JP2020137510A - Opto-mechatronics-based high class production apparatus - Google Patents

Abstract

To provide an opto-mechatronics-based production apparatus combining facilities to achieve integration of the apparatus, not requiring an intermediate transport process, enabling stop and use as necessary, extending service life, and reducing a producing cost.SOLUTION: An opto-mechatronics-based production apparatus is configured such that a supply conveyor belt 5 and a main control box 3 are mounted on a bracket, an opto-mechatronics-based smart production system is provided within the main control box, a supply conveyor is rotatably connected to a transmission motor within the main control box, a feed tank is mounted on the feed conveyor, a mixing agitation apparatus 8, a rolling apparatus 10, and a cutting apparatus 11 are mounted on an operation base, a feed hopper and a discharge hopper are connected to the mixing agitation apparatus, the feed hopper matches with the feed tank, an exit of the discharge hopper is communicated with an entrance of the rolling apparatus, the exit of the rolling apparatus is communicated with the entrance of the cutting apparatus, and a drying passage 12 for drying a finished product is provided at the exit of the cutting apparatus.SELECTED DRAWING: Figure 1

Description

The present invention belongs to the field of production equipment and is a high-class production equipment based on optomechatronics.

Optomechatronics is a synthesis and fusion of microelectronics technology, computer technology, control technology, optical technology and mechanical technology, and is the foundation of many high-tech industries and high-tech equipment. It includes both product and technology. Opt-mechatronics integrated products are high-tech products that integrate optical, mechanical, microelectronics, automatic control and communication technologies, and have abundant functions and extremely high added value. The opt-mechatronics integrated technology refers to the technology that enables the realization, use and development of the opt-mechatronics integrated product. Optomechatronics integrated technology is a comprehensive high-tech technology that integrates and integrates optics, optoelectronics, electronic information and machine manufacturing, and other related technologies, and is the basis of many high-tech industries and high-tech equipment. .. In the current livestock feed production, since mechanized production is carried out by dividing the production area, the livestock feed production and processing process is not continuous, the intermediate transportation process cannot be omitted, and human resources and physical properties. Resources are wasted, and at the same time, non-intelligent production equipment operates for a long period of time, which shortens the useful life of equipment, makes it difficult to improve production efficiency, and cannot reduce production costs. Therefore, optomechatronics Intelligent production equipment based on is expected.

Chinese Patent Application Publication No. 105196333

An object of the present invention is that the production by the current livestock feed production device cannot be integrated, and at the same time, the device / structure cannot be used and stopped immediately as needed in the operation process, so that it is difficult to reduce the production cost. In order to solve the problem, we proposed a high-class production equipment based on optomechatronics.

In order to realize the above object, the present invention adopts the following technical proposal.

A high-end production device based on optmechatronics, including a bracket and a workbench, the supply conveyor belt is fixedly attached to the bracket, and the main control box is fixedly connected to the bottom end of the bracket. A smart production system based on optomechatronics is installed in the control box, a control panel is fixedly mounted on the left side of the main control box, the control panel is electrically connected to the smart production system, and the supply conveyor belt One side of the lower end is rotationally connected to the transmission motor in the main control box, the transmission motor is electrically connected to the control panel, and feed tanks are fixedly mounted on opposite sides of both ends of the supply conveyor belt. A mixing and stirring device, a compaction device and a cutting device are fixedly mounted on the table surface of the workbench from left to right, and a feed hopper is fixedly connected to the upper left end of the mixing and stirring device. Matches with the feed tank, the discharge hopper is fixedly connected to the lower right end of the bottom of the mixing and stirring device, the outlet of the discharge hopper communicates with the inlet of the compactor, and the outlet of the compactor is said. A drying passage for drying the finished product is installed at the outlet of the cutting device in communication with the entrance of the cutting device, and the mixing and stirring device, the compaction device, the cutting device and the drying passage are all connected to the smart production system. It is electrically connected.

