CN216883159U - Inertia type piezoelectric vibration feeding mechanism - Google Patents

Abstract

The utility model relates to the field of vibration feeding, in particular to an inertia type piezoelectric vibration feeding mechanism; an inertial piezoelectric vibration feeding mechanism comprises a vibration frame, a plurality of supporting rods arranged in the vibration frame, a polishing plate and an adjusting plate, wherein the polishing plate and the adjusting plate are arranged on the vibration frame; a supporting groove is formed in the vibration frame, a plurality of chutes are formed in one side face of the supporting groove, and one end of each chute is intersected with the midpoint of the side face of the supporting groove; the adjusting plate is slidably arranged in the bearing groove; the end part of the bearing rod is slidably arranged in the chute at one side of the bearing groove; when the parts conveyed by the vibration frame are changed, the adjusting plate pushes the bearing rods, the distance between every two adjacent bearing rods is changed, the parts are supported, and then the upper surfaces of the parts are abutted to the bottom surface of the grinding plate.

Description

Inertia type piezoelectric vibration feeding mechanism

Technical Field

The utility model relates to the field of vibration feeding, in particular to an inertial type piezoelectric vibration feeding mechanism.

Background

In the patent document of the Chinese patent CN215088824U, a multi-layer screen vibrating machine is disclosed, which comprises a screening cylindrical box, wherein a centrifugal vibrating structure, a centrifugal supporting structure, a screening structure and a sealing structure are arranged in the screening cylindrical box, the centrifugal vibrating structure is arranged at the bottom end of the screening cylindrical box, the centrifugal supporting structure is arranged on the centrifugal vibrating structure, the screening structure is arranged on the centrifugal supporting structure, and the centrifugal vibrating structure comprises a centrifugal vibrating driver, a centrifugal vibrating driving concave wheel, a centrifugal vibrating driving belt, a centrifugal vibrating shaft, a centrifugal ball groove, a centrifugal balance weight disc and a centrifugal balance weight sector block. Carry out the centrifugal rotation vibrations on the horizontal direction with the concave type filter block of a plurality of through centrifugal vibrations structure, through the cooperation in centrifugal ball and centrifugal ball groove, when giving the concave type filter block of a plurality of with centrifugal vibrations transmission, on giving the screening cylinder case with centrifugal rotation vibrations consumption part retransmission, avoided the shake serious, the big power consumption of noise problem.

However, the above patent does not allow for grinding operations to be performed on parts of different specifications during the transportation process.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an inertial piezoelectric vibration feeding mechanism which is used for polishing parts with different specifications in a conveying process.

In order to achieve the above object, an embodiment of the present invention provides an inertial piezoelectric vibration feeding mechanism, which includes a vibration frame, a plurality of support rods disposed in the vibration frame, a polishing plate and an adjusting plate disposed on the vibration frame;

a supporting groove is formed in the vibration frame, a plurality of chutes are formed in one side face of the supporting groove, and one end of each chute is intersected with the midpoint of the side face of the supporting groove;

the adjusting plate is slidably arranged in the bearing groove;

the end part of the bearing rod is slidably arranged in the chute at one side of the bearing groove;

when the parts conveyed by the vibration frame are changed, the adjusting plate pushes the bearing rods to change the distance between the adjacent bearing rods so as to support the parts, and then the upper surfaces of the parts are abutted to the bottom surface of the grinding plate.

Furthermore, the inertial piezoelectric vibration feeding mechanism further comprises a limiting plate and a return spring, wherein the limiting plate and the return spring are arranged at one end of the bearing rod;

one side of the supporting groove is provided with a plurality of limiting cavities, and the limiting cavities correspond to the inclined grooves one by one;

one end of the reset spring is fixedly connected with the end part of the limiting plate, and the other end of the reset spring is fixedly connected with the cavity bottom surface of the limiting cavity.

Furthermore, one side of the support groove is provided with a plurality of inserting grooves which are in one-to-one correspondence with the inclined grooves,

the inserting groove is connected and communicated with the inclined groove.

Further, a discharge hole is formed in the side surface of the vibration frame;

the discharge hole is connected and communicated with the bearing groove.

Furthermore, the inertial piezoelectric vibration feeding mechanism also comprises a plurality of supporting columns arranged at the discharge port;

a sliding hole is formed in the vibrating frame;

each bearing column can be slidably arranged in the sliding hole, and the bottom surface of each bearing column is abutted against the upper surface of the adjusting plate.

Furthermore, the inertial piezoelectric vibration feeding mechanism further comprises an adjusting bolt in threaded connection with the bottom of the vibration frame;

the adjusting bolt is rotatably connected with the adjusting plate.

Furthermore, the inertial piezoelectric vibration feeding mechanism also comprises a top pushing plate arranged on the adjusting plate;

the end surface of the push plate is abutted against the side surface of the supporting rod.

Compared with the prior art, the embodiment of the utility model has the following beneficial effects: after the part gets into the vibration frame from the pan feeding mouth in, can make thick head card between two adjacent bearing rods under the vibration of vibration frame, and thin head passes the bearing rod and places downwards. Then the thick head end of the part can be polished.

