CN103104372A - Three-type-gate hot air engine - Google Patents

Three-type-gate hot air engine Download PDF

Info

Publication number
CN103104372A
CN103104372A CN2013100300209A CN201310030020A CN103104372A CN 103104372 A CN103104372 A CN 103104372A CN 2013100300209 A CN2013100300209 A CN 2013100300209A CN 201310030020 A CN201310030020 A CN 201310030020A CN 103104372 A CN103104372 A CN 103104372A
Authority
CN
China
Prior art keywords
cylinder piston
piston mechanism
attached
cylinder
stroke
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
CN2013100300209A
Other languages
Chinese (zh)
Inventor
靳北彪
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Molecule Power Beijing Technology Co Ltd
Original Assignee
Molecule Power Beijing Technology Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Molecule Power Beijing Technology Co Ltd filed Critical Molecule Power Beijing Technology Co Ltd
Priority to CN2013100300209A priority Critical patent/CN103104372A/en
Publication of CN103104372A publication Critical patent/CN103104372A/en
Pending legal-status Critical Current

Links

Images

Abstract

The invention discloses a three-type-gate hot air engine which comprises an air cylinder piston mechanism. An air inlet and a reciprocating circulating opening are formed in an air cylinder of the air cylinder piston mechanism. A corresponding air inlet gate is arranged on the position of the air inlet. A corresponding reciprocating circulating control gate is arranged on the position of the reciprocating circulating opening. The three-gat hot air engine further comprises an auxiliary air cylinder piston mechanism. An auxiliary reciprocating circulating opening and an exhaust gas discharging opening are formed in an air cylinder of the auxiliary air cylinder piston mechanism. A corresponding exhaust gas gate is arranged on the position of the exhaust gas opening. The reciprocating circulating opening is communicated with the auxiliary reciprocating circulating opening through a reciprocating circulating channel. A combustion chamber is arranged in the air cylinder of the air cylinder piston mechanism. According to the three-type-gate hot air engine, further using of heat energy in working media after work of combustion explosion is achieved, heat efficiency of the engine is enabled to be further improved, energy saving is benefited, and the three-type-gate hot air engine is simple in structure and strong in practicability, and has wide application prospect.

