CN220661665U - Purely mechanical control wire winding machine for FDM3D printer - Google Patents

Abstract

The utility model discloses a pure mechanical control wire winding machine for an FDM3D printer, which comprises a supporting component, a driving mechanism, a winding component and a control component, wherein the supporting component comprises a bottom plate and two vertical plates which are vertically fixed at one side of the upper end of the bottom plate and symmetrically arranged, a U-shaped groove is formed in the middle of the upper end of each vertical plate, the driving mechanism comprises a motor fixed at the side surface of one vertical plate, a driving gear fixed at the output end of the motor, a first gear meshed with the lower side of the outer wall of the driving gear and a second gear meshed with the lower side of the outer wall of the first gear, and the winding component comprises a winding shaft vertically rotatably arranged in the U-shaped groove. This a pure mechanical control wire rod coiler for FDM3D printer, when the motor drive winding roller through setting up rotates the wire rod winding, still drives the hollow rod in the control assembly and carries out the side-to-side slip to can control the winding wire rod, ensure the even winding of wire rod on the winding roller.

Description

Purely mechanical control wire winding machine for FDM3D printer

Technical Field

The utility model relates to the technical field of ground induction coil protection, in particular to a pure mechanical control wire winding machine for an FDM3D printer.

Background

FDM is a so far readily available and widely used 3D printing process, FDM3D printing technology extrudes thermoplastic filaments according to software preset coordinates, building parts layer by layer from bottom to top. It uses a professional 3D printing technique for production grade thermoplastics. The FDM3D printer needs to wind the wire during use.

When the existing wire is wound, in order to prevent the phenomenon of uneven winding of the wire, the wire in the winding process needs to be manually controlled, the winding is troublesome, and therefore, a pure mechanical control wire winding machine of an FDM3D printer is necessary.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the utility model and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description summary and in the title of the application, to avoid obscuring the purpose of this section, the description summary and the title of the utility model, which should not be used to limit the scope of the utility model.

The present utility model has been made in view of the above and/or problems occurring in the prior wire winding machines.

Therefore, the utility model aims to provide a purely mechanical control wire winding machine for an FDM3D printer, which drives a winding roller to rotate to wind wires and simultaneously drives a hollow rod in a control assembly to slide left and right, so that the wound wires can be controlled, and the wires are ensured to be uniformly wound on the winding roller.

In order to solve the technical problems, according to one aspect of the present utility model, the following technical solutions are provided:

a purely mechanically controlled wire winder for an FDM3D printer, comprising:

the support assembly comprises a bottom plate and two vertical plates which are vertically fixed at one side of the upper end of the bottom plate and are symmetrically arranged, and a U-shaped groove is formed in the middle of the upper end of each vertical plate;

the driving mechanism comprises a motor fixed on one side of the vertical plate, a driving gear fixed at the output end of the motor, a first gear meshed with the lower side of the outer wall of the driving gear and a second gear meshed with the lower side of the outer wall of the first gear;

the winding assembly comprises a winding shaft vertically arranged in the U-shaped groove in a rotating mode and a winding roller arranged outside the winding shaft and positioned at the inner sides of the two vertical plates, and a driven gear meshed with the driving gear is fixed on the outer wall of one side of the winding shaft;

the control assembly comprises a rotating shaft vertically fixed on the inner side of the second gear, a worm fixed on the outer wall of the rotating shaft, a worm wheel meshed with the outer wall of the worm, a vertical shaft fixed in the middle of the worm wheel and vertically arranged on the bottom plate in a rotating mode, a concave plate sleeved outside the vertical shaft, a sliding plate sleeved outside the vertical shaft and positioned at the upper end of the concave plate, a semicircular gear fixed on the upper end of the outer portion of the vertical shaft, a mounting plate arranged on one side of the upper end of the semicircular gear and a hollow rod arranged in the mounting plate, racks meshed with the semicircular gear are fixed on the opposite inner walls of the sliding plate, and one end of a wire rod penetrates through the hollow rod and is fixed on the winding roller;

preferably, the bottom of the bottom plate is provided with an adhesive tape. The adhesive tape arranged at the bottom of the bottom plate can fix the bottom plate at a designated position in an adhesive manner, so that the stable placement of the whole device is ensured.

