CN112974109B

CN112974109B - Polytypic tire processing equipment

Info

Publication number: CN112974109B
Application number: CN202110274049.6A
Authority: CN
Inventors: 刘瑾
Original assignee: Shandong Mileqi Tire Co ltd
Current assignee: Shandong Mileqi Tire Co ltd
Priority date: 2021-03-15
Filing date: 2021-03-15
Publication date: 2024-02-27
Anticipated expiration: 2041-03-15
Also published as: CN112974109A

Abstract

The invention relates to the field of tire processing, in particular to multi-model tire processing equipment. The thick tyre of the tyre can be coated with the liquid. Including piston subassembly, support part, check valve subassembly, rubber coating part, processing part, when realizing the drawing liquid process, one-way ball of pushing away from one-way boss one, and then make the glue solution in the glue case flow in through the glue case connecting tube, and then flow through one-way valve plate one-tenth through one-way ball of pushing away with one-way boss one between the clearance in, at this moment, one-way ball of pushing away closely laminates with one-way boss two, when realizing the flowing back, one-way ball of pushing away breaks away from with one-way boss two, and then the glue solution in the piston cylinder flows through one-way ball of pushing away with one-way boss two clearance to flow through one-way valve sleeve pipe one-tenth one end of one-way boss one-way at this moment, one-way ball of pushing away closely laminates with one-way boss.

Description

Polytypic tire processing equipment

Technical Field

The invention relates to the field of tire processing, in particular to multi-model tire processing equipment.

Background

The multi-model tire processing equipment is common equipment in the field of tire processing, but the functions of common model tire processing equipment are relatively single.

Disclosure of Invention

The invention aims to provide multi-model tire processing equipment which can be used for carrying out liquid coating processing on a tire coarse tire.

The aim of the invention is achieved by the following technical scheme:

the utility model provides a polytypic tire processing equipment, includes piston assembly, support part, check valve assembly, rubber coating part, processing part, and support part is connected with piston assembly, and the check valve assembly is connected with piston assembly, and the rubber coating part is connected with the check valve assembly, and support part is connected with processing part, and the check valve assembly is connected with processing part.

As a further optimization of the technical scheme, the multi-type tire processing equipment comprises a piston cylinder, a first inner end piston, a second inner end piston, a first piston connecting rod, a first crankshaft connecting rod, a first eccentric connecting rod, a first connecting center wheel, a first tapered gear shaft, a first crankshaft rod, a first straight gear shaft, a first straight gear, a second connecting center wheel, a second eccentric connecting rod, a second crankshaft connecting rod, a second piston connecting rod, a second tapered gear shaft, a second tapered gear and a third tapered gear, wherein the first inner end piston is in sliding connection with the piston cylinder, the second inner end piston is in sliding connection with the first inner end piston, one end of the first piston connecting rod is in hinged connection with the first crankshaft connecting rod, the other end of the first piston connecting rod is in hinged connection with the first crankshaft connecting rod, one end of the first eccentric connecting rod is in hinged connection with the first crankshaft connecting rod, the first eccentric connecting rod is in rotatable connection with the first eccentric connecting rod, the second tapered gear is in fixed connection with the first eccentric connecting center shaft, the first tapered gear is in meshed transmission with the first tapered gear, the first tapered gear is in fixed connection with the second eccentric connecting rod, the first tapered gear is in fixed connection with the first straight gear shaft, the first eccentric connecting rod is in fixed connection with the second eccentric connecting rod is in hinged connection with the second eccentric connecting rod, and the first eccentric connecting rod is in fixed connection with the second eccentric connecting rod is in hinged connection with the second eccentric connecting rod.

As a further optimization of the technical scheme, the multi-number tire processing equipment comprises a bracket rod, an upper end fixed frame, a crankshaft bracket, a crankshaft rotating rod, a double-sided rack, a regulating straight tooth and a regulating straight tooth shaft, wherein the upper end fixed frame is fixedly connected with the bracket rod, the crankshaft bracket is fixedly connected with the bracket rod, the crankshaft rotating rod is rotatably connected with the crankshaft bracket, the double-sided rack is slidably connected with the bracket rod, the regulating straight tooth shaft is rotatably connected with the bracket rod, the regulating straight tooth is fixedly connected with the regulating straight tooth shaft, the regulating straight tooth is in meshed transmission with the double-sided rack, a piston cylinder is fixedly connected with the upper end fixed frame, the crankshaft rotating rod is fixedly connected with the crankshaft rod, and the first bevel tooth shaft, the first bevel tooth shaft and the second bevel tooth shaft are all in rotary connection with the bracket rod.

