CN218433438U - Vibration dish device and vibration charging equipment of plastic part - Google Patents

Abstract

The utility model discloses a vibrating disk device of plastic part, have the second sign that is used for discerning the first sign of positive and negative and is used for discerning the orientation on the plastic part, the device includes: the inner side wall of the vibration disc is provided with a spiral feeding groove, and the spiral feeding groove is provided with at least one first micro-air hole and at least one second micro-air hole; the optical fiber assembly is arranged on the vibration disc and comprises at least one first optical fiber sensor corresponding to the first micro-air hole and at least one second optical fiber sensor corresponding to the second micro-air hole, and the first optical fiber sensor and the second optical fiber sensor are respectively used for identifying the first mark and the second mark of the plastic part in the spiral feeding groove. The vibrating disk device can screen the front and back surfaces and the orientation of the plastic parts. The utility model also discloses a vibration charging equipment of plastic part, including foretell vibration dish device.

Description

Vibration dish device and vibration charging equipment of plastic part

Technical Field

The utility model relates to a plastic part assembly technique especially relates to a vibration dish device and vibration charging equipment of plastic part.

Background

The plastic part is a precision component widely applied in the industrial fields of the electronic and electrical industry, the automobile manufacturing industry, the flat panel display industry and the like, and the plastic part is often required to be assembled into other components and finally assembled into a terminal product together with other components, so that the plastic part plays different roles in different terminal products.

The existing plastic part and other components are generally assembled by using a jig, for example, chinese patent No. CN201920350772.6 discloses a fixture for assembling a die-cut part, which includes: a base; the positioning piece is connected to the base and used for positioning the die cutting piece; the movable piece is slidably mounted on the base; the assembly part is detachably arranged on the movable part and used for positioning the plastic part and enabling one side surface of the plastic part to be aligned to the die cutting part; when the assembly part is arranged on the movable part, the die cutting part is positioned between one side surface of the positioning plastic part; one side surface of the plastic part is attached to the die cutting part when the movable part slides on the base. When the die-cutting piece needs to be assembled on the side face of the plastic piece, the die-cutting piece is positioned on the positioning piece, the plastic piece is positioned on the assembling piece, the assembling piece with the positioned plastic piece is installed on the moving piece, at the moment, the die-cutting piece is positioned between the positioning piece and one side face of the plastic piece, and one side face of the plastic piece is aligned to the die-cutting piece; the movable piece is slidably mounted on the base, so that the movable piece slides, one side face of the plastic piece can be attached to the die-cutting piece, and the die-cutting piece is assembled on the side face of the plastic piece.

Above-mentioned anchor clamps still need artifical material loading, and on the artifical relevant position of placing anchor clamps with the plastic part, not only material loading efficiency is low, and the plastic part still needs the homonymy syntropy assembly in addition when the assembly, both divides positive and reverse side, also divides the orientation, and the positive and negative and the orientation of plastic part have often been wrong during the operating personnel material loading.

SUMMERY OF THE UTILITY MODEL

In order to solve the defects of the prior art, the utility model provides a vibration disc device for plastic parts, which can screen the front and back faces and the orientation of the plastic parts.

The utility model also provides a vibration charging equipment of plastic part, including foretell vibration dish device.

The utility model discloses the technical problem that will solve realizes through following technical scheme:

the utility model provides a vibration dish device of plastic part, have the first sign that is used for discerning the positive and negative on the plastic part and be used for discerning the second sign of orientation, the device includes:

the inner side wall of the vibration disc is provided with a spiral feeding groove, and the spiral feeding groove is provided with at least one first micro-air hole and at least one second micro-air hole;

the optical fiber assembly is arranged on the vibration disc and comprises at least one first optical fiber sensor corresponding to the first micro-air hole and at least one second optical fiber sensor corresponding to the second micro-air hole, and the first optical fiber sensor and the second optical fiber sensor are respectively used for identifying the first mark and the second mark of the plastic part in the spiral feeding groove.

Further, still include:

the air valve assembly comprises at least two air valves, and the air valves are correspondingly connected with the first micro-pores or the second micro-pores through air pipes and used for controlling the air outlet of the first micro-pores or the second micro-pores;

and the amplifying assembly comprises at least two signal amplifiers, and the signal amplifiers are correspondingly connected with the first optical fiber sensor or the second optical fiber sensor through optical fibers and are used for amplifying optical signals of the first optical fiber sensor or the second optical fiber sensor.

Further, the air pump and the barometer are further included, the air pump is connected with the air valve, and the barometer is connected with the air pump.