Description

Three class door hot-air engines
Technical field
The present invention relates to heat power field, especially a kind of hot-air engine.
Background technique
Traditional combustion engine is generally that high-temperature tail gas is directly emitted, and causes thermal losses serious.Yet in traditional heat engine, gas working medium needs heat to heat, conventional mode of heating is external-burning type, the utilization efficiency of fuel is lower again, therefore for the fuel utilization efficiency of existing internal-combustion engine and heat engine, need to provide a kind of can carry out the further motor of utilization to waste heat in engine exhaust.
Summary of the invention
In order to address the above problem, the technological scheme that the present invention proposes is as follows:
Scheme 1: a kind of three class door hot-air engines, comprise cylinder piston mechanism, the cylinder of described cylinder piston mechanism is provided with suction port and reversing current port, described suction port place is provided with corresponding intake valve, described reversing current passage port is provided with corresponding reciprocal circulation control gate, described three class door hot-air engines also comprise attached cylinder piston mechanism, establish attached reversing current port and weary gas exhaust port on the cylinder of described attached cylinder piston mechanism, and the place establishes corresponding weary valve at described weary gas exhaust port; Described reversing current port is communicated with described attached reversing current port through reciprocal communicating passage; Be provided with the firing chamber in the cylinder of described cylinder piston mechanism.
Scheme 2: on the basis of scheme 1, be provided with cooler on described reciprocal communicating passage and/or on the cylinder at described attached cylinder piston mechanism.
Scheme 3: on the basis of scheme 1, establish regenerator on described reciprocal communicating passage.
Scheme 4: on the basis of scheme 3, be provided with cooler on the described reciprocal communicating passage between described regenerator and described attached reversing current port and/or on the cylinder at described cylinder piston mechanism.
Scheme 5: on the basis of scheme 1 to 4 arbitrary scheme, establish corresponding attached reciprocal circulation control gate at described attached reversing current passage port.
Scheme 6: on the basis of scheme 1 to 4 arbitrary scheme, described intake valve and described reciprocal circulation control gate are made described cylinder piston mechanism control according to the control mechanism of suction stroke-compression stroke-combustion explosion expansion stroke-air feed stroke-recharge circulation mode work of stroke-air feed stroke.
Scheme 7: on the basis of scheme 1 to 4 arbitrary scheme, described intake valve, described reciprocal circulation control gate and described weary valve are made described cylinder piston mechanism control according to the control mechanism of suction stroke-compression stroke-combustion explosion expansion stroke-air feed stroke-recharge stroke-air feed stroke-recharge circulation mode work of stroke-air feed stroke.
Scheme 8: on the basis of scheme 1 to 4 arbitrary scheme, described three class door hot-air engines also comprise turbo-power mechanism and impeller gas compressor, described weary gas exhaust port is communicated with the gas access of described turbo-power mechanism, and described suction port is communicated with the gas outlet of described impeller gas compressor.
Scheme 9: on the basis of scheme 8, described turbo-power mechanism is to described impeller gas compressor outputting power.
Scheme 10: on the basis of scheme 1 to 4 arbitrary scheme, establish attached suction port and relief opening on the cylinder of described attached cylinder piston mechanism, described relief opening is communicated with described suction port; The place establishes corresponding attached intake valve at described attached suction port, establishes corresponding exhaust valve in described exhaust ports.
Scheme 11: on the basis of scheme 1 to 4 arbitrary scheme, described three class door hot-air engines also comprise turbo-power mechanism and impeller gas compressor, described weary gas exhaust port is communicated with the working medium entrance of described turbo-power mechanism, the sender property outlet of described turbo-power mechanism is communicated with the working medium entrance of described impeller gas compressor through attached cooler, the sender property outlet of described impeller gas compressor and working medium channel connection; Passage between the sender property outlet of described turbo-power mechanism and the working medium entrance of described impeller gas compressor is provided with the working medium export mouth.
Scheme 12: on the basis of scheme 1 to 4 arbitrary scheme, described cylinder piston mechanism and/or described attached cylinder piston mechanism are made as piston liquid mechanism, described piston liquid mechanism comprises gas-liquid cylinder and gas-liquid isolating structure, and described gas-liquid isolating structure is located in described gas-liquid cylinder.
Scheme 13: on the basis of scheme 12, the inertial force sum the when gas working medium in described gas-liquid cylinder moves reciprocatingly greater than the liquid in described gas-liquid cylinder and described gas-liquid isolating structure to the pressure of described gas-liquid isolating structure.
Scheme 14: on the basis of scheme 1 to 4 arbitrary scheme, described three class door hot-air engines also comprise four class door cylinder piston mechanisms, the air supply opening of described four class door cylinder piston mechanisms is communicated with described suction port, and the mouth that recharges of described four class door cylinder piston mechanisms is communicated with described weary gas exhaust port.
Scheme 15: on the basis of scheme 1 to 4 arbitrary scheme, the mass flow rate of the material that discharge described firing chamber is greater than import the mass flow rate of the material of described firing chamber outside the working medium passage.
Scheme 16: on the basis of scheme 1 to 4 arbitrary scheme, described three class door hot-air engines also comprise low temperature cold source, described low temperature cold source is used for providing cryogenic substance, the working medium that described cryogenic substance is used for cooling described attached cylinder piston mechanism and/or is about to enter described attached cylinder piston mechanism from the working medium passage.
Scheme 17: on the basis of scheme 1 to 4 arbitrary scheme, described cylinder piston mechanism and/or described attached cylinder piston mechanism are made as the opposed pistons cylinder mechanism.
Scheme 18: on the basis of scheme 1 to 4 arbitrary scheme, described cylinder piston mechanism and described attached cylinder piston mechanism are coaxial setting, and are the V-type layout.
Scheme 19: on the basis of scheme 1 to 4 arbitrary scheme, described cylinder piston mechanism and described attached cylinder piston mechanism are α type or the setting of β type.
Scheme 20: on the basis of scheme 1 to 4 arbitrary scheme, the described reversing current port of a plurality of described cylinder piston mechanisms is communicated with the described attached reversing current port of a described attached cylinder piston mechanism.
principle of the present invention is: gas working medium enters in the cylinder of described cylinder piston mechanism from described suction port, close described intake valve, gas working medium is compressed rear generation combustion explosion in the cylinder of described cylinder piston mechanism, promote the piston acting of described cylinder piston mechanism, namely experience successively the suction stroke-compression stroke of similar internal-combustion engine-combustion explosion expansion stroke, then open described reciprocal circulation control gate, working medium in the cylinder of described cylinder piston mechanism is also compressed within it through the cylinder that described reciprocal communicating passage imports described attached cylinder piston mechanism, and before compression and/or when compression discharge a part of heat, and then pushing piston acting in described reciprocal communicating passage is led back the cylinder of described cylinder piston mechanism, circulate at least one times and so forth in the described reciprocal communicating passage of working medium between described cylinder piston mechanism and described attached cylinder piston mechanism after the combustion explosion acting, discharge from described weary gas exhaust port at last, wherein, in described attached reversing current passage port is provided with the structure of attached reciprocal circulation control gate, described weary gas exhaust port is discharged in the process of weary gas, can close described attached reciprocal circulation control gate, make in the described communicating passage between described reversing current port and described attached reversing current port and can keep certain pressure, in described attached reversing current passage port is not established the structure of attached reciprocal circulation control gate, described weary gas exhaust port is discharged in the process of weary gas, and the pressure in the described communicating passage between described reversing current port and described attached reversing current port drops to external pressure gradually.
Three class door hot-air engine work cycle of the present invention are similar to engine cycle and heat engine circulation are combined, and have increased substantially system thermal efficiency.
In the present invention, the space that when so-called working medium passage refers to described three class door hot-air engine normal operation, working medium stream can arrive.
In the present invention, so-called weary gas exhaust port refers to the relief opening of working medium process discharge two cylinders after this two cylinder repeatedly circulates in described cylinder piston mechanism and described attached cylinder piston mechanism; To be different from the relief opening of existing internal-combustion engine.
