| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 101 | 一种具有压力放大功能的液压阀及起重机液压系统 | CN201420550634.X | 2014-09-24 | CN204226318U | 2015-03-25 | 陈登民; 张洪波; 李楠; 戚振红 |
| 本实用新型公布一种具有压力放大功能的液压阀及起重机液压系统。它包括油箱、控制各执行机构动作的多路阀和为多路阀供油的变量泵;多路阀中设有多个用于将各执行机构中最高压力油反馈到变量泵变量机构中的梭阀;在最高压力油至变量泵变量机构的油路中设有压力放大阀。该阀的主要功能是可以实现对负载反馈压力的放大,从而能够使得通过对梭阀系统所获取的负载反馈压力能够真实反应执行元件的工作状态,从而使得变量泵的负载敏感系统可以更加精确的跟随负载压力的变化进行补偿,进而实现执行机构动作的精确性。 | ||||||
| 102 | 一种带有负载反馈的液压控制系统 | CN201420510799.4 | 2014-09-05 | CN204041573U | 2014-12-24 | 毛恩荣; 陈随英; 谢斌 |
| 一种带有负载反馈的高度控制液压系统,包括液压泵和液压油缸,所述液压系统中还包括由定差减压阀和2个单向阀组成的负载反馈回路,所述定差减压阀的进油口连接液压泵的供油路,定差减压阀的出油口连接液压泵的回油路,所述液压油缸的进、回油路上各连接所述单向阀的进油口,所述单向阀的出油口均连接定差减压阀的控制油口。能够依据生产中外负载的大小变化调节输出到执行元件的液压油量,提高了系统的控制精度,减小了系统的能耗损失;通过双向液压锁具有较高的锁止精度;多级并联并以插装形式集成在一个阀体内,提高了液压元件的利用率,简化了液压系统的结构,进而使系统的整机布置更为简单,可广泛应用于高地隙自走式农用机械提升装置。 | ||||||
| 103 | 起重机微动控制系统 | CN201320588762.9 | 2013-09-24 | CN203926173U | 2014-11-05 | 孙丽; 张东; 余钦伟 |
| 本实用新型公开一种起重机微动控制系统,包括:压力传感器,设置在液压马达的测压接口上以第一时间间隔周期性地向压力比较器发送实时测量的液压马达压力值;压力比较器,计算液压马达在上次停止前的瞬间压力值与当前接收到的液压马达压力值之间的差值;PID控制器,根据接收到的差值计算电流增加坡度值;电流控制单元,利用电流增加坡度值和预先设定的控制电流值产生逐步增加的控制电流,并将产生的控制电流提供给液压泵。本实用新型从补偿整个液压控制回路泄漏的角度出发进行微动控制,避免液压马达出现冲击、抖动或下滑等问题。 | ||||||
| 104 | 一种新型的液压随动控制单元 | CN201320616351.6 | 2013-10-08 | CN203584927U | 2014-05-07 | 张伟; 侯杰 |
| 本实用新型公开了一种新型的液压随动控制单元,包括三位四通换向阀第一、第一两位四通换向阀、三位四通换向阀第三、三位四通换向阀第四、两位或三位四通换向阀第五、第二两位四通换向阀,所述外接油口包括连接泵送油泵压力油的P1、连接泵送油缸的A1和B1、连接分配油泵的压力油的P2、连接分配油缸的A1和B1、连接控制压力油的P3、连接换向信号压力油的X1和X2、接通油箱的T1、T2和T3。本实用新型是一种系统可靠性高、组合性强、可用于但不限于混凝土泵用液压随动控制单元。 | ||||||
| 105 | 基于液压试验台的压力控制装置 | CN201320337972.0 | 2013-06-13 | CN203297176U | 2013-11-20 | 胡世松; 杨帆; 熊熙程; 国凯 |
| 本实用新型公开一种基于液压试验台的压力控制装置。它包括比例伺服阀、A口压力传感器、B口压力传感器和控制器,被试阀的P口与油源连接,被试阀的T口与回油箱连接,被试阀的A口与比例伺服阀的P口连接,被试阀的B口与比例伺服阀的B口连接,比例伺服阀的A、T口分别与密闭容腔连通,A口压力传感器与被试阀的A口连接,B口压力传感器与被试阀的B口连接,A口压力传感器的电信号输出端、B口压力传感器的电信号输出端和被试阀的指令信号输出端分别与控制器的输入端连接,控制器的输出端与比例伺服阀的指令输入端连接。本实用新型可解决通过被试阀的流量变化率大小变化以及方向变化时工作油口的压力精确控制问题。 | ||||||
| 106 | 径向井作业的油管控制液压系统 | CN201220194597.4 | 2012-05-03 | CN202597294U | 2012-12-12 | 成心建; 谢志双; 赵江; 费克林 |
| 本实用新型公开了一种径向井作业的油管控制液压系统,包括油箱、梭阀、至少一个滚筒液压马达、与各自滚筒液压马达配套的液压制动器、负载敏感轴向柱塞变量泵、减压阀和负载敏感比例阀,负载敏感变量柱塞泵的出油口与负载敏感比例阀的进油口相连,负载敏感变量柱塞泵的负载反馈口与负载敏感比例阀的负载反馈口相连,减压阀设于两负载反馈口之间的油路上,负载敏感比例阀的两工作油口A2、B2分别与梭阀各自对应的进、回油口A11、B11相连,梭阀的两工作油口与所有滚筒液压马达各自对应的一油口相连,所述梭阀的中位与所有滚筒液压制动器相连。本实用新型能避免油管在回收时因卡住被拉断,安全性好,确保径向井作业的顺利进行。 | ||||||
