembly 2, and a cleaning assembly 3, where the drying assembly 2 and the cleaning assembly 3 are both connected to the oscillating assembly 1, and the drying assembly 2 is connected to the cleaning assembly 3.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1-18, and the embodiment further describes the first embodiment, the oscillating assembly 1 includes a bottom plate 1-1, a motor 1-2, a motor shaft bracket 1-3, a motor shaft 1-4, a spring i 1-5, an oscillating box 1-6, a pulley i 1-7, a belt i 1-8, a tension pulley 1-9, a pulley ii 1-10, a tension pulley shaft 1-11, a tension pulley bracket 1-12, a sliding cylinder 1-13, a sliding column 1-14, a tension spring 1-15, a tension spring fixing plate 1-16, an oscillating shaft 1-17, an oscillating shaft bracket 1-18, an eccentric block 1-19, a friction block 1-20, and a ball head friction column 1-21, the motor 1-2 is connected with the bottom plate 1-1, the motor 1-2 is connected with the motor shaft 1-4, the motor shaft 1-4 is rotationally connected with the motor shaft support 1-3, the motor shaft support 1-3 is connected with the bottom plate 1-1, the spring I1-5 is respectively connected with the oscillation box 1-6 and the bottom plate 1-1 at two ends, the motor shaft 1-4 is connected with the belt wheel I1-7, the belt wheel I1-7 is connected with the tensioning belt wheel 1-9 and the belt wheel II 1-10 through the belt I1-8, the tensioning belt wheel 1-9 is connected with the tensioning belt wheel shaft 1-11, the tensioning belt wheel shaft 1-11 is rotationally connected with the tensioning belt wheel support 1-12, the tensioning belt wheel support 1-12 is connected with the sliding cylinder 1-13, the sliding cylinder 1-13 is slidably connected with the sliding column 1-14, and the tension spring 1-15 is respectively connected with the tensioning belt wheel support 1-, The tension spring fixing plates 1-16 are connected, the tension springs 1-15 are in a stretching state, the sliding columns 1-14 are connected with the tension spring fixing plates 1-16, the tension spring fixing plates 1-16 are connected with the bottom plate 1-1, the belt wheels II 1-10 are connected with the oscillating shafts 1-17, the oscillating shafts 1-17 are rotatably connected with the oscillating shaft supports 1-18, the oscillating shaft supports 1-18 are connected with the oscillating boxes 1-6, the oscillating shafts 1-17 are connected with the eccentric blocks 1-19, the six friction blocks 1-20 are respectively connected with the bottom plate 1-1 and the oscillating boxes 1-6, two ends of the three ball head friction columns 1-21 are respectively connected with the six friction blocks 1-20 in a matching mode, and resin can be better impregnated into fabrics in an oscillating mode.