Furthermore, the reflection rate of the first mark and the second mark is different from that of the plastic part, the first mark is located on the front face of the plastic part, and the second mark is located at the front end of the plastic part.

Further, the spiral feeding groove comprises at least two spiral grooves, the width of the front spiral groove is gradually reduced at the spiral top of the front spiral groove, and the spiral bottom of the rear spiral groove is positioned below the spiral top of the front spiral groove.

A vibration feeding equipment of plastic part, includes:

the vibration disc device sends out the plastic parts one by one according to the required front and back surfaces and the required direction in a vibration mode;

the direct vibration device conveys the plastic parts sent out by the vibration disc device forward in sequence in a vibration mode;

and the material distributing device divides a plurality of plastic parts sequentially sent by the direct vibration device into a group.

Furthermore, the material distributing device comprises a material distributing plate, the material distributing plate can translate along the Y direction perpendicular to the X direction of feeding of the direct vibration device, one side of the material distributing plate facing the direct vibration device is provided with a plurality of feeding grooves, and the feeding grooves are arranged along the Y direction.

Furthermore, the material distribution device also comprises a translation assembly, and the translation assembly is connected with and drives the material distribution plate to translate along the Y direction.

Further, still include:

the material taking device takes away a group of plastic parts which are well divided on the material dividing device at the same time, and comprises a plurality of material taking components, wherein one material taking component corresponds to one plastic part.

Furthermore, the material taking device further comprises a three-axis moving assembly for driving the material taking assembly to perform three-axis movement.

The utility model discloses following beneficial effect has: according to the vibration disc device, the spiral feeding groove is formed in the vibration disc, so that a plurality of plastic parts in the vibration disc are conveyed upwards in the spiral feeding groove in a spiral mode sequentially through vibration, the plastic parts sequentially pass through the first optical fiber sensor, the first micro air hole, the second optical fiber sensor and the second micro air hole in the conveying process in the spiral feeding groove, when the plastic parts pass through the first optical fiber sensor, the first optical fiber sensor judges the front and back surfaces of the plastic parts through recognizing a first mark on the plastic parts, the first micro air hole blows down the plastic parts with the back surfaces facing upwards according to the recognition result of the corresponding first optical fiber sensor, when the plastic parts pass through the second optical fiber sensor, the orientation of the plastic parts is judged through recognizing a second mark on the plastic parts, the second micro air hole blows down the plastic parts with different orientations according to the recognition result of the corresponding second optical fiber sensor, and finally all the plastic parts are discharged in the mode that the front surfaces face upwards and the orientations are the same.

Drawings

Fig. 1 is a schematic view of a vibration plate device provided by the present invention;

fig. 2 is a schematic view of a plastic part according to the present invention;

fig. 3 is a schematic view of a vibration feeding device provided by the present invention;

FIG. 4 is a schematic view of a material distributing device in the vibration feeding device shown in FIG. 3;

fig. 5 is a schematic view of the material taking device in the vibration feeding device shown in fig. 3.

Detailed Description

The invention is described in detail below with reference to the drawings, wherein examples of the embodiments are shown in the drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely 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, are not to be construed as limiting the invention.

Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or to implicitly indicate the number of technical features indicated. Thus, features defined as "first", "second", and "third" may explicitly or implicitly include one or more of the features. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and "disposed" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral part; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or may be connected through the interconnection of two elements or through the interaction of two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those of ordinary skill in the art.

Example one

As shown in fig. 1, a vibrating disk device 1 for plastic parts, as shown in fig. 2, the plastic part 5 has a first mark 51 for identifying front and back sides and a second mark 52 for identifying orientation, the device includes:

the inner side wall of the vibration disc 11 is provided with a spiral feeding groove 113, and the spiral feeding groove 113 is provided with at least one first micro-pore 114 and at least one second micro-pore 115;

the optical fiber assembly 12 is disposed on the vibration plate 11, and includes at least one first optical fiber sensor 121 corresponding to the first micro-air hole 114, and at least one second optical fiber sensor 122 corresponding to the second micro-air hole 115, and is respectively used for identifying the first identifier 51 and the second identifier 52 of the plastic part 5 in the spiral feeding groove 113.

