|Publication number||US3836084 A|
|Publication date||Sep 17, 1974|
|Filing date||Apr 9, 1973|
|Priority date||Apr 14, 1972|
|Also published as||CA972657A1, DE2318272A1|
|Publication number||US 3836084 A, US 3836084A, US-A-3836084, US3836084 A, US3836084A|
|Original Assignee||English Clays Lovering Pochin|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (2), Referenced by (8), Classifications (12)|
|External Links: USPTO, USPTO Assignment, Espacenet|
United States Patent [1 1 Luke [ Sept. 17, 1974 [5 1 AUTOMATIC REMOTE CONTROL APPARATUS William George Luke, Cornwall, England  Filed: Apr. 9, 1973  Appl. No.: 349,463
 Foreign Application Priority Data 3,583,637 6/1971 Miscovich 239/587 Primary ExaminerLloyd L. King Attorney, Agent, or Firm-Armstrong, Nikaido &
Wegner [5 7 ABSTRACT Hydraulic control apparatus for automatic remote control of a hydraulic actuating ram. The apparatus has a double-acting slave cylinder connectable hydraulically to an actuating ram, and a double-acting master cylinder the piston of which is mechanically connected to the piston of the slave cylinder, the mas- Apr. 14, 1972 Great Britain 17418/72 ter ylinder being operable by hydraulic pressure supplied via a pilot-operated valve arranged automatically  US. Cl. 239/587 to rever e the troke of the master mm at limits set ac-  Int. Cl B05b 15/08 o ding to the desired stroke of the actuating ram.  Fleld of Search 239/587, 227 The control apparatus may be used for controlling actuating rams which effect reciprocating pivotal move- [5 Re e e ce Clted ment about one or more axes of a water jet monitor.
UNITED STATES PATENTS 7 Claims, 5 Drawing Figures 3,575,351 4/]971 Warren 239/587 w o 1' g p l l 7 Q, I l ,b
PAIENIE SEP 1 H974 SHEET 2 OF 5 1 AUTOMATIC REMOTE CONTROL APPARATUS BACKGROUND OF THE INVENTION This invention relates to hydraulic control apparatus for automatic remote control of a hydraulic actuating ram, and is particularly, though not exclusively, concerned with remote control of movement of the nozzle of a high-velocity water jet monitor.
In a number of mining industries, for example the clay industry, a high-pressure water jet, from the nozzle of a water jet monitor, is used to wash minerals from the earth. This washing'process has been improved in recent years by increasing the velocity of the water jet and by directing the water jet more effectively at the area to be washed, washing being carried out by traversing the jet of water continually back and forth over a selected area of the earth. Because of the high pressure of water involved and the time required to wash a particular area effectively it is desirable to employ remote control of the movement of the nozzle so that the operator can supervise the monitor from a safe distance and avoid repetitive manual control over long periods. One method of traversing the jet back and forth is by adapting the nozzle of the monitor to be movable, for example by pivoting, by means of a hydraulic actuating ram or rams.
SUMMARY OF THE INVENTION According to one aspect of the present invention there is provided hydraulic control apparatus for automatic remote control of a hydraulic actuating ram, comprising a first double-acting cylinder, referred to as a slave cylinder, which can be connected hydraulically for driving the actuating ram, and a second doubleacting cylinder, referred to as a master cylinder, the piston of the slave cylinder being mechanically connected to the piston of the master cylinder whereby reciprocating movement of the master piston causes corresponding reciprocating movement of the slave piston, the master cylinder being operable by hydraulic pressure under the control of a pilot-operated hydraulic valve which is arranged automatically to reverse the direction of movement of the master ram in response to pilot means actuable by limit switch means arranged for determining the desired length of stroke of the actuating ram.
The pilot means may comprise two hydraulic pilot valves arranged to be actuated at completion of a preset stroke of the master or slave rams for example by latches which are adjustable so that their position determines the length of stroke of the master ram.
The control apparatus may include a manuallyoperable hydraulic valve for controlling the hydraulic actuating ram, the manual valve, when operated, overriding the automatic control of the master and slave cylinders.
