CN219066622U - Inductance wire winding production facility - Google Patents

Abstract

The utility model relates to the technical field of inductance winding production and discloses inductance winding production equipment, wherein a rotary driving assembly comprises a transmission fluted disc rotatably connected above a supporting platform and a transmission gear meshed with one side of the transmission fluted disc, a transverse transmission screw rod is rotatably connected inside a track of a transverse guide rail, and longitudinal transmission screw rods are rotatably connected inside tracks of two groups of longitudinal guide rails. According to the utility model, the clamping jaw assembly is used for fixing the magnetic core in a butt clamping manner, a traditional mode of friction driving rotation by using a roller is replaced under the rotary driving of the gear of the rotary driving assembly, the rotary driving mechanism has high-efficiency and accurate rotary transmission performance, the clamping jaw assembly is used for controlling the horizontal symmetrical displacement and the longitudinal butt clamping displacement of the clamping handles of the rotary driving mechanism, the rotary driving mechanism has flexible and adjustable performance, the magnetic cores with different sizes can be clamped, and then the rotary driving mechanism can be suitable for magnetic core coiling with different sizes under the rotary driving of the gear of the rotary driving assembly.

Description

Inductance wire winding production facility

Technical Field

The utility model relates to the technical field of inductance winding production, in particular to inductance winding production equipment.

Background

The inductor (inductance coil) is an electromagnetic induction element wound by insulated wires (such as enameled wires, yarn covered wires and the like), is one of commonly used components in electronic circuits, and is generally divided into an oscillating inductor, a correcting inductor, a kinescope deflection inductor, a choke inductor, a filtering inductor, an isolating inductor, a compensated inductor and the like, plays roles of energy storage, filtering, delay, oscillation and the like on electric elements, and is an important element for guaranteeing stable and safe operation of a board card.

In the production process of the inductor, an insulated wire is coiled on a magnetic core, and along with the development of the era, the traditional manual winding mode is gradually replaced by a machine, the magnetic core is oppositely clamped between three groups of rollers, the three groups of rollers are utilized to push the magnetic core to rotate, then the insulated wire is coiled on the magnetic core under the upper and lower hooking of a hooking device, the roller is utilized to drive the magnetic core to rotate, then the insulated wire is coiled on the magnetic core, the roller is very easy to push out of place due to friction, the rotation driving stability of the magnetic core is poor, and the insulated wire cannot be uniformly coiled on the magnetic core. Accordingly, one skilled in the art provides an inductance coil production apparatus to solve the above-mentioned problems.

Disclosure of Invention

The utility model aims to provide an inductance winding production device for solving the problems in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the inductance winding production equipment comprises a supporting platform, wherein a rotary driving assembly is arranged above the supporting platform, and a clamping jaw assembly is arranged above a transmission fluted disc in the rotary driving assembly;

the rotary driving assembly comprises a transmission fluted disc rotatably connected above the supporting platform and a transmission gear meshed with one side of the transmission fluted disc;

the clamping jaw assembly comprises a transverse guide rail arranged above a transmission fluted disc and located at a central shaft, a transverse transmission screw rod is rotationally connected inside a track of the transverse guide rail, two groups of transverse sliding tables are symmetrically sleeved at screw rod ends of the transverse transmission screw rod, transverse supports are arranged through the transverse guide rail in a penetrating mode, two groups of longitudinal guide rails are symmetrically arranged above the two groups of transverse supports, longitudinal transmission screw rods are rotationally connected inside the track of the longitudinal guide rail, two groups of longitudinal sliding tables are symmetrically sleeved at screw rod ends of the longitudinal transmission screw rod, longitudinal supports are arranged through the longitudinal guide rails in a penetrating mode at the top output ends of the longitudinal sliding tables, and two groups of clamping handles are symmetrically arranged at the output ends of the longitudinal supports.

As still further aspects of the utility model: the transmission fluted disc is rotatably connected with the supporting platform through a central shaft arranged at the central end of the transmission fluted disc.

As still further aspects of the utility model: the transmission gear is rotatably connected with the supporting platform through an output shaft arranged at the center end of the transmission gear, and a rotary driving motor is arranged at the bottom output end of the output shaft, penetrating through the supporting platform in a matched mode.

