Classifications

• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
  • F01L—CYCLICALLY OPERATING VALVES FOR MACHINES OR ENGINES
  • F01L1/00—Valve-gear or valve arrangements, e.g. lift-valve gear
  • F01L1/34—Valve-gear or valve arrangements, e.g. lift-valve gear characterised by the provision of means for changing the timing of the valves without changing the duration of opening and without affecting the magnitude of the valve lift
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
  • F02B—INTERNAL-COMBUSTION PISTON ENGINES; COMBUSTION ENGINES IN GENERAL
  • F02B27/00—Use of kinetic or wave energy of charge in induction systems, or of combustion residues in exhaust systems, for improving quantity of charge or for increasing removal of combustion residues
  • F02B27/04—Use of kinetic or wave energy of charge in induction systems, or of combustion residues in exhaust systems, for improving quantity of charge or for increasing removal of combustion residues in exhaust systems only, e.g. for sucking-off combustion gases
  • F02B27/06—Use of kinetic or wave energy of charge in induction systems, or of combustion residues in exhaust systems, for improving quantity of charge or for increasing removal of combustion residues in exhaust systems only, e.g. for sucking-off combustion gases the systems having variable, i.e. adjustable, cross-sectional areas, chambers of variable volume, or like variable means
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
  • F02B—INTERNAL-COMBUSTION PISTON ENGINES; COMBUSTION ENGINES IN GENERAL
  • F02B29/00—Engines characterised by provision for charging or scavenging not provided for in groups F02B25/00, F02B27/00 or F02B33/00 - F02B39/00; Details thereof
  • F02B29/08—Modifying distribution valve timing for charging purposes
  • F02B29/083—Cyclically operated valves disposed upstream of the cylinder intake valve, controlled by external means
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
  • F01L—CYCLICALLY OPERATING VALVES FOR MACHINES OR ENGINES
  • F01L15/00—Valve-gear or valve arrangements, e.g. with reciprocatory slide valves, other than provided for in groups F01L17/00 - F01L29/00
  • F01L15/14—Arrangements with several co-operating main valves, e.g. reciprocatory and rotary
• • Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
  • Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
  • Y02T—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
  • Y02T10/00—Road transport of goods or passengers
  • Y02T10/10—Internal combustion engine [ICE] based vehicles
  • Y02T10/12—Improving ICE efficiencies

Definitions

• This invention relates to an arrangement of a four-stroke multi-cylinder internal combustion engine. It relates particularly to valves in a cylinder head and to an embodiment of an intake and exhaust manifold, so that higher volumetric efficiency of the cylinder as well as higher overall efficiency of the combustion engine is reached, by means of the direct use of a part of energy of exhaust gas pressure waves in the exhaust manifold, ⁇ . ⁇ . : > ⁇ : ⁇ . ! ⁇ ⁇ . , ⁇ ⁇ ; - . ⁇ , : .. ⁇ i . ases i w n ⁇
• engine 'efficiency can e influenced by exhaust manifold, which uses flow momentum of exhaust gases in the manifold and enables, easier discharge of exhaust gases out of the cylinder. That leads to a decrease of the pumping work particularly during the exhaust stroke. That is an about direct using' of energy of exhaust gases for cylinder filling and for increase of efficiency of current engines. Direct use of energy of exhaUst gases by ' means of Comprex system is not as advantageous as a turbocharger. Supercharging by turbocharger is widely spread way of use of exhaust gas energy.
• That engine consists of cylinders with pistons, a cylinder head with lifting valves and a crankshaft mechanism.
• the essence of the engine is the fact that it is equipped with two cylinders that have mutually shifted four-stroke cycle and/or it is equipped with three cylinders that have mutually shifted four-stroke cycle.
