CN217172230U - Piezoelectric vibration disc for automatic production line - Google Patents

Abstract

The utility model relates to a technical field of vibration dish, concretely relates to piezoelectric type vibration dish for automation line. The utility model provides a piezoelectric type vibration dish for automation line, include: the vibration disc comprises a vibration disc body, a horizontal conveying part and a single feeding mechanism which are arranged in sequence; the horizontal conveying part is provided with a conveying track suitable for accommodating workpieces; the horizontal conveying part is provided with a material blocking assembly above the conveying track of the workpiece, and the material blocking assembly can extend into the conveying track; the upward workpiece can push the material blocking assembly to extend into the conveying track, so that the material blocking assembly blocks the subsequent workpiece; after the workpiece passes through the bottom of the material blocking assembly, the material blocking assembly loosens the subsequent workpiece. The utility model provides a piezoelectric type vibration dish for automation line overturns reverse work piece through keeping off the material subassembly, blocks subsequent work piece simultaneously to make the work piece of material loading arrange in order, in order to improve material loading efficiency.

Description

Piezoelectric vibration disc for automatic production line

Technical Field

The utility model relates to a technical field of vibration dish, concretely relates to piezoelectric type vibration dish for automation line.

Background

When the traditional vibration disk conveys the screws, the screws need to be screened into a mode that the rod parts face downwards to convey the material, and a stop rod is usually arranged at the position where the vibration disk is connected with a linear track to stop a screw rod with the rod parts facing upwards, so that the screws are orderly output.

However, in such a way, the screws which are fed are pushed back into the vibration disc, so that the screws are fed repeatedly, the feeding efficiency is low, and the threads on the screws are easily damaged in the falling process of the screws and the collision of the vibration disc.

In order to solve the above problems, it is necessary to design a piezoelectric vibration plate for an automated manufacturing line.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is: in order to solve the problems in the prior art. The utility model provides a piezoelectric type vibration dish for automation line. To solve the above problems.

The utility model provides a technical scheme that its technical problem adopted is: a piezoelectric vibratory pan for an automated manufacturing line, comprising: the vibrating disc comprises a vibrating disc body, a horizontal conveying part and a single feeding mechanism which are arranged in sequence;

the horizontal conveying part is provided with a conveying track suitable for accommodating workpieces;

the horizontal conveying part is provided with a material blocking assembly above a conveying track of a workpiece, and the material blocking assembly can extend into the conveying track; wherein

The upward workpiece can push the material blocking assembly to extend into the conveying track, so that the material blocking assembly blocks the subsequent workpiece;

and after the workpiece passes through the bottom of the material blocking assembly, the material blocking assembly loosens the subsequent workpiece.

Further, the horizontal conveying part comprises a straight vibrator, a conveying slide rail fixed on the straight vibrator and a conveying upper cover fixedly connected on the conveying slide rail; and

the conveying rail is arranged on the upper end face of the conveying slide rail.

Furthermore, a limiting groove is formed in one side, close to the vibration disc body, of the conveying upper cover, and a sliding groove is formed in one side, located on the conveying track, of the limiting groove;

the material blocking assembly slides in a manner of being matched with the sliding groove, extends into the limiting groove and protrudes downwards out of the sliding groove; wherein

The upward workpiece can push the material blocking assembly to slide along the sliding groove, so that the part of the material blocking assembly protruding out of the sliding groove extends into the conveying track.

Furthermore, a pushing groove is further formed in the side wall, located on the sliding groove, of the conveying upper cover, a containing groove corresponding to the pushing groove is formed in the conveying sliding rail, and the containing groove is communicated with the conveying rail;

the material blocking assembly comprises a material blocking rod connected in the sliding groove in a sliding mode, a push rod connected in the push groove in a sliding mode, and a push spring is arranged between the push rod and the side wall of the push groove; and

the push rod protrudes out of the push groove and extends into the accommodating groove;

the material blocking rod extends into the limit groove; wherein

The upward workpiece can push the material blocking rod to slide along the sliding groove and cross the ejector rod, so that the ejector rod extends into the conveying sliding rail.