As still further aspects of the utility model: the output end of one end of the transverse transmission screw rod penetrates through the transverse guide rail to be provided with a transverse transmission motor, the transverse transmission screw rod is bounded by a central line, the two sides of the central line are respectively provided with a positive screw tooth and a negative screw tooth which are symmetrically arranged with each other, and the transverse transmission screw rod is symmetrically sleeved with the two groups of transverse sliding tables through the positive screw tooth and the negative screw tooth.

As still further aspects of the utility model: the top output end of the longitudinal transmission screw rod penetrates through the longitudinal guide rail to be provided with a longitudinal transmission motor, the longitudinal transmission screw rod is bounded by a central line, the two sides of the central line are respectively provided with a positive screw tooth and a negative screw tooth which are symmetrically arranged with each other, and the longitudinal transmission screw rod is symmetrically sleeved with the two groups of longitudinal sliding tables through the positive screw tooth and the negative screw tooth.

As still further aspects of the utility model: the clamping face end of the clamping handle is provided with anti-slip saw teeth.

Compared with the prior art, the utility model has the beneficial effects that:

1. according to the utility model, the clamping jaw assembly is used for clamping and fixing the magnetic core, and the traditional mode of friction driving rotation by using the rolling shaft is replaced by the gear rotation driving of the rotation driving assembly, so that the device has high-efficiency and accurate rotation transmission performance, and the wire coiling uniformity of the insulated wire can be improved.

2. According to the utility model, the clamping handles of the clamping jaw assembly are controlled to horizontally and symmetrically displace and longitudinally clamp the clamping handles, so that the clamping jaw assembly has flexible and adjustable performance, and can clamp magnetic cores with different sizes, and then under the rotary driving of the gears of the rotary driving assembly, the clamping jaw assembly can adapt to the work of magnetic core coiling wires with different sizes, and the flexible adaptability is enhanced.

Drawings

FIG. 1 is a schematic diagram of an inductance coil production apparatus;

FIG. 2 is a schematic diagram of a rotary drive assembly in an induction coil production apparatus;

FIG. 3 is a schematic diagram of a jaw assembly in an induction coil production apparatus;

fig. 4 is a schematic plan view of a jaw assembly in an induction coil production apparatus.

In the figure: 1. a support platform; 2. a transmission fluted disc; 3. a transmission gear; 4. a transverse guide rail; 5. a longitudinal guide rail; 6. a clamping handle; 7. an output shaft; 8. a central shaft; 9. a transverse transmission motor; 10. a transverse support; 11. a longitudinal support; 12. a longitudinal transmission motor; 13. a screw rod is transversely driven; 14. a transverse sliding table; 15. longitudinally driving a screw rod; 16. a longitudinal sliding table.

Description of the embodiments

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1 to 4, in an embodiment of the utility model, an inductance winding production device includes a supporting platform 1, a rotary driving component is installed above the supporting platform 1, the rotary driving component includes a transmission fluted disc 2 rotatably connected above the supporting platform 1 and a transmission gear 3 engaged with and driven on one side of the transmission fluted disc 2, the transmission fluted disc 2 is rotatably connected with the supporting platform 1 through a central shaft 8 installed at the central end of the transmission fluted disc 2, the transmission gear 3 is rotatably connected with the supporting platform 1 through an output shaft 7 installed at the central end of the transmission fluted disc 3, and a rotary driving motor is arranged at the bottom output end of the output shaft 7 in a matched manner, after clamping and fixing an inductance magnetic core, the matched rotary driving motor works to drive the output shaft 7 to rotate, and synchronously drives the transmission gear 3 to rotate, and drives the transmission fluted disc 2 to rotate with the central shaft 8 as an axis through the engagement transmission of the transmission gear 3, and then drives a magnetic core at the clamping arm end of the clamping handle 6 to rotate synchronously with the central shaft 8 as an axis, and the wire hooking device is used for coiling an insulation wire on the magnetic core instead of the traditional way of using a roller to rotate, thereby achieving efficient and accurate rotation, and improving the wire insulation performance.