| 107 | 一种长螺旋钻机用动力头 | CN201220179628.9 | 2012-04-25 | CN202578490U | 2012-12-05 | 张庆伟; 徐金立; 朱安平; 宋建强; 赵新奇; 冷伦; 李威 |
| 本实用新型公开了一种长螺旋钻机用动力头,包括驱动系统,驱动系统包括变量液压马达以及通过供油管路给液压马达供油的液压系统、对变量液压马达的排量进行调节的比例阀以及将供油管路上的压力信号传输给比例阀的控制器,供油管路上设置有压力表和/或压力传感器,控制器的信号输入端与手动控制的档位开关的信号输出端和/或压力传感器的信号输出端相连,控制器的信号输出端与比例阀的信号输入端相连,本实用新型中的压力传感器和/或压力表将系统的压力信号传给控制器,控制器给比例阀一个控制流量的指令信号,比例阀根据指令信号控制液压马达的排量,作出相应转速的调节使钻机以较高的效率实施钻进,实现根据地层阻力的不同调整转速。 | ||||||
| 108 | 一种双钢轮压路机行走驱动液压系统 | CN201120489734.2 | 2011-11-30 | CN202369898U | 2012-08-08 | 綦开隆; 王群锋 |
| 本实用新型公开了一种双钢轮压路机行走驱动液压系统,包括发动机、行走泵、管路一、阀块、行走马达一和行走马达二,管路一的一端与行走泵的油口A连接,管路一的另一端与管路三连接,管路三的一端与电磁阀一连接,管路三的另一端与行走马达一连接,管路五的一端与行走马达一连接,管路五的另一端与电磁阀二连接,管路六的一端与电磁阀二连接,管路六的另一端与行走马达二连接,管路四的一端与行走马达二连接,管路四的另一端与电磁阀一连接,油路二的一端连接在管路六上,油路二的另一端与管路二的一端连接,管路二的另一端与行走泵的油口B连接。该双钢轮压路机行走驱动液压系统结构简单、使用方便,便于推广使用。 | ||||||
| 109 | 游梁式液压抽油机 | CN02244361.4 | 2002-08-08 | CN2561926Y | 2003-07-23 | 刘长年 |
| 本实用新型涉及一种游梁式液压抽油机,它由机械和液压两部分组成。其中机械部分保留原有的游梁、驴头、支架、底盘和悬绳器及悬绳;液压部分包括四腔油缸、主蓄能器、换向系统、油源和辅助系统。油缸杆与游梁后力臂端部之间有轴承连接与特殊驴头连接两种方式。该机通过主蓄能器、油缸和换向系统完成平衡与抽油功能;通过辅助系统实现节能、运动上快下慢、超断载停机报警、液位停机报警、温度停机报警、冲程冲次连续可调和消除抽油杆偏磨等功能。该机效率高、寿命长、运动平稳和重量轻。 | ||||||
| 110 | DYNAMIC TESTING SYSTEM DIAGNOSTICS | EP24197417.9 | 2024-08-29 | EP4517106A1 | 2025-03-05 | HENNEN, James; KUGEL, Ian; BYRON, Tom; CARLSON, Kevin; THURMES, Kevin |
A dynamic testing system includes a test station and at least one controller. The test station includes a hydraulic actuator configured to drive an actuation of a test subject using a hydraulic fluid flow, and a control valve that includes a housing, a valve body contained within the housing having a position that controls a flow rate and direction of the hydraulic fluid flow, a valve body driver configured to adjust the position of the valve body based on a reference signal, and a valve position sensor configured to output a position signal that is indicative of the position of the valve body. The at least one controller is configured to obtain a current position of the valve body using the position signal, obtain a diagnostic reference, detect a diagnostic condition based on a difference between the current position and the diagnostic reference, and generate a diagnostic signal.
