Hydraulic system with cross function regeneration
First Claim
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1. A regeneration method for a hydraulic system having a first actuator and a hydraulic power converting device, said regeneration method comprising the steps of:
- draining hydraulic fluid under pressure from the actuator;
sensing pressure of the hydraulic fluid drained from the actuator to produce an indication of a first pressure;
sensing pressure of hydraulic fluid at an inlet of the hydraulic power converting device to produce an indication of a second pressure;
determining when the fist pressure is greater than the second pressure; and
in response to making the determination and when a flow rate of fluid from the actuator is a predefined amount greater than a flow rate desired for fluid supplied to the hydraulic power converting device, selectively routing the hydraulic fluid drained from the actuator to the inlet of the hydraulic power converting device thereby driving the hydraulic power converting device.
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Abstract
A regeneration method for a hydraulic system enables the fluid being forced from a first actuator to be used to power a second actuator. Often the force of the load acting on a hydraulic actuator is used to move the actuator into a given position which motion forces fluid from the actuator. Rather than simply draining that fluid to the system tank, the fluid is routed to a second actuator to be powered when the pressure of the fluid draining at the first actuator is greater than the pressure required to power the second actuator. At other times the draining fluid can be used to drive the pump which has been configured to operate as a motor thereby driving the prime mover connected to the pump. Alternatively the draining fluid can be routed to an accumulator where it is stored under pressure until needed to power an actuator of the system. A unique bidirectional pilot operated poppet valve.
157 Citations
26 Claims
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1. A regeneration method for a hydraulic system having a first actuator and a hydraulic power converting device, said regeneration method comprising the steps of:
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draining hydraulic fluid under pressure from the actuator;
sensing pressure of the hydraulic fluid drained from the actuator to produce an indication of a first pressure;
sensing pressure of hydraulic fluid at an inlet of the hydraulic power converting device to produce an indication of a second pressure;
determining when the fist pressure is greater than the second pressure; and
in response to making the determination and when a flow rate of fluid from the actuator is a predefined amount greater than a flow rate desired for fluid supplied to the hydraulic power converting device, selectively routing the hydraulic fluid drained from the actuator to the inlet of the hydraulic power converting device thereby driving the hydraulic power converting device. - View Dependent Claims (2, 3, 4, 5)
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6. In a hydraulic system having a pump connected to a prime mover, a tank, first actuator, a first control valve assembly which controls flow of fluid from the pump to the first actuator and from the first actuator to the tank, a second actuator;
- and a second control valve assembly which controls flow of fluid from the pump to the second actuator and from the second actuator to the tank;
a regeneration system comprising;a proportional regeneration regulation valve coupling a tank outlet of the first control valve assembly to the tank;
a first isolation valve coupling the tank outlet of the first control valve assembly to a pump inlet of the second control valve assembly;
a first pressure sensor connected to the first actuator and providing an indication of a first pressure;
a second pressure sensor connected to the second actuator and providing an indication of a second pressure; and
a system controller having inputs connected to the first pressure sensor and the second pressure sensor, and having outputs connected to the regeneration regulation valve and the isolation valve, wherein when fluid is being drained under pressure from the first actuator the system controller at least partially closes the regeneration regulation valve and opens the isolation valve in response to the first pressure being greater than the second pressure, thereby driving the second actuator with the fluid being drained from the first actuator. - View Dependent Claims (7)
- and a second control valve assembly which controls flow of fluid from the pump to the second actuator and from the second actuator to the tank;
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8. A regeneration method for a hydraulic system having a prime mover connected to a pump to supply hydraulic fluid under pressure, a first actuator and a second actuator, said regeneration method comprising the steps of:
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draining hydraulic fluid under pressure from the first actuator;
sensing pressure of the hydraulic fluid drained from the first actuator to produce an indication of a first pressure;
selecting among a first mode of operation, a second mode of operation, and a third mode of operation;
in the first mode of operation;
(a) sensing pressure of the hydraulic fluid at an inlet of the second actuator to produce an indication of a second pressure, and (b) in response to the first pressure being greater than the second pressure, routing hydraulic fluid drained from the first actuator to the inlet of the second actuator to drive the second actuator;
in the second mode of operation;
(c) when the pump is not supplying pressurized fluid to an actuator of the hydraulic system, routing hydraulic fluid drained from the first actuator to an outlet of the pump thereby causing the pump to drive the prime mover; and
in the third mode of operation;
(d) sensing pressure of the hydraulic fluid in an accumulator to produce an indication of a third pressure, and (e) in response to the first pressure being greater than the third pressure, storing the hydraulic fluid drained from the first actuator in the accumulator. - View Dependent Claims (9)
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10. In a hydraulic system having a pump connected to a prime mover, a tank, first actuator, and a second actuator;
- a regeneration system comprising;
supply line coupled to the pump;
a first control valve which connects the supply line to the first actuator and controls flow of fluid in either direction there between;
a second control valve which is unidirectional and controls flow of fluid from the first actuator to the tank, a third control valve which is unidirectional and connects the supply line to the second actuator;
a fourth control valve which is unidirectional and controls flow of fluid from the second actuator to the tank, a first pressure sensor connected to the first actuator and providing an indication of a first pressure;
