CN112571474A - Building board processingequipment - Google Patents

Abstract

The invention relates to the field of buildings, in particular to a building board processing device. The building board can be transported and cut in one direction. Including carrying subassembly, one-way subassembly, the cutting subassembly, the chassis subassembly, power component, awl tooth two drives the axial slip of awl tooth slide bar along the awl tooth sheathed tube, make the transmission between awl tooth one and the awl tooth two inefficacy, and then make the one-way transportation to building board stop, when anticlockwise rotation rotates the cam, make the motion of the aforesaid disclosure reverse, and then make the cutting device who fixes on the cutting rectangle frame move up, and then realize lifting the sword process, make the cooperation cam along the orbit reverse motion of rotating the cam tip simultaneously, and along rotating the circular shape orbit motion of cam, and then make and continue the transmission between awl tooth one and the awl tooth two, and then make the one-way transportation to building board start.

Description

Building board processingequipment

Technical Field

The invention relates to the field of buildings, in particular to a building board processing device.

Background

The building board processing device is a common device in the field of buildings, but the function of the common building board processing device is single.

Disclosure of Invention

The invention aims to provide a building board processing device which can carry and cut building boards in a single direction.

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

the utility model provides a building board processingequipment, includes delivery subassembly, one-way subassembly, cutting subassembly, chassis subassembly, power component, the delivery subassembly is connected with one-way subassembly, and delivery subassembly, cutting subassembly, chassis subassembly all are connected with power component, and power component is connected with delivery subassembly, cutting subassembly.

As a further optimization of the technical scheme, the invention relates to a building board processing device, wherein a carrying assembly comprises a carrying bottom plate, a middle-end carriage, an extrusion carriage, a first spherical clamping groove, an extrusion carriage, an extrusion roller, a second spherical clamping groove, a first driving rod, a first spherical clamping rod, a first slider, a first inner-end slider push spring, a second spherical clamping rod, a first driving slider, a second slider, a third spherical clamping rod push spring, a third spherical clamping groove, a hinged connecting rod and a lower end turntable, wherein the middle-end carriage is fixedly connected with the carrying bottom plate, the extrusion carriage is slidably connected with the carrying bottom plate, the first spherical clamping groove is arranged on the extrusion carriage, the extrusion roller is arranged on the extrusion carriage, the second spherical clamping groove is arranged on the carrying bottom plate, the first driving rod is rotatably connected with the carrying bottom plate, the first driving rod is fixedly connected with the first driving disk, the first spherical clamping rod is connected with the extrusion sliding frame in a sliding mode, the first spherical clamping rod is connected with the second spherical clamping groove in a matching mode, the first spherical clamping rod push spring is arranged between the first spherical clamping rod and the extrusion sliding frame, the extrusion roller is connected with the first slider in a rotating mode, the first slider is connected with the first slider at the inner end in a sliding mode, the first slider at the inner end is fixedly connected with the extrusion sliding frame, the first slider at the inner end is connected with the first slider at the inner end in a sleeved mode, the second spherical clamping rod is connected with the extrusion sliding frame in a sliding mode, the second spherical clamping rod push spring is arranged between the two adjacent second spherical clamping rods, the second spherical clamping rod is connected with the first spherical clamping groove in a matching mode, the first driving slider is connected with the second driving disk in a sliding mode, the third spherical clamping groove is arranged on the first driving disk, the third spherical clamping rod is connected with, the spherical clamping rod III is connected with the spherical clamping groove III in a matched mode, one end of the hinged connecting rod is hinged to the extrusion sliding frame, the other end of the hinged connecting rod is hinged to the lower end rotary table, and the lower end rotary table is rotatably connected with the carrying bottom plate.

As a further optimization of the technical scheme, the invention relates to a building board processing device, wherein the one-way assembly comprises a middle end frame, an upper end frame, a fixed terminal, an inner end slider, an upper end sliding column, an upper end push spring, a one-way carrying plate I, a hinged sliding rod II, a hinged sliding rod push spring, a one-way carrying plate II and an inner end push spring I, the upper end frame is fixedly connected with the middle end frame, the upper end sliding column is fixedly connected with the upper end frame, the inner end slider is slidably connected with the upper end sliding column, the upper end push spring is connected with the upper end sliding column in a sleeved mode, the fixed terminal is fixedly connected with the middle end frame, the one-way carrying plate I is rotatably connected with the inner end slider, the one-way carrying plate II is slidably connected with the one-way carrying plate I, the inner end push spring I is arranged between the one-way carrying plate II and the one-way carrying plate I, the hinged sliding rod, the second hinged sliding rod is rotatably connected with the middle end frame, the push spring of the hinged sliding rod is arranged between the first hinged sliding rod and the second hinged sliding rod, the fixed terminal is slidably connected with the middle end sliding frame, and the fixed terminal is fixedly connected with the first driving sliding rod.

