1. Field of the Invention
The present invention relates to vehicles having a primary transmission and a hydraulic motor that provides a drive assist and, more particularly, a hydraulic circuit including such a hydraulic assist motor.
2. Description of the Related Art
Many large vehicles include a mechanical transmission as the primary driver of the vehicle and use hydraulic assist motors to selectively drive additional wheels. For example, such a vehicle may have rear wheels driven by the mechanical transmission and front steerable wheels that are selectively driven by hydraulic assist motors. When being driven on a paved road, such a vehicle will typically employ only the mechanical transmission. When the vehicle must be driven in poor traction or off-road conditions, e.g., when on a construction site, it can be beneficial to employ the hydraulic assist motors to provide the vehicle with an additional set of driven wheels.
As a general rule, the hydraulic assist motors employed in such vehicles are subject to damage if the pistons of the motors are not retracted when the motors are de-activated and the vehicle is in motion, e.g., traveling on a paved road. While various hydraulic circuits are known for use with such selectively actuated hydraulic motors, such circuits often rely on highly complex valves that require extensive custom machining and, thus, can be quite expensive.
The present invention provides a hydraulic circuit with a plurality of valves for controlling the operation of at least one hydraulic motor wherein the valves may take the form of relatively simple and inexpensive solenoid cartridge valves.
The invention comprises, in one form thereof, a hydraulic circuit (22, 23) that includes at least one hydraulic motor (24) and a first hydraulic discharge pump (62, 162). The motor (24) defines a motor cavity (54) and includes at least one piston (40) at least partially disposed within a piston bore (42) and moveable between an extended position and a retracted position (40R). The piston (40) permits free rotation of the motor (24) when in the retracted position. The first hydraulic pump (62, 162) has a selectively variable discharge. Hydraulic fluid can be recirculated through a first loop within the circuit (22). The first loop includes, in serial order, the first hydraulic pump (62, 162), a first hydraulic line (94), said hydraulic motor (24) and a second hydraulic line (96). A third hydraulic line (98) provides fluid communication between the first hydraulic line (94) and a first valve (86). A fourth hydraulic line (118) provides fluid communication between the second hydraulic line (96) and a second valve (88). A fifth hydraulic line (lines 126, 130, 132 combined) provides fluid communication between the first and second valves (86, 88). The first valve (86) has an open position (
In some embodiments, the hydraulic circuit (22, 23) also includes a hydraulic fluid storage vessel (60) wherein the second pump (64, 65) receives fluid (via lines 102, 140) from the storage vessel (60). An eighth hydraulic line (122, 123) provides fluid communication between the motor bearings and/or cavity (54) and the storage vessel (60).
In other embodiments, the hydraulic circuit (22, 23) further includes a ninth hydraulic line (124, 125) providing fluid communication between the third valve (84, 85) and the storage vessel (60) wherein the third valve (84, 85) provides fluid communication between the seventh (120, 144) and ninth (124, 125) hydraulic lines when the third valve (84, 85) is in its second position.
In still other embodiments, the hydraulic circuit (22, 23) includes a fourth valve (90). The fourth valve (90) has an open position allowing fluid communication from the fifth hydraulic line (126, 130, 132) to the ninth hydraulic line (124, 125) and a closed position preventing fluid communication from the fifth hydraulic line (126, 130, 132) to the ninth hydraulic line (124, 125). The fourth valve (90) is positioned in its open position when the at least one piston (40) is in its retracted position. The fourth valve (90) is moved to its closed position when extending the at least one piston (40) and actuating the at least one hydraulic motor (24).
In yet additional embodiments, the hydraulic circuit (22, 23) includes a one-way check valve (92) disposed between the fifth (126, 130, 132) and sixth (100, 101) hydraulic lines. The one-way check valve (92) allows fluid communication from the sixth hydraulic line (100, 101) to the fifth hydraulic line (126, 130, 132) and prevents fluid communication from the fifth hydraulic line (126, 130, 132) to the sixth hydraulic line (100, 101).
The first (86), second (88), third (84, 85) and fourth (90) valves may advantageously take the form of solenoid activated valves.
