Claims
- 1. An exercise apparatus, hereinafter referred to as RRE apparatus, for use by a horizontally disposed participant in implementing an exercise wherein each limb extremity of the horizontally disposed participant is coupled to the RRE apparatus by a pair of pulleys supported by flexible lines, one of the pair connected to a first limb group including a left leg and a right arm of the participant, and an other of the pair connected to a second limb group including a right leg and a left arm of the participant, the RRE apparatus comprising:a drive assembly coupled to the lines wherein the limbs are constrained for alternate elevation and lowering of the first limb group and the second limb group; an energy dissipative assembly coupled to the drive assembly; a combining and supporting structure; and the structure for nominally supporting or balancing the weight of the horizontally disposed participant's first and second limb groups one against the other such that the participant is able to alternately apply lifting force to the first limb group while pulling down on the second limb group and then lifting force to the second limb group while pulling down on the first limb group, and for dissipating power applied by the participant while the participant elevates and lowers the first and second limb groups in an alternate rhythmic manner.
- 2. The RRE apparatus of claim 1 wherein the drive assembly utilized to couple the lines to the energy dissipative assembly comprises respective leg and arm drive sprockets respectively driven by leg and arm drive belts coupled on either side thereof to respective left and right leg and arm supporting ones of the lines.
- 3. The RRE apparatus of claim 1 wherein the energy dissipative assembly is an energy dissipative hydraulic assembly additionally comprising:a reversible pump having first and second pump ports for receiving power applied to the lines by the participant and generating a flow of pressurized fluid in response thereto, either one of the first and second pump ports delivering the flow of pressurized fluid and the other one receiving a similar flow of fluid depending upon the direction of rotational motion thereof; a selected orifice; a fluid reservoir; a valve assembly for directing pressurized fluid delivered from either of the first or second pump ports to and through the selected orifice t o the reservoir; and first and second check valve assemblies respectively fluidly coupled between the reservoir and the first and second pump ports for returning the similar flow of fluid from the reservoir to the fluid receiving one of the first and second pump ports.
- 4. The RRE apparatus of claim 3 wherein the energy dissipative hydraulic assembly additionally comprises means for generating a first signal indicative of the area of the selected orifice, a pressure transducer fluidly coupled to the valve assembly for generating a second signal indicative of the fluid pressure of the pressurized fluid delivered to the selected orifice, and a controller for determining instant values of power applied to the RRE apparatus based upon the first and second signals.
- 5. The RRE apparatus of claim 1 wherein the energy dissipative assembly is an energy dissipative hydraulic assembly additionally comprising:a reversible pump having first and second pump ports for receiving power applied to the lines by the participant and generating a flow of pressurized fluid in response thereto, either one of the first and second pump ports delivering the flow of pressurized fluid and the other one receiving a similar flow of fluid depending upon the direction of rotational motion thereof; substantially identical first and second selected orifices, each respectively fluidly coupled to the first and second pump ports for receiving and transmitting the flow of pressurized fluid from either of the first and second pump ports; a fluid reservoir; a common passage fluidly coupled between the first and second orifices and the fluid reservoir for receiving the flow of fluid from either of the first and second selected orifices as partially spent fluid and delivering at least a portion thereof to the fluid reservoir; and first and second check valve assemblies respectively fluidly coupled between the reservoir and the first and second pump ports for returning the similar flow of fluid from the reservoir to the fluid receiving one of the first and second pump ports.
- 6. The RRE apparatus of claim 5 wherein the energy dissipative hydraulic assembly additionally comprises means for generating a first signal indicative of the areas of the substantially identical first and second selected orifices, a return orifice for receiving the portion of partially spent fluid and then delivering it to the reservoir as totally spent fluid, a pressure transducer fluidly coupled to the common passage for generating a second signal indicative of the fluid pressure present in the partially spent fluid delivered to the return orifice, and a controller for determining instant values of power applied to the RRE apparatus based upon the first and second signals.
- 7. The RRE apparatus of claim 1 wherein the energy dissipative assembly is an energy dissipative hydraulic assembly and the RRE apparatus additionally comprises:a first temperature transducer for measuring the temperature of the energy dissipative hydraulic assembly and providing a first signal indicative thereof; a second temperature transducer for measuring ambient temperature and providing a second signal indicative thereof; a controller for determining instant values of power applied to the RRE apparatus based upon the first and second signals.