As a further optimization of the technical scheme, the multi-number tire processing equipment comprises a first check valve sleeve, a first check valve plate, a second check valve sleeve, a second check valve plate, a first check push ball, a first check push spring, a first check boss, a second check push spring, a second check push ball and a second check boss, wherein the first check valve plate is fixedly connected with the first check valve sleeve, the inner end of the first check valve sleeve is hollowed out, the first check boss is arranged at the inner end of the first check valve sleeve, the first check push ball is matched and connected with the first check boss, one end of the first check push spring is fixedly connected with the first check push ball, the other end of the first check push spring is fixedly connected with the first check valve plate, the second check valve sleeve is fixedly connected with the second check valve plate, the second check push ball is matched and connected with the second check boss, one end of the second check push spring is fixedly connected with the second check push ball, the other end of the second check push spring is fixedly connected with the second check valve sleeve, the first check valve sleeve is fixedly connected and communicated with the piston cylinder, and the second check valve sleeve is fixedly connected and communicated with the piston cylinder.

As a further optimization of the technical scheme, the multi-type tire processing equipment comprises a first gluing connecting pipe, a gluing transition pipe, a second gluing connecting pipe, a gluing pushing spring, a first gluing support, a gluing roller, a gluing pressing rod, a middle end isolation disc, an isolation disc sliding rod, an isolation disc pushing spring, a gluing pressing plate, a first communication hole, a first communication cavity, an outer wall boss, an outer wall sliding groove and a discharge hole, wherein the first gluing connecting pipe is fixedly connected and communicated with the gluing transition pipe, the second gluing connecting pipe is fixedly connected and communicated with the first gluing connecting pipe, the first gluing support is in sliding connection with the second gluing connecting pipe, the outer wall boss is arranged on the first gluing support, the outer wall sliding groove is in matched connection with the first gluing support, the first communication cavity is arranged at the inner end of the first gluing support, the inner end of the gluing roller is hollowed out, the gluing roller is in rotary connection with the gluing support, the middle end isolation disc is in rotary connection with the gluing roller, the isolation disc sliding rod is fixedly connected with the isolation disc sliding rod, the isolation disc pushing plate is in sliding connection with the isolation disc sliding rod, the isolation disc sliding rod is fixedly connected with the first communication hole, the first communication cavity is arranged between the first communication cavity and the first gluing support and the middle end isolation disc is fixedly connected with the first communication hole, the first gluing roller is arranged on the first communication cavity, the first communication cavity is fixedly connected with the first gluing roller is arranged between the inner end of the middle end and the middle end of the middle end isolation disc.

As a further optimization of the technical scheme, the processing component comprises a processing support, a driven roller, a support boss, a rubber box connecting pipe, a driving roller, a driving rotating shaft, a first belt, an input motor, an input belt pulley, a second belt, a transmission belt pulley and a transmission belt pulley shaft, wherein the driven roller is rotationally connected with the processing support, the support boss is fixedly connected with the processing support, the rubber box connecting pipe is fixedly connected and communicated with the rubber box, the driving rotating shaft is rotationally connected with the support boss, the driving roller is fixedly connected with the driving rotating shaft, the input belt pulley is fixedly connected with the support boss, the input belt pulley is fixedly connected with an output shaft of the input motor, one end of the first belt pulley is connected with the input belt pulley, the other end of the second belt pulley is connected with the transmission belt pulley shaft, the support rod is fixedly connected with the support boss, the rubber box connecting pipe is fixedly connected and communicated with the first one-way valve sleeve, and the transmission belt pulley shaft is fixedly connected with the crankshaft rotating rod.

The multi-model tire processing equipment has the beneficial effects that:

when the liquid suction process is realized, the one-way push ball is far away from the one-way boss I, so that glue solution in the glue box flows in through the glue box connecting pipe, and flows into the piston cylinder through the one-way valve plate through a gap between the one-way push ball and the one-way boss I, at the moment, the one-way push ball is tightly attached to the one-way boss II, and when the liquid suction process is realized, the one-way push ball is separated from the one-way boss II, so that the glue solution in the piston cylinder flows out through a gap between the one-way push ball and the one-way boss II, and flows out through one end of the one-way valve sleeve II, and at the moment, the one-way push ball is tightly attached to the one-way boss I.

Drawings

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

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

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

fig. 3 is a schematic view of a piston assembly 1 according to the present invention;

fig. 4 is a second schematic structural view of the piston assembly 1 of the present invention;

fig. 5 is a schematic diagram III of the piston assembly 1 of the present invention;

fig. 6 is a schematic view of the structure of the bracket member 2 of the present invention;

FIG. 7 is a second schematic view of the structure of the bracket member 2 of the present invention;

FIG. 8 is a schematic view of the one-way valve assembly 3 of the present invention;

FIG. 9 is a second schematic illustration of the structure of the check valve assembly 3 of the present invention;

fig. 10 is a schematic view of the structure of the gumming piece 4 of the present invention;

fig. 11 is a schematic diagram of the structure of the gumming component 4 of the present invention;

fig. 12 is a schematic view of the gluing member 4 of the present invention;

FIG. 13 is a schematic view of the construction of the processing element 5 of the present invention;

fig. 14 is a second schematic structural view of the processing member 5 of the present invention;

fig. 15 is a schematic view of the structure of the processing member 5 of the present invention.

