DE102020204380A1 - METHOD OF GRINDING WORKPIECES WITH A SCREW-SHAPED PROFILE AND GRINDING MACHINE FOR MANUFACTURING SUCH WORKPIECES - Google Patents

Abstract

A method and a grinding machine for grinding a workpiece are provided on which a profile 5 corresponding to the profile 3 of the grinding wheel 4 is formed as an end contour on its outer circumference by means of a grinding wheel 4 having a helical profile 3. The profile 5 can be ground from a cylindrical solid material 6 or from a raw workpiece which has an oversize with respect to the final contour, with the final contour being ground in both variants. The cylindrical grinding wheel 4 has on its outer contour 7 a helically encircling groove 8 which, with the web 9 flanking the groove 8, forms a profile 5 which is ground by plunge grinding of the grinding wheel 4. The speed of the grinding wheel 4 is synchronized with its speed when grinding the workpiece 1. In the axial direction, the grinding wheel 4 executes at most a slight axial movement 10, referred to as shifting, for grinding the shape of the web 9 delimiting the groove 8.

Description

The invention relates to a method for grinding a workpiece with a helical profile on its outer circumference and a grinding machine for producing such a workpiece.

Such grinding methods and grinding machines for carrying out such a method are known. The helical, profiled workpieces are, for example, worms on worm shafts for gears. They represent relatively complicated components and require a correspondingly high expenditure in terms of equipment and process technology for their manufacture. Such components are used in various transmissions in the automotive sector. They are therefore required in relatively large numbers, so that the manufacturing costs play a central role in addition to the required high precision of these components.

These screw elements are also referred to as helically grooved workpieces, for which there are various options for grinding their groove geometry. The groove geometry, as well as the grinding thereof, is in many cases especially tailored to the use of such worm elements in worm gears, for which there are considerable differences in terms of their size and accuracy requirements depending on the purpose of the gearing. In addition to the size, these differences are also reflected in the required accuracies. Above all in the automotive sector, many small or medium-sized gearboxes are required in large numbers. Despite the high number of units, in most cases the highest quality requirements are placed on the respective gear units. There is therefore a general endeavor to be able to keep the production costs at least moderate.

Such a large area of application for the screw elements or helically grooved workpieces is, for example, their use in worm gears for hydraulic or electrical steering systems in the automobile sector. In addition to the high precision required for this in connection with the high number of pieces required, the cycle time is of great importance in order to achieve acceptable manufacturing costs. Continuous generating grinding, also in connection with profile grinding, has established itself for grinding such components that are complex in terms of their surface, such as helically grooved tools or worm elements.

The textbook Heisel / Klocke et al, Handbuch Spanen, Hanserverlag, page 667, Chapter 13.4.4, describes the structure of grinding machines for continuous generating grinding. This continuous generating grinding process was developed further from 1990 onwards because of the increasing improvement in CNC technology in line with the demanding dressing process in the machine for the grinding tool in the form of a worm in a dressable version. In particular, corundum-based grinding wheels are used for this purpose. Machines with electroplated CBN wheels have also been used, but these non-dressable grinding wheels have not caught on. Rather, the development was aimed at achieving the accuracy of the helically grooved workpiece to be ground by frequently dressing the dressable grinding wheel so that the accuracy could be improved. An additional dressing process, if necessary after each individual grinding process, naturally increases the cycle time and also the costs of the tool.

With helical grinding, the helical grinding wheel is swiveled with its A-axis to an angle and set in rotation. The workpiece speed is linked to the speed of the worm. The allowance on the workpiece is removed by means of a radial infeed (X) and an axial stroke (Z). This continuous generating grinding is mainly used in the manufacture of helical gears. In the case of helical gears, an additional rotation must be carried out with the workpiece axis. For this purpose, an electronic coupling is made between the Z and C axes. In most cases, a so-called tangential shifting of the worm is carried out during the axial stroke in order to bring new grinding wheel material to use. This means that the shifting described in this prior art is part of the dressing process and, for reasons of wear, extends over the entire width of the grinding slide, but is not part of the movement process carried out by the grinding wheel. Profile modifications are introduced when dressing the grinding wheel. If, in addition to the profile modifications, tooth trace modifications are required on the grinding wheel, these are generated during dressing by additional movements of the X-axis and the C-axis during the dressing axial stroke. In the case of this known prior art, it has already been pointed out that productivity can be improved if continuous generating grinding is used for roughing, while profile grinding, in particular, is used for finishing.

Furthermore, in Klocke / Brecher, Zahnrad- und Getriebetechnik, Hanserverlag, pages 248 to 250, the continuous generating grinding for medium and large-scale production is described. In this prior art, too, it is described that in continuous generating grinding a Helical tool is used, the profile of which has an involute in the end section of the screw. This continuous generating grinding is used for grinding gears, especially helical gears. A simultaneous rolling movement of the workpiece and the helical grinding wheel takes place, so that the shape of the involute of the respective tooth on the workpiece is continuously generated in the so-called envelope cut process. Tooth modifications can be generated by a reference profile modification as well as by the axis kinematics. The worm-shaped grinding wheel is swiveled by a swivel angle to the toothing and is moved continuously over the entire toothing width during machining in the axial direction at the feed speed. In this prior art, the continuous axial movement occurring over the entire width of the gear wheel is described as a continuous shift movement, which preferably takes place during roughing. Since only very marginal amounts of material are removed during finishing, finishing is carried out without this shift movement. This continuous axial offset or axial feed ultimately serves to ensure that the entire width of the grinding wheel, which is designed as a worm, can be used for grinding, i.e. the continuous shift movement relates to wear and has nothing to do with achieving high dimensional accuracy . With this prior art, too, all profile modifications such as crowning, setbacks and angle modifications are achieved by modifying the tool profile during the dressing process. This means that in the case of the continuous generating grinding process it is uniformly understood in the prior art that this is used above all for grinding wheels that are to be dressed after each grinding process. However, this stands in the way of the intended use of these screw elements in large numbers in the automotive sector for reasons of cost. The worm-shaped grinding wheel, also known as the grinding worm, used in continuous generating grinding of especially helical gears, is therefore moved axially, so that ultimately with each web, which is ground by the helical shape impressed on the workpiece accordingly, here a helical gear.