In one embodiment of the invention there is provided a water jet monitor including a nozzle mounted for pivotal movement in at least one plane, the pivotal movement being effected by means of a hydraulic actuating ram which is arranged to be controlled automatically by hydraulic control apparatus according to the invention. Conveniently a flow control valve is connected between the slave cylinder and the actuating ram for controlling the rate of movement of the actuating ram, thereby controlling the rate of pivotal movement of the monitor nozzle.
In practice, it is often desirable to control the movement of a monitor nozzle so that the water jet traverses an area to be washed in a horizontal direction, or a vertical direction, or in both horizontal and vertical directions simultaneously. In a preferred embodiment of the invention therefore, a water jet monitor is provided in which the nozzle is mounted for pivotal movement in two mutually perpendicular planes, a first actuating ram being provided for effecting movement of the nozzle in one plane and a second actuating ram being provided for effecting movement of the nozzle in the other plane, each actuating ram being arranged to be remotely controlled automatically by hydraulic control apparatus according to the invention. In this way the control apparatus may be set so as to control automatically the movement of the monitor nozzle for a large variety of different washing programmes, by selecting the stroke and speed of movement of each actuating ram, for example, in both the vertical and horizontal directions.
The hydraulic pressure for each master cylinder of the control apparatus may be supplied from a pump driven by an electric motor. This does have the disadvantage, however, of requiring installation of electrical power lines which are both costly, awkward to move when the monitor is to be moved to a new location, and constitute a hazard in a mining pit where heavy vehicles are usually operated.
According to a further aspect of the invention therefore, there is provided a high velocity water jet monitor wherein the hydraulic pressure for operating control apparatus of the water jet monitor is supplied by a pump which is coupled to a hydraulic motor driven by means of water pressure derived from the supply of water to the nozzle of the monitor. The power unit is thus self-contained and therefore avoids the hazards mentioned above, and moreover it can easily be moved to a new location together with the control apparatus and the monitor for washing different areas of the mining pit. Conveniently the hydraulic motor comprises a Pelton wheel.
BRIEF DESCRIPTION OF THE DRAWINGS The invention may be carried into practice in various ways, but one specific embodiment will now be described, by way of example, with reference to the accompanying drawings, in which:
FIG. 1 is a view of a high-velocity water jet monitor having a nozzle which can be pivoted horizontally and vertically;
FIG. 2 is a diagrammatic layout showing the arrangement of a monitor together with its remote control unit and a hydraulic power unit;
FIG. 3 is a circuit diagram showing the hydraulic circuit of the control apparatus according to the invention;
FIG. 4 is a view of the hydraulic power unit which supplies oil under pressure to the control apparatus, and
FIG. 5 is a perspective view of the control unit, showing the controls.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A high-velocity water jet monitor such as is used in the china-clay industry for washing china-clay from the earth is shown generally in FIG. 1. The monitor has a nozzle 1 from which a high-velocity jet of water issues when the monitor is in use, the jet being directed at an area of earth where the china-clay is to be washed out. The water is supplied to the nozzle under high pressure through a supply pipe 2 which is secured to a base 3 and which is further arranged in the form of a loop or coil 4 for countering the reaction thrust of the jet, the supply pipe terminating at the nozzle 1. The supply pipe, above the base, includes a first bearing 5 for pivoting the nozzle 1 about a vertical axis, and a second bearing 6 situated at the beginning of the loop 4 for pivoting the nozzle about a horizontal axis. Pivoting movement of the nozzle is effected by means of hydraulically-operated actuating rams 7 and 8 connected respectively to the bearings 5 and 6 so that the nozzle 1, and hence the jet of water, can be moved in a horizontal or vertical direction or both. The actuating rams 7 and 8 which are double-acting are operated by oil under pressure fed via flexible conduits 10, 11 and 13, 13 from a control unit as will be explained. The flexible conduits are attached to the cylinders by self-sealing releasable couplings.
