The invention relates to the field of machinery, in particular to engine braking technology, especially a multifunctional engine brake.
In the prior art, the conventional engine valve drive technology for the engine ignition is well known and its application has a history of more than one hundred years. However, for the additional requirements on engine emissions and engine braking, more and more engines need different valve motions than conventional valve motions, such as exhaust gas recirculation valve motions that reduce emissions, variable valve motions that increase fuel efficiency (including cylinder cutout with valve motions of zero lift) and engine braking valve motions that slow down the vehicle.
In order to obtain the variable valve motion, for example, from the conventional valve motion to the engine brake valve motion, people often need to add an auxiliary valve drive mechanism (VDM for short) to the conventional VDM, such as a top-mounted brake housing or an integrated brake rocker arm, etc. The structure and control are very complicated, and most of them open the engine valves by hydraulic loading.
The common variable valve motion is a lost-motion type. By changing the linkage between the cam and the valve, some or all of the cam motion is lost and cannot be transmitted to the valve, resulting in reduction or even complete elimination of the valve motion (cylinder cutout). Obviously, the valve motion of the lost-motion type will not completely follow the motion of the cam, and the seating velocity of the valve cannot be controlled by the cam.
The linkage between the cam and the valve can be roughly divided into the fixed chain type and the hydraulic type. Most of VDMs for conventional engine ignition are fixed chain type, with cam direct driving the valve or forming a fixed chain type VDM with solid-to-solid contact through rigid connectors such as a rocker arm (or a push rod and a valve bridge). The cam of the hydraulic variable valve drive mechanism (VVDM for short) is hydraulically linked to the valve, and a (built-in) valve catch (a valve seating mechanism) needs to be provided between the cam and the valve to control the seating velocity of the valve when motion is lost to avoid impact inside the drive mechanism.
For the fixed chain VVDM, there will also be times when the valve motion does not follow the cam motion, such as falling off inside the drive mechanism and valve no-following (bouncing back), which will cause the valve seating velocity to be out of control. Unfortunately, the valve seating mechanism for the hydraulic VVDM cannot be applied to the fixed chain VDM.
The applicant disclosed an engine VVDM by shifting roller in his invention patent application (authorized publication number CN 1043146333 B) on Oct. 15, 2014. The roller drive mechanism shifts the cam roller between the first axial position and the second axial position on the roller shaft through a roller fork, so that the cam roller is connected with different cams and different engine valve events are generated. The roller drive mechanism comprises a piston and a spring, the piston is connected with one end of the roller fork, the other end of the roller fork is provided with two separated guide holes, the two separated guide holes are sleeved on the roller shaft and clamp the cam roller in the middle, and the movement of the piston is transmitted to the cam roller through the roller fork. The engine VVDM from shifting roller can be used for engine cylinder cutout, engine braking, engine exhaust gas recirculation, engine starting and closing, etc.
The above-mentioned fixed chain VVDM by shifting roller still faces two problems. The first is that the roller drive mechanism drives the roller through the roller fork, which is complicated in structure and installation, and the roller fork will generate asymmetric offset load on the roller. The other is that since the brake oil feeding (and brake oil discharging) from the brake oil feed valve is random and not timed (the brake oil feed valve is turned on randomly and the oil can flow to the roller driver at any position/phase of the cam), when the roller moves from one axial position to another axial position on the roller shaft, it is possible to create a transition across two cams of different heights (one cam is in the high position and the other cam is in the low position, rather than two cams are at the same height), resulting in falling off and impact of the roller from the high cam to the low cam.
The invention aims to provide a multifunctional engine brake, which aims to solve the technical problems in the prior art that the variable valve movement mechanism and the installation thereof are complicated and asymmetric loads exist.
Further, the present invention aims to provide a seating velocity control device for slowing down the valve seating velocity, which solves the technical problem that the fixed chain VVDM in the prior art may have high valve seating velocity and impact noise.
Further, it is an object of the present invention to provide a timed oil feed method and mechanism for driving an engine brake (including a shift roller mechanism), which aims to solve the technical problem in the prior art that the roller falls off and impacts from the high cam to the low cam due to the randomness of oil feeding or discharging by the feed valve to the roller drive mechanism.
