CN112605424A - Electronic device processing tool and processing method - Google Patents

Abstract

The utility model provides an electron device processing frock and processing method, the frock includes: the processing mechanism is used for processing the electronic device to be processed by rotating; the rocking mechanism drives the processing mechanism to rotate; the driving mechanism comprises a sliding block and a first spiral rod, wherein the first surface of the first platform is movably connected with the sliding block along the second end of the first platform in the length direction, the sliding block is connected with the second surface of the second platform, one end of the first spiral rod in the length direction is connected with the sliding block, the first spiral rod rotates to drive the sliding block to move along the length direction of the first spiral rod, and the second platform is driven to move to different positions of the first platform in the length direction of the first platform. According to the electronic device machining tool and the machining method, the second platform is driven to move relative to the first platform by operating the driving mechanism so as to drive the machining mechanism connected with the second platform to move, and therefore the position of the machining mechanism can be adjusted at any time according to use requirements in the machining process.

Description

Electronic device processing tool and processing method

Technical Field

The disclosure belongs to the technical field of processing tools, and particularly relates to an electronic device processing tool and a processing method.

Background

At present, with the development of microwave technology, a corresponding tool needs to be designed for realizing a specific process in microwave device assembly, such as an inductance winding processing process, and therefore a corresponding processing tool needs to be designed; in the use process of the microwave device, part of components can be fragile or sensitive, damage can occur in the assembling, debugging and using processes, the repair difficulty is high, and the like. In traditional processing frock, the position of the processing device of installation on the operation panel is generally difficult to remove, in the course of working, can not adjust the position of processing device according to the operation demand, and the flexibility of frock is relatively poor, maneuverability is not strong.

Disclosure of Invention

The present disclosure is directed to at least one of the technical problems in the prior art, and provides a tooling and a method for processing an electronic device.

One aspect of the present disclosure provides an electronic device processing tool, the processing tool includes:

a first stage including a first surface and a second surface oppositely disposed in a thickness direction thereof;

a second platform including a first surface and a second surface oppositely disposed in a thickness direction thereof;

the processing mechanism is arranged on the first surface of the second platform and used for processing the electronic device to be processed through rotation;

the rocking mechanism is arranged at the first end of the first surface of the first platform along the length direction of the first surface, and is connected with the machining mechanism so as to drive the machining mechanism to rotate;

the driving mechanism comprises a sliding block and a first spiral rod, the second end of the first surface of the first platform along the length direction of the first surface of the first platform is movably connected with the sliding block, the sliding block is connected with the second surface of the second platform, one end of the first spiral rod along the length direction of the first spiral rod is connected with the sliding block, and the first spiral rod rotationally drives the sliding block to move along the length direction of the first spiral rod so as to drive the second platform to move to different positions of the first platform along the length direction of the first platform.

Optionally, the processing mechanism comprises a first drill bit, a second drill bit, a drill bit clamp and a locking piece;

one end of the first drill bit in the length direction is connected with the drill bit clamp through the locking piece, or one end of the second drill bit in the length direction is connected with the drill bit clamp through the locking piece;

one end of the first drill bit, which is far away from the locking piece along the length direction of the first drill bit, is a plane and is used for carrying out winding processing on an inductance coil to be wound;

and one end of the second drill bit, which deviates from the locking piece along the length direction of the second drill bit, is a curved surface and is used for stripping the insulator to be stripped from the insulator box body.

Optionally, a slider mounting groove is formed in the first surface of the first platform along the length direction of the first platform, and the slider moves in the slider mounting groove along the length direction of the slider to drive the second platform to move to different positions of the first surface of the first platform along the length direction of the first platform.

Optionally, the driving mechanism further includes a clamping piece and a screw, one end of the first screw rod along the length direction thereof penetrates through the sliding block and is connected with the central area of the clamping piece through the screw, and the edge area of the clamping piece is connected with the first platform so as to fixedly connect one end of the first screw rod along the length direction thereof with the first platform.

Optionally, the shaking mechanism comprises a rotating shaft, a telescopic rod and a crank; wherein the content of the first and second substances,

the rotating shaft is provided with a first accommodating cavity and an accommodating hole communicated with the first accommodating cavity along the length direction of the rotating shaft, and one end of the rotating shaft, which deviates from the accommodating hole along the length direction of the rotating shaft, is connected with the crank;

the first end of the telescopic rod in the length direction is connected with the processing mechanism, the second end of the telescopic rod in the length direction is movably inserted into the first accommodating cavity through the accommodating hole and is selectively and fixedly connected with the inner wall of the first accommodating cavity in the circumferential direction, so that the second end of the telescopic rod in the length direction can be fixed at different positions in the first accommodating cavity in the length direction.

Optionally, the rocking mechanism still includes rocking mechanism installed part, rocking mechanism installed part is including the fixed part and the installation department that are connected, the pivot with the fixed part is connected, the fixed part passes through the installation department with first platform fixed connection, in order to incite somebody to action the pivot with first platform fixed connection.

Optionally, the processing tool further comprises:

the supporting seat is of a shell structure with a second accommodating cavity, the supporting seat is also provided with an opening part communicated with the second accommodating cavity, the supporting seat comprises a first surface and a second surface which are oppositely arranged along the thickness direction of the supporting seat, and the first surface of the supporting seat is connected with the second surface of the first platform;

and the drawer is arranged in the second accommodating cavity through the opening part and is movably connected with the second accommodating cavity.