And finally are in DE 10 2008 035 525 B3 a method for producing a screw compressor rotor with a cylindrical basic contour and a grinding machine for grinding a workpiece with a cylindrical basic contour, which has a helical profile on its outer circumference, is described. This prior art assumes that continuous generating grinding can also be applied to the grinding of screw compressor rotors, the pre-grinding and / or finish grinding being carried out with a helical grinding tool in precisely this continuous generating grinding process.

Furthermore, this prior art document describes that a profile grinding wheel can also be used for the finish grinding in the profile grinding process, the pre-grinding also being carried out in the continuous generating grinding process because of the relatively large material removal that occurs during rough grinding. A raw workpiece is ground with the grinding wheel described, which has the end profile to be ground with a corresponding allowance to be ground. For this purpose, in the known machine described, a worm-shaped grinding tool is used for the roughing process and a profile grinding wheel is used for the finishing process. Both in continuous generating grinding and profile grinding, the respective grinding wheel is offset in the axial direction in order to grind the entire width of this workpiece according to the slope of the helically grooved workpiece while optimizing the wear of the respective grinding wheel. This is intended primarily because dressable tools are also to be used. The helical grinding tool is preferably a grinding tool with a cylindrical outer contour, in which an axial continuous movement of the helical grinding wheel with respect to the longitudinal axis of the workpiece to be ground is carried out in order to use all tooth flank sections during the grinding process. In DE 10 2008 035 525 B3 The use of a non-cylindrical worm-shaped grinding wheel, a so-called globoid worm, is also addressed, which has a diameter that tapers in its longitudinal direction from the edge to the center and then again continuously increases in diameter to the other edge based on the entire width of the Has formed helical grinding wheel. If such a globoid worm is brought into engagement, the axial stroke would not be required, or only to a limited extent, because in terms of wear and tear due to the fact that the globoid worm has at least one globoid section on its outer circumference, whereas the workpiece is cylindrical has, several webs would be in engagement between the circumferential grooves of the globoid worm. However, these grinding tools are extremely complex in their geometrical structure, nor do they prevent them from having to be dressed in their complex outer shape, so that a corresponding accuracy can be achieved on the workpiece to be ground, which is why the globoid Snails have not prevailed in the prior art. They are simply too expensive to manufacture, so that the manufacture of a mass-produced article, for which the transmissions in the automotive sector with such worm elements are intended, is by no means recommended. This would make the production costs of workpieces intolerably high.

The object of the present invention, compared to the grinding method known in the prior art and the grinding machine described there, is that a helical element is formed on a workpiece by grinding, which has a high accuracy, is suitable for mass production and can be produced at moderate production costs can.

This object is achieved by a method according to claim 1 and a grinding machine according to claim 8. Appropriate further developments are set out in the respective dependent claims.

According to the invention, the method for grinding a workpiece has a profile as the final contour, the profile being present as a negative profile in a grinding wheel grinding the workpiece. The workpiece is preferably a worm shaft. The grinding of the profile by means of the helically profiled grinding wheel is ground to the final contour from a cylindrical solid material or from a raw workpiece, which raw workpiece has the basic shape of the profile compared to the final contour, but is provided with an allowance compared to the final contour. The grinding wheel with the helical profile is cylindrical on its outer contour, the outer contour corresponding to the profile to be ground on the workpiece, also having a helical circumferential groove, which is, so to speak, the positive to the negative of the helical profile of the grinding wheel. The grinding wheel having the helical profile grinds the helical circumferential groove of the profile between a respective web by plunge-cut grinding on the workpiece. In relation to an imaginary plane through the longitudinal axis of the workpiece, the grinding wheel provided with the helical profiling has a circumferential web, between which the circumferential groove is arranged. The use of plunge-cut grinding has the advantage that the infeed movement of the grinding wheel towards the workpiece is simple. With regard to its speed when grinding the workpiece, the grinding wheel is synchronized with the speed of the workpiece. This means that if the grinding wheel has a single-thread helical profile, it has the same speed as the workpiece. With a two-thread helical profile on the workpiece, the speed of the grinding wheel is twice as high as that of the workpiece. The speed of the grinding wheel therefore corresponds to the speed of the workpiece multiplied by the number of turns of the helical shape of the workpiece. According to the invention, the grinding wheel performs at most a slight axial movement relative to the workpiece in order to grind the shape of the respective web delimiting the groove. At most, a slight axial movement means that, depending on the shape of the respective webs of the profile to be ground on the workpiece, no such movement or only a slight axial movement is required. It is therefore a modified plunge-cut grinding, which can be carried out more easily due to the technological conditions and thus has a positive effect on reduced manufacturing costs of the workpiece.

Since the diameter of a workpiece is reduced when grinding a workpiece, whereas the diameter of the grinding wheel remains almost unchanged, the cutting speed, which is set during grinding, changes, since both rotate at the same speed from the drive. Since the speed is usually ground in a range of 1,000 to 3,000 rpm, the grinding wheel must rotate with a double-flight worm profile at a speed of 2,000 to 6,000 rpm. Assuming an average workpiece diameter of, for example, 20 mm and a grinding wheel diameter of 400 mm, this results in a cutting speed of 45 to 130 m / s over this speed range. Usual cutting speeds are in the range of 80 to 100 m / s, which is mainly used when grinding with CBN grinding wheels. When grinding with corundum grinding wheels, the cutting speed is in the order of a maximum of approx. 60 m / s. These required high cutting speeds require relatively high speeds both for the workpiece and for the grinding wheel as well as the greatest possible difference in diameter between the workpiece diameter and the diameter of the grinding wheel. In order to maintain these grinding parameters, worm shafts of small to medium-sized dimensions, which are also manufactured in large numbers, are particularly suitable. The usual diameter for workpieces of this type is therefore mostly in the range from 10 to 50 mm. Of course, other, in particular larger, dimensions are also possible, but this requires an adaptation of the corresponding dimensions of the grinding machine or the grinding wheels and corresponding technology parameters.

