CN212793900U - Novel high-precision machining center equipment for mechanical die - Google Patents

Abstract

The utility model discloses a novel high accuracy mechanical die machining center equipment relates to the processing equipment field. The structure of the utility model comprises a box body, the front side of the top of the box body is fixedly connected with a front side support, the rear side of the top of the box body is fixedly connected with a rear side support, the bottom of the box body is connected with universal wheels, and the box body plays a role in protection and support; the control panel is arranged in the groove on the outer wall of the left side of the box body and controls the operation of control equipment; the polishing device is arranged on the moving box on the right side of the bottom of the support and is used for polishing edges and corners left after cutting; the cutting device is arranged in a cavity between the box body and the support and is used for cutting the die; the turnover device is arranged at the right end of the top of the box body and is used for turning over the die for processing. The utility model discloses a full-automatic structure and turn-over device can realize the continuous automatic processing to mould top and bottom.

Description

Novel high-precision machining center equipment for mechanical die

Technical Field

The invention relates to the field of processing equipment, in particular to novel high-precision machining center equipment for a mechanical die.

Background

The mould is various moulds and tools for obtaining required products by injection moulding, blow moulding, extrusion, die casting or forging forming, smelting, stamping and other methods in industrial production, and the mould is usually made of alloy materials. The mould processing equipment of prior art needs the manual work to carry out mould processing with the mode of machine cooperation more, extravagant manpower. In the prior art, only one surface of the die can be machined by one-time machining program, so that the machining efficiency is reduced.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that it is relatively poor to overcome prior art automation performance, and a procedure only processes the mould one side.

In order to solve the above technical problems, the present invention provides a novel high-precision machining center for mechanical molds, comprising,

the box body is provided with grooves on the outer walls of the top and the left side of the box body, the front side of the top plane of the box body is lower than the rear side of the top plane of the box body, the front side of the top of the box body is fixedly connected with a front side bracket, the rear side of the top of the box body is fixedly connected with a rear side bracket, three movable boxes are respectively arranged at the bottom of the front side bracket and the bottom of the rear side bracket, universal wheels are connected with the bottom of the box body, and the box;

the control panel is arranged in a groove in the outer wall of the left side of the box body, a circuit behind the control panel is connected with a driving motor, an air cylinder and a power supply in the equipment, and the control panel controls the operation of the control equipment;

the polishing device is arranged on the moving box on the right side of the bottom of the support, and polishes the edges and corners left after cutting for fine processing;

the cutting device is arranged in a cavity between the box body and the support and comprises a large-size cutting device, the top of the large-size cutting device is connected to the movable box on the left side of the bottom of the support, and the large-size cutting device cuts a processing die; the small-size cutting device is connected to the adjacent moving box of the large-size cutting device, and finely cuts the machining die;

the turnover device is arranged at the right end of the top of the box body and comprises a mechanical plate, the mechanical plate is arranged on the front side of a high plane of the top of the box body, the bottom of the mechanical plate is fixedly connected with one end of a third cylinder, and the mechanical plate overturns and carries the die; the third cylinder is arranged at the joint of a high plane and a low plane at the top of the box body, the other end of the third cylinder is fixedly connected to a first power shaft, the first power shaft is connected with a driving motor, the third cylinder drives the mechanical plate to move left and right, and the first power shaft and the driving motor drive the third cylinder to rotate back and forth; the four cylinders are arranged on the front side of the conveying belt on the high plane at the top of the box body and fixed in the groove at the top of the box body, the top of the four cylinders is fixedly connected with the baffle, and the four cylinders drive the baffle to move up and down so as to block the mold on the conveying belt.

As a further aspect of the present invention: the mechanical plate comprises a fixed plate, the fixed plate is fixedly connected to the third cylinder, the front end and the rear end of the fixed plate are respectively connected with a rotating plate through spring pieces, and the fixed plate covers the die, so that the die is convenient to carry; the fifth cylinder is arranged in grooves at the front end and the rear end of the fixed plate, the sixth cylinder is fixedly connected in the groove at the rear end of the fifth cylinder, and the fifth cylinder and the sixth cylinder prop out of the rotating plate to enable the rotating plate to rotate upwards; the grabbing plate is arranged at the upper ends of the two rotating plates, the bottom of the grabbing plate extends into the rotating plates, the bottom of the grabbing plate is fixedly connected to the seventh air cylinder, and the grabbing plate can slide in a grabbing plate sliding groove to fix or loosen the die; the seven cylinders are arranged in grooves in the upper ends of the rotating plates and are fixedly connected with the bottoms of the grabbing plates, and the seven cylinders drive the grabbing plates to move back and forth so as to fix or loosen the die.