Optionally, the processing tool further comprises a lifting mechanism for adjusting the height of the supporting seat, and the lifting mechanism comprises a bottom plate, a limiting plate, a plurality of first lifting connecting rods, a plurality of second lifting connecting rods, a plurality of first lifting shafts, a plurality of second lifting shafts, at least one third lifting shaft and a driving assembly; wherein the content of the first and second substances,

each first lifting connecting rod and the corresponding second lifting shaft are crossed to form an intersection point, and the intersection points are connected through the third lifting shaft;

the first ends of the first lifting connecting rods along the lengths of the first lifting connecting rods are connected through a first lifting shaft, the first ends of the second lifting connecting rods along the lengths of the second lifting connecting rods are connected through a first lifting shaft, each first lifting shaft is movably connected with the second surface of the supporting seat through the driving assembly, the driving assembly drives each first lifting shaft to be fixed at different positions of the second surface of the supporting seat, and the height of the supporting seat is adjusted by adjusting the distance between the first lifting shafts;

the plurality of first lifting connecting rods are connected along the second ends of the lengths thereof through the second lifting shafts, the plurality of second lifting connecting rods are connected along the second ends of the lengths thereof through the second lifting shafts, each second lifting shaft moves to different positions on the bottom plate according to the movement of the corresponding first lifting shaft, each second lifting shaft is movably connected with the bottom plate through the limiting plate, and the limiting plate limits the position of each second lifting shaft so as to limit the height of the supporting seat.

Optionally, the driving assembly includes a second screw rod, the plurality of first lifting shafts are respectively connected to the second screw rod, and the second screw rod rotationally drives each of the first lifting shafts to move along a length direction of the second screw rod, so as to adjust a distance between the plurality of first lifting shafts.

Another aspect of the present disclosure provides a multifunctional electronic device processing method using the processing tool set forth above, the processing method including:

rotating the first spiral rod to drive the sliding block to move along the length direction of the first spiral rod so as to drive the second platform to move to different positions of the first platform along the length direction of the first platform;

and rotating the rocking mechanism to drive the processing mechanism to rotate so as to process the electronic device to be processed.

In the electronic device processing tool and the processing method provided by the embodiment of the disclosure, the driving mechanism is operated to drive the second platform to move relative to the first platform, specifically, the first screw rod is rotated to drive the sliding block to move, so that the second platform connected with the sliding block is driven to move relative to the first platform, and further the processing mechanism connected with the second platform is driven to move, so that the position of the processing mechanism can be adjusted at any time according to the use requirement in the processing process, the problem that the position of a processing device mounted on an operation table cannot be adjusted in the prior art is solved, and the flexibility and operability of the processing tool are improved.

Drawings

Fig. 1 is a schematic structural diagram of an electronic device processing tool according to an embodiment of the disclosure;

FIG. 2 is a block diagram schematic of the structure of a first platform and a second platform of another embodiment of the present disclosure;

FIG. 3 is a schematic diagram of a first drill bit according to another embodiment of the present disclosure;

FIG. 4 is a schematic diagram of a second drill bit according to another embodiment of the present disclosure;

FIG. 5 is a side view of an electronic device processing tool shown in FIG. 1;

FIG. 6 is a schematic structural view of a winding fixture according to another embodiment of the present disclosure;

FIG. 7 is a schematic structural diagram of a slider according to another embodiment of the present disclosure;

FIG. 8 is a schematic flow chart diagram of a method of fabricating an electronic device according to another embodiment of the present disclosure;

fig. 9 is a schematic flow chart of a method for processing an electronic device according to another embodiment of the present disclosure.

Detailed Description

For a better understanding of the technical aspects of the present disclosure, reference is made to the following detailed description taken in conjunction with the accompanying drawings. It is to be understood that the described embodiments are only a few embodiments of the present disclosure, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the described embodiments of the disclosure without any inventive step, are within the scope of protection of the disclosure.

Unless otherwise specifically stated, technical or scientific terms used in the present disclosure shall have the ordinary meaning as understood by those of ordinary skill in the art to which the present disclosure belongs. The use of "including" or "comprising" and the like in this disclosure does not limit the referenced shapes, numbers, steps, actions, operations, members, elements and/or groups thereof, nor does it preclude the presence or addition of one or more other different shapes, numbers, steps, actions, operations, members, elements and/or groups thereof or those. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number and order of the technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present disclosure, "a plurality" means two or more unless specifically limited otherwise.

In some descriptions of the invention, unless expressly stated or limited otherwise, the terms "mounted," "connected," or "fixed" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect through an intermediate medium, whether internal to two elements or an interactive relationship between two elements. Also, the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", and the like indicate an orientation or positional relationship based on the orientation or positional relationship shown in the drawings, and are used merely to indicate a relative positional relationship, which may also be changed accordingly when the absolute position of the object being described is changed.

In the present disclosure, unless otherwise expressly stated or limited, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through an intermediate. Also, a first feature "on," "above," and "above" a second feature may be directly above or obliquely above the second feature, or merely that the first feature is at a higher level than the second feature, and a first feature "below," "under," and "under" a second feature may be directly below or obliquely below the first feature, or merely that the first feature is at a lower level than the second feature.

The relative arrangement of parts and steps, numerical expressions, and numerical values set forth in these embodiments do not limit the scope of the present disclosure unless specifically stated otherwise. Also, it should be understood that the dimensions of the various elements shown in the figures are not drawn to scale, for ease of description, and that techniques, methods and apparatus known to those of ordinary skill in the relevant art may not be discussed in detail, but are intended to be part of the specification where appropriate. In all examples shown and discussed herein, any particular other example may have a different value. It should be noted that: like symbols and letters represent like items in the following figures, and thus, once an item is defined in one figure, further discussion thereof is not required in subsequent figures.

