CN114888340A - Clamping and milling system for boss surface of air inlet front cover plate - Google Patents

Abstract

The invention relates to a clamping and milling system for a boss surface of an air inlet front cover plate, which is provided with a main system seat, wherein a transmission belt is arranged at the left part of the main system seat; the upper right part of the main system seat is provided with a positioning convex round block, a main milling implementation system and two movable pressing and fixing devices. The front side and the rear side of the main system seat are respectively provided with a bottom groove, and each movable pressing and fixing device comprises a movable table which is arranged on the corresponding bottom groove in a sliding manner; the main milling implementation system consists of a milling cutter, an elevated seat fixedly arranged on the main system seat and a main milling auxiliary control device arranged on the elevated seat; the main milling auxiliary control device is matched with the milling cutter. The invention is convenient to position the workpiece, realizes automatic compaction of the workpiece and is relatively convenient to operate and use; the milling cutter can be controlled to respectively perform rotation, annular revolution, radial feeding and vertical feeding, so that the milling of the boss surface of the workpiece is realized in a high-automation mode.

Description

Clamping and milling system for boss surface of air inlet front cover plate

Technical Field

The invention relates to machining equipment in the field related to automobile part machining, in particular to a clamping and milling system for a boss surface of an air inlet front cover plate.

Background

With the continuous updating of automobile product technology and modeling, automobile accessory manufacturers need to have technical schemes to realize the processing of single accessories for each type of automobile, then form a local system, and finally form a complete machine by assembling in a host machine factory. The air inlet front cover plate is a part belonging to an automobile air inlet system, and structurally, a boss is usually arranged on the air inlet front cover plate to ensure the hardness of the air inlet front cover plate to resist the impact of multiple aspects such as air inlet and the like. And the boss part of the air inlet front cover plate needs to be subjected to semi-finishing in a milling mode on the surface according to the actual required size after rough machining and preliminary forming, but the clamping and subsequent milling processing of the boss part are difficult to realize by the conventional mechanical equipment and the conventional clamp at present.

Disclosure of Invention

In order to overcome the defects of the traditional mechanical equipment and the clamp, the invention provides a clamping and milling system for a boss surface of an air inlet front cover plate.

The technical problem to be solved by the invention is realized by adopting the following technical scheme:

the clamping and milling system for the boss surface of the air inlet front cover plate is provided with a main system seat, and a transmission belt is arranged on the left part of the main system seat; the upper right part of the main system seat is provided with a positioning convex round block, a main milling implementation system and two movable pressing and fixing devices.

Preferably, the left part of the clamping platform is a processing position aiming at the boss surface of the front cover plate. The transmission band is convenient to be carried the work piece to the processing position. The positioning convex round block is used for positioning a workpiece, the two movable pressing and fixing devices automatically clamp the workpiece, and the main milling implementation system implements milling on the convex round surface of the workpiece.

Preferably, the front side and the rear side of the main system seat are respectively provided with a bottom groove, and each movable pressing and fixing device comprises a movable table which is slidably arranged on the corresponding bottom groove; the main milling implementation system consists of a milling cutter, an elevated seat fixedly arranged on the main system seat and a main milling auxiliary control device arranged on the elevated seat; the main milling auxiliary control device is matched with the milling cutter.

Preferably, the movable table of the invention can slide back and forth to carry out subsequent pressing work on the workpiece. The main milling auxiliary control device can control the rotation of the milling cutter, the feeding of the plane position of the milling cutter and the feeding of the milling cutter in the vertical direction, thereby implementing the milling work. The two bottom grooves are respectively positioned at the front side and the rear side of the positioning convex circular block.

Preferably, the front side and the rear side of the conveying belt of the invention are abutted with baffle plates fixed on the main system seat through bolts, and the left upper part of each baffle plate is provided with an extending part. The guard plate is used for preventing the workpiece from falling off when the workpiece is conveyed, and the extending part ensures that the workpiece can fall into a processing position after being separated from the conveying belt.

