CN212495775U - High-precision aluminum profile cutting equipment - Google Patents

Abstract

The utility model provides an aluminium alloy high accuracy cutting equipment, in the course of the work, will wait to cut the aluminium alloy and wear to establish each in transport mechanism's a transport assembly from the driving wheel and another transport assembly between each. In a conveying assembly, a conveying motor drives a conveying belt to move through a driving wheel arranged on a rotating shaft, the conveying belt drives the rotating shafts to rotate through driving wheels, and driven wheels on the rotating shafts rotate to convey the aluminum profile to a bearing block. The air extractor is used for carrying out air extraction, adsorption and fixation on the aluminum profile to be cut through the air extraction pipe and the bearing block. The driving motor drives the cutting blade to penetrate or penetrate out of the cutting groove to cut the aluminum profile through the driving shaft, the cam, the driving column and the bearing box. After the cutting mechanism cuts the aluminum profile, two conveying motors in the conveying mechanism rotate for preset time, the next aluminum profile to be cut is conveyed to the bearing block, and the cut aluminum profile is ejected out of the bearing block.

Description

High-precision aluminum profile cutting equipment

Technical Field

The utility model relates to an aluminium alloy processing field especially relates to an aluminium alloy high accuracy cutting equipment.

Background

The stable, continuous and rapid development of national economy and high and new technology of China promotes the rapid development of aluminum smelting and aluminum profile processing industry of China. The aluminum section bar industrial aluminum section bar yield in China reaches 879.3 ten thousand tons in 2006, and the aluminum section bar is the first in the world beyond the United states. In the 21 st century, the Chinese aluminum processing industry closely combines the market and scientific development requirements, so that the traditional aluminum processing material has gradually completed the conversion to the modern aluminum processing material, and therefore, the Chinese aluminum processing material has undergone great changes. The Chinese aluminum processing material has the important characteristics of developing towards high performance, high precision, energy conservation and environmental protection, and a plurality of products become famous brands at home and abroad and have high reputation on markets at home and abroad; the product quality is steadily improved, the product standard level is in the international advanced line, and all main aluminum product manufacturers can directly accept orders according to the requirements of the world advanced national standard except for producing according to the national standard. This shows that the production of aluminum processing materials in China is further internationalized, and each main aluminum processing enterprise also correspondingly formulates a plurality of internal supply technical standards in order to meet various requirements of national economy and scientific technology on high-precision aluminum materials.

However, in the processing process of the aluminum profile, the surface of the aluminum profile needs to be cut, but the traditional work of cutting the aluminum profile is often completed manually, and the manual cutting speed is low, the efficiency is low, the working intensity is high, and the labor cost is high.

SUMMERY OF THE UTILITY MODEL

Based on this, it is necessary to provide an aluminium alloy high accuracy cutting equipment to the technical problem that manual cutting's speed is slow, inefficiency, working strength is big, labour cost is high.

The utility model provides an aluminium alloy high accuracy cutting equipment, this aluminium alloy high accuracy cutting equipment includes: the device comprises a bearing frame, a cutting mechanism, a conveying mechanism and a fixing mechanism;

the bearing frame comprises a transverse bearing plate and a vertical bearing plate, and the vertical bearing plate is vertically connected with the transverse bearing plate;

