• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The present invention provides an internal combustion engine comprising at least one axial axis of cylinders and a central axial axis being said geometric axes orthogonal to each other; a first cylinder coaxial with the cylinder axis; a second cylinder coaxial with the cylinder axis provided opposite the first cylinder; a central body comprising a hole axially aligned with the central axis, a first cylindrical recess and a second cylindrical recess configured to couple the second cylinder; a central power shaft arranged in a hole in the central body; a first piston provided in the first cylinder, said first piston being connected to the central power shaft by a first pair of rods; and a second piston provided in the second cylinder in opposite relation to the first piston, said second piston being connected to the central power shaft by a second pair of rods. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2697623A1
    申请号:ES201731310
    申请日:2017-11-09
    公开日:2019-01-25
    发明作者:Lostao Luis Carrillo
    申请人:Lostao Luis Carrillo;
    IPC主号:
    专利说明:

    [0001] INTERNAL COMBUSTION ENGINE WITH OPPOSITE PISTONS AND POWER AXIS
    [0002]
    [0003]
    [0004]
    [0005] The present invention is related to internal combustion engines, particularly with internal combustion engines having opposed cylinders, each cylinder having a piston, where in operation the pistons move symmetrically with respect to a common reference point or axis .
    [0006]
    [0007]
    [0008]
    [0009] Opposite piston engines, commonly known as OP motors (Opposed Piston), are thermal machines with high energy density. Opposite piston OP and opposing cylinder OPOC (Opposed-Piston-Opposed-Cylinder) engines can be engines whose piston stroke is very long. Therefore, obtaining the required power in large applications is more complicated than simply increasing the diameter of the piston and the stroke to obtain the necessary displacement; in addition to increase such diameter and such stroke of the piston, increases the size and weight of the engine, as well as the inertias and the imbalances associated with it.
    [0010]
    [0011] In order to respond to the need to increase the energy density in OP and OPOC engines, different solutions have been proposed, as will be seen below.
    [0012]
    [0013] The US patent US 8,757,123 B2 of Ecomotors INC., Proposes an OPOC-type engine in which the pistons are arranged symmetrically, that is, with internal exhaust pistons and external intake pistons. This arrangement facilitates the arrangement of short exhaust pipes in a turbocharger. In addition, the intake pistons can be identical, the exhaust pistons can be identical and the right and left cylinders can be identical to reduce the number of unique parts in the engine and reduce the engineering design and verification effort. However, a disadvantage of the piston configuration as shown in FIG. 3 is that the balance is slightly altered. The resulting imbalance in the configuration of the motor of FIG. 3 is small compared to a conventional inline motor.
    [0014] As it is observed in this anteriority, an imbalance is generated given the place where combustion is generated, and also, although the document mentions that the number of unique pieces has been reduced, the engine is complex and difficult to construct. Also increase the power density with would increase the size of the pistons and their stroke, consequently the overall size of the engine.
    [0015]
    [0016] On the other hand, US Pat. No. 6,170,443 to Hofbauer Peter describes a two-stroke internal combustion engine having opposed cylinders, each cylinder having a pair of opposed pistons, with all the pistons connected to a common central crankshaft. The internal pistons of each cylinder are connected to the crankshaft with push rods and the outer pistons are connected to the crankshaft with tension rods. This configuration results in a compact motor of very low profile, in which the forces of the free masses can be essentially fully balanced. The engine configuration also allows asymmetric synchronization of the intake and exhaust ports by angular positioning independent of the eccentrics on the crankshaft, making the engine suitable for overfeeding.
    [0017]
    [0018] Despite the advantages obtained with the Hofbauer engine, the number of components is high and the engine is of complex construction.
    [0019]
    [0020] Likewise, US Pat. No. 3,000,366 to Blackburn Walter L. discloses an engine of the type with opposing pistons in which the block or cylinder head remains stationary, but in which valve means are provided for opening and closing the intake and discharge ports. escape in combination with the piston so that the holes open and close quickly. In this way, advantageously, a very fast opening and closing of the exhaust and inlet holes is obtained and it is not necessary to alternate the cylinder or other means to control the opening and closing of these movements so that the cylinder cools as a stationary unit avoiding the inherent disadvantages of moving the cylinder elements and the members associated with each other with heat differentials.
