CN116252177B

CN116252177B - Automatic control machine tool convenient for installing cutter

Info

Publication number: CN116252177B
Application number: CN202310511021.9A
Authority: CN
Inventors: 田冰; 栗永非; 王银明; 闫敏; 常继兵; 赵志鲁; 刘广耀; 郭亚蒲; 李志远
Original assignee: Xinxiang Vocational and Technical College
Current assignee: Xinxiang Vocational and Technical College
Priority date: 2023-05-09
Filing date: 2023-05-09
Publication date: 2023-08-04
Anticipated expiration: 2043-05-09
Also published as: CN116252177A

Abstract

The invention discloses an automatic control machine tool convenient for installing a cutter, which belongs to the technical field of machining equipment and comprises a moving mechanism, a fixing mechanism, a cutter installing mechanism and a hairbrush, wherein the moving mechanism is provided with a moving block and a three-dimensional moving assembly, the three-dimensional moving assembly is arranged on the side surface of the fixing mechanism, the cutter installing mechanism is provided with a clamp, a locking assembly and a cutter installing assembly, the clamp is connected with the cutter installing assembly, the cutter installing assembly is connected with the locking assembly, the locking assembly is connected with the moving block, the moving block is connected with the three-dimensional moving assembly, and the three-dimensional moving assembly drives the moving block to move in three degrees of freedom.

Description

Automatic control machine tool convenient for installing cutter

Technical Field

The invention relates to the technical field of machining equipment, in particular to an automatic control machine tool convenient for installing a cutter.

Background

The numerical control machine is an abbreviation of numerical control machine, and is an automatic machine provided with a program control system; the control system can logically process a program defined by a control code or other symbolic instruction, decode the program, and input the program into the numerical control device through an information carrier by using a coded digital representation; the numerical control device sends various control signals to control the action of the machine tool through operation, and parts are automatically machined according to the shape and the size required by a drawing, so that the following defects exist in the prior art: the existing numerical control machine tool needs a technician to manually position, debug and replace the tool when the tool is replaced, the replacement difficulty is high, time and labor are wasted, the tool is inconvenient for common personnel to replace by oneself, and in the use process, the tool is easy to damage due to high stress intensity, so that the numerical control machine tool convenient for installing the tool is necessary.

The bulletin number is: the Chinese patent of CN113319601B discloses a numerical control machine tool convenient for replacing a cutter, and the technical scheme of the invention is as follows: the automatic control machine tool comprises a machine tool, wherein driving devices are fixedly installed on the top ends of two sides of the outer wall of the machine tool through right angle frames, the front ends of the driving devices are connected with movable clamping devices in a meshed mode, the movable clamping devices are connected with limiting devices in a threaded mode, cutter positioning devices are connected between the movable clamping devices in a clamping mode, the bottom ends of the cutter positioning devices are connected with cutters in a threaded mode, and the top ends of the cutter positioning devices are connected with the inside of a damping disc in a clamping mode.

Disclosure of Invention

The technical scheme adopted by the invention aiming at the technical problems is as follows: the utility model provides an automatic control lathe convenient to installation cutter, including moving mechanism, brush, fixed establishment and dress sword mechanism, moving mechanism is provided with movable block and three-dimensional motion subassembly, and three-dimensional motion subassembly is installed in the fixed establishment side, dress sword mechanism is provided with anchor clamps, locking component and dress sword subassembly, and anchor clamps link to each other with dress sword subassembly, are equipped with the cutter on the anchor clamps, and dress sword subassembly is provided with the movable frame, and anchor clamps slidable mounting is on the movable frame, and the movable frame links to each other with the locking component, and the movable block links to each other with three-dimensional motion subassembly, and three-dimensional motion subassembly drives the movable block and carries out the motion of three degree of freedom directions.

The locking assembly is provided with connecting block and fixed disk continuously, connecting block and movable block fixed connection, and the side fixed mounting of connecting block towards anchor clamps has the fixed disk, and the side of connecting block installation fixed disk is provided with a plurality of locking holes along circumferencial direction equidistant, and the side slidable mounting that the anchor clamps was kept away from to the connecting block has the fourth motor, and fourth motor output fixed mounting has the movable disk, and movable frame slidable mounting is on the movable disk, and the side fixed mounting that the anchor clamps was kept away from to the connecting block has the electric jar, electric jar flexible end and fourth motor fixed connection.

