CN113183500A

CN113183500A - Multi-model tire processing equipment

Info

Publication number: CN113183500A
Application number: CN202110495417.XA
Authority: CN
Inventors: 孟凡英
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-05-07
Filing date: 2021-05-07
Publication date: 2021-07-30

Abstract

The invention relates to engineering machinery, in particular to multi-model tire processing equipment. The invention aims to provide multi-model tire processing equipment, which can enable a left-handed thread sliding block and a right-handed thread sliding block which are meshed with a double-handed thread shaft to simultaneously move in the opposite directions or opposite directions by controlling the rotation of the double-handed thread shaft, and can adjust the size of a tire by controlling the telescopic sliding of an arc plate in a sliding groove on a rotating disc through a connecting rod and a pin shaft. When the double-direction double-clutch transmission is used, the second gear is connected with a power end to perform belt calendering, the contact and separation of the half shafts of the two clutches are controlled by adjusting the position of a clutch shifting fork, the internal gear connecting sleeve is meshed with the first gear on the double-rotation-direction threaded shaft or the second gear on the first shaft, the working mode is changed, and the size of a tire is adjusted; the steel wire is through two semicircle arc pole centre gripping, is equipped with the steel wire recess of different child thickness sizes on the arc board, and the guide rail slider drives the platform that slides and slides, through rotating the angle of fork and hydraulic stem adjustment semicircle arc pole and the platform that slides in order to carry out the hoop steel wire process.

Description

Multi-model tire processing equipment

Technical Field

The invention relates to engineering machinery, in particular to multi-model tire processing equipment.

Background

The tire processing equipment is a common engineering machine and is important equipment in the process of manufacturing a green tire, and the conventional tire processing equipment can only process the green tire with fixed size and specification, namely, the same tire processing equipment cannot process tires with different models.

Disclosure of Invention

The invention aims to provide multi-model tire processing equipment, which can enable a left-handed thread sliding block and a right-handed thread sliding block which are meshed with a double-handed thread shaft to simultaneously move in the opposite directions or opposite directions by controlling the rotation of the double-handed thread shaft, and can adjust the size of a tire by controlling the telescopic sliding of an arc plate in a sliding groove on a rotating disc through a connecting rod and a pin shaft.

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

the utility model provides a polytypic tire processing equipment, includes frame assembly, radial flexible assembly, transmission assembly, steel wire hoop ring assembly, the frame assembly is connected with radial flexible assembly, and the frame assembly is connected with the transmission assembly, and the frame assembly is connected with steel wire hoop ring assembly, and radial flexible assembly is connected with the transmission assembly.

As a further optimization of the technical scheme, the invention discloses a multi-model tire processing device, which comprises a base plate, a first rib plate, a first hole, a second rib plate, a second hole, a motor transmission disc, a blower and a T-shaped guide rail, wherein the base plate is fixedly connected with the first rib plate, the second rib plate and the motor, the T-shaped guide rail is arranged on the base plate, the first hole is formed in the first rib plate, the second hole is formed in the second rib plate, the motor is rotatably connected with the motor transmission disc, and the motor is fixedly connected with the blower.

As a further optimization of the technical scheme, the invention relates to a multi-model tire processing device, wherein a radial telescopic combined body comprises a rubber inflatable tire body, a first rotating disc, a second rotating disc, a first sliding groove, a left-handed thread sliding block, a right-handed thread sliding block, an arc plate, a third hole, a roller, a steel wire groove, a movable plate, a connecting rod, a first pin shaft, a first shaft, a double-handed thread shaft, a first gear, a second shaft, a left-handed thread, a right-handed thread, a first step end face, a second step end face, an air hole, a fourth hole, a rib, a left-handed thread hole and a fifth hole, wherein the rubber inflatable tire body is fixedly connected with the first rotating disc and the second rotating disc, the first sliding groove and the fifth hole are arranged on the first rotating disc, the first sliding groove and the fifth hole are arranged on the second rotating disc, the first sliding groove is connected with the movable plate in a sliding mode, and the left-handed thread sliding block is internally provided with a left-handed thread hole, the left-handed thread slider is meshed with left-handed threads of the double-handed threaded shaft, the left-handed thread slider is provided with a rib, the right-handed thread slider is meshed with right-handed threads of the double-handed threaded shaft, the right-handed thread slider is provided with a rib, the arc plate is provided with a steel wire groove, the arc plate is fixedly connected with the moving plate, the moving plate is provided with a third hole, the moving plate is rotatably connected with the roller, the connecting rod and the pin shaft are connected with the moving plate and the rib, the first shaft is rotatably connected with the double-handed threaded shaft, the first shaft is provided with a second gear, the first shaft is rotatably connected with the second shaft, the double-handed threaded shaft is provided with a first gear, a left-handed thread, a right-handed thread, a first step end face, a second step end face, an air hole and a fourth hole, the double-handed threaded shaft is rotatably connected with the first rib plate through the first hole, and the second hole is rotatably connected with the second rib plate.

