CN219686594U - Mechanism is collected to three-dimensional printer clout - Google Patents

Abstract

The utility model relates to the field of three-dimensional printers and discloses a three-dimensional printer residual material collecting mechanism, which solves the problems that the dripped materials are hardened, so that the dripped materials are required to be manually scraped in the whole cleaning process, all the dripped materials can not be completely collected due to the fact that the colors of the materials are similar to those of a bearing plate and the like, but the labor intensity is very high because the whole cleaning process is performed manually, and the rotating mechanism is arranged.

Description

Mechanism is collected to three-dimensional printer clout

Technical Field

The utility model relates to the field of three-dimensional printers, in particular to a three-dimensional printer residual material collecting mechanism.

Background

A three-dimensional printer is a printer that stacks materials by melting them at high temperature, and its main purpose is to print objects having a three-dimensional shape, which are used in life.

When the existing three-dimensional printer is used, the spray head melts materials at high temperature, so that uncontrolled downward dripping of the materials sometimes occurs easily in a period of time after the spray head is used, when the materials are dripped on a printing bearing plate, hardening can occur due to cooling and the materials adhere to the bearing plate, the surface of the bearing plate is uneven, the bearing plate needs to be cleaned manually, the materials which are dripped need to be manually shoveled to collect the dripped materials in the whole cleaning process because the dripped materials are hardened, the materials which are collected by manually shoveling sometimes are similar in color to the bearing plate and the like, all the dripped materials cannot be collected completely, and the labor intensity is high because the whole cleaning is performed manually.

Disclosure of Invention

The utility model aims to provide a residual material collecting mechanism of a three-dimensional printer, which adopts the device to work, thereby solving the problems that the whole cleaning process needs to manually remove the material for collecting the dripping, the manual removal of the material for collecting the dripping sometimes causes that all the dripping materials cannot be collected completely because the color of the material is similar to that of a bearing plate, and the like, and the labor intensity is very high because the manual integral cleaning is carried out.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the three-dimensional printer residue collection mechanism comprises a frame, a bearing plate arranged above the frame, a three-dimensional printer main body arranged above the frame, a reciprocating mechanism arranged on the front side of the frame, and a rotating mechanism arranged on the inner side of the reciprocating mechanism, wherein the reciprocating mechanism is used for collecting dropped materials;

the rotating mechanism comprises a rotating component and a pushing component, the pushing component is arranged at the rear side of the rotating component, the rotating component is used for loosening materials adhered above the bearing plate, and the pushing component is used for pushing the loosened materials to the inside of the reciprocating mechanism.

Preferably, the reciprocating mechanism comprises a first supporting plate arranged above the front side of the frame and a motor arranged on the front side of the first supporting plate, a first transmission shaft is arranged at the output end of the motor, a first gear is arranged at the outer side of the first transmission shaft, an annular rack is arranged at the outer side of the first gear, a first connecting rod is arranged at the rear side of the annular rack, a first connecting plate is arranged at the rear side of the first supporting plate, a sliding groove is formed in the first connecting plate, a sliding block is arranged in the sliding groove, a second transmission shaft is arranged at the rear side of the first connecting plate, a second gear is arranged at the outer side of the second transmission shaft, a collecting box is arranged at the rear end of the second transmission shaft, and first straight rack racks are arranged at the two ends of the first supporting plate.

Preferably, the width of the sliding groove is consistent with the width of the sliding block, and the sliding block is fixedly connected with the first connecting rod in a connecting mode, so that the first connecting rod drives the sliding block to move in the sliding groove.

Preferably, the connection mode of the first connecting plate and the first supporting plate is transverse sliding connection, the connection mode of the first connecting plate and the second transmission shaft is annular sliding connection, and the second transmission shaft is symmetrically provided with two relative to the central axis of the first connecting plate.

Preferably, the rotating assembly comprises a second straight rack arranged at the rear side of the first supporting plate, a third gear is arranged at the rear side of the second straight rack, a second connecting rod is arranged below the third gear, a third connecting rod is arranged above the second connecting rod, and a first hole is formed in the rear side of the first connecting plate.

Preferably, the first hole is a member made of a rectangular structure, and the width of the third connecting rod is consistent with that of the first hole, so that the third connecting rod cannot rotate in the moving process.

Preferably, the second connecting rod is hinged to the third connecting rod in a connecting mode, and the second connecting rod is hinged to the third gear in a connecting mode, so that the third gear rotates to drive the third connecting rod to reciprocate.

