An optical detection device for organic optoelectronic materials
By designing an optical inspection device with a protective cover, moving components, and positioning components, the problem of contamination in open spaces for optical inspection equipment of organic optoelectronic materials has been solved, achieving high-precision inspection and extended equipment life.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- NANJING ZHIYAN TECH CO LTD
- Filing Date
- 2025-08-07
- Publication Date
- 2026-07-07
AI Technical Summary
Optical inspection equipment for organic optoelectronic materials is susceptible to contamination from dust, particulate matter, and moisture in open spaces, which can affect the accuracy and lifespan of the inspection equipment.
An optical detection device including a detection unit and an adjustment unit was designed. By using a protective cover, a moving component, and a positioning component, the optical detection device can be protected and flexibly adjusted to prevent contaminants from entering and enhance the ease of operation and stability.
It effectively prevents dust and foreign objects from entering, improves detection accuracy, extends service life, enhances operational convenience and flexibility, and ensures the stability of the detection process.
Smart Images

Figure CN224471535U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of optical detection, specifically an optical detection device for organic optoelectronic materials. Background Technology
[0002] Optical detection of organic optoelectronic materials is a key step in studying their optoelectronic properties and exploring their application potential. In the research of organic optoelectronic materials, optical detection equipment is the core tool for exploring their optoelectronic characteristics, optimizing material performance, and promoting application development. Through multi-dimensional data acquisition and in-depth analysis, it provides a solid experimental foundation for the rational design and performance optimization of organic optoelectronic materials.
[0003] In laboratory or production environments, optical inspection equipment is exposed to open spaces for extended periods when not in operation, making it susceptible to contamination from dust, particulate matter, moisture, and volatile organic solvents. These impurities not only affect the cleanliness of the equipment but may also contaminate optical components, affecting their normal use and causing unnecessary losses.
[0004] In summary, this invention provides an optical detection device for organic optoelectronic materials to solve the above-mentioned problems. Utility Model Content
[0005] To solve the above-mentioned technical problems, this utility model provides the following technical solution:
[0006] An optical detection device for organic optoelectronic materials, comprising,
[0007] The detection unit includes an optical detection device body, a fixed frame fixedly connected to the top of the optical detection device body, a protective cover slidably connected to both sides of the top of the fixed frame, and a movable component disposed on the front of the protective cover.
[0008] The adjustment unit includes a fixing tube fixedly connected to the front and back of the fixing frame, a limiting rod slidably connected to the inner cavity of the fixing tube, a fixing frame fixedly connected to both sides of the front and back of the protective cover, and a positioning component disposed on the front of the protective cover.
[0009] Furthermore, in this utility model, the movable component includes a receiving groove formed on the front of the protective cover, a push plate slidably connected to the inner cavity of the receiving groove, and a movable plate fixedly connected to one side of the push plate. The side of the movable plate away from the push plate passes through the protective cover and is slidably connected to its inner cavity.
[0010] Furthermore, in this utility model, the front and back of the fixing tube are provided with through grooves, and the fixing frame is divided into a solid state and a hollow state. The solid fixing frame is fixedly connected to one end of the limiting rod, and the hollow fixing frame is slidably connected to the surface of the fixing tube. The connecting block fixedly connected to its inner cavity extends to the inner cavity of the fixing tube through the through groove and is fixedly connected to one end of the limiting rod.
[0011] Furthermore, in this utility model, the positioning component includes movable grooves formed at the top and bottom of the push plate, a locking block slidably connected to the inner cavity of the movable groove, and a locking slot formed at the top and bottom of the inner cavity of the receiving groove on the front of the protective cover. One end of the locking block extends into the inner cavity of the locking slot and engages with its inner cavity.
[0012] Furthermore, in this utility model, the positioning component also includes a stainless steel spring fixedly connected to one side of the locking block, the end of the stainless steel spring away from the locking block being fixedly connected to the inner wall of the movable groove, and a pushing block disposed at the upper and lower ends of the front of the pushing plate, the rear end of the pushing block penetrating into the inner cavity of the movable groove and being fixedly connected to the locking block.
