CN111604998A - Plank equipment for building - Google Patents

Abstract

The invention relates to the field of buildings, in particular to a wood board device for buildings. The plate to be processed can be fixed; the device can adapt to plates with different specifications; the cutting of the plate can be realized; the cutting distance can be adjusted according to actual conditions. Including bearing the weight of the assembly, the cutting assembly, the power supply assembly, it rotates to drive the cooperation friction pulley through the transmission friction pulley, and then drive the rotation of solid fixed sleeving slide bar through solid fixed sleeving, and then drive the rotation of separation and reunion slide bar one, and then drive the rotation of separation and reunion slide bar two through inner checkposts, and then drive the output belt and rotate, and then drive the middle-end pivot and rotate, slide the drive slide bar along drive slide bar branch simultaneously, and then drive the solid fixed sleeving motion through the drive slide bar, and then make the solid fixed sleeving slide bar slide along the solid fixed sleeving slide bar, and then make the use position of cooperation friction pulley on the transmission friction pulley change, and then make the rotational speed of.

Description

Plank equipment for building

Technical Field

The invention relates to the field of buildings, in particular to a wood board device for buildings.

Background

The wood board equipment for building is a common equipment in the field of building, but the common wood board equipment for building has single function.

Disclosure of Invention

The invention aims to provide a wood board device for building, which can realize the fixation of a board to be processed; the device can adapt to plates with different specifications; the cutting of the plate can be realized; the cutting distance can be adjusted according to actual conditions.

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

the utility model provides a plank equipment for building, is including bearing the weight of the assembly, cutting assembly, power supply assembly, its characterized in that: the bearing assembly is connected with the cutting assembly, and the cutting assembly is connected with the power source assembly.

As a further optimization of the technical scheme, the invention relates to a building plank device, wherein the bearing assembly comprises a middle end plate, a rectangular slide rod, a bearing plate, a first hinged rod, a manual rotating rod boss, a manual rotating rod clamping rod, a clamping rod slide column push spring, a portal frame, a pressing rod outer ring, a pressing rod inner ring, a buffering slide rod I, a buffering slide rod spring, a buffering slide rod II, an upper end clamp, an upper end slider, a first upper end push spring, a second upper end push spring and an upper end clamping groove, the rectangular slide rod is fixedly connected with the middle end plate, the bearing plate is slidably connected with the rectangular slide rod, the first hinged rod is hinged with the bearing plate, the first hinged rod is hinged with the manual rotating rod, the manual rotating rod boss is fixedly connected with the manual rotating rod, the clamping rod is matched with the manual rotating rod boss, the clamping rod slide column is fixedly connected with the middle end plate, the clamping rod slide column push spring is sleeved with the clamping rod slide column, the clamping rod sliding column pushing spring is arranged between a clamping rod of a manual rotating rod and the clamping rod sliding column, an upper end clamping groove is formed in the bearing plate, an upper end slider is connected with the bearing plate in a sliding mode, an upper end slider is connected with the upper end slider in a sliding mode, an upper end pushing spring I is arranged between the two upper end sliders, a door-shaped frame is connected with the upper end slider in a sliding mode, an upper end pushing spring II is connected with the upper end slider in a sleeved mode, an upper end pushing spring II is arranged between the door-shaped frame and the upper end slider, an inner ring of a pressing rod is connected with the door-shaped frame in a rotating mode, a buffering sliding rod II is connected with an inner ring of the pressing rod in a hinged mode, the buffering sliding rod II is connected with the buffering sliding rod I in a sliding mode.

