CN215578205U - Magnetic ring inductor through-plate shaping machine - Google Patents

Abstract

The utility model belongs to the technical field of magnetic ring inductance production equipment, and particularly relates to a magnetic ring inductance through plate shaping machine, which comprises: the magnetic ring inductor positioning plate penetrating device is used for inserting pins on the magnetic ring inductor into the openings on the partition plate so as to form a magnetic ring inductor semi-finished product; and the shifting and shaping device is assembled on the magnetic ring inductor positioning and penetrating plate device and is used for adjusting the pin positions on the magnetic ring inductor semi-finished product on the magnetic ring inductor positioning and penetrating plate device and shaping the pins so as to form a magnetic ring inductor finished product. The magnetic ring inductor through plate shaping machine has the advantages of reasonable structural design, convenience in product assembly and the like, saves manpower, simplifies the production process of products, improves the assembly efficiency of the products, and greatly improves the assembly precision of the products, thereby improving the qualification rate of product assembly and ensuring the uniformity of product assembly styles.

Description

Magnetic ring inductor through-plate shaping machine

Technical Field

The utility model belongs to the technical field of magnetic ring inductor production equipment, and particularly relates to a magnetic ring inductor through plate shaping machine.

Background

The magnetic ring inductor is an electronic component and mainly used for electromagnetic induction conversion. The magnetic ring inductor consists of a magnetic ring body and an enameled wire wound on the magnetic ring body, and the coils are close to each other without a gap. At present, the safe distance between two windings of a magnetic ring inductor is usually ensured by adding a plastic partition plate at the pin of the magnetic ring inductor, and then the inductance of the magnetic ring inductor is prevented from being influenced after the two windings are in line contact. In the assembling process of the magnetic ring inductor and the partition board, pins on the magnetic ring inductor are manually inserted into the holes in the partition board and are shaped in the market, and finally, a finished magnetic ring inductor product is produced, so that the problems of low assembling efficiency and non-uniform product styles exist.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a magnetic ring inductor through plate shaping machine, and aims to solve the technical problems that in the prior art, a finished magnetic ring inductor is obtained by manual production, the assembly efficiency is low, and the product styles are not uniform.

In order to achieve the above object, an embodiment of the present invention provides a magnetic ring inductor through-board shaping machine, including:

the magnetic ring inductor positioning plate penetrating device is used for inserting pins on the magnetic ring inductor into the openings on the partition plate so as to form a magnetic ring inductor semi-finished product;

and the shifting and shaping device is assembled on the magnetic ring inductor positioning and penetrating plate device and is used for adjusting the pin positions on the magnetic ring inductor semi-finished product on the magnetic ring inductor positioning and penetrating plate device and shaping the pins so as to form a magnetic ring inductor finished product.

Optionally, the magnetic ring inductor positioning penetrating plate device includes:

the plate penetrating base is used for bearing the partition plate;

the partition storing and conveying mechanism is arranged on the plate penetrating base and is used for storing the batch partitions before conveying and sending the batch partitions out one by one;

and the magnetic ring inductance positioning insertion mechanism is arranged on the penetrating plate base and positioned at the conveying tail end of the partition plate storage and conveying mechanism so as to receive the partition plate and is used for correcting pins on the magnetic ring inductance so as to be accurately inserted into the open holes on the partition plate.

Optionally, a product bearing rod is arranged on the base of the penetration plate; the product bearing rod is arranged at the conveying tail end of the partition board storage and conveying mechanism and is positioned below the magnetic ring inductance positioning insertion mechanism so as to bear the partition board; the penetrating plate base is positioned on two sides of the product bearing rod and penetrates through the product bearing rod so that pins on two sides of the magnetic ring inductor can penetrate out of the product bearing rod.

Optionally, the separator storage and transport mechanism comprises:

the partition plate storage unit is arranged on the plate penetrating base, communicated with the inside of the plate penetrating base and used for sending batches of partition plates into the inside of the plate penetrating base one by one;

and the baffle conveying unit is arranged on the penetrating plate base, and the output end of the baffle conveying unit extends into the penetrating plate base and is used for conveying a single baffle to the magnetic ring inductance positioning insertion mechanism.

Optionally, a plurality of positioning and guiding insertion holes corresponding to the openings in the partition plate one to one are formed in the magnetic ring inductor positioning and inserting mechanism, and the pins on the magnetic ring inductor penetrate through the positioning and guiding insertion holes and move along the vertical direction of the positioning and guiding insertion holes.

Optionally, the magnetic ring inductance positioning insertion mechanism includes a first positioning insertion unit and a second positioning insertion unit which are arranged oppositely; notches are formed on the opposite sides of the first positioning insertion unit and the second positioning insertion unit; when the first positioning inserting unit and the second positioning inserting unit are folded, the first positioning inserting unit and the notch on the second positioning inserting unit are enclosed to form the positioning guide inserting hole.

