CA1050395A - Hydraulic boom-lift system with selective speeds - Google Patents
Hydraulic boom-lift system with selective speedsInfo
- Publication number
- CA1050395A CA1050395A CA256,014A CA256014A CA1050395A CA 1050395 A CA1050395 A CA 1050395A CA 256014 A CA256014 A CA 256014A CA 1050395 A CA1050395 A CA 1050395A
- Authority
- CA
- Canada
- Prior art keywords
- cylinder
- cylinder means
- oil
- float
- boom
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired
Links
Landscapes
- Jib Cranes (AREA)
Abstract
ABSTRACT OF THE DISCLOSURE
Greater overall speed of crane operation is made possible by using a plurality of hydraulic piston-cylinder sets together with valving which can direct the pumped hydraulic fluid selectively to either of the cylinder sets or to both of them. Preferably the two cylinder sets are of different speed-load characteristics so that the same supply of prepared oil will raise the boom faster when supplied to one than when supplied to the other. When the boom must be raised with maximum load, the same oil supply will be directed to both cylinder sets, thereby giving the maximum lifting power with a given available oil pressure and the slowest raising speed. The overall time required to accomplish a given task is reduced because most of the time the boom can be raised of lowered at a faster speed than that slow speed which must be provided for handling heaviest loads. Speeds are selected by operating one or both of two handles to the up or down position, each handle controlling its own valve spool. When only one handle is m wed to supply fluid under pressure, the other is moved to a "float" position. Each valve spool must therefore have a float position, but for safety an interlock prevents moving both spools to the float position simultaneously.
Greater overall speed of crane operation is made possible by using a plurality of hydraulic piston-cylinder sets together with valving which can direct the pumped hydraulic fluid selectively to either of the cylinder sets or to both of them. Preferably the two cylinder sets are of different speed-load characteristics so that the same supply of prepared oil will raise the boom faster when supplied to one than when supplied to the other. When the boom must be raised with maximum load, the same oil supply will be directed to both cylinder sets, thereby giving the maximum lifting power with a given available oil pressure and the slowest raising speed. The overall time required to accomplish a given task is reduced because most of the time the boom can be raised of lowered at a faster speed than that slow speed which must be provided for handling heaviest loads. Speeds are selected by operating one or both of two handles to the up or down position, each handle controlling its own valve spool. When only one handle is m wed to supply fluid under pressure, the other is moved to a "float" position. Each valve spool must therefore have a float position, but for safety an interlock prevents moving both spools to the float position simultaneously.
Description
LR /vt .
~L05~3~ , INTRODUCTION
This application is relatecl ~o copending c~4~Patent Application No. 246,343, filed February 23, 1976.
The invention of which the present disclosure is offered for public dissemination in the event that adequate A patent protection is available relates to hydraulic cranes, and particularly to the hydraulic raising of crane booms.
Heretofore, hydraulic crane operations have usually been hampered by slow speed in the raising and lowering of ~he boom; a speed undesirabl~ slow under most conditions. This undesirably slow speed tends to result from the fact that the lift cylinders must have a sufficient effective piston are~ so that the boom can be raised at maximum loading by the oil pressure available. From a practlcal standpoint, it is not usually deemed feasible to provide a type of oil supply in which there can be a greater rate of oil flow to the lift cylinders when the boom is to be raised with con-si~erably less than maximum load. In order to achieve the high oil pressures necessary for maximum loads, pumps o~
the positi~e displacement type must be used. Pumps of this typ2 in cranes are generally not capable of significantly variea output because in crane operation the speed at which pumps are driven tends to be relatively invariable. Although there may be some sophisticated possibilities for dep~rting `from this usual single-pumpage rate, they have not been widely accepted.
According to the present invention, the problem is B solved or greatly alleviated through the use of an expedient of providing two selectively-valved cylinders ~ smaller diam-eter where one cylinder of larger diameter has been usedbefore. Accomplishing this has required some new and special valving arrangements. Preferably three speeds are ~vailable , ~r ~(!IS~39S
as can be the case when the same supply of oil to one ~ he/~
cylinder yields a faster movement than to the~cyllnder.
When the two cylinders are both supplied by this same oil so~rce, the slowest speed is provided with the same load capacity as if an equivalent single cylinder had been used. A separate valve handle and its associated valve spool are provided for each of the cylinders. The problem that the unused valve would cause locking of the boom by the unused cylinder is a~oided by providing a "float" or "idle" position or each valve spool so that when only one cylinder is being supplied with pressure oil, the piston of the other cylinder is free to move, pushing oil of that cylinder through an idle circuit, out at one end and in at t~e other end. The float positions presented a safety problem which had to be solved. If both valves were moved to the float position, the boom would be permitted ; to fall too rapidly by gravity. Modern safety considerations will not permit this to be possible. It is here made impossible by an interlock such that when one of the spools is moved to the float position, the other cannot possibly be moved to that position and therefore provides the necessary safe control of the boom.
Another problem which had to be solved resulted from the safety valves required at the gravity-pressured port of any cylinder which can let a load fall if a hose bursts. This problem is solved by providing an auxiliary spool (which is opened as the main spool moves to its float position) to supply pilot pressure to the associated safety valve. This is the subject of my prior co-pending Canadian patent application Serial No. 246,343 filed February 23, 1976.