In contrast to the continuous generating grinding described in the prior art, the modified plunge-cut grinding According to the invention, a small axial movement for grinding the shape of the web delimiting the groove is also referred to as shifting. However, this shifting is not carried out as part of the dressing of the grinding wheel, but rather serves to correct the dimensions or shape of the profile to be generated on the workpiece by means of the grinding wheel during grinding. The grinding wheel having the helical profile is therefore axially offset in relation to the workpiece in the context of the modified plunge-cut grinding to achieve a dimension or shape correction, which is what is known as shifting. The preferred use of abrasion-free abrasive coatings, such as ceramic-bonded or electroplated abrasive coatings in the form of CBN, enables the grinding wheel to move accordingly, so that the required shape and the required final dimensions are possible on the workpiece within the framework of the tightest tolerances. As a result of the modified plunge grinding, which is technologically simpler than continuous generating grinding, the manufacturing costs are significantly reduced in accordance with the task. In addition, the cycle times in production are reduced, and at the same time the precision of the workpiece having the helical profile with the final contour is guaranteed despite the large number of pieces.

The method according to the invention is also particularly suitable for rough and finish grinding in a single set-up. The described grinding parameters and dimensions of workpiece and tool enable long tool life, which can be in the range of, for example, 40,000 ground grinding worms. As a result, the tool costs for rough and finish grinding can be reduced considerably. Under defined conditions, it is also possible for the method according to the invention to grind multi-start worms or threads. Overall, the method according to the invention achieves a high quality for roundness, concentricity, dimensional accuracy, diameter tolerance, surface quality, the achievable surface quality Rz1 even being achievable after finish grinding.

The grinding wheel preferably performs rough grinding and / or finish grinding and is designed without dressing. This means that plunge-cut grinding, with the possibly slight axial movement of the grinding wheel relative to the workpiece in the sense of a shift movement, can be used for both pre-grinding and finish grinding. In this case, the width of the circumferential groove is preferably corrected to the nominal size. However, it is also possible that this possibly slight axial movement of the grinding wheel with respect to the workpiece is carried out either for pre-grinding or for finish grinding. In this way, costs and quality in connection with low cycle times and high quantities to be produced can be optimally influenced.

Two grinding wheels can also be arranged on a grinding spindle, namely the helically profiled grinding wheel and a second grinding wheel for profile grinding. The two grinding wheels can be swiveled both axially parallel to the workpiece and into the slope of the circumferential groove.

According to the invention, shifting is understood to mean executing an at most slight axial movement of the cylindrical grinding wheel with a helical profile, so that the grinding wheel used for the modified plunge-cut grinding also includes a profile grinding wheel in a certain way or a profile grinding wheel is no longer required separately. This makes it possible to use the helical or thread-like profiling of the grinding wheel in conjunction with the possibly slight axial shifting to achieve, exercise and carry out a certain axial component for profile correction or dimensional correction, which would otherwise require a separate profile wheel. This also has a positive influence on a reduction in costs through reduced costs for the grinding wheels.

Furthermore, it is thereby possible to dispense with the complicated shape of a globoid-shaped grinding wheel, the production of which is associated with high costs and limited usability. The shifting according to the invention has nothing to do with an axial movement of a grinding wheel with a helical profile, which has to be moved over the entire thread length or worm length of the workpiece, and not even if the width of the grinding tool is greater than the length of the thread section on or on the workpiece. Rather, this is necessary for reasons of wear and tear. On the other hand, within the scope of its modified plunge-cut movement according to the invention, the grinding wheel already carries out all those movements which ensure high quality in terms of dimensional and shape accuracy of the helical or thread-shaped element or workpiece.

The grinding wheel according to the invention preferably executes the shift movement upwards or downwards with respect to the longitudinal axis of the workpiece during grinding into the end regions of the profile. More preferably, the shift movement is carried out along the slope of the groove.

In principle, it is of course possible that the grinding wheel is also dressed, even when using a grinding wheel with a CBN grinding layer, namely dressing after it has been determined that a defined deviation from or the presence of a defined dimensional tolerance deviation has been established. According to the invention, production is carried out within the framework of a predetermined maximum dimensional tolerance deviation. When this is achieved, or the final dimension of a ground workpiece approaches this specified dimensional tolerance deviation, the grinding wheel can also be dressed with a correspondingly corrected dressing program CNC-controlled in order to continue to achieve the highest level of quality in terms of dimensional and shape accuracy.

It is also preferably possible for the web, which delimits a respective helically formed groove on the workpiece, to be ground in terms of its shape by means of a second grinding wheel arranged separately for the helical profiling of the grinding wheel. This second grinding wheel is moved along the length of the profile on the workpiece so that the desired end shape of the web or the groove defined by two adjacent webs in between is corrected or the corresponding profile is created with great precision.

According to a second aspect of the invention, a grinding machine for grinding a workpiece, which is helically grooved or has an area designed in the sense of a threaded section, with a grinding wheel, which has a cylindrical and helical profile on its outer circumference, is provided. The workpiece is ground to a desired final contour from the solid or from a raw form with the appropriate allowance, namely by carrying out the method described above. According to this second aspect of the invention, the grinding slide is arranged on a spindle of a grinding headstock. The grinding wheel is fed to the workpiece for grinding by means of an infeed movement carried out in accordance with a plunge-cut grinding process, as a result of which the profile with the helical groove is formed on the workpiece. Plunge-cut grinding with the helical grinding wheel creates the grooves and ridges of the thread section over the entire width of the thread section of the workpiece, in that the plunge-cut grinding process carried out by the grinding wheel generates little or no axial movement along the profile of the tool to be ground. In relative terms, this is such that with this possibly slight axial movement, the web immersed in a respective groove to be ground executes this movement and thus generates or grinds a modification of the width dimension and / or the shape of the flank of the respective web.

