CN110340218B - Automatic processing equipment with electrode net arranged in medical plasma sterilizer - Google Patents

Abstract

The invention relates to the field of electrode mesh processing, in particular to automatic processing equipment for an electrode mesh of a medical plasma sterilizer, which comprises a feeding mechanism, a pressing mechanism, a quantitative cutting mechanism, a bending mechanism and a support frame, wherein the quantitative cutting mechanism comprises a cutting mechanism and a material moving mechanism, the material moving mechanism comprises a first mounting plate, a first electric sliding table, a limiting mechanism, a suction mechanism and two first support plates, the first electric sliding table is fixedly arranged at the bottom of the first mounting plate, and an extension plate is fixedly arranged on a sliding seat of the first electric sliding table. The processing efficiency is improved.

Description

Automatic processing equipment with electrode net arranged in medical plasma sterilizer

Technical Field

The invention relates to the field of electrode mesh processing, in particular to automatic processing equipment for an electrode mesh arranged in a medical plasma sterilizer.

Background

Medical disinfection and sterilization equipment for disinfecting and sterilizing medical instruments is divided into high-temperature disinfection and sterilization equipment and low-temperature disinfection and sterilization equipment, wherein the high-temperature disinfection and sterilization equipment generally adopts a high-temperature physical sterilization method, such as pulsating vacuum pressure steam sterilization equipment; low-temperature sterilization equipment, which generally adopts a physical and chemical sterilization method, such as a low-temperature hydrogen peroxide plasma sterilizer or a low-temperature glutaraldehyde plasma sterilizer, generally reduces the pressure of a chemical sterilant (hydrogen peroxide gas or glutaraldehyde gas) at a temperature of 80 ℃ or lower to vaporize the sterilant, and energizes the gaseous chemical sterilant to excite the sterilant into a plasma state, so as to enhance the sterilization effect of the sterilant on medical instruments placed in a sterilization chamber.

Generally, in a low-temperature plasma sterilizer, an electrode mesh is required to be arranged so as to form plasma in a sterilization chamber of a medical plasma sterilizer, generally, the sterilization chamber of the sterilizer is made of aluminum alloy, the electrode mesh is made of aluminum alloy or stainless steel, the electrode mesh is arranged in the sterilization chamber, the electrode mesh is connected with the sterilization chamber through an insulating support, a certain gap (the gap value is usually 1cm to 3 cm) is reserved between the periphery of the sterilization chamber and the electrode mesh, when the sterilizer works, the sterilization chamber is negatively charged, the electrode mesh is positively charged (the sterilization chamber can also be positively charged, and the electrode mesh is negatively charged), the gap between the sterilization chamber and the electrode mesh is discharged by utilizing the larger voltage difference between the sterilization chamber and the electrode mesh, so that a chemical sterilization medium (hydrogen peroxide gas or glutaraldehyde gas) in the sterilization chamber is excited into a plasma state, the electrode mesh arranged in the medical plasma sterilizer has a specific shape as shown in fig. 15, wherein the electrode mesh 71 is of a hollow tetragonal structure, two ends of the electrode mesh are open, the electrode mesh is formed by bending an aluminum alloy or stainless steel plate with the wall thickness of 0.5-2 mm, and a plurality of circular or oval through holes are formed around the electrode mesh 71 to facilitate discharging. The conventional electrode net is often cut, punched and bent during processing, and each process is processed by different equipment, so that the occupied area of the equipment is increased, a worker is required to manually process each process during processing, the processed workpiece needs to be carried after each process is finished, the workload of the worker is increased, and the processing efficiency is low.

Disclosure of Invention

Aiming at the defects in the prior art, the invention particularly provides automatic processing equipment with an electrode net arranged in a medical plasma sterilizer.

In order to achieve the purpose, the invention adopts the following technical scheme:

an automatic processing device for an electrode net in a medical plasma sterilizer comprises a feeding mechanism, a pressing mechanism, a quantitative cutting mechanism, a bending mechanism and a support frame, wherein the feeding mechanism is arranged beside the support frame, the quantitative cutting mechanism, the pressing mechanism and the bending mechanism are all fixedly arranged at the top of the support frame, the feeding mechanism, the quantitative cutting mechanism, the pressing mechanism and the bending mechanism are sequentially arranged in a straight line, the quantitative cutting mechanism comprises a cutting mechanism and a moving mechanism, the moving mechanism comprises a first mounting plate, a first electric sliding table, a limiting mechanism, a suction mechanism and two first support plates, the two first support plates are all fixedly arranged at the top of the support frame, the first mounting plate is fixedly arranged at the top of the two first support plates, the first electric sliding table is fixedly arranged at the bottom of the first mounting plate, and an extension plate is fixedly arranged on a sliding seat of the first electric sliding table, the tight mechanism of inhaling is fixed to be set up in the bottom of extension board, and stop gear is fixed to be set up on two first backup pads, and the distance between stop gear and the blank mechanism equals to wait to cut the electrode net length that takes shape.

The automatic processing equipment of establishing electrode net preferred scheme in medical plasma sterilizer as, inhale tight mechanism and include first triaxial cylinder, a plurality of sucking disc, air supply and sucking disc mounting panel, the fixed bottom that sets up at the extension board of first triaxial cylinder, the output of first triaxial cylinder is perpendicular towards the bottom of support frame, and the output and the sucking disc mounting panel fixed connection of first triaxial cylinder, a plurality of sucking disc is all fixed to be set up on the sucking disc mounting panel, and the suction inlet of sucking disc is perpendicular towards the bottom of support frame, the sucking disc passes through the air duct and is connected with the air supply, the fixed top that sets up at first mounting panel of air supply.