Further, the material blocking rod is L-shaped.

Furthermore, a material blocking spring is arranged between the material blocking rod and the side wall of the sliding groove and can be pushed and compressed by the material blocking rod; wherein

After the workpiece crosses the material blocking rod, the material blocking spring drives the material blocking rod to reset, so that the ejector rod retracts towards the ejection groove and loosens subsequent workpieces.

Furthermore, a guide inclined plane is arranged on the material blocking rod, and a pushing inclined plane matched with the guide inclined plane is arranged on the pushing rod; wherein

The material blocking rod can push the pushing rod to retract into the pushing groove.

Further, the single feeding mechanism comprises a support table arranged at the tail end of the conveying track, a guide air cylinder fixedly connected to one side of the support table and a guide plate connected to the support table in a sliding mode; and

a plug is arranged on the guide plate and is positioned at the outlet of the conveying track; wherein

The guide cylinder is suitable for driving the guide plate to slide so as to enable the single workpiece to be output from the conveying track.

Further, the bottom fixedly connected with riser of deflector, just riser fixed connection be in the expansion end of direction cylinder.

Furthermore, a lifting groove which penetrates through the guide plate up and down is formed in one side, located on the plug, of the guide plate, a feeding rod is arranged in the lifting groove in a sliding fit mode, and a feeding position which is matched with the workpiece is arranged at the end of the feeding rod;

the side wall of the vertical plate is also fixedly connected with a lifting cylinder, and the feeding rod is fixedly connected with the movable end of the lifting cylinder; wherein

The workpieces output from the conveying track can slide into the feeding position.

The beneficial effects of the utility model are that, the utility model provides a piezoelectric type vibration dish for automation line overturns reverse work piece through keeping off the material subassembly, blocks subsequent work piece simultaneously to make the work piece of material loading arrange in order, in order to improve material loading efficiency.

Drawings

The present invention will be further explained with reference to the drawings and examples.

FIG. 1 is a perspective view of a preferred embodiment of a piezoelectric vibratory pan for an automated manufacturing line of the present invention;

fig. 2 is a perspective view of a preferred embodiment of the material blocking assembly of the present invention;

fig. 3 is a perspective view of a preferred embodiment of the conveying slide of the present invention;

fig. 4 is a perspective view of a preferred embodiment of a single feed mechanism of the present invention.

In fig. 1, a disc body is vibrated;

2. a horizontal conveying section; 21. a conveying track; 22. a straight vibration device; 23. a conveying slide rail; 231. a containing groove; 24. conveying the upper cover; 241. a limiting groove; 242. a sliding groove; 243. a pushing groove;

3. a single feed mechanism; 31. a support table; 32. a guide cylinder; 33. a guide plate; 331. a plug; 332. a lifting groove; 34. a vertical plate; 35. a feeding rod; 351. loading the material; 36. a lifting cylinder;

4. the material blocking component; 41. a material blocking rod; 411. a guide slope; 42. pushing the push rod; 421. pushing the inclined plane; 43. a pushing spring; 44. keep off the material spring.

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 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 only for the purpose of explaining the present invention, and should not be construed as limiting the present invention. On the contrary, the embodiments of the invention include all changes, modifications and equivalents coming within the spirit and terms of the claims appended hereto.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "axial", "radial", "circumferential", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, and 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 therefore should not be construed as limiting the present invention.

Furthermore, the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art. In addition, in the description of the present invention, "a plurality" means two or more unless otherwise specified.

Any process or method descriptions in flow charts or otherwise described herein may be understood as representing modules, segments, or portions of code which include one or more executable instructions for implementing specific logical functions or steps of the process, and the scope of the preferred embodiments of the present invention includes other implementations in which functions may be executed out of order from that shown or discussed, including substantially concurrently or in reverse order, depending on the functionality involved, as would be understood by those reasonably skilled in the art of the embodiments of the present invention.