The speed of the workpiece and the speed of the grinding wheel are preferably synchronized with each other during grinding, the speed of the grinding wheel being dependent on the speed of the workpiece, taking into account the number of turns of the helical shape or the thread of the workpiece.

The grinding wheel is preferably designed as a rough grinding wheel and / or as a finish grinding wheel. It can therefore be used both for pre-grinding and for finish-grinding, it also being possible for the grinding wheel, according to the invention, to be designed as a pre-grinding wheel and / or as a finish-grinding wheel.

Furthermore, a dressing device for dressing the profiling of the grinding wheel is also preferably provided. The dressing is always carried out when the dimensional and shape accuracy moves in the direction of the maximum tolerance for further quantities to be produced of this workpiece having a thread section. Due to the small axial movement, which is required if the flank shape of the webs still has to be modified after the actual piercing process, a desired cross-sectional shape of the webs delimiting the helical profile of the respective groove can hardly be achieved.

Furthermore, the possibly slight axial movement of the grinding wheel can be superimposed on its main movement component during the actual piercing process. This can be programmed into today's CNC controls.

• 1: ein als Schneckenwelle ausgebildetes Werkstück;
• 2: ein weiteres Ausführungsbeispiel eines ebenfalls als Schneckenwelle ausgebildeten Werkstückes;
• 3: neun Beispiele verschiedener, gemäß der Erfindung schleifbarer Schnecken- bzw. Gewindeprofile;
• 4: eine prinzipielle Darstellung für das erfindungsgemäße Schleifen einer Schneckenwelle in ähnlicher Ausbildung wie gemäß 2;
• 5: eine erfindungsgemäße Schleifanordnung zum Schleifen eines Schneckenelements mit eingeschwenkter Schleifscheibe;
• 6: eine prinzipielle Darstellung eines eine geringe axiale Bewegung darstellenden Shiftens der schneckenförmig ausgebildeten Schleifscheibe;
• 7a,b: eine prinzipielle Darstellung eines weiteren Ausführungsbeispiels des erfindungsgemäßen Schleifens eines Schneckenelements einer Schneckenwelle, unterteilt in a) Vorschleifen und b) Fertigschleifen mit jeweils unterschiedlichen Schleifscheiben;
• 8: ein weiteres Ausführungsbeispiel für das erfindungsgemäße Schleifen einer Schneckenwelle im Sinne einer Komplettbearbeitung aus einem Vollmaterial;
• 9: ein weiteres Ausführungsbeispiel für das erfindungsgemäße Schleifen mit bezüglich des Werkstückes gegenüberliegenden, gleichzeitig im Eingriff befindlichen Schleifscheiben; und
• 10: eine prinzipielle Darstellung der geringen axialen Bewegung (Shiften) der schraubenförmig ausgebildeten Schleifscheibe in Flankenrichtung der die jeweiligen Nuten begrenzenden Stege eines Schneckenabschnittes.

Further advantages, features and possible applications of the invention will now be explained in detail with reference to the following drawing. Show it:

• 1 : a workpiece designed as a worm shaft;
• 2 : Another embodiment of a workpiece also designed as a worm shaft;
• 3 : nine examples of different worm or thread profiles that can be grinded according to the invention;
• 4th : a basic illustration of the grinding according to the invention of a worm shaft in a configuration similar to that shown in FIG 2 ;
• 5 : a grinding arrangement according to the invention for grinding a worm element with a swiveled-in grinding wheel;
• 6th : a basic representation of a shift representing a slight axial movement the helical grinding wheel;
• 7a, b : a basic representation of a further exemplary embodiment of the grinding according to the invention of a worm element of a worm shaft, subdivided into a) pre-grinding and b) finish grinding, each with different grinding wheels;
• 8th : Another exemplary embodiment for the grinding according to the invention of a worm shaft in terms of complete machining from a solid material;
• 9 : Another exemplary embodiment for the grinding according to the invention with grinding wheels which are opposite with respect to the workpiece and which are simultaneously in engagement; and
• 10 : a basic representation of the slight axial movement (shifting) of the helically designed grinding wheel in the flank direction of the webs of a worm section delimiting the respective grooves.

In 1 is a workpiece in the form of a worm shaft produced with the method according to the invention or the grinding machine according to the invention 1 shown. This worm shaft 1 has a helical section, which acts as a screw 16 is formed and which has a cylindrical outer circumference 2 having. The helical or thread-shaped section in the form of the worm 16 has a circumferential groove formed with a predetermined pitch 8th on which of the respective webs corresponding to the pitch of the helical helix 9 is limited. The on the workpiece designed as a worm shaft 1 arranged screw is to be regarded as a thread profile or a groove profile that is produced with the method according to the invention. In principle it is possible to use the worm section of the worm shaft 1 to grind from solid or to grind from a rough dimension with a corresponding allowance. The method according to the invention can be used for screws 16 any slope. To such a worm shaft 1 To completely grind, there are still additional work steps to be grinded for the shoulders and cylindrical sections and any planar sections that may be present. This is usually ground in separate setups, in which the sections mentioned can then be ground in terms of diameter and bearing seats. However, it is also possible to complete the machining including grinding the worm according to the invention 16 to be carried out in one clamping and in one grinding machine.

