Crystal oscillator detection device slide type magazine collection structure
By using a sliding plate-type material box collection structure, and utilizing a sliding plate and lifting support mechanism, the crystal oscillator wafers can be collected efficiently. This solves the problems of complex structure and low efficiency of existing devices, reduces costs, and improves collection efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- TIEWAY TECH (ZHONGSHAN) INC
- Filing Date
- 2025-07-31
- Publication Date
- 2026-07-07
AI Technical Summary
Existing crystal oscillator testing devices have complex collection structures and low efficiency. Conventional suction cup gripping methods are time-consuming and labor-intensive, making it difficult to efficiently collect qualified and defective crystal oscillators.
A sliding plate type material box collection structure for a crystal oscillator testing device was designed. By using a sliding plate and a lifting support mechanism, the material box slides onto the support plate by its own gravity, achieving efficient collection without suction cups. The structure is simple and low in cost.
This method enables efficient collection of crystal oscillators, reduces the complexity and cost of the collection process, and improves collection efficiency.
Smart Images

Figure CN224466692U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to a crystal oscillator testing machine, and more particularly to a sliding plate type material box collection structure for a crystal oscillator testing device. Background Technology
[0002] Crystal oscillators are mainly used in the field of film thickness control instruments. The thin, round crystal oscillators are derived from polyhedral quartz rods, which are first cut into hexahedral rods. After repeated cutting and grinding, the quartz rods are finally made into a pile of thin quartz sheets. Each quartz sheet is trimmed, polished and cleaned, and finally plated with metal electrodes to become a crystal oscillator, which is suitable for coating control of different stress film materials.
[0003] Current processing technology cannot guarantee that all crystal oscillators are qualified, so it is inevitable that a small number of defective crystal oscillators will appear. In order to pick out these defective crystal oscillators, they must be tested. After the test is completed, they will be put into a plastic packaging box (patent name: quartz crystal oscillator packaging box, patent number: 201520632723.3). The plastic packaging box will then be grasped and collected in a predetermined position. Therefore, the applicant has designed a crystal oscillator testing device to achieve the above purpose.
[0004] However, conventional collection methods generally use suction cups in conjunction with a motion mechanism to grab the plastic packaging box filled with crystal oscillators from the conveyor belt to the predetermined position. The above structure is relatively complex, and the suction cup needs to be raised, lowered, and moved during the grabbing process, which is relatively inefficient. Therefore, in order to address the above shortcomings, the applicant has designed a material box collection structure that is highly efficient and simple in structure. Summary of the Invention
[0005] In order to overcome the shortcomings of the existing technology, this utility model provides a sliding plate material box collection structure for a crystal oscillator detection device.
[0006] The technical solution adopted by this utility model to solve its technical problem is:
[0007] A sliding plate type material box collection structure for a crystal oscillator testing device is characterized by comprising a sliding plate, a material collection cage, a tray, and a lifting and holding mechanism. The tray is located in the material collection cage and is connected to the lifting and holding mechanism so that it can be raised and lowered in the material collection cage. The sliding plate is inclined and the relatively lower side of the sliding plate is located in the cage opening of the material collection cage. The material box can slide along the sliding plate into the material collection cage and be located on the tray.
[0008] The material collection cage has a side opening on one side, and the width of the pallet is smaller than the width of the side opening.
[0009] The material collection cage includes a bottom plate, several cage rods, and a body plate. The bottom plate and the body plate are fixed to the cage rods, thereby forming a cylindrical shape.
[0010] The cage body plate is provided with rod holes and locking screw holes that pass through the rod holes. The cage rod is located in the rod holes, and the locking screw cooperates with the locking screw hole to fix the cage body plate and the cage rod.
[0011] It also includes a base, which includes a seat plate and a vertical plate. The seat plate is provided with a bottom groove, and the bottom plate of the cage is located in the bottom groove.
