Disclosure of Invention
The invention aims to provide an intelligent processing system based on a block chain, which can realize efficient continuous grinding operation and can synchronously grind two end faces.
The purpose of the invention is realized by the following technical scheme:
the utility model provides an intelligence system of processing based on block chain, is including adjusting base, power unit, drive mechanism, transmission group frame, execution group frame, move position processing mechanism, binder and location processing mechanism, the upside threaded connection power unit of adjusting the base, the drive mechanism rigid coupling is on adjusting the base, power unit and drive mechanism friction drive, and drive mechanism is connected with transmission group frame transmission, and the rigid coupling moves position processing mechanism on the execution group frame, moves position processing mechanism and binder sliding connection, and the binder rotates to be connected the upside of execution group frame, and location processing mechanism rotates to be connected on execution group frame, and location processing mechanism sets up under moving position processing mechanism.
The adjusting base comprises a base body, a lead screw, a belt wheel I and a motor I, the base body is rotatably connected with the two lead screws, the lower sides of the two lead screws are fixedly connected with the belt wheel I respectively, the two belt wheels I are connected through a transmission belt, the motor I drives one of the lead screws to rotate, and the motor I is fixedly connected to the base body.
The power mechanism comprises a base, a motor II and a friction disc, the upper end of the base is fixedly connected with the motor II, and an output shaft of the motor II is fixedly connected with the friction disc; the base is in threaded connection with the two lead screws.
The transmission mechanism comprises a bearing seat I, a shaft I, a friction disc II, a force loss groove and a helical gear I, wherein the upper end of the bearing seat I rotates a connecting shaft I, the left end and the right end of the shaft I are fixedly connected with the helical gear I and the friction disc II respectively, the force loss groove is formed in the rotating center of the right end of the friction disc II, the bearing seat I is fixedly connected onto the base body, the right end face of the friction disc II is in friction transmission connection with the outer ring of the friction disc, and the friction disc can pass through the friction disc II in the vertical direction.
The transmission group frame includes frame I, axle II, helical gear II, band pulley II, axle III, helical gear III and band pulley III, the downside of frame I rotates connecting axle II, and the rigid coupling has helical gear II and band pulley II from top to bottom on the axle II, and axle III rotates the upside of connecting at the transmission group frame, and by supreme helical gear III and band pulley III of rigid coupling down on the axle III, the upside and the III meshing transmission of helical gear of the upside and the I left end of helical gear I left end, the I left end side downside of helical gear and the II meshing transmission of helical gear.
The execution group frame comprises a frame II and a positioning pipe, the positioning pipe is fixedly connected to the upper side of the frame II, and the upper end of the frame II is fixedly connected with the upper end of the frame I.
The movable position processing mechanism comprises a grinding chuck I, an electric telescopic rod and transmission rods, the upper end of the grinding chuck I is rotatably connected with the movable end of the electric telescopic rod, the upper end of the grinding chuck I is fixedly connected with the two transmission rods, the middle point of the connection line of the two transmission rods is superposed with the rotating center of the grinding chuck I, and the upper end of the electric telescopic rod is fixedly connected in the positioning pipe.
The combination part comprises a multipurpose wheel and transmission pipes, the lower end of the multipurpose wheel is fixedly connected with the two transmission pipes, the multipurpose wheel is rotatably connected to the outer ring of the positioning pipe, the two transmission rods are respectively connected in the two transmission pipes in a sliding mode, and the multipurpose wheel is in transmission connection with the belt wheel III through a transmission belt.
The positioning machining mechanism comprises a shaft IV, a grinding chuck II and a belt wheel IV, the shaft IV is rotatably connected to the lower side of the frame II, the belt wheel IV and the grinding chuck II are fixedly connected to the shaft IV from bottom to top, and the belt wheel IV and the belt wheel II are in transmission connection through a transmission belt.
The transmission ratio of the bevel gear I and the bevel gear II is the same as that of the bevel gear I and the bevel gear III, and the transmission ratio of the belt wheel II and the belt wheel IV is the same as that of the belt wheel III and the multipurpose wheel.