As a further optimization of the technical scheme, the invention relates to a wood board device for buildings, wherein the cutting assembly comprises a cutting outer frame, side sliding columns, spherical clamping grooves, a middle end rotating shaft, a cutting support, a first matching belt wheel, a first circular saw blade, a middle end driving belt wheel, a second matching belt wheel, a fourth matching belt wheel, a second circular saw blade, a first middle end sliding column pushing spring, a second matching belt wheel, a fifth matching belt wheel, a first sliding support, a third matching belt wheel, a second sliding support, a sixth matching belt wheel, a first bidirectional screw rod, a screw belt, screw conical teeth, matching conical teeth, spherical clamping rods and spherical clamping rod pushing springs, wherein the side sliding columns are fixedly connected with the cutting outer frame, the spherical clamping grooves are arranged on the side sliding columns, the middle end rotating shaft is rotatably connected with the cutting outer frame, the first matching belt wheel and the fourth matching belt wheel are rotatably connected with the cutting support, the side sliding column is connected with the cutting support in a sliding mode, the circular saw blade I is fixedly connected with the matching belt wheel III, the matching belt wheel VI is fixedly connected with the circular saw blade II, the middle-end driving belt wheel is rotatably connected with the cutting support, the middle-end driving belt wheel is slidably connected with the middle-end rotating shaft in a matching mode, the middle-end sliding column I is fixedly connected with the cutting support, the middle-end sliding column push spring I is connected with the middle-end sliding column I in a sleeved mode, the sliding support II is slidably connected with the middle-end sliding column I, the matching belt wheel V, the matching belt wheel VI is rotatably connected with the sliding support II, the matching belt wheel II and the matching belt wheel III are rotatably connected with the sliding support, the middle-end sliding column II is connected with the middle-end sliding column push spring II in a sleeved mode, the middle-end sliding column II is slidably connected with the sliding support I, the matching belt wheel I, the middle-end driving belt wheel II, the matching, The cutting device comprises a sixth matching belt wheel, a fourth matching belt wheel, a first bidirectional screw rod and a cutting support, a screw taper tooth and the cutting support are connected in a rotating mode, the matching taper tooth and the screw taper tooth are meshed for transmission, the matching taper tooth and the middle-end driving belt wheel are fixedly connected, a screw belt is connected between the first bidirectional screw rod and the screw taper tooth, a first sliding support, a second sliding support and a first bidirectional screw rod are in threaded connection, a spherical clamping rod is in sliding connection with the cutting support, a spherical clamping rod pushing spring is arranged between the spherical clamping rod and the cutting support, the spherical clamping rod is connected with a spherical clamping groove in a matching mode, and a cutting outer frame is fixedly connected with the middle-end.

As a further optimization of the technical scheme, the invention relates to a wood board device for buildings, wherein the power source assembly comprises an input motor, an input friction wheel, a transmission friction wheel, a matching friction wheel, a driving slide rod support rod, an annular clamping groove, a fixed sleeve slide rod, a clutch slide rod I, a clutch sleeve, a hinged connecting rod, a clutch slide rod II, an output belt, a driving rotating rod, a push spring, an inner end clamp push spring, a hemispherical clamp rod push spring and a power bottom plate, wherein the input motor is fixedly connected with the power bottom plate, the input friction wheel is fixedly connected with the input motor, the transmission friction wheel is rotatably connected with the power bottom plate, the input friction wheel is in friction transmission with the transmission friction wheel, the matching friction wheel is in friction transmission with the transmission friction wheel, the fixed sleeve is fixedly connected with the matching friction wheel, and, the annular clamping groove is arranged on the driving slide bar supporting rod, the hemispherical clamping bar is connected with the driving slide bar in a sliding manner, the hemispherical clamping bar push spring is arranged between the hemispherical clamping bar and the driving slide bar, the hemispherical clamping bar is connected with the annular clamping groove in a matching manner, the fixed sleeve slide bar is connected with the fixed sleeve in a sliding manner, the fixed sleeve slide bar is fixedly connected with the clutch slide bar I, the clutch slide bar I is rotatably connected with the power bottom plate, the clutch sleeve is connected with the clutch slide bar I in a sliding manner, the clutch sleeve is hinged with the hinged connecting rod, the hinged connecting rod is hinged with the inner end clamp, the inner end clamp is connected with the clutch slide bar I in a sliding manner, the inner end clamp push spring is arranged between the inner end clamp and the clutch slide bar I, the inner end clamp is connected with the clutch slide bar II in a matching manner, the clutch, the output belt is connected with the middle-end rotating shaft.

The wood board equipment for the building has the beneficial effects that:

the invention relates to a wood board device for buildings, wherein an input motor is a three-phase asynchronous motor, the rotation of the input motor drives a transmission friction wheel to rotate through an input friction wheel, then drives a matching friction wheel to rotate through the transmission friction wheel, further drives a fixed sleeve slide bar to rotate through a fixed sleeve, further drives a clutch slide bar to rotate through an inner end clip, further drives an output belt to rotate, further drives a middle-end rotating shaft to rotate, simultaneously drives a slide bar to slide along a drive slide bar supporting rod, further drives a fixed sleeve to move through the drive slide bar, further enables the fixed sleeve to slide along the fixed sleeve slide bar, further enables the use position of the matching friction wheel on the transmission friction wheel to change, and further enables the rotating speed of the middle-end rotating shaft to change.

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 diagram of the carrier assembly of the present invention;

FIG. 5 is a second schematic structural diagram of the carrier assembly of the present invention;

FIG. 6 is a third schematic structural view of the bearing assembly of the present invention;

FIG. 7 is a first schematic view of a cutting assembly according to the present invention;

FIG. 8 is a second schematic structural diagram of the cutting assembly of the present invention;

FIG. 9 is a third schematic view of the cutting assembly of the present invention;

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

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

FIG. 12 is a first schematic view of the power source assembly of the present invention;

FIG. 13 is a schematic structural diagram of a power source assembly according to the present invention;

fig. 14 is a third schematic structural view of the power source assembly of the present invention.

