Code spraying and scanning integrated device
By utilizing a tray and drive components in an integrated inkjet and scan device to achieve synchronous movement of the inkjet and scan structures, the problem of low verification efficiency after inkjet printing on workpieces is solved, and a highly efficient inkjet verification process is realized.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DONGGUAN DAZU BEIJIN EQUIPMENT CO LTD
- Filing Date
- 2025-08-19
- Publication Date
- 2026-07-07
AI Technical Summary
On industrial production lines, the efficiency of verifying codes after inkjet printing on workpieces is low, requiring the transfer of products for verification, which leads to low work efficiency.
Design an integrated inkjet and scan device. By setting a tray and a drive component on the base, the inkjet and scan structures are driven to move along a first direction to achieve synchronous inkjet and scan. The inkjet structure is adjacent to the scan structure and located behind the inkjet structure, so that the workpiece is simultaneously inkjet and scanned.
It improves the processing efficiency of workpiece inkjet printing verification, making inkjet printing and scanning a continuous synchronous process, thus improving work efficiency.
Smart Images

Figure CN224465508U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of spraying technology, and in particular to an integrated inkjet and barcode scanning device. Background Technology
[0002] On industrial production lines, to facilitate product traceability, anti-counterfeiting, and logistics management, the surface of workpieces is usually coated with inkjet printing equipment to print variable information such as QR codes, characters, or graphics. Subsequently, to ensure the quality of the printing and the accuracy of the data, the printing results need to be verified after the coating process is completed.
[0003] When verifying product codes, the product usually needs to be transferred to the verification equipment. Whether it is continuously flowing along the conveyor line or handled by humans or robots, the work efficiency is low. Utility Model Content
[0004] The main purpose of this invention is to propose an integrated inkjet and scanning device to solve the technical problem of low efficiency in workpiece inkjet coding verification.
[0005] To achieve the above objectives, the present invention proposes an integrated inkjet and barcode scanning device, comprising:
[0006] Base;
[0007] A tray is disposed on the base, the tray has multiple buffer positions for positioning workpieces, and the multiple buffer positions are spaced apart along a first direction;
[0008] A coding and scanning assembly includes a mounting base and a coding structure and a scanning structure disposed on the mounting base. The mounting base is disposed on a base. The coding structure is used to code the workpiece on the buffer position, and the scanning assembly is used to scan and verify the coded workpiece on the buffer position.
[0009] A first driving component is disposed on the base and is drivenly connected to the mounting base. The first driving component drives the inkjet printing structure and the scanning structure to move along the first direction so as to sequentially inkjet print and scan the multiple workpieces.
[0010] In one embodiment, the inkjet scanning assembly further includes a support base and a drive structure. The inkjet coding structure is disposed on the support base, and the drive structure is disposed on the mounting base. The drive structure is driven to be connected to the support base. The drive structure drives the support base to move along a second direction, so that the inkjet coding structure on the support base moves closer to or further away from the workpiece.
[0011] In one embodiment, multiple inkjet printing structures and multiple scanning structures are provided, with the multiple inkjet printing structures spaced apart on the support base along the first direction, and the multiple scanning structures spaced apart on the mounting base along the first direction, and each inkjet printing structure corresponds to one scanning structure.
[0012] In one embodiment, the scanning structure includes:
[0013] A first support frame is disposed on the mounting base;
[0014] The barcode scanner is rotatably mounted on the first support frame to adjust its angle.
[0015] In one embodiment, the integrated inkjet and scan device further includes a positioning component, with each buffer bit corresponding to a positioning component. The positioning component is used to position the two ends of the workpiece along the second direction to restrict the movement of the workpiece.
[0016] In one embodiment, the integrated inkjet and barcode scanning device further includes a bracket extending along the first direction, and the positioning component includes:
[0017] An elastic element is disposed on one side of the tray, the elastic element facing the buffer position;
[0018] An abutment plate is disposed on the bracket, and the abutment plate is opposite to the elastic member, and is used to abut the two ends of the workpiece respectively.
[0019] In one embodiment, a tray extending in a first direction is provided on the side of the tray away from the bracket, the elastic element is provided on the tray, and the tray slides on the tray in a second direction.