[0012] The bottom groove is provided with a positioning post, and the bottom plate of the cage is provided with a positioning hole that cooperates with the positioning post.
[0013] Furthermore, the cage rods are four in number and arranged in a square, and the cage body plate is C-shaped.
[0014] The lifting and supporting mechanism includes a supporting motor, an upper supporting pulley, a lower supporting pulley, and a supporting belt disposed on the upper supporting pulley and the lower supporting pulley. A connecting seat is fixed on the supporting belt, and the support plate is fixed to the connecting seat.
[0015] The connecting seat includes a seat body and a clamping plate. The support plate is fixed to the seat body, and the support strap is fixed to the seat body through the clamping plate.
[0016] It also includes a linear guide rail and a slider, with the base and slider fixed together.
[0017] The beneficial effects of this utility model are: This utility model has a simple structure. It uses the weight of the material box itself to slide from the slide plate to the tray, thereby stacking them into a pile in the collection cage. There is no need for a suction cup gripping mechanism. It is not only low in cost, but also has a short falling distance of the material box, thus achieving high collection efficiency. Attached Figure Description
[0018] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0019] Figure 1 This is a structural view of the present invention in conjunction with the belt conveyor device;
[0020] Figure 2 This is a structural view of the present invention and the base plate;
[0021] Figure 3 This is a structural view of the connector and the material box. Detailed Implementation
[0022] The advantages and features of this disclosure, as well as its implementation methods, will be illustrated by the following embodiments described with reference to the accompanying drawings. However, this disclosure may be embodied in different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be comprehensive and complete, and will fully convey the scope of this disclosure to those skilled in the art. Furthermore, this disclosure is limited only by the scope of the claims.
[0023] The shapes, dimensions, scales, angles, and numbers disclosed in the accompanying drawings used to describe embodiments of this disclosure are merely examples, and therefore this disclosure is not limited to the details shown. Throughout this specification, the same reference numerals refer to the same elements. In the following description, detailed descriptions of relevant known functions or configurations will be omitted where it is determined that such detailed descriptions would unnecessarily obscure the focus of this disclosure. Where the terms “comprising,” “having,” and “including” are used in this specification, additional components may be added unless “only” is used. Unless otherwise indicated, singular terms may include plural forms.
[0024] When interpreting components, even if not explicitly described, the components are understood to include a range of tolerances.
[0025] When describing positional relationships, such as "on," "above," "below," and "adjacent to," one or more parts may be arranged between two other parts unless "immediately following" or "directly" is used.
[0026] When describing temporal relationships, such as when time sequence is described as “after,” “following,” “next,” and “before,” discontinuous cases may be included unless “exactly” or “directly” is used.
[0027] It should be understood that although the terms “first,” “second,” etc., may be used herein to describe various elements, these elements should not be limited by these terms. These terms are used only to distinguish one element from other elements. For example, a first element may be referred to as a second element, and similarly, a second element may be referred to as a first element, without departing from the scope of this disclosure.
[0028] As will be fully understood by those skilled in the art, the features of the different embodiments of this disclosure may be coupled or combined with each other in part or in whole, and may cooperate with each other and be technically driven in various ways. The embodiments of this disclosure may be implemented independently of each other, or may be implemented together in an interdependent relationship.
[0029] Reference Figures 1 to 3 This utility model discloses a sliding plate type material box collection structure for a crystal oscillator testing device, including a sliding plate 1, a material collection cage 2, a support plate 3, and a lifting and holding mechanism. The support plate 3 is located in the material collection cage 2, and the support plate 3 is connected to the lifting and holding mechanism so that it can be raised and lowered in the material collection cage 2. The sliding plate 1 is inclined and the relatively lower side of the sliding plate 1 is located in the cage opening of the material collection cage 2. The material box 5 can slide along the sliding plate 1 into the material collection cage 2 and be located on the support plate 3.
