阅读说明：本技术 用于硬质合金铣刀成型加工轧制装置 (Be used for carbide milling cutter contour machining rolling device ) 是由 徐金海 李友军 苗顺顺 于 2021-03-25 设计创作，主要内容包括：本发明公开了用于硬质合金铣刀成型加工轧制装置,包括底座和左承台和右承台,所述底座上设置有固定台一和固定台二,所述左承台与固定台一和固定台二之间分别设置有定轧辊和动轧辊。本发明中,根据铣刀原料的直径调节动轧辊的位置,驱动电机二带动驱动轮齿转动,驱动轮齿带动大齿环转动,大齿环通过支撑杆带动齿轮转动,在小齿环的限位作用下,齿轮围绕小齿环做圆周转动,齿轮的圆周运动带动偏心块同步运动,同时偏心块在限位环槽的内部滑动,从而带动限位环槽进行左右移动,操控液压伸缩杆二伸缩带动动轧辊的另一端同步移动,从而实现动轧辊与定轧辊之间的距离调节,便于对不同直径的铣刀原料进行加工,提高了轧制装置的加工效率。(The invention discloses a rolling device for forming and processing a hard alloy milling cutter, which comprises a base, a left bearing platform and a right bearing platform, wherein a first fixed platform and a second fixed platform are arranged on the base, and a fixed roller and a movable roller are respectively arranged between the left bearing platform and the first fixed platform and between the left bearing platform and the second fixed platform. According to the milling cutter, the position of the movable roller is adjusted according to the diameter of the milling cutter raw material, the driving motor II drives the driving gear to rotate, the driving gear drives the large gear ring to rotate, the large gear ring drives the gear to rotate through the supporting rod, the gear rotates circumferentially around the small gear ring under the limiting effect of the small gear ring, the circumferential motion of the gear drives the eccentric block to move synchronously, meanwhile, the eccentric block slides inside the limiting ring groove, so that the limiting ring groove is driven to move leftwards and rightwards, the hydraulic telescopic rod II is controlled to stretch out and draw back to drive the other end of the movable roller to move synchronously, the distance between the movable roller and the fixed roller is adjusted, the milling cutter raw material with different diameters can be conveniently processed, and the processing.)

1. Be used for carbide milling cutter contour machining rolling device, including base (1) and left cushion cap (2) and right cushion cap (3), its characterized in that, be provided with fixed station (6) and fixed station two (7) on base (1), be provided with between left side cushion cap (2) and fixed station one (6) and fixed station two (7) respectively and decide roll (4) and move roll (5), the roller one end of moving roll (5) runs through left cushion cap (2) and the cover is equipped with bearing housing one (9), the roller other end of moving roll (5) runs through fixed station one (6) and the cover is equipped with bearing housing two (22), the roller other end of moving roll (5) passes through hydraulic telescoping rod two (23) and is connected with base (1), bearing housing one (9) are connected with spacing annular (11) through connecting rod (10), the lateral wall of left side cushion cap (2) is connected with little ring (15) and big ring gear (14) through the pivot, the utility model discloses a hydraulic drive mechanism, including big ring gear (14), the inside equidistance of big ring gear (14) distributes and has bracing piece (16), one of them rotate on bracing piece (16) and be connected with gear (17), the preceding terminal surface of gear (17) is provided with eccentric block (18), one side of big ring gear (14) is provided with two (12) of driving motor with left cushion cap (2) fixed connection, the output shaft of two (12) of driving motor is provided with the driving teeth of a cogwheel (13), be provided with installation piece (19) on right cushion cap (3), one side of installation piece (19) is provided with driving motor (20), the output shaft of driving motor (20) has hydraulic telescoping rod (25), the end connection of hydraulic telescoping rod (25) has milling cutter fixing base (21).

2. The milling device for carbide milling cutter forming machining according to claim 1, characterized in that the eccentric mass (18) is located inside the limit ring groove (11) and is in sliding fit with the limit ring groove (11).

3. The forming and rolling device for the hard alloy milling cutter according to claim 1, wherein the left bearing platform (2) and the first fixing platform (6) are provided with abdicating grooves (8).