As an establish electrode mesh's automatic processing equipment's preferred scheme in medical plasma sterilizer, stop gear includes the bar limiting plate, first contact sensor, first conveyer belt, two L shape mounting panels and first pair of axle cylinder, two L shape mounting panels are fixed respectively and are set up on two first backup pads, the bottom of two first pair of axle cylinders all with two L shape mounting panel fixed connection respectively, the output of two first pair of axle cylinders all with the top fixed connection of bar limiting plate, the fixed outer fringe bottom that sets up at the bar limiting plate of first contact sensor, the fixed top that sets up at the support frame of first conveyer belt, and the bottom of bar limiting plate is contradicted with the top of first conveyer belt.

As an establish automatic processing equipment's of electrode net preferred scheme in medical plasma sterilizer, blank mechanism includes the cutter, the lower tool, two hydro-cylinders, the limiting plate, L shape backup pad and second backup pad, and the lower tool, two L shape backup pads and the equal fixed top that sets up at the support frame of limiting plate, distance between two limiting plates equals the width of waiting to process the electrode net, two second backup pads are all fixed to be set up on the limiting plate, and leave the clearance that supplies the cutter to pass through between two second backup pads, the fixed hydro-cylinder frame plate that is provided with in top of two L shape backup pads, the fixed top that sets up at the hydro-cylinder frame plate of hydro-cylinder, and the output of hydro-cylinder is towards the blade department of lower tool, the top of going up the cutter is all fixed to be set up on the output of two hydro-cylinders.

As a preferred scheme of automatic processing equipment for an electrode net arranged in a medical plasma sterilizer, a roller type conveyor belt is arranged beside a first conveyor belt, a rubber sleeve is arranged on a roller of the roller type conveyor belt, and the roller type conveyor belt is in transmission connection with a material pressing mechanism through a connecting plate.

As a preferred scheme of automatic processing equipment for an electrode net arranged in a medical plasma sterilizer, a material pressing mechanism comprises a press machine, a support plate, a female die, a male die and a plurality of male die support plates, wherein the plurality of male die support plates are fixedly connected through a second mounting plate, the second mounting plate is fixedly arranged at the top of a support frame, the male die is fixedly arranged at the top of the male die support plates, the top of each male die support plate is fixedly provided with two L-shaped guide plates, the two L-shaped guide plates are respectively attached to two sides of the width of the male die, the female die is arranged under the male die, the top of the male die is fixedly provided with four lower pressure columns, the four lower pressure columns penetrate through the support plate and are in transmission connection with the press machine, the support plate is fixedly arranged at the bottom of the press machine, the side of the support plate is provided with four, the female die is provided with a groove for the protrusion to punch a hole, four through holes are formed in four corners of the male die, a guide pillar is arranged on each through hole, each guide pillar is equally connected with the corresponding through hole in a sliding mode, the male die penetrates through the bottom of the guide pillar, an annular pressing block is fixedly arranged at the bottom of the guide pillar, a spring is sleeved on the guide pillar, two ends of the spring are respectively abutted to the bottoms of the annular pressing block and the male die, a clamping block is fixedly arranged at the top of the guide pillar, and the bottom of the clamping block is abutted to the top of.

As an optimal scheme of automatic processing equipment for the built-in electrode mesh in the medical plasma sterilizer, the material pressing mechanism further comprises a material baffle plate, a second contact sensor, two second double-shaft cylinders and two groups of symmetrically arranged grabbing mechanisms, wherein the second contact sensor is fixedly arranged at the top of the outer edge of the material baffle plate, the two second double-shaft cylinders are fixedly arranged at the top of the support frame, the output ends of the two second double-shaft cylinders are fixedly connected with the material baffle plate, the material baffle plate is positioned at the upper end of the support frame, and the two grabbing mechanisms are symmetrically arranged on two sides of the material baffle plate.

As an establish the preferred scheme of the automatic processing equipment of electrode net in medical plasma sterilizer, every snatchs the mechanism and all includes the finger cylinder, two clamping jaws and the electronic slip table of second, the fixed top that sets up at the support frame of the electronic slip table of second, and the direction of operation of the slide rail direction perpendicular to equipment of the electronic slip table of second, the fixed third mounting panel that is provided with in top of the electronic slip table of second, the finger cylinder is fixed to be set up on the third mounting panel, and the direction of operation perpendicular to the electronic slip table of second's slide rail direction of the electronic slip table of finger cylinder, two clamping jaws are all fixed to be set up on the output of finger cylinder, the inboard of the electronic slip table of two second is fixed and is provided with a second conveyer belt, the second conveyer belt passes through supporting seat and support frame fixed connection, the.

As a preferred scheme of automatic processing equipment for an electrode mesh in a medical plasma sterilizer, a bending mechanism comprises a bending seat, a third three-axis cylinder, a pressure plate, a top plate and two second three-axis cylinders, wherein the bending seat is fixedly arranged at the top of a support frame, the two second three-axis cylinders are fixedly arranged at the top of the bending seat, the inner sides of the two bending seats are fixedly provided with two bending baffles, the distance between the inner sides of the two bending baffles is equal to the width of the electrode mesh, the output ends of the two second three-axis cylinders are fixedly connected through a fourth mounting plate, the pressure plate is fixedly arranged at the bottom of the fourth mounting plate, the length direction of the pressure plate is smaller than the distance between the inner sides of the two bending baffles, the third three-axis cylinder is fixedly arranged at the top of the support frame, the top plate is fixedly arranged at the output end of the third three-axis cylinder, and the third three-axis cylinder is positioned, one side of the length direction of the top plate is attached to the bending seat, the other side of the top plate is provided with a material blocking box, one side of the material blocking box, which is close to the top plate, is provided with two heightening plates for fixing the bottom of the opening mechanism and the material blocking box, the bottom of each heightening plate is fixedly connected with the support frame, and one side of the material blocking box, which is far away from the top plate, is fixedly provided with a third contact sensor.