[0020] In one embodiment, the integrated inkjet and barcode scanning device further includes a second drive component, which is disposed on the bracket and is connected to the tray drive. The second drive component drives the tray to move along the second direction so that the tray moves closer to or away from the abutment plate.
[0021] In one embodiment, a stop is provided at the end of the tray, and buffers are provided at both ends of the stop. The buffers are located on the base so as to abut against the stop when the tray moves in the second direction.
[0022] In one embodiment, the integrated inkjet and scan device further includes a sensing component, and each positioning component is provided with a corresponding sensing component, which is used to detect whether the buffer position has the workpiece.
[0023] In this invention, a tray for supporting workpieces is provided on a base, and multiple workpieces are placed on the tray at intervals along a first direction. A first driving component is provided on the base, which drives a mounting base to move along the first direction, thereby driving the inkjet printing structure and the scanning structure on the mounting base to move along the first direction. This allows the inkjet printing structure to sequentially print on the workpieces spaced apart along the first direction on the tray. After printing, the scanning structure then sequentially scans and verifies the workpieces. It is important to note that the scanning structure is adjacent to the inkjet printing structure and located behind the inkjet printing structure. This ensures that when the inkjet printing structure prints on one workpiece and moves to the next, the scanning structure has just moved to the workpiece that was previously printed and is verifying it. In other words, printing and scanning are a synchronous and continuous process, which improves the processing efficiency of workpiece printing verification. Attached Figure Description
[0024] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on the structures shown in these drawings without creative effort.
[0025] Figure 1 A schematic diagram of the integrated inkjet and barcode scanning device provided by this utility model;
[0026] Figure 2 A top view of the integrated inkjet and barcode scanning device provided by this utility model;
[0027] Figure 3 A front view schematic diagram of the integrated inkjet and barcode scanning device provided by this utility model;
[0028] Figure 4 A side view of the integrated inkjet and barcode scanning device provided by this utility model;
[0029] Figure 5 A schematic diagram of the scanning structure in the integrated inkjet and scan device provided by this utility model;
[0030] Figure 6 A schematic diagram of the tray structure in the integrated inkjet and barcode scanning device provided by this utility model;
[0031] Figure 7 for Figure 6 A magnified view of a section at point A in the middle;
[0032] Figure 8 for Figure 6 A magnified view of a section at point B in the middle.
[0033] Explanation of icon numbers:
[0034] 10. Workpiece;
[0035] 100. Base; 110. Buffer;
[0036] 200, Tray; 210, Buffer Slot; 220, Stop; 230, Scale Marker;
[0037] 300. Inkjet and barcode scanning assembly; 310. Mounting base; 320. Inkjet structure; 330. Barcode scanning structure; 331. First support frame; 332. Barcode scanner; 333. Adapter plate; 334. Arc groove; 340. Support base; 341. Sliding hole; 350. Drive structure;
[0038] 400. First drive component;
[0039] 510. Elastic component; 520. Abutment plate;
[0040] 600. Bracket; 610. Pallet;
[0041] 700, Second drive component;
[0042] 800, Sensing component; 810, Transmitter; 820, Receiver.
[0043] The realization of the purpose, functional features and advantages of this utility model will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation
[0044] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the scope of protection of the present utility model.
[0045] It should be noted that if the embodiments of this utility model involve directional indicators (such as up, down, left, right, front, back, etc.), the directional indicators are only used to explain the relative positional relationship and movement of the components in a specific posture. If the specific posture changes, the directional indicators will also change accordingly.
[0046] Furthermore, if the embodiments of this utility model involve descriptions such as "first" or "second," these descriptions are for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined with "first" or "second" may explicitly or implicitly include at least one of those features. Additionally, the use of "and / or" or "and / or" throughout the text includes three parallel solutions. For example, "A and / or B" includes solution A, solution B, or a solution where both A and B are satisfied simultaneously. Furthermore, the technical solutions of the various embodiments can be combined with each other, but this must be based on the ability of those skilled in the art to implement them. When the combination of technical solutions is contradictory or impossible to implement, it should be considered that such a combination of technical solutions does not exist and is not within the scope of protection claimed by this utility model.
[0047] On industrial production lines, to facilitate product traceability, anti-counterfeiting, and logistics management, the surface of workpieces is usually coated with inkjet printing equipment to print variable information such as QR codes, characters, or graphics. Subsequently, to ensure the quality of the printing and the accuracy of the data, the printing results need to be verified after the coating process is completed.