the cutting mechanism comprises a bearing box, a driving motor, a driving shaft, a cam, a driving column, a cutting assembly, a bearing block, two connecting columns and two extension springs; the driving motor and the bearing box are arranged on the vertical bearing plate from top to bottom; the driving motor is in driving connection with the cam through the driving shaft, a sliding groove is formed in the periphery of the cam, a sliding block is arranged at one end of the driving column, and the sliding block is inserted into the sliding groove and is in sliding connection with the cam; the cutting assembly comprises a bearing box, a screw rod motor, a cutting motor and a cutting blade; the screw rod motor is connected with the receiving box, the screw rod motor is in driving connection with the cutting motor, the cutting motor is in driving connection with the cutting blade, and the cutting motor is accommodated in the receiving box; the bearing box is provided with a through hole, and one end of the driving column, which is far away from the sliding block, penetrates through the through hole and is connected with the bearing box; the two connecting columns are arranged on two sides of the driving column and are connected with the bearing box; each connecting column is connected with the inner side wall of the bearing box through one extension spring; sliding grooves are formed in two parallel inner side walls of the bearing box, sliding blocks are arranged at two ends of the bearing box, and each sliding block is inserted into one sliding groove and is connected with the bearing box in a sliding mode; one surface of the bearing box, which is back to the driving column, is provided with a cutting opening, and the cutting blade is partially exposed out of the cutting opening; the bearing block is connected with the transverse bearing plate, one surface of the bearing block, which is back to the transverse bearing plate, is uniformly provided with cutting grooves, and the driving motor drives the cutting blade to penetrate into or penetrate out of the cutting grooves through the driving shaft, the cam, the driving column and the bearing box;

the conveying mechanism is arranged on one side of the bearing block; the conveying mechanism comprises a connecting plate, a bearing plate, two conveying assemblies and a plurality of limiting assemblies; the connecting plate and the bearing plate are arranged in parallel and are connected with the transverse bearing plate; the two conveying assemblies are arranged up and down and comprise conveying motors, conveying belts and a plurality of rotating shafts; the conveying motors in the two conveying assemblies are arranged on the connecting plate up and down. Each rotating shaft penetrates through the bearing plate and is in rotating connection with the bearing plate; one end of the rotating shaft is provided with a driving wheel, and the other end of the rotating shaft is provided with a driven wheel; the conveying motor drives the conveying belt to move through a driving wheel arranged on the rotating shaft, the conveying belt drives the rotating shafts to rotate through the driving wheels, and the driven wheels on the rotating shafts rotate to convey the aluminum profile to the bearing block; the aluminum profile is transmitted between the driven wheels in the two transmission assemblies which are arranged up and down; each limiting component is uniformly arranged on two sides of the driven wheel and comprises a rotating column and a limiting wheel; each rotating column is uniformly arranged on two sides of the driven wheel, and each rotating column is rotatably connected with one limiting wheel; the side wall of each limiting wheel is provided with a limiting groove, and an aluminum profile is inserted into each limiting groove and is connected with each limiting wheel in a sliding manner;

the fixing mechanism comprises an air pump and an air pumping pipe, the bearing block is provided with an air pumping cavity, one surface of the bearing block, which faces away from the transverse bearing plate, is uniformly provided with a plurality of air pumping holes, each air pumping hole is communicated with the air pumping cavity, and the air pump is communicated with the air pumping cavity through the air pumping pipe.

In one embodiment, each of the air exhaust holes is uniformly opened at two sides of the cutting groove.

In one embodiment, the drive motor is a stepper motor.

In one embodiment, the drive motor is a servo motor.

In one embodiment, a filter screen is arranged at the input end of the exhaust tube.

In one embodiment, the filter screen is an air conditioner filter screen.

In one embodiment, the filter mesh is a metal filter mesh.

In one embodiment, the filter is a ventilation filter.

In one embodiment, the filter screen is a metal rubber filter screen.

In one embodiment, the air exhaust holes are uniformly arranged on two sides of the cutting groove in two rows.

The aluminum profile high-precision cutting equipment is characterized in that the aluminum profile to be cut is arranged between each driven wheel in one conveying assembly and each driven wheel in the other conveying assembly in a penetrating mode in the working process. In a conveying assembly, a conveying motor drives a conveying belt to move through a driving wheel arranged on a rotating shaft, the conveying belt drives the rotating shafts to rotate through driving wheels, and driven wheels on the rotating shafts rotate to convey the aluminum profile to a bearing block. The air extractor is used for carrying out air extraction, adsorption and fixation on the aluminum profile to be cut through the air extraction pipe and the bearing block. The driving motor drives the cutting blade to penetrate or penetrate out of the cutting groove to cut the aluminum profile through the driving shaft, the cam, the driving column and the bearing box. After the cutting mechanism cuts the aluminum profile, two conveying motors in the conveying mechanism rotate for preset time, the next aluminum profile to be cut is conveyed to the bearing block, and the cut aluminum profile is ejected out of the bearing block. The aluminum profile high-precision cutting equipment is high in cutting speed and efficiency of aluminum profiles, and labor intensity of aluminum profile cutting is reduced.