4. The milling device for hard alloy milling cutter forming machining according to claim 1, characterized in that the large gear ring (14) is in rotating fit with a rotating shaft on the left bearing platform (2), and the small gear ring (15) is fixedly connected with the rotating shaft on the left bearing platform (2).

5. The milling device for hard alloy milling cutter forming machining according to claim 4, characterized in that the large gear ring (14) and the small gear ring (15) are concentrically arranged, and the small gear ring (15) is in meshed connection with the gear (17).

6. The milling device for hard alloy milling cutter forming machining according to the claim 1 is characterized in that the guide sleeve (24) is sleeved outside the connecting rod (10), and the guide sleeve (24) is fixedly connected with the left bearing platform (2).

Technical Field

The invention relates to the technical field of milling cutters, in particular to a forming and rolling device for a hard alloy milling cutter.

Background

A milling cutter is a rotating tool with one or more cutter teeth for milling. When in work, each cutter tooth cuts off the allowance of the workpiece in sequence and intermittently. The milling cutter is mainly used for processing planes, steps, grooves, formed surfaces, cut-off workpieces and the like on a milling machine. The number of cutting inserts involved in cutting at any one time is an advantage, but too many, the power required is dependent on how many cutting edges are involved in cutting, and the position of the milling cutter relative to the workpiece plays an important role in chip formation, cutting edge loading and machining results. In order to ensure that a sufficiently high average chip thickness per tooth feed is used, the number of cutter teeth suitable for the process must be correctly determined. The pitch of the milling cutter is the distance between the active cutting edges. The milling cutter can be divided into 3 types, namely a dense-tooth milling cutter, a sparse-tooth milling cutter and a super-dense-tooth milling cutter according to the value. The milling is an essential step in the milling process, which is usually referred to as the mechanical process of deformation of the rolled piece between the rolls. In order to facilitate the analysis of the relationships between the various basic parameters of the rolling process, a so-called simple ideal rolling process is established, assuming that the metal to be rolled is a homogeneous continuous rigid-plastic body of rectangular cross section. The rollers are a pair of flat roller rigid bodies with equal diameter and speed, and have no external tension or thrust, so that the main parameters of the deformation zone are determined.

At present, in the process of processing the milling cutter, the milling cutter raw material is usually placed between two rollers, and the extrusion of the rollers forms knife lines on the milling cutter raw material, but the distance between the two rollers of the existing rolling device is difficult to adjust, and the milling cutter with the same size can only be processed, so that the limitation of the rolling device is increased, and the processing efficiency of the alloy milling cutter is reduced.

Disclosure of Invention

The invention aims to: the rolling device for the forming machining of the hard alloy milling cutter is provided for solving the problems that a roller of the rolling device is inconvenient to adjust and has large machining limitation.

In order to achieve the purpose, the invention adopts the following technical scheme:

be used for carbide milling cutter contour machining rolling device, including base and left cushion cap and right cushion cap, be provided with fixed station one and fixed station two on the base, be provided with the fixed roll respectively between left side cushion cap and fixed station one and the fixed station two and move the roll, the roll axle one end of moving the roll runs through left cushion cap and overlaps and be equipped with bearing housing one, the roll axle other end of moving the roll runs through the fixed station and overlaps and be equipped with bearing housing two in the lump, the roll axle other end of moving the roll is connected with the base through hydraulic telescoping rod two, bearing housing one is connected with spacing annular through the connecting rod, the lateral wall of left cushion cap is connected with little ring gear and big ring gear through the pivot, the inside equidistance distribution of big ring gear has the bracing piece, one of them rotate on the bracing piece and be connected with the gear, the preceding terminal surface of gear is provided with the eccentric block, one side of big ring gear is provided with driving motor two, the output shaft of the driving motor II is provided with driving gear teeth, the right bearing platform is provided with an installation block, one side of the installation block is provided with the driving motor I, the output shaft of the driving motor I is connected with the hydraulic telescopic rod I, and the end part of the hydraulic telescopic rod I is connected with the milling cutter fixing seat.