As a further optimization of the technical scheme, the invention relates to a multi-model tire processing device, wherein a transmission assembly comprises an internal gear connecting sleeve, a first support lug, a first connecting rod, a second connecting rod, a driving disc, a second support lug, a sleeve, a clutch shifting fork, a first clutch half shaft, a second clutch half shaft, a belt, a gas conveying pipe, a second chute, a fifth hole, a handle, a second pin shaft and a cylindrical lug, wherein the internal gear connecting sleeve is meshed with a first gear on a double-rotation-direction threaded shaft or a second gear on the first shaft, the internal gear connecting sleeve is fixedly connected with the first support lug, the first support lug is rotatably connected with the first connecting rod through the second pin shaft, the first connecting rod is rotatably connected with the second connecting rod through the second pin shaft, the second connecting rod is rotatably connected with the second support lug through the second pin shaft, the driving disc is fixedly connected with the second support lug, the sleeve is rotatably connected with the fifth clutch shifting, the clutch shifting fork is provided with a second sliding groove and a fifth hole, the clutch shifting fork is fixedly connected with the handle, the first clutch half shaft and the second clutch half shaft can be fixedly connected under the control of the clutch shifting fork, the second clutch half shaft is connected with the motor transmission disc through a belt, the gas transmission pipe is connected with the blower and the second shaft, and the second shaft is rotatably connected with the first clutch half shaft and the second clutch half shaft.

As a further optimization of the technical scheme, the invention provides a multi-model tire processing device, wherein the steel wire hoop assembly comprises a semicircular arc rod, a sixth hole, a seventh hole, a sliding table, a third support lug, a eighth hole, a fourth support lug, a ninth hole, a guide rail sliding block, a third pin shaft, a rotary fork and a hydraulic rod, the semicircular arc rod is provided with the sixth hole and the seventh hole, the semicircular arc rod is rotatably connected with the sliding table through the third pin shaft, the semicircular arc rod is rotatably connected with the rotary fork through the sixth hole, the sliding table is fixedly connected with the third support lug, the sliding table is fixedly connected with the fourth support lug, the sliding table is fixedly connected with the guide rail sliding block, the third support lug is provided with the eighth hole, the fourth support lug is provided with the ninth hole, the rotary fork is slidably connected with the hydraulic rod, the sliding table is rotatably connected with the hydraulic rod through the third pin shaft, and the guide rail sliding block is slidably connected with a T-shaped guide rail on a bottom plate.

The beneficial effects of the invention are as follows:

the invention relates to a multi-model tire processing device, a bottom plate is connected with two rib plates, holes are respectively arranged on the two rib plates and used for being rotationally connected with a radial telescopic combination body and a transmission combination body, a motor and a blower are fixed on the bottom plate, and a T-shaped guide rail is used for being slidably connected with a steel wire hoop combination body; when the double-rotation-direction threaded shaft rotates, the left-rotation threaded slider and the right-rotation threaded slider move in opposite directions simultaneously, and the arc plate is controlled to stretch and slide in the first sliding grooves of the first rotating disc and the second rotating disc through the connecting rod and the first pin shaft to adjust the size of the tire; when the rubber inflation tire body needs to be inflated, a blower sucks air to work, and air is inflated into the rubber inflation tire body through a gas pipe and the second shaft; the steel wire is through two semicircle arc pole centre gripping, is equipped with the steel wire recess of different child thickness sizes on the arc board, and the guide rail slider drives the T type guide rail of platform on the bottom plate that slides and slides, and semicircle arc pole can rotate around journal stirrup three, through rotating fork and hydraulic stem adjustment semicircle arc pole and the angle of the platform that slides in order to carry out the hoop steel wire process.

