CN115159825A

CN115159825A - Intelligent numerical control cutting machine tool for glass processing

Info

Publication number: CN115159825A
Application number: CN202210890537.4A
Authority: CN
Inventors: 徐家兵; 韦厚瑞; 张航; 周新强
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-07-27
Filing date: 2022-07-27
Publication date: 2022-10-11

Abstract

The invention discloses an intelligent numerical control cutting machine tool for glass processing, which comprises a movable main body structure, a bearing structure and a cutting structure, wherein the movable main body structure is provided with a bearing hole; the invention relates to the technical field of glass processing, and relates to a glass cutting device, which is characterized in that a bearing structure is fixedly arranged on a movable main body structure and is positioned at the central part, and a cutting structure is fixedly arranged on the movable structure and is positioned above the bearing structure; the glass can be fixed through the bearing structure, and meanwhile, the stress borne by the cleaning solution can be borne during cutting, so that the glass is prevented from being broken and damaged during cutting; with the help of cutting structure and bearing structure and major structure mutually support, can realize hanging the planar angle of the relative glass of card cutting wheel and walk the settlement of line, can satisfy and realize that horizontal line, vertical line, diagonal line, curve walk the demand of position, realize diversified cutting.

Description

Intelligent numerical control cutting machine tool for glass processing

Technical Field

The invention relates to the technical field of glass processing, in particular to an intelligent numerical control cutting machine tool for glass processing.

Background

The glass is an amorphous inorganic non-metallic material, and is generally prepared by taking various inorganic minerals (such as quartz sand, borax, boric acid, barite, barium carbonate, limestone, feldspar, soda ash and the like) as main raw materials and adding a small amount of auxiliary raw materials;

the light-transmitting composite material is widely applied to buildings, is used for isolating wind and transmitting light, and belongs to a mixture; at present ordinary glass is in production, for satisfying the user demand, mostly is cutting corresponding size, for example a monoblock glass needs the isovolumetric cutting, perhaps for using beautifully, will mould the type to glass more, cuts corresponding shape promptly, consequently designs a glass processing and uses intelligent numerical control cutting off machine at present.

Disclosure of Invention

The invention aims to provide an intelligent numerical control cutting machine tool for glass processing, which is used for solving the problem of convenience in cutting glass with different sizes and shapes.

In order to achieve the purpose, the invention provides the following technical scheme: an intelligent numerical control cutting machine tool for glass processing comprises a movable main body structure, a bearing structure and a cutting structure;

the bearing structure is fixedly arranged on the movable main body structure and is positioned at the central part, and the cutting structure is fixedly arranged on the movable structure and is positioned above the bearing structure.

Preferably, the main body structure comprises a main frame group, a numerical control box, two pairs of universal wheels, a pair of hydraulic cylinders, a first displacement assembly, a first shell, a first motor and a second displacement assembly;

the main frame group is formed by symmetrically welding two connecting rods between a pair of door-shaped frames, a round pipe is arranged at the center of each door-shaped frame, the numerical control box is fixedly arranged on the upper wall of the left end of each main frame group and positioned on the front side, two pairs of universal wheels are fixedly arranged on the lower walls of the four ends of each main frame group respectively, one ends of a pair of hydraulic cylinders are fixedly penetrated in the round pipes respectively, the first displacement assembly is fixedly arranged on the other end of each hydraulic cylinder and parallel to the main frame group, the first shell is fixedly arranged on the first displacement assembly, a first bearing is fixedly embedded in the lower wall, the first motor is fixedly arranged in the first shell, the driving end of the first motor is fixedly penetrated in the first bearing, the second displacement assembly is identical to the first displacement assembly in structure, and the second displacement assembly is fixedly arranged on the driving end of the first motor and is perpendicular to the main frame group.

Preferably, the first displacement assembly is composed of a first moving frame, a second motor, a first screw rod and a first moving seat;

the first moving frame is of a door-shaped frame structure, a through first sliding groove is formed in the center of the upper wall of the first moving frame, the second motor is fixedly arranged on the left side wall of the first moving frame, the driving end of the second motor movably penetrates through the left end of the first moving sliding groove, one end of the first spiral rod is fixedly connected to the driving end of the second motor, the other end of the first spiral rod is movably embedded in the right side wall of the first groove, a first spiral hole is formed in the center of the first moving frame, the first moving frame movably penetrates through the first sliding groove, and the first moving frame movably is connected to the first spiral rod in a rotating mode.