    [0021]
    [0022] Accordingly, the need to provide a counterbalanced OP piston motor with self-balancing, in which there is an increase in power density compared to motors of the same size, but in which the complexity of the parts is shown, is evident. decrease, facilitating manufacturing and decreasing costs.
    [0023]
    [0024] In order to overcome the disadvantages and solve the needs found, the present invention provides an internal combustion engine comprising at least one axial axis of cylinders and a central axial axis, said geometric axes being orthogonal to each other; a first cylinder coaxial with the cylinder axis; a second cylinder coaxial with the cylinder axis provided opposite the first cylinder; a central body comprising a hole axially aligned with the central axis, a first cylindrical recess and a second cylindrical recess configured to couple the second cylinder; a central power shaft arranged in a hole in the central body; a first piston provided in the first cylinder, said first piston being connected to the central power shaft by a first pair of rods; and a second piston provided in the second cylinder in opposite relation to the first piston, said second piston being connected to the central power shaft by a second pair of rods.
    [0025]
    [0026] In alternative embodiments of the invention the internal combustion engine each of the rods of the first pair of rods and the second pair of rods comprise eccentric mechanisms that rotatably connect said first pair of rods and second pair of rods to the center central power shaft , wherein said eccentric mechanisms are configured to convert the linear movement of the first piston and the second piston into circular motion in the central power shaft.
    [0027]
    [0028] In other alternative embodiments of the internal combustion engine the central power shaft comprises at least a smooth cylindrical portion configured to be in the bore of the central body, and at least two connection portions configured to connect to the eccentric mechanisms and to receive a torque from said eccentric mechanisms.
    [0029]
    [0030] Preferably the central body of the internal combustion engine further comprises an intake channel extending in a direction parallel to the axial axis of cylinders and passing through the central body, an exhaust channel extending in a direction parallel to the axial axis of cylinders. and passing through the central body, an intake port in fluid connection with the intake channel, an exhaust port in fluid connection with the exhaust channel.
    [0031] In other embodiments of the invention the internal combustion engine comprises at least one intake manifold tube in connection with the intake port of the central body, at least one exhaust manifold tube in connection with the exhaust port of the central body, at least one intake valve operatively linked to the intake port and configured to control the intake of gases from the intake manifold tube to the intake port, and at least one exhaust valve operatively linked to the exhaust port and configured to control the evacuation of gases from the exhaust port to the exhaust manifold.
    [0032]
    [0033] In other alternative embodiments the internal combustion engine comprises a support cage configured to support the internal combustion engine as a whole from the clamping of the first cylinder and the second cylinder.
    [0034]
    [0035] An advantage achieved with the present invention is that the central body, which could well be called a cylinder head, is shared by the two pistons, and therefore the channels disposed therein are equally shared, whereby the number of parts of the engine is reduces and simplifies, making it more economical and easier to produce.
    [0036]
    [0037] Another advantage obtained with the engine of the present invention is related to the intake and exhaust valves that, not being mounted on the cylinder, can have a larger size, which facilitates the intake of air and / or the air mixture / fuel and the exhaust of combustion gases, improving the efficiency of the combustion cycle.
    [0038]
    [0039] Another remarkable advantage of the invention is achieved in the transformation of the alternative linear movement in circular motion in the central power axis. Since the linear movement of the pistons is transmitted to the central power shaft by the eccentric mechanism arranged in the connecting rods, said center power shaft only receives the torque from the eccentric mechanism and is therefore not subjected to the alternating forces to which the crankshafts are commonly subjected, which allows reducing the size of said axle, reducing the weight of the engine and its size, and making the engine is inherently balanced.
    [0040]
    [0041] A noteworthy advantage of the engine of the invention is the ability to use different fuels, and changes in the operation of the thermal cycle, that is to say operate in two times or four times, making minimal structural variations in said engine, particularly in the central body and in the elements linked to it, which makes the engine a versatile engine, easily adaptable to a particular situation.
    [0042]
    [0043] Another advantage obtained with the present invention is related to the stroke / diameter ratio of the piston. The claimed motor is generally of square or super-squared configuration. Since the pistons work in the same time of the thermal cycle, the total stroke per cycle is the sum of the strokes of each of the pistons, so the power density of the engine is favored, because having a joint race by a longer cycle the torque at the output is increased.
    [0044]
    [0045]
    [0046]
    [0047] The foregoing and other advantages and features will be more fully understood from the following detailed description of exemplary embodiments with reference to the accompanying drawings, which should be considered by way of illustration and not limitation, in which:
    [0048]
    [0049] - Fig. 1 is a perspective view of the internal combustion engine of the present invention including at least two pistons.