Optionally, grooves are formed on opposite sides of the first positioning insertion unit and the second positioning insertion unit; when the first positioning plug-in unit and the second positioning plug-in unit are folded, the first positioning plug-in unit and a groove on the second positioning plug-in unit are enclosed to form a partition guiding sliding groove matched with the partition storing and conveying mechanism for use, the positioning guiding insertion holes are correspondingly arranged at the tail ends of the partition guiding sliding grooves, and the partition moves to the positioning guiding insertion holes along the partition guiding sliding grooves.

Optionally, the displacement profiling apparatus comprises:

the linear movement driving mechanism is assembled on the magnetic ring inductor positioning plate penetrating device;

the pin clamping mechanism is assembled on the linear movement driving mechanism;

the pin opening and bending mechanism is assembled on the pin clamping mechanism;

the pin clamping mechanism and the pin bending mechanism are synchronously folded and used for clamping pins on two sides of the magnetic ring inductor semi-finished product; the linear movement driving mechanism drives the pin clamping mechanism and the pin opening and bending mechanism to move downwards, and is used for driving pins on two sides of the magnetic ring inductor semi-finished product to move downwards relative to the partition plate; the pin clamping mechanism and the pin opening and bending mechanism are synchronously separated and are used for opening pins on two sides of the magnetic ring inductor semi-finished product to enable the pins on the two sides to be splayed and abut against the bottom of the partition plate.

Optionally, the pin clamping mechanism comprises a dual output clamping drive source and a pin clamping unit; the double-output clamping driving source is assembled on the linear movement driving mechanism; the pin clamping unit is assembled on the output shaft of the double-output clamping driving source, and a clamping area is formed on the pin clamping unit and used for clamping pins on the magnetic ring inductor semi-finished product; the dual-output clamping driving source drives the pin clamping unit to act so as to reduce or open the clamping area.

Optionally, the open-pin bending mechanism includes a dual-output open-pin driving source and a pin bending unit; the double-output pin driving source is assembled on the pin clamping mechanism; the pin bending unit is assembled on the output shaft of the double-output pin-opening driving source; the double-output pin-opening driving source drives the pin bending unit to be opened, and pins on two sides of the magnetic ring inductor semi-finished product are opened.

One or more technical schemes in the magnetic ring inductor through plate shaping machine provided by the embodiment of the utility model at least have one of the following technical effects: compared with the prior art, the magnetic ring inductor through-plate shaping machine realizes that a single device finishes the operations of inserting the pins on the magnetic ring inductor into the holes on the partition plate, adjusting the positions of the pins and shaping the pins by the mutual matching of the magnetic ring inductor positioning through-plate device and the shifting shaping device. In conclusion, the magnetic ring inductor through plate shaping machine has the advantages of being reasonable in structural design, convenient to assemble products and the like, manpower is saved, production procedures of the products are simplified, assembling efficiency of the products is improved, assembling precision of the products is greatly improved, accordingly, qualification rate of product assembling is improved, and uniformity of product assembling styles is guaranteed.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise.

Fig. 1 is a perspective view of a magnetic ring inductor through-board shaping machine according to an embodiment of the present invention.

Fig. 2 is an exploded schematic view of a magnetic ring inductor through-board shaping machine according to an embodiment of the present invention.

Fig. 3 is a front view of a magnetic ring inductor through-board shaper (with installation housing omitted) according to an embodiment of the present invention.

Fig. 4 is a perspective view of a magnetic ring inductor positioning plate penetrating device provided in an embodiment of the present invention in a closed state.

Fig. 5 is a perspective view of a magnetic ring inductor positioning plate penetrating device provided in an embodiment of the present invention in a separated state.

Fig. 6 is a bottom view of a magnetic ring inductor positioning board penetrating device (omitting a board penetrating base) according to an embodiment of the present invention.

Fig. 7 is a schematic structural diagram of a first positioning plug unit and a second positioning plug unit according to an embodiment of the present invention.

Fig. 8 is a perspective view of a shift shaping device according to an embodiment of the present invention.

Fig. 9 is a front view of a shift shaper in accordance with an embodiment of the present invention.

Fig. 10 is a perspective view of a linear motion driving mechanism according to an embodiment of the present invention.

Fig. 11 is a perspective view of a pin clamping mechanism according to an embodiment of the utility model.

Fig. 12 is a perspective view of the leg opening and bending mechanism according to the embodiment of the present invention.

