CN113084260A

CN113084260A - Processing equipment for spherical cavity or quasi-spherical cavity of hub mold

Info

Publication number: CN113084260A
Application number: CN202110380912.6A
Authority: CN
Inventors: 付国军
Original assignee: Individual
Current assignee: Sichuan Yingxin Huitong Industrial Co ltd
Priority date: 2021-04-09
Filing date: 2021-04-09
Publication date: 2021-07-09
Anticipated expiration: 2041-04-09
Also published as: CN113084260B

Abstract

The invention relates to the field of hub die processing, in particular to processing equipment for a spherical cavity or a quasi-spherical cavity of a hub die. The spherical cavity or the similar spherical cavity of the hub mould can be processed, and the sphere diameter and the sphere radian can be adjusted. The device comprises a fixing assembly, a cavity processing assembly and a power assembly, wherein the fixing assembly is connected with the power assembly in a matched mode, and the cavity processing assembly is connected with the power assembly in a matched mode. And then through one-way separation and reunion kelly one with to the one-way cooperation rotation of separation and reunion kelly two avoid, one-way separation and reunion kelly one with to the one-way rotation of separation and reunion kelly two effective, one-way separation and reunion kelly one with to the separation and reunion kelly two one-way rotation effective can make the ball footpath that sword one and sword two can cut change, one-way separation and reunion kelly one with to the separation and reunion kelly two between ineffective function interference of avoiding of relative antiport.

Description

Processing equipment for spherical cavity or quasi-spherical cavity of hub mold

Technical Field

The invention relates to the field of hub die processing, in particular to processing equipment for a spherical cavity or a quasi-spherical cavity of a hub die.

Background

The processing equipment of the hub mould spherical cavity or the quasi-spherical cavity is common equipment in the field of hub mould processing, but the processing equipment of the general hub mould spherical cavity or the quasi-spherical cavity has single function.

Disclosure of Invention

The invention aims to provide a processing device of a spherical cavity or a sphere-like cavity of a hub die, which can process the spherical cavity or the sphere-like cavity of the hub die and can adjust the sphere diameter and the sphere radian.

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

the utility model provides a processing equipment of spherical cavity of wheel hub mould or quasi-spherical cavity, includes fixed subassembly, cavity processing subassembly, power component, fixed subassembly is connected with the power component cooperation, and cavity processing subassembly is connected with the power component cooperation.

As a further optimization of the technical scheme, the hub mold spherical cavity or quasi-spherical cavity processing equipment comprises a fixing assembly and a fixing assembly, wherein the fixing assembly comprises an outer end sleeve, a fixing slider, a fixing round wheel, a rectangular sliding groove, a spiral sliding groove, a back plate, a spherical clamping rod pushing spring and a spherical clamping groove, the rectangular sliding groove is formed in the outer end sleeve, the fixing slider is connected with the rectangular sliding groove in a sliding mode, the fixing round wheel is connected with the fixing slider in a rotating mode, the fixing slider is connected with the spiral sliding groove in a sliding mode, the spiral sliding groove is formed in the back plate, the back plate is connected with the outer end sleeve in a rotating mode, the spherical clamping rod is connected with the back plate in a sliding mode, the spherical clamping rod pushing spring is arranged between the spherical clamping rod and the back plate, the spherical clamping rod is connected with.

As a further optimization of the technical scheme, the invention relates to a processing device of a spherical cavity or a quasi-spherical cavity of a hub die, wherein a cavity processing assembly comprises a middle end bracket, a first driving rotary table, a first cutting edge connecting rod, a first connecting rod rotating rod, a first bevel gear shaft, a first bevel gear, a second bevel gear, a third bevel gear, a fourth bevel gear, a fifth bevel gear, a sixth bevel gear, a second driving rotary table, a seventh bevel gear, an eighth bevel gear, a ninth bevel gear, a first straight gear, a tenth bevel gear, a manual driving rod, a first bevel gear shaft sleeve, a second bevel gear shaft, a second connecting rod rotating rod, a second cutting edge connecting rod, a first connecting sleeve, a second connecting sleeve, a third bevel gear shaft, a first matching clamping rod pushing spring, a second cutting edge, a first one-way clutch clamping rod, a second one-way clutch clamping rod pushing spring and a hinged frame, wherein the first cutting edge is connected with the first driving rotary table in a sliding manner, and one end of the first cutting edge is connected with the first cutting edge, the other end of the first cutting edge connecting rod is hinged with the first connecting rod rotating rod, the first connecting rod rotating rod is fixedly connected with the first bevel gear shaft, the second bevel gear is fixedly connected with the first bevel gear shaft, one end of the first bevel gear shaft sleeve is fixedly connected with the first driving turntable, the other end of the first bevel gear shaft sleeve is fixedly connected with the first bevel gear, the first bevel gear shaft is rotatably connected with the middle end bracket, the first bevel gear shaft is rotatably connected with the first bevel gear shaft sleeve, the third bevel gear is in meshing transmission with the second bevel gear, the third bevel gear is fixedly connected with the second connecting sleeve, the second connecting sleeve is rotatably connected with the first connecting sleeve, the first bevel gear is fixedly connected with the first connecting sleeve, the fourth bevel gear is in meshing transmission with the first bevel gear, the fifth bevel gear is in meshing transmission with the third bevel gear, the sixth bevel gear is in meshing transmission with the fourth bevel gear, one end of the second bevel gear shaft is fixedly connected with the fifth bevel gear, the other end of the second connecting rod rotating rod, and one end of the second bevel gear is fixedly connected with the, the other end of the bevel gear shaft sleeve II is fixedly connected with the driving rotary table II, the bevel gear shaft sleeve II is rotatably connected with the middle end bracket, the bevel gear shaft II is rotatably connected with the bevel gear shaft sleeve II, one end of the connecting rod rotating rod II is fixedly connected with the bevel gear shaft II, the other end of the connecting rod rotating rod II is hinged with the cutting edge connecting rod II, the cutting edge connecting rod II is hinged with the cutting edge II, the cutting edge II is slidably connected with the driving rotary table II, the bevel gear nine is rotatably connected with the middle end bracket, the straight tooth I is fixedly connected with the bevel gear nine, the bevel gear nine is in meshing transmission with the bevel gear seven, the bevel gear seven is fixedly connected with the connecting sleeve I, the bevel gear eight is fixedly connected with the connecting sleeve II, the bevel gear eight is in meshing transmission with the bevel gear ten, the bevel gear shaft III is rotatably connected with the middle end bracket, the bevel gear shaft III is fixedly connected with the manual driving rod, the manual driving rod is in matching connection with the clamping rod I, the matching clamping rod I is slidably connected with the middle end bracket, and the matching, one-way clutch clamping rod II is fixedly connected with the bevel gear II, one-way clutch clamping rod I is connected with the clutch clamping rod II in a matched mode, the one-way clutch clamping rod I is connected with the bevel gear shaft III in a sliding mode, a one-way clutch clamping rod push spring is connected with the one-way clutch clamping rod I in a sleeved mode, the one-way clutch clamping rod push spring is arranged between the one-way clutch clamping rod I and the bevel gear shaft III, the one-way clutch clamping rod II is rotatably connected with the hinged frame, and the hinged frame is fixedly connected with the middle-end support.

