Deprecated: The each() function is deprecated. This message will be suppressed on further calls in /home/zhenxiangba/zhenxiangba.com/public_html/phproxy-improved-master/index.php on line 456
GB2135256A - Vehicle differential drive steering system - Google Patents
[go: Go Back, main page]

GB2135256A - Vehicle differential drive steering system - Google Patents

Vehicle differential drive steering system Download PDF

Info

Publication number
GB2135256A
GB2135256A GB08400120A GB8400120A GB2135256A GB 2135256 A GB2135256 A GB 2135256A GB 08400120 A GB08400120 A GB 08400120A GB 8400120 A GB8400120 A GB 8400120A GB 2135256 A GB2135256 A GB 2135256A
Authority
GB
United Kingdom
Prior art keywords
steering
pressure
steering system
hydrostatic transmission
valve
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.)
Granted
Application number
GB08400120A
Other versions
GB8400120D0 (en
GB2135256B (en
Inventor
Stanley Henshaw Booth
John Christopher Eglingt Flint
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
COMMERCIAL HYDRAULICS Ltd
Original Assignee
COMMERCIAL HYDRAULICS Ltd
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Priority claimed from GB838300483A external-priority patent/GB8300483D0/en
Application filed by COMMERCIAL HYDRAULICS Ltd filed Critical COMMERCIAL HYDRAULICS Ltd
Priority to GB08400120A priority Critical patent/GB2135256B/en
Publication of GB8400120D0 publication Critical patent/GB8400120D0/en
Publication of GB2135256A publication Critical patent/GB2135256A/en
Application granted granted Critical
Publication of GB2135256B publication Critical patent/GB2135256B/en
Expired legal-status Critical Current

Links

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B62LAND VEHICLES FOR TRAVELLING OTHERWISE THAN ON RAILS
    • B62DMOTOR VEHICLES; TRAILERS
    • B62D11/00Steering non-deflectable wheels; Steering endless tracks or the like
    • B62D11/02Steering non-deflectable wheels; Steering endless tracks or the like by differentially driving ground-engaging elements on opposite vehicle sides
    • B62D11/06Steering non-deflectable wheels; Steering endless tracks or the like by differentially driving ground-engaging elements on opposite vehicle sides by means of a single main power source
    • B62D11/10Steering non-deflectable wheels; Steering endless tracks or the like by differentially driving ground-engaging elements on opposite vehicle sides by means of a single main power source using gearings with differential power outputs on opposite sides, e.g. twin-differential or epicyclic gears

Landscapes

  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Transportation (AREA)
  • Mechanical Engineering (AREA)
  • Non-Deflectable Wheels, Steering Of Trailers, Or Other Steering (AREA)

Abstract

A vehicle having tracks or sets of wheels on opposite sides thereof, is provided with a steering system which comprises a differential drive for the tracks or wheel sets which includes a hydrostatic transmission 29, 30, 33, 34, and a control which is operative in response to a steering demand to cause the hydraulic transmission to drive the tracks or wheel sets at different relative speeds and thereby steer the vehicle. When the pressure in the hydrostatic transmission rises above a predetermined level during such steering, a brake 28 is automatically actuated to apply a braking effect to the appropriate track or wheel set, thereby supplementing the steering action. The action of the brake is progressive, i.e. it applies an increasing braking effect with increased steering demand. <IMAGE>

