CN218987760U - Crystal oscillator piece detects machine convenient to pay-off - Google Patents

Abstract

The utility model discloses a crystal oscillator wafer detector convenient for feeding, which comprises a frame and a conveyor belt, wherein a blanking hopper is movably arranged on the frame, a plurality of protruding blocks are arranged on the belt surface of the conveyor belt, and the protruding blocks are driven to move so as to drive the blanking hopper to uniformly blanking. According to the crystal oscillator wafer detector convenient to feed, when the crystal oscillator wafer to be detected is detected, the crystal oscillator wafer to be detected is placed in the blanking hopper, the conveyor belt works to drive the convex blocks on the belt surface to move, the convex blocks push the blanking hopper to enable the blanking hopper to vibrate, the blanking hopper is convenient to drop the crystal oscillator wafer between the convex blocks on the conveyor belt, the convex blocks separate the crystal oscillator wafer, and the conveyor belt is convenient to independently convey the crystal oscillator wafer to crystal oscillator wafer detection equipment so as to carry out detection work.

Description

Crystal oscillator piece detects machine convenient to pay-off

Technical Field

The utility model relates to the technical field of crystal oscillator wafer detection, in particular to a crystal oscillator wafer detector convenient for feeding.

Background

The crystal oscillator is a thin wafer cut by a polyhedral quartz rod, and is mainly made into various electronic components by utilizing piezoelectricity.

According to publication (bulletin) number CN206378545U, publication (bulletin) date 2017.08.04, the disclosed crystal oscillator wafer detector is characterized in that: the machine comprises a machine table, wherein the machine table is provided with: the magazine type feeding mechanism is used for conveying a carrier disc provided with crystal oscillator wafers to a feeding working position, the feeding conveying mechanism is used for sucking the crystal oscillator wafers positioned in the feeding working position onto the indexing mechanism, the electrode detection mechanism is used for detecting the crystal oscillator wafers positioned in the indexing mechanism, the grabbing and transferring mechanism is used for sucking the detected crystal oscillator wafers out of the indexing mechanism and conveying the crystal oscillator wafers to a discharging working position, the discharging conveying mechanism is used for sucking the crystal oscillator wafers positioned in the discharging working position onto an empty carrier disc, the magazine type feeding mechanism comprises a feeding box and a material taking mechanism, a plurality of supporting tables are arranged on two side walls of the feeding box relatively, the supporting tables are used for supporting the carrier disc provided with the crystal oscillator wafers, and a lifting driving mechanism for pushing the feeding box to lift and a translation driving mechanism for driving the material taking mechanism to move are further arranged below the machine table, and the lifting driving mechanism can drive the feeding box to lift and place the carrier disc on the material taking mechanism. The device comprises a magazine type feeding mechanism for conveying a carrier plate filled with crystal oscillator wafers to a feeding working position, a feeding conveying mechanism for sucking the crystal oscillator wafers positioned at the feeding working position onto a dividing mechanism, an electrode detection mechanism for detecting the crystal oscillator wafers positioned in the dividing mechanism, a grabbing and transferring mechanism for sucking the detected crystal oscillator wafers out of the dividing mechanism and conveying the detected crystal oscillator wafers to a discharging working position, and a discharging conveying mechanism for sucking the crystal oscillator wafers positioned at the discharging working position onto an empty-load plate.

In the prior art including the above patent, when the crystal oscillator wafer is inspected, it is necessary to separate the crystal oscillator wafer and perform inspection alone, but the size of the crystal oscillator wafer is too small (thickness 0.23mm, diameter 13.98 mm), and it is difficult to completely separate the crystal oscillator wafer by conventional separation means.

Disclosure of Invention

The utility model aims to provide a crystal oscillator wafer detector convenient for feeding, and aims to solve the problem that crystal oscillator wafers are difficult to separate independently during detection.

In order to achieve the above purpose, the utility model provides a crystal oscillator wafer detector convenient for feeding, which comprises a frame and a conveyor belt, wherein a blanking hopper is movably arranged on the frame, a plurality of protruding blocks are arranged on the belt surface of the conveyor belt, and the protruding blocks are driven to move so as to drive the blanking hopper to uniformly blanking.