    [0050] - Fig. 2 is a perspective view of the central body of the combustion engine of the present invention that includes at least two pistons.
    [0051] - Fig. 3 is a sectional view of the internal combustion engine of the present invention.
    [0052] - Fig. 4 is a perspective view of one of the pistons of the combustion engine of the present invention.
    [0053] - Fig. 5 is a perspective view in which the central power shaft is shown with one of the rods.
    [0054] - Fig. 6 is a view of a particular embodiment of the combustion engine with four central bodies, eight cylinders and eight pistons.
    [0055]
    [0056] In the following detailed description, numerous specific details are set forth in the form of examples to provide a thorough understanding of the relevant teachings. However, it will be apparent to those skilled in the art that the present teachings can be practiced without such details.
    [0057]
    [0058] To simplify the description, several of the elements and subsystems of the combustion engine have been omitted. Therefore only those elements of the engine necessary to visualize the novel technical elements and facilitate the understanding of the technical effects achieved with them are illustrated. Obviously, other conventional parts of the internal combustion engine are used to provide a complete engine. Since these parts are conventional, their description is not considered necessary.
    [0059]
    [0060] According to a preferred embodiment, and as can be seen in FIG. 1, the present invention provides an internal combustion engine (1) of the type of opposed pistons facing with respect to a central body (3).
    [0061]
    [0062] As seen in Figure 1, the internal combustion engine (1) defines at least one axial axis of cylinders (A1) and a central axial axis (C1), said geometric axes being orthogonal to each other. As will be seen later, the axial axis of cylinders (A1) has been defined to show that the axial axis of the first cylinder (2) and the axial axis of the second cylinder (2 ') are coaxially aligned with each other in relation to said axis (A1), and consequently the first piston (5) and the second piston (5 ') in their reciprocating movement move linearly in the direction of said axial axis of cylinders (A1). Therefore, the internal combustion engine (1) of the present invention is configured to be coupled by pairs of cylinders and pistons with respect to a central body. Thus, and to simplify the explanation, the internal combustion engine (1) illustrated in Figure 1 comprises a pair of cylinders and pistons aligned with respect to the axial axis of cylinders (A1), however, in other preferred embodiments it is possible to have two or more pairs of cylinders and pistons aligned with respect to their corresponding axes (A2), (A3), (A4), etc., according to the engine requirements for each particular application.
    [0063]
    [0064] As said above, the internal combustion engine (1) comprises at least a first cylinder (2) coaxial with the cylinder axis (A1), and at least one second cylinder (2 ') coaxial with the cylinder axis (A1) provided opposite and in the direction facing the first cylinder (2). Since the first cylinder (2) and the second cylinder (2 ') are essentially the same in construction, the first cylinder (2) will be described, understanding that the same characteristics are present in the second cylinder (2'). As can be seen in Figure 3, the first cylinder (2) has on its outer surface a projection (2A) configured to abut a section of a support cage (15). As will be described later, the internal combustion engine (1), as a whole, is supported by a support cage (15), where said support cage holds the cylinders and secures them against the central body (3).
    [0065]
    [0066] In preferred embodiments, and as shown in FIGS. 1 and 3, there is provided a first complementary cylinder (2B) in which the first cylinder (2) is inserted, and a second complementary cylinder (2'B) in which the second cylinder (2) is inserted. insert the second cylinder (2 '). Said complementary cylinders (2B) (2'B) have as their main function to extract the heat generated by the combustion and to attach additional elements for the normal operation of the engine.
