LU600041B1 - Laminated glass production and cutting device - Google Patents

Abstract

The present invention relates to a laminated glass production and cutting device, belonging to the technical field of glass production. The device comprises a placement frame, with a cutting assembly arranged on the placement frame. The cutting assembly includes two support members horizontally positioned on the upper and lower sides of the placement frame. Two cutting discs are positioned on the sides of the two support members close to the placement frame. A first rotational power unit is connected to the rotating shaft of the cutting discs. Two barrel bodies are vertically positioned between the two support members and the placement frame. A linear displacement mechanism is arranged on the placement frame to drive the support members to move. This invention utilizes a linear displacement mechanism to drive staggered dual cutting discs to move synchronously, enabling intermittent cutting on both the upper and lower sides of the laminated glass. This not only prevents the cutting discs from being jammed by the adhesive film but also allows water sprayed from the upper barrel body during cutting to enter the cutting seam. Using negative pressure equipment, the water is directed along the cutting seam toward the lower barrel body, thereby increasing the contact time between water and the glass, enhancing the cooling effect of the laminated glass, and ensuring the safety of the laminated glass cutting process.

Description

LAMINATED GLASS PRODUCTION AND CUTTING DEVICE

Technical Field

The present invention belongs to the technical field of glass production, specifically relating to a laminated glass production and cutting device.

Background Technology

Laminated glass is a composite glass product in which one or more layers of organic polymer interlayer films are sandwiched between two sheets of glass, and then permanently bonded into a single unit through specialized high-temperature prepressing and high-temperature high-pressure processing techniques. During the manufacturing process of laminated glass, it is necessary to cut the glass to the required dimensions.

When cutting laminated glass, it is placed on a horizontal support platform, and a cutting wheel on the platform is used to divide the glass. However, during the cutting process, the temperature at the cutting seam continuously rises, and glass is prone to cracking when heated. To prevent the laminated glass from cracking during cutting, water is used to cool the cutting wheel. During cutting, when the cutting wheel extends into the interlayer film of the laminated glass, it can easily become jammed by the film.

As a result, only one side of the glass can be cut initially. The laminated glass then needs to be flipped, and the cutting wheel is used to cut along the cutting path on the opposite side of the glass. Finally, a blade is used to cut the interlayer film in the cutting seam. This process significantly reduces the efficiency of laminated glass cutting.

Currently, to improve the efficiency of laminated glass cutting, cutting devices using dual cutting wheels have been developed. These devices enable simultaneous cutting of the glass and the interlayer film on both the upper and lower sides of the laminated glass. By sharing the workload of cutting the interlayer film, dual cutting wheels effectively prevent the cutting wheels from becoming jammed. However, when dual cutting wheels are used to cut laminated glass simultaneously, the cooling water passes rapidly through the cutting seam, resulting in poor cooling of the laminated 17600041 glass and making it difficult to ensure the safety of the cutting process.

Summary of the Invention

In view of the above, the present invention provides a laminated glass production and cutting device capable of performing intermittent cutting on the upper and lower sides of laminated glass, increasing the contact time between water and the glass, and improving the cooling effect of laminated glass to address the deficiencies in the existing technology.

The technical solution of the present invention is as follows: A laminated glass production and cutting device, comprising a placement frame configured to horizontally position laminated glass, a cutting assembly arranged on the placement frame. The cutting assembly comprises two support members horizontally arranged on the upper and lower sides of the placement frame, with the two support members being parallel to each other. Both ends of the support members are slidably connected to the placement frame. Two cutting discs are arranged on the sides of the two support members close to the placement frame. The two cutting discs are staggered, rotatably connected to the support members, and their rotation shafts are parallel to the support members. The support members are provided with a first rotational power unit, which is connected to the rotation shafts of the cutting discs. Two barrel bodies are vertically arranged between the two support members and the placement frame.

The barrel bodies are located on the same side of the two cutting discs, with their openings abutting the laminated glass. The barrel bodies are connected to the support members, with the barrel body above the placement frame being connected to an external water source and the barrel body below the placement frame being connected to external negative pressure equipment. A linear displacement mechanism is arranged on the placement frame, and its output end is connected to the support members to drive them to move.

Preferably, the support members are vertically provided with through holes, and the barrel bodies pass through the through holes, being slidably connected to them.

Elastic members are arranged between the bottom of the barrel bodies and the 17600041 support members, driving the openings of the barrel bodies to abut against the laminated glass via the elastic members.

Preferably, one side of the barrel bodies close to the cutting discs is vertically provided with a first through slot. The cutting discs pass through the first through slot and extend into the barrel bodies. The inner wall of the through holes is vertically provided with a second through slot aligned with the first through slot. A sealing block is vertically fixed within the second through slot, extending into the first through slot and slidably sealing with it.