The multifunctional engine brake of the present invention comprises an engine valve motion conversion mechanism, and it is characterized in that the engine valve motion conversion mechanism comprises camshaft, roller, roller shaft, roller shaft housing and an axial roller driving mechanism, the camshaft is provided with two or more different cams, the roller shaft housing is provided with a roller groove, both ends of the roller shaft are mounted into the roller shaft housing, the middle of the roller shaft spans the roller groove, the length of the roller shaft in the roller groove is longer than the axial length of the roller, and the roller is arranged on the roller shaft in a rotatable way. The roller is also slidable axially and has two or more axial positions on the roller shaft, the axial roller driving mechanism comprises a piston driving mechanism arranged in the roller shaft, the piston driving mechanism in the roller shaft moves the roller from one axial position to another axial position on the roller shaft, and different engine valve motions are generated by switching the links between the roller and the different cams.
Further, the two or more different cams include a conventional cam and an engine brake cam, and the different engine valve motions include a conventional valve motion and an engine brake valve motion.
Further, the piston drive mechanism comprises a drive piston and a drive spring arranged in the roller shaft, wherein one end of the drive piston is acted by fluid and the other end of the drive piston is acted by the drive spring, and the drive piston drives the roller on the roller shaft through a connector.
Further, the connector comprises at least one drive pin, one end of the drive pin is mounted on the drive piston in the roller shaft, the other end of the drive pin is connected with the roller on the roller shaft, and the middle part of the drive pin passes through an axial groove on the roller shaft.
Further, the camshaft is parallel to the roller shaft, and the roller is linked to only one of the two or more different cams at each axial position on the roller shaft, and the cam generates corresponding engine valve motion.
Further, the multifunctional engine brake further comprises a seating velocity control mechanism, wherein the seating velocity control mechanism is arranged between one end of the roller shaft housing and the engine valve, and the seating velocity control mechanism comprises a positioning mechanism and a flow limiter, and the flow through the flow limiter decreases with the reduction of engine valve seating distance.
Further, the positioning mechanism comprises a connector and a position adjuster, one end of the connector is fixed on the engine, the position adjuster is arranged at the other end of the connector, the flow limiter is arranged in the roller shaft housing, and a positioning lash is arranged between the position adjuster and the roller shaft housing or the flow limiter.
Further, the multifunctional engine brake also comprises a directional valve mechanism, which controls the oil feeding and discharging of the axial roller drive mechanism.
Further, the multifunctional engine brake further comprises an accumulator which reduces oil pressure fluctuation so that the axial roller drive mechanism can feed oil continuously and stably.
Further, the multifunctional engine brake also comprises an oil control timing mechanism, which comprises a timing valve system to control the timing or phase of oil feeding or discharging of the engine brake.
Further, the roller shaft housing comprises a rocker arm of the engine, and the timing valve system comprises a directional valve, wherein the directional valve is positioned in the rocker arm; when the rocker arm rotates to a predetermined angle, the timing valve system is turned on, the directional valve in the rocker arm is shifted, and oil is fed to or discharged from the engine brake.
Further, the timing valve system further comprises a timing piston and a timing piston stop mechanism, wherein the timing piston is positioned in the rocker arm at a predetermined position by the timing piston stop mechanism, wherein the timing piston closes the oil passage to the directional valve; When the cam drives the rocker arm to rotate, the timing piston makes a relative movement in the rocker arm. When the relative movement is greater than a predetermined distance, the timing piston opens the oil passage to the directional valve, the directional valve in the rocker arm is shifted, and oil is fed to or discharged from the engine brake.
The invention also discloses an oil control timing method for driving the engine brake, which comprises an oil control timing process for controlling the oil feeding time or the oil discharging time of the engine brake by using an oil control timing mechanism, wherein the engine brake comprises a non-timing brake oil feed valve, the oil control timing mechanism comprises a timing oil path and a timing valve system, the timing oil path connects the brake oil feeding valve with the timing valve system, and the timing valve system controls the time or phase of oil feeding to or oil discharging from the engine brake, and it is characterized in that the oil control timing process comprises the following steps: firstly, turning on the brake oil feeding valve; Secondly, the timing valve system is turned on for a predetermined period of time or phase within the engine cycle, and finally, oil is fed to or discharged from the engine brake.
Further, the timing valve system includes a directional valve located in the rocker arm of the engine. When the rocker arm rotates to a predetermined angle, the timing valve system opens an oil passage to the directional valve, oil pressure drives the directional valve in the rocker arm to move, and oil is fed to or discharged from the engine brake.