As shown in fig. 1 and 2, the present disclosure provides an electronic device processing tool, which includes a first platform 100, a second platform 200, a processing mechanism 300, a rocking mechanism 400, and a driving mechanism 500; as shown in fig. 2, the first stage 100 includes a first surface 110 and a second surface 120 oppositely disposed in a thickness direction thereof, and the second stage 200 includes a first surface 210 and a second surface 220 oppositely disposed in a thickness direction thereof; as shown in fig. 1, the processing mechanism 300 is disposed on the first surface 210 of the second platform 200, that is, the upper surface of the second platform in fig. 1, and the processing mechanism 300 is used for processing an electronic device to be processed by rotating, for example, the electronic device to be processed includes an inductor to be wound or an insulator to be stripped; the rocking mechanism 400 is disposed at a first end of the first surface 110 of the first platform 100 along the length direction thereof, that is, at the right end of the upper surface of the first platform in fig. 1, the rocking mechanism 400 is connected to the processing mechanism 300, and the processing mechanism 300 is driven to rotate by rotating the rocking mechanism; the driving mechanism 500 includes a slider 510 and a first spiral rod 520, the second end of the first surface 110 of the first platform 100 along the length direction thereof is movably connected with the slider 510, the slider 510 is connected with the second surface 220 of the second platform 200 to drive the second platform to move relative to the first platform through the movement of the slider, illustratively, as shown in fig. 1, the left end of the upper surface of the first platform is movably connected with the slider, the slider is fixedly connected with the lower surface of the second platform, illustratively, the movable connection includes a sliding connection, a plugging connection, and the like, the fixed connection includes a welding, a riveting, and the like, one end of the first spiral rod 520 along the length direction thereof is connected with the slider 510, illustratively, as shown in fig. 1, the left end of the first spiral rod is connected with the right end of the slider, the first spiral rod 520 drives the slider 510 to move along the length direction of the first spiral rod by rotating itself, i.e., the x-direction in fig. 1, so as to drive the second platform 200 to move to a different position of the first platform 100 along the length direction of the first platform, i.e., the x-direction in the figure, and further drive the machining mechanism to move relative to the rocking mechanism, for example, the driving mechanism further includes a first knob 530 connected to an end of the first screw rod facing away from the slider along the length direction thereof, i.e., connected to the right end of the first screw rod, the first knob being used for rotating the first screw rod, so as to improve the operability of the tool; illustratively, as shown in fig. 1, the processing mechanism 300 is coupled to the rocking mechanism 400 via a first coupling 810.

For example, as shown in fig. 1, when the machining tool in this embodiment is used to machine an electronic device, the first screw rod may be rotated to drive the slider to move left and right in the x direction in the drawing, so as to drive the second platform connected to the slider to move left and right in the x direction in the drawing relative to the first platform, further drive the machining mechanism disposed on the second platform to move left and right in the x direction in the drawing, that is, to move left and right relative to the rocking mechanism, and adjust the position of the machining mechanism during machining by moving the machining mechanism, especially when the machining tool is used with a microscope, the second platform may be driven to move the machining mechanism to a proper position within the field of view of the microscope. After the processing mechanism is adjusted to a proper position, the rocking mechanism is rotated manually, the processing mechanism is driven to rotate through the rotation of the rocking mechanism, and the processing mechanism completes the processing of the electronic device to be processed through the rotation. In addition to adjusting the position of the machining mechanism at the start of machining, the position of the second platform may be adjusted at any time by the driving mechanism during machining, and the position of the machining mechanism may be adjusted at any time according to the use requirement.

The electronic device machining tool provided in the embodiment drives the second platform to move relative to the first platform by operating the driving mechanism, and particularly drives the sliding block to move by rotating the first screw rod, so that the second platform connected with the sliding block is driven to move relative to the first platform, and further drives the machining mechanism connected with the second platform to move, the position of the machining mechanism is adjusted at any time according to use requirements in the machining process, the problem that the position of a machining device mounted on an operating platform cannot be adjusted in the prior art is solved, and the flexibility and operability of the machining tool are improved.

The specific structure of the processing mechanism will be further explained with reference to fig. 1 to 5.

Illustratively, as shown in fig. 1, 3 and 4, the machining mechanism 300 includes a first drill 310, a second drill 320, a drill holder 330 and a locking member 340, wherein one end of the first drill 310 along the length direction thereof, i.e., the right end in fig. 1, is connected with the drill holder 330 through the locking member 340, or one end of the second drill 320 along the length direction thereof, i.e., the right end in fig. 1, is connected with the drill holder 330 through the locking member 340, and the machining mechanism selectively mounts the first drill or the second drill on the drill holder to implement different machining processes for different electronic devices; illustratively, as shown in fig. 3, an end of the first drill 310 facing away from the locking member in the length direction thereof, that is, the left end in the drawing, is a plane for winding the inductor coil to be wound, that is, when the first drill is selected to be mounted on the drill chuck, the inductor coil is subjected to a winding process, illustratively, as shown in fig. 4, an end of the second drill 320 facing away from the locking member in the length direction thereof, that is, the left end in the drawing, is a curved surface for peeling the insulator to be peeled off from the insulator box, that is, when the second drill is selected to be mounted on the drill chuck, the insulator box is subjected to a rework process for peeling the insulator with peeling off from the insulator box, illustratively, an end of the second drill facing away from the locking member in the length direction thereof may be a curved surface which is first protruded and then recessed in the radial direction thereof, or may be a conical curved surface or an elliptical curved surface, those skilled in the art can set the setting according to actual use requirements, and the embodiment is not particularly limited; for example, the diameter of the first drill and the second drill can be set by those skilled in the art according to the actual use requirement, and the present embodiment is not particularly limited; illustratively, the locking member includes a key-locking portion, and the locking connection between the first bit or the second bit and the bit holder is achieved by inserting a key.

Illustratively, as shown in fig. 2, a bit holder clamping groove 230 is further disposed on the first surface 210 of the second platform 200, that is, the upper surface in the drawing, for fixedly mounting a bit holder 330, so as to improve the stability of mounting the bit holder on the second plane and the stability of mounting the machining mechanism on the second platform, for example, the bit holder may be connected to the bit holder clamping groove by screwing, welding, riveting, or the like, which is not specifically limited in this embodiment, and for example, the bit holder clamping groove may be a rectangular groove or an arc groove matching with the bit holder, and a person skilled in the art may set a specific shape of the bit holder clamping groove according to actual use requirements, which is not specifically limited in this embodiment.