Preferably, the pushing assembly comprises a fourth connecting rod arranged at the rear end of the third connecting rod, a second connecting plate is arranged at the rear side of the first connecting plate, a groove is formed in the second connecting plate, a fifth connecting rod is arranged in the groove, and cutters are arranged on two sides of the fourth connecting rod.

Preferably, the groove is a member made of an inclined structure, and the width of the groove is consistent with that of the fifth connecting rod, so that the fifth connecting rod does not shake when moving in the groove.

Preferably, the connection mode of the fourth connecting rod and the cutter is vertical sliding connection, and the connection mode of the fourth connecting rod and the third connecting rod is horizontal sliding connection, so that the fourth connecting rod moves left and right.

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

1. according to the three-dimensional printer residue collection mechanism provided by the utility model, the rotating mechanism is arranged, when the reciprocating mechanism reciprocates to drive the rotating mechanism to reciprocate, the rotating mechanism can be used for removing the dripping materials above the bearing plate back and forth in the reciprocating motion process, the removed dripping materials are conveyed into the reciprocating mechanism, the whole bearing plate is cleaned and removed, and the purposes of avoiding missing phenomenon and reducing labor intensity are achieved.

2. According to the three-dimensional printer residual material collecting mechanism, the reciprocating mechanism is arranged, when the rotating mechanism feeds the removed dripping materials into the reciprocating mechanism, the reciprocating mechanism drives the removed dripping materials to move, and the materials arrive when the materials move to the top end, so that the purpose of automatic collection is achieved.

Drawings

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

FIG. 2 is a schematic perspective view of a reciprocating mechanism and a rotating mechanism according to the present utility model;

fig. 3 is a schematic rear perspective view of the first support plate of the present utility model;

fig. 4 is a schematic front perspective view of a first support plate according to the present utility model;

FIG. 5 is a schematic view of the structure of FIG. 2A according to the present utility model;

FIG. 6 is a schematic view of the structure of FIG. 3B according to the present utility model;

fig. 7 is a schematic view of the structure of fig. 3 at C according to the present utility model.

In the figure: 1. a frame; 2. a carrying plate; 3. a three-dimensional printer body; 4. a reciprocating mechanism; 5. a rotating mechanism; 51. a rotating assembly; 52. a pushing assembly; 401. a first support plate; 402. a motor; 403. a first drive shaft; 404. a first gear; 405. an annular rack; 406. a first connecting rod; 407. a first connection plate; 408. a chute; 409. a slide block; 410. a second drive shaft; 411. a second gear; 412. a collection box; 413. a first rack of straight teeth; 5101. a second spur rack; 5102. a third gear; 5103. a second connecting rod; 5104. a third connecting rod; 5105. a first hole; 5201. a fourth connecting rod; 5202. a second connecting plate; 5203. a groove; 5204. a fifth connecting rod; 5205. a cutter.

Detailed Description

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. 1-7, the present utility model provides the following technical solutions: the three-dimensional printer residue collection mechanism comprises a frame 1, a bearing plate 2 arranged above the frame 1, a three-dimensional printer main body 3 arranged above the frame 1, a reciprocating mechanism 4 arranged at the front side of the frame 1, a rotating mechanism 5 arranged at the inner side of the reciprocating mechanism 4, and a collecting mechanism 4 for collecting dropped materials; the rotating mechanism 5 comprises a rotating assembly 51 and a pushing assembly 52, the pushing assembly 52 is arranged at the rear side of the rotating assembly 51, the rotating assembly 51 is used for loosening materials adhered above the bearing plate 2, and the pushing assembly 52 is used for pushing the loosened materials into the reciprocating mechanism 4.

The reciprocating mechanism 4 comprises a first supporting plate 401 arranged above the front side of the frame 1 and a motor 402 arranged on the front side of the first supporting plate 401, a first transmission shaft 403 is arranged at the output end of the motor 402, a first gear 404 is arranged on the outer side of the first transmission shaft 403, an annular rack 405 is arranged on the outer side of the first gear 404, a first connecting rod 406 is arranged on the rear side of the annular rack 405, a first connecting plate 407 is arranged on the rear side of the first supporting plate 401, a sliding groove 408 is arranged in the first connecting plate 407, a sliding block 409 is arranged in the sliding groove 408, a second transmission shaft 410 is arranged on the rear side of the first connecting plate 407, a second gear 411 is arranged on the outer side of the second transmission shaft 410, a collecting box 412 is arranged at the rear end of the second transmission shaft 410, and first straight racks 413 are arranged at the two ends of the first supporting plate 401.