As a further aspect of the present invention: the cutting device comprises a cutting knife, the cutting knife is arranged at the bottommost end of the cutting device and is connected with a first driving motor through a power shaft, and the cutting knife is used for processing a die; the first driving motor is fixed in the first protective shell and drives the cutting knife to rotate; the two ends of the first air cylinder are respectively connected to the bottom end of the second air cylinder and the outer wall of the first protective shell through rotating shafts, and the first air cylinder stretches and retracts to change the angle between the first protective shell and the second air cylinder; the second cylinder is arranged in a groove of the second protective shell, the top of the second cylinder is fixedly connected with a second driving motor, the bottom of the second cylinder is connected with the first protective shell through a rotating shaft, and the second cylinder stretches to enable the cutting knife to move up and down; no. two driving motor, No. two driving motor fix in No. two protecting sheathing's recess, No. two driving motor connects the top of No. two cylinders, No. two driving motor drive No. two cylinder horizontal rotation.

As a further aspect of the present invention: a conveying device is arranged in the groove in the top of the box body and comprises a conveying belt, a driving motor and a pulley, a partition plate is arranged on the surface of the conveying belt, and the partition plate is used for fixing the die.

As a further aspect of the present invention: the box body comprises a box body and is characterized in that two left side walls and two right side walls of the box body are respectively connected with a fixed support, the fixed supports are connected with the box body through rotating shafts, the fixed supports can rotate up and down around the rotating shafts, and the fixed supports are used for fixing equipment and preventing the equipment from sliding at will.

As a further aspect of the present invention: the box outer wall at the top of each fixing support is connected with a wrench, the wrench is connected with the box outer wall through a bearing, the wrench can rotate around the bearing, and the wrench can fix the fixing supports on the box outer wall, so that the equipment can be conveniently moved.

As a further aspect of the present invention: the inner structure of the moving box comprises a left guide cylinder and a right guide cylinder, the left guide cylinder and the right guide cylinder are arranged on the rear side of the moving box, the left end of the left guide cylinder and the right guide cylinder are fixedly connected with a front guide cylinder and a rear guide cylinder, the right end of the left guide cylinder and the right end of the right guide cylinder are fixedly connected with a large-size cutting device, a small-size cutting device or a polishing device, and the left guide cylinder and the right guide; and the front and rear guide cylinder is fixed at the front part of the movable box, and the front and rear guide cylinder driving device moves back and forth.

As a further aspect of the present invention: the rear end of the front side support is fixedly connected with the front end of the rear side support, the lower end of the connection part is provided with a separation plate, and the separation plate divides the front side processing area from the rear side processing area.

As a further aspect of the present invention: the front outer wall and the rear outer wall of the isolation plate are provided with grooves, water pipes are fixed in the grooves, the water pipes penetrate through the isolation plate to be connected with a high-pressure water pump fixedly connected to the outer wall of the right side of the isolation plate, the water pipes and the high-pressure water pump wash out waste residues generated in the machining of the die, and the water pipes and the high-pressure water pump cool the die in the machining process.

As a further aspect of the present invention: the side respectively is equipped with a wedge profile around the top of box, the wedge profile is the glide plane, the glide plane communicates the drain on the box outer wall, glide plane and drain make the sewage and the waste residue discharge apparatus who washes.

As a further aspect of the present invention: the cutting device and the polishing device are provided with two sets, the two sets of devices are respectively arranged in the front end region and the rear end region of the isolation plate, and the two sets of devices are used for processing the top and the bottom of the die respectively.

As a further aspect of the present invention: the universal wheels have four, four universal wheels are fixed in four angle departments of bottom half respectively through the support column, when the universal wheel supports the box, make things convenient for the removal of equipment.