Wherein, in the figures, the respective reference numerals:

100. a magnetic ring inductor positioning plate penetrating device;

200. a base plate penetrating; 210. a product carrier bar; 220. a first side positioning guide seat; 221. a baffle plate discharge hole; 222. a partition transportation chute; 230. a second side positioning guide seat;

300. a separator storage and transport mechanism; 310. a partition storage unit; 311. a partition plate limiting guide pillar; 320. a partition conveying unit; 321. a separator push rod; 322. a partition pushing drive source;

400. a magnetic ring inductor positioning and inserting mechanism; 410. positioning the guide jack; 420. a partition plate guide chute; 430. a first positioning plug-in unit; 440. a second positioning plug-in unit; 450. positioning the plugboard; 460. a jack panel drive source; 470. a driving connecting block;

500. a displacement shaping device;

600. a linear movement driving mechanism; 610. moving the mounting platform; 620. a moving stretching drive source; 630. a drive source mounting bracket;

700. a pin clamping mechanism; 710. a dual output clamping drive source; 720. a pin clamping unit; 721. a first clamping member; 722. a second clamping member; 723. a connecting portion; 724. a clamping portion;

800. a foot opening and bending mechanism; 810. a dual-output foot-opening driving source; 820. a pin bending unit; 821. a first bending member; 822. a second bending member; 823. a fixed part; 824. a push-open part;

900. and (5) installing the shell.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary and intended to be illustrative of the embodiments of the present invention, and should not be construed as limiting the utility model.

In the description of the embodiments of the present invention, it should be understood that the terms "length", "width", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience in describing the embodiments of the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of 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 embodiments of the present invention, "a plurality" means two or more unless specifically limited otherwise.

In the embodiments of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," "fixed," and the like are to be construed broadly, e.g., as being fixedly connected, detachably connected, or integrated; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. Specific meanings of the above terms in the embodiments of the present invention can be understood by those of ordinary skill in the art according to specific situations.

In an embodiment of the present invention, as shown in fig. 1 to 3, there is provided a magnetic ring inductor through plate shaping machine, including:

the magnetic ring inductor positioning and penetrating plate device 100 is used for inserting pins on the magnetic ring inductor into the openings on the partition plate so as to form a semi-finished product of the magnetic ring inductor;

and the shifting and shaping device 500 is assembled on the magnetic ring inductor positioning plate penetrating device 100, and is used for adjusting the pin positions on the magnetic ring inductor semi-finished product on the magnetic ring inductor positioning plate penetrating device 100 and shaping the pins, so as to form a magnetic ring inductor finished product.

Specifically, in this embodiment, when the magnetic ring inductor through-board shaping machine is used: firstly, pins on the magnetic ring inductor are inserted into the holes on the partition plate in a mode of manually combining the magnetic ring inductor positioning plate penetrating device 100 to obtain a semi-finished product of the magnetic ring inductor; and then, the pin positions and the pin shaping on the semi-finished product of the magnetic ring inductor on the magnetic ring inductor positioning plate penetrating device 100 are adjusted by using the displacement shaping device 500, and finally, a finished product of the magnetic ring inductor is obtained through production. Therefore, the magnetic ring inductor through-plate shaping machine realizes that a single device finishes the operations of inserting the pins on the magnetic ring inductor into the holes on the partition plate, adjusting the positions of the pins and shaping the pins by the mutual matching of the magnetic ring inductor positioning through-plate device 100 and the displacement shaping device 500. In conclusion, the magnetic ring inductor through plate shaping machine has the advantages of being reasonable in structural design, convenient to assemble products and the like, manpower is saved, production procedures of the products are simplified, assembling efficiency of the products is improved, assembling precision of the products is greatly improved, accordingly, qualification rate of product assembling is improved, and uniformity of product assembling styles is guaranteed.

In addition, the magnetic ring inductor through plate shaping machine further comprises an installation shell 900, and the magnetic ring inductor positioning through plate device 100 and the displacement shaping device 500 are assembled in the installation shell 900 to obtain airtight protection, so that the service life is prolonged.

In another embodiment of the present invention, as shown in fig. 4 to 5, the magnetic ring inductor positioning board penetrating device 100 includes:

a base 200 for receiving the partition plate;

the partition storing and conveying mechanism 300 is arranged on the plate penetrating base 200 and used for storing the batch partitions before conveying and sending out the batch partitions one by one;

and a magnetic ring inductor positioning insertion mechanism 400, wherein the magnetic ring inductor positioning insertion mechanism 400 is arranged on the through board base 200 and is positioned at the conveying tail end of the partition board storage and conveying mechanism 300 so as to receive the partition board and correct pins on the magnetic ring inductor so as to be accurately inserted into the open holes on the partition board.

