Thermal engine utilizing isothermal piston timing for automatic, self-regulating, speed control
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F01B-029/10
F01B-029/00
출원번호
UP-0804072
(2007-05-17)
등록번호
US-7584613
(2009-09-22)
발명자
/ 주소
Crow, Darby
대리인 / 주소
Baker, Rod D.
인용정보
피인용 횟수 :
6인용 특허 :
6
초록▼
A method and apparatus for converting thermal energy to mechanical energy. Operating on a thermodynamic cycle of isentropic compression, isothermal expansion, isentropic expansion and finally constant pressure cooling and contraction, an external heat engine utilizes a heat exchanger carrying heat f
A method and apparatus for converting thermal energy to mechanical energy. Operating on a thermodynamic cycle of isentropic compression, isothermal expansion, isentropic expansion and finally constant pressure cooling and contraction, an external heat engine utilizes a heat exchanger carrying heat from an external energy source to the working parts of the engine. Apparatus and methods are disclosed for engine piston timing, such that during isothermal expansion, each unit angular rotation of a drive shaft results in the capture of a constant, unit amount of working fluid expansion energy. Thus, the amount of energy captured during each unit angular rotation of apparatus drive shaft is a constant. Timing the working fluid expansion and fluid flow assures that the working fluid undergoes isothermal expansion, regardless of the quantum of heat energy applied. The modulation of heat input to the heat exchanger results in an automatic modulation of engine speed.
대표청구항▼
I claim: 1. A method for operating a thermal engine to convert thermal energy to mechanical energy, comprising the steps of: providing a unit mass of working fluid at an ambient temperature and an ambient pressure; isentropically compressing the unit mass of working fluid to a higher temperature an
I claim: 1. A method for operating a thermal engine to convert thermal energy to mechanical energy, comprising the steps of: providing a unit mass of working fluid at an ambient temperature and an ambient pressure; isentropically compressing the unit mass of working fluid to a higher temperature and a higher pressure; isothermally expanding the unit mass to a first subsequent volume; uniformly adding heat energy to the unit mass of working fluid by moving the unit mass past a heat exchanger while maintaining a constant Reynolds number through the heat exchanger; isentropically expanding the unit mass of working fluid to a second subsequent volume; driving with the isothermally expanding working fluid a first piston and a second piston in respective cylinders, thereby turning a shaft through at least one angular rotation; timing the driving of the first piston and the second piston such that a substantially equal amount of working fluid expansion energy is used for each angular rotation of the shaft; and exhausting at least a portion of the unit mass of working fluid; wherein the positions of the pistons in the cylinders during isothermal expansion are a function of a shaft rotation angle. 2. The method of claim 1 wherein the step of timing the driving of the pistons further comprises determining a required total engine volume as a function the shaft rotation angle. 3. The method of claim 2 wherein the step of determining a required total engine volume comprises determining a required total engine volume V as a function of a shaft rotation angle θ, using the formulae dE(θ)/dθ=P·dV=Constant and V=VieK/ RT(θ-θ1) wherein P is pressure and E is the energy extracted from the expanding working fluid, engine volume V is a function of the engine shaft rotation angle θ, K is an angular power increment, θ1 is a shaft angle at the beginning of isothermal expansion, and Vi is an engine volume at the start of isothermal expansion. 4. The method of claim 3 further comprising determining the position of the first piston as a function of the shaft rotation angle θ during isothermal expansion. 5. The method of claim 4 wherein the step of determining the position of the first piston comprises: choosing a constant Reynolds number value Re; defining with the first piston and its corresponding cylinder a first working chamber; and calculating a first working chamber volume V1 using the formulae and V=VieK/ RT(θ-θ1) wherein Um is mean flow velocity, μ is the thermal diffusivity of the working fluid, ρ is the density of the working fluid, and L is the characteristic length of the heat exchanger. 6. The method of claim 5 further comprising: defining with the second piston and is corresponding cylinder a second working chamber; and determining the position of the second piston using the formula V=V1+V2+Dead_Volume wherein V1 is the first working chamber volume, V2 is a second working chamber volume, and Dead_Volume is the un-swept volume in the engine, including the heat exchanger volume. 7. A method for timing the operation of a thermal engine exploiting a thermodynamic cycle including an isothermal expansion step, comprising: isothermally expanding a working fluid against a moveable piston to turn a loaded shaft through at least one angular rotation; determining a required total engine volume V as a function of a shaft angle θ, using the formulae dE(θ)/dθ=P·dV=Constant and V=VieK/ RT(θ-θ1) wherein P is pressure and E is the energy extracted from the expanding working fluid, engine volume V is a function of the engine shaft angle θ, K is an angular power increment, θ1 is an isothermal begin angle, and Vi is the engine volume at the start of isothermal expansion; and determining a piston position as a function of shaft angle during isothermal expansion. 8. The method of claim 7 further comprising inputting substantially uniformly heat energy into the expanding working fluid by constraining fluid flow through the heat exchanger such that Reynolds number is constant. 9. A thermal engine for converting thermal energy to mechanical energy, comprising: means for drawing a unit mass of working fluid into a compression chamber at an ambient temperature and an ambient pressure, comprising: a compression piston slidably movable within a compression cylinder; and a transfer piston slidably moveable within a transfer cylinder, said transfer cylinder in fluid communication with said compression cylinder; means for iseniropically compressing said unit mass of working fluid to a higher temperature and a higher pressure, comprising; said compression piston slidably movable within said compression cylinder; and said transfer piston slidably moveable within a transfer cylinder in fluid communication with said compression cylinder; a heat exchanger, external to the working fluid, for uniformly adding heat energy to said unit mass while isothermally expanding the unit mass of working fluid to a first subsequent volume, wherein said compression piston is slidably movable in said compression cylinder to push at least a portion of said unit mass past said heat exchanger while maintaining a constant Reynolds number through said heat exchanger; a drive shaft in operative connection with said pistons, whereby isothermally expanding working fluid causes said shaft to turn through at least one angular rotation; means for isentropically expanding said unit mass to a second subsequent volume, comprising said compression piston moving within said compression cylinder; and a valve for exhausting working fluid from the engine; wherein positions of said pistons in said cylinders during isothermal expansion are a function of a rotation angle of said drive shaft. 10. The engine of claim 9 wherein, during isothermal expansion, timing of the sliding movements of said pistons causes a unit of angular rotation of said drive shaft to capture of a constant unit amount of working fluid expansion energy.
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이 특허에 인용된 특허 (6)
Proeschel Richard A., Afterburning ericsson cycle engine.
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