As a further optimization of the technical solution, the invention provides a building board processing device, comprising: the cutting assembly comprises a cutting outer frame, belt wheels, a belt, a cutting rectangular frame, a rotating cam, a matching cam, an eccentric cam I, a cam driving rod, a matching runner, an eccentric cam II, a cam rotating rod I, a cam rotating rod II, an auxiliary sliding rod, a matching clamping device and a matching clamping push spring, wherein the belt wheels are rotatably connected with the cutting outer frame, the belt is cooperatively connected between the two belt wheels, the auxiliary sliding rod is fixedly connected with the cutting outer frame, the cutting rectangular frame is slidably connected with the auxiliary sliding rod, the rotating cam is fixedly connected with the cam rotating rod I, the cam rotating rod I is fixedly connected with the eccentric cam I, the matching cam is cooperatively connected with the rotating cam, the cam driving rod is rotatably connected with the eccentric cam I and the eccentric cam II, the matching runner is cooperatively connected with the cam driving rod, the matching runner is rotatably connected with the matching clamping device, and the matching clamping, the matching clamping device is connected with the cutting rectangular frame in a sliding way, the matching clamping push spring is arranged between the matching clamping device and the cutting rectangular frame, the cam rotating rod II is rotationally connected with the cutting outer frame, the eccentric cam II is fixedly connected with the cam rotating rod II, the belt is arranged at the inner end of the cutting rectangular frame,

as a further optimization of the technical scheme, the building board processing device provided by the invention is characterized in that the cam rotating rod I is fixedly connected to the eccentric position of the eccentric cam I, the cam rotating rod II is fixedly connected to the eccentric position of the eccentric cam II, and the upper end of the cutting rectangular frame is fixedly provided with the cutting edge.

As a further optimization of the technical scheme, the building board processing device comprises an underframe assembly, a containing box, a bearing plate and a bearing push spring, wherein the containing box is fixedly connected with the underframe body, the bearing plate is slidably connected with the containing box, the bearing push spring is arranged between the bearing plate and the containing box, a carrying bottom plate is fixedly connected with the underframe body, and a cutting outer frame is fixedly connected with the underframe body.

As a further optimization of the technical scheme, the invention relates to a building board processing device, wherein the power assembly comprises a power underframe, an input motor, a first bevel gear, a second bevel gear, a bevel gear slide rod push spring, a bevel gear sleeve, a third bevel gear, a fourth bevel gear, a bevel gear shaft, a transmission belt, a clutch slide rod push spring, a first clutch slide rod, a second clutch slide rod, a clutch output rod, a driving bracket and a driving rotating rod, wherein an output shaft of the input motor is fixedly connected with the first bevel gear, the input motor is fixedly connected with the power underframe, the second bevel gear is in meshing transmission with the first bevel gear, the second bevel gear is fixedly connected with the bevel gear slide rod, the bevel gear slide rod push spring is in sleeve connection with the bevel gear slide rod, the bevel gear sleeve is in sliding connection with the bevel gear slide rod, the bevel gear slide rod push spring is arranged between the bevel gear sleeve and the bevel gear slide rod, the third bevel gear is fixedly connected with the bevel gear, the bevel gear four is in meshing transmission with the bevel gear three, the bevel gear four is fixedly connected with a bevel gear shaft, the bevel gear shaft is rotatably connected with a power chassis, a transmission belt is in fit connection with the bevel gear shaft, a clutch slide bar is fixedly connected with an output shaft of an input motor, the clutch slide bar is rotatably connected with the power chassis, a clutch slide bar push spring is in sleeve connection with the clutch slide bar, the clutch slide bar push spring is arranged between the clutch slide bar I and the clutch slide bar, the clutch slide bar II is in fit connection with the clutch slide bar I, the clutch slide bar II is fixedly connected with a clutch output bar, the clutch output bar is rotatably connected with the power chassis, a driving support is in rotate fit connection with the bevel gear II, the driving rotating bar is fixedly connected with the driving support, the driving rotating bar is rotatably connected with a fit cam, the power chassis is fixedly connected with a chassis body.

The building board processing device has the beneficial effects that:

according to the building board processing device, the bevel gear II drives the bevel gear sliding rod to slide along the axial direction of the bevel gear sleeve, so that transmission between the bevel gear I and the bevel gear II fails, and further, unidirectional transportation of a building board is stopped.

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 first schematic view of the carrying assembly of the present invention;

FIG. 4 is a second schematic view of the carrier assembly of the present invention;

FIG. 5 is a third schematic view of the carrier assembly of the present invention;

FIG. 6 is a fourth schematic view of the carrier assembly of the present invention;

FIG. 7 is a fifth schematic view of the carrier assembly of the present invention;

FIG. 8 is a first schematic view of a unidirectional assembly of the present invention;

FIG. 9 is a second schematic view of the unidirectional assembly of the present invention;

FIG. 10 is a first schematic view of the cutting assembly of the present invention;

FIG. 11 is a second schematic view of the cutting assembly of the present invention;

FIG. 12 is a third schematic view of the cutting assembly of the present invention;

FIG. 13 is a first structural view of the undercarriage assembly of the present invention;

FIG. 14 is a second structural view of the undercarriage assembly of the present invention;

FIG. 15 is a schematic view of the power assembly configuration of the present invention.