[0048] When verifying product codes, the product usually needs to be transferred to the verification equipment. Whether it is continuously flowing along the conveyor line or handled by humans or robots, the work efficiency is low.
[0049] This utility model proposes an integrated inkjet and barcode scanning device.
[0050] Please see Figure 1 and Figure 4 In one embodiment of the present invention, the integrated inkjet and barcode scanning device includes a base 100, a tray 200, an inkjet and barcode scanning assembly 300, and a first drive assembly 400.
[0051] The tray 200 is disposed on the base 100. The tray 200 has multiple buffer positions 210, which are used to position the workpiece 10. The multiple buffer positions 210 are spaced apart along the first direction.
[0052] The inkjet-scanning component 300 includes a mounting base 310 and an inkjet-printing structure 320 and a scanning structure 330 disposed on the mounting base 310. The mounting base 310 is disposed on a base 100. The inkjet-printing structure 320 is used to print ink onto the workpiece 10 on the buffer position 210. The scanning component is used to scan and verify the printed workpiece 10 on the buffer position 210.
[0053] The first drive assembly 400 is disposed on the base 100 and is drivenly connected to the mounting base 310. The first drive assembly 400 drives the inkjet printing structure 320 and the scanning structure 330 to move along the first direction so as to sequentially inkjet print and scan multiple workpieces 10.
[0054] In the technical solution of this utility model, a tray 200 for supporting workpieces 10 is provided on the base 100. Multiple workpieces 10 are placed on the tray 200, and the multiple workpieces 10 are spaced apart along a first direction on the tray 200. By providing a first driving component 400 on the base 100, the first driving component 400 drives the mounting base 310 to move along the first direction, thereby driving the inkjet printing structure 320 and the scanning structure 330 on the mounting base 310 to move along the first direction, so that the inkjet printing structure 320 sequentially scans the workpieces 10 on the tray 200 spaced apart along the first direction. The workpiece 10 is marked with inkjet printing. After marking, the scanning structure 330 scans the workpiece 10 sequentially for verification. It should be noted that the scanning structure 330 is adjacent to the marking structure 320 and is located behind the marking structure 320. This is so that when the marking structure 320 marks one workpiece 10 and moves to the next workpiece 10, the scanning structure 330 will have just moved to the workpiece 10 that has been marked and is verifying it. In other words, marking and scanning are a synchronous and continuous process, which improves the processing efficiency of marking and verifying the workpiece 10.
[0055] Specifically, the base 100 is a mounting base, and its shape and material are not limited, such as Figure 1 and Figure 6As shown, a tray 200 is provided on the base 100, extending along a first direction. Multiple limiting grooves, one lower in the middle and one higher on both sides, are provided on the tray 200 and spaced apart along the length of the tray 200. These limiting grooves are configured as buffer positions 210, with the sides of the buffer position 210 higher than the bottom center, allowing for stable placement of the workpiece 10. In this embodiment, the workpiece 10 is a battery, but not limited to batteries. Specifically, the workpiece 10 can be placed into the buffer position 210 manually one by one, or it can be placed into the buffer position 210 by a robotic arm; no limitation is made here. In one embodiment, the first driving component 400 can be a drive motor and a conveyor belt, etc. The mounting base 310 is connected to the conveyor belt. The drive motor drives the conveyor belt to rotate, thereby driving the mounting base 310 to move along the first direction, which in turn drives the inkjet printing structure 320 and the scanning structure 330 on the mounting base 310 to move along the first direction. The first driving component 400 can also be a linear drive component such as a lead screw and nut pair to drive the mounting base 310 to move along the first direction; no limitation is made here. In one embodiment, a coding structure 320 is provided on the mounting base 310. The coding structure 320 is communicatively connected to the control system. Through the positioning of the control system, the coding structure 320 is driven to move to the position of the workpiece 10, receives barcode instructions, and performs QR code printing on the workpiece 10. The coding structure 320 can print different barcodes each time it prints, or it can print the same barcode multiple times. Figure 3 As shown, after the inkjet printing structure 320 finishes printing, as the mounting base 310 moves to the next workpiece 10, the scanning structure 330 reaches the corresponding previous workpiece 10 and automatically collects and reads the printed QR code to determine whether the printed QR code can be effectively recognized. At the same time, it determines that the read information is consistent with the inkjet printing information. The first driving component 400 drives the mounting base 310 to move along the first direction, so that the inkjet printing structure 320 can sequentially print codes on the workpieces 10 in the first direction, and the rear scanning structure 330 can sequentially scan and verify the printed workpieces 10, that is, the inkjet printing and code verification are carried out simultaneously.