Preferably, the second displacement component comprises a second movable frame, a third motor is mounted on the second movable frame, the driving end of the third motor is connected with a second screw rod, a second sliding seat is sleeved on the second screw rod, and the second sliding seat penetrates through the second movable frame.

Preferably, in order to realize the multi-point displacement requirement, the first displacement assembly and the second displacement assembly form a cross-shaped sliding rail, a second sliding seat in the second displacement assembly is fixedly connected with a driving end of the first motor, and the second displacement assembly can rotate 360 degrees.

Preferably, the bearing structure comprises a bearing box, a drain valve, a filter screen, a pair of first electric push rods, a second electric push rod, a turnover frame, a turnover table, a plurality of suckers and an air pump;

the bearing box is of a rectangular box structure, a water outlet is formed in the lower wall of the bearing box, the bearing box is fixedly arranged on a main frame group and is located at the center, jacks are formed in the upper wall of the bearing box close to four corners, one end of a drain valve is fixedly connected to the water outlet, a filter screen is fixedly arranged at the position of the lower wall of the bearing box, one end of a pair of first electric push rods is movably arranged at the lower wall of the bearing box respectively and is located close to the left side and the right side of a front end central line, a pair of first electric push rods are movably arranged at the telescopic ends of the first electric push rods, a pair of second electric push rods are movably arranged at the lower wall of the bearing box respectively, the second electric push rods are located close to the center of the rear end, the overturning frame is fixedly arranged at the telescopic ends of the second electric push rods, the overturning table is movably embedded in the bearing box, the lower front end of the overturning frame is fixedly arranged on the overturning frame, the lower end of the overturning table is movably connected to the two ends of the overturning frame, three rows of water leakage holes are formed in the center of the upper wall of the overturning table at equal intervals, a plurality of the suckers are fixedly arranged on the upper wall of the overturning table and are fixedly arranged at the upper wall of the overturning table respectively and are arranged at the same intervals, the three rows of the suckers and are arranged in series with water holes, a plurality of the suckers, a plurality of suction pipes, the suction pipes, and are connected with the suction pipes in series, and are connected with the suction pipes, and are connected with the right side of the bearing box in series, and the suction pipes, and are connected with the suction pipes, and the suction pipes.

Preferably, in order to clean broken slag during cutting and prevent the glass from being damaged by stress, cleaning liquid is collected in the bearing box.

Preferably, the cutting structure comprises a dropping rotating frame, a second bearing, a cutting frame, a cutting wheel, a gear, a third electric push rod and a rack;

the adjustable rotary frame is of an L-shaped structure, the thickness of one end of the adjustable rotary frame is smaller than that of the other end of the adjustable rotary frame, the center of one end of the adjustable rotary frame is fixedly welded on the lower wall of the second sliding seat, a driving groove penetrating through the other end of the adjustable rotary frame is formed in the center of the lower wall of one end of the adjustable rotary frame, the second bearings are fixedly embedded in the upper side wall and the lower side wall of the other end of the adjustable rotary frame respectively, one end of the cutting frame is fixedly penetrated through the second bearings respectively and penetrates through the driving groove, the cutting wheel is movably arranged in the other end of the cutting frame and is positioned above the bearing box, the gear is fixedly sleeved on one end of the cutting frame and is positioned at the center of the other end of the adjustable rotary frame, the third electric push rod is fixedly arranged in the driving groove of one end of the adjustable rotary frame, one end of the rack is fixedly arranged on the telescopic end of the third electric push rod, and the other end of the rack is meshed with the gear.

Preferably, the cutting structure is capable of performing curvilinear and linear runs on the glass in order to achieve the glass cutting, trimming and molding requirements.

Preferably, the bearing box is further buckled with a pad cover which is of a rectangular structure, and the four corners of the lower wall are provided with the inserting columns, so that large-size glass sheets can be conveniently cut and used.

The intelligent numerical control cutting machine tool for glass processing provided by the invention has the beneficial effects that:

1. according to the invention, the cross-shaped sliding rail can be formed through the main body structure to move in a large range, and the second moving assembly can also be driven to rotate, so that 360-degree rotation and arc line displacement during cutting are realized;

2. according to the invention, the glass can be fixed through the bearing structure, and meanwhile, stress borne by the cleaning liquid can be borne during cutting, so that breakage and damage during glass cutting are avoided;

3. according to the invention, by means of the mutual matching of the cutting structure, the bearing structure and the main body structure, the setting of the angle of the glass-hanging cutting wheel relative to the plane of the glass and the routing can be realized, the requirements of realizing transverse routing, vertical routing, diagonal routing and curve routing can be met, and diversified cutting can be realized.