In 2 is a further embodiment of a workpiece produced with the method according to the invention and the grinding machine according to the invention 1 , which is also designed as a worm shaft, shown. The one on this worm shaft 1 trained section of a snail 16 points with regard to the shape of the circumferential groove 8th delimiting webs 9 towards the 1 a different shape. In the cross-section are the webs 9 made thinner. The snail 16 is designed as a two-flight screw and has an outer circumference 2 on, which is cylindrical. The worm shaft 1 also has a covenant 17th in the form of a stop, which can be ground in a setting that is different from the setting in which the worm 16 is sanded. Also with this in 2 shown shape of the worm shaft 1 it is possible to carry out all grinding operations in addition to the grinding operation according to the invention for the worm 16 in one set-up in the sense of a complete machining of the worm shaft 1 to grind. The workpiece shown 1 can be used, for example, for a steering gear and therefore does not have a very large dimension. For example, such a worm shaft 1 have a length between 100 to 150 mm and a diameter of 15 to 25 mm. It goes without saying that with the method according to the invention, any size of such screw shafts 1 can be produced. The sequence of the production of such a worm shaft in the sense of a complete machining is for the individual steps to be carried out in 8th explained in detail.

According to the invention, the grinding wheel grinding the worm area of the worm shaft is designed, so to speak, as a negative shape for the positive shape of the webs forming the worm or the thread. Depending on the design of the negative shape of the worm or the helical circumferential profiling, a different web shape can be ground. In 3 various examples are shown which can be produced with the method according to the invention or the grinding machine according to the invention with a grinding wheel grinding the respective webs of the worm. In 3 are starting from left to right at the top, then arranged in the middle and finally arranged at the bottom, the following different web shapes and thus different thread shapes are shown in the broadest sense, which can be ground according to the invention. These are trapezoidal threads 18th , a buttress thread 19th , a special thread 20th , a conveyor screw thread 21 , a cross thread 22nd , a coarse thread 23 , a round thread 24 , a pointed thread 25th and a fine thread 26th . This illustration is intended to make it clear that, with the method according to the invention and the grinding machine according to the invention, basically any type of such screw or thread sections can be produced and formed on components.

In 4th is shown as a section of a snail 16 on a worm shaft 1 which is similar to the one in 2 is made according to the invention. Thereby the thread-like profile 5 the worm shaft 1 with a grinding wheel 4th ground, the width of which is greater than the entire length of the worm 16 . The grinding wheel shown, correspondingly profiled in the sense of a negative shape 4th is preferably dressing-free, which reduces the costs for the grinding machine, since a dressing device does not have to be provided in such a case. The grinding wheel 4th is on a grinding spindle 13th arranged, which by means of an infeed movement 15th in the sense of plunge-cut grinding, so to speak, as plunge-cut grinding main component of movement on the worm shaft 1 to be produced screws can be delivered. The worm shaft to be ground 1 is from a workpiece spindle 27 worn in a clamping device, not shown, during grinding. Furthermore is the worm shaft 1 by means of a bezel 28 on a cylindrical section next to the screw 16 supported so that the longitudinal axis 11 of the workpiece can be retained unchanged during machining. The one on the worm shaft next to the worm 16 still further arranged sections, such as the collar 17th , cylindrical sections in the area of the steady rest or in front of the transition area on the left side of the worm shown in the drawing 16 to the covenant 17th available, which can be ground by means of separate grinding wheels or a separate grinding wheel in the sense of a complete machining in one clamping. However, it is also possible for these additional sections of the worm shaft to be decoupled, so to speak, from the grinding of the worm in a further set-up 16 by means of the grinding wheel 4th can be produced.

Will now be the grinding wheel 4th with their helical profile 3 fed to the worm shaft, which has a cylindrical section 2 in the area of the screw to be produced later 16 has, the diameter of which is the maximum diameter of the screw 16 corresponds, ie the snail 16 on the worm shaft 1 If the solid is ground, then the shape of the worm is created by plunge grinding 16 from the negative form on the grinding wheel 4th shown in the positive form on the worm shaft. Electroplated CBN grinding wheels are usually used as grinding wheels that are not to be dressed. At the in 4th The manufacturing variant shown is the grinding wheel 4th in one plane of the worm shaft 1 in the sense of a delivery 15th (please refer 7a) fed, which is the longitudinal axis 11 of the workpiece 1 cuts. It becomes the complete screw profile or complete thread profile in this helically grooved area of the workpiece 1 in the so-called normal section to the longitudinal axis 11 the worm shaft, which is why the grinding wheel does not have to be swiveled in in this embodiment. When the longitudinal axis of the grinding wheel 4th is not swiveled in, the workpiece is lying 1 and the grinding wheel 4th parallel to each other.

The axes of rotation of the workpiece 1 and the grinding wheel 4th are electrically or electronically coupled because, as already stated, the negative groove profile or thread profile is profiled with the desired groove pitch or thread pitch in the grinding wheel or in the grinding wheel coating. It is of great importance for the precision of the screws, in particular, to maintain the speed ratios of these two rotational movements with great precision. That means the speed of the tool 4th and the speed of the workpiece 1 must be electrically or electronically synchronized, otherwise the shape of the profile 5 would run away with regard to their geometry and the nominal dimensions of the screw profile could not be adhered to. Synchronization should be understood here to mean that the speeds of the workpiece 1 and the grinding wheel 4th must be identical.

The one with the grinding wheel 4th The cutting speed to be achieved results from the diameter ratio between the workpiece 1 and the grinding wheel 4th . The grinding process used is therefore comparable to plunge grinding. The use of electroplated grinding wheels 4th has the advantage that screw profile 5 on the workpiece with a single grinding wheel 4th can be pre-ground and finish-ground. The advantage of the grinding wheel 4th Infeed in the plunge-cut grinding process, results from the fact that an axial displacement of the grinding wheel to achieve the worm 16 is not required. According to the invention, it can now be provided that a slight axial displacement is definitely also desired in order to improve the profile 5 regarding the width of the webs 9 or the width of the grooves 8th , based on the flanks of the webs facing the groove 9 can be influenced directly in the desired manner. When using electroplated CBN grinding wheels, the worm can 16 or the helical or helical profile 5 with one and the same grinding wheel 4th be pre-ground and finish-ground. The slight axial displacement of the grinding wheel, known as shifting 4th based on the longitudinal extension of the screw section on the screw shaft 1 but can also be used specifically so that the profile 5 on the width or flank shape of the respective groove 8th facing webs 9 can be influenced. With that, the The process of grinding also in particular with regard to the grinding of the flanks of the profile 5 be executed on the one hand on one or both sides, namely pre-ground, for example with the plunge-cut grinding feed movement 15th the grinding wheel 4th without an axial shift movement, followed by finish grinding, in which the flank shape of the webs is modified directly in a targeted manner. In such a case, one speaks of modified plunge-cut grinding. This slight axial shift movement can be necessary in order to achieve special geometrical and surface accuracies of the screw profile or its surfaces. This slight axial displacement 10 the grinding zones can, however, also be achieved in such a way that the synchronization of the speed of the workpiece 1 and the speed of the grinding wheel 4th from whose "zero position" will take place, the shifting from the so-called "zero position" from a shift of the point of engagement of the grinding wheel with its profile 3 is equivalent to. In such a case, a relative longitudinal displacement between the workpiece can then be assumed 1 and grinding wheel 4th be waived. However, it is also conceivable to combine both variants with one another. The selection of the respective process depends on the respective geometry of the workpiece to be achieved 1 so that this ultimately depends on the profile to be ground 5 and the further geometry of the workpiece 1 is.