[0056] In one embodiment, the coding structure 320 includes a coding gun and a feed tube. The coding gun is mounted on a mounting base 310 and moves along a first direction with the mounting base 310. The feed tube is connected to the coding gun and is used to supply ink to the coding gun so that the coding gun can print the trajectory on the workpiece 10. A spring sleeve is provided on the base 100 to cover the feed tube. The spring sleeve also protects a recovery tube to draw back undeflected waste ink to the main ink path. The spring sleeve wraps the feed tube and the recovery tube together, which can absorb tension and torsion and prevent the feed tube from frequently swinging and becoming stuck when the mounting base 310 moves the coding gun along the first direction, thus preventing it from feeding ink.
[0057] Please refer to Figure 2 and Figure 3In an embodiment of this utility model, the inkjet scanning assembly 300 further includes a support base 340 and a drive structure 350. The inkjet coding structure 320 is disposed on the support base 340, and the drive structure 350 is disposed on the mounting base 310. The drive structure 350 is driven to connect with the support base 340. The drive structure 350 drives the support base 340 to move along the second direction, so that the inkjet coding structure 320 on the support base 340 moves closer to or further away from the workpiece 10.
[0058] Specifically, a support base 340 is provided above the mounting base 310, and the support base 340 is arranged parallel to the mounting base 310. A drive structure 350 is provided between the mounting base 310 and the support base 340. The drive structure 350 drives the support base 340 to move along the second direction on the mounting base 310, thereby driving the inkjet printing structure 320 on the mounting base 310 to move along the second direction. The second direction is perpendicular to the first direction. With the cooperation of the drive structure 350 and the first drive assembly 400, the inkjet printing structure 320 can move along the first direction and the second direction. When it is necessary to print inkjet print on the workpiece 10, the inkjet printing structure 320 moves along the second direction to get closer to the workpiece 10 on the tray 200. After the first workpiece 10 is printed, it moves along the first direction under the drive of the first drive assembly 400, and prints inkjet print on each workpiece 10 in sequence. After the printing is completed, the drive structure 350 drives the support base 340 to move along the second direction away from the tray 200, so as to move away from the workpiece 10, making the printing process accurate and efficient.
[0059] In one embodiment, the drive structure 350 may be a linear drive component such as a lead screw module, a cylinder, a hydraulic cylinder, or an electric telescopic rod, and there are no restrictions on this.
[0060] Please refer to Figure 2 In the embodiments of this utility model, multiple inkjet printing structures 320 and scanning structures 330 are provided, and multiple inkjet printing structures 320 are spaced apart on the support base 340 along the first direction, and multiple scanning structures 330 are spaced apart on the mounting base 310 along the first direction, and the inkjet printing structure 320 and the scanning structure 330 correspond one-to-one.
[0061] Specifically, multiple scanning structures 330 are spaced apart along the first direction on the mounting base 310, and multiple inkjet printing structures 320 are spaced apart along the first direction on the support base 340. The scanning structures 330 are set on the mounting base 310, and each inkjet printing structure 320 is set adjacent to the corresponding scanning structure 330, with the distance between two workpieces 10. This allows the scanning structure 330 to scan and verify the previously printed workpiece 10 when the inkjet printing structure 320 prints the next workpiece 10, so that printing and scanning are performed synchronously. Furthermore, setting multiple inkjet printing structures 320 allows multiple workpieces 10 to be printed simultaneously, improving efficiency.
[0062] It is important to note that, such as Figure 2 As shown, in order to prevent the setting of the barcode scanning structure 330 from affecting the movement of the support base 340 in the second direction, a sliding hole 341 extending in the second direction is provided through the support base 340. Multiple sliding holes 341 are provided and spaced apart in the first direction. Each sliding corresponds to a barcode scanning structure 330. One end of the barcode scanning structure 330 is mounted on the mounting base 310, and the other end passes through the sliding hole 341 above the support base 340 to scan and verify the workpiece 10. When the driving structure 350 drives the support base 340 to slide in the second direction, the sliding hole 341 moves along the barcode scanning structure 330, which can avoid being blocked by the barcode scanning structure 330, so that the inkjet printing structure 320 can move in both the first direction and the second direction.