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 schematic view of the construction of the rack assembly of the present invention;

FIG. 3 is a first schematic view of the radial expansion assembly of the present invention;

FIG. 4 is a schematic view of the structure of the arc-shaped retractable plate of the present invention;

FIG. 5 is a schematic view of a dual-handed threaded shaft of the present invention;

FIG. 6 is a schematic view of a radial expansion assembly of the present invention;

FIG. 7 is a first schematic structural diagram of the transmission assembly of the present invention;

FIG. 8 is a second schematic structural view of the transmission assembly of the present invention;

FIG. 9 is a schematic view of a clutch fork of the present invention;

FIG. 10 is a schematic view of the construction of the wire-grommet assembly of the present invention;

FIG. 11 is a schematic view of a semi-circular arc bar configuration of the present invention;

fig. 12 is a schematic structural view of the guide rail sliding table of the invention.

In the figure: a rack assembly 1; a bottom plate 1-1; 1-2 parts of a ribbed plate I; 1-3 of a first hole; a second rib plate 1-4; 1-5 of a second hole; 1-6 of a motor; 1-7 of a motor transmission disc; 1-8 parts of a blower; 1-9 of T-shaped guide rail; a radial telescopic assembly 2; 2-1 of a rubber inflatable tire body; 2-2 of a rotating disc; 2-3 of a rotating disc II; 2-4 of a first sliding chute; 2-5 of a left-handed thread slider; 2-6 of right-handed thread sliding blocks; 2-7 of arc plates; 2-8 of a third hole; 2-9 parts of rollers; 2-10 parts of a steel wire groove; moving the plates 2-11; 2-12 of a connecting rod; a first pin shaft 2-13; a first shaft 2-14; 2-15 parts of a double-rotation-direction threaded shaft; 2-16 parts of a first gear; 2-17 parts of a second gear; shaft two 2-18; 2-19 of left-handed thread; 2-20 of right-handed threads; 2-21 of step end face I; 2-22 of a step end face II; 2-23 of air holes; 2-24 of holes; ribs 2-25; left-handed threaded holes 2-26; hole five 2-27; a transmission assembly 3; the internal gear is connected with a sleeve 3-1; a first support lug 3-2; 3-3 of a first connecting rod; 3-4 of a second connecting rod; driving discs 3-5; 3-6 of a second lug; 3-7 of a sleeve; 3-8 of a clutch shifting fork; a first clutch half shaft 3-9; a second clutch half shaft 3-10; 3-11 parts of a belt; 3-12 gas transmission pipes; 3-13 of a second sliding chute; 3-14 parts of a hole five; 3-15 parts of a handle; 3-16 parts of a second pin shaft; 3-17 parts of a cylindrical lug; a steel wire hoop assembly 4; a semi-circular arc rod 4-1; hole six 4-2; 4-3 of a hole seven; 4-4 of a sliding table; 4-5 of a branch ear; eight 4-6 holes; 4-7 of a support lug; 4-8 parts of a hole nine; 4-9 of guide rail sliding blocks; 4-10 of a pin shaft; 4-11 parts of a rotating fork; and 4-12 hydraulic rods.

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; 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 12, and a multi-model tire processing apparatus includes a rack assembly 1, a radial telescopic assembly 2, a transmission assembly 3, and a steel wire hoop assembly 4, where the rack assembly 1 is connected to the radial telescopic assembly 2, the rack assembly 1 is connected to the transmission assembly 3, the rack assembly 1 is connected to the steel wire hoop assembly 4, and the radial telescopic assembly 2 is connected to the transmission assembly 3.

The second embodiment is as follows:

this embodiment will be described with reference to fig. 1 to 12, which further illustrate the first embodiment, the frame assembly 1 comprises a bottom plate 1-1, a first rib plate 1-2, a first hole 1-3, a second rib plate 1-4, a second hole 1-5, a motor 1-6, a motor transmission disc 1-7, an air blower 1-8 and a T-shaped guide rail 1-9, wherein the bottom plate 1-1 is fixedly connected with the first rib plate 1-2, the second rib plate 1-4 and the motor 1-6, the T-shaped guide rail 1-9 is arranged on the bottom plate 1-1, the first rib plate 1-2 is provided with the first hole 1-3, the second rib plate 1-4 is provided with the second hole 1-5, the motor 1-6 is rotatably connected with the motor transmission disc 1-7, and the motor 1-6 is fixedly connected with the air blower 1-8;

the bottom plate 1-1 is connected with a first rib plate 1-2 and a second rib plate 1-4, holes are formed in the two rib plates and used for being in rotary connection with the radial telescopic combination 2 and the transmission combination 3, the motor 1-6 is fixed on the bottom plate, the blower 1-8 is fixed on the motor 1-6, and the T-shaped guide rail 1-9 is used for being in sliding connection with the steel wire hoop combination 4.