Description

SPECIFICATION Vehicle steering system This invention relates to a steering system for a vehicle having tracks or sets of wheels on opposite sides thereof, the vehicle being steered by varying the speed of one track or wheel set relative to the speed of the other.
In a particular example of a steering system of this type, each track or wheel set is coupled to a planet carrier of a respective epicyclic gearing, a sun gear and an annular gear of this gearing being coupled respectively to a common mechanical drive parallel with a respective hydrostatic pump/motor, and to a direct mechanical connection. The pumps/motors, which are of variable displacement, form part of a closed hydrostatic transmission circuit and are operatively interlocked by means of a linkage such that an increase in the displacement of one pump/motor will cause a decrease in the displacement of the other.
In steering systems of this type, the direction of rotation of the sunwheels may be the same as that of their respective output shafts or opposite to that of their respective output shafts. While the descriptions that follow are based on the first of these arrangements, the systems would work equally well with the second arrangement.
During normal forward drive, both ofthe pumps/ motors operate at the same displacement so that the tracks or wheel sets are driven at the same speeds.
However, when the vehicle is turned to the left or right, the aforementioned linkage is operated to decrease the displacement of the pump/motor coupled to the track or wheel set on the opposite side of the vehicle to the turning direction, thereby increasing the speed of that track or wheel set. At the same time, the displacement of the other pump/motor is increased so as to decrease the speed of its associated track or wheel set. Differential gearing is provided in the common mechanical drive to permit the speeds of the tracks or wheel sets to vary inversely in this manner.
For small radius turns, where the pumps/motors are unable to provide enough steering torque on their own, the steering action is supplemented by applying a braking effect to the gear member (usually a sunwheel) whose speed is to be reduced.
More particularly, when the pressure in the hydrostatic transmission exceeds a predetermined value, a value is actuated to apply the hydraulic fluid to a brake on the appropriate side of the vehicle. However, the steering system tends to be rather unstable under such conditions of operation, because the action of applying the hydraulic fluid to the brake tends to reduce the hydrostatic pressure at the pumps/motors to a level below the aforementioned predetermined value, thereby causing the value to de-actuate and the brake to be released. The pressure in the hydrostatic transmission will then rise above the predetermined value to actuate the value once again, and so on. This instability gives rise to significant drawbacks in the operation of the previous steering system.
Another drawback of the system just described is caused by the fact that the pumps/motors are interlocked in their operation so that their displacements cannot be varied except in an inverse manner.
This means that the percentage of the capacity of each pump/motor which is available for steering power is limited.
It is an object of the present invention to overcome the above-described drawbacks.
According to the present invention, a steering system for a vehicle having tracks or sets of wheels on opposite sides thereof comprises a differential drive for said tracks or wheel sets which includes a hydrostatic transmission, control means operative in response to a steering demand to cause the hydraulic transmission to drive the tracks or wheel sets at different relative speeds and thereby steer the vehicle, and brake means which when the pressure in the hydrostatic transmission rises above a predetermined level causes a braking effect to be applied to the appropriate side of the system and thereby supplement the steering action, said braking effect increasing progressively with increasing steering demand.
Preferably, the control means includes an input member which is moved in accordance with said steering demand, an output member which moves in response to movement of the input member to cause the hydrostatic transmission to drive the tracks or wheel sets at different speeds, spring means which operatively interconnects the input and output members, and override means applying to the output member in opposition to the spring means a force which is dependent upon the pressure in the hydrostatic transmission, the spring means having a pre-load which is set so as to be overcome by the override means in the event that the pressure in the hydrostatic transmission exceeds a predetermined maximum safe level.
Desirably, the hydrostatic transmission includes a respective variable displacement pump/motor operatively coupled to each track or wheel set, and the control means is operative in response to said steering demand to alter the displacement of an appropriate one of the pumps/motors while maintaining the displacement of the other pump/motor substantially constant. In the absence of any steering demand both pumps/motors can be set to their maximum displacement, with the appropriate one having its displacement reduced in response to said steering demand.