In the figure: a load-bearing assembly 1; a middle end plate 1-1; a rectangular slide bar 1-2; a carrier plate 1-3; 1-4 of a hinge rod; 1-5 of a manual rotating rod; 1-6 of a manual rotating rod boss; a manual rotating rod is clamped by 1-7; 1-8 of a clamping rod sliding column; a clamping rod sliding column push spring 1-9; 1-10 of a portal frame; 1-11 parts of an outer ring of the pressing rod; 1-12 of the inner ring of the pressing rod; buffering the first sliding rod 1-13; buffer slide rod springs 1-14; a second buffer slide bar 1-15; upper end clips 1-16; 1-17 of upper end slider; the upper end pushes the spring 1-18; a second push spring 1-19 at the upper end; 1-20 parts of an upper end clamping groove; a cutting assembly 2; cutting the outer frame 2-1; 2-2 of side sliding columns; 2-3 of a spherical clamping groove; a middle-end rotating shaft 2-4; cutting the bracket 2-5; 2-6 of a matching belt wheel; matching the first belt 2-7; 2-8 parts of a circular saw blade I; the middle end drives the belt wheel 2-9; 2-10 of a second matching belt; 2-11 of a matching belt wheel; 2-12 parts of circular saw blade II; 2-13 of a middle sliding column I; a middle sliding column push spring I is 2-14; 2-15 parts of a middle sliding column II; a middle sliding column push spring II 2-16; 2-17 of a second matching belt wheel; matching with a belt wheel V2-18; 2-19 of a sliding support I; 2-20 of a matching belt wheel; 2-21 parts of a second sliding support; six matched belt wheels 2-22; 2-23 parts of a bidirectional screw rod I; 2-24 parts of a screw belt; 2-25 of screw conical teeth; 2-26 of matching bevel teeth; 2-27 parts of a spherical clamping rod; 2-28 parts of a spherical clamping rod push spring; a power source assembly 3; inputting a motor 3-1; an input friction wheel 3-2; 3-3 of a transmission friction wheel; 3-4 of a matching friction wheel; driving the slide bar 3-5; driving the slide bar supporting rod 3-6; 3-7 of a ring-shaped clamping groove; 3-8 of a fixed sleeve; fixing a sleeve sliding rod 3-9; 3-10 parts of a clutch slide bar I; 3-11 parts of clutch sleeve; 3-12 of hinged connecting rod; a second clutch sliding rod 3-13; output belts 3-14; driving the rotating rod 3-15; 3-16 parts of a push spring; inner end clips 3-17; the inner end is clamped and pushed by springs 3-18; 3-19 parts of a hemispherical clamping rod; 3-20 parts of a hemispherical clamping rod push spring; power chassis 3-21.

Detailed Description

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

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

The first embodiment is as follows:

the present embodiment is described below with reference to fig. 1 to 14, and a wood board device for building includes a bearing assembly 1, a cutting assembly 2, and a power source assembly 3, and is characterized in that: the bearing assembly 1 is connected with the cutting assembly 2, and the cutting assembly 2 is connected with the power source assembly 3.

The second embodiment is as follows:

the following describes the present embodiment with reference to fig. 1 to 14, and the present embodiment further describes the first embodiment, where the bearing assembly 1 includes a middle end plate 1-1, a rectangular sliding rod 1-2, a bearing plate 1-3, a first hinge rod 1-4, a manual rotating rod 1-5, a manual rotating rod boss 1-6, a manual rotating rod clamping rod 1-7, a clamping rod sliding column 1-8, a clamping rod sliding column push spring 1-9, a door type frame 1-10, a press rod outer ring 1-11, a press rod inner ring 1-12, a buffer sliding rod 1-13, a buffer sliding rod spring 1-14, a buffer sliding rod two 1-15, an upper end clip 1-16, an upper end slider 1-17, an upper end push spring one-18, an upper end push spring two 1-19, and an upper end clamping groove 1-20, a rectangular slide bar 1-2 is fixedly connected with a middle end plate 1-1, a bearing plate 1-3 is slidably connected with the rectangular slide bar 1-2, a first hinged bar 1-4 is hinged with the bearing plate 1-3, a first hinged bar 1-4 is hinged with a manual rotating bar 1-5, a manual rotating bar boss 1-6 is fixedly connected with a manual rotating bar 1-5, a manual rotating bar clamping bar 1-7 is matched and connected with the manual rotating bar boss 1-6, a clamping bar sliding column 1-8 is fixedly connected with a middle end plate 1-1, a clamping bar sliding column push spring 1-9 is sleeved and connected with a clamping bar sliding column 1-8, a clamping bar sliding column push spring 1-9 is arranged between the manual rotating bar clamping bar 1-7 and the clamping bar sliding column 1-8, an upper end clamping groove 1-20 is arranged on the bearing plate 1-3, the upper end sliders 1-17 are connected with the bearing plates 1-3 in a sliding manner, the upper end clamps 1-16 are connected with the upper end sliders 1-17 in a sliding manner, the upper end push springs 1-18 are arranged between the two upper end clamps 1-16, the door type frames 1-10 are connected with the upper end sliders 1-17 in a sliding manner, the upper end push springs 1-19 are connected with the upper end sliders 1-17 in a sleeved manner, the upper end push springs 1-19 are arranged between the door type frames 1-10 and the upper end sliders 1-17, the inner rings 1-12 of the press fit rods are rotatably connected with the door type frames 1-10, the buffer slider II 1-15 is hinged with the inner ring 1-12 of the press fit rod, the buffer slider II 1-15 is connected with the buffer slider I1-13 in a sliding manner, the buffer slider springs 1-14 are arranged between the buffer slider II 1-15 and the buffer slider I1-13, the first buffer sliding rod 1-13 is hinged with the outer ring 1-11 of the pressing rod.