The third concrete implementation mode:

the first embodiment is further described with reference to fig. 1-12, and the radial telescopic assembly 2 includes a rubber pneumatic tire body 2-1, a first rotating disk 2-2, a second rotating disk 2-3, a first sliding chute 2-4, a left-handed thread sliding block 2-5, a right-handed thread sliding block 2-6, an arc plate 2-7, a third hole 2-8, a roller 2-9, a steel wire groove 2-10, a moving plate 2-11, a connecting rod 2-12, a first pin shaft 2-13, a first shaft 2-14, a double-handed thread shaft 2-15, a first gear 2-16, a second gear 2-17, a second shaft 2-18, a left-handed thread 2-19, a right-handed thread 2-20, a first step end face 2-21, a second step end face 2-22, a first step end face 2-16, a second step end face 2-18, a third step end face 2-3, a fourth step end face 2-12, a fourth step end face 2-15, a fourth end face 2-2, a fourth end face, a, 2-23 parts of air hole, 2-24 parts of hole IV, 2-25 parts of rib, 2-26 parts of left-handed thread hole and 2-27 parts of hole V, 2-1 parts of rubber inflatable tire body, 2-2 parts of rotating disc I and 2-3 parts of rotating disc II, 2-2 parts of rotating disc I are fixedly connected, 2-4 parts of sliding groove I and 2-27 parts of hole V are arranged on 2-2 parts of rotating disc I, 2-2 parts of rotating disc I lean against 2-21 parts of step end face I, 2-3 parts of rotating disc II are provided with sliding groove I2-4 parts and 2-27 parts of hole V, 2-3 parts of rotating disc II lean against 2-22 parts of step end face II, 2-4 parts of sliding groove I are connected with 2-11 parts of moving plate in a sliding manner, 2-26 parts of left-handed thread slide block 2-5 is arranged in left-handed thread slide block 2-5, 2-5 parts of left-handed thread slide block is engaged with 2-19 parts of double-15 parts of double-handed thread shaft, the left-handed thread slider 2-5 is provided with ribs 2-25, the right-handed thread slider 2-6 is engaged with right-handed threads 2-20 of a double-handed thread shaft 2-15, the right-handed thread slider 2-6 is provided with ribs 2-25, the arc plate 2-7 is provided with a steel wire groove 2-10, the arc plate 2-7 is fixedly connected with a moving plate 2-11, the moving plate 2-11 is provided with a hole three 2-8, the moving plate 2-11 is rotatably connected with a roller 2-9, a connecting rod 2-12 and a pin shaft one 2-13 are connected with the moving plate 2-11 and the ribs 2-25, the shaft one 2-14 is rotatably connected with the double-handed thread shaft 2-15, the shaft one 2-14 is provided with a gear two 2-17, and the shaft one 2-14 is rotatably connected with the shaft two 2-18, the double-rotation-direction threaded shaft 2-15 is provided with a first gear 2-16, a left-rotation thread 2-19, a right-rotation thread 2-20, a first step end face 2-21, a second step end face 2-22, an air hole 2-23 and a fourth hole 2-24, the double-rotation-direction threaded shaft 2-15 is rotatably connected with the first rib plate 1-2 through a first hole 1-3, and the second shaft 2-18 is rotatably connected with the second rib plate 1-4 through a second hole 1-5;

when in use, the rubber inflatable tire body 2-1 is fixedly connected with the first rotating disc 2-2 and the second rotating disc 2-3, the first rotating disc 2-2 leans against the first step end face 2-21, the second rotating disc 2-3 leans against the second step end face 2-22, the second gear 2-17 on the first shaft 2-14 is connected with the power end, the first shaft 2-14 rotates to drive the first rotating disc 2-2, the second rotating disc 2-3 and the circular arc plate 2-7 to synchronously rotate for belt calendering, when the tire model needs to be adjusted, the first gear 2-16 on the double-rotation threaded shaft 2-15 is connected with the power end, the double-rotation threaded shaft 2-15 is provided with two sections of threads with opposite rotation directions, namely a left-rotation thread 2-19 and a right-rotation thread 2-20, which are respectively engaged with a left-rotation thread slider 2-5 and a right-rotation thread slider 2-6, when the double-screwing-direction threaded shaft 2-15 rotates, the left-handed thread sliding block 2-5 and the right-handed thread sliding block 2-6 simultaneously move in opposite directions or in reverse directions, the ribs 2-25 on the left-handed thread sliding block 2-5 and the right-handed thread sliding block 2-6 are connected with the moving plate 2-11 through the connecting rods 2-12 and the pin shafts 2-13, the rollers 2-9 on the moving plate 2-11 roll on the end faces of the first rotating disc 2-2 and the second rotating disc 2-3, the arc plates 2-7 are controlled to stretch and slide in the first sliding grooves 2-4 on the first rotating disc 2-2 and the second rotating disc 2-3, and the size of the tire is adjusted.