• each cylinder head of each cylinder is at least one intake port, connected with at least one exhaust port and at least one lifting valve, while the intake port is equipped with at least one valve and an exhaust branch is connected to the exhaust port and simultaneously exhaust branches of both cylinders with mutually shifted 4-stroke cycle are farther joined in a joint, into one cross-section and/or exhaust branches of three cylinders with mutually shifted four-stroke cycle are farther joined in another joint into one cross-section.
• Lifting valves have both intake and exhaust function.
• a valve of the intake port is advantageously in the shape of a rotary valve and/or in the shape of a reed valve.
• the valve of the intake port can be equipped with electronic control.
• An intake manifold is advantageously connected to the intake port.
• This intake manifold is equipped with a centrifugal compressor and/or with a positive displacement compressor that is mechanically connected to the engine and/or equipped with an electric motor.
• turbocharger There can be placed a turbine of a turbocharger behind the joint of two exhaust branches and/or behind another joint of three exhaust branches and there is a compressor of the turbocharger in the intake manifold, while the exhaust outlet pipe joins outlet of the turbine of the turbocharger.
• the multi-cylinder internal combustion engine comprises more cooperating cylinder pairs with mutually shifted four-stroke cycle and with joints of exhaust branches and/or it comprises more cooperating cylinder trios with mutually shifted four-stroke cycle and with other joints of exhaust branches.
• the multi-cylinder internal combustion engine can consist of more, cooperating cylinder pairs with mutually shifted four-stroke cycle and with joints of exhaust branches and/or it can consist of more cooperating cylinder trios with mutually shifted four-stroke cycle and with other joints of exhaust branches, while joints and/or other joints are farther connected to separate sections of inlet housing of a turbine of a turbocharger.
• the lifting valve has a valve head in the annular shape in an advantageous embodiment.
• Four-stroke internal combustion engine according to the invention enables an improvement of engine performance parameters, decrease of its specific mass as well as decrease of its specific fuel consumption. That is achieved for two reasons. '
• the first important reason for an increase in engine parameters is direct use of a part of exhaust gas energy. That is enabled due to the engine arrangement-with interconnected intake and exhaust port in the cylinder: head and appropriate tuning of the whole system of a valve gear and engine manifold.
• the difference between operation of the multi-cylinder engine according to the invention and operation of a traditional four-stroke cycle is in intensive scavenging of the cylinder head at the end of the exhaust stroke, taking gas in during the intake stroke also in the exhaust branch besides the cylinder and subsequent refilling of the gas into the cylinder by means of pressure of exhaust gas. Described effect can be achieved only in such an engine with two or three cooperating cylinders of the engine.
• a part of energy of the exhaust pressure wave is used directly for compressing intake gas into the cylinder and so it is possible to reach significantly higher cylinder filling. That increases mean effective pressure of the engine as well as its efficiency.
• a naturally aspirated variant of the engine according to the invention in one configuration of valve timing and pipes geometry has excellent parameters in a relatively narrow range of engine speed. That does not have to be disadvantage in case of using this engine at a generator.
• the absence of a turbocharger and related turbo lag increasing time required for run-up till the full power can be an advantage in this case, in comparison with a traditional engine with similar performance and dimensions.
• Four-stroke combustion engine according to the invention in turbocharged version achieves characteristic Suitable 'for a commoh driving' cycle With
• the most advantageous is using a lifting valve with a valve head in the annular shape that ;, ha ⁇ . both intake, and exhaust function.
• his yal e enables . to achieve the .best flow parameters in intake direction into ⁇ cylinder, exhaust direction from cylinder as well as in direction of scavenging the cylinder , head.
• the use of shared lifting valves for intake and exhaust that are placed in the entire area of the cylinder head has further ' advantages.
• the cylinder head and , lifting' valves are significantly less thermally stressed due to the changing of intake and exhaust period. There will be no creation of .
• FIG. 1 schematically shows a multi-cylinder combustion engine with two cylinders with a four-stroke cycle that is mutually shifted about 360 ° .