In a particular example of the above, each pump/ motor has a control member which is movable to alter its displacement, and the control means includes a linkage which interconnects the control members and which is moved in response to said steering demand, the link occupying a neutral position when there is no steering demand wherein the displacements of both pumps/motors are equal, and being moved in one or the opposite direction when a steering demand is applied to the control unit to alter the displacement of said appropriate one of the pumps/motors. Preferably, the link is connected to the control members by respective pin-and-slot connections.
The brake means may include fluid pressureoperated brakes associated with a hydrostatic transmission and valve means operatively connected between the brakes and a source of pressurised fluid (which is preferably independent of the hydrostatic transmission), the valve means being operated to increase the fluid pressure supplied to the appropriate brake in response to said increasing steering demand. Conveniently, the valve means is responsive to the pressure in the hydrostatic transmission.
The control means may include an input member which is moved in accordance with said steering demand, and means (such as a pressurised fluid obtained from the hydrostatic transmission and passed through at least one pressure-reducing constriction) operative to apply a force to the input member which opposes such movementthereofto a degree dependent upon the pressure in the hydrostatic transmission.In this case, the valve means can include a valve member which is moved in one or the opposite direction from a neutral position to increase the fluid pressure applied to one or the other of said brakes respectively, the valve member and the input member of the control means being pivotally connected to a common link to which said steering demand is applied, preferably by way of an operating member which is pivotally connected to the link at a point intermediate the pivotal connections to the valve and input members.
In a preferred construction of the valve means, the valve member is axially movable within a cylinder to vary the size of one or the other of two constrictions in respective fluid paths from the pressurised fluid source. In one embodiment of such valve means, each constriction is normally open and is provided in a respective fluid path between the pressurised fluid source and drain, and each brake is connected to a point between the source and a respective one of the constrictions.In an alternative embodiment, each constriction is normally closed and is provided in a respective fluid path between the pressurised fluid source and a respective one of the brakes, and the valve means includes two further constrictions whose size can be varied by axial movement of the valve member within the cylinder, each of the further constrictions being provided between a respective one of the brakes and drain, and being normally open but being closed when the valve member moves to open the constriction between the respective brake and the source. Each constriction can be defined between opposed shoulders on the valve member and the cylinder respectively, in which case one of the shoulders (preferably the one on the valve member) can be grooved or notched at spaced points on its periphery.
Alternatively, where the hydrostatic transmission includes a respective hydrostatic pump/motor operatively coupled to each track or wheel set and the two pumps/motors are connected together by hyd raulic lines so as to form a closed hydraulic circuit, the valve means can comprise a pair of valves each of which is responsive to the pressure in a respective one of said hydrostatic lines to operate a respective one of said brakes. In this case, each valve can include a valve member which is axially movable within a cylindertovarythesize of a constriction in a fluid path from the pressurised fluid source, and the valve member can be moved in dependence upon the pressure in the hydrostatic transmission to reduce the size of the constriction with increasing pressure. The constriction is preferably of the form mentioned above.
In addition, the valve member can be acted upon in opposite axial directions by a fluid whose pressure is dependent upon the pressure in the hydrostatic transmission and by a spring having a pre-load which can be overcome by said fluid pressure when the pressure in the hydrostatic transmission reaches said predetermined level. This fluid pressure can be obtained by connecting the valve to the hydrostatic transmission through at least one pressure-reducing constriction.
The invention will now be further described, by way of example, with reference to the accompanying drawings, in which: Figure lisa diagram of a first embodiment of a vehicle steering system according to the present invention; Figure 2 is a sectional view of a steering control unit which forms part of the system shown in Figure 1; Figure 3 is a sectional view of a brake control valve which also forms part of the system shown in Figure 1; Figure 4 is a diagram of a second embodiment of a vehicle steering system according to the present invention; Figure 5 is a sectional view of a steering and brake control unit which forms part of the system shown in Figure 4, the control unit being illustrated in a neutral position; Figure 6 is a similar view to Figure 5 but showing the control unit in a full steering position; and Figure 7 is a sectional view of a modified valve unit which can be used in the control unit shown in Figure 5.