In 5 a further embodiment of the grinding of a worm or a worm-shaped element is shown. With regard to this further exemplary embodiment, it is shown that the profile 5 of the workpiece 1 because of the special shape of the screw profile in the normal section to the longitudinal axis 11 the worm shaft 1 cannot be shown completely. Hence the grinding wheel 4th with their helical profile 3 into the thread or groove profile of the worm 16 swiveled in. The width of the helical profile 3 the one cylindrical outer contour 7th having grinding wheel 4th is so large that it covers at least the length of the complete thread or groove profile. According to the invention, the grinding wheel is moved in the axial direction, ie in the direction of the longitudinal axis 11 of the workpiece 1 , not mandatory.

So that the profile 5 of the screws in the entire area of the groove 8th and the webs 9 can be ground with a precise shape and surface, it has to be as a result of the grinding wheel swiveling in 4th by the angle of attack β to the longitudinal axis 11 of the workpiece 1 be shifted in their height and in their axial direction. Only then can the in the outer contour 7th cylindrical grinding worm 4th a finished part with a cylindrical outer contour can be obtained. This is due to the upward movement 10.1 or the downward movement 10.2 , based on the longitudinal axis of the grinding wheel 4th , achieved. Because the helical profiling 3 the grinding wheel 4th by the angle of incidence β with respect to the longitudinal axis 11 of the workpiece 1 is inclined, results both in the upward movement 10.1 as well as the downward movement 10.2 a small axial component, which by definition corresponds to shifting according to the invention.

In 6th shows five different positions of the axis of rotation of the grinding wheel 4th with helical profiling 3 with respect to the longitudinal axis 11 of the workpiece 1 . In the middle illustration is the grinding wheel 4th regarding the worm to be ground 16 or the profile to be ground 5 arranged in the middle. This is represented by the point which is exactly at the intersection of the longitudinal axis 11 of the workpiece 1 and the axis of rotation of the grinding wheel 4th centered with respect to the width of the grinding wheel 4th is arranged. The details described here relate to the geometry of the workpiece to be ground 1 and the geometry of the helical profile 3 the grinding wheel 4th , ie the grinding worm, are cylindrical. So that the grinding worm 4th at the ends of the profile to be ground lying in the axial direction 5 in terms of height can be brought to the grinding point, it is necessary that the grinding wheel 4th is to be moved in terms of height by means of the CNC control. This is clearly illustrated in particular in the partial image on the far left and in the partial image on the far right. Between the middle figure and the two end figures are shown intermediate positions, in which the distance between the longitudinal axis represented by the point 11 of the workpiece 1 and the axis of rotation of the grinding wheel 4th , based on the center of the width of the grinding wheel 4th , either down or up by this upward movement 10.1 or downward movement 10.2 are shifted by a smaller amount than in the end areas. In the figure on the left, this point is below the longitudinal axis 11 of the workpiece 1 , whereas in the figure on the right this point is above the longitudinal axis 11 of the workpiece 1 lies.

Different procedures or procedures are now possible when grinding. On the one hand it is possible that as the beginning or as the end of the thread profile or screw profile 5 the grinding point is used as a base. On the other hand, the middle grinding point is used as the basis, which is shown in the middle illustrations of the five figures in 6th is shown. In all grinding points that occur when grinding the workpiece 1 in the horizontal plane not on the longitudinal axis 11 of the workpiece 1 will be the profile 5 not finish ground. So that an intermediate or finish grinding of the profile 5 can take place, the Grinding wheel 4th be moved in the vertical direction. This is done using the existing CNC control via the so-called Y-axis. So that the desired screw profile 5 on the workpiece 1 can be produced with a precise shape, must in addition to the method of the grinding wheel 4th the grinding wheel in the vertical direction 4th in the axial direction of the longitudinal axis 11 of the workpiece 1 be used as a correction in the sense of shifting, provided that the synchronization (in the zero position) of the rotation of the workpiece 1 and that of the grinding wheel 4th should not be corrected. However, it is also possible that the slight axial displacement of the grinding wheel 4th also through a targeted correction of the synchronization of the speeds of the workpiece 1 and grinding wheel 4th is replaced with each other. A combination of both variants is of course also possible.