Illustratively, as shown in fig. 5, the machining mechanism 300 further includes a drill clamp 350, a first end of the drill clamp 350 along a length direction thereof is connected to the first surface 210 of the second platform 200, and a second end of the drill clamp 350 along the length direction thereof crosses over an end of the drill clamp 330 away from the second platform and is connected to the first surface 210 of the second platform 200, so as to fix the drill clamp 350 to the first surface 210 of the second platform 200.

Exemplarily, as shown in fig. 1, when an inductor needs to be wound, a first drill is mounted to a locking member, the locking member is locked to realize fixed connection between the first drill and a drill clamp, then a winding wire, such as an enameled wire or a gold wire, is fixed on the first drill in a direction perpendicular to the first drill, a shaking mechanism is rotated to drive a processing mechanism to rotate, specifically, the first drill is driven to rotate by the drill clamp to realize winding of an inductor coil, when the number of winding turns reaches a predetermined number, the operation of the shaking mechanism is stopped, the enameled wire or the gold wire is cut by scissors, and the inductor is pulled down by a needle along the axial direction of the first drill to complete winding of the inductor; when the damaged insulator needs to be repaired, the insulator may be bonded or sintered on the insulator box body, when all other processes are assembled, but the insulator is damaged, the repair needs to consider stripping and replacing the insulator without affecting the quality of other processes, so that no large flaw exists after the repair, at this time, the second drill bit can be mounted on the locking piece, the locking piece is locked to realize the fixed connection between the second drill bit and the drill bit clamp, the insulator to be stripped is aligned to the second drill bit, the shaking mechanism is rotated to drive the processing mechanism to rotate, specifically, the second drill bit is driven to rotate by the drill bit clamp, the insulator is stripped from the insulator box body by the rotation of the second drill bit, when the insulator ring is stripped, the operation of the shaking mechanism is stopped, the stripping of the damaged insulator is completed, and then a new insulator can be mounted on the insulator box body, thereby completing the insulator repair process.

According to the electronic device processing tool provided by the embodiment, the processing mechanism selects the first drill bit or the second drill bit to be arranged on the drill bit clamp so as to realize different processing technologies for different electronic devices, when the inductor needs to be wound, the first drill bit with the planar end face is selected, and when the insulator needs to be stripped, the second drill bit with the curved end face is selected, so that different processing technologies for different electronic devices are realized, multifunctional processing of the processing tool is realized, the problem that most of the existing processing tools can only realize a certain specific processing technology is solved, and the processing cost and the operation difficulty are reduced.

The specific structure of the first platform and the driving mechanism will be further explained with reference to fig. 1 and 2.

Illustratively, as shown in fig. 2, the first surface 110 of the first platform 100 is provided with a slider mounting groove 130 along the length direction thereof, i.e. the left end of the first surface is provided with a slider mounting groove, the slider 510 moves in the slider mounting groove 130 along the length direction thereof, i.e. the left and right directions thereof, so as to drive the second platform 200 to move to different positions of the first surface 110 of the first platform 100 along the length direction of the first platform 100, and the movable connection between the slider and the first platform is realized through the sliding connection; exemplarily, the shape of the slider mounting groove corresponds to the shape of the slider, so as to improve the mobility between the slider and the first platform, for example, if one end of the slider connected to the first platform is a rectangular parallelepiped, the slider mounting groove is correspondingly set to be a rectangular groove, and a person skilled in the art can set the specific shape of the slider mounting groove according to actual use requirements, which is not specifically limited in this embodiment.

Illustratively, as shown in fig. 1, the driving mechanism 500 further includes a clamping piece 540 and a screw 550, for example, the clamping piece may be a circular piece, the slider 510 is provided with a first screw rod mounting hole 513 penetrating through the length direction thereof, one end of the first screw rod 520 along the length direction thereof is inserted into the slider 510 through the first screw rod mounting hole 513, one end, i.e., the left end in the drawing, of the first screw rod 520 along the length direction thereof is connected with the central region of the clamping piece 540 through the screw 550, and the edge region of the clamping piece 540 is connected with the left end of the first platform 100, so as to fixedly connect one end, i.e., the left end in the drawing, of the first screw rod 520 along the length direction thereof to the first platform 100.

The utility model provides an electron device processing frock realizes the sliding connection between slider and the first platform through setting up the slider mounting groove, improves the mobility between slider and the first platform, is fixed in first hob on the first platform through setting up card and screw, improves the stability of first hob installation to can operate first hob rotation better and remove with the drive slider.

The specific structure of the rocking mechanism will be further explained below with reference to fig. 1.