In the figure: a carrier assembly 1; a carrying floor 1-1; a middle end carriage 1-2; 1-3 of an extrusion sliding frame; 1-4 parts of a spherical clamping groove I; 1-5 of an extrusion sliding frame; 1-6 parts of an extrusion roller; 1-7 parts of a spherical clamping groove II; 1-8 of a driving rod I; driving discs I1-9; 1-10 parts of a spherical clamping rod I; a first spherical clamping rod push spring 1-11; 1-12 parts of a slider I; the inner end of the sliding rod I is 1-13; the inner end of the sliding rod is provided with a push spring I1-14; 1-15 parts of a second spherical clamping rod; a second spherical clamping rod push spring 1-16; driving the first sliding rod 1-17; 1-18 parts of a slider II; 1-19 parts of a spherical clamping rod III; 1-20 parts of a spherical clamping rod push spring; 1-21 parts of spherical clamping groove III; articulation links 1-22; a lower end rotary table 1-23; a unidirectional component 2; a middle end frame 2-1; an upper end frame 2-2; a fixed terminal 2-3; 2-4 of inner end slider; 2-5 of upper end sliding column; the upper end pushes springs 2-6; a one-way carrying plate I2-7; hinging the first sliding rod 2-8; 2-9 of a hinged sliding rod II; hinged sliding rod push spring 2-10; 2-11 of a one-way carrying plate II; the inner end of the push spring I is 2-12; a cutting assembly 3; cutting the outer frame 3-1; a pulley 3-2; 3-3 of a belt; cutting the rectangular frame 3-4; rotating the cam 3-5; matching with the cams 3-6; 3-7 parts of an eccentric cam I; 3-8 parts of a cam driving rod; matching with 3-9 rotating wheels; 3-10 parts of a second eccentric cam; 3-11 cam rotating rods; 3-12 parts of a cam rotating rod II; auxiliary slide bars 3-14; matching with a clamping device 3-15; 3-16 of a matched clamping push spring; a chassis assembly 4; a chassis body 4-1; a storage box 4-2; 4-3 of a bearing plate; a bearing push spring 4-4; a power assembly 5; a power chassis 5-1; inputting a motor 5-2; 5-3 of a first bevel gear; 5-4 parts of a second bevel gear; 5-5 of a bevel gear sliding rod; 5-6 parts of bevel gear slide bar push spring; 5-7 parts of a bevel gear sleeve; 5-8 parts of bevel gear III; 5-9 parts of bevel gear; 5-10 parts of a bevel gear shaft; 5-11 parts of a transmission belt; 5-12 parts of a clutch slide bar; 5-13 parts of clutch slide rod push spring; 5-14 parts of a clutch sliding rod I; 5-15 parts of a clutch slide bar II; 5-16 of clutch output rod; 5-17 of a driving bracket; the rotating rods 5-18 are driven.

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 embodiment is described below with reference to fig. 1 to 15, and a building board processing device includes a carrying assembly 1, a one-way assembly 2, a cutting assembly 3, a chassis assembly 4, and a power assembly 5, where the carrying assembly 1 is connected to the one-way assembly 2, the carrying assembly 1, the cutting assembly 3, and the chassis assembly 4 are all connected to the power assembly 5, and the power assembly 5 is connected to the carrying assembly 1 and the cutting assembly 3.

The second embodiment is as follows:

the first embodiment is further described with reference to fig. 1-15, and the carrying assembly 1 includes a carrying bottom plate 1-1, a middle end carriage 1-2, an extrusion carriage 1-3, a first spherical slot 1-4, an extrusion carriage 1-5, an extrusion roller 1-6, a second spherical slot 1-7, a first driving rod 1-8, a first driving disk 1-9, a first spherical clamping rod 1-10, a first spherical clamping rod push spring 1-11, a first slider 1-12, a first inner end sliding rod 1-13, a first inner end sliding rod push spring 1-14, a second spherical clamping rod 1-15, a second spherical clamping rod push spring 1-16, a first driving sliding rod 1-17, a second slider 1-18, a third spherical clamping rod 1-19, a third spherical clamping rod push spring 1-20, A third spherical clamping groove 1-21, a hinged connecting rod 1-22, a lower end rotary table 1-23, a middle end carriage 1-2 fixedly connected with a carrying bottom plate 1-1, an extrusion carriage 1-3 slidably connected with the carrying bottom plate 1-1, a first spherical clamping groove 1-4 arranged on the extrusion carriage 1-3, an extrusion carriage 1-5 slidably connected with the extrusion carriage 1-3, an extrusion roller 1-6 arranged on the extrusion carriage 1-5, a second spherical clamping groove 1-7 arranged on the carrying bottom plate 1-1, a first driving rod 1-8 rotatably connected with the carrying bottom plate 1-1, a first driving rod 1-8 fixedly connected with a first driving disc 1-9, a first spherical clamping rod 1-10 slidably connected with the extrusion carriage 1-3, a first spherical clamping rod 1-10 cooperatively connected with the second spherical clamping groove 1-7, the first spherical clamping rod push spring 1-11 is arranged between the first spherical clamping rod 1-10 and the extrusion sliding frame 1-3, the extrusion roller 1-6 is rotatably connected with the first slider 1-12, the first slider 1-12 is slidably connected with the first inner end slider 1-13, the first inner end slider 1-13 is fixedly connected with the extrusion sliding frame 1-5, the first inner end slider push spring 1-14 is connected with the first inner end slider 1-13 in a sleeved mode, the second spherical clamping rod 1-15 is slidably connected with the extrusion sliding frame 1-5, the second spherical clamping rod push spring 1-16 is arranged between the two adjacent second spherical clamping rods 1-15, the second spherical clamping rod 1-15 is connected with the first spherical clamping groove 1-4 in a matched mode, the first driving slider 1-17 is connected with the second slider 1-18 in a matched mode, and the second slider 1-18 is slidably connected with the first driving disk 1-9, the spherical clamping grooves III 1-21 are arranged on the driving disc I1-9, the spherical clamping rods III 1-19 are connected with the sliders II 1-18 in a sliding mode, the spherical clamping rod pushing springs III 1-20 are arranged between the two spherical clamping rods III 1-19, the spherical clamping rods III 1-19 are connected with the spherical clamping grooves III 1-21 in a matching mode, one ends of the hinged connecting rods 1-22 are hinged to the extrusion sliding frames 1-3, the other ends of the hinged connecting rods 1-22 are hinged to the lower end rotating discs 1-23, and the lower end rotating discs 1-23 are rotatably connected with the carrying bottom plate 1-1.