- 8. The RRE apparatus of claim 1 wherein the energy dissipative assembly is an energy dissipative electric assembly additionally comprising:electrical generating apparatus for receiving power applied to the lines by the participant and generating a flow of electrical current in response thereto; and a resistor bank for receiving the flow of electrical current.
- 9. The RRE apparatus of claim 8 wherein the energy dissipative electric assembly additionally comprises a voltage transducer electrically coupled to the resistor bank for generating a signal indicative of the voltage associated with the flow of electrical current delivered to the resistor bank, and a controller for determining instant values of power applied to the RRE apparatus based upon the signal.
- 10. The RRE apparatus of claim 1 wherein the RRE apparatus is semi-portable RRE apparatus additionally comprising:a hub; respective leg and arm supporting reels coupled to the lines and commonly mounted upon the hub; power transmission means for drivingly coupling the hub to the energy dissipative assembly; and an elevated housing supported above the horizontally disposed participant via a horizontal member and tripod legs for commonly mounting the hub, leg and arm supporting reels, energy dissipative assembly and other functional components in a compact manner.
- 11. A method for enhancing physical activity and cardiovascular health of a horizontally disposed participant utilizing an RRE apparatus wherein the method comprises the steps of:positioning the participant under the RRE apparatus in a horizontally disposed manner; coupling a first limb group including a left leg and right arm of the participant to a first flexible line and coupling a second limb group including a right leg and a left arm of the participant to a second flexible line; supporting or balancing the weight of the limb groups one against the other via respectively coupling the first and second lines to opposite sides of the drive assembly; coupling the drive assembly to the energy dissipative assembly; drivingly elevating and lowering the limb groups in an alternate manner against a resistive mechanical impedance load presented by the energy dissipative assembly thereby applying power thereto; and dissipating the applied power as heat.
- 12. A method for determining instant values of power applied to the RRE apparatus of claim 11 wherein the method comprises the steps of:conveying a first signal representative of the area of the selected orifice to the controller; actuating the RRE apparatus such that there is a flow of fluid through the selected orifice; measuring fluid pressure present in the fluid delivered to the selected orifice; conveying a second signal representative of fluid pressure present in the fluid delivered to the selected orifice to the controller; and determining instant values of power applied to the RRE apparatus according to the formula Pwr=CdA(2/ρ)0.5(P)1.5 where Pwr is a signal representative of an instant value of applied power, Cd is a signal representing the operative flow coefficient, A is the first signal, ρ is a signal representing fluid density, and P is the second signal.
- 13. A method for determining instant values of power applied to the RRE apparatus of claim 12 wherein the method comprises the steps of:conveying a first signal representative of the areas of the substantially identical selected first and second orifices to the controller; actuating the RRE apparatus such that there is a flow of fluid through the selected first and second orifices and the return orifice; measuring pressure present in the partially spent fluid delivered to the return orifice; conveying a second signal representative of pressure present in the partially spent fluid delivered to the return orifice to the controller; and determining instant values of power applied to the RRE apparatus according to the formula Pwr=Cd((2Ao3+2Ao2Ar+AoAr2+Ar3)/Ao2)(2/ρ)½(Pt){fraction (3/2)}where Pwr is a signal representative of an instant value of applied power, Cd is a signal representing the operative flow coefficient, Ao is the first signal, Ar is a signal representing the area of the return orifice, ρ is a signal representing fluid density, and Pt is the second signal.
- 14. A method for determining running values of power applied to an RRE apparatus of claim 11 wherein the method comprises the steps of:actuating the RRE apparatus such that power is dissipated in the energy dissipative hydraulic assembly; measuring the temperature of the energy dissipative hydraulic assembly; conveying a first signal indicative of the temperature of the energy dissipative hydraulic assembly to the controller; measuring the ambient temperature; conveying a second signal indicative of the ambient temperature to the controller; sampling the first signal at sequential equal increments of time; subtracting the immediately previous first signal value from the instant first signal value to obtain a differential first signal value; determining the rate of change of the first signal by dividing the differential first signal value by the increment of time; determining running values of power applied to the RRE apparatus according to the formula Pwr=K1dTo/dt+K2(To−Ta)+K3(To4−Ta4) where Pwr is a signal representative of a running value of applied power, K1 is a first constant relating to transient heating determined by calibration procedures, dTo/dt is the rate of change of the first signal, K2 is a second constant relating to heat transfer via conduction and convection determined by calibration procedures, (To−Ta) is the difference between the first and second signals, K3 is a third constant relating to heat transfer via radiation also determined by calibration procedures, and (To4−Ta4) is the difference in the first and second signals each raised to the fourth power; andmultiplying the running value of applied power by a constant suitable for its conversion into any desirable units such as Kilogram-Meters/minute.
