CN111336027A - Engine with one-way valve piston noise reduction fence - Google Patents
Engine with one-way valve piston noise reduction fence Download PDFInfo
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- CN111336027A CN111336027A CN201911195613.4A CN201911195613A CN111336027A CN 111336027 A CN111336027 A CN 111336027A CN 201911195613 A CN201911195613 A CN 201911195613A CN 111336027 A CN111336027 A CN 111336027A
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- piston
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02F—CYLINDERS, PISTONS OR CASINGS, FOR COMBUSTION ENGINES; ARRANGEMENTS OF SEALINGS IN COMBUSTION ENGINES
- F02F3/00—Pistons
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23H—WORKING OF METAL BY THE ACTION OF A HIGH CONCENTRATION OF ELECTRIC CURRENT ON A WORKPIECE USING AN ELECTRODE WHICH TAKES THE PLACE OF A TOOL; SUCH WORKING COMBINED WITH OTHER FORMS OF WORKING OF METAL
- B23H1/00—Electrical discharge machining, i.e. removing metal with a series of rapidly recurring electrical discharges between an electrode and a workpiece in the presence of a fluid dielectric
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23H—WORKING OF METAL BY THE ACTION OF A HIGH CONCENTRATION OF ELECTRIC CURRENT ON A WORKPIECE USING AN ELECTRODE WHICH TAKES THE PLACE OF A TOOL; SUCH WORKING COMBINED WITH OTHER FORMS OF WORKING OF METAL
- B23H1/00—Electrical discharge machining, i.e. removing metal with a series of rapidly recurring electrical discharges between an electrode and a workpiece in the presence of a fluid dielectric
- B23H1/04—Electrodes specially adapted therefor or their manufacture
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B25—HAND TOOLS; PORTABLE POWER-DRIVEN TOOLS; MANIPULATORS
- B25B—TOOLS OR BENCH DEVICES NOT OTHERWISE PROVIDED FOR, FOR FASTENING, CONNECTING, DISENGAGING OR HOLDING
- B25B11/00—Work holders not covered by any preceding group in the subclass, e.g. magnetic work holders, vacuum work holders
- B25B11/02—Assembly jigs
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- 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
- F02B75/00—Other engines
- F02B75/32—Engines characterised by connections between pistons and main shafts and not specific to preceding main groups
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02F—CYLINDERS, PISTONS OR CASINGS, FOR COMBUSTION ENGINES; ARRANGEMENTS OF SEALINGS IN COMBUSTION ENGINES
- F02F3/00—Pistons
- F02F3/0015—Multi-part pistons
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02F—CYLINDERS, PISTONS OR CASINGS, FOR COMBUSTION ENGINES; ARRANGEMENTS OF SEALINGS IN COMBUSTION ENGINES
- F02F3/00—Pistons
- F02F3/28—Other pistons with specially-shaped head
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16J—PISTONS; CYLINDERS; SEALINGS
- F16J1/00—Pistons; Trunk pistons; Plungers
- F16J1/10—Connection to driving members
- F16J1/14—Connection to driving members with connecting-rods, i.e. pivotal connections
- F16J1/16—Connection to driving members with connecting-rods, i.e. pivotal connections with gudgeon-pin; Gudgeon-pins
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01T—SPARK GAPS; OVERVOLTAGE ARRESTERS USING SPARK GAPS; SPARKING PLUGS; CORONA DEVICES; GENERATING IONS TO BE INTRODUCED INTO NON-ENCLOSED GASES
- H01T13/00—Sparking plugs
- H01T13/02—Details
- H01T13/06—Covers forming a part of the plug and protecting it against adverse environment
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02F—CYLINDERS, PISTONS OR CASINGS, FOR COMBUSTION ENGINES; ARRANGEMENTS OF SEALINGS IN COMBUSTION ENGINES
- F02F2200/00—Manufacturing
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Chemical & Material Sciences (AREA)
- Combustion & Propulsion (AREA)
- Manufacturing & Machinery (AREA)
- Pistons, Piston Rings, And Cylinders (AREA)
Abstract
The engine with the noise reduction fence of the check valve piston is characterized in that a check valve (47) is arranged in the piston, the inlet end of the check valve is connected with the cavity (41), and the outlet end of the check valve is connected with an auxiliary air port (28); a pressure increasing spring (48) is arranged below a valve core steel ball of a one-way valve (47) arranged in a piston of an engine for increasing the pressure of a one-way valve piston, and the pressure increasing spring (48) is connected with the outlet end of the one-way valve to achieve secondary buffering, noise reduction and auxiliary pressure increase on the upper part of a piston surface.
Description
Technical Field
The invention relates to an automatic clamping and positioning mechanism and method for simultaneously mounting two G-shaped elastic pads at the pin end of a piston of a small-sized engine and the engine with a one-way valve piston noise reduction fence, belonging to the technical field of pistons and crank connecting rods of internal combustion engines.
Background
The assembly of the piston with the crank-connecting rod has great potential to be excavated. At present, the automatic clamping and positioning mechanism and the method for simultaneously installing two G-shaped elastic pads at the pin end of a small engine also have the defects that in the search, the piston and a crank connecting rod are assembled, and the two G-shaped elastic pads can not be simultaneously installed at the pin end of the small engine; the method comprises the steps that G-shaped elastic cushions are installed at the pin ends of pistons of the small-sized engine, and basically in a manual production mode, an operator manually installs a first G-shaped elastic cushion, to be clamped in a piston sinking groove, at the left end of each piston pin, of which a piston is connected with a crank connecting rod through the piston pin, and then manually installs a second G-shaped elastic cushion, to be clamped in the piston sinking groove, at the right end of each piston pin, of which the piston is connected with the crank connecting rod through the piston pin; because the G-shaped elastic cushion is elastic and has a variable outer diameter; the diameter of the piston pin is 8mm, the major diameter of the piston sinking groove is 10mm, namely, the G-shaped elastic pad with the major diameter of 10mm is held and compressed to 8mm by hand pliers and pushed into the piston sinking groove, and then the G-shaped elastic pad is restored to the major diameter of 10 mm; and a first G-shaped elastic cushion in the piston sinking groove at the left end of the piston pin is completely installed, and a second G-shaped elastic cushion in the piston sinking groove at the right end of the piston pin is also installed. Not only is the labor intensity of workers high and the production efficiency low, but also the G-shaped elastic cushion is deformed due to overlarge operation force or is not properly assembled due to too small operation force. With the increase of labor cost and the appearance of wasted labor, the automatic production of simultaneously mounting two G-shaped elastic cushions at the pin end of the piston of the small-sized engine is urgent, but the expensive full-automatic high-precision equipment is too expensive, so that enterprises are difficult to bear; how to flexibly assemble the piston and the elastic pad of the crank connecting rod, and a mechanism and a method for simultaneously installing two G-shaped elastic pads at the pin end of the piston of a small-sized engine are sought, which is a long-standing problem related to energy conservation and emission reduction.
Disclosure of Invention
The assembly of the piston with the crank-connecting rod has great potential to be excavated. An automatic clamping and positioning mechanism and method for installing two G-shaped elastic pads at the pin end of a piston of a small engine simultaneously are disclosed. Aiming at the assembly of the piston and the crank connecting rod, two G-shaped elastic cushions cannot be arranged at the pin end of the piston of the small-sized engine at the same time; the method comprises the steps that G-shaped elastic cushions are installed at the pin ends of pistons of the small-sized engine, and basically in a manual production mode, an operator manually installs a first G-shaped elastic cushion, to be clamped in a piston sinking groove, at the left end of each piston pin, of which a piston is connected with a crank connecting rod through the piston pin, and then manually installs a second G-shaped elastic cushion, to be clamped in the piston sinking groove, at the right end of each piston pin, of which the piston is connected with the crank connecting rod through the piston pin; because the G-shaped elastic cushion is elastic and has a variable outer diameter; the diameter of the piston pin is 8mm, the major diameter of the piston sinking groove is 10mm, namely, the G-shaped elastic pad with the major diameter of 10mm is held and compressed to 8mm by hand pliers and pushed into the piston sinking groove, and then the G-shaped elastic pad is restored to the major diameter of 10 mm; the first G-shaped elastic cushion in the piston sinking groove at the left end of the piston pin is completely installed, and the second G-shaped elastic cushion in the piston sinking groove at the right end of the piston pin is also installed; not only the labor intensity of workers is high, the production efficiency is low, but also the G-shaped elastic cushion is deformed because of overlarge operation force, or the G-shaped elastic cushion is not properly installed because of too small operation force and too skew; with the increase of labor cost and the appearance of wasted labor, the automatic production of simultaneously mounting two G-shaped elastic cushions at the pin end of the piston of the small-sized engine is urgent, but the situation that an enterprise cannot bear the piston is caused by the expensive full-automatic high-precision equipment; the method for assembling the elastic pads of the piston and the crank connecting rod flexibly is a method for simultaneously installing two G-shaped elastic pads at the pin end of the piston of a small-sized engine, and solves the problem that the two G-shaped elastic pads cannot be installed at the same time.