[0063] Please refer to Figure 5 In an embodiment of this utility model, the scanning structure 330 includes:
[0064] The first support frame 331 is mounted on the mounting base 310;
[0065] The barcode scanner 332 is rotatably mounted on the first support frame 331 to adjust the angle of the barcode scanner 332.
[0066] Specifically, the barcode scanning structure 330 includes a first support frame 331, which includes a vertical rod and a horizontal rod. The vertical rod is vertically mounted on the mounting base 310, and the horizontal rod is mounted on the vertical rod and perpendicular to it. The horizontal rod is fixed to the vertical rod by screws and fixing blocks, and its relative position on the vertical rod can be adjusted to adjust the height of the barcode scanning structure 330 for better scanning. A barcode scanner 332 is connected to one end of the horizontal rod. Figure 3 As shown, the barcode scanner 332 is mounted on the end of the crossbar via an adapter plate 333. The adapter plate 333 includes a first plate and a second plate arranged vertically. The barcode scanner 332 is mounted on the first plate. The second plate has an arc-shaped groove 334. Fasteners such as screws pass through the arc-shaped groove 334 and are connected to the crossbar to fix the barcode scanning structure 330. When it is necessary to scan the workpiece 10, the screws are loosened according to the position between the barcode scanning structure 330 and the workpiece 10. The relative position of the second plate is adjusted to adjust the relative distance and angle between the barcode scanner 332 and the workpiece 10 so that the barcode scanner 332 can perform barcode scanning verification more accurately.
[0067] Please refer to Figure 6 In an embodiment of this utility model, the integrated inkjet and scan device further includes a positioning component. Each buffer bit 210 is provided with a corresponding positioning component. The positioning component is used to position the two ends of the workpiece 10 along the second direction to restrict the movement of the workpiece 10.
[0068] Specifically, the positioning component positions the workpiece 10 at the buffer position 210, enabling the workpiece 10 to complete the two processes of inkjet printing and barcode scanning verification while stationary, thereby improving the accuracy of inkjet printing and the efficiency of barcode scanning verification. This eliminates the need for repeated debugging and saves time.
[0069] In one embodiment, the integrated inkjet and barcode scanning device further includes a bracket 600 extending along a first direction, and the positioning components include:
[0070] The elastic element 510 is located on one side of the tray 200, and the elastic element 510 faces the buffer position 210;
[0071] Abutment plate 520 is provided on bracket 600, and abutment plate 520 is opposite to elastic member 510, and is used to abut the two ends of workpiece 10 respectively.
[0072] Specifically, such as Figure 6 As shown, the bracket 600 is opposite to the tray 200. On the side of the tray 200 away from the bracket 600, a plurality of elastic elements 510 are spaced apart along the first direction. On the bracket 600, a plurality of abutment plates 520 are spaced apart along the first direction. The elastic elements 510 and the abutment plates 520 abut against the two ends of the workpiece 10 respectively. On the one hand, this can reduce the movement of the workpiece 10. On the other hand, the setting of the elastic elements 510 provides a certain buffer space, which can avoid damage to the workpiece 10 caused by forcibly pressing it. Furthermore, the existence of the buffer space can also accommodate workpieces 10 of different lengths, making it highly adaptable.
[0073] In one embodiment, such as Figure 8 As shown, the workpiece 10 is a battery, with a protruding terminal at one end. To avoid damaging the terminal, multiple abutment plates 520 are spaced apart on the bracket 600. A portion of two adjacent abutment plates 520 abuts against both sides of the terminal at the end of one workpiece 10, while the other portion abuts against one side of the terminal of another workpiece 10. The spacing between two adjacent abutment plates 520 precisely avoids the terminal, thus preventing damage to the terminal and ensuring stable contact with the workpiece 10, preventing the workpiece 10 from moving.
[0074] Please refer to Figure 6 and Figure 7 In an embodiment of this utility model, a tray 610 extending in a first direction is provided on the side of the tray 200 away from the bracket 600, an elastic member 510 is provided on the tray 610, and the tray 610 slides on the tray 200 in a second direction.