As an establish electrode mesh's automatic processing equipment's preferred scheme in medical plasma sterilizer, feed mechanism includes the material loading roller, material loading frame, alignment jig and two regulating rollers, the material loading roller can the pivoted setting on material loading frame, the alignment jig is located one side that the material loading roller is close to quantitative cutting mechanism, and the both sides of two regulating rollers all are provided with the installation piece, and the setting that the alignment roller can rotate is on the installation piece, every installation piece homoenergetic gliding setting is on the alignment jig, leave the clearance that equals electrode mesh thickness between two regulating rollers.

The invention has the beneficial effects that: according to the automatic processing equipment for the electrode mesh arranged in the medical plasma sterilizer, three processes of cutting, punching and bending are realized through one equipment, so that the occupied area of the equipment is reduced, and after each process is finished, the continuous automatic work of a production line is realized.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required to be used in the embodiments of the present invention will be briefly described below. It is obvious that the drawings described below are only some embodiments of the invention, and that for a person skilled in the art, other drawings can be derived from them without inventive effort.

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of the present invention.

Fig. 3 is an exploded perspective view of the material moving mechanism.

Fig. 4 is an exploded perspective view of the blanking mechanism.

Fig. 5 is a partial perspective exploded view of the present invention.

Fig. 6 is an exploded perspective view of the pressing mechanism.

Fig. 7 is a partially enlarged view of fig. 6 at B.

Fig. 8 is a schematic perspective view of the male mold.

Fig. 9 is a partial perspective view of the first embodiment of the present invention.

Fig. 10 is a partial enlarged view of fig. 9 at C.

Fig. 11 is a partially enlarged view of a portion a of fig. 1.

Fig. 12 is a partial perspective view illustrating a second embodiment of the present invention.

Fig. 13 is an exploded perspective view of the bending mechanism.

Fig. 14 is an exploded perspective view of the feeding mechanism.

FIG. 15 is a structural view of an electrode net installed in a medical plasma sterilizer

In the figure: 1. a feeding mechanism; 2. a material pressing mechanism; 3. a quantitative cutting mechanism; 4. a bending mechanism; 5. a support frame; 6. a material cutting mechanism; 7. a material moving mechanism; 8. a first mounting plate; 9. a first electric sliding table; 10. a first support plate; 11. an extension plate; 12. a first triaxial cylinder; 13. a suction cup; 14. a sucker mounting plate; 15. an L-shaped mounting plate; 16. a strip-shaped limiting plate; 17. a first contact sensor; 18. a first double-shaft cylinder; 19. a first conveyor belt; 20. feeding a cutter; 21. a lower cutter; 22. an oil cylinder; 23. a limiting plate; 24. an L-shaped support plate; 25. a second support plate; 26. an oil cylinder frame plate; 27. a roller conveyor belt; 28. a rubber sleeve; 29. a connecting plate; 30. a press machine; 31. a pillar; 32. a support plate; 33. a female die; 34. a male die; 35. a male die support plate; 36. a second mounting plate; 37. pressing the column; 38. a protrusion; 39. a groove; 40. a guide post; 41. an annular pressing block; 42. a spring; 43. a clamping block; 44. an L-shaped guide plate; 45. perforating; 46. a striker plate; 47. a second contact sensor; 48. a second double-shaft cylinder; 49. a grabbing mechanism; 50. a finger cylinder; 51. a clamping jaw; 52. a second electric sliding table; 53. a third mounting plate; 54. a second conveyor belt; 55. a supporting seat; 56. a bending seat; 57. a second triaxial cylinder; 58. pressing a plate; 59. a top plate; 60. a third triaxial cylinder; 61. bending the baffle; 62. a fourth mounting plate; 63. a material blocking box; 64. heightening plates; 65. a third contact sensor; 66. a feeding roller; 67. a feeding frame; 68. an adjusting bracket; 69. a regulating roller; 70. mounting blocks; 71. an electrode mesh.

Detailed Description

The technical scheme of the invention is further explained by the specific implementation mode in combination with the attached drawings.

The electrode mesh arranged in the medical plasma sterilizer has a specific shape as shown in fig. 15, wherein the electrode mesh 71 is of a hollow tetragonal structure, two ends of the electrode mesh are open, the electrode mesh is formed by bending an aluminum alloy or stainless steel plate with the wall thickness of 0.5-2 mm, and a plurality of circular or oval through holes are formed around the electrode mesh 71 to facilitate discharging.