In the vibration tray device 1, the spiral feeding groove 113 is formed in the vibration tray 11, so that the plurality of plastic parts 5 in the vibration tray 11 are sequentially conveyed upwards in the spiral feeding groove 113 through vibration, the plastic parts 5 sequentially pass through the first optical fiber sensor 121, the first micro air hole 114, the second optical fiber sensor 122 and the second micro air hole 115 in the conveying process in the spiral feeding groove 113, when the plastic parts 5 pass through the first optical fiber sensor 121, the first optical fiber sensor 121 identifies the first identifier 51 on the plastic parts 5 to judge the front and back surfaces of the plastic parts 5, the first micro air hole 114 blows the plastic parts 5 with the back surfaces facing upwards according to the identification result of the corresponding first optical fiber sensor 121, when the plastic parts 5 pass through the second optical fiber sensor 122, the second optical fiber sensor 122 judges the orientation of the plastic parts 5 by identifying the second identifier 52 on the plastic parts 5, and the second micro air hole 115 blows the plastic parts 5 with different orientations according to the identification result of the corresponding second optical fiber sensor 122, and finally all the plastic parts 5 face upwards in the same manner.

In this embodiment, the vibrating disk 11 includes a disk bottom 111 and a disk wall portion 112, and the seismic source of the vibrating disk 11 is disposed in the disk bottom 111; the inner side wall of the disk wall part 112 is obliquely arranged to form a flared space; the radius of the spiral feed chute 113 gradually increases from bottom to top.

Preferably, the spiral feed chute 113 comprises at least two spiral grooves, the width of the former spiral groove is gradually reduced at the spiral top thereof, and the spiral bottom of the latter spiral groove is positioned below the spiral top of the former spiral groove.

When the spiral upwards conveys in the spiral feeding groove 113, the plastic part 5 is gradually conveyed to the top of the spiral from the bottom of the spiral of the previous spiral groove, then the width of the previous spiral groove gradually decreases at the top of the spiral, the plastic part naturally falls down at the top of the spiral of the previous spiral groove, and the bottom of the spiral of the next spiral groove is positioned below the top of the spiral of the previous spiral groove, so that the plastic part 5 is caught by the bottom of the spiral of the next spiral groove when falling down, and the plastic part is continuously conveyed on the next spiral groove, so that the whole length of the spiral feeding groove 113 can be increased, and more plastic parts 5 are conveyed simultaneously.

The reflective rate of the first mark 51 and the second mark 52 is different from that of the plastic part 5, the first mark 51 is located on the front surface of the plastic part 5, and the second mark 52 is located at the front end of the plastic part 5.

The first optical fiber sensor 121 and the second optical fiber sensor 122 are both reflective sensors, and transmit optical signals to the plastic part 5, and recognize the first mark 51 and the second mark 52 according to the reflected optical signals, so as to determine the front side, the back side and the orientation of the plastic part 5. When the first optical fiber sensor 121 recognizes the first identifier 51, the vibration plate device 1 may determine that the plastic part 5 faces upward, and when the second optical fiber sensor 122 recognizes the second identifier 52 twice, the vibration plate device 1 may determine that the two adjacent plastic parts 5 face the same direction.

In this embodiment, the first mark 51 is a pattern, a character, a logo, a color, or an insert made of different materials on the front surface of the plastic part 5, and the second mark 52 is an injection nozzle (a notch) on the front end of the plastic part 5.

In this embodiment, the number of the first optical fiber sensor 121 and the second optical fiber sensor 122 is two, correspondingly, the number of the first micro air hole 114 and the second micro air hole 115 is also two, one first micro air hole 114 corresponds to one first optical fiber sensor 121, and one second micro air hole 115 corresponds to one second optical fiber sensor 122; the first micro-vent 114 is located in front of the corresponding first optical fiber sensor 121 along the spiral conveying direction, and the second micro-vent 115 is located in front of the corresponding second optical fiber sensor 122 along the spiral conveying direction, so as to meet a time difference between the reflected signals received from the first optical fiber sensor 121 and the second optical fiber sensor 122 and the air blown out from the corresponding first micro-vent 114 and the corresponding second micro-vent 115.

The first optical fiber sensor 121 and the second optical fiber sensor 122 are each fixed to the disk wall portion 112 of the vibration disk 11 by a corresponding optical fiber holder 123.

The vibrating disk device 1 further includes:

the air valve assembly 13 comprises at least two air valves, and the air valves are correspondingly connected with the first micro air holes 114 or the second micro air holes 115 through air pipes and used for controlling the air outlet of the first micro air holes 114 or the second micro air holes 115;

the amplifying assembly 14 includes at least two signal amplifiers, and the signal amplifiers are correspondingly connected to the first optical fiber sensor 121 or the second optical fiber sensor 122 through optical fibers, and are configured to amplify optical signals of the first optical fiber sensor 121 or the second optical fiber sensor 122.

