CN110270706B

CN110270706B - Special face milling equipment for intake manifold

Info

Publication number: CN110270706B
Application number: CN201910595010.7A
Authority: CN
Inventors: 许晓丽
Original assignee: Taizhou Luqiao Opal Spray Electrophoresis Co Ltd
Current assignee: Taizhou Luqiao opal spray electrophoresis Co., Ltd
Priority date: 2019-07-03
Filing date: 2019-07-03
Publication date: 2020-08-14
Anticipated expiration: 2039-07-03
Also published as: CN110270706A

Abstract

The invention discloses special face milling equipment for an intake manifold, which comprises a rack base, wherein two slide rails which are arranged in parallel in the left-right direction are fixed on the rack base, the right end of each slide rail is connected with a clamp for fastening the intake manifold in a sliding manner, and a driving mechanism for driving the clamp to move along the slide rails is arranged on the rack base; the middle part of the frame base is fixed with a first face milling device and a second face milling device, the first face milling device comprises a first milling cutter used for machining a cylinder cover combined flange face of the intake manifold, and the second face milling device comprises a second milling cutter used for machining a throttle valve body combined flange face of the intake manifold. The invention can process the cylinder cover combined flange surface and the throttle valve body combined flange surface of the intake manifold at one time, and can effectively improve the processing efficiency of the intake manifold.

Description

Special face milling equipment for intake manifold

Technical Field

The invention relates to the technical field of intake manifolds, in particular to special face milling equipment for an intake manifold.

Background

The intake manifold has the function that when air and fuel mixture is distributed to each cylinder of an intake engine from a carburetor or a throttle body to work, the air pressure fluctuation of the intake manifold is large, the requirement on the sealing performance of the intake manifold is provided, the requirements on the flatness and the smoothness of a cylinder cover combination flange surface connected with a cylinder cover and a throttle body combination flange surface combined with a throttle body are high, two procedures are generally needed when the existing surface milling processing is carried out on the cylinder cover combination flange surface and the throttle body combination flange surface, the clamping and the transferring are needed twice, and the processing efficiency of the intake manifold is low.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides special face milling equipment for an intake manifold, which can process a cylinder cover combined flange face and a throttle valve combined flange face of the intake manifold at one time and can effectively improve the processing efficiency of the intake manifold.

The scheme for solving the technical problems is as follows:

the special face milling equipment for the intake manifold comprises a rack base, wherein two slide rails which are arranged in parallel in the left-right direction are fixed on the rack base, a clamp for fastening the intake manifold is connected to the right end of each slide rail in a sliding manner, and a driving mechanism for driving the clamp to move along the slide rails is arranged on the rack base; the middle part of the frame base is fixed with a first face milling device and a second face milling device, the first face milling device comprises a first milling cutter used for machining a cylinder cover combined flange face of the intake manifold, and the second face milling device comprises a second milling cutter used for machining a throttle valve body combined flange face of the intake manifold.

The driving mechanism comprises a connecting arm fixedly connected with the clamp, the connecting arm is connected to a screw rod arranged in parallel with the sliding rail in a threaded mode, two ends of the screw rod are hinged to corresponding hinged seats respectively, the screw rod penetrates through the extending end of one hinged seat to be connected with the motor, and the motor is fixed to the base of the rack.

A plurality of bolt mounting holes are formed in the surface of the cylinder cover combining flange;

the clamp comprises a sliding base in a right-angle plate shape, two sliding grooves matched with the sliding rails are formed in the lower bottom surface of the sliding base, and the sliding grooves are inserted and sleeved on the sliding rails; two positioning rods protruding forwards are fixed on the front side wall of the sliding base, and the two positioning rods are inserted in two bolt mounting holes; the back surface of the cylinder cover combined flange surface is pressed against the front side wall of the sliding base; the rear end of the sliding base is provided with a pair of pressing mechanisms arranged left and right.

The pressing mechanism comprises a supporting rod arranged in the front-back direction, a rotary moving part is sleeved on the supporting rod, a helical gear is formed at the rear end of the rotary moving part, the helical gear is meshed with a helical rack which is vertically arranged, the helical rack is fixed at one end of a bending arm, and the other end of the bending arm is fixedly connected with a piston rod of the air cylinder; a pressing plate is formed at the front end of the rotary moving part and is pressed against the outer wall of the manifold on the outer side of the air inlet manifold; two ends of the supporting rod are respectively fixed on the front side wall of the sliding base and the supporting seat, and the supporting seat and the cylinder are fixed on the bottom surface of the sliding base.

The lower side of the pressing plate is formed with a slot which is inserted and sleeved on the manifold.

The helical rack is formed with a guide part, the guide part is inserted and sleeved on a guide seat, and the guide seat is fixed on the sliding base.