The general layout of the monitor with its control unit is shown diagrammatically in FIG. 2. This figure shows the monitor, indicated generally at 15, the remote control apparatus 20 and the hydraulic power unit 50 for supplying oil under pressure to the control apparatus. As shown, the four conduits 10, 11 and 12, 13 connect the actuating rams 7 and 8 of the monitor to the control apparatus, oil being supplied through these conduits to operate the actuating rams 7 and 8 for moving the nozzle. The conduits 10, 11 and 12, 13may be made of any suitable length, normally 100 ft., so that the control apparatus 20 can be located at a safe working distance from the monitor. This feature is required since the high-velocity jet of water from the nozzle 1 causes rocks and mud to be thrown considerable distances owing to the impact with which the water hits the earth.
The control apparatus 20 and its hydraulic power unit are conveniently housed in a hut 60 which further protects the operator and makes operating possible in bad weather conditions.
Using the present invention it is possible for the operator to set a programme on the control apparatus so that operation of the actuating rams 7 and 8 will continue automatically, the programme being selected by the operator according to the way in which the area is to be washed by the water jet. The control circuit by which this is achieved is shown in FIG. 3. This diagram shows the hydraulic circuit for operating one of the actuating rams, for example ram 7 which produces horizontal movement of the nozzle. The circuit for operating the other ram 8 is not shown but is identical in all respects.
The double-acting actuating ram 7 which has oil conduits l0 and 11 connected to opposite ends of its cylinder can be operated in two ways, either manually through the control lever 28 of a manual control valve 23 or through the automatic circuit indicated generally at 24. The manual valve is a directional, 3-position valve in which the valve spool is spring-biassed to its centre closed position. Movement of the valve spool, for example to the left in FIG. 3, puts conduit in communication with an oil reservoir, and admits oil pressure through conduit 11 to the cylinder of the actuating ram 7, causing its ram to move outwardly. Conversely if the valve spool is moved to the right, oil pressure is fed to conduit 10 and conduit 11 is connected to the reservoir, so that the ram of the actuating cylinder moves into the cylinder.
In the centre position of the valve 23, as shown in the Figure, the actuating cylinder 7 is hydraulically locked against movement.
For automatic operation, the actuating ram 7 is operated through conduits 25 and 26 which communicate with conduits l1 and 10 respectively. Conduit 25 has a needle valve 27 for controlling the rate of flow of oil from the automatic circuit 24 to the ram 7; if the needle valve 27 is closed the ram 7 is isolated from the automatic control.
The control circuit 24 comprises basically two opposed double-acting rams, referred to as a slave cylinder 30 and a master cylinder 31, the pistons of which are directly coupled via a common piston rod 32 which carries a roller 33 for operating latches for reversing the direction at the completion of a stroke of the master and slave rams, as will be explained. The slave cylinder 30 is hydraulically connected to the actuating ram 7 via the conduits 25 and 26 which are connected to opposite ends by the slave cylinder 30, and the bore of the slave cylinder 30 is the same as that of the actuating ram 7 so that reciprocating movement of the slave ram will cause exactly corresponding reciprocating linear movement of the actuating ram 7.
The master cylinder 31 is operated by oil pressure supplied from the hydraulic power unit 50 through conduits 35 and 36 under the control of a pilot-operated, 3-position directional valve 37, the centre position of the spool being a closed position. This reversing valve 37 is operated by two pilot valves 38 and 39 which are operated by hydraulic pressure and actuated by associatedlatches 40 and 41 are arranged to be depressed in turn by the roller 33 on the piston rod 32. Thus in operation the master ram moves in one direction until the roller 33 depresses one of the latches, say 40 which operates its associated pilot valve 38, thereby changing over the main valve 37 to reverse the direction of movement of the master ram. At the other end of the stroke, roller 33 will depress the latch 41, again to reverse the valve 37 through the pilot valve 39. The reciprocating movement of the master ram 31 produces corresponding reciprocating movement of the slave ram 30 which in turn effects reciprocating movement of the actuating ram 7, thereby to oscillate the water jet horizontally.