The technical scheme and the method for solving the technical problem are as follows:
because only the cylinder is provided with the inclined grooves, the complicated manipulator comprising a plurality of follow-up fingers is skillfully omitted for deformationally clamping the G-shaped elastic pad in an unfixed state, and the device is not only simple, but also easy to operate and easy to use; the core technology is that the angle of the chute is the included angle between the chute (2) of the clamping cylinder (1, 1b) provided with the chute (2) and the axis of the clamping cylinder; and the follow-up push-pull mechanism is composed of a main follow-up push plate, a cylinder push plate and a main follow-up pull block, so that over-restraint is overcome.
An automatic clamping and positioning mechanism for simultaneously mounting two G-shaped elastic pads at the pin end of a piston of a small engine is composed of clamping cylinders (1, 1b) provided with chutes (2), a main body guide seat (15), an anti-rotation stop block (13), a main push rod (8), a cylinder mounting seat (16), a cylinder (19), a cylinder push plate (21), a main follow-up push plate (20), a main follow-up pull block (22), an auxiliary clamp seat (23) and a machine seat (24), wherein the main body guide seat (15), the cylinder mounting seat (16) and the cylinder (19) are symmetrically and sequentially mounted on the left side and the right side of the middle part of the machine seat respectively; a piston (17) provided with a crank connecting rod and a piston pin is arranged in the middle of the engine base, and an auxiliary clamp seat (23) of an auxiliary clamp is arranged on the upper part of the middle of the engine base; the method is characterized in that: the clamping cylinders (1, 1b) provided with the inclined grooves (2) are symmetrically arranged in the main body guide seat (15) at the left and right sides, and the inclined grooves (2) are used for placing G-shaped elastic pads; the main push rod (8) is movably inserted into the clamping cylinders (1, 1b) provided with the inclined grooves (2); the end parts of the main body guide seats (15) are respectively provided with the anti-rotation stop blocks (13); the rear part of the main push rod (8) is provided with the main follow-up push plate (20); the movable extension part of the cylinder (19) is connected with the cylinder push plate (21); and the main follow-up pulling block (22) passes through the gap of the main follow-up push plate (20) and is connected with the cylinder push plate (21).
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the included angle between the inclined groove (2) of the clamping cylinder (1, 1b) provided with the inclined groove (2) and the axis of the clamping cylinder is more than 1 degree; an axial through hole (3) is arranged in the clamping cylinders (1, 1b) provided with the inclined grooves (2) so as to facilitate the main push rod (8) to pass through; the chute is a radial through hole and is only communicated with the upper cylinder wall but not communicated with the lower cylinder wall; the chute is a rectangle with two parallel sides in a top view; it is longer than 10mm and wider than 0.8mm to fit loosely into the G-shaped elastic pad.
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the inclined groove (2) of the clamping cylinder (1, 1b) provided with the inclined groove (2) and the axis of the clamping cylinder form an included angle of 1-38.66 degrees.
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the clamping cylinder (1, 1b) provided with the chute (2) is characterized in that the included angle between the chute (2) and the axis of the clamping cylinder is 10-25 degrees.
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the clamping cylinder is characterized in that the inclined groove (2) of the clamping cylinder (1, 1b) provided with the inclined groove (2) and the axis of the clamping cylinder form an included angle of 15-20 degrees.
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the inclined groove (2) of the clamping cylinder (1, 1b) provided with the inclined groove (2) and the axis of the clamping cylinder form an included angle of 15.7-17.66 degrees.
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the inclined groove (2) of the clamping cylinder (1, 1b) provided with the inclined groove (2) forms an included angle with the axis of the clamping cylinder of 16.7 degrees.
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the main push rod (8) is provided with an anti-rotation platform (9).
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the anti-rotation device is characterized in that an anti-rotation stop block (13) arranged at the end part of the main body guide seat (15) is provided with an anti-rotation groove (14) so as to be matched with an anti-rotation left platform (5) and an anti-rotation right platform (6) which are arranged on the clamping barrels (1, 1b) provided with the inclined grooves (2).
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the clamping cylinder (1, 1b) provided with the chute (2) is provided with a left rotation preventing platform (5) and a right rotation preventing platform, and the head of the clamping cylinder is also provided with a clamping platform (4) so as to be matched with the piston.
The technical scheme and method adopted for solving the technical problems are an engine with a one-way valve piston noise reduction fence; the automatic clamping and positioning mechanism for simultaneously mounting the two G-shaped elastic pads at the pin end of the piston of the small-sized engine can be used for production, but has the outstanding problem of high rejection rate. Many engine pistons have worn out inlets at the pin end of the piston to render the engine piston unusable; many solutions have been tried and found to be unsatisfactory for several years, but have been solved afterwards in an unexpected way, i.e. the inlet of the piston pin end of the engine piston is not chamfered by the usual bore, the direct mounting of the two G-shaped elastic pads results in a rejection rate of zero, which has been successfully used for several years in production, it is certain that the inlet of the piston pin end of the engine piston is not chamfered by the usual bore, has a bore, and is not chamfered. The reason may be that a certain part of the G-shaped elastic cushion with the opening is inclined when abutting against the chamfer (d18) of the upper pin hole, so that the piston is scrapped, and the piston is good without the chamfer, so that the chamfer (d18) of the pin hole on the drawing of the engine piston is removed, and people do not think before. According to the regulations of machine manufacturing, it is not conceivable that a significant bore such as the inlet of a piston pin end of an engine piston that fits a crankpin, generally speaking, is not the usual chamfer of the bore. On the contrary, under the accidental condition that the chamfer is forgotten to be processed, the piston without the chamfer is placed into an automatic clamping and positioning mechanism which is provided with two G-shaped elastic pads at the same time at the pin end of the piston of the small-sized engine to know that the rejection rate is zero, then the piston pin and the crank connecting rod are assembled, and the whole machine test and export are carried out for several years to confirm the finding; the inlet of the piston pin end of the engine piston is improved into a pin corrugation inlet without common chamfer angles of holes, and the effect is remarkable. If the work is required to be performed without chamfering, burrs are often left.
The invention has the advantages that: the automatic production of improving the engine piston pin end and simultaneously installing two G-shaped elastic cushions is urgent, but the expensive full-automatic high-precision equipment is too expensive, so that enterprises cannot bear the high-precision equipment; the method is a method for simultaneously installing two G-shaped elastic cushions at the pin end of a piston of a small-sized engine, and solves the problem that the simultaneous installation of two G-shaped elastic cushions cannot be realized; the method is developed in practice for many years, is also a crystal of experience at home and abroad, and has the advantages of being beneficial to the auxiliary guide of the piston to ensure the piston to be good, being beneficial to the auxiliary action on mixed gas to reduce the emission of hydrocarbon, and being beneficial to the auxiliary lubrication and heat dissipation; the assembly precision and the product quality are improved; the labor intensity is reduced; promote the popularization and the application of mass automatic feeding equipment and improve the production benefit. The inlet of the piston pin end of the engine piston is improved into a pin corrugation inlet without common chamfer angles of holes, and the effect is remarkable. If the work is required to be performed without chamfering, burrs are often left. The partial assembly of the piston (17) with the cylinder (26) and the auxiliary port (28) also requires auxiliary effects.