[0013] Beneficial effects: This utility model has the following beneficial effects:
[0014] The optical inspection device body of this utility model serves as the core inspection component, undertaking the task of collecting and analyzing the optical performance parameters of organic optoelectronic materials. It is the basic carrier for realizing the optical inspection function. The protective cover protects the optical inspection device body, preventing dust, foreign objects, etc. from entering the device and affecting the inspection accuracy. At the same time, its position can be flexibly adjusted according to the inspection needs. For example, it can cover the device body when inspection is not needed and remove it when inspection is needed, thereby improving the protective performance of the device and extending its service life. Its mobility enhances the ease of operation and flexibility of the device. The moving component provides the operator with a space to operate when the protective cover does not need to be completely removed, and the positioning component is used to position the moving component. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the main structure of this utility model;
[0016] Figure 2 This is a schematic diagram of the main structure of the protective cover of this utility model;
[0017] Figure 3 This is a schematic diagram of the main structure of this utility model;
[0018] Figure 4 This is a partial side view cross-sectional structural diagram of the push plate of this utility model.
[0019] In the picture:
[0020] 1. Detection unit; 101. Optical detection device body; 102. Fixing frame; 103. Protective cover; 104. Moving component; 1041. Push plate; 1042. Movable plate; 2. Adjustment unit; 201. Fixing tube; 202. Limiting rod; 203. Fixing frame; 204. Positioning component; 2041. Movable groove; 2042. Locking block; 2043. Locking slot; 2044. Stainless steel spring. Detailed Implementation
[0021] To better understand the technical content of this utility model, specific embodiments are described below in conjunction with the accompanying drawings. Various aspects of this utility model are described in this disclosure with reference to the accompanying drawings, which illustrate numerous illustrative embodiments. The embodiments of this disclosure are not necessarily defined to include all aspects of this utility model. It should be understood that the various concepts and embodiments described above, as well as those described in more detail below, can be implemented in any of many ways, because the concepts and embodiments disclosed in this utility model are not limited to any particular implementation. Furthermore, some aspects of this utility model can be used alone or in any suitable combination with other aspects disclosed in this utility model.
[0022] Example 1
[0023] like Figure 1-4 As shown, this is the first embodiment of the present invention. This embodiment provides an optical detection device for organic optoelectronic materials, including...
[0024] The detection unit 1 includes an optical detection device body 101, a fixed frame 102 fixedly connected to the top of the optical detection device body 101, a protective cover 103 slidably connected to both sides of the top of the fixed frame 102, and a moving component 104 disposed on the front of the protective cover 103.
[0025] The adjustment unit 2 includes a fixing tube 201 fixedly connected to the front and back of the fixing frame 102, a limiting rod 202 slidably connected to the inner cavity of the fixing tube 201, a fixing bracket 203 fixedly connected to both sides of the front and back of the protective cover 103, and a positioning component 204 disposed on the front of the protective cover 103.
[0026] like Figure 1-4As shown, the optical detection device body 101, as the core detection component, undertakes the acquisition and analysis of optical performance parameters of organic optoelectronic materials and is the basic carrier for realizing the optical detection function. The fixed frame 102 provides a stable installation platform for the protective cover 103, and works in conjunction with components such as the fixed tube 201 in the adjustment unit 2 to construct a stable frame structure for the entire detection device, ensuring that the positions of each component are relatively fixed and can operate normally. The protective cover 103 is used to protect the optical detection device body 101, preventing dust, foreign objects, etc. from entering the device and affecting the detection accuracy. At the same time, its position can be flexibly adjusted according to the detection needs. For example, it can cover the device body when detection is not needed and remove it when detection is needed, improving the protective performance of the device and extending its service life. Its mobility enhances the ease of operation and flexibility of the device. The moving component 104 provides operating space for the operator when the protective cover 103 does not need to be removed as a whole. The fixed tube 201 provides sliding space for the limiting rod 202. The track, in conjunction with the movement of the limiting rod 202, adjusts the position of the protective cover 103. Through slots on its front and back provide a channel for the movement of the connecting block, enabling the entire adjustment system to function normally. The limiting rod 202, connected to the fixing frame 203, limits and guides the movement of the protective cover 103, ensuring it moves along a predetermined trajectory and preventing deviation or wobbling. The solid fixing frame 203 is fixedly connected to one end of the limiting rod 202, connecting the protective cover 103 and the limiting rod 202 into a single unit, allowing the protective cover 103 to move with the limiting rod 202. The hollow fixing frame 203 slides on the surface of the fixing tube 201, and its inner cavity connecting block is fixedly connected to one end of the limiting rod 202 through a through slot, further enhancing the connection strength and stability between the protective cover 103 and the adjustment unit 2, ensuring the protective cover 103 remains stable during movement. The positioning component 204 is used to position the moving component 104.