Drawings

The utility model is further illustrated with reference to the following figures and examples.

FIG. 1 illustrates a functional block diagram of the present invention;

FIG. 2 shows a schematic structural view of a support bracket of the present invention;

FIG. 3 shows an enlarged partial view of A of FIG. 2 of the present invention;

FIG. 4 shows a close-up view of B of FIG. 2 of the present invention;

in the figure: 100. A vibration frame; 1001. a chute; 101. a support rod; 103. an adjusting plate; 104. a limiting plate; 105. a return spring; 106. a cover plate; 108. grinding the plate; 109. adjusting the bolt; 110. a support post; 111. and (4) inserting grooves.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.

Those skilled in the art will understand that: the material shaking machine is powered on, the mixing time is set, the switch is pressed, and the materials are turned over in a reciprocating mode through mechanical transmission to obtain a product which is mixed uniformly. In this embodiment, a suitable material shaking machine is used to repeatedly vibrate the parts to be processed, and the parts are arranged in order by matching with a related structure.

And steel wool, also called steel velvet, is in a velvet shape and is formed into a band shape with a certain width by a plurality of continuous fibers. In the embodiment, the upper end surface of the part is polished by steel wool.

As shown in fig. 1 and 2, the present invention provides an inertial type piezoelectric vibration feeding mechanism, including: a vibration frame 100, a supporting rod 101, a grinding plate and a regulating plate 103. The vibratory frame 100 is adapted to vibrate shake the material. The carrier bar 101 is adapted to support a part. The polishing plate is suitable for polishing the thick head end of the part. The adjustment plate 103 is adapted to adjust the height of the support bar 101. With respect to the above components, a detailed description is given below.

Vibration rack 100

The vibrating frame 100 is a rectangular frame, and the vibrating frame 100 has openings at two sides, which are a feeding port and a discharging port respectively. The parts can enter the inner cavity of the vibration frame 100 from one side of the feeding port, and can be taken out from the discharging port after being subjected to vibration arrangement and polishing treatment.

A supporting groove is arranged in the vibrating frame 100 and is arranged below the feeding port, and the supporting groove is perpendicular to the bottom wall of the vibrating frame 100. The support groove is connected and communicated with the discharge hole.

A plurality of chutes 1001 are formed on one side surface of the supporting groove. The lower end of each inclined groove 1001 is intersected at the midpoint of the side surface of the support groove, the upper end of each inclined groove 1001 is inclined towards two sides, and the inclined degree of the inclined groove 1001 closer to the two sides of the susceptor groove is larger. The support groove one side is still provided with a plurality of limiting cavities, and the limiting cavities correspond to the chutes 1001 one by one, specifically, one limiting cavity is correspondingly arranged on one side of one chute 1001 far away from the inner cavity of the vibration rack 100.

One side of the vibration frame 100, which is far away from the supporting slot, is provided with a sliding hole, the sliding hole is in a long strip shape, and the sliding hole penetrates through the bottom wall of the vibration frame 100 along the width direction of the vibration frame 100.

Support rod 101

The support rod 101 is slidably disposed within the vibratory frame 100. Specifically, the support rods 101 are horizontally disposed, and the support rods 101 are parallel to each other. A support rod 101 is inserted into a corresponding slot 1001. The support bars 101 are adapted to support the parts and each support bar 101 can be slid up and down the chute 1001 in unison to adjust the spacing between each support bar 101. The part shown in this embodiment is in a long strip shape, one end of the part is a thick head with a larger diameter, the other end of the part is a thin head with a smaller diameter, and the gravity center of the part is close to one end of the thin head. After the parts enter the vibration rack 100 from the feeding port, the thick heads can be clamped between two adjacent support rods 101 under the vibration of the vibration rack 100, and the thin heads pass through the support rods 101 to be placed downwards. Then the thick head end of the part can be polished.

The side surface of the bearing rod 101 is a grinding surface, and when the part is conveyed forwards, the side surface of the part can be ground.

Fig. 3 only shows a schematic structural diagram of a limiting cavity, in order to achieve the above effect, a limiting plate 104 and a return spring 105 are arranged at one end of the support rod 101 close to the chute 1001, the limiting plate 104 and the return spring 105 are both arranged in the limiting cavity, one end of the return spring 105 is fixedly connected with an end portion of the limiting plate 104, and the other end of the return spring 105 is fixedly connected with a cavity bottom surface of the limiting cavity. The limiting cavity can limit the radial deformation of the return spring 105, so that the return spring 105 can only be stretched or compressed along the length direction of the limiting cavity.

In order to facilitate replacement of the support rod 101 and the limit plate 104, a plurality of insertion grooves 111 are formed in one side of the support groove, the insertion grooves 111 correspond to the inclined grooves 1001 one by one, and the insertion grooves 111 are connected and communicated with the inclined grooves 1001. The inertial piezoelectric vibration feeding mechanism further comprises a cover plate 106 matched with the insertion groove 111. Through the arrangement of the insertion groove 111, the bearing rod 101 can be conveniently inserted into the vibration rack 100 along the inclined groove 1001, and the limiting plate 104 and the return spring 105 can be synchronously inserted into the insertion groove 111; the end of the return spring 105 is normally held against the cover 106.