Specifically, in this embodiment, when the magnetic ring inductor positioning through-plate device 100 is used: firstly, a batch of partition boards are stored in the partition board storage and conveying mechanism 300, then the partition board storage and conveying mechanism 300 sends out the batch of partition boards one by one to the magnetic ring inductance positioning insertion mechanism 400, and pins on the magnetic ring inductance are inserted into the holes on the partition boards in a mode of manually combining the magnetic ring inductance positioning insertion mechanism 400, so that a semi-finished magnetic ring inductance product is obtained. It can be seen that the magnetic ring inductor positioning and board penetrating device 100 achieves operations of loading the partition board and inserting the pins on the magnetic ring inductor into the openings on the partition board through the mutual cooperation between the partition board storage and conveying mechanism 300 and the magnetic ring inductor positioning and inserting mechanism 400. In summary, with the aid of the magnetic ring inductor positioning insertion mechanism 400, the shape of the pins on the magnetic ring inductor can be adapted to, so that the flexibility of pin punching is realized, the pin punching period is shortened, and the assembly efficiency is improved.

In another embodiment of the present invention, as shown in fig. 5, a product carrying rod 210 is disposed on the base 200; the product bearing rod 210 is arranged at the conveying end of the separator storage and conveying mechanism 300 and below the magnetic ring inductance positioning insertion mechanism 400 to bear the separator; the board penetrating base 200 is disposed on two sides of the product carrying rod 210, and is used for the pins on two sides of the magnetic ring inductor to penetrate out. Specifically, in this embodiment, the product bearing rod 210 is arranged to bear the partition board and position the partition board, so that not only the pins on the magnetic ring inductor are conveniently inserted into the openings on the partition board by the magnetic ring inductor positioning and inserting mechanism 400, but also the positions of the pins on the two sides of the magnetic ring inductor semi-finished product relative to the partition board are conveniently adjusted by the displacement shaping device 500.

In another embodiment of the present invention, as shown in fig. 4 to 5, the partition storing and conveying mechanism 300 includes:

the partition storage unit 310 is installed on the through-board base 200, is communicated with the inside of the through-board base 200, and is used for feeding batches of partitions into the inside of the through-board base 200 one by one;

and the partition conveying unit 320 is installed on the board penetrating base 200, and the output end of the partition conveying unit 320 extends into the board penetrating base 200, so as to convey the single partition to the magnetic ring inductance positioning insertion mechanism 400.

Specifically, in the present embodiment, the separator storage and transport mechanism 300, when in use: firstly, a batch of partition boards are stored in the partition board storage unit 310, then the batch of partition boards fall down from the partition board storage unit 310 one by one and are sent into the interior of the through board base 200, and finally the output end of the partition board conveying unit 320 extends into the interior of the through board base 200 and sends the single partition board to the magnetic ring inductance positioning insertion mechanism 400, so that a process of loading the partition boards is completed. Therefore, the partition storing and conveying mechanism 300 realizes the automatic operation of partition loading, simplifies the production process of the product and improves the assembly efficiency of the product through the mutual cooperation between the partition storing unit 310 and the partition conveying unit 320.

Further, in this embodiment, the partition storage unit 310 includes a plurality of partition retaining guide pillars 311 vertically disposed on the base 200, and the batch of partitions are stored in a space surrounded by the plurality of partition retaining guide pillars 311. The baffles are blocked by the baffle limiting guide pillars 311 on the periphery, so that the baffles in batches are stacked up and down neatly.

Further, in the present embodiment, the separator conveying unit 320 includes a separator pushing rod 321 and a separator pushing driving source 322; the front end of the partition push rod 321 is movably arranged inside the board penetrating base 200; the partition pushing driving source 322 is installed on the board penetrating base 200, and an output shaft of the partition pushing driving source 322 is connected to a tail end of the partition pushing rod 321 to drive the partition pushing rod 321 to move. The partition pushing driving source 322 may be, but is not limited to, an electric screw set, a hydraulic cylinder, a pneumatic cylinder, or the like, and is not limited in the present invention.

In another embodiment of the present invention, as shown in fig. 4 to 6, the base 200 is provided with a first side positioning guide seat 220 and a second side positioning guide seat 230; the partition storing and conveying mechanism 300 is connected with the first side positioning guide seat 220 in a matching way; the first side positioning guide seat 220 and the second side positioning guide seat 230 are arranged at intervals, and a sliding track is formed in the middle of the first side positioning guide seat and the second side positioning guide seat, and the magnetic ring inductance positioning insertion mechanism 400 is slidably arranged in the sliding track. Specifically, in this embodiment, the first side positioning guide seat 220 and the second side positioning guide seat 230 are arranged to provide a guiding function for the magnetic ring inductance positioning insertion mechanism 400, so that the magnetic ring inductance positioning insertion mechanism has the characteristics of compact structure, high guiding precision, small resistance and no lubrication, and further ensures accurate positioning of the magnetic ring inductance positioning insertion mechanism 400 and ensures product quality.