Preferably, the sides of the two support members close to each other are vertically provided with two mounting members. One end of the mounting members is fixedly connected to the support members, and the other end is rotatably connected to the rotation shafts of the cutting discs. The output shaft of the first rotational power unit is connected to the rotation shafts of the cutting discs via a belt transmission mechanism.

Preferably, the placement frame comprises a rectangular frame, with support legs vertically fixed to the bottom of the rectangular frame. Multiple support rods are horizontally and equidistantly arranged inside the rectangular frame in parallel. The support rods are perpendicular to the rotation shafts of the cutting discs, and both ends of the support rods are fixedly connected to the rectangular frame. The support rods abut against the laminated glass, and the support members are slidably connected to the rectangular frame. The linear displacement mechanism is located on the rectangular frame.

Preferably, the support rods are hollow, and the upper sides of the support rods are equidistantly and vertically connected to multiple press-fit connectors. One end of the press-fit connectors is in communication with the interior of the support rods, and the other end is connected to suction cups. The suction cups abut against the laminated glass, and the interior of the support rods is connected to an external pump via a pipeline.

Preferably, the linear displacement mechanism comprises a first screw rod. The rectangular frame near the two ends of the support rods is provided with third through 17600041 slots. The first screw rod is arranged within the third through slots and parallel to them.

The two ends of the first screw rod are rotatably connected to the rectangular frame.

Sliders are embedded within the third through slots and slidably connected to them.

The first screw rod passes through the sliders and is threadedly connected to them.

The two ends of the support members are connected to the sliders. The rectangular frame is connected to a second rotational power unit, with the output shaft of the second rotational power unit fixedly connected to the first screw rod.

Preferably, connectors are arranged on the two sides of the sliders near the support members. Telescopic rods are vertically arranged between the connectors and the sliders. One end of the telescopic rods is fixedly connected to the sliders, and the other end is fixedly connected to the connectors. The support members are connected to each other.

Preferably, multiple second screw rods are horizontally arranged through the support members in parallel. The second screw rods are threadedly connected to the support members, and both ends of the second screw rods are rotatably connected to the connectors. The connectors are connected to a third rotational power unit, with the output shaft of the third rotational power unit fixedly connected to the second screw rods.

Compared with the existing technology, the laminated glass production and cutting device provided by the present invention utilizes the support members, cutting discs, and linear displacement mechanism of the cutting assembly on the placement frame. The linear displacement mechanism drives the staggered dual cutting discs to move synchronously, enabling intermittent cutting on both the upper and lower sides of the laminated glass. This prevents the cutting discs from being jammed by the interlayer film. Simultaneously, water sprayed from the upper barrel body during cutting enters the cutting seam and is guided by negative pressure equipment to move along the cutting seam into the lower barrel body. This increases the contact time between water and the glass, enhances the cooling effect, and ensures the safety of laminated glass cutting. The cutting device of the present invention is convenient to use, simple to operate, highly practical, and worth promoting. 17600041

Description of the Drawings

FIG.1 is a front view of the present invention; 5 FIG.2 is a top view of the present invention;

FIG.3 is a side view of the present invention;

FIG.4 is a sectional view along line A-A of the present invention;

FIG.5 is a sectional view along line B-B of the present invention.

Detailed Embodiments

The present invention provides a laminated glass production and cutting device, described below in conjunction with the structural schematic diagrams in FIGs. 1 to 5.

In the description of the present invention, it should be understood that the terms such as "center," "longitudinal," "transverse," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "axial," "radial," "circumferential," and others indicating spatial or positional relationships are based on the spatial or positional relationships shown in the figures.

These terms are used solely for describing the technical solutions of the invention and simplifying the description, rather than indicating or implying that the described devices or elements must have specific spatial orientations, configurations, or operations. Therefore, these terms should not be interpreted as limiting the invention.

During the cutting of laminated glass, the temperature at the cutting seam rises continuously, and glass is prone to cracking when heated. To prevent the laminated glass from cracking during cutting, water is required to cool the cutting wheel during the process. However, when the cutting wheel cuts into the interlayer film within the laminated glass, it is highly likely to become jammed. In such cases, only one side of the laminated glass can be cut initially. The glass must then be flipped, and the cutting wheel is used to cut along the cutting path on the opposite side. Finally, a blade is used to cut the interlayer film within the cutting seam, which significantly reduces cutting efficiency.