The intelligent processing system based on the block chain has the beneficial effects that:
the grinding chuck II and the grinding chuck I can synchronously rotate, and the rotation directions of the grinding chuck II and the grinding chuck I are opposite. The power source of the grinding chuck II and the grinding chuck I is a friction disc. The complex machining process can be realized through simple lifting of the friction disc, the input signal is simple, and programming, regulation and control and maintenance are easy. The grinding chuck II and the grinding chuck I can be used for clamping, grinding or grinding the object to be processed by different using methods.
Detailed Description
The present invention will be described in further detail with reference to the accompanying drawings.
The first embodiment is as follows:
as shown in fig. 1-9, an intelligent processing system based on a block chain includes an adjusting base 1, a power mechanism 2, a transmission mechanism 3, a transmission assembly frame 4, an execution assembly frame 5, a movable position processing mechanism 6, a combining member 7 and a positioning processing mechanism 8, wherein the upper side of the adjusting base 1 is in threaded connection with the power mechanism 2, the transmission mechanism 3 is fixedly connected to the adjusting base 1, the power mechanism 2 and the transmission mechanism 3 are in friction transmission, the transmission mechanism 3 and the transmission assembly frame 4 are in transmission connection, the execution assembly frame 5 is fixedly connected with the movable position processing mechanism 6, the movable position processing mechanism 6 and the combining member 7 are in sliding connection, the combining member 7 is rotatably connected to the upper side of the execution assembly frame 5, the positioning processing mechanism 8 is rotatably connected to the execution assembly frame 5, and the positioning processing mechanism 8 is arranged under the movable position processing mechanism 6. The grinding chuck II 802 and the grinding chuck I601 can synchronously rotate, and the rotation directions of the grinding chuck II 802 and the grinding chuck I601 are opposite. The power sources of the grinding chuck II 802 and the grinding chuck I601 are friction discs 203. The complex machining process can be realized by simply lifting the friction disc 203, and the input signal is simple and easy to program, regulate and maintain. The grinding chuck II 802 and the grinding chuck I601 can be used for clamping, grinding or grinding the object to be processed by different using methods.
The second embodiment is as follows:
as shown in fig. 1-9, the adjusting base 1 includes a base body 101, screws 102, belt pulleys i 103 and a motor i 104, the base body 101 is rotatably connected with two screws 102, the lower sides of the two screws 102 are respectively fixedly connected with one belt pulley i 103, the two belt pulleys i 103 are connected through a transmission belt, the motor i 105 drives one of the screws 102 to rotate, and the motor i 105 is fixedly connected to the base body 101. The output shaft of the motor i 105 may be coupled to the lower end of one of the lead screws 102 through a coupling, and the lower end of the lead screw 102 penetrates through the base body 101. Starting motor I104, motor I104 drive rotates rather than the lead screw 102 who is connected, and then two I103 rotations of band pulley, and then two lead screws 102 rotate.
The third concrete implementation mode:
as shown in fig. 1-9, the power mechanism 2 includes a base 201, a motor ii 202, and a friction disc 203, wherein the upper end of the base 201 is fixedly connected to the motor ii 202, and an output shaft of the motor ii 202 is fixedly connected to the friction disc 203; the base 201 is screwed to the two lead screws 102. The two lead screws 102 can drive the base 201 to move up and down, so that the friction disc 203 can move up and down, the motor II 202 is started, the motor II 202 drives the friction disc 203 to rotate, and then the friction disc 203 can rotate and move up and down.
