A thickness detection device for processing tempered hollow glass
By designing a tempered insulating glass thickness detection device with supporting and buffering components, the problems of poor fit between the detection device and the glass and lack of buffering were solved, achieving high-precision detection and device stability, protecting the glass and extending its service life.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- WUHAN XINERTE GLASS DECORATION CO LTD
- Filing Date
- 2025-05-29
- Publication Date
- 2026-06-23
AI Technical Summary
Existing tempered insulating glass thickness testing devices suffer from problems such as difficulty in achieving a tight fit between the testing pad and the glass surface during testing, lack of self-adjustment capability, and lack of effective buffer structure. This results in insufficient testing accuracy and device stability, and can easily damage both the glass and the device.
A thickness detection device including a support component, a pressing component, and a buffer component was designed. The device uses an electric screw to drive a lifting platform and a connecting column to achieve adaptive lifting of the detection pad. The buffer component absorbs the reaction force of the glass, protecting the glass and the device.
This achieves a tight fit between the testing pad and the glass surface, improving the accuracy and stability of the testing, protecting the glass and the equipment, extending its service life, and reducing production costs.
Smart Images

Figure CN224398610U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of glass processing and manufacturing technology, and in particular to a thickness detection device for tempered insulating glass processing. Background Technology
[0002] With the development of the construction and home decoration industries, the demand for tempered insulated glass is constantly increasing, and the quality requirements for glass are also getting higher and higher. As an important factor affecting its performance and quality, the thickness of glass requires precise testing equipment to ensure product quality.
[0003] However, in practical use, thickness detection devices with similar structures still have many shortcomings. For example, in traditional tempered insulating glass thickness detection devices, the existing thickness detection devices may not be able to ensure a tight fit between the detection pad and the glass surface due to unreasonable structure of the pressing component, or they may lack adaptive adjustment capabilities, which affects the accuracy of detection when detecting glass of different thicknesses. At the same time, existing thickness detection devices may not have a dedicated buffer structure, or the buffer structure may be incomplete. During the detection process, the impact force between the glass and the detection device can easily damage the glass and the device. Therefore, it is necessary to design a thickness detection device for tempered insulating glass processing. Utility Model Content
[0004] To solve the above-mentioned technical problems, this utility model provides a thickness detection device for tempered insulating glass processing.
[0005] This utility model is achieved using the following technical solution: a thickness detection device for tempered insulating glass processing, comprising a support assembly, the support assembly including a base plate, a bearing column and a guide rod fixedly installed on the top of the base plate, a placement plate fixedly installed on the top of the bearing column, and an electric screw fixedly installed inside the placement plate, further comprising:
[0006] The pressing assembly includes a lifting platform threadedly connected to the inside of an electric screw, a top plate mounted on the top of the lifting platform via a connecting column, and a detector fixedly mounted on the top of the top plate;
[0007] A buffer assembly, comprising a main connecting rod rotatably mounted on the bottom of a top plate, wherein a buffer plate is provided at the bottom of the main connecting rod.
[0008] As a further improvement to the above solution, a connecting column is fixedly installed on the top of the lifting platform, and a top plate is fixedly installed on the top of the connecting column.
[0009] By fixing the connecting column to the top of the lifting platform and the top plate to the top of the connecting column, the lifting motion of the lifting platform can be stably transmitted to the top plate, ensuring the smooth vertical movement of the top plate and the detectors and other components installed on it, thus providing a stable structural foundation for accurately detecting glass thickness.
[0010] As a further improvement to the above solution, a telescopic rod is fixedly connected to the bottom of the detector, a detection pad is fixedly connected to the bottom of the telescopic rod, a probe is fixedly connected inside the detection pad, and the probe is connected to the detector by a wire.
[0011] The above technical solution enables effective transmission of detection signals. At the same time, the telescopic rod can adapt to the slight displacement when the buffer plate contacts the glass, ensuring good contact between the probe and the glass surface, which helps to improve the accuracy and stability of the detection.