The width of the sliding groove 408 is consistent with the width of the sliding block 409, the sliding block 409 and the first connecting rod 406 are fixedly connected, the first connecting rod 406 drives the sliding block 409 to move in the sliding groove 408, the first connecting plate 407 and the first supporting plate 401 are connected in a transverse sliding mode, the first connecting plate 407 and the second transmission shaft 410 are connected in an annular sliding mode, and the second transmission shaft 410 is symmetrically provided with two transmission shafts with respect to the central axis of the first connecting plate 407.

The rotating assembly 51 comprises a second spur rack 5101 arranged at the rear side of the first supporting plate 401, a third gear 5102 is arranged at the rear side of the second spur rack 5101, a second connecting rod 5103 is arranged below the third gear 5102, a third connecting rod 5104 is arranged above the second connecting rod 5103, a first hole 5105 is arranged in the rear side of the first connecting plate 407, the first hole 5105 is a member made of a rectangular structure, the width of the third connecting rod 5104 is consistent with the width of the first hole 5105, the third connecting rod 5104 cannot rotate in the moving process, the second connecting rod 5103 is hinged with the third connecting rod 5104 in a hinged mode, the second connecting rod 5103 is hinged with the third gear 5102 in a connected mode, the third gear 5102 rotates to drive the third connecting rod 5104 to reciprocate, the pushing component 52 comprises a fourth connecting rod 5201 arranged at the rear end of a third connecting rod 5104, a second connecting plate 5202 is arranged at the rear side of the first connecting plate 407, a groove 5203 is arranged in the second connecting plate 5202, a fifth connecting rod 5204 is arranged in the groove 5203, cutters 5205 are arranged on two sides of the fourth connecting rod 5201, the groove 5203 is a component made of an inclined structure, the width of the groove 5203 is consistent with that of the fifth connecting rod 5204, the fifth connecting rod 5204 cannot shake when moving in the groove 5203, the fourth connecting rod 5201 is in vertical sliding connection with the cutters 5205, and the fourth connecting rod 5201 is in transverse sliding connection with the third connecting rod 5104 in a connecting mode, so that the fourth connecting rod 5201 moves left and right.

The first transmission shaft 403 is driven to rotate by the starting motor 402, so as to drive the first gear 404 and the annular rack 405 to rotate, the first connecting rod 406 is fixedly connected with the annular rack 405, so that the first connecting rod 406 moves along with the annular rack 405, the first connecting rod 406 is fixedly connected with the sliding block 409, the sliding block 409 is arranged in the first connecting plate 407, so that the first connecting plate 407 is driven to move, the outer side surface of the second straight rack 5101 is meshed with the outer side surface of the third gear 5102, so that the third gear 5102 rotates, the second connecting rod 5103 is hinged with the third connecting rod 5104, the second connecting rod 5103 is hinged with the third gear 5102, so that the third connecting rod 5102 rotates to drive the third connecting rod 5104 to reciprocate, the fourth connecting rod 5201 is vertically and slidingly connected with the cutter 5205, and the connection mode of the fourth connecting rod 5201 and the third connecting rod 5104 is transversely and slidably connected, when the third connecting rod 5104 moves forwards and backwards, the fourth connecting rod 5201 is driven to move forwards and backwards due to the transverse and sliding connection of the connection mode of the fourth connecting rod 5201 and the third connecting rod 5104, the fifth connecting rod 5204 moves forwards and backwards due to the fixed connection of the connection mode of the fourth connecting rod 5201 and the fifth connecting rod 5204, the groove 5203 is a member made of an inclined structure, the width of the groove 5203 is consistent with the width of the fifth connecting rod 5204, when the fifth connecting rod 5204 moves forwards and backwards, the groove 5203 moves along the inclined track, the fourth connecting rod 5201 is driven to move forwards and backwards, and the cutter 5205 is driven to push the shoveled material into the collecting box 412 when the fourth connecting rod 5201 moves forwards and backwards, the whole bearing plate 2 is cleaned and shoveled without manual cleaning and shoveling, so that the purposes of avoiding missing phenomena and reducing labor intensity are achieved.