The third concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 14, and the present embodiment further describes the first embodiment, where the cutting assembly 2 includes a cutting outer frame 2-1, a side sliding column 2-2, a spherical slot 2-3, a middle rotating shaft 2-4, a cutting support 2-5, a first fitting pulley 2-6, a first fitting belt 2-7, a first circular saw blade 2-8, a middle driving pulley 2-9, a second fitting belt 2-10, a fourth fitting pulley 2-11, a second circular saw blade 2-12, a first middle sliding column 2-13, a first middle sliding column push spring 2-14, a second middle sliding column 2-15, a second middle sliding column push spring 2-16, a second fitting pulley 2-17, a fifth fitting pulley 2-18, a first sliding support 2-19, a third fitting pulley 2-20, and a third fitting pulley 2-9, 2-21 parts of a second sliding support, 2-22 parts of a matched belt wheel, 2-23 parts of a bidirectional screw, 2-24 parts of a screw belt, 2-25 parts of screw bevel teeth, 2-26 parts of matched bevel teeth, 2-27 parts of a spherical clamping rod and 2-28 parts of a spherical clamping rod push spring, 2-2 parts of a side sliding column are fixedly connected with 2-1 parts of a cutting outer frame, 2-3 parts of a spherical clamping groove are arranged on 2-2 parts of the side sliding column, 2-4 parts of a middle end rotating shaft are rotatably connected with 2-1 parts of the cutting outer frame, 2-6 parts of a matched belt wheel and 2-11 parts of a matched belt wheel are rotatably connected with 2-5 parts of the cutting support, 2-2 parts of the side sliding column is slidably connected with 2-5 parts of the cutting support, 2-8 parts of a circular saw blade is fixedly connected with 2-20 parts of a matched belt wheel, the middle end driving belt wheel 2-9 is rotationally connected with the cutting support 2-5, the middle end driving belt wheel 2-9 is connected with the middle end rotating shaft 2-4 in a sliding fit manner, the middle end sliding column I2-13 is fixedly connected with the cutting support 2-5, the middle end sliding column push spring I2-14 is connected with the middle end sliding column I2-13 in a sleeved manner, the sliding support II 2-21 is connected with the middle end sliding column I2-13 in a sliding manner, the matching belt wheel V2-18 and the matching belt wheel VI 2-22 are rotationally connected with the sliding support II 2-21, the matching belt wheel II 2-17 and the matching belt wheel III 2-20 are rotationally connected with the sliding support I2-19, the middle end sliding column II 2-15 is connected with the middle end sliding column push spring II 2-16 in a sleeved manner, and the middle end sliding column II 2-15 is connected with the sliding support I2-19 in a sliding manner, a first matching belt 2-7 is in matching connection with a first matching belt wheel 2-6, a middle-end driving belt wheel 2-9, a second matching belt wheel 2-17 and a third matching belt wheel 2-20, a second matching belt 2-10 is in matching connection with a middle-end driving belt wheel 2-9, a fifth matching belt wheel 2-18, a sixth matching belt wheel 2-22 and a fourth matching belt wheel 2-11, a first bidirectional screw 2-23 is in rotating connection with a cutting support 2-5, a conical tooth 2-25 of the screw is in rotating connection with the cutting support 2-5, a conical tooth 2-26 of the matching screw is in meshing transmission with a conical tooth 2-25 of the screw, a 2-26 of the matching conical tooth is fixedly connected with the middle-end driving belt wheel 2-9, a 2-24 of the screw is connected between the first bidirectional screw 2-23 and the conical tooth 2-25 of the screw, and, The second sliding support 2-21 is in threaded connection with the first bidirectional screw rod 2-23, the spherical clamping rod 2-27 is in sliding connection with the cutting support 2-5, the spherical clamping rod push spring 2-28 is arranged between the spherical clamping rod 2-27 and the cutting support 2-5, the spherical clamping rod 2-27 is in matched connection with the spherical clamping groove 2-3, and the cutting outer frame 2-1 is fixedly connected with the middle end plate 1-1.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1-14, and the embodiment further describes the first embodiment, where the power source assembly 3 includes an input motor 3-1, an input friction wheel 3-2, a transmission friction wheel 3-3, a matching friction wheel 3-4, a drive slide bar 3-5, a drive slide bar support bar 3-6, an annular clamping groove 3-7, a fixed sleeve 3-8, a fixed sleeve slide bar 3-9, a clutch slide bar one 3-10, a clutch sleeve 3-11, a hinged connecting bar 3-12, a clutch slide bar two 3-13, an output belt 3-14, a drive rotary bar 3-15, a push spring 3-16, an inner end clip 3-17, an inner end clip push spring 3-18, a hemispherical clamp bar 3-19, a hemispherical clamp bar push spring 3-20, a semi-spherical clamp bar push spring 3-20, a power source assembly 3-, A power bottom plate 3-21, an input motor 3-1 fixedly connected with the power bottom plate 3-21, an input friction wheel 3-2 fixedly connected with the input motor 3-1, a transmission friction wheel 3-3 rotatably connected with the power bottom plate 3-21, an input friction wheel 3-2 in friction transmission with the transmission friction wheel 3-3, a matching friction wheel 3-4 in friction transmission with the transmission friction wheel 3-3, a fixed sleeve 3-8 fixedly connected with the matching friction wheel 3-4, a driving slide bar support rod 3-6 fixedly connected with the power bottom plate 3-21, an annular clamping groove 3-7 arranged on the driving slide bar support rod 3-6, a hemispherical clamping rod 3-19 in sliding connection with the driving slide bar 3-5, a hemispherical clamping rod push spring 3-20 arranged between the hemispherical clamping rod 3-19 and the driving slide bar 3-5, the hemispherical clamping rod 3-19 is matched and connected with the annular clamping groove 3-7, the fixed sleeve sliding rod 3-9 is matched and connected with the fixed sleeve 3-8 in a sliding way, the fixed sleeve sliding rod 3-9 is fixedly connected with the clutch sliding rod one 3-10, the clutch sliding rod one 3-10 is rotationally connected with the power bottom plate 3-21, the clutch sleeve 3-11 is connected with the clutch sliding rod one 3-10 in a sliding way, the clutch sleeve 3-11 is connected with the hinge connecting rod 3-12 in a hinged way, the hinge connecting rod 3-12 is connected with the inner end clamp 3-17 in a hinged way, the inner end clamp 3-17 is connected with the clutch sliding rod one 3-10 in a sliding way, the inner end clamp push spring 3-18 is arranged between the inner end clamp 3-17 and the clutch sliding rod one 3-10, and the inner end clamp 3-, a second clutch sliding rod 3-13 is rotatably connected with a second power bottom plate 3-21, an output belt 3-14 is in fit connection with the second clutch sliding rod 3-13, the power bottom plate 3-21 is fixedly connected with a cutting outer frame 2-1, and the output belt 3-14 is connected with a middle end rotating shaft 2-4;

starting an input motor 3-1, wherein the input motor 3-1 is a three-phase asynchronous motor, the input motor 3-1 rotates to drive a transmission friction wheel 3-3 to rotate through an input friction wheel 3-2, further drives a matching friction wheel 3-4 to rotate through the transmission friction wheel 3-3, further drives a fixed sleeve slide bar 3-9 to rotate through a fixed sleeve 3-8, further drives a clutch slide bar one 3-10 to rotate, further drives a clutch slide bar two 3-13 to rotate through an inner end clip 3-17, further drives an output belt 3-14 to rotate, further drives a middle end rotating shaft 2-4 to rotate, simultaneously slides along a driving slide bar support bar 3-6 to drive a slide bar 3-5, further drives the fixed sleeve 3-8 to move through the driving slide bar 3-5, so that the fixed sleeve 3-8 slides along the fixed sleeve slide bar 3-9, the use position of the matching friction wheel 3-4 on the transmission friction wheel 3-3 is changed, and the rotating speed of the middle end rotating shaft 2-4 is changed.