The third concrete implementation mode:

the embodiment will be described with reference to fig. 1-18, and the embodiment will be further described, wherein the drying assembly 2 comprises a bevel gear i 2-1, a bevel gear ii 2-2, a bevel gear ii shaft 2-3, a bevel gear ii shaft bracket 2-4, a clutch box 2-5, a control lever bracket 2-6, a clutch disc i 2-7, an output shaft 2-8, a sliding cylinder 2-9, a ball groove 2-10, a clutch disc ii 2-11, a shifting ball 2-12, a shifting bracket 2-13, a clutch control lever 2-14, a belt wheel iii 2-15, a belt ii 2-16, a belt wheel iv 2-17, a belt wheel iv shaft 2-18, a bracket i 2-19, a drying chamber 2-20, a drying chamber support leg 2-21, a gear i 2-22, a gear ii 2-23, a belt pulley iv 2-17, a belt wheel iv shaft 2-, 2-24 parts of gear II shaft, 2-25 parts of rolling roller, 2-26 parts of belt wheel V, 2-27 parts of belt III, 2-28 parts of belt wheel VI, 2-29 parts of belt wheel VI, 2-30 parts of support II, 2-31 parts of gear III, 2-32 parts of gear IV shaft, 2-33 parts of gear IV shaft, 2-34 parts of conveying roller, 2-35 parts of fabric channel, 2-36 parts of rotary table, 2-37 parts of rotary table shaft, 2-38 parts of connecting rod I, 2-39 parts of connecting rod II, 2-40 parts of sliding shaft I, 2-41 parts of door opening and closing support, 2-42 parts of sliding shaft II, 2-43 parts of sliding rail I, 2-44 parts of sliding rail II, 2-45 parts of heating column, 2-46 parts of drying chamber door and 2-47 parts of sliding rail plate, 1-4 parts of motor shaft is connected with I2-1 part of bevel gear I, the bevel gear II 2-2 is connected with a bevel gear II shaft 2-3, the bevel gear II shaft 2-3 is rotationally connected with a bevel gear II shaft support 2-4 and a clutch box 2-5, the bevel gear II shaft support 2-4 and the clutch box 2-5 are connected with a bottom plate 1-1, the bevel gear II shaft 2-3 is connected with a clutch disc I2-7, an output shaft 2-8 is rotationally connected with the clutch box 2-5, the output shaft 2-8 is in sliding connection with a sliding barrel 2-9, a ball groove 2-10 is positioned on the sliding barrel 2-9, the sliding barrel 2-9 is connected with a clutch disc II 2-11, a poking ball 2-12 is in sliding connection with the ball groove 2-10, the ball groove 2-10 is connected with a poking frame 2-13, the poking frame 2-13 is connected with a clutch control lever 2-14, the clutch control lever 2-14 is hinged with the control lever bracket 2-6, the control lever bracket 2-6 is connected with the clutch box 2-5, the output shaft 2-8 is connected with the belt wheel III 2-15, the belt wheel III 2-15 is connected with the belt wheel IV 2-17 through the belt II 2-16, the belt wheel IV 2-17 is connected with the belt wheel IV shaft 2-18, the belt wheel IV shaft 2-18 is rotatably connected with the bracket I2-19, the bracket I2-19 is connected with the drying chamber 2-20, the drying chamber 2-20 is connected with the drying chamber support leg 2-21, the drying chamber support leg 2-21 is connected with the bottom plate 1-1, the belt wheel IV shaft 2-18 is connected with the gear I2-22, the gear I2-22 is meshed with the gear II 2-23, the gear II 2-23 is connected with the gear II shaft 2-24, the gear II shaft 2-24 is rotationally connected with a bracket I2-19, the belt wheel IV shaft 2-18 and the gear II shaft 2-24 are respectively connected with two rolling rollers 2-25, the gear II shaft 2-24 is connected with a belt wheel V2-26, the belt wheel V2-26 is connected with a belt wheel VI 2-28 through a belt III 2-27, the belt wheel VI 2-28 is connected with a belt wheel VI shaft 2-29, the belt wheel VI shaft 2-29 is rotationally connected with a bracket II 2-30, the bracket II 2-30 is connected with a drying chamber 2-20, the belt wheel VI shaft 2-29 is connected with a gear III 2-31, the gear III 2-31 is meshed with a gear IV 2-32, the gear IV 2-32 is connected with a gear IV shaft 2-33, the gear IV shaft 2-33 is rotationally connected with a bracket II 2-30, a wheel VI shaft 2-29 and a gear IV shaft 2-33 are respectively connected with two conveying rollers 2-34, two fabric channels 2-35 are respectively positioned at two sides of a drying chamber 2-20, a rotary disc 2-36 is connected with a rotary disc shaft 2-37, the rotary disc 2-36 and the rotary disc shaft 2-37 are rotatably connected with the drying chamber 2-20, the rotary disc shaft 2-37 is connected with a connecting rod I2-38, the connecting rod I2-38 is hinged with a connecting rod II 2-39, the connecting rod II 2-39 is rotatably connected with a sliding shaft I2-40, the sliding shaft I2-40 is rotatably connected with two door opening and closing supports 2-41, the two door opening and closing supports 2-41 are both connected with a drying chamber door 2-46, the drying chamber 2-46 is in clearance fit with the drying chamber 2-20, the two door opening and closing supports 2-41 are respectively connected with two sliding shafts II 2-42, the two sliding shafts II 2-42 are respectively connected with the two sliding rails I2-43 in a sliding mode, two ends of each sliding shaft I2-40 are respectively connected with the two sliding rails I2-43 and the two sliding rails II 2-44 in a sliding mode, the two sliding rails I2-43 and the two sliding rails II 2-44 are respectively located on the two sliding rail plates 2-47, the two sliding rail plates 2-47 are respectively connected with two side walls of the drying chamber 2-20, the heating columns 2-45 are connected with the drying chamber 2-20, and impregnated fabrics can be rolled and dried.