Figure 1 shows one form of driving and steering system, for mounting in a tracked or wheeled vehicle, comprising an input shaft 10, connected to the vehicle's engine, driving, through bevel gears 12 and 13, a differential casing 11 which carries two gear wheels 14, 15 fixed thereto to drive engaging gear wheels 16, 17 rotatably mounted on a main driving shaft 18 located transversely in the vehicle. A sliding clutch member f9 connects either of the gear wheels 16, 17 to the main driving shaft 18 thus providing alternative gear ratios between the differential casing 11 and the main driving shaft 18.
Although only a two ratio gear is shown, any suitable multi-ratio gearing may be used. Located on each side of the vehicle is an epicyclic gearing 21 and the ends of the main driving shaft 18 are respectively connected to the annular gears 20 of such epicyclic gearings 21. The planet carriers 23 of these epicyclic gearings 21 drive the track or wheels (not shown) on the left and right hand side of the vehicle. Drive is also taken from the input shaft 10 through a differential gearing to the sunwheel 25 of both left and right hand epicyclic gearings 21. Two similar variable displacement hydraulic motor/pumps, namely a left and a right hand motor/pump 29,30 are arranged in the vehicle and are gearably connected to the sun wheel 25 in the left and right hand epicyclic gearing 21 by means of gear wheels 31.
The pumps/motors 29,30 are of the variable displacement type, and are provided with respective control levers 32 and 32' which can be moved to vary the displacement. The pumps/motors 29 and 30 are hydraulically connected in a closed circuit by hydraulic lines 33 and 34. Although not actually illustrated, an auxiliary hydraulic pump will be provided to replace any hydraulic fluid lost from this circuit. A control unit 35 is provided for controlling the relative displacements of the two pumps/motors 29,30 in response to a steering demand: the manner in which this unit operates will be described later.
A respective brake 28 co-operates with each of the sun wheels 25, and is actuable by means of fluid pressure derived from a source 36. This source is preferably separate from that which supplies the hydraulic circuit between the pumps/motors 29 and 30. The fluid pressure actually applied to each brake is controlled by a respective valve unit 37 according to the fluid pressure in a respective one of the hydraulic lines 33 and 34. The manner in which the valve units 37 operate will also be described later.
During normal forward travel of the vehicle, the tracks will be driven from the vehicle's engine by way of the drive shaft 10, the differential casing, the change speed gear wheels 14 and 16 or 15 and 17, the shaft 18, the epicyclic gearings 21 and the shafts 24. At this time, the pumps/motors 29 and 30 will be set to the same (preferably maximum) displacement, so that they rotate the sun wheels 25 of the epicyclic gearings 21 at the same speed: hence, the two shafts 24 will rotate at the same speed, applying equal drive to both sides of the vehicle. In order to steer the vehicle to the left, the control unit 35 is operated to make the displacement of the right-hand pump/ motor 30 smaller than that of the left-hand pump/ motor 29.The sun wheel 25 of the right-hand epicyclic gearing 21 is thereby rotated faster than its counterpart in the left-hand gearing 21, so that the right-hand shaft 24 rotates faster than the left-hand shaft 24. The unequal drive thus applied to the tracks causes the vehicle to turn to the left. Steering to the right is accomplished in an analogous manner, with the control unit 35 being operated to make the displacement of the pump/motor 29 smaller than that of the pump/motor 30. In the case of small radius turns, where the torque required to vary the relative speeds of the two sun wheels 25 exceeds the capacity of the pumps/motors 29 and 30, the steering action is supplemented by applying an appropriate one of the brakes 28, such application occurring automatically when the hydrostatic pressure in one or other of the lines 33 and 34 exceeds a preset level.
The control unit 35 is shown in detail in Figure 2.
Reference numeral 38 denotes an input member which is moved in accordance with the steering demand (rightwards as viewed to steer the vehicle to the left, leftwards to steer the vehicle to the right). A pair of annular abutment members 39 are slidably mounted on the exterior of the input member 38, and under normal conditions of operation are urged by a compression spring 40 therebetween into engagement with respective stops 41 on the input member 38. The abutment members 39 are slidably housed within a cylinder 42, with one member 39 normally abutting an end wall 43 of the cylinder and the other member 39 normally abutting a stop 44 on the cylinder interior. The cylinder 42 is itself sur rounded by two axially spaced, annular pistons 45 having a compression spring 46 interposed therebetween, the spring 46 normally urging the pistons 45 into engagement with respective stops 47.The pistons 45 are in turn slidably housed in a cylindrical chamber 48 in a fixed block 49. An annular space 50 is thus defined between the pistons 45, the exterior of the cylinder 42 and the internal wall of the chamber 48: to this space is supplied fluid at a pressure which is dependent upon the hydrostatic pressure in at the pumps/motors 29 and 30, by way of a supply passage 51. This fluid pressure may be derived by connecting the passage 51 to the closed hydraulic circuit of the pumps/motors in such a way that the pressure in the annular space 50 is a set fraction of that in the hydraulic circuit. Alternatively, the pressure may be derived from a separate low-pressure source and may be regulated by a valve in accordance with the pressure in the hydraulic circuit.
