CN214517844U - Blanking machine for aluminum profile machining - Google Patents

Abstract

The utility model discloses an unloader is used in aluminium alloy processing, the utility model discloses a be located subaerial and from left to right cutting device, conveyor, the unloader that distributes in proper order, be located subaerial storage device. Unloader includes the fixed plate, install the transportation dish on the fixed plate with removing, install at the epaxial incomplete gear of commentaries on classics, install in transportation dish bottom and with gear engagement's rack, rotate drive shaft A who installs on the fixed plate through antifriction bearing, drive shaft B, install the first sprocket on drive shaft A, the second sprocket, install the third sprocket on drive shaft B, the fourth sprocket, with first sprocket, the annular chain A of third sprocket meshing, with the second sprocket, the annular chain B of fourth sprocket meshing, install drive block A on annular chain A, install drive block B on annular chain B. Through unloader, storage device solved current aluminium alloy cutting and relied on artifical manual unloading after accomplishing, problem consuming time and power.

Description

Blanking machine for aluminum profile machining

Technical Field

The utility model particularly relates to an unloader is used in aluminium alloy processing.

Background

With the rapid advance of large-scale capital construction investment and industrialization process in China, the yield and consumption of the whole aluminum profile industry are rapidly increased, and China also becomes the largest aluminum profile production base and consumption market in the world. The aluminum profile is mainly applied to the transportation industry, the equipment and mechanical equipment manufacturing industry, the durable consumer goods industry and the like, accounts for about 10%, 10% and 12% of the aluminum profile in China, and the consumption of the industrial aluminum profile in China will be continuously increased in the future.

In the aluminium alloy application, need use the aluminium alloy segmentation of cutting device intercepting suitable length according to actual conditions, current aluminium alloy is after the cutting is accomplished, stacks in disorder on the workstation, seriously influences the cutting of back section bar, need cut usually one section just rely on artifical manual unloading, consuming time and wasting power, work efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the defects of the prior art, the utility model provides an unloader is used in aluminium alloy processing.

The utility model provides a technical scheme of above-mentioned problem does: a blanking machine for processing aluminum profiles comprises a cutting device, a conveying device, a blanking device and a storage device, wherein the cutting device, the conveying device and the blanking device are positioned on the ground and are sequentially distributed from left to right along the X direction;

the blanking device comprises a fixed plate, support columns which are arranged at the bottom of the fixed plate and are positioned at four corners of the fixed plate, a first groove body is arranged at the middle position of the fixed plate, a first groove body and a second groove body which are distributed along the X direction are arranged on the fixed plate, a third groove body which is positioned between the first groove body and the second groove body is arranged on the fixed plate, the first groove body and the second groove body are symmetrical relative to the third groove body, a transfer disc which is movably arranged on the fixed plate, a rotating shaft which is arranged at the bottom of the fixed plate through a rolling bearing in a rotating mode, a transfer motor which is arranged at the bottom of the fixed plate and an output shaft is arranged on the rotating shaft, an incomplete gear which is arranged on the rotating shaft and is positioned in the third groove body, a rack which is arranged at the bottom of the transfer disc and is meshed with the gear, a driving shaft A and a driving shaft B which are arranged at the bottom of the fixed plate through a rolling bearing in a rotating mode and are arranged on the driving shaft A, install on drive shaft A and along the first sprocket that drive shaft A the central axis direction distributes, the second sprocket, install on drive shaft B and along the third sprocket that drive shaft B the central axis direction distributes, the fourth sprocket, first sprocket all is located first cell body with the third sprocket, the second sprocket all is located the second cell body with the fourth sprocket, simultaneously with first sprocket, the annular chain A of third sprocket meshing, simultaneously with the second sprocket, the annular chain B of fourth sprocket meshing, install the drive block A on annular chain A, install on annular chain B and in the motion process all the time with drive block A be about the drive block B of third cell body bilateral symmetry.

