DE19517677A1 - Crank for converting a linear movement into a rotary movement, or vice versa - Google Patents

Abstract

Described is a crankshaft (10) for transforming a linear motion into a rotational one (26) or vice versa, one end (12) of the crankshaft (10) being fixed to a rotating shaft (14) and the other end (16) of the crankshaft (10) being remote from the shaft (14). The crankshaft (10) has a first section (18) and a second section (20) which are rigidly joined to each other at a joint (22). The first and second sections (18, 20) of the crankshaft are dimensioned and joined to each other in such a way that the first section (18), which stands out rigidly from the shaft (14), makes an angle ( alpha ), at the shaft (14), with the imaginary radial line (24) between the shaft (14) and the far end (16) of the second section (20) of the crankshaft, the angle satisfying the condition 90 DEG </= alpha </= 270 DEG .

Description

The invention relates to a for converting a linear Movement into a rotational movement, or vice versa Crank with one end torque-proof on one Axis of rotation is attached, and the second, from the axis of rotation spaced joint end.

Such cranks are usually between the axis of rotation and simply designed in a straight line at the end of the joint. The same is true angled between the axis of rotation and the hinge end trained cranks, for example from FR 2 660 615 A1 or known from DE-GM 78 07 914. FR-C 2 185 997 and the FR-C 8 87 784 disclose cranks between the Axis of rotation and the radially spaced joint end are arcuately curved.

From DE 34 25 342 A1 a crank is known, the two Has crank parts that are limited in relation to each other are pivotable, one between the two crank parts Spring device is provided.  

All of these known cranks mentioned above are of this type trained that they are between the axis of rotation and the Joint end in a single radial direction - accordingly angled - extend so that at the end of the joint in the Crank initiated impulse acts directly on the axis of rotation.

The invention has for its object a crank to create the type mentioned, its on the axis of rotation acting impulse behavior and their efficiency between the Axis of rotation and the joint end is improved.

This task is performed with a crank of the type mentioned solved according to the invention in that the first end at a first crank part and the hinge end on a second Crank part of the crank is provided, which together with one another common connection point are rigidly connected, the first and second crank part dimensioned and are interconnected that the first crank part on the Axis of rotation with the imaginary radial connecting line between a certain crank angle α of the axis of rotation and joint end for which the following applies: 90 ° α 270 °.

In the crank according to the invention, the first extends Crank part from the axis of rotation not to the end of the joint, but it closes with the imaginary junction between the Axis of rotation and the joint end a crank angle α of at least 90 ° or at most a crank angle of 270 °. At the second crank part is adapted to the respective crank angle dimensioned, the one with the hinge end and on the other hand, with the second end remote from the axis of rotation of the first crank part is rigidly connected.  

It has been shown that, for example, one with such a Crank-equipped internal combustion engine on one Dynamometer essential under otherwise identical conditions is more easy to turn, d. H. its limit speed is essential larger than that of the same internal combustion engine conventional crank rod. Come two such according to the invention Cranks in a bicycle as pedal cranks to use, so shows that the energy expenditure, for example, during a Uphill is significantly reduced. Is it with one known to be trained bicycle, d. H. with a bike with two conventional straight cranks during one Uphill ride required to climb from the bike saddle to the appropriate power and energy in the pedal cranks the same mountain with the same bike, if it is equipped with cranks according to the invention, in Sitting will be conquered. It all depends on the inventive design of the crank together.

In the crank according to the invention, the radial distance of the Junction of the axis of rotation and the radial distance of the Joint end of the axis of rotation at least approximately the same size his. Of course, it is also possible to use the radial one Distance between the axis of rotation and the common Connection point of the two crank parts smaller or larger dimension as the radial distance between the axis of rotation and the hinge end of the second crank part. In this way the corresponding gear ratio is as desired adjustable. The last mentioned radial distances are at the crank according to the invention is changeable, so on this Way an adjustable translation can be realized.

The first crank part of the crank according to the invention can be straightforward. Of course it would be too possible the first crank part with a straight shape  to develop a different shape. The second crank part can in the crank according to the invention straight or curved be curved, the curvature then expediently oriented in the direction of rotation of the crank is. Of course, the curvature can also refer to the direction of rotation be oppositely oriented.

The first and second crank parts can, for example Rod material or the like. Likewise, it is possible that first and second crank part through a suitable slot to realize a disc. Here is the Axis of rotation preferably in the center of the disc.

The first and / or second crank part can be rigid or be resilient in sections.

In the crank according to the invention, the crank angle can be α-like has been carried out - be between 90 and 270 °. It may be useful if the junction of the two Crank parts of the joint end in radial relation to the axis of rotation Direction is at least approximately opposite, so that the Crank angle α is at least approximately 180 °. Of the Crank angle can also be greater than 180 °.

According to the invention, the crank according to the invention can - as already has been mentioned - as a crank on a bicycle, at an internal combustion engine or in a compressor application Find. Of course, the crank according to the invention not limited to the latter uses, but it can advantageously be used anywhere Get application where a linear movement into a Rotational movement, or vice versa, is converted.