In the figure: a piston assembly 1; a piston cylinder 1-1; 1-2 of inner end pistons; the second inner end piston is 1-3; 1-4 of a piston connecting rod; 1-5 of crankshaft connecting rod I; 1-6 of eccentric connecting rods; 1-7 of connecting heart wheels; 1-8 of bevel gear shafts; 1-9 parts of a crankshaft rod; 1-10 of bevel teeth; straight gear shaft 1-11; straight teeth 1-12; 1-13 parts of a connecting heart wheel II; eccentric connecting rod II 1-14; 1-15 parts of a crankshaft connecting rod II; piston connecting rod II 1-16; 1-17 of a bevel gear shaft II; 1-18 of bevel teeth II; bevel gears III 1-19; a bracket member 2; a bracket rod 2-1; the upper end is fixed with a frame 2-2; 2-3 of a crankshaft bracket; 2-4 parts of a crankshaft rotating rod; 2-5 parts of double-sided racks; adjusting the straight teeth by 2-6; adjusting the straight gear shaft 2-7; a check valve assembly 3; 3-1 parts of one-way valve sleeve; 3-2 parts of one-way valve plate; 3-3 parts of a second check valve sleeve; 3-4 of a one-way valve plate; one-way ball pushing is 3-5; 3-6 parts of one-way push spring; 3-7 of one-way boss I; 3-8 of a unidirectional push spring II; 3-9 of one-way pushing ball II; 3-10 of a one-way boss II; a glue spreading part 4; gluing a connecting pipe I4-1; gluing a transition pipe 4-2; gluing connecting pipes II 4-3; 4-4 parts of gluing pushing springs; the first gluing bracket is 4-5; glue spreading rollers 4-6; 4-7 of gluing pressing rod; 4-8 of middle end isolation discs; 4-9 of a separation disc slide bar; 4-10 of a separation disc pushing spring; 4-11 parts of gluing pressing plate; the first communication hole is 4-12; the first communicating cavity is 4-13; an outer wall boss; an outer wall chute; 4-16 parts of discharge holes; a processing member 5; processing a bracket 5-1; driven roller 5-2; 5-3 parts of bracket bosses; 5-4 parts of a glue box; 5-5 parts of glue box connecting pipes; active rollers 5-6; 5-7 parts of a driving rotating shaft; 5-8 of a belt I; 5-9 of input motor; 5-10 of an input belt pulley; 5-11 parts of a second belt; 5-12 parts of a driving belt wheel; pulley shafts 5-13.

Detailed Description

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

The fixed connection in the device is fixed by welding, thread fixing and other modes, and different fixing modes are used in combination with different use environments; the rotating connection of the bearing is realized by baking the bearing on a shaft, a spring retainer ring groove is arranged on the shaft or the shaft hole, and the axial fixation of the bearing is realized by clamping the spring retainer ring in the retainer ring groove; the sliding connection of the slide block is realized by sliding the slide block in the slide groove or the guide rail, and the slide groove or the guide rail is generally in a ladder shape so as to prevent the slide block from falling off in the slide groove or the guide rail; the hinge of the pin shaft is a movable connection mode on the connection parts such as the hinge, the pin shaft, the short shaft and the like; the sealing is realized by a sealing ring or an O-shaped ring at the required sealing positions.

The first embodiment is as follows:

the following describes a multi-model tire processing apparatus with reference to fig. 1 to 15, which includes a piston assembly 1, a bracket member 2, a check valve assembly 3, a glue coating member 4, and a processing member 5, wherein the bracket member 2 is connected with the piston assembly 1, the check valve assembly 3 is connected with the piston assembly 1, the glue coating member 4 is connected with the check valve assembly 3, the bracket member 2 is connected with the processing member 5, and the check valve assembly 3 is connected with the processing member 5.

The second embodiment is as follows:

in the following description of the present embodiment with reference to fig. 1-15, the piston assembly 1 includes a piston cylinder 1-1, an inner end piston 1-2, an inner end piston 1-3, a piston rod 1-4, a crankshaft connecting rod 1-5, an eccentric connecting rod 1-6, a connecting wheel 1-7, a cone gear shaft 1-8, a crankshaft shaft 1-9, a cone gear 1-10, a straight gear shaft 1-11, a straight gear 1-12, a connecting wheel two 1-13, an eccentric connecting rod two 1-14, a crankshaft connecting rod two 1-15, a piston connecting rod two 1-16, a cone gear shaft two 1-17, a cone gear two 1-18, a cone gear three 1-19, the inner end piston 1-2 is slidably connected with the piston cylinder 1-1, the inner end piston II 1-3 is connected with the piston cylinder 1-1 in a sliding way, the inner end piston II 1-3 is connected with the inner end piston I1-2 in a sliding way, one end of the piston connecting rod I1-4 is connected with the inner end piston I1-2 in a hinging way, the other end of the piston connecting rod I1-4 is connected with the crankshaft connecting rod I1-5 in a hinging way, the crankshaft connecting rod I1-5 is rotationally connected with the crankshaft rod 1-9, one end of the eccentric connecting rod I1-6 is connected with the crankshaft connecting rod I1-5 in a hinging way, the eccentric connecting rod I1-6 is rotationally connected with the connecting core wheel I1-7, the bevel gear II 1-18 is fixedly connected with the bevel gear I1-8, the bevel gear I1-10 is meshed with the bevel gear II 1-18, the first bevel gear 1-10 is fixedly connected with the first straight gear shaft 1-11, the first straight gear shaft 1-11 is fixedly connected with the first straight gear 1-12, the second connecting wheel 1-13 is rotationally connected with the second eccentric connecting rod 1-14, the second eccentric connecting rod 1-14 is hinged with the second crankshaft connecting rod 1-15, the second crankshaft connecting rod 1-15 is rotationally connected with the first crankshaft rod 1-9, the second crankshaft connecting rod 1-15 is hinged with the second piston connecting rod 1-16, the second piston connecting rod 1-16 is hinged with the second inner end piston 1-3, the second bevel gear shaft 1-17 is rotationally connected at the eccentric position of the second connecting wheel 1-13, the third bevel gear 1-19 is fixedly connected with the second bevel gear shaft 1-17, and the third bevel gear 1-19 is meshed with the first bevel gear 1-10 for transmission.

And a third specific embodiment:

in the following description of the first embodiment with reference to fig. 1-15, the bracket component 2 includes a bracket rod 2-1, an upper end fixing frame 2-2, a crank bracket 2-3, a crank rotating rod 2-4, a double-sided rack 2-5, an adjusting spur gear 2-6, an adjusting spur gear 2-7, an upper end fixing frame 2-2 fixedly connected with the bracket rod 2-1, a crank bracket 2-3 fixedly connected with the bracket rod 2-1, a crank rotating rod 2-4 rotatably connected with the crank bracket 2-3, a double-sided rack 2-5 slidably connected with the bracket rod 2-1, an adjusting spur gear 2-6 fixedly connected with the adjusting spur gear 2-7, an adjusting spur gear 2-6 meshed with the double-sided rack 2-5, a piston cylinder 1-1 fixedly connected with the upper end fixing frame 2-2, a crank rotating rod 2-4 fixedly connected with the crank shaft 1-9, a conical gear 1-8, a spur gear 1-11, a conical gear 1-17 rotatably connected with the bracket rod 2-1, and a double-sided rack 2-5 meshed with the double-sided rack 2-5.

The specific embodiment IV is as follows:

in the following description of the first embodiment with reference to fig. 1-15, the first check valve assembly 3 includes a first check valve sleeve 3-1, a first check valve plate 3-2, a second check valve sleeve 3-3, a second check valve plate 3-4, a first check push ball 3-5, a first check push spring 3-6, a first check boss 3-7, a second check push spring 3-8, a second check push ball 3-9, a second check boss 3-10, a first check valve plate 3-2 fixedly connected with the first check valve sleeve 3-1, a hollow inner end of the first check valve sleeve 3-1, a first check boss 3-7 disposed at an inner end of the first check valve sleeve 3-1, a first check push ball 3-5 fixedly connected with the first check boss 3-7, a first check push spring 3-6 having one end fixedly connected with the first check push ball 3-5, a second check spring 3-6 having another end fixedly connected with the first check valve plate 3-2, a second check valve sleeve 3-3 fixedly connected with the second check spring 3-4, a second check boss 3-10 disposed at an inner end of the second check boss 3-9 fixedly connected with the second check valve sleeve 3-1, a second check valve plate 3-8 fixedly connected with the second piston sleeve 3-1 and fixedly connected with the second end of the second check valve sleeve 1-1.