Drawings

FIG. 1 is a schematic structural diagram of a high-precision aluminum profile cutting device in one embodiment;

FIG. 2 is a schematic structural diagram of another view angle of the aluminum profile high-precision cutting equipment in the embodiment of FIG. 1;

FIG. 3 is a schematic structural diagram of another view angle of the aluminum profile high-precision cutting device in the embodiment of FIG. 1;

fig. 4 is a schematic structural diagram of another view angle of the aluminum profile high-precision cutting equipment in the embodiment of fig. 1.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the invention and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through an intermediate. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Please refer to fig. 1 to 4 together, the utility model provides an aluminium alloy high accuracy cutting equipment 10, this aluminium alloy high accuracy cutting equipment 10 includes: carrier 100, cutting mechanism 200, transport mechanism 300, and securing mechanism 400. The receiving frame 100 is used for receiving the cutting mechanism 200, the conveying mechanism 300 and the fixing mechanism 400. The receiving rack 100 includes a horizontal bearing plate 110 and a vertical bearing plate 120, and the vertical bearing plate 120 and the horizontal bearing plate 110 are vertically connected.

The cutting mechanism 200 is used for cutting the aluminum profile, and the cutting mechanism 200 includes a carrying box 210, a driving motor 220, a driving shaft 230, a cam 240, a driving column 250, a cutting assembly 260, a receiving block 270, two connecting columns 280 and two extension springs 290. The driving motor 220 and the carrying box 210 are arranged on the vertical carrying plate 120 up and down. In the present embodiment, the driving motor 220 is a stepping motor. In another embodiment, the drive motor is a servo motor. The driving motor 220 is drivingly connected to the cam 240 through the driving shaft 230, a sliding slot 201 is formed around the cam 240, and a sliding block 251 is disposed at one end of the driving column 250, in this embodiment, the sliding block 251 is a circular disk. The sliding block 251 is inserted in the sliding slot 201 and slidably coupled with the cam 240. The cutting assembly 260 includes a receiving box 261, a lead screw motor 262, a cutting motor (not shown), and a cutting blade 263. The lead screw motor 262 is connected with the receiving box 261, the lead screw motor 262 is in driving connection with the cutting motor, the cutting motor is in driving connection with the cutting blade 263, and the cutting motor is accommodated in the receiving box 261. In the cutting process, the lead screw motor 262 drives the cutting motor to move back and forth, the cutting motor moves back and forth to drive the cutting blade 263 to move back and forth, and the cutting motor moving back and forth drives the cutting blade 263 to rotate to cut the aluminum profile. The carrying box 210 is opened with a through opening 202, and one end of the driving column 250 far away from the sliding block 251 passes through the through opening 202 and is connected with the carrying box 261. Two connection posts 280 are provided on both sides of the driving post 250 and connected to the receiving case 261. Each connecting post 280 is connected to the inner sidewall of the cassette 210 by a tension spring 290. The two parallel inner side walls of the carrying box 210 are both provided with a sliding groove 203, and both ends of the carrying box 261 are both provided with a sliding block (not shown), and each sliding block is inserted into one sliding groove 203 and is connected with the carrying box 210 in a sliding manner. The side of the receiving box 261 facing away from the driving column 250 is provided with a cutting opening 204, and the cutting blade 263 is partially exposed out of the cutting opening 204. The bearing block 270 is connected with the transverse bearing plate 110, the cutting grooves 205 are uniformly formed in one surface of the bearing block 270, which faces away from the transverse bearing plate 110, and the driving motor 220 drives the cutting blades 263 to penetrate into or penetrate out of the cutting grooves 205 through the driving shaft 230, the cam 240, the driving column 250 and the bearing box 261. In this embodiment, both sides of one surface of the receiving block 270 facing away from the transverse bearing plate 110 are provided with a limiting rail 271, so as to further limit the position of the aluminum profile and the transmission track of the aluminum profile.

