RU2369469C1 - Method of machining spur gear wheels by shaving-rolling together - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: method is intended for machining gear wheels with circular or arc-like tooth shape and comprises free rolling of tool that features cutting edges offset along helical surface, and machined gear wheel. Note that the tool engages gear wheel to be machined out-of-pole, machining being carried out during intermittent radial feed after each of 2 to 4 machining cycles that include turning the tool back and forth for the number of revolutions equal to that of the gear wheel teeth. Aforesaid cycles do not comprise radial feed during 1 to 2 rolling cycles that include turning the tool back and forth for the number of revolutions equal to that of the gear wheel teeth. Note here that the tool has the number of teeth with no common multipliers with the number of machined gear teeth, except for unity. Tool and gear wheel are located on axes intersecting at 90°. Machining is performed with the tool with circular or arc-like tooth shape. Note that cutting edges of aforesaid teeth are located on flat cutting wheel.

EFFECT: perfected method.

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Description

The invention relates to the field of engineering, in particular to the processing of circular or arched teeth of spur gears.

, где z - число выступов каждой впадины [А.с. СССР №1296327, В23F 9/02, Бюл. №10, 1987].A known method of cutting circular gear teeth with a tool in the form of two faceplates with protrusions uniformly spaced around the circumference, on which the cutting elements are placed in the same direction of the spirals, while the facets are informed of rotation in the opposite direction with a constant phase shift by an angle

where z is the number of protrusions of each cavity [A.S. USSR No. 1296327, B23F 9/02, Bull. No. 10, 1987].

The disadvantage of this method is that it allows you to process only barrel-shaped teeth, the line of which differs from the arc of a circle.

A known method of processing the circular teeth of the wheels of cylindrical and helical gears by the method of continuous division, a tool with a spiral forming surface, while the angle of intersection of the axes of the tool and the workpiece is 90 ° [A. USSR No. 429909, B23F 9/02, B23F 9/08, Bull. No. 20, 1974]. The tool or workpiece is brought into relative rectilinear motion in a direction perpendicular to the axis of the workpiece or tool, or in a circular motion around the axis of the producing wheel and the workpiece or tool is informed of an additional feed movement along the tool axis.

The disadvantage of this method is that it does not allow to process circular symmetrical teeth.

A known method of processing cylindrical gears by shewing-rolling, including a free run-in of a shaver-prikatnik having cutting edges offset along a helical surface, and a machined wheel mounted on parallel axes, wherein the engagement of the shaver-prikatnik with the machined wheel is performed out of pole, and the processing is carried out with periodic radial feed after each of 2-4 working cycles, including turning the shaver-prikatnik in forward and reverse directions by the number of revolutions equal to the number of memory beat the machined wheel, and without radial feed for 1-2 nursing cycles, including turning the shaver-prikatnik in the forward and reverse directions by the number of revolutions equal to the number of teeth of the machined wheel, using a shaver-prikatnik, the number of teeth of which does not have common factors with the number of teeth of the machined wheel, except for a unit [Pat. RF №2224624, IPC ⁷ В23F 19/06, Bull. No. 6, 2004].

The disadvantage of this method is the limitation of the minimum number of teeth of the workpiece. This is because with small numbers of teeth of the workpiece, it is not possible to provide the required condition for out-of-pole engagement between the tool and the workpiece due to the sharpening of the teeth of the tool.

The objective of the invention is the expansion of technological capabilities of the method of processing cylindrical gears by shewing-rolling, creating the possibility of processing gears with a small number of teeth.

The problem is solved in that the method of processing cylindrical gears by shewing-rolling involves free rolling in a tool having cutting edges offset along a helical surface and a machined wheel, while engaging the tool with the machined wheel is performed out-of-pole, and processing is carried out with periodic radial feed after each of 2-4 operating cycles, including turning the tool in the forward and reverse directions by the number of revolutions equal to the number of teeth of the machined wheel and without radial feed for 1-2 nursing cycles, including turning the tool in the forward and reverse directions by the number of revolutions equal to the number of teeth of the machined wheel, using a tool whose number of teeth does not have common factors with the number of teeth of the machined wheel, except units, and the tool and the workpiece-wheel are mounted on axes intersecting at an angle of 90 °, the treatment is performed with a tool whose tooth line has a circular or arched shape, and the cutting edges are circular or arched tool teeth are located on the flat producing wheel.

The drawing shows a diagram of a method of processing cylindrical gears by shewing-rolling.

The tool 1 is made in the form of a flat producing wheel mounted on a cylindrical mandrel 2, and is rigidly fixed to it by a nut 3. The blank-wheel 4 is mounted freely on a cylindrical mandrel 5.

