The invention relates to hydraulic apparatus, and more particularly, to apparatus for pulsed pressure testing of hydraulic apparatus sealing components.
Hydraulic systems are widely used in many industries. Examples include motor vehicle engines, braking systems, aeronautical control systems, industrial pumping systems, presses, rolling mills, earth-moving equipment, floor conveyors, agricultural machines, truck loading cranes, injection molding machines, marine hydraulics, and many others.
So as to ensure reliability and longevity even under challenging conditions, it is often necessary to submit hydraulic designs to rigorous and prolonged pressure testing, so as to ensure that there is no excessive material fatigue or seal wear even after long term, demanding use. For certain applications, the pressure testing requires repeated application and release of a specified hydraulic pressure to the part under test (“PUT”). This “pulsed pressure” testing is typically carried out for a specified number of pressure cycles.
The output of the pump 100 is also connected through a solenoid control valve 108 to the PUT 110. The solenoid valve 108 is opened and closed by a control signal 112, which is typically supplied as a train of “square” voltage pulses 112 that cause the system to repetitively apply the hydraulic pressure P to the PUT, and then to release the pressure again. Typically, a counter (not shown) counts the voltage pulses 112, and stops the test after a specified number of repetitions N has been applied. If the PUT does not include a mechanism that returns it to its starting configuration after each pressure pulse is applied, then a return spring 114 or other such mechanism is provided.
As testing requirements have become more demanding and sophisticated, for example requiring 360,000 pressure pulse cycles or more, the maximum rate at which hydraulic testing apparatus can apply pressure pulses has often proven to be too slow, due to pressure delays in the hydraulic lines and limitations in the operating speed of the solenoid valve. In particular, it is not uncommon for the solenoid valve to require 60 ms or more to switch on and off. As a result, weeks or even months may be required to apply a specified number of pressure pulses to the PUT.
In addition, systems such as the apparatus illustrated in
What is needed, therefore, is a hydraulic testing apparatus that is faster and more flexible than current designs.
The present invention is an enhanced pressure testing apparatus that is faster and more flexible than current designs. Pressure delays in the hydraulic lines are minimized by using hydraulic lines that are significantly larger in diameter than previous designs. For example, lines that are 1¼ inches in diameter are used in some embodiments for applications where ¼ inch diameter lines have typically been used in the past. A fluid accumulator is used to avoid pump output capacity delays by storing a volume of hydraulic fluid that is pre-pressurized while the control valve is closed, and then supplements the pump output when the control valve is open. Delays that might otherwise arise due to the enlarged volume of the hydraulic lines are thereby avoided.
Rather than providing only a single pressure delivery channel, the present invention includes two pressure delivery channels, each of which includes its own pump, regulator, accumulator, and control valve. As a result, a PUT that requires a separately applied pneumatic pressure to return it to its initial configuration can be easily accommodated. And in some embodiments, if it is desirable to apply pressure to a single input of the PUT at two different pressure values, for example alternately, the outputs of the two delivery channels can be combined at the input of the PUT.
Embodiments of the present invention use servo valves, which typically switch much faster than solenoid valves (for example 10 ms switching time for a servo valve compared to 60 ms for a solenoid valve). In some of these embodiments, output signals of pressure transducers provided at the outputs of the servo valves are used by feedback comparators in a “proportional integral and derivative” (“PID”) loop to obtain a desired pressure output from each servo valve. In various embodiments, by controlling and shaping the servo valve control voltages, a wide range of different pressure outputs, and even pressure output profiles, can be provided on either or both pressure channels.
In some embodiments, the hydraulic pump is a variable-vane pump, which allows the system to adapt to a wider range of pressure requirements and PUT volumes.
Certain embodiments further include selectable high and low pressure ranges on one or both of the pressure channels. In some of these embodiments, the hydraulic output of the pump is split into two parallel channels, passed through parallel regulators, accumulators, and control valves, and then recombined.
The present invention is a system for applying hydraulic pressure pulses to a part under test (“PUT”). The system includes:
a first pressure channel including:
Embodiments further include a first pressure transducer configured to measure a pressure of the first pressure channel output and a second pressure transducer configured to measure a pressure of the second pressure channel output.