- 15. A method for determining instant values of power applied to the RRE apparatus of claim 11 wherein the method comprises the steps of:actuating the RRE apparatus such that a flow of electrical current is delivered to the resistor bank; measuring voltage associated with the flow of electrical current delivered to the resistor bank; conveying a signal indicative of voltage associated with the flow of electrical current delivered to the resistor bank to the controller; and determining instant values of power applied to the RRE apparatus according to the formula Pwr=V2/R where Pwr is a signal representative of an instant value of applied power, V is the signal indicative of voltage associated with the flow of electrical current delivered to the resistor bank, and R is a signal representing the resistance value for the resistor bank.
- 16. A method for determining running values of power applied to an exercise RRE apparatus in conjunction with a method for determining instant values of power applied to RRE apparatus, the apparatus for use by a horizontally disposed participant in implementing an exercise wherein each limb extremity of the horizontally disposed participant is coupled to the RRE apparatus by a pair of pulleys supported by flexible lines, one of the pair connected to a first limb group including a left leg and a right arm of the participant, an other of the pair connected to a second limb group including a right leg and a left arm of the participant wherein the method comprises the steps of:sampling instant values of applied power once during each unit of time where a time unit is a selected fraction of average RRE apparatus cycle time; summing the first N samples of instant applied power values over N time units where N time units are at least equal to a maximum RRE apparatus cycle time; dividing by the number N to obtain a first average value of applied power; concomitantly eliminating the oldest sample of instant applied power values and adding the most recent sample thereof; dividing by the number N to obtain the running value of applied power; and multiplying the running value of applied power by a constant suitable for its conversion into any desirable units such as Kilogram-Meters/minute.
- 17. A method for determining a running applied energy value of energy applied to an RRE exercise apparatus in conjunction with a method for determining running values of power applied to an RRE apparatus, the apparatus for use by a horizontally disposed participant in implementing an exercise wherein each limb extremity of the horizontally disposed participant is coupled to the RRE apparatus by a pair of pulleys supported by flexible lines, one of the pair connected to a first limb group including a left leg and a right arm of the participant, an other of the pair connected to a second limb group including a right leg and a left arm of the participant wherein the method comprises the steps of:partitioning time into time increments each defined by a sequential passage of N time units; multiplying the running value of applied power attained at the end of each time increment by that time increment to obtain a value of applied energy for that particular time increment; generating a running sum of the applied energy values to determine the running value of energy applied to the RRE apparatus; and multiplying the running value of applied energy by a constant suitable for its conversion into any desirable units such as Calories.
- 18. The RRE apparatus of claim 1 wherein the RRE apparatus additionally comprises a controller and means for providing the controller with a suitable signal or signals for determining running values of power applied to the RRE apparatus based upon the signal or signals.
- 19. A method for determining a coefficient of performance (hereinafter “COP”) for a horizontally disposed participant utilizing an RRE apparatus of claim 18, where a COP value of 100% is referenced to the assumed ability of an average healthy 150 pound human to continuously deliver applied power at a 0.1 rate, and wherein the method comprises the steps of:programming the participant's weight in the controller; positioning the participant under the RRE apparatus in a horizontally disposed manner; coupling the horizontally disposed participant's limb groups to the rope lines; supporting or balancing the weight of the limb groups one against the other via respectively coupling the lines to opposite sides of the drive assembly; coupling the drive assembly to the energy dissipative assembly; drivingly elevating and lowering the limb groups in an alternate manner against a resistive mechanical impedance load presented by the energy dissipative assembly thereby applying power thereto; dissipating the applied power as heat; determining running values of applied power; determining running values of the participant's COP according to the formula COP=K(Pwr/Wt)where K is a dimensioned constant utilized to rectify units of measurement, Pwr is a signal representing the running applied power value and Wt is a signal representing the participant's weight; andpresenting the participant's COP value to him or her.