Illustratively, as shown in fig. 1, the rocking mechanism 400 includes a rotating shaft 410, an expansion link 420 and a crank 430, the rotating shaft 410 is provided with a first accommodating cavity 411 and an accommodating hole 412 communicating with the first accommodating cavity 411 along a length direction thereof, one end of the rotating shaft 410, which is away from the accommodating hole 412 along the length direction thereof, is connected with the crank 430, illustratively, as shown in the drawing, the left end of the rotating shaft is provided with an accommodating hole, the right end is connected with the crank, illustratively, the rotating shaft 410 is connected with the crank 430 through a second coupler 820, illustratively, the crank is further provided with a crank collar 450, which is used for increasing friction between a handle and a handle so as to well control the crank; the first end of the telescopic rod 420 along the length direction thereof is connected with the processing mechanism 300, the second end of the telescopic rod along the length direction thereof is movably inserted into the first accommodating cavity 411 through the accommodating hole 412 and is selectively and fixedly connected with the inner wall of the first accommodating cavity 411 along the circumferential direction thereof, so that the second end of the telescopic rod 420 along the length direction thereof can be fixed at different positions in the first accommodating cavity 411 along the length direction thereof, exemplarily, as shown in the figure, the left end of the telescopic rod 420 is connected with the bit holder 330 in the processing mechanism 300 through the first coupler 810, the right end of the telescopic rod penetrates into the first accommodating cavity through the accommodating hole, exemplarily, the second end of the telescopic rod along the length direction thereof is provided with a clamping portion, the inner wall of the first accommodating cavity is provided with a plurality of clamping portions corresponding to the clamping portions along the length direction thereof, after the telescopic rod is adjusted to a proper position, the clamping portion on the telescopic rod can be clamped with the clamping portion arranged on the inner wall of the first accommodating, the telescopic rod is fixedly connected with the inner wall of the first accommodating cavity, and therefore the second end of the telescopic rod in the length direction, namely the right end in the drawing, is fixed at different positions of the inner wall of the first accommodating cavity in the length direction according to actual use requirements.

Exemplarily, as shown in fig. 1, when the second platform is moved by the driving mechanism to adjust the position of the processing mechanism, the telescopic rod connected to the processing mechanism can be extended and retracted along with the movement of the processing mechanism, for example, the processing mechanism moves leftward in the drawing, and the telescopic rod extends leftward for a distance corresponding to the first accommodating cavity, and the entire length of the rocking mechanism is increased, so that the linkage between the processing mechanism and the rocking mechanism is realized by the telescopic rod, and after the telescopic rod is extended and retracted to a proper position, the telescopic rod is fixedly connected to the inner wall of the first accommodating cavity, so that the fixed connection between the telescopic rod and the rotating shaft is realized, and further, when the rotating shaft is driven to rotate by the crank, the rotation of the telescopic rod can be further driven, so that the rotation of the processing.

Illustratively, as shown in fig. 1, the rocking mechanism 400 further includes a rocking mechanism mounting member 440, the rocking mechanism mounting member 440 includes a fixing portion 441 and a mounting portion 442 connected to each other, the rotating shaft 410 is connected to the fixing portion 441, the fixing portion 441 is fixedly connected to the first platform 100 through the mounting portion 442 to fixedly connect the rotating shaft 410 to the first platform 100, illustratively, the fixing portion may be a cylinder, the rotating shaft is fixedly connected to an inner wall of the cylinder to improve stability of the fixed connection, and illustratively, the mounting portion may be a plurality of columnar structures, and two ends of the columnar structures are respectively connected to the fixing portion of the rocking mechanism mounting member and the first surface of the first platform.

The electronic device processing tool provided in the embodiment of the invention is used by matching the telescopic shaking mechanism with the processing mechanism, specifically, the length of the shaking mechanism is adjustable by matching the telescopic rod and the rotating shaft, that is, the telescopic rod connected with the processing mechanism can be stretched along with the movement of the processing mechanism, so that the linkage between the processing mechanism and the shaking mechanism is realized by the telescopic rod, the effect of matching the movement of the processing mechanism is achieved, further, the shaking mechanism is fixedly installed on the first platform by using the shaking mechanism installation part, the stability of the fixed connection is improved,

the specific structure of the processing tool will be further explained with reference to fig. 1.

Illustratively, as shown in fig. 1, the processing tool further includes a support 610 and a drawer 620, wherein the support 610 is a shell structure having a second accommodating cavity 611, the support 610 further has an opening 612 communicating with the second accommodating cavity 611, the support 610 includes a first surface and a second surface, i.e., an upper surface and a lower surface in the drawing, which are oppositely arranged along a thickness direction of the support 610, the first surface of the support 610 is connected with the second surface 120 of the first platform 100, and as shown, the upper surface of the support is connected with the lower surface of the first platform; the drawer 620 is disposed in the second accommodating cavity 611 through the opening 612 and movably connected to the second accommodating cavity 611, for example, a drawer rail may be disposed at the bottom of the second accommodating cavity, and the drawer is slidably connected to the second accommodating cavity through the drawer rail, when the processing tool is used, the drawer 620 may be pulled out from the second accommodating cavity for placing tools, electronic devices or auxiliary materials, such as wound inductors, and the like, and the drawer may be pushed back when not used.

Illustratively, as shown in fig. 1 and 5, the processing tool further includes a lifting mechanism 700 for adjusting the height of the supporting base, the lifting mechanism 700 includes a bottom plate 710, a limiting plate 720, a plurality of first lifting links 731, a plurality of second lifting links 732, a plurality of first lifting shafts 741, a plurality of second lifting shafts 742, at least one third lifting shaft 753, and a driving assembly 750; each first lifting connecting rod 731 and the corresponding second lifting shaft 732 form intersection points in a crossed mode, and the intersection points are connected through a third lifting shaft 743; the first ends, i.e., upper ends, of the plurality of first lifting links 731 along the lengths thereof are connected by a first lifting shaft 741, the first ends, i.e., upper ends, of the plurality of second lifting links 732 along the lengths thereof are connected by a first lifting shaft 741, each first lifting shaft 741 is movably connected to the second surface, i.e., lower surface, of the support base 610 by a driving assembly 750, the driving assembly 750 drives each first lifting shaft 741 to be fixed at different positions on the second surface of the support base 610, and the heights of the support base 610 are adjusted by adjusting the distances between the plurality of first lifting shafts 741, i.e., the support base 610 is adjusted to move in the y direction shown in fig. 1; the plurality of first lifting links 731 are connected along a second end of the length thereof, i.e., a lower end thereof in the drawing, by a second lifting shaft 742, the plurality of second lifting links 732 are connected along a second end of the length thereof, i.e., a lower end thereof in the drawing, by a second lifting shaft 742, each of the second lifting shafts 742 moves to different positions on the base plate 710 according to the movement of the corresponding first lifting shaft 741, each of the second lifting shafts 742 is movably connected with the base plate 710 by a stopper plate 720, and the stopper plate 720 defines the position of each of the second lifting shafts 742 to define the height of the supporting base 610.

