Apparatus and method for training oarsmen

US 4,984,986 A
Filed: 11/07/1989
Issued: 01/15/1991
Est. Priority Date: 11/07/1989
Status: Expired due to Fees

First Claim

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1. Apparatus for training oarsmen to row a racing shell operationally exhibiting give mass and hydrodynamic drag terms, comprising:

a racing shell simulative housing having a longitudinal roll axis and a given boat plane;

an oarsman seat mounted upon said housing;

an oarlock supported from said housing;

a simulated oar extending along an oar axis and pivotally mounted with a oarlock;

a rotatable mass mounted for rotation with respect to said housing for simulating said mass term;

a drive linkage coupled in driven relationship with said oar and in driving relationship with a rotatable mass;

drag means for imposing a select drag upon said rotatable mass simulative of said hydrodynamic drag term;

a sweep angle transducer responsive to the sweep angle of said oar for providing a sweep angle output;

a force transducer responsive to the forces transmitted by an oarsman through said oar while positioned upon said seat for providing a force output;

control means responsive to said sweep angle output and said force output for deriving a power stroke output representing values of said force exerted from said oar with respect to sweep angle; and

readout means responsive to said power stroke output for providing a perceptible readout representative thereof.

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Abstract

A pair boat simulator is provided including a housing which is mounted about a longitudinal roll axis upon supports above a training facility floor. Two racing shell seats are mounted within the housing adjacent simulated oars which are mounted, in turn, upon oarlocks positioned, in turn, upon outrigger assemblies. The simulated oars are foreshortened and include a blade flotation assembly at their tips along with load beam type force transducers. The oars serve to drive a rotatable mass such as a flywheel. Thus, the physical output of each oarsman is commonly coupled to the rotating mass. Instrumentation includes transducers looking to inclinations of the housing about the roll or longitudinal axis, oar elevation and sweep angle as well as blade rotation. These parameters are combined and developed under computer driven control into data presented at visual readouts made available both to the oarsman and coach. Such readouts include, for example, force versus sweep angle graphs, animated displays of heading, lateral position and hull velocity; values of effective power and rowing efficiency.

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28 Claims

1. Apparatus for training oarsmen to row a racing shell operationally exhibiting give mass and hydrodynamic drag terms, comprising:
- a racing shell simulative housing having a longitudinal roll axis and a given boat plane;
  
  an oarsman seat mounted upon said housing;
  
  an oarlock supported from said housing;
  
  a simulated oar extending along an oar axis and pivotally mounted with a oarlock;
  
  a rotatable mass mounted for rotation with respect to said housing for simulating said mass term;
  
  a drive linkage coupled in driven relationship with said oar and in driving relationship with a rotatable mass;
  
  drag means for imposing a select drag upon said rotatable mass simulative of said hydrodynamic drag term;
  
  a sweep angle transducer responsive to the sweep angle of said oar for providing a sweep angle output;
  
  a force transducer responsive to the forces transmitted by an oarsman through said oar while positioned upon said seat for providing a force output;
  
  control means responsive to said sweep angle output and said force output for deriving a power stroke output representing values of said force exerted from said oar with respect to sweep angle; and
  
  readout means responsive to said power stroke output for providing a perceptible readout representative thereof.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
- - 2. The apparatus of claim 1 including:
    - rotation transducer means responsive to the angular orientation of said oar about said oar axis for providing a rotation output;
      
      said control means is responsive to said rotation output for deriving a rotation output signal.
  - 3. The apparatus of claim 1 including:
    - oar elevation transducer means responsive to the angle of said oar axis with respect to said boat plane for deriving an elevation output; and
      
      said control means is responsive to said elevation output for deriving an elevation output signal.
  - 4. The apparatus of claim 1 including a blade flotation simulator fixed to said oar and resiliently deformable to simulate the floation of an oar blade in water.
  - 5. The apparatus of claim 1 in which:
    - said oar extends a predetermined distance beyond said oarlock over a contact surface; and
      