Preferably, the mixing stirrer comprises a stirring casing, the induction rotary motor is fixedly mounted on the top of the stirring casing, the induction rotary motor is electrically connected to the smart production system, and the induction rotary motor is rotated. The gears are fixedly connected, a first stirring chamber and a second stirring chamber are installed in the stirring casing, respectively, and a transfer plate is fixedly connected to the inner center end of the stirring casing via a connecting rod. The left upper end of the first stirring chamber communicates with the feed hopper, the lower end outlet of the first stirring chamber matches the upper end of the transfer plate, and the bottom right side of the second stirring chamber communicates with the discharge hopper. 2 The upper left end of the stirring chamber matches the lower end of the transfer plate, and a first transmission rod whose lower end penetrates the inside of the first stirring chamber is rotatably connected to the top of the first stirring chamber. The first transmission gear is fixedly connected to the upper end face, and a second transmission rod whose lower end penetrates the inside of the second stirring chamber is rotationally connected to the top of the second stirring chamber, and the upper end of the second transmission rod is connected. The second transmission gear is fixedly connected to the end face, the paddle is fixedly connected to the lower outer surface of the first transmission rod and the second transmission rod, and the rims of the first transmission gear and the second transmission gear are respectively connected. Is meshed with the left and right rims of the rotary gear, thereby facilitating sufficient mixing and stirring of the material.

Preferably, the compaction device comprises a compaction box so that the inlet of the compaction box communicates with the outlet of the discharge hopper to facilitate the propulsion of material on the inner wall with respect to the inlet of the lower end of the compaction box. The supply transfer block is fixedly connected, and the discharge transfer block for facilitating material extrusion is fixedly connected to the inner wall with respect to the outlet of the compaction box, and between the supply transfer block and the discharge transfer block. A moving belt is installed in the moving belt, drive rollers are movably connected to both ends of the moving belt, and several sets of support rollers for rolling compaction support are movably connected to the central portion of the moving belt, and are connected to the inner top end of the rolling compaction box. The electrically controlled hydraulic rods are fixedly connected, the lower end of the electrically controlled hydraulic rod is fixedly connected to the central end of the upper surface of the compaction plate, and several sets of rolling to roll the material to the lower end of the compaction plate. The compression wheels are movably connected and the drive rollers and electrically controlled hydraulic rods are electrically connected to the smart production system, thereby facilitating compaction forming of the material.

Preferably, the cutting device comprises a cutting box, a material flow path is provided at the inner bottom end of the cutting box, and both ends of the material flow path communicate with the compactor and the drying passage, respectively, in the cutting box. A vertical cutting chamber and a horizontal cutting chamber are installed, several sets of vertical cutting concave grooves are installed in the vertical cutting chamber, a rod connecting groove is installed at the bottom of the vertical cutting concave groove, and electrical control is performed in the rod connecting groove. The telescopic rod is fixedly mounted, the outer end of the electrically controlled telescopic rod is fixedly connected to the upper center end of the vertical cutting cutter, and the vertical cutting cutter is slidably connected to the vertical cutting groove. An inverted L-shaped inner groove is installed in the horizontal cutting chamber, the vertical groove of the inverted L-shaped inner groove is slidably connected to the horizontal cutting cutter, and an induction drive is performed in the horizontal groove of the inverted L-shaped inner groove. The motor is fixed and mounted, the cam is fixedly connected to the induction drive motor, the cam contacts one side of the top surface of the transverse cutting cutter, and several sets of tensions are placed on the other side of the top surface of the transverse cutting cutter. The spring is fixedly connected, the upper end of the tension spring is fixedly connected to the bottom of the lateral groove of the inverted L-shaped inner groove, and the electrically controlled telescopic rod and the inductive drive motor are electrically connected to the smart production system. Connected, thereby facilitating the cutting and molding of the material.

Preferably, an optical sensor electrically connected to the smart production system is also installed in the feed hopper and the discharge hopper, thereby facilitating intelligent control.

Compared with the prior art, the present invention provides a high-end production apparatus based on optomechatronics and has the following beneficial effects.