In still other embodiments of the invention, the circuit (22, 23) may include a tenth hydraulic line (108, 125) providing fluid communication between the sixth hydraulic line (100, 101) and a storage vessel (60) wherein a pressure relief valve (66, 67) is disposed in the tenth hydraulic line (108, 125) and releases hydraulic fluid from the sixth hydraulic line (100, 101) toward the storage vessel (60) when the fluid pressure within the sixth hydraulic line (100, 101) exceeds a predetermined threshold value.
The above mentioned and other features of this invention, and the manner of attaining them, will become more apparent and the invention itself will be better understood by reference to the following description of embodiments of the invention taken in conjunction with the accompanying drawings, wherein:
Corresponding reference characters indicate corresponding parts throughout the several views. Although the exemplification set out herein illustrates embodiments of the invention, in several forms, the embodiments disclosed below are not intended to be exhaustive or to be construed as limiting the scope of the invention to the precise forms disclosed.
A vehicle 20 having a hydraulic circuit 22 that includes two hydraulic motors 24 is schematically depicted in
When vehicle 20 is operating, power train 28 and wheels 30 provide the primary driving wheels for vehicle 20 while motors 24 and wheels 34 provide a pair of auxiliary drive wheels for use when vehicle 20 is being operated in poor traction conditions, on rough terrain, or in other circumstances in which providing additional drive wheels is advantageous. In the illustrated embodiment, wheels 34 are steerable wheels while wheels 30 are non-steerable wheels. The present invention, however, may be used with a variety of other vehicles. For example, hydraulic motors 24 can also be used with non-steerable wheels and the primary drive system of the vehicle could employ a hydraulic circuit with hydraulic motors located between engine 26 and primary drive wheels 30 rather than a mechanical power train.
After discussing the general structure and operation of hydraulic motors 24, the structure and operation of hydraulic circuit 22 within which hydraulic motors 24 are located will be discussed.
The illustrated hydraulic motors 24 used in hydraulic circuit 22 are conventional hydraulic motors and a cross sectional view of hydraulic motors 24 is provided in
Cam ring 46 is secured to a conventional wheel hub assembly (not shown) by inserting fasteners through holes 48 in cam ring 46. A wheel 34 is mounted on the wheel hub assembly whereby operation of each of the hydraulic motors 24 drivingly rotates one of the wheels 34.
As can be seen in
During operation of motor 24, high pressure hydraulic fluid will be supplied to some of the bores 42 forcing the pistons 40 and rolling cam members 44 associated with those bores 42 radially outwardly while other pistons 40 and cam members 44 are being forced radially inwardly and expelling relatively low pressure hydraulic fluid. As one having ordinary skill in the art will understand, this will drivingly rotate camming ring 46 and wheel 34 mounted thereon. By altering the sequence in which piston bores 42 receive the high pressure hydraulic fluid, camming ring 46 can be driven in either rotational direction and thereby selectively rotate wheels 34 in either the forward or reverse direction.
As discussed in greater detail below, the hydraulic fluid for driving pistons 40 is supplied to and returned from motors 24 through hydraulic lines 94, 94a and 96, 96a. When high pressure hydraulic fluid is supplied to motors 24 through lines 94, 94a and reduced pressure hydraulic fluid returned through lines 96, 96a, motors 24 will rotate cam rings 46 and wheels 34 in one direction, e.g., forward. When high pressure hydraulic fluid is supplied to motors through lines 96, 96a and reduced pressure hydraulic fluid returned through lines 94, 94a, motors 24 will rotate cam rings 46 and wheels 34 in the opposite direction, e.g., reverse.
It is sometimes desirable to have the ground engaging wheels 34 secured to motors 24 rotate freely without having hydraulic motors 24 powering the rotation of wheels 34. During such periods of free wheel rotation or “roading,” pistons 40 are retracted so that rolling cam members 44 do not interfere with the rotation of cam ring 46. As discussed in greater detail below, retraction of pistons 40 is accomplished by reducing the flow and pressure of the hydraulic oil communicated to all of the piston bores 42 while maintaining the hydraulic oil within motor case cavities 54 at a greater pressure. Hydraulic lines 120, 120a are in communication with motor case cavity 54 and, as discussed in greater detail below, are used to regulate the pressure of hydraulic fluid within motor case cavities 54. In
When free-wheeling, the pressure of the oil located between camming ring 46 and cylinder block 36 is regulated not only to maintain the pressure at a value that keeps pistons 40 retracted but also to replace the volume of oil seeping from motor 24. The motor seepage oil cools and lubricates bearings (not shown) located on spindle shaft 38. After lubricating the bearings, this seepage oil is advantageously returned by internal passages to lines 122, 122a by which it is conveyed to tank 60. The circulation of seepage oil occurs when vehicle 20 is operating with motors 24 in a free-wheeling configuration with pistons 40 retracted and when motors 24 are operating and driving wheels 34.