The sliding base is formed with a manifold avoiding groove with an opening at the upper side, and the manifold is inserted and sleeved in the manifold avoiding groove.

The first milling device also comprises a first motor for driving the first milling cutter to rotate; the second face milling device also comprises a second motor which drives the second milling cutter to rotate.

The invention has the following outstanding effects: compared with the prior art, the processing method can be used for processing the cylinder cover combination flange surface and the throttle valve body combination flange surface of the intake manifold at one time, and can effectively improve the processing efficiency of the intake manifold.

Drawings

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

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

FIG. 3 is a schematic view of the clamp of the present invention assembled with an intake manifold.

Detailed Description

In an embodiment, as shown in fig. 1 to 3, a special face milling device for an intake manifold comprises a rack base 1, wherein two slide rails 2 arranged in parallel in the left-right direction are fixed on the rack base 1, a clamp 3 for fastening an intake manifold 9 is slidably connected to the right end of each slide rail 2, and a driving mechanism 4 for driving the clamp 3 to move along the slide rails 2 is arranged on the rack base 1; a first face milling device 5 and a second face milling device 6 are fixed in the middle of the rack base 1, the first face milling device 5 comprises a first milling cutter 51 used for machining a cylinder cover combined flange face 91 of the intake manifold 9, and the second face milling device 6 comprises a second milling cutter 61 used for machining a throttle body combined flange face 92 of the intake manifold 9.

Furthermore, the driving mechanism 4 includes a connecting arm 41 fixedly connected to the clamp 3, the connecting arm 41 is screwed on a screw rod 42 disposed in parallel with the slide rail 2, two ends of the screw rod 42 are respectively hinged on a corresponding one of the hinged seats 43, the screw rod 42 passes through an extending end of one of the hinged seats 43 to be connected with a motor 44, and the motor 44 is fixed on the rack base 1.

Furthermore, a plurality of bolt mounting holes 93 are formed on the cylinder head combining flange surface 91;

the clamp 3 comprises a slide base 31 in a right-angle plate shape, two sliding grooves 311 matched with the slide rails 2 are formed on the lower bottom surface of the slide base 31, and the sliding grooves 311 are inserted on the slide rails 2; two positioning rods 32 protruding forwards are fixed on the front side wall of the sliding base 31, and the two positioning rods 32 are inserted into two bolt mounting holes 93; the back surface of the cylinder cover combining flange surface 91 is pressed against the front side wall of the sliding base 31; the rear end of the sliding base 31 is provided with a pair of pressing mechanisms 7 arranged left and right.

Furthermore, the pressing mechanism 7 includes a supporting rod 71 disposed in the front-back direction, the supporting rod 71 is sleeved with a rotating moving part 72, a helical gear 73 is formed at the rear end of the rotating moving part 72, the helical gear 73 is engaged with a helical rack 74 disposed vertically, the helical rack 74 is fixed at one end of a bending arm 75, and the other end of the bending arm 75 is fixedly connected with a piston rod of the cylinder 76; a pressing plate 77 is formed at the front end of the rotary moving part 72, and the pressing plate 77 is pressed against the outer wall of a manifold 94 on the outer side of the intake manifold 9; two ends of the support rod 71 are respectively fixed on the front side wall of the sliding base 31 and the supporting seat 78, and the supporting seat 78 and the air cylinder 76 are fixed on the bottom surface of the sliding base 31.

Further, the lower side of the pressing plate 77 is formed with a slot 771, and the slot 771 is inserted into the manifold 94.

Further, the rack gear 74 is formed with a guide portion 741, the guide portion 741 is inserted into the guide seat 79, and the guide seat 79 is fixed to the slide base 31.

Further, the slide base 31 is formed with a manifold escape groove 312 opened at an upper side, and the manifold 94 is inserted into the manifold escape groove 312.

Furthermore, the first face milling device 5 further includes a first motor for driving the first milling cutter 51 to rotate; the second milling device 6 further comprises a second motor for driving the second milling cutter 61 in rotation.

The working principle is as follows: firstly, a bolt mounting hole 93 of an air inlet manifold 9 is sleeved in a manner of aligning with a positioning rod 32, and the back surface of a cylinder cover combining flange surface 91 is pressed on the front side wall of a sliding base 31; secondly, the piston rods of the two air cylinders 76 extend, the piston rods of the air cylinders 76 drive the helical rack 74 to move upwards, the helical rack 74 drives the helical gear 73 to rotate, the helical gear 73 drives the pressing plate 77 to rotate through the rotating moving part 72, when the slot 771 of the pressing plate 77 is inserted and pressed on the manifold 94, the pressing plate 77 cannot move continuously under the blocking effect of the manifold 94, at the moment, the helical rack 74 moves upwards continuously to drive the helical gear 73 to move backwards, the helical gear 73 drives the pressing plate 77 to move backwards through the rotating moving part 72, the pressing plate 77 abuts against the outer wall of the manifold 94, and the pressing plate 77 exerts two downward and backward acting forces on the manifold 94 under the action of the helical gear 73, so that the air intake manifold is; thirdly, the motor 44 drives the screw rod 42 to rotate, the screw rod 42 drives the connecting arm 41 to move left, and the connecting arm 41 drives the clamp and the intake manifold to move left along the slide rail 2; when the cylinder cover combined flange surface of the intake manifold 9 and the throttle body combined flange surface move to the corresponding first milling cutter and second milling cutter, the first milling cutter performs milling processing on the cylinder cover combined flange surface, and the second milling cutter performs milling processing on the throttle body combined flange surface.