Further, the timing valve system further comprises a timing piston and a timing piston stop mechanism, wherein the directional valve and the timing piston are positioned in the rocker arm of the engine, the timing piston is positioned at a predetermined position by the timing piston stop mechanism, and in the predetermined position, the timing piston closes the oil passage to the directional valve; When the cam drives the rocker arm to rotate, the timing piston makes a relative movement in the rocker arm. When the relative movement is greater than a predetermined distance, the timing piston opens the oil passage to the directional valve, oil pressure drives the directional valve in the rocker arm to move, and oil is fed to or discharged from the engine brake.
The working principle of the invention: when it is necessary to convert the normal ignition operation of the engine into other operation modes (e.g. engine braking), the valve motion control mechanism (e.g. brake oil feed valve) is turned on, the axial roller drive mechanism moves the roller between different axial positions on the roller shaft, and the connection between the roller and different cams (e.g. ignition cam and brake cam) is switched to generate different engine valve motions (e.g. ignition valve motion and brake valve motion).
During the above-mentioned conversion of engine operation modes, if there is a falling off in the inside of the fixed-chain VVDM and the valve is out of control to have a high velocity seating, the seating velocity control mechanism will generate more and more resistance to the rocker arm or valve bridge of the fixed-chain VVDM, make its motion slower and slower, thus effectively slow down and control the valve's seating velocity.
Another effective way to reduce falling off inside the VVDM is to use an oil control timing (oil feeding and discharging) mechanism. When the no-timing brake oil feed valve is turned on or off to feed or discharge oil randomly, the engine brake will not necessarily to follow to turn on or off immediately, but oil is fed to or discharged from the engine brake through the timing valve system of the oil control timing mechanism at a predetermined timing or phase within the engine cycle (for example, when the rocker arm of the engine rotates within a predetermined angle range), so that the engine brake is timed (at a predetermined time or phase) to turn on or off.
Compared with the prior art, the present invention has positive and obvious effects. According to the invention, the drive mechanism in the roller shaft moves the roller to different axial positions on the roller shaft to realize the conversion of different engine valve motions. The axial roller drive mechanism is placed in the roller shaft, which has the advantages of simple and compact structure, symmetrical and reliable loading, easy manufacture and assembly, convenient and wide application, etc. Since different cams are independent of each other, their performance can be optimized. For example, the brake cam includes at least one but not more than four brake lobes, resulting in four-stroke braking, two-stroke braking, or one-point five-stroke braking. Transmission of load through mechanical linkage eliminates the defects or failure modes of traditional hydraulic engine brakes such as high oil pressure, high deformation, high leakage and hydraulic jacks caused by hydraulic loading.
In addition, the present invention supplies oil to the engine brake through the oil control timing mechanism, so that the engine brake is turned on at its correct timing, that is to say, the axial position of the engine roller on the roller shaft can be changed only within a predetermined period of time or phase within the engine cycle, so that the roller will not fall off and cause impact during the transition period from one cam's high position to another cam's low position, and the reliability, stability and durability of the roller shifting mechanism are increased.
Furthermore, the seating velocity control mechanism of the present invention can also effectively slow down and control the seating velocity of the valve and the internal impact of the axial roller drive mechanism in event that there is a falling off in the inside of the fixed chain VVDM, such as when the roller slides from the high position of one cam to the low position of the other cam.
Embodiment 1
The end of the rocker arm 210 close to the valve 301 may also be provided with a seating velocity control mechanism 250, which is composed of a positioning mechanism and a flow limiter (
When it is necessary to convert the engine ignition valve motion into the engine braking valve motion, the engine brake oil feed valve 50 is turned on to feed oil to the engine brake. The oil flows into the drive piston bore 190 from the brake oil passage, such as the axial hole 211 in the rocker shaft 205, the oil hole 214 in the rocker arm 210, and the oil hole 215 in the roller shaft 231. One side (right side in
When engine brake is not required, the engine brake oil feed valve 50 is turned off to discharge oil from the engine brake, and without oil pressure the drive piston 160 moves to the right under the action of the drive spring 156, which moves the roller 235 to the axial position shown in
When the roller 235 moves from one axial position to another axial position on the roller shaft 231, a falling off (from a high position of one cam to a low position of the other cam) and impact may occur between the roller 235 and the cam 230 or 2302. The seating velocity control mechanism 250 may be used to eliminate or reduce such impact. Once such falling off happens, it will result in a large gap (or separation) in the valve drive chain. The engine oil (lubricating oil) enters the flow limiting piston bore 254 through the lubricating oil passage, such as the axial oil passage 151 in the rocker arm shaft 205, the oil hole 153 in the rocker arm 210 and the oil hole 261 in the adjusting screw 110 shown as
It is noted that the above description applies to both exhaust and intake valves as well as single and double valve actuation.