• Figure 2 schematically shows a multi-cylinder internal combustion engine with two cylinders with a four-stroke cycle that is mutually shifted about 360 ° , similarly to the fig . 1 .
• the difference is that the intake port is equipped with a rotary valve and a reed valve and there is an exhaust valve in the shape of an exhaust rotary valve behind the joint of exhaust branches.
• Figure 3 schematically shows a multi-cylinder internal combustion engine with two cylinders with four-stroke cycle that is mutually shifted about 360°, similarly to the fig 1 .
• the difference is that the intake port is equipped with a reed valve and there is a centrifugal compressor in the intake port.
• Figure 4 schematically shows a multi-cylinder internal combustion engine with two cylinders, similarly the fig. 2. The difference is that there is a positive displacement compressor in the intake manifold. '
• Figure 5 schematically shows a multi-cylinder internal combustion engine with two cylinders, similar to the, fig. 3. The difference is that behind the joint of exhaust branches there is a turbine of. a turbocharger and a compressor of the turbocharger is situated in the intake manifold.
• Figure 6 schematically shows a multi-cylinder internal combustion engine with two cylinders with a cycle that is shifted about 360°. That engine is equipped with a turbocharger, similarly to the figure 5. The difference is that even a rotary valve is placed in the intake port besides the reed valve.
• Figure 7 schematically shows a multi-cylinder internal combustion engine with two cylinders with a four-stroke cycle that is mutually shifted about 360 ° , similarly to the figure 1 .
• An exhaust valve is additionally placed behind the joint of exhaust branches.
• Figure 8 graphically shows dependence of some parameters of a two-cylinder engine according to the fig. 7. All curves are dependent on crankshaft angle that is represented by x axis.
• Curves IA and IIA represent behaviour of a cross-sectional area of lifting valves.
• Curves Ip and Up represent behaviour of pressure in exhaust ports in a cylinder head.
• Curve B represents behaviour of a cross-sectional area of the exhaust valve.
• Figure 9 shows a multi-cylinder internal combustion engine according to the fig. 7 in crankshaft angle positions from 0 ° to 720° in 90 ° intervals. That demonstrates working of the engine during the entire cycle.
• Intake gas is represented by gray colour. Exhaust gases are not coloured.
• Figure 10 shows a multi-cylinder internal combustion engine with two cylinders with a cycle that is shifted about 360 ° , similarly to the fig. 7, in crankshaft angle positions from 0 ° to 720° in 90° intervals with the difference that in the exhaust manifold there is placed a rotary valve and a reed valve is used in the intake manifold.
• Intake gas is represented by gray colour. Exhaust gases are not coloured.
• Figure 1 schematically shows a multi-cylinder internal combustion engine with three cylinders with a cycle that is mutually shifted about 240 ° .
• Intake and exhaust ports in a cylinder head are interconnected and lifting valves are shared for both intake into the cylinder and exhaust out of the cylinder.
• There are cyclically working valves in intake ports and exhaust branches of the three cylinders are joined into one outlet pipe. r . . , . . .
• Figure 12 schematically shows a multi-cylinder internal combustion engine with three cylinders, similarly to the fig. 1 1 .
• a centrifugal blower is additionally placed in the intake manifold. ' . .
• Figure 13 schematically shows a multi-cylinder internal combustion engine with three cylinders, similarly to the fig. 1 1. The difference is that the engine is equipped with a turbocharger.
• Figure 14 schematically shows a multi-cylinder internal combustion engine with three cylinders with four-stroke cycle that is mutually shifted about 240° and a turbocharger, similarly to the fig. 13. The difference is that intake ports are equipped with reed valves and a positive displacement compressor is situated in the intake manifold.
• Figure 15 schematically shows a multi-cylinder internal combustion engine with three cylinders with four-stroke cycle that is shifted about 240°, similarly to the fig. 1 1. The difference is that there is a positive displacement compressor in ' 'the ' intake manifold and an exhaust valve is additionally placed behind the joint 1 ' of "exhaust branches.