The fourth concrete implementation mode:

the first embodiment is further described with reference to fig. 1-12, the transmission assembly 3 includes an internal gear connecting sleeve 3-1, a support lug I3-2, a connecting rod I3-3, a connecting rod II 3-4, a driving disk 3-5, a support lug II 3-6, a sleeve 3-7, a clutch fork 3-8, a clutch half shaft I3-9, a clutch half shaft II 3-10, a belt 3-11, a gas pipe 3-12, a sliding chute II 3-13, a hole five 3-14, a handle 3-15, a pin shaft II 3-16, a cylindrical lug 3-17, an internal gear connecting sleeve 3-1 meshed with a gear I2-16 on a double-rotation direction threaded shaft 2-15 or a gear II 2-17 on a shaft I2-14, an internal gear connecting sleeve 3-1 is fixedly connected with a support lug I3-2, the support lug I3-2 is rotatably connected with a connecting rod I3-3 through a pin II 3-16, the connecting rod I3-3 is rotatably connected with a connecting rod II 3-4 through a pin II 3-16, the connecting rod II 3-4 is rotatably connected with a support lug II 3-6 through a pin II 3-16, a driving disc 3-5 is fixedly connected with the support lug II 3-6, a sleeve 3-7 is rotatably connected with a clutch shifting fork 3-8 through a hole V3-14 and a cylindrical lug 3-17, the sleeve 3-7 is rotatably connected with a clutch half shaft I3-9, a sliding groove II 3-13 and a hole V3-14 are arranged on the clutch shifting fork 3-8, the clutch shifting fork 3-8 is fixedly connected with a handle 3-15, the first clutch half shaft 3-9 and the second clutch half shaft 3-10 can be fixedly connected under the control of a clutch shifting fork 3-8, the second clutch half shaft 3-10 is connected with a motor transmission disc 1-7 through a belt 3-11, a gas transmission pipe 3-12 is connected with a blower 1-8 and a second shaft 2-18, and the second shaft 2-18 is rotationally connected with the first clutch half shaft 3-9 and the second clutch half shaft 3-10;

when the motor 1-6 works, power is transmitted to the clutch half shaft two 3-10 from the motor transmission disc 1-7 through the belt 3-11, the clutch half shaft two 3-10 rotates on the shaft two 2-18, the sleeve 3-7 is sleeved on the clutch half shaft one 3-9 and is connected with the clutch half shaft one 3-9 in a rotating way, the position of the clutch shifting fork 3-8 is adjusted to control the contact and separation of the clutch half shaft one 3-9 and the clutch half shaft two 3-10, so that the power transmission is realized, the driving disc 3-5 is connected with the connecting sleeve 3-1 through the support lug one 3-2, the connecting rod one 3-3, the connecting rod two 3-4, the support lug two 3-6 and the pin shaft two 3-16, an internal gear of the internal gear connecting sleeve 3-1 is meshed with the gear one 2-16 on the double-screwing-direction threaded shaft 2-15 or the gear two 2-17 on the shaft one 2-14, changing the working mode, adjusting the size of the tire, when the rubber pneumatic tire body 2-1 needs to be inflated, the air blower 1-8 sucks air to work, and air is inflated into the rubber pneumatic tire body 2-1 through the air delivery pipe 3-12 and the shaft II 2-18.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 12, and the embodiment further describes the first embodiment, where the wire hoop assembly 4 includes a semicircular arc rod 4-1, a hole six 4-2, a hole seven 4-3, a sliding table 4-4, a support lug three 4-5, a hole eight 4-6, a support lug four 4-7, a hole nine 4-8, a guide rail slider 4-9, a pin shaft three 4-10, a rotating fork 4-11, and a hydraulic rod 4-12, the semicircular arc rod 4-1 is provided with a hole six 4-2 and a hole seven 4-3, the semicircular arc rod 4-1 is rotatably connected with the sliding table 4-4 through the pin shaft three 4-10, the semicircular arc rod 4-1 is rotatably connected with the rotating fork 4-11 through the hole six 4-2, the sliding table 4-4 is fixedly connected with the support lug three 4-5, the sliding table 4-4 is fixedly connected with the four support lugs 4-7, the sliding table 4-4 is fixedly connected with the guide rail sliding blocks 4-9, the three support lugs 4-5 are provided with eight holes 4-6, the four support lugs 4-7 are provided with nine holes 4-8, the rotating forks 4-11 are slidably connected with the hydraulic rods 4-12, the sliding table 4-4 is rotatably connected with the hydraulic rods 4-12 through the three pin shafts 4-10, and the guide rail sliding blocks 4-9 are slidably connected with the T-shaped guide rails 1-9 on the bottom plate 1-1;