      including a blade flotation simulator fixed to said oar at a location outwardly from said oarlock and resiliently deformably contactable with said contact surface in simulation of the flotation of an oar blade in water.
  - 6. The apparatus of claim 1 including:
    - a support structure pivotally supporting said housing for rotatable movement about said longitudinal roll axis simulation of the flotation of said racing shell upon water;
      
      a roll transducer responsive to said housing rotatable movement to derive a roll output; and
      
      said control means is responsive to said roll output for deriving a roll output signal.
  - 7. The apparatus of claim 6 in which said roll transducer is a potentiometer configured as a damped inclinometer coupled to the vicinity of said housing along said longitudinal roll axis.
  - 8. The apparatus of claim 1 in which:
    - said oarsman seat is mounted for movement along said housing longitudinal roll axis between end positions;
      
      wherein said apparatus further excluding including seat transducer means responsive to said seat movement for deriving a seat position output representing the position thereof along said longitudinal roll axis; and
      
      said control means is responsive to said seat position output for deriving a seat output signal.
  - 9. The apparatus of claim 1 in which said drag means comprises a hydrodynamic drag simulator mounted in driven relationship with said rotatable means and simulating said hydrodynamic drag term.
  - 10. The apparatus of claim 1 in which:
    - said rotatable mass is a flywheel; and
      
      said drag means comprises a fan having a shaft positioned in driven relationship with said flywheel and having an input component adjustable to the extent of air input thereto.
  - 11. The apparatus of claim 1 including:
    - a support structure pivotally supporting said housing for rotatable movement about said longitudinal axis in simulation of the flotation of said racing shell upon water; and
      
      a blade flotation simulator fixed to said oar and resiliently deformable to simulate the flotation of an oar blade in water.

12. Apparatus for training oarsmen to row a racing shell operationally exhibiting given mass and hydrodynamic drag terms, comprising:
- a racing shell simulative housing having a longitudinal axis and a given boat plane;
  
  first and second spaced oarsman'"'"'s seats mounted upon said housing;
  
  first and second oarlocks supported from said housing adjacent respective said first and second seats;
  
  first and second simulated oars each extending along an oar axis and pivitally mounted with respective said first and second oarlocks;
  
  a rotatable mass mounted for rotation with respect to said housing for simulating a mass term;
  
  a first drive linkage connected in driven relationship with said first oar and in driving relationship with said rotatable mass;
  
  a second drive linkage connected in driven relationship with said second oar and in driving relationship with said rotatable mass; and
  
  drag means for imposing a select drag upon said rotatable mass simulative of a viscous drag term.
- View Dependent Claims (13, 14, 15, 16)
- - 13. The apparatus of claim 12 including a support structure pivotally supporting said housing for rotatable movement about said longitudinal axis in simulation of the flotation of said racing shell upon water.
  - 14. The apparatus of claim 13 in which:
    - each said first and second oars extend a predetermined distance beyond respective said first and second oarlocks over a contact surface; and
      
      wherein said apparatus further including first and second blade flotation simulators fixed respectively to said first and second oars at a location outwardly of respective said first and second oarlocks, each being resiliently deformably contactable with said contact surface in simulation of the flotation of an oar blade in water.
  - 15. The apparatus of claim 12 in which:
    - said housing includes first and second outriggers extending laterally outwardly to an oarlock support from the vicinity of respective said first and second oarsmans seats in generally parallel relationship with said boat plane; and
      
      said first and second oarlocks are mounted upon the said oarlock support of respective said first and second outriggers.
  - 16. The apparatus of claim 12 including:
    - first and second sweep angle transducers responsive to the sweep angle of respective said first and second oars for respectively providing first and second sweep angle outputs;
      
      first and second force transducers responsive to the force transmitted by said oarsmen through said first and second oars when positioned respectively upon said first and second for providing respective first and second force outputs;
      
      control means responsive to said first and second sweep angle outputs and said first and second force outputs for deriving respective first and second power stroke outputs representing the relationship of force with respect to sweep angle; and
      
      readout means responsive to said first and second power stroke outputs for providing perceptible readouts representative thereof.

