Method of controlling a free piston external combustion engine

US 4,653,274 A
Filed: 10/21/1985
Issued: 03/31/1987
Est. Priority Date: 03/06/1984
Status: Expired due to Fees

First Claim

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1. A method for controlling the operation of an external combustion engine wherein said engine comprises a compressor for compressing ambient air for supply to a combustion member including a free piston travelling between two end closures of a sleeve in which said piston slides reciprocatingly thus defining two combustion chambers between each end closure and the corresponding end of the piston and in which fuel is introduced for burning and the combusted gas resulting therefrom is expanded in an expansion member of the engine for driving the compressor and a power delivery member, attachments to both the piston and the sleeve end closure which cooperate for imparting a rotational movement to the piston during its reciprocating sliding axial motion thus providing two coordinated motions of the piston for location and motion direction detections so as to generate signals, air inlet and gas outlet valving means in the combustion member, a compressed air and combusted gas storage tank located between the power delivery member and the combustion member, means for sensing the pressure and temperature of the compressed air in said tank, means for introducing the fuel and means for igniting the fuel, a brake system located between the piston and the sleeve cooperating attachments, means for detecting the piston axial location in the sleeve, means for sensing compressed air pressure downstream of the storage tank and of a metering orifice, means for setting the power level that an engine operator demands, and a control system including a central processing unit having input ports, output ports and memory storage, said method comprising the steps of:

generating a first set of signals from the compressed air pressure and temperature sensing means, said first set of signals representing the conditions of the air to be later introduced inside the combustion chambers;

generating a first signal from the piston location detecting means when the piston reaches the end of each and every stroke, said first signal representing both the time at which the beginning of a piston cycle and the end of the previous cycle occur;

generating a second set of signals from the piston location detecting means during the first quarter of the piston stroke, said second set of signals representing the beginning, the end and the duration of the period of time taken by the piston to travel a fixed distance along its axial movement;

generating a second signal from the piston location detecting means during the fourth quarter of the piston stroke, said second signal representing the time at which the piston reaches a known and fixed location toward the end of its stroke;

generating a third signal from the the pressure sensing means located downstream of the storage tank and of a metering orifice representing the compressed air pressure in the combustion chamber being filled with air, during a short instant following the initiation of the generation of the second set of signals;

generating a fourth signal from the means for setting the power level demanded by the operator, said fourth signal representing a set fraction of the range of power levels that the engine is capable of delivering between idle and full power settings;

processing each one of said signals of the second set to generate a fifth signal representing the average velocity reached by the piston during the fixed distance travelled, and located in the first quarter of its stroke;

processing each of said signals of the first set in combination with each of said second, third, fourth and fifth signals to generate a sixth signal representing the total amount of air to be introduced in the chamber being filled with compressed air during the open period of the inlet valving means;

processing each said sixth signal representing said amount of air in combination with each said fourth signal to generate a seventh signal representing the amount of fuel to be introduced for combustion in the combustion chamber during the remnant of the piston stroke; and

processing each said seventh signal representing the amount of fuel to be burned to generate an eighth signal representing the ignition time for initiating the activation of the means for igniting the fuel;

whereby the fuel burns in the compressed air to provide the energy required of the gas expansion member so as to produce the power demanded of the engine by the operator.

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Abstract

A free-piston combustion member comprising air compression and gas expansion chambers is combined with a rotary motor. The rotary motor shaft drives an air compressor, receives power from the gases expanding in an expansion chamber and provides residual torque and power for external use. Two combustion chambers located at each end of the free piston receive compressed air and fuel for combustion outside of the rotary motor assembly. The motion of the free piston between the two combustion chambers is independent of the motor rotary motion. The air admission inside the combustion chambers, the fuel injection and the combustion initiation process are all controlled and timed by the free piston movement back and forth. A heat exchanger is located between the combustion-chamber/free-piston assembly and the rotary motor. It also serves as storage tank for the compressed air before its admission in the combustion chambers in order to smooth out pressure surges in the compressed air entering the combustion chambers. The power output of the rotary motor is determined by the adjustment of the amounts of air and fuel admitted in the combustion chambers. Air and fuel admissions are controlled simultaneously in a programmed manner. The results are a slower, more efficient combustion process and the concomitant possible use of inexpensive fuels, and the emission of a lesser amount of pollutants in the exhaust gas.

