CN222569633U - Efficient laser processing platform - Google Patents

Abstract

The utility model discloses an efficient laser processing platform, comprising a frame and a transmission assembly arranged on the frame, the frame comprising a mounting frame and a supporting frame connected in cooperation, the transmission assembly comprising a transmission wheel and a transmission belt arranged on the mounting frame, a first workbench is arranged on the mounting frame, a second workbench is arranged between the two mounting frames, the first workbench is connected to the transmission belt through a first connecting block, the second workbench is connected to the transmission belt through a second connecting block, the first connecting block and the second connecting block are arranged at the upper and lower ends of the transmission belt and are staggered, the first connecting block and the second connecting block are arranged at the upper and lower ends of the transmission belt and are staggered, this layout ensures that the transmission belt can simultaneously drive the two workbenches to move when rotating without interfering with each other, when the first workbench is at the working position, the second workbench is located at the other end of the frame, when the first workbench completes the work, the positions of the first workbench and the second workbench are interchanged, thereby improving the work efficiency.

Description

Efficient laser processing platform

Technical Field

The utility model relates to the technical field of processing platforms, in particular to a high-efficiency laser processing platform.

Background

The laser has good space control and time control, has great freedom on the material, shape, size and processing environment of a processing object, is particularly suitable for automatic processing, can form high-efficiency automatic processing equipment by combining a laser processing system with a computer numerical control technology, becomes a key technology for enterprises to carry out timely production, opens up a wide prospect for high-quality, high-efficiency and low-cost processing and production, can apply the laser technology to the clothing cutting field in the prior art, and a processing platform in the prior art is generally singly provided, and because the clothing is processed, raw materials are required to be placed on a processing table and then are processed through laser, the time in a laser processing diagram is wasted after the product is taken down, and the efficiency is poor.

Disclosure of utility model

The utility model provides a high-efficiency laser processing platform, which solves the problems of poor operation efficiency and low precision of the processing platform in the prior art.

In order to solve the technical problems, the utility model adopts the following technical scheme:

a high efficiency laser processing platform, comprising

The frame comprises a mounting frame and a supporting frame, and the supporting frame is arranged between the two mounting frames;

The transmission assembly comprises a transmission wheel arranged on the mounting frame and a transmission belt matched with the transmission wheel;

The device is characterized in that a first workbench is arranged on each mounting frame, a second workbench is arranged between the two mounting frames, the first workbench is connected with the transmission belt through a first connecting block, the second workbench is connected with the transmission belt through a second connecting block, the first connecting block and the second connecting block are arranged at the upper end and the lower end of the transmission belt and are arranged in a staggered mode, the driving belt can drive the two workbench to move at the same time when rotating, mutual interference is avoided, when the first workbench is located at a working position, the second workbench is located at the other end of the frame, and after the first workbench finishes working, the positions of the first workbench and the second workbench are interchanged, so that working efficiency is improved.

Further, be equipped with first slide rail on the mounting bracket, install first slider on the slide rail, first linkage piece is connected to first slider, and first slider moves on the slide rail, has guaranteed the stability of first workstation at the removal in-process, has reduced rocking and deviation, and slide rail and slider cooperation can control the travel distance and the position of first workstation accurately, and this is crucial to the laser application that needs high accuracy processing.

Further, the inboard of mounting bracket is equipped with the second slide rail, installs the second slider on the second slide rail, and the second connecting block is connected to the second slider, improves the stationarity of second workstation in the motion, reduces and rocks and deviation, and the cooperation of slide rail and slider makes the second workstation more smooth and easy when removing.

Further, be equipped with the third slide rail on the mounting bracket, be connected through the gyro wheel between slide rail and the mounting bracket, be equipped with the third slider on the third slide rail, be equipped with the cooperation wheel on the third slider, the cooperation wheel is equipped with the gyro wheel cooperation and is realized that the third slider removes along the third slide rail, cooperation wheel and gyro wheel on the third slider closely cooperate, provide accurate direction and location for the slider, stability and accuracy of slider in the removal in-process have been ensured in this kind of cooperation, the demand of high accuracy processing has been satisfied, the cooperation of gyro wheel and cooperation wheel can also reduce the friction of cooperation transmission, the transmission of convenient third slider.