As a further optimization of the technical scheme, the invention relates to a processing device of a spherical cavity or a quasi-spherical cavity of a hub die, which comprises a power underframe, a slide bar bracket I, a lower end rotating rod I, a transmission belt I, a belt wheel I, a lower end auxiliary rod, a driving belt wheel, a driving belt, a driving roller, a bidirectional circulating groove, a matching roller wheel, a roller wheel rotating frame, a rack bar bracket, a tension spring I, a driving rack bar, a limiting rod I, a limiting rod II, a manual straight tooth, a lower end rack I, a lower end rack II, an upper end fixing rod and a rectangular groove, wherein the slide bar bracket I is connected with the power underframe in a sliding way, the lower end rotating rod I is connected with the slide bar bracket in a rotating way, the belt wheel I is fixedly connected with the lower end rotating rod I, the transmission belt wheel I is connected with the belt wheel I in a matching way, the lower end auxiliary rod is connected with the power underframe in a, a lower end rotating rod I is connected with a lower end auxiliary rod in a sliding fit manner, a driving roller is connected with a power chassis in a rotating manner, a bidirectional circulating groove is formed in the driving roller, a fit roller is connected with the bidirectional circulating groove in a matching manner, the fit roller is connected with a roller rotating frame in a rotating manner, an upper end fixing rod is fixedly connected with the roller rotating frame, the roller rotating frame is connected with a rack rod support in a rotating manner, one end of a tension spring I is connected with the rack rod support, the other end of the tension spring I is connected with the upper end fixing rod, the driving rack rod is fixedly connected with the rack rod support, a rectangular groove is formed in the power chassis, a lower end rack II is connected with the rectangular groove in a sliding manner, the lower end rack II is fixedly connected with a limiting rod I, manual straight teeth are connected to the inner end of the rectangular groove in a rotating manner, the lower end rack I is connected with the rectangular groove in, the first transmission belt is matched and connected with the back plate, the driving belt is matched and connected with the driving roller, and the first straight tooth is meshed and transmitted with the driving rack rod.

As the technical scheme is further optimized, the contact surface of the first lower rotating rod and the lower auxiliary rod is non-circular.

As a further optimization of the technical scheme, according to the processing equipment for the spherical cavity or the quasi-spherical cavity of the hub die, the driving roller is externally connected with a matched motor a, and the matched motor a is arranged on the power underframe.

The processing equipment for the spherical cavity or the quasi-spherical cavity of the hub die has the beneficial effects that:

the invention relates to a processing device of a spherical cavity or a quasi-spherical cavity of a hub die, which aims to avoid functional interference between processing when the sphere diameter which can be cut by a first carving edge and a second carving edge is changed and processing of reciprocating swing of the first carving edge and the second carving edge, and further avoid the functional interference by one-way matching and rotating of a one-way clutch clamping rod I and a clutch clamping rod II.

Drawings

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

FIG. 1 is a first general structural diagram of the present invention;

FIG. 2 is a second overall structural schematic of the present invention;

FIG. 3 is a third schematic view of the overall structure of the present invention;

FIG. 4 is a first schematic structural view of the fixing member 1 of the present invention;

FIG. 5 is a second structural view of the fixing member 1 of the present invention;

FIG. 6 is a first schematic structural view of the cavity machining assembly 2 of the present invention;

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

FIG. 8 is a schematic illustration of the construction of the cavity machining assembly 2 of the present invention;

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

FIG. 10 is a first schematic structural view of the power assembly 3 of the present invention;

FIG. 11 is a second schematic structural view of the power assembly 3 of the present invention;

fig. 12 is a third structural schematic diagram of the power assembly 3 of the present invention.