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| 111 | MONITORING OF VALVE CONTROLLER AND ITS COMPONENTS | EP15184920.5 | 2015-09-11 | EP3141973B1 | 2020-01-01 | PRIISHOLM, Thomas; MADSEN, Karsten Schack; LUND HENRIKSEN, Axel |
| 112 | HYDRAULIC DRIVE SYSTEM | EP05852725.0 | 2005-12-01 | EP1828618A2 | 2007-09-05 | KADLICKO, George |
| A hydraulic drive system for an actuator uses a pair of pressure compensated hydraulic machines to control flow to and from the drive chambers of the actuator by varying the controlled pressure of one of the machines. The machines are mechanically coupled to permit energy recovery and charge an accumulator to store supplies energy. The drive system may be combined with other services including a transmission for incorporation in a vehicle. The transmission uses a pressure compensated supply and torque control of the wheels. | ||||||
| 113 | DUAL VALVE FLUID ACTUATOR ASSEMBLY | PCT/US2018/017868 | 2018-02-12 | WO2018152069A1 | 2018-08-23 | POON, Alex, Ka Tim; CHOI, Yeong-jun; YANG, Pai-Hsueh; LEE, Sandy; KESWANI, Gaurav; MAI, Rocky |
A stage assembly (10) includes a stage (14), and a fluid actuator assembly (24) that moves the stage (14). The fluid actuator assembly (24) includes a piston housing (32) that defines a piston chamber (34); (ii) a piston (36) that separates the piston chamber (34) into a first chamber (34A) and a second chamber (34B); (iii) a supply valve (38C) that controls the flow of the working fluid (40) into the first chamber (34A); and (iv) an exhaust valve (38D) that controls the flow of the working fluid (40) out of the first chamber (34A). The supply valve (38C) has a supply orifice (250G) having a supply orifice area, and the exhaust valve (38D) has an exhaust orifice (352G) having an exhaust orifice area. Moreover, the supply orifice area is different from the exhaust orifice area. Further multiple valves of different sizes can be used in combination for the supply and exhaust for each chamber (34A), (34B). |
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| 114 | AGRICULTURAL IMPLEMENT WITH ELECTRO-HYDRAULIC CYLINDERS | PCT/US2015/012685 | 2015-01-23 | WO2015112862A1 | 2015-07-30 | HAHN, Dustan; ROLFFS, Merlan; MULHERIN, John P.; ACHEN, Courtney N.; VOLZ, Gary; NOLTE, Steve; LEGGE, Ryan; SCHILDROTH, Rhett |
An agricultural implement includes the use of one or more electromechanical hydraulic cylinder assembly in place of hydraulic cylinders. The assemblies may take various forms for actuation, and can convert an electric power source to hydraulic power for use on or with the implement. A control system is also provided for connecting to a tractor to provide control information to the assemblies or to a central hydraulic supply via a ISOBUS that rebroadcasts input controls from a source, such as a tractor used in conjunction with the agricultural implement. |
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| 115 | ENERGY RECOVERY SYSTEM FOR HYDRAULIC MACHINE | PCT/US2014/016083 | 2014-02-12 | WO2014130324A1 | 2014-08-28 | MA, Pengfei; SHANG, Tonglin; ZHANG, Jiao; CHEN, Dayao; WEN, Gang Victor |
An energy recovery system (50) is disclosed for use with a hydraulic machine (10). The energy recovery system may have a tank (60), a pump (58) configured to draw fluid from the tank and pressurize the fluid, an actuator (28), and an actuator control valve (202) movable to direct pressurized fluid from the pump to the actuator and from the actuator to the tank to move the actuator. The energy recovery system may also have a motor (241) mechanically connected to a rotary device (58,59) and configured to selectively receive fluid discharged from the actuator, and at least one valve (254, 256) movable to selectively redirect fluid exiting the motor back to the actuator. |