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8 Claims

1. A method for controlling the operation of an external combustion engine wherein said engine comprises a compressor for compressing ambient air for supply to a combustion member including a free piston travelling between two end closures of a sleeve in which said piston slides reciprocatingly thus defining two combustion chambers between each end closure and the corresponding end of the piston and in which fuel is introduced for burning and the combusted gas resulting therefrom is expanded in an expansion member of the engine for driving the compressor and a power delivery member, attachments to both the piston and the sleeve end closure which cooperate for imparting a rotational movement to the piston during its reciprocating sliding axial motion thus providing two coordinated motions of the piston for location and motion direction detections so as to generate signals, air inlet and gas outlet valving means in the combustion member, a compressed air and combusted gas storage tank located between the power delivery member and the combustion member, means for sensing the pressure and temperature of the compressed air in said tank, means for introducing the fuel and means for igniting the fuel, a brake system located between the piston and the sleeve cooperating attachments, means for detecting the piston axial location in the sleeve, means for sensing compressed air pressure downstream of the storage tank and of a metering orifice, means for setting the power level that an engine operator demands, and a control system including a central processing unit having input ports, output ports and memory storage, said method comprising the steps of:
- generating a first set of signals from the compressed air pressure and temperature sensing means, said first set of signals representing the conditions of the air to be later introduced inside the combustion chambers;
  
  generating a first signal from the piston location detecting means when the piston reaches the end of each and every stroke, said first signal representing both the time at which the beginning of a piston cycle and the end of the previous cycle occur;
  
  generating a second set of signals from the piston location detecting means during the first quarter of the piston stroke, said second set of signals representing the beginning, the end and the duration of the period of time taken by the piston to travel a fixed distance along its axial movement;
  
  generating a second signal from the piston location detecting means during the fourth quarter of the piston stroke, said second signal representing the time at which the piston reaches a known and fixed location toward the end of its stroke;
  
  generating a third signal from the the pressure sensing means located downstream of the storage tank and of a metering orifice representing the compressed air pressure in the combustion chamber being filled with air, during a short instant following the initiation of the generation of the second set of signals;
  
  generating a fourth signal from the means for setting the power level demanded by the operator, said fourth signal representing a set fraction of the range of power levels that the engine is capable of delivering between idle and full power settings;
  
  processing each one of said signals of the second set to generate a fifth signal representing the average velocity reached by the piston during the fixed distance travelled, and located in the first quarter of its stroke;
  
  processing each of said signals of the first set in combination with each of said second, third, fourth and fifth signals to generate a sixth signal representing the total amount of air to be introduced in the chamber being filled with compressed air during the open period of the inlet valving means;
  
  processing each said sixth signal representing said amount of air in combination with each said fourth signal to generate a seventh signal representing the amount of fuel to be introduced for combustion in the combustion chamber during the remnant of the piston stroke; and
  
  processing each said seventh signal representing the amount of fuel to be burned to generate an eighth signal representing the ignition time for initiating the activation of the means for igniting the fuel;
  
  whereby the fuel burns in the compressed air to provide the energy required of the gas expansion member so as to produce the power demanded of the engine by the operator.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
- - 2. The method recited in claim 1 wherein minimum and maximum values for the fuel-amount to air-amount ratio are established for each type of fuel to be used and are stored in the central processing unit memory and wherein a set value of said ratio is established for each power level setting of the engine, said method comprising the further steps of:
    - generating a ninth signal from the fuel/air ratio values stored in the memory representing the ratio limits which the value of the seventh signal is not allowed to exceed in either direction; and
      
      processing each of said seventh and ninth signals to insure that, during large rapid variations of the power level demand, values of the seventh signal are enabled to reach the limit values of the fuel/air ratio represented by the ninth signal;
      
      whereby;
      
      (1) a maximum average temperature of the combusted gas in the combustion chamber is never exceeded while maximum acceleration rates of the engine are always available, and (2) the engine deceleration rate is automatically maximized.
  - 3. The method recited in claim 2 wherein the fuel is provided by a fuel system at a pressure which enables fuel injectors to finely break the fuel jet into the combustion chamber for efficient and fast burning and during a period of time such that the amount of fuel injected corresponds to the amount required for each piston cycle, and wherein the burning characteristics of various types of fuels are stored in the central processing unit, said method comprising the further steps of:
    - generating a tenth signal from the central processing unit memory storage and representing the burning characteristics of the fuel being used in the engine as indicated by an engine operator;
      
      processing said seventh and tenth signals to generate a third set of two signals, one representing the fuel injection pressure and the other representing the duration of the fuel injection;
      
      applying the fuel injection pressure signal to means for adjusting said pressure for each piston cycle, and the fuel injection duration signal to timing means for causing the fuel injection to start and to stop at determined times during the piston stroke in response to said central processing unit generated signals;
      