The fourth concrete implementation mode:

the embodiment is described below by combining with figures 1-18, and the embodiment further describes the first embodiment, the cleaning assembly 3 comprises bevel gears III 3-1, bevel gears IV 3-2, bevel gears IV shafts 3-3, cleaning chambers 3-4, cleaning chamber support legs 3-5, screens 3-6, half gear discs 3-7, straight gears 3-8, straight gear shafts 3-9 and fan blades 3-10, the motor shafts 1-4 are connected with the bevel gears III 3-1, the bevel gears III 3-1 are meshed with the bevel gears IV 3-2, the bevel gears IV 3-2 are connected with the bevel gears IV shafts 3-3, the bevel gears IV shafts 3-3 are rotatably connected with a bottom plate 1-1 and the cleaning chambers 3-4, the screens 3-6 are slidably connected with the cleaning chambers 3-4, the cleaning chamber 3-4 is connected with a cleaning chamber support leg 3-5, the cleaning chamber support leg 3-5 is connected with a bottom plate 1-1, a bevel gear IV shaft 3-3 is connected with a half gear disc 3-7, the half gear disc 3-7 is in meshed connection with two straight gears 3-8, the two straight gears 3-8 are respectively connected with two straight gear shafts 3-9, the two straight gear shafts 3-9 are rotatably connected with the cleaning chamber 3-4, the two straight gear shafts 3-9 are respectively connected with two fan blades 3-10, and the dried fabric automatically falls into the cleaning chamber to clean resin residues.

The invention relates to a fabric resin treatment device, which has the working principle that: starting a motor 1-2, wherein the motor 1-2 drives a motor shaft 1-4 to rotate, the motor shaft 1-4 drives a belt wheel I1-7 to rotate, the belt wheel I1-7 drives a tension belt wheel 1-9 and a belt wheel II 1-10 to rotate through a belt I1-8, the belt wheel II 1-10 drives an oscillation shaft 1-17 to rotate, the oscillation shaft 1-17 drives an eccentric block 1-19 to rotate, the eccentric block 1-19 rotates to generate vibration, the oscillation shaft 1-17 and an oscillation shaft bracket 1-18 drive an oscillation box to generate vibration, a spring I1-5 supports the oscillation box 1-6, the oscillation shaft 1-17 vibrates to drive the belt wheel II 1-10 to vibrate, the belt wheel II 1-10 drives a belt I1-8 to contract and expand in a reciprocating manner, and the belt I1-8 drives the belt wheel 1-9 to rotate through the tension belt wheel 1, The tensioning belt wheel shaft 1-11 and the tensioning belt wheel support 1-12 drive the sliding cylinder 1-13 to slide on the sliding column 1-14, the tension spring 1-15 drives the tensioning belt wheel support 1-12, the tensioning belt wheel shaft 1-11 and the tensioning belt wheel 1-9 to slide in a reciprocating manner by pulling the sliding cylinder, the tensioning belt wheel 1-9 can always tension the belt I1-8 to keep normal transmission motion, the oscillation box 1-6 drives the friction block 1-20 to vibrate, the friction block 1-20 drives the ball head friction column 1-21 to rotate in the two friction blocks 1-20, the friction force of the friction blocks 1-20 and the ball head friction column 1-21 limits the vibration amplitude of the oscillation box 1-6, the resin can be better impregnated into the fabric fiber by keeping low-amplitude high-frequency vibration, after impregnation is finished, rotating the turntables 2-36, the turntables 2-36 drive the turntable shafts 2-37 to rotate, the turntable shafts 2-37 drive the connecting rods I2-38 to rotate, the connecting rods I2-38 drive the hinged connecting rods II 2-39 to move, the connecting rods II 2-39 drive the sliding shafts I2-40 to slide in the sliding rails I2-43, the sliding shafts I2-40 drive the two sliding shafts II 2-42 to slide in the two