CN114210882B - Double-end pin cutting device for electronic component processing - Google Patents

Abstract

The invention discloses a double-head pin cutting device for processing electronic elements, which has the technical scheme that: comprises a machine body, wherein an inner cavity of the machine body is provided with an adjusting mechanism; the adjustment mechanism includes first threaded rod, first sliding tray has all been seted up to organism inner chamber middle part both sides, first threaded rod locates inside the first sliding tray and rotates with the organism through the bearing and be connected, organism inner chamber both sides both ends all are equipped with the bracing piece, the equal fixedly connected with sliding block in bracing piece outside both ends, inside first sliding tray is located to the sliding block and with organism sliding connection, bracing piece both ends respectively fixedly connected with first support piece and second support piece, first support piece bottom is equipped with cutting assembly, second support piece bottom is equipped with the subassembly of polishing, the double-end foot cutting device that an electronic component processing was used beneficial effect is: the problem of current electronic component most two-sided all can weld the metal wire, single face cutting machine need carry out twice cutting to motor element, the comparatively waste time is solved.

Description

Double-end pin cutting device for electronic component processing

Technical Field

The invention relates to the technical field of electronic element processing, in particular to a double-head pin cutting device for electronic element processing.

Background

The pin cutter can be divided into a high-speed pin cutter and a low-speed pin cutter according to the rotating speed, and the low-speed pin cutter is generally operated by a motor with the rotating speed of a machine core below 3000 r/min; the high-speed pin cutting machine has the advantages that the rotating speed of the machine core can reach above 4500r/min through speed change, and can reach 5000r/min in some cases, but the higher the rotating speed is, the better the machine core of the pin cutting machine is, the faster the rotating speed is, so that a blade gland is easily damaged, and unnecessary troubles occur.

Most of the existing electronic component pin cutting machines are used for cutting single-sided pins of electronic components, and as most of the existing electronic components are welded with metal wires on two sides, the single-sided cutting machines need to cut motor components twice, and time is wasted relatively.

Disclosure of Invention

Therefore, the invention provides a double-head pin cutting device for processing electronic elements, which can effectively drive cutting assemblies and polishing assemblies on the upper side and the lower side of an inner cavity of a machine body to move in opposite directions or move in opposite directions through the arrangement of threads on the two ends of the outer side of a first threaded rod, so that the distance between two polishing discs and two cutting blades can be adjusted while the electronic elements are polished in double faces, and the problems that most double faces of the existing electronic elements are welded with metal wires, and a single-face cutting machine needs to cut a motor element twice and wastes time are solved.

In order to achieve the above object, the present invention provides the following technical solutions: the double-end pin cutting device for processing the electronic element comprises a machine body, wherein two sides of the machine body are respectively provided with a feed inlet and a discharge outlet, and an inner cavity of the machine body is provided with an adjusting mechanism;

the utility model provides a grinding machine for a polishing machine, including machine body inner chamber, adjustment mechanism, including first threaded rod, first sliding tray has all been seted up to machine body inner chamber middle part both sides, first threaded rod locates inside and through bearing and the machine body rotation connection of first sliding tray, first threaded rod outside both ends screw thread is opposite, first threaded rod bottom fixedly connected with first bevel gear, first rotating tray has been seted up to machine body one side bottom, first rotating tray inside rotates through the bearing and is connected with the dwang, the equal fixedly connected with second bevel gear in dwang outside both ends, second bevel gear is connected with first bevel gear meshing, machine body outside fixedly connected with sixth motor, sixth motor output and dwang one end fixed connection, machine body inner chamber both ends all are equipped with the bracing piece, the equal fixedly connected with sliding block in bracing piece outside both ends, the inside and with machine body sliding connection of first sliding tray is located to the sliding block, first threaded rod runs through the sliding block and is connected with the sliding block, the spacing groove has all been seted up at machine body inner chamber both ends, the bracing piece is close to inside both ends fixedly connected with the dwang, the stopper is located at inner wall one side both ends, inside and is equipped with second bevel gear and first bevel gear meshing connection, the second motor output end fixedly connected with first support assembly is equipped with first end, first end bottom support assembly is equipped with the first end, first end support assembly is located to cut.

Specifically, through the opposite setting of first threaded rod outside both ends screw thread, can effectually drive the cutting assembly of organism inner chamber upper and lower both sides and polish the subassembly and do opposite movement or move dorsad, and then when polishing to the electronic component two sides, can also adjust the distance between two polishing discs and two cutting blades to solve the current electronic component most two sides and all can weld the metal wire, single face cutting machine needs to carry out twice cutting to motor element, the problem of waste time.