In the present invention, the fuel that the combustion chemistry reaction occurs in described firing chamber can be hydrocarbon, hydrocarbon oxygen compound or solid carbon.Solid carbon have do not have after burning water to generate and the burning afterproduct in the advantages such as high, the easy liquefaction of gas concentration lwevel; Solid carbon can adopt spray into after solid assembled in advance, powdered or powdered after input described firing chamber with the mode that sprays into after liquid or atmospheric carbon dioxide fluidisation again.
In the present invention, described gas-liquid cylinder refers to hold gas working medium and/or liquid, and the container of energy bearing certain pressure, described gas-liquid cylinder is separated into gas end and liquid end by described gas-liquid isolating structure, the gas end of described gas-liquid cylinder is provided with the gas working medium communication port, and described gas working medium communication port is used for other devices or the mechanism connection with described working medium passage; The liquid end of described gas-liquid cylinder is provided with the liquid communication mouth, and described liquid communication mouth is used for being communicated with hydraulic power mechanism and/or liquid working substance send-back system.
In the present invention, described gas-liquid isolating structure refers to the structure that can move reciprocatingly in described gas-liquid cylinder, as isolating plate, isolating film, piston etc., its effect is gas working medium and the liquid in the described gas-liquid cylinder of isolation, preferably, described gas-liquid isolating structure and described gas-liquid cylinder sealed sliding are movingly.In described piston liquid mechanism working procedure, be in diverse location in described gas-liquid cylinder according to described gas-liquid isolating structure, may be all gas working medium in described gas-liquid cylinder, may be also all liquid, perhaps gas working medium and liquid exist simultaneously.
in the present invention, liquid in described gas-liquid cylinder is different from traditional piston crank mechanism with described gas-liquid isolating structure, piston in traditional piston crank mechanism can be stopped by the thrust of connecting rod or pulling force, thereby realize the restriction to piston stroke, and in described gas-liquid cylinder, when the gas working medium in described gas-liquid cylinder is done positive work, described gas-liquid isolating structure is stressed and moves to the lower dead center direction, liquid is discharged described gas-liquid cylinder with high voltage style and promoted externally acting of hydraulic power mechanism (for example liquid motor), when liquid is about to drain, change liquid motor operations pattern or start liquid working medium send-back system, liquid in described gas-liquid cylinder is no longer reduced, this moment, liquid can apply braking force to the described gas-liquid isolating structure in described gas-liquid cylinder, it is stopped, to prevent that it from clashing into the wall of the liquid bottom section of gas-liquid cylinder, when constantly in the described gas-liquid cylinder during infusion fluid, described gas-liquid isolating structure can constantly move to the top dead center direction, in the time of near arriving top dead center, stop in the described gas-liquid cylinder infusion fluid or make the liquid in described gas-liquid cylinder reduce (outflow), however, liquid and described gas-liquid isolating structure in described gas-liquid cylinder still can be because inertia moves to the top dead center direction, at this moment, if the pressure of the gas working medium in described gas-liquid cylinder is not high enough, can cause described gas-liquid isolating structure continue to move upward and clash into the wall at gas-liquid cylinder top, for fear of this shock, need to make the pressure of gas working medium in gas-liquid cylinder enough high, inertial force sum when it is moved reciprocatingly greater than the liquid in described gas-liquid cylinder and described gas-liquid isolating structure to the pressure of described gas-liquid isolating structure.
in the present invention, inertial force sum when the liquid in gas-liquid cylinder described in the working procedure of described three class door hot-air engines and described gas-liquid isolating structure move reciprocatingly changes, therefore should guarantee all to satisfy at any operation time the condition of " the inertial force sum the when gas working medium in described gas-liquid cylinder moves reciprocatingly greater than the liquid in described gas-liquid cylinder and described gas-liquid isolating structure to the pressure of described gas-liquid isolating structure " in engineering design, for example by adjusting the working pressure in described working medium passage, adjust the quality of gas-liquid isolating structure, the modes such as fluid density or adjustment liquid depth of adjusting realize, wherein, described liquid depth refers to the degree of depth of the liquid of liquid on the direction that moves reciprocatingly.
So-called " adjusting the working pressure in described working medium passage " is to flow into and/or the volume flowrate that flows out the gas working medium of described working medium passage realizes by adjustment, for example can realize by the switch gap of adjusting described weary gas exhaust port, each time of opening and/or the openings of sizes of described weary gas exhaust port.
In the present invention, working pressure (for example can realize by the switching time of adjusting described weary gas exhaust port) by adjusting described working medium passage and the discharge capacity of described cylinder piston mechanism, to control the quality discharge capacity of described cylinder piston mechanism, make the flow mass M of the material of described firing chamber discharge 2Greater than import the flow mass M of the material of described firing chamber outside described working medium passage 1That is to say except importing from described working medium passage outside the material of described firing chamber, some material imports described internal combustion firing chamber from described working medium passage, because described firing chamber is arranged in described working medium passage, so that is to say that the material of discharging from described firing chamber has at least a part to flow back to described firing chamber, namely realized working medium back and forth flowing between described cylinder piston mechanism and described attached cylinder piston mechanism.Can be oxygenant, fuel or pressurized gas etc. from the material of the export-oriented described firing chamber importing of described working medium passage.
In the present invention, described low temperature cold source refers to provide the device of temperature at the cryogenic substance below 0 ℃, mechanism or storage tank, the storage tank that stores cryogenic substance that for example adopts the business buying pattern to obtain, described cryogenic substance can be liquid nitrogen, liquid oxygen, liquid helium or liquefied air etc.When oxygenant in the present invention was liquid oxygen, liquid oxygen can be directly as described cryogenic substance.So-called liquid oxygen comprises the liquid oxygen of business liquid oxygen or in situ preparation.
In the present invention, described low temperature cold source is in the direct mode that described cryogenic substance is mixed with described working medium channel connection with the working medium in described working medium passage, perhaps making the mode of the working medium heat exchange in described cryogenic substance and described working medium passage through heat-exchanger rig, in described attached cylinder piston structure or the working medium that is about to enter described attached cylinder piston mechanism carry out cooling processing.Heat engine be a kind of work cycle near the power mechanism of Carnot's cycle, the calculating of its thermal efficiency can be with reference to the Carnot cycle Thermal efficiency formula:
Figure BDA00002781664500051
Therefrom as can be known, as sink temperature T 2During decline, thermal efficiency η raises, and reduces to the heat of low-temperature receiver discharging, if sink temperature T 2Decline by a big margin, namely sink temperature is very low, and thermal efficiency η is very high, and is very little to the heat of low-temperature receiver discharging.Infer thus, the cryogenic substance that usable temp is quite low makes sink temperature T 2Decline to a great extent, thereby significantly reduce to the heat of low-temperature receiver discharging, effectively improve engine efficiency.
The cryogenic substance that temperature is lower (such as liquid oxygen, liquid nitrogen or liquid helium etc.), need to consume more energy in manufacture process, but with regard to unit mass, the contribution that engine thermal efficiency η is promoted is larger, like storing the energy in the very low material of temperature, the concept that is equivalent to a kind of novel battery, described cryogenic substance can wait the very low energy of cost to make with the rubbish electricity, thereby effectively reduces the user cost of motor.
In the present invention, after the described cryogenic substance performance cooling action in described low temperature cold source, both can import in described working medium passage, as the cycle fluid of described three class door hot-air engines, also can not import in described working medium passage.
In the present invention, described four class door cylinder piston mechanisms refer to that cylinder is provided with suction port, relief opening, air supply opening and recharges mouth, described suction port, described relief opening, described air supply opening and described recharge mouthful place corresponding successively intake valve, exhaust valve are set, for valve with recharge the cylinder piston mechanism of door.
In the present invention, the setting of so-called two cylinder piston mechanism α types refers to the set-up mode of two cylinder piston mechanisms in α type Stirling engine, and the setting of so-called two cylinder piston mechanism β types refers to the set-up mode of two cylinder piston mechanisms in β type Stirling engine.
In the present invention, the so-called regenerator of establishing on described reciprocal communicating passage comprises that described regenerator is arranged on the structure in described reciprocal communicating passage.