~A
~050395 The invention may be broadly defined as a hydraulic system for ac-tuating a member at differQnt speeds in each of opposite dixections when using a generally constant-speed supply of pressured oil including a first cylinder means, a second cylinder means of larger diameter, and valving means for jointly supplying pressured-oil from a single source optionally:
(a) to the first cylinder means while the second cylinder means is allowed to float, (b) to the second cylinder means while the first cylinder means is allowed to float, or (c) to both cylinder means simultaneously to achieve the maximum actuation force available by supplying said oil pressure to the combined piston areas of both cylinder means, with a resultant lower operating speed than when either cylinder means is powered alone~
Advantages of the in~ention will be more apparent from the following description and from the drawings.
-2a-A
~L~5~395 DES IGNATI ON OF E'IGUR:ES
Fig. 1 is a side view of an embodiment of the present invention with the ~oom raised, part; of the boom being omitted.
ig. 2 is a corresponding view with the boom lowered.
Fig. 3 is a schematic view illustrating the hydraulic circuitry.
Fig. ~ is a view of the twin valve-control levers~
their marking and their interlock, as might be used in the circuitry of Fig. 3.
B~CKGROUND_DESCRIPTIO~
Although the invention could be used in connection with any boom which swings up~ardly, it has been illustrated in connectîon with a truck crane. Here a chassis ll carries a turnt~ble 12 which carries a crane base 13 on which a boom 14 is pivoted about a horizontal axis 16. Preferably an oper-ator's cab 17 is also mounted on turntable 12 Heretofore, the boo.~ 14 has been raised and lowered by cylinder means 18 connected to the boom about a single horizontal axis 19. The - drawings only show one side o~ the crane. It should be under-stood that the cylinders shown would be matched by like cylin-ders on the far side, although in theory a single cylinder centered under the boom could be the~cylinder means 18.
Conventionally boom 14 is raised and lowered by control of a single valve handle accessible to the operator in cab l7, for controlling the flow of oil to and from the cylin-der means 18. The speed of the boom, being raised or lowered, is generally the slow speed appropriate for maximum loads.
THE SPEED-CHOICE OF THE PRESE~T I~ENTIO~
As seen in Figs. l and 2, additional cylinder means 21 has been provided, approximately parallel to cylinder ~.eans 18, and slightly forwardl-I of it~ It should be understood that LR/vt . .
, 1~5~3~5 although the cylinder means 18 comprises two cylinders on opposite sides of the boom 14, and the same is true o~ cylin-der meàns 21, the two cylinders oE each cylinder means 'unction as one and hence no figure to show the far-side cylinders is deemed necessary For simplicity, each cylinder means ma~ be discussed as if it were a single cylinder.
In Fig. 3, cylinder 18 has been illustrated as of smaller diameter than cylinder 21. As a result~ given flow of oil, such as the output of pump 25, into cylinder 18 will cause more rapid piston movement than the same flow of oil into cylin-der 21. Thus directing oil from pump 25 to cylinder 18 only woula raise the boom more rapidly than directing oil to cylinder 21 cnly. Even if the two cylinders were of the same diame~er, som~ differential of speed would result from the fact that cylinder 21 is more remote from the axis 16 than is cylinder 18 so that a greater piston movement is required to achieve a given angular movement of the boom 14. There would be a practical adv~ntage in having all of the boom-lift cylinders ali~e, and with care~uL salection this advantage can be achieved even with a desirablo differential of boom-lift speed for a given oil f1ow.
As illustrated in Fig. 3, cylinder means 18 is con-trolled mainly by reversing valve 23, the spool of which is actu-ated-by handle 2a~ A reversing valve will connect pum~ 25 to either end of the cylinder it controls, connecting the other end to aischarge 29. Likewise the cylinder 21 is controlled by handle 27 As illustrated in Fig. 4, each of the valves 23 and 26 are four-position valves. As with most such valves, these valves are spring-return2d to a neutral position marked "Hold" in Fi~. a To raise the boom either or both handles 24 and 27 can be pulled rearwardly toward thc opsrator to the position marked "Up". To LR/vt ~05~39S
lower the boom either or both of these handles may be moved ~on~ardly or away from the operator to the position marked "Down".
Actually, it is not enough to move one of the handles 24 and 27 to the "Up" or "Down" position while leaving the other o~ these handles at the "Hold" position. This is because these valves are of the neutral-closed type so that each hydrau-lically locks its cylinder when in the "Hold" position. It would accomplish nothing (except waste o~ power through a pressur~ relief valve, not shown) to move one of the handles 24 to an operating position while retaining the other in the "Hold"
position and thus keeping its cylinder hydraulically locked.
- To permit the raising of the boom by either of the cylinders 18 or 21, each of the valves 23 and 26 is provided with a fourth position m~r~ed "Idle" in Fig. 4, in which the spool provides the connections normally called "Float". In the float position, each valve opens both or its cylinder con-nectio,~s to 2ach other and to the tank discharge connection 29 to allow all of its associated cylinder to flow freely out one end of the cylinder and -in the other, undar the in~luence of movement of the piston within the cylinder. Safety valve 31 and 32 are here ignored for the moment.