[0030] The material box 5 collected by this material box 5 collection structure is conveyed by a conveyor belt with a conveyor device 4. In order to achieve gravity-based collection, the height of the conveyor belt is higher than the height of the collection cage 2. Therefore, the relatively higher side of the slide plate 1 is located at the exit of the conveyor belt. When the material box 5 is delivered to the slide plate 1 from the exit of the conveyor belt at a certain speed, it will slide along the slide plate 1 into the cage opening of the collection cage 2. It will fall down along the collection cage 2 onto the pallet 3 due to the constraint of the collection cage 2, thus stacking into a pile. The pallet 3 of this application is moved to the position closest to the cage opening by a lifting and holding mechanism, thereby ensuring that the material box 5 sliding down from the slide plate 1 falls the shortest distance. Moreover, when a material box 5 falls onto the pallet 3, the pallet 3 will drop by the thickness of the material box 5, thereby ensuring that the material box 5 has enough space for flipping and stacking.
[0031] As shown in the figure, as a preferred structure, the material collection cage 2 has a side opening 6 on one side. The width of the pallet 3 is smaller than the width of the side opening 6, but the width of the side opening 6 is smaller than the diameter of the material box 5. The material box 5 in this application is a circular plastic box 5 used to hold crystal oscillators. In this way, when the material collection cage 2 is filled with a predetermined number of material boxes 5, the material collection cage 2 can be lifted directly and then transferred to the packing process. During this process, the pallet 3 can be removed from the side opening 6 without causing any obstruction.
[0032] As shown in the figure, the specific structure of the material collection cage 2 includes a cage bottom plate 7, several cage rods 8, and a cage body plate 9. Both the cage bottom plate 7 and the cage body plate 9 are fixed to the cage rods 8, thus forming a cylindrical shape for the material collection cage 2. This structure is simple, easy to process and manufacture, and very lightweight, facilitating manual handling. Furthermore, there are four cage rods 8 arranged in a square, and the cage body plate 9 is C-shaped. The notch in the cage body plate 9 forms part of the side opening 6, facilitating the lifting and separation of the support plate 3.
[0033] Specifically, the cage body plate 9 is provided with rod holes and locking screw holes 10 that pass through the rod holes. The cage rod 8 is located in the rod holes. The locking screw cooperates with the locking screw hole 10 to fix the cage body plate 9 and the cage rod 8. The above structure is convenient for installation and manufacturing.
[0034] As shown in the figure, it also includes a base 11, which includes a seat plate 12 and a vertical plate 13. The seat plate 12 is provided with a bottom groove 14, and the cage bottom plate 7 is located in the bottom groove 14. The bottom groove 14 is surrounded by three side plates 15 surrounding the seat plate 12. Because the side opening 6 of the collection cage 2 and the support plate 3 are opposite to each other and have directionality, the bottom groove 14 is a square groove, and the cage bottom plate 7 is a square plate, so as to ensure that the cage bottom plate 7 does not rotate and interfere with the support plate 3 after being placed in the bottom groove 14.
[0035] As a preferred structure, the bottom groove 14 is provided with positioning posts 16, and the bottom plate 7 of the cage is provided with positioning holes 17 that cooperate with the positioning posts 16. When the collection cage 2 is placed into the bottom groove 14, it is positioned by the cooperation of the positioning posts 16 and the positioning holes 17. The end of the positioning posts 16 is tapered, which facilitates the guidance of the positioning posts 16 to cooperate with the positioning holes 17. There are two positioning posts 16 in this application.
[0036] As shown in the figure, the lifting and supporting mechanism includes a supporting motor 18, an upper supporting pulley 19, a lower supporting pulley 20, and a supporting belt 21 disposed on the upper supporting pulley 19 and the lower supporting pulley 20. A connecting seat 22 is fixed on the supporting belt 21, and the supporting plate 3 is fixed to the connecting seat 22. The supporting motor 18 is connected to the lower supporting pulley 20 through a shaft to drive it. Of course, the above-mentioned pulley transmission mechanism is a conventional structure, so the structure and installation structure of the pulley are not described in detail. The supporting motor 18, the upper supporting pulley 19, and the lower supporting pulley 20 are all mounted on the upright plate.