Preferably, each movable pressing and fixing device is also provided with a supporting seat arranged on the movable table, a pressing plate block hinged on the supporting seat and a cylinder connected with the movable table; the air cylinders are arranged in the corresponding bottom grooves. The cylinder can promote the activity platform and slide back and forth for the clamp plate piece is close the work piece. In practice, an elastic pressing block can be externally connected to the lower end of the pressing plate block, which is close to one side of the positioning convex circular block, so as to prevent the workpiece from being damaged by pressure.

Preferably, the pressure plate block is provided with a spring connected with the movable table through a hook between one side far away from the positioning convex circular block and the movable table. The pressing plate block can be controlled to press the workpiece by the elasticity of the spring.

Preferably, the left end of the pressing plate block close to one side of the positioning convex circular block is welded with a side auxiliary cylinder. The side auxiliary cylinder is arranged for automatically pressing the workpiece conveniently.

Preferably, two movable carriers are mounted on the main system seat, and the upper end of each movable carrier is provided with an inclined surface correspondingly abutted against the side auxiliary circular column. The height of the inclined plane close to one side of the positioning convex block is smaller than the height of the inclined plane far away from one side of the positioning convex block.

Preferably, the main milling auxiliary control device is further provided with a lifting table, an A-type motor, a side slide rail and a ball screw, wherein the A-type motor and the side slide rail are all arranged on the elevated seat; the lifting platform is connected with the side slide rail in a sliding manner; the ball screw is in threaded connection with the lifting platform. Namely, the lifting platform can be controlled to lift through the transmission of the screw rod nut, so that the milling cutter is controlled to feed in the vertical direction.

Preferably, the main milling auxiliary control device is further provided with a B-type motor arranged on the lifting table, a main rotating frame connected with the B-type motor, and a milling direct drive device arranged on the main rotating frame. The axle of B-type motor is collinear with the axle of convex block. The B-type motor can drive the main rotating frame to rotate, so that the milling cutter is driven to revolve, and the milling cutter is controlled to feed in the planar annular direction.

Preferably, the milling direct-drive device is composed of a motor, an auxiliary sliding sleeve, a main center rod, a hydraulic cylinder arranged on a main rotating frame and a device mounting frame arranged on the auxiliary sliding sleeve; the auxiliary sliding sleeve is connected with the hydraulic cylinder, in particular to an L-shaped external extension part arranged on the auxiliary sliding sleeve is connected with the hydraulic cylinder. The main core rod is respectively connected with a motor and a milling cutter. The milling cutter rotates to perform milling, the motor drives the milling cutter, and the hydraulic cylinder can control the milling cutter to feed in the radial direction of the plane through pushing and pulling the auxiliary sliding sleeve.

Preferably, the main rotating frame is provided with a penetrating groove matched with the auxiliary sliding sleeve in a sliding manner; the main core rod is arranged in the auxiliary sliding sleeve in a sliding mode, and the motor is arranged on the device mounting frame; the above structure is of conventional design.

The invention has the beneficial effects that:

1. the automatic feeding device realizes automatic feeding of workpieces, and saves conveying labor.

2. The invention is convenient to position the workpiece, realizes automatic compaction of the workpiece and is relatively convenient to operate and use.

3. The invention provides a clamping and milling system for a boss surface of an air inlet front cover plate, which can control a milling cutter to respectively perform rotation, annular revolution, radial feeding and vertical feeding, thereby realizing milling processing on the boss surface of a workpiece in a high-automation mode.

Drawings

The invention is further illustrated with reference to the following figures and examples.

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

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

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

FIG. 4 is an enlarged view of a portion of FIG. 3 at I;

FIG. 5 is a perspective view of a primary mill implement system;

FIG. 6 is a partial enlarged view at II of FIG. 5;

FIG. 7 is a structural view of an intake front cover plate;

fig. 8 is a state diagram of an implementation of the present invention.