Amounting 52 on the end wall 43 of the cylinder 42 provides a pivot point for one end of a lever 53. At its other end, the lever 53 is pivotally coupled to cross-links 54 which interconnect the displacement control levers 32 and 32' of the pumps/motors 29 and 30, each control lever having a pin 55 on its free end which slidably engages in a slot 56 in a respective one of the cross-links 54. In a neutral position of the control unit 35 (as illustrated), the slots 56 just engage the pins 55 with the pumps/ motors 29 and 30 set at maximum displacement. A fulcrum for the lever 53 is provided by a fixed pivot 57 on the block 49.
In order to steer the vehicle to the left, the input member 38 is moved rightwards (as mentioned previously). This causes the cylinder 42 to move rightwards also: the spring 40 between the two abutment members 39 is set such that it does not compress at this time. The lever 53 is thus pivoted anti-ciockwise about the fulcrum 57, thereby moving the cross-links 54to the left. During such movement of the cross-links, the control lever 32 of the pump/motor 29 will remain at its maximum displacement position because the pin 55 will slide along the respective slot 56. However, the control lever 32' of the pump/motor 30 will be carried along with the cross-links 54 to reduce the displacement of that pump/motor. Hence, the pump/motor 30 will now run at a faster speed than the pump/motor 29, causing the vehicle to turn to the left in the manner described previously. Steering of the vehicle to the right is performed in an analagous manner, with the control lever 32' of the pump/motor 30 remaining at the maximum displacement position while the control lever 32 of the pump/motor 29 is moved to reduce the displacement.
During the steering operation, movement of the cylinder 42 of the control unit 35 to the left or right will cause one of the annular pistons 45 to move towards the other, thereby compressing the space 50 therebetween. As described previously, the space 50 is supplied with fluid at a pressure which is dependent upon the hydrostatic pressure at the pumps/motors 29 and 30, which will impose a resistance on such movement of the pistons 45.
Since the hydrostatic pressure will rise with increased steering demand, the magnitude of this resistance will also rise as the steering demand is increased. Moreover, this resistance will be transmitted through the cylinder 42 to the input member 38 to which the steering demand is applied. Hence, the input member 38 is given as a suitable "feel".
The force of the spring 40 between the two annular abutment members 39 is set so as to equal the force applied to the annular pistons 45 by the fluid in the space 50 when the hydrostatic pressure at the pumps/motors 29 and 30 reaches a maximum safe value. Hence, if the hydrostatic pressure exceeds this value during a steering operation, the force of the spring 40 will be overcome and the cylinder 42 will be moved towards its neutral position under the action of the fluid in the space 50. This will in turn cause the cross-links 54 to be moved back towards their neutral position, thereby increasing the displacement of the pump/motor 29 or 30 whose speed had previously been increased, until the hydrostatic pressure has returned to a safe level.
As mentioned previously, when the torque required to steer the vehicle exceeds the capacity of the pumps/motors 29 and 30, the steering action is supplemented by applying an appropriate one of the brakes 28, such application being performed automatically by means of the valve units 37. One of the value units 37 is shown in detail in Figure 3, the other unit being identical thereto. Each unit includes a spool 57 which has axial steps 58 and 59 therein, the spool being slidably received in a configurated cylinder 60. The axial step 58 defines a shoulder against which acts fluid at a pressure dependent upon the hydrostatic pressure at the pumps/motors 29 and 30, this fluid being supplied to the cylinder 60 by way of a passage 61. Preferably, the same fluid pressure is employed as is supplied to the space 50 in the control unit 35.The axial step 59 is grooved at localised points 62 on its periphery, and co-operates with a facing step 63 on the cylinder side wall to define a variable constriction. Fluid from the source 36 (see Figure 1) is supplied by way of a passage 64 to one side of the variable constriction, the other side of the constriction being connected to drain by way of a passage 65. A branch line 66 from the passage 64 is connected to the respective brake 28 (not shown in Figure 3): the pressure of fluid in this line acts on the spool in opposition to the fluid in passage 61.
A compression spring 67 normally urges the spool 57 into a position wherein the steps 59 and 63 present substantialiy no resistance to fluid flow therebetween. Hence, as long as the force applied to the spool 57 by the fluid from passage 61 is below the force of the spring 67, the fluid pressure in line 66 will be insufficient to actuate the brake 28. When, however, the hydrostatic pressure in either of the hydraulic lines 33 and 34 (Figure 1) exceeds a preset level, the pressure of the fluid in the passage 61 of the appropriate valve unit 37 will be sufficient to overcome the force of the spring 67, thereby moving the spool 57 to the right, as viewed in Figure 3.This will in turn cause the steps 59 and 63 to restrict the flow of fluid from the passage 64 to drain, so that the pressure of the fluid in the passage 64 (and hence in the line 66) will increase, eventually to a level which is sufficient to actuate the appropriate brake 28.