Preferably, the discharging hopper is provided with a tenon block extending to the inside of the frame, and the frame is provided with a tenon groove matched with the tenon block.

Preferably, the blanking hopper comprises a blanking part and a storage part, and the inner diameter of the blanking part is the same as the size of the crystal oscillator piece.

Preferably, sliding rods distributed in a circumferential array are movably arranged in the blanking part.

Preferably, the sliding rod is provided with first wedges which are distributed in a linear array and are used for separating crystal oscillator wafers.

Preferably, a spring is arranged between the slide bar and the blanking part.

Preferably, a movable ring is movably arranged in the blanking part, and second wedge blocks which are distributed in a circumferential array and used for pushing the sliding rods are arranged on the movable ring.

Preferably, a slope matched with the second wedge block is arranged on the sliding rod.

Preferably, third wedges for pushing the second wedges are symmetrically and movably arranged on the discharging part, and slopes are arranged on the parts, extending to the outer sides of the discharging part, of the third wedges.

Preferably, the bump includes an inclined portion and a pushing portion for pressing the third wedge, and the height of the pushing portion is the same as the thickness of the crystal oscillator wafer.

In the technical scheme, the crystal oscillator wafer detector convenient for feeding has the following beneficial effects: when detecting, put the crystal oscillator piece that waits to detect in the hopper down, the conveyer belt work drives the lug on its area and removes, and the lug supports to push away down the hopper, makes down the hopper produce vibrations, makes things convenient for down between the lug that the hopper falls the crystal oscillator piece on the conveyer belt, and the lug separates the crystal oscillator piece, makes things convenient for the conveyer belt to carry on the crystal oscillator piece check out test equipment with the crystal oscillator piece alone on to detect the work.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present utility model, and other drawings may be obtained according to these drawings for a person having ordinary skill in the art.

FIG. 1 is a schematic diagram of the overall structure provided by an embodiment of the present utility model;

FIG. 2 is a schematic diagram of an internal structure according to an embodiment of the present utility model;

fig. 3 is an enlarged view at a in fig. 2.

Reference numerals illustrate:

1. a frame; 11. discharging a hopper; 12. a blanking part; 121. a first wedge; 122. a slide bar; 123. a spring; 13. a movable ring; 131. a second wedge; 132. a third wedge; 14. tenon blocks; 15. a storage part; 2. a conveyor belt; 21. a bump; 22. a pushing part; 23. an inclined portion.

Detailed Description

In order to make the technical scheme of the present utility model better understood by those skilled in the art, the present utility model will be further described in detail with reference to the accompanying drawings.

As shown in fig. 1-3, a crystal oscillator wafer detector convenient for feeding comprises a frame 1 and a conveyor belt 2, wherein a blanking hopper 11 is movably arranged on the frame 1, a plurality of protruding blocks 21 are arranged on the belt surface of the conveyor belt 2, and the protruding blocks 21 are driven to move so as to drive the blanking hopper 11 to uniformly blanking.

In the above technical scheme, when detecting, the crystal oscillator wafer to be detected is placed in the blanking hopper 11, the conveyor belt 2 works to drive the lug 21 on the belt surface to move, the lug 21 pushes the blanking hopper 11 to vibrate, the blanking hopper 11 is convenient to shake, the blanking hopper 11 drops the crystal oscillator wafer between the lugs 21 on the conveyor belt 2, the lugs 21 separate the crystal oscillator wafer, and the conveyor belt 2 is convenient to independently convey the crystal oscillator wafer to crystal oscillator wafer detection equipment so as to carry out detection work.