The clamping jaw assembly is arranged above the transmission fluted disc 2 in the rotary driving assembly, the clamping jaw assembly comprises a transverse guide rail 4 which is arranged above the transmission fluted disc 2 and is positioned at a central shaft, a transverse transmission screw rod 13 is rotationally connected inside a track of the transverse guide rail 4, two groups of transverse sliding tables 14 are symmetrically sleeved at screw rod ends of the transverse transmission screw rod 13, top output ends of the two groups of transverse sliding tables 14 penetrate through the transverse guide rail 4 and are provided with transverse supports 10, one end output end of the transverse transmission screw rod 13 penetrates through the transverse guide rail 4 and is provided with a transverse transmission motor 9, the transverse transmission screw rod 13 takes a central line as a boundary, two sides of the central line are respectively provided with a positive wire tooth and a negative wire tooth which are symmetrically arranged with each other, the transverse transmission screw rod 13 is symmetrically sleeved with the two groups of transverse sliding tables 14 through the positive wire tooth and the negative wire tooth, when an inductance magnetic core is wound and produced, the magnetic core is placed between the clamping handles 6, the center of the magnetic core is right above the central shaft 8, then the transverse transmission motor 9 works to drive the transverse transmission screw rod 13 to rotate, the positive wire tooth and the negative wire tooth which are symmetrically arranged with each other, the two groups of transverse sliding tables 14 are pushed to symmetrically slide in the transverse guide rail 4, and then push the clamping handles 6 to symmetrically slide, so that the two sides of the clamping handles 6 are symmetrically displaced to the two sides.

The upper parts of the two groups of transverse supporting seats 10 are symmetrically provided with two groups of longitudinal guide rails 5, the inside of the tracks of the two groups of longitudinal guide rails 5 is rotationally connected with a longitudinal transmission screw rod 15, screw rod ends of the longitudinal transmission screw rod 15 are symmetrically sleeved with two groups of longitudinal sliding tables 16, top output ends of the two groups of longitudinal sliding tables 16 penetrate through the longitudinal guide rails 5 and are provided with longitudinal supporting seats 11, the top output ends of the longitudinal transmission screw rod 15 penetrate through the longitudinal guide rails 5 and are provided with longitudinal transmission motors 12, the longitudinal transmission screw rod 15 takes a central line as a boundary, two sides of the central line are respectively provided with positive and negative screw teeth which are symmetrically arranged with each other, the longitudinal transmission screw rod 15 is symmetrically sleeved with the two groups of longitudinal sliding tables 16 through the positive and negative screw teeth, when the clamping handle 6 is symmetrically moved to two sides of a magnetic core, the longitudinal transmission motor 12 starts to rotate, the two groups of longitudinal sliding tables 16 are pushed to symmetrically slide in the longitudinal guide rails 5 through the positive and negative screw teeth which are symmetrically arranged with each other, the clamping handle 6 is clamped and fixed, the magnetic core is fixed right above the central shaft 8, and the magnetic core is kept concentrically and rotationally driven with the central shaft 8.

The output end symmetry of vertical support 11 is provided with two sets of clamp handles 6, and the clamp face end of clamp handle 6 is provided with anti-skidding sawtooth, when winding production to inductance magnetic core, through the horizontal symmetrical displacement of clamp handle 6 of clamping jaw subassembly control and vertical to the clamp displacement, has nimble adjustable performance, can carry out the clamp work to the magnetic core of equidimension not, then under the gear rotary drive of rotary drive subassembly, can adapt to the magnetic core coiling work of equidimension not, strengthens its nimble adaptability.