[0037] As shown in the figure, the connecting seat 22 includes a seat body 23 and a clamping plate 24. The support plate 3 is fixed to the seat body 23, and the supporting strap 21 is fixed to the seat body 23 through the clamping plate 24. The above structure is simple and easy to manufacture. In order to ensure that the connecting seat 22 is stable and does not shake, it also includes a linear guide rail and a slider. The seat body 23 is fixed to the slider, so that the connecting seat 22 can move accurately and stably in a straight line along the linear guide rail.
[0038] The above provides a detailed description of the sliding plate material box 5 collection structure of the crystal oscillator detection device provided by the embodiments of this utility model. Specific examples have been used to illustrate the principle and implementation of this utility model. The description of the above embodiments is only for the purpose of helping to understand the method and core idea of this utility model. At the same time, for those skilled in the art, there will be changes in the specific implementation and application scope based on the idea of this utility model. Therefore, the content of this specification should not be construed as a limitation of this utility model.
Claims
1. A sliding plate type material box collection structure for a crystal oscillator testing device, characterized in that: It includes a slide plate, a collection cage, a pallet, and a lifting and holding mechanism. The pallet is located in the collection cage and is connected to the lifting and holding mechanism so that it can be raised and lowered in the collection cage. The slide plate is inclined and the relatively lower side of the slide plate is located in the cage opening of the collection cage. The material box can slide along the slide plate into the collection cage and be located on the pallet.
2. The sliding plate type material box collection structure of the crystal oscillator testing device according to claim 1, characterized in that: The material collection cage has a side opening on one side, and the width of the pallet is smaller than the width of the side opening.
3. The sliding plate type material box collection structure of the crystal oscillator testing device according to claim 1, characterized in that: The material collection cage includes a bottom plate, several cage rods, and a body plate. The bottom plate and the body plate are fixed to the cage rods, thereby forming a cylindrical shape.
4. The sliding plate type material box collection structure of the crystal oscillator testing device according to claim 3, characterized in that: The cage body plate is provided with rod holes and locking screw holes that pass through the rod holes. The cage rod is located in the rod holes, and the locking screw cooperates with the locking screw hole to fix the cage body plate and the cage rod.
5. The sliding plate type material box collection structure of the crystal oscillator testing device according to claim 3, characterized in that: It also includes a base, which includes a seat plate and a vertical plate. The seat plate is provided with a bottom groove, and the bottom plate of the cage is located in the bottom groove.
6. The sliding plate type material box collection structure of the crystal oscillator testing device according to claim 5, characterized in that: The bottom groove is provided with a positioning post, and the bottom plate of the cage is provided with a positioning hole that cooperates with the positioning post.
7. The sliding plate type material box collection structure of the crystal oscillator testing device according to claim 3, characterized in that: Furthermore, the cage rods are four in number and arranged in a square, and the cage body plate is C-shaped.
8. The sliding plate type material box collection structure of the crystal oscillator testing device according to claim 1, characterized in that: The lifting and supporting mechanism includes a supporting motor, an upper supporting pulley, a lower supporting pulley, and a supporting belt disposed on the upper supporting pulley and the lower supporting pulley. A connecting seat is fixed on the supporting belt, and the support plate is fixed to the connecting seat.
9. The sliding plate type material box collection structure of the crystal oscillator testing device according to claim 8, characterized in that: The connecting seat includes a seat body and a clamping plate. The support plate is fixed to the seat body, and the support strap is fixed to the seat body through the clamping plate.
10. The sliding plate type material box collection structure of the crystal oscillator testing device according to claim 9, characterized in that: It also includes a linear guide rail and a slider, with the base and slider fixed together.