In the present invention, it may be that the compression ignite mode may be also ignition combustion mode that fuel burns in described firing chamber, if adopt the mode of ignition, also need to set up an office fiery device, for example spark plug on described cylinder piston mechanism.
in the present invention, working medium in described working medium passage need to be through overcompression, heat temperature raising boosts, acting and the process that is cooled, this just requires described working medium passage capable of being bearing certain pressure, optionally, the bearing capacity of described working medium passage can be made as greater than 2MPa, 2.5MPa, 3MPa, 3.5MPa, 4MPa, 4.5MPa, 5MPa, 5.5MPa, 6MPa, 6.5MPa, 7MPa, 7.5MPa, 8MPa, 8.5MPa, 9MPa, 9.5MPa, 10MPa, 10.5MPa, 11MPa, 11.5MPa, 12MPa, 12.5MPa, 13MPa, 13.5MPa, 14MPa, 14.5MPa, 15MPa, 15.5MPa, 16MPa, 16.5MPa, 17MPa, 17.5MPa, 18MPa, 18.5MPa, 19MPa, 19.5MPa, 20MPa, 20.5MPa, 21MPa, 22MPa, 23MPa, 24MPa, 25MPa, 26MPa, 27MPa, 28MPa, 29MPa, 30MPa, 31MPa, 32MPa, 33MPa, 34MPa, 35MPa, 36MPa, 37MPa, 38MPa, 39MPa or greater than 40MPa.
In the present invention, power pressure and its bearing capacity in described working medium passage are complementary, and namely the maximum pressure of the working medium of described working medium passage reaches its bearing capacity.
In the present invention, so-calledly coaxially refer to described cylinder piston mechanism and be connected attached cylinder piston mechanism and all be connected with the same rod journal of same bent axle, the axis of two cylinders is made as V-type; Or referring to that two cylinders are connected with two rod journals of same bent axle out of phase, the axis angle of two cylinders is less than 90 degree.
The inventor proposes the new elaboration mode of out-of-phase diagram as described below and the second law of thermodynamics:
Pressure and temperature is the most basic, the most important status parameter of working medium.Yet, in thermodynamic study up to now, do not have the out-of-phase diagram take pressure P and temperature T as coordinate is used for research to thermodynamic process and thermodynamic cycle.In more than 200 year since thermomechanics is born, the inventor proposes the thought with out-of-phase diagram research thermodynamic process and thermodynamic cycle for the first time.In utilizing out-of-phase diagram research thermodynamic process and thermodynamic cycle, the inventor finds that out-of-phase diagram all has obvious advantage than P-V figure commonly used and T-S figure, it more constitutionally the variation of working medium state in thermodynamic process and thermodynamic cycle is described, make the inventor to thermodynamic process and thermodynamic cycle, more deep understanding be arranged.Utilize out-of-phase diagram, the inventor has summed up the new elaboration mode of ten second laws of thermodynamics, although it is of equal value that these new elaboration modes and Kelvin in the past and Clausius's thermomechanics is set forth mode, but clearer and more definite announcement to the difference of heating process and the compression process of working medium, also indicated direction for the exploitation of high efficiency thermal machine.This new method and new law will promote the progress of thermodynamic (al) development and heat engine industry greatly.Specific as follows:
P-V figure and T-S figure are widely used in thermodynamic study already, yet in view of P, T are the most important status parameters of working medium, so the inventor has drawn out-of-phase diagram take pressure P and temperature T as coordinate, and Carnot Cycle and Otto Cycle are identified in out-of-phase diagram shown in Figure 14.Clearly, out-of-phase diagram makes the variation of working medium state in thermodynamic process and thermodynamic cycle more apparent, and the essence of thermodynamic process and thermodynamic cycle is more readily understood.For example: the out-of-phase diagram of Carnot Cycle shown in Figure 14, can make the inventor easily draw such conclusion: the mission of the reversible adiabatic compression process of Carnot Cycle is that the mode with reversible adiabatic compression is increased to the temperature of working medium the temperature of its high temperature heat source, under the prerequisite that is consistent with the temperature that realizes with high temperature heat source from high temperature heat source constant temperature heat absorption inflation process.In addition, the inventor can also find out significantly: when the temperature of the high temperature heat source of Carnot Cycle raises, the inventor must be with more plus depth ground compression of working medium in the reversible adiabatic compression process of Carnot Cycle, make it reach higher temperature, to reach the temperature of the high temperature heat source after intensification, with realize with heat up after the prerequisite that is consistent of the temperature of high temperature heat source under high temperature heat source constant temperature heat absorption inflation process after heating up, thereby the raising of implementation efficiency.
According to adiabatic process equation
Figure BDA00002781664500071
(wherein, C is constant, and k is the adiabatic index of working medium), the inventor with the Drawing of Curve of adiabatic process equation of different C values in Figure 15.According to mathematical analysis, and as shown in figure 15, any two adiabatic process curves are all non-intersect.This means: the process on same adiabatic process curve is adiabatic process, and with the process of any adiabatic process curve intersection be diabatic process, in other words, the process of two different adiabatic process curves of any connection is diabatic process (so-called diabatic process refers to have the process that heat transmits, the i.e. process of heat release and the process of heat absorption).In Figure 16, the inventor has marked two state points, namely puts A and puts B.If a thermal procession or a series of interconnective thermal procession are from an A point of arrival B, the inventor is referred to as the process of tie point A and some B, otherwise the inventor is referred to as the process of tie point B and some A.According to shown in Figure 16, the inventor can draw such conclusion: on adiabatic process curve at some A place, the process of tie point A and some B is adiabatic process as a B; As the right side of a B at adiabatic process curve at some A place, the process of tie point A and some B is endothermic process; As the left side of a B at adiabatic process curve at some A place, the process of tie point A and some B is exothermic process.Because the process of tie point A and some B may be exothermic process, adiabatic process or endothermic process, thus the inventor take a B as reference, will put A be defined as respectively have superfluous temperature, ideal temperature and not enough temperature.In like manner, the process of tie point B and some A may be exothermic process, adiabatic process or endothermic process, thus the inventor take an A as reference, will put B be defined as respectively have superfluous temperature, ideal temperature and not enough temperature.
By these analyses and definition, the inventor draws following ten about the new elaboration mode of the second law of thermodynamics:
1, there is no the participation of endothermic process, exothermic process can not be returned to its initial point.
2, there is no the participation of exothermic process, endothermic process can not be returned to its initial point.
3, there is no the participation of diabatic process, diabatic process can not be returned to its initial point.
4, only use adiabatic process, diabatic process can not be returned to its initial point.
When 5, making the pressure of endothermic process return to the pressure of its initial point with the thermal procession beyond exothermic process, its temperature is necessarily higher than the temperature of its initial point.
When 6, making the pressure of exothermic process return to the pressure of its initial point with the thermal procession beyond endothermic process, its temperature is necessarily lower than the temperature of its initial point.
7, endothermic process can produce superfluous temperature.
8, exothermic process can produce not enough temperature.
9, any in compression process the efficient of the heat engine of not heat release can not reach the efficient of Carnot's cycle.
10, be to the heating process of working medium with to the difference of the compression process of working medium: heating process necessarily produces superfluous temperature, and compression process is quite different.
About ten of the second law of thermodynamics new elaboration modes, be of equal value, also can be through mathematical proof, any one in these ten elaboration modes all can be used separately.Inventor's suggestion: in the thermodynamic study process, answer extensive use out-of-phase diagram and above-mentioned new elaboration mode about the second law of thermodynamics.Out-of-phase diagram and the exploitation to thermodynamic (al) progress and high efficiency thermal machine is significant about the new elaboration mode of the second law of thermodynamics.
The English expression of the new elaboration mode of the second law of thermodynamics:
1.It?is?impossible?to?return?a?heat?rejection?process?to?its?initial?state?without?a?heat?injection?process?involved.
2.It?is?impossible?to?return?a?heat?injection?process?to?its?initial?state?without?a?heat?rejection?process?involved.
3.It?is?impossible?to?return?a?non-adiabatic?process?to?its?initial?state?without?a?non-adiabatic?process?involved.
4.It?is?impossible?to?return?a?non-adiabatic?process?to?its?initial?state?only?by?adiabatic?process.
5.If?the?final?pressure?of?heat?injection?process?is?returned?to?its?initial?pressure?by?process?other?than?heat?rejection?process,the?temperature?of?that?state?is?higher?than?that?of?the?initial?state.
6.If?the?final?pressure?of?heat?rejection?process?is?returned?to?its?initial?pressure?by?process?other?than?heat?injection?process,the?temperature?ofthat?state?is?lower?than?that?ofthe?initial?state.
7.It?is?impossible?to?make?heat?injection?process?not?generate?excess-temperature.
8.It?is?impossible?to?make?heat?rejection?process?not?generate?insufficient-temperature.