Further, the fixed disk is annular, the projection of the locking hole on the side surface of the fixed disk is positioned in the inner ring of the fixed disk, the connecting block is fixedly arranged on the side surface of the connecting block towards the clamp, and the projection of the contact switch on the side surface of the fixed disk is positioned in the inner ring of the fixed disk.

Further, the movable disc and the fixed disc are coaxial, the diameter of the movable disc is equal to the diameter of the inner wall of the fixed disc, an iron block is fixedly arranged on the movable disc towards the side face of the fixed disc, four magnets are fixedly arranged on the connecting block towards the side face of the clamp, and the projection of each magnet on the side face of the fixed disc is located in the inner ring of the fixed disc.

Further, the magnets are distributed on the side face of the connecting block at equal intervals along the circumferential direction, each magnet is not contacted with the contact switch, and each magnet is not contacted with the locking hole.

Further, the locking assembly is further provided with an electromagnet, the electromagnet is fixedly arranged on the side face, facing the clamp, of the movable disc, a groove is formed in the side face, facing the movable disc, of the clamp, and the cross section shape and the cross section size of the groove and the electromagnet of the clamp are consistent.

Further, the side face of the movable frame facing the movable disc is provided with four cylindrical protrusions, the end face of the cylindrical protrusion of the movable frame is hemispherical, the radius of the cylindrical protrusion of the movable frame is equal to that of the locking hole, and the side faces of the two cylindrical protrusions of the movable frame are provided with grooves.

Further, two mounting tables are fixedly mounted on the side face, facing the moving disc, of the clamp at equal intervals along the circumferential direction, a groove rod is rotatably mounted on each mounting table, and each groove rod is rotatably connected with a cylindrical protrusion, provided with a groove, of the moving frame.

Further, the locking component is also provided with a fixed rod, the side surface of the groove rod is provided with a sliding groove, a fixed shaft is slidably arranged in the sliding groove of the groove rod, the fixed shaft is fixedly arranged on the side surface of the fixed rod, and the fixed rod is fixedly arranged on the side surface of the movable disc, which faces the clamp.

Further, when the clamp groove contacts the end face of the electromagnet, the side face of the groove rod is parallel to the end face of the clamp, and a gap is reserved between the cylindrical protrusion of the movable frame and the locking hole.

Compared with the prior art, the invention has the beneficial effects that: (1) 1: when the cutter is replaced, the cutter head is automatically reset to adjust the position of the cutter to a proper position, so that the cutter is prevented from falling into the machine tool; (2) When the cutter is absent on the cutter disc, the cutter disc is automatically locked, and when the cutter is reset, the cutter disc is unlocked, so that the cutter is convenient to install; (3) When the cutter is replaced, the workpiece automatically retreats, the outer surface of the workpiece is cleaned in the retreating process of the workpiece, and the influence of the residue of scraps on subsequent processing is avoided.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present invention.

Fig. 2 is a schematic view of a three-dimensional motion assembly according to the present invention.

Fig. 3 is a partially enlarged schematic view of fig. 2 at a.

FIG. 4 is a schematic diagram of the connection between the moving mechanism and the fixed mechanism according to the present invention.

Fig. 5 is a schematic diagram of the positional relationship between a fixed plate and a movable block according to the present invention.

Fig. 6 is a partially enlarged schematic view of fig. 5 at B.

Fig. 7 is an enlarged partial schematic view at C in fig. 5.

Fig. 8 is a schematic view of the knife assembly of the present invention.

Fig. 9 is a partially enlarged schematic view of fig. 8 at D.

FIG. 10 is a schematic view of the locking assembly of the present invention.

Fig. 11 is a partially enlarged schematic illustration of fig. 10 at E.

Reference numerals: 1-a moving mechanism; 2-a fixing mechanism; 3-a knife loading mechanism; 4-hairbrush; 101-a fixed plate; 102-a first motor; 103-a first scaffold; 104-a first slide bar; 105-a first screw; 106-moving the plate; 107-a second motor; 108-a second scaffold; 109-a second screw; 110-a second slide bar; 111-moving blocks; 112-a third motor; 113-a third bracket; 114-a third slide bar; 115-a third screw; 116-displacement block; 117-follower block; 201-a bottom plate; 202-clamping a plate; 203-a bed body; 301-clamping; 302-a mobile rack; 303-connecting plates; 304-connecting blocks; 305-moving the disc; 306-a fixed disk; 307-electric cylinder; 308-fourth motor; 309-guard plate; 310-locking holes; 311-contact switch; 312-magnet; 313-iron block; 314-an electromagnet; 315-slot bar; 316-a fixed rod; 317-fixed shaft; 318-mount.