    [0067]
    [0068] As seen in Figure 1, and in more detail in Figure 2, the internal combustion engine comprises a central body (3) in which a first cylindrical recess (3B) configured to couple the first cylinder (2) is defined and a second cylindrical recess (3B ') configured to couple the second cylinder (2'). These recesses (3B) (3B '), for adequately coupling the cylinders (2) (2'), preferably have a cylindrical shape whose axial axis is coaxial with the geometric axial axis of cylinders (A1). Therefore, and as can be seen in figure 1, the central body (3) is shared by the first (2) and second (2 ') cylinders. On the other hand and according to what is taught in figure 2, the central body (3) additionally comprises an intake channel (3C) that extends in a direction parallel to the axial axis of cylinders (A1) and that passes through the central body (3), an exhaust channel (3D) extending in a direction parallel to the axial axis of cylinders (A1) and passing through the central body (3). In previous lines it has been mentioned that the combustion engine (1) of the present invention has the capacity to be able to use different fuels, and to be able to make changes in the thermal cycle operation, that is, to operate in two times or four times, making variations minimum structural elements in said engine. This advantage is obtained mainly from the central body (3) for the reasons described below. Since the intake (3C) and exhaust (3D) channels pass through the central body (3), the first cylinder (2) and the second cylinder (2 ') are in fluid communication through said channels (3C) ( 3D) and therefore the compression is done in the mentioned channels (3C) (3D), as shown in figure 3, and not between the cylinder head and the piston as it is done in conventional combustion engines. Thus, the compression ratio is controlled by the shape and size of the channels, which is adequate to be able to adapt to the fuel to be used. The central body also comprises an intake port (3E) in fluid connection with the intake channel (3C), an exhaust port (3F) in fluid connection with the exhaust channel (3D), where the gas inlet, such as air or an air / fuel mixture, through the intake port (3E) is regulated by at least one intake valve (12) operatively linked to said intake port (3E), and the output of the product gases of combustion is regulated by at least one exhaust valve (13) operatively linked to said intake port (3E). Since the intake (3E) and exhaust (3F) ports are not limited by the size of the cylinders (2) (2 '), it is possible to vary the size thereof, as well as having different numbers and configurations of valves for the admission and / or escape of gases. The particular arrangement of the central body (3) also allows the incorporation of injectors, turbos, depending on the type of fuel and the power and torque requirements of the engine. The person skilled in the art that such elements can be included and is within the scope of the invention.
    [0069]
    [0070] The central body (3) also comprises a hole (3A) passing through said central body (3A) and which is axially aligned with the central axial axis (C1). The hole (3A) is provided to receive a central power shaft (4). Since the central body (3) is shared by the first (2) and second (2 ') cylinders facing each one side of the central body (3), this is located in a central part of the engine (1), in Consequently, the central power shaft (4) is arranged in the center of the motor (1), which represents some technical advantages that will be analyzed later.
    [0071]
    [0072] As said before, the central power shaft (4) is arranged in the hole (3A) of the central body (3) and comprises at least a smooth cylindrical portion (4A) and at least some connection portions (4B) (4C), as can be seen in Figure 5. The smooth cylindrical portion (4A) is that which runs through the hole (3A) of the central body (3), while the connecting portions are outside the central body ( 3) and are configured to connect with eccentric mechanisms (8) (8 ') (9) (9') arranged in a first pair of rods (6) (6 ') and in a second pair of rods (7) ( 7 ') and to receive a pair from said eccentric mechanisms (8) (8') (9) (9 '). The eccentric mechanisms (8) (8 ') (9) (9') and their interaction with the connection portions (4B) (4C) will be detailed below. In alternative embodiments, the central power shaft (4) has a central passage (4D) the which is configured to distribute lubricant to the components connected thereto, as well as to reduce weight.
    [0073]
    [0074] On the other hand, and according to figures 1 and 3, the internal combustion engine (1) comprises a first piston (5) provided in the first cylinder (2), said first piston (5) being connected to the central axis of the piston (5). power (4) by a first pair of connecting rods (6) (6 '); and a second piston (5 ') provided in the second cylinder (2') in opposite relation to the first piston (5), said second piston (5 ') being connected to the central power shaft (4) by means of a second pair of connecting rods (7) (7 '). Since the first piston (5) and the second piston (5 ') are of equal construction, only the first of these will be described. As seen in figures 1, 3 and 4, the first piston (5) comprises a head (5A), a skirt (5B), a coupling (5C) arranged at the end of said skirt (5B) and a pin ( 5D) configured to rotatably couple the first pair of rods (6) (6 ') to said piston (5). Components such as scraper rings, retaining rings, retainers, etc., have been omitted to simplify the description, however the person skilled in the art will observe that they are indispensable for the normal operation of the internal combustion engine (1).