In the figure: 1. a total system seat; 2. a conveyor belt; 3. a guard plate; 4. a movable table; 5. an elevated seat; 6. milling cutters; 7. a support base; 8. pressing plates; 9. a cylinder; 10. positioning the convex round block; 11. a spring; 12. a side auxiliary cylinder; 13. a movable carrier; 14. a type A motor; 15. a side slide rail; 16. a lifting platform; 17. a ball screw; 18. a B-type motor; 19. a main rotating frame; 20. a motor; 21. an auxiliary sliding sleeve; 22. a main mandrel; 23. a hydraulic cylinder; 24. and (5) assembling the device.

Detailed Description

In order to make those skilled in the art better understand the technical solution of the present invention, the present invention will be described more clearly and more completely with reference to the drawings in the following embodiments, and it is understood that the described embodiments are only a part of the present invention, rather than all of the present invention, and based on the embodiments, other embodiments obtained by those skilled in the art without inventive exercise are within the protection scope of the present invention.

As shown in fig. 1 to 6, the clamping and milling system for the boss surface of the air inlet front cover plate is provided with a main system seat 1, and a conveying belt 2 is arranged on the left part of the main system seat 1; the upper right part of the main system seat 1 is provided with a positioning convex round block 10, a main milling implementation system and two movable pressing and fixing devices.

As an embodiment of the present invention, as shown in fig. 1 and 3, the upper left portion of the clamping platform 1 of the present invention is a processing position for the boss surface of the front cover plate. The conveying belt 2 is convenient for conveying the workpiece to a processing position. The positioning convex round block 10 is used for positioning a workpiece, the two movable pressing and fixing devices automatically clamp the workpiece, and the main milling implementation system implements milling on a convex round surface of the workpiece. The positioning convex round block 10 is fixed on the clamping platform 1.

As an embodiment of the present invention, as shown in fig. 4, the front and rear sides of the total system base 1 of the present invention are provided with bottom grooves 1a, and each movable press-fixing device includes a movable table 4 slidably mounted on the corresponding bottom groove 1 a; the main milling implementation system consists of a milling cutter 6, an elevated seat 5 fixedly arranged on the main system seat 1 and a main milling auxiliary control device arranged on the elevated seat 5; the main milling auxiliary control device is matched with the milling cutter 6.

Specifically, as shown in fig. 4, the movable table 4 can slide back and forth to perform subsequent pressing work on the workpiece. The main milling auxiliary control device can control the rotation of the milling cutter, the feeding of the plane position of the milling cutter and the feeding of the milling cutter in the vertical direction, thereby implementing the milling work. The two bottom grooves 1a are respectively positioned at the front and rear sides of the positioning boss 10.

As an embodiment of the present invention, as shown in fig. 3, the front and rear sides of the conveyor belt 2 are abutted with guard plates 3 fixed to the main system base 1 by bolts, and the upper left portion of each guard plate 3 is provided with an extended portion 3 a. The guard plate 3 is used for preventing the workpiece from falling off when the workpiece is conveyed, and the extension portion 3a ensures that the workpiece can fall into a processing position after being separated from the conveyor belt 2.

As an embodiment of the present invention, referring to fig. 4, further, each movable pressing device is further provided with a supporting base 7 installed on the movable table 4, a pressing plate block 8 hinged on the supporting base 7, and a cylinder 9 connected with the movable table 4; the air cylinders 9 are installed in the corresponding bottom grooves 1 a. The cylinder 9 can push the movable table 4 to slide back and forth, so that the pressing plate block 8 approaches to the workpiece. In practice, an elastic pressing block can be externally connected to the lower end of the pressing plate block 8 close to the positioning convex round block 10 side to prevent the workpiece from being damaged by pressing.

As shown in fig. 4, the pressure plate block 8 of the present invention has a spring 11 connected to the movable table 4 through a hook between a side thereof away from the positioning boss 10. The pressing plate block 8 can be controlled to press the workpiece by the elasticity of the spring 11.