In another embodiment of the present invention, as shown in fig. 4 to 6, a partition discharging hole 221 for the partition to fall down is formed on the first side positioning guide seat 220, a partition transporting chute 222 for transporting the partition is formed at two ends of the middle of the first side positioning guide seat 220, and the partition transporting chute 222 is communicated with the partition discharging hole 221. Specifically, in the present embodiment, by providing the partition discharging hole 221 and the partition transporting chute 222, the matching tightness between the partition storing and conveying mechanism 300 and the first side positioning guide seat 220 is improved, the structure is compact and firm, and the operation reliability is strong.

In another embodiment of the present invention, as shown in fig. 4, a plurality of positioning guiding insertion holes 410 corresponding to the openings of the partition board one by one are formed on the magnetic ring inductor positioning insertion mechanism 400, and the pins on the magnetic ring inductor penetrate through the positioning guiding insertion holes 410 and move along the vertical direction thereof.

The positioning guide insertion hole 410 is a tapered hole with a wide upper end and a narrow lower end, and the diameter of the opening at the upper end of the positioning guide insertion hole 410 is larger than the diameter of the opening at the lower end of the positioning guide insertion hole 410.

Further, the shape of the lower end opening of the positioning guide insertion hole 410 matches the shape of the opening of the partition plate.

Further, the diameter of the lower opening of the positioning guide insertion hole 410 is equal to or smaller than the diameter of the opening of the partition.

Specifically, in this embodiment, the positioning guide insertion holes 410 are arranged to be wide at the top and narrow at the bottom, so that the smoothness of inserting the pins on the magnetic ring inductor into the openings on the partition board can be improved, and the pins on the magnetic ring inductor under different shapes and contours can be adapted to smoothly guide the pins into the openings on the partition board.

In another embodiment of the present invention, the number of the pins on the magnetic loop inductor, the number of the openings on the partition board, and the number of the positioning guiding insertion holes 410 are the same, and four pins are provided, so as to ensure that each pin on the magnetic loop inductor can be smoothly inserted into the opening on the partition board.

In another embodiment of the present invention, as shown in fig. 4 to 5, the magnetic ring inductance positioning insertion mechanism 400 includes a first positioning insertion unit 430 and a second positioning insertion unit 440, which are oppositely disposed; notches are formed on the opposite sides of the first positioning insertion unit 430 and the second positioning insertion unit 440; when the first positioning inserting unit 430 and the second positioning inserting unit 440 are folded, the first positioning inserting unit 430 and the second positioning inserting unit 440 form the positioning guiding inserting hole 410 by surrounding with a gap. Specifically, in the present embodiment, the first positioning plug unit 430 and the second positioning plug unit 440 can be closed or separated. When the first positioning plug-in unit 430 and the second positioning plug-in unit 440 are close to each other, the positioning guide insertion hole 410 is formed, so as to position the pin on the magnetic ring inductor. When the first positioning insertion unit 430 and the second positioning insertion unit 440 are far away from each other, the magnetic ring inductor is released to be processed or taken and placed in the next step, so that the overall structure is simplified, the tooling cost is lower, and the operation is simpler and more convenient.

In another embodiment of the present invention, as shown in fig. 6, grooves are further formed on opposite sides of the first positioning plug unit 430 and the second positioning plug unit 440; when the first positioning plug-in unit 430 and the second positioning plug-in unit 440 are folded, the first positioning plug-in unit 430 and the groove on the second positioning plug-in unit 440 are enclosed to form a partition guiding chute 420 used in cooperation with the partition storing and conveying mechanism 300, a plurality of positioning guiding insertion holes 410 are correspondingly arranged at the tail end of the partition guiding chute 420, and the partition moves to the positioning guiding insertion holes 410 along the partition guiding chute 420. Specifically, in this embodiment, when the first positioning insertion unit 430 and the second positioning insertion unit 440 are close to each other, the partition guiding chute 420 is formed at the same time, so as to guide the partition conveyed by the partition storage and conveying mechanism 300, thereby ensuring that the partition can accurately move to the positioning guiding insertion hole 410, and the positioning precision is higher.

In another embodiment of the present invention, as shown in fig. 7, the first positioning plug unit 430 and the second positioning plug unit 440 have the same structure, and each include a positioning plug board 450 and a plug board driving source 460; one end of the positioning insertion board 450 adjacent to the insertion board driving source 460 is connected to an output shaft of the insertion board driving source 460 through a driving connection block 470, and one end of the positioning insertion board 450 far away from the insertion board driving source 460 is provided with the notch and the groove. Specifically, in the present embodiment, the positioning plug board 450 is driven to move by the plug board driving source 460, wherein the plug board driving source 460 may be, but is not limited to, an electric screw set, an oil pressure cylinder, or a pneumatic cylinder, and the utility model is not limited thereto.