The fourth concrete implementation mode:
as shown in fig. 1-9, the transmission mechanism 3 includes a bearing seat i 301, a shaft i 302, a friction disc ii 303, a force loss groove 304 and a helical gear i 305, the upper end of the bearing seat i 301 rotates the connecting shaft i 302, the left end and the right end of the shaft i 302 are respectively fixedly connected with the helical gear i 305 and the friction disc ii 303, the force loss groove 304 is arranged at the rotation center of the right end of the friction disc ii 303, the bearing seat i 301 is fixedly connected to the base body 101, the right end surface of the friction disc ii 303 is in friction transmission connection with the outer ring of the friction disc 203, and the friction disc 203 can pass through the friction disc ii 303 from the vertical direction. The initial position of the friction disc 203 is set at the force loss groove 304 of the friction disc ii 303, at this time, the friction disc 203 cannot contact the friction disc ii 303, when the rotating friction disc 203 moves upwards, the distance between the friction disc 203 and the rotation center of the friction disc ii 303 gradually increases, further, the speed of the friction disc ii 303 driven by the friction disc 203 rotates is faster and faster, and then the rotation speed of the friction disc ii 303 driven by the friction disc 203 is gradually reduced. Until the friction disc 203 passes through the force loss groove 304 again, the friction disc 203 stops driving the friction disc ii 303 to rotate, the friction disc 203 continues to move downwards, the friction disc 203 drives the friction disc ii 303 to rotate again, the rotation direction of the friction disc ii 303 is changed, and the further friction disc 203 is farther away from the rotation center of the friction disc ii 303 so that the rotation speed of the friction disc ii 303 is faster and faster. When friction disc 203 moves upward until it stops at force loss groove 304, friction disc ii 303 is gradually slowed to no rotation. The whole rotation process of the friction disc II 303 is that the rotation is carried out in one direction from slow to fast and then from fast to slow to stop, then the rotation direction of the friction disc II 303 is changed, and the rotation speed is changed from slow to fast and then from fast to slow to stop. The friction disc II 303 drives the bevel gear I305 to rotate through the shaft I302, and the rotation condition of the bevel gear I305 is the same as that of the friction disc II 303.
The fifth concrete implementation mode:
as shown in the figures 1-9, the transmission assembly frame 4 comprises a frame I401, a shaft II 402, a bevel gear II 403, a belt pulley II 404, a shaft III 405, a bevel gear III 406 and a belt pulley III 407, wherein the lower side of the frame I401 rotates to connect the shaft II 402, the shaft II 402 is fixedly connected with the bevel gear II 403 and the belt pulley II 404 from top to bottom, the shaft III 405 is rotatably connected to the upper side of the transmission assembly frame 4, the shaft III 405 is fixedly connected with the bevel gear III 406 and the belt pulley III 407 from bottom to top, the upper side of the left end of the bevel gear I305 is in meshing transmission with the bevel gear III 406, and the lower side of the left end of the bevel gear I305 is in meshing transmission with the bevel gear II 403. The rotating friction disc II 303 drives the bevel gear II 403 and the bevel gear III 406 to rotate synchronously, but the rotation directions of the bevel gear II 403 and the bevel gear III 406 are opposite. Bevel gear III 406 drives pulley III 407 to rotate through shaft III 405, and the two realize synchronous rotation. The helical gear II 403 drives the belt pulley II 404 to rotate through the shaft II 402, and the two rotate synchronously.
The sixth specific implementation mode:
as shown in fig. 1-9, the execution group frame 5 includes a frame ii 501 and a positioning pipe 502, the positioning pipe 502 is fixedly connected to the upper side of the frame ii 501, and the upper end of the frame ii 501 is fixedly connected to the upper end of the frame i 401.
The seventh embodiment:
as shown in fig. 1 to 9, the movable position processing mechanism 6 includes a grinding chuck i 601, an electric telescopic rod 602 and transmission rods 603, the upper end of the grinding chuck i 601 is rotatably connected to the movable end of the electric telescopic rod 602, the upper end of the grinding chuck i 601 is fixedly connected to the two transmission rods 603, the middle point of the connecting line of the two transmission rods 603 coincides with the rotation center of the grinding chuck i 601, and the upper end of the electric telescopic rod 602 is fixedly connected to the positioning tube 502. The electric telescopic rod 602 can drive the grinding chuck I601 to lift, so that the distance between the grinding chuck I601 and the positioning and processing mechanism 8 is changed.
The specific implementation mode is eight:
as shown in fig. 1-9, the coupling member 7 comprises a multipurpose wheel 701 and a transmission pipe 702, the lower end of the multipurpose wheel 701 is fixedly connected with two transmission pipes 702, the multipurpose wheel 701 is rotatably connected to the outer ring of the positioning pipe 502, two transmission rods 603 are respectively connected in the two transmission pipes 702 in a sliding manner, and the multipurpose wheel 701 and the pulley iii 407 are in transmission connection through a transmission belt. The rotating belt wheel III 407 drives the multipurpose wheel 701 to rotate, and the multipurpose wheel 701 and the multipurpose wheel realize synchronous rotation. The multipurpose wheel 701 drives the transmission rod 603 to rotate through the transmission pipe 702, so that the grinding chuck I601 and the multipurpose wheel 701 synchronously rotate. Namely, the grinding chuck I601 and the bevel gear III 406 can realize synchronous rotation.