As a further description of the above technical solution:

the eccentric block is positioned in the limiting ring groove and is in sliding fit with the limiting ring groove.

As a further description of the above technical solution:

and the left bearing platform and the fixed platform are both provided with a yielding groove.

As a further description of the above technical solution:

the large gear ring is in running fit with the rotating shaft on the left bearing platform, and the small gear ring is fixedly connected with the rotating shaft on the left bearing platform.

As a further description of the above technical solution:

the large gear ring and the small gear ring are arranged concentrically, and the small gear ring is meshed with the gear.

As a further description of the above technical solution:

the outside cover of connecting rod is equipped with the uide bushing, uide bushing and left cushion cap fixed connection.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

in the invention, a milling cutter raw material is connected with a milling cutter fixing seat, the milling cutter raw material is arranged between a fixed roller and a movable roller, the position of the movable roller is adjusted according to the diameter of the milling cutter raw material, a second driving motor is started, the second driving motor drives a driving gear to rotate, the driving gear drives a large gear ring to rotate, the large gear ring drives a gear to rotate through a supporting rod, under the limiting action of a small gear ring, the gear performs circular rotation around the small gear ring, the circular motion of the gear drives an eccentric block to synchronously move, the eccentric block slides in a limiting ring groove simultaneously, so that a limiting ring groove is driven to move left and right, the left and right movement of the limiting ring groove drives a first bearing sleeve to move left and right through a connecting rod, the first bearing sleeve drives one end of the movable roller to move, and controls a second hydraulic telescopic rod to stretch to drive the, the milling cutter raw materials with different diameters can be conveniently processed, and the processing efficiency of the rolling device is improved.

Drawings

Fig. 1 is a schematic top view of a rolling device for forming machining of a hard alloy milling cutter according to the present invention;

FIG. 2 is a schematic side view of the rolling device for milling cutter forming machining of cemented carbide according to the present invention;

FIG. 3 is a schematic view of a connection structure between a large gear ring and a small gear ring and between gears of the rolling device for forming the hard alloy milling cutter, which is provided by the invention;

fig. 4 is an enlarged structural schematic diagram of a part a in fig. 2 for the milling device for forming cemented carbide milling cutter according to the present invention.

Illustration of the drawings:

1. a base; 2. a left cushion cap; 3. a right cushion cap; 4. fixing a roller; 5. moving a roller; 6. a first fixed table; 7. a second fixed table; 8. a yielding groove; 9. a first bearing sleeve; 10. a connecting rod; 11. a limiting ring groove; 12. a second driving motor; 13. a drive gear tooth; 14. a large toothed ring; 15. a small toothed ring; 16. a support bar; 17. a gear; 18. an eccentric block; 19. mounting blocks; 20. driving a motor I; 21. a milling cutter fixing seat; 22. a second bearing sleeve; 23. a second hydraulic telescopic rod; 24. a guide sleeve; 25. and (5) hydraulically stretching the rod I.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Referring to fig. 1-4, a rolling device for forming and processing a hard alloy milling cutter comprises a base 1, a left bearing platform 2 and a right bearing platform 3, wherein a first fixed platform 6 and a second fixed platform 7 are arranged on the base 1, a fixed roller 4 and a movable roller 5 are respectively arranged between the left bearing platform 2 and the first fixed platform 6 as well as between the left bearing platform 2 as well as between the second fixed platform 7, a milling cutter raw material is connected with a milling cutter fixed seat 21 and is arranged between the fixed roller 4 and the movable roller 5, the position of the movable roller 5 is adjusted according to the diameter of the milling cutter raw material, one end of a roller shaft of the movable roller 5 penetrates through the left bearing platform 2 and is sleeved with a first bearing sleeve 9, the other end of the roller shaft of the movable roller 5 penetrates through the first fixed platform 6 and is sleeved with a second bearing sleeve 22, the other end of the roller shaft of the movable roller 5 is connected with the base 1 through a second hydraulic telescopic rod 23, the first bearing sleeve 9 is connected with, the supporting rods 16 are equidistantly distributed in the large toothed ring 14, one of the supporting rods 16 is rotatably connected with a gear 17, the front end face of the gear 17 is provided with an eccentric block 18, one side of the large toothed ring 14 is provided with a driving motor II 12 fixedly connected with the left bearing platform 2, an output shaft of the driving motor II 12 is provided with a driving gear tooth 13, the driving motor II 12 drives the driving gear tooth 13 to rotate, the driving gear tooth 13 drives the large toothed ring 14 to rotate, the large toothed ring 14 drives the gear 17 to rotate through the supporting rod 16, under the limiting action of the small toothed ring 15, the gear 17 circularly rotates around the small toothed ring 15, the circular motion of the gear 17 drives the eccentric block 18 to synchronously move, meanwhile, the eccentric block 18 slides in the limiting ring groove 11 to drive the limiting ring groove 11 to move left and right, the mounting block 19 is arranged on the right bearing platform 3, one side of the mounting block 19 is provided with a driving motor I20, an output shaft of the, the end connection of the first hydraulic telescopic rod 25 is provided with a milling cutter fixing seat 21, during machining, the first driving motor 20 is started, the first driving motor 20 drives the first hydraulic telescopic rod 25 to rotate, the first hydraulic telescopic rod 25 stretches and drives the milling cutter raw material to move left and right, so that the milling cutter raw material is moved and rotated in the machining process, and the milling cutter is machined through the fixed roller 4 and the movable roller 5 in an extrusion mode.

