The invention relates to a grinding center for grinding crankshafts having main and rod bearings, wherein a plurality of main and rod bearings are ground simultaneously.
Grinding centers of this type are used for the rough-grinding and/or precision-grinding of crankshafts in high piece numbers. The crankshafts involved are frequently for four-cylinder in-line engines in the automobile industry, in which two rod bearings are in each case arranged in the same angular position with respect to the longitudinal axis of the crankshaft. Said two rod bearings are ground simultaneously (at the same time) to increase productivity. An example of such a procedure is described in EP 1 044 764 A2 and EP 1 088 621 B1.
For the main bearings of crankshafts, the simultaneous grinding of a plurality of bearings has already been known for a relatively long time, for example from U.S. Pat. No. 3,487,588. In this case, the grinding spindle for the main bearings has a number of grinding wheels equal to the number of main bearings. The grinding wheels are located on a common axis. A more recent disclosure in this regard is found in DE 101 44 644 B4.
In the case of the grinding center for crankshafts according to EP 1 044 764 A2, for the simultaneous grinding of two rod bearings of a crankshaft, use is made of a rough-grinding wheel and a finish-grinding wheel which are each mounted fixedly on a dedicated cross slide via the associated grinding spindle. The two cross slides are movable independently of each other in the longitudinal direction (Z direction) of the crankshaft and are advanceable in the direction of the crankshaft (X direction). Via a corresponding control of the cross slides and grinding spindles, simultaneous machining of two rod bearings in one clamping set-up is possible, wherein the one rod bearing is rough-ground and the other is finish-ground. In this case, the grinding operation is monitored continuously via associated measuring devices.
EP 1 088 621 B1 describes a method and an apparatus for the simultaneous grinding of at least two bearings of a crankshaft, in which there is substantial structural and operational overlap with the grinding center shown in EP 1 044 764 A2. A common feature of both systems is that they each use a dedicated cross slide for each of the two grinding spindles used. Each of said cross slides has to be activated separately for the entire grinding operation and constantly monitored and corrected in accordance with real time data, which is determined via measuring heads, regarding the roundness and the dimensions of the ground bearing. The construction of the grinding center with two separate cross slides—just for the machining of two bearings—requires a large amount of space and a considerable outlay on components and associated control systems.
Proceeding from said prior art, it is the object of the invention to indicate a grinding center for the grinding of crankshafts, in which the structural outlay and space required are substantially reduced and with which the simultaneous high-quality grinding of main bearings and rod bearings is possible in a particularly rapid and economical manner.
This object is achieved by a grinding center having the features according to claim 1.
In the case of the grinding center according to the invention, the space required and the structural outlay are advantageously already reduced by the fact that two stations for the simultaneous (isochronous) grinding of at least two bearings are combined to form a grinding center. In the first station, together with the main bearings, centrally encircling parts of the journal-side and flange-side crankshaft end can also be ground, to be precise on the (planar) face side and/or in diameter. Since all of the main bearings can be ground simultaneously in the first station, there is, in contrast to the second station, a spare amount of time which can be used.
If the two stations are arranged in a common axial direction of the crankshafts to be ground, the moving of the crankshafts from the one station into the other also proves to be very simple. Furthermore, a number of advantages emerge from the arrangement of two grinding spindles for machining rod bearings on a common cross slide. Said additional advantages are considered in particular to be a simplification of the control of the grinding process and the reduction in the number of components and in the space required.
According to the invention, the joint grinding of two rod bearings is controlled in such a manner that the rate of advance and the monitoring/correction of the removal of material from and of the true running of the ground bearings initially take place only via the control of the movements of the common rod-bearing cross slide. In this phase, the main removal of material of the grinding of both rod bearings takes place. The first grinding spindle and the second grinding spindle are controlled differently in terms of movement only when the desired dimensions are approximately reached. The first rod-bearing grinding spindle, which is connected to the rod-bearing cross slide rigidly with respect to the advancing direction (X direction) of the grinding wheels, is furthermore controlled via the control system of the rod-bearing cross slide in accordance with dimensional and roundness values, which are determined via a measuring device, in such a manner that the required final desired values for the grinding operating in question are achieved.