9.It?is?impossible?for?any?device?that?operates?on?a?cycle?to?reach?the?efficiency?indicated?by?Carnot?cycle?without?heat?rejection?in?compression?process.
10.The?difference?between?heat?injection?process?and?compression?process?which?are?applied?to?working?fluid?of?thermodynamic?process?or?cycle?is?that?heat?injection?process?must?generate?excess-temperature,but?compression?process?must?not.
In the present invention, should according to the known technology in motor, heat engine and heat power field, necessary parts, unit or system be set in the place of necessity.
Beneficial effect of the present invention is as follows: three class door hot-air engines of the present invention utilize working medium after one combustion explosion acting as the high-temperature gas working medium of heat engine, carry out the heat engine circulation under the cooperation of described cylinder piston mechanism and described attached cylinder piston mechanism, realized the further utilization to heat in the working medium after once doing work, thereby make the thermal efficiency of motor be improved, be conducive to energy saving, and simple in structure, practical, have broad application prospects.
Description of drawings
Shown in Figure 1 is the structural representation of the embodiment of the present invention 1;
Shown in Figure 2 is the structural representation of the embodiment of the present invention 2;
Shown in Figure 3 is the structural representation of the embodiment of the present invention 3;
Shown in Figure 4 is the structural representation of the embodiment of the present invention 4;
Shown in Figure 5 is the structural representation of the embodiment of the present invention 5;
Shown in Figure 6 is the structural representation of the embodiment of the present invention 6;
Shown in Figure 7 is the structural representation of the embodiment of the present invention 7;
Shown in Figure 8 is the structural representation of the embodiment of the present invention 8;
Shown in Figure 9 is the structural representation of the embodiment of the present invention 9;
Shown in Figure 10 is the structural representation of the embodiment of the present invention 10;
Shown in Figure 11 is the structural representation of the embodiment of the present invention 11;
Shown in Figure 12 is the structural representation of the embodiment of the present invention 12;
Shown in Figure 13 is the structural representation of opposed cylinder piston mechanism of the present invention;
Shown in Figure 14 is the out-of-phase diagram of Carnot's cycle and Alto circulation, wherein, and C 0, C 1And C 2Be the constant of different numerical value, k is adiabatic index, and circulation 0-1-2-3-0 is Carnot's cycle, and circulation 0-1-4-5-0 is the Carnot's cycle after the high temperature heat source temperature raises, and circulation 0-6-7-8-0 is the Alto circulation;
Shown in Figure 15 is the out-of-phase diagram of many different adiabatic process curves, wherein, and C 1, C 2, C 3, C 4And C 5Be the constant of different numerical value, k is adiabatic index, and A and B are state points;
Shown in Figure 16 is the out-of-phase diagram of adiabatic process curve, and wherein, C is constant, and k is adiabatic index, and A and B are state points;
In figure:
1 cylinder piston mechanism, 11 suction ports, 110 intake valves, 12 reversing current ports, 120 reciprocal circulation control gates, 21 impeller gas compressors, 22 turbo-power mechanisms, 25 coolers, 26 attached coolers, 3 attached cylinder piston mechanisms, 31 attached reversing current ports, 33 attached suction ports, 34 relief openings, 310 attached reciprocal circulation control gates, 32 weary gas exhaust ports, 320 weary valves, 4 regenerators, 5 firing chambers, 23 working medium export mouths, 8 low temperature cold sources, 96 hydraulic power mechanisms, 97 liquid send-back systems, 99 process control mechanisms, 100 reciprocal communicating passage, 111 gas-liquid cylinders, 112 gas-liquid interrupters, 113 liquid communication mouths, 200 4 class door cylinder piston mechanisms, 201 suction ports of calming the anger, 202 attached relief openings, 203 air supply openings, 204 recharge mouth.
Embodiment
Embodiment 1
Three class door hot-air engines as shown in Figure 1, comprise cylinder piston mechanism 1 and attached cylinder piston mechanism 3, the cylinder of described cylinder piston mechanism 1 is provided with suction port 11 and reversing current port 12, described suction port 11 places are provided with corresponding intake valve 110, described reversing current port 12 places are provided with corresponding reciprocal circulation control gate 120, and are provided with firing chamber 5 in the cylinder of described cylinder piston mechanism 1; The cylinder of described attached cylinder piston mechanism 3 is provided with attached reversing current port 31 and weary gas exhaust port 32, and described weary gas exhaust port 32 places are provided with corresponding weary valve 320; Described reversing current port 12 is communicated with described attached reversing current port 31 through reciprocal communicating passage 100.
Described weary valve 320 on the cylinder of the described intake valve 110 on the cylinder of described cylinder piston mechanism 1, described reciprocal circulation control gate 120 and described attached cylinder piston mechanism 3, controlled by the control mechanism of motor of the present invention, make described cylinder piston mechanism 1 according to suction stroke-compression stroke-combustion explosion expansion stroke-air feed stroke-recharge six-stroke circulation mode work of stroke-air feed stroke.Requirement according to above-mentioned work cycle, the control mechanism of selecting to be fit to is controlled the piston movement in cylinder piston mechanism described in the present invention 1 and described attached cylinder piston mechanism 3, makes described attached cylinder piston mechanism 3 according to the circulation mode work corresponding with described cylinder piston mechanism 1.Air feed stroke in the six-stroke circulation mode of described cylinder piston mechanism 1-recharge stroke is corresponding to recharging stroke-air feed stroke in the work cycle of described attached cylinder piston mechanism 3, these two described working strokes consist of the heat engine circulation mode, make the described reciprocal communicating passage 100 interior reversing current of working medium between described cylinder piston mechanism 1 and described attached cylinder piston mechanism 3 pass to few once, the weary gas exhaust port from the cylinder of described attached cylinder piston mechanism 3 is discharged at last.
Can embed as required a plurality of heat engine circulations in the work cycle of described cylinder piston mechanism 1 and described attached cylinder piston mechanism 3.
The fuel that the combustion chemistry reaction occurs in described firing chamber 5 can be hydrocarbon, hydrocarbon oxygen compound or solid carbon, wherein, solid carbon optionally adopt spray into after solid assembled in advance, powdered or powdered after input described firing chamber 5 with the mode that sprays into after liquid or atmospheric carbon dioxide fluidisation again.
Embodiment 2
Three class door hot-air engines as shown in Figure 2, itself and embodiment's 1 difference is: described attached cylinder piston mechanism 3 is provided with cooler 25.
Described weary valve 320 on the cylinder of the described intake valve 110 on the cylinder of described cylinder piston mechanism 1, described reciprocal circulation control gate 120 and described attached cylinder piston mechanism 3, controlled by the control mechanism of motor of the present invention, make described cylinder piston mechanism 1 according to suction stroke-compression stroke-combustion explosion expansion stroke-air feed stroke-recharge stroke-air feed stroke-recharge eight stroke cycle work patterns of stroke-air feed stroke.Requirement according to above-mentioned work cycle, the control mechanism of selecting to be fit to is controlled the piston movement in cylinder piston mechanism described in the present invention 1 and described attached cylinder piston mechanism 3, makes described attached cylinder piston mechanism 3 according to the circulation mode work corresponding with described cylinder piston mechanism 1.
Optionally, described cooler 25 can also be located on described reciprocal communicating passage 100.
Embodiment 3
Three class door hot-air engines as shown in Figure 3, its difference with embodiment 2 is: described attached reversing current port 31 places are provided with corresponding attached reciprocal circulation control gate 310, and the described reciprocal communicating passage 100 between described reversing current port 12 and described attached reversing current port 31 is provided with regenerator 4.Described cooler 25 changes on the described reciprocal communicating passage 100 that is located between described regenerator 4 and described attached reversing current port 31.
Embodiment 4
Three class door hot-air engines as shown in Figure 4, itself and embodiment's 2 difference is: the communicating passage between described reversing current port 12 and described attached reversing current port 31 is provided with regenerator 4, is being equipped with cooler 25 on described attached cylinder piston mechanism 3 and on the passage between described regenerator 4 and described attached reversing current port 31.
Embodiment 5
Three class door hot-air engines as shown in Figure 5, itself and embodiment's 2 difference is: this motor also includes impeller gas compressor 21 and turbo-power mechanism 22, described weary gas exhaust port 32 is communicated with the working medium entrance of described turbo-power mechanism 22, and described suction port 11 is communicated with the sender property outlet of described impeller gas compressor 21.Communicating passage between described reversing current port 12 and described attached reversing current port 31 is provided with regenerator 4.
Preferably, 22 pairs of described impeller gas compressor 21 outputting powers of described turbo-power mechanism.
Embodiment 6