When the first connecting plate 407 moves left and right, the second transmission shaft 410 is driven to move left and right, the collection box 412 and the second gear 411 are driven to move left and right, when the second gear 411 is meshed with the first rack, the second gear 411 and the second transmission shaft 410 rotate, the collection box 412 is driven to rotate due to the fact that the connection mode of the second transmission shaft 410 and the collection box 412 is fixedly connected, materials in the collection box 412 are poured out, the recovery boxes are placed on two sides of the device, and the materials are poured into the recovery boxes, so that the purpose of automatic collection is achieved.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. The utility model provides a three-dimensional printer clout collection mechanism, including frame (1), set up loading board (2) in frame (1) top, set up three-dimensional printer main part (3) in frame (1) top, its characterized in that: a reciprocating mechanism (4) is arranged at the front side of the frame (1), a rotating mechanism (5) is arranged at the inner side of the reciprocating mechanism (4), and the reciprocating mechanism (4) is used for collecting dripped materials;

the rotating mechanism (5) comprises a rotating assembly (51) and a pushing assembly (52), the pushing assembly (52) is arranged on the rear side of the rotating assembly (51), the rotating assembly (51) is used for loosening materials adhered to the upper portion of the bearing plate (2), and the pushing assembly (52) is used for pushing the loosened materials into the reciprocating mechanism (4).

2. The three-dimensional printer remainder collection mechanism of claim 1, wherein: the reciprocating mechanism (4) comprises a first supporting plate (401) arranged above the front side of the frame (1) and a motor (402) arranged on the front side of the first supporting plate (401), a first transmission shaft (403) is arranged at the output end of the motor (402), a first gear (404) is arranged on the outer side of the first transmission shaft (403), an annular rack (405) is arranged on the outer side of the first gear (404), a first connecting rod (406) is arranged on the rear side of the annular rack (405), a first connecting plate (407) is arranged on the rear side of the first supporting plate (401), a sliding groove (408) is arranged in the first connecting plate (407), a sliding block (409) is arranged in the sliding groove (408), a second transmission shaft (410) is arranged on the rear side of the first connecting plate (407), a second gear (411) is arranged on the outer side of the second transmission shaft (410), a collecting box (412) is arranged at the rear end of the second transmission shaft (410), and first straight teeth (413) are arranged at the two ends of the first supporting plate (401).

3. The three-dimensional printer remainder collection mechanism according to claim 2, wherein: the width of the sliding groove (408) is consistent with the width of the sliding block (409), and the sliding block (409) is fixedly connected with the first connecting rod (406), so that the first connecting rod (406) drives the sliding block (409) to move in the sliding groove (408).

4. The three-dimensional printer remainder collection mechanism according to claim 2, wherein: the first connecting plate (407) is connected with the first supporting plate (401) in a transverse sliding mode, the first connecting plate (407) is connected with the second transmission shaft (410) in an annular sliding mode, and the second transmission shaft (410) is symmetrically provided with two connecting plates relative to the central axis of the first connecting plate (407).

5. The three-dimensional printer remainder collection mechanism according to claim 4, wherein: the rotating assembly (51) comprises a second straight-tooth rack (5101) arranged on the rear side of the first supporting plate (401), a third gear (5102) is arranged on the rear side of the second straight-tooth rack (5101), a second connecting rod (5103) is arranged below the third gear (5102), a third connecting rod (5104) is arranged above the second connecting rod (5103), and a first hole (5105) is formed in the rear side of the first connecting plate (407).

6. The three-dimensional printer remainder collection mechanism of claim 5, wherein: the first hole (5105) is a member made of a rectangular structure, and the width of the third connecting rod (5104) is consistent with that of the first hole (5105), so that the third connecting rod (5104) cannot rotate in the moving process.

7. The three-dimensional printer remainder collection mechanism of claim 6, wherein: the second connecting rod (5103) is hinged to the third connecting rod (5104) in a connecting mode, and the second connecting rod (5103) is hinged to the third gear (5102) in a connecting mode, so that the third gear (5102) rotates to drive the third connecting rod (5104) to reciprocate.

8. The three-dimensional printer remainder collection mechanism according to claim 4, wherein: the pushing assembly (52) comprises a fourth connecting rod (5201) arranged at the rear end of a third connecting rod (5104), a second connecting plate (5202) is arranged at the rear side of the first connecting plate (407), a groove (5203) is formed in the second connecting plate (5202), a fifth connecting rod (5204) is arranged in the groove (5203), and cutters (5205) are arranged on two sides of the fourth connecting rod (5201).

9. The three-dimensional printer remainder collection mechanism of claim 8, wherein: the groove (5203) is a member made of an inclined structure, and the width of the groove (5203) is consistent with that of the fifth connecting rod (5204), so that the fifth connecting rod (5204) cannot shake when moving in the groove (5203).

10. The three-dimensional printer remainder collection mechanism of claim 8, wherein: the connection mode of fourth connecting rod (5201) and cutter (5205) is vertical sliding connection, and the connection mode of fourth connecting rod (5201) and third connecting rod (5104) transversely sliding connection for fourth connecting rod (5201) carries out the left and right movement.