The invention has the beneficial effects that:

(1) the utility model improves the cutting device, when cutting, the second cylinder extends, the first protective shell connected with the second cylinder moves downwards, and the cutting knife moves downwards to attach the die; a first driving motor drives a power shaft to rotate, a cutting knife connected with the power shaft rotates, and a die is machined; the first cylinder contracts, the second cylinder and the first protective shell form different angles through the first cylinder, and the cutting knife forms different angles to process the die; the second driving motor operates to drive the second air cylinder to horizontally rotate, and the cutting knife horizontally rotates to align to the cutting part of the die; the left and right guide cylinders contract to drive the cutting device to horizontally move leftwards; the front and back guide cylinders contract to drive the cutting device to move forwards and horizontally. The utility model discloses a full-automatic cutting structure realizes the full-automatic fine machining to the mould.

(2) The utility model is provided with the turnover device, the fifth cylinder extends, the fifth cylinder pushes the rotating plate out, and the rotating plate rotates upwards around the spring piece; the driving motor drives the first power shaft to rotate, the third air cylinder connected with the first power shaft rotates towards the front side, and the mechanical plate is clamped above the die; the sixth cylinder extends to abut against one end of the rotating plate, so that the rotating plate and the fixed plate form an angle of 90 degrees, and the fixed plate and the rotating plate are tightly attached to the outer wall of the mold; the seventh cylinder contracts to drive the grabbing plate to move inwards so that the grabbing plate is inserted into the bottom of the mold, and the mechanical plate grabs the mold; the driving motor drives the first power shaft to rotate, the third air cylinder turns to the rear side plane, the third air cylinder extends, and the mechanical plate is conveyed onto a conveying belt on the rear side of the box body; the seventh cylinder extends, the grabbing plate leaves the bottom of the mold, the fifth cylinder and the sixth cylinder contract, and the rotating plate rotates away under the elastic action of the spring piece; the fourth cylinder contracts and drives the baffle plate to move downwards so that the baffle plate moves to be horizontal to the center of the die; the third cylinder contracts, the third cylinder drives the mechanical plate to move forwards, and the baffle plate blocks the fixed die between the two partition plates on the conveyor belt; the conveyor belt moves to the left and transports the mold to the bottom of the mold under the device in the rear region of the dividing plate. The utility model discloses set up turn-over device, can realize saving manpower and time to the continuous automatic processing in mould top and bottom.

Drawings

FIG. 1 is a front view structural diagram of the present invention;

FIG. 2 is a rear view structural diagram of the present invention;

fig. 3 is a left side view of the present invention;

FIG. 4 is a view showing the construction of the cutting apparatus;

FIG. 5 is a view showing the construction of the turn-over apparatus;

FIG. 6 is a mechanical plate structure view;

fig. 7 is a structural view of the movable box.

Wherein: the device comprises a box body 1, a front side bracket 2, a large-size cutting device 3, a cutting knife 31, a first driving motor 32, a first protective shell 33, a rotating shaft 34, a first air cylinder 35, a second air cylinder 36, a second driving motor 37, a second protective shell 38, a small-size cutting device 4, a polishing device 5, a mold 6, a rear side bracket 7, a turn-over device 8, a mechanical plate 81, a fixing plate 810, a rotating plate 811, a fifth air cylinder 812, a sixth air cylinder 813, a seventh air cylinder 814, a grabbing plate 815, a spring plate 816, a grabbing plate chute 817, a third air cylinder 82, a first power shaft 83, a baffle 84, a fourth air cylinder 85, a conveyor belt 9, a universal wheel 10, a wrench 11, a fixing bracket 12, a water pipe 13, a high-pressure water pump 14, a partition board 15, a partition board 16, a sliding surface 17, a sewage draining outlet 18, a control panel 19, a movable box 20, a left and right guide air cylinders 201.

Detailed Description

The structure of the novel high-precision machining center device provided by the embodiment is shown in fig. 1-7, and comprises,

the box body 1 is provided with grooves on the outer walls of the top and the left side of the box body 1, the front side of the top plane of the box body 1 is low, and the rear side of the top plane of the box body 1 is high, the front side of the top of the box body 1 is fixedly connected with a front side bracket 2, the rear side of the top of the box body 1 is fixedly connected with a rear side bracket 7, the bottom of the front side bracket 2 and the bottom of the rear side bracket 7 are respectively provided with three movable boxes 20, the bottom of the box body 1 is connected with universal wheels 10, and;

the control panel 19 is arranged in a groove in the outer wall of the left side of the box body 1, a circuit behind the control panel 19 is connected with a driving motor, an air cylinder and a power supply in the equipment, and the control panel 19 controls the operation of the control equipment;