Embodiment 2
When engine braking is required, the engine brake oil feed valve 50 is turned on to feed oil (brake oil feeding) to the directional piston bore 690 from the brake oil passage, such as the axial hole 211 in the rocker arm shaft 205 and the oil hole 213 in the rocker arm 210. One side (right side in
When the engine brake is not required, the engine brake oil feed valve 50 is turned off to discharge oil (brake oil discharging), and without oil pressure, the directional piston 660 moves rightward under the action of the directional spring 656 to reach the position shown in
Embodiment 3
The seating velocity control mechanism of embodiment 3 includes a flow limiter 550 and a positioning mechanism 500 (
When the rocker arm 210 is separated from the positioning mechanism 500 (engine body) (the valve 300 opens downward), the buffer piston 560 moves outward (upward) from the piston bore 590 in the rocker arm 210 until the pin 141 of the stop mechanism stops the buffer piston 560 through the annular groove 537. At this time, the flow limit mechanism 550 is in the “high position” (
When the rocker arm 210 is getting close to the positioning mechanism 500 (engine body) (the valve 300 is seating and closing upward), the positioning mechanism 500 (adjusting bolt 501) prevents the upward movement of the buffer piston 560, and the buffer piston 560 moves inward (downward) in the piston bore 590 of the rocker arm 210, so that the flow rate of the flow limit valve 575 becomes smaller, and the pressure (also the resistance acting on the rocker arm 210) in the hydraulic chamber 562 between the buffer piston 560 and the piston hole 590 increases, slowing down the movement of the rocker arm 210 and the seating velocity of the engine valve 300. When the buffer piston 560 approaches or rests on the bottom surface of the piston bore 590, the flow limit mechanism 550 is in the “low position” (
The fixed chain type VVDM may also suffer a situation that the valve seating velocity is too high. For example, the valve bounces off, the roller falling off between the cams or in the VDM, all of which will cause the opened valve to get out of control and to have a high velocity seating. For example, when the roller 235 in
Embodiment 4
The upper end of the buffer piston 560 has a profile 564 for controlling the discharging flow rate, forming a spool valve. The lower end of the buffer piston 560 is a guide rod 563 located in a guide hole 573 in the rocker arm 210. In order to form a closed hydraulic chamber 562 between the buffer piston 560 and the piston bore 590, a one-way valve 170 (
When the rocker arm 210 is separated from the positioning mechanism 500 (engine body) (the valve 300 opens downward), the buffer piston 560 moves outward (upward) from the piston bore 590 of the rocker arm 210 until the snap ring 142 of the stop mechanism stops the buffer piston 560 (
When the rocker arm 210 is getting close to the positioning mechanism 500 (engine body) (the valve 300 is seating and closing upward), the positioning mechanism 500 (adjusting bolt 501) prevents the movement of the buffer piston 560, but the rocker arm 210 continues to move upward under the push of the valve 300, causes the buffer piston 560 to move inward (downward) in the piston bore 590 of the rocker arm 210, reducing the discharging flowrate of the flow limit valve 575, increasing the pressure in the hydraulic chamber 562 between the buffer piston 560 and the piston bore 590 (also the resistance acting on the rocker arm 210), slow down the movement of the rocker arm 210 and the seating velocity of the engine valve 300.
The flow limiter shown here may also be arranged in the valve bridge of the engine, and the valve body of the flow limiter needs not be a sphere or a cylinder, and its shape, size, position and installation mode may all be altered.
