Glass pressure plate structure
By designing an adjustable glass pressure plate structure, the problem of existing technologies being unable to adapt to different glass thicknesses is solved, achieving a stable connection between the glass and the keel, and improving the stability and reliability of the installation.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- WULIN CONSTR ENG
- Filing Date
- 2025-07-22
- Publication Date
- 2026-07-03
AI Technical Summary
The existing glass pressure plate structure cannot adapt to glass of different thicknesses, resulting in ineffective contact and affecting the sealing and structural stability of the installation.
A glass pressure plate structure was designed, comprising a base plate, a square protrusion, an abutment block, an adjustment plate, and a spring. The adjustment mechanism enables the abutment block to fit tightly against the glass, and the spring force provides stable pressure.
It enables flexible adjustment based on glass thickness, ensuring a stable connection between the glass and the keel, improving the stability and reliability of installation, and avoiding glass displacement caused by environmental factors.
Smart Images

Figure CN224452620U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to a glass pressure plate structure and belongs to the field of pressure plate technology. Background Technology
[0002] After the glass is installed and the sealant is applied, a glass clamp must be installed on the outside of the keel before the sealant dries. The glass clamp presses the glass against the keel, thereby fixing the glass to the keel. This operation effectively prevents the glass from shifting or falling off due to external forces such as wind loads and vibrations before the sealant is completely dry, thus ensuring the stability of the installation structure and providing reliable temporary support for the subsequent sealant curing process, ensuring the safety and firmness of the glass installation project. For example, Chinese utility model patent CN207728241U discloses a glass fastening assembly with a sealing function, specifically disclosing a fastening assembly body disposed between an aluminum frame, a wooden frame, and glass. The fastening assembly body includes a buckle and a glass pressure plate. The buckle is located at the upper end of the glass pressure plate and extends into the buckle cavity of the aluminum frame. One end of the glass pressure plate is located between the aluminum frame and the wooden frame, and the other end is located between the aluminum frame and the glass. A serrated groove is provided at the bottom of the glass pressure plate, located between the wooden frame and the glass, and a sealing strip is provided within the serrated groove. A connecting groove is provided at the upper end of the buckle, through which screws fix the fastening assembly body to the wooden frame. A gasket is provided between the glass pressure plate and the glass, and a protrusion is provided at the contact position between the glass pressure plate and the aluminum frame. At least one buckle is provided. In this assembly structure, a glass pressure plate is used to achieve the pressing and fixing of the glass. However, it should be noted that this type of pressure plate is a fixed-specification design and is only suitable for glass of a specific thickness. In practical applications, if the glass thickness does not exceed the outer end face of the wooden frame, the glass pressure plate and the glass surface will not form an effective contact. In this case, the pressure plate will be unable to exert its clamping effect, thereby affecting the sealing and structural stability of the component installation. Utility Model Content
[0003] The purpose of this invention is to provide a glass pressure plate structure. This invention can be flexibly adjusted according to the glass thickness to ensure effective contact with the outer end face of the glass. It has a simple structure and is easy to use.
[0004] The technical solution of this utility model is as follows: a glass pressure plate structure, including a base plate, with square protrusions on the upper and lower front sides of the base plate, each square protrusion having a groove, and an abutment block slidably connected within the groove, the outer end of the abutment block protruding from the groove and facing forward; an adjusting plate is provided between the inner end of the abutment block and the inner wall of the groove, and multiple springs are connected between the adjusting plate and the abutment block; multiple adjusting mechanisms are provided between the base plate and the adjusting plate; and connecting strips are symmetrically arranged on the front side of the middle of the base plate.
[0005] In the aforementioned glass pressure plate structure, the adjustment mechanism includes a bolt rotatably connected to the base plate and a first threaded hole disposed on the adjustment plate; the threaded end of the bolt passes into the sliding groove; the threaded end of the bolt engages with the first threaded hole.
[0006] In the aforementioned glass pressure plate structure, the base plate is provided with a plurality of first mounting holes; the bolt is disposed in the first mounting hole; the side of the first mounting hole is provided with a side ring groove; the upper end of the bolt is provided with a convex ring, which cooperates with the side ring groove.
[0007] In the aforementioned glass pressure plate structure, the top of the bolt is provided with a cross groove.
[0008] In the aforementioned glass pressure plate structure, the connecting strip includes a vertical strip, which is elastic; a semi-circular protrusion is provided on the inner side of the outer end of the vertical strip.
[0009] In the aforementioned glass pressure plate structure, the base plate has multiple second mounting holes linearly distributed in the middle.
[0010] In the aforementioned glass pressure plate structure, the cross-section of the contact block is T-shaped.
[0011] In the aforementioned glass pressure plate structure, the base plate and the square protrusion are integrally connected; both the base plate and the square protrusion are made of aluminum alloy.