Three class door hot-air engines as shown in Figure 6, itself and embodiment's 4 difference is: reduced the cooler 25 on the cylinder that is located at described attached cylinder piston mechanism 3; Described cylinder piston mechanism 1 and described attached cylinder piston mechanism 3 are coaxial setting, and for V-type is arranged, the piston of the piston of described cylinder piston mechanism 1 and described attached cylinder piston mechanism 3 is rotationally connected through the same rod journal of connecting rod and bent axle, and phase difference is 90 degree; Described cylinder piston mechanism 1 arranges for the α type with described attached cylinder piston mechanism 3.
Optionally, described in actual use cylinder piston mechanism 1 can arrange for the β type with described attached cylinder piston mechanism 3.
Embodiment 7
Three class door hot-air engines as shown in Figure 7, its difference with embodiment 2 is: described attached reversing current port 31 places are provided with corresponding attached reciprocal circulation control gate 310; In addition, the cylinder of described attached cylinder piston mechanism 3 is provided with attached suction port 33 and relief opening 34, and described relief opening 34 is communicated with described suction port 11; Described attached suction port 33 places are provided with corresponding attached intake valve, and described relief opening 34 places are provided with corresponding exhaust valve.Described reciprocal communicating passage 100 between described reversing current port 12 and described attached reversing current port 31 is provided with regenerator 4.
Described attached cylinder piston mechanism 3 can be air-breathing by described attached suction port 33, the firing chamber 5 internal combustion blast actings of described cylinder piston mechanism 1 are delivered in compression by described relief opening 34 and described suction port 11, described attached cylinder piston mechanism 3 can strengthen the gettering ability of the suction stroke of described cylinder piston mechanism 1.
Embodiment 8
Three class door hot-air engines as shown in Figure 8, itself and embodiment's 3 difference is: described cylinder piston mechanism 1 is provided with two, being equipped with the described attached reversing current port 31 that described reversing current port 12 on the cylinder of 5, two the described cylinder piston mechanisms 1 in firing chamber respectively hangs oneself on the cylinder of described regenerator 4 and described attached cylinder piston mechanism 3 in two described cylinder piston mechanisms 1 is communicated with; Described reversing current port 12 places are provided with corresponding reciprocal circulation control gate 120, and described attached reversing current port 31 places are provided with corresponding attached reciprocal circulation control gate 310; Described cooler 25 is arranged on the cylinder of described attached cylinder piston mechanism 3.
Selectively, can similarly increase as required the quantity of described cylinder piston mechanism 1, for example the described reversing current port 12 on the cylinder of three described cylinder piston mechanisms 1 respectively the described attached reversing current port 31 on the cylinder of described regenerator 4 and a described attached cylinder piston mechanism 3 be communicated with.
Embodiment 9
three class door hot-air engines as shown in Figure 9, itself and embodiment's 2 difference is: described three class door hot-air engines also comprise turbo-power mechanism 22 and impeller gas compressor 21, described weary gas exhaust port 32 is communicated with the working medium entrance of described turbo-power mechanism 22, the sender property outlet of described turbo-power mechanism 22 is communicated with the working medium entrance of described impeller gas compressor 21 through cooler 3, the sender property outlet of described impeller gas compressor 21 is through control valve and described working medium channel connection, specifically with described reversing current port 12 and described attached reversing current port 31 between communicating passage be communicated with, passage between the sender property outlet of described turbo-power mechanism 22 and the working medium entrance of described impeller gas compressor 21 is provided with attached cooler 26, and the passage between the working medium entrance of described attached cooler 26 and described impeller gas compressor 21 is provided with working medium export mouth 23.
Optionally, described working medium export mouth 23 also can be located on the sender property outlet and the passage between described attached cooler 26 of described turbo-power mechanism 22.The sender property outlet of described impeller gas compressor 21 is communicated with connecting port on being located at described working medium passage, this connecting port does not overlap with described weary gas exhaust port 32, can be located at the diverse location on described working medium passage, as described on the cylinder of cylinder piston mechanism 1, on the cylinder of described cylinder piston mechanism 3, described reciprocal communicating passage 100 is first-class.
Embodiment 10
three class door hot-air engines as shown in figure 10, itself and embodiment's 3 difference is: described cylinder piston mechanism 1 is made as piston liquid mechanism, described piston liquid mechanism comprises gas-liquid cylinder 111 and gas-liquid interrupter 112, described gas-liquid isolating structure 112 is located in described gas-liquid cylinder 111, the liquid communication mouth 113 of the liquid end of described gas-liquid cylinder 111 is communicated with the working medium entrance of hydraulic power mechanism 96, the sender property outlet of described hydraulic power mechanism 96 is communicated with the working medium entrance of liquid send-back system 97, the sender property outlet of described liquid send-back system 97 is communicated with another described liquid communication mouth 113 of the liquid end of described gas-liquid cylinder 111, described hydraulic power mechanism 96 and described liquid send-back system 97 are controlled by process control mechanism 99.
Inertial force sum when the gas working medium in described gas-liquid cylinder 111 moves reciprocatingly greater than the liquid in described gas-liquid cylinder 111 and described gas-liquid isolating structure 112 to the pressure of described gas-liquid isolating structure 112.
Optionally, described gas-liquid isolating structure 112 can be made as platy structure, membrane structure or piston-like structure etc.Preferably, described gas-liquid isolating structure 112 and described gas-liquid cylinder 111 sealed sliding are movingly.But two described liquid communication mouth 113 integrated setting.
In the present embodiment, described piston liquid mechanism can control the motion of described gas-liquid isolating structure 112 and liquid (being equivalent to the piston in traditional cylinder piston mechanism) effectively, is convenient to realize work cycle of the presently claimed invention.
Embodiment 11
Three class door hot-air engines as shown in figure 11, itself and embodiment's 6 difference is: described three class door hot-air engines also comprise low temperature cold source 8, described low temperature cold source 8 is the storage tanks that store liquid nitrogen, and the liquid nitrogen in storage tank is used for the working medium of cooling described attached cylinder piston mechanism 3.
In the present embodiment, described low temperature cold source 8 directly is communicated with the cylinder of described attached cylinder piston mechanism 3, is provided with control valve on the communicating passage between the cylinder of described low temperature cold source 8 and described attached cylinder piston mechanism 3.
Selectively, the working medium heat exchange that described low temperature cold source 8 can also be in heat-exchanger rig makes described cryogenic substance and described working medium passage; After described cryogenic substance performance cooling action in described low temperature cold source 8, both can import in described working medium passage, as the cycle fluid of three class door hot-air engines, also can not import in described working medium passage.
Embodiment 12
Three class door hot-air engines as shown in figure 12, itself and embodiment's 4 difference is: described three class door hot-air engines also comprise four class door cylinder piston mechanisms 200, suction port on the cylinder of described four class door cylinder piston mechanisms 200 is made as the suction port 201 of calming the anger, relief opening on the cylinder of described four class door cylinder piston mechanisms 200 is made as attached relief opening 202, the air supply opening 203 of described four class door cylinder piston mechanisms 200 is communicated with described suction port 11, and the mouth 204 that recharges of described four class door cylinder piston mechanisms 200 is communicated with described weary gas exhaust port 32.The described suction port 201 of calming the anger, described attached relief opening 202, described air supply opening 203 and described recharge mouthful 204 places successively correspondence intake valve, exhaust valve are set, for valve with recharge door.
In the present embodiment, the working medium that enters in the cylinder of described cylinder piston mechanism 1 is first interior compressed at described four class door cylinder piston mechanisms 200; The weary gas of discharging from described weary gas exhaust port 32 enters described four class door cylinder piston mechanism 200 interior actings again, and then discharges through described attached relief opening 202.
Described cylinder piston mechanism 1 in above-described embodiment is or/and described attached cylinder piston mechanism 3 all can adopt opposed pistons cylinder mechanism as shown in figure 13 to replace.
Selectively, the described attached cylinder piston mechanism 3 in above embodiment also can be made as described piston liquid mechanism.
In above embodiment, the mass flow rate of the material that discharge described firing chamber 5 is greater than import the mass flow rate of the material of described firing chamber 5 outside described working medium passage.
Obviously, the invention is not restricted to above embodiment, according to known technology and the technological scheme disclosed in this invention of related domain, can derive or association goes out many flexible programs, all these flexible programs also should be thought protection scope of the present invention.