[0012] As a further improvement to the above solution, a buffer plate is fixedly connected to the outer surface of the detection pad, and a support base is fixedly installed on the top of the buffer plate.
[0013] Through the above technical solution, when the buffer plate is subjected to the reaction force of the glass, the force can be transmitted to the subsequent buffer structure through the support seat, thereby achieving effective buffering of the impact force and ensuring the stability of the detection pad.
[0014] As a further improvement to the above solution, a limiting frame is fixedly installed on the top of the support base, and two sliding seats are slidably installed inside the limiting frame. A main connecting rod is rotatably installed on the top of the outer surface of the sliding seats.
[0015] Through the above technical solution, the limiting frame provides precise guidance for the sliding of the sliding seat, ensuring accurate force transmission direction during the buffering process, enabling the main connecting rod to rotate according to design requirements, thereby realizing the effective buffering action of the buffer assembly and improving the stability and reliability of the entire device.
[0016] As a further improvement to the above solution, an auxiliary connecting rod is rotatably mounted on the bottom of the outer surface of the sliding seat, and the side of the auxiliary connecting rod away from the sliding seat is rotatably mounted on the top of the buffer plate.
[0017] The above technical solution enables the force on the buffer plate to be effectively transferred to the sliding seat through the auxiliary connecting rod during the buffering process, further dispersing the impact force, enhancing the buffering effect, and protecting the glass and the device.
[0018] As a further improvement to the above solution, mounting blocks are fixedly connected to the outer surfaces of the two sliding seats, and the outer surfaces of the two mounting blocks are fixedly connected by a damper.
[0019] Through the above technical solution, the damper can absorb and dissipate energy when the two sliding seats move relative to each other, playing a good buffering role, effectively preventing the device from being damaged by excessive impact force, and extending the service life of the device.
[0020] Compared with the prior art, the beneficial effects of this utility model are as follows:
[0021] This invention utilizes a pressing assembly consisting of an electric screw, a lifting platform, a connecting column, a top plate, a detector, a telescopic rod, and a detection pad to achieve contact between the detection pad and the glass surface. Driven by the electric screw, it adaptively adjusts its height according to the glass thickness, ensuring a tight fit between the detection pad and the glass surface. This provides a foundation for accurate detection and enables high-precision thickness detection of tempered insulated glass of varying thicknesses, improving the accuracy and reliability of the detection and guaranteeing product quality.
[0022] This invention utilizes a buffer assembly comprised of a main connecting rod, an auxiliary connecting rod, a sliding seat, a limiting frame, a support seat, and a damper. During the testing process, when the buffer plate contacts the glass, it effectively absorbs and buffers the reaction force of the glass on the testing device, making the testing process more stable and preventing damage to the glass and testing device due to excessive impact force. This not only protects the integrity of the glass and reduces the breakage rate during testing, but also extends the service life of the testing device and reduces production costs. Attached Figure Description
[0023] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0024] Figure 2 This is a schematic diagram of the support component structure of this utility model;
[0025] Figure 3 This is a schematic diagram of the internal structure of the buffer component of this utility model;
[0026] Figure 4 This utility model Figure 3 Enlarged schematic diagram of the structure at point A;
[0027] Figure 5 This utility model Figure 4 Enlarged schematic diagram of the structure at point B.
[0028] Explanation of key symbols:
[0029] 1. Support assembly; 101. Base plate; 102. Bearing column; 103. Guide rod; 104. Placement plate; 105. Electric screw; 2. Pressing assembly; 201. Lifting platform; 202. Connecting column; 203. Top plate; 204. Detector; 205. Lifting rod; 206. Detection pad; 3. Buffer assembly; 301. Main connecting rod; 302. Sliding seat; 303. Auxiliary connecting rod; 304. Buffer plate; 305. Support seat; 306. Limiting frame; 307. Mounting block; 308. Damper. Detailed Implementation
[0030] The present invention will be further described below with reference to the accompanying drawings and specific embodiments. It should be noted that, without conflict, the various embodiments or technical features described below can be arbitrarily combined to form new embodiments.