the polishing device 5 is arranged on the moving box 20 on the right side of the bottom of the support, and edges and corners left after cutting are polished by the polishing device 5 for fine machining;

the cutting device is arranged in a cavity between the box body 1 and the support and comprises a large-size cutting device 3, the top of the large-size cutting device 3 is connected to a movable box 20 on the left side of the bottom of the support, and the large-size cutting device 3 cuts the processing die 6; the small-size cutting device 4 is connected to the moving box 20 adjacent to the large-size cutting device 3, and the small-size cutting device 4 finely cuts the machining die 6;

the turnover device 8 is arranged at the right end of the top of the box body 1, the turnover device 8 comprises a mechanical plate 81, the mechanical plate 81 is arranged on the front side of a high plane at the top of the box body 1, the bottom of the mechanical plate 81 is fixedly connected with one end of a third air cylinder 82, and the mechanical plate 81 overturns the carrying mold 6; the third cylinder 82 is arranged at the joint of the high plane and the low plane at the top of the box body 1, the other end of the third cylinder 82 is fixedly connected to a first power shaft 83, the first power shaft 83 is connected with a driving motor, the third cylinder 82 drives the mechanical plate 81 to move left and right, and the first power shaft 83 and the driving motor drive the third cylinder 82 to rotate back and forth; no. four cylinders 85, No. four cylinders 85 set up in the conveyer belt 9 front side of box 1 top high plane, No. four cylinders 85 are fixed in the recess at box 1 top, No. four cylinder 85 top fixed connection baffle 84, No. four cylinder 85 drive baffle 84 reciprocates to keep off mould 6 on conveyer belt 9.

The mechanical plate 81 comprises a fixed plate 810, the fixed plate 810 is fixedly connected to the third cylinder 82, the front end and the rear end of the fixed plate 810 are respectively connected with a rotating plate 811 through spring pieces 816, and the fixed plate 810 covers the mold 6, so that the mold 6 is convenient to carry; the five-cylinder 812 is arranged in grooves at the front end and the rear end of the fixed plate 810, the six-cylinder 813 is fixedly connected in the groove at the rear end of the five-cylinder 812, and the five-cylinder 812 and the six-cylinder 813 push out of the rotating plate 811 to enable the rotating plate 811 to rotate upwards; the grabbing plate 815 is arranged at the upper ends of the two rotating plates 811, the bottom of the grabbing plate 815 is inserted into the rotating plates 811, the bottom of the grabbing plate 815 is fixedly connected to the seventh air cylinder 814, and the grabbing plate 815 can slide in a grabbing plate sliding groove 817 to fix or release the mold 6; the seven cylinder 814 is arranged in a groove at the upper end of the rotating plate 811, the seven cylinder 814 is fixedly connected with the bottom of the grabbing plate 815, and the seven cylinder 814 drives the grabbing plate 815 to move back and forth to fix or release the mold 6.

The cutting device comprises a cutting knife 31, the cutting knife 31 is arranged at the bottommost end of the cutting device, the cutting knife 31 is connected with a first driving motor 32 through a power shaft, and the cutting knife 31 is used for processing the die 6; the first driving motor 32 is fixed in the first protective shell 33, and the first driving motor 32 drives the cutting knife 31 to rotate; the two ends of the first air cylinder 35 are respectively connected to the bottom end of the second air cylinder 36 and the outer wall of the first protective shell 33 through rotating shafts, and the first air cylinder 35 stretches and retracts to change the angle between the first protective shell 33 and the second air cylinder 36; the second air cylinder 36 is arranged in a groove of the second protective shell 38, the top of the second air cylinder 36 is fixedly connected with a second driving motor 37, the bottom of the second air cylinder 36 is connected with the first protective shell 33 through a rotating shaft 34, and the second air cylinder 36 stretches to enable the cutting knife 31 to move up and down; no. two driving motor 37, No. two driving motor 37 are fixed in the recess of No. two protecting sheathing 38, No. two driving motor 37 connects the top of No. two cylinders 36, No. two driving motor 37 drive No. two cylinders 36 horizontal rotation.

A conveying device is arranged in a groove in the top of the box body 1 and comprises a conveying belt 9, a driving motor and pulleys, a partition plate 16 is arranged on the surface of the conveying belt 9, and the partition plate 16 is used for fixing the mold 6.