      whereby both the values of the fuel injection pressure and of the fuel injection duration are optimally balanced between set limits so as to cause the fuel of the type being used to burn most effectively and efficiently during said piston stroke.
  - 4. The method recited in claim 1 wherein means for adjusting the values of variable coefficients used by the central processing unit are provided, said method comprising the further steps of:
    - processing each combination of each of said first signal and second signal, said combination representing the time elapsed from the start of the piston cycle to the time at which the piston reaches a known and fixed location during the fourth quarter of the piston stroke to generate an eleventh signal representing the piston average velocity over said elapsed time;
      
      comparing each value of said eleventh signal with each corresponding value of the fifth signal to generate a twelfth signal representing the amount of adjustment by which the variable coefficient used by the means for generating the fifth signal must be corrected to make the values of the fifth and eleventh signal coincide within a specified percentage differential value, andapplying said coefficient adjustment to the means for generating the fifth signal during the next piston cycle;
      
      whereby, during quasi steady-state engine operation, the piston average velocity determined during the first quarter of the piston stroke is caused to approximate very closely the piston velocity averaged over most of its stroke, thereby providing more accurate timing means during the second and third quarters of the piston stroke.
  - 5. The method recited in claim 3 wherein the operational timing of the inlet and the outlet valving means is directly and automatically regulated by the two piston coordinated motions, said method comprising the further steps of:
    - generating a thirteenth signal from the piston location detecting means when the piston reaches the end of the n_th cycle, n being a specified whole odd number of cycles counted from the start of the first cycle of said n cycles;
      
      measuring the time elapsed between the first signal of said first cycle and said thirteenth signal at the end of the n_th cycle to generate a fourteenth signal representing a piston cycle average duration and to generate a fifteenth signal representing the piston average velocity over said elapsed time; and
      
      processing each of said fourteenth and fifteenth signals to generate a real time reference base for relating piston location timing to real-time timing;
      
      whereby fuel injection duration may be expressed in real time and ignition means timing may be expressed in fraction of piston stroke and cycle duration.
  - 6. The method recited in claim 4 wherein the inlet and outlet valving means includes poppet valves situated on the sleeve end closures and the operation of said valves is actuated by control means, said method comprising the further steps of:
    - processing each said first signal representing the origin of each piston cycle and each said eleventh signal obtained during the preceding cycle to generate a sixteenth signal representing the time at which the corresponding inlet valve is to open;
      
      applying said sixteenth signal to the inlet valve actuating control means during the first quarter of each piston cycle;
      
      processing each said fourth signal from the means for setting the power level demanded by the operator to generate a seventeenth signal representing the time at which the corresponding inlet valve is to close for adjusting the amount of compressed air introduced in the corresponding combustion chamber;
      
      applying each of said seventeenth signal to the corresponding inlet valve actuating control means;
      
      processing each said eleventh signal representing the piston average velocity over most of its stroke to generate a fourth set of two signals representing the times at which the outlet valves will open and close before the end of said piston stroke, the first one of said fourth set signals corresponding to the opening of the outlet valve of the combustion chamber in which fuel combustion occurs during said piston stroke and the second one of said fourth set signals corresponding to the closing of the outlet valve of the other combustion chamber located at the opposite end of the sleeve, said outlet valve opening being timed to occur prior to said outlet valve closing; and
      
      applying each one of said signals of said fourth set to the outlet valve actuating control means;
      
      whereby;
      
      (1) the inlet valves are caused to timely open and close for controlling the amount of air admitted in each combustion chamber during each and every piston cycle, thereby adjusting the engine power delivery capability, (2) the opening created by an open inlet valve constitutes the air metering orifice, (3) the needed amount of combusted gas is caused to remain trapped between the piston end and the corresponding sleeve end closure to insure the timely bouncing back of the piston at the end of its stroke, and (4) at least one outlet valve is open so as to provide an uninterrupted flow of combusted gas to the storage tank and the power delivery member.
  - 7. The method recited in claim 5 wherein a compressed air intake valve and associated actuating means are provided between the storage tank and the inlet valving means for adjusting the compressed air flow into the combustion member, said method comprising the further steps of:
    - processing each said fourth signal from the means for setting the engine power level to generate an eighteenth signal representing the degree of opening of the intake valve corresponding to the power level demanded by the engine operator; and
      
      applying each said eithteenth signal to the intake valve actuating means;
      
      whereby the opening offered by the intake valve to the compressed air flow constitutes the air metering orifice needed for adjusting the amount of compressed air introduced in each combustion chamber during each piston stroke.
  - 8. The method recited in claim 3 wherein the engine further includes a dump valve and associated actuating means for venting the storage tank to the atmosphere, an exhaust shut-off valve and associated actuating means for shutting off the compressed gas flow from the storage tank to the expansion member, a starter, means for preventing the combusted gas to flow back from the storage tank to the combustion member and processing means within the central processing unit for automatically scheduling the engine starting and stopping phases, said method further comprising the steps of:
    - generating a fifth set of signals when the central processing unit is switched on, from the starting processing means, for initiating the engine starting phase, said signals of the fifth set being programmed to be generated and applied according to a set time sequence as follows in the order indicated hereinunder;
      