As a further provided embodiment of the present utility model, as shown in fig. 2-3, a tenon 14 extending into the frame 1 is provided on the blanking hopper 11, a mortise adapted to the tenon 14 is provided on the frame 1, the tenon 14 cooperates with the mortise to guide the blanking hopper 11 to move, the blanking hopper 11 includes a blanking portion 12 and a storage portion 15, the inner diameter of the blanking portion 12 is the same as the size of the crystal oscillator wafer, sliding rods 122 distributed in a circumferential array are movably provided in the blanking portion 12, first wedges 121 distributed in a linear array and used for separating the crystal oscillator wafer are provided on the sliding rods 122, springs 123 are provided between the sliding rods 122 and the blanking portion 12, and slopes are provided at the bottom of the blanking portion 12; during detection, a crystal oscillator sheet to be detected is placed in the blanking hopper 11, the crystal oscillator sheet enters the blanking portion 12 from the storage portion 15 and is supported by the first wedges 121, the crystal oscillator sheet falling into the blanking portion 12 is kept horizontal, at the moment, the conveyor belt 2 works to drive the bumps 21 on the belt surface to move, the blanking hopper 11 moves upwards along the inclined portions 23 of the bumps 21, the blanking portion 12 abuts against the top of the bumps 21, the bumps 21 continue to move, the bumps 21 are separated from the blanking portion 12, the blanking hopper 11 falls onto the conveyor belt 2 under the action of gravity, the crystal oscillator sheet in the blanking portion generates vibration, the blanking portion 12 is embedded between the two bumps 21, the pushing portions 22 of the two bumps 21 are matched to squeeze the third wedges 132, the third wedges 132 push the second wedges 131 to drive the movable ring 13 to rotate, the movable ring 13 drive the second wedges 131 to move, the movable ring 122 is pushed to move along the direction of the first wedges 121 away from the center of the blanking portion 12, the first wedges 121 continue to move, the first wedges 121 are separated from the blanking portion 12, the crystal oscillator sheet can be pushed down to the blanking portion 21 under the action of gravity, the crystal oscillator sheet can be separated from the blanking portion 21 by the first wedges 21, the crystal oscillator sheet can be pushed down to the first wedges 21 to the side wall of the crystal oscillator sheet 21 in the conveyor belt 2, the crystal oscillator sheet can be separated from the crystal oscillator sheet can be pushed down by the first wedges 21, the crystal oscillator sheet can be pushed down by the third wedges 132, and the crystal oscillator sheet can be pushed down by the sliding rod 132 to move up, the crystal oscillator sheet can be separated from the crystal oscillator sheet 21 to the crystal oscillator sheet 21, and separated from the crystal oscillator sheet 21 is pushed down by the crystal oscillator sheet 21 to move, and the crystal oscillator sheet is separated from the crystal oscillator sheet 21 is pushed down by the crystal, and the crystal oscillator sheet and is separated to move the crystal, and is separated.

As still another embodiment of the present utility model, as shown in fig. 2-3, a movable ring 13 is movably disposed in the blanking portion 12, a second wedge 131 distributed in a circumferential array and used for pushing against the sliding rod 122 is disposed on the movable ring 13, a slope adapted to the second wedge 131 is disposed on the sliding rod 122, a third wedge 132 used for pushing against the second wedge 131 is symmetrically and movably disposed on the blanking portion 12, a slope is disposed on a portion of the third wedge 132 extending to the outer side of the blanking portion 12, the bump 21 includes an inclined portion 23 and a pushing portion 22 used for pressing against the third wedge 132, and the height of the pushing portion 22 is the same as the thickness of the crystal oscillator wafer; during detection, a crystal oscillator sheet to be detected is placed in the blanking hopper 11, the crystal oscillator sheet enters the blanking portion 12 from the storage portion 15 and is supported by the first wedges 121, the crystal oscillator sheet falling into the blanking portion 12 is kept horizontal, at the moment, the conveyor belt 2 works to drive the bumps 21 on the belt surface to move, the blanking hopper 11 moves upwards along the inclined portions 23 of the bumps 21, the blanking portion 12 abuts against the top of the bumps 21, the bumps 21 continue to move, the bumps 21 are separated from the blanking portion 12, the blanking hopper 11 falls onto the conveyor belt 2 under the action of gravity, the crystal oscillator sheet in the blanking portion generates vibration, the blanking portion 12 is embedded between the two bumps 21, the pushing portions 22 of the two bumps 21 are matched to squeeze the third wedges 132, the third wedges 132 push the second wedges 131 to drive the movable ring 13 to rotate, the movable ring 13 drive the second wedges 131 to move, the movable ring 122 is pushed to move along the direction of the first wedges 121 away from the center of the blanking portion 12, the first wedges 121 continue to move, the first wedges 121 are separated from the blanking portion 12, the crystal oscillator sheet can be pushed down to the blanking portion 21 under the action of gravity, the crystal oscillator sheet can be separated from the blanking portion 21 by the first wedges 21, the crystal oscillator sheet can be pushed down to the first wedges 21 to the side wall of the crystal oscillator sheet 21 in the conveyor belt 2, the crystal oscillator sheet can be separated from the crystal oscillator sheet can be pushed down by the first wedges 21, the crystal oscillator sheet can be pushed down by the third wedges 132, and the crystal oscillator sheet can be pushed down by the sliding rod 132 to move up, the crystal oscillator sheet can be separated from the crystal oscillator sheet 21 to the crystal oscillator sheet 21, and separated from the crystal oscillator sheet 21 is pushed down by the crystal oscillator sheet 21 to move, and the crystal oscillator sheet is separated from the crystal oscillator sheet 21 is pushed down by the crystal, and the crystal oscillator sheet and is separated to move the crystal, and is separated.