The technical scheme and the method for solving the technical problem are as follows:
the engine with the noise reduction fence of the check valve piston is characterized in that two G-shaped elastic cushions are simultaneously installed at the piston pin end of a small engine, and the method is characterized in that the common chamfer of a hole is not needed at the inlet of a piston pin hole at the piston pin end of the engine piston (17), and the non-chamfer position of the hole at the inlet of the piston pin hole is improved into a wave inlet (25); the noise reduction wedge structure is characterized in that a plurality of noise reduction wedges are arranged on the piston surface of the engine piston (17), and three circles of noise reduction wedges are sequentially arranged from the outer circle of the piston surface to the outside and are close to the circle center to form an outer noise reduction wedge (29), a middle noise reduction wedge (30) and an inner noise reduction wedge (31); the outer layer noise reduction wedges (29), the middle layer noise reduction wedges (30) and the inner layer noise reduction wedges (31) are arranged and combined in a plurality of arrays around the circular axis of the piston; the right section (33) of each wedge of the noise reduction wedges is in a trapezoid shape with a large bottom and a small upper part; the right section (33) of each wedge of the noise reduction wedges is in a trapezoid shape with a large bottom and a small upper part, and a through hole (32) is formed in the trapezoid shape; the outer layer noise reduction wedge (29), the middle layer noise reduction wedge (30) and the inner layer noise reduction wedge (31) are respectively provided with a through hole (32); the right section (33) of each wedge of the noise reduction wedges is in a shape of a trapezoid with a large bottom and a small upper part, and a cavity is arranged inside each wedge provided with a through hole (32); the upper surface of each wedge of the plurality of noise reduction wedges is also provided with an oval inlet (34); the wave shape of the wave inlet is prepared by the following steps:
adopting PRO/ENGINEER WILDFIRE drawing software, newly setting a working catalog, newly building parts, and sketching 2 concentric circles;
opening a variable cross-section scanning (Var Sect Sweep) instruction, and selecting the 2 circles as a scanning track and a reference track;
drawing a straight line parallel to the 2-circle plane, wherein the length L is (D-D)/2, and the straight line corresponds to the projection line of the edge of the circle;
set-up PARAMETER (PARAMETER) 1: c real number (real number), which can be assigned between 0.01 and 1 according to specific working conditions, and is taken as 0.3;
set-up PARAMETER (PARAMETER) 2: n integer (integer), can follow the value of selecting between 2-100 according to the concrete working condition, choose 13; the relationship (relationship) is established, i.e. the inventive sine wave equation is:
SDi=C*SIN(TRAJPAR*360*N)
in the above formula, i is a size number serial number; SIN ═ SINE, SINE function; TRAJPAR, trace function;
then, adopting instructions of rotation, combination, materialization and the like;
firstly, manufacturing an electrode on tungsten copper by using a CNC machine tool, and then processing a waveform on a piston by using an electric spark machine tool;
an oil containing groove is further formed in a piston pin hole of the piston pin end of the engine piston (17), the oil containing groove is a wave-shaped extension of an inlet along the axial direction of the hole, and the formed groove is called as the oil containing groove to be beneficial to lubrication between the oil containing groove and the piston pin;
an engine with a piston with an inner filter screen adopts a spark plug (35) which is provided with a protective welding skin (36) and is wrapped beside a discharge electrode (38) so as to be beneficial to the loss of the discharge electrode (38) and a receiving electrode (35); the component of the protective welding skin (36) contains titanium dioxide; the interior of each wedge of the engine with the one-way valve piston noise reduction fence is communicated with a cavity (41), and the space of the cavity is arranged between the piston surface of the engine piston (17) and the layer surface of the upper part of a piston pin hole of the piston pin end of the engine piston (17) to form a buffer gap and a noise reduction space; each wedge of the engine with the built-in wedge piston is provided with at least one escape hole (42) so as to be communicated with the through holes (32) and the oval inlet (34) through the inside of each wedge to form the cavity (41), a plurality of hexagonally-pyramidal built-in wedges (45) are arranged in the lower layer of the cavity (41), hexagonal through holes (44) are arranged at the small end of the hexagonally-pyramidal built-in wedges, and oval outlets (43) are arranged at the large end of the hexagonally-pyramidal built-in wedges to achieve secondary buffering and noise reduction; an engine with a piston inner check valve, wherein a check valve (47) is arranged in the piston, the inlet end of the check valve is connected with the cavity (41), and the outlet end of the check valve is connected with an auxiliary air port (28); when the piston just moves downwards in the explosion process, the one-way valve is closed due to large pressure of the piston surface, so that downward force transmission work is facilitated; when the piston just moves upwards in the exhaust process, the one-way valve is opened due to small pressure of the piston surface, so that the gas near the cavity and the wedge can move to the auxiliary air port (28), and the exhaust valve has the advantages of saving energy, reducing emission, and being beneficial to auxiliary noise reduction and auxiliary scavenging.
The method is characterized in that:
the engine with the noise reduction fence of the check valve piston is characterized in that two G-shaped elastic cushions are simultaneously installed at the piston pin end of a small engine, and the method is characterized in that the common chamfer of a hole is not needed at the inlet of a piston pin hole at the piston pin end of the engine piston (17), and the non-chamfer position of the hole at the inlet of the piston pin hole is improved into a wave inlet (25); the two G-shaped elastic cushions are arranged at the pin end of the piston of the small engine at the same time, so that the small engine is convenient to prevent the shell from being clamped and waste products are avoided; arranging a plurality of noise reduction wedges on the piston surface of the engine piston (17) for further noise reduction, wherein the noise reduction wedges are sequentially arranged into an outer layer noise reduction wedge (29), a middle layer noise reduction wedge (30) and an inner layer noise reduction wedge (31) in three circles from the outside to the position close to the circle center; the outer layer noise reduction wedges (29), the middle layer noise reduction wedges (30) and the inner layer noise reduction wedges (31) are arranged and combined in a plurality of arrays around the circular axis of the piston; the right section (33) of each wedge of the noise reduction wedges is in a trapezoid shape with a large bottom and a small upper part; the right section (33) of each wedge of the noise reduction wedges is in a trapezoid shape with a large bottom and a small upper part, and a through hole (32) is formed in the trapezoid shape; the outer layer noise reduction wedge (29), the middle layer noise reduction wedge (30) and the inner layer noise reduction wedge (31) are respectively provided with a through hole (32); the right section (33) of each wedge of the noise reduction wedges is in a shape of a trapezoid with a large bottom and a small upper part, and a cavity is arranged in each wedge with a through hole (32). When the noise airflow in the process of pressure-in explosion is rushed in from the through hole (32) which is arranged on the trapezoid with a large bottom and a small upper part and has the right section (33) of each wedge of the plurality of noise reduction wedges, when the noise airflow in the pressure-entering and explosion-exhausting process is punched in from the through hole (32) formed on the trapezoid with the large bottom and the small upper part of the right section (33) of each wedge of the plurality of noise-reducing wedges and the oval inlet (34) formed on the upper surface of each wedge of the plurality of noise-reducing wedges, the noise airflow is compressed and then enters the cavity formed in each wedge to be expanded, the expanded noise air flow is compressed again from all the through holes (32) of each wedge of the plurality of noise reduction wedges and then overflows to the outside to be expanded again, therefore, the noise reduction effect of the noise reduction wedges is achieved, and the noise reduction wedges are compressed and expanded again and then expand to consume noise airflow energy. The manufacturing method of the waveform of the wave inlet has the advantages of high precision:
adopting PRO/ENGINEER WILDFIRE drawing software, newly setting a working catalog, newly building parts, and sketching 2 concentric circles;
opening a variable cross-section scanning (Var Sect Sweep) instruction, and selecting the 2 circles as a scanning track and a reference track;
drawing a straight line parallel to the 2-circle plane, wherein the length L is (D-D)/2, and the straight line corresponds to the projection line of the edge of the circle;
set-up PARAMETER (PARAMETER) 1: c real number (real number), which can be assigned between 0.01 and 1 according to specific working conditions, and is taken as 0.3;
set-up PARAMETER (PARAMETER) 2: n integer (integer), can follow the value of selecting between 2-100 according to the concrete working condition, choose 13; the relationship (relationship) is established, i.e. the sine wave equation of the present invention is:
SDi=C*SIN(TRAJPAR*360*N)
in the above formula, i is a size number serial number; SIN ═ SINE, SINE function; TRAJPAR, trace function;
then, adopting instructions of rotation, combination, materialization and the like;
firstly, manufacturing an electrode on tungsten copper by using a CNC machine tool, and then processing a waveform on a piston by using an electric spark machine tool;
an oil containing groove is further formed in a piston pin hole of the piston pin end of the engine piston (17), the oil containing groove is a wave-shaped extension of an inlet along the axial direction of the hole, the formed groove is called as the oil containing groove, and the indium-plated oil groove inlet piston is further improved and is used for lubricating the engine and the piston pin;