      (1) applying a first signal to the dump valve actuating means so as to close said valve, (2) applying a second signal to activate the starter for compressing air, (3) applying a third signal to the air metering orifice actuating means so as to insure that a combustion chamber fills up with compressed air, (4) applying a fourth signal to the exhaust shut-off valve actuating means so as to slowly open said valve, (5) applying a fifth signal to the fuel introduction means so as to inject a set amount of fuel into said combustion chamber being filled with compressed air, (6) applying a sixth signal to the means for igniting the fuel so as to initiate the first combustion cycle, (7) applying a seventh signal to actuating means for releasing the piston securing means of the piston brake system, (8) applying an eighth signal to actuating means of the outlet valving closing means so as to cause a set amount of ambient air to become trapped in the combustion chamber opposite to that in which said first combustion cycle is taking place, (9) then applying a time-delayed ninth signal to the central processing unit so as to initiate the normal engine operation control and stop the engine starting phase, and (10) applying a tenth signal to the starter switching means to stop its assistance to the power delivery member; and
      
      generating a sixth set of signals from the stopping processing means when the central processing unit is switched off for initiating and completing the stopping phase of the engine, said signals of the sixth set being programmed to be generated and applied according to a set time sequence as follows, in the order indicated hereinunder;
      
      (1) applying a first signal to the fuel introduction means and to the ignition means so as to stop their operation instantly, (2) applying a second signal to the dump valve actuating means so as to open said valve for venting the storage tank to the atmosphere, (3) applying a third signal to the exhaust shut-off valve actuating means so as to close said valve, (4) applying a fourth signal to the actuating means of the inlet valving means so as to close the air metering orifice, (5) applying a fifth signal to the actuating means of the piston brake system so as to stop and then secure the piston in place, (6) applying a sixth signal to the actuating means of the piston brake system for releasing the brake upon securing the piston, and (7) applying a seventh signal to the central processing unit for shutting itself off entirely;
      
      whereby the processing means for automatically starting and stopping the engine assumes control of the operation of all air and gas flow regulating valves and of the combustion member in response to the central processing unit being switched on for the starting phase and being switched off for the stopping phase and thus insuring that;
      
      (1) during the starting phase, the means for supplying compressed air remains power assisted by the starter until the combusted gas expansion member generates enough power to drive the compressor without further assistance, at which time the storage tank has become fully pressurized, (2) no more than a few full piston cycles are required for reaching such self-sustaining operation which defines idle speed, (3) the central processing unit assumes normal control, from the processing means for automatically scheduling the starting phase, of the combustion member operation upon completion of the first piston cycle when the piston has just bounced back from the end of its stroke, (4) during the stopping phase, the piston average velocity continues to be monitored by the central processing unit, (5) the brake system is activated when the average piston velocity after a rebounce becomes less than a set value, (6) the piston is stopped before engaging the piston securing means, (7) the piston brake system becomes inactivated when the piston has been secured in place, and (8) the piston remains secured in place, with the brake system inactive, until said piston is released during a following starting phase.

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Current Assignee
Constant V. David
Original Assignee
Constant V. David
Inventors
David, Constant V.
Primary Examiner(s)
Koczo, Michael

Application Number

US06/789,451
Time in Patent Office

526 Days
Field of Search

60/595, 123/46 R, 123/46 A
US Class Current

60/595
CPC Class Codes

F01B 3/0079   having pistons with rotary ...

F02B 1/04   with fuel-air mixture admis...

F02B 2053/005   Wankel engines

F02B 71/045   with hydrostatic transmission

F02B 75/04   Engines with variable dista...

F02F 2200/04   Forging of engine parts

F02F 3/22   the fluid being liquid

F02G 2250/03   Brayton cycles

F05C 2201/021   Aluminium

Method of controlling a free piston external combustion engine

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Method of controlling a free piston external combustion engine

First Claim

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Abstract

27 Citations

8 Claims

Specification

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