Drawings

FIG. 1 is a schematic view of a first assembly configuration of the present invention;

FIG. 2 is a second assembled configuration of the present invention;

FIG. 3 is a schematic view of a first split structure of the present invention;

FIG. 4 is a schematic view of a second split structure of the present invention;

FIG. 5 is a schematic view of a third split structure of the present invention;

FIG. 6 is an enlarged view of the part A of the present invention;

fig. 7 is a schematic view of the enlarged structure at the position B of the present invention.

In the figure: 1. the main body structure, 11, the main frame group, 12, the numerical control box, 13, the universal wheel, 14, the hydraulic cylinder, 15, the first displacement assembly, 151, the first moving frame, 152, the second motor, 153, the first screw rod, 154, the first moving seat, 16, the first shell, 17, the first motor, 18, the second displacement assembly, 2, the bearing structure, 21, the bearing box, 22, the liquid discharge valve, 23, the filter screen, 24, the first electric push rod, 25, the second electric push rod, 26, the roll-over stand, 27, the roll-over stand, 28, the suction cup, 29, the air suction pump, 3, the cutting structure, 31, the roll-over stand, 32, the second bearing, 33, the cutting stand, 34, the cutting wheel, 35, the gear, 36, the third electric push rod, 37, the rack, 4, and the cushion cover.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, the present invention provides a technical solution: an intelligent numerical control cutting machine tool for glass processing comprises a movable main body structure 1, a bearing structure 2 and a cutting structure 3; the bearing structure 2 is fixedly arranged on the movable main body structure 1 and is positioned at the central part, and the cutting structure 3 is fixedly arranged on the movable structure and is positioned above the bearing structure 2.

The following electric devices have the following types and functions:

hydraulic cylinder: it is prior art, as long as the pneumatic cylinder that is applicable to this scheme all can use.

A first electric push rod: it is prior art, as long as the electric putter that is applicable to this scheme all can use.

A second electric push rod: it is prior art, as long as the electric putter that is applicable to this scheme all can use.

A third electric push rod: it is prior art, as long as the electric putter that is applicable to this scheme all can use.

A first motor: it is prior art, as long as the motor that is applicable to this scheme all can use.

A second motor: it is prior art, as long as the motor that is applicable to this scheme all can use.

A third motor: it is prior art, as long as the motor that is applicable to this scheme all can use.

The following materials are used in the scheme:

cleaning solution: and (4) clear water.

Preferably, the main structure 1 further comprises

The main frame group 11, the main frame group 11 is formed by symmetrically welding two connecting rods between a pair of door-shaped frames, and a circular tube is arranged at the central part of each door-shaped frame;

the numerical control box 12 is fixedly arranged on the upper wall of the left end of the main frame group 11 and is positioned on the front side;

the two pairs of universal wheels 13 are respectively fixedly arranged on the lower walls of the four ends of the main frame group 11;

one ends of the hydraulic cylinders 14 are respectively and fixedly penetrated in the round pipes;

the first displacement assembly 15 is fixedly arranged at the other end of the hydraulic cylinder 14, and the first displacement assembly 15 is parallel to the main frame group 11;

the first shell 16 is fixedly arranged on the first displacement component 15, and a first bearing is fixedly embedded in the lower wall of the first shell 16;

the first motor 17, the first motor 17 is fixedly disposed in the first casing 16, and the driving end is fixedly penetrated in the first bearing;

and a second displacement assembly 18, wherein the second displacement assembly 18 is the same as the first displacement assembly 15 in structure, and the second displacement assembly 18 is fixedly arranged on the driving end of the first motor 17 and is vertical to the main frame assembly 11.

Preferably, the first displacement assembly 15 is further composed of a first moving frame 151, a second motor 152, a first screw rod 153 and a first moving base 154;

first removal frame 151 is door type frame construction, and upper wall central point department sets up the first spout that link up, second motor 152 is fixed to be settled in first removal frame 151 left side wall, and the drive end activity runs through in first removal spout left end, first hob 153 one end fixed connection is on second motor 152 drive end, and other end activity inlays the dress and in first inslot right side wall, first removal seat 154 is I shape structure, and central point department has seted up first spiral hole, first removal frame 151 activity runs through in first spout, and the activity connects soon on first hob 153.

