A glass bottle forming apparatus
By combining the drive unit and the Hall sensor, the rotation of the jaw mechanism of the glass bottle forming device is precisely controlled, which solves the problem of inaccurate control of rotation direction and angle in traditional devices and improves the precision and quality of glass bottle forming.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- TANGSHAN TAIFENG GLASS PROD CO LTD
- Filing Date
- 2025-06-16
- Publication Date
- 2026-07-03
AI Technical Summary
Traditional glass bottle forming equipment struggles to precisely control the rotation direction and angle of the jaw mechanism, resulting in insufficient forming precision at the bottle mouth and impacting product quality.
The device employs a drive mechanism that uses a hydraulic telescopic rod to rotate a moving plate and a rack and pinion mechanism, thereby rotating the jaw mechanism. Combined with a Hall sensor to monitor the position changes of the magnet in real time, the rotation direction and angle of the jaw mechanism are precisely controlled.
It achieves precise rotational control of the clamping mechanism, ensuring the accuracy and quality of glass bottle mouth forming, providing stable rotational power transmission, and improving real-time data feedback in the production process.
Smart Images

Figure CN224450538U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of glass processing technology, specifically to a glass bottle forming device. Background Technology
[0002] A glass bottle forming device is a specialized piece of equipment used to process molten glass raw materials into glass bottles. It is a core component of glass container manufacturing. The row-type bottle forming machine is the core equipment of the glass bottle forming device, while the external servo flipping mechanism is an auxiliary module.
[0003] Traditional glass bottle forming equipment struggles to precisely control the rotation direction and angle of the jaw mechanism, resulting in insufficient forming accuracy at the bottle neck and impacting product quality. Therefore, a new glass bottle forming device is needed to address these issues. Utility Model Content
[0004] This invention provides a glass bottle forming apparatus to solve the problems in the background art.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a glass bottle forming device, including a bottle-making machine frame, a jaw clamp mechanism, and a control device. Support frames are arranged side-by-side at the top center of the bottle-making machine frame. A jaw clamp mechanism gear is fixedly connected to the center of the outer surface of the jaw clamp mechanism. A driving device is provided at the top of the bottle-making machine frame. The driving device includes a slide rod, a hydraulic telescopic rod, a rack, a mounting frame, a slide rail, a mounting base, a Hall sensor, a moving plate, a magnet, and a slide groove. There are two hydraulic telescopic rods, two moving plates, and two mounting frames. There are four slide rods, four magnets, four mounting bases, four Hall sensors, four slide rails, and four racks. The bottoms of the two hydraulic telescopic rods are respectively connected to the top right side of the bottle-making machine frame. The two mounting brackets are fixedly connected to the front and rear ends of the bottle-making machine frame. The bottom of the two mounting brackets is fixedly connected to the center of the front and rear ends of the top right side of the bottle-making machine frame. The output ends of the two hydraulic telescopic rods are fixedly connected to the center of the right side of the two moving plates. The left sides of the two moving plates are fixedly connected to the right sides of the four straight racks. The bottom of the four slide rails are arranged side by side on the top of the bottle-making machine frame and fixedly connected thereto. The bottom of the four mounting seats are arranged side by side on the top of the bottle-making machine frame near the left side and fixedly connected thereto. The left sides of the four mounting seats are fixedly connected to the mounting ends of the four Hall sensors. The left sides of the four straight racks are fixedly connected to the mounting ends of the four magnets.
[0006] Furthermore, the left sides of the four slide rods are fixedly connected to the right sides of the two movable plates near the front and rear ends, respectively. The right sides of the four slide rods pass through the left side of the mounting frame and extend out of the right side of the mounting frame. The connection between the slide rods and the mounting frame is a movable sleeve.
[0007] Furthermore, the four grooves are respectively opened at the bottom center of the rack, and the outer surfaces of the four slide rails are slidably connected to the interior of the four grooves.
[0008] Furthermore, the output ends of the two hydraulic telescopic rods pass through the right side of the two mounting brackets and extend to the left side of the mounting brackets, where they are connected to the rack and pinion.
[0009] Furthermore, the four racks are located directly below the multiple jaw mechanism gears, and the jaw mechanism gears mesh with the racks, with the number of racks being the same as the number of jaw mechanism gears.
[0010] Furthermore, the four magnet blocks are respectively symmetrically arranged with the four Hall sensors.
[0011] Furthermore, multiple support frames are connected in series by connecting rods and are fixedly connected to the connecting rods. There are multiple jaw mechanisms, and the interior of each jaw mechanism is movably sleeved with the outer surface of the connecting rod. The multiple jaw mechanisms are located between the front and rear ends of multiple symmetrically arranged support frames.