Preferably, the first supporting piece comprises two first supporting plates and a U-shaped plate, one end of each first supporting plate is fixedly connected with the two supporting rods, and the U-shaped plate is arranged in the middle of each first supporting plate, and two ends of each U-shaped plate are respectively fixedly connected with the first supporting plates.

Preferably, the cutting assembly comprises a cutting blade, the first motor of U-shaped board top fixedly connected with, U-shaped board top axle center department is connected with the connecting rod through the bearing rotation, connecting rod top and first motor output fixedly connected with connecting block, connecting rod bottom fixedly connected with connecting block, the draw-in groove has all been seted up at connecting block bottom both ends, cutting blade top fixedly connected with fixed block, the second sliding tray has all been seted up at fixed block top both ends, fixed block top both ends all are equipped with the fixture block, fixture block bottom fixedly connected with movable block, inside and the fixed block sliding connection of second sliding tray are located to the movable block, the fixture block is located inside and cup joints with the connecting block activity of draw-in groove.

Specifically, drive cutting blade's rotation through first motor, cut the metal wire of component body both sides, cup joint through the activity between fixture block and the draw-in groove simultaneously, the dismouting of cutting blade of being convenient for is changed.

Preferably, the second sliding groove is internally connected with a second threaded rod through bearing rotation, threads at two ends of the outer side of the second threaded rod are opposite, two ends of the second threaded rod respectively penetrate through the movable block and are in threaded connection with the movable block, a rotating block is arranged on one side of the fixed block, and one end of the rotating block is fixedly connected with one end of the second threaded rod.

Specifically, through the opposite setting of second threaded rod outside both ends screw thread, can effectually drive the fixture block of both sides and do opposite movement or back to the motion, and then control the coincidence and the dismantlement between fixture block and the draw-in groove.

Preferably, the second supporting piece comprises a second supporting plate and two vertical plates, two ends of the second supporting plate are fixedly connected with the two supporting rods respectively, and the two vertical plates are arranged on two sides of the bottom of the second supporting plate and are fixedly connected with the second supporting plate.

Preferably, the polishing assembly comprises a polishing disc, a third sliding groove is formed in one side of each vertical plate, each vertical plate is internally and slidably connected with a lifting table, moving blocks are fixedly connected to the tops of two sides of each lifting table, each moving block is arranged in the third sliding groove and is slidably connected with each vertical plate, a placing cavity is formed in one side of each lifting table, a second motor is arranged in each placing cavity, the second motor is fixedly connected with the lifting table, a movable shaft is rotatably connected to the bottom of each lifting table through a bearing, one end of each movable shaft is fixedly connected with the output end of each second motor, each movable shaft penetrates through each lifting table and extends to the bottom of each lifting table, and each movable shaft is arranged at the axle center of the top of each polishing disc and is fixedly connected with the corresponding polishing disc.

Specifically, the setting through the subassembly of polishing polishes the component body both ends end of a thread after the cutting, avoids sharp cutting port to cut the operator, simultaneously because the dynamics of cutting and polishing to the component body is different for the distance between two and the component body is different with the distance between cutting blade and the component body, through the sliding connection between elevating platform and the riser, can effectually adjust alone the height of polishing dish, thereby can not damage the component body when being convenient for polish to the component body.

Preferably, the third sliding groove is internally connected with a third threaded rod through rotation, the third threaded rod penetrates through the moving block and is in threaded connection with the moving block, a third bevel gear is fixedly connected with the top of the third threaded rod, a second rotating groove is formed in the second supporting plate, a rotating shaft is rotatably connected in the second rotating groove through a bearing, fourth bevel gears are fixedly connected with the two ends of the outer side of the rotating shaft, the fourth bevel gears are in meshed connection with the third bevel gears, a first placing groove is formed in one side of the top of the second supporting plate, a third motor is arranged in the first placing groove, the third motor is arranged in the first placing groove and is fixedly connected with the second supporting plate, and one end of the rotating shaft is fixedly connected with the output end of the third motor.

Specifically, through the meshing connection between third bevel gear and the fourth bevel gear, drive the rotation of third threaded rod, through the threaded connection between third threaded rod and the elevating platform, can effectually drive the lift of elevating platform to the distance between grinding dish and the electronic component is adjusted alone.