[0012] Compared with existing technologies, this utility model has the following advantages: During installation, the glass is first connected to the keel, and adhesive is applied to the edges of the glass. Then, the utility model is fixed to the keel using connecting strips, with the outer end face of the contact block facing the glass. The adjustment mechanism is operated to move the adjustment plate towards the contact block, reducing the distance between them. The spring is compressed, generating elastic force that pushes the contact block closer to the glass until it contacts the outer end face. Finally, the adjustment mechanism is used again to finely adjust the distance between the adjustment plate and the contact block, maintaining appropriate spring force, thus ensuring the contact block tightly adheres to the outer end face of the glass. This continuously provides stable pressure to the glass towards the keel, ensuring the stability and reliability of the glass installation. Attached Figure Description
[0013] Figure 1 This is a schematic diagram of the structure of this utility model;
[0014] Figure 2 This is an installation diagram of this utility model.
[0015] The markings in the attached diagram are as follows: 1-base plate, 2-square protrusion, 3-slide groove, 4-abutting block, 5-adjusting plate, 6-spring, 7-adjusting mechanism, 8-connecting strip, 9-second mounting hole, 10-glass, 11-keel, 70-bolt, 71-first threaded hole, 72-first mounting hole, 73-side ring groove, 74-protruding ring, 75-cross groove, 80-vertical strip, 81-semi-circular protrusion. Detailed Implementation
[0016] The present invention will be further described below with reference to the accompanying drawings and embodiments, but this should not be construed as limiting the present invention.
[0017] Example: Glass pressure plate structure, configured as follows Figure 1-2 As shown, the device includes a base plate 1, with square protrusions 2 on the upper and lower front sides of the base plate 1, and the base plate 1 and square protrusions 2 are integrally connected; both the base plate 1 and the square protrusions are made of aluminum alloy; the square protrusions 2 have a groove 3, and an abutment block 4 is slidably connected in the groove 3, with the outer end of the abutment block 4 protruding from the groove 3 and facing forward, and the cross-section of the abutment block 4 is T-shaped; an adjusting plate 5 is provided between the inner end of the abutment block 4 and the inner wall of the groove 3, and multiple springs 6 are connected between the adjusting plate 5 and the abutment block 4. When the adjusting plate 5 moves, the springs 6 are compressed to generate elastic force, which can push the abutment block 4 gradually closer to the glass 10. By utilizing the elastic buffering effect of the springs 6, it can ensure that the abutment block 4 is in close contact with the glass 10, and avoid damage to the glass 10 due to excessive pressure; multiple adjusting mechanisms 7 are provided between the base plate 1 and the adjusting plate 5; and connecting strips 8 are symmetrically arranged on the front side of the middle part of the base plate 1. The base plate 1 is connected to the keel 11 via the connecting strip 8, with the outer end face of the contact block 4 facing the glass 10. The adjustment mechanism 7 is operated to move the adjustment plate 5 towards the contact block 4, reducing the distance between them. At this point, the spring 6 is compressed, generating elastic force that pushes the contact block 4 closer to the glass 10 until it contacts the outer end face of the glass 10. Finally, the adjustment mechanism 7 is used again to finely adjust the distance between the adjustment plate 5 and the contact block 4, maintaining appropriate elastic force on the spring 6. This ensures that the contact block 4 fits tightly against the outer end face of the glass 10, continuously providing stable pressure to the glass 10 towards the keel 11, guaranteeing the stability and reliability of the glass 10 installation.
[0018] Preferably, such as Figure 1 and Figure 2As shown, the adjusting mechanism 7 includes a bolt 70 rotatably connected to the base plate 1 and a first threaded hole 71 provided on the adjusting plate 5; the threaded end of the bolt 70 passes into the sliding groove 3; the threaded end of the bolt 70 meshes with the first threaded hole 71. Because the threaded end of the bolt 70 is screwed into the first threaded hole 71, and because the sliding groove 3 restricts the adjusting plate 5 to only move up and down, when the bolt 70 is rotated, the adjusting plate 5 will move up and down according to the change of the helix angle. The base plate 1 is provided with multiple first mounting holes 72; the bolt 70 is set in the first mounting hole 72; the side of the first mounting hole 72 is provided with a side ring groove 73; the upper end of the bolt 70 is provided with a convex ring 74. Through the cooperation of the convex ring 74 and the side ring groove 73, the bolt 70 can rotate flexibly in the first mounting hole 72 without axial movement, ensuring the stability and accuracy of the adjustment process. The top of the bolt 70 is provided with a cross groove 75, which makes it easy for workers to rotate the bolt 70 with a Phillips screwdriver. Furthermore, the inner end of the abutment block 4 is provided with a plurality of anti-collision holes, which correspond to the threaded end of the bolt 70 and have a diameter larger than that of the threaded end of the bolt 70, so as to prevent the abutment block 4 from interfering with or colliding with the bolt 70 during movement.