Illustratively, as shown in fig. 1 and 5, the upper ends of two first lifting links 731 are connected by a first lifting shaft 741, the upper ends of two second lifting rods 732 are connected by a first lifting shaft 741, the lower ends of the two first lifting links 731 are connected by a second lifting shaft 742, the lower ends of the two second lifting rods 732 are connected by a second lifting shaft 742, the central regions of the first and second lifting links intersect to form an intersection point, two sets of the first and second lifting rods respectively form two intersection points, the two intersection points are connected by a third lifting shaft, the two first lifting shafts 741 are respectively connected to a driving assembly 750, when the height of the supporting frame needs to be adjusted, the two first lifting shafts are driven by the driving assembly to move in the left and right directions in the drawing, the distances between the plurality of first lifting shafts 741 are changed, thereby shearing motion is done to the first lifter of drive and second lifter, shearing motion makes first lifter and second lifter change along the projection length of vertical direction, thereby adjust the height of supporting seat, in addition, the shearing motion of first lifter and second lifter drives two second lift axles 742 and removes along the left and right sides direction in the picture, also move to the different positions on the bottom plate promptly, after the altitude mixture control of supporting seat is accomplished, prescribes a limit to the position of two second lift axles on the bottom plate through the limiting plate, thereby locking second lift axle, prescribes a limit to the height of supporting seat unchangeably.

Specifically, as shown in fig. 1, the driving assembly 750 includes a second screw rod 751, a plurality of first elevation shafts 741 are respectively connected to the second screw rod 751, the second screw rod 751 drives each of the first elevation shafts 741 to move along a length direction of the second screw rod 751, that is, in a left-right direction in the drawing, by rotation so as to adjust a distance between the plurality of first elevation shafts 741, and exemplarily, the driving assembly 750 further includes a second knob 752 connected to one end of the second screw rod along the length direction thereof, that is, connected to a right end of the second screw rod, the second knob being used for rotating the second screw rod, thereby improving operability of the tool.

The electronic device processing tool provided by the embodiment provides a storage space for articles to be placed in the processing process by arranging the supporting seat and the drawer, improves the convenience of the processing tool in use, adjusts the height of the supporting seat by arranging the lifting mechanism so as to adjust the heights of the first platform and the second platform arranged on the supporting seat and further adjust the height of the processing mechanism, so that the processing tool in the embodiment can adjust the position in the horizontal direction and also can adjust the position in the vertical direction, further improves the flexibility and operability of the processing tool, further specifically limits the composition of the lifting mechanism and the specific structure of the driving assembly, realizes lifting adjustment by using a combined structure of the lifting connecting rod and the lifting shaft, has simple structure and easy operation, drives the movement of the lifting shaft by using the screw rod, and can finish height adjustment by only rotating the screw rod, and a lifting connecting rod or a lifting shaft does not need to be moved, so that the use convenience of the processing tool is further improved.

The specific structure of the processing tool will be further described with reference to fig. 1, 5 to 7.

Illustratively, as shown in fig. 1 and 5, the second platform 200 is further provided with a winding fixing member 900 for fixing a winding when performing an induction winding, and illustratively, the winding may be an enameled wire or a gold wire, and specifically, as shown in fig. 6, the winding fixture 900 includes a winding fixture body 910, and a mounting hole 920 provided at a first end of the wire fixing body 910 in a length direction thereof, i.e., a lower end in the drawing, and a wire fixing hole 930 provided at a second end thereof in a length direction thereof, i.e., an upper end in the drawing, and, for example, the mounting hole may be plural, wherein, the mounting hole 920 is used for fixedly mounting the winding wire fixing member main body 910 on the second platform 200, the winding wire fixing hole 930 is used for accommodating the winding wire, the winding wire fixing member 940 is movably inserted into the winding wire fixing hole 930, to secure the wire in the wire securing hole 930, the wire securing member may be, for example, a screw. Exemplarily, when the inductor needs to be wound, one end of a winding is penetrated into the winding fixing hole, the winding fixing piece is inserted into the winding fixing hole, the winding is compressed, the end of the winding is fixed, the winding is vertically placed on the first drill bit, the inductor winding is achieved through the rotation of the drill bit, and the winding of the inductor is completed.

Illustratively, as shown in fig. 7, the slider 510 includes a first connection portion 511 and a second connection portion 512 fixedly connected to each other, the first connection portion 511 is used for fixedly connecting the slider to the second platform, the second connection portion 512 is used for movably connecting the slider to the first platform, illustratively, the length of the first connection portion is greater than that of the second connection portion, the second connection portion is connected to a central region of the first connection portion along the length direction thereof, that is, the first connection portion and the second connection portion form a T-shaped structure, two ends of the first connection portion along the length direction thereof are fixedly connected to a second surface, that is, a lower surface of the second platform, illustratively, two ends of the first connection portion along the length direction thereof are respectively provided with a threaded hole fixedly connected to the second platform by a screw, and illustratively, the second connection portion 512 is clamped in the slider mounting groove to realize a connection with the first surface of the first platform, I.e., the sliding connection of the upper surface, the slider 510 is illustratively provided with a first screw mounting hole 513 extending through the length thereof for mounting a first screw.

The utility model provides an electron device processing frock, fix the wire winding in the inductance wire winding through setting up the wire winding mounting, thereby make at inductance coiling in-process wire winding can not remove, the stability of coiling process has been improved, the coiling efficiency has been promoted, in addition, further refine the structure of slider, use the first connecting portion fixed connection second platform in the slider, use the movably first platform of connection of second connecting portion in the slider, improve the convenience of slider and two platform mountings.