sliding rails I2-43 through the two door opening and closing supports 2-41, the two door opening and closing supports 2-41 drive the drying chamber doors 2-46 to slide out of the drying chamber 2-20, when the two sliding shafts II 2-42 slide to the ends of the two sliding rails I2-43, the sliding shafts I2-40 slide to the intersection of the two sliding rails I2-43 and the two sliding rails II 2-44, the two sliding shafts II 2-42 rotate in the two sliding rails I2-43, the connecting rod II 2-39 drives the sliding shaft I2-40 to slide into the two sliding rails II 2-44, the sliding shaft I2-40 drives the two door opening and closing supports 2-41 to turn over, the two door opening and closing supports 2-41 drive the drying chamber door 2-46 to turn over, at the moment, the drying chamber 2-20 is not blocked by the drying chamber door 2-46, the fabric passes through the two rolling rollers 2-25, the fabric channel 2-35 and the conveying rollers 2-34, the rolling rollers 2-25 roll out the residual resin on the fabric and fall into the vibration box 1-6, the rotating disc 2-36 is rotated reversely again, the transmission process is repeated, the drying chamber door 2-46 is reset, the heating columns 2-45 are opened, the heating columns 2-45 begin to emit heat to promote the condensation of the resin among fabric fibers, and after the fabric in the drying box is dried, the clutch operating lever 2-14 is pushed, the clutch operating lever 2-14 rotates around a hinged shaft with the operating lever bracket 2-6, the clutch operating lever 2-14 drives a shifting frame 2-13 and a shifting ball 2-12 to rotate, the shifting ball 2-12 drives a sliding barrel 2-9 to slide on an output shaft 2-8 through a shifting ball groove 2-10, the sliding barrel 2-9 drives a clutch disc II 2-11 to be buckled with a clutch disc I2-7, a motor 1-2 is started, the motor 1-2 drives a motor shaft 1-4 to rotate, the motor shaft 1-4 drives a bevel gear I2-1 to rotate, the bevel gear I2-1 drives a bevel gear II 2-2 to rotate, the bevel gear II 2-2 drives a bevel gear II shaft 2-3 to rotate, and the bevel gear II shaft 2-3 drives the clutch disc I2-7 to rotate, the clutch disc I2-7 drives the clutch disc II 2-11 to rotate, the clutch disc II 2-11 drives the sliding barrel 2-9 to rotate, the sliding barrel 2-9 drives the output shaft 2-8 to rotate, the output shaft 2-8 drives the belt wheel III 2-15 to rotate, the belt wheel III 2-15 drives the belt wheel IV 2-17 to rotate at a reduced speed through the belt II 2-16, the belt wheel IV 2-17 drives the belt wheel IV shaft 2-18 to rotate, the belt wheel IV shaft 2-18 drives the gear I2-22 to rotate, the gear I2-22 drives the gear II 2-23 to rotate, the gear II 2-23 drives the gear II shaft 2-24 to rotate, the gear II shaft 2-24 and the belt wheel IV shaft 2-18 respectively drive the two rolling rollers 2-25 to rotate slowly and oppositely, the gear II shaft 2-24 drives the belt wheel V2-26 to rotate, the belt wheel V2-26 drives the belt wheel VI 2-28 to rotate through a belt III 2-27, the belt wheel VI 2-28 drives the belt wheel VI shaft 2-29 to rotate, the belt wheel VI shaft 2-29 drives the gear III 2-31 to rotate, the gear III 2-31 drives the gear IV 2-32 to rotate, the gear IV 2-32 drives the gear IV shaft 2-33 to rotate, the belt wheel VI shaft 2-29 and the gear IV shaft 2-33 respectively drive the two conveying rollers 2-34 to rotate slowly and oppositely, the two conveying rollers 2-34 and the two rolling rollers 2-25 drive the fabric to be dried and slowly moved by the drying chamber 2-20 through the fabric channel 2-35, the fabric is discharged by the two conveying rollers 2-34 and falls into the cleaning chamber 3-4, and the motor shaft 1-4 drives the bevel gear III 