(1) When a user of a high-end production apparatus based on the optomechatronics uses the invention, the raw material is placed in a feed tank on a supply conveyor belt, and then a smart based on optomechatronics in a control panel and a main control box. By simply performing production operations via the production system, the processing and production of livestock feed can be integrated, which is quick and convenient, shortens the production time, saves the cost of intermediate transportation, and improves the production efficiency. The control panel adjusts and controls the rotation of the transmission motor of the main control box, rotates the supply conveyor belt in the bracket, and when the feed tank rotates to the bottom end of the supply conveyor belt, the feed raw material is produced by one worker. Is put into the feed tank, then transported to the top of the feed conveyor belt, and when it is rotated and returned, it falls into the feed hopper by the action of gravity, and the feed tank is installed on the opposite sides of both ends of the feed conveyor belt. As a result, it is possible to realize cyclical material input, which shortens the material input time. In the feed hopper, the optical sensor detects the dropped raw material, triggers the smart production system to activate the mixing and stirring device on the workbench, and the raw material is sufficiently cut, stirred and mixed in the mixing and stirring device, and then the discharge hopper. When the mixed raw material passes through the discharge hopper, it is detected by the optical sensor to trigger the smart production system to stop the mixing and stirring device, and at the same time, it is disconnected from the rolling device. By operating the device, finishing the mixed raw material, drying it in the drying passage, and then packaging it by the user, the production of livestock feed is completed and the optical sensor is installed in the drying passage, so it is smart. It can trigger the production system to control the stoppage and use of rolling and cutting devices, while at the same time triggering the operation of the drying passage, during the production process, through the smart production system, with the stoppage of equipment as needed. The use can be controlled, thereby avoiding the danger of long-term operation of the equipment and further effectively improving the production efficiency.

(2) A mixing and stirring device is installed in the high-class production device based on the optomechatronics, and when the raw material enters the mixing and stirring device, the smart production system controls and rotates the induction rotary motor, and the rotation of the rotary gear causes the first step. The 1st transmission gear and the 2nd transmission gear are rotationally driven, whereby the lower parts of the 1st transmission rod and the 2nd transmission rod are rotated in the 1st stirring chamber and the 2nd stirring chamber, respectively, and the paddle is moved to cut the raw material. By stirring and mixing in this way, the stirring efficiency can be improved and sufficient processing can be performed. Smart shutters are installed at the lower ends of both the first stirring chamber and the second stirring chamber for smart production. The stirring time in the first stirring chamber and the second stirring chamber can be controlled respectively by the control by the system, and the smart production system controls the opening and closing of the smart shutter to pass the mixed raw material in the first stirring chamber through the transfer plate. The mixed raw material in the second stirring chamber can be made to flow into the second stirring chamber, or the mixed raw material in the second stirring chamber can be made to flow into the compaction device through the discharge hopper, and immediately after all the mixed raw materials flow out from the discharge hopper, the mixing and stirring device quickly Stop the operation and wait until the next processing process starts and restarts.

(3) A compaction device is installed in the high-class production device based on the optomechatronics, and when the mixed raw material flows out from the discharge hopper, the smart production system is triggered to rotate the drive roller to rotate the moving belt. When driving, extending an electrically controlled hydraulic rod, compacting the mixed raw material via a rolling wheel whose lower end is movably connected to the rolling plate, and the mixed raw material entering the discharge hopper and sliding into the rolling box. Transferring to the moving belt via the feed transfer block controls the moving speed of the moving belt, thereby facilitating high speed compaction forming and allowing the support rollers to effectively support the moving belt when rolling. The compaction molding can be facilitated, and then the cutting process can be performed by transferring the compaction to a cutting device via a discharge transfer block.

(4) A cutting device is installed in a high-class production device based on the optomechatronics, and the mixed raw material after compaction enters the cutting box in the cutting device through the discharge transfer block, and through the material flow path. A vertical cutting chamber and a horizontal cutting chamber are set up above the material flow path, respectively, and the mixed raw material is vertically cut with a vertical cutting cutter that is slidably connected to several sets of vertical cutting recesses in the vertical cutting chamber. At the same time, the smart production system controls and stretches the electrically controlled telescopic rods in the vertical cutting grooves to achieve the spacing between several sets of vertical cutting cutters, thereby controlling the vertical cutting width of the compaction material. The smart production system controls and rotates the induction drive motor in the transverse cutting chamber, moves the cam to periodically push the transverse cutting cutter, and the tension spring exerts a tensile effect on the transverse cutting cutter. By combining, the vertical reciprocating motion of the inverted L-shaped inner groove of the horizontal cutting cutter in the vertical groove is realized, thereby realizing the horizontal cutting to the compaction material, and rolling by performing the horizontal cutting and the vertical cutting operation. The shape and size of the pressure material can be controlled.