• Figure 16 graphicafly shows dependency of sbme ' paiameters of ' a t o-cylirider engine according to the fig. ' 15. All curves are dependent on crankshaft angle that is represented by x axis. Curves ' IA, IIA and MIA represent behaviour of a cross-sectional cn ea of lifting valves. Curves Ip, lip and lllp represent behaviour of pressure in exhaust ports in the cylinder head. Curve B represents behaviour of cross-sectional area of the exhaust valve. , . . ; , : , ⁇ w , Figure 17 shows an internal combustion engine according' to 'the fig. e; 15 in crankshaft angle positions from 0° to 720 ° in 120 ° intervals. That .demonstrates the working of the engine during the entire cycle. Intake gas is represented by gray colour. Exhaust gases are not coloured.
• Figure 18 shows a multi-cylinder internal combustion engine with three cylinders with a cycle shifted about 240 ° , similarly to the fig . 7, in crankshaft ' angle positions from 0 ° to ' 720 ° in 120° intervals. The difference is that there is a reed valve in the intake port and the engine is not equipped with an exhaust valve. Intake gas is represented by gray colour. Exhaust gases are not coloured.
• Figure 19 shows a multi-cylinder internal combustion engine with four cylinders on condition that it consists of two pairs of cooperating cylinders. Two outlet pipes going from joints of exhaust branches are connected to separate sections of outlet of turbine housing of a shared turbocharger. .
• Figure 20 shows a cross-sectional view of the cylinder head that is perpendicular to the cylinder axis in the view direction into the cylinder. The figure shows a valve head of the lifting valve and the intake and exhaust port.
• Figure 21 shows a cross-sectional view of the cylinder head that is perpendicular to the cylinder axis in the view direction into the cylinder.
• the figure shows valve heads of two lifting valves and the intake arid exhaust port.
• Figure 22 shows a cross-section of the cylinder head that is perpendicular to the cylinder axis in the view direction into the cylinder.
• the figure shows valve heads of two lifting valves and the intake and exhaust port, .
• Figure 23 shows a cross-section of the cylinder head that is perpendicular to the cylinder axis in the view direction into the cylinder.
• the figure shows valve heads of four lifting valves and the intake and exhaust port.
• Figure 24 shows a cross-section of the cylinder head that is perpendicular to the cylinder axis in the view direction into the cylinder.
• the figure shows a centrally positioned lifting valve with a valve head in the annular shape and the intake and exhaust port.
• Figure 25 shows a cross-section of the cylinder head that is perpendicular to the cylinder axis in the view direction into the cylinder.
• the figure shows a centrally placed lifting valve with a valve head in the annular shape and an eccentric intake and exhaust port.
• the model multi-cylinder internal combustion engine supercharged by exhaust gases comprises two cylinders 1_0 with pistons 2, a cylinder head 1 with lifting valves 7 and . a crankshaft mechanism 3.
• Two cylinders 10 have a cycle that is mutually shifted about 1/2 of four-stroke cycle.
• the intake port 5 is equipped with a cyclically working valve 8 and an exhaust branch 9 is connected to the exhaust port 6.
• Exhaust branches 9 of both cylinders 0 are joined into one cross-section in a joint 11 and an outlet exhaust pipe 22 goes on from that joint.
• a valve 8 is replaced with a rotary valve 8a together with a reed valve 8b.
• an exhaust valve 21 in the shape of an exhaust rotary valve behind the joint of exhaust branches 9.
• the embodiment of a multi-cylinder internal combustion engine according to the figure 3 is based on the embodiment according to the figure 1 .
• a valve 8 is replaced with a reed valve 8b.
• the engine is equipped with an intake manifold 4, in which a centrifugal compressor 13 is placed.
• the embodiment of a multi-cylinder internal combustion engine according to the figure 4 is based on the embodiment according to the figure 2.