The roundness values do not absolutely have to be measured for each rod bearing. After a measurement, said correction values can be recorded in the control system and stored for a certain number of crankshafts until a further measurement of roundness takes place.
Although the advancing of the second rod-bearing grinding spindle in this phase also follows the movement of the rod-bearing cross slide, a further movement component in the X direction is also superimposed on said movement. Said further movement component serves for a differential correction of dimensional and/or roundness deviations occurring at the two simultaneously machined rod bearings. Such deviations can be caused, for example, by means of different wear of the two grinding wheels. A further substantial reason for said deviation is that the shafts are distorted slightly during the grinding, since stresses may be released in the material. According to the invention, said deviations are detected by continuous determination of the dimensions and roundness of the two rod bearings, for which purpose corresponding measuring devices are provided for each rod bearing.
In the final grinding phase, the differences to be corrected between the two rod bearings are only small; experience has shown that they lie within the range of a hundredth or thousandth of a millimeter. Therefore, only a small adjustment range is needed for the movement of the second rod-bearing grinding spindle. Said range advantageously needs to comprise only approximately +/−0.2 mm.
According to claim 2, the two rod-bearing grinding spindles are adjustable relative to each other in the axial direction on the rod-bearing cross slide. This permits adaptation to different axial distances between the rod-bearing pairs to be ground, and also adjustment to different types of crankshaft. The axial adjustability is expediently incorporated into the control system of the machine and is automatically triggered. In general, the second rod-bearing grinding spindle which in any case is arranged adjustably in the radial direction is also designed to be axially adjustable, although the construction the other way round is also conceivable, in which the second rod-bearing grinding spindle is axially fixed on the rod-bearing cross slide while the first rod-bearing grinding spindle is used for the axial adjustment on the rod-bearing cross slide.
In an embodiment of the invention, a configuration of the drive for movement of the one (second) grinding spindle in the dimensional and roundness correction axis as an NC axis is preferred according to claim 3, since such an axis can easily be integrated into the CNC machine control system.
An advantage is also afforded in the case of a configuration of the grinding cell according to claim 4, in which the machining in the first station also includes grinding of the face sides of the crankshaft. By this means, the time T1 can be used and adapted in such a manner that two pairs of rod bearings are machined in the corresponding time T2.
The planar faces of the bearing points of the crankshafts can be ground either by the main-bearing cross slide being offset in the Z direction or by the main-bearing grinding wheels being offset axially on the main-bearing grinding spindle, cf. claims 5 and 6. However, it is also possible to offset the crankshaft in the axial direction in relation to the main-bearing grinding wheels, cf. claim 7.
If the machining times T1 and T2 for the main and rod bearings according to claim 6 are coordinated with each other, a particularly economical operation of the grinding center is produced, since the loading or unloading of the two stations can then be carried out simultaneously and therefore waiting times dispensed with.
According to claim 9, the pendulum stroke movement is preferably used for the grinding of the rod bearings, thus resulting in simplification for the crankshaft mounting and drive for machining of the rod bearings. In this connection, the main bearings which are ground in the first station can readily be used for the crankshaft mounting in the second station, thus enabling a high degree of accuracy in the machining of the rod bearings to be achieved. Furthermore, the arrangement according to the invention and the activation of the two rod-bearing grinding spindles on just one cross slide leads to there being only a single advancing slide. The main movement of the two grinding wheels, namely the pendulum stroke movement and the feed motion, are therefore brought about by a single advancing slide. This results in a substantial simplification of the control system in relation to the prior art, since only one advancing slide has to be monitored and controlled during the predominant part of the machining operation. The different control of the movement of the two grinding spindles in the final grinding phase ensures that any deviations between the two rod bearings are detected and compensated, such that at the end the two rod bearings have been ground to the desired dimensions.
