Technical Trends Regarding Machine Tool High-Efficiency Machining, Main Spindles and Bearings

Technical Trends Regarding Machine Tool High-Efficiency Machining, Main Spindles and Bearings A. CHIKAMORI * H. URANO ** * Koyo Machine Industries Co., Ltd. **Product Engineering Center, Aerospace & Super Precision Engineering Department Various kinds of production systems have been established with high efficiency and flexibility in order to respond to the diversification of customer needs and machining cost reduction requests from makers. Manufacturing machines, which are considered to be at the core of the production system, play a very important role in achieving high manufacturing capability and efficiency. Machining centers, which can be considered general purpose manufacturing machines, have recently made rapid advances with regard to their high efficiency. The main spindle is one of the most important parts of a machine tool for achieving this high efficiency, and the main spindle bearings are an essential component for promoting high-speed operation. This paper presents the current status and future technical trends for main spindles and bearings. 1. Introduction Various kinds of production systems have been established with advanced efficiency and flexibility in order to respond the diversification of consumer needs and user demands of cost reduction. Manufacturing machinery functions as the core of the production system, and therefore improving capability and efficiency of such machinery is extremely important. Machining centers are production machinery designed for general use. In recent years there has been striking progress in high-efficiency machining of machining centers. Using multithread ball screws or linear motors for feeding the table and main spindle has made feed rates of 60 m/min or more possible. Machining centers having feed rates of 80 to 100 m/min have also been developed and are now being improved for practical use. In the MAS standard BT40 class, the main spindles for machining work are becoming capable of higher speeds and output. The main spindles of this size are generally operating at speeds between 20 000 to 30 000 min 1. As a results of progress related to inverters, spindles are being equipped with motors rated at 30 kw of power or higher. For some spindles, automatic tool changing (ATC) time is now less than one second, and the percentage of actual machining time during the total machining cycle time is steadily increasing. As shown in Fig. 1 1), when automobile part machining simulation is done, based on the current level of manufacturing machinery, main spindle high-speed operation directly involved in actual machining time is an important factor in high-efficiency machining. This paper reports on the current status and future direction of the main spindle, one of the important factors for highly efficient machining, and rolling bearings, which contribute to higher speeds 2). Time, sec 400 300 200 100 0 Tool changing time Main spindle control time Positioning time Machining time,,,, Case 1 Case 2 Case 3 Case 4 Case 5 Case 1 Case 2 Case 3 Case 4 Case 5 Machining conditions Current Current Current High-speed High-speed Table feed rate, mm/min 30 60 60 30 60 Table feed rate (acceleration/deceleration), m/s 2 3.4 3.4 12 3.4 12 Spindle speed, min 1 10 000 12 000 12 000 25 000 25 000 Spindle acceleration 3.7 1.5 1.5 3.3 3.3 / deceleration, sec Fig. 1 Machining cycle time simulation of automobile parts 39

Table 1 Results of analysis of machine tools exhibited at the 19th Machine Tool Trade Fair, held in Osaka in 1998 Maker Machine Spindle style Speed, min 1 Main spindle diameter, mm Taper No. Lubrication method Rolling element material Bearing preload method Drive system dn value, 10 4 A Machining center Vertical type 20 000 65 NC5-63 Under-race oil/air lubrication Ceramics Spring method Built-in 130 A Machining center Vertical type 8 000 100 NC5-85 Oil/air lubrication Ceramics Spring method Gear 80 A Machining center Horizontal type 14 000 70 40 Oil/air lubrication Ceramics Spring method Built-in 98 B Machining center Horizontal type 10 000 110 50 Oil/air lubrication Ceramics Spring method Built-in 110 B Machining center Horizontal type 25 000 60 HSK63A Oil/air lubrication Ceramics Changeover Built-in 150 B Machining center Vertical type 35 000 60 KM6350 Oil/air lubrication Ceramics Spring method Built-in 210 C Machining center