To improve the cutting efficiency of laminated glass, dual cutting wheels have 17600041 been adopted in cutting devices, enabling simultaneous cutting of both the glass and the interlayer film on the upper and lower sides of the laminated glass. This effectively prevents the cutting wheels from jamming. However, when dual cutting wheels are used for simultaneous cutting, the cooling water rapidly passes through the cutting seam, resulting in inadequate cooling and making it challenging to ensure the safety of the laminated glass cutting process.

To address these issues, the embodiment of the present invention provides a laminated glass production and cutting device that utilizes the support members, cutting discs, and linear displacement mechanism of the cutting assembly on the placement frame. This configuration allows the linear displacement mechanism to drive staggered dual cutting discs to move synchronously, enabling intermittent cutting on the upper and lower sides of the laminated glass. This prevents the cutting discs from jamming due to the interlayer film. Furthermore, as the cutting discs operate, water sprayed from the upper barrel body enters the cutting seam. The negative pressure equipment then guides the water along the cutting seam into the lower barrel body, increasing the contact time between water and glass, enhancing the cooling effect, and ensuring safe cutting of laminated glass.

As shown in FIG.1, which illustrates a front view of the embodiment, the laminated glass production and cutting device includes a placement frame configured to horizontally place laminated glass. A cutting assembly is arranged on the placement frame, and the cutting assembly comprises two support members 1 horizontally positioned on the upper and lower sides of the placement frame. The two support members 1 are parallel to each other, and their ends are slidably connected to the placement frame. Two cutting discs 2 are positioned on the sides of the two support members 1 close to the placement frame. The two cutting discs 2 are staggered and rotatably connected to the support members 1. The rotation shafts of the cutting discs 2 are parallel to the support members 1. The support members 1 are equipped with a first rotational power unit 4, which is connected to the rotation shafts of the cutting discs 2. The two cutting discs 2 cut the laminated glass. Two barrel bodies 3 are vertically positioned between the two support members 1 and the placement frame. 17600041

The barrel bodies 3 are located on the same side as the two cutting discs 2, with their openings abutting the laminated glass. The barrel bodies 3 are connected to the support members 1. The barrel body 3 above the placement frame is connected to an external water source, while the barrel body 3 below the placement frame is connected to external negative pressure equipment. À linear displacement mechanism is arranged on the placement frame, and its output end is connected to the support members 1 to drive their movement.

When using this cutting device, the staggered upper and lower cutting wheels enable intermittent cutting on both sides of the laminated glass. After the upper side of the laminated glass is cut, the lower side remains uncut, forming a cutting seam capable of holding water. As shown in FIG.5, the B-B sectional view of the embodiment, water sprayed from the upper barrel body enters the cutting seam. The negative pressure equipment then guides the water through the cutting seam into the lower barrel body, allowing full contact between water and the glass to maximize the cooling effect.

The device sprays water into the cutting seam using the upper barrel body and guides it through the cutting seam using the lower barrel body and negative pressure equipment. To optimize performance, the distance between the opening of the barrel body 3 and the glass must be minimized. Otherwise, water sprayed from the upper barrel body may rebound off the glass and splash around, reducing the guidance effect of the lower barrel body and negative pressure equipment.

To address this issue, the embodiment proposes a solution: Preferably, the support member 1 is vertically provided with a through hole 11. The barrel body 3 passes through the through hole 11 and is slidably connected to it. An elastic member is arranged between the bottom of the barrel body 3 and the support member 1, driving the opening of the barrel body 3 to abut against the laminated glass via the elastic member.

In this embodiment, the through hole 11 on the support member 1 is used in conjunction with the elastic member to ensure that the opening of the barrel body 3 abuts against the laminated glass. This design not only prevents water sprayed from 17600041 the upper barrel body from splashing outward but also maximizes the effect of water suction and movement when the lower barrel body works in conjunction with the negative pressure equipment.

When the cutting disc 2 cuts the laminated glass, its temperature increases continuously and requires cooling to prevent high temperatures from transferring to the glass during the cutting process.

To address this, the barrel body 3 is improved in this embodiment. Preferably, one side of the barrel body 3 close to the cutting disc 2 is vertically provided with a first through slot 31. The cutting disc 2 passes through the first through slot 31 and extends into the barrel body 3. The inner wall of the through hole 11 is vertically provided with a second through slot aligned with the first through slot 31. À sealing block 32 is vertically fixed within the second through slot, extending into the first through slot 31 and slidably sealing with it.

This embodiment allows part of the cutting disc 2 to extend into the barrel body 3 through the first through slot 31, enabling the water in the barrel body 3 to cool the cutting disc 2. At the same time, the second through slot works in conjunction with the sealing block 32, which automatically adjusts its position when the cutting disc cuts into the laminated glass, preventing water from leaking out of the second through slot.