Preferably, annular plates are fixed at two ends of the outer wall of the winding roller, and a plurality of through holes are uniformly formed in the annular plates. The through holes formed in the annular plate can facilitate operators to know the quantity of the wires wound on the winding roller.

Preferably, the outer wall of the sliding plate is attached to the inner wall of the concave plate. The sliding plate with the outer wall attached to the inner wall of the concave plate can generate certain friction force with the concave plate when sliding, so that the sliding plate is ensured to be stable in the sliding process.

Preferably, a fixed plate is fixed on the side wall of the mounting plate, and a first bolt penetrates through the fixed plate and is arranged at the upper end of the fixed plate. The mounting panel is installed on the sliding plate through first bolt under the effect of fixed plate, and later stage operator of being convenient for carries out the dismouting to the mounting panel.

Preferably, a second bolt is arranged at the upper end of the mounting plate, a hole channel for placing the hollow rod is formed in the mounting plate, and the second bolt penetrates into the hole channel. The hollow rod is arranged in the pore canal of the mounting plate under the action of the second bolt, and a later operator can take down the second bolt to take down the hollow rod so as to disassemble, assemble and replace the hollow rod.

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

(1) The winding roller is driven by the motor to rotate to wind the wire rod, and the hollow rod in the control assembly is driven to slide left and right, so that the wound wire rod can be controlled, and the wire rod is ensured to be uniformly wound on the winding roller.

(2) Through the through hole of seting up on the ring board can be convenient for the operator know how much the wire rod of winding on the winding roller.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the following detailed description of the embodiments of the present utility model will be given with reference to the accompanying drawings, which are to be understood as merely some embodiments of the present utility model, and from which other drawings can be obtained by those skilled in the art without inventive faculty. Wherein:

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic perspective view of a control assembly according to the present utility model;

FIG. 3 is a schematic diagram of an exploded view of a control assembly according to the present utility model;

in the figure: 100. a support assembly; 110. a bottom plate; 120. a vertical plate; 200. a driving mechanism; 210. a motor; 220. a drive gear; 230. a first gear; 240. a second gear; 300. a winding assembly; 310. a winding shaft; 311. a driven gear; 320. a winding roller; 400. a control assembly; 410. a rotating shaft; 420. a worm; 430. a worm wheel; 440. a concave plate; 450. a sliding plate; 460. a semicircular gear; 470. a mounting plate; 471. a fixing plate; 472. a first bolt; 473. a second bolt; 480. a hollow rod.

Detailed Description

In order that the above objects, features and advantages of the utility model will be readily understood, a more particular description of the utility model will be rendered by reference to the appended drawings.

Next, the present utility model will be described in detail with reference to the drawings, wherein the sectional view of the device structure is not partially enlarged to general scale for the convenience of description, and the drawings are only examples, which should not limit the scope of the present utility model. In addition, the three-dimensional dimensions of length, width and depth should be included in actual fabrication.

For the purpose of making the objects, technical solutions and advantages of the present utility model more apparent, embodiments of the present utility model will be described in further detail below with reference to the accompanying drawings.

The utility model provides a pure mechanical control wire winding machine for an FDM3D printer, which drives a winding roller to rotate to wind wires and simultaneously drives a hollow rod in a control assembly to slide left and right, so that the wound wires can be controlled, and the wires are ensured to be uniformly wound on the winding roller.

Fig. 1 to 3 are schematic structural views of an embodiment of a purely mechanical control wire winding machine for an FDM3D printer according to the present utility model, referring to fig. 1 to 3, a main body portion of the purely mechanical control wire winding machine for an FDM3D printer includes a support assembly 100, a driving mechanism 200, a winding assembly 300 and a control assembly 400.