[0027] Example 2
[0028] Reference Figure 2 and 3 This is the second embodiment of the present invention, which is based on the previous embodiment.
[0029] In this embodiment, the moving component 104 includes a receiving groove formed on the front of the protective cover 103, a push plate 1041 slidably connected to the inner cavity of the receiving groove, and a movable plate 1042 fixedly connected to one side of the push plate 1041. The side of the movable plate 1042 away from the push plate 1041 passes through the protective cover 103 and is slidably connected to its inner cavity.
[0030] The front and back of the fixing tube 201 are provided with through grooves. The fixing frame 203 is divided into a solid state and a hollow state. The solid fixing frame 203 is fixedly connected to one end of the limiting rod 202. The hollow fixing frame 203 is slidably connected to the surface of the fixing tube 201, and the connecting block fixedly connected to its inner cavity extends through the through groove to the inner cavity of the fixing tube 201 and is fixedly connected to one end of the limiting rod 202.
[0031] like Figure 2 and 3 As shown, the push plate 1041 facilitates the movement of the movable plate 1042, providing additional operating space for the protective cover 103, allowing workers to perform inspection work without removing the protective cover 103. The solid fixed frame 203 is fixedly connected to one end of the limiting rod 202, connecting the protective cover 103 and the limiting rod 202 into a whole, allowing the protective cover 103 to move with the movement of the limiting rod 202. The hollow fixed frame 203 is slidably connected to the surface of the fixed tube 201, and its inner cavity connecting block is fixedly connected to one end of the limiting rod 202 through a through groove, further enhancing the connection strength and stability between the protective cover 103 and the adjustment unit 2, ensuring that the protective cover 103 remains stable during movement.
[0032] Example 3
[0033] Reference Figure 4 This is the third embodiment of the present invention, which is based on the first two embodiments.
[0034] In this embodiment, the positioning component 204 includes a movable groove 2041 formed at the top and bottom of the push plate 1041, a locking block 2042 slidably connected to the inner cavity of the movable groove 2041, and a locking slot 2043 formed at the top and bottom of the inner cavity of the receiving groove on the front of the protective cover 103. One end of the locking block 2042 extends into the inner cavity of the locking slot 2043 and engages with its inner cavity.
[0035] The positioning component 204 also includes a stainless steel spring 2044 fixedly connected to one side of the locking block 2042. The end of the stainless steel spring 2044 away from the locking block 2042 is fixedly connected to the inner wall of the movable groove 2041. It also includes a push block disposed at the upper and lower ends of the front of the push plate 1041. The rear end of the push block extends through the inner cavity of the movable groove 2041 and is fixedly connected to the locking block 2042.
[0036] like Figure 4As shown, when the push plate 1041 is pushed to seal the protective cover 103, the locking block 2042, under the action of the stainless steel spring 2044, extends one end into the inner cavity of the slot 2043 and engages with it, thereby fixing the position of the protective cover 103 and preventing it from moving accidentally during the testing process, ensuring the stability of the testing process. Through the push blocks set at the upper and lower ends of the front of the push plate 1041, the user can easily control the movement of the locking block 2042, thereby releasing the locking state between the locking block 2042 and the slot 2043, allowing the push plate 1041 to move and adjust its position.