Preferably, two mounting members 12 are vertically arranged on the sides of the two support members 1 close to each other. One end of each mounting member 12 is fixedly connected to the support member 1, while the other end is rotatably connected to the rotation shaft of the cutting disc 2. The output shaft of the first rotational power unit 4 is connected to the rotation shaft of the cutting disc 2 via a belt transmission mechanism.

A specific configuration of the placement frame is provided in this embodiment.

Preferably, the placement frame includes a rectangular frame 21. The bottom of the rectangular frame 21 is vertically fixed with support legs 22. Multiple support rods 23 are horizontally and equidistantly arranged inside the rectangular frame 21 in parallel.

The support rods 23 are perpendicular to the rotation shafts of the cutting discs 2. Both ends of the support rods 23 are fixedly connected to the rectangular frame 21, and the 17600041 support rods 23 abut against the laminated glass. The support members 1 are slidably connected to the rectangular frame 21, and the linear displacement mechanism is located on the rectangular frame 21. The support rods 23 provide support for the laminated glass.

This device is required to cut the laminated glass, it must be fixed on the placement frame.

Based on this, the support rods 23 are improved in this embodiment. As shown in FIG.4 A-A sectional view, the interior of the support rod 23 is hollow. The upper side of the support rod 23 is equidistantly and vertically connected to multiple press-fit connectors 231. One end of each press-fit connector 231 is in communication with the interior of the support rod 23, while the other end is connected to a suction cup 232.

The suction cup 232 abuts against the laminated glass. The interior of the support rod 23 is connected to an external pump via a pipeline.

This embodiment uses press-fit connectors 231, suction cups 232, and an external pump to press the laminated glass onto the press-fit connectors 231, enabling the suction cups 232 to adhere to and fix the laminated glass. Press-fit connectors 231 not in contact with the laminated glass automatically disconnect the suction cups 232 from the external pump.

As shown in FIG.1 top view, the linear displacement mechanism is configured as follows: It includes a first screw rod 211. The rectangular frame 21 near both ends of the support rods 23 is provided with third through slots 212. The first screw rod 211 is arranged within the third through slots 212 and parallel to them. Both ends of the first screw rod 211 are rotatably connected to the rectangular frame 21. Sliders 213 are embedded within the third through slots 212 and slidably connected to them. The first screw rod 211 passes through the sliders 213 and is threadedly connected to them.

Both ends of the support members 1 are connected to the sliders 213. The rectangular frame 21 is connected to a second rotational power unit 214, and the output shaft of the second rotational power unit 214 is fixedly connected to the first screw rod 211.

This embodiment provides a detailed configuration for the linear displacement mechanism. The second rotational power unit 214 drives the first screw rod 211 to 17600041 rotate, causing the sliders 213 to move and thereby driving the support members 1 and the cutting discs to move longitudinally.

As shown in FIG.1 side view, the sliders 213 are equipped with connectors 215 on their sides near the support members 1. Telescopic rods 216 are vertically arranged between the connectors 215 and the sliders 213. One end of each telescopic rod 216 is fixedly connected to the slider 213, while the other end is fixedly connected to the connector 215. The two support members 1 are connected.

This embodiment uses telescopic rods 216 and connectors 215 to adjust the spacing between the two cutting discs, allowing the cutting discs to slowly penetrate the glass.

Preferably, multiple second screw rods 217 are horizontally arranged through the support members 1 in parallel. The second screw rods 217 are threadedly connected to the support members 1, and both ends of the second screw rods 217 are rotatably connected to the connectors 215. The connectors 215 are connected to a third rotational power unit 218, and the output shaft of the third rotational power unit 218 is fixedly connected to the second screw rods 217.

This embodiment uses the second screw rods 217 and the third rotational power unit 218 to drive the entire cutting assembly to move laterally.

The above disclosure is only a preferred embodiment of the present invention.

However, the embodiments of the present invention are not limited to this. Any modifications that can be conceived by those skilled in the art should fall within the scope of protection of the present invention.