One of the latches 41 is adjustable by means of a lever 43 which in a particular construction can be set in any one of 13 positions, the position of the latch determining the length of stroke of the master ram 31 and therefore the length of stroke of the actuating ram 7.
As explained, the other actuating ram 8 for vertical movement of the nozzle is also controlled by a similar automatic control circuit.
FIG. 5 shows the control unit with the various controls: the control lever 28, the needle valve 27 and the stroke adjustment lever 43 for controlling the horizontal actuating ram 7; and corresponding controls 28A, 27A and 43A for controlling the vertical actuating ram 8.
It will be appreciated therefore that by selecting the stroke and speed of actuation of each of the actuating rams 7 and 8, using the controls 43, 43A and 27, 27A,
a wide range of automatic working programmes can be achieved. 'Once set, a programme will be followed continuously, until the operator changes the controls. If the operator decides to move the jet to a new washing position all that is necessary is to operate the relevant manual valve 23, by means of its control lever 28 or 28A, which will then override the automatic control until the control lever is released, when the valve spool will again return to its centre, locked position and the preselected programme will re-commence.
In the embodiment described the slave cylinder has a maximum stroke of 4" whereas the actuating ram 7 has a maximum stroke of Thus under automatic control the range of movement is only a proportion of the maximum range; for example, the horizontal movement possible with a full stroke of the actuating ram 7 may constitute a swing through 120 of the jet and under automatic control the maximum horizontal swing would be 32; this provides a safe and effective range in practice. If the 15 required to be directed at an area lying outside the 120, the nozzle assembly can be swung round to a new direction by means of a clamp 14, shown in FIG. 1.
A feature of the construction is the safety, in that, if by accident one of the conduits is cut or torn away from its coupling, the oil under pressure which is normally fed to the actuating rams 7 and 8 will vent to atmosphere and movement of the nozzle will cease. Furthermore, since under automatic operation the actuating rams 7 and 8 are in a closed hydraulic circuit with their associated slave cylinders, there is no danger of drift outside the programmed range, provided there is no leakage of oil past those rams.
The hydraulic pressure for operating the master ram 31, and the corresponding master ram of the vertical movement control circuit, is supplied by the power unit 50, as illustrated in FIG. 4. The oil pressure for the control apparatus is supplied from an oil pump 51 which pumps oil from a reservoir 52 via a conduit 55 and thence under pressure to the control apparatus via a pressure supply conduit 56. An oil return conduit 57 returns oil from the control apparatus to the reservoir 52.
The oil pump 51 is driven by a simple water-powered Pelton wheel arrangement 53 the Pelton wheel being driven by water under pressure fed through an inlet pipe 54 from the water supply pipe 2 which supplies the wash water to the nozzle. This provides a simple and efficient arrangement and it is found that 5 gallons of water per minute provides adequate power. It will be appreciated that this feature provides a selfcontained power unit obviating the expense and danger of electrical power lines.
Furthermoresince the monitor, the control unit and the power unit are interconnected by quick release couplings any one of these units may be replaced quickly in event of trouble thereby avoiding loss of operating time and eliminating the need to service the units in difficult conditions.
In a further specific embodiment, not shown in the drawings, a single control circuit, as shown in FIG. 3, is used to control automatically either a vertical movement actuating ram or a horizontal movement actuating ram but not both simultaneously. In this case the slave ram is connected hydraulically to both vertical and horizontal actuating rams via a manual valve which can be operated to engage automatic control for whichever actuating ram is selected. Since only one control circuit is used in this case the control apparatus is simpler and less expensive to install.
1. A hydraulic monitor including a water jet nozzle mounted for pivoting movement in at least one plane, the pivoting movement being effected by a hydraulic actuating ram which is arranged to be controlled automatically by hydraulic control apparatus comprising a first double-acting cylinder, referred to as a slave cylinder, which can be connected hydraulically for driving the actuating ram, a second double-acting ram, referred to as a master cylinder, a mechanical connection between the piston of the slave cylinder and the piston of the master cylinder, the connection being adapted to cause reciprocating movement of the slave piston corresponding to reciprocating movement of the master piston, a pilot-operated hydraulic valve adapted to control the hydraulic pressure supply to the master cylinder, the pilot-operated hydraulic valve being arranged automatically to reverse the direction of movement of the master ram, pilot means adapted to control the pilot-operated hydraulic valve, and limit switch means adapted to actuate the pilot means and arranged for determining the desired length of stroke of the actuating ram.