Detailed Description

The technical scheme of the invention is further described in the following by combining with the specific embodiments.

As shown in fig. 1 to 11, a moving mechanism 1 is provided with a moving block 111 and a three-dimensional moving component, the three-dimensional moving component is arranged on the side surface of a fixed mechanism 2, a knife loading mechanism 3 is provided with a clamp 301, a locking component and a knife loading component, the clamp 301 is connected with the knife loading component, a knife is arranged on the clamp 301, the knife loading component is provided with a moving frame 302, the clamp 301 is slidably arranged on the moving frame 302, the moving frame 302 is connected with the locking component, the moving block 111 is connected with the three-dimensional moving component, and the three-dimensional moving component drives the moving block 111 to move in three degrees of freedom; the locking assembly is provided with a connecting block 304 and a fixed disc 306 which are connected, the connecting block 304 is fixedly connected with the movable block 111, the fixed disc 306 is fixedly arranged on the side surface of the connecting block 304, which faces the clamp 301, a plurality of locking holes 310 are formed in the side surface of the connecting block 304, which faces away from the clamp 301, at equal intervals in the circumferential direction, a fourth motor 308 is slidably arranged on the side surface of the connecting block 304, which faces away from the clamp 301, a movable disc 305 is fixedly arranged at the output end of the fourth motor 308, a movable frame 302 is slidably arranged on the movable disc 305, an electric cylinder 307 is fixedly arranged on the side surface of the connecting block 304, which faces away from the clamp 301, and the telescopic end of the electric cylinder 307 is fixedly connected with the fourth motor 308.

As shown in fig. 2 to 11, the fixed disk 306 is annular, projections of the locking holes 310 on the side surface of the fixed disk 306 are all located in the inner ring of the fixed disk 306, the connecting block 304 is fixedly provided with a contact switch 311 towards the side surface of the clamp 301, and projections of the contact switch 311 on the side surface of the fixed disk 306 are all located in the inner ring of the fixed disk 306; the movable disc 305 and the fixed disc 306 are coaxial, the diameter of the movable disc 305 is equal to the diameter of the inner wall of the fixed disc 306, an iron block 313 is fixedly arranged on the side surface of the movable disc 305 facing the fixed disc 306, four magnets 312 are fixedly arranged on the side surface of the connecting block 304 facing the clamp 301, and the projection of each magnet 312 on the side surface of the fixed disc 306 is positioned in the inner ring of the fixed disc 306; the magnets 312 are equally spaced apart in the circumferential direction on the side of the connection block 304, each magnet 312 is not in contact with the contact switch 311, each magnet 312 is not in contact with the locking hole 310, and the contact switch 311 is electrically connected to the third motor 112.

As shown in fig. 2 to 10, the locking assembly is further provided with an electromagnet 314, the electromagnet 314 is fixedly arranged on the side surface of the movable disc 305 facing the clamp 301, the side surface of the clamp 301 facing the movable disc 305 is provided with a groove, and the cross section shape and the size of the groove of the clamp 301 are consistent with those of the electromagnet 314; the side of the movable frame 302 facing the movable disk 305 is provided with four cylindrical protrusions, the end faces of the cylindrical protrusions of the movable frame 302 are hemispherical, the radius of the cylindrical protrusions of the movable frame 302 is equal to that of the locking holes 310, and the side faces of the two cylindrical protrusions of the movable frame 302 are provided with grooves.

As shown in fig. 3 to 11, two mounting tables 318 are fixedly mounted on the side surface of the clamp 301 facing the moving disc 305 at equal intervals in the circumferential direction, a groove rod 315 is rotatably mounted on each mounting table 318, and each groove rod 315 is rotatably connected with a cylindrical protrusion provided with a groove of the moving frame 302; the locking assembly is further provided with a fixed rod 316, a chute is arranged on the side face of the chute rod 315, a fixed shaft 317 is slidably arranged in the chute of the chute rod 315, the fixed shaft 317 is fixedly arranged on the side face of the fixed rod 316, and the fixed rod 316 is fixedly arranged on the side face of the movable disc 305 facing the clamp 301; when the groove of the clamp 301 contacts the end face of the electromagnet 314, the side face of the groove rod 315 is parallel to the end face of the clamp 301, and at this time, the cylindrical protrusion of the moving frame 302 is spaced from the locking hole 310.