In some embodiments at least one of the control valves is a servo valve. In some of these embodiments the output of the servo valve provides a variable pressure channel output according to a varying amplitude of the corresponding electrical control signal. In other of these embodiments the variable pressure channel output is linearly proportional to the varying amplitude of the corresponding electrical control signal.
In various embodiments the first pressure channel output and the second pressure channel output can be combined and applied jointly to the PUT, thereby allowing the system controller to apply pressure from either pressure channel to the PUT in any desired sequence.
In certain embodiments, the output of the first pump is in simultaneous fluid communication with a high pressure branch and a low pressure branch, each of the high and low pressure branches including a pressure regulator, a fluid accumulator, and a control valve, outputs of the high and low pressure branches being in combined fluid communication with the first control valve, so that a fluid pressure delivered to the first control valve is selectable between a pressure set by the high pressure branch regulator and a pressure set by the low pressure branch regulator. And in some of these embodiments the first control valve is a servo valve that provides a variable pressure output according to a variable electrical control signal, selection of the high or low pressure channel thereby selecting between a high pressure range and a low pressure range over which the first control valve is able to vary the first pressure channel output.
And in various embodiments at least one of the first and second pumps is a variable vane pump.
The features and advantages described herein are not all-inclusive and, in particular, many additional features and advantages will be apparent to one of ordinary skill in the art in view of the drawings, specification, and claims. Moreover, it should be noted that the language used in the specification has been principally selected for readability and instructional purposes, and not to limit the scope of the inventive subject matter.
The present invention is an enhanced pressure testing apparatus that is faster and more flexible than current designs. Pressure delays in the hydraulic lines are minimized by using hydraulic lines that are larger in diameter than previous designs. For example, lines that are 1¼ inches in diameter are used in some embodiments for applications where ¼ inch diameter lines have typically been used in the past.
With reference to
In addition, each pressure channel includes a fluid accumulator 200 in which a volume of hydraulic fluid is pre-pressurized while the control valve 202 is closed, and then supplements the pump output when the control valve 202 is open, so that the larger volume of the hydraulic lines does not cause pressure delivery delays due to limited pump output capacity.
Embodiments of the present invention use servo valves 202, which typically switch much faster than solenoid valves (for example 10 ms switching time for a servo valve 108 compared to 60 ms for a solenoid valve 202). In some of these embodiments, pressure transducers 204 are provided at the outputs of the servo valves 202, and the outputs of the pressure transducers 204 are used by feedback comparators (not shown) in a “proportional integral and derivative” (“PID”) loop to obtain a desired pressure output from each servo valve 202. In various embodiments, by controlling and shaping the valve control voltages, a wide range of different pressure outputs, and even pressure output profiles, can be provided on either or both pressure channels.
In some embodiments, the hydraulic pump 208 is a variable-vane pump 208, which allows the system to adapt to a wider range of pressure requirements and PUT volumes as compared to a rotary pump 100.
With reference to
With reference to
With reference to
With reference to
In embodiments, the control voltages are supplied to the control valves 202 by programmable logic controllers (“PLC's”), and in some embodiments operator control is available through a graphical user interface such as LabView. In various embodiments, the system displays the pressures measured by the pressure transducers 106, 204 as well as the number of completed cycles N, and in some embodiments these parameters are periodically recorded and logged for later review. In similar embodiments, the current and/or logged values of these parameters can be monitored remotely using any internet-capable device.
The foregoing description of the embodiments of the invention has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Many modifications and variations are possible in light of this disclosure. It is intended that the scope of the invention be limited not by this detailed description, but rather by the claims appended hereto.
This application claims the benefit of U.S. Provisional Application No. 61/812,798, filed Apr. 17, 2013, which is herein incorporated by reference in its entirety for all purposes.
Filing Document | Filing Date | Country | Kind |
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PCT/US2014/018815 | 2/24/2014 | WO | 00 |
Number | Date | Country | |
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61812798 | Apr 2013 | US |