Patent Application
20100192896
The present disclosure is related to internal combustion engines. In particular, the present disclosure is related to internal combustion engines with a ring-shaped cylinder and associated methods of operation.
The German technician named Karl Benz was credited to invent the first modern automobile in 1886. The automobile he invented was a tricycle carrying a gasoline internal combustion engine. Since then, the automobiles have “compressed” time and space of modern living, changed lifestyles of countless people, and effectively improved labor productivity.
Most conventional engines have a reciprocating piston configuration. One exception is the Wankel engine, which has a rotary configuration. However, the Wankel rotary engine has not been widely used due to manufacturing complexity and high costs. Therefore, the vast majority of internal combustion engines in the market today have the reciprocating piston configuration.
The reciprocating piston type engines are mechanically complex and have low efficiencies. For example, one four-cylinder four-stroke engine typically include hundreds if not thousands of individual components. In operation, only one stage of the four-stroke cycle produces work while the remaining three stages consume energy. With other losses in connecting links and other mechanical components, reciprocating piston type engines typically have energy-to-work efficiencies below 30%. Accordingly, there is a need in the art for internal combustion engines that have low manufacturing costs and high energy-to-work efficiency.
Specific details of several embodiments of the disclosure are described below with reference to internal combustion engines with a ring-shaped cylinder and associated methods of operation. The term “internal combustion engine” generally refers to an engine in which the combustion of a fuel (e.g., gasoline, diesel, and/or other types of suitable fuels) occurs with an oxidizer (e.g., air) in a combustion chamber of the engine. Several embodiments can have configurations, components, or procedures different than those described in this section, and other embodiments may eliminate particular components or procedures. A person of ordinary skill in the relevant art, therefore, may understand that the technology can have other embodiments with additional elements, and/or can have other embodiments without several of the features shown and described below with reference to
Several embodiments of the technology are directed to an internal combustion engine with improved energy efficiency and reduced mechanical complexity. The internal combustion engine can include an engine body with a ring-shaped cylinder and a plurality of synchronizing valves at least proximate to the outer circumference of the ring-shaped cylinder. The synchronizing valves can individually have a valve shaft and a valve opening.
The internal combustion engine can also include a rotor at a center of the ring-shaped combustion chamber and a plurality of isolation blocks on the rotor. The rotor can be coupled to an output shaft and/or other suitable components for outputting mechanical energy. In certain embodiments, a top portion of the isolation blocks can be hollow. In other embodiments, the isolation block can include at least one of a wedged block mount on the rotor; a securing screw or rivet at the top portion of the wedged block mount. In further embodiments, the isolation blocks can be bowl-shaped or dish-shaped and are coupled with the securing screw or rivet. Spacers can be between the adjacent bowl-shaped or dish-shaped isolation blocks and can also be on the securing screw or rivet between the bowl-shaped or dish-shaped isolation blocks and the wedged block mount. In yet further embodiments, the isolation blocks can also include other suitable components and/or configurations.
During operation, the rotor, the top portion of the isolation blocks, and the valve openings of the synchronizing valves can form a combustion/compression chamber. The internal combustion chamber can also include a fuel nozzle to the combustion/compression chamber and a gas discharging valve with an opening to the ring-shaped cylinder. In certain embodiments, the synchronizing valve shafts are coupled with respective pinions, for example, though a key. The output shaft can be coupled with a bull gear, for example, through another key, and the bull gear and the pinions are engaged with one another. A bearing or bushing can be provided on the output shaft.
The isolation block and the valve opening are configured such that an elastic sealing can be achieved therebetween. For example, in certain embodiments, a sealing gasket is positioned between the bottom surface of the isolation block and the rotor, and the sealing gasket can be fixed on the isolation block with a screw and/or other suitable fastener. In other embodiments, other sealing mechanisms may also be used.
In certain embodiments, the individual synchronizing valves can include positioning holes and seals and/or sealing rings on the outer circumference of the synchronizing valves. Both ends of the seals can be locked in the positioning holes in the synchronizing valves with, for example, springs between both ends of the seals. As discussed in more detail below, three to five sets of seals can be provided on the synchronizing valves and each set can include three to five individual seals. In other embodiments, the individual synchronizing valves can also include any other desired number of sets of seals and/or number of seals in an individual set.
In certain embodiments, the internal combustion engine can also include sealing rings between the rotor and the engine body, between the bearing and the engine body, and/or between the bearing and the rotor. A protective cover can be at one side of the engine body where the synchronizing valve shafts and the output shaft extend from the engine body. In several embodiments, the internal combustion engine can include an anti-vibration mounting and/or an anti-vibration rubber sleeve for the engine body. The anti-vibration mounting and the anti-vibration rubber sleeve can be fixed to a vehicle frame through a bolt and/or other suitable fasteners. A coolant passage can also be in the engine body. In other embodiments, the internal combustion engine may be mounted via other suitable techniques.