Furthermore, cutting device includes the workstation, installs on the workstation and is located the workstation and is close to conveyor one end, the grudging post of U-shaped structure, installs the cylinder at the grudging post top, installs on the cylinder telescopic link and be the backup pad of L-shaped structure, installs the cutting motor in the backup pad, installs the cutting knife in cutting motor output shaft.

Further, the tooth of the partial gear subtends a central angle of 90 °.

Furthermore, a pair of first inserting columns and second inserting columns distributed along the X direction are mounted at the bottom of the transfer plate, the first inserting columns are matched with the first groove body in shape, the first inserting columns are inserted into the first groove body, the second inserting columns are matched with the second groove body in shape, and the second inserting columns are inserted into the second groove body;

limiting baffles which are distributed along the Y direction and are respectively positioned at the front side and the rear side of the transfer disc are arranged at the top of the transfer disc; a plurality of baffles which are uniformly distributed along the Y direction and are positioned between the two limit baffles are arranged at the top of the transfer disc.

Further, the lift is a scissor lift platform.

Further, the conveying device is a belt conveyor.

Furthermore, a placing pit is arranged on the ground and is positioned in front of the blanking device;

the storage device comprises a lifter positioned in the placing pit and a storage rack arranged on the lifter;

the storage rack comprises a plurality of storage disks distributed along the Z direction, and 4 fixing columns which are positioned between every two adjacent storage disks, wherein two ends of each fixing column are respectively installed on the storage disks, and the fixing columns are respectively positioned on four corners of each storage disk;

the storage disc is close to unloader one end and is equipped with the hold up tank that supplies third sprocket, fourth sprocket to pass, and the storage disc up end is equipped with a pair of fourth cell body, the fifth cell body that distributes along the X direction, communicates with the hold up tank.

Furthermore, the fourth groove body is matched with the first inserting column in shape, and the fifth groove body is matched with the second inserting column in shape.

The utility model discloses beneficial effect has: the utility model discloses an unloader, storage device have solved current aluminium alloy cutting and have accomplished the back and rely on artifical manual unloading, consuming time power, problem that work efficiency is low. The blanking device is meshed with the incomplete gear through a rack to drive the transfer disc to move intermittently and work in cooperation with the conveying device to ensure that the cut aluminum profile enters an empty transfer area; the driving block A and the driving block B are driven to move through chain transmission of the chain wheel, and the driving block A and the driving block B push the transfer plate filled with the cut aluminum profiles into the storage and transportation device. The storage and transportation device is arranged under the ground, the installation position is saved, the scissor-type lifting platform is matched with the blanking device to work, the storage rack is lifted by the height of one storage disc at a time, and the transfer disc can enter the vacant storage disc.

Drawings

Fig. 1 is a top view of the present invention;

FIG. 2 is a front view of the present invention;

fig. 3 is a cross-sectional view of the third tank body of the blanking device of the present invention;

fig. 4 is a cross-sectional view of the first tank body of the blanking device of the present invention;

fig. 5 is a top view of the storage tray of the present invention.

In the figure:

100-cutting device, 101-conveying device, 102-blanking device, 103-storage device, 104-workbench, 105-vertical frame, 106-cylinder, 107-supporting plate, 108-cutting motor, 109-cutting knife, 110-fixing plate, 111-supporting column, 112-first groove body, 113-second groove body, 114-third groove body, 115-transfer disk, 116-rotating shaft, 117-incomplete gear, 118-rack, 119-driving shaft A, 120-driving shaft B, 121-first chain wheel, 122-second chain wheel, 123-third chain wheel, 124-fourth chain wheel, 125-annular chain A, 126-annular chain B, 127-driving block A, 129-first inserting column, 131-limit baffle, 132-partition board, 133-placing pit, 134-lifter, 135-storage rack, 136-storage tray, 137-fixing column, 139-storage tank, 140-fourth tank body and 141-fifth tank body.

Detailed Description

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

A blanking machine for processing aluminum profiles comprises a cutting device 100, a conveying device 101, a blanking device 102 and a storage device 103, wherein the cutting device 100, the conveying device 101, the blanking device 102 and the storage device 103 are located on the ground and are sequentially distributed from left to right along the X direction.