Preferably, the transmission assembly comprises a moving table, the carriage is fixedly connected with in organism inner chamber middle part, the fourth sliding tray has all been seted up to carriage top both sides, moving table bottom fixedly connected with slider, the slider is located fourth sliding tray inside and with carriage sliding connection, the transmission groove has been seted up to moving table outside edge, the internal cavity has all been seted up to moving table both sides, the inside drive wheel that is connected with through the bearing rotation of internal cavity, moving table top fixedly connected with fourth motor, fourth motor output and drive wheel one end fixed connection, the drive wheel outside activity has cup jointed the drive belt, the drive belt is located inside the transmission groove, the inside component body that is equipped with of drive groove, the component body both sides are all located inside the transmission groove and are laminated mutually in the drive belt.

Specifically, laminating mutually through between drive belt and the component body to and the drive wheel drives drive belt pivoted setting, can effectually drive the component body and remove, simultaneously through sliding connection between mobile station and the loading board, can effectually adjust the distance between two mobile stations, thereby increased the practicality of this device, be applicable to the operation of the component body of various width.

Preferably, the fourth sliding groove is internally connected with a fourth threaded rod through bearing rotation, threads at two ends of the outer side of the fourth threaded rod are opposite, two ends of the fourth threaded rod penetrate through the sliding block and are in threaded connection with the sliding block, the top of the bearing plate is provided with a second placing groove, a fifth motor is arranged in the second placing groove, the fifth motor is arranged in the second placing groove and is fixedly connected with the bearing plate, and one end of the fourth threaded rod is fixedly connected with the output end of the fifth motor.

Specifically, through the opposite arrangement of the threads at the two ends of the outer side of the fourth threaded rod, the movable table can be effectively driven to move in opposite directions or move in opposite directions, and therefore the distance between the two movable tables is adjusted.

The embodiment of the invention has the following advantages:

1. according to the invention, the first threaded rod is driven to rotate through the meshing connection between the first bevel gear and the second bevel gear, and the cutting assemblies and the polishing assemblies on the upper side and the lower side of the inner cavity of the machine body can be effectively driven to move in opposite directions or move in opposite directions through the threaded connection between the first threaded rod and the supporting rod and the opposite arrangement of the threads at the two ends of the outer side of the first threaded rod, so that the electronic components are polished in double sides, and the problems that most of double sides of the existing electronic components are welded with metal wires, the single-sided cutting machine needs to cut the motor components twice, and time is wasted are effectively solved.

2. According to the invention, through the design that the polishing component and the cutting component are simultaneously arranged on the supporting rod, the electronic component is polished after being cut, so that the cutting injury of an operator caused by the cutting port being too sharp is avoided, and meanwhile, the distance between the two polishing components and the two cutting components can be effectively adjusted through the opposite arrangement of the threads at the two ends of the outer side of the first threaded rod, so that the practicability of the device is improved, and the cutting of electronic components with various thicknesses is facilitated.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It will be apparent to those of ordinary skill in the art that the drawings in the following description are exemplary only and that other implementations can be obtained from the extensions of the drawings provided without inventive effort.

The structures, proportions, sizes, etc. shown in the present specification are shown only for the purposes of illustration and description, and are not intended to limit the scope of the invention, which is defined by the claims, so that any structural modifications, changes in proportions, or adjustments of sizes, which do not affect the efficacy or the achievement of the present invention, should fall within the ambit of the technical disclosure.

FIG. 1 is a schematic view of the overall structure provided by the present invention;

FIG. 2 is a cross-sectional view of a machine body structure provided by the invention;

FIG. 3 is a schematic view of an adjusting mechanism according to the present invention;

FIG. 4 is a schematic view of a cutting assembly according to the present invention;

FIG. 5 is a cross-sectional view of a cutting blade configuration provided by the present invention;

FIG. 6 is a schematic view of a polishing assembly according to the present invention;

FIG. 7 is a cross-sectional view of a lifting platform according to the present invention;

FIG. 8 is a cross-sectional view of a mobile station structure provided by the present invention;

FIG. 9 is a cross-sectional view of a carrier plate structure provided by the present invention;

in the figure: 1 machine body, 2 feed inlet, 3 discharge outlet, 4 first threaded rod, 5 first sliding groove, 6 first bevel gear, 7 rotating rod, 8 second bevel gear, 9 sixth motor, 10 supporting rod, 11 sliding block, 12 limiting block, 13 first supporting piece, 14 second supporting piece, 15 cutting component, 16 polishing component, 17 transmission component, 18 first supporting plate, 19U-shaped plate, 20 cutting blade, 21 first motor, 22 connecting rod, 23 connecting block, 24 clamping groove, 25 fixed block, 26 second sliding groove, 27 clamping block, 28 movable block, 29 second threaded rod, 30 rotating block, 31 second supporting plate, 32 vertical plate, 33 polishing disc, 34 third sliding groove, 35 lifting table, 36 moving block, 37 second motor, 38 movable shaft, 39 third threaded rod, 40 third bevel gear, 41 rotating shaft, 42 fourth bevel gear, 43 third motor, 44 moving table, 45 bearing plate, 46 fourth sliding groove, 47 sliding block, 48, 49 fourth motor, 50 driving wheel, 51 element body, 52 fourth motor, 53.

