CN215415933U - Double-end automatic engraving and code scanning detection mechanism - Google Patents

Abstract

The utility model relates to a double-end automatic engraving and code scanning detection mechanism which comprises a bottom plate, wherein an engraving component and a convex flange are arranged at the top end of the bottom plate, a rotary table is arranged at the top end of the flange, tools distributed circumferentially are arranged at the top end of the rotary table, a partition plate is arranged between every two tools, a first detection component, an engraving component, a code scanning component and a second detection component are arranged on the bottom plate around the flange anticlockwise, the second detection component and the engraving component are arranged on two sides of the flange oppositely, a second detection component is arranged at one end of the partition plate, a divider is arranged at the bottom end of the rotary table, and the divider is connected to a driving motor. This automatic seal of double-end is carved and is swept a yard detection mechanism and have automatic seal and sweep a yard detection, reduce work load, shorten seal cycle, avoid the error, improve advantages such as yield.

Description

Double-end automatic engraving and code scanning detection mechanism

Technical Field

The utility model relates to the technical field of automatic engraving equipment, in particular to a double-head automatic engraving and code scanning detection mechanism.

Background

The existing marking and code scanning detection is carried out manually and independently, a manual workpiece is taken firstly to be marked on a marking station, and then a product is conveyed to a code scanning detection station after marking is finished, and code scanning detection is carried out.

The manual work is carved seal and is swept a yard detection alone, increases work load, reduces production efficiency, and when the manual work was operated for a long time, easy error production reduced the product yield.

Therefore, a double-head automatic marking and code scanning detection mechanism is developed to solve the defects.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art and provides a double-head automatic engraving and code scanning detection mechanism which has the advantages of automatic engraving and code scanning detection, workload reduction, engraving period shortening, error avoidance, yield improvement and the like.

In order to achieve the purpose, the utility model adopts the technical scheme that: the double-end automatic engraving and code scanning detection mechanism comprises a bottom plate, wherein an engraving component and a convex flange are arranged at the top end of the bottom plate, a rotary plate is arranged at the top end of the flange, tools distributed circumferentially are arranged at the top end of the rotary plate, an L-shaped partition plate is arranged between every two tools, the number of the partition plates is 3, a first detection component, the engraving component, two code scanning components and a second detection component are arranged around the flange on the bottom plate in an anticlockwise mode, the second detection component and the engraving component are arranged on two sides of the flange oppositely, one end of each partition plate is provided with the second detection component, a divider is arranged at the bottom end of the rotary plate, and the divider is connected to a driving motor.

Preferably, the marking assembly comprises a translation assembly and a marking machine fixed on the translation assembly, the translation assembly comprises two rails arranged at the top end of the bottom plate in parallel, a first sliding block and a linear guide rail sliding block are connected at the top end of the rails in a sliding manner, the first sliding block is connected with the linear guide rail sliding block through an L-shaped block, and a fixing plate is arranged at the top end of the linear guide rail sliding block.

Preferably, the top end of the fixing plate is provided with a mounting plate of the imprinter and a block nut, the top end of the bottom plate is provided with a first supporting block and a second supporting block, the first supporting block, the second supporting block and the block nut are provided with a trapezoidal screw in a penetrating manner, and one end of the trapezoidal screw is provided with a hand wheel.

Preferably, the first detection assembly comprises a first supporting rod arranged at the top end of the bottom plate, a first adjusting block penetrates through the first supporting rod, and a first photoelectric sensor is arranged at the bottom end of the first adjusting block.

Preferably, the second detection assembly comprises a second support rod arranged at the top end of the bottom plate, a second adjusting block penetrates through the second support rod, and a second photoelectric sensor is arranged at the bottom end of the second adjusting block.

Preferably, the code scanning assembly comprises a Z-shaped support and a code scanning gun, and the code scanning gun is connected with the top end of the Z-shaped support.

Preferably, the bottom ends of the partition plates are provided with a plurality of through holes, the top ends of two adjacent partition plates are connected through a V-shaped block, and the through holes are connected with the rotary table.

Preferably, four corners of the bottom plate are respectively provided with a connecting hole.