The cutting device 100 comprises a workbench 104, a vertical frame 105 which is arranged on the workbench 104 and is positioned at one end of the workbench 104 close to the conveying device 101 and has a U-shaped structure, a cylinder 106 arranged at the top of the vertical frame 105, a supporting plate 107 which is arranged on an expansion rod of the cylinder 106 and has an L-shaped structure, a cutting motor 108 arranged on the supporting plate 107, and a cutting knife 109 arranged on an output shaft of the cutting motor 108.

Cutting device 100 still includes the clamping component who is used for pressing from both sides tight aluminium alloy in the cutting process, and clamping component can be pneumatic clamping mechanism, also can manual clamping mechanism, and clamping component is purchase the piece outward, and the structure is prior art, and this application is not repeated.

The conveyor 101 is a belt conveyor.

The aluminum profile is cut by the cutting device 100, the belt conveyor works in cooperation with the cutting device 100, and the cut aluminum profile is transported to the blanking device 102.

The blanking device 102 comprises a fixing plate 110, support columns 111 which are arranged at the bottom of the fixing plate 110 and are positioned at four corners of the fixing plate 110, a first groove body 112 is arranged at the middle position of the fixing plate 110, a first groove body 112 and a second groove body 113 which are distributed along the X direction are arranged on the fixing plate 110, a third groove body 114 which is positioned between the first groove body 112 and the second groove body 113 is arranged on the fixing plate 110, the first groove body 112 and the second groove body 113 are symmetrical relative to the third groove body 114, a transfer disc 115 which is movably arranged on the fixing plate 110, a rotating shaft 116 which is rotatably arranged at the bottom of the fixing plate 110 through a rolling bearing, a transfer motor which is arranged at the bottom of the fixing plate 110 and an output shaft of which is arranged on the rotating shaft 116, an incomplete gear 117 which is arranged on the rotating shaft 116 and is positioned in the third groove body 114, the central angle of the tooth of the incomplete gear 117 is 90 degrees, and a rack 118 which is arranged at the bottom of the transfer disc 115 and is meshed with the gear, a driving shaft A119 and a driving shaft B120 which are rotatably arranged at the bottom of the fixed plate 110 through rolling bearings and distributed along the Y direction, a driving motor which is arranged at the bottom of the fixed plate 110 and an output shaft of which is arranged on the driving shaft A119, a first chain wheel 121 and a second chain wheel 122 which are arranged on the driving shaft A119 and distributed along the central axis direction of the driving shaft A119, a third chain wheel 123 and a fourth chain wheel 124 which are arranged on the driving shaft B120 and distributed along the central axis direction of the driving shaft B120, wherein the first chain wheel 121 and the third chain wheel 123 are both positioned in the first groove body 112, the second chain wheel 122 and the fourth chain wheel 124 are both positioned in the second groove body 113, an endless chain a125 meshed with the first sprocket 121 and the third sprocket 123 simultaneously, an endless chain B126 meshed with the second sprocket 122 and the fourth sprocket 124 simultaneously, a driving block a127 mounted on the endless chain a125, and a driving block B mounted on the endless chain B126 and bilaterally symmetric to the driving block a127 about the third slot 114 during movement;

a pair of first inserting columns 129 and second inserting columns distributed along the X direction are mounted at the bottom of the transfer tray 115, the first inserting columns 129 are matched with the first groove body 112 in shape, the first inserting columns 129 are inserted into the first groove body 112, the second inserting columns are matched with the second groove body 113 in shape, and the second inserting columns are inserted into the second groove body 113;

limiting baffles 131 which are distributed along the Y direction and are respectively positioned at the front side and the rear side of the transfer disc 115 are arranged at the top of the transfer disc 115; a plurality of partition plates 132 which are uniformly distributed along the Y direction and are positioned between the two limit baffles 131 are installed at the top of the transfer tray 115, and a transfer area is formed between two adjacent partition plates 132 or between the partition plates 132 and the limit baffles 131.