It follows that if handle 2a is moved to the "Up"
position and handle 27 to the "Idle" position, boom 14 is raised by the oil delivered from pump 25 to cylinder 18, while cylinder 21 idles or exerts no in1uence. This providas the highest speed o raising of boom 14.
If handle 27 is moved to the "Up" position and handle 24 to the '~Idle~l position, boo~ 1~ is raised by the full oil flow from pump 25 to cylinder 21 while cylinder 18 idles This provides a slower raising of boom 14, but also provides more lifting power in case a heavier load is bainq liftod.
.
If both of handles 24 and 27 are moved to the "Up"
position, oil from pump 25 is supplied to both of cylinders 18 and 21 and the boom 1~ is raised by the joint action of both of these cylinders~ However, inasmuch as the oil is still the same output supplied by the same pump 25, the rais-ing speed will be considerably slower than with raising being - accomplished only by cylinder 21 and very much slower than with raising being accoYnplished only by cylinder 18. However, this provides the maximum lifting force for raising the maxi-mum load. In ~act, cylin~er sizes would of course be chosenby the crane designer such that with the pressure available from pum.p 25 the maximum design capacity could be raised. The pistons o~ cylinder means 18 and 21 combined might have the same area as would in the past have been provided in cylinder mean3 18 as the sole cylin~er means.
This designing of the components to be able to lift the load at a rated capacity is of course standard practice.
Heretofore, however, it has been accompanied by the disadvantage that the speed of movement determined by this method o~ design would be the speed o movement for all boom-raising operations The boom-lowering operations have been slightly faster because the piston rods reduce the effective piston area on boom-lowering operations. Nevertheless, the slow speed o~ lowering resulting from the design for maximum loads has been applicable to all boom-lo~w2ring operations~
- As already explained, how2ver, the present invention permits two faster operations o~ raising and lowering boom 14.
The fastest is by powering cylinder 18 alone and the slower or intermediate speed is by powering cylinder 21 alone.
Designers may in some instances choose to increase rated capacities by using slightly larger total piston area Y'--'~Y
., , ~
r ~V--~VJ
LR/vt , :~S0395 than before, knowing that by the present invention the previous disadvantage of slow speed can be avoided in most operations.
SELECTIVE OPE~ING OF SAFEI~ VALVES
Safety requirements require the use of such safety valves as 31 and 32. Such a valve controls the flow of oil out~ardly through the lower or gravity pressured port or a cylinder. These valves prevent the flow of oil out through their respective ports except when actuated or opened by a R p;/~t pilot pressure through their respective ~ lines 33 and 34.
In the case of a normal lowering operation, for example by moving valve handle 27 to the "Down" position, pressure from pump 25 will be directed through the lowering line 36 to upper -port 37 ~f cylinder 21. This alone would not cause the lowering of the boom because closed valve 32 would prevent the discharge of oil from bel~w the piston of cylinder 210 However, the pres-sure ap~lied to lowering line 36 is also applied ~through valve 38 in Fig. 3) to pilot line 34 thereby opening valve 32 to allow the necessary outf 1QW of oil from the lower end of cylinder 21.
~he speed of lowe~ing can be delicately controlled by handle 27 because iE it merely cracks op~.n val~e 26, the pressure applied to lGwering line 36 will be quic'~ly reduced by the downward move-ment of the piston in cylinder -21, thereby allowing safety val~e 32 to reclose or partially reclose. In short~ if only a slight ~low of oil is permitted by valve 26, only a correspondingly slow speed of movement of boom 14 will result.
In order to achieve the "Idle" or "Float" condition for cylinder 18 or cylinder 21, it is necessary to supply ~
pilot pressure of oil to its pilot line 33 or 34 when its valve 23 or 26 is moved to the "Idle" position. This function is accomplished by the auxiliary valve 41, for valve 23, or 42 for valve 26. Thus as handle 27 moves from the "Vown" position to t~.e "Idle" position~ it actuates plun~er 43 which actuates the .. . .
105~39S
spool in valve 42 to 5upply oil to the Eloat-pilot line 44.
1'his pressure trips valve 3~ to cloc;e its connection to line 36 so that the pressure supplied to line ~4 is directed entirely to pilot line 34.
Valve 38 is a type of valve Xn~n as a shuttle valve.
The characteristic of such valves is tha~ if pressure is sup-plied to it by line 44, it closes its connection to line 36, and if pressure is supplied to it by line 36, it closes its connection to line 44. Without valve 38 the needed pilot pressure would not reach valve 32. When valve 42 is not actu-ated by its plunger 43, it is spring returned.to its neutral position which connects line 44 to discharge 29. ~ikewise line 36 is connected to discharge 29 when valve 26 is in lts idle position. Hence it is necessary to close the respective connections to either of these lines when the other line is supplied wi~h pressure, in order for that pressurs to be con-~eyed to pilot line 34 instead of being wasied to discharge 29.