All parts not mentioned of the device are the same as or can be realized by the prior art, and the present invention is equipped with a mixing stirrer, a compactor and a cutting device, a supply conveyor belt, a drying passage and optomechatronics. By combining the smart production system based on, the livestock feed production equipment can be integrated, no intermediate transportation process is required, and the equipment structure allows it to be stopped and used as needed, extending its useful life. And reduce the production cost.

Is a schematic front structure diagram of a high-class production apparatus based on optomechatronics according to the present invention. Is a schematic front cross-sectional structure of a mixing and stirring device of a high-class production device based on optomechatronics according to the present invention. Is a structural schematic view of a front cross section of a compaction device of a high-class production device based on optomechatronics according to the present invention. Is a structural schematic view of a front cross section of a cutting device of a high-class production device based on optomechatronics according to the present invention. Is a structural schematic diagram of a left cross section of a vertical cutting chamber of a high-class production apparatus based on optomechatronics according to the present invention. Is a three-dimensional schematic diagram of the connection between the induction drive motor and the cam of a high-class production device based on optomechatronics according to the present invention.

In the figure, 1, bracket, 2, workbench, 3, main control box, 4, control panel, 5, supply conveyor belt, 6, feed tank, 7, feed hopper, 8, mixing and stirring device, 9, discharge hopper. 10, Rolling device, 11, Cutting device, 12, Drying passage, 13, Stirring casing, 14, 1st stirring chamber, 15, 2nd stirring chamber, 16, Transfer plate, 17, 1st transmission rod, 18, 2nd transmission rod, 19, 1st transmission gear, 20, 2nd transmission gear, 21, rotary gear, 22, induction rotary motor, 23, paddle, 24, compaction box, 25, electrically controlled hydraulic rod, 26, rolling Pressure plate, 27, rolling wheel, 28, supply transfer block, 29, discharge transfer block, 30, moving belt, 31, drive roller, 32, support roller, 33, vertical cutting chamber, 34, horizontal cutting chamber, 35, vertical Cutting concave groove, 36, electrically controlled telescopic rod, 37, vertical cutting cutter, 38, inverted L-shaped inner groove, 39, induction drive motor, 40, cam, 41, horizontal cutting cutter, 42, tension spring.

In the following, the technical means in the examples of the present invention will be clearly and completely described with reference to the drawings in the examples of the present invention, and of course, the described examples are only a part of the examples of the present invention. Not all examples.

In the description of the present invention, terms such as "top", "bottom", "front", "rear", "left", "right", "top", "bottom", "inside", and "outside" The orientation or positional relationship shown in is the orientation or positional relationship shown based on the drawings, and is merely for facilitating the description of the present invention and simplifying the description, and the device or element shown is not necessarily specific. It does not indicate or suggest that it has an orientation and is configured or manipulated in a particular orientation and therefore should not be understood as a limitation on the present invention.

Example 1:

As shown in FIG. 1, it is a high-class production device based on optomechatronics including a bracket 1 and a workbench 2, in which a supply conveyor belt 5 is fixedly mounted on the bracket 1 and a main control is performed on the bottom end of the bracket 1. The box 3 is fixedly connected, a smart production system based on optomechatronics is installed in the main control box 3, the control panel 4 is fixedly mounted on the left side of the main control box 3, and the control panel 4 is the smart production system. One side of the lower end of the supply conveyor belt 5 is rotationally connected to the transmission motor in the main control box 3, the transmission motor is electrically connected to the control panel 4, and both ends of the supply conveyor belt 5 face each other. The feed tank 6 is fixedly mounted on each side, and the mixing and stirring device 8, the compaction device 10 and the cutting device 11 are fixedly mounted on the table surface of the work table 3 from left to right, respectively, and the mixing and stirring device 8 is mounted. The feed hopper 7 is fixedly connected to the upper left end of the hopper, the feed hopper 7 matches the feed tank 6, and the discharge hopper 9 is fixedly connected to the lower right end of the bottom of the mixing and stirring device 8, and the outlet of the discharge hopper 9 is connected. Communicates with the inlet of the compaction device 10, the outlet of the compaction device 10 communicates with the inlet of the cutting device 11, and a drying passage 12 for drying the finished product is installed at the outlet of the cutting device 11 to mix and stir. The device 8, the compaction device 10, the cutting device 11, and the drying passage 12 are all electrically connected to the smart production system.