Horizontal type 15 000 65 40 Oil/air lubrication Ceramics Gear 98 C Machining center Horizontal type 10 000 100 50 Oil/air lubrication Ceramics Gear 100 C Machining center Vertical type 15 000 65 40 Oil/air lubrication Ceramics Gear 98 D Internal grinder Horizontal type 100 000 20 Oil mist lubrication Ceramics Built-in 200 D Internal grinder Horizontal type 50 000 40 Oil mist lubrication Ceramics Built-in 200 D Internal grinder Horizontal type 29 000 35 Grease Ceramics Belt 102 D Internal grinder Horizontal type 60 000 40 Oil mist lubrication Ceramics 240 E Machining center Horizontal type 15 000 70 40 Oil mist lubrication Ceramics 105 F Machining center Vertical type 25 000 70 40 Oil/air lubrication Ceramics Spring method Built-in 175 F Machining center Vertical type 10 000 90 Oil/air lubrication Ceramics 90 F Machining center Horizontal type 15 000 55 Oil/air lubrication Bearing steel 83 G Machining center Horizontal type 15 000 90 BIG50+ Oil/air lubrication Ceramics Direct couple 135 G Machining center Vertical type 10 000 100 50 Oil/air lubrication Ceramics Locating method Direct couple 100 G Machining center Vertical type 20 000 65 40 Oil/air lubrication Ceramics Locating method Direct couple 130 H Machining center Vertical type 12 000 80 40 Under-race oil/air lubrication Ceramics Locating method Built-in 96 H Machining center Horizontal type 12 000 100 50 Under-race oil/air lubrication Ceramics Locating method Built-in 120 H Machining center Horizontal type 12 000 80 40 Under-race oil/air lubrication Ceramics Locating method Built-in 96 I Machining center Horizontal type 12 000 100 50 Oil mist lubrication Ceramics Locating method Built-in 120 I Machining center Vertical type 12 000 100 50 Oil mist lubrication Ceramics Locating method Built-in 120 I Machining center Vertical type 12 000 70 40 Grease Ceramics Locating method Built-in 84 J Machining center Vertical type 60 000 25 20 Oil/air lubrication Ceramics Locating method Built-in 150 J Machining center Vertical type 8 000 100 50 Oil/air lubrication Ceramics Locating method Direct couple 80 J Machining center Vertical type 12 000 80 40 Grease Ceramics Locating method Direct couple 96 K Machining center Vertical type 12 000 80 40 Oil mist lubrication Ceramics Built-in 96 L Machining center Horizontal type 20 000 100 50 Under-race oil/air lubrication Ceramics Built-in 200 L High-speed manufacturing machine Horizontal type 50 000 50 Collet Hydrostatic air bearing 250 L Machining center Vertical type 12 000 90 50 Oil mist lubrication Ceramics Built-in 108 M Machining center Vertical type 20 000 75 40 Oil/air lubrication Ceramics Locating method Built-in 150 N Machining center Horizontal type 25 000 65 HSK6350 Oil mist lubrication Ceramics Changeover Built-in 163 O Machining center Horizontal type 20 000 70 HSK63A Oil/air lubrication Ceramics Spring method Built-in 140 O High-speed manufacturing machine Horizontal type 40 000 65 KM5040 Jet Ceramics Spring method Built-in 260 O Machining center Horizontal type 15 000 100 50 Oil/air lubrication Ceramics Built-in 150 P Machining center Horizontal type 16 000 75 HSKA63 Under-race jet lubrication Ceramics Locating method Built-in 120 P Machining center Vertical type 20 000 90 40 Under-race jet lubrication Ceramics Locating method Built-in 180 Q Machining center Vertical type 36 000 30 20 Oil/air lubrication Ceramics Spring method Built-in 108 40

2. Transition of High-Efficiency Machining Machine tools have evolved along two parallel routes to meet the production demands of productivity and flexibility. To meet the flexibility requirements of modern industry, the machining center evolved along the first route by taking numerical control (NC) and integrating it with the function provided by the automatic tool changing (ATC). To meet the high productivity demands and thereby address the question of how economical mass production can be, the second path that was followed combined the single purpose machine and the NC special purpose machine based on the process allotment concept and evolved into the transfer machine (TR). Transfer machinery can provide quality assurance with an extremely high productivity rate relative to initial investment. The current trend has manufacturers attempting to control the increase of part types by making common parts for diversified production; however, the number of items continues to increase steadily. In order to settle this problem, Flexible Line Transfer (FTL), or being able to handle various kinds of machining by automatic change of many spindle heads etc., has been developed and has come to be introduced. But FTL is said not to have enough flexibility to satisfy production requirements. Furthermore, the development of machine tools with higher efficiency than present ones is probably be desired. 