As shown in fig. 1 to 4, the utility model provides a piezoelectric vibration dish for automation line, its characterized in that includes: the vibration plate comprises a vibration plate body 1, a horizontal conveying part 2, a single feeding mechanism 3 and a material blocking assembly 4. The vibratory pan body 1 is adapted to vibrate a workpiece. The horizontal conveying part 2 is adapted to convey the workpiece on the vibration plate body 1. The material blocking assembly 4 is suitable for detecting the orientation of the workpiece and overturning the upward workpiece to be arranged downward. The single feed mechanism 3 is adapted to guide the materials at the end of the horizontal conveying section 2 to be sequentially fed upward. With respect to the above components, detailed description will be made below.

Vibration disk body

Vibration dish body 1 sets gradually, and vibration dish body 1 is whole to be discoid, and 1 openings of vibration dish body set up, is suitable for in the vibration dish body 1 to place a plurality of work pieces to vibration dish body 1 self can produce the vibration, and drives the work piece vibration in the vibration dish body 1, in order to order about the work piece and carry in proper order on horizontal transport portion 2.

Horizontal conveying part

Horizontal transport portion 2 sets up in vibration dish body 1 one side, and horizontal transport portion 2 one end extends to the vibration dish lateral wall and connects and communicate. The workpieces in the vibration disc body 1 can sequentially enter the horizontal conveying part 2. The horizontal conveying part 2 can convey the materials entering the horizontal conveying part 2 to the side far away from the vibrating disk body 1.

To achieve the above effect, the horizontal conveying part 2 has a conveying rail 21 adapted to receive the workpiece. The conveying rail 21 is opened along the longitudinal direction of the horizontal conveying part 2, and the width of the conveying rail 21 is smaller than the maximum width of the workpiece. In this embodiment, the workpiece is a large-headed nail-like object to show that the workpiece has a sharp thick head at one end and a needle-like thin head at the other end. When the work enters the conveying rail 21, two states are set. The first is that the thin head faces downwards; the second is bold face down.

In order to convey the workpiece falling on the conveying rail 21 to the end far away from the vibration plate body 1, the horizontal conveying part 2 includes a straight vibrator 22, a conveying slide rail 23 fixed on the straight vibrator 22, and a conveying upper cover 24 fixedly connected to the conveying slide rail 23. The conveying rail 21 is arranged on the upper end face of the conveying slide rail 23. When the workpiece enters the conveying slide rails 23, the thick head of the workpiece is abutted against the end surfaces of the conveying slide rails 23 on the two sides, and the thin head is suspended downwards between the two side walls of the conveying track 21; alternatively, the thick end of the workpiece abuts against the end face of the conveying slide rail 23, and the thin end is disposed downward. The straight vibrator 22 is disposed on one side of the conveying slide rail 23, and the straight vibrator 22 can drive the conveying slide rail 23 to vibrate along the horizontal direction, so that the workpiece slides along the conveying slide rail 23 to the side far away from the vibration tray body 1.

In addition, a limiting groove 241 is formed on one side of the upper conveying cover 24 close to the vibration disc body 1. The width of the limiting groove 241 is the same as the width of the conveying slide rail 23, and when the workpiece with the upward thin head slides along the conveying slide rail 23, the thin head of the workpiece can move between two side walls of the limiting groove 241.

Material blocking assembly

Keep off material subassembly 4 and set up in the delivery track 21 top that is located the work piece, just keep off material subassembly 4 can extend to in the delivery track 21. The work piece up can promote keep off material subassembly 4 and stretch into delivery track 21, so that keep off material subassembly 4 and block follow-up work piece, keep off material subassembly 4 and be suitable for the orientation that detects the work piece to overturn thin head work piece up to setting up down, can follow after the work piece upset and keep off material subassembly 4 bottom and pass through, the work piece passes through the back, keep off material subassembly 4 and loosen follow-up work piece.