The method of machining cylindrical gears by shaving-rolling is suitable for machining a billet-wheel with pre-shaped highly productive methods: casting, plastic deformation, machining, and other teeth. According to the method, the tool 1 is mounted on a cylindrical mandrel 2 and fixed with a nut 3. The billet-wheel 4 is mounted loosely on a cylindrical mandrel 5 and is engaged in a tight (clearance-free on the sides) engagement with tool 1. After that, the rotational movement is reported to tool 1 — rolling motion in forward and reverse directions with an angular velocity ω ₀ . In this case, the workpiece-wheel 4 rotates with a speed ω. The specified movement is working because it cuts thin layers of chips and smooths the side surfaces of the teeth of the workpiece-wheel 4 due to the profile sliding of the cutting edges of the tool 1 along the side surfaces of the teeth of the workpiece-wheel 4. Processing of the side surfaces of the teeth along their entire length is provided when two conditions are met: firstly, by the presence of cutting edges offset on adjacent teeth of the tool 1 relative to each other, formed as a result of the intersection of its side surfaces teeth with helical surfaces of the chip groove; secondly, the absence of common factors of the number of teeth of the tool and the workpiece-wheel 4. The lateral surfaces of the teeth of the workpiece-wheel 4 are formed for the number of revolutions of the tool 1, equal to the number of teeth of the workpiece-wheel 4. The workpiece-wheel 4 makes the number revolutions equal to the number of teeth of the tool 1. Next, make a cutting - the approach of the axes of the tool 1 and the wheel blank 4 intersecting at an angle of 90 °, with intermittent feed S _bp by 0.03 ... 0.05 mm. This completes one work cycle. For a complete processing cycle, to remove the entire allowance from the side surfaces of the teeth of the workpiece-wheel 4, it is necessary to carry out from two to five duty cycles. When the nominal center distance a _{w is} reached, the infeed S _{b p is} stopped. To improve the quality of processing, after the end of the working cycles, nursing is carried out - the tool is rotated in the forward and reverse directions at the nominal center distance and on axes intersecting at an angle of 90 °.

To ensure high parameters of productivity and quality of processing, the number of teeth z _{0 of the} tool 1 should have the greatest possible value, as well as be determined by the rational dimensions of its outer diameter d ₀ . The diameter of the initial circumference of the wheel blank d _w is chosen so that it is outside the limits of its active section of the profile, i.e., pre-polar or polar gearing P. is provided. In this case, there will be no points at which the sliding speed is zero over the entire working section of the tooth profile.

The proposed method was implemented when processing a cylindrical gear with circular teeth with a module m = 2 mm, the number of teeth z = l1, the displacement coefficient of the original contour χ = 0, the nominal radius of curvature of the tooth arch R = 20 mm, made of steel 20X. Preliminary shaping of the teeth of the billet-wheel was carried out by one incisor head. The final processing was carried out with a tool with the following parameters: module m ₀ = 2 mm, number of teeth Z _o = 31, displacement coefficient of the initial contour χ ₀ = 1,909 mm. Processing modes: removable allowance, determined by the scan of the initial cylinder in the middle section of the tooth, - 0.12 mm, tool rotation speed n = 125 min ^-1 , infeed feed 0.03 mm per working cycle, number of working cycles - 4, number of cycles nursing - 2.

The kinematic accuracy of the gear after processing by shewing-rolling increases by 1 degree, and the norms of smoothness - by 2-3 degrees.

The presented data indicate the possibility of applying the proposed method for the effective processing of cylindrical gears with a small number of teeth, as well as high productivity and correcting ability of the proposed method.

Claims (1)

A method of processing cylindrical gears with a circular or arched tooth shape by shearing-rolling, including a free run-in of a tool having cutting edges displaced along a helical surface and a machined wheel, while engaging the tool with the machined wheel is performed out-of-pole, and processing is carried out with periodic radial feed after each of 2-4 working cycles, including turning the tool in the forward and reverse directions by the number of revolutions equal to the number of teeth of the machined wheel, and without radial feed for 1-2 nursing cycles, including turning the tool in the forward and reverse directions by the number of revolutions equal to the number of teeth of the machined wheel, using a tool whose number of teeth does not have common factors with the number of teeth of the machined wheel except one, the tool and the wheel blank are mounted on axes intersecting at an angle of 90 °, the treatment is carried out with a tool whose tooth line has a circular or arched shape, and the cutting edges of circular or arched teeth tools are located on a flat producing wheel.

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