The support assembly 100 includes a base plate 110 and two vertical plates 120 vertically fixed to one side of the upper end of the base plate 110 and symmetrically arranged, and a U-shaped groove is formed in the middle of the upper end of each vertical plate 120. Preferably, in the present embodiment, the bottom of the base plate 110 is provided with an adhesive tape, and the adhesive tape provided at the bottom of the base plate 110 can fix the base plate 110 at a designated position by gluing, thereby ensuring stable placement of the entire device.

The driving mechanism 200 includes a motor 210 fixed to a side of the one side riser 120, a driving gear 220 fixed to an output end of the motor 210, a first gear 230 engaged with a lower side of an outer wall of the driving gear 220, and a second gear 240 engaged with a lower side of an outer wall of the first gear 230.

The winding assembly 300 includes a winding shaft 310 vertically rotatably disposed in the U-shaped groove and a winding roller 320 disposed outside the winding shaft 310 and positioned inside the two risers 120, and a driven gear 311 engaged with the driving gear 220 is fixed to an outer wall of one side of the winding shaft 310. Preferably, in this embodiment, the two ends of the outer wall of the winding roller 320 are fixed with circular plates, and a plurality of through holes are uniformly formed in the circular plates, so that the operator can know how much wire is wound on the winding roller 320.

The control assembly 400 includes a rotation shaft 410 vertically fixed to the inside of the second gear 240, a worm 420 fixed to the outer wall of the rotation shaft 410, a worm wheel 430 engaged to the outer wall of the worm wheel 420, a vertical shaft fixed to the middle of the worm wheel 430 and vertically rotatably provided on the base plate 110, a concave plate 440 sleeved outside the vertical shaft, a sliding plate 450 sleeved outside the vertical shaft and positioned at the upper end of the concave plate 440, a semicircular gear 460 fixed to the upper end of the outside of the vertical shaft, a mounting plate 470 installed at one side of the upper end of the semicircular gear 460, and a hollow rod 480 provided in the mounting plate 470, racks engaged with the semicircular gear 460 being fixed to the opposite inner walls of the sliding plate 450, and one end of the wire passing through the hollow rod 480 and being fixed to the winding roller 320. Preferably, in this embodiment, the outer wall of the sliding plate 450 is attached to the inner wall of the concave plate 440, the sliding plate 450 with the outer wall attached to the inner wall of the concave plate 440 can generate a certain friction force with the concave plate 440 when sliding, so as to ensure the stability of the sliding plate 450 in the sliding process, the side wall of the mounting plate 470 is fixed with a fixing plate 471, the upper end of the fixing plate 471 is provided with a first bolt 472, the first bolt 472 penetrates through the fixing plate 471 to the sliding plate 450, the mounting plate 470 is mounted on the sliding plate 450 through the first bolt 472 under the action of the fixing plate 471, the mounting plate 470 is convenient for a later operator to mount and dismount the mounting plate 470, the upper end of the mounting plate 470 is provided with a second bolt 473, a hole for placing the hollow rod 480 is formed in the mounting plate 470, the second bolt 473 penetrates into the hole, the hollow rod 480 is mounted in the hole of the mounting plate 470 under the action of the second bolt 473, and the later operator can take down the second bolt 473 to take down the hollow rod 480, so as to mount and dismount the hollow rod 480.

Referring to fig. 1-3, the pure mechanical control wire winder for FDM3D printers of the present embodiment is specifically used as follows: the operator passes through the hollow bar 480 at one end of the wire to be wound and fixes the wire on the winding roller 320, the motor 210 is started, the motor 210 drives the driving gear 220 to rotate, the rotating driving gear 220 drives the driven gear 311 to rotate, and then drives the winding roller 320 to rotate, thereby winding the wire, the driving gear 220 drives the first gear 230 and the second gear 240 to rotate synchronously in the rotating process, and then drives the rotating shaft 410 and the worm 420 to rotate, the rotating worm 420 drives the worm wheel 430 to rotate, and then drives the semicircular gear 460 to rotate, the rotating semicircular gear 460 drives the sliding plate 450 to slide in the concave plate 440, thereby driving the mounting plate 470 and the hollow bar 480 to slide, and further controlling the wound wire, so as to ensure that the wire is uniformly wound on the winding roller 320.