The transfer mechanism 300 is used to supply the aluminum profiles to the aluminum profile high-precision cutting apparatus 10. The transfer mechanism 300 is disposed at one side of the receiving block 270. The transfer mechanism 300 includes a connecting plate 310, a receiving plate 320, two transfer assemblies 330, and a plurality of stop assemblies 340. The connecting plate 310 and the bearing plate 320 are disposed in parallel and are connected to the lateral bearing plate 110. The two conveying assemblies 330 are arranged up and down, and the conveying assemblies 330 include a conveying motor 331, a conveying belt 332 and a plurality of rotating shafts 333. The transfer motors 331 of the two transfer units 330 are disposed up and down on the connection plate 310. Each of the rotation shafts 333 passes through the receiving plate 320 and is rotatably coupled to the receiving plate 320. One end of the rotation shaft 333 is provided with a driving pulley 334, and the other end of the rotation shaft 333 is provided with a driven pulley 335. The conveying motor 331 drives the conveying belt 332 to move through a driving wheel 334 arranged on a rotating shaft 333, the conveying belt 332 drives each rotating shaft 333 to rotate through each driving wheel 334, and a driven wheel 335 on each rotating shaft 333 rotates to convey the aluminum profile onto the receiving block 270. The aluminum profiles are transferred between the driven pulleys 335 in the two transfer assemblies 330 disposed one above the other. The limiting assemblies 340 are uniformly arranged at two sides of the driven wheel 335, and the limiting assemblies 340 comprise a rotating column 341 and a limiting wheel 342. The rotating columns 341 are uniformly disposed on both sides of the driven wheel 335, and each rotating column 341 is rotatably connected to a limiting wheel 342. Limiting grooves 301 are formed in the side walls of the limiting wheels 342, and the aluminum profiles are inserted into the limiting grooves 301 and are connected with the limiting wheels 342 in a sliding mode.

The fixing mechanism 400 includes an air extractor 410 and an air extracting tube 420, an air extracting cavity is formed in the receiving block 270, a plurality of air extracting holes 401 are uniformly formed in one surface of the receiving block 270 opposite to the lateral bearing plate 110, and in this embodiment, the air extracting holes 401 are uniformly formed in two sides of the cutting groove 205. Further, the air exhaust holes 401 are uniformly opened on two sides of the cutting groove 205 in two rows. Each of the pumping holes 401 is communicated with a pumping chamber, and the air pump 410 is communicated with the pumping chamber through a pumping pipe 420. In this embodiment, the suction fan 410 is connected to the transverse carrier plate 110.

During the operation of the aluminum profile high-precision cutting device 10, the aluminum profile to be cut is inserted between each driven wheel 335 in one conveying assembly 330 and each driven wheel 335 in the other conveying assembly 330 of the conveying mechanism 300. In a conveying assembly 330, a conveying motor 331 drives a conveying belt 332 to move through a driving wheel 334 arranged on a rotating shaft 333, the conveying belt 332 drives each rotating shaft 333 to rotate through each driving wheel 334, and a driven wheel 335 on each rotating shaft 333 rotates to convey the aluminum profile to the receiving block 270. The air extractor 410 performs air extraction, adsorption and fixation on the aluminum profile to be cut through the air extraction pipe 420 and the bearing block 270. The driving motor 220 drives the cutting blade 263 to penetrate into or penetrate out of the cutting groove 205 through the driving shaft 230, the cam 240, the driving column 250 and the receiving box 261, in the cutting process, the lead screw motor 262 drives the cutting motor to move back and forth, the cutting motor moves back and forth to drive the cutting blade 263 to move back and forth, and the cutting motor driving the cutting blade 263 to move back and forth rotates to cut the aluminum profile. After the cutting mechanism 200 cuts the aluminum profile, the two conveying motors 331 in the conveying mechanism 300 rotate for a preset time to convey the next aluminum profile to be cut to the receiving block 270, and the cut aluminum profile is ejected from the receiving block 270. The aluminum profile high-precision cutting equipment 10 is high in aluminum profile cutting speed and efficiency, and reduces the labor intensity of aluminum profile cutting.