Further, the cooperation wheel includes first cooperation wheel and second cooperation wheel, first cooperation wheel setting is in the top of gyro wheel, the second cooperation wheel setting is in the below of gyro wheel, first cooperation wheel presss from both sides tightly from both sides from top to bottom with the second cooperation wheel pair gyro wheel, prevent that the third slider from coming off, when the third slider moves on the third slide rail, this first cooperation wheel and second cooperation wheel can closely laminate on the gyro wheel, form a stable clamping structure, this kind of structure not only can ensure the stability of slider in the removal process, can also prevent effectively that the slider from coming off because of vibration or other external factors, simultaneously, because the tight fit between cooperation gyro wheel and the gyro wheel, the moving track of slider is more accurate controllable, thereby ensured the high accuracy of course of working.

Further, the third slide rail includes ascending section and descending section, the descending section is located the below of ascending section, be connected through the changeover portion between ascending section and the descending section, the third slider moves along the third slide rail and realizes the oscilaltion of second workstation, guide section when ascending section when guiding the ascending movement of third slider, the descending section is the guide section when the third slider descends, the changeover portion is the guide section that the third slider descends from ascending to descending or descends to change to ascending, when the third slider moves along the third slide rail, it drives the second workstation that is connected with it and moves about the oscilaltion of realization second workstation together.

Further, the connecting rod is rotationally connected to the second sliding block, the other end of the connecting rod is connected with the second working table, the connecting rod is rotationally connected to the third sliding block, when the second working table is in ascending or descending state, the rotation angle of the connecting rod is adjusted through the rotation of the connecting rod, the connection enables the movement of the connecting rod to be limited or influenced by the position of the third sliding block, therefore, more complex movement control is achieved, the up-and-down movement of the second working table is achieved, and dead points of the mechanism are prevented.

Further, the driving wheels which are close to the power assembly on the two mounting frames are connected through the fixing rods, one ends of the fixing rods are connected with the synchronous wheels, the synchronous wheels are connected with the motor through the synchronous belt, synchronous transmission of the driving belts on the mounting frames on the two sides is achieved, when the motor rotates, the motor drives the synchronous wheels to transmit through the synchronous belt, and the synchronous wheels drive the driving belts on the mounting frames on the two sides to rotate through the fixing rods, so that movement of the first workbench and the second workbench is achieved.

Further, be equipped with limit switch on keeping away from drive assembly's the support frame, limit switch is used for responding to the position of first workstation and second workstation, when the workstation reached the assigned position, trigger switch in order to stop the back change the direction of motion of workstation again, prevent that the workstation from surpassing safety margin, avoid bumping with other equipment or structures.

Further, one side of the frame is provided with a controller, the controller can receive limit switch signals and control the start and stop of the transmission assembly, the controller can accurately control the start and stop of the transmission assembly according to the limit switch signals, the workbench is ensured to operate at the correct time and position, and the controller can be programmed and configured according to different working requirements so as to adapt to different production scenes and operation requirements.

Due to the adoption of the technical scheme, the utility model has the following beneficial effects:

The utility model relates to a high-efficiency laser processing platform, a first workbench is arranged on a mounting frame, a second workbench is arranged between two mounting frames, the first workbench is connected with a transmission belt through a first connecting block, the second workbench is connected with the transmission belt through a second connecting block, the first connecting block and the second connecting block are arranged at the upper end and the lower end of the transmission belt and are arranged in a staggered mode, the arrangement ensures that the transmission belt can drive the two workbench to move at the same time when rotating, mutual interference is avoided, the second workbench is arranged at the other end of the frame when the first workbench is positioned at a working position, and after the first workbench finishes working, the positions of the first workbench and the second workbench are exchanged, so that the working efficiency is improved.

Drawings

The utility model is further described below with reference to the accompanying drawings:

FIG. 1 is a schematic diagram of a high efficiency laser processing platform according to the present utility model;

FIG. 2 is a top view of FIG. 1;

FIG. 3 is a cross-sectional view taken along the direction B-B in FIG. 2;

FIG. 4 is a schematic view of a third slider assembly according to the present utility model;

FIG. 5 is an enlarged view of a portion of FIG. 1 at A;

fig. 6 is a schematic structural view of a part of the components in the present utility model.

In the drawing the view of the figure,

10-Frame, 11-mounting frame, 12-supporting frame, 13-first workbench, 14-second workbench, 15-transmission component, 16-first connecting block, 17-first sliding block, 18-limit switch, 19-first sliding rail, 20-third sliding block, 21-third sliding rail, 22-second matching wheel, 23-first matching wheel, 24-roller, 25-connecting rod, 26-fixed rod, 27-fixed block, 28-mounting plate, 29-motor, 30-synchronous wheel, 31-synchronous belt, 32-driving wheel, 33-driving belt, 34-second sliding rail, 35-rotating pair, 36-second connecting block, 37-transition section, 38-descending section, 39-ascending section and 40-second sliding block.

