CN211102223U

CN211102223U - Support gusset high-precision improved laser cutting device of laboratory reagent frame

Info

Publication number: CN211102223U
Application number: CN201922144072.4U
Authority: CN
Inventors: 徐福然
Original assignee: Jiangsu Silmei Experimental Equipment Technology Co ltd
Current assignee: Jiangsu Silmei Experimental Equipment Technology Co ltd
Priority date: 2019-12-04
Filing date: 2019-12-04
Publication date: 2020-07-28
Anticipated expiration: 2029-12-04

Abstract

The utility model discloses a high-precision improved laser cutting device for a supporting angle plate of a laboratory reagent rack, which comprises a three-dimensional sliding table module and a first material pushing mechanism, wherein a metal supporting net rack is paved on a cutting table, and a laser cutting head is arranged on the three-dimensional sliding table module; the cutting table is provided with a material collecting groove, an automatic stacking mechanism and a second material pushing mechanism are arranged in the material collecting groove, the side face of the material collecting groove, which is communicated with the cutting table, forms a discharge hole, the automatic stacking mechanism is arranged at the inner groove bottom of the material collecting groove, the second material pushing mechanism is arranged on the inner groove wall of the material collecting groove, and the second material pushing mechanism corresponds to the discharge hole. The utility model provides a pair of high-accuracy improved generation laser cutting device of support gusset of laboratory reagent frame has the advantage that cutting accuracy is high, machining efficiency is high.

Description

Support gusset high-precision improved laser cutting device of laboratory reagent frame

Technical Field

The utility model belongs to the technical field of laboratory equipment processing equipment, especially, relate to a support gusset high-precision improved generation laser cutting device of laboratory reagent frame.

Background

The attached figure 1 is a processing procedure structure diagram of a supporting angle plate 400, and the specific procedures are that firstly, original blanks 100 are cut into blank sections 200 by using laser cutting equipment, then the blank sections 200 are bent into L type plates 300 by using bending equipment, and finally, mounting holes are drilled in L type plates 300 by using punching equipment to form finished supporting angle plates 400.

Disclosure of Invention

The purpose of the invention is as follows: in order to overcome the not enough of existence among the prior art, the utility model provides a support gusset high-precision improved generation laser cutting device of laboratory reagent frame has the advantage that cutting accuracy is high, machining efficiency is high.

The technical scheme is as follows: in order to achieve the purpose, the utility model discloses a high-precision improved laser cutting device of support gusset of laboratory reagent frame, include the three-dimensional slip table module that erects on the cutting bed through the support frame, the cutting bed upper berth is equipped with the metal support rack, be provided with the laser cutting head on the Z axle slip table of three-dimensional slip table module, the laser cutting head sets up vertically downwards, and the laser cutting head drives the cutting range of moving in overlooking the direction through the three-dimensional slip table module and is in the peripheral edge profile of metal support rack encloses the scope;

the first material pushing mechanism is arranged on the cutting table; the cutting table is provided with a material collecting groove, an automatic stacking mechanism and a second material pushing mechanism are arranged in the material collecting groove, the side face of the material collecting groove, which is communicated with the cutting table, forms a discharge hole, the automatic stacking mechanism is arranged at the inner groove bottom of the material collecting groove, the second material pushing mechanism is arranged at the inner groove wall of the material collecting groove, and the second material pushing mechanism corresponds to the discharge hole.

Further, the first material pushing mechanism comprises a linear sliding table module arranged on the cutting table, a cross rod arranged on the linear sliding table module and a first material pushing plate connected to the lower end of the cross rod; the first material pushing plate stretches across the metal support net rack, and the bottom end of the first material pushing plate is slightly higher than the top end of the metal support net rack.

Furthermore, the automatic stacking mechanism comprises a supporting plate which is elastically supported at the bottom of the trough in the collecting trough through vertical springs and a vibrator which is arranged on the bottom surface of the supporting plate, and the supporting plate is elastically supported and kept in a horizontal posture through a plurality of vertical springs which are uniformly distributed at the bottom of the supporting plate;

the side surface of the supporting plate is integrally connected with a limiting block, and the top surface of the limiting block and the top surface of the supporting plate are positioned in the same plane; the inner groove wall of the material collecting groove is provided with limiting grooves in one-to-one correspondence with the limiting blocks, and the limiting blocks are matched with each other to extend into the limiting grooves.