Specifically, as shown in fig. 2 and 4, the eccentric block 18 is located inside the limit ring groove 11 and is in sliding fit with the limit ring groove 11, so that the rotation of the eccentric block 18 drives the limit ring groove 11 to move in the horizontal direction.

Specifically, as shown in fig. 2, the left cushion cap 2 and the first fixed station 6 are both provided with a yielding groove 8, and the yielding groove 8 provides a moving space for the moving roller 5.

Specifically, as shown in fig. 2, the large gear ring 14 is rotationally engaged with the rotating shaft on the left bearing platform 2, and the small gear ring 15 is fixedly connected with the rotating shaft on the left bearing platform 2, so that the large gear ring 14 rotates relative to the left bearing platform 2, and the small gear ring 15 is in a stationary state relative to the left bearing platform 2.

Specifically, as shown in fig. 3, the large gear ring 14 and the small gear ring 15 are concentrically arranged, and the small gear ring 15 is meshed with the gear 17, so that the large gear ring 14 can drive the gear 17 to rotate around the small gear ring 15.

Specifically, as shown in fig. 2, a guide sleeve 24 is sleeved outside the connecting rod 10, the guide sleeve 24 is fixedly connected with the left bearing platform 2, and the guide sleeve 24 limits the connecting rod 10, so that the connecting rod 10 can only move in the horizontal direction.

The working principle is as follows: when the milling cutter is used, a milling cutter raw material is connected with a milling cutter fixing seat 21, the milling cutter raw material is placed between a fixed roller 4 and a movable roller 5, the position of the movable roller 5 is adjusted according to the diameter of the milling cutter raw material, a driving motor II 12 is started, the driving motor II 12 drives a driving gear tooth 13 to rotate, the driving gear tooth 13 drives a large gear ring 14 to rotate, the large gear ring 14 drives a gear 17 to rotate through a supporting rod 16, under the limiting action of a small gear ring 15, the gear 17 rotates around the small gear ring 15 in a circular manner, the circular motion of the gear 17 drives an eccentric block 18 to move synchronously, meanwhile, the eccentric block 18 slides in a limiting ring groove 11, so as to drive the limiting ring groove 11 to move leftwards and rightwards, the left and rightwards movement of the limiting ring groove 11 drives a bearing sleeve I9 to move leftwards through a connecting rod 10, the bearing sleeve I9 drives one end, therefore, the distance between the movable roller 5 and the fixed roller 4 is adjusted, milling cutter raw materials with different diameters can be conveniently processed, and the processing efficiency of the rolling device is improved.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.