The rack 118 is meshed with the incomplete gear 117 to drive the transfer disc 115 to move intermittently, and the transfer disc is matched with the conveying device 101 to work, so that the cut aluminum profile enters an empty transfer area; through sprocket chain drive, drive block A127, the motion of drive block B, drive block A127, drive block B will fill in the transportation dish 115 propelling movement to the storage device of cutting back aluminium alloy.

A placing pit 133 is arranged on the ground, and the placing pit 133 is positioned in front of the blanking device 102;

storage device 103 includes a scissor lift platform positioned within placement pit 133, a storage rack 135 positioned on the scissor lift platform;

the storage rack 135 includes a plurality of storage trays 136 distributed along the Z direction, 4 fixing posts 137 located between two adjacent storage trays 136 and having two ends respectively mounted on the storage trays 136, the fixing posts 137 being located at four corners of the storage trays 136 respectively;

one end of the storage disc 136 close to the blanking device 102 is provided with a storage groove 139 for the third chain wheel 123 and the fourth chain wheel 124 to pass through, and the upper end surface of the storage disc 136 is provided with a pair of fourth groove bodies 140 and fifth groove bodies 141 which are distributed along the X direction and are communicated with the storage groove 139.

The fourth slot 140 is matched with the first insert post 129 in shape, and the fifth slot 141 is matched with the second insert post in shape.

By placing the storage and transport device under the ground, saving installation space, the scissor lift platform works in conjunction with the blanking device 102, so that the storage rack 135 is raised by the height of one storage tray 136 at a time, ensuring that the transfer tray 115 can enter the empty storage tray 136.

The utility model discloses the theory of operation:

(1) placing the aluminum profile to be cut on a workbench 104, and driving a cutting knife 109 to finish cutting by a cutting device 100;

(2) the transfer motor drives the gear to rotate, the gear is meshed with the rack 118 to drive the transfer disc 115 to move along the Y direction, and the vacant transfer area is aligned to the aluminum profile to be cut;

(3) the conveying device 101 conveys the cut aluminum profiles to an empty transfer area;

(4) repeating (1), (2) and (3), and filling the empty transfer area;

(5) the elevator 134 lifts the storage rack 135 up to align the empty storage tray 136 with the transfer tray 115:

(6) after the transfer tray 115 is full, the incomplete gear is meshed with the rack 118 to move to the maximum stroke, and the gear is not meshed with the rack 118 any more; the driving motor works, the chain wheel and the chain are in transmission, the driving block A127 and the driving block B work along with the chain, and the transferring disk 115 is pushed onto the storage disk 136 by the driving block A127 and the driving block.

(7) Repeat (5) and (6) and fill the empty storage shelves 135.

Many other changes and modifications can be made without departing from the spirit and scope of the invention. It is to be understood that the invention is not to be limited to the specific embodiments, and that the scope of the invention is defined by the appended claims.

Claims (5)

1. The blanking machine for processing the aluminum profile is characterized by comprising a cutting device (100), a conveying device (101), a blanking device (102) and a storage device (103), wherein the cutting device (100), the conveying device (101) and the blanking device (102) are located on the ground and are sequentially distributed from left to right along the X direction;