A major advantage of this method is that the grinding forces can be kept moderate and thus the load on the grinding machine can also be kept in a range that is favorable for the grinding machine. Another advantage is that the grinding times, ie the cycle times for manufacturing a workpiece 1 , can be kept relatively low. In principle, the grinding wheel must be used for this type of grinding 4th in relation to the longitudinal axis 11 of the workpiece 1 not necessarily be shifted axially. Shifting is therefore not absolutely necessary. However, a shift in the axial direction may well be desired, because it affects the profile 5 of the workpiece 1 its width can be influenced. This means that a corresponding flank geometry (see 10 ) or the flank geometry can be influenced in the desired manner. It is also possible to use the flanks of the profile 5 To be pre-sanded and finish-sanded on one or both sides. This is useful when special geometrical partial accuracies and special shape parameters or surface qualities are to be achieved. This slight axial displacement 10 the grinding zones, ie the grinding wheel 4th with their helical profile 3 , can, however, be replaced by synchronizing the speed of the workpiece 1 and that of the grinding wheel 4th is shifted to the zero position. Then you can move the grinding wheel longitudinally 4th in relation to the workpiece 1 be waived. However, it is also possible to combine both variants with one another. The selection of which of the possibilities of the method are used depends on the result to be achieved, on the cycle time to be observed and, for example, also on a positive influence on the service life, in particular of the grinding wheel 4th . The desired detailed workpiece geometry can also have an influence on the selection of the method options described.

In 7th is shown according to a further embodiment, such as a screw profile 5 , 16 by means of plunge-cut grinding by means of a helical profiling 3 having grinding wheel is ground, namely by a separation of pre-grinding and finish grinding, the pre-grinding with the helically profiled grinding wheel 4th and finish grinding by means of a second grinding wheel 12th is generated by profile grinding. In 7a is a grinding spindle 13th shown which the the helical profiling 3 having grinding wheel 4th and a second grinding wheel 12th for profile grinding. The grinding spindle 13th is in the sense of an infeed movement 15th , characterized by the double arrow, in the manner of plunge-cut grinding in the area of the workpiece 1 with the worm to be sharpened 16 feedable. The worm shaft 1 points next to the helical element 16 further various cylindrical sections and a collar 17th on, is by means of a bezel 28 supported at one cylindrical end and is by means of a workpiece spindle 27 clamped in a clamping element not shown and held driving.

7a represents the process of pre-grinding 29 represent. The grinding wheel 4th is usually designed as a grinding wheel, which does not have to be dressed and enables a high metal removal rate. The second grinding wheel 12th , ie the finished grinding wheel, then grinds in a second step after a corresponding axial offset of the grinding spindle 13th after the second grinding wheel 12th is brought into engagement with the screw profile. This finishing wheel 12th must have the complete profile 5 as a so-called single-tooth grinding wheel in the direction of the longitudinal axis 11 of the workpiece 1 run over and is usually a grinding wheel that is dressed. Grinding wheels with a wide variety of abrasives and bonds are used for pre-grinding and finish grinding. For example, corundum grinding wheels, CBN grinding wheels or also diamond grinding wheels with all bonds common in the prior art can be used.

In 7b is the grinding spindle 13th in the axial direction with respect to the longitudinal axis 11 of the workpiece 1 Move so far that the grinding wheel 4th by an infeed movement 15th , as in 7a shown in a circumferential groove 8th immersed, which by a circumferential bridge 9 is limited and thus forms the actual snail. While grinding the groove 8th and the flanks of the bridge 9 becomes according to the pitch of the screw 5 in the axial direction relative to the workpiece 1 procedure. The worm shaft 1 is by means of a collet 32 and a plan stop 31 the workpiece spindle 27 kept rotationally driven.

In 8th is the complete process sequence for the production of a worm shaft 1 according to the method according to the invention or a grinding machine according to the invention, in which an additional outer contour grinding wheel 34 is provided. The worm shaft is made from a solid material 6th , ie a bar stock 33 , will be produced. A total of six process steps are shown, which are briefly explained below. The workpiece spindle 27 is only hinted at. From the representation according to 8th it can be seen that the grinding of such a worm shaft 1 in a two-station grinding machine for producing the outer geometry of the worm shaft on the one hand 1 and on the other hand the thread-shaped or helical part of the workpiece 1 is shown, wherein the grinding takes place in two stations, but in a single grinding cell. In Fig. 8, the bar material is fed into the grinding machine in the grinding station on the left and first cut to the desired length. For this cutting process there is a thin grinding wheel on the spindle for the outer contour grinding wheel 34 additionally arranged. In picture 8 the outer contour of the workpiece is shown 1 by means of the outer contour grinding slide 34 Ground, with a steady rest being arranged on a collar and the steady rest 28 corresponding to the support on the workpiece 1 is employed.

Then, in step 8, the workpiece is removed from the station at which the solid material 6th the outer contour of the worm shaft has been ground, fed to the second station, in which the actual worm 16 on the workpiece 1 is produced. In sub-step 8, after the workpiece has been moved 1 this clamped in the corresponding clamping devices on the left and right grinding headstock, ie held.

In process step 8, the workpiece 1 by means of a parting-off grinding process in the left-hand grinding area using the outer contour grinding wheel 34 severed. Finally, in step 8, the screw is pre-ground and finished 16 or the thread profile 5 in the worm section of the worm shaft 1 . In addition, the workpiece geometry there is finish-ground in the area of the left end of the worm shaft. And finally, in step 8, the workpiece that has previously been finish-ground is unloaded 1 from the right grinding station including its removal. The illustrated method with steps 8 to 8.6 or the associated grinding machine realizing this method is especially suitable for the large-scale production of such worm shafts.

In 9 Another embodiment of the grinding of a worm on a workpiece to produce a worm shaft is shown, the worm being designed as a two-flight worm. This can be easily achieved by using a grinding wheel 4.1 for one side A of the workpiece 1 and another grinding wheel 4.2 for one side B of the workpiece 1 are provided, which each have a helical profile and between these two helical profiles, that is, between them, the workpiece 1 in the area of the profile 5 of the workpiece 1 grind from both sides. The grinding wheel takes over 4.1 the grinding of the first course of the two-course profile on side A and the grinding wheel opposite to it 4.2 grinding the worm on side B of the workpiece 1 . It grinds the second gear of the two-course profile. A major advantage of such an arrangement is that the bending stresses on the workpiece 1 compensate while grinding. This means that separate supports with steady rests can be dispensed with when grinding a worm shaft with a two-flight worm. Depending on the workpiece geometry, the quality of the workpiece can even be improved, since the compensation of the bending stress results in grinding of the worm 16 the worm shaft 1 can always take place about a longitudinal axis of the workpiece that is not pivoted out of a zero position. As a result, an even higher machining volume per unit of time can also be achieved in an advantageous manner, which further reduces the manufacturing costs.