Due to the application of the technical scheme, compared with the prior art, the utility model has the following advantages:

the double-head automatic engraving and code scanning detection mechanism realizes automatic engraving and code scanning detection on products through a three-station structure; the mechanism realizes that the original manual operation is replaced by an automatic flow, the workload of an operator is reduced, and the engraving period is greatly shortened; automatic seal and sweep sign indicating number and detect, avoided artificial error, improve the product yield.

Drawings

FIG. 1 is a schematic top view of the dual-headed automatic imprint and code-scan detection mechanism of the present invention;

FIG. 2 is a schematic side view of the double-headed automatic imprint and code-scan detection mechanism of the present invention.

Detailed Description

The utility model is described in further detail below with reference to the figures and the embodiments.

In the attached drawings 1 to 2, a double-end automatic engraving and code scanning detection mechanism comprises a bottom plate 5, wherein an engraving component and a convex flange 10 are arranged at the top end of the bottom plate 5. The top end of the flange plate 10 is provided with a rotary disc 11. Carousel 11 includes 3 stations: the device comprises a manual feeding station, an engraving station and a code scanning station. The top end of the turntable 11 is provided with a circumferentially distributed tool 12, and a product 100 is placed on the tool 12. An L-shaped partition plate 15 is arranged between every two fixtures 12, the number of the partition plates 15 is 3, a plurality of through holes 151 are formed in the bottom end of each partition plate 15, the top ends of every two adjacent partition plates 15 are connected through a V-shaped block 16, and the through holes 151 are connected with the rotary table 11. A first detection assembly, an imprinting assembly, two code scanning assemblies and a second detection assembly are arranged on the bottom plate 5 around the flange plate 10 in a counterclockwise mode. Four corners of the bottom plate 5 are respectively provided with a connecting hole 6, and the connecting holes 6 are connected to the installation workbench.

The second detection assembly is arranged on two sides of the flange plate 10 opposite to the marking assembly. One end of a partition 15 is provided with a second detection assembly, the bottom end of the rotary table 11 is provided with a divider 81, and the divider 81 rotates to switch the product position. The divider 81 is connected to a driving motor 80, the driving motor 80 drives the divider 81 to drive the flange plate 10 to rotate, the feeding is performed manually in sequence, the marking assembly is automatically marked, and the code scanning assembly is automatically detected.

The marking assembly comprises a translation assembly and a marking machine 20 fixed on the translation assembly, and the marking machine 20 marks the two-dimensional code. The translation assembly comprises two rails 22 arranged in parallel at the top end of the bottom plate 5, and a first slide block 21 and a linear guide rail slide block 24 are slidably connected at the top end of the rails 22. The first slider 21 is connected with the linear guide slider 24 through an L-shaped block 23. The top end of the linear guide rail slide block 24 is provided with a fixed plate 25, and the top end of the fixed plate 25 is provided with an imprinter mounting plate 26 and a block nut 33. The top end of the bottom plate 5 is provided with a first supporting block 32 and a second supporting block 35, and the side surface of the mounting plate 26 of the imprinter is provided with an imprinting hole 261. A trapezoidal screw 31 penetrates through the first supporting block 32, the second supporting block 35 and the block-shaped screw cap 33, and a hand wheel 30 is arranged at one end of the trapezoidal screw 31. Different products are adjusted in distance from the product 100 by the imprinter 20 via the handwheel 30.

The first detecting component comprises a first supporting rod 50 arranged at the top end of the bottom plate 5, and a first adjusting block 51 penetrates through the first supporting rod 50. A first photoelectric sensor 52 is disposed at the bottom end of the first adjusting block 51. The second detecting member includes a second support rod 70 provided at the top end of the base plate 5. A second adjusting block 71 is arranged on the second support bar 70 in a penetrating way. A second photoelectric sensor 72 is disposed at the bottom end of the second adjusting block 71. The first photoelectric sensor 52 and the second photoelectric sensor 72 respectively detect the product 100 on the manual material placing station, and after the product exists, the product is automatically moved to the marking station, and the product after automatic marking is moved to the code scanning station. The first and second regulating blocks 51 and 71 may be regulated according to different products 100.