Referring to fig. 1 to 14, the automatic processing equipment for an internal electrode mesh of a medical plasma sterilizer comprises a feeding mechanism 1, a pressing mechanism 2, a quantitative cutting mechanism 3, a bending mechanism 4 and a support frame 5, wherein the feeding mechanism 1 is arranged beside the support frame 5, the quantitative cutting mechanism 3, the pressing mechanism 2 and the bending mechanism 4 are all fixedly arranged at the top of the support frame 5, the feeding mechanism 1, the quantitative cutting mechanism 3, the pressing mechanism 2 and the bending mechanism 4 are sequentially arranged in a straight line, the quantitative cutting mechanism 3 comprises a cutting mechanism 6 and a material moving mechanism 7, the material moving mechanism 7 comprises a first mounting plate 8, a first electric sliding table 9, a limiting mechanism, a suction mechanism and two first support plates 10, the two first support plates 10 are all fixedly arranged at the top of the support frame 5, the first mounting plate 8 is fixedly arranged at the tops of the two first support plates 10, the first electric sliding table 9 is fixedly arranged at the bottoms of the first mounting plates 8, an extension plate 11 is fixedly arranged on a sliding seat of the first electric sliding table 9, a suction mechanism is fixedly arranged at the bottom of the extension plate 11, a limiting mechanism is fixedly arranged on the two first supporting plates 10, and the distance between the limiting mechanism and the cutting mechanism 6 is equal to the length of an electrode mesh to be cut and formed (namely the circumference of the four sides of the cross section of the square electrode mesh).

Inhale tight mechanism and include first triaxial cylinder 12, a plurality of sucking disc 13, air supply and sucking disc mounting panel 14, first triaxial cylinder 12 is fixed to be set up in the bottom of extension board 11, the output of first triaxial cylinder 12 is perpendicular downwards towards support frame 5, and the output of first triaxial cylinder 12 and sucking disc mounting panel 14 fixed connection, a plurality of sucking disc 13 is all fixed to be set up on sucking disc mounting panel 14, and the suction inlet of sucking disc 13 is perpendicular downwards towards support frame 5, sucking disc 13 passes through the air duct and is connected with the air supply, the fixed top that sets up at first mounting panel 8 of air supply. When equipment needs to be started, firstly, the electrode net to be processed is pulled and placed on the quantitative cutting mechanism 3 through the manual work, the first electric sliding table 9 is started, and further the first electric sliding table 9 is made to drive the extension plate 11 to move, the extension plate 11 is made to drive the sucking mechanism to move towards the electrode net to be processed, when the sliding seat of the first electric sliding table 9 moves to the top of the rail, the first triaxial cylinder 12 is driven downwards, and further the sucking disc 13 is made to contact with the electrode net to be processed, and then the sucking disc 13 is made to suck the electrode net to be processed through the starting of the air source, and then the sucking disc 13 is made to suck the electrode net to be processed, and the first electric sliding table 9 is made to move again, the electrode net to be processed is driven to collide with the limiting mechanism to stop, the cutting mechanism 6 is started, and the.

Stop gear includes bar limiting plate 16, first contact sensor 17, first conveyer belt 19, two L shape mounting panels 15 and first pair of axle cylinder 18, two L shape mounting panels 15 are fixed respectively and are set up on two first backup pads 10, the bottom of two first pair of axle cylinders 18 respectively with two L shape mounting panels 15 fixed connection, the output of two first pair of axle cylinders 18 and the top fixed connection of bar limiting plate 16, first contact sensor 17 is fixed to be set up in the outer fringe bottom of bar limiting plate 16, first conveyer belt 19 is fixed to be set up at the top of support frame 5, under the promotion of first pair of axle cylinder 18, the bottom of bar limiting plate 16 can be close to or the contact to the top of first conveyer belt 19. Bar limiting plate 16 is the normally closed state, when the electrode net that treats processing contacts the first contact sensor 17 on bar limiting plate 16, first contact sensor 17 gives the controller with signal of telecommunication, the electrode net that the processing was treated to controller control blank mechanism 6 cuts, treat the electrode net cutting completion back of processing when blank mechanism 6, signal of telecommunication after the cutting completion will be given the controller, the controller will control first double-shaft cylinder 18 and upwards withdraw, make the electrode net after the cutting completion convey next process through the effect of first conveyer belt 19.

Blank mechanism 6 includes cutter 20, lower tool 21, two hydro-cylinders 22, limiting plate 23, L shape backup pad 24 and second backup pad 25, and lower tool 21, two L shape backup pads 24 and limiting plate 23 are all fixed to be set up at the top of support frame 5, distance between two limiting plates 23 equals the width of treating the processing electrode net (being the distance between the two open ends of square electrode net), two second backup pads 25 are all fixed to be set up on limiting plate 23, and leave the clearance that supplies cutter 20 to pass through between two second backup pads 25, the fixed hydro-cylinder frame board 26 that is provided with in top of two L shape backup pads 24, hydro-cylinder 22 is fixed to be set up at the top of hydro-cylinder frame board 26, and the output of hydro-cylinder 22 is towards the sword mouth department of lower tool 21, the top of going up cutter 20 is all fixed to be set up on the output of two hydro-cylinders 22. Through the effect of two limiting plates 23 for when cutting the electrode net, the electrode net can not because the skew about the motion of first conveyer belt 19 takes place, when the electrode net of treating processing places the completion through moving material mechanism 7, drives hydro-cylinder 22 through the controller and moves downwards, and then makes hydro-cylinder 22 drive cutter 20 and move downwards, through the combined action of last cutter 20 and bottom knife 21, and then cuts the electrode net of treating processing.

A roller type conveyor belt 27 is arranged beside the first conveyor belt 19, a rubber sleeve 28 is arranged on a roller of the roller type conveyor belt 27, and the roller type conveyor belt 27 is in transmission connection with the material pressing mechanism 2 through a connecting plate 29. Because when the electrode net after the completion of cutting conveys, area of contact on the conveyer belt reduces gradually, make first conveyer belt 19 be difficult to convey the electrode net after the completion of cutting, through installing roll-type conveyer belt 27 and rubber sleeve 28 additional, frictional force when having increased the electrode net after the completion of cutting and conveying, and then when making the electrode net after the completion of cutting convey, can not take place unable driven condition, effect through connecting plate 29, make the electrode net after the completion of cutting more be convenient for convey on swager 2.