The specific implementation method nine:
as shown in fig. 1-9, the positioning processing mechanism 8 comprises a shaft iv 801, a grinding chuck ii 802 and a pulley iv 803, the shaft iv 801 is rotatably connected to the lower side of the frame ii 501, the pulley iv 803 and the grinding chuck ii 802 are fixedly connected to the shaft iv 801 from bottom to top, and the pulley iv 803 and the pulley ii 404 are in transmission connection through a transmission belt. The pulley IV 803 and the pulley II 404 realize synchronous rotation, and the pulley IV 803 drives the grinding chuck II 802 to synchronously rotate through a shaft IV 801. Namely, the grinding chuck II 802 and the bevel gear II 403 can realize synchronous rotation. Namely, the grinding chuck II 802 and the grinding chuck I601 can realize synchronous rotation, and the rotation directions of the two are opposite. The power sources of the grinding chuck II 802 and the grinding chuck I601 are friction discs 203. If the article to be processed needs to be fixed, the friction disc 203 can not be driven to rotate, and then the grinding chuck plate II 802 and the grinding chuck plate I601 stop rotating, so that the grinding chuck plate I601 descends to be close to the grinding chuck plate II 802, and the article to be processed can be clamped and fixed. If the article to be processed needs to be ground, the article to be ground can be placed on the upper end face of the grinding chuck plate II 802 as large particles, the rubber ring is sleeved on the outer ring of the grinding chuck plate II 802 and is higher than the outer ring of the grinding chuck plate II 802, so that the grinding chuck plate II 802 and the grinding chuck plate I601 start to rotate in two directions respectively, high-speed grinding is realized through rotation in the two directions, and the grinding efficiency is improved. The grinding chuck II 802 and the grinding chuck I601 are slow to fast, large particles are firstly broken, the large particles are broken from breaking to grinding along with the increase of the rotating speed, then the large particles are stopped from fast to slow, the powder materials ground at high speed are finely ground at low speed, then the friction disc II 303 stops rotating, the rotating direction is changed, the rotating speed is changed from slow to fast, reverse secondary grinding is carried out, the stress direction of the upper surface and the lower surface of the ground materials is changed, and then the grinding is finely ground again from fast to slow to stop. The whole process can be realized by the lifting friction disc 203, and the input signal is simple and easy to program, regulate and maintain. If the upper and lower plane end faces of the belt processing article need to be polished, the two plane end faces are polished by directly using the polishing chuck II 802 and the polishing chuck I601. The grinding degree can be adjusted through the lifting of the grinding chuck plate I601, and the grinding speed can be adjusted through the lifting of the friction disc 203.
The detailed implementation mode is ten:
as shown in fig. 1-9, the transmission ratio of bevel gear i 305 and bevel gear ii 403 is the same as that of bevel gear i 305 and bevel gear iii 406, and the transmission ratio of pulley ii 404 and pulley iv 803 is the same as that of pulley iii 407 and utility wheel 701. The rotating speed of the grinding chuck II 802 is the same as that of the grinding chuck I601. The grinding effect of the grinding chuck II 802 and the grinding chuck I601 is better.