[0012] Compared with the prior art, the present invention provides a glass bottle forming device, which has the following beneficial effects:
[0013] 1. This glass bottle forming device, through a drive mechanism, uses a hydraulic telescopic rod to move a movable plate, causing a rack and pinion to move left and right, which in turn rotates the jaw mechanism gears. This allows for precise control of the jaw mechanism's clockwise or counterclockwise rotation, meeting various glass bottle forming requirements. Precise control of the jaw mechanism's rotational movement ensures the accuracy and quality of the glass bottle mouth forming, achieving stable rotational power transmission. A Hall effect sensor monitors the positional changes of the magnet block in real time, accurately determining the rotation direction and angle of the jaw mechanism gears and jaw mechanism itself, providing real-time data feedback for the production process. Attached Figure Description
[0014] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0015] Figure 2 This is a structural diagram of the drive device of this utility model;
[0016] Figure 3 This is a rear view of the straight rack of this utility model.
[0017] In the diagram: 1. Bottle making machine frame; 2. Drive unit; 3. Gear of the jaw clamp mechanism; 4. Jaw clamp mechanism; 5. Support frame; 6. Control device; 201. Slide rod; 202. Hydraulic telescopic rod; 203. Straight rack; 204. Mounting frame; 205. Slide rail; 206. Mounting base; 207. Hall sensor; 208. Moving plate; 209. Magnet block; 210. Slide groove. Detailed Implementation
[0018] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0019] Please see Figure 1-3 This utility model discloses a glass bottle forming device, including a bottle-making machine frame 1, a jaw clamp mechanism 4, and a control device 6. Support frames 5 are arranged side-by-side at the top center of the bottle-making machine frame 1. A jaw clamp mechanism gear 3 is fixedly connected to the center of the outer surface of the jaw clamp mechanism 4. A drive device 2 is provided on the top of the bottle-making machine frame 1. The drive device 2 includes a slide rod 201, a hydraulic telescopic rod 202, a rack 203, a mounting frame 204, a slide rail 205, a mounting base 206, a Hall sensor 207, a moving plate 208, a magnet 209, and a slide groove 210. There are two hydraulic telescopic rods 202, two moving plates 208, and two mounting frames 204. There are four slide rods 201, four magnets 209, four mounting bases 206, four Hall sensors 207, four slide rails 205, and four racks 203. The bottoms of the two hydraulic telescopic rods 202 are respectively... The bottom of the two mounting brackets 204 are fixedly connected to the top right side of the bottle making machine frame 1 near the front and rear ends. The output ends of the two hydraulic telescopic rods 202 are fixedly connected to the right center of the two moving plates 208 respectively. The left side of the two moving plates 208 near the front and rear ends are fixedly connected to the right side of the four straight racks 203 respectively. The bottom of the four slide rails 205 are arranged side by side on the top of the bottle making machine frame 1 and fixedly connected thereto. The bottom of the four mounting seats 206 are arranged side by side on the top of the bottle making machine frame 1 near the left side and fixedly connected thereto. The left side of the four mounting seats 206 is fixedly connected to the mounting ends of the four Hall sensors 207 respectively. The left side of the four straight racks 203 is fixedly connected to the mounting ends of the four magnet blocks 209 respectively.
[0020] Specifically, the left sides of the four slide rods 201 are fixedly connected to the right sides of the two movable plates 208 near the front and rear ends, respectively. The right sides of the four slide rods 201 pass through the left side of the mounting bracket 204 and extend out of the right side of the mounting bracket 204. The connection between the slide rods 201 and the mounting bracket 204 is a movable sleeve.
[0021] Specifically, four grooves 210 are respectively opened at the bottom center of the rack 203, and the outer surfaces of the four slide rails 205 are slidably connected to the interior of the four grooves 210.
[0022] Specifically, the output ends of the two hydraulic telescopic rods 202 pass through the right side of the two mounting brackets 204 and extend to the left side of the mounting brackets 204, and are connected to the rack and pinion 203.
[0023] Specifically, four racks 203 are located directly below multiple jaw mechanism gears 3, and the jaw mechanism gears 3 mesh with the racks 203. The number of racks 203 and jaw mechanism gears 3 is the same.
[0024] Specifically, the four magnet blocks 209 are symmetrically arranged with the four Hall sensors 207 respectively.
[0025] Specifically, multiple support frames 5 are connected in series by connecting rods and are fixedly connected to the connecting rods. There are multiple jaw mechanisms 4, and the interior of the multiple jaw mechanisms 4 is movably sleeved with the outer surface of the connecting rods. The multiple jaw mechanisms 4 are respectively located between the front and rear ends of the multiple symmetrically arranged support frames 5.
[0026] When using the glass bottle forming device, the hydraulic telescopic rod 202 in the drive unit 2 is activated. The output end of the hydraulic telescopic rod 202 drives the moving plate 208 to move to the left. The movement of the moving plate 208 drives the slide rod 201 to move, and simultaneously, the movement of the moving plate 208 also drives the rack 203 to move to the left along the slide rail 205. When the rack 203 moves to the left, it can rotate the jaw mechanism gear 3. The rotation of the jaw mechanism gear 3 drives the jaw mechanism 4 to rotate clockwise. As the rack 203 moves to the left, the magnet 209 approaches the Hall sensor 207. The Hall sensor 207 senses the change in the position of the magnet 209, thereby determining the rotation direction and angle of the jaw mechanism gear 3 and the jaw mechanism 4. To make the jaw mechanism gear 3 and the jaw mechanism 4 rotate counterclockwise, simply control the output end of the hydraulic telescopic rod 202 to retract, causing the moving plate 208 to move to the right. The movement of the movable plate 208 causes the slide bar 201 to move to the right, simultaneously causing the rack 203 to move to the right along the slide rail 205. As the rack 203 moves to the right, it actuates the jaw mechanism gear 3 to rotate counterclockwise, thereby causing the jaw mechanism 4 to rotate counterclockwise. At this time, because the rack 203 moves to the right, the magnet 209 moves away from the Hall sensor 207. The Hall sensor 207 detects the change in the position of the magnet 209, thereby determining the rotation direction and angle of the jaw mechanism gear 3 and the jaw mechanism 4.