In order to achieve the above effect, a sliding groove 242 is formed in one side of the limiting groove 241 on the conveying rail 21. The sliding groove 242 is formed along the length direction of the stopper groove 241. The side wall of the upper conveying cover 24 located on the sliding groove 242 is further provided with a pushing groove 243, the conveying slide rail 23 is provided with an accommodating groove 231 corresponding to the pushing groove 243, and the accommodating groove 231 is communicated with the conveying track 21. The pushing groove 243 corresponds to the containing groove 231. The pushing groove 243 is perpendicular to the limiting groove 241, and the containing groove 231 is perpendicular to the conveying track 21. The material blocking assembly 4 comprises a material blocking rod 41 connected in the sliding groove 242 in a sliding mode, an ejector rod 42 connected in the ejector groove 243 in a sliding mode, and an ejector spring 43 is further arranged between the ejector rod 42 and the side wall of the ejector groove 243. The material blocking rod 41 and the sliding groove 242 are adapted to slide, and the material blocking rod 41 extends into the limiting groove 241. The ejector rod 42 protrudes downward out of the sliding groove 242, the material blocking rod 41 is attached to the conveying track 21, and the material blocking rod 41 is matched with the accommodating groove 231. In order to sequentially process the workpieces with the thin heads facing upwards, the material blocking rod 41 is in an L shape. One end of the striker rod 41 coincides with the sliding groove 242, and the other end is perpendicular to the sliding groove 242. The length of the material blocking rod 41 is larger than half of the width of the limiting groove 241, so that when a thin head of a workpiece enters the limiting groove 241, the workpiece can abut against the material blocking rod 41. The length of the ejector pin 42 is greater than the width of the limiting groove 241. By the mode, when the workpiece moves, the workpiece with the thin head facing upwards pushes the material blocking rod 41 to slide along the sliding groove 242, when the material blocking rod 41 slides to be separated from the contact with the pushing rod 42, the pushing spring 43 pushes the pushing rod 42 to slide outwards, so that the pushing rod 42 partially extends into the conveying track 21 and is inserted into the accommodating groove 231, and the pushing rod 42 can block subsequent workpieces from passing through. The upward workpiece can push the material blocking rod 41 to slide along the sliding groove 242 and cross the ejector rod 42, so that the ejector rod 42 extends into the conveying slide rail 23. When the material blocking rod 41 slides to abut against the bottom of the limiting groove 241, the workpiece can turn around the material blocking rod 41, so that the thin head faces downwards.

In order to facilitate the resetting of the material blocking rod 41, the limiting groove 241 is opened so that the next workpiece with a thin head facing the limiting groove 241 enters the limiting groove 241, a material blocking spring 44 is further arranged between the material blocking rod 41 and the side wall of the sliding groove 242, and the material blocking spring 44 can be pushed and compressed by the material blocking rod 41. After the workpiece passes over the striker rod 41, the striker spring 44 drives the striker rod 41 to return, so that the ejector rod 42 retracts towards the ejector groove 243 and releases the subsequent workpiece. When the workpiece pushes against the striker plate, the striker spring 44 is compressed. When the workpiece is separated from the striker plate, the striker plate is pushed to reset by the striker spring 44.

In order to facilitate the resetting of the ejector rod 42, the material blocking rod 41 is provided with a guide inclined surface 411, and the ejector rod 42 is provided with an ejector inclined surface 421 matched with the guide inclined surface 411. The striker rod 41 can push the ejector rod 42 to retract into the ejector groove 243. When the workpiece is separated from the striker plate, the striker spring 44 pushes the striker plate to move to abut against the guide inclined surface 411, and the striker spring 44 can push the ejector rod 42 to retract into the pushing groove 243 through the guide inclined surface 411.