Several embodiments of the internal combustion engine can have simpler structures and higher volume-to-power output ratios than conventional reciprocating piston type engines. Several embodiments of the internal combustion engine can at least reduce or even eliminate vibration and energy consumption of the reciprocating pistons at the upper and lower stroke dead ends in the conventional engine. It has been shown that the fuel consumption of several embodiments of the internal combustion engine in accordance with the present technology can be ⅓ to ½ less than certain conventional reciprocating piston type engines.
Several particular embodiments of the internal combustion engine in accordance with the present technology are described below. The described embodiments with respect to different figures may have components that are generally similar in structure and/or function. As a result, common acts and structures are identified by common reference numbers.
Synchronizing valves 1 can be located on the outer circumference of the ring-shaped cylinder and individually have a valve opening 11. A rotor 4 can be at the center of the ring-shaped cylinder with a plurality of isolation blocks 3 on the rotor 4. The isolation blocks 3, the synchronizing valves 1, and the ring-shaped cylinder are configured in such a way that sealing is achieved (1) between the individual isolation blocks 3 and the corresponding synchronizing valves 1 and (2) between the isolation blocks 3 and the ring-shaped cylinder.
Combustion chambers 22 can be formed in the engine body 6 at a side proximate to the synchronizing valves 1. An injection window 25 can be at the individual combustion chambers 22. A seal 23 is located on a surface of the isolation block 3, which is at least approximately tangent to the synchronizing valves 1 and the ring-shaped cylinder.
The isolation block 3 can include positioning holes 26. Both ends of the seals 23 can be engaged or locked in the positioning holes 26 of the isolation block 3 with springs 24 and/or other suitable fasteners in the positioning holes 26 between both ends of the seals 23. In the illustrated embodiment, the isolation block 3 has four seals, though any other desired number of seals may also be used. Both sides of the isolation block 3 are configured to produce elastic sealing between both sides of the isolation block 3 and the side walls of the valve opening 11.
In the illustrated embodiment, a gasket 17 is between a bottom surface of the isolation block 3 and the rotor 4. The gasket 17 can be fixed on the isolation block 3 via a screw 17. In certain embodiments, each isolation block 3 can have one to thirty sets of screws. In other embodiments, any other desired number of screws may also be used. In further embodiments, other suitable sealing components may be used between the bottom surface of the isolation block 3 and the rotor 4.
The internal combustion engine can also include one, two, or other desired number of nozzles 18 in the combustion chamber 22. In embodiments with only one nozzle 18, both fuel and exhaust gases can pass through the nozzle 18. In other embodiments with two nozzles 18, fuel can pass through a first nozzle 18 while exhaust gases can pass through a second nozzle 18. In further embodiments, other injection and/or exhaust configurations may be used.
The internal combustion engine can also include gas discharging valves 21 with openings to the ring-shaped cylinder. The gas discharging valves 21 can connect with a gas discharging pipe and a muffler and/or other suitable exhaust components (not shown). The gas discharging windows 25 can be arranged at respective locations where the gas discharging valves 21 connect with the ring-shaped cylinder. The gas discharging windows 25 can be in conformity with the inner surface of the ring-shaped cylinder in flatness and smoothness.
In the illustrated embodiment, the synchronizing valve 1 can include a synchronizing valve shaft 2, and the rotor 4 is coupled with an output shaft 7 via a key 16-3. The synchronizing valve shaft 2 is coupled with a pinion 12 though a key 16-1, and the output shaft 7 is coupled with a bull gear 9 through a key 16-2. The bull gear 9 and the pinion 12 are engaged so that the synchronizing valve shaft 2 and the output shaft 7 can synchronously rotate. In other embodiments, other synchronizing mechanisms may also be used.
In the illustrated embodiment, a bearing (or bushing) 10 is on the output shaft 7. Sealing rings 8-1, 8-2, and 8-3 are between the rotor 4 and the engine body 6, between the bearing 10 and the engine body 6, and between the bearing 10 and the rotor 4. Thus, in the illustrated embodiment, three sets of sealing structures are at both sides of the rotor 4. In other embodiments, the internal combustion engine may include other sealing mechanisms on the output shaft 7.
In the illustrated embodiment, the sealing structures include three-stage seals. However, in other embodiments, the number of the sealing rings can be increased or decreased based on power, pressure, temperature, and/or other characteristics of the particular engines. Typically, 2-10-stage seals can be used, though any number of stage seals may be used. The three-stage seals in the illustrated embodiment includes a high temperature sealing ring, an intermediate temperature sealing ring, and a low temperature sealing ring. Other configurations of the seals may also be suitable in other embodiments.