• the engine is equipped with the intake manifold 4, in which a positive displacement compressor 14 is placed.
• the embodiment of a multi-cylinder internal combustion engine according to the figure 5 is based on the embodiment according to the figure 3.
• the embodiment of a multi-cylinder internal combustion engine according to the figure 6 is based on the embodiment according to the figure 5. There are additionally placed rotary valves 8a in intake ports 5.
• the embodiment of a multi-cylinder internal combustion engine according to the figure 7 is based on the embodiment according to the figure 1 .
• the model multi-cylinder internal combustion engine supercharged by exhaust gases according to the figure 1 1 comprises three cylinders 10 with pistons 2, a cylinder head 1 with lifting valves 7 and a crankshaft mechanism 3.
• Three cylinders 10 have a cycle that is mutually shifted about 1 /3 of four-stroke cycle.
• the intake port 5 interconnected to the exhaust port 6 and valves 7 with both intake and exhaust function in the cylinder head 1 of each cylinder 10.
• the intake port 5 is equipped with a cyclically working valve 8 and the exhaust branch 9 is connected to the exhaust port 6.
• Exhaust branches 9 of all three cylinders 10 are joined into one cross-section in a joint 12 and the outlet exhaust pipe 22 goes on from that joint.
• the embodiment of a multi-cylinder internal combustion engine according to the figure 12 is based on the embodiment according to the , figure : 1 1, ( TJie, ⁇ engine is equipped wit an intake manifold 4 that is equipped with a centrifugal compressor 13,.
• the embodiment of a multi-cylinder internal combustion engine according to the figure 13 is based on 'the dmbodimerit according to the figure 1 .
• a turbine 23 of a turbocharger behind the joint 12 of exhaust branches 9 and a compressor 15 ' of the turbocharger in the intake manifold 4.
• valve 8 is replaced with a reed valve 8b. There is additionally placed a positive displacement compressor 14 into the intake manifold 4.
• the embodiment of a multi-cylinder internal combustion engine according to the figure 15 is based on the embodiment according to the figure 1 1.
• the engine is equipped with the intake manifold ' 4, in which the positive displacement compressor 4 is placed and there is additionally placed an exhaust valve 21 behind the joint of exhaust branches 9. . '
• the model multi cylinder internal combustion engine according to the figure 19 comprises two cooperating pairs of cylinders 10 in an arrangement according to the figure 1 . It is equipped with a shared intake manifold 4, in which a compressor 15 of a shared turbocharger is placed, and both joints 1 of exhaust branches 9 are connected to separate section of inlet ; housing 26 of a turbine 23 of a shared turbocharger. . . . . ; ⁇ .
• the embodiment of a multi-cylinder internal combustion engine according to, the figure 20 is equipped with the head 1 of the cylinder 10..
• the head is equipped with a classic lifting valve 7.
• the embodiment of a multi-cylinder internal combustion engine according to the figure 21 and 22 has the head 1 of the cylinder 10.
• the head 1 is equipped with two classic lifting valves 7.
• the embodiment of a multi-cylinder internal combustion engine according to the figure 23 has the head 1 of the cylinder 10.
• the head 1 is equipped with two classic lifting valves 7. - . " ⁇ . .
• the embodiment of a multi-cylinder internal combustion engine according to the figure 24 and 25 has the head 1 of the cylinder 10.
• the head is equipped with one lifting valve 7, the head of which is in the annular shape.
• the function of a multi-cylinder internal combustion engine supercharged by exhaust gases is following.
• a two-cylinder engine works in the four-stroke cycle on condition that the cycle of cylinders 10 is mutually shifted about 1/2 of the cycle, it means 360 ° .
• the first cylinder 10 starts usually with ignition and subsequent expansion.
• the exhaust stroke begins by opening lifting valves 7 in the head 1 of the first cylinder 10 at the end of the expansion, before the bottom dead centre.