In the figure: a fixing assembly 1; an outer end sleeve 1-1; 1-2 of a fixed slider; 1-3 of a fixed round wheel; 1-4 of a rectangular chute; 1-5 of a spiral chute; 1-6 of a back plate; 1-7 parts of a spherical clamping rod; 1-8 parts of a spherical clamping rod push spring; 1-9 parts of a spherical clamping groove; a cavity machining assembly 2; a middle bracket 2-1; driving the first rotating disc 2-2; 2-3 of a first carving edge; 2-4 of a nicking edge connecting rod; a first connecting rod rotating rod 2-5; 2-6 parts of a bevel gear shaft I; 2-7 parts of a first bevel gear; 2-8 parts of a second bevel gear; 2-9 parts of bevel gear III; 2-10 parts of bevel gear; 2-11 parts of bevel gear five; 2-12 parts of bevel gear; driving a second rotating disc 2-13; 2-14 parts of bevel gear seven; eight 2-15 of bevel gear; nine 2-16 conical teeth; 2-17 parts of straight teeth I; ten 2-18 parts of bevel gear; a manual drive lever 2-19; 2-20 parts of a first bevel gear shaft sleeve; 2-21 parts of a second bevel gear shaft sleeve; 2-22 parts of a second bevel gear shaft; a second connecting rod rotating rod 2-23; 2-24 of a nicking edge connecting rod; connecting sleeves I2-25; connecting sleeves II 2-26; 2-27 parts of a bevel gear shaft; 2-28 of a first matching clamping rod; 2-29 of a push spring matched with the clamping rod; 2-30 parts of a second carving edge; a one-way clutch clamping rod I2-31; 2-32 of a one-way clutch clamping rod II; the one-way clutch clamping rod pushes the spring 2-33; hinge brackets 2-34; a power assembly 3; a power chassis 3-1; 3-2 parts of a sliding rod bracket I; a lower end rotating rod I3-3; 3-4 parts of a first transmission belt; 3-5 of a first belt wheel; 3-6 parts of lower auxiliary rod; a drive pulley 3-7; 3-8 of a driving belt; drive rollers 3-9; 3-10 parts of a bidirectional circulation tank; matching with rollers 3-11; 3-12 roller rotating frames; rack bar supports 3-13; 3-14 parts of a first tension spring; driving the rack bar 3-15; 3-16 parts of a first limiting rod; 3-17 parts of a second limiting rod; 3-18 parts of manual straight teeth; the lower end of the rack I is 3-19; 3-20 parts of a second rack at the lower end; fixing rods 3-21 at the upper end; rectangular slots 3-22.

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 following describes this embodiment with reference to fig. 1 to 12, and a processing apparatus for a spherical cavity or a quasi-spherical cavity of a hub mold includes a fixing component 1, a cavity processing component 2, and a power component 3, where the fixing component 1 is connected to the power component 3 in a matching manner, and the cavity processing component 2 is connected to the power component 3 in a matching manner.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 12, and the embodiment further describes the first embodiment, where the fixing assembly 1 includes an outer end sleeve 1-1, a fixing slider 1-2, a fixing circular wheel 1-3, a rectangular sliding groove 1-4, a spiral sliding groove 1-5, a back plate 1-6, a spherical clamping rod 1-7, a spherical clamping rod pushing spring 1-8, and a spherical clamping groove 1-9, the rectangular sliding groove 1-4 is disposed on the outer end sleeve 1-1, the fixing slider 1-2 is slidably connected with the rectangular sliding groove 1-4, the fixing circular wheel 1-3 is rotatably connected with the fixing slider 1-2, the fixing slider 1-2 is slidably connected with the spiral sliding groove 1-5, the spiral sliding groove 1-5 is disposed on the back plate 1-6, the back plate 1-6 is rotatably connected with the outer end sleeve 1-1, the spherical clamping rods 1-7 are connected with the back plate 1-6 in a sliding mode, the spherical clamping rod push springs 1-8 are arranged between the spherical clamping rods 1-7 and the back plate 1-6, the spherical clamping rods 1-7 are connected with the spherical clamping grooves 1-9 in a matched mode, and the spherical clamping grooves 1-9 are arranged at the inner end of the outer end sleeve 1-1.

The third concrete implementation mode:

the first embodiment is further described with reference to fig. 1-12, and the first embodiment is further described, wherein the cavity processing assembly 2 comprises a middle end support 2-1, a first driving rotary table 2-2, a first nicking edge 2-3, a first nicking edge connecting rod 2-4, a first connecting rod rotating rod 2-5, a first conical tooth shaft 2-6, a first conical tooth 2-7, a second conical tooth 2-8, a third conical tooth 2-9, a fourth conical tooth 2-10, a fifth conical tooth 2-11, a sixth conical tooth 2-12, a second driving rotary table 2-13, a seventh conical tooth 2-14, an eighth conical tooth 2-15, a ninth conical tooth 2-16, a first straight tooth 2-17, a tenth conical tooth 2-18, a manual driving rod 2-19, a first conical tooth shaft sleeve 2-20, a second conical tooth shaft sleeve 2-21, a second conical tooth shaft 2-22, a third conical tooth shaft 2-7, a third conical tooth shaft 2-8, a, A second connecting rod rotating rod 2-23, a second nicking edge connecting rod 2-24, a first connecting sleeve 2-25, a second connecting sleeve 2-26, a third conical gear shaft 2-27, a first matching clamping rod 2-28, a first matching clamping rod push spring 2-29, a second nicking edge 2-30, a first one-way clutch clamping rod 2-31, a second one-way clutch clamping rod 2-32, a first one-way clutch clamping rod push spring 2-33 and a hinge frame 2-34, wherein the first nicking edge 2-3 is connected with the first driving turntable 2-2 in a sliding manner, one end of the first nicking edge connecting rod 2-4 is connected with the first nicking edge 2-3 in a hinged manner, the other end of the first nicking edge connecting rod 2-4 is connected with the first connecting rod rotating rod 2-5 in a hinged manner, the first connecting rod rotating rod 2-5 is fixedly connected with the first conical gear shaft 2-6, and the second conical gear 2-8 is fixedly connected with, one end of a first bevel gear shaft sleeve 2-20 is fixedly connected to a first driving turntable 2-2, the other end of the first bevel gear shaft sleeve 2-20 is fixedly connected to a first bevel gear 2-7, the first bevel gear shaft sleeve 2-20 is rotatably connected with a middle end support 2-1, a first bevel gear shaft 2-6 is rotatably connected with the first bevel gear shaft sleeve 2-20, a third bevel gear 2-9 is in meshing transmission with a second bevel gear 2-8, a third bevel gear 2-9 is fixedly connected with a second connecting sleeve 2-26, a second connecting sleeve 2-26 is rotatably connected with a first connecting sleeve 2-25, a first connecting sleeve 2-25 is rotatably connected with the middle end support 2-1, a fourth bevel gear 2-10 is fixedly connected with the first connecting sleeve 2-25, a fourth bevel gear 2-10 is in meshing transmission with the first bevel gear 2-7, a fifth bevel gear 2-11 is in meshing transmission with the third bevel gear 2-9, bevel gear six 2-12 is in meshed transmission with bevel gear four 2-10, one end of a bevel gear shaft two 2-22 is fixedly connected with bevel gear five 2-11, the other end of the bevel gear shaft two 2-22 is fixedly connected with a connecting rod rotating rod two 2-23, one end of a bevel gear shaft sleeve two 2-21 is fixedly connected with bevel gear six 2-12, the other end of the bevel gear shaft sleeve two 2-21 is fixedly connected with a driving turntable two 2-13, the bevel gear shaft sleeve two 2-21 is rotatably connected with a middle end bracket 2-1, the bevel gear shaft two 2-22 is rotatably connected with the bevel gear shaft sleeve two 2-21, one end of the connecting rod rotating rod two 2-23 is fixedly connected with the bevel gear shaft two 2-22, the other end of the connecting rod rotating rod two 2-23 is hinged with a cutter connecting rod two 2-24, the cutter connecting rod two 2-24 is hinged with a cutter second 2-30, the second cutting edge 2-30 is connected with the second driving turntable 2-13 in a sliding manner, the ninth bevel gear 2-16 is connected with the middle end bracket 2-1 in a rotating manner, the first straight gear 2-17 is fixedly connected with the ninth bevel gear 2-16, the ninth bevel gear 2-16 is in meshing transmission with the seventh bevel gear 2-14, the seventh bevel gear 2-14 is fixedly connected with the first connecting sleeve 2-25, the eighth bevel gear 2-15 is fixedly connected with the second connecting sleeve 2-26, the eighth bevel gear 2-15 is in meshing transmission with the tenth bevel gear 2-18, the third bevel gear shaft 2-27 is connected with the middle end bracket 2-1 in a rotating manner, the third bevel gear shaft 2-27 is fixedly connected with the manual driving rod 2-19, the manual driving rod 2-19 is in matching connection with the first matching clamping rod 2-28, and the first matching clamping rod 2-28 is in sliding connection with the middle end bracket 2-1, the first matching clamping rod push spring 2-29 is arranged between the first matching clamping rod 2-28 and the middle support 2-1, the second one-way clutch clamping rod 2-32 is fixedly connected with the cross gear 2-18, the first one-way clutch clamping rod 2-31 is connected with the second one-way clutch clamping rod 2-32 in a matching mode, the first one-way clutch clamping rod 2-31 is connected with the third one-way gear shaft 2-27 in a sliding mode, the push spring 2-33 of the first one-way clutch clamping rod is connected with the first one-way clutch clamping rod 2-31 in a sleeved mode, the push spring 2-33 of the first one-way clutch clamping rod is arranged between the first one-way clutch clamping rod 2-31 and the third one-way gear shaft 2-27, the second one-way clutch clamping rod 2-32 is connected with the hinge support 2-34 in a rotating mode, and the hinge support 2-34 is;