3-1 to rotate, the bevel gear III 3-1 drives a bevel gear IV 3-2 to rotate, the bevel gear IV 3-2 drives a bevel gear IV shaft 3-3 to rotate, the bevel gear IV shaft 3-3 drives a half gear disc 3-7 to rotate, the half gear disc 3-7 drives two straight gears 3-8 to rotate alternately, the two straight gears 3-8 drive two straight gear shafts 3-9 to rotate alternately, the two straight gear shafts 3-9 drive two blades 3-10 to rotate alternately, the two blades alternately stir cleaning liquid, the rotation center of the cleaning liquid is alternately changed to drive the fabric to reciprocate in the cleaning liquid, the cleaning effect is good, and the resin residue on the surface of the fabric is cleaned, so that the resin treatment of the fabric is completed.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (4)

1. The utility model provides a fabric resin treatment facility, includes and shakes assembly (1), stoving assembly (2) and washs assembly (3), its characterized in that: the drying assembly (2) and the cleaning assembly (3) are both connected with the oscillating assembly (1), and the drying assembly (2) is connected with the cleaning assembly (3).

2. A fabric resing apparatus according to claim 1, characterized in that: the vibration assembly (1) comprises a bottom plate (1-1), a motor (1-2), a motor shaft support (1-3), a motor shaft (1-4), a spring I (1-5), a vibration box (1-6), a belt wheel I (1-7), a belt I (1-8), a tension belt wheel (1-9), a belt wheel II (1-10), a tension belt wheel shaft (1-11), a tension belt wheel support (1-12), a sliding cylinder (1-13), a sliding column (1-14), a tension spring (1-15), a tension spring fixing plate (1-16), a vibration shaft (1-17), a vibration shaft support (1-18), an eccentric block (1-19), a friction block (1-20) and a ball head friction column (1-21), wherein the motor (1-2) is connected with the bottom plate (1-1), the motor (1-2) is connected with the motor shaft (1-4), the motor shaft (1-4) is rotationally connected with the motor shaft bracket (1-3), the motor shaft bracket (1-3) is connected with the bottom plate (1-1), two ends of the spring I (1-5) are respectively connected with the oscillation box (1-6) and the bottom plate (1-1), the motor shaft (1-4) is connected with the belt wheel I (1-7), the belt wheel I (1-7) is connected with the tensioning belt wheel (1-9) and the belt wheel II (1-10) through the belt I (1-8), the tensioning belt wheel (1-9) is connected with the tensioning belt wheel shaft (1-11), the tensioning belt wheel shaft (1-11) is rotationally connected with the tensioning belt wheel bracket (1-12), the tensioning belt wheel bracket (1-12) is connected with the sliding barrel (1-13), the sliding cylinder (1-13) is connected with the sliding column (1-14) in a sliding mode, two ends of a tension spring (1-15) are respectively connected with a tension belt wheel support (1-12) and a tension spring fixing plate (1-16), the tension spring (1-15) is in a stretching state, the sliding column (1-14) is connected with the tension spring fixing plate (1-16), the tension spring fixing plate (1-16) is connected with a bottom plate (1-1), a belt wheel (1-10) is connected with a vibration shaft (1-17), the vibration shaft (1-17) is rotatably connected with a vibration shaft support (1-18), the vibration shaft support (1-18) is connected with a vibration box (1-6), the vibration shaft (1-17) is connected with an eccentric block (1-19), and six friction blocks (1-20) are respectively connected with the bottom plate (1-1), The oscillating boxes (1-6) are connected, and two ends of the three ball head friction columns (1-21) are respectively connected with the six friction blocks (1-20) in a matching manner.