In another embodiment of the present invention, as shown in FIGS. 8 to 9, the displacement shaper 500 comprises:

the linear movement driving mechanism 600, the linear movement driving mechanism 600 is assembled on the magnetic ring inductor positioning plate penetrating device 100;

a pin clamping mechanism 700, said pin clamping mechanism 700 being mounted on said linear motion driving mechanism 600;

and a pin-opening bending mechanism 800, wherein the pin-opening bending mechanism 800 is assembled on the pin clamping mechanism 700.

Specifically, in the present embodiment, the displacement shaper device 500, when in use: firstly, the pin clamping mechanism 700 and the open pin bending mechanism 800 are synchronously closed and clamp the pins on two sides of the magnetic ring inductor semi-finished product; then, the linear movement driving mechanism 600 drives the pin clamping mechanism 700 and the pin bending mechanism 800 to move downwards and drive the pins on the two sides of the magnetic ring inductor semi-finished product to move downwards relative to the partition plate; and finally, synchronously separating the pin clamping mechanism 700 and the pin bending mechanism 800 and opening the pins on two sides of the semi-finished product of the magnetic ring inductor, so that the pins on the two sides are splayed and abut against the bottom of the partition plate, thereby obtaining the finished product of the magnetic ring inductor. Therefore, the displacement shaping device 500 realizes the adjustment of the position of the partition on the magnetic ring inductor and the full-automatic operation of pin shaping by the mutual cooperation among the linear motion driving mechanism 600, the pin clamping mechanism 700 and the pin bending mechanism 800, and greatly improves the product assembly efficiency. In addition, the linear movement driving mechanism 600, the pin clamping mechanism 700 and the pin opening and bending mechanism 800 are fixed together, so that the time for repeated movement and positioning can be saved in the processing process, and the working efficiency is greatly improved.

In another embodiment of the present invention, as shown in fig. 10, the linear movement driving mechanism 600 includes a movable mounting platform 610 and a movable tension driving source 620; the movable stretching driving source 620 is assembled on the magnetic ring inductance positioning plate penetrating device 100, and an output shaft of the movable stretching driving source 620 is connected with the movable mounting platform 610; the pin clamping mechanism 700 is mounted on the movable mounting platform 610; the movable driving source 620 drives the movable mounting platform 610 and the pin clamping mechanism 700 to move linearly. Specifically, in this embodiment, the movable stretching driving source 620 has a simple structure, and can ensure high traveling precision, so as to precisely control the displacement of the pin clamping mechanism 700 and the open-pin bending mechanism 800, thereby improving the processing precision. The moving and stretching driving source 620 may be, but is not limited to, an electric screw set, a hydraulic cylinder, a pneumatic cylinder, etc., and is not limited in the present invention.

In another embodiment of the present invention, as shown in fig. 10, the moving tension driving source 620 is provided in two; the two movable stretching driving sources 620 are arranged at the two ends of the movable mounting platform 610 at intervals, a movable accommodating space for the pin clamping mechanism 700 to work is formed between the two movable stretching driving sources 620, and the pin clamping mechanism 700 is arranged in the movable accommodating space and clamped between the two movable stretching driving sources 620. Specifically, in this embodiment, the two symmetrically disposed moving stretching driving sources 620 can improve the stability of the pin clamping mechanism 700 and the pin bending mechanism 800 during the linear motion, and can well control the inertia generated during the motion.

In another embodiment of the present invention, as shown in fig. 10, the main body of the movable stretching driving source 620 is mounted to the magnetic ring inductor positioning board penetrating device 100 through a driving source mounting bracket 630; the driving source mounting bracket 630 is arranged in an L shape, the vertical edge of the driving source mounting bracket 630 is attached to and fixed with the main body of the movable stretching driving source 620, and the horizontal edge of the driving source mounting bracket 630 is attached to and fixed with the magnetic ring inductance positioning plate penetrating device 100. Specifically, in this embodiment, the driving source mounting bracket 630 has a simple structure, can improve the mounting rapidity of the movable stretching driving source 620, and can ensure the mounting and fixing reliability of the movable stretching driving source 620, and has the advantages of a small number of mounting parts and low mounting cost.

In another embodiment of the present invention, as shown in fig. 11, the pin clamping mechanism 700 includes a dual output clamping drive source 710 and a pin clamping unit 720; the dual output grip driving source 710 is assembled to the linear movement driving mechanism 600; the pin clamping unit 720 is assembled on the output shaft of the dual-output clamping driving source 710, and a clamping area is formed on the pin clamping unit 720 for clamping the pins on the magnetic ring inductor semi-finished product; the dual-output clamping driving source 710 drives the pin clamping unit 720 to act, so as to achieve the reduction or expansion of the clamping area. Specifically, in the present embodiment, the pin clamping mechanism 700 facilitates miniaturization by the cooperation between the dual output clamping driving source 710 and the pin clamping unit 720, thereby improving the operation accuracy and reliability.