[0031] Example:
[0032] Please combine Figure 1-5 This embodiment of a thickness detection device for tempered insulating glass processing includes a support assembly 1. The support assembly 1 includes a base plate 101. A bearing column 102 and a guide rod 103 are fixedly installed on the top of the base plate 101. A placement plate 104 is fixedly installed on the top of the bearing column 102. An electric screw 105 is fixedly installed inside the placement plate 104. The device also includes:
[0033] The pressing assembly 2 includes a lifting platform 201 threadedly connected to the electric screw 105. A top plate 203 is installed on the top of the lifting platform 201 through a connecting column 202. A detector 204 is fixedly installed on the top of the top plate 203.
[0034] The buffer assembly 3 includes a main connecting rod 301 rotatably mounted on the bottom of the top plate 203, and a buffer plate 304 is provided at the bottom of the main connecting rod 301.
[0035] A connecting column 202 is fixedly installed on the top of the lifting platform 201, and a top plate 203 is fixedly installed on the top of the connecting column 202.
[0036] A telescopic rod 205 is fixedly connected to the bottom of the detector 204, and a detection pad 206 is fixedly connected to the bottom of the telescopic rod 205. A probe is fixedly connected inside the detection pad 206, and the probe is connected to the detector 204 by a wire.
[0037] The probe and detector 204 are connected by wires. After the buffer plate 304 contacts the glass and the buffer assembly functions stably, the detector 204 sends a signal to the probe through the wires. The probe contacts the glass surface and measures relevant data. Through the principle of ultrasonic reflection, the measured data is fed back to the detector 204 through the wires.
[0038] A buffer plate 304 is fixedly connected to the outer surface of the detection pad 206, and a support base 305 is fixedly installed on the top of the buffer plate 304.
[0039] A limiting frame 306 is fixedly installed on the top of the support base 305. Two sliding seats 302 are slidably installed inside the limiting frame 306. A main connecting rod 301 is rotatably installed on the top of the outer surface of the sliding seat 302.
[0040] An auxiliary connecting rod 303 is rotatably mounted on the bottom of the outer surface of the sliding seat 302, and the side of the auxiliary connecting rod 303 away from the sliding seat 302 is rotatably mounted on the top of the buffer plate 304.
[0041] As a further improvement to the above scheme, mounting blocks 307 are fixedly connected to the outer surfaces of the two sliding seats 302, and the outer surfaces of the two mounting blocks 307 are fixedly connected by dampers 308.
[0042] Since the auxiliary connecting rods 303 on both sides of the top of the buffer plate 304 are rotatably mounted on the outer surface of the sliding seat 302, the two sliding seats 302 will move closer to each other. The mounting blocks 307 on the outer surface of the two sliding seats 302 are connected by a damper 308. The damper 308 can absorb and buffer the energy in this process, thereby protecting the glass and the device.
[0043] The implementation principle of the thickness detection device for tempered insulating glass processing in this application embodiment is as follows: the base plate 101 serves as the foundation of the entire detection device, providing stable support for the device. The bearing column 102 and the guide rod 103 are vertically fixed to the top of the base plate 101. The top of the bearing column 102 is fixedly installed with a placement plate 104, which is a platform for placing the tempered insulating glass to be tested. The electric screw 105 fixedly installed inside the placement plate 104 is the power source for the lifting action during the entire testing process.
[0044] The motor inside the electric screw 105 drives the lead screw to rotate. Since the lifting platform 201 is threadedly connected to the electric screw 105, and the lifting platform 201 can only move vertically under the limit of the guide rod 103 and the bearing column 102, the top of the lifting platform 201 is fixedly installed with the top plate 203 through the connecting column 202. The detector 204 on the top of the top plate 203 will move with the lifting platform 201. The telescopic rod 205 is mainly used to connect the top plate 203 and the buffer plate 304, and plays the role of transmitting force and maintaining the structural connection.