in order to avoid functional interference between the machining when the diameter of the ball which can be cut by the first carving edge 2-3 and the second carving edge 2-30 is changed and the machining of the reciprocating swing of the first carving edge 2-3 and the second carving edge 2-30, and then the unidirectional matching rotation is avoided through the unidirectional clutch clamping rod I2-31 and the unidirectional matching rotation is avoided towards the clutch clamping rod II 2-32, the unidirectional rotation of the unidirectional clutch clamping rod I2-31 and the unidirectional rotation towards the clutch clamping rod II 2-32 is effective, the relative reverse rotation between the unidirectional clutch clamping rod I2-31 and the unidirectional rotation towards the clutch clamping rod II 2-32 is ineffective, the unidirectional rotation of the unidirectional clutch clamping rod I2-31 and the unidirectional rotation towards the clutch clamping rod II 2-32 is effective, the ball diameter which can be cut by the carving edge I2-3 and the carving edge II 2-30 can be changed, and the relative reverse rotation between the unidirectional clutch clamping rod I2-31 and the unidirectional rotation towards the clutch clamping rod II 2-32 is ineffective to avoid functional interference.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1-12, and the embodiment will be further described, wherein the power assembly 3 comprises a power chassis 3-1, a first sliding rod support 3-2, a first lower rotating rod 3-3, a first transmission belt 3-4, a first belt pulley 3-5, a second lower auxiliary rod 3-6, a driving belt pulley 3-7, a driving belt 3-8, a driving roller 3-9, a bidirectional circulating groove 3-10, a matching roller 3-11, a roller rotating frame 3-12, a rack rod support 3-13, a first tension spring 3-14, a driving rack rod 3-15, a first limit rod 3-16, a second limit rod 3-17, a manual straight gear 3-18, a first lower rack 3-19, a second lower rack 3-20, and a fixed upper end rod 3-21, A rectangular groove 3-22, a first slide rod support 3-2 is connected with a power chassis 3-1 in a sliding manner, a first lower rotating rod 3-3 is connected with a first slide rod support 3-2 in a rotating manner, a first belt wheel 3-5 is fixedly connected with a first lower rotating rod 3-3, a first transmission belt 3-4 is connected with the first belt wheel 3-5 in a matching manner, a lower auxiliary rod 3-6 is connected with the power chassis 3-1 in a rotating manner, a driving belt wheel 3-7 is fixedly connected with the lower auxiliary rod 3-6, one end of a driving belt 3-8 is connected with a driving belt wheel 3-7 in a matching manner, the first lower rotating rod 3-3 is connected with the lower auxiliary rod 3-6 in a sliding manner, a driving roller 3-9 is connected with the power chassis 3-1 in a rotating manner, and a bidirectional circulating groove 3-10 is arranged on, the matched roller 3-11 is matched and connected with the bidirectional circulating groove 3-10, the matched roller 3-11 is rotatably connected with a roller rotating frame 3-12, the upper end fixing rod 3-21 is fixedly connected with the roller rotating frame 3-12, the roller rotating frame 3-12 is rotatably connected with a rack bar bracket 3-13, one end of a first tension spring 3-14 is connected with the rack bar bracket 3-13, the other end of the first tension spring 3-14 is connected with the upper end fixing rod 3-21, a driving rack bar 3-15 is fixedly connected with the rack bar bracket 3-13, a rectangular groove 3-22 is arranged on the power chassis 3-1, a second lower rack 3-20 is slidably connected with the rectangular groove 3-22, the second lower rack 3-20 is fixedly connected with a first limiting rod 3-16, and a manual straight tooth 3-18 is rotatably connected at the inner end of the rectangular groove 3-22, the lower end rack I3-19 is connected with the rectangular groove 3-22 in a sliding mode, the lower end rack I3-19 is fixedly connected with the limiting rod II 3-17, the middle end support 2-1 is fixedly connected with the power underframe 3-1, the back plate 1-6 is rotatably connected with the power underframe 3-1, the transmission belt I3-4 is connected with the back plate 1-6 in a matching mode, the driving belt 3-8 is connected with the driving roller 3-9 in a matching mode, and the straight tooth I2-17 is meshed with the driving rack rod 3-15 for transmission.

The fifth concrete implementation mode:

the present embodiment is described below with reference to fig. 1 to 12, and the present embodiment further describes the first embodiment, in which the contact surface between the lower rotating rod one 3-3 and the lower auxiliary rod 3-6 is non-circular.

The sixth specific implementation mode:

the present embodiment is described below with reference to fig. 1 to 12, and the present embodiment further describes the first embodiment, in which the driving roller 3-9 is externally connected with a matching motor a, and the matching motor a is disposed on the power chassis 3-1.

The invention relates to a processing device of a spherical cavity or a quasi-spherical cavity of a hub die, which has the working principle that:

when in use, the driving rollers 3-9 are started to be externally connected with the matched motor A, so as to drive the driving rollers 3-9 to rotate, further drive the driving belts 3-8 to move through the driving rollers 3-9, further drive the driving belt wheels 3-7 to move through the driving belts 3-8, further drive the lower end auxiliary rods 3-6 to rotate through the driving belt wheels 3-7, further drive the lower end rotary rods 3-3 to rotate through the lower end auxiliary rods 3-6, further drive the belt wheels 3-5 to rotate through the lower end rotary rods 3-3, further drive the transmission belt wheels 3-4 to rotate through the belt wheels 3-5, further drive the back plates 1-6 to rotate through the transmission belt wheels 3-4, and further drive the spherical clamping rods 1-7 through the back plates 1-6, the spherical clamping rod 1-7 is connected with the spherical clamping groove 1-9 in a matched mode to drive the outer end sleeve 1-1 to rotate, the outer end sleeve 1-1 drives the rectangular sliding groove 1-4 to move, the rectangular sliding groove 1-4 drives the fixed slider 1-2 to move, the fixed circular wheel 1-3 is driven by the fixed slider 1-2 to move, and the fixed circular wheel 1-3 drives the fixed wheel hub to rotate, so that a spherical cavity of the wheel hub is conveniently machined; meanwhile, the back plate 1-6 and the outer end sleeve 1-1 can be relatively rotated, so that the back plate 1-6 drives the spiral chute 1-5 to move, the fixed slider 1-2 is driven to slide along the rectangular chute 1-4 through the spiral chute 1-5, the relative distance among the fixed sliders 1-2 is changed, and the hubs with different specifications can be conveniently fixed; meanwhile, the first sliding rod support 3-2 is pushed, the fixed hub and the first engraving blade 2-3 and the second engraving blade 2-30 are driven by the first sliding rod support 3-2, the driving roller 3-9 rotates to drive the bidirectional circulation groove 3-10 to move, the matching roller 3-11 is driven by the bidirectional circulation groove 3-10 to move, the matching roller 3-11 slides along the tangential direction through the bidirectional circulation groove 3-10, the roller rotating frame 3-12 is driven by the matching roller 3-11 to move, the rack bar support 3-13 is driven by the roller rotating frame 3-12 to move, the rack bar support 3-13 drives the driving rack bar 3-15 to move, and the straight teeth one 2-17 is driven by the driving rack bar 3-15 to rotate, the bevel teeth nine 2-16 are driven to rotate by the straight teeth I2-17, the bevel teeth seven 2-14 are driven to rotate by the bevel teeth nine 2-16, the connecting sleeve I2-25 is driven to rotate by the bevel teeth seven 2-14, the bevel teeth III 2-9 are driven to rotate by the connecting sleeve I2-25, the bevel teeth I2-7 and the bevel teeth VI 2-12 are respectively driven to rotate by the bevel teeth IV 2-10, the driving rotary disc I2-2 and the driving rotary disc II 2-13 are respectively driven to simultaneously rotate, the cutting edges I2-3 and the cutting edges II 2-30 are simultaneously driven to simultaneously rotate, and a spherical or quasi-spherical cavity is conveniently formed on the fixed hub; meanwhile, when the upper end fixing rod 3-21 is in contact with the first limiting rod 3-16 or the second limiting rod 3-17, the direction of the upper end fixing rod 3-21 is changed, the direction of the roller rotating frame 3-12 is changed under the driving of the upper end fixing rod 3-21, the direction of the matching roller 3-11 is changed along the axial movement direction of the driving roller 3-9, and meanwhile, the first engraving blade 2-3 and the second engraving blade 2-30 rotate reversely through the disclosed transmission relation, so that secondary processing of a spherical or quasi-spherical cavity is realized; meanwhile, the second limiting rod 3-17 is manually rotated, and the first lower-end rack 3-19 and the second lower-end rack 3-20 are driven to simultaneously move towards two sides through the second limiting rod 3-17, so that the distance between the first limiting rod 3-16 and the second limiting rod 3-17 is changed, the range of the reciprocating swing angle between the first engraving edge 2-3 and the second engraving edge 2-30 is changed, and cavities with different radians are conveniently formed; meanwhile, the manual driving rod 2-19 is manually rotated, the bevel gear shaft III 2-27 is driven to rotate by the manual driving rod 2-19, the one-way clutch clamping rod I2-31 is driven to move by the bevel gear shaft III 2-27, the one-way clutch clamping rod II 2-32 is driven to move by the one-way clutch clamping rod I2-31, the bevel gear V2-18 is driven to rotate by the one-way clutch clamping rod II 2-32, the bevel gear V2-15 is driven to rotate by the bevel gear V2-18, the connecting sleeve II 2-26 is driven to rotate by the bevel gear V2-26, the bevel gear III 2-9 is driven to rotate by the connecting sleeve II 2-26, and the bevel gear II 2-8 and the bevel gear V2-11 are driven to simultaneously rotate by the bevel gear III 2-9, the bevel gear shaft I2-6 and the bevel gear shaft II 2-22 are respectively driven to rotate, the connecting rod rotating rod I2-5 and the connecting rod rotating rod II 2-23 are respectively driven to move, the carving edge connecting rod I2-4 and the carving edge connecting rod II 2-24 are respectively driven to move, the carving edge I2-3 and the carving edge II 2-30 are respectively driven to radially slide, and the sphere diameter which can be cut by the carving edge I2-3 and the carving edge II 2-30 is changed; in order to avoid functional interference between the machining when the diameter of the ball which can be cut by the first carving edge 2-3 and the second carving edge 2-30 is changed and the machining of the reciprocating swing of the first carving edge 2-3 and the second carving edge 2-30, and then the unidirectional matching rotation is avoided through the unidirectional clutch clamping rod I2-31 and the unidirectional matching rotation is avoided towards the clutch clamping rod II 2-32, the unidirectional rotation of the unidirectional clutch clamping rod I2-31 and the unidirectional rotation towards the clutch clamping rod II 2-32 is effective, the relative reverse rotation between the unidirectional clutch clamping rod I2-31 and the unidirectional rotation towards the clutch clamping rod II 2-32 is ineffective, the unidirectional rotation of the unidirectional clutch clamping rod I2-31 and the unidirectional rotation towards the clutch clamping rod II 2-32 is effective, the ball diameter which can be cut by the carving edge I2-3 and the carving edge II 2-30 can be changed, and the relative reverse rotation between the unidirectional clutch clamping rod I2-31 and the unidirectional rotation towards the clutch clamping rod II 2-32 is ineffective to avoid functional interference.