the hooping steel wire is an important process in the green tire manufacturing process, the steel wire is clamped by two semicircular arc rods 4-1, steel wire grooves 2-10 with different tire thickness sizes are formed in the arc plates 2-7, the sliding table 4-4 is driven by the guide rail sliding blocks 4-9 to slide in the T-shaped guide rails 1-9 on the bottom plate 1-1, the semicircular arc rods 4-1 can rotate around the three support lugs 4-5, and the angles of the semicircular arc rods 4-1 and the sliding table 4-4 are adjusted through the rotating forks 4-11 and the hydraulic rods 4-12 so as to carry out the hooping steel wire process.

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

the bottom plate 1-1 is connected with a first rib plate 1-2 and a second rib plate 1-4, holes are respectively formed in the two rib plates and used for being in rotary connection with the radial telescopic combination 2 and the transmission combination 3, the motor 1-6 is fixed on the bottom plate, the blower 1-8 is fixed on the motor 1-6, and the T-shaped guide rail 1-9 is used for being in sliding connection with the steel wire hoop combination 4; when in use, the rubber inflatable tire body 2-1 is fixedly connected with the first rotating disc 2-2 and the second rotating disc 2-3, the first rotating disc 2-2 leans against the first step end face 2-21, the second rotating disc 2-3 leans against the second step end face 2-22, the second gear 2-17 on the first shaft 2-14 is connected with the power end, the first shaft 2-14 rotates to drive the first rotating disc 2-2, the second rotating disc 2-3 and the circular arc plate 2-7 to synchronously rotate for belt calendering, when the tire model needs to be adjusted, the first gear 2-16 on the double-rotation threaded shaft 2-15 is connected with the power end, the double-rotation threaded shaft 2-15 is provided with two sections of threads with opposite rotation directions, namely a left-rotation thread 2-19 and a right-rotation thread 2-20, which are respectively engaged with a left-rotation thread slider 2-5 and a right-rotation thread slider 2-6, when the double-screwing-direction threaded shaft 2-15 rotates, the left-handed thread sliding block 2-5 and the right-handed thread sliding block 2-6 simultaneously move in opposite directions or in reverse directions, ribs 2-25 on the left-handed thread sliding block 2-5 and the right-handed thread sliding block 2-6 are connected with the moving plate 2-11 through connecting rods 2-12 and a pin shaft I2-13, rollers 2-9 on the moving plate 2-11 roll on the end faces of the rotating disc I2-2 and the rotating disc II 2-3, and the arc plate 2-7 is controlled to stretch and slide in a sliding groove I2-4 on the rotating disc I2-2 and the rotating disc II 2-3 to adjust the size of the tire; when the motor 1-6 works, power is transmitted to the clutch half shaft two 3-10 from the motor transmission disc 1-7 through the belt 3-11, the clutch half shaft two 3-10 rotates on the shaft two 2-18, the sleeve 3-7 is sleeved on the clutch half shaft one 3-9 and is connected with the clutch half shaft one 3-9 in a rotating way, the position of the clutch shifting fork 3-8 is adjusted to control the contact and separation of the clutch half shaft one 3-9 and the clutch half shaft two 3-10, so that the power transmission is realized, the driving disc 3-5 is connected with the connecting sleeve 3-1 through the support lug one 3-2, the connecting rod one 3-3, the connecting rod two 3-4, the support lug two 3-6 and the pin shaft two 3-16, an internal gear of the internal gear connecting sleeve 3-1 is meshed with the gear one 2-16 on the double-screwing-direction threaded shaft 2-15 or the gear two 2-17 on the shaft one 2-14, changing the working mode, adjusting the size of the tire, when the rubber pneumatic tire body 2-1 needs to be inflated, the air blower 1-8 sucks air to work, and air is inflated into the rubber pneumatic tire body 2-1 through the air delivery pipe 3-12 and the shaft II 2-18; the hooping steel wire is an important process in the green tire manufacturing process, the steel wire is clamped by two semicircular arc rods 4-1, steel wire grooves 2-10 with different tire thickness sizes are formed in the arc plates 2-7, the sliding table 4-4 is driven by the guide rail sliding blocks 4-9 to slide in the T-shaped guide rails 1-9 on the bottom plate 1-1, the semicircular arc rods 4-1 can rotate around the three support lugs 4-5, and the angles of the semicircular arc rods 4-1 and the sliding table 4-4 are adjusted through the rotating forks 4-11 and the hydraulic rods 4-12 so as to carry out the hooping steel wire process.