Fifth embodiment:

in the following description of the first embodiment with reference to fig. 1-15, the glue coating component 4 includes a glue coating connecting tube 4-1, a glue coating transition tube 4-2, a glue coating connecting tube two 4-3, a glue coating pushing spring 4-4, a glue coating bracket one 4-5, a glue coating roller 4-6, a glue coating pressing rod 4-7, a middle end isolation disc 4-8, an isolation disc sliding rod 4-9, an isolation disc pushing spring 4-10, a glue coating pressing plate 4-11, a communication hole one 4-12, a communication cavity one 4-13, an outer wall boss, an outer wall chute and a discharge hole 4-16, the glue coating connecting tube one 4-1 is fixedly connected and communicated with the glue coating transition tube 4-2, the glue coating connecting tube two 4-3 is fixedly connected and communicated with the glue coating transition tube 4-2, the first gluing support 4-5 is in sliding connection with the second gluing connecting pipe 4-3, the outer wall boss is fixedly connected with the second gluing connecting pipe 4-3, the outer wall chute is arranged on the first gluing support 4-5, the outer wall boss is in matched connection with the outer wall chute, the second gluing connecting pipe 4-3 is communicated with the first gluing support 4-5, the first communicating cavity 4-13 is arranged at the inner end of the first gluing support 4-5, the inner end of the gluing roller 4-6 is hollowed out, the gluing roller 4-6 is in rotary connection with the first gluing support 4-5, the middle end isolation disc 4-8 is in rotary connection with the gluing roller 4-6, the isolation disc slide bar 4-9 is fixedly connected with the middle end isolation disc 4-8, the gluing pressing plate 4-11 is in sliding connection with the isolation disc slide bar 4-9, the isolation disc pushing spring 4-10 is connected with the isolation disc sliding rod 4-9 in a sleeved mode, the isolation disc pushing spring 4-10 is arranged between the gluing pressing plate 4-11 and the middle isolation disc 4-8, the gluing pressing rod 4-7 is arranged at the inner end of the discharging hole 4-16, the discharging hole 4-16 is arranged on the gluing roller 4-6, the communication hole I4-12 is communicated with the communication cavity I4-13, the gluing support I4-5 is communicated with the communication cavity I4-13, and the one-way valve sleeve II 3-3 is fixedly connected and communicated with the gluing connecting pipe I4-1;

the flowing glue solution flows into the glue coating connecting pipe I4-1 through the one-way valve sleeve II 3-3, flows into the glue coating bracket I4-5 through the glue coating transition pipe 4-2 and the glue coating connecting pipe II 4-3, then flows into the glue coating roller 4-6 through the communication between the communication cavity I4-13 and the communication hole I4-12, when the glue coating roller 4-6 contacts with the surface of the tire coarse tire, the glue coating pressing rod 4-7 moves radially inwards, the discharging hole 4-16 is communicated with the inner end of the glue coating roller 4-6, the glue solution flows out through the discharging hole 4-16, and meanwhile, the glue coating roller 4-6 enters into the tire coarse tire through the surface friction force with the tire coarse tire, so that the glue coating roller 4-6 rotates, and even coating of the tire coarse tire is realized.

Specific embodiment six:

in the following description of the first embodiment with reference to fig. 1-15, the processing unit 5 includes a processing bracket 5-1, a driven roller 5-2, a bracket boss 5-3, a glue box 5-4, a glue box connecting tube 5-5, a driving roller 5-6, a driving rotating shaft 5-7, a belt one 5-8, an input motor 5-9, an input pulley 5-10, a belt two 5-11, a driving pulley 5-12, a driving pulley shaft 5-13, a driven roller 5-2 rotatably connected with the processing bracket 5-1, a bracket boss 5-3 fixedly connected with the processing bracket 5-1, a glue box 5-4 fixedly connected with the processing bracket 5-1, a glue box connecting tube 5-5 fixedly connected and communicated with the glue box 5-4, a driving rotating shaft 5-7 rotatably connected with the bracket boss 5-3, a driving roller 5-6 fixedly connected with the driving rotating shaft 5-7, an input motor 5-9 fixedly connected with the bracket boss 5-3, an input pulley 5-10 fixedly connected with an output shaft of the input motor 5-9, a belt one end of the belt one end 5-8 of the belt pulley 5-10 is fixedly connected with the driving pulley 5-9, the belt one end of the belt one end 5-8 is fixedly connected with the driving pulley 5-10 and the other end of the driving pulley 5-2-11 and fixedly connected with the other end of the driving pulley 5-11-2 on the driving pulley 5-2, the rubber box connecting pipe 5-5 is fixedly connected and communicated with the one-way valve sleeve 3-1, and the transmission belt wheel shaft 5-13 is fixedly connected with the crankshaft rotating rod 2-4.

The invention relates to multi-model tire processing equipment, which has the working principle that:

when the device is used, the input motor 5-9 is started, the input belt pulley 5-10 is driven to rotate by the input motor 5-9, the belt 5-8 is driven to move by the input belt pulley 5-10, the driving rotating shaft 5-7 is driven to rotate by the belt 5-8, the driving roller 5-6 is driven to rotate by the driving rotating shaft 5-7, the tire coarse tire is driven to move by the driving roller 5-6, and meanwhile glue solution is added into the glue box 5-4; the driving rotating shaft 5-7 is detachable, so that the tire to be processed can be conveniently loaded and unloaded; meanwhile, the input motor 5-9 rotates to drive the belt II 5-11 to move, and then the belt II 5-11 drives the driving belt wheel 5-12 to move, and then the driving belt wheel shaft 5-13 is driven to move through the driving belt wheel 5-12, so that power output is facilitated; simultaneously, the crankshaft rotating rod 2-4 is driven to move through the transmission belt wheel shaft 5-13, the crankshaft rod 1-9 is driven to rotate through the crankshaft rotating rod 2-4, the crankshaft connecting rod 1-5 is driven to move through the crankshaft rod 1-9, the piston connecting rod 1-4 is driven to move through the crankshaft connecting rod 1-5, the inner end piston 1-2 is driven to reciprocate along the inner end of the piston cylinder 1-1 through the piston connecting rod 1-4, meanwhile, the crankshaft rod 1-9 is driven to move through the crankshaft connecting rod 1-15, the piston connecting rod 2-16 is driven to move through the piston connecting rod 1-16, the inner end piston 1-3 is driven to reciprocate along the inner end of the piston cylinder 1-1, the inner end piston 1-2 and the inner end piston 1-3 are opposite in moving direction, the glue solution sucking process is realized when the inner end piston 1-2 and the inner end piston 1-3 are far away from each other, and the glue solution discharging process is realized when the inner end piston 1-2 and the inner end piston 1-3 are close to each other; simultaneously, the adjusting straight teeth 2-6 are manually driven to move, the double-sided rack 2-5 is driven to axially slide through the adjusting straight teeth 2-6, the straight teeth 1-12 are driven to rotate through the double-sided rack 2-5, the straight tooth shaft 1-11 is driven to rotate through the straight teeth 1-12, the bevel teeth 1-10 are driven to rotate through the straight tooth shaft 1-11, the bevel teeth two 1-18 are driven to rotate through the bevel teeth 1-10, the bevel teeth shaft 1-8 is driven to move through the bevel teeth two 1-18, the eccentric connecting rod 1-6 is driven by the eccentric connecting rod 1-7 through the connecting wheel 1-7, the diameter of the movement track of the crankshaft connecting rod 1-5 is changed, so that the formation of the reciprocating motion of the inner end piston 1-2 is changed, meanwhile, the first bevel gear 1-10 rotates to drive the third bevel gear 1-19 to rotate, the third bevel gear 1-19 drives the second bevel gear shaft 1-17 to rotate, the second bevel gear shaft 1-17 drives the second connecting wheel 1-13 to move, the second connecting wheel 1-13 drives the second eccentric connecting rod 1-14 to move, the diameter of the motion track of the second crankshaft connecting rod 1-15 is changed through the second eccentric connecting rod 1-14, the reciprocating motion track of the second inner end piston 1-3 is changed, the rotating directions of the second bevel gear 1-18 and the third bevel gear 1-19 are opposite, the relative adjusting directions of the first inner end piston 1-2 and the second inner end piston 1-3 are opposite, the limit values of the maximum distance and the minimum distance between the first inner end piston 1-2 and the second inner end piston 1-3 are changed simultaneously, so that the quantity of the glue solution extracted or discharged in unit time is changed, and the glue spreading speed of the tire coarse tire is conveniently adjusted according to actual conditions; when the liquid pumping process is realized, the one-way push ball I3-5 is far away from the one-way boss I3-7, so that glue liquid in the glue box 5-4 flows in through the glue box connecting pipe 5-5, flows through the one-way valve plate I3-2 through a gap between the one-way push ball I3-5 and the one-way boss I3-7, flows into the piston cylinder 1-1, at the moment, the one-way push ball II 3-9 is tightly attached to the one-way boss II 3-10, when liquid discharging is realized, the one-way push ball II 3-9 is separated from the one-way boss II 3-10, so that the glue liquid in the piston cylinder 1-1 flows out through a gap between the one-way push ball II 3-9 and the one-way boss II 3-10, and flows out through one end of the one-way valve sleeve II 3-3, and at the moment, the one-way push ball II 3-5 is tightly attached to the one-way boss I3-7; simultaneously, the glue solution flowing out flows into the glue coating connecting pipe I4-1 through the check valve sleeve II 3-3, flows into the glue coating bracket I4-5 through the glue coating transition pipe 4-2 and the glue coating connecting pipe II 4-3, and then flows into the glue coating roller 4-6 through the communication between the communication cavity I4-13 and the communication hole I4-12, when the glue coating roller 4-6 contacts with the surface of the tire coarse tire, the glue coating pressing rod 4-7 is further enabled to move radially inwards, the discharging hole 4-16 is further enabled to be communicated with the inner end of the glue coating roller 4-6, the glue solution flows out through the discharging hole 4-16, and meanwhile, the glue coating roller 4-6 enters into the tire coarse tire through the surface friction force with the tire coarse tire, so that the glue coating roller 4-6 rotates, and even liquid coating of the tire coarse tire is further achieved.