the engine with the noise reduction fence of the check valve piston adopts a spark plug (35) which is provided with a protective welding skin (36) and is wrapped beside a discharge electrode (38) so as to be beneficial to the loss of the discharge electrode (38) and a receiving electrode (35); the component of the protective welding skin (36) contains titanium dioxide; the discharge electrode (38) adopts a section of curve of the logarithmic spiral approximately similar to the discharge part of the receiving electrode (35) so as to make the impact pressure tend to be balanced by utilizing the equal characteristic at the pressure angle of the logarithmic spiral as much as possible. An engine with a function connection spark plug adopts a spark plug (35) which is provided with a protective welding skin (36) and is wrapped beside a discharge electrode (38) so as to facilitate the loss of the discharge electrode (38) and a receiving electrode (35); the component of the protective welding skin (36) contains titanium dioxide; the discharge electrode (38) adopts a segment of a curve of a logarithmic spiral approximately similar to the discharge portion of the receiving electrode (35); a flexible metal grid (37) is arranged on a curve section of a discharging part of the receiving electrode (35); the flexible metal grid is woven by silk threads formed by winding platinum wires with molybdenum wires; a kind of function connects the spark plug and connects the junction with high-pressure union to set up a kind of logarithm to connect the hook head (39), it has function to connect arcuate outline, it is similar to a section of the logarithm spiral approximately, in order to utilize the pressure angle of the logarithm spiral equal characteristic everywhere to connect the hook head and make a kind of function connect spark plug and high-pressure union to stop contacting the bad old and difficult problem of the accidental mistake ignition through the said logarithm; a spark plug with movable grid electrode is provided with a movable electrode (40) with welding skin, which is movably arranged in a discharge area between the upper part of a flexible metal grid (37) of a receiving electrode (35) and the lower part of a discharge electrode (38) so as to form two discharge points above and below the movable electrode (40) with welding skin; the interior of each wedge is communicated with a cavity (41), and the space of the cavity is arranged between the piston surface of the engine piston (17) and the layer surface of the upper part of the piston pin hole of the piston pin placing end of the engine piston (17) to form a buffer gap and a noise reduction space; the interior of each wedge of the engine with the one-way valve piston noise reduction fence is communicated with a cavity (41), and the space of the cavity is arranged between the piston surface of the engine piston (17) and the layer surface of the upper part of a piston pin hole of the piston pin end of the engine piston (17) to form a buffer gap and a noise reduction space; the wedges of the engine of the supercharged one-way valve piston are respectively provided with at least one escape hole (42) so as to be communicated with the through holes (32) and the oval inlets (34) through the interiors of the wedges to communicate with the cavity (41) for buffering and noise reduction; the interior of each wedge of the engine with the one-way valve piston noise reduction fence is communicated with a cavity (41), and the space of the cavity is arranged between the piston surface of the engine piston (17) and the layer surface of the upper part of a piston pin hole of the piston pin end of the engine piston (17) to form a buffer gap and a noise reduction space; each wedge of the engine with the one-way valve piston noise reduction fence is provided with at least one escape hole (42) so as to be communicated with the through holes (32) and the oval inlet (34) through the inside of each wedge to form the cavity (41), a plurality of hexagonally-pyramidal built-in wedges (45) are arranged in the lower layer of the cavity (41), hexagonal through holes (44) are arranged at the small ends of the hexagonally-pyramidal built-in wedges, and oval outlets (43) are arranged at the large ends of the hexagonally pyramidal built-in wedges, so that secondary buffering and noise reduction are achieved; the engine with the noise reduction fence of the check valve piston, the piston is internally provided with the check valve, the inlet end of the check valve is connected with the cavity (41), and the outlet end of the check valve is connected with the auxiliary air port (28); when the piston just moves downwards in the explosion process, the one-way valve is closed due to large pressure of the piston surface, so that downward force transmission work is facilitated; when the piston just moves upwards in the discharging process, the one-way valve is opened due to small pressure of the piston surface, so that the gas near the cavity and the wedge can move to the auxiliary air port (28) conveniently, and the device has the advantages of saving energy, reducing emission, assisting in noise reduction and scavenging, facilitating removal of carbon deposit, reducing loss and forming two discharging points for better ignition; the space of the cavity (41) communicated with the interior of each wedge is arranged between the piston surface of the engine piston (17) and the layer surface of the upper part of the piston pin hole of the piston pin end of the engine piston (17), and the expanded glass fiber (46) is filled between the lower layer and the upper layer of the cavity (41) to form a secondary buffer gap and a noise reduction space; an engine of a supercharged check valve piston is characterized in that a check valve (47) is arranged in the piston, the inlet end of the check valve is connected with a cavity (41), and the outlet end of the check valve is connected with an auxiliary air port (28); a pressure increasing spring (48) is arranged below a valve core steel ball of a one-way valve (47) arranged in the piston of the engine with the one-way valve piston noise reduction fence, and the pressure increasing spring (48) is connected with the outlet end of the one-way valve to achieve secondary buffering and noise reduction and boost on the upper part of an auxiliary piston surface; a pressure increasing spring (48) is arranged below a valve core steel ball of a one-way valve (47) arranged in the piston of the engine with the one-way valve piston noise reduction fence, and the pressure increasing spring (48) is connected with the outlet end of the one-way valve; the outlet end of the one-way valve (47) arranged in the piston of the engine with the one-way valve piston noise reduction fence is connected with an auxiliary air port (28) through a noise reduction fence (49); the noise reduction fence (49) is provided with a plurality of noise reduction wedge micropores and a noise reduction fence made of platinum wires.
Drawings
The invention is further illustrated with reference to the following figures and examples.
FIG. 1 is a schematic diagram of an automatic clamping and positioning mechanism for simultaneously mounting two G-shaped elastic pads at the pin end of a piston of a small engine.
Fig. 2 is a perspective view of the main body guide (15).
Fig. 3 is a schematic perspective view of the clamping cylinders (1, 1b) provided with the chute (2).
Fig. 4 is a schematic view of the side of the G-shaped elastic pad (7).
Fig. 5 is a perspective view of the main push rod (8).
Fig. 6 is a schematic view of the side of the piston pin (10).
FIG. 7 is an enlarged side view of the piston pin (10) with fillets (11) and taper (12).
Figure 8 is a schematic perspective view of another angle of the clamping cylinder (1) provided with a chute (2).
Fig. 9 is a perspective view of the chuck (1b) provided with the inclined groove (2).
Figure 10 is a schematic view of the end faces of the clamping cylinders (1, 1b) provided with a chute (2).
Figure 11 is a schematic illustration of a top-down middle section of a chuck (1) provided with a chute (2).
Fig. 12 is a schematic diagram of a top-down middle section of the chuck cylinder (1b) provided with the inclined groove (2).
Fig. 13 is a perspective view of an anti-rotation stopper (13) provided with an anti-rotation groove (14).
Fig. 14 is a perspective view of another angle of the body guide (15).
Fig. 15 is a perspective view of the cylinder mount (16).
Fig. 16 is a cross-sectional view of a piston having a sink groove (18) at both ends for receiving a G-shaped elastic pad (7).
Fig. 17 is an assembly sectional view of the main follower push plate (20), the cylinder push plate (21), and the main follower pull block (22).
Fig. 18 is a schematic view showing the assembly of a part of the piston (17) with the cylinder (26) and the auxiliary port (28).
FIG. 19 is a schematic view of an engine.
Fig. 20 is a schematic view of the assembly of a part of the piston (17) with the auxiliary air port (28).
Fig. 21 is a schematic view of a spark plug.
FIG. 22 is a schematic view of an oval noise reducing wedge.
Fig. 23 is a schematic view of a piston.
Fig. 24 is a schematic view of a spark plug.
FIG. 25 is a schematic view of a noise reduction bar for a check valve piston of an engine having a check valve piston noise reduction bar.
FIG. 26 is a schematic view of a wedge-shaped hole.
In the figure:
1. is a clamping cylinder on the left side which is symmetrical on the left and the right;
1b, a clamping cylinder is arranged on the left side and the right side which are symmetrical;
2. is a chute;
3. is an axial through hole of the clamping cylinder;
4. is a clamping table;
5. is an anti-rotation left platform;
6. is an anti-rotation right platform;
7. is a G-shaped elastic cushion;
8. is a main push rod (8);
9. is an anti-rotation platform (9) of the main push rod (8);
10. is a piston pin;
11. is a chamfer of the piston pin;
12. is the taper of the piston pin;
13. is an anti-rotation stopper (13);
14. is an anti-rotation slot;
15. is a main body guide seat;
16. is a cylinder mounting seat;
17. is a piston;
18. two sinking grooves of the piston are used for placing G-shaped elastic pads (7);
19. is a cylinder;
20. is a main follow-up push plate;
21. is a cylinder push plate;
22. is a main follow-up pull block;
23. is an auxiliary clamp seat;
24. is a stand;
25. a wave inlet;
26. a cylinder (26);
27. an engine;
28. an auxiliary air port (28);
29. outer noise reduction wedges (29);
30. a middle noise reduction wedge (30);
31. inner layer noise reduction wedges (31);
32. a through hole (32) is formed;
33. a wedge-shaped right section (33);
34. an elliptical inlet;
35. a spark plug (35);
36. a protective weld skin (36);
37. a flexible metal mesh (37);
38. a discharge electrode (38);
39. a logarithmic coupling hook (39);
40. a movable electrode (40) with a welding skin;
41. a cavity (41);
42. an escape aperture (42);
43. an elliptical outlet (43);
44. a hexagonal through hole (44);
45. a hexagonal pyramidal built-in wedge (45);
46. an inner filter web (46) of expanded glass fibers;
47. a check valve (47) is arranged in the piston;
48. a compression spring (48);
49. and a noise reduction fence (49).
Detailed Description
The invention is further illustrated with reference to the following figures and examples.
The assembly of the piston and the crank connecting rod has great potential to be dug; the following tooling is described first.