. ~t will be apparent that in similar manner, when handle 24 is moved to the "Idle" position~ it ac~uates plunger 46 to actuate the spool of valve 41 to supply pressure from pump 25 to its float-~ilot lin9 47 and through its associated shuttle t~alve 38 to pilot line 33 for actuating or opening pilot valve 31 so that oil can 1Ow from beneath the piston of cylinder.18 through valve 23 to discharge 29 or.to the upper end of cylinder 18~ It should be understood that valves .23, 26, 41 and 42 will in practice usually be four side-by-side spools in a single valve block represented by the broken lin9s 49. Oil pressure from pump 25 is made available by this valve block to all of the spools but passes to discharge 29 when no spool is actuated, or when a predetermined maximum working pressure is exceeded.
8 :`~
~/vt ~5~395 It is expected that-a valving system,under which all .
of the cylinders supporting boom 14 would be ef~ectively in the ~Float" condition would be prohibited for safety reasons.
That would permit the boom 1~ to fall as rapidly as its pistons could discharge the oil through wide-open safety valves 31 and 32 and connecting lines To positlvely prevent this unsafe occurrence, some interlock such as bar 51, seen best in Fig. 4, is preferably provided. If handle 27 is moved to the 'lIdlel~
position represented by broken lines 27', it swings the inter-lock lever 51 to the position shown in Fig. 4 so that the handle24 can be moved no f,urther toward the "Idle" position than is represented by broken,lines 24'. In this position, it will not yet have actuated its plunger 46. Likewise, if handle 24 is thrust to its "Idle" position, it reverses the position of interlock bar 51 so that handle 27 can be moved no further tha~
to the "Down" position at which it has not yet actuated its plunger 43.
For the purpose of illustration, Fig. 3 has shown valve sets 23, 41 and 26, 42 in positions such that the inter-lock be~ween their handIes would not be as simple as seen inFig. 4. ~evertheLess, the interlock bar 51 has been shown in conjunction with handle 27 with a phantom or partly broken away showing o~ handle 24 in the background as if obstructed by the interlock bar 51.
ACHIEVEM~NT
From the foregoing it is apparent that the present invention can provide three speeds of boom operation with a single constant-flow supply of oil under pressure. The fastest speed results from powering only cylinder 18, a slower speed by powering cylinder 21, and the slowest speed by powering both cylinders. Operation is exceedingly simple, the operator .. 9 "
LK/Vt -- ` 105039S
normally operating only-one valve control handle for ~oom raising or lowering as has been the case heretofore; the other valve handle being left in the "Idle" posi-tion. Thus when lisht loads are to be handledy handle 27 wilL be thrust to the "Idle" position and left there, and the boom will be raised and lowered by movements of handle 24. When moderately heavier loads are to be handled, handle 24 will be thrust to ~he '~Idle~ position and the boom will be raised and lowered under the control of handle 27. When loads too heavy for cylinder 21 are to be handled, which in many jobs will be only rarely, both of handles 24 and 27 will be operated simul-taneously for controlling the raising and lowering of the . boom 14. Preferably these handles are close enough togetherto be grasped by one hand and moved by that hand simultaneo~sly~
leaving the o~her hand free for controlling another function . such as ~oom swing or raising or~lowering the line.
In the claims, the term "oil" should be understood to include any hydraulic fluid used for powering the cy1inders.
.
.
. ' ' . ' ' ' ' ' .
, - 1~ '-'.
~L05~3~ , INTRODUCTION
This application is relatecl ~o copending c~4~Patent Application No. 246,343, filed February 23, 1976.
The invention of which the present disclosure is offered for public dissemination in the event that adequate A patent protection is available relates to hydraulic cranes, and particularly to the hydraulic raising of crane booms.
Heretofore, hydraulic crane operations have usually been hampered by slow speed in the raising and lowering of ~he boom; a speed undesirabl~ slow under most conditions. This undesirably slow speed tends to result from the fact that the lift cylinders must have a sufficient effective piston are~ so that the boom can be raised at maximum loading by the oil pressure available. From a practlcal standpoint, it is not usually deemed feasible to provide a type of oil supply in which there can be a greater rate of oil flow to the lift cylinders when the boom is to be raised with con-si~erably less than maximum load. In order to achieve the high oil pressures necessary for maximum loads, pumps o~
the positi~e displacement type must be used. Pumps of this typ2 in cranes are generally not capable of significantly variea output because in crane operation the speed at which pumps are driven tends to be relatively invariable. Although there may be some sophisticated possibilities for dep~rting `from this usual single-pumpage rate, they have not been widely accepted.
According to the present invention, the problem is B solved or greatly alleviated through the use of an expedient of providing two selectively-valved cylinders ~ smaller diam-eter where one cylinder of larger diameter has been usedbefore. Accomplishing this has required some new and special valving arrangements. Preferably three speeds are ~vailable , ~r ~(!IS~39S
as can be the case when the same supply of oil to one ~ he/~
cylinder yields a faster movement than to the~cyllnder.
