Process method for forging low door type front axle of heavy commercial vehicle

Abstract

The invention relates to a process method for forging a low door type front axle of a heavy commercial vehicle, which mainly includes the steps: producing a forging piece with the weight larger than that 140Kg on a 125MN hot die forging press; adopting a three-path rolling forging die; setting a V-shaped groove for the forming bending die, and extruding a spring seat portion difficult to form in advance to form; performing die stripping by adopting the smallest draft angle, namely, when a spring seat is wider than 170mm, a lubricating device and an ejecting device are in normal operation, and the draft angle is 1.5 degrees; by means of designing the die into a step shape, sectionally burring so that equipment loads are reduced; and burring after the die firstly contacts with the middle of the front axle and then contacts with two ends of the front axle, so that burring is continuous and the equipment loads are reduced. The process method has the advantages that raw materials and energy resources are saved, forging qualified rate is increased, and production efficiency is improved.

Description

technical field

[0001] The invention relates to a forging process technology, in particular to a forging process method for a front axle of a low-door heavy commercial vehicle. Background technique

[0002] In the past, the traditional automobile front axle was made of alloy forged steel and formed by die forging with large-scale forging equipment. The forging die used in this type of die forging has a long processing cycle, expensive raw materials, large investment, and a certain amount of waste. More importantly, the existing low-door heavy-duty commercial vehicle front axle has a large drop and a large cross-section change, so that the traditional forging process is prone to creases and is not full enough; the blank used for production weighs nearly 180Kg, and the The load-bearing limit of the manipulator is nearly 340mm, which is close to the limit of the manipulator’s turnover, resulting in poor process stability, many quality problems, and low production efficiency. T...