The material pressing mechanism 2 comprises a press machine 30, a support plate 32, a female die 33, a male die 34 and a plurality of male die support plates 35, wherein the plurality of male die support plates 35 are fixedly connected through a second mounting plate 36, the second mounting plate 36 is fixedly arranged at the top of the support frame 5, the male die 34 is fixedly arranged at the top of the male die support plates 35, two L-shaped guide plates 44 are fixedly arranged at the top of the male die support plates 35, the two L-shaped guide plates 44 are respectively attached to two sides of the width of the male die 34, the female die 33 is arranged right below the male die 34, four lower pressure columns 37 are fixedly arranged at the top of the male die 34, the four lower pressure columns 37 penetrate through the support plate 32 and are in transmission connection with the press machine 30, the support plate 32 is fixedly arranged at the bottom of the press machine 30, the support plate 32 is provided with four support columns 31, the lower ends of the four support, the female die 33 is provided with a groove 39 for the protrusion 38 to punch, four corners of the male die 34 are provided with four through holes 45, each through hole 45 is provided with a guide pillar 40, each guide pillar 40 is connected with the corresponding through hole 45 in a sliding mode, the bottom of each guide pillar 40 penetrates through the male die 34, an annular pressing block 41 is fixedly arranged at the bottom of each guide pillar 40, a spring 42 is sleeved on each guide pillar 40, two ends of each spring 42 respectively abut against the annular pressing block 41 and the bottom of the male die 34, a clamping block 43 is fixedly arranged at the top of each guide pillar 40, and the bottom of each clamping block 43 abuts against the top of the male die 34. The press machine 30 drives the four lower pressing columns 37 to move, the lower pressing columns 37 drive the male die 34 to move up and down, the press machine 30 drives the male die 34 to move down, the annular pressing block 41 compresses the electrode mesh firstly, the press machine 30 continues to drive the male die 34 to move down, the guide post 40 continues to withdraw upwards through the action of the perforation 45, the convex die 34 continues to move downwards, the male die 34 and the female die 33 interact, the electrode mesh after cutting is punched, the press machine 30 drives the four lower pressing columns 37 to move upwards after punching is completed, the male die 34 is driven to move upwards, the annular pressing block 41 is enabled to be restored to the position where the cutting is just started through the action of the spring 42, and the annular clamping block 43 and the guide post 40 cannot fall off from the male die 34.

The material pressing mechanism 2 further comprises a material blocking plate 46, a second contact sensor 47, two second double-shaft cylinders 48 and two groups of symmetrically-arranged grabbing mechanisms 49, the second contact sensor 47 is arranged at the top of the outer edge of the material blocking plate 46, the two second double-shaft cylinders 48 are fixedly arranged at the top of the support frame 5, the output ends of the two second double-shaft cylinders 48 are connected with the material blocking plate 46, the material blocking plate 46 is located at the upper end of the support frame 5, and the two grabbing mechanisms 49 are symmetrically arranged on two sides of the material blocking plate 46. Electrode net after the cutting is accomplished passes through the conveying of roll-type conveyer belt 27, when conflicting second contact sensor 47 on striker plate 46, second contact sensor 47 gives the controller with electric signal transmission, the controller just controls press 30 and works, after the processing of punching to electrode net is accomplished, press 30 will give the controller to the electric signal transmission after the process is accomplished, the controller just controls snatchs mechanism 49 and snatchs electrode net, after snatching the completion, the controller just controls second double-shaft cylinder 48 downstream, make and snatch mechanism 49 and can drive electrode net and remove.

Every snatchs mechanism 49 and all includes finger cylinder 50, two clamping jaws 51 and the electronic slip table 52 of second, the fixed top that sets up at support frame 5 of the electronic slip table 52 of second, and the slide rail direction perpendicular to equipment's of the electronic slip table 52 of second working direction, the fixed third mounting panel 53 that is provided with in top of the electronic slip table 52 of second, finger cylinder 50 is fixed to be set up on third mounting panel 53, and finger cylinder 50's working direction perpendicular to second electronic slip table 52's slide rail direction, two clamping jaws 51 are all fixed to be set up on the output of finger cylinder 50, the inboard of two electronic slip tables 52 of second is fixed and is provided with second conveyer belt 54, second conveyer belt 54 passes through supporting seat 55 and support frame 5 fixed connection, supporting seat 55 is fixed to be set up at the top of support frame 5. After the grabbing mechanism 49 grabs the electrode mesh, the second electric sliding table 52 drives the electrode mesh to move towards the bending mechanism 4, after the electrode mesh is moved in place, the second electric sliding table 52 transmits a signal to the controller, the controller controls the press machine 30 to work, after the second electric sliding table 52 and the press machine 30 work, the finger cylinder 50 is loosened, and the punched electrode mesh is transmitted to the bending mechanism 4 through the transmission effect of the second transmission belt 54.