Of course, the above description is not intended to limit the invention, but rather the invention is not limited to the above examples, and variations, modifications, additions or substitutions within the spirit and scope of the invention will be within the scope of the invention.

Claims

1. The utility model provides a polytypic tire processing equipment, includes piston assembly (1), support part (2), check valve subassembly (3), rubber coating part (4), processing part (5), its characterized in that: the device comprises a bracket component (2), a piston component (1), a one-way valve component (3), a gluing component (4), a processing component (5) and a one-way valve component (3), wherein the bracket component (2) is connected with the piston component (1), the one-way valve component (3) is connected with the piston component (1), and the gluing component (4) is connected with the one-way valve component (3);

the piston assembly (1) comprises a piston cylinder (1-1), an inner end piston I (1-2), an inner end piston II (1-3), a piston connecting rod I (1-4), a crankshaft connecting rod I (1-5), an eccentric connecting rod I (1-6), a connecting wheel I (1-7), a bevel gear shaft I (1-8), a crankshaft rod (1-9), a bevel gear I (1-10), a straight gear shaft I (1-11), a straight gear I (1-12), a connecting wheel II (1-13), an eccentric connecting rod II (1-14), a crankshaft connecting rod II (1-15), a piston connecting rod II (1-16), a bevel gear shaft II (1-17), a bevel gear II (1-18) and a bevel gear III (1-19), wherein the inner end piston I (1-2) is in sliding connection with the piston cylinder (1-1), the inner end piston II (1-3) is in sliding connection with the inner end piston I (1-2), one end of the piston I (1-4) is in hinge connection with the crankshaft connecting rod II (1-2), the other end of the piston II (1-4) is in hinge connection with the crankshaft connecting rod II (1-4), the first crankshaft connecting rod (1-5) is rotationally connected with the first crankshaft rod (1-9), one end of the first eccentric connecting rod (1-6) is fixedly connected with the first crankshaft connecting rod (1-5), the first eccentric connecting rod (1-6) is rotationally connected with the first connecting wheel (1-7), the first conical tooth shaft (1-8) is rotationally connected at the eccentric position of the first connecting wheel (1-7), the second conical tooth (1-18) is fixedly connected with the first conical tooth shaft (1-8), the first conical tooth (1-10) is meshed with the second conical tooth (1-18) for transmission, the first conical tooth shaft (1-10) is fixedly connected with the first straight tooth shaft (1-11), the second connecting wheel (1-13) is rotationally connected with the second eccentric connecting rod (1-14), the second eccentric connecting rod (1-14) is rotationally connected with the second crankshaft connecting rod (1-15), the second conical tooth shaft (1-15) is rotationally connected with the first crankshaft connecting rod (1-9), the second conical tooth shaft (1-15) is rotationally connected with the second crankshaft connecting rod (1-16), the second piston (1-16) is rotationally connected with the second crankshaft connecting rod (1-16) and the second piston (1-13) is rotationally connected with the second crankshaft connecting rod (1-16), the third bevel gear (1-19) is fixedly connected with the second bevel gear shaft (1-17), and the third bevel gear (1-19) is meshed with the first bevel gear (1-10) for transmission;

the bracket component (2) comprises a bracket rod (2-1), an upper end fixing frame (2-2), a crankshaft bracket (2-3), a crankshaft rotating rod (2-4), a double-sided rack (2-5), an adjusting straight tooth (2-6) and an adjusting straight tooth shaft (2-7), wherein the upper end fixing frame (2-2) is fixedly connected with the bracket rod (2-1), the crankshaft bracket (2-3) is fixedly connected with the bracket rod (2-1), the crankshaft rotating rod (2-4) is rotationally connected with the crankshaft bracket (2-3), the double-sided rack (2-5) is in sliding connection with the bracket rod (2-1), the adjusting straight tooth shaft (2-7) is rotationally connected with the bracket rod (2-1), the adjusting straight tooth (2-6) is in meshed transmission with the double-sided rack (2-5), the piston cylinder (1-1) is fixedly connected with the upper end fixing frame (2-2), the crankshaft rotating rod (2-4) is rotationally connected with the crankshaft bracket (1-9), the first straight tooth shaft (1-8) and the second straight tooth shaft (1-17) are rotationally connected with the bracket rod (1-1), the straight tooth I (1-12) is meshed with the double-sided rack (2-5) for transmission;