The code scanning assembly comprises a Z-shaped bracket 60 and a code scanning gun 61, wherein the code scanning gun 61 confirms whether the marked two-dimensional code is qualified or not and records the product number. A yard scanning gun 61 is attached to the top of the Z-shaped support 60. The two code scanning guns 61 respectively scan the two marked products automatically.

The mechanism is divided into three stations: a manual material placing station, an engraving station and a code scanning station which are separated by a partition plate 15. Firstly, manually putting a product 100 to a manual material placing station, and pressing a starting button with two hands; the divider 81 rotates, the unetched product 100 rotates to the engraving station, the engraving machine confirms the engraving position through program presetting, the product 100 is engraved, and meanwhile, an operator continues to put the unetched product 100 to the manual feeding station; after the marking station finishes marking, pressing a start button with two hands, rotating the product 100 of the manual material placing station to the marking station, rotating the original marking station to the code scanning station, continuously placing the material to the manual material placing station by an operator, simultaneously marking by the marking machine 20, and scanning, confirming and recording codes by the code scanning gun 61 through a preset program; after completion, the operator presses the start button with both hands, the divider 81 rotates, manually takes out the code-scanned finished product, puts into the finished product bin, puts into the non-imprinted product 100 again, and repeats the previous operations.

The above is only a specific application example of the present invention, and the protection scope of the present invention is not limited in any way. All the technical solutions formed by equivalent transformation or equivalent replacement fall within the protection scope of the present invention.

Claims (8)

1. The utility model provides an automatic seal of double-end and sweep a yard detection mechanism which characterized in that: the automatic stamping device comprises a bottom plate, wherein an engraving component and a convex flange are arranged at the top end of the bottom plate, a rotary plate is arranged at the top end of the flange, tools distributed in the circumferential direction are arranged at the top end of the rotary plate, an L-shaped partition plate is arranged between every two tools, the number of the partition plates is 3, a first detection component, the engraving component, two code sweeping components and a second detection component are arranged on the bottom plate around the flange in the anticlockwise direction, the second detection component and the engraving component are arranged on two sides of the flange oppositely, one end of each partition plate is provided with the second detection component, a divider is arranged at the bottom end of the rotary plate and connected to a driving motor, the driving motor drives the divider to rotate, and products are sequentially subjected to manual feeding, automatic engraving and automatic code sweeping detection.

2. The double-headed automatic imprint and code scanning detection mechanism of claim 1, wherein the imprint assembly comprises a translation assembly and an imprinter fixed on the translation assembly, the translation assembly comprises two rails arranged in parallel at the top end of the bottom plate, a first slider and a linear guide rail slider are slidably connected at the top end of the rails, the first slider and the linear guide rail slider are connected through an L-shaped block, and a fixed plate is arranged at the top end of the linear guide rail slider.

3. The automatic double-headed imprinting and code-scanning detecting mechanism according to claim 2, wherein the top end of the fixing plate is provided with an imprinting machine mounting plate and a block nut, the top end of the bottom plate is provided with a first supporting block and a second supporting block, the first supporting block, the second supporting block and the block nut are provided with a trapezoidal screw, and a hand wheel is provided at one end of the trapezoidal screw.

4. The dual-headed automatic imprint and code scanning detection mechanism of claim 1, wherein the first detection assembly includes a first support rod disposed at the top end of the bottom plate, the first support rod is provided with a first adjustment block, and a first photoelectric sensor is disposed at the bottom end of the first adjustment block.

5. The dual-headed automatic imprint and code scanning detection mechanism of claim 1, wherein the second detection assembly includes a second support rod disposed at the top end of the bottom plate, the second support rod is provided with a second adjustment block, and a second photoelectric sensor is disposed at the bottom end of the second adjustment block.

6. The dual-headed automated imprint and code scanning detection mechanism of claim 1 wherein the code scanning assembly includes a Z-shaped support and a code scanning gun coupled to a top end of the Z-shaped support.

7. The double-headed automatic imprint and code scanning detection mechanism of claim 1, wherein a plurality of through holes are formed in the bottom ends of the partition plates, the top ends of two adjacent partition plates are connected through a V-shaped block, and the through holes are connected with the turntable.

8. The dual-headed automatic imprint and code scanning detection mechanism of claim 1 wherein each of the four corners of the base plate has a connection hole.

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