[0019] Preferably, such as Figure 2 As shown, the connecting strip 8 includes a vertical strip 80, which is elastic; a semi-circular protrusion 81 is provided on the inner side of the outer end of the vertical strip 80. The keel 11 is provided with an arc groove corresponding to the semi-circular protrusion 81. The semi-circular protrusion 81 is inserted into the arc groove, and a tight snap-fit connection structure is formed by the cooperation between the arc surfaces. This connection method is not only convenient to install, but also has good positioning and anti-detachment effects, which can ensure the stability of the connection between the base plate 1 and the keel 11.
[0020] Preferably, such as Figure 1 and Figure 2 As shown, the base plate 1 has multiple second mounting holes 9 linearly distributed in the middle. The keel 11 is provided with second threaded holes corresponding to the second mounting holes 9. After the base plate 1 is connected to the keel 11 through the connecting strip 8, the bolt 70 is passed through the second mounting holes 9 and screwed into the second threaded holes to strengthen the connection between the base plate 1 and the keel 11.
[0021] Working principle:
[0022] First, the base plate 1 is connected to the keel 11 via the connecting strip 8. The semi-circular protrusion 81 on the connecting strip 8 engages with the arc groove on the keel 11 to initially position the base plate 1 and the keel 11. At the same time, the second mounting hole 9 in the middle of the base plate 1 and the corresponding second threaded hole on the keel 11 are tightened with bolts 70 to further strengthen the connection and ensure that the base plate 1 is firmly installed on the keel 11. At this time, the outer end face of the contact block 4 faces the glass 10.
[0023] Next, the adjusting mechanism 7 is operated. The bolt 70 in the adjusting mechanism 7 engages with the first threaded hole 71 on the adjusting plate 5. Since the sliding groove 3 restricts the adjusting plate 5 to move only up and down, when the bolt 70 is rotated, the rotation of the bolt 70 is converted into the lifting and lowering movement of the adjusting plate 5, causing the adjusting plate 5 to move towards the abutment block 4. As the adjusting plate 5 approaches the abutment block 4, the distance between the two decreases, and the spring 6 between the adjusting plate 5 and the abutment block 4 is compressed. The spring 6 generates elastic force after being compressed, which pushes the abutment block 4 gradually closer to the glass 10 until the abutment block 4 abuts against the outer end face of the glass 10.
[0024] Finally, the adjusting mechanism 7 is finely adjusted again by rotating the bolt 70 to change the distance between the adjusting plate 5 and the abutment block 4, controlling the compression degree of the spring 6 and maintaining the appropriate elastic force of the spring 6. At this time, the abutment block 4 is tightly attached to the outer end face of the glass 10 under the action of the spring force of the spring 6, continuously providing the glass 10 with a stable pressure in the direction of the keel 11, firmly fixing the glass 10 to the keel 11, ensuring the stability and reliability of the installation of the glass 10, and at the same time, using the elasticity of the vertical bar 80 of the connecting strip 8 to buffer the displacement of the glass 10 caused by environmental factors and avoid rigid collisions.
Claims
1. A glass platen structure, characterized by: The base plate (1) has square protrusions (2) on the front of the upper and lower sides respectively. The square protrusions (2) have grooves (3) inside. Abutment blocks (4) are slidably connected in the grooves (3). The outer end of the abutment blocks (4) protrudes from the grooves (3) and faces forward. An adjustment plate (5) is provided between the inner end of the abutment blocks (4) and the inner wall of the grooves (3). Multiple springs (6) are connected between the adjustment plate (5) and the abutment blocks (4). Multiple adjustment mechanisms (7) are provided between the base plate (1) and the adjustment plate (5). Connecting strips (8) are symmetrically arranged on the front of the middle part of the base plate (1).
2. The glass press plate structure of claim 1, wherein: The adjustment mechanism (7) includes a bolt (70) rotatably connected to the base plate (1) and a first threaded hole (71) provided on the adjustment plate (5); the threaded end of the bolt (70) passes into the slide groove (3); the threaded end of the bolt (70) meshes with the first threaded hole (71).
3. The glass press plate structure of claim 2, wherein: The base plate (1) is provided with a plurality of first mounting holes (72); the bolt (70) is set in the first mounting hole (72); the side of the first mounting hole (72) is provided with a side ring groove (73); the upper end of the bolt (70) is provided with a convex ring (74), and the convex ring (74) cooperates with the side ring groove (73).
4. The glass pressure plate structure according to claim 2, characterized in that: The top of the bolt (70) is provided with a cross groove (75).
5. The glass press plate structure of claim 1, wherein: The connecting strip (8) includes a vertical strip (80) which is elastic; a semi-circular protrusion (81) is provided on the inner side of the outer end of the vertical strip (80).
6. The glass press plate structure of claim 1, wherein: The base plate (1) has multiple second mounting holes (9) linearly distributed in the middle.
7. The glass press plate structure of claim 1, wherein: The cross-section of the contact block (4) is T-shaped.
8. The glass press plate structure of claim 1, wherein: The base plate (1) and the square protrusion (2) are integrally connected; both the base plate (1) and the square protrusion (2) are made of aluminum alloy.