[0045] When thickness testing is required, the glass is placed on the surface of the placement plate 104, and then the electric screw 105 drives the lifting platform 201 to descend. During this process, the buffer plate 304 will gradually approach the glass. When the buffer plate 304 contacts the glass, the buffer plate 304 will start to move upward due to the upward reaction force of the glass on the buffer plate 304. At this time, the auxiliary connecting rods 303 connected to the top two sides of the buffer plate 304 will push the sliding seat 302 to slide inside the limit frame 306. Since the auxiliary connecting rods 303 on the top two sides of the buffer plate 304 are rotatably installed on the outer surface of the sliding seat 302, the two sliding seats 302 will move closer to each other. The mounting blocks 307 on the outer surface of the two sliding seats 302 are connected by a damper 308. The damper 308 can absorb and buffer the energy in this process, thereby protecting the glass and the device.
[0046] A probe is fixedly connected inside the detection pad 206. The probe is connected to the detector 204 by a wire. After the buffer plate 304 contacts the glass and the buffer assembly functions stably, the detector 204 sends a signal to the probe through the wire. The probe contacts the glass surface and measures relevant data. Through the principle of ultrasonic reflection, the measured data is fed back to the detector 204 through the wire. The detector 204 calculates the thickness of the glass based on these data, thereby realizing the detection of the thickness of tempered insulated glass.
[0047] It should be noted that the detector 204 can be an ultrasonic thickness gauge from the Beijing Times brand, model number "TT100 / 130".
[0048] The above embodiments are merely preferred embodiments of this utility model and should not be construed as limiting the scope of protection of this utility model. Any non-substantial changes and substitutions made by those skilled in the art based on this utility model shall fall within the scope of protection claimed by this utility model.
Claims
1. A thickness detection device for tempered insulating glass processing, comprising a support assembly (1), the support assembly (1) comprising a base plate (101), a bearing column (102) and a guide rod (103) fixedly installed on the top of the base plate (101), a placement plate (104) fixedly installed on the top of the bearing column (102), and an electric screw (105) fixedly installed inside the placement plate (104), characterized in that, Also includes: The pressing assembly (2) includes a lifting platform (201) threadedly connected to the inside of an electric screw (105). A top plate (203) is installed on the top of the lifting platform (201) through a connecting column (202). A detector (204) is fixedly installed on the top of the top plate (203). The buffer assembly (3) includes a main connecting rod (301) rotatably mounted on the bottom of the top plate (203), and a buffer plate (304) is provided at the bottom of the main connecting rod (301).
2. The thickness detection device for tempered insulating glass processing as described in claim 1, characterized in that: A connecting column (202) is fixedly installed on the top of the lifting platform (201), and a top plate (203) is fixedly installed on the top of the connecting column (202).
3. The thickness detection device for tempered insulating glass processing as described in claim 1, characterized in that: The bottom of the detector (204) is fixedly connected to a telescopic rod (205), the bottom of the telescopic rod (205) is fixedly connected to a detection pad (206), a probe is fixedly connected inside the detection pad (206), and the probe is connected to the detector (204) by a wire.
4. The thickness detection device for tempered insulating glass processing as described in claim 3, characterized in that: A buffer plate (304) is fixedly connected to the outer surface of the detection pad (206), and a support base (305) is fixedly installed on the top of the buffer plate (304).
5. The thickness detection device for tempered insulating glass processing as described in claim 4, characterized in that: A limiting frame (306) is fixedly installed on the top of the support base (305). Two sliding seats (302) are slidably installed inside the limiting frame (306). A main connecting rod (301) is rotatably installed on the top of the outer surface of the sliding seat (302).
6. The thickness detection device for tempered insulating glass processing as described in claim 5, characterized in that: An auxiliary connecting rod (303) is rotatably mounted on the bottom of the outer surface of the sliding seat (302), and the side of the auxiliary connecting rod (303) away from the sliding seat (302) is rotatably mounted on the top of the buffer plate (304).
7. The thickness detection device for tempered insulating glass processing as described in claim 6, characterized in that: Mounting blocks (307) are fixedly connected to the outer surfaces of the two sliding seats (302), and the outer surfaces of the two mounting blocks (307) are fixedly connected by dampers (308).