The invention relates to an intelligent processing system based on a block chain, which has the working principle that:
the output shaft of the motor i 105 may be coupled to the lower end of one of the lead screws 102 through a coupling, and the lower end of the lead screw 102 penetrates through the base body 101. Starting motor I104, motor I104 drive rotates rather than the lead screw 102 who is connected, and then two I103 rotations of band pulley, and then two lead screws 102 rotate. The two lead screws 102 can drive the base 201 to move up and down, so that the friction disc 203 can move up and down, the motor II 202 is started, the motor II 202 drives the friction disc 203 to rotate, and then the friction disc 203 can rotate and move up and down. The initial position of the friction disc 203 is set at the force loss groove 304 of the friction disc ii 303, at this time, the friction disc 203 cannot contact the friction disc ii 303, when the rotating friction disc 203 moves upwards, the distance between the friction disc 203 and the rotation center of the friction disc ii 303 gradually increases, further, the speed of the friction disc ii 303 driven by the friction disc 203 rotates is faster and faster, and then the rotation speed of the friction disc ii 303 driven by the friction disc 203 is gradually reduced. Until the friction disc 203 passes through the force loss groove 304 again, the friction disc 203 stops driving the friction disc ii 303 to rotate, the friction disc 203 continues to move downwards, the friction disc 203 drives the friction disc ii 303 to rotate again, the rotation direction of the friction disc ii 303 is changed, and the further friction disc 203 is farther away from the rotation center of the friction disc ii 303 so that the rotation speed of the friction disc ii 303 is faster and faster. When friction disc 203 moves upward until it stops at force loss groove 304, friction disc ii 303 is gradually slowed to no rotation. The whole rotation process of the friction disc II 303 is that the rotation is carried out in one direction from slow to fast and then from fast to slow to stop, then the rotation direction of the friction disc II 303 is changed, and the rotation speed is changed from slow to fast and then from fast to slow to stop. The friction disc II 303 drives the bevel gear I305 to rotate through the shaft I302, and the rotation condition of the bevel gear I305 is the same as that of the friction disc II 303. The rotating friction disc II 303 drives the bevel gear II 403 and the bevel gear III 406 to rotate synchronously, but the rotation directions of the bevel gear II 403 and the bevel gear III 406 are opposite. Bevel gear III 406 drives pulley III 407 to rotate through shaft III 405, and the two realize synchronous rotation. The helical gear II 403 drives the belt pulley II 404 to rotate through the shaft II 402, and the two rotate synchronously. The electric telescopic rod 602 can drive the grinding chuck I601 to lift, so that the distance between the grinding chuck I601 and the positioning and processing mechanism 8 is changed. The multipurpose wheel 701 drives the transmission rod 603 to rotate through the transmission pipe 702, so that the grinding chuck I601 and the multipurpose wheel 701 synchronously rotate. Namely, the grinding chuck I601 and the bevel gear III 406 can realize synchronous rotation. The pulley IV 803 and the pulley II 404 realize synchronous rotation, and the pulley IV 803 drives the grinding chuck II 802 to synchronously rotate through a shaft IV 801. Namely, the grinding chuck II 802 and the bevel gear II 403 can realize synchronous rotation. Namely, the grinding chuck II 802 and the grinding chuck I601 can realize synchronous rotation, and the rotation directions of the two are opposite. The power sources of the grinding chuck II 802 and the grinding chuck I601 are friction discs 203. If the article to be processed needs to be fixed, the friction disc 203 can not be driven to rotate, and then the grinding chuck plate II 802 and the grinding chuck plate I601 stop rotating, so that the grinding chuck plate I601 descends to be close to the grinding chuck plate II 802, and the article to be processed can be clamped and fixed. If the article to be processed needs to be ground, the article to be ground can be placed on the upper end face of the grinding chuck plate II 802 as large particles, the rubber ring is sleeved on the outer ring of the grinding chuck plate II 802 and is higher than the outer ring of the grinding chuck plate II 802, so that the grinding chuck plate II 802 and the grinding chuck plate I601 start to rotate in two directions respectively, high-speed grinding is realized through rotation in the two directions, and the grinding efficiency is improved. The grinding chuck II 802 and the grinding chuck I601 are slow to fast, large particles are firstly broken, the large particles are broken from breaking to grinding along with the increase of the rotating speed, then the large particles are stopped from fast to slow, the powder materials ground at high speed are finely ground at low speed, then the friction disc II 303 stops rotating, the rotating direction is changed, the rotating speed is changed from slow to fast, reverse secondary grinding is carried out, the stress direction of the upper surface and the lower surface of the ground materials is changed, and then the grinding is finely ground again from fast to slow to stop. The whole process can be realized by the lifting friction disc 203, and the input signal is simple and easy to program, regulate and maintain. If the upper and lower plane end faces of the belt processing article need to be polished, the two plane end faces are polished by directly using the polishing chuck II 802 and the polishing chuck I601. The grinding degree can be adjusted through the lifting of the grinding chuck plate I601, and the grinding speed can be adjusted through the lifting of the friction disc 203. The rotating speed of the grinding chuck II 802 is the same as that of the grinding chuck I601. The grinding effect of the grinding chuck II 802 and the grinding chuck I601 is better. The friction transmission can be used for slipping when an object to be processed is too hard during processing, so that the transmission is stopped when the upper limit of the load is automatically reached, and equipment is protected. The multifunctional integrated processing is beneficial to the rapid statistics of data by a system.
It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.