the blanking device (102) comprises a fixing plate (110), supporting columns (111) which are arranged at the bottom of the fixing plate (110) and are positioned at four corners of the fixing plate (110), a first groove body (112) is arranged at the middle position of the fixing plate (110), a first groove body (112) and a second groove body (113) which are distributed along the X direction are arranged on the fixing plate (110), a third groove body (114) which is positioned between the first groove body (112) and the second groove body (113) is arranged on the fixing plate (110), the first groove body (112) and the second groove body (113) are symmetrical relative to the third groove body (114), a transfer disc (115) which is movably arranged on the fixing plate (110), a rotating shaft (116) which is arranged at the bottom of the fixing plate (110) through a rolling bearing in a rotating mode, a transfer motor which is arranged at the bottom of the fixing plate (110) and an output shaft is arranged on the rotating shaft (116), an incomplete gear (117) which is arranged on the rotating shaft (116) and is positioned in the third groove body (114), a rack (118) which is arranged at the bottom of the transfer disc (115) and is meshed with the gear, a driving shaft A (119) and a driving shaft B (120) which are arranged at the bottom of the fixed plate (110) in a rotating way through a rolling bearing and are distributed along the Y direction, a driving motor which is arranged at the bottom of the fixed plate (110) and has an output shaft arranged on the driving shaft A (119), a first chain wheel (121) and a second chain wheel (122) which are arranged on the driving shaft A (119) and are distributed along the central axis direction of the driving shaft A (119), a third chain wheel (123) and a fourth chain wheel (124) which are arranged on the driving shaft B (120) and are distributed along the central axis direction of the driving shaft B (120), the first chain wheel (121) and the third chain wheel (123) are both positioned in a first groove body (112), the second chain wheel (122) and the fourth chain wheel (124) are both positioned in a second groove body (113), and an annular chain A (125) which is meshed with the first chain wheel (121) and the third chain wheel (123) is simultaneously, the driving device comprises an annular chain B (126) meshed with a second chain wheel (122) and a fourth chain wheel (124) at the same time, a driving block A (127) arranged on the annular chain A (125), and a driving block B which is arranged on the annular chain B (126) and is symmetrical to the driving block A (127) in the left-right direction of a third groove body (114) all the time in the motion process.

2. The blanking machine for the aluminum profile processing as claimed in claim 1, wherein the cutting device (100) comprises a workbench (104), a U-shaped stand (105) which is arranged on the workbench (104) and is positioned at one end of the workbench (104) close to the conveying device (101), an air cylinder (106) which is arranged at the top of the stand (105), a supporting plate (107) which is arranged on an expansion link of the air cylinder (106) and is in an L-shaped structure, a cutting motor (108) which is arranged on the supporting plate (107), and a cutting knife (109) which is arranged on an output shaft of the cutting motor (108).

3. The blanking machine for the processing of aluminium profiles according to claim 2, characterized in that the teeth of the incomplete gear (117) subtend an angle of 90 ° at the centre of the circle.

4. The blanking machine for the aluminum profile processing as claimed in claim 1, wherein a pair of first inserting columns (129) and second inserting columns distributed along the X direction are installed at the bottom of the transfer plate (115), the first inserting columns (129) are matched with the first groove body (112) in shape, the first inserting columns (129) are inserted into the first groove body (112), the second inserting columns are matched with the second groove body (113) in shape, and the second inserting columns are inserted into the second groove body (113);

limiting baffles (131) which are distributed along the Y direction and are respectively positioned at the front side and the rear side of the transfer disc (115) are arranged at the top of the transfer disc (115); a plurality of partition plates (132) which are uniformly distributed along the Y direction and are positioned between the two limit baffles (131) are arranged at the top of the transfer disc (115).

5. The blanking machine for aluminum profile processing as recited in claim 1, wherein a placing pit (133) is arranged on the ground, and the placing pit (133) is positioned in front of the blanking device (102);

the storage device (103) comprises an elevator (134) positioned in the placing pit (133), and a storage rack (135) arranged on the elevator (134);

the storage rack (135) comprises a plurality of storage disks (136) distributed along the Z direction, and 4 fixing columns (137) which are positioned between two adjacent storage disks (136) and are respectively arranged on the storage disks (136) at two ends, wherein the fixing columns (137) are respectively positioned on four corners of the storage disks (136);

one end of the storage disc (136), which is close to the blanking device (102), is provided with a storage groove (139) through which the third chain wheel (123) and the fourth chain wheel (124) penetrate, and the upper end face of the storage disc (136) is provided with a pair of fourth groove bodies (140) and fifth groove bodies (141) which are distributed along the X direction and communicated with the storage groove (139).

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