1. A vertical axis wind engine comprising:
a vertical axis mounted on a base;
a transmission provided in a lower portion of the vertical axis for rotational movement output from the vertical axis;
at least one arm, each arm having an end rotatably coupled to the vertical axis wherein at least one pair of upper and lower arms are adapted to define an airfoil receiving space therein;
at least one airfoil, each airfoil including two pivot pins provided at a top and a bottom thereof respectively, the pivot pins being located distal to the vertical axis, and each airfoil being adapted to be pivotably mounted within the respective airfoil receiving space by pivoting about the pivot pins;
at least one elastic stop member provided on each arm proximate to the airfoil and spaced from the pivot pin, each stop member being adapted to limit a pivot angle of the respective airfoil;
wherein each stop member is adapted to lift the pivot limitation of each respective airfoil for allowing the airfoil to pivot when the airfoil experiences a pushing force of the wind that is larger than a maximum resistance force thereof;
wherein each of some airfoils are adapted to exhibit a narrow contour for offering the least resistance to wind disposed at the leeward side of the respective airfoils;
wherein each of some airfoils are adapted to exhibit a wide contour for offering the most resistance to wind by pivoting the respective stop members to their limits when the respective airfoils are disposed at their leeward side; and
two opposite pivotal pawl elements at each pair of the arms, each pawl element being located near a free end of respective arms distal to the vertical axis; wherein each pawl element is adapted to pivot toward a predetermined direction only in response to force exerted thereon and is adapted to return to its original position after the force is removed, such that the pawl elements are adapted to stop and prevent the airfoils from pivoting counterclockwise to their windward sides from their leeward sides and enable the airfoils to have a wide contour; and wherein each airfoil is adapted to pivot clockwise to contact and pass the pawl elements after the pivot limitations imposed on the airfoils by the respective stop members have been lifted by a strong wind so as to enable each airfoil to have a normal wide contour.
2. The vertical axis wind engine according to claim 1, wherein the stop member is provided on the arm proximate to the airfoil and has a length to enable it to contact a surface of the airfoil for limiting the pivot angle of the airfoil, and wherein the stop member is adapted to lift the pivot limitation of the airfoil by pivoting away from the airfoil for allowing the airfoil to pivot when the airfoil experiences a pushing force of the wind larger than a maximum resistance force thereof.
3. The vertical axis wind engine of claim 2, wherein each airfoil further comprises at least one auxiliary airfoil longitudinally, pivotably mounted on its windward side proximate an outer end thereof between the pivot pins, and wherein the auxiliary airfoil is adapted to either exhibit a wide contour of the airfoil in the windward side of the airfoil or exhibit a narrow contour of the airfoil by pivoting onto the airfoil in the leeward side thereof.
4. The vertical axis wind engine of claim 2, wherein a section of each arm as viewed from either a top or a bottom thereof toward the airfoil receiving space has a curved outer surface designed according to the principles of air dynamics.
5. The vertical axis wind engine of claim 2, further comprising an upright weight at an outer end of each airfoil between the pivot pins, and wherein the weight is adapted to shift a center of gravity of the airfoil to a position substantially between the pivot pins.
The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.
I claim:
1. A method of determining a degree of compaction during ground compaction with a vibrating plate compactor or a roller having a top section (1) and a vibrating bottom section (2), driven at a defined excitation frequency, comprising the steps of determining at least one amplitude value of a vibration at approximately an excitation frequency of the bottom section (2) relative to the top section (1), determining at least one amplitude value of one or more vibrations of the bottom section (2) relative to the top section (1) at a maximum of 60% of the excitation frequency, and calculating a quotient of the amplitude values as a measure of the current degree of compaction of the ground.
2. The method according to claim 1, wherein the amplitude values of the vibration at a maximum 60% of the excitation frequency are collected from a broad frequency band.
3. The method according to claim 2, wherein the amplitude values from a frequency band of about 1% to about 50% of the excitation frequency are collected.
4. The method according to claim 1, wherein a fixed value for the excitation frequency is preset for measurement of the amplitudes at excitation frequency.
5. The method according to claim 1, wherein the step of determining the amplitudes at excitation frequency comprises inputting a variable value for the excitation frequency corresponding to its actual current value.
6. The method according to claim 1, wherein the amplitude values determined andor the quotient are subjected to averaging.
7. The method according to claim 6, wherein averaging is effected using envelope curves.
8. The method according to claim 1, wherein the amplitude values of the various frequency ranges are determined by Fourier transformation and are used to calculate the degree of compaction.
9. The method according to claim 8, wherein the Fourier transformation is a Fast Fourier Transformation (FFT).
10. The method according to claim 1, wherein a signal is generated for the operator when the quotient exceeds a defined limit value.
11. A device for determining a degree of compaction during ground compaction with a vibrating plate compactor or a roller, comprising a top section (1) and a vibrating bottom section (2), driven at a defined excitation frequency, wherein the top section (1) has a sensor (3) for non-contact detection of relative movements between the top section (1) and the bottom section (2).
12. The device according to claim 11, wherein the sensor (3) corresponds with a measuring face (4) which lies opposite thereto on the bottom section (2).
13. The device according to claim 12, wherein the sensor (3) is a sensor for inductive data acquisition.
14. The device according to claim 11, wherein the sensor (3) is a displacement pick-up.
15. The device according to claim 11, further comprising a high-pass filter for determining amplitude values of vibration of the bottom section (2) relative to the top section (1) occurring at approximately the excitation frequency.
16. The device according to claim 11, further comprising a bandpass filter for determining amplitude values from a frequency range of about 1% to about 50% of the excitation frequency.