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

1. The utility model provides a polytypic tire processing equipment which characterized in that: including frame assembly (1), radial flexible assembly (2), transmission assembly (3), steel wire hoop ring assembly (4), frame assembly (1) is connected with radial flexible assembly (2), and frame assembly (1) is connected with transmission assembly (3), and frame assembly (1) is connected with steel wire hoop ring assembly (4), and radial flexible assembly (2) is connected with transmission assembly (3).

2. A multiple model tire building apparatus according to claim 1, wherein: the rack assembly (1) comprises a bottom plate (1-1), a first rib plate (1-2), a first hole (1-3), a second rib plate (1-4), a second hole (1-5), a motor (1-6), a motor transmission disc (1-7), a blower (1-8) and a T-shaped guide rail (1-9), the bottom plate (1-1) is fixedly connected with the first rib plate (1-2), the second rib plate (1-4) and the motor (1-6), the T-shaped guide rail (1-9) is arranged on the bottom plate (1-1), the first rib plate (1-2) is provided with a first hole (1-3), the second rib plate (1-4) is provided with a second hole (1-5), the motor (1-6) is rotatably connected with the motor transmission disc (1-7), and the motor (1-6) is fixedly connected with the blower (1-8).

3. A multiple model tire building apparatus according to claim 1, wherein: the radial telescopic assembly (2) comprises a rubber inflatable tire body (2-1), a first rotating disc (2-2), a second rotating disc (2-3), a first sliding groove (2-4), a left-handed thread sliding block (2-5), a right-handed thread sliding block (2-6), an arc plate (2-7), a third hole (2-8), a roller (2-9), a steel wire groove (2-10), a moving plate (2-11), a connecting rod (2-12), a first pin shaft (2-13), a first shaft (2-14), a double-handed thread shaft (2-15), a first gear (2-16), a second gear (2-17), a second shaft (2-18), a left-handed thread (2-19), a right-handed thread (2-20), a first step end face (2-21), A second step end face (2-22), air holes (2-23), a fourth hole (2-24), ribs (2-25), a left-handed threaded hole (2-26) and a fifth hole (2-27), a rubber inflatable tire body (2-1) is fixedly connected with the first rotating disc (2-2) and the second rotating disc (2-3), a first sliding chute (2-4) and the fifth hole (2-27) are arranged on the first rotating disc (2-2), the first rotating disc (2-2) leans against the first step end face (2-21), a first sliding chute (2-4) and a fifth hole (2-27) are arranged on the second rotating disc (2-3), the second rotating disc (2-3) leans against the second step end face (2-22), and the first sliding chute (2-4) is connected with a moving plate (2-11) in a sliding manner, a left-handed thread hole (2-26) is arranged in the left-handed thread slider (2-5), the left-handed thread slider (2-5) is meshed with a left-handed thread (2-19) of a double-handed thread shaft (2-15), a rib (2-25) is arranged on the left-handed thread slider (2-5), a right-handed thread slider (2-6) is meshed with a right-handed thread (2-20) of the double-handed thread shaft (2-15), a rib (2-25) is arranged on the right-handed thread slider (2-6), a steel wire groove (2-10) is arranged on the arc plate (2-7), the arc plate (2-7) is fixedly connected with a moving plate (2-11), a third hole (2-8) is arranged on the moving plate (2-11), and the moving plate (2-11) is rotatably connected with a roller (2-9), the connecting rod (2-12) and the pin shaft I (2-13) are connected with the moving plate (2-11) and the rib (2-25), the shaft I (2-14) is rotationally connected with the double-rotation-direction threaded shaft (2-15), the shaft I (2-14) is provided with a gear II (2-17), the shaft I (2-14) is rotationally connected with the shaft II (2-18), the double-rotation-direction threaded shaft (2-15) is provided with a gear I (2-16), a left-rotation thread (2-19), a right-rotation thread (2-20), a step end face I (2-21), a step end face II (2-22), an air hole (2-23) and a hole IV (2-24), the double-rotation-direction threaded shaft (2-15) is rotationally connected with the rib plate I (1-2) through the hole I (1-3), and the shaft II (2-18) is rotationally connected with the rib plate II (1-4) through the hole II (1-5) And (4) connecting.