Claims (10)

1. class door hot-air engine, comprise cylinder piston mechanism (1), the cylinder of described cylinder piston mechanism (1) is provided with suction port (11) and reversing current port (12), described suction port (11) locates to be provided with corresponding intake valve (110), described reversing current port (12) locates to be provided with corresponding reciprocal circulation control gate (120), it is characterized in that: described three class door hot-air engines also comprise attached cylinder piston mechanism (3), establish attached reversing current port (31) and weary gas exhaust port (32) on the cylinder of described attached cylinder piston mechanism (3), locate to establish corresponding weary valve (320) at described weary gas exhaust port (32), described reversing current port (12) is communicated with described attached reversing current port (31) through reciprocal communicating passage (100), be provided with firing chamber (5) in the cylinder of described cylinder piston mechanism (1).
2. three class door hot-air engines as claimed in claim 1, is characterized in that: be provided with cooler (25) on described reciprocal communicating passage and/or on the cylinder of described attached cylinder piston mechanism (3).
3. three class door hot-air engines as claimed in claim 1, is characterized in that: establish regenerator (4) on described reciprocal communicating passage (100).
4. three class door hot-air engines as claimed in claim 3 is characterized in that: the described reciprocal communicating passage (100) between described regenerator (4) and described attached reversing current port (31) is upper and/or be provided with cooler (25) on the cylinder of described cylinder piston mechanism (3).
5. as three class door hot-air engines as described in any one in claim 1 to 4, it is characterized in that: locate to establish corresponding attached reciprocal circulation control gate (310) at described attached reversing current port (31).
6. as three class door hot-air engines as described in any one in claim 1 to 4, it is characterized in that: described intake valve (110) and described reciprocal circulation control gate (120) are made described cylinder piston mechanism (1) control according to the control mechanism of suction stroke-compression stroke-combustion explosion expansion stroke-air feed stroke-recharge circulation mode work of stroke-air feed stroke.
7. as three class door hot-air engines as described in any one in claim 1 to 4, it is characterized in that: described intake valve (110), described reciprocal circulation control gate (120) and described weary valve (320) are made described cylinder piston mechanism (1) control according to the control mechanism of suction stroke-compression stroke-combustion explosion expansion stroke-air feed stroke-recharge stroke-air feed stroke-recharge circulation mode work of stroke-air feed stroke.
8. as three class door hot-air engines as described in any one in claim 1 to 4, it is characterized in that: described three class door hot-air engines also comprise turbo-power mechanism (22) and impeller gas compressor (21), described weary gas exhaust port (32) is communicated with the gas access of described turbo-power mechanism (22), and described suction port (11) is communicated with the gas outlet of described impeller gas compressor (21).
9. three class door hot-air engines as claimed in claim 8, it is characterized in that: described turbo-power mechanism (22) is to described impeller gas compressor (21) outputting power.
10. as three class door hot-air engines as described in any one in claim 1 to 4, it is characterized in that: establish attached suction port (33) and relief opening (34) on the cylinder of described attached cylinder piston mechanism (3), described relief opening (34) is communicated with described suction port (11); Locate to establish corresponding attached intake valve at described attached suction port (33), locate to establish corresponding exhaust valve at described relief opening (34).
CN2013100300209A 2012-01-29 2013-01-28 Three-type-gate hot air engine Pending CN103104372A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN2013100300209A CN103104372A (en) 2012-01-29 2013-01-28 Three-type-gate hot air engine