The invention relates to a wood board device for buildings, which has the working principle that:

when the device is used, a plate to be cut penetrates between the bearing plates 1-3 and the outer rings 1-11 of the pressing rods, under the action of the elastic force of the upper end push springs 1-19, the door-shaped frames 1-10 are far away from the upper end sliders 1-17, the outer rings 1-11 of the pressing rods are in contact with the plate to be cut, the plate to be cut is pressed, the upper end sliders 1-17 are manually pushed, the upper end sliders 1-17 slide on the bearing plates 1-3, the pressing positions of the outer rings 1-11 of the pressing rods on the plate to be cut are changed through the door-shaped frames 1-10, the device is convenient to adapt to plates with different widths, the length of the plate to be processed can be adjusted according to actual conditions, the manual rotating rods 1-5 are manually rotated, and the hinged rods 1-4 are driven to move through the manual rotating rods 1-5, the bearing plates 1-3 are driven to slide on the rectangular sliding rods 1-2 through the first hinge rods 1-4, so that the distance between the two bearing plates 1-3 is changed, and the bearing plates are convenient to adapt to plates with different lengths; the middle-end rotating shaft 2-4 rotates to drive the middle-end driving belt wheel 2-9 to rotate, and further the middle-end driving belt wheel 2-9 drives the matching belt I2-7; the second belt 2-10 is matched to rotate simultaneously, and then the first circular saw blade 2-8 is driven by the third matched belt wheel 2-20 and the sixth matched belt wheel 2-22 respectively; 2-12 of the circular saw blade is rotated, and then the circular saw blade passes through 2-8 of the circular saw blade; the circular saw blade II 2-12 is in contact with the plate, so that the plate is cut, meanwhile, when the middle-end driving belt wheel 2-9 rotates, the screw conical teeth 2-25 are driven to rotate through the matching conical teeth 2-26, the screw belt 2-24 is driven to rotate through the screw conical teeth 2-25, the bidirectional screw I2-23 is driven to rotate, and the bidirectional screw I2-19 passes through the sliding supports I2-19 respectively; the sliding support II 2-21 drives the circular saw blade I2-8; 2-12 transverse movements of the circular saw blade II, and then realize 2-8 of the circular saw blade I; feeding the circular saw blade II by 2-12; meanwhile, the cutting supports 2-5 are manually pushed to slide along the side sliding columns 2-2, so that the distance between the two cutting supports 2-5 is changed, the width of the plate which can be processed by the device is changed, and the width of the plate which can be cut is adjusted; starting an input motor 3-1, wherein the input motor 3-1 is a three-phase asynchronous motor, the input motor 3-1 rotates to drive a transmission friction wheel 3-3 to rotate through an input friction wheel 3-2, further drives a matching friction wheel 3-4 to rotate through the transmission friction wheel 3-3, further drives a fixed sleeve slide bar 3-9 to rotate through a fixed sleeve 3-8, further drives a clutch slide bar one 3-10 to rotate, further drives a clutch slide bar two 3-13 to rotate through an inner end clip 3-17, further drives an output belt 3-14 to rotate, further drives a middle end rotating shaft 2-4 to rotate, simultaneously slides along a driving slide bar support bar 3-6 to drive a slide bar 3-5, further drives the fixed sleeve 3-8 to move through the driving slide bar 3-5, further enabling the fixed sleeve 3-8 to slide along the fixed sleeve sliding rod 3-9, further enabling the use position of the matching friction wheel 3-4 on the transmission friction wheel 3-3 to change, and further enabling the rotating speed of the middle-end rotating shaft 2-4 to change; meanwhile, the rotating direction of the middle-end rotating shaft 2-4 is changed by changing the phase of the input current of the starting input motor 3-1, so that a circular saw blade I2-8 is realized; the feed direction of the circular saw blades two 2-12 is changed.

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

Claims (4)

1. The utility model provides a plank equipment for building, is including bearing assembly (1), cutting assembly (2), power supply assembly (3), its characterized in that: the bearing assembly (1) is connected with the cutting assembly (2), and the cutting assembly (2) is connected with the power source assembly (3).