Detailed Description

Other advantages and advantages of the present invention will become apparent to those skilled in the art from the following detailed description, which, by way of illustration, is to be read in connection with certain specific embodiments, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-9, the invention provides a double-head pin cutting device for processing electronic elements, which comprises a machine body 1, wherein two sides of the machine body 1 are respectively provided with a feed inlet 2 and a discharge outlet 3, and an inner cavity of the machine body 1 is provided with an adjusting mechanism;

the adjusting mechanism comprises a first threaded rod 4, first sliding grooves 5 are respectively formed in two sides of the middle part of an inner cavity of the machine body 1, the first threaded rod 4 is arranged in the first sliding grooves 5 and is in rotary connection with the machine body 1 through a bearing, threads at two ends of the outer side of the first threaded rod 4 are opposite, a first bevel gear 6 is fixedly connected to the bottom of the first threaded rod 4, a first rotary groove is formed in the bottom of one side of the machine body 1, a rotary rod 7 is rotatably connected in the first rotary groove through a bearing, second bevel gears 8 are respectively fixedly connected to two ends of the outer side of the rotary rod 7, the second bevel gears 8 are in meshed connection with the first bevel gear 6, a sixth motor 9 is fixedly connected to the outer side of the machine body 1, an output end of the sixth motor 9 is fixedly connected with one end of the rotary rod 7, support rods 10 are respectively arranged at two ends of the inner cavity of the machine body 1, the two ends of the outer side of the supporting rod 10 are fixedly connected with sliding blocks 11, the sliding blocks 11 are arranged in the first sliding grooves 5 and are in sliding connection with the machine body 1, the first threaded rod 4 penetrates through the sliding blocks 11 and is connected with the sliding blocks 11, limiting grooves are formed in two ends of two sides of an inner cavity of the machine body 1, the limiting blocks 12 are fixedly connected with two ends of one side of the supporting rod 10, which is close to the inner wall of the machine body 1, of the supporting rod 10, the limiting blocks 12 are arranged in the limiting grooves and are in sliding connection with the machine body 1, the two ends of the supporting rod 10 are respectively fixedly connected with a first supporting piece 13 and a second supporting piece 14, the first supporting piece 13 is arranged at one end of the feed inlet 2, the second supporting piece 14 is arranged at one end of the discharge outlet 3, a cutting assembly 15 is arranged at the bottom of the first supporting piece 13, a polishing assembly 16 is arranged at the bottom of the second supporting piece 14, and a transmission assembly 17 is arranged in the middle of the inner cavity of the machine body 1.

In this embodiment, a user drives the rotating rod 7 to rotate through the sixth motor 9, so as to drive the engagement connection between the first bevel gear 6 and the second bevel gear 8, and further drive the first threaded rod 4 to rotate, drive the lifting of the supporting rod 10 through the threaded connection between the first threaded rod 4 and the sliding block 11, so as to polish and cut two sides of the element body 51, and simultaneously, through the opposite arrangement of the threads at two ends of the outer side of the first threaded rod 4, the supporting rods 10 on the upper and lower sides of the inner cavity of the machine body 1 synchronously move in opposite directions and move in opposite directions, so as to adjust the distance between the polishing assemblies 16 and the cutting assemblies 15 on the upper and lower sides, thereby improving the practicability of the device, facilitating the cutting of electronic elements with various thicknesses, wherein the number of the supporting rods 10 is four, and two groups of polishing assemblies 16 and cutting assemblies 15 are respectively arranged on the left and right sides of the inner cavity of the machine body 1, and two groups of the upper and lower sides of the inner cavity of the machine body 1 are respectively arranged;