2. A hydraulic monitor as claimed in claim 1, in which the hydraulic pressure for operating the master cylinder is supplied by a pump adapted to be driven by a hydraulic motor driven by means of water pressure derived from the supply of water to the nozzle of the monitor.
3. A hydraulic monitor including a nozzle mounted for pivoting movement in two mutually perpendicular planes, a first actuating ram for effecting movement of the nozzle in one plane and a second actuating ram for effecting movement of the nozzle in the other plane, each actuating ram being arranged to be remotely controlled automatically by hydraulic control apparatus comprising a first double-acting cylinder, referred to as a slave cylinder, which can be connected hydraulically for driving the actuating ram, a second double-acting ram, referred to as a master cylinder, a mechanical connection between the piston of the slave cylinder and the piston of the master cylinder, the connection being adapted to cause reciprocating movement of the slave piston corresponding to reciprocating movement of the master piston, a pilot-operated hydraulic valve adapted to control the hydraulic pressure supply to the master cylinder, the pilot-operated hydraulic valve being arranged automatically to reverse the direction of movement of the master ram, pilot means adapted to control the pilot-operated hydraulic valve, and limit switch means adapted to actuate the pilot means and arranged for determining the desired length of stroke of the actuating ram.
4. A hydraulic monitor as claimed in claim 3, wherein the bore of each slave cylinder is the same as the bore of the actuating ram associated with it.
5. A hydraulic monitor as claimed in claim 4, wherein the effective stroke length of each slave cylinder is shorter than the effective stroke length of the actuating cylinder associated with it.
6. A hydraulic monitor as claimed in claim 5, wherein the hydraulic motor is a Pelton wheel.
7. A hydraulic monitor as claimed in claim 3, wherein the control apparatus is hydraulically connected to each actuating ram by flexible conduits including selfsealing releasable couplings.
|Cited Patent||Filing date||Publication date||Applicant||Title|
|US3575351 *||Apr 9, 1970||Apr 20, 1971||Stang Hydronics Inc||Hydraulic monitor incorporating improved power-operated and manually operated swivel joint|
|US3583637 *||Apr 14, 1969||Jun 8, 1971||Stang Hydronics Inc||Airport runway fire-fighting system and apparatus|
|Citing Patent||Filing date||Publication date||Applicant||Title|
|US4615487 *||Apr 16, 1984||Oct 7, 1986||J-B Industrial Corp.||Hydrocannon system for cleaning power plants|
|US6715971||Apr 9, 2002||Apr 6, 2004||Gary L. Curtis||Automated coolant delivery method and system for a machine tool|
|US7025543 *||Jan 9, 2004||Apr 11, 2006||Curtis Gary L||Method of automated coolant delivery for a machine tool|
|US7191964 *||Nov 9, 2004||Mar 20, 2007||Elkhart Brass Manufacturing Company, Inc.||Fire-fighting monitor with remote control|
|US8714466||Jan 11, 2013||May 6, 2014||Elkhart Brass Manufacturing Company, Inc.||Fire-fighting monitor with remote control|
|US20040141819 *||Jan 9, 2004||Jul 22, 2004||Curtis Gary L.||Method of automated coolant delivery for a machine tool|
|US20050167122 *||Nov 9, 2004||Aug 4, 2005||Trapp James M.||Fire-fighting monitor with remote control|
|US20110253397 *||Oct 20, 2011||Elkhart Brass Manufacturing Company, Inc.||Fire fighting monitor|
|International Classification||B05B3/14, B05B3/00, F15B17/00, E21C35/00, E21C35/24|
|Cooperative Classification||E21C35/24, B05B3/14, F15B17/00|
|European Classification||B05B3/14, E21C35/24, F15B17/00|