Aiming at the current situation that automatic production for simultaneously installing two G-shaped elastic cushions at the pin end of an engine is urgent, but the current situation that an enterprise is difficult to bear due to the fact that expensive full-automatic high-precision equipment is too high in price is achieved, the method for assembling the piston and the elastic cushions of the crank connecting rods flexibly is disclosed, and the method is a method for simultaneously installing the two G-shaped elastic cushions at the pin end of the piston of the small engine and solves the problem that the simultaneous installation of the two G-shaped elastic cushions cannot be achieved; the method is developed in practice for many years, is also a crystal of experience at home and abroad, and has the beneficial effects of being beneficial to the auxiliary guidance of the piston to ensure the piston to be good; the assembly precision and the product quality are improved; the labor intensity is reduced; promote the popularization and the application of mass automatic feeding equipment and improve the production benefit.
Because only the cylinder is provided with the inclined grooves, the complicated manipulator comprising a plurality of follow-up fingers is skillfully omitted for deformationally clamping the G-shaped elastic pad in an unfixed state, and the device is not only simple, but also easy to operate and easy to use; the core technology is the angle of the chute, namely the included angle between the chute (2) of the clamping cylinder (1, 1b) provided with the chute (2) and the axis of the clamping cylinder is seemingly simple, but is difficult to think out, and a great amount of practice is good; the angle is not proper and fails.
Because the automatic clamping and positioning mechanism for installing two G-shaped elastic pads at the piston pin end of a small engine simultaneously consists of clamping cylinders (1, 1b) provided with chutes (2), a main body guide seat (15), an anti-rotation stop block (13), a main push rod (8), a cylinder installation seat (16), a cylinder (19), a cylinder push plate (21), a main follow-up push plate (20), a main follow-up pull block (22), an auxiliary clamp seat (23) and a machine seat (24), the main body guide seat (15), the cylinder installation seat (16) and the cylinder (19) are symmetrically and sequentially arranged on the left side and the right side of the middle part of the machine seat respectively; a piston (17) provided with a crank connecting rod and a piston pin is arranged in the middle of the engine base, and an auxiliary clamp seat (23) of an auxiliary clamp is arranged on the upper part of the middle of the engine base; the method is characterized in that: the clamping cylinders (1, 1b) provided with the inclined grooves (2) are symmetrically arranged in the main body guide seat (15) at the left and right sides, and the inclined grooves (2) are used for placing G-shaped elastic pads; the main push rod (8) is movably inserted into the clamping cylinders (1, 1b) provided with the inclined grooves (2); the end parts of the main body guide seats (15) are respectively provided with the anti-rotation stop blocks (13); the rear part of the main push rod (8) is provided with the main follow-up push plate (20); the movable extension part of the cylinder (19) is connected with the cylinder push plate (21); the main follow-up pulling block (22) passes through the gap of the main follow-up pushing plate (20) and is connected with the cylinder pushing plate (21), so that the two cylinders are easy to realize the propelling and returning of the two cylinders under the conventional simple electric control of connecting two air passages in parallel.
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the included angle between the inclined groove (2) of the clamping cylinder (1, 1b) provided with the inclined groove (2) and the axis of the clamping cylinder is more than 1 degree; an axial through hole (3) is arranged in the clamping cylinders (1, 1b) provided with the inclined grooves (2) so as to facilitate the main push rod (8) to pass through; the chute is a radial through hole and is only communicated with the upper cylinder wall but not communicated with the lower cylinder wall; the chute is a rectangle with two parallel sides in a top view; it is longer than 10mm and wider than 0.8mm to fit loosely into the G-shaped elastic pad. Because only the cylinder is provided with the inclined grooves, the complicated manipulator comprising a plurality of follow-up fingers is skillfully omitted for deformationally clamping the G-shaped elastic pad in an unfixed state, and the device is not only simple, but also easy to operate and easy to use. Failure without angle, because it has no radial component, cannot be installed.
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the inclined groove (2) of the clamping cylinder (1, 1b) provided with the inclined groove (2) and the axis of the clamping cylinder form an included angle of 1-38.66 degrees. Since the outside diameter of the pads is 10mm and the inside diameter of the pin-receiving inlets of the wrist pin and piston is 8mm, the tangent angle ARCTAN (θ. 8/10) is 38.66 degrees if the two legs of the calculated right triangle are 8 and 10, respectively.
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the clamping barrel with the inclined grooves (2) (1, 1b) is characterized in that the inclined grooves (2) and the axis of the clamping barrel form an included angle of 10-25 degrees, and the effect is good.
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the clamping barrel with the inclined grooves (2) (1, 1b) is characterized in that the inclined grooves (2) and the axis of the clamping barrel form an included angle of 15-20 degrees, and the effect is better.
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the clamping cylinder (1, 1b) provided with the chute (2) is characterized in that the included angle between the chute (2) and the axis of the clamping cylinder is 15.7-17.66 degrees, and the effect is remarkable.
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the clamping cylinder (1, 1b) provided with the chute (2) is characterized in that the included angle between the chute (2) and the axis of the clamping cylinder is 16.7 degrees, and the effect is remarkable and good.
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the main push rod (8) is provided with an anti-rotation platform (9) for limiting the rotation freedom.
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the end part of the main body guide seat (15) is provided with an anti-rotation stop block (13) which is provided with an anti-rotation groove (14) so as to be matched with an anti-rotation left platform (5) and an anti-rotation right platform (6) which are arranged on the clamping cylinders (1, 1b) provided with the inclined grooves (2) to limit the rotation freedom.
Further experiment is improved the automatic clamping positioning mechanism who installs two G type cushion simultaneously at small-size engine piston round pin end, characterized by: the clamping cylinder (1, 1b) provided with the chute (2) is provided with a left rotation preventing platform (5) and a right rotation preventing platform, and the head of the clamping cylinder is also provided with a clamping platform (4) so as to be matched with the piston.
Because the piston pin is inserted into the 8mm hole of the piston well, the chamfer angle of the piston pin and the oblique taper of the piston pin are provided, but the function is also provided, so that a gap is formed between the pin and the hole, a gap between the sinking groove and the pin end of the piston is added, a gap between the groove of the sinking groove and the non-circular elastic pad is added, the G-shaped elastic pad is manually placed, the deformation at two sides is different, the piston pin is oblique actually, the elastic pads are arranged twice, the piston pin is inclined, one side is more, the other side is less, one end of the piston pin is closer to the elastic pad sinking groove, and the balance of the rotational inertia and the energy conservation and emission reduction; the automatic clamping and positioning mechanism which is changed to be used for installing two G-shaped elastic pads at the end of a piston pin of a small engine at the same time is improved.
The over-constraint of directly screwing the main push rod by the extending part of the cylinder is failed, because the direct screwing of the extending parts of the two opposite cylinders to the main push rod and the sliding fit of other parts cannot be over-precise; the over-constraint is overcome only by using a follow-up push-pull mechanism consisting of a main follow-up push plate, a cylinder push plate and a main follow-up pull block, namely the main follow-up push plate (20) is arranged at the rear part of the main push rod (8); the movable extension part of the cylinder (19) is connected with the cylinder push plate (21); the main follow-up pulling block (22) passes through the gap of the main follow-up pushing plate (20) and is connected with the cylinder pushing plate (21), so that the push-pull mechanism is easy to use and performs reciprocating action.
An auxiliary clamp seat (23) of an auxiliary clamp is arranged at the upper part of the middle part of the machine seat, and the auxiliary clamp seat is provided with a conventional clamp which is not shown because of the conventional structure; a piston (17) provided with a crank connecting rod and a piston pin is arranged in the middle of the engine base, and the crank connecting rod and the piston pin are not shown in the figure but do not influence the implementation of reciprocating motion.
The clamping cylinders (1, 1b) provided with the inclined grooves (2) are symmetrically arranged in the main body guide seat (15) at the left and right sides, and the inclined grooves (2) are used for placing G-shaped elastic pads; the main push rod (8) is movably inserted into the clamping cylinders (1, 1b) provided with the inclined grooves (2); placing into G-shaped elastic pad, or manually or by automatic feeding equipment.
The invention has the advantages that: the automatic production of improving the engine piston pin end and simultaneously installing two G-shaped elastic cushions is urgent, but the expensive full-automatic high-precision equipment is too expensive, so that enterprises cannot bear the high-precision equipment; the method is a method for simultaneously installing two G-shaped elastic cushions at the pin end of a piston of a small-sized engine, and solves the problem that the simultaneous installation of two G-shaped elastic cushions cannot be realized; the method is developed in practice for many years, is also a crystal of experience at home and abroad, and has the advantages of being beneficial to the auxiliary guide of the piston to ensure the piston to be good, being beneficial to the auxiliary action on mixed gas to reduce the emission of hydrocarbon, and being beneficial to the auxiliary lubrication and heat dissipation; the assembly precision and the product quality are improved; the labor intensity is reduced; promote the popularization and the application of mass automatic feeding equipment and improve the production benefit.