As shown in fig. 1 to 6, the first motor 102 is fixedly installed on the side of the first bracket 103, the first bracket 103 is fixedly installed on the side of the fixed plate 101, the fixed plate 101 is fixedly installed on the bed 203, the fixed plate 101 is fixedly installed with the first sliding rod 104, the fixed plate 101 is rotatably installed with the first screw rod 105, the first screw rod 105 is fixedly installed with the output end of the first motor 102, the first screw rod 105 and the moving plate 106 form a spiral fit, the moving plate 106 is slidably installed on the outer surface of the first sliding rod 104, the upper side of the moving plate 106 is fixedly installed with the second bracket 108, the second bracket 108 is fixedly installed with the second motor 107, the output end of the second motor 107 is fixedly installed with the second screw rod 109, the second screw rod 109 and the moving block 111 form a spiral fit, the moving plate 106 is fixedly installed with the second sliding rod 110, the moving block 111 is slidably installed on the outer surface of the second sliding rod 110, the side of the bed 203 is fixedly installed with the third bracket 113, the third bracket 113 is fixedly provided with a third motor 112, the bed body 203 is fixedly provided with a third slide bar 114, the output end of the third motor 112 is fixedly provided with a third screw rod 115, the third screw rod 115 and a displacement block 116 form spiral fit, the displacement block 116 is fixedly arranged at the lower side of a bottom plate 201, the lower side of the bottom plate 201 is fixedly provided with a following block 117, the following block 117 is slidably arranged on the outer surface of the third slide bar 114, the bottom plate 201 is slidably arranged at the upper side of the bed body 203, the upper side of the bed body 203 is slidably provided with a clamping plate 202, the clamping plate 202 is provided with threads, a screw rod is connected between the clamping plate 202 and the bottom plate 201, the screw rod and the threads on the clamping plate 202 form spiral fit, the clamping plate 202 is driven to slide along the surface of the bottom plate 201 through the threaded screw rod, thereby realizing the clamping of a workpiece, the bed body 203 is fixedly provided with a brush 4, the side surface of the moving block 111 is fixedly provided with a connecting plate 303, the connecting plate 303 is fixedly arranged on the side surface of the connecting block 304, a guard plate 309 is fixedly arranged on the inner side of the connecting plate 303, and a fourth motor 308 is slidably arranged on the inner side of the guard plate 309.

The working principle of the device is as follows.

Firstly, before starting working, a workpiece is placed on the bottom plate 201, then the clamping plate 202 is driven to move by rotating a screw rod between the clamping plate 202 and the bottom plate 201, so that the workpiece is clamped, then the moving block 111 is driven to move by rotating the first motor 102 and the second motor 107, so that the position of the moving block 111 is adjusted, the bottom plate 201 is driven to move by starting the third motor 112, so that the position of the workpiece is adjusted, and further the machining is facilitated.

When the tool is installed, the clamp 301 is pushed, the electromagnet 314 is started, the installation table 318 is driven to move when the clamp 301 moves, the installation table 318 drives the groove rod 315 to move, the moving frame 302 is driven to move through the fixed shaft 317, the moving frame 302 and the clamp 301 move in opposite directions, when the clamp 301 is stopped to move after being contacted with the electromagnet 314, the electric cylinder 307 is started, the electric cylinder 307 drives the fourth motor 308 to move backwards, the fourth motor 308 drives the moving disc 305 to move backwards, when the moving disc 305 contacts the contact switch 311, the iron block 313 is driven to move through magnetism of the magnet 312, the iron block 313 drives the moving disc 305 to rotate, and further the clamp 301 is driven to rotate, so that the clamp 301 is adjusted to an angle suitable for installing the tool, meanwhile, the contact switch 311 sends an electric signal to the third motor 112, the third motor 112 drives the base plate 201 to move away from the clamp 301 through the third screw 115, and the tool is installed on the clamp 301.

And thirdly, when the cutter is replaced, the electromagnet 314 stops working, the clamp 301 is reversely pushed out, the clamp 301 drives the mounting table 318 to move, the mounting table 318 drives the groove rod 315 to move, the groove rod 315 drives the movable frame 302 to move through the fixed rod 316, and therefore the cylindrical protrusion of the movable frame 302 is inserted into the locking hole 310, and locking is completed.