Preferably, the second displacement assembly 18 includes a second movable frame, a third motor is mounted on the second movable frame, a driving end of the third motor is connected to a second screw rod, a second sliding seat is sleeved on the second screw rod, and the second sliding seat penetrates through the second movable frame.

As an optimal solution, further, in order to realize the requirement of multipoint displacement and multi-way cutting and routing, the cross-shaped sliding rail can be realized through the moving structure, and simultaneously, the second moving assembly can be driven to rotate relatively to perform circular or large-range arc cutting.

Preferably, the supporting structure 2 further comprises

The bearing box 21 is of a rectangular box structure, a water outlet is formed in the lower wall of the bearing box 21, the bearing box 21 is fixedly arranged on the main frame group 11 and is located at the center, and inserting holes are formed in the upper wall of the bearing box 21 close to the four corners;

one end of the drain valve 22 is fixedly connected to the drain outlet;

the filter screen 23 is fixedly arranged at the position of a water outlet of the lower wall in the bearing box 21;

one end of each of the first electric push rods 24 is movably arranged on the inner lower wall of the bearing box 21, the first electric push rods are positioned at the left side and the right side close to the center line of the front end and are symmetrical to each other, and the telescopic ends of the first electric push rods 24 are movably provided with turnover seats;

one end of the second electric rod is fixedly arranged at the inner lower wall of the carrier box 21 and is located near the center of the rear end;

the roll-over stand 26 is fixedly arranged on the telescopic end of the second electric push rod 25;

the overturning platform 27 is movably embedded in the bearing box 21, the lower wall of the front end of the overturning platform 27 is fixedly arranged on the overturning seat, the lower wall of the rear end of the overturning platform 27 is movably connected to two ends of the overturning frame 26, and three rows of a plurality of water leakage holes are formed in the center part of the upper wall of the overturning platform 27 at equal intervals;

the sucking discs 28 are fixedly arranged on the upper wall of the overturning platform 27 at equal intervals, and are respectively staggered with the water holes in three rows, and the sucking discs 28 are respectively connected in series through pipelines;

the air pump 29 is fixedly arranged at the right side of the bearing box 21, and the air suction end of the air pump 29 is connected with the suction cup 28 through a pipeline.

Preferably, the cutting structure 3 further comprises

The adjusting and rotating frame is of an L-shaped structure, the thickness of one end of the adjusting and rotating frame is smaller than that of the other end of the adjusting and rotating frame, the central part of one end of the adjusting and rotating frame is fixedly welded on the lower wall of the second sliding seat, and a driving groove penetrating through the other end of the adjusting and rotating frame is formed in the central part of the lower wall of one end of the adjusting and rotating frame;

the second bearings 32 are respectively and fixedly embedded in the upper side wall and the lower side wall of the other end of the turning frame, and one end of the cutting frame 33 is of a rod body structure;

one end of the cutting frame 33 is respectively fixed and penetrates through the second bearing 32 and penetrates through the driving groove;

the cutting wheel 34 is movably arranged in the other end of the cutting frame 33 and is positioned above the bearing box 21;

the gear 35 is fixedly sleeved on one end of the cutting frame 33 and is positioned in the center of the other end of the turning frame;

the third electric push rod 36, the third electric push rod 36 is fixedly arranged in the driving groove at one end of the adjusting bracket;

and one end of the rack 37 is fixedly arranged on the telescopic end of the third electric push rod 36, and the other end of the rack 37 is meshed with the gear 35.

Preferably, the inside of the carrying case 21 is filled with a cleaning liquid.

As a preferable scheme, furthermore, in order to prevent the glass from being broken and realize the cutting of multiple sizes and shapes, the glass is submerged in the cleaning solution during the cutting, the cutting structure 3 can be controlled to do curvilinear swinging motion to adjust the displacement of the cutter, and in the cutting process, the acting force of the cutter on the glass can be separated by the cleaning solution to prevent the glass from being broken under the action of the cleaning solution.

Preferably, the carrying box 21 is further provided with a pad cover 4 in a buckled manner, the pad cover 4 is of a rectangular structure, and the four corners of the lower wall are provided with inserting columns.

The detailed connection means is a technique known in the art, and the following mainly describes the working principle and process, and the specific operation is as follows.