• Valve 8 in the intake port 5 is closed and prevents flowing of exhaust gases through the intake port 5.
• Pressure wave of exhaust gases travels through the exhaust branch 9 of the first cylinder 10 to the joint H and from here it advances through the second exhaust branch 9 to lifting valves 7 of the second cylinder 10.
• Valve 8 in the intake port 5 is of the second cylinder 10 is closing and gas that was drawn into the exhaust port 6 and the exhaust branch 9 before is pushed into the second cylinder ⁇ 0.
• Lifting valves 7 of the second cylinder 1_0 closes afterwards and the compression stroke can start. That causes an improvement in the filling of the second cylinder 10.
• the first cylinder 10 finishes the exhaust stroke of the piston 2 and the pressure in the exhaust port 6 decreases at the end of the exhaust stroke.
• Valve 8 in the intake port 5 of the first cylinder 10 opens and the head 1 is scavenged by . gas that is drawn from the intake port 5 into the exhaust port 6 of the first cylinder 10. As the piston moves during the intake stroke, the gas is drawn into the first cylinder 10 and that gas simultaneously flows into the exhaust branch 9 of the first cylinder 1_0, until the exhaust pressure wave from the second cylinder 0 arrives. Valve 8 in the intake port 5 of the first cylinder 10 is subsequently closed and gas previously taken into the exhaust port 6 and the exhaust branch 9 is pushed into the first cylinder 10. Closing of lifting valves 7 of the first cylinder 10 ensues and the compression stroke can start. That enables an improvement in filling of the first cylinder 10.
• the process in the second cylinder is the same as in the first cylinder.
• the engine in naturally aspirated variant will achieve excellent parameters only in a harrow range of engine speed.
• the whole system tuning is significantly influenced by all valve timing of all valves, particularly lengths and cross-sectional areas of exhaust branches 9 and outlet pipes 22. It can be influenced for instance by the angle a that is an angle between inlets entering the joint H of exhaust branches 9. Considerable change of the most advantageous engine speed in naturally aspirated variant is possible to reach only by the change of length of exhaust branches 9 and of the. outlet pipe 22.
• the work of a valve can be electronically controlled after processing instantaneous data that are read from the engine.
• Two-cylinder engine with the rotary valve 8a and the reed valve 8b in the intake port 5 enables automatic and quick opening and closing of the intake port 5.
• the rotary valve 8a prevents gas flowing into the exhaust branch 9 of the cylinder 10 during the compression and .expansion in this cylinder 1_0. It actually prevents unnecessary high excess of drawing gas in exhaust gases of the engine. If there is the exhaust valve 2_1 behind the joint H, it is possible to increase the amplitude of the exhaust pressure wave.
• the exhaust valve 2 closes the outlet cross-section of the joint 11 at the time, when the pressure wave of exhaust gases reaches this joint V ⁇ _. The cross-section is subsequently opened in order to enable pressure decrease in exhaust branches 9.
• Figure 8 shows behaviour of cross-sectional area IA, IIA in lifting valves 7 and pressure lp, lip in exhaust ports 6 of the head of both cylinders 10.lt also shows behaviour of a cross-sectional area B of the exhaust valve 21. Behaviour of a two-cylinder engine without using the exhaust valve 21 is similar to that case with the exhaust valve 21 Just the values of pressures lp and Hp are lower.
• Two-cylinder engine according to the figure 3 with the reed valve 8b in the intake port 5 enables automatic and quick opening and closing of the intake port 5.