2. A building plank apparatus as claimed in claim 1, wherein: the bearing assembly (1) comprises a middle end plate (1-1), a rectangular sliding rod (1-2), a bearing plate (1-3), a hinged rod I (1-4), a manual rotating rod (1-5), a manual rotating rod boss (1-6), a manual rotating rod clamping rod (1-7), a clamping rod sliding column (1-8), a clamping rod sliding column push spring (1-9), a door-shaped frame (1-10), a pressing rod outer ring (1-11), a pressing rod inner ring (1-12), a buffering sliding rod I (1-13), a buffering sliding rod spring (1-14), a buffering sliding rod II (1-15), an upper end clamp (1-16), an upper end slider (1-17), an upper end push spring I (1-18), an upper end push spring II (1-19) and an upper end clamping groove (1-20), a rectangular sliding rod (1-2) is fixedly connected with a middle end plate (1-1), a bearing plate (1-3) is connected with the rectangular sliding rod (1-2) in a sliding manner, a first hinged rod (1-4) is hinged with the bearing plate (1-3), a first hinged rod (1-4) is hinged with a manual rotating rod (1-5), a boss (1-6) of the manual rotating rod is fixedly connected with the manual rotating rod (1-5), a clamping rod (1-7) is matched and connected with the boss (1-6) of the manual rotating rod, a clamping rod sliding column (1-8) is fixedly connected with the middle end plate (1-1), a clamping rod sliding column pushing spring (1-9) is connected with a clamping rod sliding column (1-8) in a sleeved manner, and a clamping rod sliding column pushing spring (1-9) is arranged on the clamping rod (1-7) of the manual rotating rod, Between the clamping rod sliding columns (1-8), an upper end clamping groove (1-20) is arranged on the bearing plate (1-3), an upper end slider (1-17) is connected with the bearing plate (1-3) in a sliding way, an upper end clamp (1-16) is connected with the upper end slider (1-17) in a sliding way, an upper end push spring I (1-18) is arranged between the two upper end clamps (1-16), the door-shaped frame (1-10) is connected with the upper end slider (1-17) in a sliding way, an upper end push spring II (1-19) is connected with the upper end slider (1-17) in a sleeved way, an upper end push spring II (1-19) is arranged between the door-shaped frame (1-10) and the upper end slider (1-17), a pressing rod inner ring (1-12) is connected with the door-shaped frame (1-10) in a rotating way, a buffer sliding rod II (1-15) is connected with the rod inner ring (1-12) in a pressing way, the buffer slide bar II (1-15) is connected with the buffer slide bar I (1-13) in a sliding mode, the buffer slide bar spring (1-14) is arranged between the buffer slide bar II (1-15) and the buffer slide bar I (1-13), and the buffer slide bar I (1-13) is hinged with the pressing rod outer ring (1-11).

3. A building plank apparatus as claimed in claim 1, wherein: the cutting assembly (2) comprises a cutting outer frame (2-1), side sliding columns (2-2), spherical clamping grooves (2-3), a middle-end rotating shaft (2-4), a cutting support (2-5), a first matching belt wheel (2-6), a first matching belt (2-7), a first circular saw blade (2-8), a middle-end driving belt wheel (2-9), a second matching belt (2-10), a fourth matching belt wheel (2-11), a second circular saw blade (2-12), a first middle-end sliding column (2-13), a first middle-end sliding column push spring (2-14), a second middle-end sliding column (2-15), a second middle-end sliding column push spring (2-16), a second matching belt wheel (2-17), a fifth matching belt wheel (2-18), a first sliding support (2-19), A third matching belt wheel (2-20), a second sliding support (2-21), a sixth matching belt wheel (2-22), a first bidirectional screw (2-23), a screw belt (2-24), screw bevel teeth (2-25), matching bevel teeth (2-26), spherical clamping rods (2-27) and spherical clamping rod push springs (2-28), wherein the side sliding columns (2-2) are fixedly connected with the cutting outer frame (2-1), spherical clamping grooves (2-3) are arranged on the side sliding columns (2-2), a middle-end rotating shaft (2-4) is rotatably connected with the cutting outer frame (2-1), the first matching belt wheel (2-6) and the fourth matching belt wheel (2-11) are rotatably connected with the cutting support (2-5), and the side sliding columns (2-2) are slidably connected with the cutting support (2-5), a circular saw blade I (2-8) is fixedly connected with a matching belt wheel III (2-20), a matching belt wheel VI (2-22) is fixedly connected with a circular saw blade II (2-12), a middle-end driving belt wheel (2-9) is rotatably connected with a cutting support (2-5), a middle-end driving belt wheel (2-9) is slidably connected with a middle-end rotating shaft (2-4), a middle-end sliding column I (2-13) is fixedly connected with the cutting support (2-5), a middle-end sliding column push spring I (2-14) is connected with the middle-end sliding column I (2-13) in a sleeved mode, a sliding support II (2-21) is slidably connected with the middle-end sliding column I (2-13), a matching belt wheel V (2-18), a matching belt wheel VI (2-22) is rotatably connected with the sliding support II (2-21), and a matching belt wheel II (2-17), A third matching belt wheel (2-20) is rotationally connected with a first sliding support (2-19), a second middle-end sliding column (2-15) is connected with a second middle-end sliding column push spring (2-16) in a sleeved mode, a second middle-end sliding column (2-15) is connected with a first sliding support (2-19) in a sliding mode, a first matching belt (2-7) is connected with a first matching belt wheel (2-6), a second middle-end driving belt wheel (2-9), a second matching belt wheel (2-17) and a third matching belt wheel (2-20) in a matching mode, a second matching belt (2-10) is connected with a second middle-end driving belt wheel (2-9), a fifth matching belt wheel (2-18), a sixth matching belt wheel (2-22) and a fourth matching belt wheel (2-11) in a matching mode, a first bidirectional screw rod (2-23) is rotationally connected with a first cutting support (2, the screw taper teeth (2-25) are rotatably connected with the cutting support (2-5), the matching taper teeth (2-26) are in meshing transmission with the screw taper teeth (2-25), the matching taper teeth (2-26) are fixedly connected with the middle-end driving belt wheel (2-9), the screw belt (2-24) is connected between the bidirectional screw I (2-23) and the screw taper teeth (2-25), the sliding support I (2-19) and the sliding support II (2-21) are in threaded connection with the bidirectional screw I (2-23), the spherical clamping rod (2-27) is in sliding connection with the cutting support (2-5), the spherical clamping rod push spring (2-28) is arranged between the spherical clamping rod (2-27) and the cutting support (2-5), the spherical clamping rod (2-27) is in matching connection with the spherical clamping groove (2-3), the cutting outer frame (2-1) is fixedly connected with the middle end plate (1-1).