Example (b): as can be seen from the accompanying fig. 1-7 of the specification:

firstly, the equipment can be moved and adjusted in position through the universal wheels 13 below the main frame group 11 in the main body structure 1; the equipment is powered on, the first electric push rod 24 and the second electric push rod 25 in the bearing structure 2 are driven to extend together, and the overturning platform 27 is driven to ascend above the bearing box 21; a certain amount of cleaning liquid (clear water) can be injected into the bearing box 21;

then, the glass can be placed on the sucking disc 28, after being sucked and fixed by driving the air suction pump 29, the first electric push rod 24 and the second electric push rod 25 are controlled to contract and reset, and the glass is driven to descend into the bearing box 21 and be soaked in the cleaning solution;

secondly, programming a cutting walking path through the numerical control box 12 according to cutting requirements; after the hydraulic cylinder 14 is controlled to contract, the first displacement assembly 15 and the second displacement assembly 18 are driven to descend, so that the cutting wheel 34 in the cutting structure 3 is attached to the surface of the glass;

during cutting, the second motor 152 drives the first screw rod 153 to rotate, so as to drive the first movable seat 154 to move left and right, and realize transverse displacement;

the cutting wheel 34 can be driven to move back and forth to carry out vertical walking by driving the second displacement assembly 18, and the second displacement assembly 18 can be matched with the first displacement assembly 15 to realize multi-range movement such as diagonal wiring;

the cutting structure 3 can be driven to rotate 360 degrees to cut shapes such as arcs, circles and the like by driving the second displacement assembly 18 to rotate under the driving of the first motor 17 in the first shell 16;

in the process of driving the first displacement assembly 15 and the second displacement assembly 18, the third electric push rod 36 in the cutting structure 3 is controlled to be driven to extend and retract, the gear 35 is driven to rotate positively and negatively through the rack 37, the cutting frame 33 is driven to rotate in the second bearing 32 on the turning frame, the cutting wheel 34 is driven to swing left and right, back and forth, and the like, so that curve cutting modeling is performed, stress borne by glass in cutting is protected by cleaning liquid, and impact force is reduced to prevent damage;

finally, after the cutting is finished, the first electric push rod 24 is controlled to extend for a certain height, and then the second electric push rod 25 is controlled to extend, so that the overturning platform 27 is obliquely lifted through the overturning frame 26 and the overturning seat, liquid on the surface of the glass is drained, and residue of broken slag is prevented; later stage accessible flowing back valve 22 discharge liquid, and keep apart through filter screen 23 and save the glass bits and pieces and clear up, also can carry out the isometric cutting of glass's great volume with filling up lid 4 spiral-lock at bearing box 21 case and carrying out glass.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a glass processing is with intelligent numerical control cutting off machine, its characterized in that: comprises a mobile main body structure (1), a bearing structure (2) and a cutting structure (3);

the bearing structure (2) is fixedly arranged on the movable main body structure (1) and is positioned at the central part, and the cutting structure (3) is fixedly arranged on the movable structure and is positioned above the bearing structure (2).

2. The intelligent numerical control cutting machine tool for glass processing according to claim 1, characterized in that: the main body structure (1) comprises a main frame group (11), a numerical control box (12), two pairs of universal wheels (13), a hydraulic cylinder (14), a first displacement assembly (15), a first shell (16), a first motor (17) and a second displacement assembly (18);

the numerical control hydraulic cylinder type numerical control hydraulic control mechanism is characterized in that the main frame group (11) is formed by symmetrically welding two connecting rods between a pair of door-shaped frames, a round pipe is arranged at the center of each door-shaped frame, the numerical control box (12) is fixedly arranged on the upper wall of the left end of the main frame group (11) and is positioned on the front side, two pairs of universal wheels (13) are fixedly arranged on the lower walls of the four ends of the main frame group (11), one end of the hydraulic cylinder (14) is fixedly arranged in the round pipe in a penetrating mode, the first displacement assembly (15) is fixedly arranged on the other end of the hydraulic cylinder (14) and is parallel to the main frame group (11), the first shell (16) is fixedly arranged on the first displacement assembly (15), a first bearing is fixedly embedded in the lower wall of the first displacement assembly, the first motor (17) is fixedly arranged in the first shell (16), a driving end of the first displacement assembly is fixedly arranged in the first bearing in a penetrating mode, the second displacement assembly (18) is identical to the first displacement assembly (15) in structure, and the second displacement assembly (18) is fixedly arranged on the driving end of the first motor (17) and is perpendicular to the main frame group (11).