The left side wall and the right side wall of the box body 1 are respectively connected with a fixed support 12, the fixed supports 12 are connected with the box body 1 through rotating shafts, the fixed supports 12 can rotate up and down around the rotating shafts, and the fixed supports 12 fix equipment to prevent the equipment from sliding randomly.

Be connected with a spanner 11 on the 1 outer wall of box at each fixed bolster 12 top, spanner 11 passes through bearing and 1 outer wall connection of box, spanner 11 can rotate around the bearing, spanner 11 can fix fixed bolster 12 on the 1 outer wall of box, makes things convenient for the removal of equipment.

The internal structure of the moving box 20 comprises a left guide cylinder 201 and a right guide cylinder 201, the left guide cylinder 201 and the right guide cylinder 201 are arranged on the rear side of the moving box 20, the left end of the left guide cylinder 201 is fixedly connected with a front guide cylinder 202 and a rear guide cylinder 202, the right end of the left guide cylinder 201 is fixedly connected with a large-size cutting device 3, a small-size cutting device 4 or a grinding device 5, and a left guide cylinder 201 and a right guide cylinder 201 driving device move left and right; and a front and rear guide cylinder 202, wherein the front and rear guide cylinder 202 is fixed at the front part of the movable box 20, and the front and rear guide cylinder 202 drives the device to move back and forth.

The rear end of the front side bracket 2 is fixedly connected with the front end of the rear side bracket 7, the lower end of the connection part is provided with a separation plate 15, and the separation plate 15 divides the front side processing area from the rear side processing area.

The front outer wall and the rear outer wall of the isolation plate 15 are provided with grooves, water pipes 13 are fixed in the grooves, the water pipes 13 penetrate through the isolation plate 15 to be connected with high-pressure water pumps 14 fixedly connected to the right outer wall of the isolation plate 15, the water pipes 13 and the high-pressure water pumps 14 flush waste residues generated in the processing of the die 6, and the water pipes 13 and the high-pressure water pumps 14 cool the die 6 during the processing.

The side respectively is equipped with a wedge profile around the top of box 1, the wedge profile is smooth surface 17, smooth surface 17 communicates drain 18 on the box 1 outer wall, smooth surface 17 and drain 18 make the sewage and the waste residue discharge apparatus who washes.

The cutting device and the polishing device 5 are provided with two sets, the two sets are respectively arranged at the front end region and the rear end region of the isolation plate 15, and the two sets are used for respectively processing the top and the bottom of the die 6.

The universal wheels 10 are four, the four universal wheels 10 are fixed at four corners of the bottom of the box body 1 through support columns respectively, and the universal wheels 10 facilitate movement of equipment when supporting the box body 1.

The utility model discloses a theory of operation: when in use, a user operates the operation panel 19 to operate the equipment; clamping the die 6 between the partition plates 16 on the surface of the conveyor belt 9, rotating the conveyor belt 9 rightwards, and conveying the die 6 to the position right below the large-size cutting device 3; during cutting, the second cylinder 36 extends, the first protective shell 33 connected with the second cylinder 36 moves downwards, and the cutting knife 31 moves downwards to attach to the die 6; a first driving motor 32 drives the power shaft to rotate, and a cutting knife 31 connected with the power shaft rotates to machine the die 6; the first air cylinder contracts 35, the second air cylinder 36 and the first protective shell 33 are in different angles through the first air cylinder 35, and the cutting knife 31 is in different angles to process the die 6; the second driving motor 37 operates, the second driving motor 37 drives the second air cylinder 36 to horizontally rotate, and the cutting knife 31 horizontally rotates to align to the cutting part of the die 6; the left and right guide cylinders 201 contract to drive the cutting device 3 to horizontally move leftwards; the front and rear guide cylinders 202 contract to drive the cutting device 3 to move forwards and horizontally; after the large-size cutting device 3 finishes processing, the conveyor belt 9 continues to rotate rightwards, and the die 6 is conveyed to the small-size cutting device 4 for fine processing; after the small-size cutting device 4 finishes processing, the conveyor belt 9 continues to rotate rightwards, and the die 6 is conveyed to the lower part of the grinding device 5 for grinding processing; after the top of the mold 6 is machined, the turnover device 8 operates to continue machining the bottom of the mold. The utility model discloses a full-automatic structure realizes the full-automatic processing to the mould.