[0037] In use, the optical detection device body 101 can utilize optical principles to detect the properties of materials by analyzing optical phenomena such as reflection, transmission, and scattering of organic optoelectronic materials. Both the protective cover 103 and the push plate 1041 are made of light-transmitting materials. In the idle state, the two protective covers 103 are close to each other and combined to form a sealed frame to protect the top of the optical detection device body 101. When needed, the protective cover 103 can be moved from the top of the optical detection device body 101 to the sides by pushing it, leaving an operating space for the operator. At the same time, if the required operating space is too small, the operating space can also be freed up by moving the moving component 104. In this case, the push block is moved first, and the push block drives the locking block 2042 to move into the inside of the movable slot 2041 until the locking block 2042 moves out of the inside of the slot 2043. At this time, the positioning effect of the push plate 1041 disappears, and the operating space can be left for the operator by pushing the push plate 1041.
[0038] All standard parts used in this application can be purchased from the market, and can be customized according to the description and drawings. The specific connection methods of each part adopt conventional methods such as bolts, rivets, and welding that are mature in the prior art. The machinery, parts and equipment adopt conventional models in the prior art. The control method is automatic control through a controller. The control circuit of the controller can be implemented by simple programming by those skilled in the art and is common knowledge in the field. Since this application is mainly used to protect mechanical devices, the control method and circuit connection will not be explained in detail in this application.
[0039] Although the present invention has been disclosed above with reference to preferred embodiments, it is not intended to limit the present invention. Those skilled in the art to which this invention pertains can make various modifications and refinements without departing from the spirit and scope of the present invention. Therefore, the scope of protection of this invention shall be determined by the claims.
Claims
1. An optical detection device for organic optoelectronic materials, characterized in that: include, The detection unit (1) includes an optical detection device body (101), a fixed frame (102) fixedly connected to the top of the optical detection device body (101), a protective cover (103) slidably connected to both sides of the top of the fixed frame (102), and a moving component (104) disposed on the front of the protective cover (103). The adjustment unit (2) includes a fixing tube (201) fixedly connected to the front and back of the fixing frame (102), a limiting rod (202) slidably connected to the inner cavity of the fixing tube (201), a fixing bracket (203) fixedly connected to both sides of the front and back of the protective cover (103), and a positioning component (204) disposed on the front of the protective cover (103).
2. The optical detection device for organic optoelectronic materials as described in claim 1, characterized in that: The movable component (104) includes a receiving groove formed on the front of the protective cover (103), a push plate (1041) slidably connected to the inner cavity of the receiving groove, and a movable plate (1042) fixedly connected to one side of the push plate (1041). The side of the movable plate (1042) away from the push plate (1041) passes through the protective cover (103) and is slidably connected to its inner cavity.
3. The optical detection device for organic optoelectronic materials as described in claim 1, characterized in that: The front and back of the fixing tube (201) are provided with through grooves. The fixing frame (203) is divided into a solid state and a hollow state. The solid fixing frame (203) is fixedly connected to one end of the limiting rod (202). The hollow fixing frame (203) is slidably connected to the surface of the fixing tube (201), and the connecting block fixedly connected to its inner cavity extends through the through groove to the inner cavity of the fixing tube (201) and is fixedly connected to one end of the limiting rod (202).
4. The optical detection device for organic optoelectronic materials as described in claim 2, characterized in that: The positioning component (204) includes a movable groove (2041) formed at the top and bottom of the push plate (1041), a locking block (2042) slidably connected to the inner cavity of the movable groove (2041), and a locking groove (2043) formed at the top and bottom of the inner cavity of the receiving groove on the front of the protective cover (103). One end of the locking block (2042) extends into the inner cavity of the locking groove (2043) and engages with its inner cavity.
5. The optical detection device for organic optoelectronic materials as described in claim 4, characterized in that: The positioning component (204) also includes a stainless steel spring (2044) fixedly connected to one side of the locking block (2042), the end of the stainless steel spring (2044) away from the locking block (2042) being fixedly connected to the inner wall of the movable groove (2041), and a pushing block disposed at the upper and lower ends of the front of the pushing plate (1041), the rear end of the pushing block penetrating into the inner cavity of the movable groove (2041) and fixedly connected to the locking block (2042).