The third concrete implementation mode:

the following describes the present embodiment with reference to fig. 1-15, and the present embodiment further describes the first embodiment, where the unidirectional assembly 2 includes a middle end frame 2-1, an upper end frame 2-2, a fixed terminal 2-3, an inner end slider 2-4, an upper end sliding column 2-5, an upper end push spring 2-6, a unidirectional carrying plate one 2-7, a hinged sliding rod one 2-8, a hinged sliding rod two 2-9, a hinged sliding rod push spring 2-10, a unidirectional carrying plate two 2-11, and an inner end push spring one 2-12, the upper end frame 2-2 is fixedly connected with the middle end frame 2-1, the upper end sliding column 2-5 is fixedly connected with the upper end frame 2-2, the inner end slider 2-4 is slidably connected with the upper end sliding column 2-5, the upper end push spring 2-6 is connected with the upper end sliding column 2-5 in a sleeved manner, the fixed terminal 2-3 is fixedly connected with the middle end frame 2-1, the one-way carrying plate I2-7 is rotatably connected with the inner end slider 2-4, the one-way carrying plate II 2-11 is slidably connected with the one-way carrying plate I2-7, the inner end push spring I2-12 is arranged between the one-way carrying plate II 2-11 and the one-way carrying plate I2-7, the hinged slide bar I2-8 is rotatably connected with the one-way carrying plate I2-7, the connecting slide bar I2-8 is slidably connected with the hinged slide bar II 2-9, the hinged slide bar II 2-9 is rotatably connected with the middle end frame 2-1, the hinged slide bar push spring 2-10 is arranged between the connecting slide bar I2-8 and the hinged slide bar II 2-9, the fixed terminal 2-3 is slidably connected with the middle end carriage 1-2, and the fixed terminal 2-3 is fixedly connected with the driving slide bar I1-17.

The fourth concrete implementation mode:

the first embodiment is further described with reference to fig. 1-15, the cutting assembly 3 includes a cutting outer frame 3-1, a belt wheel 3-2, a belt 3-3, a cutting rectangular frame 3-4, a rotating cam 3-5, a matching cam 3-6, an eccentric cam I3-7, a cam driving rod 3-8, a matching rotating wheel 3-9, an eccentric cam II 3-10, a cam rotating rod I3-11, a cam rotating rod II 3-12, an auxiliary sliding rod 3-14, a matching clamping device 3-15, a matching clamping push spring 3-16, a belt wheel 3-2 is rotatably connected with the cutting outer frame 3-1, a belt 3-3 is connected between the two belt wheels 3-2 in a matching manner, and an auxiliary sliding rod 3-14 is fixedly connected with the cutting outer frame 3-1, a cutting rectangular frame 3-4 is connected with an auxiliary sliding rod 3-14 in a sliding manner, a rotating cam 3-5 is fixedly connected with a cam rotating rod I3-11, a cam rotating rod I3-11 is fixedly connected with an eccentric cam I3-7, a matching cam 3-6 is connected with a rotating cam 3-5 in a matching manner, a cam driving rod 3-8 is rotatably connected with an eccentric cam I3-7 and an eccentric cam II 3-10, a matching rotating wheel 3-9 is connected with a cam driving rod 3-8 in a matching manner, a matching rotating wheel 3-9 is rotatably connected with a matching clamping device 3-15, a matching clamping push spring 3-16 is connected with a matching clamping device 3-15 in a sleeving manner, a matching clamping device 3-15 is connected with the cutting rectangular frame 3-4 in a sliding manner, a matching clamping push spring 3-16 is arranged between the matching clamping device 3-15 and the cutting rectangular frame 3-4, a second cam rotating rod 3-12 is rotationally connected with the cutting outer frame 3-1, a second eccentric cam 3-10 is fixedly connected with the second cam rotating rod 3-12, a belt 3-3 is arranged at the inner end of the cutting rectangular frame 3-4,

the fifth concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 15, and the present embodiment further describes the first embodiment, the cam rotating rod one 3 to 11 is fixedly connected to the eccentric position of the eccentric cam one 3 to 7, the cam rotating rod two 3 to 12 is fixedly connected to the eccentric position of the eccentric cam two 3 to 10, and the upper end of the cutting rectangular frame 3 to 4 is fixed with a cutting edge.

The sixth specific implementation mode:

the present embodiment is described below with reference to fig. 1-15, and the present embodiment further describes the first embodiment, where the chassis assembly 4 includes a chassis body 4-1, a receiving box 4-2, a bearing plate 4-3, and a bearing push spring 4-4, the receiving box 4-2 is fixedly connected to the chassis body 4-1, the bearing plate 4-3 is slidably connected to the receiving box 4-2, the bearing push spring 4-4 is disposed between the bearing plate 4-3 and the receiving box 4-2, the bearing bottom plate 1-1 is fixedly connected to the chassis body 4-1, and the cutting outer frame 3-1 is fixedly connected to the chassis body 4-1.