Claims (9)

1. A laminated glass production and cutting device, characterized by comprising: A placement frame, configured to horizontally place laminated glass; a cutting assembly, arranged on the placement frame, wherein the cutting assembly comprises: Two support members (1), horizontally arranged on the upper and lower sides of the placement frame, the two support members (1) being arranged parallel to each other, with both ends of the support members (1) slidably connected to the placement frame; Two cutting discs (2), arranged on one side of the two support members (1) close to the placement frame, the two cutting discs (2) being staggered, with the cutting discs (2) rotatably connected to the support members (1), and the rotation shafts of the cutting discs (2) being parallel to the support members (1), wherein the support members (1) are provided with a first rotational power unit (4), and the first rotational power unit (4) is connected to the rotation shafts of the cutting discs (2); Two barrel bodies (3), vertically arranged between the two support members (1) and the placement frame, the barrel bodies (3) being located on the same side of the two cutting discs (2), with the openings of the barrel bodies (3) abutting against the laminated glass, wherein the barrel bodies (3) are connected to the support members (1), the barrel body (3) located above the placement frame being in communication with an external water source, and the barrel body (3) located below the placement frame being in communication with external negative pressure equipment; A linear displacement mechanism, arranged on the placement frame, with the output end of the linear displacement mechanism connected to the support members (1) for driving the support members (1) to move.

2. The laminated glass production and cutting device according to Claim 1, characterized in that the support members (1) are vertically provided with through holes (11), the barrel bodies (3) pass through the through holes (11) and are slidably connected thereto, and an elastic member is arranged between the bottom of the barrel bodies (3) and the support members (1), driving the openings of the barrel 17600041 bodies (3) to abut against the laminated glass via the elastic member.

3. The laminated glass production and cutting device according to Claim 2, characterized in that one side of the barrel bodies (3) close to the cutting discs (2) is vertically provided with a first through slot (31), the cutting discs (2) pass through the first through slot (31) and extend into the barrel bodies (3), the inner wall of the through holes (11) is vertically provided with a second through slot, the second through slot being aligned with the first through slot (31), and a sealing block (32) is vertically fixed within the second through slot, extending into the first through slot (31) and slidably sealing with it.

4. The laminated glass production and cutting device according to Claim 1, characterized in that two mounting members (12) are vertically arranged on the sides of the two support members (1) facing each other, one end of the mounting members (12) being fixedly connected to the support members (1), and the other end being rotatably connected to the rotation shafts of the cutting discs (2), wherein the output shaft of the first rotational power unit (4) is connected to the rotation shafts of the cutting discs (2) via a belt transmission mechanism.

5. The laminated glass production and cutting device according to Claim 1, characterized in that the placement frame comprises a rectangular frame (21), the bottom of the rectangular frame (21) being vertically fixed with support legs (22), and multiple support rods (23) being horizontally and equidistantly arranged inside the rectangular frame (21) in parallel, the support rods (23) being perpendicular to the rotation shafts of the cutting discs (2), with both ends of the support rods (23) fixedly connected to the rectangular frame (21), and the support rods (23) abutting against the laminated glass, wherein the support members (1) are slidably connected to the rectangular frame (21), and the linear displacement mechanism is positioned on the rectangular frame (21).

6. The laminated glass production and cutting device according to Claim 5, characterized in that the support rods (23) are hollow, the upper sides of the support rods (23) are equidistantly and vertically connected with multiple press-fit connectors (231), one end of the press-fit connectors (231) is in communication with the interior of the support rods (23), and the other end is connected with suction cups (232), the suction cups (232) abutting against the laminated glass, wherein the interior of the support rods (23) is in communication with an external pump through a pipeline.

7. The laminated glass production and cutting device according to Claim 5, characterized in that the linear displacement mechanism comprises: a first screw rod (211), with the rectangular frame (21) near the two ends of the support rods (23) being provided with third through slots (212), wherein the first screw rod (211) is arranged within the third through slots (212) and parallel to them, the two ends of the first screw rod (211) are rotatably connected to the rectangular frame (21), and sliders (213) are embedded within the third through slots (212) and slidably connected to them, wherein the first screw rod (211) passes through the sliders (213) and is threadedly connected to them, the two ends of the support members (1) are connected to the sliders (213), and the rectangular frame (21) is connected to a second rotational power unit (214), with the output shaft of the second rotational power unit (214) being fixedly connected to the first screw rod (211).

8. The laminated glass production and cutting device according to Claim 7, characterized in that connectors (215) are arranged on the two sides of the sliders (213) near the support members (1), with telescopic rods (216) vertically arranged between the connectors (215) and the sliders (213), wherein one end of each telescopic rod (216) is fixedly connected to the sliders (213), and the other end is fixedly connected to the connectors (215), the support members (1) being connected to each other.

9. The laminated glass production and cutting device according to Claim 8,

characterized in that multiple second screw rods (217) are horizontally arranged 17600041 through the support members (1) in parallel, with the second screw rods (217) being threadedly connected to the support members (1), and both ends of the second screw rods (217) being rotatably connected to the connectors (215), wherein the connectors (215) are connected to a third rotational power unit (218), and the output shaft of the third rotational power unit (218) is fixedly connected to the second screw rods (217).