3. A fabric resing apparatus according to claim 1, characterized in that: the drying assembly (2) comprises a bevel gear I (2-1), a bevel gear II (2-2), a bevel gear II shaft (2-3), a bevel gear II shaft support (2-4), a clutch box (2-5), a control lever support (2-6), a clutch disc I (2-7), an output shaft (2-8), a sliding barrel (2-9), a ball groove (2-10), a clutch disc II (2-11), a shifting ball (2-12), a shifting frame (2-13), a clutch control lever (2-14), a belt wheel III (2-15), a belt II (2-16), a belt wheel IV (2-17), a belt wheel IV shaft (2-18), a support I (2-19), a drying chamber (2-20), a drying chamber support leg (2-21), a gear I (2-22), Gear II (2-23), gear II shaft (2-24), rolling roller (2-25), belt wheel V (2-26), belt III (2-27), belt wheel VI (2-28), belt wheel VI shaft (2-29), support II (2-30), gear III (2-31), gear IV (2-32), gear IV shaft (2-33), conveying roller (2-34), fabric channel (2-35), rotary table (2-36), rotary table shaft (2-37), connecting rod I (2-38), connecting rod II (2-39), sliding shaft I (2-40), door opening and closing support (2-41), sliding shaft II (2-42), sliding rail I (2-43), sliding rail II (2-44), heating column (2-45), A drying room door (2-46) and a sliding rail plate (2-47), a motor shaft (1-4) is connected with a bevel gear I (2-1), the bevel gear I (2-1) is meshed with a bevel gear II (2-2), the bevel gear II (2-2) is connected with a bevel gear II shaft (2-3), the bevel gear II shaft (2-3) is connected with a bevel gear II shaft bracket (2-4) and a clutch box (2-5) in a rotating way, the bevel gear II shaft bracket (2-4) and the clutch box (2-5) are connected with a bottom plate (1-1), the bevel gear II shaft (2-3) is connected with a clutch disc I (2-7), an output shaft (2-8) is connected with the clutch box (2-5) in a rotating way, the output shaft (2-8) is connected with a sliding barrel (2-9) in a sliding way, the ball groove (2-10) is positioned on the sliding barrel (2-9), the sliding barrel (2-9) is connected with a clutch disc II (2-11), the ball shifting (2-12) is connected with the ball groove (2-10) in a sliding way, the ball groove (2-10) is connected with a shifting frame (2-13), the shifting frame (2-13) is connected with a clutch control lever (2-14), the clutch control lever (2-14) is hinged with a control lever bracket (2-6), the control lever bracket (2-6) is connected with a clutch box (2-5), an output shaft (2-8) is connected with a belt wheel III (2-15), the belt wheel III (2-15) is connected with a belt wheel IV (2-17) through a belt II (2-16), the belt wheel IV (2-17) is connected with a belt wheel IV shaft (2-18), the pulley IV shaft (2-18) is rotatably connected with a support I (2-19), the support I (2-19) is connected with a drying chamber (2-20), the drying chamber (2-20) is connected with drying chamber support legs (2-21), the drying chamber support legs (2-21) are connected with a bottom plate (1-1), the pulley IV shaft (2-18) is connected with a gear I (2-22), the gear I (2-22) is meshed with a gear II (2-23), the gear II (2-23) is connected with a gear II shaft (2-24), the gear II shaft (2-24) is rotatably connected with the support I (2-19), the pulley IV shaft (2-18) and the gear II shaft (2-24) are respectively connected with two rolling rollers (2-25), the gear II shaft (2-24) is connected with a pulley V (2-26), the belt wheel V (2-26) is connected with a belt wheel VI (2-28) through a belt III (2-27), the