In this embodiment, the number of the air valves is four, one air valve is correspondingly connected to one first micro air hole 114 or one second micro air hole 115, and the vibration plate device 1 controls the first micro air hole 114 and the second micro air hole 115 to blow air by controlling the switch of the corresponding air valve. The number of the signal amplifiers is also four, one signal amplifier is correspondingly connected with one first optical fiber sensor 121 or one second optical fiber sensor 122, and the vibration disc device 1 amplifies the optical signals of the first optical fiber sensor 121 and the second optical fiber sensor 122 through the corresponding signal amplifier.

The vibrating disk device 1 further comprises an air pump 15 and an air pressure gauge 16, wherein the air pump 15 is connected with the air valve, and the air pressure gauge 16 is connected with the air pump 15.

The air pumps 15 simultaneously supply air to all the first micro air holes 114 and the second micro air holes 115 through the air valves, and each air pump 15 selectively blows air into the first micro air holes 114 and the second micro air holes 115 by being turned on or off.

The vibration disc 11, the air valve assembly 13, the amplifying assembly 14, the air pump 15, the barometer 16 and the like are all arranged on the machine table 100 of the vibration disc device 1, wherein the air valve assembly 13, the amplifying assembly 14, the air pump 15 and the barometer 16 are fixedly arranged on the machine table 100 through a vertical frame 17.

Example two

As shown in fig. 3, a vibration feeding apparatus for plastic parts 5 includes:

the vibrating disk device 1 according to the first embodiment sends out the plastic parts 5 one by one according to the required front and back sides and the required orientation in a vibrating manner;

the direct vibration device 2 is used for sequentially conveying the plastic parts 5 sent out by the vibration disc device 1 forwards in a vibration mode;

and the material distributing device 3 divides a plurality of plastic parts 5 sequentially sent by the direct vibration device 2 into a group.

This vibration charging outfit passes through feed divider 3 will the plastic part 5 that vibration dish device 1 and the device 2 of directly shaking sent is divided into groups, and a plurality of plastic parts 5 divide into a set ofly to make things convenient for subsequent extracting device 4 to take away the plastic part 5 of the same group simultaneously, improve material loading efficiency.

As shown in fig. 4, the material distributing device 3 includes a material distributing plate 31, the material distributing plate 31 can translate along a Y direction perpendicular to an X direction of feeding by the direct vibration device 2, a plurality of material feeding slots 311 are opened on one side of the material distributing plate 31 facing the direct vibration device 2, the plurality of material feeding slots 311 are arranged along the Y direction, when feeding, the material distributing plate 31 moves along the Y direction, so that each material feeding slot 311 is sequentially aligned with a material discharging position of the direct vibration device 2, and then the direct vibration device 2 sequentially sends each plastic part 5 into the corresponding material feeding slot 311.

In this embodiment, the number of the feeding slots 311 is four, and the feeding slots 311 are sequentially arranged on one side of the material distributing plate 31 facing the feeding slots 311, and one feeding slot 311 accommodates one plastic part 5.

The material distributing device 3 further comprises a translation assembly, and the translation assembly is connected to drive the material distributing plate 31 to translate along the Y direction. As shown in fig. 4, the translation assembly includes a material distribution table 32, a material distribution guide rail 33 and a material distribution driver 34, the material distribution guide rail 33 and the material distribution driver 34 are disposed on the material distribution table 32, and the material distribution guide rail 33 is disposed along the Y direction; the material distributing plate 31 is slidably disposed on the material distributing guide rail 33 and can freely slide on the material distributing guide rail 33; the material distributing driver 34 is connected to drive the material distributing plate 31 to slide on the material distributing guide rail 33, so as to align each material feeding slot 311 with the material discharging position of the direct vibration device 2 in sequence.

EXAMPLE III

As an improved embodiment of the second embodiment, the vibration feeding device of the present embodiment further includes:

the material taking device 4 takes away a set of plastic parts 5 divided by the material dividing device 3 at the same time, as shown in fig. 5, and includes a plurality of material taking assemblies 41, and one material taking assembly 41 corresponds to one plastic part 5.

In this embodiment, the number of the material taking assemblies 41 is four, and one material taking assembly 41 correspondingly grabs the plastic part 5 in one feeding chute 311; the material taking assembly 41 is a vacuum suction nozzle and grabs the plastic part 5 in a vacuum adsorption mode.