As shown in fig. 4, the present invention is further limited, and the left ends of the pressure plates 8 near the positioning convex round blocks 10 are welded with side auxiliary round columns 12. The side auxiliary cylinder 12 is provided for the purpose of automatically pressing the workpiece.

Two movable carriers 13 are installed on the main system seat 1, and the upper end of each movable carrier 13 is provided with an inclined surface 13a which is correspondingly abutted with the side auxiliary column 12.

The height of the inclined surface 13a on the side close to the positioning boss 10 is smaller than the height on the side away from the positioning boss 10. That is, when the auxiliary side cylinder 12 slides away from the positioning boss 10, the inclined surface 13a raises the auxiliary side cylinder 12, so that the pressing plate block 8 located on the front side rotates clockwise, and the pressing plate block 8 located on the rear side rotates counterclockwise, thereby releasing the pressing of the workpiece.

As an embodiment of the present invention, as shown in fig. 5, the main milling auxiliary control device of the present invention further includes an elevating platform 16, an a-type motor 14, a side slide rail 15, and a ball screw 17 connected to the a-type motor 14, all of which are mounted on the elevated frame 5; the lifting platform 16 is connected with the side slide rail 15 in a sliding way; the ball screw 17 is screwed to the elevating table 16. Namely, the lifting platform 16 can be controlled to lift through the transmission of the screw nut, so that the milling cutter is controlled to feed in the vertical direction.

The main milling auxiliary control device is also provided with a B-shaped motor 18 arranged on the lifting platform 16, a main rotating frame 19 connected with the B-shaped motor 18 and a milling direct drive device arranged on the main rotating frame 19. The axis of the B-type motor 18 is collinear with the central axis of the positioning boss 10. Namely, the B-type motor 18 can drive the main rotating frame 19 to rotate, and further drive the milling cutter to revolve, namely, the milling cutter is controlled to feed in the planar annular direction.

As shown in fig. 6, specifically, the milling direct drive device of the present invention is composed of a motor 20, an auxiliary sliding sleeve 21, a main spindle 22, a hydraulic cylinder 23 mounted on the main rotating frame 19, and an assembling frame 24 mounted on the auxiliary sliding sleeve 21; the sub-sliding bush 21 is connected to a hydraulic cylinder 23, and specifically, an L-shaped outer extension portion 21a provided in the sub-sliding bush 21 is connected to the hydraulic cylinder 23. The main spindle 22 is connected to the motor 20 and the milling cutter 6, respectively. The milling cutter 6 is driven by the motor 20 to perform the rotation milling, and the hydraulic cylinder 23 can control the milling cutter 6 to feed in the radial direction of the plane by pushing and pulling the auxiliary sliding bush 21.

A penetrating groove 19a matched with the auxiliary sliding sleeve 21 in a sliding manner is arranged on the main rotating frame 19; the main core rod 22 is arranged in the auxiliary sliding sleeve 21 in a sliding way, and the motor 20 is arranged on the device frame 24; the above structure is of conventional design.

The method comprises the following specific implementation steps:

step 1: the front intake cover plate shown in fig. 7 is conveyed to the left processing position on the overall system base 1 by the conveyor belt 2.

Step 2: the workpiece is manually placed and positioned in a mode that the positioning convex round block 10 is matched with the center hole of the workpiece, and the convex round block faces upwards.

And step 3: the cylinder 9 of each movable press-fixing device pushes the movable table 4 to the direction of the workpiece. When the movable table 4 is partially moved to the upper side of the workpiece, the movable table 4 presses the workpiece under the elastic force of the spring 11, and the workpiece is in a state shown in fig. 8.

And 4, step 4: according to the actual milling amount and the requirement of the machining size, the height of the milling cutter is adjusted by driving the ball screw 17 to rotate through the A-type motor 14.

And 5: the motor 20 drives the milling cutter to rotate.

And 6: the B-type motor 18 drives the milling cutter to rotate for one circle to mill a circle of area on the convex table surface of the workpiece.