17. The method for evaluating the performance capability of an oarsman for rowing a racing shell exhibiting given mass and hydrodynamic drag terms, comprising the steps of:
- providing a racing shell simulative housing having a longitudinal axis and a given boat plane;
  
  providing an oarlock supported from said housing;
  
  providing a simulated oar extending along an oar axis and pivotally mounted with said oarlock;
  
  providing an oarsman seat mounted for rotation with respect to said housing for simulating a mass term;
  
  providing a drive linkage coupled in driven relationship with said oar and in driving relationship with said rotatable mass;
  
  providing a drag assembly for selectively controlling the rotation of said rotatable mass;
  
  providing a sweep angle transducer responsive to the sweep angle of said oar for providing a sweep angle output;
  
  providing a force transducer responsive to the forces transmitted by an oarsman through said oar into said drive linkage and rotating mass while positioned upon said seat for providing a force output;
  
  causing said oarsman to sit upon said seat and execute an oarstroke with said oar;
  
  providing a computer driven control responsive to said sweep angle output and said force output for generating a power;
  
  a power stroke output representing the values of force exerted during said oarstroke with respect to sweep angle; and
  
  displaying said power stroke output to said oarsman in visual graphic form.
- View Dependent Claims (18, 19, 20, 21, 22, 23, 24, 25, 26)
- - 18. The method of claim 17 further including the steps of:
    - providing an elevation transducer responsive to the angle of said oar axis with respect to said boat plane for deriving an elevation output;
      
      configuring said control for response to said elevation output;
      
      generating an oar elevation versus sweep angle output; and
      
      displaying said oar elevation versus sweep angle output to said oarsman in visual graphic form.
  - 19. The method of claim 17 further including the steps of:
    - providing said seat to be movable along said longitudinal axis;
      
      providing a seat transducer responsive to movement of said seat for deriving a seat position output;
      
      configuring said control for response to said seat position output;
      
      generating a seat position versus sweep angle output; and
      
      displaying said seat position versus sweep angle output to said oarsman in visual graphic form.
  - 20. The method of claim 17 further including the steps of:
    - providing an elevation transducer responsive to the angle of said oar axis with respect to said boat plane for deriving an elevation output;
      
      configuring said control for response to said elevation output;
      
      computing the simulated position of the blade centroid of said oar, the blade force vector based upon said force output, boat acceleration, velocity and position;
      
      deriving for each of a sequence of sampling intervals, a Delta Effective Work value as the effective product of Delta Boat Position and Stoke Oar Force representing vectors parallel with said longitudinal axis, and summing said Delta Effective Work values derived over the interval of said oarstroke to generate a Stroke Effective Work value;
      
      deriving the value of Effective Stroke Power by dividing the value of said Stroke Effective Work value by the value of said interval of said oarstroke; and
      
      displaying said value of Effective Stroke Power to said oarsman in visual form.
  - 21. The method of claim 20 further including the steps of:
    - generating an accumulative number of said oarstrokes and deriving an Effective Stroke Power versus Oarstroke Number relationship output; and
      
      displaying said Effective Stroke Power versus Oarstroke Number relationship output to said oarsman in visual graphic form.
  - 22. The method of claim 20 further including the steps of:
    - providing a support structure pivotally supporting said housing for rotatable movement about said longitudinal axis in simulation of the flotation of said racing shell in water;
      
      providing a roll transducer responsive to said housing rotatable movement to provide a roll output; and
      
      wherein said step of computing said position of said blade centroid includes an evaluation of said roll output.
  - 23. The method of claim 20 further including the steps of:
    - providing a rotation transducer responsive to the angular orientation of said oar about said oar axis for providing a rotation output; and
      
      wherein said step of computing said position of blade centroid and blade force vector includes an evaluation of said rotation output.
  - 24. The method of claim 17 further including the steps of:
    - providing an elevation transducer responsive to the angle of said oar axis with respect to said boat plane for deriving an elevation output;
      