4. A multiple model tire building apparatus according to claim 1, wherein: the transmission assembly (3) comprises an internal gear connecting sleeve (3-1), a support lug I (3-2), a connecting rod I (3-3), a connecting rod II (3-4), a driving disc (3-5), a support lug II (3-6), a sleeve (3-7), a clutch shifting fork (3-8), a clutch half shaft I (3-9), a clutch half shaft II (3-10), a belt (3-11), a gas pipe (3-12), a sliding groove II (3-13), a hole II (3-14), a handle (3-15), a pin shaft II (3-16) and a cylindrical lug (3-17), wherein the internal gear connecting sleeve (3-1) is meshed with a gear I (2-16) on a double-rotation direction threaded shaft (2-15) or a gear II (2-17) on the shaft I (2-14), an internal gear connecting sleeve (3-1) is fixedly connected with a support lug I (3-2), the support lug I (3-2) is rotatably connected with a connecting rod I (3-3) through a pin shaft II (3-16), the connecting rod I (3-3) is rotatably connected with a connecting rod II (3-4) through a pin shaft II (3-16), the connecting rod II (3-4) is rotatably connected with the support lug II (3-6) through a pin shaft II (3-16), a driving disc (3-5) is fixedly connected with the support lug II (3-6), a sleeve (3-7) is rotatably connected with a clutch shifting fork (3-8) through a hole V (3-14) and a cylindrical lug (3-17), the sleeve (3-7) is rotatably connected with a clutch half shaft I (3-9), and a sliding groove II (3-13) is arranged on the clutch shifting fork (3-8), The hole five (3-14), the clutch shift fork (3-8) and the handle (3-15) are fixedly connected, the clutch half shaft one (3-9) and the clutch half shaft two (3-10) can be fixedly connected under the control of the clutch shift fork (3-8), the clutch half shaft two (3-10) and the motor transmission disc (1-7) are connected through a belt (3-11), the air delivery pipe (3-12) is connected with the blower (1-8) and the shaft two (2-18), and the shaft two (2-18) is rotatably connected with the clutch half shaft one (3-9) and the clutch half shaft two (3-10).

5. A multiple model tire building apparatus according to claim 1, wherein: the steel wire hoop combination body (4) comprises a semicircular arc rod (4-1), a hole six (4-2), a hole seven (4-3), a sliding table (4-4), a support lug three (4-5), a hole eight (4-6), a support lug four (4-7), a hole nine (4-8), a guide rail sliding block (4-9), a pin shaft three (4-10), a rotating fork (4-11) and a hydraulic rod (4-12), wherein the semicircular arc rod (4-1) is provided with the hole six (4-2) and the hole seven (4-3), the semicircular arc rod (4-1) is rotatably connected with the sliding table (4-4) through the pin shaft three (4-10), the semicircular arc rod (4-1) is rotatably connected with the rotating fork (4-11) through the hole six (4-2), the sliding table (4-4) is fixedly connected with the support lug three (4-5), the sliding table (4-4) is fixedly connected with the four support lugs (4-7), the sliding table (4-4) is fixedly connected with the guide rail sliding block (4-9), the three support lugs (4-5) are provided with eight holes (4-6), the four support lugs (4-7) are provided with nine holes (4-8), the rotating forks (4-11) are slidably connected with the hydraulic rods (4-12), the sliding table (4-4) is rotatably connected with the hydraulic rods (4-12) through the three pin shafts (4-10), and the guide rail sliding block (4-9) is slidably connected with the T-shaped guide rail (1-9) on the bottom plate (1-1).