the one-way valve component (3) comprises a one-way valve sleeve I (3-1), a one-way valve plate I (3-2), a one-way valve sleeve II (3-3), a one-way valve plate II (3-4), a one-way push ball I (3-5), a one-way push spring I (3-6), a one-way boss I (3-7), a one-way push spring II (3-8), a one-way push ball II (3-9) and a one-way boss II (3-10), wherein the one-way valve plate I (3-2) is fixedly connected with the one-way valve sleeve I (3-1), the one-way boss I (3-7) is arranged at the inner end of the one-way valve sleeve I (3-1), the one-way push ball I (3-5) is matched and connected with the one-way boss I (3-7), one end of the one-way push spring I (3-6) is fixedly connected with the one-way valve plate I (3-2), the one-way valve sleeve II (3-4) is fixedly connected with the one-way valve plate II (3-4) at the inner end of the one-way valve sleeve I (3-4), the one-way pushing ball II (3-9) is connected with the one-way boss II (3-10) in a matched manner, one end of the one-way pushing spring II (3-8) is fixedly connected with the one-way pushing ball II (3-9), the other end of the one-way pushing spring II (3-8) is fixedly connected with the one-way valve sleeve II (3-3), the one-way valve sleeve I (3-1) is fixedly connected and communicated with the piston cylinder (1-1), and the one-way valve sleeve II (3-3) is fixedly connected and communicated with the piston cylinder (1-1);

the gluing component (4) comprises a gluing connecting pipe I (4-1), a gluing transition pipe (4-2), a gluing connecting pipe II (4-3), a gluing pushing spring (4-4), a gluing support II (4-5), a gluing roller (4-6), a gluing pressing rod (4-7), a middle end isolation disc (4-8), an isolation disc sliding rod (4-9), an isolation disc pushing spring (4-10), a gluing pressing plate (4-11), a communication hole I (4-12), a communication cavity I (4-13), an outer wall boss, an outer wall sliding groove and a discharging hole (4-16), wherein the gluing connecting pipe I (4-1) is fixedly connected and communicated with the gluing transition pipe (4-2), the gluing connecting pipe II (4-3) is fixedly connected and communicated with the gluing transition pipe (4-2), the gluing support I (4-5) is fixedly connected with the gluing connecting pipe II (4-3), the outer wall boss is fixedly connected with the gluing connecting pipe II (4-3), the outer wall sliding groove is arranged on the gluing support I (4-5), the outer wall boss is matched with the outer wall sliding groove II (4-3) is connected with the gluing connecting pipe II (4-3) and is communicated with the gluing cavity I (4-5), the inner end of the gluing roller (4-6) is hollowed out, the gluing roller (4-6) is rotationally connected with a gluing support I (4-5), a middle end isolation disc (4-8) is rotationally connected with the gluing roller (4-6), an isolation disc sliding rod (4-9) is fixedly connected with the middle end isolation disc (4-8), a gluing pressing plate (4-11) is in sliding connection with the isolation disc sliding rod (4-9), a isolation disc pushing spring (4-10) is sleeved and connected with the isolation disc sliding rod (4-9), the isolation disc pushing spring (4-10) is arranged between the gluing pressing plate (4-11) and the middle end isolation disc (4-8), a gluing pressing rod (4-7) is arranged at the inner end of a discharging hole (4-16), the discharging hole (4-16) is arranged on the gluing roller (4-6), a communication hole I (4-12) is arranged on the gluing roller (4-6), the communication hole I (4-12) is communicated with a communication cavity I (4-13), the gluing support I (4-5) is communicated with the first communication cavity (4-13) and is fixedly communicated with a first one-way valve (3-3;

the processing component (5) comprises a processing bracket (5-1), a driven roller (5-2), a bracket boss (5-3), a rubber box (5-4), a rubber box connecting pipe (5-5), a driving roller (5-6), a driving rotating shaft (5-7), a belt I (5-8), an input motor (5-9), an input belt pulley (5-10), a belt II (5-11), a driving belt pulley (5-12) and a driving belt pulley shaft (5-13), wherein the driven roller (5-2) is rotationally connected with the processing bracket (5-1), the bracket boss (5-3) is fixedly connected with the processing bracket (5-1), the rubber box (5-4) is fixedly connected with the processing bracket (5-1), the rubber box connecting pipe (5-5) is fixedly connected and communicated with the rubber box (5-4), the driving rotating shaft (5-7) is rotationally connected with the bracket boss (5-3), the driving roller (5-6) is fixedly connected with the driving rotating shaft (5-7), the input motor (5-9) is fixedly connected with the bracket boss (5-3), the driving belt pulley (5-10) is fixedly connected with the input shaft (5-9), one end of a first belt (5-8) is connected to an input belt wheel (5-10), the other end of the first belt (5-8) is connected with a driving rotating shaft (5-7), one end of a second belt (5-11) is connected to an output shaft of an input motor (5-9), the other end of the second belt (5-11) is connected with a driving belt wheel (5-12), the driving belt wheel (5-12) is fixedly connected with a driving belt wheel shaft (5-13), a support rod (2-1) is fixedly connected with a support boss (5-3), a rubber box connecting pipe (5-5) is fixedly connected and communicated with a one-way valve sleeve (3-1), and a driving belt wheel shaft (5-13) is fixedly connected with a crankshaft rotating rod (2-4).