An optical sensor electrically connected to the smart production system is installed in both the feed hopper 7 and the discharge hopper 9.

When using the invention, the user places the raw material in the feed tank 6 on the supply conveyor belt 5 and then performs the production operation via the optomechatronics-based smart production system on the control panel 4 and the main control box 3. Only by itself, the integrated processing and production of livestock feed can be realized, it is quick and convenient, the production time is shortened, the cost of intermediate transportation is saved, the production efficiency is improved, and the control panel 4 is the main control box. When the rotation of the transmission motor 3 is adjusted and controlled, the supply conveyor belt 5 in the bracket 1 is rotated, and the feed tank 6 is rotated to the bottom end of the supply conveyor belt 5, the feed raw material is fed by one worker. It is put into 6 and then transported to the top of the supply conveyor belt 5, and when it is rotated and returned, it falls into the feed hopper 7 due to the action of gravity, and the feed tank 6 is installed on the opposite sides of both ends of the supply conveyor belt 5. By doing so, it is possible to realize cyclical material input, which shortens the material input time. The feed hopper 7 detects the dropped raw material with an optical sensor, triggers the smart production system to operate the mixing and stirring device 8 on the workbench 2, and sufficiently cuts, stirs and mixes the raw material into the mixing and stirring device 8. Next, the compaction device 10 is entered through the discharge hopper 9 to perform compaction processing, and when the mixed raw material passes through the discharge hopper 9, the optical sensor detects it, triggers the smart production system, and stops the mixing and stirring device 8. At the same time, the compaction device 10 and the cutting device 11 are operated to finish the mixed raw material, and the mixed raw material is further dried in the drying passage 12 and then packaged by the user to complete the production of livestock feed and dry. Since the optical sensor is also installed in the passage 12, the smart production system can be triggered to control the stoppage and use of the compaction device 10 and the cutting device 11, and at the same time, the operation of the drying passage 12 can be triggered, and in the production process. , Immediate stop and start of equipment can be controlled as needed through smart production system, thereby avoiding the danger of long-term operation of equipment and further improving production efficiency effectively. ..

Example 2: With reference to FIG. 2, the differences from the first embodiment are as follows.

The mixing stirring device 8 includes a stirring casing 13, in which an induction rotary motor 22 is fixedly mounted on the top of the stirring casing 13, the induction rotation motor 22 is electrically connected to the smart production system, and a rotary gear is attached to the induction rotation motor 22. 21 is fixedly connected, the first stirring chamber 14 and the second stirring chamber 15 are installed in the stirring casing 13, respectively, and the transfer plate 16 is fixed to the inner central end of the stirring casing 13 via the connection rod. The upper left end of the first stirring chamber 14 communicates with the feed hopper 7, the lower end outlet of the first stirring chamber 14 matches the upper end of the transfer plate 16, and the lower right side of the bottom of the second stirring chamber 15 is the discharge hopper 9. The upper left end of the second stirring chamber 15 matches the lower end of the transfer plate 16, and the first transmission rod 17 whose lower end penetrates the inside of the first stirring chamber 14 rotates at the top of the first stirring chamber 14. The first transmission gear 19 is fixedly connected to the upper end surface of the first transmission rod 17, and the lower end of the second transmission rod 18 penetrates the inside of the second stirring chamber 15 at the top of the second stirring chamber 15. Is rotationally connected, the second transmission gear 20 is fixedly connected to the upper end surface of the second transmission rod 18, and the paddle 23 is fixedly connected to the lower outer surface of the first transmission rod 17 and the second transmission rod 18. The rims of the first transmission gear 19 and the second transmission gear 20 are meshed and connected to the rims on both the left and right sides of the rotary gear 21, respectively.