The bending mechanism 4 comprises a bending seat 56, a third triaxial cylinder 60, a pressing plate 58, a top plate 59 and two second triaxial cylinders 57, the bending seat 56 is fixedly arranged at the top of the support frame 5, the two second triaxial cylinders 57 are fixedly arranged at the top of the bending seat 56, two bending baffles 61 are fixedly arranged at the inner sides of the two bending seats 56, the distance between the inner sides of the two bending baffles 61 is equal to the width of the electrode mesh, the output ends of the two second triaxial cylinders 57 are fixedly connected through a fourth mounting plate 62, the pressing plate 58 is fixedly arranged at the bottom of the fourth mounting plate 62, the length of the pressing plate 58 is smaller than the distance between the inner sides of the two bending baffles 61, the third triaxial cylinder 60 is fixedly arranged at the top of the support frame 5, the top plate 59 is fixedly arranged at the output end of the third triaxial cylinder 60, and the third triaxial cylinder 60 is positioned at the triaxial cylinder 60 far side of the bending seat 56 from the second conveyor, one side of the length direction of the top plate 59 is attached to the bending seat 56, the other side of the top plate 59 is provided with a material blocking box 63, one side, close to the top plate 59, of the material blocking box 63 is an opening mechanism, two heightening plates 64 are fixedly arranged at the bottom of the material blocking box 63, the bottoms of the heightening plates 64 are fixedly connected with the support frame 5, and a third contact sensor 65 is fixedly arranged on one side, far away from the top plate 59, of the material blocking box 63. Through the transmission action of the second conveyor belt 54, the top of the punched electrode net is abutted against the third contact sensor 65, the sensor transmits an electric signal to the controller, the controller controls the second triaxial cylinder 57 to move downwards, so that the bottom of the pressing plate 58 presses the electrode net on the bending seat 56, and then controls the third triaxial cylinder 60 to move upwards, so that the electrode net is bent, after the electrode net is bent for the first time, the controller controls the second triaxial cylinder 57 to move upwards, the third triaxial cylinder 60 moves downwards, the electrode net continues to move under the action of the second conveyor belt 54, so that the electrode net contacts the third contact sensor 65 again, so that the electrode net is bent again, after the electrode net is bent for three times, the electrode net is bent and formed, as shown in detail in fig. 13, the bent and formed electrode net is clamped on the fourth mounting plate 62, because the electrode net is of an open structure, the electrode net is taken down from the bending mechanism 4 by workers.

As shown in fig. 14, the feeding mechanism 1 includes a feeding roller 66, a feeding frame 67, an adjusting frame 68 and two adjusting rollers 69, the feeding roller 66 is rotatably disposed on the feeding frame 67, the adjusting frame 68 is located on one side of the feeding roller 66 close to the quantitative cutting mechanism 3, mounting blocks 70 are disposed on two sides of the two adjusting rollers 69, the adjusting rollers 69 are rotatably disposed on the mounting blocks 70, the mounting blocks 70 are disposed on the adjusting frame 68, and a gap equal to the thickness of the electrode mesh is reserved between the two adjusting rollers 69. The electrode web to be processed is manually loaded onto the loading roll 66, drawn through the space between the two adjusting rolls 69 and placed on the quantitative cutting mechanism 3.

The working principle is as follows: firstly, an electrode mesh plate material to be processed is installed on a feeding roller 66 manually, the electrode mesh plate material passes through the gap between two adjusting rollers 69, then the electrode mesh plate material to be processed is placed on a quantitative cutting mechanism 3 manually, a first electric sliding table 9 is started, and further the first electric sliding table 9 drives an extension plate 11 to move, so that the extension plate 11 drives a suction mechanism to move towards the electrode mesh direction to be processed, when a sliding seat of the first electric sliding table 9 moves to the topmost part of a track, a three-shaft cylinder drives downwards, so that a sucker 13 contacts the electrode mesh to be processed, then the sucker 13 props against the electrode mesh to be processed by starting an air source, the sucker 13 props against the electrode mesh to be processed tightly, then the electrode mesh to be processed is driven to a limiting mechanism by the movement of the first electric sliding table 9 to stop, a cutting mechanism 6 is started, and the electrode mesh to be processed is cut, after the cutting mechanism 6 finishes cutting the electrode mesh to be processed, the cut electric signal is transmitted to the controller, the controller controls the first double-shaft cylinder 18 to withdraw upwards, so that the electrode mesh after cutting is continuously transmitted to the roller-type conveyor belt 27 forwards under the action of the first conveyor belt 19, when the electrode mesh after cutting is transmitted by the roller-type conveyor belt 27 and collides with the second contact sensor 47 on the material baffle plate 46, the second contact sensor 47 transmits the electric signal to the controller, the controller controls the press machine 30 to work, the press machine 30 drives the four lower pressing columns 37 to move, the lower pressing columns 37 drive the male die 34 to press downwards, the annular pressing block 41 is firstly pressed to the electrode mesh after cutting, the press machine 30 continuously drives the male die 34 to move downwards, and the guide column 40 is continuously withdrawn upwards under the action of the perforation 45, then the male die 34 continues to move downwards, so that the male die 34 and the female die 33 interact with each other, thereby punching the cut electrode mesh is realized, after punching is completed, the press machine 30 drives the four lower pressing columns 37 to move upwards to drive the male die 34 to move upwards, after one-time punching is completed on the electrode mesh, the press machine 30 transmits an electric signal after the completion of the process to the controller, the controller controls the grabbing mechanism 49 to grab the electrode mesh, after grabbing is completed, the controller controls the second double-shaft cylinder 48 to move downwards, so that the grabbing mechanism 49 can drive the electrode mesh to move, after the grabbing mechanism 49 grabs the electrode mesh, the second electric sliding table 52 drives the electrode mesh to move towards the bending mechanism 4 for one punching station, after movement is completed, the second electric sliding table 52 transmits a signal to the controller, and the controller controls the press machine 30 to work, after the second electric sliding table 52 and the press machine 30 are finished, the finger cylinder 50 will be loosened, the punched electrode mesh is conveyed to the bending mechanism 4 by the conveying action of the second conveying belt 54, the top of the punched electrode mesh is abutted to the third contact sensor 65 by the conveying action of the second conveying belt 54, the sensor transmits an electric signal to the controller, the controller controls the second three-axis cylinder 57 to move downwards, the electrode mesh is pressed on the bending seat 56 by the bottom of the pressing plate 58, the electrode mesh is bent by controlling the third three-axis cylinder 60 to move upwards, after the electrode mesh is bent for the first time, the controller controls the second three-axis cylinder 57 to move upwards, the third three-axis cylinder 60 moves downwards, the electrode mesh continues to move under the action of the second conveying belt 54, and the electrode mesh is contacted with the third contact sensor 65 again, make the electrode net once more bent, after bending the cubic, the electrode net will block on fourth mounting panel 62, because the electrode net is open structure, takes off the electrode net from bending mechanism 4 through the workman.