Single feed mechanism

A single feed mechanism 3 is provided at the end of the conveying track 21, the single feed mechanism 3 being adapted to guide the material at the end of the horizontal conveying section 2 to be fed upwards in sequence. The single feeding mechanism 3 includes a support table 31 installed at the end of the conveying rail 21, a guide cylinder 32 fixedly connected to one side of the support table 31, and a guide plate 33 slidably connected to the support table 31. The support table 31 is suitable for supporting the guide cylinder 32 and the guide plate 33, a through groove matched with the guide plate 33 is formed in the support table 31, and the guide plate 33 is arranged in the through groove in a sliding mode. The shell of the guide cylinder 32 is fixedly connected with the support table 31, a piston rod of the guide cylinder 32 is horizontally arranged, a vertical plate 34 is fixedly connected to the bottom of the guide plate 33, and the vertical plate 34 is fixedly connected to the movable end of the guide cylinder 32. When the guide cylinder 32 works, the vertical plate 34 can be driven to drive the guide plate 33 to horizontally slide along the through groove. A plug 331 is disposed on the guide plate 33, and the plug 331 is located at an outlet of the conveying track 21. The plug 331 can plug the outlet of the conveying track 21 so that the workpiece can be retained at the outlet of the conveying track 21.

The guide plate 33 is located one side of the choke plug 331 is provided with a lifting groove 332 penetrating up and down, a feeding rod 35 slides in the lifting groove 332 in a matching manner, and the end of the feeding rod 35 is provided with a feeding position 351 matched with a workpiece. The loading level 351 is adapted to a workpiece. The lateral wall of riser 34 is fixedly connected with lift cylinder 36 still, material loading pole 35 fixed connection be in lift cylinder 36's expansion end. The workpieces transported out of the conveyor track 21 can slide down into the loading position 351. During operation, the lifting cylinder 36 can drive the feeding rod 35 to move to the feeding position 351, and the feeding position is vertically flush with the conveying track 21; the guide cylinder 32 can drive the guide plate 33 to horizontally slide until the upper level 351 is horizontally level with the conveying rail 21. The workpiece now enters the loading position 351. The guide cylinder 32 can drive the guide plate 33 to horizontally slide to the feeding position 351 and horizontally displace with the conveying rail 21, and the lifting cylinder 36 can drive the feeding rod 35 to move to the feeding position 351 and vertically displace with the conveying rail 21.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, a schematic representation of the term does not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

In light of the foregoing, it will be apparent to those skilled in the art from this disclosure that various changes and modifications can be made without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (10)

1. A piezoelectric vibration plate for an automatic production line, comprising:

the vibration plate comprises a vibration plate body (1), a horizontal conveying part (2) and a single feeding mechanism (3) which are arranged in sequence;

the horizontal conveying part (2) is provided with a conveying track (21) suitable for accommodating workpieces;

a material blocking assembly (4) is arranged above a conveying track (21) of the workpiece on the horizontal conveying part (2), and the material blocking assembly (4) can extend into the conveying track (21); wherein

The upward workpiece can push the material blocking assembly (4) to extend into the conveying track (21) so that the material blocking assembly (4) blocks a subsequent workpiece;

and after the workpiece passes through the bottom of the material blocking assembly (4), the material blocking assembly (4) loosens the subsequent workpiece.

2. The piezoelectric vibration plate for an automated manufacturing line according to claim 1,

the horizontal conveying part (2) comprises a straight vibrator (22), a conveying slide rail (23) fixed on the straight vibrator (22) and a conveying upper cover (24) fixedly connected on the conveying slide rail (23); and

the conveying rail (21) is arranged on the upper end face of the conveying sliding rail (23).