Furthermore, a material pushing plate position and a channel are sequentially arranged on the inner groove wall of the material collecting groove opposite to the discharge hole and penetrating through the side surface of the cutting table; the second pushing mechanism comprises an electric push rod arranged in the channel through a plug and a second pushing plate arranged in the pushing plate position, and the second pushing plate is fixedly connected with a pushing end of the electric push rod.

Further, the top surface of the supporting plate is always lower than the bottom surface of the second material pushing plate and higher than the lower opening edge of the material outlet.

Furthermore, the edge of the notch of the collecting groove close to the metal support net rack is an inclined plane inclined towards the inner bottom of the collecting groove.

Furthermore, the table top position of the cutting table corresponding to the metal support net rack is an ash deposition groove, and the metal support net rack is laid in the groove opening of the ash deposition groove or covers the ash deposition groove.

Has the advantages that: the utility model discloses a high-accuracy improved generation laser cutting device of support gusset of laboratory reagent frame, beneficial effect as follows:

1) the utility model discloses in, three-dimensional slip table module drives the laser cutting head and removes and carry out laser cutting to the original blank on the metal support rack, constitutes the stock billet, and cutting accuracy is high, and the back is accomplished in the cutting, utilizes first pushing equipment to push the stock billet section and collects the silo in, and the stock billet section is through the automatic windrow mechanism realization that collects the silo in stacking, and at last, the stock billet section that the second pushing equipment will stack is released from the discharge gate to improve machining efficiency.

2) The utility model discloses an automatic windrow mechanism's setting has realized the temporary storage of material base section and has stacked, improves ejection of compact convenience and efficiency.

Drawings

FIG. 1 is a schematic structural diagram of a production process of a support gusset;

FIG. 2 is a schematic view of the overall structure of the present invention;

FIG. 3 is a specific embodiment of the present invention;

FIG. 4 is a front view of a portion of the structure of FIG. 2;

FIG. 5 is an embodiment of FIG. 4;

FIG. 6 is a top view of a portion of the structure of FIG. 2;

fig. 7 is a schematic structural diagram of the automatic stacking mechanism.

Detailed Description

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

As shown in the attached

drawings

2, 3 and 5, the high-precision improved laser cutting device for the supporting angle plate of the laboratory reagent rack comprises a three-dimensional sliding table module 3 erected on a cutting table 1 through a supporting frame 2, a metal supporting net rack 5 is paved on the cutting table 1, a laser cutting head 4 is arranged on a Z-axis sliding table of the three-dimensional sliding table module 3, the laser cutting head 4 is arranged vertically downwards, and the moving cutting range of the laser cutting head 4 in the overlooking direction driven by the three-dimensional sliding table module 3 is located in the enclosing range of the outline of the peripheral edge of the metal supporting net rack 5; the device also comprises a first material pushing mechanism 7 arranged on the cutting table 1; the cutting table is characterized in that a material collecting groove 11 is formed in the cutting table 1, an automatic stacking mechanism 6 and a second material pushing mechanism 8 are arranged in the material collecting groove 11, a discharge hole 13 is formed in the side face, conducting on the cutting table 1, of the material collecting groove 11, the automatic stacking mechanism 6 is arranged at the bottom of an inner groove of the material collecting groove 11, the second material pushing mechanism 8 is arranged on the inner groove wall of the material collecting groove 11, and the second material pushing mechanism 8 corresponds to the discharge hole 13. The utility model discloses in, three-dimensional slip table module 3 drives laser cutting head 4 and removes and carries out laser cutting to original blank 100 on the metal support rack 5, constitutes blank section 200, and the back is accomplished in the cutting, utilizes first pushing equipment 7 to push into the silo 11 that gathers materials with material blank 200, and material blank section 200 realizes stacking the windrow through the automatic windrow mechanism 6 that gathers materials in the silo 11, and finally, the material blank section 200 that second pushing equipment 8 will stack is released from discharge gate 13. The cutting device has the advantages of high cutting precision and high machining efficiency. Furthermore, the utility model discloses an automatic windrow mechanism 6's setting has realized the temporary storage of material billet 200 and has stacked, improves ejection of compact convenience and efficiency.