The fifth cylinder 812 extends, the fifth cylinder 812 pushes the rotating plate 811 out, and the rotating plate 811 rotates upwards around the spring 816; the driving motor drives the first power shaft 83 to rotate, the third air cylinder 82 connected with the first power shaft 83 rotates towards the front side, and the mechanical plate 81 is clamped above the die 6; the sixth cylinder 813 extends, the sixth cylinder 813 props against one end of the rotating plate 811, so that the rotating plate 811 and the fixing plate 810 form an angle of 90 degrees, and the fixing plate 810 and the rotating plate 811 are tightly attached to the outer wall of the mold 6; the seven cylinder 814 is contracted, the seven cylinder 814 drives the gripping plate 815 to move inwards, so that the gripping plate 815 is inserted into the bottom of the mold 6, and the mechanical plate 81 grips the mold 6; the driving motor drives the first power shaft 83 to rotate, the third air cylinder 82 turns to the rear side plane, the third air cylinder 82 extends, and the mechanical plate 81 is conveyed to the rear side conveying belt 9 of the box body 1; the seventh cylinder 814 is extended, the gripping plate 815 leaves the bottom of the mold 6, the fifth cylinder 812 and the sixth cylinder 813 are contracted, and the rotating plate 811 rotates away under the elastic action of the spring 816; the fourth cylinder 85 contracts, and the fourth cylinder 85 drives the baffle 84 to move downwards, so that the baffle 84 moves to be horizontal to the center of the mold 6; the third cylinder 82 contracts, the third cylinder 82 drives the mechanical plate 81 to move forwards, and the baffle plate 84 blocks the fixed die 6 between the two partition plates 16 on the conveyor belt 9; the conveyor 9 moves to the left and transports the mould 6 under the device in the rear area of the separating plate 15 for processing the bottom of the mould 6. The utility model discloses set up turn-over device 8, can realize practicing thrift manpower and time to 6 tops of mould and the continuous automatic processing in bottom.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (6)

1. A novel high-precision machining center device for mechanical dies is characterized by comprising,

the box body (1), the outer walls of the top and the left side of the box body (1) are provided with grooves, the front side of the top plane of the box body (1) is low, the rear side of the top plane of the box body (1) is high, the front side of the top of the box body (1) is fixedly connected with a front side bracket (2), the rear side of the top of the box body (1) is fixedly connected with a rear side bracket (7), the bottom of the front side bracket (2) and the bottom of the rear side bracket (7) are respectively provided with three movable boxes (20), the bottom of the box body (1) is connected with universal wheels (10), and;

the control panel (19) is arranged in a groove in the outer wall of the left side of the box body (1), a circuit behind the control panel (19) is connected with a driving motor, an air cylinder and a power supply in the equipment, and the control panel (19) controls the operation of the control equipment;

the polishing device (5) is arranged on the moving box (20) on the right side of the bottom of the support, and the polishing device (5) polishes edges and corners left after cutting for fine machining;

the cutting device is arranged in a cavity between the box body (1) and the support and comprises a large-size cutting device (3), the top of the large-size cutting device (3) is connected to a movable box (20) on the left side of the bottom of the support, and the large-size cutting device (3) cuts the processing die (6); the small-size cutting device (4) is connected to the moving box (20) adjacent to the large-size cutting device (3), and the small-size cutting device (4) finely cuts the machining die (6);

the turnover device (8) is arranged at the right end of the top of the box body (1), the turnover device (8) comprises a mechanical plate (81), the mechanical plate (81) is arranged on the front side of a high plane at the top of the box body (1), the bottom of the mechanical plate (81) is fixedly connected with one end of a third cylinder (82), and the mechanical plate (81) overturns the carrying mold (6); the third cylinder (82), the third cylinder (82) is arranged at the joint of a high plane and a low plane at the top of the box body (1), the other end of the third cylinder (82) is fixedly connected to a first power shaft (83), the first power shaft (83) is connected with a driving motor, the third cylinder (82) drives the mechanical plate (81) to move left and right, and the first power shaft (83) and the driving motor drive the third cylinder (82) to rotate back and forth; no. four cylinders (85), No. four cylinders (85) set up conveyer belt (9) front side at box (1) top high plane, No. four cylinders (85) are fixed in the recess at box (1) top, No. four cylinders (85) top fixed connection baffle (84), No. four cylinders (85) drive baffle (84) reciprocate to keep off mould (6) on conveyer belt (9).