in order to achieve the purpose of cutting two sides of an electronic element, the device is achieved by adopting the following technical scheme: the first supporting piece 13 comprises two first supporting plates 18 and a U-shaped plate 19, one end of each first supporting plate 18 is fixedly connected with two supporting rods 10, the U-shaped plate 19 is arranged in the middle of each first supporting plate 18, two ends of each U-shaped plate are fixedly connected with the corresponding first supporting plates 18, the cutting assembly 15 comprises a cutting blade 20, the top of each U-shaped plate 19 is fixedly connected with a first motor 21, the axis center of the top of each U-shaped plate 19 is rotatably connected with a connecting rod 22 through a bearing, the top of each connecting rod 22 is fixedly connected with the output end of each first motor 21, the bottom of each connecting rod 22 is fixedly connected with a connecting block 23, two ends of the bottom of each connecting block 23 are respectively provided with a clamping groove 24, the top of each cutting blade 20 is fixedly connected with a fixed block 25, two ends of each fixed block 25 are respectively provided with a second sliding groove 26, the bottom of each fixed block 25 is fixedly connected with a movable block 28, each movable block 28 is arranged in the second sliding groove 26 and is slidably connected with the fixed block 25, each clamping block 27 is sleeved in the clamping groove 24 and is movably connected with the corresponding threaded rod 23, the threaded rod is rotatably connected with the two ends of the threaded rod 29 through the corresponding second bearing 29, and the threaded rod 29 is rotatably connected with one side of the threaded rod 30;

when a user installs the cutting blade 20 to cut the element body 51, the user places the clamping block 27 inside the clamping groove 24, then drives the second threaded rod 29 to rotate through the rotation of the rotating block 30, drives the clamping blocks 27 on two sides to do reverse movement through the opposite screw threads at two ends of the outer side of the second threaded rod 29 and the screw thread connection between the second threaded rod 29 and the movable block 28, and further enables the clamping blocks 27 to enter the clamping groove 24, so that the cutting blade 20 is installed, and then drives the connecting rod 22 to rotate through the first motor 21, so that the cutting blade 20 is driven to rotate, and then the two sides of the element body 51 are cut;

in order to achieve the purpose of polishing two sides of an electronic element, the device is achieved by adopting the following technical scheme: the second supporting member 14 comprises a second supporting plate 31 and two vertical plates 32, two ends of the second supporting plate 31 are fixedly connected with the two supporting rods 10 respectively, two vertical plates 32 are arranged at two sides of the bottom of the second supporting plate 31 and are fixedly connected with the second supporting plate 31, the polishing assembly 16 comprises a polishing disc 33, a third sliding groove 34 is formed at one side of each of the two vertical plates 32, two lifting tables 35 are slidingly connected inside the vertical plates 32, moving blocks 36 are fixedly connected at the tops of two sides of each lifting table 35, the moving blocks 36 are arranged inside the third sliding grooves 34 and are slidingly connected with the vertical plates 32, a placing cavity is formed at one side of each lifting table 35, a second motor 37 is arranged inside the placing cavity and is fixedly connected with the lifting tables 35, a movable shaft 38 is rotationally connected at the bottom of each lifting table 35 through a bearing, one end of the movable shaft 38 is fixedly connected with the output end of the second motor 37, the movable shaft 38 penetrates through the lifting table 35 and extends to the bottom of the lifting table 35, the movable shaft 38 is arranged at the axle center of the top of the grinding disc 33 and is fixedly connected with the grinding disc 33, a third threaded rod 39 is connected inside the third sliding groove 34 through rotation, the third threaded rod 39 penetrates through the moving block 36 and is in threaded connection with the moving block 36, a third bevel gear 40 is fixedly connected to the top of the third threaded rod 39, a second rotating groove is formed inside the second supporting plate 31, a rotating shaft 41 is rotatably connected inside the second rotating groove through a bearing, fourth bevel gears 42 are fixedly connected to two ends of the outer side of the rotating shaft 41, the fourth bevel gears 42 are in meshed connection with the third bevel gear 40, a first placing groove is formed in one side of the top of the second supporting plate 31, a third motor 43 is arranged inside the first placing groove, the third motor 43 is disposed inside the first placement groove and is fixedly connected with the second support plate 31, and one end of the rotating shaft 41 is fixedly connected with the output end of the third motor 43;

when the user polishes the element body 51, the distance between the element body 51 and the cutting blade 20 is different from the distance between the element body 51 due to different cutting and polishing forces of the element body 51, at the moment, the user drives the rotating shaft 41 to rotate through the third motor 43, so as to drive the meshing connection between the third bevel gear 40 and the fourth bevel gear 42, further drive the third threaded rod 39 to rotate, and drive the lifting table 35 to lift through the threaded connection between the third threaded rod 39 and the lifting table 35, so that the distance between the polishing discs 33 on two sides and the element body 51 is adjusted, and the element body 51 is polished without damaging the element body 51;