It should be noted that the width L1 of the trough 11 is slightly larger than the width L2 of the billet 200 as shown in fig. 5, so that stacking of the billets 200 can be more effectively achieved.

As shown in fig. 2, the first pushing mechanism 7 includes a linear sliding table module 71 disposed on the cutting table 1, a cross bar 72 disposed on the linear sliding table module 71, and a first pushing plate 73 connected to a lower end of the cross bar 72; the first material pushing plate 73 is arranged across the metal supporting net rack 5, and the bottom end of the first material pushing plate 73 is slightly higher than the top end of the metal supporting net rack 5. The linear sliding table module 71 drives the first material pushing plate 73 to push the material blank section 200 of the metal support net rack 5 into the material collecting groove 11; it should be noted that the first stripper plate 73 of the present invention also serves to push the green stock 100 onto the metal support grid 5.

As shown in fig. 4 and 7, the automatic stacking mechanism 6 includes a supporting plate 61 elastically supported at the bottom of the trough 11 by vertical springs 62 and a vibrator 63 mounted on the bottom surface of the supporting plate 61, and the supporting plate 61 is elastically supported by a plurality of vertical springs 62 uniformly distributed at the bottom thereof to maintain a horizontal posture; in the stacking process, the vibrator 63 is started to drive the supporting plate 61 to vibrate, so that the blank sections 200 on the vibrator are stacked neatly, the structure is simple, and the stacking and stacking effect is good.

More specifically, the side surface of the supporting plate 61 is integrally connected with a limiting block 64, and the top surface of the limiting block 64 and the top surface of the supporting plate 61 are in the same plane; the inner groove wall of the material collecting groove 11 is provided with limiting grooves 16 which correspond to the limiting blocks 64 one to one, and the limiting blocks 64 are matched to extend into the limiting grooves 16.

As shown in fig. 6, a material pushing plate position 15 and a channel 14 are sequentially arranged on the inner wall of the material collecting groove 11 opposite to the material outlet 13 and penetrating through the side surface of the cutting table 1; the second pushing mechanism 8 includes an electric push rod 81 disposed in the channel 14 through a plug 83, and a second pushing plate 82 disposed in the pushing plate position 15, and the second pushing plate 82 is fixedly connected to a pushing end of the electric push rod 81. When the second pushing mechanism 8 does not push materials, the second pushing plate 82 is pulled by the electric push rod 81 to be located in the pushing plate position 15; in the pushing state of the second pushing mechanism 8, the second pushing plate 82 pushes the material blank sections 200 stacked on the supporting plate 61 to be pushed out from the material outlet 13 by the electric push rod 81.

It should be noted that the top surface of the supporting plate 61 is always kept lower than the bottom surface of the second ejector plate 82 and higher than the lower edge of the discharge opening 13, so that the ejection of the material blank sections 200 stacked on the supporting plate 61 from the discharge opening 13 can be achieved by the second ejector mechanism 8.

As shown in fig. 2, the edge of the trough 11 close to the opening of the metal support net rack 5 is an inclined plane 12 inclined towards the inner bottom of the trough 11, so that the billet 200 is pushed by the first material pushing plate 73 to slide into the trough 11.

More specifically, correspond with metal support rack 5 the mesa position of cutting bed 1 is the deposition groove of seting up, metal support rack 5 lays in the notch of deposition groove or covers the deposition groove, and the dust that laser cutting produced falls into in the deposition groove.

The above description is only a preferred embodiment of the present invention, and it should be noted that: for those skilled in the art, without departing from the principle of the present invention, several improvements and modifications can be made, and these improvements and modifications should also be considered as the protection scope of the present invention.