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 processing equipment of spherical cavity of wheel hub mould or quasi-spherical cavity, includes fixed subassembly (1), cavity processing subassembly (2), power component (3), its characterized in that: the fixed component (1) is connected with the power component (3) in a matching mode, and the cavity processing component (2) is connected with the power component (3) in a matching mode.

2. The apparatus for processing a spherical cavity or a quasi-spherical cavity of a hub mold according to claim 1, wherein: the fixing component (1) comprises an outer end sleeve (1-1), a fixing slider (1-2), a fixing round wheel (1-3), a rectangular sliding groove (1-4), a spiral sliding groove (1-5), a back plate (1-6), a spherical clamping rod (1-7), a spherical clamping rod push spring (1-8) and a spherical clamping groove (1-9), wherein the rectangular sliding groove (1-4) is arranged on the outer end sleeve (1-1), the fixing slider (1-2) is in sliding connection with the rectangular sliding groove (1-4), the fixing round wheel (1-3) is in rotating connection with the fixing slider (1-2), the fixing slider (1-2) is in sliding connection with the spiral sliding groove (1-5), the spiral sliding groove (1-5) is arranged on the back plate (1-6), the back plate (1-6) is rotatably connected with the outer end sleeve (1-1), the spherical clamping rod (1-7) is slidably connected with the back plate (1-6), the spherical clamping rod push spring (1-8) is arranged between the spherical clamping rod (1-7) and the back plate (1-6), the spherical clamping rod (1-7) is connected with the spherical clamping groove (1-9) in a matched mode, and the spherical clamping groove (1-9) is arranged at the inner end of the outer end sleeve (1-1).

3. The apparatus for processing a spherical cavity or a quasi-spherical cavity of a hub mold according to claim 1, wherein: the cavity processing assembly (2) comprises a middle end support (2-1), a driving rotary table I (2-2), a first cutting edge (2-3), a first cutting edge connecting rod (2-4), a first connecting rod rotary rod (2-5), a cone gear shaft I (2-6), a cone gear I (2-7), a cone gear II (2-8), a cone gear III (2-9), a cone gear IV (2-10), a cone gear V (2-11), a cone gear VI (2-12), a driving rotary table II (2-13), a cone gear VII (2-14), a cone gear VIII (2-15), a cone gear nine (2-16), a straight gear I (2-17), a cone gear VI (2-18), a manual driving rod (2-19), a cone gear shaft sleeve I (2-20), a cone gear shaft sleeve II (2-21), A second bevel gear shaft (2-22), a second connecting rod rotating rod (2-23), a second nicking edge connecting rod (2-24), a first connecting sleeve (2-25), a second connecting sleeve (2-26), a third bevel gear shaft (2-27), a first matching clamping rod (2-28), a first matching clamping rod push spring (2-29), a second nicking edge (2-30), a first one-way clutch clamping rod (2-31), a second one-way clutch clamping rod (2-32), a first one-way clutch clamping rod push spring (2-33) and a hinged frame (2-34), wherein the first nicking edge (2-3) is in sliding connection with the first driving turntable (2-2), one end of the first nicking edge connecting rod (2-4) is hinged with the first nicking edge (2-3), and the other end of the first nicking edge connecting rod (2-4) is hinged with the first connecting rod rotating rod (2-5), a connecting rod rotating rod I (2-5) is fixedly connected with a bevel gear shaft I (2-6), a bevel gear II (2-8) is fixedly connected with the bevel gear shaft I (2-6), one end of a bevel gear shaft sleeve I (2-20) is fixedly connected with a driving turntable I (2-2), the other end of the bevel gear shaft sleeve I (2-20) is fixedly connected with a bevel gear I (2-7), the bevel gear shaft sleeve I (2-20) is rotatably connected with a middle end bracket (2-1), the bevel gear shaft I (2-6) is rotatably connected with the bevel gear shaft sleeve I (2-20), a bevel gear III (2-9) is in meshing transmission with the bevel gear II (2-8), the bevel gear III (2-9) is fixedly connected with a connecting sleeve II (2-26), the connecting sleeve II (2-26) is rotatably connected with a connecting sleeve I (2-25), the connecting sleeve I (2-25) is rotationally connected with the middle end bracket (2-1), the bevel gear IV (2-10) is fixedly connected with the connecting sleeve I (2-25), the bevel gear IV (2-10) is in meshing transmission with the bevel gear I (2-7), the bevel gear V (2-11) is in meshing transmission with the bevel gear III (2-9), the bevel gear VI (2-12) is in meshing transmission with the bevel gear IV (2-10), one end of the bevel gear shaft II (2-22) is fixedly connected with the bevel gear V (2-11), the other end of the bevel gear shaft II (2-22) is fixedly connected with the connecting rod rotating rod II (2-23), one end of the bevel gear shaft sleeve II (2-21) is fixedly connected with the bevel gear VI (2-12), the other end of the bevel gear shaft sleeve II (2-21) is fixedly connected with the driving turntable II (2-13), a second bevel gear shaft sleeve (2-21) is rotationally connected with the middle end bracket (2-1), a second bevel gear shaft (2-22) is rotationally connected with the second bevel gear shaft sleeve (2-21), one end of a second connecting rod rotating rod (2-23) is fixedly connected with the second bevel gear shaft (2-22), the other end of the second connecting rod rotating rod (2-23) is hinged with a second nicking edge connecting rod (2-24), the second nicking edge connecting rod (2-24) is hinged with the second nicking edge (2-30), the second nicking edge (2-30) is slidably connected with a second driving turntable (2-13), a ninth bevel gear (2-16) is rotationally connected with the middle end bracket (2-1), a first straight tooth (2-17) is fixedly connected with a ninth bevel gear (2-16), and the ninth bevel gear (2-16) is meshed with a seventh bevel gear (2-14), a bevel gear seven (2-14) is fixedly connected with a connecting sleeve I (2-25), a bevel gear eight (2-15) is fixedly connected with a connecting sleeve II (2-26), a bevel gear eight (2-15) is in meshing transmission with a bevel gear ten (2-18), a bevel gear shaft III (2-27) is in rotating connection with a middle end bracket (2-1), a bevel gear shaft III (2-27) is fixedly connected with a manual driving rod (2-19), the manual driving rod (2-19) is in matching connection with a matching clamping rod I (2-28), the matching clamping rod I (2-28) is in sliding connection with the middle end bracket (2-1), a matching clamping rod push spring I (2-29) is arranged between the matching clamping rod I (2-28) and the middle end bracket (2-1), a one-way clutch clamping rod II (2-32) is fixedly connected with the bevel gear ten (2-18), the one-way clutch clamping rod I (2-31) is connected with the two-way clutch clamping rod II (2-32) in a matched mode, the one-way clutch clamping rod I (2-31) is connected with the bevel gear shaft III (2-27) in a sliding mode, the one-way clutch clamping rod push spring (2-33) is connected with the one-way clutch clamping rod I (2-31) in a sleeved mode, the one-way clutch clamping rod push spring (2-33) is arranged between the one-way clutch clamping rod I (2-31) and the bevel gear shaft III (2-27), the one-way clutch clamping rod II (2-32) is connected with the hinged frame (2-34) in a rotating mode, and the hinged frame (2-34) is fixedly connected with the middle end support (2-1).