[0027] In summary, this glass bottle forming device, through the installation of a drive unit 2, uses a hydraulic telescopic rod 202 to extend and retract, moving a movable plate 208. This causes the rack and pinion 203 to move left and right, rotating the jaw mechanism gear 3. This allows for precise control of the jaw mechanism 4's clockwise or counterclockwise rotation, meeting various glass bottle forming requirements. Precise control of the jaw mechanism 4's rotational movement ensures the accuracy and quality of the glass bottle mouth forming, achieving stable rotational power transmission. The Hall sensor 207 monitors the positional changes of the magnet 209 in real time, accurately determining the rotational direction and angle of the jaw mechanism gear 3 and jaw mechanism 4, providing real-time data feedback for the production process.
[0028] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A glass bottle forming apparatus comprising a bottle maker frame (1), a mouth jaw mechanism (4) and a control device (6), characterized in that: Support frames (5) are arranged side by side at the top center of the bottle-making machine frame (1). A jaw mechanism gear (3) is fixedly connected to the center of the outer surface of the jaw mechanism (4). A drive device (2) is provided on the top of the bottle-making machine frame (1). The drive device (2) includes a slide rod (201), a hydraulic telescopic rod (202), a rack (203), a mounting bracket (204), a slide rail (205), a mounting seat (206), a Hall sensor (207), a moving plate (208), a magnet (209), and a slide groove (210). There are two hydraulic telescopic rods (202), two moving plates (208), and two mounting brackets (204). There are four slide rods (201), four magnets (209), four mounting seats (206), four Hall sensors (207), four slide rails (205), and four racks (203). The bottoms of the two hydraulic telescopic rods (202) are respectively connected to the bottle-making machine frame (1). The top right side of the bottle making machine frame (1) is fixedly connected to the front and rear ends. The bottom of the two mounting brackets (204) is fixedly connected to the front and rear ends of the top right side of the bottle making machine frame (1) near the center. The output ends of the two hydraulic telescopic rods (202) are fixedly connected to the center of the right side of the two moving plates (208). The left side of the two moving plates (208) is fixedly connected to the right side of the four straight racks (203) near the front and rear ends. The bottom of the four slide rails (205) is arranged side by side on the top of the bottle making machine frame (1) and fixedly connected thereto. The bottom of the four mounting seats (206) is arranged side by side on the top of the bottle making machine frame (1) near the left side and fixedly connected thereto. The left side of the four mounting seats (206) is fixedly connected to the mounting ends of the four Hall sensors (207). The left side of the four straight racks (203) is fixedly connected to the mounting ends of the four magnets (209).
2. A glass bottle forming apparatus as claimed in claim 1, wherein: The left sides of the four slide rods (201) are fixedly connected to the right sides of the two movable plates (208) near the front and rear ends, respectively. The right sides of the four slide rods (201) pass through the left side of the mounting frame (204) and extend out of the right side of the mounting frame (204). The connection between the slide rods (201) and the mounting frame (204) is a movable sleeve.
3. A glass bottle forming apparatus as claimed in claim 1, wherein: The four grooves (210) are respectively opened at the bottom center of the rack (203), and the outer surfaces of the four slide rails (205) are slidably connected to the interior of the four grooves (210).
4. A glass bottle forming apparatus as claimed in claim 1, wherein: The output ends of the two hydraulic telescopic rods (202) pass through the right side of the two mounting brackets (204) and extend to the left side of the mounting brackets (204) and are connected to the rack (203).
5. A glass bottle forming apparatus as claimed in claim 1, wherein: The four racks (203) are located directly below the multiple jaw mechanism gears (3), and the jaw mechanism gears (3) mesh with the racks (203). The number of racks (203) and jaw mechanism gears (3) is the same.
6. A glass bottle forming apparatus as claimed in claim 1, wherein: The four magnet blocks (209) are respectively symmetrically arranged with the four Hall sensors (207).
7. A glass bottle forming apparatus as claimed in claim 1, wherein: Multiple support frames (5) are connected in series by connecting rods and fixedly connected to the connecting rods. There are multiple jaw mechanisms (4). The interior of the multiple jaw mechanisms (4) is movably sleeved with the outer surface of the connecting rods, and the multiple jaw mechanisms (4) are respectively located between the front and rear ends of the multiple symmetrically arranged support frames (5).