Claims

1. An automatic control lathe convenient to installation cutter, includes moving mechanism (1), brush (4), its characterized in that: the three-dimensional knife assembly device is characterized by further comprising a fixing mechanism (2) and a knife assembly mechanism (3), wherein the moving mechanism (1) is provided with a moving block (111) and a three-dimensional movement assembly, the three-dimensional movement assembly is arranged on the side face of the fixing mechanism (2), the knife assembly mechanism (3) is provided with a clamp (301), a locking assembly and a knife assembly, the clamp (301) is connected with the knife assembly, a knife is arranged on the clamp (301), the knife assembly is provided with a moving frame (302), the clamp (301) is slidably arranged on the moving frame (302), the moving frame (302) is connected with the locking assembly, the moving block (111) is connected with the three-dimensional movement assembly, and the three-dimensional movement assembly drives the moving block (111) to move in three degrees of freedom;

an iron block (313) is fixedly arranged on the moving disc (305) towards the side face of the fixed disc (306), four magnets (312) are fixedly arranged on the connecting block (304) towards the side face of the clamp (301), and the projection of each magnet (312) on the side face of the fixed disc (306) is positioned in the inner ring of the fixed disc (306);

the locking assembly is connected with a connecting block (304) and a fixed disc (306), the connecting block (304) is fixedly connected with the moving block (111), the fixed disc (306) is fixedly arranged on the side face, facing the clamp (301), of the connecting block (304), a plurality of locking holes (310) are formed in the side face, facing the clamp (301), of the connecting block (304 at equal intervals along the circumferential direction, a fourth motor (308) is slidably arranged on the side face, facing away from the clamp (301), of the connecting block (304), the moving disc (305) is fixedly arranged at the output end of the fourth motor (308), the moving frame (302) is slidably arranged on the moving disc (305), an electric cylinder (307) is fixedly arranged on the side face, facing away from the clamp (301), of the connecting block (304), and the telescopic end of the electric cylinder (307) is fixedly connected with the fourth motor (308);

the locking assembly is further provided with an electromagnet (314), the electromagnet (314) is fixedly arranged on the side surface of the movable disc (305) facing the clamp (301), a groove is formed in the side surface of the clamp (301) facing the movable disc (305), and the cross section shape and the cross section size of the groove of the clamp (301) are consistent with those of the electromagnet (314);

four cylindrical protrusions are arranged on the side face, facing the movable disc (305), of the movable frame (302), the end faces of the cylindrical protrusions of the movable frame (302) are hemispherical, the radius of the cylindrical protrusions of the movable frame (302) is equal to that of the locking holes (310), and grooves are formed on the side faces of the two cylindrical protrusions of the movable frame (302);

two mounting tables (318) are fixedly arranged on the side surface of the clamp (301) facing the moving disc (305) at equal intervals along the circumferential direction, a groove rod (315) is rotatably arranged on each mounting table (318), and each groove rod (315) is rotatably connected with a cylindrical protrusion provided with a groove of the moving frame (302);

the locking assembly is further provided with a fixed rod (316), a chute is arranged on the side face of the chute rod (315), a fixed shaft (317) is slidably arranged in the chute of the chute rod (315), the fixed shaft (317) is fixedly arranged on the side face of the fixed rod (316), and the fixed rod (316) is fixedly arranged on the side face of the movable disc (305) facing the clamp (301);

when the groove of the clamp (301) is contacted with the end face of the electromagnet (314), the side face of the groove rod (315) is parallel to the end face of the clamp (301), and a gap is reserved between the cylindrical protrusion of the movable frame (302) and the locking hole (310).

2. An automated control machine for facilitating the installation of tools as defined in claim 1, wherein: the fixed disk (306) is annular, projections of the locking holes (310) on the side face of the fixed disk (306) are all located in the inner ring of the fixed disk (306), the connecting block (304) is fixedly provided with the contact switch (311) towards the side face of the clamp (301), and projections of the contact switch (311) on the side face of the fixed disk (306) are all located in the inner ring of the fixed disk (306).

3. An automated control machine for facilitating the installation of tools as defined in claim 2, wherein: the movable disc (305) and the fixed disc (306) are coaxial, and the diameter of the movable disc (305) is equal to the diameter of the inner wall of the fixed disc (306).

4. An automated control machine for facilitating the installation of tools as defined in claim 3, wherein: the magnets (312) are distributed on the side surface of the connecting block (304) at equal intervals along the circumferential direction, each magnet (312) is not contacted with the contact switch (311), and each magnet (312) is not contacted with the locking hole (310).