It should be understood that the above-described embodiments are merely preferred embodiments of the invention and the technical principles applied thereto. It will be understood by those skilled in the art that various modifications, equivalents, changes, and the like can be made to the present invention. However, such variations are within the scope of the invention as long as they do not depart from the spirit of the invention. In addition, certain terms used in the specification and claims of the present application are not limiting, but are used merely for convenience of description.

Claims (10)

1. An automatic processing device for an electrode mesh in a medical plasma sterilizer is characterized by comprising a feeding mechanism (1), a pressing mechanism (2), a quantitative cutting mechanism (3), a bending mechanism (4) and a support frame (5), wherein the feeding mechanism (1) is positioned beside the support frame (5), the quantitative cutting mechanism (3), the pressing mechanism (2) and the bending mechanism (4) are arranged at the top of the support frame (5), the quantitative cutting mechanism (3) comprises a cutting mechanism (6) and a moving mechanism (7), the moving mechanism (7) comprises a first mounting plate (8), a first electric sliding table (9), a limiting mechanism, a suction mechanism and two first support plates (10), the two first support plates (10) are arranged at the top of the support frame (5), the first mounting plate (8) is arranged at the top of the two first support plates (10), the first electric sliding table (9) is arranged at the bottom of the first mounting plate (8), an extension plate (11) is arranged on a sliding seat of the first electric sliding table (9), a suction mechanism is arranged at the bottom of the extension plate (11), and a limiting mechanism is arranged on the two first supporting plates (10).

2. The automatic processing equipment for the internal electrode mesh of the medical plasma sterilizer as claimed in claim 1, wherein the tight suction mechanism comprises a first triaxial cylinder (12), a plurality of suckers (13), an air source and a sucker mounting plate (14), the first triaxial cylinder (12) is arranged at the bottom of the extension plate (11), the output end of the first triaxial cylinder (12) vertically faces downwards to the support frame (5), the output end of the first triaxial cylinder (12) is fixedly connected with the sucker mounting plate (14), the plurality of suckers (13) are arranged on the sucker mounting plate (14), the suction ports of the suckers (13) vertically face downwards to the support frame (5), the suckers (13) are connected with the air source through air guide pipes, and the air source is arranged on the first mounting plate (8).

3. The automatic processing equipment of electrode mesh in medical plasma sterilizer according to claim 1, the device is characterized in that the limiting mechanism comprises a strip-shaped limiting plate (16), a first contact sensor (17), a first conveyor belt (19), two L-shaped mounting plates (15) and first double-shaft cylinders (18), the two L-shaped mounting plates (15) are fixedly arranged on two first supporting plates (10) respectively, the bottoms of the two first double-shaft cylinders (18) are connected with the two L-shaped mounting plates (15) respectively, the output ends of the two first double-shaft cylinders (18) are connected with the top of the strip-shaped limiting plate (16), the first contact sensor (17) is arranged at the bottom of the outer edge of the strip-shaped limiting plate (16), the first conveyor belt (19) is arranged at the top of the supporting frame (5), under the pushing of the first double-shaft cylinder (18), the bottom of the strip-shaped limiting plate (16) can be close to or contacted with the top of the first conveyor belt (19).

4. The automatic processing equipment for the electrode mesh in the medical plasma sterilizer according to claim 1, wherein the cutting mechanism (6) comprises an upper cutter (20), a lower cutter (21), two oil cylinders (22), limiting plates (23), L-shaped supporting plates (24) and second supporting plates (25), the lower cutter (21), the two L-shaped supporting plates (24) and the limiting plates (23) are all arranged at the top of the support frame (5), the distance between the two limiting plates (23) is equal to the width of the electrode mesh to be processed, the two second supporting plates (25) are all arranged on the limiting plates (23), a gap for the upper cutter (20) to pass through is reserved between the two second supporting plates (25), an oil cylinder frame plate (26) is arranged at the top of the two L-shaped supporting plates (24), the oil cylinders (22) are arranged on the oil cylinder frame plate (26), the output ends of the oil cylinders (22) face the cutting edge of the lower cutter (21), the top of the upper cutter (20) is arranged on the output ends of the two oil cylinders (22).

5. The automatic processing equipment for the internal electrode mesh of the medical plasma sterilizer as claimed in claim 3, wherein a roller conveyor belt (27) is arranged beside the first conveyor belt (19), a rubber sleeve (28) is arranged on a roller of the roller conveyor belt (27), and the roller conveyor belt (27) is in transmission connection with the material pressing mechanism (2) through a connecting plate (29).