In another embodiment of the present invention, as shown in fig. 11, the pin clamping unit 720 includes a first clamping member 721 and a second clamping member 722; the first clamping member 721 is disposed opposite to the second clamping member 722 and disposed at both sides of the dual output clamping driving source 710; the clamping area is formed between the first clamp 721 and the second clamp 722; output shafts on two sides of the dual-output clamping driving source 710 are respectively connected with the first clamping part 721 and the second clamping part 722, and are used for driving the first clamping part 721 and the second clamping part 722 to move relatively to adjust the distance between the two clamping parts. Specifically, in this embodiment, wide type gas claw cylinder is chooseed for use to dual output centre gripping driving source 710, and then realizes through one dual output centre gripping driving source 710 can drive first holder 721 with the action of centre gripping is done to second holder 722, and its simple operation can be effectively and quick completion centre gripping location operation, is favorable to guaranteeing the efficiency of processing and the precision of processing, and stability in use is good, and the suitability is strong and the practicality is good.

In another embodiment of the present invention, as shown in fig. 11, the first clamping member 721 and the second clamping member 722 have the same structure, and each of the first clamping member 721 and the second clamping member 722 includes a connecting portion 723 for connecting to an output shaft of the dual-output clamping driving source 710, and a clamping portion 724 for clamping a pin on the magnetic ring inductor semi-finished product, where the connecting portion 723 and the clamping portion 724 are integrally formed and are arranged in a trapezoid shape. Specifically, in the present embodiment, the connecting portion 723 and the clamping portion 724 have high integrity, a stable structure, and a long service life, and are effectively prevented from being deformed.

In another embodiment of the present invention, as shown in fig. 12, the open-pin bending mechanism 800 includes a dual-output open-pin driving source 810 and a pin bending unit 820; the dual output pin drive source 810 is mounted on the pin clamping mechanism 700; the pin bending unit 820 is assembled on the output shaft of the dual-output pin-opening driving source 810; the double-output pin-opening driving source 810 drives the pin bending unit 820 to open, so that pins on two sides of the magnetic ring inductor semi-finished product are opened. Specifically, in this embodiment, the open-pin bending mechanism 800 can bend pins on two sides at one time by the mutual cooperation between the dual-output open-pin driving source 810 and the pin bending unit 820 under the condition of ensuring the bending quality, so that the manual labor intensity is low in the process, time and labor are saved, and the requirement of mass production is met.

In another embodiment of the present invention, as shown in fig. 12, the pin bending unit 820 includes a first bending part 821 and a second bending part 822; the first bending part 821 and the second bending part 822 are adjacently disposed and disposed at both sides of the dual output foot driving source 810; output shafts on two sides of the dual-output foot-open driving source 810 are respectively connected to the first bending part 821 and the second bending part 822, and are used for driving the first clamping part 721 and the second clamping part 722 to move relatively to adjust the distance between the two clamping parts. Specifically, in this embodiment, pneumatic clamping jaw is chooseed for use to dual output open foot driving source 810, and then realizes through one dual output open foot driving source 810 can drive first bending 821 with the relative movement is made to second bending 822, and its simple operation can open the operation of both sides pin effectively and quick completion, is favorable to guaranteeing the efficiency of processing and the precision of processing, and stability in use is good, and the suitability is strong and the practicality is good.

In another embodiment of the present invention, as shown in fig. 12, the first bending part 821 and the second bending part 822 have the same structure, and each of the first bending part 821 and the second bending part 822 includes a fixing part 823 for connecting to an output shaft of the dual-output pin driving source 810 and a stretching part 824 for stretching pins on the magnetic ring inductor semi-finished product, and the fixing part 823 is integrally formed with the stretching part 824 and is disposed in an L shape. Specifically, in this embodiment, the fixing portion 823 and the pushing and expanding portion 824 have high integrity, stable structure, effective deformation prevention, and long service life.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. Magnetic ring inductance through-plate shaper, its characterized in that includes:

the magnetic ring inductor positioning plate penetrating device is used for inserting pins on the magnetic ring inductor into the openings on the partition plate so as to form a magnetic ring inductor semi-finished product;

and the shifting and shaping device is assembled on the magnetic ring inductor positioning and penetrating plate device and is used for adjusting the pin positions on the magnetic ring inductor semi-finished product on the magnetic ring inductor positioning and penetrating plate device and shaping the pins so as to form a magnetic ring inductor finished product.