4. The apparatus for processing a spherical cavity or a quasi-spherical cavity of a hub mold according to claim 1, wherein: the power component (3) comprises a power underframe (3-1), a sliding rod support I (3-2), a lower end rotating rod I (3-3), a transmission belt I (3-4), a belt wheel I (3-5), a lower end auxiliary rod (3-6), a driving belt wheel (3-7), a driving belt (3-8), a driving roller (3-9), a bidirectional circulating groove (3-10), a matching roller (3-11), a roller rotating frame (3-12), a rack rod support (3-13), a tension spring I (3-14), a driving rack rod (3-15), a limiting rod I (3-16), a limiting rod II (3-17), manual straight teeth (3-18), a lower end rack I (3-19), a lower end rack II (3-20), An upper end fixing rod (3-21) and a rectangular groove (3-22), wherein a first sliding rod support (3-2) is connected with a power chassis (3-1) in a sliding manner, a first lower rotating rod (3-3) is connected with the first sliding rod support (3-2) in a rotating manner, a first belt wheel (3-5) is fixedly connected with a first lower rotating rod (3-3), a first transmission belt (3-4) is connected with the first belt wheel (3-5) in a matching manner, a lower auxiliary rod (3-6) is connected with the power chassis (3-1) in a rotating manner, a driving belt wheel (3-7) is fixedly connected with a lower auxiliary rod (3-6), one end of the driving belt (3-8) is connected with the driving belt wheel (3-7) in a matching manner, and the first lower rotating rod (3-3) is connected with the lower auxiliary rod (3-6) in a sliding manner, the driving roller (3-9) is rotationally connected with the power chassis (3-1), the bidirectional circulating groove (3-10) is arranged on the driving roller (3-9), the matching roller (3-11) is in matching connection with the bidirectional circulating groove (3-10), the matching roller (3-11) is rotationally connected with the roller rotating frame (3-12), the upper end fixing rod (3-21) is fixedly connected with the roller rotating frame (3-12), the roller rotating frame (3-12) is rotationally connected with the rack bar bracket (3-13), one end of the first tension spring (3-14) is connected with the rack bar bracket (3-13), the other end of the first tension spring (3-14) is connected with the upper end fixing rod (3-21), and the driving rack bar (3-15) is fixedly connected with the rack bar bracket (3-13), the rectangular groove (3-22) is arranged on the power chassis (3-1), the lower end rack II (3-20) is connected with the rectangular groove (3-22) in a sliding manner, the lower end rack II (3-20) is fixedly connected with the limiting rod I (3-16), the manual straight tooth (3-18) is rotatably connected with the inner end of the rectangular groove (3-22), the lower end rack I (3-19) is connected with the rectangular groove (3-22) in a sliding manner, the lower end rack I (3-19) is fixedly connected with the limiting rod II (3-17), the middle end bracket (2-1) is fixedly connected with the power chassis (3-1), the back plate (1-6) is rotatably connected with the power chassis (3-1), the transmission belt I (3-4) is connected with the back plate (1-6) in a matching manner, the driving belt (3-8) is connected with the driving roller (3-9) in a matching manner, the straight teeth I (2-17) are meshed with the driving rack rods (3-15) for transmission.

5. The apparatus for processing a spherical cavity or a quasi-spherical cavity of a hub mold according to claim 4, wherein: the contact surface of the lower end rotating rod I (3-3) and the lower end auxiliary rod (3-6) is non-circular.

6. The apparatus for processing a spherical cavity or a quasi-spherical cavity of a hub mold according to claim 4, wherein: the driving rollers (3-9) are externally connected with a matched motor A, and the matched motor A is arranged on the power chassis (3-1).