The automatic clamping and positioning mechanism for simultaneously mounting the two G-shaped elastic pads at the pin end of the piston of the small-sized engine can be used for production, but has the outstanding problem of high rejection rate. Many engine pistons have worn out inlets at the pin end of the piston to render the engine piston unusable; many solutions have been tried and found to be unsatisfactory for several years, but have been solved afterwards in an unexpected way, i.e. the inlet of the piston pin end of the engine piston is not chamfered by the usual bore, the direct mounting of the two G-shaped elastic pads results in a rejection rate of zero, which has been successfully used for several years in production, it is certain that the inlet of the piston pin end of the engine piston is not chamfered by the usual bore, has a bore, and is not chamfered. The reason may be that a certain part of the G-shaped elastic cushion with the opening is inclined when abutting against the chamfer (d18) of the upper pin hole, so that the piston is scrapped, and the piston is good without the chamfer, so that the chamfer (d18) of the pin hole on the drawing of the engine piston is removed, and people do not think before. According to the regulations of machine manufacturing, it is not conceivable that a significant bore such as the inlet of a piston pin end of an engine piston that fits a crankpin, generally speaking, is not the usual chamfer of the bore. On the contrary, under the accidental condition that the chamfer is forgotten to be processed, the piston without the chamfer is placed into an automatic clamping and positioning mechanism which is provided with two G-shaped elastic pads at the same time at the pin end of the piston of the small-sized engine to know that the rejection rate is zero, then the piston pin and the crank connecting rod are assembled, and the whole machine test and export are carried out for several years to confirm the finding; the inlet of the piston pin end of the engine piston is improved into a pin corrugation inlet without common chamfer angles of holes, and the effect is remarkable. If the work is required to be performed without chamfering, burrs are often left. The partial assembly of the piston (17) with the cylinder (26) and the auxiliary port (28) also requires auxiliary effects.
Bright spot:
an engine with a booster check valve piston is provided with a movable mesh electrode spark plug with a welding skin movable electrode (40) which is movably arranged on a flexible metal grid (37) of a receiving electrode (35) and in a discharge area between a discharge electrode (38) so as to form two discharge points above and below the movable mesh electrode (40). The spark plug (35) is provided with a protective welding skin (36) and is wrapped beside the discharge electrode (38) so as to be beneficial to the loss of the discharge electrode (38) and the receiving electrode (35); the component of the protective welding skin (36) contains titanium dioxide. When two G-shaped elastic pads are simultaneously installed at the piston pin end of a small engine, the common chamfer angle of the hole is not needed at the inlet of the piston pin end of the engine piston, the chamfer-free position of the hole is improved into a pin wave inlet, and then the pin wave inlet is improved into an indium-plated oil groove inlet piston, so that the effect is remarkable. Burrs are easy to remain when the processing is required to be carried out without chamfering; a logarithmic connection hook (39) is provided in the connection portion of a spark plug with functional connection and a high-voltage connector, and has an arc outline of functional connection, which is a section similar to a logarithmic spiral, so that the old and difficult problem of poor contact caused by accidental sparking is solved by utilizing the characteristic that the pressure angle of the logarithmic spiral is equal everywhere through the logarithmic connection hook.
The engine with the noise reduction fence of the check valve piston adopts a spark plug (35) which is provided with a protective welding skin (36) and is wrapped beside a discharge electrode (38) so as to be beneficial to the loss of the discharge electrode (38) and a receiving electrode (35); the component of the protective welding skin (36) contains titanium dioxide; installing two G-shaped elastic pads at the piston pin end of a small engine simultaneously, which is characterized in that the inlet of a piston pin hole at the piston pin end of the engine piston (17) is improved into a wave inlet (25) without a chamfer angle of a common hole; the two G-shaped elastic cushions are arranged at the pin end of the piston of the small engine at the same time, so that the small engine is convenient to prevent the shell from being clamped and waste products are avoided; in order to further arrange noise reduction wedges, a plurality of noise reduction wedges are arranged on the piston surface of the engine piston (17), and the noise reduction wedges are sequentially arranged into an outer layer noise reduction wedge (29), a middle layer noise reduction wedge (30) and an inner layer noise reduction wedge (31) in three circles from the outside to the position close to the circle center; the outer layer noise reduction wedges (29), the middle layer noise reduction wedges (30) and the inner layer noise reduction wedges (31) are arranged and combined in a plurality of arrays around the circular axis of the piston; the right section (33) of each wedge of the noise reduction wedges is in a trapezoid shape with a large bottom and a small upper part; the right section (33) of each wedge of the noise reduction wedges is in a trapezoid shape with a large bottom and a small upper part, and a through hole (32) is formed in the trapezoid shape; the outer layer noise reduction wedge (29), the middle layer noise reduction wedge (30) and the inner layer noise reduction wedge (31) are respectively provided with a through hole (32); the right section (33) of each wedge of the noise reduction wedges is in a shape of a trapezoid with a large bottom and a small upper part, and a cavity is arranged in each wedge with a through hole (32). When the noise airflow in the process of pressure-in explosion-discharge is rushed in from the through hole (32) formed on the trapezoid with a large bottom and a small upper part of the right section (33) of each wedge of the plurality of noise reduction wedges and the oval inlet (34) formed on the upper surface of each wedge of the plurality of noise reduction wedges, the noise airflow is compressed, when noise airflow in the process of pressure-entering and explosion-discharging rushes in through holes (32) formed in a trapezoid with a large bottom and a small upper part of the right section (33) of each wedge of the plurality of noise-reducing wedges, the noise airflow is compressed and then enters a cavity arranged in each wedge to be expanded, the expanded noise air flow is compressed again from all the through holes (32) of each wedge of the plurality of noise reduction wedges and then overflows to the outside to be expanded again, therefore, the noise reduction effect of the noise reduction wedges is achieved, and the noise reduction wedges are compressed and expanded again and then expand to consume noise airflow energy. An engine with a piston with an inner filter screen adopts a spark plug (35) which is provided with a protective welding skin (36) and is wrapped beside a discharge electrode (38) so as to be beneficial to the loss of the discharge electrode (38) and a receiving electrode (35); the component of the protective welding skin (36) contains titanium dioxide. The piston surface is provided with a plurality of noise reduction wedges, and the noise reduction wedges are sequentially arranged into outer layer noise reduction wedges (29), middle layer noise reduction wedges (30) and inner layer noise reduction wedges (31) in three circles from the outside to the position close to the circle center; the right section (33) of each wedge of the noise reduction wedges is in a trapezoid shape with a large bottom and a small upper part, and a through hole (32) is formed in the trapezoid shape; the interior of each wedge is hollow. When noise airflow in the process of pressure-entering and explosion-exhausting is rushed in or extruded from a through hole (32) formed in a trapezoid with a large bottom and a small upper part and an oval inlet (34) of the right section (33) of each wedge of the noise-reducing wedges, the noise-reducing effect of the noise-reducing wedges, which is compressed and expanded again and then expanded, for consuming noise airflow energy is achieved.
PRO/ENGINEER WILDFIRE drawing software is adopted to newly set a work catalog, newly set parts and draft 2 concentric circles.
The variable cross-section scanning (Var search Sweep) command is turned on, and the above 2 circles are selected as the scanning track and the reference track.
Drawing a straight line parallel to the 2-circle plane, wherein the length L is (D-D)/2, and the straight line corresponds to the projection line of the circle edge.
Set-up PARAMETER (PARAMETER) 1: the real number (real number) of C can be assigned between 0.01 and 1, for example, 0.3, according to specific working conditions.
Set-up PARAMETER (PARAMETER) 2: the integer N, may be selected between 2 and 100, for example 13, depending on the particular operating condition. The relationship (relationship) is established, i.e. the sine wave equation of the present invention is:
SDi=C*SIN(TRAJPAR*360*N);
in the above formula, i is a size number serial number; SIN ═ SINE, SINE function; TRAJPAR, trace function.
Then, the instructions of rotation, combination, materialization and the like are adopted.
It should be noted that other waveforms may be used, such as other mathematical functions or other somewhat rounded waveforms that are not sharp fold lines.
Firstly, manufacturing an electrode on tungsten copper by using a CNC machine tool, and then processing a waveform on a piston by using an electric spark machine tool; the piston pin hole of putting the piston pin end of engine piston (17) is downthehole, still establishes including the oil groove, including the oil groove is the wave form of import along the axial extension of hole, and the groove that forms is called including the oil groove, and further improvement is an indium-plated oil groove import piston again for the engine, do benefit to and the piston pin between lubricated.
