高速旋削に対応した切削抵抗

External turning as an example, there are three turning components: main turning force Fc (Fz), depth resistance Fp (Fy) (also called radial force), feed resistance Ff (Fx) (also called axial force).
The main turning force is the most important. In the case of neglecting the power consumption of Ff, the turning power is Pc=Fc.v×103 (kw) where Fc and the unit N; the unit of v is m/min.
初期の頃, 高速旋削時の切削力試験を実施. 図に示すように 1, 曲がるとき 45 鋼鉄 (正規化する, HB187), 旋回速度を100m/minから270m/minに上げた場合, 主な回転力は約約減少します 7%. 図に示すように 2, 鋳造アルミニウム合金 ZL10 旋削加工時 (HB45), 旋回速度を100m/minから720m/minに上げた場合, 主な回転力は約約減少します 50%.

When turning steel, the effect of cutting speed on turning force

形 1. The effect of turning speed on cutting force when turning 45 鋼鉄 (ap=3mmf=0.25mm/r)

When turning ZL10, the influence of cutting speed on turning force

形 2. The effect of turning speed on cutting force when turning ZL10 (ap=4mmf=0.3mm/r)

A university used LT55 ceramic turning tool to turn 45 鋼鉄 (quenched and tempered, HRC35～40). The relationship between turning force and cutting speed is shown in Figure 9. It can be seen from Figure 9 that the cutting force is the largest when the turning speed is about 300m/min, and it decreases immediately. The cutting force does not change much when the turning speed is above 500m/min.

Cutting force of ceramic tools when turning quenched and tempered steel

形 3, the cutting force when turning 45 quenched and tempered steel with ceramic turning tool
A certain university conducted a turning force test of quenched and tempered steel (HRC30～32) and hardened steel (HRC50～52). Quenched and tempered steel: ap=0.2～0.5mm, f=0.1～0.25mm/r, v=700～1000m/min. Hardened steel: ap=0.15～0.5mm, f=0.1～0.25mm/r, v=100～400m/min. A three-factor formula for the three-way turning force is established (テーブル 1).

Three-factor formula of high-speed turning force

テーブル 1. Three-factor formula of high-speed turning force
The turning rate manual lists: the cutting force experience of turning medium carbon structural steel at normal speed, the formula is
Fz=Czap1f 0.75v-0.15
Fy=Cyap0.90f 0.60v -0.3
Fx=Cxap1f 0.5v-0.4

Compared with Table 1, there is a big difference. The formula in Table 1 may be problematic. Compared with turning, the milling force formula is more complicated, because in addition to the three elements of cutting consumption, there are also factors such as the number of teeth of the milling cutter, the diameter of the milling cutter, and the milling width. The multi-factor empirical formula of cutting force and turning power established in the past for end milling at general cutting speed. The turning force formula under modern high-speed turning is not yet known.
A certain university filled this vacancy. A three-factor formula for turning force is made:
Within the range of ap=0.5～1mm, f=0.05～0.2mm/r, v=251～1256m/min,
Fc=5018ap0.344fz0.364v-0.394 (旋回 45 鋼鉄)
Fc=864ap0.384fz0.176v-0.287 (turned aluminum alloy 5A02)
It seems that the data obtained from the experiment is not ideal, which can be used for reference.
A certain university used ceramic cutters to turn hardened steel, high-strength steel, and hard nickel cast iron at high speed and did a fruitful turning force test.
(1) LT55 (Al2O3TiC) ceramic tool for turning hardened 45 鋼鉄 (HRC50～55), v =30～120m/min, ap=0.35～1.4mm, f=0.08～0.32mm/r, Fz=2525 ap0.99 f 0.80 v-0.01(N)
(2) LT55 tool is used for turning ultra-high-strength steel 35CrMnSiA (HRC45～48), the cutting amount range is the same as above.
Fz=2779 ap0.79 f 0.59 v -0.08(N)
(3) SG-4 (Al2O3-TiC, WC) Ceramic Tool cutting hardened high carbon tool steel (HRC55 ~ 62), the cutting amount in the range above.
Fz=3444 ap0.88 f 0.65 v -0.12(N)
(4) SG-4 tool is used for turning hardened 45 鋼鉄 (HRC50～55), the cutting amount range is the same as above.
Fz=2309 ap1.04 f 0.75 v -0.01(N)
(5) AT6 (Al2O3―TiC) ceramic tool for turning hard nickel cast iron (HRC56～62)
V =50～70m/min, ap=1.5～2.3mm, f=0.09～0.16mm/r
Fz=1210 ap0.73f 0.42v-0.09(N)
The cutting force test data for high-speed turning of hard materials with ceramic tools is more credible.