Finally, the above embodiments are only for illustrating the present invention and not for limiting the present invention, and those skilled in the art can make various changes and modifications without departing from the spirit and scope of the present invention, so that all equivalent technical solutions also belong to the scope of the present invention, and the scope of the present invention should be defined by the claims.

Claims

1. The utility model provides an air intake manifold's special plane equipment of milling, includes frame base (1), its characterized in that: two slide rails (2) which are arranged in parallel in the left-right direction are fixed on the rack base (1), a clamp (3) for fastening an air inlet manifold (9) is connected to the right end of each slide rail (2) in a sliding manner, and a driving mechanism (4) for driving the clamp (3) to move along the slide rails (2) is arranged on the rack base (1); a first face milling device (5) and a second face milling device (6) are fixed in the middle of the rack base (1), the first face milling device (5) comprises a first milling cutter (51) used for machining a cylinder cover combined flange face (91) of the intake manifold (9), and the second face milling device (6) comprises a second milling cutter (61) used for machining a throttle valve body combined flange face (92) of the intake manifold (9);

a plurality of bolt mounting holes (93) are formed in the cylinder cover combining flange surface (91);

the clamp (3) comprises a slide base (31) in a right-angle plate shape, two sliding grooves (311) matched with the slide rails (2) are formed in the lower bottom surface of the slide base (31), and the sliding grooves (311) are inserted and sleeved on the slide rails (2); two positioning rods (32) protruding forwards are fixed on the front side wall of the sliding base (31), and the two positioning rods (32) are inserted into two bolt mounting holes (93); the back surface of the cylinder cover combining flange surface (91) is pressed against the front side wall of the sliding base (31); the rear end of the sliding base (31) is provided with a pair of pressing mechanisms (7) which are arranged left and right.

2. The special face milling machine equipment for the intake manifold as claimed in claim 1, wherein: the driving mechanism (4) comprises a connecting arm (41) fixedly connected with the clamp (3), the connecting arm (41) is screwed on a screw rod (42) arranged in parallel with the sliding rail (2), two ends of the screw rod (42) are respectively hinged on a corresponding hinged seat (43), the screw rod (42) penetrates through the extending end of one hinged seat (43) to be connected with a motor (44), and the motor (44) is fixed on the rack base (1).

3. The special face milling machine equipment for the intake manifold as claimed in claim 1, wherein: the pressing mechanism (7) comprises a supporting rod (71) arranged in the front-back direction, a rotary moving part (72) is sleeved on the supporting rod (71), a helical gear (73) is formed at the rear end of the rotary moving part (72), the helical gear (73) is meshed with a vertically arranged helical rack (74), the helical rack (74) is fixed at one end of a bending arm (75), and the other end of the bending arm (75) is fixedly connected with a piston rod of an air cylinder (76); a pressure plate (77) is formed at the front end of the rotary moving part (72), and the pressure plate (77) is pressed against the outer wall of a manifold (94) on the outer side of the air inlet manifold (9); two ends of the supporting rod (71) are respectively fixed on the front side wall of the sliding base (31) and the supporting seat (78), and the supporting seat (78) and the cylinder (76) are fixed on the bottom surface of the sliding base (31).

4. The special face milling machine equipment for the intake manifold as claimed in claim 3, wherein: the lower side of the pressing plate (77) is formed with a slot (771), and the slot (771) is inserted and sleeved on the manifold (94).

5. The special face milling machine equipment for the intake manifold as claimed in claim 3, wherein: the helical rack (74) is formed with a guide part (741), the guide part (741) is inserted and sleeved on the guide seat (79), and the guide seat (79) is fixed on the sliding base (31).

6. The special face milling machine equipment for the intake manifold as claimed in claim 1, wherein: the sliding base (31) is formed with a manifold avoiding groove (312) with an opening at the upper side, and the manifold (94) is inserted in the manifold avoiding groove (312).

7. The special face milling machine equipment for the intake manifold as claimed in claim 1, wherein: the first face milling device (5) further comprises a first motor for driving the first milling cutter (51) to rotate; the second face milling device (6) also comprises a second motor which drives the second milling cutter (61) to rotate.