- 20. RRE apparatus for use in cardiovascular stress testing of a horizontally disposed heart patient while the patient implements RRE, comprising:pulley supported flexible lines respectively coupled to the extremities of the legs of the horizontally disposed heart patient; a hand bar for the heart patient to hold on to and achieve stability as the patient implements RRE via drivingly elevating and lowering the legs; a drive assembly coupled to the lines; an energy dissipative assembly coupled to the drive assembly; a combining and supporting structure; a controller; means for providing the controller with a suitable signal or signals for determining running values of power applied to the RRE apparatus based upon the signal or signals; and electrocardiographic equipment for collecting electrocardiographic data as the heart patient implements RRE; the combination for nominally supporting or balancing the weight of the horizontally disposed heart patient's legs one against the other such that the heart patient is able to alternately apply lifting force to the left leg while pulling down on the right and then lifting force to the right leg while pulling down on the left, for dissipating power applied by the heart patient while he or she periodically elevates and lowers the legs in an alternate rhythmic manner, and for enabling the generation of a coefficient of performance produced by the heart patient concomitantly with the gathering of electrocardiographic data in order to test his or her cardiovascular capacity as he or she implements RRE.
- 21. A method for testing cardiovascular capacity of a horizontally disposed heart patient utilizing the RRE apparatus of claim 20 via generating running coefficient of performance (hereinafter “COP”) values where a COP value of 100% is referenced to the assumed ability of an average healthy 150 pound human to continuously deliver applied power at a 0.1 rate, and wherein the method comprises the steps of:programming the heart patient's weight in the controller; hooking up the heart patient to the electrocardiographic equipment; positioning the heart patient under the RRE apparatus in a horizontally disposed manner; coupling the horizontally disposed heart patient's legs to the flexible lines; supporting or balancing the weight of the legs one against the other via respectively coupling the lines to opposite sides of the drive assembly; coupling the drive assembly to the energy dissipative assembly; instructing the heart patient to drivingly elevate and lower the patient's legs in an alternate manner against a resistive mechanical impedance load presented by the energy dissipative assembly thereby applying power thereto; dissipating the applied power as heat; determining running values of applied power; determining running values of the heart patient's COP according to the formula COP=K(Pwr/Wt) where K is a dimensioned constant utilized to rectify units of measurement, Pwr is a signal representing the running applied power value and Wt is a signal representing the heart patient's weight;presenting a target COP value to the heart patient; presenting the heart patient's actual COP value to the patient; increasing the target COP value as a function of time; instructing the heart patient to observe the patient's actual COP value and keep it ahead of the increasing target COP value by exercising in a progressively more vigorous manner via higher repetition rates and/or longer stroke length; terminating testing either when the heart patient is no longer able to exceed the increasing target COP value, or alternately, upon the heart patient encountering ischemia or any other irregularity; and evaluating resulting electrocardiographic data with reference to synchronously obtained COP values.
CROSS-REFERENCE TO RELATED APPLICATIONS
The subject matter of the present application is largely taken from that of Provisional U.S. patent application Ser. No. 60/146,741 dated Aug. 2, 1999 and from Provisional U.S. patent application Ser. No. 60/165,756 dated Nov. 16, 1999 both entitled “Method and Apparatus for Enhancing and Evaluating Cardiovascular Health”, and therefore claims priority in part from those dates. In addition, the subject matter of the present application is also related to that of U.S. patent application Ser. No. 09/174,391 dated Oct. 14, 1998, which in turn, drew priority from Provisional U.S. patent application Ser. No. 60/097,206 dated Aug. 29, 1998 and Provisional U.S. Patent Application Ser. No. 60/099,378 dated Sep. 8, 1998 all entitled “Method and Apparatus for Enhancing Cardiovascular Activity and Health Through Rhythmic Limb Elevation”. Because of their precursive association with the present invention, the patent application '391 and the provisional patent applications '206, '378, '741 and '756 are expressly incorporated herein by reference.
US Referenced Citations (7)
Non-Patent Literature Citations (2)
Entry |
Brochure entitled EECP Treatment, an educational service of Vasomedical, Inc. |
Brochure entitled EECP A New Therapy For Angina Ppectoris (A Patient's Guide to Enhanced External Counterpulsation) by Vasomedical, Inc. Heartbeat, vol. 3, No. 2 p. 1-4. |
Provisional Applications (4)
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Number |
Date |
Country |
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60/146741 |
Aug 1999 |
US |
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60/165756 |
Nov 1999 |
US |
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60/097206 |
Aug 1998 |
US |
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60/099378 |
Sep 1998 |
US |