And finally in 10 a schematic representation of a cross section through the web of a screw 16 shown, with a ridge of the helical profile 3 the otherwise not shown grinding wheel is immersed in the groove. To a defined flank shape or web shape of the worm of the workpiece 1 To get the profile you want 5 on the workpiece 1 by a slight movement, in the case of the 10 , from right to left in terms of the slight axial movement 10 , which is also referred to as shifting, take place. It is thus possible to influence the flank shape of the webs which limit the circumferential groove of a worm or of a thread-like, ie helical, profile.

List of reference symbols

1

Workpiece / worm shaft

2

Outer circumference

3

helical profiling grinding wheel

4th

Grinding wheel / grinding worm

4.1

Grinding wheel side A of the workpiece

4.2

Grinding wheel side B of the workpiece

5

Profile workpiece

6th

Solid material

7th

External contour grinding wheel

8th

helically circumferential groove

9

web

10

low axial movement / shifting

10.1

Upward movement

10.2

Downward movement

11

Longitudinal axis of the workpiece

12th

second grinding wheel

13th

Spindle / grinding spindle

14th

Grinding headstock

15th

Infeed movement / plunge-cut grinding main movement component

16

slug

17th

Federation

18th

Trapezoidal thread

19th

Buttress thread

20th

Special thread

21

Conveyor screw thread

22nd

Cross thread

23

Coarse thread

24

Round thread

25th

Pointed thread

26th

Fine thread

27

Workpiece spindle

28

Bezel

29

Pre-grinding with a grinding wheel 4

30th

Finish grinding with a second grinding wheel 12

31

Plan stop

32

Collet

33

Bar stock

34

Outer contour grinding wheel

35

β angle of the grinding wheel to the longitudinal axis of the workpiece

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 102008035525 B3 [0008, 0009]

Claims (15)

Method for grinding a workpiece (1) on which a profile (5) corresponding to the profile (3) of the grinding wheel (4) is formed as the final contour on its outer circumference (2) by means of a grinding wheel (4) having a helical profile (3) , the profile (5) being ground to the final contour from a cylindrical solid material (6) or from a rough workpiece having an oversize with respect to the final contour, characterized in that the grinding wheel (4), which is cylindrical on its outer contour (7), is one screw-shaped circumferential groove (8) having profile (5) on the workpiece (1) by plunge grinding the groove (8) formed between a respective web (9) grinds, the grinding wheel (4) with regard to its speed when grinding the workpiece (1) with it Speed is synchronized and relative to the workpiece (1) at most a slight axial movement (10) for grinding the shape of the web (9) delimiting the groove (8) executes. Procedure according to Claim 1 , characterized in that the grinding wheel (4) carries out preliminary and / or finish grinding and is designed without dressing. Procedure according to Claim 1 or 2 , characterized in that the grinding wheel (4) grinds axially parallel to the workpiece longitudinal axis (11) or pivoted into the slope of the circumferential groove (8). Method according to one of the Claims 1 until 3 , characterized in that the grinding wheel (4) during grinding into the end regions of the profile (5) has a shift movement (10) with respect to the longitudinal axis (11) of the workpiece (1) upwards (10.1) or downwards (10.2) executes. Procedure according to Claim 4 , characterized in that the shift movement (10) is carried out along the slope of the groove (8). Method according to one of the Claims 1 or 3 until 5 , characterized in that the grinding wheel (4) is dressed after it has been determined that it is approaching or reaching a defined or the presence of a defined dimensional tolerance deviation. Method according to one of the Claims 1 until 6th , characterized in that the web (9) delimiting the helically formed groove (8) is ground in terms of its shape by means of a second grinding wheel (12) arranged separately for the helical profiling (3) of the grinding wheel (4), and this is ground along the length of the profile (5) of the workpiece (1) is moved. Grinding machine for grinding a workpiece (1) with a grinding wheel (4) which has a cylindrical and helical profile (3) on its outer circumference (2), the workpiece (1) having a raw shape with a profile (5) with opposite its end contour has existing allowance for performing the method according to one of the Claims 1 until 7th , characterized in that the grinding wheel (4) is arranged on a spindle (13) of a grinding headstock (14) which forms the profile (5) during grinding on the workpiece (1) by means of an infeed movement (15) corresponding to a plunge-cut grinding process, and although without any or at most a slight axial movement (10) along the profile (5) of the tool (1) to be ground. Grinding machine after Claim 8 , characterized in that the speed of the workpiece (1) and the speed of the grinding wheel (4) are synchronized with each other during grinding. Grinding machine after Claim 9 characterized in that the speed of the grinding wheel (4) and workpiece (1) can be controlled so that the speed of the grinding wheel (4) corresponds to the speed of the workpiece (1) multiplied by the number of turns of the helical shape of the workpiece (1). Grinding machine according to one of the Claims 8 until 10 characterized in that the grinding wheel (4) is designed as a rough and / or finish grinding wheel. Grinding machine according to one of the Claims 8 until 11 , characterized in that a dressing device is provided for dressing the profiling (3) of the grinding wheel (4). Grinding machine according to one of the Claims 8 until 12th , characterized in that the grinding wheel (4) can be advanced slightly axially to the longitudinal axis (11) of the workpiece for grinding a cross-sectional shape of the webs (9) of the grooves (8) delimiting the helical profile (5). Grinding machine after Claim 13 , characterized in that the slight axial movement (10) of the grinding wheel (4) can be superimposed on its plunge-cut grinding main movement component (15). Grinding machine according to one of the Claims 8 until 14th , characterized in that at least the helically profiled grinding wheel (4) axially parallel to the workpiece longitudinal axis (11) or is arranged pivoted into the slope of the circumferential groove (8).

Images