3. Trends Related to High-Speed Main Spindles 3. 1 High-Speed Spindles Increasing the main spindle speed is an important element in raising production efficiency. To study the high-speed spindles, Koyo conducted a study of bearings mainly for machining centers at the 19th JIMTOF held in November 1998. Results corresponding to high-speed spindles are given in Table 1. Table 1 shows that many spindles can be operated at speeds of 15 000 to 30 000 min 1. Because in this speed range there are problems related to belt and gear drive heat generation, output, vibration, etc. that are difficult to handle, spindles with built-in high-output motors are often used. Also spindles for machining center, not only run at high-speeds but have variable functions for the purpose of increasing machining efficiency. Because of this, machining of 4 000 cc/min or more is possible. An example is given in Table 2. Here, an example of a built-in type high-speed main spindle is shown in Fig. 2. The spindle has a tapered bore at the end to mount a tool holder, but recently manufacturers are switching from the retaining system of the tapered part only to the two-surface constraining system that holds the tool holder due to contact at both the inside taper and spindle shoulder. On the tool side, four rows of ceramic angular contact ball bearings with ceramic balls are used for the bearings that support this spindle to increase spindle rigidity, and two rows of ceramic angular contact ball bearings are similarly used for the rear. Angular contact ball bearings that have little bearing internal Table. 2 Milling of aluminum (example) Face mill of φ80 with four blades End mill of φ32 with two blades Rotation sensor Ceramic angular contact ball bearing High-output motor Ceramic angular contact ball bearing (with outer ring) Cutting volume 4 000 cc/min Main spindle speed 11 500 min 1 Feed rate 18 400 mm/min Machining width 50 mm Machining depth 40 mm Cutting volume 3 000 cc/min Main spindle rotation speed 20 000 min 1 Feed rate 12 000 mm/min Machining width 20 mm Machining depth 12 mm HSK-A63 φ70 φ220 Drawbar Fig. 2 High speed spindle of built-in-type (example) loss and enable high precision are commonly used in many cases for high-speed spindles. For these bearings, ceramic balls have low specific gravity and little effect of centrifugal force at high-speed, and are therefore used more often as rolling elements than steel balls. Also, the bearing preload shown in Fig. 2 is a method of constant preload given by springs. In addition, there is also preload given by locating method that controls axial clearance of the bearing. Preload given by the locating method is often used for high speeds. 325 760 41

Both preload methods have their respective characteristics regarding rigidity, temperature rise and vibration, and are properly selected according to running conditions. Also, the following functions are also required of main spindles for machining centers in addition to high speed performance. 1) Drawbar for automatic tool changing 2) Through tool cooling 3) Small main spindle heat displacement 4) Orientation 5) High power 6) High rigidity 7) Easy main spindle assembly 3. 2 Bearings for High-Speed Main Spindle A summary of Table 1 concerning trends of bearings for high-speed main spindles is as follows: 1. Bearings with ceramic rolling elements are often used for main spindles in which the dn value (bearing inner diameter mm rotation speed min 1 ) is in excess of 1 000 000. It can be said that ceramic rolling elements are generally used. With the use of ceramic rolling elements and oil/air lubrication as the lubrication method, a dn value of 2 000 000 (d m n value: approx. 2 500 000, d m n value is bearing P.C.D. mm rotation speed min 1 ) has become practical. With the use of ceramic rolling elements and grease as the lubrication method, a dn value 1 000 000 (d m n value: approx. 1 250 000) has become practical. 