Detailed Description

It should be noted that, without conflict, the embodiments of the present utility model and features of the embodiments may be combined with each other. The utility model will be described in detail below with reference to the drawings in connection with embodiments.

In order that those skilled in the art will better understand the present utility model, a technical solution in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in which it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, shall fall within the scope of the utility model.

It should be noted that the terms "first," "second," and the like in the description and the claims of the present utility model and the above figures are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. Furthermore, the terms "comprise" and "have," as well as any variations thereof, are intended to cover a non-exclusive inclusion.

As shown in fig. 1 to 6, the efficient laser processing platform of the present utility model mainly has the function that a first workbench 13 and a second workbench 14 are installed on a mounting frame 11, the first workbench 13 is connected with a driving belt 33 through a first connecting block 16, the second workbench 14 is connected with the driving belt 33 through a second connecting block 36, and the driving belt 33 can simultaneously drive the two workbench to move relatively when rotating, so that the working efficiency is improved.

The utility model relates to a high-efficiency laser processing platform, which comprises a frame 10, a first workbench 13 and a second workbench 14, wherein the frame 10 comprises two mounting frames 11 and supporting frames 12, the two mounting frames 11 are provided with a plurality of supporting frames 12, the specific number of the supporting frames 12 is set according to actual conditions, the supporting strength of the frame 10 is improved by setting the supporting frames 12, one end of one side of each mounting frame 11 is connected with a mounting plate 28, a transmission assembly 15 is arranged on the mounting plate 28, the mounting plate 28 is connected with the mounting frames 11 through bolts, a mounting hole is formed in the mounting plate 28, a motor 29 is arranged in the mounting hole, the output end of the motor 29 is connected with a synchronous wheel 30, the synchronous wheel 30 is provided with a large and a small synchronous wheels, a synchronous belt 31 is connected with the synchronous wheel 30, 4 driving wheels 32 are arranged between the two mounting frames 11, two driving wheels 32 close to the motor 29 are connected with the synchronous wheel 30 through fixing rods 26, the fixing rods 26 penetrate through the mounting plates 28 to be connected with the large synchronous wheels, the driving wheels 32 are movably connected with the mounting frames 11 through fixing blocks 27, the fixing blocks 27 are connected with the mounting frames 11 through bolts, the driving wheels 32 can rotate in the fixing blocks 27, the driving wheels 32 are connected with the fixing blocks through bolts, the driving wheels 32 through the bolts, the motor 32 are connected with the motor 33 through the motor drive the motor 33 to rotate, and the two driving wheels 32 on the same 11 through the motor 33, and the driving wheels are connected with the motor 33 through the motor 33, and the motor 33 are driven by the motor 33 to rotate through the driving wheels 33, and the driving wheels 33 through the driving wheels 33 to rotate through the driving wheels 33, and change directions of the driving wheels 33 through the driving wheels 33 when the driving wheels 33 are realized.

The upper end of every mounting bracket 11 all is equipped with first slide rail 19, install first slider 17 on the slide rail, all be equipped with two first sliders 17 on every first ring gauge, first slider 17 is connected with first connecting block 16, first connecting block 16 sets up in the top of passing the power area, first connecting block 16 that is close to motor 29 is connected with drive belt 33, first connecting block 16 is connected with first workstation 13, drive first slider 17 when drive belt 33 moves and remove on the slide rail, the stability of first workstation 13 in the removal in-process has been ensured, rocking and deviation have been reduced, slide rail and slider cooperation can control the travel distance and the position of first workstation 13 accurately, this is crucial for the laser application that needs high accuracy processing.

The inside surface of each mounting bracket 11 is provided with a second slide rail 34, the second slide rail 34 is arranged below the transmission belt 33, a second sliding block 40 is arranged on the second slide rail 34, the second sliding block 40 is connected with a second connecting block 36, the second connecting block 36 is arranged below the transmission belt 33, the second connecting block 36 is connected with the transmission belt 33, two second connecting blocks 36 are arranged at two ends of the second slide rail 34, the stability of the second workbench 14 in movement is improved, shaking and deviation are reduced, and the cooperation of the slide rail and the sliding block enables the second workbench 14 to be smoother in movement.