The seventh embodiment:

the embodiment is described below with reference to fig. 1 to 15, and the embodiment will be further described, wherein the power assembly 5 includes a power chassis 5-1, an input motor 5-2, a first bevel gear 5-3, a second bevel gear 5-4, a sliding rod 5-5, a sliding rod push spring 5-6, a sleeve 5-7, a third bevel gear 5-8, a fourth bevel gear 5-9, a shaft 5-10, a driving belt 5-11, a sliding rod 5-12, a sliding rod push spring 5-13, a sliding rod 5-14, a second sliding rod 5-15, an output rod 5-16, a driving bracket 5-17, and a rotating rod 5-18, an output shaft of the input motor 5-2 is fixedly connected with the first bevel gear 5-3, the input motor 5-2 is fixedly connected with the power chassis 5-1, a second bevel gear 5-4 is in meshed transmission with a first bevel gear 5-3, a second bevel gear 5-4 is fixedly connected with a sliding rod 5-5, a pushing spring 5-6 of the sliding rod 5-5 is in sleeved connection with the sliding rod 5-5, a sleeve 5-7 of the bevel gear is in sliding connection with the sliding rod 5-5, a pushing spring 5-6 of the sliding rod 5-6 of the bevel gear is arranged between the sleeve 5-7 of the bevel gear and the sliding rod 5-5 of the bevel gear, a third bevel gear 5-8 is fixedly connected with the sleeve 5-7 of the bevel gear, the sleeve 5-7 of the bevel gear is in rotating connection with a power chassis 5-1, a fourth bevel gear 5-9 is in meshed transmission with the third bevel gear 5-8, a fourth bevel gear 5-9 is fixedly connected with a shaft 5-10 of the bevel gear, the shaft 5-10 of the bevel gear is in rotating connection with the power chassis 5-1, a transmission belt 5-11, a clutch slide bar 5-12 is fixedly connected with an output shaft of an input motor 5-2, the clutch slide bar 5-12 is rotationally connected with a power chassis 5-1, a clutch slide bar push spring 5-13 is connected with the clutch slide bar 5-12 in a sleeved mode, a clutch slide bar I5-14 is connected with the clutch slide bar 5-12 in a sleeved mode, the clutch slide bar push spring 5-13 is arranged between the clutch slide bar I5-14 and the clutch slide bar I5-12, a clutch slide bar II 5-15 is connected with the clutch slide bar I5-14 in a matched mode, a clutch slide bar II 5-15 is fixedly connected with a clutch output bar 5-16, the clutch output bar 5-16 is rotationally connected with the power chassis 5-1, a driving bracket 5-17 is connected with a cone tooth II 5-4 in a rotationally matched mode, and a driving rotating bar 5-18 is fixedly connected with, the driving rotating rod 5-18 is rotationally connected with the matching cam 3-6, the power underframe 5-1 is fixedly connected with the underframe body 4-1, the belt wheel 3-2 is fixedly connected with the clutch output rod 5-16, and the transmission belt 5-11 is connected with the driving rod I1-8 in a matching way;

and then the matching cam 3-6 drives the driving rotating rod 5-18 to drive the driving bracket 5-17 to move, and further drives the bevel gear II 5-4 to move through the driving bracket 5-17, so that the bevel gear II 5-4 drives the bevel gear sliding rod 5-5 to slide along the axial direction of the bevel gear sleeve 5-7, the transmission between the bevel gear I5-3 and the bevel gear II 5-4 is disabled, and further the one-way transportation to the building board is stopped, when the rotating cam 3-5 rotates anticlockwise, the disclosed movement is reversed, and further the cutting device fixed on the cutting rectangular frame 3-4 moves upwards, so that the cutter lifting process is realized, and simultaneously the matching cam 3-6 moves reversely along the track of the pointed end of the rotating cam 3-5 and moves along the circular track of the rotating cam 3-5, and further, the first bevel gear 5-3 and the second bevel gear 5-4 are continuously driven, and the one-way transportation of the building board is started.

The invention relates to a building board processing device, which has the working principle that:

when the power output device is used, the input motor 5-2 is started, the first bevel gear 5-3 is driven to rotate by the input motor 5-2, the first clutch slide bar 5-12 is driven to rotate by the first bevel gear 5-3, the first clutch slide bar 5-14 is driven to rotate by the first clutch slide bar 5-12, the second clutch slide bar 5-15 is driven to rotate by the first clutch slide bar 5-14, and the second clutch slide bar 5-15 is driven to rotate the second clutch output bar 5-16, so that power output of related functions is facilitated; meanwhile, the rotation of the first bevel gear 5-3 drives the rotation of the second bevel gear 5-4, further drives the movement of the second bevel gear 5-4 through the second bevel gear 5-5, further drives the movement of the bevel gear sleeve 5-7 through the bevel gear slide rod 5-5, further drives the movement of the third bevel gear 5-8 through the bevel gear sleeve 5-7, further drives the movement of the fourth bevel gear 5-9 through the third bevel gear 5-8, further drives the movement of the bevel gear shaft 5-10 through the fourth bevel gear 5-9, further drives the movement of the transmission belt 5-11 through the bevel gear shaft 5-10, and further facilitates the power output of related functions; meanwhile, the driving support 5-17 is driven to move through the driving rotating rod 5-18, and further the driving support 5-17 drives the bevel gear II 5-4 to move, so that the bevel gear II 5-4 drives the bevel gear sliding rod 5-5 to slide along the axial direction of the bevel gear sleeve 5-7, the transmission between the bevel gear I5-3 and the bevel gear II 5-4 is disabled, and further the power output of the function related to the transmission belt 5-11 is separated; the building board to be processed is placed on the carrying bottom plate 1-1, the building board is extruded through the extrusion rollers 1-6, the building board is prevented from being separated from the carrying bottom plate 1-1 in the processing process, meanwhile, the extrusion position can be adjusted according to the actual situation through relative sliding of the extrusion sliding frame 1-3 and the carrying bottom plate 1-1, meanwhile, the specification of the building board capable of being extruded can be adjusted through the relative position between the extrusion sliding frame 1-5 and the extrusion sliding frame 1-3, and the extrusion rollers 1-6 only slightly extrude the building board; the driving belts 5-11 move to drive the driving rods 1-8 to rotate, the driving rods 1-8 drive the driving disks 1-9 to rotate, the driving disks 1-9 drive the sliders 1-18 to move, the sliders 1-18 drive the driving rods 1-17 to move, the driving rods 1-17 drive the fixing terminals 2-3 to move along the middle end sliding frames 1-2, the middle end sliding frames 1-2 drive the middle end frames 2-1 to move, the building boards are placed between the middle end frames 2-1 and the one-way carrying plates 2-11, the middle end frames 2-1 drive the inner end sliders 2-4 to move, and the inner end sliders 2-4 drive the one-way carrying plates 2-7 to move, the unidirectional carrying plate 2-11 is driven to move by the unidirectional carrying plate 2-7, and the unidirectional carrying plate 2-11 is contacted with the building board, so that unidirectional transportation of the building board is realized; the two sliders 1-18 are arranged at eccentric positions of the first driving disc 1-9, the two sliders 1-18 form a circular track along with the movement of the first driving disc 1-9, the position change of the two sliders 1-18 in the vertical direction is released through the relative sliding between the two sliders 1-18 and the first driving sliding rods 1-17, the two sliders 1-18 drive and drive the first driving sliding rods 1-17 to transversely reciprocate, the first driving sliding rods 1-17 drive the fixed terminals 2-3 to drive the middle end frame 2-1 and the two unidirectional carrying plates 2-11 to simultaneously transversely reciprocate, the two unidirectional carrying plates 2-11 are unidirectionally tightened, the two unidirectional carrying plates 2-11 are reversely loosened, and the unidirectional transportation of the building plates is realized; meanwhile, the sliders II 1-18 and the driving discs I1-9 can slide relatively, so that the radii of circular tracks formed by the sliders II 1-18 along with the movement of the driving discs I1-9 are changed, the amplitudes of the transverse reciprocating movements of the sliders I1-17 are further driven and driven by the sliders II 1-18 to change, the amplitudes of the transverse reciprocating movements of the middle end frames 2-1 and the unidirectional carrying plates II 2-11 are further driven by the driving sliders I1-17 to drive the fixed terminals 2-3 to drive the middle end frames 2-1 and the unidirectional carrying plates II 2-11 to change simultaneously, the amplitude of the unidirectional transportation of the building plates is further changed, and the unidirectional transportation frequency of the building plates is changed conveniently; the clutch output rod 5-16 rotates through the belt wheel 3-2, the belt wheel 3-2 drives the belt 3-3 to rotate, the rotating cam 3-5 is manually rotated clockwise, the rotating cam 3-5 drives the cam rotating rod one 3-11 to rotate through the rotating cam 3-5, the cam rotating rod one 3-11 drives the eccentric cam one 3-7 to move, the rotating cam 3-5 is in a pointed shape at one end, the rotating cam 3-5 is in a circular shape at the other end, the eccentric cam one 3-7 drives the cam driving rod 3-8 to move, due to the eccentric position of the eccentric cam one 3-7, the cam driving rod 3-8 presses the right side matching rotating wheel 3-9 to the right side while moving, so that the right side matching rotating wheel 3-9 moves to the right side, and the corresponding matching clamping pushing spring 3-16 is compressed, and then the left matching rotating wheel 3-9 moves further along with the movement of the cam driving rod 3-8, and further under the pushing of the left matching clamping pushing spring 3-16, the belt 3-3 is extruded between the matching clamping device 3-15 and the cutting rectangular frame 3-4, and further the cutting device fixed on the cutting rectangular frame 3-4 moves downwards, and further the cutting device contacts with the building board, and further the building board is cut, meanwhile, when the rotating cam 3-5 is rotated clockwise, the matching cam 3-6 is driven by the rotating cam 3-5, and the matching cam 3-6 moves along the track of the pointed end of the rotating cam 3-5, and further the matching cam 3-6 drives the driving rotating rod 5-18 to drive the driving support 5-17 to move, and then the driving bracket 5-17 drives the bevel gear II 5-4 to move, so that the bevel gear II 5-4 drives the bevel gear slide rod 5-5 to slide along the axial direction of the bevel gear sleeve 5-7, the transmission between the bevel gear I5-3 and the bevel gear II 5-4 is disabled, the one-way transportation of the building board is stopped, when the rotating cam 3-5 is rotated anticlockwise, the disclosed movement is reversed, the cutting device fixed on the cutting rectangular frame 3-4 moves upwards, the tool lifting process is further realized, meanwhile, the matching cam 3-6 moves reversely along the track of the tip of the rotating cam 3-5 and moves along the circular track of the rotating cam 3-5, and the transmission between the bevel gear I5-3 and the bevel gear II 5-4 is further continued, so as to start the one-way transportation of the building board; the cut building boards fall into the storage box 4-2 and are collected.

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 (7)

1. The utility model provides a building board processingequipment, includes delivery subassembly (1), one-way subassembly (2), cutting subassembly (3), chassis subassembly (4), power component (5), its characterized in that: the carrying assembly (1) is connected with the one-way assembly (2), the carrying assembly (1), the cutting assembly (3) and the chassis assembly (4) are all connected with the power assembly (5), and the power assembly (5) is connected with the carrying assembly (1) and the cutting assembly (3).