In order to increase the working stability of the transmission mechanism 300, in one embodiment, the driven wheel 335 is provided with an anti-slip layer to increase the friction between the driven wheel 335 and the aluminum profile, and increase the stability of the driven wheel 335 driving the aluminum profile to move. In this embodiment, the skid resistant course is soft rubber cover, and soft rubber cover has certain elasticity, good toughness and non-skid property, and soft rubber cover can play good barrier propterty to the aluminium alloy, and simultaneously, soft rubber cover can increase from the frictional force between driving wheel 335 and the aluminium alloy. Further, the soft rubber sleeve is provided with anti-slip lines to further increase the friction between the driven wheel 335 and the aluminum profile, and further increase the stability of the driven wheel 335 driving the aluminum profile to move. In this manner, the presence of the slip resistant layer on the driven wheel 335 increases the operational stability of the transfer mechanism 300.

In order to filter the large particle debris and prevent the large particle debris from entering the air extractor 410, in one embodiment, the input end of the air extraction pipe 420 is provided with a filter screen. In this embodiment, the filter screen is the metal rubber filter screen, and the metal rubber filter screen adopts stainless steel wire to make, and the raw and other materials of metal rubber filter screen are stainless steel wire, have capillary loose structure, are particularly suitable for solving gas, liquid filtration problem under the environment such as high low temperature, big difference in temperature, high pressure, high vacuum, strong radiation, violent vibration and corruption. In another embodiment, the filter screen is an air conditioner filter screen which is in a concave-convex honeycomb structure, and the air conditioner filter screen can be widely applied to sewage filtration systems and air filtration. The air conditioner filter screen is easy to clean and replace for many times, and the acting time is long. And the air conditioner filter screen is convenient to clean. In another embodiment, the filter screen is a metal filter screen, and the metal filter screen is formed by rolling a plurality of layers of expanded aluminum foil screens or stainless steel screens into a wave net shape and overlapping the expanded aluminum foil screens or the stainless steel screens in a crossed manner at a correct angle, so that the flow direction of the waste water is changed for a plurality of times when the waste water passes through the filter screen, and the filtering effect of the waste water is improved. In another embodiment, the filter screen is a ventilation filter screen which has the best acid and alkali resistance and corrosion resistance, low resistance, repeated cleaning and relatively high economical efficiency. Thus, the filter screen disposed at the input end of the exhaust tube 420 prevents large particles from entering the air extractor 410.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. The utility model provides an aluminium alloy high accuracy cutting equipment which characterized in that includes: the device comprises a bearing frame, a cutting mechanism, a conveying mechanism and a fixing mechanism;

the bearing frame comprises a transverse bearing plate and a vertical bearing plate, and the vertical bearing plate is vertically connected with the transverse bearing plate;