The general structure of hydraulic circuit 22 will now be discussed with reference to
Pump module 56 includes a reversible variable displacement pump 62 and a charge pump 64 that are powered by PTO shaft 32. PTO shaft 32 drives pumps 62, 64 whenever engine 26 is operating. Charge pump 64 is a constant displacement pump and discharges hydraulic oil at a substantially constant pressure. In the illustrated embodiment, charge pump 64 discharges hydraulic oil at a pressure that remains substantially constant at about 400 psi. Variable displacement pump 62 discharges oil at variable quantities and pressures.
Hydraulic lines 94, 96 act as the inflow and discharge lines for variable displacement pump 62. The illustrated variable displacement pump 62 is a selectively reversible pump. Thus, pump 62 has two operating conditions: one in which line 96 is the inflow line and line 94 is the discharge line and another one in which line 94 is the inflow line and line 96 is the discharge line.
Lines 94 and 96 lead to ports on each of the hydraulic motors 24 either directly or through branch lines 94a, 96a. The pumps 24 are arranged in parallel. Lines 94, 96 and 94a, 96a are in communication with the internal valve assembly within motors 24 that feed and drain hydraulic fluid from cylinder bores 42. As mentioned above, when high pressure hydraulic fluid is provided to motors 24 through hydraulic lines 94, 94a and reduced pressure hydraulic fluid is returned to pump 62 through lines 96, 96a, pumps 24 will operate in a first rotational direction. When pump 62 is reversed and high pressure fluid is provided to motors 24 through hydraulic lines 96, 96a and reduced pressure hydraulic fluid is returned to pump through lines 94, 94a, motors 24 will operate in the opposite rotational direction. Because the hydraulic fluid is returned directly to pump 62 from motors 24, hydraulic system 22 is referred to as a closed system.
Hydraulic line 94 (and pump 62) is also in communication with valve cartridge 86 through hydraulic line 98. Similarly, hydraulic line 96 (and the opposite side of pump 62) is in communication with valve cartridge 88 through hydraulic line 118. The purpose of hydraulic lines 98, 118 and valve module 58 is discussed in greater detail below.
Charge pump 64 receives hydraulic fluid from tank 60 through hydraulic line 102 and discharges hydraulic fluid into hydraulic line 100. Hydraulic line 100 connects charge pump 64 with valve cartridge 84. Valve cartridge 84 is also in fluid communication with motor case cavities 54 of motors 24 through hydraulic lines 120, 120a and with tank 60 through hydraulic line 124.
Hydraulic line 104 is in communication with discharge line 100 and provides fluid communication to pressure relief valve 66 via hydraulic line 106. Hydraulic oil flowing through pressure relief valve 66 enters hydraulic line 108 which conveys the hydraulic oil toward tank 60. In the illustrated embodiment, pressure relief valve 66 is set such that the pressure within discharge line 100 will not exceed a pressure of approximately 50 psi. Charge pump 64 has a substantially constant discharge rate with a discharge pressure of approximately 400 psi. When pump 64 is discharging fluid into line 100, a fraction of this discharge flow will, thus, flow through pressure relief valve 66 into hydraulic line 108.
Hydraulic fluid entering hydraulic line 108 passes through oil cooler 76 and oil filter 80 before entering tank 60. Oil cooler 76 includes an internal bypass valve 78 that allows hydraulic fluid to bypass cooler 76 and continue flowing toward tank 60 if cooler 76 becomes clogged. Similarly, oil filter 80 includes an internal bypass valve 82 that allows hydraulic fluid to bypass filter 80 and continue flowing toward tank 60 if filter 80 becomes clogged. It is also noted that hydraulic line 109 conveys seepage oil from pump 62 to line 108 where it enters the flow of hydraulic oil being conveyed to tank 60. The volume of hydraulic fluid conveyed through oil seepage lines 109 and lines 122, 122a is relatively minimal compared with the volumes of hydraulic oil conveyed through the discharge ports of pumps 62, 64.