2. A building board processing apparatus as claimed in claim 1, wherein: the carrying assembly (1) comprises a carrying bottom plate (1-1), a middle-end sliding frame (1-2), an extrusion sliding frame (1-3), a spherical clamping groove I (1-4), an extrusion sliding frame (1-5), an extrusion roller (1-6), a spherical clamping groove II (1-7), a driving rod I (1-8), a driving disk I (1-9), a spherical clamping rod I (1-10), a spherical clamping rod push spring I (1-11), a slider I (1-12), an inner-end sliding rod I (1-13), an inner-end sliding rod push spring I (1-14), a spherical clamping rod II (1-15), a spherical clamping rod push spring II (1-16), a driving sliding rod I (1-17), a slider II (1-18), a spherical clamping rod III (1-19), a spherical clamping rod push spring III (1-20), A spherical clamping groove III (1-21), a hinged connecting rod (1-22) and a lower end rotary table (1-23), a middle end sliding frame (1-2) is fixedly connected with a carrying bottom plate (1-1), an extrusion sliding frame (1-3) is connected with the carrying bottom plate (1-1) in a sliding way, a spherical clamping groove I (1-4) is arranged on the extrusion sliding frame (1-3), an extrusion sliding frame (1-5) is connected with the extrusion sliding frame (1-3) in a sliding way, an extrusion roller (1-6) is arranged on the extrusion sliding frame (1-5), a spherical clamping groove II (1-7) is arranged on the carrying bottom plate (1-1), a driving rod I (1-8) is rotationally connected with the carrying bottom plate (1-1), a driving rod I (1-8) is fixedly connected with a driving disc I (1-9), the first spherical clamping rod (1-10) is connected with the extrusion sliding frame (1-3) in a sliding manner, the first spherical clamping rod (1-10) is connected with the second spherical clamping groove (1-7) in a matching manner, the first spherical clamping rod push spring (1-11) is arranged between the first spherical clamping rod (1-10) and the extrusion sliding frame (1-3), the extrusion roller (1-6) is connected with the first slider (1-12) in a rotating manner, the first slider (1-12) is connected with the first inner end slider (1-13) in a sliding manner, the first inner end slider (1-13) is fixedly connected with the extrusion sliding frame (1-5), the first inner end slider push spring (1-14) is connected with the first inner end slider (1-13) in a sleeved manner, the second spherical clamping rod (1-15) is connected with the extrusion sliding frame (1-5) in a sliding manner, and the second spherical clamping rod push spring (1-16) is arranged between the second adjacent spherical clamping rods (1-15), the spherical clamping rods II (1-15) are connected with the spherical clamping grooves I (1-4) in a matching mode, the driving slide rods I (1-17) are connected with the sliders II (1-18) in a matching mode, the sliders II (1-18) are connected with the driving disc I (1-9) in a sliding mode, the spherical clamping grooves III (1-21) are arranged on the driving disc I (1-9), the spherical clamping rods III (1-19) are connected with the sliders II (1-18) in a sliding mode, the spherical clamping rod push springs III (1-20) are arranged between the two spherical clamping rods III (1-19), the spherical clamping rods III (1-19) are connected with the spherical clamping grooves III (1-21) in a matching mode, one ends of the hinged connecting rods (1-22) are connected with the extrusion sliding frames (1-3) in a hinged mode, the other ends of the hinged connecting rods (1-22) are connected with the lower end turntables (1-23, the lower end rotary disc (1-23) is rotationally connected with the carrying bottom plate (1-1).

3. A building board processing apparatus as claimed in claim 1, wherein: the unidirectional assembly (2) comprises a middle end frame (2-1), an upper end frame (2-2), a fixed terminal (2-3), an inner end slider (2-4), an upper end sliding column (2-5), an upper end push spring (2-6), a unidirectional transport plate I (2-7), a hinged sliding rod I (2-8), a hinged sliding rod II (2-9), a hinged sliding rod push spring (2-10), a unidirectional transport plate II (2-11) and an inner end push spring I (2-12), the upper end frame (2-2) is fixedly connected with the middle end frame (2-1), the upper end sliding column (2-5) is fixedly connected with the upper end frame (2-2), the inner end slider (2-4) is slidably connected with the upper end sliding column (2-5), the upper end push spring (2-6) is connected with the upper end sliding column (2-5) in a sleeved mode, the fixed terminal (2-3) is fixedly connected with the middle end frame (2-1), the one-way carrying plate I (2-7) is rotatably connected with the inner end slider (2-4), the one-way carrying plate II (2-11) is slidably connected with the one-way carrying plate I (2-7), the inner end push spring I (2-12) is arranged between the one-way carrying plate II (2-11) and the one-way carrying plate I (2-7), the hinged slide bar I (2-8) is rotatably connected with the one-way carrying plate I (2-7), the connecting slide bar I (2-8) is slidably connected with the hinged slide bar II (2-9), the hinged slide bar II (2-9) is rotatably connected with the middle end frame (2-1), the hinged slide bar push spring (2-10) is arranged between the connecting slide bar I (2-8) and the slide bar hinged slide bar II (2-9), the fixed terminal (2-3) is connected with the middle end sliding frame (1-2) in a sliding mode, and the fixed terminal (2-3) is fixedly connected with the driving sliding rod I (1-17).