Applications Claiming Priority (19)

Application Number Priority Date Filing Date Title
CN201210020454 2012-01-29
CN201210020454.6 2012-01-29
CN201210021914 2012-01-31
CN201210021914.7 2012-01-31
CN201210037353.X 2012-02-17
CN201210037353 2012-02-17
CN201210134753 2012-04-28
CN201210134753.2 2012-04-28
CN201210204806 2012-06-16
CN201210204806.3 2012-06-16
CN201210211996.1 2012-06-22
CN201210211996 2012-06-22
CN201210217812 2012-06-27
CN201210217812.2 2012-06-27
CN201210232716.5 2012-07-05
CN201210232716 2012-07-05
CN201210299879 2012-08-21
CN201210299879.5 2012-08-21
CN2013100300209A CN103104372A (en) 2012-01-29 2013-01-28 Three-type-gate hot air engine

Publications (1)

Publication Number Publication Date
CN103104372A true CN103104372A (en) 2013-05-15

Family

ID=48312511

Family Applications (1)

Application Number Title Priority Date Filing Date
CN2013100300209A Pending CN103104372A (en) 2012-01-29 2013-01-28 Three-type-gate hot air engine

Country Status (1)

Country Link
CN (1) CN103104372A (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104295403A (en) * 2014-08-15 2015-01-21 宁波高新区金杉新能源科技有限公司 Medium energy engine device and acting mode thereof

Citations (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4055951A (en) * 1976-08-16 1977-11-01 D-Cycle Associates Condensing vapor heat engine with two-phase compression and constant volume superheating
US4276858A (en) * 1979-02-26 1981-07-07 Ateliers De La Motobecane Two-cycle internal combustion engine
SU1320475A1 (en) * 1984-01-26 1987-06-30 И. Г. Бурдейный, В. И. Бурдейный, А. И. Бурдейный и В. Л. Букшань Internal-combustion engine and method of its operation
RU2056510C1 (en) * 1993-02-01 1996-03-20 Юрий Михайлович Болычевский Method of operation of two-stroke internal combustion engine
US7389755B2 (en) * 2005-07-21 2008-06-24 Ronald Dean Noland Tandem-piston engine
CN101680354A (en) * 2007-08-07 2010-03-24 史古德利集团有限责任公司 Split-cycle engine with early crossover compression valve opening
CN201560839U (en) * 2009-08-25 2010-08-25 刘贺青 Internal combustion stirling engine
US20110023817A1 (en) * 2005-11-22 2011-02-03 Lung-Tan Hu Variable-coordination-timing type self-cooling engine with variable-profile-camshaft

Patent Citations (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4055951A (en) * 1976-08-16 1977-11-01 D-Cycle Associates Condensing vapor heat engine with two-phase compression and constant volume superheating
US4276858A (en) * 1979-02-26 1981-07-07 Ateliers De La Motobecane Two-cycle internal combustion engine
SU1320475A1 (en) * 1984-01-26 1987-06-30 И. Г. Бурдейный, В. И. Бурдейный, А. И. Бурдейный и В. Л. Букшань Internal-combustion engine and method of its operation
RU2056510C1 (en) * 1993-02-01 1996-03-20 Юрий Михайлович Болычевский Method of operation of two-stroke internal combustion engine
US7389755B2 (en) * 2005-07-21 2008-06-24 Ronald Dean Noland Tandem-piston engine
US20110023817A1 (en) * 2005-11-22 2011-02-03 Lung-Tan Hu Variable-coordination-timing type self-cooling engine with variable-profile-camshaft
CN101680354A (en) * 2007-08-07 2010-03-24 史古德利集团有限责任公司 Split-cycle engine with early crossover compression valve opening
CN201560839U (en) * 2009-08-25 2010-08-25 刘贺青 Internal combustion stirling engine

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104295403A (en) * 2014-08-15 2015-01-21 宁波高新区金杉新能源科技有限公司 Medium energy engine device and acting mode thereof

Similar Documents

Publication Publication Date Title
CN103133178B (en) Twin channel entropy cycle engine
CN202811059U (en) Piston type composite thermal power system
CN202745999U (en) High-pressure inflation and explosion discharging engine
CN103089486A (en) Three-valve hot-air engine
CN103122805A (en) Three-cylinder hot-air engine
CN103195607A (en) Heat source working hot air engine
CN103104374B (en) Cylinder internal combustion Stirling engine
CN202811060U (en) Gated, cylinder-shared and U-shaped flow piston thermal power system
CN103089484A (en) Hot-air engine with three types of doors
CN103104372A (en) Three-type-gate hot air engine
CN103216358A (en) Hot cylinder door control Stirling engine
CN103089485A (en) Three-valve hot-air engine
CN103206316A (en) Working unit thermomotor
CN103089482B (en) Air injection unit heat engine
CN103104370B (en) Single-cylinder three-valve entropy circulation engine
CN202746009U (en) Non-collision free piston explosive exhaust engine
CN103114939B (en) Air cylinder phase cycle engine
CN103133177B (en) Reciprocating channel entropy circulating engine
CN103195606B (en) Acting unit heat engine
CN105240154A (en) Reciprocating channel entropy circulating engine
CN103104371A (en) Three-type-gate hot air engine
CN103104375B (en) Cylinder internal combustion Stirling engine
CN103147878A (en) Phase cycling engine for hot cylinder
WO2013078775A1 (en) Dual-conduit entropy-cycle engine
CN107882627A (en) Valve control common cylinder U flow piston thermal power system, method

Legal Events

Date Code Title Description
C06 Publication
PB01 Publication
C10 Entry into substantive examination
SE01 Entry into force of request for substantive examination
C02 Deemed withdrawal of patent application after publication (patent law 2001)
WD01 Invention patent application deemed withdrawn after publication

Application publication date: 20130515