[0075] Specifically, the pallet 610 is opposite to the bracket 600 and slides on the tray 200, causing the pallet 610 to move closer to or away from the bracket 600. This causes the elastic element 510 on the pallet 610 to move closer to or away from the abutment plate 520 on the bracket 600, thereby adjusting the space between the elastic element 510 and the abutment plate 520 to expand the range of applicable workpiece 10 sizes. In addition, the elastic element 510 is arranged on the pallet 610 and is positioned in the same direction in the second direction to ensure the consistency of the distance between the elastic element 510 and the abutment plate 520.
[0076] In one embodiment, such as Figure 7 As shown, the two ends of the tray 610 are respectively provided with elongated holes extending in the second direction. Screws are provided to pass through the elongated holes and screwed to the tray 200 at the bottom of the tray 610 to fix the tray 610 and the tray 200. Loosen the screws and move the tray 610 in the second direction. The elongated holes move along the screws. After reaching the appropriate position, tighten the screws to lock them.
[0077] In one embodiment, as shown in the figure, scale marks 230 are provided at both ends of the tray 200 along its length direction for precise positioning when the tray 610 moves along the second direction.
[0078] Please refer to Figure 7 In an embodiment of this utility model, the integrated inkjet and barcode scanning device further includes a second drive component 700. The second drive component 700 is disposed on the bracket 600 and is drivenly connected to the tray 200. The second drive component 700 drives the tray 200 to move along a second direction so that the tray 200 moves closer to or further away from the abutment plate 520.
[0079] like Figure 6 As shown, the second drive assembly 700 can adopt a structure such as a cylinder or an electric telescopic cylinder. The fixed end of the second drive assembly 700 is fixed on the bracket 600, and the output end is connected to the tray 200. By extending and retracting the output end of the second drive assembly 700, the tray 200 moves away from or closer to the bracket 600, adjusting the distance between the elastic element 510 and the abutment plate 520. When the workpiece 10 needs to be placed, the output end of the second drive assembly 700 extends, causing the tray 200 to move away from the bracket 600 to avoid the buffer position 210. The workpiece 10 is placed on the buffer position 210, and the output end of the second drive assembly 700 retracts, causing the tray 200 to move closer to the bracket 600 until the abutment plate 520 contacts the workpiece 10, limiting the continuous movement of the tray 200 to prevent damage to the workpiece 10.
[0080] In one embodiment, a guide rail extending in a second direction is provided on the base 100, and a slider is provided at the bottom of the tray 200. The slider slides along the guide rail to improve the stability of the sliding.
[0081] Please refer to Figure 6 In an embodiment of this utility model, a stop block 220 is provided at the end of the tray 200, and a buffer 110 is provided at both ends of the stop block 220. The buffer 110 is provided on the base 100 so as to abut against the stop block 220 when the tray 200 moves in the second direction.
[0082] As shown in Figure 6, a stop 220 is provided at one end of the tray 200. In one embodiment, both ends of the tray 200 may be provided with stop 220. This is not a limitation. The description will focus on one end. A buffer 110 is provided on the base 100. When the second drive assembly 700 drives the tray 200 to move in the second direction, the buffers 110 on both sides limit the movement to prevent the tray 200 from moving excessively and damaging the workpiece 10 or detaching from the base 100.
[0083] Please refer to Figure 6 , Figure 7 and Figure 8 In an embodiment of this utility model, the integrated inkjet and scan device further includes a sensing component 800. Each positioning component is provided with a corresponding sensing component 800. The sensing component 800 is used to detect whether the buffer position 210 has a workpiece 10.
[0084] Specifically, the sensing component 800 includes a transmitter 810 and a receiver 820. In one embodiment, the transmitter 810 is disposed on the tray 610, and the receiver 820 is disposed on the bracket 600. The transmitter 810 and the receiver 820 are respectively disposed at both ends of the buffer position 210. Each set of transmitters 810 and receivers 820 corresponds to one buffer position 210. The transmitter 810 emits infrared light or laser towards the buffer position 210. The receiver 820 monitors the light intensity in real time on the other side of the buffer position 210. If there is a workpiece 10 in the buffer position 210, the light beam emitted by the transmitter 810 is blocked by the workpiece 10, and the receiver 820 cannot receive the light beam signal. This indicates that the buffer position 210 contains a workpiece 10. If the receiver 820 receives the light beam signal, it indicates that there is no workpiece 10 in the buffer position 210. It is necessary to remind the staff to put the workpiece 10 in in time. After detecting the workpiece 10, the workpiece 10 is then marked to avoid the workpiece 10 being missed. In another embodiment, the transmitter 810 may also be disposed on the bracket 600 and the receiver 820 may be disposed on the tray 610, without limitation.