A third sliding rail 21 is arranged in the middle of the driving belt 33 and positioned on the inner side surface of the mounting frame 11, the sliding rail is connected with the mounting frame 11 through a roller 24, a matching cavity is formed between the mounting frame 11 and the roller 24, the roller 24 can rotate in the matching cavity,

The third slide rail 21 is provided with a third slide block 20, the third slide block 20 is a sliding moving pair, the third slide block 20 is provided with a matching wheel, the matching wheel comprises a first matching wheel 23 and a second matching wheel 22, the first matching wheel 23 is provided with two matching wheels, the first matching wheel 23 is arranged above the roller 24 and is clamped in the mounting cavity to be in contact with the roller 24, the second matching wheel 22 is arranged below the roller 24 and is also clamped in the mounting cavity to be in contact with the roller 24, when the third slide block 20 moves on the third slide rail 21, the first matching wheel 23 and the second matching wheel 22 can be tightly attached to the roller 24 to form a stable clamping structure, and the structure not only can ensure the stability of the slide block in the moving process, but also can effectively prevent the slide block from falling off due to vibration or other external factors, meanwhile, due to the tight matching between the matching roller 24 and the roller 24, the moving track of the slide block is more accurately controllable, and thus the high precision of the processing process is ensured.

The third sliding rail 21 comprises an ascending section 39 and a descending section 38, the ascending section 39 is provided with two sections, the two sections are arranged at two ends of the descending section 38, the descending section 38 is positioned below the ascending section 39, the ascending section 39 and the descending section 38 are connected through a transition section 37, the third sliding block 20 moves along the third sliding rail 21 to realize the up-and-down movement of the second working table 14, the ascending section 39 guides the guiding section when the third sliding block 20 moves upwards, the descending section 38 is the guiding section when the third sliding block 20 moves downwards, the transition section 37 is the guiding section when the third sliding block 20 moves downwards from ascending to descending or from descending to ascending, when the third sliding block 20 moves along the third sliding rail 21, the third sliding block 20 drives the second working table 14 connected with the third sliding block to move up-and-down and-left to realize the up-and-right movement of the second working table 14, the second slide blocks 40 are rotatably connected with the connecting rods 25, the connecting rods 25 on each second slide block 40 are respectively provided with two connecting rods 25 far away from the motor 29, the two connecting rods 25 are connected through the limiting rods, the other ends of the connecting rods 25 are connected with the second workbench 14, the connecting rods 25 are rotatably connected with the third slide blocks 20 close to the motor 29, the third slide blocks 20 are provided with rotating pairs 35, the connecting rods 25 are matched with the rotating pairs 35, when the second workbench 14 is in ascending or descending state, through the rotation of the connecting rods 25, the rotating angles of the connecting rods 25 are adjusted, and the connection enables the movement of the connecting rods 25 to be limited or influenced by the positions of the third slide blocks 20, so that more complex movement control is achieved, the upward and downward movement of the second workbench 14 is achieved, and dead points are prevented from being generated by a mechanism.

The support frame 12 far away from the motor 29 is provided with a limit switch 18, the limit switch 18 is used for sensing the positions of the first workbench 13 and the second workbench 14, when the workbench reaches a designated position, the trigger switch is used for stopping and then changing the movement direction of the workbench, the workbench is prevented from exceeding a safety range and avoiding collision with other equipment or structures, one side of the frame 10 is provided with a controller (not shown in the figure), the controller can receive signals of the limit switch 18 and control the start and stop of the transmission assembly 15, the controller can accurately control the start and stop of the transmission assembly 15 according to the signals of the limit switch 18, the workbench is ensured to operate at the right time and position, and the controller can be programmed and configured according to different working requirements so as to adapt to different production scenes and operation requirements.

The working principle of the utility model is as follows:

Firstly, setting parameters according to actual demands by a controller, carrying out homing treatment on equipment before starting, classifying the homing treatment into treatment, namely, setting a first workbench 13 at the limit position of the left end of a frame 10, setting a second workbench 14 at the limit position of one side close to a motor 29, at the moment, setting the second workbench 14 as a working position, placing a product to be processed on the first workbench 13, starting the equipment, starting forward rotation of the motor 29, the synchronous wheel 30 is driven to start rotating by the synchronous belt 31, the synchronous wheel 30 drives the driving wheel 32 to rotate by the fixed rod 26, the driving wheel 32 drives the driving belt 33 to start driving, the first sliding block 17 is driven to start moving to the side close to the motor 29 along the first guide rail, the first working table 13 synchronously moves along with the movement of the first sliding block 17, meanwhile, the second sliding block 40 starts moving along the second sliding rail 34, the second working table 14 is driven to move to the side far away from the motor 29, when the third slider 20 moves from the ascending section 39 to the transition section 37 along with the movement of the second slider 40, the second workbench 14 starts to move downwards along with the cooperation of the second slider 40, the third slider 20 and the revolute pair 35, the second workbench 14 starts to move along the descending section 38, the second workbench 14 moves below the first workbench 13 at the moment, no collision is generated between the second workbench 14 and the second workbench, the second workbench 14 starts to ascend until the third slider 20 moves to the transition section 37 at the other end, the second workbench 14 continues to move along the ascending section 39 until the limit switch 18 senses the position of the second workbench 14, at the moment, the controller controls the motor 29 to stop rotating, the first workbench 13 and the second workbench are interchanged, other equipment processes raw materials on the first workbench 13, an operator performs feeding processing on the second workbench 14, after completion, the motor 29 is reversed, and the positions of the first and second work stations 14 are interchanged to continue the above operation, thereby improving the working efficiency.

The above is only a specific embodiment of the present utility model, but the technical features of the present utility model are not limited thereto. Any simple changes, equivalent substitutions or modifications and the like made on the basis of the present utility model to solve the substantially same technical problems and achieve the substantially same technical effects are included in the scope of the present utility model.

Claims (10)

1. An efficient laser processing platform, comprising A frame, the frame comprising a mounting frame and a supporting frame, the supporting frame being arranged between the two mounting frames; A transmission assembly, the transmission assembly comprising a transmission wheel disposed on the mounting frame and a transmission belt matched with the transmission wheel; It is characterized in that: a first workbench is provided on the mounting frame, and a second workbench is provided between the two mounting frames, the first workbench is connected to the transmission belt through a first connecting block, and the second workbench is connected to the transmission belt through a second connecting block, the first connecting block and the second connecting block are arranged at the upper and lower ends of the transmission belt and are staggered, and the first workbench and the second workbench are driven to move staggered by the rotation of the transmission belt. 2. A high-efficiency laser processing platform according to claim 1, characterized in that: a first slide rail is provided on the mounting frame, a first slider is installed on the slide rail, and the first slider is connected to the first connecting block. 3. An efficient laser processing platform according to claim 1, characterized in that: a second slide rail is provided on the inner side of the mounting frame, a second slider is installed on the second slide rail, and the second slider is connected to the second connecting block. 4. A high-efficiency laser processing platform according to claim 3, characterized in that: a third slide rail is provided on the mounting frame, the slide rail and the mounting frame are connected by a roller, a third slider is provided on the third slide rail, and a mating wheel is provided on the third slider, and the mating wheel cooperates with the roller to realize the movement of the third slider along the third slide rail. 5. An efficient laser processing platform according to claim 4, characterized in that: the mating wheel includes a first mating wheel and a second mating wheel, the first mating wheel is arranged above the roller, and the second mating wheel is arranged below the roller, and the first mating wheel and the second mating wheel clamp the roller up and down to prevent the third slider from falling off. 6. An efficient laser processing platform according to claim 4, characterized in that: the third slide rail includes an ascending section and a descending section, the descending section is located below the ascending section, the ascending section and the descending section are connected by a transition section, and the third slider moves along the third slide rail to realize the up and down movement of the second workbench. 7. A high-efficiency laser processing platform according to claim 4, characterized in that: a connecting rod is rotatably connected to the second slider, the other end of the connecting rod is connected to the second workbench, and the connecting rod is rotatably connected to the third slider. 8. A high-efficiency laser processing platform according to claim 1, characterized in that: the transmission wheels on the two mounting frames close to the power assembly are connected by a fixed rod, one end of the fixed rod is connected to the synchronous wheel, and the synchronous wheel is connected to the motor through a synchronous belt to achieve synchronous transmission of the transmission belts on the mounting frames on both sides. 9. An efficient laser processing platform according to claim 1, characterized in that: a limit switch is provided on the support frame away from the transmission assembly, and the limit switch is used to sense the positions of the first workbench and the second workbench. 10. An efficient laser processing platform according to claim 9, characterized in that: a controller is provided on one side of the frame, and the controller can receive the limit switch signal and control the start and stop of the transmission component.