2. The magnetic ring inductor through plate shaper as set forth in claim 1, wherein: the magnetic ring inductance positioning plate penetrating device comprises:

the plate penetrating base is used for bearing the partition plate;

the partition storing and conveying mechanism is arranged on the plate penetrating base and is used for storing the batch partitions before conveying and sending the batch partitions out one by one;

and the magnetic ring inductance positioning insertion mechanism is arranged on the penetrating plate base and positioned at the conveying tail end of the partition plate storage and conveying mechanism so as to receive the partition plate and is used for correcting pins on the magnetic ring inductance so as to be accurately inserted into the open holes on the partition plate.

3. The magnetic ring inductor through plate shaper as set forth in claim 2, wherein: a product bearing rod is arranged on the base of the penetration plate; the product bearing rod is arranged at the conveying tail end of the partition board storage and conveying mechanism and is positioned below the magnetic ring inductance positioning insertion mechanism so as to bear the partition board; the penetrating plate base is positioned on two sides of the product bearing rod and penetrates through the product bearing rod so that pins on two sides of the magnetic ring inductor can penetrate out of the product bearing rod.

4. The magnetic ring inductor through plate shaper as set forth in claim 2, wherein: the baffle storage conveying mechanism comprises:

the partition plate storage unit is arranged on the plate penetrating base, communicated with the inside of the plate penetrating base and used for sending batches of partition plates into the inside of the plate penetrating base one by one;

and the baffle conveying unit is arranged on the penetrating plate base, and the output end of the baffle conveying unit extends into the penetrating plate base and is used for conveying a single baffle to the magnetic ring inductance positioning insertion mechanism.

5. The magnetic ring inductor through plate shaper as set forth in claim 2, wherein: the magnetic ring inductor positioning and inserting mechanism is provided with a plurality of positioning and guiding jacks which are in one-to-one correspondence with the holes in the partition plate, and pins on the magnetic ring inductor penetrate through the positioning and guiding jacks and move along the vertical direction of the positioning and guiding jacks.

6. The magnetic ring inductor through plate shaper as set forth in claim 5, wherein: the magnetic ring inductance positioning insertion mechanism comprises a first positioning insertion unit and a second positioning insertion unit which are arranged oppositely; notches are formed on the opposite sides of the first positioning insertion unit and the second positioning insertion unit; when the first positioning inserting unit and the second positioning inserting unit are folded, the first positioning inserting unit and the notch on the second positioning inserting unit are enclosed to form the positioning guide inserting hole.

7. The magnetic ring inductor through plate shaper as set forth in claim 6, wherein: grooves are formed on the opposite sides of the first positioning insertion unit and the second positioning insertion unit; when the first positioning plug-in unit and the second positioning plug-in unit are folded, the first positioning plug-in unit and a groove on the second positioning plug-in unit are enclosed to form a partition guiding sliding groove matched with the partition storing and conveying mechanism for use, the positioning guiding insertion holes are correspondingly arranged at the tail ends of the partition guiding sliding grooves, and the partition moves to the positioning guiding insertion holes along the partition guiding sliding grooves.

8. The magnetic ring inductor through plate shaper as set forth in claim 1, wherein: the displacement reshaping device comprises:

the linear movement driving mechanism is assembled on the magnetic ring inductor positioning plate penetrating device;

the pin clamping mechanism is assembled on the linear movement driving mechanism;

the pin opening and bending mechanism is assembled on the pin clamping mechanism;

the pin clamping mechanism and the pin bending mechanism are synchronously folded and used for clamping pins on two sides of the magnetic ring inductor semi-finished product; the linear movement driving mechanism drives the pin clamping mechanism and the pin opening and bending mechanism to move downwards, and is used for driving pins on two sides of the magnetic ring inductor semi-finished product to move downwards relative to the partition plate; the pin clamping mechanism and the pin opening and bending mechanism are synchronously separated and are used for opening pins on two sides of the magnetic ring inductor semi-finished product to enable the pins on the two sides to be splayed and abut against the bottom of the partition plate.

9. The magnetic ring inductor through plate shaper as set forth in claim 8, wherein: the pin clamping mechanism comprises a double-output clamping driving source and a pin clamping unit; the double-output clamping driving source is assembled on the linear movement driving mechanism; the pin clamping unit is assembled on the output shaft of the double-output clamping driving source, and a clamping area is formed on the pin clamping unit and used for clamping pins on the magnetic ring inductor semi-finished product; the dual-output clamping driving source drives the pin clamping unit to act so as to reduce or open the clamping area.

10. The magnetic ring inductor through plate shaper as set forth in claim 8, wherein: the pin opening and bending mechanism comprises a double-output pin opening driving source and a pin bending unit; the double-output pin driving source is assembled on the pin clamping mechanism; the pin bending unit is assembled on the output shaft of the double-output pin-opening driving source; the double-output pin-opening driving source drives the pin bending unit to be opened, and pins on two sides of the magnetic ring inductor semi-finished product are opened.

Images