The discharge flow from charge pump 64 is also communicated through discharge line 100 and line 104 to hydraulic lines 110 and 112 and, thus, one-way by-pass valves 74 and 70. By-pass valve 74 is positioned parallel with pressure relief valve 72 with both valves 74 and 72 positioned between hydraulic line 94 (via hydraulic line 114) and hydraulic line 100 (via hydraulic line 104). Pressure relief valve 72 is positioned to relieve the pressure within hydraulic line 94 if it exceeds a predetermined threshold, e.g., a pressure that would damage pump 62 or motors 24. Pressure relief valve 72 will allow the flow of hydraulic fluid from line 94 into hydraulic line 104 where it can flow through hydraulic line 106, pressure relief valve 66 and into hydraulic line 108 which will convey the fluid to tank 60. If the pressure within line 94 becomes excessively low relative to hydraulic line 100, one-way valve 74 will allow the passage of hydraulic fluid from line 100 through lines into hydraulic line 94 via the interconnecting hydraulic lines 104, 110 and 114.
Similarly, by-pass valve 70 is positioned parallel with pressure relief valve 68 with both valves 70 and 68 positioned between hydraulic line 96 (via hydraulic line 116) and hydraulic line 100 (via hydraulic line 104). Pressure relief valve 68 is positioned to relieve the pressure within hydraulic line 96 if it exceeds a predetermined threshold, e.g., a pressure that would damage pump 62 or motors 24. Pressure relief valve 68 will allow the flow of hydraulic fluid from line 96 into hydraulic line 104 where it can flow through hydraulic line 106, pressure relief valve 66 and into hydraulic line 108 which will convey the fluid to tank 60. If the pressure within line 96 becomes excessively low relative to hydraulic line 100, one-way valve 70 will allow the passage of hydraulic fluid from line 100 into hydraulic line 96 via the interconnecting hydraulic lines 104, 112 and 116.
As mentioned above, hydraulic line 118 is in fluid communication with valve cartridge 88. Hydraulic line 126 extends between valve cartridge 88 and valve cartridge 90. Valve cartridge 90 is, in turn, in fluid communication with hydraulic line 124 through hydraulic line 128. Hydraulic line 130 extends between line 126 and hydraulic line 100 and includes a one-way check valve 92. Hydraulic line 132 provides fluid communication between hydraulic line 130 and valve cartridge 86. Check valve 92 is positioned so that it prevents hydraulic fluid from lines 126 and 132 from entering hydraulic line 100. If the pressure within hydraulic line 100 exceeds the pressure within line 130, check valve 92 will open allowing hydraulic fluid from line 100 to enter line 130. Once such fluid has entered line 130, the flow of the fluid will depend, in part, on the positions of valves 86, 88 and 90.
Valve cartridges 84, 86, 88 and 90 are commonly available conventional valve cartridges. The use of valve cartridges 84, 86, 88 and 90 in the arrangement depicted in
Valve cartridges 86, 88 and 90 each have a common structure with two valve arrangements 86a, 86b; 88a, 88b; 90a, 90b, a solenoid 86c, 88c, 90c and a biasing member 86d, 88d, 90d. The biasing members 86d, 88d, 88d of valve cartridges 86, 88, 90 respectively urge valve arrangements 86a, 88a, 90a into communication with the hydraulic lines connected with the cartridges while activation of solenoids 86c, 88d, 90d will place valve arrangements 86b, 88b, 90b into communication with the hydraulic lines connected with the cartridges. Each of the valve cartridges 86, 88 and 90 are connected with two hydraulic lines and valve arrangements 86a, 88a, 90a provide fluid communication between the two hydraulic lines. Valve arrangements 86b, 88b, 90b each include a one-way check valve. Valve arrangement 86b only allows fluid flow from line 132 to line 98, valve arrangement 88b only allows fluid flow from line 126 to line 118 and valve arrangement 90b only allows fluid flow from line 128 to line 126. Valves 86, 88 and 90 are referred to herein as being “open” when valve arrangements 86a, 88a, 90a are being employed and “closed” when valve arrangements 86b, 88b, 90b are being employed.