While certain exemplary embodiments of the present utility model have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that modifications may be made to the described embodiments in various different ways without departing from the spirit and scope of the utility model. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive of the scope of the utility model, which is defined by the appended claims.

Claims (10)

1. The utility model provides a crystal oscillator piece detects machine convenient to pay-off, its characterized in that includes frame (1) and conveyer belt (2), the activity is provided with down hopper (11) on frame (1), be provided with a plurality of lugs (21) on the area face of conveyer belt (2), lug (21) are driven and are removed in order to order about down hopper (11) evenly unloading.

2. The crystal oscillator wafer detection machine convenient to feed according to claim 1, wherein a tenon block (14) extending to the inside of the frame (1) is arranged on the discharging hopper (11), and a mortise matched with the tenon block (14) is formed in the frame (1).

3. The crystal oscillator wafer inspection machine convenient to feed according to claim 1, wherein the blanking hopper (11) comprises a blanking portion (12) and a storage portion (15), and the inner diameter of the blanking portion (12) is the same as the crystal oscillator wafer in size.

4. A crystal oscillator wafer inspection machine facilitating feeding according to claim 3, wherein sliding rods (122) distributed in a circumferential array are movably arranged in the blanking portion (12).

5. The crystal oscillator wafer inspection machine for facilitating feeding according to claim 4, wherein the sliding rod (122) is provided with first wedges (121) which are distributed in a linear array and are used for separating crystal oscillator wafers.

6. The crystal oscillator wafer inspection machine with convenient feeding according to claim 4, wherein a spring (123) is arranged between the slide bar (122) and the blanking portion (12).

7. The crystal oscillator wafer inspection machine convenient for feeding according to claim 4, wherein a movable ring (13) is movably arranged in the blanking portion (12), and second wedges (131) distributed in a circumferential array and used for pushing against the sliding rod (122) are arranged on the movable ring (13).

8. The crystal wafer inspection machine for facilitating feeding according to claim 7, wherein a slope adapted to the second wedge (131) is provided on the slide bar (122).

9. The crystal oscillator wafer inspection machine convenient for feeding according to claim 7, wherein a third wedge block (132) for pushing against the second wedge block (131) is symmetrically and movably arranged on the blanking portion (12), and a slope is arranged on a portion of the third wedge block (132) extending to the outer side of the blanking portion (12).

10. The crystal oscillator wafer inspection machine with convenient feeding according to claim 9, wherein the bump (21) comprises an inclined portion (23) and a pushing portion (22) for pressing the third wedge (132), and the height of the pushing portion (22) is the same as the thickness of the crystal oscillator wafer.

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