a second pressure sensor connected to the second actuator and providing an indication of a second pressure; and
a system controller having inputs connected to the first pressure sensor and the second pressure sensor, and having outputs connected to the first control valve, the second control valve, the third control valve, and the fourth control valve, wherein when fluid is being drained under pressure from the first actuator the system controller opens the third control valve and at least partially opens the first control valve in response to the first pressure being greater than the second pressure thereby driving the second actuator with the fluid being drained from the first actuator. - View Dependent Claims (11, 12, 13, 14, 15)
- a regeneration system comprising;
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16. In a hydraulic system having a pump connected to a prime mover, a tank, an actuator, and a double acting cylinder having a first chamber and a second chamber;
- a regeneration system comprising;
supply line coupled to the pump;
a first control valve which connects the supply line to the first chamber of the double acting cylinder;
a second control valve which controls flow of fluid from the first chamber of the double acting cylinder to the tank;
a first bidirectional pilot operated control valve which connects the supply line to the second chamber of the double acting cylinder;
a third control valve which controls flow of fluid from the second chamber of the double acting cylinder to the tank;
a second bidirectional-pilot operated control valve which connects the supply line to the actuator;
a fourth control valve which controls flow of fluid from the actuator to the tank;
a first pressure sensor connected to the first chamber of the double acting cylinder and providing an indication of a first pressure;
a second pressure sensor connected to the second chamber of the double acting cylinder and providing an indication of a second pressure;
a third pressure sensor connected to the actuator and providing an indication of a third pressure; and
a system controller having inputs connected to the first pressure sensor and the second pressure sensor, and having outputs connected to the first bidirectional control valve, the second bidirectional control valve, the first control valve, the second control valve, the third control valve, and the fourth control valve;
wherein when fluid is being drained under pressure from the second chamber of the double acting cylinder, the system controller at least partially opens the first bidirectional control valve and the second bidirectional control valve in response to the first pressure being greater than the second pressure, thereby driving the actuator with the fluid being drained from the second chamber; and
wherein when fluid is being drained under pressure from the actuator, the system controller at least partially opens the second bidirectional control valve and one of the first bidirectional control valve and the first control valve, thereby driving the double acting cylinder with the fluid being drained from the actuator. - View Dependent Claims (17, 18, 19, 20)
- a regeneration system comprising;
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21. In a hydraulic system having a pump connected to a prime mover, a tank, a double acting cylinder having a first chamber and a second chamber, and an actuator, a regeneration system comprising:
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a first control valve which connects the pump to the first chamber of the double acting cylinder;
a second control valve which controls flow of fluid from the first chamber of the double acting cylinder to the tank;
a bidirectional control valve which connects the pump to the second chamber of the double acting cylinder;
a third control valve which controls flow of fluid from the second chamber of the double acting cylinder to the tank;
a fourth control valve which connects the pump to the actuator;
a fifth control valve which controls flow of fluid from the actuator to the tank; and
a system controller having outputs connected to the bidirectional control valve, the first control valve, the second control valve, and the third control valve;
wherein when fluid is being drained under pressure from the second chamber of the double acting cylinder, the system controller enters one of a first mode and a second mode, in the first mode the first control valve and the bidirectional control valve are opened thereby supplying the first chamber with fluid from the second chamber, and in the second mode the first bidirectional control valve and the fourth control valve are opened, thereby driving the actuator with the fluid being drained from the second chamber. - View Dependent Claims (22, 23, 24, 25, 26)
a first pressure sensor connected to the first chamber of the double acting cylinder and providing an indication of a first pressure that is applied to the system controller;
a second pressure sensor connected to the second chamber of the double acting cylinder and providing an indication of a second pressure that is applied to the system controller; and
a third pressure sensor connected to the actuator and providing an indication of a third pressure that is applied to the system controller.
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26. The regeneration system as recited in claim 21 wherein the first control valve, the second control valve, the third control valve, the fourth control valve, and the fifth control valve are unidirectional.
Specification
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Current AssigneeHusco International Incorporated
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Original AssigneeHusco International Incorporated
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InventorsJackson, Randall S., Clifton, Brian, Stephenson, Dwight B.
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Primary Examiner(s)LOPEZ, FRANK D
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Application NumberUS09/658,842Time in Patent Office851 DaysField of Search604/14, 604/22, 604/24, 604/61US Class Current60/414CPC Class CodesE02F 9/2217 with energy recovery arrang...E02F 9/2296 Systems with a variable dis...F15B 11/006 Hydraulic "Wheatstone bridg...F15B 11/024 by means of differential co...F15B 11/16 with two or more servomotorsF15B 13/0405 for seat valves, i.e. poppe...F15B 13/043 with electrically-controlle...F15B 21/08 Servomotor systems incorpor...F15B 21/14 Energy-recuperation meansF15B 2211/20569 capable of working as pump ...F15B 2211/30575 in a Wheatstone Bridge arra...F15B 2211/3144 the positions being continu...F15B 2211/31588 having a single pressure so...F15B 2211/327 electrically or electronicallyF15B 2211/35 Directional control combine...F15B 2211/40515 with variable throttles or ...F15B 2211/40584 the flow control means arra...F15B 2211/41545 being connected to multiple...F15B 2211/625 AccumulatorsF15B 2211/6309 the pressure being a pressu...View All
