1. Field of the Invention
The invention pertains to a rotary combustion engine with at least one working unit.
2. Description of the Related Art
In mass production of rotary combustion engines of the known design, a plurality of tie rods, which are parallel to the eccentric shaft of the engine and arranged outside the epitrochoidal orbit of the engine's combustion chamber at relatively short distances from each other, are used to seal off the working spaces from the outside. Before the housing parts are assembled, the eccentric shaft module and the piston module are laid in place, and then the tie rods are used to form a working unit by connecting the terminal side plate, the peripheral housing, and the side plate on the power takeoff side to each other along their flat surfaces, which are provided for this purpose. The hole pattern is, thus, the same for all three housing parts. When a center plate is used to build a rotary combustion engine consisting of two working units connected to each other, this hole pattern must also include the center plate. The bores which accommodate the tie rods increase the overall size of the unit, because they must be surrounded by housing material. This additional housing material takes space away from the water jacket, and the overall size of the unit must therefore be increased to compensate for the loss.
One disadvantage of this design is the increase in weight caused by the additional material around the bores and by the tie rods themselves. Another disadvantage is that the housing parts are held together along their flat surfaces by the friction produced by the pretension of the tie rods. In contrast to the parts of reciprocating engines, these parts must withstand the high shear forces which occur when high combustion pressures act on the epitrochoidal orbit and thus cause a housing force, acting in the radial direction.
A need, therefore, exists for providing a working unit for a combustion engine subject to high loads, with additional measures that are taken to control the housing forces caused by combustion. A further need exists for providing these measures so as to yield simultaneously savings in weight and advantages with respect to the design of the overall unit.
As an elaboration of the previously described manner of assembling a rotary combustion engine, it is proposed that the housing parts of one working unit be welded together. When it is desired to build a rotary combustion engine with several working units, center plates are installed between pairs of peripheral housings, the plates and the housings being connected to each other along their flat surfaces as usual. Because each of the housing parts is in contact with the adjacent one by a flat surface, which is in a plane perpendicular to the eccentric shaft, it is possible to use the electron beam welding method under vacuum to make a weld in each of these plane, proceeding radially from the outside and into the flat surfaces. The process makes it possible to control the depth of the weld, so that the weld can extend up to a point close to the epitrochoidal orbit. A water jacket is provided around the epitrochoidal orbit. The radial dimension of this jacket is small, because there is no longer any need to provide areas of extra material around the bores. As a result, the overall size of the unit can be considerably reduced, and this also obviously means considerable savings in weight as well.
The welds cause almost no distortion of the housing parts, which means that the shapes of the flat surfaces of the side plates and of the surface lines of the epitrochoidal orbit are not changed. Before the welding operation, however, the module consisting of the piston with its set of teeth and sealing elements and the module consisting of the eccentric shaft and its bearings must be laid in place.
So that the various parts of the working unit of a rotary combustion engine can be assembled in mass production, it is necessary to use a process which can be divided into individual steps. An assembly and/or welding jig is used, into which one of the two side plates, such as the side plate on the power takeoff side, is first laid. The eccentric shaft with its bearings, forming one module, is then laid into the side plate fastened in the jig, namely, pushed into the bearing bores provided for this purpose, and the piston with its sealing elements is then pushed over the eccentric shaft. The peripheral housing can then be fitted around the piston and onto the power takeoff side plate. The working unit is then closed by the terminal side plate and prepared for the welding operation. In the case of a rotary combustion engine consisting of several working units, a center plate is first fitted onto the peripheral housing, to which the elements of a second working unit are then connected. Now the housing parts, all of which are lying next to each other in sandwich fashion, are clamped together in the axial direction and laid in an additional device designed to produce a vacuum around the working units. The side plates, the peripheral housing, and the optional center plate can now be welded together. Finally, the pretension required for the welding operation is released, and the working unit(s) is/are removed from the device. As indicated, it is also possible to increase the efficiency of the process by placing several working units into the additional device simultaneously, because it is advisable to produce as many welds as possible with a single evacuation.
To further improve the stability of the working unit, it is proposed that reinforcement in the form of a binding element be laid around the working unit to prevent the housing forces developed during combustion from negatively affecting the fatigue strength of the housing parts. The contour of the external surface of the rotary combustion engine would be made circular in the ideal case; at the very least, it should have a continuous curvature which is inward-directed at all points and which thus makes it possible to install a binding element which, after it has been installed under pretension, generates a certain contact pressure around the entire circumference of the contour. The contact pressure will be higher at points where the curvature of the contour is more pronounced and vice versa. If it is desired to have an especially high pretension act on a certain section of the contour, this can be achieved by reducing the radius of curvature in that section.
The binding elements of steel strip can have various forms, for which reason a second exemplary embodiment with a tightening band will be explained here. The binding element with a width which corresponds to the length of the working unit has several tongues at each end. These tongues at one end are offset from those at the other end, and the width of the intermediate spaces at one end is identical to the width of the tongues on the opposite end. In addition, the binding element has openings, which lie above channels, spark plugs, and similar elements important for supplying the working unit, so that the working unit can be connected to systems important for its operation outside the binding element.
The length of the binding element is calculated so that the tongues will engage with each other when the binding element has been wrapped around the contour of the working unit. To complete the reinforcement, another process is required by means of which the binding element can be given the required pretension. For this purpose, it is necessary to lay the working unit and the binding element together in a tensioning jig on a hydraulically operated machine. After the binding element has been laid around the working unit and arranged in the necessary position, the ends of the tongues can then be clamped. The binding element can now be pretensioned by applying tensile force to the ends of the tongues in opposite directions in a common tangential direction. The tongues are also wrapped around a certain angle so that gaps extending in the circumferential direction are produced between adjacent tongues, these gaps being of sufficient length for the production of good welds. After the tongues have been welded together along their adjacent, arc-shaped edges, the tensioning jig can be released. The working unit and the binding element now form a single structural unit and can be removed together. The ends of the tongues are now bent into their throats and welded in place there, if necessary. Finally, it has been found that the visual appearance of the structural unit can be enhanced in the area of the welds by a grinding operation. It will be appreciated that the rotary combustion engine described herein can be used in motor vehicles.
Other objects and features of the present invention will become apparent from the following detailed description considered in conjunction with the accompanying drawings. It is to be understood, however, that the drawings are designed solely for purposes of illustration and not as a definition of the limits of the invention, for which reference should be made to the appended claims. It should be further understood that the drawings are not necessarily drawn to scale and that, unless otherwise indicated, they are merely intended to conceptually illustrate the structures and procedures described herein.
In the drawings:
A rotary combustion engine with reinforcement is explained below on the basis of seven diagrams:
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Thus, while there have shown and described and pointed out fundamental novel features of the invention as applied to a preferred embodiment thereof, it will be understood that various omissions and substitutions and changes in the form and details of the devices illustrated, and in their operation, may be made by those skilled in the art without departing from the spirit of the invention. For example, it is expressly intended that all combinations of those elements and/or method steps which perform substantially the same function in substantially the same way to achieve the same results are within the scope of the invention. Moreover, it should be recognized that structures and/or elements and/or method steps shown and/or described in connection with any disclosed form or embodiment of the invention may be incorporated in any other disclosed or described or suggested form or embodiment as a general matter of design choice. It is the intention, therefore, to be limited only as indicated by the scope of the claims appended hereto.
Number | Date | Country | Kind |
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10 2004 035 418.9 | Jul 2004 | DE | national |