6. The automatic processing equipment for the electrode mesh arranged in the medical plasma sterilizer as claimed in claim 1, wherein the pressing mechanism (2) comprises a press machine (30), a support plate (32), a female die (33), a male die (34) and a plurality of male die support plates (35), the plurality of male die support plates (35) are all connected through a second mounting plate (36), the second mounting plate (36) is arranged at the top of the support frame (5), the male die (34) is arranged at the top of the male die support plate (35), the top of the male die support plate (35) is provided with two L-shaped guide plates (44), the two L-shaped guide plates (44) are both attached to two sides of the width of the male die (34), the female die (33) is arranged below the male die (34), the top of the male die (34) is provided with four lower pressing columns (37), and the four lower pressing columns (37) pass through the support plate (32) and are in transmission connection with the, the support plate (32) is arranged at the bottom of the press machine (30), four support columns (31) are arranged beside the support plate (32), protrusions (38) used for punching the electrode mesh are arranged on the male die (34), grooves (39) used for punching the protrusions (38) are arranged on the female die (33), four through holes (45) are formed in four corners of the male die (34), guide pillars (40) are arranged on each through hole (45), each guide pillar (40) is respectively in sliding connection with the corresponding through hole (45), the male die (34) is penetrated through the bottom of each guide pillar (40), and the bottom of the guide post (40) is provided with an annular pressing block (41), the guide post (40) is sleeved with a spring (42), two ends of the spring (42) are respectively abutted to the annular pressing block (41) and the bottom of the male die (34), the top of the guide post (40) is provided with a clamping block (43), and the bottom of the clamping block (43) is abutted to the top of the male die (34).

7. The automatic processing equipment for the internal electrode mesh of the medical plasma sterilizer as claimed in claim 6, wherein the material pressing mechanism (2) further comprises a material baffle plate (46), a second contact sensor (47), two second double-shaft cylinders (48) and two sets of symmetrically arranged grabbing mechanisms (49), the second contact sensor (47) is arranged at the top of the outer edge of the material baffle plate (46), the two second double-shaft cylinders (48) are arranged at the top of the support frame (5) and the output ends of the two second double-shaft cylinders (48) are connected with the material baffle plate (46), the material baffle plate (46) is positioned at the upper end of the support frame (5), and the two grabbing mechanisms (49) are symmetrically arranged at two sides of the material baffle plate (46).

8. The automatic processing equipment for the electrode mesh arranged in the medical plasma sterilizer as claimed in claim 7, wherein each grabbing mechanism (49) comprises a finger cylinder (50), two clamping jaws (51) and a second electric sliding table (52), the second electric sliding table (52) is arranged at the top of the support frame (5), the direction of the sliding rail of the second electric sliding table (52) is perpendicular to the working direction of the equipment, the top of the second electric sliding table (52) is provided with a third mounting plate (53), the finger cylinder (50) is arranged on the third mounting plate (53), the working direction of the finger cylinder (50) is perpendicular to the direction of the sliding rail of the second electric sliding table (52), the two clamping jaws (51) are arranged at the output end of the finger cylinder (50), the inner sides of the two second electric sliding tables (52) are provided with a second conveyor belt (54), and the second conveyor belt (54) is connected with the support frame (5) through a support seat (55), the supporting seat (55) is arranged at the top of the supporting frame (5).

9. The automatic processing equipment for the electrode mesh arranged in the medical plasma sterilizer as claimed in claim 8, wherein the bending mechanism (4) comprises a bending seat (56), a third triaxial cylinder (60), a pressing plate (58), a top plate (59) and two second triaxial cylinders (57), the bending seat (56) is arranged at the top of the support frame (5), the two second triaxial cylinders (57) are arranged at the top of the bending seat (56), the inner sides of the two bending seats (56) are provided with two bending baffles (61), the distance between the inner sides of the two bending baffles (61) is equal to the width of the electrode mesh, the output ends of the two second triaxial cylinders (57) are connected through a fourth mounting plate (62), the pressing plate (58) is arranged at the bottom of the fourth mounting plate (62), the length direction of the pressing plate (58) is smaller than the distance between the inner sides of the two bending baffles (61), the third triaxial cylinder (60) is arranged at the top of the support frame (5), the roof (59) is established on the output end of third triaxial cylinder (60), and third triaxial cylinder (60) are located one side that second conveyer belt (54) were kept away from in seat of bending (56), one side and seat of bending (56) laminating of roof (59) length direction, and the opposite side of roof (59) is equipped with fender box (63), one side that fender box (63) are close to roof (59) is opening mechanism, and the bottom of fender box (63) is equipped with two and increases board (64), the bottom that increases board (64) is connected with support frame (5), one side that roof (59) were kept away from in fender box (63) is equipped with third contact pick-up ware (65).

10. The automatic processing equipment for the electrode mesh in the medical plasma sterilizer as claimed in claim 1, wherein the feeding mechanism (1) comprises a feeding roller (66), a feeding frame (67), an adjusting frame (68) and two adjusting rollers (69), the feeding roller (66) is rotatably arranged on the feeding frame (67), the adjusting frame (68) is positioned on one side of the feeding roller (66) close to the quantitative cutting mechanism (3), mounting blocks (70) are arranged on both sides of the two adjusting rollers (69), the adjusting rollers (69) are rotatably arranged on the mounting blocks (70), each mounting block (70) is arranged on the adjusting frame (68), and a gap equal to the thickness of the electrode mesh is reserved between the two adjusting rollers (69).

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