The operation of hydraulic circuit 22 and its control of motors 24 will now be discussed with reference to
As can also be seen in
The operating condition illustrated in
As can be seen in
Because valve 84 does not allow fluid in line 100 to enter line 120, fluid discharged from pump 64 entering line 100 will pass through one-way check valve 92. With both valve cartridges 86, 88 being in an “open” position, i.e., with valve arrangements 86a and 88a providing fluid communication between lines 98 and 132 and between lines 118 and 126 respectively, fluid flowing from line 100 into line 130 and then lines 126 and 132 will pass through valves 86 and 88 and enter lines 98 and 118. After entering lines 98 and 118 the fluid will be in communication with lines 94/94a and 96/96a.
Because valve cartridges 86, 88 are each in an “open” position, fluid within line 98, and lines 94/94a which are in fluid communication therewith, and line 118, and lines 96/96a which are in fluid communication therewith, will all substantially equalize. Thus, the fluid pressure within lines 94/94a and 96/96a will also be increased and motors 24 will experience a fluid pressure increase in piston bores 42. This increase in the fluid pressure will extend pistons 40 and re-engage rolling cam members 44 with camming surface 50. Because the increased pressure in lines 94/94a is substantially equivalent to the increased pressure in lines 96/96a, motors 24 will not experience a pressure differential between lines 96 and 94 or between lines 96a and 94a and the increased fluid pressure in piston bores 42 will not cause motors 24 to rotate due to hydraulic pressure. The motors 24 may, however, be rotating due to motion of the vehicle.
After closing valves 86, 88, hydraulic lines 94/94a and 96/96a form a closed loop that includes pump 62 and motors 24 with motors 24 being arranged in parallel. Depending upon which direction pump 62 is pumping either line 94/94a will be a high pressure discharge line with line 96/96a being a relatively low pressure return line, or, line 96/96a will be a high pressure discharge line with line 94/94a being a relatively low pressure return line. The pressure differential and fluid flow across motors 24 in this situation will cause motors 24 to rotate and drive wheels 34. The direction of rotation of motors 24 will depend upon the direction in which pump 62 is operating.
Seepage oil and oil from cavity 54 is returned to tank 60 through lines 109, 122, 122a and 124 in the motor operation condition depicted in
When it is desirable to stop the operation of motors 24 and return to the free-wheeling condition depicted in
With regard to the control valves for circuit 23, valves 86, 88, 90 and 92 all operate in the same manner as described above with reference to
Hydraulic lines 146 and 148 are oil seepage lines that are in communication with line 125 and return pump lubricating seepage to tank 60 while hydraulic line 150 is used to provide variable displacement pump 162 with hydraulic oil to replace seepage and other losses when pump 162 is operating. With regard to the replacement of seepage losses, it is noted
When making the transition from the free-wheeling condition depicted in
After pistons 40 have been extended, valves 86 and 88 are closed to separate the forward and reverse lines 94/94a and 96/96a feeding motors 24. Pumps 162, 164 are then actuated. A clutch (not shown) is disposed between pumps 162, 164 and the PTO shaft to selectively activate and deactivate pumps 162, 164. The discharge volume of pump 162 is then raised thereby raising the pressure in either hydraulic lines 94/94a or in hydraulic lines 96/96a depending upon the direction in which pump 162 is operating. As a result of the hydraulic fluid flow through lines 94/94a and 96/96a, motors 24 will begin operating and driving wheels 34 in either a forward or reverse direction depending upon the operating direction of pump 162.
While the illustrated embodiments employed charge pumps in combination with variable displacement pumps 62, 162, alternative embodiments could utilize other constant sources of low pressure hydraulic fluid instead of charge pumps.
While this invention has been described as having an exemplary design, the present invention may be further modified within the spirit and scope of this disclosure. This application is therefore intended to cover any variations, uses, or adaptations of the invention using its general principles.
This is a continuation of and claims priority of application Ser. No. 12/387,685 filed May 6, 2009 now U.S. Pat. No. 8,276,376 the disclosure of which is hereby incorporated herein by reference.
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Number | Date | Country | |
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Parent | 12387685 | May 2009 | US |
Child | 13573263 | US |