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| 116 | SERVO SYSTEM AUGMENTED WITH AN ACTIVE MATERIAL COMPONENT | PCT/US2009030899 | 2009-01-14 | WO2009091767A8 | 2009-10-15 | MANKAME NILESH D; BUCKNOR NORMAN K; BROWNE ALAN L; ALEXANDER PAUL W; WHITMARSH BRIAN W; JOHNSON NANCY L; POWELL STEPHEN W; USORO PATRICK B; GAO XIUJIE |
| A servo system includes pressurized fluid, and one or more fluid control devices (FCD) such as a valve or actuator, with at least one FCD having an element with a variable property that varies in response to a stimulus. The FCD controls a flow rate or pressure transmission of the fluid within the servo system. The element may include an active return spring having a variable stiffness. The servo system may operate as an interlock system for a transmission. A method for moving an output load using a servo system includes providing a first FCD with an active element, connecting an output load to a second FCD, activating the active element with a stimulus to vary a property of the active element, transmitting a force from the pressurized fluid to the second FCD, and moving the output load from a first position to a second position in response to the force. | ||||||
| 117 | VALVE ACTUATOR SYSTEM | PCT/DK2008/050233 | 2008-09-26 | WO2009039856A1 | 2009-04-02 | JAKOBSEN, Poul Elholm |
Valve actuator system and a system for operation of valves, which valve comprises a valve housing, which valve housing comprises at least one inlet and at least one outlet, which valve housing further comprises a valve closing element, which valve element is mechanical connected to a valve actuator, which valve actuator comprises at least one piston, which piston is moved in a housing by a pressurised fluid in at least one direc¬ tion, which valve actuator is connected to a control valve which control valve regulates a flow of a liquid medium from a pressure source to a first cavity chamber in the hosing of the valve actuator where the valve is a sanitary valve primarily for regulation of a flow of Fluid food, which valve actuator is activated by a liquid medium. |
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| 118 | A METHOD OF CONTROLLING THE FORCE OF A PNEUMATIC ACTUATING DEVICE | EP20808190.1 | 2020-10-30 | EP4052110A1 | 2022-09-07 | ROMEO, Rocco Antonio; PUCCI, Daniele; FIORIO, Luca; ROSSI, Marco |
| 119 | VALVE ACTUATOR SYSTEM | EP08801409.7 | 2008-09-26 | EP2201277A4 | 2017-10-18 | JAKOBSEN, Poul Elholm |
| 120 | AGRICULTURAL IMPLEMENT WITH ELECTRO-HYDRAULIC CYLINDERS | EP15702934.9 | 2015-01-23 | EP3096598A1 | 2016-11-30 | HAHN, Dustan; ROLFFS, Merlan; MULHERIN, John P.; ACHEN, Courtney N.; VOLZ, Gary; NOLTE, Steve; LEGGE, Ryan; SCHILDROTH, Rhett |
| An agricultural implement includes the use of one or more electromechanical hydraulic cylinder assembly in place of hydraulic cylinders. The assemblies may take various forms for actuation, and can convert an electric power source to hydraulic power for use on or with the implement. A control system is also provided for connecting to a tractor to provide control information to the assemblies or to a central hydraulic supply via a ISOBUS that rebroadcasts input controls from a source, such as a tractor used in conjunction with the agricultural implement. | ||||||