Adjusting plate 103

As shown in FIG. 4, the adjustment plate 103 is slidably disposed within the receiving slot. Specifically, the adjusting plate 103 is disposed parallel to the bottom wall of the vibration frame 100, and the adjusting plate 103 is adapted to adjust the height of the support rod 101.

In order to achieve the above effect, two ends of the adjusting plate 103 are further fixed with a top pushing plate, and the top pushing plate is arranged along the width direction of the vibration frame 100. The end surface of the pushing plate is abutted against the side surface of the supporting rod 101. When the adjusting plate 103 slides up and down, the two positioning plates can push the supporting rods 101 to synchronously slide up and down, and the supporting rods 101 can open towards two sides or close inwards along the inclined groove 1001. In order to further support the adjusting plate 103, the inertial piezoelectric vibration feeding mechanism further comprises a plurality of support columns 110 arranged at the discharge port. The bearing column 110 is slidably arranged in the sliding hole, the bottom surface of the bearing column 110 is abutted to the upper surface of the adjusting plate 103, the bearing column 110 is fixedly connected with the bearing rod 101, and the bearing rod 101 can drive the bearing column 110 to slide along the length direction of the sliding hole when sliding along the inclined groove 1001.

In order to adjust the height of the adjusting plate 103, the inertial piezoelectric vibration feeding mechanism further comprises an adjusting bolt 109 in threaded connection with the bottom of the vibration frame 100. The adjusting bolt 109 is rotatably connected with the adjusting plate 103. When the adjusting bolt 109 is rotated, the adjusting plate 103 is abutted against the bearing groove, so that the adjusting plate 103 is reset to rotate along with the adjusting bolt 109 and only can slide up and down along the bearing groove. In this way, the adjusting plate 103 can be driven to push the support rods 101 to synchronously slide up and down.

Polishing plate

The polishing plate is arranged at the top of the vibrating frame 100, steel wool is arranged on the bottom surface of the polishing plate, and when the vibrating frame 100 vibrates the part until the thick head faces upwards, the upper surface of the part is abutted to the bottom surface of the polishing plate. The vibratory frame 100 can continue to drive the vibratory frame 100 to vibrate so that the sanding plate will grind the top of the button.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. An inertial piezoelectric vibration feeding mechanism is characterized by comprising a vibration frame, a plurality of supporting rods arranged in the vibration frame, a grinding plate and an adjusting plate, wherein the grinding plate and the adjusting plate are arranged on the vibration frame;

a supporting groove is formed in the vibration frame, a plurality of chutes are formed in one side face of the supporting groove, and one end of each chute is intersected with the midpoint of the side face of the supporting groove;

the adjusting plate is slidably arranged in the bearing groove;

the end part of the bearing rod is slidably arranged in the chute at one side of the bearing groove;

when the parts conveyed by the vibration frame are changed, the adjusting plate pushes the bearing rods to change the distance between the adjacent bearing rods so as to support the parts, and then the upper surfaces of the parts are abutted to the bottom surface of the grinding plate.

2. An inertial type piezoelectric vibration feeding mechanism according to claim 1,

the inertia type piezoelectric vibration feeding mechanism further comprises a limiting plate and a return spring, wherein the limiting plate and the return spring are arranged at one end of the bearing rod;

one side of the supporting groove is provided with a plurality of limiting cavities, and the limiting cavities correspond to the inclined grooves one by one;

one end of the reset spring is fixedly connected with the end part of the limiting plate, and the other end of the reset spring is fixedly connected with the cavity bottom surface of the limiting cavity.

3. An inertial type piezoelectric vibration feeding mechanism according to claim 2,

one side of the supporting groove is provided with a plurality of inserting grooves which are in one-to-one correspondence with the inclined grooves,

the inserting groove is connected and communicated with the inclined groove.

4. An inertial type piezoelectric vibration feeding mechanism according to claim 3,

a discharge hole is formed in the side surface of the vibration frame;

the discharge hole is connected and communicated with the bearing groove.

5. An inertial type piezoelectric vibration feeding mechanism according to claim 4,

the inertia type piezoelectric vibration feeding mechanism also comprises a plurality of supporting columns arranged at the discharge port;

the vibration rack is provided with a sliding hole;

each bearing column can be slidably arranged in the sliding hole, and the bottom surface of each bearing column is abutted against the upper surface of the adjusting plate.

6. An inertial piezoelectric vibration feeding mechanism according to claim 5,

the inertia type piezoelectric vibration feeding mechanism further comprises an adjusting bolt in threaded connection with the bottom of the vibration frame;

the adjusting bolt is rotatably connected with the adjusting plate.

7. An inertial type piezoelectric vibration feeding mechanism according to claim 6,

the inertia type piezoelectric vibration feeding mechanism further comprises a top push plate arranged on the adjusting plate;

the end surface of the push plate is abutted against the side surface of the supporting rod.

Images