The engine with the one-way valve piston noise reduction fence is characterized in that a plurality of noise reduction wedges are arranged on the piston surface, and three circles of noise reduction wedges are sequentially arranged from outside to outside and are close to the circle center as an outer layer noise reduction wedge (29), a middle layer noise reduction wedge (30) and an inner layer noise reduction wedge (31); through holes (32) are formed on the noise reduction wedges; the interior of each wedge is hollow. When noise airflow in the process of pressure-entering and explosion-exhausting is rushed in or extruded from a through hole (32) formed in a trapezoid with a large bottom and a small upper part and an oval inlet (34) of the right section (33) of each wedge of the noise-reducing wedges, the noise-reducing effect of the noise-reducing wedges, which is compressed and expanded again and then expanded, for consuming noise airflow energy is achieved. Firstly, the waveform parameter equation is processed into an electrode on tungsten copper by a CNC machine tool, and then the waveform is processed on a piston by an electric spark machine tool. An oil containing groove is also arranged in the piston pin hole for placing the piston pin end, the oil containing groove is an oil containing groove formed by extending the wave-shaped inlet along the axial direction of the hole, and the oil containing groove is further improved into an indium-plated oil groove which is beneficial to the lubrication between the oil containing groove and the piston pin; a spark plug (35) used for an engine of a supercharged one-way valve piston is provided with a protective welding skin (36) and covers a discharge electrode (38) to facilitate the loss of the discharge electrode (38) and a receiving electrode (35); the component of the protective welding skin (36) contains titanium dioxide; the discharge electrode (38) adopts a section of curve of the logarithmic spiral approximately similar to the discharge part of the receiving electrode (35) so as to make the impact pressure tend to be balanced by utilizing the equal characteristic at the pressure angle of the logarithmic spiral as much as possible. The curved section of the discharge part of the receiving electrode (35) is provided with a flexible metal grid (37); the flexible metal grid is woven by platinum wires and molybdenum wires.
The method has the advantages of saving energy, reducing emission, and being beneficial to removing carbon deposit, reducing loss and leading the impact pressure to tend to be balanced.
The invention has the beneficial effects and aims to save energy, reduce emission, and is beneficial to removing carbon deposit and reducing loss; the device is matched with a function wave combustion chamber to improve the efficiency, improve the working condition of the combustion chamber, obtain the effect of emission reduction reaching the standard, and can be selected by various machine types. But the invention that people pursue perfection is endless ever, and the piston and scavenging have great potential to dig. The so-called optimal geometry of the combustion chamber and the piston is of course important but has to be adapted to the engine model and to the ignition device in order to achieve a better result. Particularly, the fuel economy of the two-stroke gasoline engine is poorer than that of the four-stroke gasoline engine, and the emission of hydrocarbon in tail gas is always overproof; the matching of a combustion chamber and a piston of the internal combustion engine, an ignition device and scavenging is an old and difficult problem related to energy conservation and emission reduction. People know that the discharge of the secondary flushing machine exceeds the standard, but no people can thoroughly solve the problem; although the spark ignition process and the detailed physicochemical process are very complex and still unknown in many aspects, we probably can preliminarily think that although the mechanism of the atomic scale is yet to be explored in the future, the beneficial effect is self-evident, the service life of the electrode is prolonged and the carbon deposition is favorably removed. The method is favorable for wedge collision and turbulence effect of mixed gas, the collision and the turbulence are also favorable for repelling carbon molecular flow, and the mixture with liquefaction tendency in the gap has not only the opportunity of electric arc discharge but also drum-shaped discharge similar to electric spark machining discharge, thereby improving the quality of spark discharge and having better working condition performance due to the comprehensive effect. The discharge electrode (38) adopts a section of curve of the logarithmic spiral approximately similar to the discharge part of the receiving electrode (35) so as to make the impact pressure tend to be balanced by utilizing the equal characteristic at the pressure angle of the logarithmic spiral as much as possible. An engine with a piston with an inner filter screen adopts a spark plug (35) which is provided with a protective welding skin (36) and is wrapped beside a discharge electrode (38) so as to be beneficial to the loss of the discharge electrode (38) and a receiving electrode (35); the component of the protective welding skin (36) contains titanium dioxide; the discharge electrode (38) adopts a segment of a curve of a logarithmic spiral approximately similar to the discharge portion of the receiving electrode (35); a flexible metal grid (37) is arranged on a curve section of a discharging part of the receiving electrode (35); the flexible metal grid is woven by platinum wires and molybdenum wires.
The engine with the noise reduction fence of the check valve piston adopts a spark plug (35) which is provided with a protective welding skin (36) and is wrapped beside a discharge electrode (38) so as to be beneficial to the loss of the discharge electrode (38) and a receiving electrode (35); the component of the protective welding skin (36) contains titanium dioxide. A plurality of noise reduction wedges are arranged on the piston surface, and through holes (32) are formed in the noise reduction wedges; the interior of each wedge is hollow. The wavy axial extension of the piston pin hole, which is provided with an inlet, is an oil-containing groove, and the oil-containing groove is further improved into an indium-plated oil groove which is beneficial to the lubrication between the piston pin hole and the indium-plated oil groove. The discharge electrode (38) adopts a curve of a logarithmic spiral approximately similar to the discharge portion of the receiving electrode (35) in order to make the impact pressure tend to be equalized by making the most use of the characteristic of equality at the pressure angle of the logarithmic spiral. The discharge electrode (38) adopts a segment of a curve of a logarithmic spiral approximately similar to the discharge portion of the receiving electrode (35); a flexible metal grid (37) is arranged on a curve section of a discharging part of the receiving electrode (35); the flexible metal grid is woven by wires formed by winding molybdenum wires around platinum wires, so that the discharge quality of the spark plug is improved although the cost is high. A spark plug with movable grid electrode is provided with a movable electrode (40) with welding skin, which is movably arranged in a discharge area between the upper part of a flexible metal grid (37) of a receiving electrode (35) and the lower part of a discharge electrode (38) so as to form two discharge points above and below the movable electrode (40) with welding skin; the cavities (41) are communicated with each other, and the space of the cavity is arranged between the piston surface of the engine piston (17) and the layer surface of the upper part of the piston pin hole of the piston pin end of the engine piston (17) to form a buffer gap and a noise reduction space. The connecting part of the spark plug and the high-voltage connector with the function connection is internally provided with a logarithmic connection hook head (39) which has an arc outline of the function connection and is a section similar to a logarithmic spiral approximately, so that the old and difficult problem of poor contact caused by accidental sparking in the connection of the spark plug and the high-voltage connector with the function connection can be solved by utilizing the characteristic that the pressure angle of the logarithmic spiral is equal everywhere through the logarithmic connection hook head. The interior of each wedge of the engine with the one-way valve piston noise reduction fence is communicated with a cavity (41), and the space of the cavity is arranged between the piston surface of the engine piston (17) and the layer surface of the upper part of a piston pin hole of the piston pin end of the engine piston (17) to form a buffer gap and a noise reduction space; the wedges of the engine with the one-way valve piston noise reduction fence are respectively provided with at least one escape hole (42) so as to be communicated with the through holes (32) and the oval inlets (34) through the interiors of the wedges to form the cavity (41) for buffering and noise reduction; the interior of each wedge of the further improved engine with the inner filter screen piston is communicated with a cavity (41), and the space of the cavity is arranged between the piston surface of the engine piston (17) and the upper layer surface of a piston pin hole at the piston pin placing end of the engine piston (17) to form a buffer gap and a noise reduction space; each wedge of the engine with the built-in wedge piston is provided with at least one escape hole (42) so as to be communicated with the through holes (32) and the oval inlet (34) through the inside of each wedge to form the cavity (41), a plurality of hexagonally-pyramidal built-in wedges (45) are arranged in the lower layer of the cavity (41), hexagonal through holes (44) are arranged at the small end of the hexagonally-pyramidal built-in wedges, and oval outlets (43) are arranged at the large end of the hexagonally-pyramidal built-in wedges to achieve secondary buffering and noise reduction. An inner filter screen (46) of expanded glass fiber is arranged between the lower layer and the upper layer of the cavity (41) to further improve secondary buffering and noise reduction; an engine of a supercharged check valve piston is characterized in that a check valve (47) is arranged in the piston, the inlet end of the check valve is connected with a cavity (41), and the outlet end of the check valve is connected with an auxiliary air port (28); when the piston just moves downwards in the explosion process, the one-way valve is closed due to large pressure of the piston surface, so that downward force transmission work is facilitated; when the piston just moves upwards in the exhaust process, the one-way valve is opened due to small pressure of the piston surface, so that the gas near the cavity and the wedge can move to the auxiliary air port (28), and the exhaust valve has the advantages of saving energy, reducing emission, and being beneficial to auxiliary noise reduction and auxiliary scavenging. Each wedge is provided with at least one escape hole (42) so as to be communicated with the plurality of through holes (32) and the oval inlet (34) through the inside of each wedge to form the cavity (41), a plurality of hexagonally-pyramidal built-in wedges (45) are arranged in the lower layer of the cavity (41), hexagonal through holes (44) are arranged at the small ends of the hexagonally-pyramidal built-in wedges, oval outlets (43) are arranged at the large ends of the hexagonally-pyramidal built-in wedges, and an inner filter screen (46) for bulking glass fibers is arranged between the lower layer and the upper layer of the cavity (41) so as to achieve secondary buffering and noise reduction; the piston is internally provided with a one-way valve (47), the inlet end of the one-way valve is connected with the cavity (41), and the outlet end of the one-way valve is connected with the auxiliary air port (28); when the piston just moves downwards in the explosion process, the one-way valve is closed due to large pressure of the piston surface, so that downward force transmission work is facilitated; when the piston just moves upwards in the discharging process, the one-way valve is opened due to small pressure of the piston surface, so that the gas near the cavity and the wedge can move to the auxiliary air port (28) conveniently, and the auxiliary air-discharging exhaust valve has the advantages of saving energy, reducing emission, and being beneficial to auxiliary noise reduction, auxiliary scavenging and pressurization of the upper part of the auxiliary piston surface. The engine with the noise reduction fence of the check valve piston is characterized in that a check valve (47) is arranged in the piston, the inlet end of the check valve is connected with the cavity (41), and the outlet end of the check valve is connected with an auxiliary air port (28); a pressure increasing spring (48) is arranged below a valve core steel ball of a one-way valve (47) arranged in the piston, and the pressure increasing spring (48) is connected with the outlet end of the one-way valve to achieve secondary buffering, noise reduction and auxiliary pressurization on the upper part of the piston surface. A pressure increasing spring (48) is arranged below a valve core steel ball of a one-way valve (47) arranged in the piston of the engine with the one-way valve piston noise reduction fence, and the pressure increasing spring (48) is connected with the outlet end of the one-way valve; the outlet end of the one-way valve (47) arranged in the piston of the engine with the one-way valve piston noise reduction fence is connected with an auxiliary air port (28) through a noise reduction fence (49); the noise reduction fence (49) is provided with a plurality of noise reduction wedge micropores and a noise reduction fence made of platinum wires.