When the two cylinders are both supplied by this same oil so~rce, the slowest speed is provided with the same load capacity as if an equivalent single cylinder had been used. A separate valve handle and its associated valve spool are provided for each of the cylinders. The problem that the unused valve would cause locking of the boom by the unused cylinder is a~oided by providing a "float" or "idle" position or each valve spool so that when only one cylinder is being supplied with pressure oil, the piston of the other cylinder is free to move, pushing oil of that cylinder through an idle circuit, out at one end and in at t~e other end. The float positions presented a safety problem which had to be solved. If both valves were moved to the float position, the boom would be permitted ; to fall too rapidly by gravity. Modern safety considerations will not permit this to be possible. It is here made impossible by an interlock such that when one of the spools is moved to the float position, the other cannot possibly be moved to that position and therefore provides the necessary safe control of the boom.
Another problem which had to be solved resulted from the safety valves required at the gravity-pressured port of any cylinder which can let a load fall if a hose bursts. This problem is solved by providing an auxiliary spool (which is opened as the main spool moves to its float position) to supply pilot pressure to the associated safety valve. This is the subject of my prior co-pending Canadian patent application Serial No. 246,343 filed February 23, 1976.
~A
~050395 The invention may be broadly defined as a hydraulic system for ac-tuating a member at differQnt speeds in each of opposite dixections when using a generally constant-speed supply of pressured oil including a first cylinder means, a second cylinder means of larger diameter, and valving means for jointly supplying pressured-oil from a single source optionally:
(a) to the first cylinder means while the second cylinder means is allowed to float, (b) to the second cylinder means while the first cylinder means is allowed to float, or (c) to both cylinder means simultaneously to achieve the maximum actuation force available by supplying said oil pressure to the combined piston areas of both cylinder means, with a resultant lower operating speed than when either cylinder means is powered alone~
Advantages of the in~ention will be more apparent from the following description and from the drawings.
-2a-A
~L~5~395 DES IGNATI ON OF E'IGUR:ES
Fig. 1 is a side view of an embodiment of the present invention with the ~oom raised, part; of the boom being omitted.
ig. 2 is a corresponding view with the boom lowered.
Fig. 3 is a schematic view illustrating the hydraulic circuitry.
Fig. ~ is a view of the twin valve-control levers~
their marking and their interlock, as might be used in the circuitry of Fig. 3.
B~CKGROUND_DESCRIPTIO~
Although the invention could be used in connection with any boom which swings up~ardly, it has been illustrated in connectîon with a truck crane. Here a chassis ll carries a turnt~ble 12 which carries a crane base 13 on which a boom 14 is pivoted about a horizontal axis 16. Preferably an oper-ator's cab 17 is also mounted on turntable 12 Heretofore, the boo.~ 14 has been raised and lowered by cylinder means 18 connected to the boom about a single horizontal axis 19. The - drawings only show one side o~ the crane. It should be under-stood that the cylinders shown would be matched by like cylin-ders on the far side, although in theory a single cylinder centered under the boom could be the~cylinder means 18.
Conventionally boom 14 is raised and lowered by control of a single valve handle accessible to the operator in cab l7, for controlling the flow of oil to and from the cylin-der means 18. The speed of the boom, being raised or lowered, is generally the slow speed appropriate for maximum loads.
THE SPEED-CHOICE OF THE PRESE~T I~ENTIO~
As seen in Figs. l and 2, additional cylinder means 21 has been provided, approximately parallel to cylinder ~.eans 18, and slightly forwardl-I of it~ It should be understood that LR/vt . .
, 1~5~3~5 although the cylinder means 18 comprises two cylinders on opposite sides of the boom 14, and the same is true o~ cylin-der meàns 21, the two cylinders oE each cylinder means 'unction as one and hence no figure to show the far-side cylinders is deemed necessary For simplicity, each cylinder means ma~ be discussed as if it were a single cylinder.
In Fig. 3, cylinder 18 has been illustrated as of smaller diameter than cylinder 21. As a result~ given flow of oil, such as the output of pump 25, into cylinder 18 will cause more rapid piston movement than the same flow of oil into cylin-der 21. Thus directing oil from pump 25 to cylinder 18 only woula raise the boom more rapidly than directing oil to cylinder 21 cnly. Even if the two cylinders were of the same diame~er, som~ differential of speed would result from the fact that cylinder 21 is more remote from the axis 16 than is cylinder 18 so that a greater piston movement is required to achieve a given angular movement of the boom 14. There would be a practical adv~ntage in having all of the boom-lift cylinders ali~e, and with care~uL salection this advantage can be achieved even with a desirablo differential of boom-lift speed for a given oil f1ow.
As illustrated in Fig. 3, cylinder means 18 is con-trolled mainly by reversing valve 23, the spool of which is actu-ated-by handle 2a~ A reversing valve will connect pum~ 25 to either end of the cylinder it controls, connecting the other end to aischarge 29. Likewise the cylinder 21 is controlled by handle 27 As illustrated in Fig. 4, each of the valves 23 and 26 are four-position valves. As with most such valves, these valves are spring-return2d to a neutral position marked "Hold" in Fi~. a To raise the boom either or both handles 24 and 27 can be pulled rearwardly toward thc opsrator to the position marked "Up". To LR/vt ~05~39S
lower the boom either or both of these handles may be moved ~on~ardly or away from the operator to the position marked "Down".