As shown in fig. 8, the present disclosure provides an electronic device processing method using a processing tool set forth in its entirety, the processing method including:

s100: rotating first hob 520, drive slider 510 moves along the length direction of first hob, that is, moves along the left-right direction in fig. 1, to drive second platform 200 to move to different positions of first platform along the length direction of first platform, that is, to drive second platform to move relative to first platform along the left-right direction in fig. 1, to move to different positions of first platform, and then drive the relative rocking mechanism of processing mechanism to move, adjust the position of processing mechanism in the course of processing through moving the processing mechanism, and stop until adjusting the processing mechanism to suitable position.

Illustratively, as shown in fig. 1, a telescopic rod in the rocking mechanism is connected to the processing mechanism, and the telescopic rod is extended and contracted according to the movement of the processing mechanism to adjust the relative position between the processing mechanism and the rocking mechanism, and specifically, when the second platform is moved by the driving mechanism to adjust the position of the processing mechanism, the telescopic rod connected with the processing mechanism in the shaking mechanism can stretch along with the movement of the processing mechanism, for example, when the processing mechanism moves leftwards in the drawing, the telescopic rod extends leftwards for a distance corresponding to the first accommodating cavity, thereby realizing the linkage between the processing mechanism and the shaking mechanism through the telescopic rod, after the telescopic rod is stretched to a proper position, then is fixedly connected with the inner wall of the first accommodating cavity, thereby realizing the fixed connection between the telescopic rod and the rotating shaft, and then when the rotating shaft is driven to rotate through the crank, the telescopic rod can be further driven to rotate, so that the machining mechanism is driven to rotate.

S200: the rocking mechanism 400 is rotated manually to drive the processing mechanism 300 to rotate so as to process an electronic device to be processed, which includes, for example, an inductor to be wound or an insulator to be stripped.

It should be noted that, in addition to the position of the processing mechanism being adjusted by the driving mechanism at the beginning of the processing, that is, at step S100, the position of the second platform may also be adjusted by the driving mechanism at any time during the processing, that is, during the processing performed at step S200, and then the position of the processing mechanism may be adjusted at any time according to the use requirement until the processing of the electronic device is completed.

In the electronic device processing method provided in the embodiment, the driving mechanism is operated to drive the second platform to move relative to the first platform, specifically, the first screw rod is rotated to drive the sliding block to move, so that the second platform connected with the sliding block is driven to move relative to the first platform, and then the processing mechanism connected with the second platform is driven to move, so that the position of the processing mechanism can be adjusted at any time according to use requirements in the processing process, the problem that the position of the processing mechanism cannot be adjusted at any time in the existing processing technology is solved, and the flexibility and operability of the processing tool are improved.

Illustratively, as shown in fig. 9, before step S200, a step S300 is further included, specifically:

s300: the first drill 310 or the second drill 320 is mounted to the drill holder 330 through the locking member 340 according to the machining process to be performed, and specifically, the first drill 310 is mounted to the drill holder 330 through the locking member 340 when the machining process is a wound inductor, and the second drill 320 is mounted to the drill holder 330 through the locking member 340 when the machining process is a stripped damaged insulator. In this case, step S200 further includes:

s210: when the machining process is to wind the inductor, the rotating and shaking mechanism 400 drives the machining mechanism 300 to rotate, the inductor coil is wound through the rotation of the first drill bit, the winding of the inductor coil is stopped when the winding number of the inductor coil reaches a preset number, specifically, one end of an enameled wire or a gold wire is vertically fixed on the first drill bit, the rotating and shaking mechanism drives the machining mechanism to rotate, specifically, the first drill bit is driven to rotate, the winding of the inductor coil is achieved, when the number of winding turns reaches a preset number, the operation of the shaking mechanism is stopped, the enameled wire or the gold wire is cut off by scissors and the like, and the inductor is pulled down along the axial direction of the first drill bit by a needle, so that the inductor winding is completed.

S220: when the processing technology is winding inductance, the swinging mechanism 400 is rotated to drive the processing mechanism 300 to rotate, the insulator to be stripped is stripped from the insulator box body through the rotation of the second drill bit, the insulator to be stripped is stopped when the insulator is stripped, specifically, the insulator to be stripped is aligned to the second drill bit, the swinging mechanism is rotated to drive the processing mechanism to rotate, specifically, the second drill bit is driven to rotate, the insulator is stripped from the insulator box body through the rotation of the second drill bit, the operation of the swinging mechanism is stopped after the circular ring of the insulator is stripped, and then a new insulator can be installed on the insulator box body, so that the insulator repairing process is completed.

It should be noted that step S300 may be before step S100 or after step S100, and this embodiment is not particularly limited.

In the processing method for the electronic device, the processing mechanism selects the first drill bit or the second drill bit to be mounted on the drill bit clamp to realize different processing technologies for different electronic devices, when the inductor needs to be wound, the first drill bit with the planar end surface is selected, and when the insulator needs to be stripped, the second drill bit with the curved end surface is selected, so that different processing technologies for different electronic devices are realized, the problem that the existing processing technology can only be realized through a certain specific processing tool is solved, and the processing cost and the operation difficulty are reduced.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present disclosure. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

It is to be understood that the above embodiments are merely exemplary embodiments that are employed to illustrate the principles of the present disclosure, and that the present disclosure is not limited thereto. It will be apparent to those skilled in the art that various changes and modifications can be made therein without departing from the spirit and scope of the disclosure, and these are to be considered as the scope of the disclosure.