Embodiment 5
When the engine braking is required, the brake oil feed valve 50 (the usual oil feed valve without timing function which can be turned on or off at a random engine timing) is turned on to feed oil to the timing piston 772 through the timing oil passage 713. However, at this time, the timing piston 772 is held still by the timing piston stop mechanism 700, so that the timing oil passage 714 to the directional valve 660 remains closed, and the directional valve 660 is pressed against the bottom of the piston bore 690 by the spring 656, closing the oil feed passage 113 to the engine brake 100. When the cam of the engine drives the rocker arm 210 to rotate, the rocker arm 210 and the timing piston 772 are separated from the timing piston stop mechanism 700, and the timing piston 772 is forced upward in the rocker arm by oil from the brake oil feed valve 50 in the timing oil passage 713. When the relative movement of the timing piston 772 within the rocker arm is greater than a predetermined distance, the timing oil passage 714 to the directional valve 660 is opened (
When the engine braking is not required, the brake oil feed valve 50 (the conventional oil feed valve without timing function which can be turned on or off at a random engine timing) is turned off, and the oil in the directional valve bore 690 in
Embodiment 6
When the engine braking is required, the brake oil feed valve 50 (the conventional valve without timing function which can be turned on or off at a random engine timing) is turned on to feed oil to the timing oil passage 713 in the second rocker arm 220 through the oil passage 211 in the rocker arm shaft 205. However, at this time, the outlet 715 of the timing oil passage 713 in the second rocker arm 220 and the outlet 716 of the timing oil passage 714 in the first rocker arm 210 are misaligned (
When the engine braking is not required, the brake oil feed valve 50 (the conventional oil feed valve without timing function which can be turned on or off at a random engine timing) is turned off to discharge oil, but only when the outlet 715 of the timing oil passage 713 in the second rocker arm 220 intersects or overlap with the outlet 716 of the timing oil passage 714 in the first rocker arm 210 and the timing oil passages 713 and 714 are connected, the oil from the directional valve bore 690 can be forced to discharge from the timing oil passages 714 and 713 as well as the oil passage 211 in the rocker arm 205 to the brake oil feed valve 50. At this time, the directional valve 660, without oil pressure, moves toward the bottom (right) of the bore 690 under the action of the spring 656, closes the oil feed passage 113 to the engine brake 100 and simultaneously opens the oil discharge passage 167 of the engine brake 100 (
In general, with the oil control timing mechanism of the present invention, the on or off of the engine brake 100 does not necessarily occur at the time when the brake oil feed valve 50 is turned on or off, but at a predetermined time or timing within the engine cycle when the valve timing system of the oil control timing mechanism is turned on.
The above description contains different specific embodiments, which should not be regarded as limiting the scope of the present invention, but as some specific examples representing the present invention from which many other variations are possible. For example, the multifunctional engine brake shown here can be used not only for top-mounted cam engines, but also for push rod/push tube engines. It can be used not only to drive the exhaust valve but also to drive the intake valve. It can be used not only for valve motion of engine braking, but also for exhaust gas recirculation, cold start, cylinder cutout and other engine variable valve motions.
In addition, many mechanisms shown here, such as the axial roller drive mechanism, the directional valve mechanism, the timing valve mechanism, the accumulator and the rocker arm mechanism, can have different shapes, sizes, positions and mounting modes.
Also, the engine brake here includes not only the roller shifting mechanism, two-stroke brake or one-point five-stroke brake, but also other forms of engine brake mechanisms and methods.
So the scope of the present invention should not be determined by the specific examples described above, but by the appended claims and their legal equivalents.
Number | Date | Country | Kind |
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2016 1 0176380 | Mar 2016 | CN | national |
2016 1 0905887 | Oct 2016 | CN | national |
2017 1 0166614 | Mar 2017 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2017/077783 | 3/23/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/162182 | 9/28/2017 | WO | A |
Number | Name | Date | Kind |
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7980211 | Ihlemann | Jul 2011 | B2 |
Number | Date | Country |
---|---|---|
102477880 | May 2012 | CN |
102650224 | Aug 2012 | CN |
104314633 | Jan 2015 | CN |
104314636 | Jan 2015 | CN |
104358600 | Feb 2015 | CN |
204140153 | Feb 2015 | CN |
204163782 | Feb 2015 | CN |
204212827 | Mar 2015 | CN |
104712396 | Jun 2015 | CN |
105715323 | Jun 2016 | CN |
102007049074 | Apr 2009 | DE |
102010011827 | Sep 2011 | DE |
06185322 | Jul 1994 | JP |
Entry |
---|
International Preliminary Report on Patentability for PCT/CN2017/077783, filed Jun. 27, 2017. |
International Search Report for PCT/CN2017/077783, filed Jun. 27, 2017. |
Written Opinion for PCT/CN2017/077783, filed Jun. 27, 2017. |
European Application No. EP 17769459.3, Search Report, dated Sep. 12, 2019. |
Number | Date | Country | |
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20190072012 A1 | Mar 2019 | US |