the cutting mechanism comprises a bearing box, a driving motor, a driving shaft, a cam, a driving column, a cutting assembly, a bearing block, two connecting columns and two extension springs; the driving motor and the bearing box are arranged on the vertical bearing plate from top to bottom; the driving motor is in driving connection with the cam through the driving shaft, a sliding groove is formed in the periphery of the cam, a sliding block is arranged at one end of the driving column, and the sliding block is inserted into the sliding groove and is in sliding connection with the cam; the cutting assembly comprises a bearing box, a screw rod motor, a cutting motor and a cutting blade; the screw rod motor is connected with the receiving box, the screw rod motor is in driving connection with the cutting motor, the cutting motor is in driving connection with the cutting blade, and the cutting motor is accommodated in the receiving box; the bearing box is provided with a through hole, and one end of the driving column, which is far away from the sliding block, penetrates through the through hole and is connected with the bearing box; the two connecting columns are arranged on two sides of the driving column and are connected with the bearing box; each connecting column is connected with the inner side wall of the bearing box through one extension spring; sliding grooves are formed in two parallel inner side walls of the bearing box, sliding blocks are arranged at two ends of the bearing box, and each sliding block is inserted into one sliding groove and is connected with the bearing box in a sliding mode; one surface of the bearing box, which is back to the driving column, is provided with a cutting opening, and the cutting blade is partially exposed out of the cutting opening; the bearing block is connected with the transverse bearing plate, one surface of the bearing block, which is back to the transverse bearing plate, is uniformly provided with cutting grooves, and the driving motor drives the cutting blade to penetrate into or penetrate out of the cutting grooves through the driving shaft, the cam, the driving column and the bearing box;

the conveying mechanism is arranged on one side of the bearing block; the conveying mechanism comprises a connecting plate, a bearing plate, two conveying assemblies and a plurality of limiting assemblies; the connecting plate and the bearing plate are arranged in parallel and are connected with the transverse bearing plate; the two conveying assemblies are arranged up and down and comprise conveying motors, conveying belts and a plurality of rotating shafts; the conveying motors in the two conveying assemblies are arranged on the connecting plate up and down; each rotating shaft penetrates through the bearing plate and is in rotating connection with the bearing plate; one end of the rotating shaft is provided with a driving wheel, and the other end of the rotating shaft is provided with a driven wheel; the conveying motor drives the conveying belt to move through a driving wheel arranged on the rotating shaft, the conveying belt drives the rotating shafts to rotate through the driving wheels, and the driven wheels on the rotating shafts rotate to convey the aluminum profile to the bearing block; the aluminum profile is transmitted between the driven wheels in the two transmission assemblies which are arranged up and down; each limiting component is uniformly arranged on two sides of the driven wheel and comprises a rotating column and a limiting wheel; each rotating column is uniformly arranged on two sides of the driven wheel, and each rotating column is rotatably connected with one limiting wheel; the side wall of each limiting wheel is provided with a limiting groove, and an aluminum profile is inserted into each limiting groove and is connected with each limiting wheel in a sliding manner;

the fixing mechanism comprises an air pump and an air pumping pipe, the bearing block is provided with an air pumping cavity, one surface of the bearing block, which faces away from the transverse bearing plate, is uniformly provided with a plurality of air pumping holes, each air pumping hole is communicated with the air pumping cavity, and the air pump is communicated with the air pumping cavity through the air pumping pipe.

2. The aluminum profile high-precision cutting equipment according to claim 1, wherein the air exhaust holes are uniformly formed in two sides of the cutting groove.

3. The aluminum profile high-precision cutting equipment as claimed in claim 2, wherein the driving motor is a stepping motor.

4. The aluminum profile high-precision cutting equipment as claimed in claim 3, wherein the driving motor is a servo motor.

5. The aluminum profile high-precision cutting equipment according to claim 4, wherein a filter screen is arranged at the input end of the exhaust tube.

6. The aluminum profile high-precision cutting equipment as claimed in claim 5, wherein the filter screen is an air conditioner filter screen.

7. The aluminum profile high-precision cutting equipment according to claim 5, wherein the filter screen is a metal filter screen.

8. The aluminum profile high-precision cutting equipment according to claim 5, wherein the filter screen is a ventilation filter screen.

9. The aluminum profile high-precision cutting equipment according to claim 5, wherein the filter screen is a metal rubber filter screen.

10. The aluminum profile high-precision cutting equipment according to claim 1, wherein the air exhaust holes are uniformly arranged on two sides of the cutting groove in two rows.

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