The clamping and the rotational drive of the crankshafts via specially designed main-bearing and rod-bearing headstocks or corresponding tailstocks according to claim 10 permits a particularly flexible use of the grinding center. Clamping of the crankshaft with the option of rotation about the main-bearing longitudinal axis or about the rod-bearing longitudinal axis permits the choice between normal grinding or pendulum stroke grinding for the rod-bearing grinding.
A continuous measurement of the dimensions and of the roundness of the bearings in the machining operation according to claim 11 permits a near-instantaneous detection and highly accurate correction of the grinding result.
Of course, with a grinding center according to the invention, in addition to four-cylinder crankshafts, other crankshafts can also be ground if they have two rod bearings each fitted in the same angular position on the crankshaft. Therefore, the machining of camshafts is also possible if the latter have at least two main bearings and two cams each arranged in the same angular position.
The invention also relates to a method for grinding the main and rod bearings and/or central parts of crankshafts according to claim 12. Refinements of said method are described in the dependent claims.
The grinding center and the method according to the invention are explained in more detail below with reference to the exemplary embodiments which are illustrated in the drawings, in which:
The first station 3 of the grinding cell 1, which station is illustrated individually in
The second station 4 of the grinding cell 1, which station is shown individually in
The crankshaft 22 to be ground is also clamped centrally in the second station 4, i.e. the common longitudinal axis of the clamping devices on both sides is identical to the longitudinal axis 29 of the crankshaft 22, which longitudinal axis is defined by the main bearings 23 of the crankshaft. As can be seen from
According to
The shape of the receptacle of the crankshaft 22 in the second station 4 can be varied and optimized in accordance with the specific individual case.
In both stations 3 and 4, the crankshaft 22 can be supported by one or more self-centering steady rests.
A rod-bearing cross slide 11 which is movable in the direction of the axes Z2 and X2 which are perpendicular to each other, i.e. is movable parallel to the crankshaft longitudinal axis 29 and perpendicularly thereto, is provided in the second station. The rod-bearing cross slide 11 supports a first rod-bearing grinding spindle 14 and a second rod-bearing grinding spindle 15. Of said grinding spindles, the first rod-bearing grinding spindle 14 is connected fixedly to the rod-bearing cross slide 11 in the direction perpendicular to the crankshaft longitudinal axis 29. By contrast, the second rod-bearing grinding spindle 15 is arranged movably on the rod-bearing cross slide 11 in the direction perpendicular to the crankshaft longitudinal axis 29. The movement of said second rod-bearing grinding spindle is controlled in accordance with a dimensional or roundness error which is obtained from an in-process measurement during the grinding operation. For this purpose, the diameters of the rod bearings 24, 27 and 25, 26 which are to be ground in pairs are measured continuously during the grinding operation by in-process measuring heads 19 of a measuring device 20 (
Each of the two rod-bearing grinding spindles 14, 15 bears a rod-bearing grinding wheel 17, 18, the axial distance of which from each other has to correspond to the distance between the rod bearings 24 to 27 to be ground in pairs. For this purpose, the two rod-bearing grinding spindles 14, 15 have to be movable in relation to each other in their axial direction, i.e. in the direction of the axis of rotation of their rod-bearing grinding wheels 17, 18, on the rod-bearing cross slide 11. The axial distance between the rod-bearing grinding spindles and grinding wheels has to be adjusted each time a different type of crankshaft is to be ground or, in the case of a specific crankshaft, a pair of rod bearings with a changed distance is to be ground. Insofar as this is concerned, the change in the distance has to be incorporated into the entire control system of the grinding operation. In this case, the first rod-bearing grinding spindle 14 or the second rod-bearing grinding spindle 15 can be arranged adjustably in the direction of its longitudinal axis on the rod-bearing cross slide 11.