When the raw material enters the mixing / stirring device 8, the smart production system controls and rotates the induction rotary motor 22, and the rotation of the rotary gear 21 rotationally drives the first transmission gear 19 and the second transmission gear 20. The lower parts of the first transmission rod 17 and the second transmission rod 18 are rotated in the first stirring chamber 14 and the second stirring chamber 15, respectively, and the paddle 23 is moved to cut the raw materials and stir and mix them. By stirring, the stirring efficiency can be improved and sufficient processing can be performed. Smart shutters are installed at the lower ends of the first stirring chamber 14 and the second stirring chamber 15, and the first stirring chamber 14 is controlled by the smart production system. And the stirring time in the second stirring chamber 15 can be controlled respectively, and the smart production system controls the opening and closing of the smart shutter to transfer the mixed raw material in the first stirring chamber 14 through the transfer plate 16 to the second stirring chamber. The mixed raw material in the second stirring chamber 15 can be made to flow into the compaction device 10 through the discharge hopper 7, and immediately after all the mixed raw materials flow out from the discharge hopper 7, the mixing and stirring device 8 is quickly operated. The operation is stopped and waits until the next processing process starts and restarts.

Example 3: With reference to FIG. 3, the differences from Example 1 are as follows.

The compaction device 10 includes a compaction box 24, and the inlet of the compaction box 24 communicates with the outlet of the discharge hopper 9, and a supply for facilitating the propulsion of materials to the inner wall with respect to the entrance portion of the lower end of the compaction box 24. The transfer block 28 is fixedly connected, and the discharge transfer block 29 for facilitating material extrusion is fixedly connected to the inner wall with respect to the outlet of the compaction box 24, and the supply transfer block 28 and the discharge transfer block 29 are connected to each other. A moving belt 30 is installed between them, drive rollers 31 are movably connected to both ends of the moving belt 30, and several sets of support rollers 32 for rolling compaction support are movably connected to the central part of the moving belt 30, and the rolling compaction box 24 The electrically controlled hydraulic rod 25 is fixedly connected to the inner top end of the above, the lower end of the electrically controlled hydraulic rod 25 is fixedly connected to the central end of the upper surface of the compaction plate 26, and the material is compacted to the lower end of the compaction plate 26. Several sets of compaction wheels 27 for this purpose are movably connected, and the drive rollers 31 and the electrically controlled hydraulic rods 25 are electrically connected to the smart production system.

When the mixed raw material flows out of the discharge hopper 7, the smart production system is triggered to rotate the drive roller 31 to rotationally drive the moving belt 30, extend the electrically controlled hydraulic rod 25, and the lower end thereof becomes the compaction plate 26. When the mixed raw material is compacted through the movably connected rolling wheel 27 and the mixed raw material enters the discharge hopper 7 and slides into the rolling box 24, it is transferred to the moving belt 30 via the supply transfer block 28. The moving speed of the moving belt 30 is controlled, thereby facilitating high-speed compaction, and the support roller 32 can effectively support the moving belt 30 when rolling, facilitating compaction and then discharging. It can be transferred to the cutting device 11 via the transfer block 29 for cutting.

Example 4: With reference to FIG. 4-6, the differences from Example 1 are as follows.

The cutting device 11 is provided with a cutting box, and a material flow path is installed at the inner bottom end of the cutting box, both ends of the material flow path communicate with the compaction device 10 and the drying passage 12, respectively, and the vertical cutting chamber 33 is provided in the cutting box. And a horizontal cutting chamber 34 is installed, several sets of vertical cutting concave grooves 35 are installed in the vertical cutting chamber 33, a rod connecting groove is installed at the bottom of the vertical cutting concave groove 35, and electrically controlled expansion and contraction in the rod connecting groove. The rod 36 is fixedly attached, the outer end of the electrically controlled telescopic rod 36 is fixedly connected to the upper center end of the vertical cutting cutter 37, and the vertical cutting cutter 37 is slidably connected to the vertical cutting groove 35. An inverted L-shaped inner groove 38 is installed in the transverse cutting chamber 34, and the vertical groove of the inverted L-shaped inner groove 38 is slidably connected to the transverse cutting cutter 41, and the lateral groove of the inverted L-shaped inner groove is formed. The induction drive motor 39 is fixedly mounted inside, the cam 40 is fixedly connected to the induction drive motor 39, the cam 40 comes into contact with one side of the upper surface of the transverse cutting cutter 41, and the upper surface of the transverse cutting cutter 41 Several sets of tension springs 42 are fixedly connected to the other side, and the upper end of the tension spring 42 is fixedly connected to the bottom of the lateral groove of the inverted L-shaped inner groove 38, and the electrically controlled telescopic rod 36 and the induction drive motor 39 are connected. Is electrically connected to the smart production system.