Actually, it is not enough to move one of the handles 24 and 27 to the "Up" or "Down" position while leaving the other o~ these handles at the "Hold" position. This is because these valves are of the neutral-closed type so that each hydrau-lically locks its cylinder when in the "Hold" position. It would accomplish nothing (except waste o~ power through a pressur~ relief valve, not shown) to move one of the handles 24 to an operating position while retaining the other in the "Hold"
position and thus keeping its cylinder hydraulically locked.
- To permit the raising of the boom by either of the cylinders 18 or 21, each of the valves 23 and 26 is provided with a fourth position m~r~ed "Idle" in Fig. 4, in which the spool provides the connections normally called "Float". In the float position, each valve opens both or its cylinder con-nectio,~s to 2ach other and to the tank discharge connection 29 to allow all of its associated cylinder to flow freely out one end of the cylinder and -in the other, undar the in~luence of movement of the piston within the cylinder. Safety valve 31 and 32 are here ignored for the moment.
It follows that if handle 2a is moved to the "Up"
position and handle 27 to the "Idle" position, boom 14 is raised by the oil delivered from pump 25 to cylinder 18, while cylinder 21 idles or exerts no in1uence. This providas the highest speed o raising of boom 14.
If handle 27 is moved to the "Up" position and handle 24 to the '~Idle~l position, boo~ 1~ is raised by the full oil flow from pump 25 to cylinder 21 while cylinder 18 idles This provides a slower raising of boom 14, but also provides more lifting power in case a heavier load is bainq liftod.
.
If both of handles 24 and 27 are moved to the "Up"
position, oil from pump 25 is supplied to both of cylinders 18 and 21 and the boom 1~ is raised by the joint action of both of these cylinders~ However, inasmuch as the oil is still the same output supplied by the same pump 25, the rais-ing speed will be considerably slower than with raising being - accomplished only by cylinder 21 and very much slower than with raising being accoYnplished only by cylinder 18. However, this provides the maximum lifting force for raising the maxi-mum load. In ~act, cylin~er sizes would of course be chosenby the crane designer such that with the pressure available from pum.p 25 the maximum design capacity could be raised. The pistons o~ cylinder means 18 and 21 combined might have the same area as would in the past have been provided in cylinder mean3 18 as the sole cylin~er means.
This designing of the components to be able to lift the load at a rated capacity is of course standard practice.
Heretofore, however, it has been accompanied by the disadvantage that the speed of movement determined by this method o~ design would be the speed o movement for all boom-raising operations The boom-lowering operations have been slightly faster because the piston rods reduce the effective piston area on boom-lowering operations. Nevertheless, the slow speed o~ lowering resulting from the design for maximum loads has been applicable to all boom-lo~w2ring operations~
- As already explained, how2ver, the present invention permits two faster operations o~ raising and lowering boom 14.
The fastest is by powering cylinder 18 alone and the slower or intermediate speed is by powering cylinder 21 alone.
Designers may in some instances choose to increase rated capacities by using slightly larger total piston area Y'--'~Y
., , ~
r ~V--~VJ
LR/vt , :~S0395 than before, knowing that by the present invention the previous disadvantage of slow speed can be avoided in most operations.
SELECTIVE OPE~ING OF SAFEI~ VALVES
Safety requirements require the use of such safety valves as 31 and 32. Such a valve controls the flow of oil out~ardly through the lower or gravity pressured port or a cylinder. These valves prevent the flow of oil out through their respective ports except when actuated or opened by a R p;/~t pilot pressure through their respective ~ lines 33 and 34.
In the case of a normal lowering operation, for example by moving valve handle 27 to the "Down" position, pressure from pump 25 will be directed through the lowering line 36 to upper -port 37 ~f cylinder 21. This alone would not cause the lowering of the boom because closed valve 32 would prevent the discharge of oil from bel~w the piston of cylinder 210 However, the pres-sure ap~lied to lowering line 36 is also applied ~through valve 38 in Fig. 3) to pilot line 34 thereby opening valve 32 to allow the necessary outf 1QW of oil from the lower end of cylinder 21.
~he speed of lowe~ing can be delicately controlled by handle 27 because iE it merely cracks op~.n val~e 26, the pressure applied to lGwering line 36 will be quic'~ly reduced by the downward move-ment of the piston in cylinder -21, thereby allowing safety val~e 32 to reclose or partially reclose. In short~ if only a slight ~low of oil is permitted by valve 26, only a correspondingly slow speed of movement of boom 14 will result.
In order to achieve the "Idle" or "Float" condition for cylinder 18 or cylinder 21, it is necessary to supply ~
pilot pressure of oil to its pilot line 33 or 34 when its valve 23 or 26 is moved to the "Idle" position. This function is accomplished by the auxiliary valve 41, for valve 23, or 42 for valve 26. Thus as handle 27 moves from the "Vown" position to t~.e "Idle" position~ it actuates plun~er 43 which actuates the .. . .
105~39S
spool in valve 42 to 5upply oil to the Eloat-pilot line 44.