4. A building plank apparatus as claimed in claim 1, wherein: the power source assembly (3) comprises an input motor (3-1), an input friction wheel (3-2), a transmission friction wheel (3-3), a matched friction wheel (3-4), a driving slide rod (3-5), a driving slide rod support rod (3-6), an annular clamping groove (3-7), a fixed sleeve (3-8), a fixed sleeve slide rod (3-9), a clutch slide rod I (3-10), a clutch sleeve (3-11), a hinged connecting rod (3-12), a clutch slide rod II (3-13), an output belt (3-14), a driving rotating rod (3-15), a push spring (3-16), an inner end clamp (3-17), an inner end clamp push spring (3-18), a hemispherical clamping rod (3-19), a hemispherical clamping rod push spring (3-20), The power bottom plate (3-21), the input motor (3-1) is fixedly connected with the power bottom plate (3-21), the input friction wheel (3-2) is fixedly connected with the input motor (3-1), the transmission friction wheel (3-3) is rotatably connected with the power bottom plate (3-21), the input friction wheel (3-2) is in friction transmission with the transmission friction wheel (3-3), the matching friction wheel (3-4) is in friction transmission with the transmission friction wheel (3-3), the fixed sleeve (3-8) is fixedly connected with the matching friction wheel (3-4), the driving slide bar support rod (3-6) is fixedly connected with the power bottom plate (3-21), the annular clamping groove (3-7) is arranged on the driving slide bar (3-6), and the hemispherical clamping bar (3-19) is in sliding connection with the driving slide bar (3-5), the hemispherical clamping rod push spring (3-20) is arranged between the hemispherical clamping rod (3-19) and the driving slide rod (3-5), the hemispherical clamping rod (3-19) is connected with the annular clamping groove (3-7) in a matching way, the fixed sleeve slide rod (3-9) is connected with the fixed sleeve (3-8) in a sliding way, the fixed sleeve slide rod (3-9) is fixedly connected with the clutch slide rod I (3-10), the clutch slide rod I (3-10) is rotationally connected with the power bottom plate (3-21), the clutch sleeve (3-11) is connected with the clutch slide rod I (3-10) in a sliding way, the clutch sleeve (3-11) is connected with the hinged connecting rod (3-12) in a hinged way, the hinged connecting rod (3-12) is connected with the inner end clamp (3-17) in a hinged way, the inner end clamp (3-17) is connected with the clutch slide rod I (3-10) in a, an inner end clamp push spring (3-18) is arranged between an inner end clamp (3-17) and a clutch slide bar I (3-10), the inner end clamp (3-17) is connected with a clutch slide bar II (3-13) in a matching mode, the clutch slide bar II (3-13) is rotatably connected with a power bottom plate (3-21), an output belt (3-14) is connected with the clutch slide bar II (3-13) in a matching mode, the power bottom plate (3-21) is fixedly connected with a cutting outer frame (2-1), and the output belt (3-14) is connected with a middle end rotating shaft (2-4).

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