2. The most commonly used lubrication methods are oil/air lubrication and oil mist lubrication. Because jet lubrication requires a large amount of lubricant and complicated ancillary equipment and has large dynamic loss due to stirring resistance of the lubricant, it tends to be avoided. 3. Roller bearings and hydrostatic air bearings are used to support machine tool spindles. Problems associated with hydrostatic air bearings are low load capacity, low rigidity and high cost. Rolling bearings therefore occupy the majority of the market. Spindles using magnetic or hydrostatic air bearings can be found, and those that install both these bearings to cover the weak points of each other were exhibited. 4. Bearing makers have exhibited prototype spindles with locating method preload, ceramic rolling elements, oil/air lubrication and shaft-center cooling to make rolling bearing speeds of dn value 3 000 000 (d m n value: 3 600 000) possible. Further means of increasing the speed of rolling bearings include improving centrifugal force, rigidity, heat generation, life and lubrication method. Reduction of bearing centrifugal force is considered from the aspect of internal design. If the ball diameter is made smaller, the effect of centrifugal force is reduced (even more in case of ceramic balls) 3), the sliding of balls is diminished, and heat generation is restrained. Displacement relative to load is also reduced, as shown in Fig. 3. We have given attention to ball diameter and the number of balls (if ball diameter is larger, the number of balls in the bearing is reduced; if ball diameter is smaller, the number of balls increases; the number of balls is naturally decided according to the ball diameter) and the relationship with rigidity in Fig. 3. No. of balls Few Many Small Large Ball diameter No. of balls Axial displacement Radial displacement Fig. 3 Relationship between ball diameter, number of balls and displacement Small Large Displacement It is known that if the ball diameter is reduced and the number of balls increases, rigidity goes up. However, if ball diameter becomes smaller, the basic dynamic load rating decreases, and therefore the calculated life is reduced. As a life improvement countermeasure, ceramic, carburized steel, or high refining steel can be used as the material for the raceways or rolling elements, and the rolling surfaces can receive carburizing or carbonitriding treatment. Critical circumferential stress is improved if a carburizing or carbonitriding part is used for the raceway, and therefore such parts are also effective for centrifugal fracture. In addition to supplying oil from the side, lubrication methods to improve bearing lubrication reliability include supplying oil from the outer ring side (see Fig. 4) and under-race lubrication. By considering these themes, a d m n value of approximately 4 000 000 would be possible for rolling bearings. Fig. 4 Bearing with an oil inlet hole (example) 42

4. Conclusion Items to study in relation to high-efficiency machining include discharge of chips, transfer rate of the main spindle, transfer rate of the work, the blade change rate and the acceleration/deceleration time of main spindle. Of these, raising the main spindle speed is considered most effective. Using ceramic for the rolling elements and oil/air lubrication for the lubrication of high-speed main spindle bearings has made a dn value 2 000 000 (d m n value: approx. 2 500 000) possible, and using ceramic for the rolling elements and grease for lubrication has made a dn value of 1 000 000 (d m n value: approx. 1 250 000) possible. Furthermore, using the spring preload method and cooling through the center shaft has shown the possibility of enabling a dn value of 3 000 000 (d m n value: 3 600 000). It is believed that machining speed will continue to increase in the future, but bearings must be improved comprehensively in the areas of centrifugal force (centrifugal fracture, etc.), rigidity, vibration, unbalance, heat generation, life, drive method, lubrication method and simplification of lubrication equipment. Also, overcoming conflicting items will probably be a theme in the future. References 1) T. Takada, Y. Yamaoka, K. Suzuki, H.Mizumoto : 1996 Seimitsu Kogakukai Shukitaikai Gakujyutsukoenkai Koen Ronbunshuu. (International Symposium on Technology for Angle Manufacturing, 1996). 2) A. Chikamori, H. Urano : Gekkan Toraiborogii (THE TRIBOLOGY), 139, 3 (1999) 4. 3) Y. Kawakami, H. Urano : Gekkan Toraiborogii (THE TRIBOLOGY), 118, 6 (1997) 30. 43