The mixed raw material after compaction enters the cutting box in the cutting device 11 through the discharge transfer block 29, in which it flows through the material flow path, and the vertical cutting chamber 33 and the horizontal cutting chamber 34, respectively, above the material flow path. Is installed, and the mixed raw material is vertically cut by the vertical cutting cutter 37 which is slidably connected to several sets of the vertical cutting concave grooves 35 in the vertical cutting chamber 33, and at the same time, the smart production system is electrically controlled expansion and contraction in the vertical cutting concave groove 35. By controlling and extending the rod 36, the spacing width between several sets of longitudinal cutting cutters 37 is realized, thereby controlling the longitudinal cutting width of the compaction material, and the smart production system has the lateral cutting chamber 34. By controlling and rotating the induction drive motor 39 in the above, moving the cam 40 to periodically extrude the transverse cutting cutter 41, and combining the tensile effect of the tension spring 42 on the transverse cutting cutter 41, the transverse cutting Achieves vertical reciprocating motion of the cutter 41 in the vertical groove of the inverted L-shaped inner groove, thereby realizing lateral cutting into the compaction material, and by performing lateral cutting and vertical cutting operations, the shape of the compaction material and You can control the size.

Example 5: The differences from Example 1 are as follows.

The compaction material after cutting is conveyed to the drying passage 12 by the pressing force and the transfer force, and the smart production system is triggered by the optical sensor in the drying passage 12 to operate the drying system in the drying passage 12 to dry the compaction material. Process and then effectively package.

The above is only a preferred embodiment of the present invention, and the scope of protection of the present invention is not limited thereto, and the technical proposal of the present invention and the technical scope thereof are within the technical scope disclosed by those skilled in the art. All equivalent substitutions or alterations made under the invention should belong to the scope of the invention.

Claims (5)