A particular characteristic of crankshafts 22 for four-cylinder in-line engines can be seen particularly clearly from
This characteristic is used for the economical operation of the grinding center according to the invention. This is because, with the two rod-bearing grinding wheels 17 and 18, the two rod bearings 24, 27 and 25, 26 are each simultaneously ground per se, wherein the word “simultaneously” also stands for the expressions “at the same time” or “isochronously” which can be encountered in grinding technology. It is therefore meant in each case that the grinding operation proceeds approximately at the same time, but not that it has to be ended exactly at the same time. The second rod bearing is more frequently finish-ground only after the first one since, for example, a residual oversize of 0.02 mm still has to be removed.
At the beginning of the rod-bearing grinding in the second station 4, the mutual axial distance between the two rod-bearing grinding wheels 17, 18 is adjusted, for example, to the distance between the rod bearings 24 and 27. The grinding of said rod bearings 24, 27 then begins in the CNC-controlled pendulum stoke movement. For this purpose, the two rod-bearing grinding spindles 14, 15 are first of all moved together perpendicular to the crankshaft longitudinal axis 29; in the process, the second rod-bearing grinding spindle 15 remains immovable in relation to the rod-bearing cross slide 11. This applies to the coarse-grinding or rough-grinding phase. However, the diameter precisely reached on each of the rod bearings 24, 27 during the grinding operation is measured and the roundness determined. As the finished dimensions are approached in the precision-grinding phase, the movement of the second grinding spindle 15 is decoupled from that of the rod-bearing cross slide 11. The rod-bearing cross slide 11 is moved in the direction of a dimensional or roundness correction axis 44 in accordance with the measurement at the rod bearing 24, and the final dimensions and the required roundness of the rod bearing 24 are finally achieved by means of the first rod-bearing grinding spindle 14. The second rod-bearing grinding spindle 27 simultaneously executes correction movements in relation to the rod-bearing cross slide 11 in accordance with the separate measurement at the rod bearing 27 if the measurements at the rod bearing 27 deviate from those of the rod bearing 24. Said deviations emerge from the continuous measurement at both rod bearings 24 and 27. The computer of the machine control system analyzes the measuring results and forms corresponding correction and control signals for the drive of the second rod-bearing grinding spindle 15.
Of course, the second rod-bearing grinding spindle 15 needs to be movable in relation to the rod-bearing cross slide 11 only to a small extent in the direction of the X axis. An adjustment distance which is advantageous in practice can be, for example, in the range of +/−0.2 mm. The grinding center can be adjusted in such a manner that the grinding time T1 is equal to the grinding time T2. Two of the main bearings 23 are then ground at approximately the same time as one pair 24, 27 or 25, 26 of the rod bearings.
The rod-bearing cross slide 11 is subsequently moved back, the distance of the two rod-bearing grinding spindles 14, 15 from each other is adjusted to the distance of the central rod bearings 25, 26 and the grinding cycle begins again.
Number | Date | Country | Kind |
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10 2007 026 562 | Jun 2007 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2008/056186 | 5/20/2008 | WO | 00 | 1/14/2010 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2008/148638 | 12/11/2008 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2054364 | De Leeuw | Sep 1936 | A |
2232228 | Groene | Feb 1941 | A |
5997452 | Assie | Dec 1999 | A |
6102838 | Assie | Aug 2000 | A |
6334806 | Sano et al. | Jan 2002 | B1 |
6419563 | Ido et al. | Jul 2002 | B1 |
6913522 | Junker | Jul 2005 | B2 |
Number | Date | Country |
---|---|---|
198 59 360 | Jul 2000 | DE |
695 18 856 | Apr 2001 | DE |
101 44 644 | Apr 2003 | DE |
103 04 252 | Aug 2004 | DE |
1 044 764 | Oct 2000 | EP |
1 088 621 | Apr 2001 | EP |
WO-2005000507 | Jan 2005 | WO |
Number | Date | Country | |
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20100173565 A1 | Jul 2010 | US |