And 7: the hydraulic cylinder 23 pushes or pulls the milling cutter in the radial direction for feeding.

And 8: and (5) alternately executing the step 6 and the step 7 until the milling of the whole boss surface is finished.

And step 9: the milling cutter is lifted, the air cylinder 9 pulls the movable table 4 back to release the clamping of the workpiece, and the processed workpiece is taken out.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. Air inlet front shroud boss face clamping and milling system has total system seat (1), its characterized in that: a transmission belt (2) is arranged on the left part of the main system seat (1); the upper right part of the main system seat (1) is provided with a positioning convex round block (10), a main milling implementation system and two movable pressing and fixing devices;

the front side and the rear side of the main system seat (1) are respectively provided with a bottom groove (1a), and each movable pressing and fixing device comprises a movable table (4) which is arranged on the corresponding bottom groove (1a) in a sliding manner; the main milling implementation system consists of a milling cutter (6), an elevated seat (5) fixedly arranged on the main system seat (1) and a main milling auxiliary control device arranged on the elevated seat (5); the main milling auxiliary control device is matched with the milling cutter (6).

2. The intake front cover plate boss face clamping and milling system of claim 1, wherein: both sides all support to have closed fender board (3) on being fixed in total system seat (1) through the bolt around transmission band (2), and the upper left portion of every fender board (3) all is equipped with extension (3 a).

3. The intake front cover plate boss face clamping and milling system of claim 1, wherein: each movable pressing and fixing device is also provided with a supporting seat (7) arranged on the movable table (4), a pressing plate block (8) hinged on the supporting seat (7) and a cylinder (9) connected with the movable table (4); the air cylinders (9) are arranged in the corresponding bottom grooves (1 a).

4. The intake front cover plate boss face clamping and milling system of claim 3, wherein: a spring (11) connected with the pressure plate block (8) and the movable table (4) through a hook is arranged between one side of the pressure plate block far away from the positioning convex circular block (10) and the movable table.

5. The intake front cover plate boss face clamping and milling system of claim 3, wherein: the left end of the pressing plate block (8) close to one side of the positioning convex circular block (10) is welded with a side auxiliary cylinder (12).

6. The intake front cover plate boss face clamping and milling system of claim 5, wherein: two movable carriers (13) are installed on the main system seat (1), and the upper end of each movable carrier (13) is provided with an inclined surface (13a) which is correspondingly abutted against the side auxiliary cylinder (12).

7. The intake front cover plate boss face clamping and milling system of claim 1, wherein: the main milling auxiliary control device is also provided with a lifting platform (16), an A-shaped motor (14) which is arranged on the elevated seat (5), a side slide rail (15) and a ball screw (17) which is connected with the A-shaped motor (14); the lifting platform (16) is connected with the side slide rail (15) in a sliding way; the ball screw (17) is in threaded connection with the lifting platform (16).

8. The intake front cover plate boss face clamping and milling system of claim 7, wherein: the main milling auxiliary control device is also provided with a B-type motor (18) arranged on the lifting platform (16), a main rotating frame (19) connected with the B-type motor (18) and a milling direct drive device arranged on the main rotating frame (19).

9. The intake front cover plate boss face clamping and milling system of claim 8, wherein: the milling direct-drive device consists of a motor (20), an auxiliary sliding sleeve (21), a main core rod (22), a hydraulic cylinder (23) arranged on a main rotating frame (19) and an assembling frame (24) arranged on the auxiliary sliding sleeve (21); the auxiliary sliding sleeve (21) is connected with a hydraulic cylinder (23), and the main core rod (22) is respectively connected with a motor (20) and a milling cutter (6).

10. The intake front cover plate boss face clamping and milling system of claim 9, wherein: a penetrating groove (19a) which can enable the auxiliary sliding sleeve (21) to slide is arranged on the main rotating frame (19); the main core rod (22) is arranged in the auxiliary sliding sleeve (21) in a sliding mode, and the motor (20) is arranged on the device mounting frame (24).

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