Claims (10)

1. The utility model provides an electron device processing frock, its characterized in that, processing frock includes:

a first stage including a first surface and a second surface oppositely disposed in a thickness direction thereof;

a second platform including a first surface and a second surface oppositely disposed in a thickness direction thereof;

the processing mechanism is arranged on the first surface of the second platform and used for processing the electronic device to be processed through rotation;

the rocking mechanism is arranged at the first end of the first surface of the first platform along the length direction of the first surface, and is connected with the machining mechanism so as to drive the machining mechanism to rotate;

the driving mechanism comprises a sliding block and a first spiral rod, the second end of the first surface of the first platform along the length direction of the first surface of the first platform is movably connected with the sliding block, the sliding block is connected with the second surface of the second platform, one end of the first spiral rod along the length direction of the first spiral rod is connected with the sliding block, and the first spiral rod rotationally drives the sliding block to move along the length direction of the first spiral rod so as to drive the second platform to move to different positions of the first platform along the length direction of the first platform.

2. The tool according to claim 1, wherein the machining mechanism comprises a first drill bit, a second drill bit, a drill bit clamp and a locking member;

one end of the first drill bit in the length direction is connected with the drill bit clamp through the locking piece, or one end of the second drill bit in the length direction is connected with the drill bit clamp through the locking piece;

one end of the first drill bit, which is far away from the locking piece along the length direction of the first drill bit, is a plane and is used for carrying out winding processing on an inductance coil to be wound;

and one end of the second drill bit, which deviates from the locking piece along the length direction of the second drill bit, is a curved surface and is used for stripping the insulator to be stripped from the insulator box body.

3. The tooling of claim 1 or 2, wherein a slider mounting groove is formed in the first surface of the first platform along the length direction of the first platform, and the slider moves in the slider mounting groove along the length direction of the slider mounting groove to drive the second platform to move to different positions of the first surface of the first platform along the length direction of the first platform.

4. The tooling of claim 3, wherein the driving mechanism further comprises a clamping piece and a screw, one end of the first screw rod along the length direction of the first screw rod is arranged in the sliding block in a penetrating mode and is connected with the central area of the clamping piece through the screw, and the edge area of the clamping piece is connected with the first platform so as to fixedly connect one end of the first screw rod along the length direction of the first screw rod and the first platform.

5. The tool according to claim 1 or 2, wherein the shaking mechanism comprises a rotating shaft, a telescopic rod and a crank; wherein the content of the first and second substances,

the rotating shaft is provided with a first accommodating cavity and an accommodating hole communicated with the first accommodating cavity along the length direction of the rotating shaft, and one end of the rotating shaft, which deviates from the accommodating hole along the length direction of the rotating shaft, is connected with the crank;

the first end of the telescopic rod in the length direction is connected with the processing mechanism, the second end of the telescopic rod in the length direction is movably inserted into the first accommodating cavity through the accommodating hole and is selectively and fixedly connected with the inner wall of the first accommodating cavity in the circumferential direction, so that the second end of the telescopic rod in the length direction can be fixed at different positions in the first accommodating cavity in the length direction.

6. The tool according to claim 5, wherein the rocking mechanism further comprises a rocking mechanism mounting member, the rocking mechanism mounting member comprises a fixing portion and a mounting portion which are connected, the rotating shaft is connected with the fixing portion, and the fixing portion is fixedly connected with the first platform through the mounting portion so as to fixedly connect the rotating shaft with the first platform.

7. The tooling of claim 1 or 2, wherein the machining tooling further comprises:

the supporting seat is of a shell structure with a second accommodating cavity, the supporting seat is also provided with an opening part communicated with the second accommodating cavity, the supporting seat comprises a first surface and a second surface which are oppositely arranged along the thickness direction of the supporting seat, and the first surface of the supporting seat is connected with the second surface of the first platform;

and the drawer is arranged in the second accommodating cavity through the opening part and is movably connected with the second accommodating cavity.

8. The tool according to claim 7, wherein the processing tool further comprises a lifting mechanism for adjusting the height of the supporting seat, and the lifting mechanism comprises a bottom plate, a limiting plate, a plurality of first lifting connecting rods, a plurality of second lifting connecting rods, a plurality of first lifting shafts, a plurality of second lifting shafts, at least one third lifting shaft and a driving assembly; wherein the content of the first and second substances,

each first lifting connecting rod and the corresponding second lifting shaft are crossed to form an intersection point, and the intersection points are connected through the third lifting shaft;

the first ends of the first lifting connecting rods along the lengths of the first lifting connecting rods are connected through a first lifting shaft, the first ends of the second lifting connecting rods along the lengths of the second lifting connecting rods are connected through a first lifting shaft, each first lifting shaft is movably connected with the second surface of the supporting seat through the driving assembly, the driving assembly drives each first lifting shaft to be fixed at different positions of the second surface of the supporting seat, and the height of the supporting seat is adjusted by adjusting the distance between the first lifting shafts;

the plurality of first lifting connecting rods are connected along the second ends of the lengths thereof through the second lifting shafts, the plurality of second lifting connecting rods are connected along the second ends of the lengths thereof through the second lifting shafts, each second lifting shaft moves to different positions on the bottom plate according to the movement of the corresponding first lifting shaft, each second lifting shaft is movably connected with the bottom plate through the limiting plate, and the limiting plate limits the position of each second lifting shaft so as to limit the height of the supporting seat.

9. The tool according to claim 8, wherein the driving assembly comprises a second screw rod, the plurality of first lifting shafts are respectively connected with the second screw rod, and the second screw rod rotationally drives each first lifting shaft to move along the length direction of the second screw rod so as to adjust the distance between the plurality of first lifting shafts.

10. A method for processing a multifunctional electronic device, wherein the processing tool of any one of claims 1 to 9 is used, the method comprising:

rotating the first spiral rod to drive the sliding block to move along the length direction of the first spiral rod so as to drive the second platform to move to different positions of the first platform along the length direction of the first platform;

and rotating the rocking mechanism to drive the processing mechanism to rotate so as to process the electronic device to be processed.

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