2. The novel high-precision machining center device of claim 1, wherein:

the mechanical plate (81) comprises a fixed plate (810), the fixed plate (810) is fixedly connected to the third cylinder (82),

the front end and the rear end of the fixing plate (810) are respectively connected with a rotating plate (811) through spring pieces (816), and the fixing plate (810) covers the mold (6), so that the mold (6) is convenient to carry; the five-cylinder (812) is arranged in grooves at the front end and the rear end of the fixing plate (810), the six-cylinder (813) is fixedly connected in the groove at the rear end of the five-cylinder (812), and the five-cylinder (812) and the six-cylinder (813) prop out of the rotating plate (811) to enable the rotating plate (811) to rotate upwards; the grabbing plate (815) is arranged at the upper ends of the two rotating plates (811), the bottom of the grabbing plate (815) extends into the rotating plates (811), the bottom of the grabbing plate (815) is fixedly connected to the seven cylinders (814), and the grabbing plate (815) can slide in a grabbing plate sliding groove (817) to fix or release the mold (6); the seven-cylinder (814) is arranged in a groove in the upper end of the rotating plate (811), the seven-cylinder (814) is fixedly connected with the bottom of the grabbing plate (815), and the seven-cylinder (814) drives the grabbing plate (815) to move back and forth so as to fix or loosen the mold (6).

3. The novel high-precision machining center device of claim 1, wherein: the cutting device comprises a cutting knife (31), the cutting knife (31) is arranged at the bottommost end of the cutting device, the cutting knife (31) is connected with a first driving motor (32) through a power shaft, and the cutting knife (31) is used for machining the die (6); the first driving motor (32), the first driving motor (32) is fixed in the first protective shell (33), and the first driving motor (32) drives the cutting knife (31) to rotate; the two ends of the first air cylinder (35) are respectively connected to the bottom end of the second air cylinder (36) and the outer wall of the first protective shell (33) through rotating shafts, and the first air cylinder (35) stretches and retracts to change the angle between the first protective shell (33) and the second air cylinder (36); the second air cylinder (36) is arranged in a groove of a second protective shell (38), the top of the second air cylinder (36) is fixedly connected with a second driving motor (37), the bottom of the second air cylinder (36) is connected with a first protective shell (33) through a rotating shaft (34), and the second air cylinder (36) stretches to enable the cutting knife (31) to move up and down; no. two driving motor (37), No. two driving motor (37) are fixed in the recess of No. two protecting sheathing (38), No. two driving motor (37) are connected the top of No. two cylinder (36), No. two driving motor (37) drive No. two cylinder (36) horizontal rotation.

4. The novel high-precision machining center device of claim 1, wherein: the box body (1) is characterized in that the left side wall and the right side wall of the box body (1) are respectively connected with a fixed support (12), the fixed supports (12) are connected with the box body (1) through rotating shafts, the fixed supports (12) can rotate up and down around the rotating shafts, and the fixed supports (12) fix equipment and prevent the equipment from sliding randomly.

5. The novel high-precision machining center device of claim 4, wherein: be connected with one spanner (11) on box (1) outer wall at each fixed bolster (12) top, spanner (11) pass through bearing and box (1) outer wall connection, spanner (11) can rotate around the bearing, spanner (11) can be fixed bolster (12) on box (1) outer wall, make things convenient for the removal of equipment.

6. The novel high-precision machining center device of claim 1, wherein: the inner structure of the moving box (20) comprises a left guide cylinder and a right guide cylinder (201), the left guide cylinder and the right guide cylinder (201) are arranged on the rear side of the moving box (20), the left end of the left guide cylinder and the right end of the left guide cylinder (201) are fixedly connected with a front guide cylinder and a rear guide cylinder (202), the right end of the left guide cylinder and the right guide cylinder (201) are fixedly connected with a large-size cutting device (3), a small-size cutting device (4) or a grinding device (5), and a driving device of the left guide cylinder and the right; the front and rear guide cylinder (202), the front and rear guide cylinder (202) is fixed in the front of the movable box (20), and the front and rear guide cylinder (202) driving device moves back and forth.

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