Claims

1. The utility model provides a support gusset high accuracy improved generation laser cutting device of laboratory reagent frame which characterized in that: the three-dimensional sliding table device is characterized by comprising a three-dimensional sliding table module (3) erected on a cutting table (1) through a support frame (2), wherein a metal supporting net rack (5) is paved on the cutting table (1), a laser cutting head (4) is arranged on a Z-axis sliding table of the three-dimensional sliding table module (3), the laser cutting head (4) is arranged vertically downwards, and the laser cutting head (4) is driven by the three-dimensional sliding table module (3) to move in the overlooking direction within a cutting range within the outline enclosing range of the peripheral edge of the metal supporting net rack (5);

the cutting machine also comprises a first material pushing mechanism (7) arranged on the cutting table (1); the cutting table is characterized in that a material collecting groove (11) is formed in the cutting table (1), an automatic stacking mechanism (6) and a second material pushing mechanism (8) are arranged in the material collecting groove (11), the side face of the material collecting groove (11) communicated with the cutting table (1) forms a discharge hole (13), the automatic stacking mechanism (6) is arranged at the bottom of an inner groove of the material collecting groove (11), the second material pushing mechanism (8) is arranged on the inner groove wall of the material collecting groove (11), and the second material pushing mechanism (8) corresponds to the discharge hole (13).

2. The high-precision improved laser cutting device for the supporting angle plate of the laboratory reagent rack as claimed in claim 1, wherein: the first material pushing mechanism (7) comprises a linear sliding table module (71) arranged on the cutting table (1), a cross rod (72) arranged on the linear sliding table module (71) and a first material pushing plate (73) connected to the lower end of the cross rod (72); the first material pushing plate (73) stretches across the metal supporting net rack (5), and the bottom end of the first material pushing plate (73) is slightly higher than the top end of the metal supporting net rack (5).

3. The high-precision improved laser cutting device for the supporting angle plate of the laboratory reagent rack as claimed in claim 2, wherein: the automatic stacking mechanism (6) comprises a supporting plate (61) which is elastically supported at the bottom of the inner trough of the collecting trough (11) through vertical springs (62) and a vibrator (63) which is installed on the bottom surface of the supporting plate (61), and the supporting plate (61) is elastically supported and kept in a horizontal posture through a plurality of vertical springs (62) which are uniformly distributed at the bottom of the supporting plate;

the side surface of the supporting plate (61) is integrally connected with a limiting block (64), and the top surface of the limiting block (64) and the top surface of the supporting plate (61) are in the same plane; the inner groove wall of the material collecting groove (11) is provided with limiting grooves (16) which correspond to the limiting blocks (64) one by one, and the limiting blocks (64) are matched and extend into the limiting grooves (16).

4. The high-precision improved laser cutting device for the supporting angle plate of the laboratory reagent rack as claimed in claim 3, wherein: a material pushing plate position (15) and a channel (14) are sequentially arranged on the inner groove wall of the material collecting groove (11) opposite to the material outlet (13) and penetrating through the side surface of the cutting table (1); the second pushing mechanism (8) comprises an electric push rod (81) arranged in the channel (14) through a plug (83) and a second pushing plate (82) arranged in the pushing plate position (15), and the second pushing plate (82) is fixedly connected with a pushing end of the electric push rod (81).

5. The high-precision improved laser cutting device for the supporting angle plate of the laboratory reagent rack as claimed in claim 4, wherein: the top surface of the supporting plate (61) is always lower than the bottom surface of the second material pushing plate (82) and higher than the lower opening edge of the discharge opening (13).

6. The high-precision improved laser cutting device for the supporting angle plate of the laboratory reagent rack according to any one of claims 1 to 5, wherein: the end edge of the trough (11) close to the notch of the metal support net rack (5) is an inclined plane (12) which inclines towards the inner bottom of the trough (11).

7. The high-precision improved laser cutting device for the supporting angle plate of the laboratory reagent rack according to any one of claims 1 to 5, wherein: the table board position of the cutting table (1) corresponding to the metal supporting net rack (5) is an ash deposition groove, and the metal supporting net rack (5) is laid in a groove opening of the ash deposition groove or covers the ash deposition groove.