1'his pressure trips valve 3~ to cloc;e its connection to line 36 so that the pressure supplied to line ~4 is directed entirely to pilot line 34.
Valve 38 is a type of valve Xn~n as a shuttle valve.
The characteristic of such valves is tha~ if pressure is sup-plied to it by line 44, it closes its connection to line 36, and if pressure is supplied to it by line 36, it closes its connection to line 44. Without valve 38 the needed pilot pressure would not reach valve 32. When valve 42 is not actu-ated by its plunger 43, it is spring returned.to its neutral position which connects line 44 to discharge 29. ~ikewise line 36 is connected to discharge 29 when valve 26 is in lts idle position. Hence it is necessary to close the respective connections to either of these lines when the other line is supplied wi~h pressure, in order for that pressurs to be con-~eyed to pilot line 34 instead of being wasied to discharge 29.
. ~t will be apparent that in similar manner, when handle 24 is moved to the "Idle" position~ it ac~uates plunger 46 to actuate the spool of valve 41 to supply pressure from pump 25 to its float-~ilot lin9 47 and through its associated shuttle t~alve 38 to pilot line 33 for actuating or opening pilot valve 31 so that oil can 1Ow from beneath the piston of cylinder.18 through valve 23 to discharge 29 or.to the upper end of cylinder 18~ It should be understood that valves .23, 26, 41 and 42 will in practice usually be four side-by-side spools in a single valve block represented by the broken lin9s 49. Oil pressure from pump 25 is made available by this valve block to all of the spools but passes to discharge 29 when no spool is actuated, or when a predetermined maximum working pressure is exceeded.
8 :`~
~/vt ~5~395 It is expected that-a valving system,under which all .
of the cylinders supporting boom 14 would be ef~ectively in the ~Float" condition would be prohibited for safety reasons.
That would permit the boom 1~ to fall as rapidly as its pistons could discharge the oil through wide-open safety valves 31 and 32 and connecting lines To positlvely prevent this unsafe occurrence, some interlock such as bar 51, seen best in Fig. 4, is preferably provided. If handle 27 is moved to the 'lIdlel~
position represented by broken lines 27', it swings the inter-lock lever 51 to the position shown in Fig. 4 so that the handle24 can be moved no f,urther toward the "Idle" position than is represented by broken,lines 24'. In this position, it will not yet have actuated its plunger 46. Likewise, if handle 24 is thrust to its "Idle" position, it reverses the position of interlock bar 51 so that handle 27 can be moved no further tha~
to the "Down" position at which it has not yet actuated its plunger 43.
For the purpose of illustration, Fig. 3 has shown valve sets 23, 41 and 26, 42 in positions such that the inter-lock be~ween their handIes would not be as simple as seen inFig. 4. ~evertheLess, the interlock bar 51 has been shown in conjunction with handle 27 with a phantom or partly broken away showing o~ handle 24 in the background as if obstructed by the interlock bar 51.
ACHIEVEM~NT
From the foregoing it is apparent that the present invention can provide three speeds of boom operation with a single constant-flow supply of oil under pressure. The fastest speed results from powering only cylinder 18, a slower speed by powering cylinder 21, and the slowest speed by powering both cylinders. Operation is exceedingly simple, the operator .. 9 "
LK/Vt -- ` 105039S
normally operating only-one valve control handle for ~oom raising or lowering as has been the case heretofore; the other valve handle being left in the "Idle" posi-tion. Thus when lisht loads are to be handledy handle 27 wilL be thrust to the "Idle" position and left there, and the boom will be raised and lowered by movements of handle 24. When moderately heavier loads are to be handled, handle 24 will be thrust to ~he '~Idle~ position and the boom will be raised and lowered under the control of handle 27. When loads too heavy for cylinder 21 are to be handled, which in many jobs will be only rarely, both of handles 24 and 27 will be operated simul-taneously for controlling the raising and lowering of the . boom 14. Preferably these handles are close enough togetherto be grasped by one hand and moved by that hand simultaneo~sly~
leaving the o~her hand free for controlling another function . such as ~oom swing or raising or~lowering the line.
In the claims, the term "oil" should be understood to include any hydraulic fluid used for powering the cy1inders.
.
.
. ' ' . ' ' ' ' ' .
, - 1~ '-'.
Claims (8)
1. A hydraulic system for actuating a member at different speeds in each of opposite directions when using a generally constant-speed supply of pressured-oil including a first cylinder means, a second cylinder means of larger diameter, and valving means for jointly supplying pressured-oil from a single source optionally (a) to the first cylinder means while the second cylinder means is allowed to float;
(b) to the second cylinder means while the first cylinder means is allowed to float, or (c) to both cylinder means simultaneously to achieve the maximum actuation force available by supplying said oil pressure to the combined piston areas of both cylinder means, with a resultant lower operating speed than when either cylinder means is powered alone.
(b) to the second cylinder means while the first cylinder means is allowed to float, or (c) to both cylinder means simultaneously to achieve the maximum actuation force available by supplying said oil pressure to the combined piston areas of both cylinder means, with a resultant lower operating speed than when either cylinder means is powered alone.