The material taking device 4 further comprises a three-axis moving assembly for driving the material taking assembly 41 to move in three axes. The three-axis moving assembly comprises a first moving mechanism 42, a second moving mechanism 43 and a third moving mechanism 44, wherein the number of the first moving mechanisms 42 is two, the two first moving mechanisms are parallel to the X direction, and the two first moving mechanisms are oppositely arranged in parallel along the Y direction; the second moving mechanism 43 is parallel to the Y direction, and two ends of the second moving mechanism are respectively arranged on the two first moving mechanisms 42, and the second moving mechanism 42 is driven by the two first moving mechanisms 42 to translate along the X direction; the number of the third moving mechanisms 44 is four, the third moving mechanisms are parallel to the vertical direction and are relatively parallel to each other along the Y direction, the second moving mechanisms 43 drive the third moving mechanisms to translate along the Y direction, and the third moving mechanisms and the second moving mechanisms 43 synchronously translate along the X direction; each material taking assembly 41 is arranged on the corresponding third moving mechanism 44, is driven by the corresponding third moving mechanism 44 to translate along the vertical direction, and synchronously translates along the X direction and the Y direction along with the corresponding third moving mechanism 44.

It should be finally noted that the above embodiments are only used for illustrating the technical solutions of the embodiments of the present invention and not for limiting the same, and although the embodiments of the present invention are described in detail with reference to the preferred embodiments, those skilled in the art should understand that the technical solutions of the embodiments of the present invention can still be modified or replaced with equivalents, and these modifications or equivalent replacements cannot make the modified technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. The utility model provides a vibrating disk device of plastic part which characterized in that, have the first sign that is used for discerning the positive and negative face and be used for discerning the second sign of orientation on the plastic part, the device includes:

the inner side wall of the vibration disc is provided with a spiral feeding groove, and the spiral feeding groove is provided with at least one first micro-air hole and at least one second micro-air hole;

the optical fiber assembly is arranged on the vibration disc and comprises at least one first optical fiber sensor corresponding to the first micro-air hole and at least one second optical fiber sensor corresponding to the second micro-air hole, and the first optical fiber sensor and the second optical fiber sensor are respectively used for identifying the first mark and the second mark of the plastic part in the spiral feeding groove.

2. The plastic member vibrating disk apparatus according to claim 1, further comprising:

the air valve assembly comprises at least two air valves, and the air valves are correspondingly connected with the first micro-pores or the second micro-pores through air pipes and used for controlling the air outlet of the first micro-pores or the second micro-pores;

and the amplifying assembly comprises at least two signal amplifiers, and the signal amplifiers are correspondingly connected with the first optical fiber sensor or the second optical fiber sensor through optical fibers and are used for amplifying optical signals of the first optical fiber sensor or the second optical fiber sensor.

3. The vibrating disk device for plastic parts according to claim 2, further comprising an air pump and an air pressure gauge, wherein the air pump is connected to the air valve, and the air pressure gauge is connected to the air pump.

4. The vibrating disk apparatus for plastic parts as claimed in claim 1, wherein the first mark and the second mark have different reflectances from the plastic part, the first mark is located on a front surface of the plastic part, and the second mark is located at a front end of the plastic part.

5. The plastic part vibrating tray device according to claim 1, wherein the spiral feed chute includes at least two spiral grooves, a front spiral groove having a width gradually decreasing at a spiral top thereof, and a spiral bottom of a rear spiral groove being located below the spiral top of the front spiral groove.

6. The utility model provides a plastic part's vibration charging equipment which characterized in that includes:

the vibratory tray assembly of any of claims 1-5, wherein the plastic parts are fed out one by one in a vibratory manner with desired front and back sides and orientation;

the direct vibration device conveys the plastic parts sent out by the vibration disc device forward in sequence in a vibration mode;

and the material distributing device divides a plurality of plastic parts sequentially sent by the direct vibration device into a group.

7. The apparatus for feeding plastic parts according to claim 6, wherein the material distributor comprises a material distributor plate, the material distributor plate is capable of translating in a Y direction perpendicular to the X direction of the material fed by the direct vibration device, and a plurality of material feeding grooves are formed on one side of the material distributor plate facing the direct vibration device, and the material feeding grooves are arranged in the Y direction.

8. The apparatus for vibratory feeding of plastic parts according to claim 7, wherein said material distribution device further comprises a translation assembly, said translation assembly being connected to drive said material distribution plate to translate along the Y-direction.

9. The apparatus for vibratory feeding of plastic parts as set forth in claim 7, further comprising:

the material taking device takes away a group of plastic parts which are well divided on the material dividing device at the same time, and comprises a plurality of material taking components, wherein one material taking component corresponds to one plastic part.

10. The plastic part vibrating feeding device as claimed in claim 9, wherein the material taking device further comprises a three-axis moving assembly for driving the material taking assembly to perform three-axis movement.

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