3. The intelligent numerical control cutting machine tool for glass processing according to claim 2, characterized in that: the first displacement assembly (15) consists of a first moving frame (151), a second motor (152), a first screw rod (153) and a first moving seat (154);

the first moving frame (151) is of a door-shaped frame structure, a through first sliding groove is formed in the center of the upper wall, the second motor (152) is fixedly arranged on the left side wall of the first moving frame (151), the driving end of the second motor movably penetrates through the left end of the first moving sliding groove, one end of the first spiral rod (153) is fixedly connected to the driving end of the second motor (152), the other end of the first spiral rod is movably embedded in the right side wall of the first groove, the first moving seat (154) is of an I-shaped structure, a first spiral hole is formed in the center of the first moving seat, and the first moving frame (151) movably penetrates through the first sliding groove and is movably screwed on the first spiral rod (153).

4. The intelligent numerical control cutting machine tool for glass processing according to claim 2, characterized in that: the second displacement assembly (18) comprises a second movable frame, a third motor is mounted on the second movable frame, the driving end of the third motor is connected with a second spiral rod, a second sliding seat is sleeved on the second spiral rod, and the second sliding seat penetrates through the second movable frame.

5. The intelligent numerical control cutting machine tool for glass processing according to claim 1, characterized in that: the bearing structure (2) comprises a bearing box (21), a liquid discharge valve (22), a filter screen (23), a first electric push rod (24), a second electric push rod (25), a turnover frame (26), a turnover table (27), a suction cup (28) and an air suction pump (29);

the bearing box (21) is a rectangular box structure, a water outlet is arranged on the lower wall of the bearing box, the bearing box (21) is fixedly arranged on the main frame group (11) and is positioned at the central part, jacks are arranged on the upper wall of the bearing box (21) close to the four corners, one end of the drain valve (22) is fixedly connected to the water outlet, the filter screen (23) is fixedly arranged at the position of the water outlet of the lower wall in the bearing box (21), one end of the first electric push rod (24) is respectively and movably arranged at the lower wall in the bearing box (21) and is positioned close to the central part of the rear end, the first electric push rod (24) is respectively and symmetrically arranged on the left side and the right side close to the central line of the front end, the first electric push rod (24) is movably provided with a turnover seat, one end of the second electric push rod is fixedly arranged at the lower wall in the bearing box (21) and is positioned close to the central part of the rear end, the turnover frame (26) is fixedly arranged at the telescopic end of the second electric push rod (25), the turnover frame (27) is movably embedded in the bearing box (21) and is fixedly arranged on the lower wall, the left side of the turnover frame (27), the turnover frame (28), the three water outlet holes are respectively arranged at the central part of the fixed suction cup (28), the suction holes (28), and are respectively arranged on the three suction cup (21), and the air exhaust end is connected with the suction cup (28) through a pipeline.

6. The intelligent numerical control cutting machine tool for glass processing according to claim 1, characterized in that: the cutting structure (3) comprises a falling rotating frame (31), a second bearing (32), a cutting frame (33), a cutting wheel (34), a gear (35), a third electric push rod (36) and a rack (37);

the adjustable rotary frame is of an L-shaped structure, the thickness of one end of the adjustable rotary frame is smaller than that of the other end of the adjustable rotary frame, the center of one end of the adjustable rotary frame is fixedly welded to the lower wall of the second sliding seat, a driving groove penetrating through the other end of the adjustable rotary frame is formed in the center of the lower wall of one end of the adjustable rotary frame, the second bearings (32) are fixedly embedded in the upper side wall and the lower side wall of the other end of the adjustable rotary frame respectively, one end of the cutting frame (33) is of a rod body structure, one end of the cutting frame (33) fixedly penetrates through the second bearings (32) and penetrates through the driving groove, the cutting wheel (34) is movably arranged in the other end of the cutting frame (33) and is located above the bearing box (21), the gear (35) is fixedly sleeved on one end of the cutting frame (33) and is located in the center of the other end of the adjustable rotary frame, the third electric push rod (36) is fixedly arranged in the driving groove in one end of the adjustable rotary frame, one end of the rack (37) is fixedly arranged on the telescopic end of the third electric push rod (36), and the other end of the rack is meshed with the gear (35).

7. The intelligent numerical control cutting machine tool for glass processing according to claim 5, characterized in that: the bearing box (21) is internally provided with cleaning liquid.

8. The intelligent numerical control cutting machine tool for glass processing according to claim 5, characterized in that: the bearing box (21) is also buckled with a pad cover (4), the pad cover (4) is of a rectangular structure, and the four corners of the lower wall are provided with inserting columns.