In the illustrated embodiment, a protective cover 20 is at one side of the engine body 6 where the synchronizing valve shafts 2 and the output shaft 7 extend out of the engine body 6. The engine body 6 at this side is detachable. In certain embodiments, the engine body 6 can be integrated with an anti-vibration mounting 13 which may include an anti-vibration rubber sleeve 14. The anti-vibration mounting 13 and the anti-vibration rubber sleeve 14 can be fixed on the vehicle frame via bolts 15. A coolant passage 19, which communicates with the engine cycle cooling system (not shown) to control the engine temperature, can be located in the engine body 6.
The internal combustion engine can also include seals or sealing rings 23 on the outer circumference of the synchronizing valve 1 and positioning holes 26 in the synchronizing valve 1. Both ends of the seals 23 can be locked in the positioning holes 26 in the synchronizing valve 1, and the diameter of the holes 26 can be slightly greater than the cross-section of the seals 23 so that the seals 23 may move within the holes 26.
Without being bound by theory, it is believed that the sealing quality can be enhanced by virtue of a centrifugal force when the synchronizing valve 1 is rotated. Springs 24 are between both ends of the seals 23 within the position limitation hole 26. In the illustrated embodiment, five sets of seals are provided on the synchronizing valve 1 and each set includes three seals, which are believed to improve the sealing quality by using resilient expansion sealing and centrifugal sealing. In other embodiments, any other desired number of sets of seals and/or number of seals in a set may be used.
When starting the internal combustion engine, a starter (not shown, e.g., an electrical motor) can drive the synchronizing valves 1 and pinions to rotate. The pinions in turn drive the bull gear, the rotor 4, and the isolation block 3 to rotate. After the isolation block 3 passes through the synchronizing valve opening 11, the isolation block 3, the synchronizing valve 1 and the rotor 4 form a sealed combustion chamber. A fuel (e.g., gasoline) is then injected into the combustion chamber via the nozzle 18 and subsequently ignited to push the isolation block 3 moving forward. After the fuel injection and combustion are completed, the exhaust gases are discharged via the gas discharging valves 21. The isolation block 3 drives the rotor 4 to rotate, and the rotor 4 drives the output shaft 7 to rotate so that the rotating momentum can be transmitted to a gear box (not shown) to drive wheels of a vehicle.
Even though the internal combustion engine shown in
During start-up, a starter (not shown, e.g., an electrical motor) drives the synchronizing valves 1 and pinions to rotate. The pinions drive the bull gear 9 to move, and the bull gear 9 drives the rotor 4 and the isolation blocks 3 to rotate. After the isolation block 3 passes through the synchronizing valve opening 11, sealing is formed between the surface of the synchronizing valve body and the inner wall of the cylinder. As the isolation block 3 is gradually inserted into the valve opening 11 (shown as a U-shaped opening, though other configurations may also be used), the valve opening 11 and the isolation block 3 form a sealed chamber, and the pressure of the chamber is increased with the insertion of the isolation block 3 because force is applied to the top portion of the isolation block 3.
As the top portion of the isolation block 3 is hollowed, the arch face at the peak of the top portion is slightly curved, depressed, and/or otherwise deformed. After the arch curve is pressed, both side walls of the isolation block 3 are expanded in both left and right directions so that tight sealing is achieved between both side walls of the isolation block 3 and the valve opening 11. The pressure in the sealed valve chamber is increased until a fuel compression ignition pressure is reached.
At this time, a fuel (e.g., diesel) is injected via the nozzle 18 and is ignited. The isolation block 3 is rapidly rotated under the push of the ignition pressure. After the sealing pressurization, fuel injection, compression ignition, and rotation are finished, the exhaust gases are discharged from the gas discharging valve opening 21. During operation, it is believed that when the ignited fuel pushes the arch face of the isolation block 3 the sealing pressure of the top surface of the isolation block 3, as well as the sealing between the isolation block 3 and the ring-shaped cylinder, are enhanced.
From the foregoing, it will be appreciated that specific embodiments of the technology have been described herein for purposes of illustration, but that various modifications may be made without deviating from the technology. For example, in certain embodiments, the bull gear 9 and the pinion can be replaced with synchronous belts, sprocket wheels, and/or chain transmission. In other embodiments, internal combustion engine can include two or more rotors in series on one output shaft 7 based on a desired power output requirement. Many of the elements of one embodiment may be combined with other embodiments in addition to or in lieu of the elements of the other embodiments. Accordingly, the technology is not limited except as by the appended claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 200710157480.2 | Oct 2007 | CN | national |
| 200710157481.7 | Oct 2007 | CN | national |
This application claims priority to PCT Application No. PCT/CN2008/001566, filed on Sep. 2, 2008 which further claims priority to Chinese Patent Application Nos. 200710157480.2 and 200710157481.7, the disclosures of which are incorporated herein by reference in their entirety.
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/CN2008/001566 | Sep 2008 | US |
| Child | 12756936 | US |