2. A hydraulic system for actuating a member at different speeds in each of opposite directions when using a generally constant-speed supply of pressured-oil including a first cylinder means, a second cylinder means of larger diameter, and separate valving means for each cylinder means for jointly supplying pressured-oil from a single source optionally (a) to the first cylinder means while the second cylinder means is allowed to float, (b) to the second cylinder means while the first cylinder means is allowed to float, or (c) to both cylinder means simultaneously to achieve the maximum actuation force available by supplying said oil pressure to the combined piston areas of both cylinder means, with a resultant lower operating speed than when either cylinder means is powered alone.
3. A hydraulic system for raising and lowering a boom, each at different speeds, when using a generally constant-speed supply of pressured-oil including a first cylinder means, a second cylinder means of larger diameter, and separate valving means for each cylinder means for jointly supplying pressured-oil from a single source optionally:
(a) to the first cylinder means while the second cylinder means is allowed to float, (b) to the second cylinder means while the first cylinder means is allowed to float, or (c) to both cylinder means simultaneously to achieve the maximum lifting force available by supplying said oil pressure to the combined piston areas of both cylinder means, with a resultant lower operating speed than when either cylinder means is powered alone.
(a) to the first cylinder means while the second cylinder means is allowed to float, (b) to the second cylinder means while the first cylinder means is allowed to float, or (c) to both cylinder means simultaneously to achieve the maximum lifting force available by supplying said oil pressure to the combined piston areas of both cylinder means, with a resultant lower operating speed than when either cylinder means is powered alone.
4. A hydraulic system according to claims 1, 2 or 3 in which the valving means for each cylinder means includes a reversing valve with neutral, cylinder-extending, cylinder-retracting, and idle positions.
5. A hydraulic system according to claims 1, 2 or 3 in which the valving means for each cylinder means includes a reversing valve with neutral, cylinder-extending, cylinder-retracting, and idle positions, and a second valve actuated as the reversing valve is moved to idle position for supplying pilot pressure to open a cylinder safety valve.
6. A hydraulic system according to claims 1, 2 or 3 in which the valving means for each cylinder means includes a reversing valve with neutral, cylinder-extending, cylinder-retracting, and idle positions, and a second valve actuated as the reversing valve is moved to idle position for supplying pilot pressure to open a cylinder safety valve; said system including interlock means for preventing the simultaneous supply of pilot pressure from both of said second valves.
7. A hydraulic system according to claims 1, 2 or 3 including interlock means for preventing the simultaneous float condition of both the cylinder means.
8. A hydraulic system according to claims 1, 2 or 3 in which the valving means for each cylinder means includes a reversing valve with neutral, cylinder-extending, cylinder-retracting, and idle positions; said system including interlock means for preventing the reversing valves from being simultane-ously in idle positions.
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US05/593,374 US4033468A (en) | 1975-03-17 | 1975-07-07 | Hydraulic boom-lift system with selective speeds |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1050395A true CA1050395A (en) | 1979-03-13 |
Family
ID=24374460
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA256,014A Expired CA1050395A (en) | 1975-07-07 | 1976-06-29 | Hydraulic boom-lift system with selective speeds |
Country Status (1)
| Country | Link |
|---|---|
| CA (1) | CA1050395A (en) |
-
1976
- 1976-06-29 CA CA256,014A patent/CA1050395A/en not_active Expired
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| JPH081202B2 (en) | Operating circuit of single-acting hydraulic cylinder | |
| US3990583A (en) | Device for controlling the boom elevation of a side crane | |
| GB2057580A (en) | Hydraulic control circuit system | |
| KR20020071003A (en) | Mobile handling device | |
| US4344733A (en) | Hydraulic control circuit for decelerating a swinging backhoe | |
| US4165675A (en) | Load check valve cylinder mounted | |
| US4365429A (en) | Maximum lift system for hydraulic hoe | |
| JPH11247805A (en) | Control device for quick drop valve | |
| US6308612B1 (en) | Hydraulic leveling control system for a loader type vehicle | |
| CA2342661C (en) | Hydraulic boom control | |
| US4801126A (en) | Hydraulically operated lift mechanism | |
| CA1050395A (en) | Hydraulic boom-lift system with selective speeds | |
| US4033468A (en) | Hydraulic boom-lift system with selective speeds | |
| JPS63138026A (en) | Oil-pressure circuit of oil-pressure shovel | |
| US4018350A (en) | Hydraulic cyliner systems with safeguarded float action | |
| JPH05202903A (en) | Liquid-pressure driving system | |
| CN109356218B (en) | Distribution valve for loader and loader hydraulic system | |
| EP0279356B1 (en) | Hydraulic system for a construction machine | |
| US3483890A (en) | Multispool control valve with limited series operation | |
| JP2000327270A (en) | Actuator control circuit of crane truck and its actuator control method | |
| JPH0118686Y2 (en) | ||
| JPS6312241Y2 (en) | ||
| JP3005869B2 (en) | Circuit for preventing sudden change in low-pressure actuator speed during combined operation | |
| JPS61119803A (en) | Safety device in hydraulic circuit of agricultural tractor | |
| JPH02128026A (en) | Hydraulic circuit of hydraulic system excavator |