    [0075]
    [0076] As seen in Figure 1, the first piston (5) is connected to the central power shaft (4) by a first pair of connecting rods (6) (6 ') and the second piston (5') by a second pair of connecting rods (7) (7 '). The connecting rods that make up the pairs of connecting rods (6) (6 ') (7) (7') are the same in construction, therefore only one of them will be described. In figure 5, the second connecting rod (6 ') comprising a piston connection end (6'A) which is configured to receive the pin (5D) of the piston (5), and a connecting end is shown. central axis (6'B) in which the eccentric mechanism (8 ') is provided. The connecting rods work by pairs of connecting rods (6) (6 ') each located on one side of their respective piston, first piston (5), to dynamically balance said piston. The connecting rods are responsible for transmitting and converting the reciprocating movement of the pistons (5) (5 ') originated by the combustion from the eccentric mechanism (8) (8') into a circular movement of torque on the power shaft (4). ). With reference to Figure 5, it is noted that the eccentric mechanism (8 ') is formed by a fixed part (8'A) and a rotating part (8'B) configured to rotate with respect to the fixed part (8'A) ); wherein the rotating part (8'B) comprises a connection part (8'C) configured to connect with the connection portion (4C) of the central power shaft (4). In the embodiment presented in Figure 5, the portions of connecting portions (4B) (4C) of the central power shaft (4) are shown as flat surfaces that fit flat surfaces (not shown) provided in the connection (8'C) so that the center power shaft (4) does not rotate with respect to the connection part (8'C). How is it well known is the distance between the center of rotation of the rotating part (8'B) and the center of rotation of the central power shaft (4), which is the same central axial axis (C1), causes an alternate movement that is it is reflected at the piston connection end (6'A) of the connecting rod (6 '); reciprocally reciprocating movement of the piston connecting end (6'A) will generate through the eccentric mechanism (8 ') a circular movement in the central power shaft (4) around the central axial axis (C1), the which is the operation principle of the combustion engine (1) of the present invention.
    [0077]
    [0078] In preferred embodiments the stroke of the piston (5) is equal to or smaller than the diameter thereof, whereby the motor is configured as a square or super-square motor.
    [0079]
    [0080] As can be seen in figure 3 the internal combustion engine comprises at least one intake manifold tube (10) in connection with the intake port (3E) of the central body (3) and at least one exhaust manifold tube (11) in connection with the exhaust port (3F) of the central body (3). As mentioned in previous lines, the intake valve (12) is operatively linked to the intake port (3E) and is configured to control the intake of gases from the intake manifold (10) to the intake port ( 3E), while the exhaust valve (13) is operatively linked to the exhaust port (3F) and is configured to control the evacuation of gases produced by combustion from the exhaust port (3F) to the exhaust manifold ( eleven).
    [0081]
    [0082] As can be seen in figures 1 and 3, in order to support the internal combustion engine (1), a support cage (15) configured to support the internal combustion engine as a whole has been arranged from the fastening of the first cylinder (2) and the second cylinder (2 '). The support cage (15) comprises at least first cylinder supports (15A) (15A ') configured to hold the first cylinder (5), second cylinder supports (15B) (15B') configured to hold the second cylinder (5 '), crosspieces (15C) (15C') configured to hold the first cylinder supports (15A) (15A ') and the second cylinder supports (15B) (15B') butt against the projections (2A) ( 2'A) of the first cylinder (2) and the second cylinder (2'A) so that said first (5) and second (5 ') cylinders are firmly clamped against the central body (3) to diametrically imprison the first supports of cylinder (15A) (15A ') against the first (2) the cage comprises first exterior struts (15D). Similarly, the support cage (15) comprises a second external braces (15D ') configured to diametrically imprison the second cylinder (2 '). When all the elements of the support cage (15) come together, the assembly of the internal combustion engine (1) of the present invention is formed.
    [0083]
    [0084] Up to now the invention has been described as an internal combustion engine (1) of opposed pistons having a single central body (3) and two cylinders (5) (5 '); however, depending on the requirements of the engine, it is possible to put as many central bodies with their respective pair of cylinders, pistons and rods, extending and sharing a single central axis (3).
    [0085]
    [0086] Exemplifying the above in figure 6, an internal combustion engine (100) with four central bodies, eight cylinders, eight pistons and sixteen connecting rods connected to a single central power shaft (40) has been represented. This and other more elongated or shorter configurations are possible thanks to the self-balanced configuration of the combustion engine with respect to the central axis.