4. A building board processing apparatus as claimed in claim 1, wherein: the cutting component (3) comprises a cutting outer frame (3-1), belt wheels (3-2), a belt (3-3), a cutting rectangular frame (3-4), a rotating cam (3-5), a matching cam (3-6), an eccentric cam I (3-7), a cam driving rod (3-8), a matching rotating wheel (3-9), an eccentric cam II (3-10), a cam rotating rod I (3-11), a cam rotating rod II (3-12), an auxiliary sliding rod (3-14), a matching clamping device (3-15) and a matching clamping push spring (3-16), wherein the belt wheels (3-2) are rotatably connected with the cutting outer frame (3-1), the belt (3-3) is connected between the two belt wheels (3-2) in a matching way, the auxiliary sliding rod (3-14) is fixedly connected with the cutting outer frame (3-1), the cutting rectangular frame (3-4) is connected with the auxiliary sliding rod (3-14) in a sliding manner, the rotating cam (3-5) is fixedly connected with the cam rotating rod I (3-11), the cam rotating rod I (3-11) is fixedly connected with the eccentric cam I (3-7), the matching cam (3-6) is connected with the rotating cam (3-5) in a matching manner, the cam driving rod (3-8) is connected with the eccentric cam I (3-7) and the eccentric cam II (3-10) in a rotating manner, the matching rotating wheel (3-9) is connected with the cam driving rod (3-8) in a matching manner, the matching rotating wheel (3-9) is connected with the matching clamping device (3-15) in a rotating manner, the matching clamping push spring (3-16) is connected with the matching clamping device (3-15) in a sleeving manner, and the matching clamping device (3-15) is connected with the cutting rectangular frame (3-4) in a, the matched clamping push spring (3-16) is arranged between the matched clamping device (3-15) and the cutting rectangular frame (3-4), the cam rotating rod II (3-12) is rotatably connected with the cutting outer frame (3-1), the eccentric cam II (3-10) is fixedly connected with the cam rotating rod II (3-12), and the belt (3-3) is arranged at the inner end of the cutting rectangular frame (3-4).

5. The building board processing apparatus according to claim 4, wherein: the cam rotating rod I (3-11) is fixedly connected at the eccentric position of the eccentric cam I (3-7), the cam rotating rod II (3-12) is fixedly connected at the eccentric position of the eccentric cam II (3-10), and the upper end of the cutting rectangular frame (3-4) is fixedly provided with a cutting edge.

6. A building board processing apparatus as claimed in claim 1, wherein: the chassis assembly (4) comprises a chassis body (4-1), a containing box (4-2), a bearing plate (4-3) and a bearing push spring (4-4), wherein the containing box (4-2) is fixedly connected with the chassis body (4-1), the bearing plate (4-3) is slidably connected with the containing box (4-2), the bearing push spring (4-4) is arranged between the bearing plate (4-3) and the containing box (4-2), a carrying bottom plate (1-1) is fixedly connected with the chassis body (4-1), and a cutting outer frame (3-1) is fixedly connected with the chassis body (4-1).

7. A building board processing apparatus as claimed in claim 1, wherein: the power assembly (5) comprises a power chassis (5-1), an input motor (5-2), a first bevel gear (5-3), a second bevel gear (5-4), a slide rod of the bevel gear (5-5), a push spring of the slide rod of the bevel gear (5-6), a sleeve of the bevel gear (5-7), a third bevel gear (5-8), a fourth bevel gear (5-9), a shaft of the bevel gear (5-10), a transmission belt (5-11), a slide rod of the clutch (5-12), a push spring of the slide rod of the clutch (5-13), a first slide rod of the clutch (5-14), a second slide rod of the clutch (5-15), an output rod of the clutch (5-16), a driving bracket (5-17) and a driving rotating rod (5-18), wherein an output shaft of the input motor (5-2) is fixedly connected with the first bevel gear (5-3, an input motor (5-2) is fixedly connected with a power chassis (5-1), a bevel gear II (5-4) is in meshing transmission with a bevel gear I (5-3), a bevel gear II (5-4) is fixedly connected with a bevel gear slide rod (5-5), a bevel gear slide rod push spring (5-6) is in sleeve connection with the bevel gear slide rod (5-5), a bevel gear sleeve (5-7) is in sliding connection with the bevel gear slide rod (5-5), the bevel gear slide rod push spring (5-6) is arranged between the bevel gear sleeve (5-7) and the bevel gear slide rod (5-5), a bevel gear III (5-8) is fixedly connected with the bevel gear sleeve (5-7), the bevel gear sleeve (5-7) is in rotating connection with the power chassis (5-1), a bevel gear IV (5-9) is in meshing transmission with the bevel gear III (5-8), a bevel gear IV (5-9) is fixedly connected with a bevel gear shaft (5-10), the bevel gear shaft (5-10) is rotatably connected with a power chassis (5-1), a transmission belt (5-11) is matched and connected with the bevel gear shaft (5-10), a clutch slide bar (5-12) is fixedly connected with an output shaft of an input motor (5-2), a clutch slide bar (5-12) is rotatably connected with the power chassis (5-1), a clutch slide bar push spring (5-13) is sleeved and connected with the clutch slide bar (5-12), a clutch slide bar I (5-14) is sleeved and connected with the clutch slide bar (5-12), a clutch slide bar push spring (5-13) is arranged between the clutch slide bar I (5-14) and the clutch slide bar (5-12), a clutch slide bar II (5-15) is matched and connected with the clutch slide bar I (5-14), the clutch sliding rod II (5-15) is fixedly connected with the clutch output rod (5-16), the clutch output rod (5-16) is rotatably connected with the power chassis (5-1), the driving support (5-17) is rotatably matched and connected with the bevel gear II (5-4), the driving rotating rod (5-18) is fixedly connected with the driving support (5-17), the driving rotating rod (5-18) is rotatably connected with the matching cam (3-6), the power chassis (5-1) is fixedly connected with the chassis body (4-1), the belt wheel (3-2) is fixedly connected with the clutch output rod (5-16), and the transmission belt (5-11) is matched and connected with the driving rod I (1-8).

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