3. The piezoelectric vibration plate for an automated manufacturing line according to claim 2,

one side, close to the vibration disc body (1), of the conveying upper cover (24) is provided with a limiting groove (241), and one side, located on the conveying track (21), of the limiting groove (241) is provided with a sliding groove (242);

the material blocking assembly (4) is matched with the sliding groove (242) to slide, the material blocking assembly (4) extends into the limiting groove (241), and the material blocking assembly (4) protrudes out of the sliding groove (242) downwards; wherein

The upward workpiece can push the material blocking assembly (4) to slide along the sliding groove (242), so that the part of the material blocking assembly (4) protruding out of the sliding groove (242) extends into the conveying track (21).

4. The piezoelectric vibration plate for an automated manufacturing line according to claim 3,

a pushing groove (243) is further formed in the side wall, located on the sliding groove (242), of the conveying upper cover (24), a containing groove (231) corresponding to the pushing groove (243) is formed in the conveying sliding rail (23), and the containing groove (231) is communicated with the conveying rail (21);

the material blocking assembly (4) comprises a material blocking rod (41) which is connected in the sliding groove (242) in a sliding mode, a pushing rod (42) which is connected in the pushing groove (243) in a sliding mode, and a pushing spring (43) is arranged between the pushing rod (42) and the side wall of the pushing groove (243); and

the ejector rod (42) protrudes out of the ejector groove (243) and extends into the containing groove (231);

the material blocking rod (41) extends into the limiting groove (241); wherein

The upward workpiece can push the material blocking rod (41) to slide along the sliding groove (242) and cross the ejector rod (42), so that the ejector rod (42) extends into the conveying sliding rail (23).

5. The piezoelectric vibration plate for an automated manufacturing line according to claim 4,

the material blocking rod (41) is L-shaped.

6. The piezoelectric vibration plate for an automated manufacturing line according to claim 5,

a material blocking spring (44) is further arranged between the material blocking rod (41) and the side wall of the sliding groove (242), and the material blocking spring (44) can be pushed and compressed by the material blocking rod (41); wherein

After the workpiece passes over the material blocking rod (41), the material blocking spring (44) drives the material blocking rod (41) to reset, so that the ejector rod (42) retracts towards the ejector groove (243) and releases subsequent workpieces.

7. The piezoelectric vibration plate for an automated manufacturing line according to claim 6,

the material blocking rod (41) is provided with a guide inclined plane (411), and the push rod (42) is provided with a push inclined plane (421) matched with the guide inclined plane (411); wherein

The material blocking rod (41) can push the ejector rod (42) to retract into the ejector groove (243).

8. The piezoelectric vibration plate for an automated manufacturing line according to claim 1,

the single feeding mechanism (3) comprises a supporting table (31) arranged at the tail end of the conveying track (21), a guide air cylinder (32) fixedly connected to one side of the supporting table (31) and a guide plate (33) connected to the supporting table (31) in a sliding mode; and

a plug (331) is arranged on the guide plate (33), and the plug (331) is positioned at the outlet of the conveying track (21); wherein

The guide cylinder (32) is suitable for driving the guide plate (33) to slide so as to enable the single workpiece to be output from the conveying track (21).

9. The piezoelectric vibratory plate for an automated manufacturing line of claim 8,

the bottom fixedly connected with riser (34) of deflector (33), just riser (34) fixed connection be in the expansion end of direction cylinder (32).

10. The piezoelectric vibratory plate for an automated manufacturing line of claim 9,

a lifting groove (332) which penetrates through the guide plate (33) up and down is formed in one side, located on the plug (331), of the guide plate, a feeding rod (35) is matched and slides in the lifting groove (332), and a feeding position (351) matched with a workpiece is formed in the end portion of the feeding rod (35);

the side wall of the vertical plate (34) is also fixedly connected with a lifting cylinder (36), and the feeding rod (35) is fixedly connected with the movable end of the lifting cylinder (36); wherein

The workpieces conveyed out of the conveying track (21) can slide into the loading position (351).

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