Claims (1)
1. When two G-shaped elastic cushions are simultaneously installed at the piston pin end of a small-sized engine, the engine with the one-way valve piston noise reduction fence is characterized in that the inlet of a piston pin hole at the piston pin end of the engine piston (17) is not required to be chamfered commonly, but the non-chamfered part of the hole at the inlet of the piston pin hole is improved into a wavy inlet (25); the noise reduction wedge structure is characterized in that a plurality of noise reduction wedges are arranged on the piston surface of the engine piston (17), and three circles of noise reduction wedges are sequentially arranged from the outer circle of the piston surface to the outside and are close to the circle center to form an outer noise reduction wedge (29), a middle noise reduction wedge (30) and an inner noise reduction wedge (31); the outer layer noise reduction wedges (29), the middle layer noise reduction wedges (30) and the inner layer noise reduction wedges (31) are arranged and combined in a plurality of arrays around the circular axis of the piston; the right section (33) of each wedge of the noise reduction wedges is in a trapezoid shape with a large bottom and a small upper part; the right section (33) of each wedge of the noise reduction wedges is in a trapezoid shape with a large bottom and a small upper part, and a through hole (32) is formed in the trapezoid shape; the outer layer noise reduction wedge (29), the middle layer noise reduction wedge (30) and the inner layer noise reduction wedge (31) are respectively provided with a through hole (32); the right section (33) of each wedge of the noise reduction wedges is a trapezoid with a large bottom and a small upper part, and the inside of each wedge is provided with a communication cavity (41) of a through hole (32); the upper surface of each wedge of each noise reduction wedge is also provided with an oval inlet (34); the wave shape of the wave inlet is prepared by the following steps:
adopting PRO/ENGINEER WILDFIRE drawing software, newly setting a working catalog, newly building parts, and sketching 2 concentric circles;
opening a variable cross-section scanning (Var Sect Sweep) instruction, and selecting the 2 circles as a scanning track and a reference track;
drawing a straight line parallel to the 2-circle plane, wherein the length L is (D-D)/2, and the straight line corresponds to the projection line of the edge of the circle;
set-up PARAMETER (PARAMETER) 1: c real number (real number), which can be assigned between 0.01 and 1 according to specific working conditions, and is taken as 0.3; set-up PARAMETER (PARAMETER) 2: n integer (integer), can follow the value of selecting between 2-100 according to the concrete working condition, choose 13; the relationship (relationship) is established, i.e. the sine wave equation of the present invention is:
SDi=C*SIN(TRAJPAR*360*N)
in the above formula, i is a size number serial number; SIN ═ SINE, SINE function; TRAJPAR, trace function;
then, adopting instructions of rotation, combination, materialization and the like;
firstly, manufacturing an electrode on tungsten copper by using a CNC machine tool, and then processing a waveform on a piston by using an electric spark machine tool;
an oil containing groove is further formed in a piston pin hole of the piston pin end of the engine piston (17), the oil containing groove is a wave-shaped extension of an inlet along the axial direction of the hole, the formed groove is called as the oil containing groove, and the indium-plated oil groove inlet piston is further improved to be used for an engine so as to be beneficial to lubrication between the piston pin and the engine;
the engine with the noise reduction fence of the check valve piston adopts a spark plug (35) which is provided with a protective welding skin (36) and is wrapped beside a discharge electrode (38) so as to be beneficial to the loss of the discharge electrode (38) and a receiving electrode (35); the component of the protective welding skin (36) contains titanium dioxide; the discharge electrode (38) adopts a segment of a curve of a logarithmic spiral approximately similar to the discharge portion of the receiving electrode (35); a flexible metal grid (37) is arranged on a curve section of a discharging part of the receiving electrode (35); the flexible metal grid is woven by silk threads formed by winding platinum wires with molybdenum wires; a logarithmic connection hook head (39) is arranged in the connection part of the spark plug and the high-voltage connector, has an arc outline of function connection and is a section similar to a logarithmic spiral approximately, so that the old and difficult problem of poor contact caused by accidental mis-ignition can be solved by connecting the spark plug and the high-voltage connector through the logarithmic connection hook head by utilizing the equal characteristics of pressure angles of the logarithmic spiral; a spark plug with movable grid electrode is provided with a movable electrode (40) with welding skin, which is movably arranged in a discharge area between the upper part of a flexible metal grid (37) of a receiving electrode (35) and the lower part of a discharge electrode (38) so as to form two discharge points above and below the movable electrode (40) with welding skin; the interior of each wedge of the engine with the one-way valve piston noise reduction fence is communicated with a cavity (41), and the space of the cavity is arranged between the piston surface of the engine piston (17) and the layer surface of the upper part of a piston pin hole of the piston pin end of the engine piston (17) to form a buffer gap and a noise reduction space; each wedge of the engine with the inner filter screen piston is provided with at least one escape hole (42) so as to be communicated with the through holes (32) and the oval inlet (34) through the inside of each wedge to form the cavity (41), a plurality of hexagonally-pyramidal built-in wedges (45) are arranged in the lower layer of the cavity (41), hexagonal through holes (44) are arranged at the small ends of the hexagonally-pyramidal built-in wedges, oval outlets (43) are arranged at the large ends of the hexagonally pyramidal built-in wedges, and an inner filter screen (46) of expanded glass fibers is arranged between the lower layer and the upper layer of the cavity (41) to achieve secondary buffering and noise reduction; the engine with the noise reduction fence of the check valve piston is characterized in that a check valve (47) is arranged in the piston, the inlet end of the check valve is connected with the cavity (41), and the outlet end of the check valve is connected with an auxiliary air port (28); a pressure increasing spring (48) is arranged below a valve core steel ball of a one-way valve (47) arranged in the piston of the engine with the one-way valve piston noise reduction fence, and the pressure increasing spring (48) is connected with the outlet end of the one-way valve; the outlet end of the one-way valve (47) arranged in the piston of the engine with the one-way valve piston noise reduction fence is connected with an auxiliary air port (28) through a noise reduction fence (49); the noise reduction fence (49) is provided with a plurality of noise reduction wedge micropores and a noise reduction fence made of platinum wires.
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CN201911195613.4A CN111336027A (en) | 2019-11-22 | 2019-11-22 | Engine with one-way valve piston noise reduction fence |
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CN201911195613.4A CN111336027A (en) | 2019-11-22 | 2019-11-22 | Engine with one-way valve piston noise reduction fence |
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CN201911195613.4A Withdrawn CN111336027A (en) | 2019-11-22 | 2019-11-22 | Engine with one-way valve piston noise reduction fence |
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Application publication date: 20200626 |