A high-class production device based on optomechatronics including a bracket (1) and a workbench (2), in which a supply conveyor belt (5) is fixedly attached to the bracket (1) and the bottom of the bracket (1) is attached. A main control box (3) is fixedly connected to the end, a smart production system based on optomechatronics is installed in the main control box (3), and a control panel (4) is installed on the left side of the main control box (3). Is fixedly mounted, the control panel (4) is electrically connected to the smart production system, and one side of the lower end of the supply conveyor belt (5) is rotationally connected to the transmission motor in the main control box (3). The transmission motor is electrically connected to the control panel (4), and the feed tanks (6) are fixedly mounted on the opposite sides of both ends of the supply conveyor belt (5), respectively, and the work table (3). ), The mixing and stirring device (8), the compaction device (10) and the cutting device (11) are fixedly mounted from left to right, respectively, and the feed hopper (8) is attached to the upper left end of the mixing and stirring device (8). 7) is fixedly connected, the feed hopper (7) is matched with the feed tank (6), and the discharge hopper (9) is fixedly connected to the lower right end of the bottom of the mixing and stirring device (8). The outlet of the discharge hopper (9) communicates with the inlet of the compaction device (10), the outlet of the compaction device (10) communicates with the inlet of the cutting device (11), and the cutting device (11) A drying passage (12) for drying the finished product is installed at the outlet of the above, and the mixing and stirring device (8), the compaction device (10), the cutting device (11) and the drying passage (12) are all described above. A high-end production device based on optomechatronics that is electrically connected to a smart production system. The mixing and stirring device (8) is provided with a stirring casing (13), and an induction rotation motor (22) is fixedly mounted on the top of the stirring casing (13), and the induction rotation motor (22) is attached to a smart production system. It is electrically connected, and the rotary gear (21) is fixedly connected to the induction rotary motor (22), and the first stirring chamber (14) and the second stirring chamber (15) are respectively inside the stirring casing (13). ) Is installed, the transfer plate (16) is fixedly connected to the inner central end of the stirring casing (13) via a connecting rod, and the upper left end of the first stirring chamber (14) is the feed hopper (7). ), The lower end outlet of the first stirring chamber (14) matches the upper end of the transfer plate (16), and the right side of the bottom of the second stirring chamber (15) communicates with the discharge hopper (9). The upper left end of the second stirring chamber (15) matches the lower end of the transfer plate (16), and the lower end of the top of the first stirring chamber (14) penetrates the inside of the first stirring chamber (14). The transmission rod (17) is rotationally connected, the first transmission gear (19) is fixedly connected to the upper end end surface of the first transmission rod (17), and the lower end is connected to the top of the second stirring chamber (15). The second transmission rod (18) penetrating the inside of the second stirring chamber (15) is rotationally connected, and the second transmission gear (20) is fixedly connected to the upper end surface of the second transmission rod (18). A paddle (23) is fixedly connected to the lower outer surface of the first transmission rod (17) and the second transmission rod (18), and the rims of the first transmission gear (19) and the second transmission gear (20) are connected. The high-grade production apparatus based on optomechatronics according to claim 1, wherein each of the rotary gears (21) is meshed with and connected to the rims on both left and right sides. The compaction device (10) includes a compaction box (24), the inlet of the compaction box (24) communicates with the outlet of the discharge hopper (9), and the entrance portion of the lower end of the compaction box (24). A supply transfer block (28) for facilitating material propulsion is fixedly connected to the inner wall with respect to the discharge transfer block (28) for facilitating material extrusion to the inner wall with respect to the outlet of the compaction box (24). 29) is fixedly connected, a moving belt (30) is installed between the supply transfer block (28) and the discharge transfer block (29), and drive rollers (31) are installed at both ends of the moving belt (30). ) Is movably connected, several sets of support rollers (32) for rolling compaction support are movably connected to the central portion of the moving belt (30), and an electrically controlled hydraulic rod () is movably connected to the inner top end of the compaction box (24). 25) is fixedly connected, the lower end of the electrically controlled hydraulic rod (25) is fixedly connected to the central end of the upper surface of the compaction plate (26), and the material is rolled to the lower end of the compaction plate (26). Claim 1 is characterized in that several sets of compaction wheels (27) for compression are movably connected, and the drive roller (31) and the electrically controlled hydraulic rod (25) are electrically connected to a smart production system. High-end production equipment based on optomechatronics described in. The cutting device (11) is provided with a cutting box, and a material flow path is installed at the inner bottom end of the cutting box, and both ends of the material flow path communicate with the compaction device (10) and the drying passage (12), respectively. A vertical cutting chamber (33) and a horizontal cutting chamber (34) are installed in the cutting box, and several sets of vertical cutting recesses (35) are installed in the vertical cutting chamber (33). A rod connecting groove is installed at the bottom of the groove (35), an electrically controlled telescopic rod (36) is fixedly mounted in the rod connecting groove, and the outer end of the electrically controlled telescopic rod (36) is a vertical cutting cutter (36). It is fixedly connected to the upper center end of 37), the vertical cutting cutter (37) is slidably connected to the vertical cutting concave groove (35), and an inverted L shape is formed in the horizontal cutting chamber (34). An inner groove (38) is installed, the vertical groove of the inverted L-shaped inner groove (38) is slidably connected to the transverse cutting cutter (41), and an induction drive is performed in the lateral groove of the inverted L-shaped inner groove. The motor (39) is fixedly mounted, the cam (40) is fixedly connected to the induction drive motor (39), and the cam (40) comes into contact with one side of the upper surface of the transverse cutting cutter (41). , Several sets of tension springs (42) are fixedly connected to the other side of the upper surface of the lateral cutting cutter (41), and the upper end of the tension spring (42) is a lateral groove of the inverted L-shaped inner groove (38). The optomechatronics according to claim 1, wherein the electrically controlled telescopic rod (36) and the induction drive motor (39) are fixedly connected to the bottom of the smart production system and electrically connected to the smart production system. Based on high-end production equipment. The high-grade optomechatronics based on claim 1, wherein an optical sensor electrically connected to the smart production system is installed in both the feed hopper (7) and the discharge hopper (9). Production equipment.