in order to achieve the purpose of electronic element transmission, the device is realized by adopting the following technical scheme: the transmission assembly 17 comprises a moving table 44, a bearing plate 45 is fixedly connected to the middle part of an inner cavity of the machine body 1, fourth sliding grooves 46 are formed in two sides of the top of the bearing plate 45, a sliding block 47 is fixedly connected to the bottom of the moving table 44, the sliding block 47 is arranged in the fourth sliding grooves 46 and is in sliding connection with the bearing plate 45, a transmission groove is formed in the edge of the outer side of the moving table 44, internal cavities are formed in two sides of the moving table 44, a transmission wheel 48 is rotatably connected to the inside of the internal cavities through bearings, a fourth motor 49 is fixedly connected to the top of the moving table 44, the output end of the fourth motor 49 is fixedly connected with one end of the transmission wheel 48, a transmission belt 50 is movably sleeved on the outer side of the transmission wheel 48, the transmission belt 50 is arranged in the transmission groove, an element body 51 is arranged in the transmission groove, two sides of the element body 51 are respectively arranged in the transmission groove and are in contact with the transmission belt 50, a fourth threaded rod 52 is rotatably connected to the inside of the fourth sliding groove 46 through bearings, two ends of the fourth threaded rod 52 are opposite in threads, the fourth threaded rod 52 penetrates through the sliding block 47 and is fixedly connected to the sliding block 47, a fifth threaded rod 53 is fixedly connected to the top of the second threaded rod 45, and the fifth threaded rod 53 is fixedly arranged at the top of the second threaded rod is placed in the bearing plate, and the fifth threaded rod 53 is fixedly connected to the top of the transmission plate is placed;

the user places the component body 51 in the transmission groove outside the movable table 44 at the two sides of the top of the bearing plate 45, then drives the fourth threaded rod 52 to rotate through the fifth motor 53, and effectively drives the movable tables 44 at the two sides to move in opposite directions through the arrangement of the threads at the two ends of the outer side of the fourth threaded rod 52, so that the two ends of the component body 51 are attached to one side of the transmission belt 50, then drives the rotating wheel to rotate through the fourth motor 49, thereby driving the transmission belt 50 to rotate, further driving the component body 51 to move, and effectively adjusting the distance between the two movable tables 44 through the sliding connection between the movable tables 44 and the bearing plate 45, thereby increasing the practicability of the device, and being suitable for the operation of the component body 51 with various widths;

the application process of the invention is as follows: when the invention is used, a user places the element body 51 in the transmission groove at the outer side of the movable table 44 at the two sides of the top of the bearing plate 45, then drives the fourth threaded rod 52 to rotate through the fifth motor 53, and effectively drives the movable table 44 at the two sides to move in opposite directions through the arrangement of the threads at the two ends at the outer side of the fourth threaded rod 52, so that the two ends of the element body 51 are attached to one side of the transmission belt 50, and then drives the rotating wheel to rotate through the fourth motor 49, so as to drive the transmission belt 50 to rotate, and further drive the element body 51 to move;

when the element body 51 is placed, a user drives the rotating rod 7 to rotate through the sixth motor 9, so that the first bevel gear 6 is driven to be in meshed connection with the second bevel gear 8, the first threaded rod 4 is driven to rotate, the supporting rods 10 are driven to lift through threaded connection between the first threaded rod 4 and the sliding block 11, so that two sides of the element body 51 are polished and cut, and simultaneously, the supporting rods 10 on the upper side and the lower side of the inner cavity of the machine body 1 synchronously move oppositely and back to back through the arrangement of threads on the two ends of the outer side of the first threaded rod 4, so that the distance between the polishing assemblies 16 and the cutting assemblies 15 on the upper side and the lower side is adjusted, and the device is further suitable for cutting and polishing of the element body 51;

before cutting and polishing, because the cutting and polishing forces on the element body 51 are different, the distance between the element body 51 and the cutting blade 20 is different from the distance between the element body 51, the distance between the polishing disc 33 and the element body 51 needs to be independently adjusted by a user, the user drives the rotating shaft 41 to rotate through the third motor 43, so as to drive the meshing connection between the third bevel gear 40 and the fourth bevel gear 42, further drive the third threaded rod 39 to rotate, and drive the lifting table 35 to lift through the threaded connection between the third threaded rod 39 and the lifting table 35, so as to adjust the distance between the polishing discs 33 on two sides and the element body 51;

after the adjustment, the user needs to install the cutting blade 20, the user places the clamping block 27 inside the clamping groove 24, then drives the second threaded rod 29 to rotate through the rotation of the rotating block 30, and drives the clamping blocks 27 on two sides to move back through the opposite screw threads at the two ends of the outer side of the second threaded rod 29 and the screw thread connection between the second threaded rod 29 and the movable block 28, so that the clamping block 27 enters the clamping groove 24, and the cutting blade 20 is installed;

after the cutting blade 20 is installed, the user cuts and polishes the wafer body, at this time, the user drives the connecting rod 22 to rotate through the first motor 21, so as to drive the cutting blade 20 to rotate, and then cut two sides of the element body 51, and simultaneously drives the polishing disc 33 to rotate through the second motor 37, and then cut and polish the element body 51.