[0085] The above description is merely an exemplary embodiment of the present utility model and does not limit the scope of protection of the present utility model. Any equivalent structural transformations made based on the technical concept of the present utility model and the contents of the present utility model specification and drawings, or direct / indirect applications in other related technical fields, are included within the scope of protection of the present utility model.
Claims
1. A coding and scanning integrated device, characterized in that, include: Base; A tray is disposed on the base, the tray has multiple buffer positions for positioning workpieces, and the multiple buffer positions are spaced apart along a first direction; The inkjet and barcode scanning assembly includes a mounting base and an inkjet and barcode scanning structure disposed on the mounting base. The mounting base is disposed on the base. The inkjet and barcode scanning structure is used to inkjet and barcode the workpiece on the buffer position. The barcode scanning assembly is used to scan and verify the inkjet and barcode scanning of the workpiece on the buffer position. as well as A first driving component is disposed on the base and is drivenly connected to the mounting base. The first driving component drives the inkjet printing structure and the scanning structure to move along the first direction so as to sequentially inkjet print and scan the multiple workpieces.
2. The integrated inkjet and barcode scanning device as described in claim 1, characterized in that, The inkjet coding assembly further includes a support base and a drive structure. The inkjet coding structure is disposed on the support base, and the drive structure is disposed on the mounting base. The drive structure is driven to be connected to the support base. The drive structure drives the support base to move along a second direction, so that the inkjet coding structure on the support base moves closer to or further away from the workpiece.
3. The integrated inkjet and barcode scanning device as described in claim 2, characterized in that, Multiple inkjet printing structures and multiple scanning structures are provided, with the multiple inkjet printing structures spaced apart on the support base along the first direction, and the multiple scanning structures spaced apart on the mounting base along the first direction, and each inkjet printing structure corresponds to one scanning structure.
4. The integrated inkjet and barcode scanning device as described in any one of claims 1-3, characterized in that, The scanning structure includes: A first support frame is disposed on the mounting base; The barcode scanner is rotatably mounted on the first support frame to adjust its angle.
5. The integrated inkjet and barcode scanning device as described in claim 2, characterized in that, The integrated inkjet and scan device also includes a positioning component. Each of the buffer positions is provided with a corresponding positioning component. The positioning component is used to position the two ends of the workpiece along the second direction to restrict the movement of the workpiece.
6. The integrated inkjet and barcode scanning device as described in claim 5, characterized in that, The integrated inkjet and barcode scanning device further includes a bracket that extends along the first direction, and the positioning component includes: An elastic element is disposed on one side of the tray, the elastic element facing the buffer position; An abutment plate is disposed on the bracket, and the abutment plate is opposite to the elastic member, and is used to abut the two ends of the workpiece respectively.
7. The integrated inkjet and barcode scanning device as described in claim 6, characterized in that, A tray extending in a first direction is provided on the side of the tray away from the bracket, the elastic element is provided on the tray, and the tray slides on the tray in a second direction.
8. The integrated inkjet and barcode scanning device as described in claim 7, characterized in that, The integrated inkjet and scan device further includes a second drive component, which is disposed on the bracket and connected to the tray drive. The second drive component drives the tray to move along the second direction so that the tray moves closer to or away from the abutment plate.
9. The integrated inkjet and barcode scanning device as described in claim 5, characterized in that, The tray is provided with a stop at one end, and a buffer is provided at both ends of the stop. The buffer is located on the base so as to abut against the stop when the tray moves in the second direction.
10. The integrated inkjet and barcode scanning device as described in claim 5, characterized in that, The integrated inkjet and scan device also includes a sensing component. Each positioning component is provided with a corresponding sensing component, which is used to detect whether the workpiece is present in the buffer position.