The working principle of the utility model is as follows: when the inductance magnetic core is wound and produced, the magnetic core is placed between the clamping handles 6, the center of the magnetic core is right above the central shaft 8, then the transverse transmission motor 9 works to drive the transverse transmission screw rod 13 to rotate, the two groups of transverse sliding tables 14 are pushed to symmetrically slide in the transverse guide rail 4 through the right and the reverse screw teeth which are symmetrically arranged with each other, then the clamping handles 6 are pushed to symmetrically slide, the clamping handles 6 are symmetrically displaced to the two sides of the magnetic core, then after the clamping handles 6 symmetrically move to the two sides of the magnetic core, the longitudinal transmission motor 12 starts to work to drive the longitudinal transmission screw rod 15 to rotate, the two groups of longitudinal sliding tables 16 are pushed to symmetrically slide in the longitudinal guide rail 5 through the right and the reverse screw teeth which are symmetrically arranged with each other, the clamping handles 6 are clamped in pairs, the magnetic core is fixed above the central shaft 8, concentric rotation transmission is kept between the two groups of the magnetic core 8, further matched rotation driving motors work to drive the output shaft 7 to rotate, the synchronous driving transmission gears 3 rotate, the transmission shafts 2 are meshed with the transmission gears 3 to drive the transmission shafts 8 to rotate, the transmission shafts 2 to rotate around the central shaft 8 as the axis, and then the clamping arms 6 are pushed to wind the magnetic core around the central shaft 8 as the axis, and the magnetic core is simultaneously, and the magnetic core is wound on the transmission wire is insulated.

Claims (6)

1. The inductance winding production equipment comprises a supporting platform (1) and is characterized in that a rotary driving assembly is arranged above the supporting platform (1), and a clamping jaw assembly is arranged above a transmission fluted disc (2) in the rotary driving assembly;

the rotary driving assembly comprises a transmission fluted disc (2) rotatably connected above the supporting platform (1) and a transmission gear (3) meshed with and transmitted to one side of the transmission fluted disc (2);

the clamping jaw assembly comprises a transverse guide rail (4) which is arranged above a transmission fluted disc (2) and located at a central shaft, a transverse transmission screw rod (13) is connected to the inside of a track of the transverse guide rail (4) in a rotating mode, two groups of transverse sliding tables (14) are symmetrically sleeved at screw rod ends of the transverse transmission screw rod (13), transverse supports (10) are arranged at top output ends of the transverse sliding tables (14) in a penetrating mode, two groups of longitudinal guide rails (5) are symmetrically arranged above the two groups of transverse supports (10), longitudinal transmission screw rods (15) are rotatably connected to the inside of the track of the longitudinal guide rails (5), two groups of longitudinal sliding tables (16) are symmetrically sleeved at screw rod ends of the longitudinal transmission screw rods (15), longitudinal supports (11) are arranged at top output ends of the longitudinal sliding tables (16) in a penetrating mode, and two groups of clamping handles (6) are symmetrically arranged at output ends of the longitudinal supports (11).

2. An induction winding production device according to claim 1, characterized in that the driving toothed disc (2) is rotatably connected with the supporting platform (1) by means of a central shaft (8) mounted with its central end.

3. An induction winding production device according to claim 1, characterized in that the transmission gear (3) is rotatably connected with the supporting platform (1) by an output shaft (7) arranged at the center end of the transmission gear, and a rotary driving motor is arranged at the bottom output end of the output shaft (7) penetrating through the supporting platform (1) in a matched manner.

4. An induction winding production device according to claim 1, characterized in that one end output end of the transverse transmission screw rod (13) penetrates through the transverse guide rail (4) and is provided with a transverse transmission motor (9), the transverse transmission screw rod (13) is bounded by a central line, two sides of the central line are respectively provided with positive screw teeth and negative screw teeth which are symmetrically arranged with each other, and the transverse transmission screw rod (13) is symmetrically sleeved with two groups of transverse sliding tables (14) through the positive screw teeth and the negative screw teeth.

5. The inductance winding production device according to claim 1, wherein a longitudinal transmission motor (12) is arranged at the top output end of the longitudinal transmission screw rod (15) penetrating through the longitudinal guide rail (5), the longitudinal transmission screw rod (15) is bounded by a central line, positive screw teeth and negative screw teeth which are symmetrically arranged with each other are respectively arranged on two sides of the central line, and the longitudinal transmission screw rod (15) is symmetrically sleeved with two groups of longitudinal sliding tables (16) through the positive screw teeth and the negative screw teeth.

6. An induction winding production device according to claim 1, characterized in that the clamping face end of the clamping handle (6) is provided with anti-slip serrations.

Images