      configuring said control for response to said elevation output;
      
      computing the simulated position of the blade centroid of said oar, the blade force vector based upon said force output, boat acceleration, velocity and position;
      
      deriving for each of a sequence of sampling intervals, a Delta Effective Work value as the effective product of Delta Boat Position and Stroke Oar Force representing vectors parallel with said longitudinal axis, and summing said Delta Effective Work values derived over the interval of said oarstroke to generate a Stroke Effective Work value;
      
      deriving for each of a sequence of sampling intervals the value of Delta Rower Work as the absolute value of the effective product of the torque value of said force output and the corresponding movement of sweep angle output, and summing said values of Delta Rower Work derived over the interval of said oarstroke to generate a Stroke Rower Work value; and
      
      deriving a Rower Effectiveness factor as the relation of said Stroke Effective Work value to the values of said Stroke Rower Work; and
      
      displaying said Rower Effectiveness factor to said oarsman in visual form.
  - 25. The method of claim 24 further including the steps of:
    - providing a support structure pivotally supporting said housing for rotatable movement about said longitudinal axis in simulation of the flotation of said racing shell in water;
      
      providing a roll transducer responsive to said housing rotatable movement to provide a roll output; and
      
      wherein said step of computing said position of said blade centroid includes an evaluation of said roll output.
  - 26. The method of claim 24 further including the steps of:
    - providing a rotation transducer responsive to the angular orientation of said oar about said oar axis for providing a rotation output; and
      
      wherein said step of computing said position of blade centroid and blade force vector includes an evaluation of said rotation output.

27. Apparatus for training oarsmen to row a racing shell operationally exhibiting given mass and hydrodynamic drag terms, comprising:
- a racing shell simulative housing having a longitudinal roll axis and a given boat plane;
  
  an oarsman seat mounted upon said housing;
  
  an oarlock supported from said housing;
  
  a simulated oar extending along an axis and pivotally mounted with said oarlock;
  
  a rotatable mass mounted for rotation with respect to said housing for simulating a mass term;
  
  a drive linkage coupled in driven relaitonship with said oar and in driving relationship with said rotatable mass;
  
  drag means for imposing a select drag upon said rotatable mass simulative of a hydrodynamic drag term; and
  
  a blade flotation simulator responsive to movement of said oar and simulating the flotation of an oar blade in water.
- View Dependent Claims (28)
- - 28. The apparatus of claim 27 in which:
    - said oar extends a predetermined distance beyond said oarlock over a contact surface; and
      
      said blade flotation simulator is fixed to said oar at a location outwardly from said oarlock and resiliently deformable contactable with said contact surface in simulation of the flotation of an oar blade in water.g

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Current Assignee
Vincent J. Vohnout
Original Assignee
Vincent J. Vohnout
Inventors
Vohnout, Vincent J.
Primary Examiner(s)
Apley, Richard J.
Assistant Examiner(s)
Cheng, Joe H.

Application Number

US07/432,595
Time in Patent Office

434 Days
Field of Search

434/247, 434/255, 434/392, 272/72, 272/129, 272/DIG. 5, 73/379, 128/25 R, 273/148, 114/363, 440/105
US Class Current

434/247
CPC Class Codes

A63B 2069/064   with pivoting handlebars

A63B 2071/0641   with a marker advancing in ...

A63B 21/0052   induced by electromagnets A...

A63B 21/0084   by moving the surrounding w...

A63B 21/225   with flywheels

A63B 21/285   in cooperation

A63B 2220/16   Angular positions

A63B 2220/54   Torque

A63B 2225/107   Resisting devices being of ...

A63B 2230/06   heartbeat rate only

A63B 23/03508   For a single arm or leg, A6...

A63B 24/00   Electric or electronic cont...

A63B 69/06   for rowing or sculling

Apparatus and method for training oarsmen

First Claim

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74 Citations

28 Claims

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Apparatus and method for training oarsmen

First Claim

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Abstract

74 Citations

28 Claims

Specification

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