The above description is of the preferred embodiments of the present invention, and any person skilled in the art may modify the present invention or make modifications to the present invention with the technical solutions described above. Therefore, any simple modification or equivalent made according to the technical solution of the present invention falls within the scope of the protection claimed by the present invention.

Claims (5)

1. The utility model provides a double-end pin cutting device that electronic component processing was used, includes organism (1), its characterized in that: two sides of the machine body (1) are respectively provided with a feed inlet (2) and a discharge outlet (3), and an inner cavity of the machine body (1) is provided with an adjusting mechanism;

the adjusting mechanism comprises a first threaded rod (4), a first sliding groove (5) is formed in two sides of the middle of an inner cavity of the machine body (1), the first threaded rod (4) is arranged inside the first sliding groove (5) and is rotationally connected with the machine body (1) through a bearing, threads at two ends of the outer side of the first threaded rod (4) are opposite, a first bevel gear (6) is fixedly connected to the bottom of the first threaded rod (4), a first rotating groove is formed in one side bottom of the machine body (1), a rotating rod (7) is rotationally connected inside the first rotating groove through a bearing, a second bevel gear (8) is fixedly connected to two ends of the outer side of the rotating rod (7), a sixth motor (9) is fixedly connected to one end of the rotating rod (7), two ends of the inner cavity of the machine body (1) are fixedly connected with a supporting rod (10), a sliding block (11) is fixedly connected to two ends of the outer side of the supporting rod (10), a second bevel gear (8) is fixedly connected to the first bevel gear (6) in a meshed mode, the second bevel gear (8) is fixedly connected to the first bevel gear (6), the outer side of the machine body (1) is fixedly connected to the sixth motor (9), two ends of the output end of the rotating rod (7) are fixedly connected to one end of the sliding block (11), two ends of the inner side of the inner cavity (1) are fixedly connected to the sliding block (11), the novel grinding machine is characterized in that limiting blocks (12) are fixedly connected to two ends of one side, close to the inner wall of the machine body (1), of the supporting rod (10), the limiting blocks (12) are arranged in limiting grooves and are in sliding connection with the machine body (1), a first supporting piece (13) and a second supporting piece (14) are fixedly connected to two ends of the supporting rod (10), the first supporting piece (13) is arranged at one end of the feeding hole (2), the second supporting piece (14) is arranged at one end of the discharging hole (3), a cutting assembly (15) is arranged at the bottom of the first supporting piece (13), a grinding assembly (16) is arranged at the bottom of the second supporting piece (14), and a transmission assembly (17) is arranged in the middle of an inner cavity of the machine body (1);

the first supporting piece (13) comprises two first supporting plates (18) and a U-shaped plate (19), one ends of the two first supporting plates (18) are fixedly connected with the two supporting rods (10), and the U-shaped plate (19) is arranged in the middle of the two first supporting plates (18) and two ends of the U-shaped plate are respectively fixedly connected with the first supporting plates (18);

the cutting assembly (15) comprises a cutting blade (20), a first motor (21) is fixedly connected to the top of the U-shaped plate (19), a connecting rod (22) is rotatably connected to the axis of the top of the U-shaped plate (19) through a bearing, the top of the connecting rod (22) is fixedly connected with the output end of the first motor (21), a connecting block (23) is fixedly connected to the bottom of the connecting rod (22), clamping grooves (24) are formed in two ends of the bottom of the connecting block (23), a fixed block (25) is fixedly connected to the top of the cutting blade (20), second sliding grooves (26) are formed in two ends of the top of the fixed block (25), clamping blocks (27) are respectively arranged at two ends of the top of the fixed block (25), movable blocks (28) are fixedly connected to the bottom of the clamping blocks (27), and the movable blocks (28) are arranged inside the second sliding grooves (26) and are in sliding connection with the fixed blocks (25), and the clamping blocks (27) are movably sleeved on the inside the clamping grooves (24).