    权利要求:
    Claims (6)
    [1]
    1. Internal combustion engine (1) characterized in that it comprises at least:
    - an axial axis of cylinders (A1) and a central axial axis (C1), said geometric axes being orthogonal to each other;
    - a first cylinder (2) coaxial with the cylinder axis (A1);
    - a second cylinder (2 ') coaxial with the cylinder axis (A1) provided opposite to at least said first cylinder (2);
    - a central body (3) comprising a hole (3A) passing through said central body (3A) and which is axially aligned with the central axial axis (C1), a first cylindrical recess (3B) configured to couple the first cylinder (2) and a second cylindrical recess (3B ') configured to couple the second cylinder (2');
    - a central power shaft (4) arranged in a hole (3A) of the central body (3);
    - a first piston (5) provided in the first cylinder (2), said first piston (5) being connected to the central power shaft (4) by means of a first pair of rods (6) (6 '); Y
    - a second piston (5 ') provided in the second cylinder (2') in opposite relation to the first piston (5), said second piston (5 ') being connected to the central power shaft (4) by means of a second pair of rods (7) (7 ').
    [2]
    2. Internal combustion engine according to claim 1, characterized in that each of the rods of the first pair of rods (6) (6 ') and the second pair of rods (7) (7') comprises eccentric mechanisms (8) (8). ') (9) (9') which rotatably connect said first pair of connecting rods (6) (6 ') and second pair of rods (7) (7') to the center central power shaft (4), where said eccentric mechanisms (8) (8 ') (9) (9') are configured to convert the linear movement of the first piston (5) and the second piston (5 ') to circular motion in the central power shaft (4).
    [3]
    3. Internal combustion engine according to claim 2, characterized in that the central power shaft (4) comprises at least a smooth cylindrical portion (4A) configured to be in the hole (3A) of the central body, and at least two connection portions ( 4B) (4C) configured to connect with the eccentric mechanisms (8) (8 ') (9) (9') and to receive a pair from said eccentric mechanisms (8) (8 ') (9) (9').
    [4]
    4. Internal combustion engine according to any of the preceding claims, characterized in that the central body (3) additionally comprises:
    - an intake channel (3C) extending in a direction parallel to the axial axis of cylinders (A1) and passing through the central body (3);
    - an exhaust channel (3D) extending in a direction parallel to the axial axis of cylinders (A1) and passing through the central body (3);
    - an intake port (3E) in fluid connection with the intake channel (3C);
    - an exhaust port (3F) in fluid connection with the exhaust channel (3D);
    [5]
    5. Internal combustion engine according to claim 4, characterized in that it comprises: - at least one intake manifold tube (10) in connection with the intake port (3E) of the central body (3);
    - at least one exhaust manifold tube (11) in connection with the exhaust port (3F) of the central body (3);
    - at least one intake valve (12) operatively connected to the intake port (3E) and configured to control the admission of gases from the intake manifold (10) to the intake port (3E); Y
    - at least one exhaust valve (13) operatively linked to the exhaust port (3F) and configured to control the gas evacuation from the exhaust port (3F) to the exhaust manifold (11).
    [6]
    6. Internal combustion engine according to any of the preceding claims, characterized in that it comprises:
    - a support cage (15) configured to support the internal combustion engine as a whole from the clamping of the first cylinder (2) and the second cylinder (2 ').
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    同族专利:
    公开号 | 公开日
    EP3708770A1|2020-09-16|
    CN111344476A|2020-06-26|
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    WO2019092298A1|2019-05-16|
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    US9328692B2|2009-02-20|2016-05-03|Achates Power, Inc.|Opposed piston engines with controlled provision of lubricant for lubrication and cooling|
    法律状态:
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    ES201731310A|ES2697623B2|2017-11-09|2017-11-09|INTERNAL COMBUSTION ENGINE WITH OPPOSITE PISTONS AND CENTRAL POWER SHAFT|ES201731310A| ES2697623B2|2017-11-09|2017-11-09|INTERNAL COMBUSTION ENGINE WITH OPPOSITE PISTONS AND CENTRAL POWER SHAFT|
    US16/762,192| US20200355115A1|2017-11-09|2018-11-08|Internal combustion engine with opposed pistons and a central drive shaft|
    EP18849474.4A| EP3708770A1|2017-11-09|2018-11-08|Internal combustion engine with opposed pistons and a central drive shaft|
    CN201880072614.7A| CN111344476A|2017-11-09|2018-11-08|Internal combustion engine with opposed cylinders and central drive shaft|
    PCT/ES2018/070721| WO2019092298A1|2017-11-09|2018-11-08|Internal combustion engine with opposed pistons and a central drive shaft|
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