• the reed valve 8b opens whenever the value of the pressure in the exhaust port 6 drops below the value of the pressure in the intake manifold 4. That enables that the flow of intake gas into the exhaust port 6 is enabled not only during the intake into the cylinder 10, but also during the compression and expansion in the cylinder 10. That can be used in case that there is a requirement of increase in amount of drawn gas in exhaust branches 9. If there is placed a centrifugal compressor 13 in the intake h n inifold 4, the filling, of cylinders 10. by intake gas will
• Gas exchange process of the. cylinder 10 of the three-cylinder engine variant is similar to two-cylinder variant. The process is in four-stroke cycle on condition that the " . ' ' - 14 - ' "
• a two-cylinder variant has cooperating cylinders 10, whose cycles are shifted about 1/2 cycle, it means 360° and the pressure wave of exhaust gases arrives at the cylinder 10, in which the intake stroke near the bottom dead centre of the piston 2 is in progress. Actually at the end of the intake stroke.
• the cycle shift of cooperating cylinders 10 at a three-cylinder variant is 1/3, it means 240 ° , the exhaust pressure wave arrives at the cylinder 10, where the intake stroke is in progress, earlier than in the two-cylinder variant.
• lifting valves 7 there can be placed any number of lifting valves 7 in the cylinder head according to the figures 20 to 23. These valves must enable both intake into the cylinder 10 and exhaust out of the cylinder 10. Therefore it is advantageous to use them all for both intake and exhaust. In addition to all arrangements with classic poppet lifting valves 7, there is an interesting possibility to use a lifting valve 7 with an annular valve head according to the figure 24 and 25. In addition to that that it enables to reach the best flow parameters, it is also possible to advantageously form the intake port 5 as well as the exhaust port 6 to achieve swirl of intake gas in the cylinder 10.
• the difference between operation of a multi-cylinder engine according to the invention and operation of a classic four-stroke cycle is in intensive scavenging of the head at the end of the exhaust stroke, intake of gas during rthe intake stroke not only into the cylinder 10, but even in the exhaust branch 9 and subsequent pushing of gas from the exhaust branch 9 to the cylinder 1_0 b pressure of exhaust gases.
• This effect is enabled by the cylinder head I that has the interconnected intake port 5 with an exhaust port 6 and joined exhaust branches 9 of two or three cooperating cylinders 10. Tuning of the system depends on many parameters. It is possible to achieve described effect only with an engine with two or three cooperating engine cylinders 10.
• valves 8 and lifting valves 7 of low flow resistance are necessary.
• Low flow resistance in the direction of scavenging the head from the intake port s into the exhaust port 6 is particularly important.
• Length and cross-sectional area of exhaust branches 9 and arrangement of their joint 11 or 12 is crucial.
• Further 1 there are influences of valve timing settings and ways of regulation of a turboehar'ger'.
• classic four-stroke cycle is possibility of Use of natural exhaust gas recirculation in part load as well as full load of the engine. That can be influenced by many regulations, for e ample by throttling in the intake port 4.
• Multi-cylinder internal combustion engine according to the invention in naturally aspirated variant is suitable particularly for diesel arrangement for driving a generator, for example as a range extender for electric cars.
• Variants of an engine according to the invention with a compressor ora turbocharger are suitable as a drive of current vehicles.
• Spark ignition variant with direct injection could find use on small aeroplanes market thanks to its high specific power. Possibility of use as gas engines running on natural gas is also promising. It would be advantageous to blow the gas directly into the cylinder of such an engine:

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• Engineering & Computer Science (AREA)
• Mechanical Engineering (AREA)
• General Engineering & Computer Science (AREA)
• Chemical & Material Sciences (AREA)
• Combustion & Propulsion (AREA)
• Supercharger (AREA)
• Output Control And Ontrol Of Special Type Engine (AREA)
• Cylinder Crankcases Of Internal Combustion Engines (AREA)

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• 2011
  • 2011-06-03 CZ CZ20110333A patent/CZ303350B6/cs not_active IP Right Cessation
• 2012
  • 2012-06-04 US US14/123,169 patent/US20140102408A1/en not_active Abandoned
  • 2012-06-04 WO PCT/CZ2012/000046 patent/WO2012163310A1/en active Application Filing

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