The second sliding groove (26) is internally connected with a second threaded rod (29) in a rotating way through a bearing, threads at two ends of the outer side of the second threaded rod (29) are opposite, two ends of the second threaded rod (29) respectively penetrate through the movable block (28) and are in threaded connection with the movable block (28), a rotating block (30) is arranged on one side of the fixed block (25), and one end of the rotating block (30) is fixedly connected with one end of the second threaded rod (29);

the second support piece (14) comprises a second support plate (31) and two vertical plates (32), two ends of the second support plate (31) are fixedly connected with the two support rods (10) respectively, and the two vertical plates (32) are arranged on two sides of the bottom of the second support plate (31) and are fixedly connected with the second support plate (31).

2. The dual head pin cutting apparatus for electronic component manufacturing according to claim 1, wherein: the polishing assembly (16) comprises a polishing disc (33), a third sliding groove (34) is formed in one side of each riser (32), a lifting table (35) is connected to the bottom of each riser (32) in a sliding mode, moving blocks (36) are fixedly connected to the tops of two sides of each lifting table (35), the moving blocks (36) are arranged in the third sliding groove (34) and are in sliding connection with the risers (32), a placing cavity is formed in one side of each lifting table (35), a second motor (37) is arranged in each placing cavity, the second motor (37) is arranged in each placing cavity and is fixedly connected with the lifting table (35), a movable shaft (38) is connected to the bottom of each lifting table (35) in a rotating mode through a bearing, one end of each movable shaft (38) is fixedly connected to the output end of each second motor (37), and each movable shaft (38) penetrates through the lifting table (35) and extends to the bottom of each lifting table (35), and each movable shaft (38) is arranged at the top axle center of each grinding disc (33) and is fixedly connected with the polishing disc (33).

3. The dual head pin cutting apparatus for electronic component manufacturing according to claim 2, wherein: the novel sliding device is characterized in that a third threaded rod (39) is connected to the inside of the third sliding groove (34) through rotation, the third threaded rod (39) penetrates through the moving block (36) and is in threaded connection with the moving block (36), a third bevel gear (40) is fixedly connected to the top of the third threaded rod (39), a second rotating groove is formed in the second supporting plate (31), a rotating shaft (41) is rotatably connected to the inside of the second rotating groove through a bearing, fourth bevel gears (42) are fixedly connected to two ends of the outer side of the rotating shaft (41), the fourth bevel gears (42) are in meshed connection with the third bevel gear (40), a first placing groove is formed in one side of the top of the second supporting plate (31), a third motor (43) is arranged in the first placing groove, the third motor (43) is fixedly connected to the inside of the second supporting plate (31), and one end of the rotating shaft (41) is fixedly connected to the output end of the third motor (43).

4. A dual head pin cutting apparatus for electronic component processing according to claim 3, wherein: the transmission assembly (17) comprises a moving table (44), a bearing plate (45) is fixedly connected to the middle of an inner cavity of the machine body (1), fourth sliding grooves (46) are formed in two sides of the top of the bearing plate (45), sliding blocks (47) are fixedly connected to the bottom of the moving table (44), the sliding blocks (47) are arranged inside the fourth sliding grooves (46) and are in sliding connection with the bearing plate (45), transmission grooves are formed in the outer edges of the moving table (44), inner cavities are formed in two sides of the moving table (44), driving wheels (48) are rotatably connected to the inner cavities through bearings, a fourth motor (49) is fixedly connected to the top of the moving table (44), the output end of the fourth motor (49) is fixedly connected with one end of the driving wheel (48), a driving belt (50) is movably sleeved on the outer side of the driving wheel (48), the driving belt (50) is arranged inside the transmission grooves, element bodies (51) are arranged inside the transmission grooves, and two sides of the element bodies (51) are arranged inside the transmission grooves and are attached to the driving belt (50).

5. The dual head pin cutting apparatus for electronic component manufacturing according to claim 4, wherein: the novel bearing is characterized in that a fourth threaded rod (52) is connected inside the fourth sliding groove (46) through bearing rotation, threads at two ends of the outer side of the fourth threaded rod (52) are opposite, two ends of the fourth threaded rod (52) penetrate through a sliding block (47) and are in threaded connection with the sliding block (47), a second placing groove is formed in the top of the bearing plate (45), a fifth motor (53) is arranged inside the second placing groove, the fifth motor (53) is arranged inside the second placing groove and is fixedly connected with the bearing plate (45), and one end of the fourth threaded rod (52) is fixedly connected with the output end of the fifth motor (53).

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