belt wheel VI (2-28) is connected with a belt wheel VI shaft (2-29), the belt wheel VI shaft (2-29) is rotationally connected with a support II (2-30), the support II (2-30) is connected with a drying chamber (2-20), the belt wheel VI shaft (2-29) is connected with a gear III (2-31), the gear III (2-31) is in meshing connection with a gear IV (2-32), the gear IV (2-32) is connected with a gear IV shaft (2-33), the gear IV shaft (2-33) is rotationally connected with the support II (2-30), the belt wheel VI shaft (2-29) and the gear IV shaft (2-33) are respectively connected with two conveying rollers (2-34), two fabric channels (2-35) are respectively positioned at two sides of a drying chamber (2-20), turntables (2-36) are connected with turnplate shafts (2-37), turnplates (2-36) and turnplate shafts (2-37) are rotatably connected with the drying chamber (2-20), the turnplate shafts (2-37) are connected with connecting rods I (2-38), connecting rods I (2-38) are hinged with connecting rods II (2-39), connecting rods II (2-39) are rotatably connected with sliding shafts I (2-40), sliding shafts I (2-40) are rotatably connected with two door opening and closing supports (2-41), two door opening and closing supports (2-41) are both connected with drying chamber doors (2-46), the drying chamber doors (2-46) are in clearance fit with the drying chamber (2-20), the two door opening and closing supports (2-41) are respectively connected with two sliding shafts II (2-42), the two sliding shafts II (2-42) are respectively connected with the two sliding rails I (2-43) in a sliding mode, the two ends of the sliding shaft I (2-40) are respectively connected with the two sliding rails I (2-43) and the two sliding rails II (2-44) in a sliding mode, the two sliding rails I (2-43) and the two sliding rails II (2-44) are respectively located on the two sliding rail plates (2-47), the two sliding rail plates (2-47) are respectively connected with the two side walls of the drying chamber (2-20), and the heating column (2-45) is connected with the drying chamber (2-20).

4. A fabric resing apparatus according to claim 1, characterized in that: the cleaning assembly (3) comprises a bevel gear III (3-1), a bevel gear IV (3-2), a bevel gear IV shaft (3-3), a cleaning chamber (3-4), cleaning chamber support legs (3-5), a screen (3-6), a half gear disc (3-7), a straight gear (3-8), a straight gear shaft (3-9) and fan blades (3-10), a motor shaft (1-4) is connected with the bevel gear III (3-1), the bevel gear III (3-1) is meshed with the bevel gear IV (3-2), the bevel gear IV (3-2) is connected with the bevel gear IV shaft (3-3), the bevel gear IV shaft (3-3) is rotatably connected with a bottom plate (1-1) and the cleaning chamber (3-4), and the screen (3-6) is slidably connected with the cleaning chamber (3-4), the cleaning chamber (3-4) is connected with cleaning chamber support legs (3-5), the cleaning chamber support legs (3-5) are connected with a bottom plate (1-1), a bevel gear IV shaft (3-3) is connected with a half gear disc (3-7), the half gear disc (3-7) is meshed with two straight gears (3-8), the two straight gears (3-8) are respectively connected with two straight gear shafts (3-9), the two straight gear shafts (3-9) are rotatably connected with the cleaning chamber (3-4), and the two straight gear shafts (3-9) are respectively connected with two fan blades (3-10).

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