Although the utility model has been described hereinabove with reference to embodiments, various modifications thereof may be made and equivalents may be substituted for elements thereof without departing from the scope of the utility model. In particular, the features of the disclosed embodiments may be combined with each other in any manner as long as there is no structural conflict, and the exhaustive description of these combinations is not given in this specification merely for the sake of omitting the descriptions and saving resources. Therefore, it is intended that the utility model not be limited to the particular embodiment disclosed, but that the utility model will include all embodiments falling within the scope of the appended claims.

Claims (6)

1. A pure mechanical control wire winding machine for FDM3D printer, its characterized in that includes:

the support assembly (100) comprises a bottom plate (110) and two vertical plates (120) which are vertically fixed at one side of the upper end of the bottom plate (110) and are symmetrically arranged, and a U-shaped groove is formed in the middle of the upper end of each vertical plate (120);

the driving mechanism (200) comprises a motor (210) fixed on one side of the vertical plate (120), a driving gear (220) fixed at the output end of the motor (210), a first gear (230) meshed with the lower side of the outer wall of the driving gear (220) and a second gear (240) meshed with the lower side of the outer wall of the first gear (230);

the winding assembly (300) comprises a winding shaft (310) vertically and rotatably arranged in the U-shaped groove and a winding roller (320) arranged outside the winding shaft (310) and positioned at the inner sides of the two vertical plates (120), and a driven gear (311) meshed with the driving gear (220) is fixed on the outer wall of one side of the winding shaft (310);

the control assembly (400) comprises a rotating shaft (410) vertically fixed on the inner side of the second gear (240), a worm (420) fixed on the outer wall of the rotating shaft (410), a worm wheel (430) meshed with the outer wall of the worm (420), a vertical shaft fixed in the middle of the worm wheel (430) and vertically rotating and arranged on the bottom plate (110), a concave plate (440) sleeved on the outer portion of the vertical shaft, a sliding plate (450) sleeved on the outer portion of the vertical shaft and positioned at the upper end of the concave plate (440), a semicircular gear (460) fixed on the upper end of the outer portion of the vertical shaft, a mounting plate (470) mounted on one side of the upper end of the semicircular gear (460) and a hollow rod (480) arranged in the mounting plate (470), wherein racks meshed with the semicircular gear (460) are fixed on the opposite inner walls of the sliding plate (450), and one end of a wire rod penetrates through the hollow rod (480) and is fixed on the winding roller (320).

2. The purely mechanically controlled wire winder for an FDM3D printer according to claim 1, characterised in that the bottom of the bottom plate (110) is provided with adhesive tape.

3. The purely mechanical control wire winding machine for an FDM3D printer according to claim 1, wherein circular plates are fixed at both ends of the outer wall of the winding roller (320), and a plurality of through holes are uniformly formed in the circular plates.

4. The purely mechanical controlled wire winder for an FDM3D printer of claim 1, wherein the outer wall of the sliding plate (450) fits against the inner wall of the female plate (440).

5. The purely mechanical controlled wire winder for FDM3D printers according to claim 1, wherein the side wall of the mounting plate (470) is fixed with a fixing plate (471), the upper end of the fixing plate (471) is provided with a first bolt (472), and the first bolt (472) penetrates the fixing plate (471) into the sliding plate (450).

6. The purely mechanical control wire winder for the FDM3D printer according to claim 1, wherein a second bolt (473) is provided at the upper end of the mounting plate (470), and the mounting plate (470) is provided with a hole for placing the hollow rod (480), and the second bolt (473) penetrates into the hole.