Further details, features and advantages result from the following description of schematically in the drawing illustrated versions of the crank according to the invention. It demonstrate:

Fig. 1 a first embodiment of the crank,

Fig. 2 shows a second embodiment of the crank,

Fig. 3 shows a third embodiment of the crank, and

Fig. 4 shows a fourth embodiment of the crank.

Fig. 1 shows a side view of a first embodiment of the crank 10 according to the invention, which is provided for converting a linear movement into a rotary movement, or vice versa, and which is connected with its first end 12 to an axis of rotation 14 in a torque-proof manner, and the second , Hinge end 16 radially spaced from the axis of rotation 14 . The first end 12 rigidly connected to the axis of rotation 14 is provided on a first crank part 18 . The hinge end 16 is provided on a second crank part 20 . The two crank parts 18 and 20 are rigidly connected to one another at a common connection point 22 . The connection point 22 is provided at the end of the first and second crank parts 18 and 20 remote from the first end 12 of the first crank part 18 and from the articulated end 16 of the second crank part 12 .

The first and second crank parts 18 and 20 are dimensioned and rigidly connected to one another in such a way that the first crank part 18 has a certain crank angle at its first end 12 or at the axis of rotation 14 with the imaginary radial connecting line 24 between the axis of rotation 14 and the hinge end 16 α includes. This crank angle α is in the angular range between 90 and 270 °. In Fig. 1, a crank 10 is shown, in which the crank angle α is at least approximately 180 °, so that the connection point 22 is diametrically opposite the hinge end 16 . In contrast, 2 3, FIG. Formation of the crank 10, in which the crank angle α smaller than 180 °, and Figs., An embodiment of the crank 10, in which the crank angle α greater than 180 °.

The same details are designated in FIGS . 2 and 3 with the same reference numerals as in FIG. 1, so that it is not necessary to describe all these details in detail in connection with FIGS. 2 and 3.

The first crank part 18 is designed in a straight line in the configurations of the crank 10 according to FIGS. 1, 2 and 3. In the embodiment according to FIG. 2, moreover, the second crank portion 20 is formed straight. In contrast, FIGS. 1 and 3 show configurations of the crank 10 in which the second crank part 20 is in each case curved in an arcuate manner, the curvature being oriented in the direction of rotation of the crank. This direction of rotation of the crank 10 is indicated in FIGS. 1 to 3 by the arrow 26 .

While the Fig. 1 illustrate to 3 embodiments of the crank 10, in which the radial distance between the axis of rotation 14 and the joint end 16 is equal to the radial distance between the axis of rotation and the common junction 22 of the two crank portions 18 and 20, shows the Fig. 4 shows a configuration of the crank 10, wherein the radial distance R between the rotation axis 14 and the joint end 16 is greater than the radial distance r between the axis of rotation 14 and the common junction 22 of the two crank portions 18 and 20. Of course, it is also possible that the radius r is larger than the radius R.

In Figs. 1 to 4 cranks 10 are illustrated, the crank parts 18 and 20 consist of a rod material. However, the crank parts 18 and 20 can also be realized by suitable slitting of a disk.

Claims (11)

1. To convert a linear movement into a rotary movement, or vice versa, provided crank ( 10 ), which is attached with its one end ( 12 ) torque-proof to an axis of rotation ( 14 ), and which is a second, spaced from the axis of rotation ( 14 ) Hinge end ( 16 ), characterized in that the first end ( 12 ) is provided on a first crank part ( 18 ) and the hinge end ( 16 ) on a second crank part ( 20 ) of the crank ( 10 ), which are connected to one another at a common connection point ( 22 ) are rigidly connected, the first and second crank parts ( 18 , 20 ) being dimensioned and connected to one another such that the first crank part ( 18 ) on the axis of rotation ( 14 ) with the imaginary radial connecting line ( 24 ) between the axis of rotation ( 14 ) and the joint end ( 16 ) includes a certain crank angle (α), for which the following applies:
90 ° α 270 °. 2. Crank according to claim 1, characterized in that the radial distance (r) of the connection point ( 22 ) from the axis of rotation ( 14 ) and the radial distance (R) of the hinge end ( 16 ) from the axis of rotation ( 14 ) at least approximately the same size are. 3. Crank according to claim 1, characterized in that the first crank part ( 18 ) is rectilinear. 4. Crank according to claim 1, characterized in that the second crank part ( 20 ) is arcuate, the curvature being oriented in the direction of rotation ( 26 ) of the crank ( 10 ). 5. Crank according to one of claims 1 to 4, characterized in that the connection point ( 22 ) of the two crank parts ( 18 , 20 ) at least approximately opposite the hinge end ( 16 ) with respect to the axis of rotation ( 14 ) in the radial direction, so that the Crank angle (α) is at least approximately 180 °. 6. Crank according to claim 5, characterized , that the crank angle (α) is greater than 180 °. 7. Crank according to one of claims 1 to 6, characterized in that the two crank parts ( 18 , 20 ) consist of rod material. 8. Crank according to one of claims 1 to 6, characterized in that the two crank parts ( 18 , 20 ) are formed by slitting a disc. 9. Use of a crank according to one of claims 1 to 8 as a crank on a bicycle. 10. Use of a crank according to one of claims 1 to 8 in an internal combustion engine. 11. Use of a crank according to one of claims 1 to 8 with a compressor.