Because the step 59 in the spool 57 is provided with grooves 62, the flow restriction imposed by the steps 59 and 63 will increase progressively as the spool moves further to the right, reaching a maximum when the grooves 62 pass fully under the step 63. Consequently, the force applied by the brake 28 will also increase progressively as the hydrostatic pressure in the line 33 or 34 rises with increasing steering demand. The increased braking action will in turn mitigate the rise in the hydrostatic pressure, resulting in the steering system being very stable in operation. This is to be contrasted with the previous arrangement described above, wherein the brakes act on a simple on/off principle and thereby give rise to instability.
A second embodiment of the invention is shown in Figures 4to 6 and is generally similar to that described above with reference to Figure 1, similar parts being accorded the same reference numerals.
In this embodiment, however, the valve units 37 and the control unit 35 are combined into a single module, which is shown in detail in Figure 5.
Additionally, both valve units are now combined into a single construction, which comprises a spool 68 axially slidable within a configurated cylinder 69 formed in the block 49 of the control unit 35.
The spool 68 has at its middle a portion 70 of relatively large diameter which, when the spool 68 is in a neutral position as shown in Figure 5, locates in an annular recess 71 in the cylinder 69. A passage 72 provides communication between the recess 71 and drain. On either side of the portion 70, the spool has an annular recess 73 which terminates at a step 74 having grooves 75 at spaced points on its periphery.
Each step 74 confronts a corresponding step 76 on the cylinder 69 to define a variable constriction, in the same manner as the steps 59 and 63 in Figure 3.
The fluid source 36 (Figure 4) for braking is connected to a bifurcated passage 77 each branch of which opens into the cylinder 69 on one side of a respectice one of the variable constrictions. On the opposite side of each constriction, a respective passage 78 formed through the interior of the spool 68 opens into the appropriate recess 73. Each passage 78 also opens into a respective further recess 79 between the spool 68 and the cylinder 69, this passage being connected to a respective one of the brakes 28 by way of a passage 80.
At one end thereof, the spool 68 has an extension 81 which projects into a housing 82 provided on the block 49. Mounted in the housing 82 and surrounding the extension 81 are a pair of annular abutment members 83 having a compression spring 84 interposed therebetween. The abutment members 83 are connected to the extension 81 in such a manner that movement of the spool 68 either to the right or to the left will cause the members 83 to compress the spring 84. At its other end, the spool 68 has a pivot point 85 where it is connected to an end of a link 86, the opposite end of the link 86 being connected to the input member 38 of the control unit 35 at a pivot point 87. An operating member 88, to which the steering demand is applied, is pivotally connected to the link 86 at a location intermediate the pivot points 85 and 87.
In order to steer the vehicle to the left, the operating member 88 is moved rightward. At this time, the force exerted by the spring 84 due to its preload prevents the spool 68 from moving, with the result that the link 86 pivots with the point 85 as a fulcrum. The input member 38 of the control unit 35 is thereby moved rightward, whereupon the control device acts exactly as described previously to move the control lever 32' of the pump/motor 30 to reduce the displacement while the pump/motor 29 remains at maximum displacement.
As steering demand increases and the hydrostatic pressure at the pumps/motors 29 and 30 rises, the fluid pressure in the space 50 of the control unit 35 will oppose movement of the input member 38 sufficiently to cause the point 87 to act as a fulcrum for pivoting of the link 86. Hence, rightward movement of the operating member 88 will cause rightward movement of the spool 86, thereby increasing the constriction defined by the left-hand pair of steps 75,76 as viewed in Figure 5. The fluid pressure in the path defined by the right-hand branch of the passage 77, the right-hand passage 78 in the spool 68, and the right-hand passage 80 thus rises because of the increased constriction between the source 36 and the drain passage 72, thereby actuating the left brake of the vehicle.At this time, the right brake remains inoperative since the passage 80 to which it is connected (i.e. the left-hand passage 80 in Figure 5) communicates freely with the drain passage 72 via the left-hand passage 78 in the spool 68. In the same manner as described with reference to Figure 3, progressive movement of the spool 68 causes the constriction between the appropriate pair of steps 74,75 to be progressively narrowed, thereby actuating the brake in a progressive manner with increasing steering demand.
As a further brake action is demanded with point 87 remaining as the fulcrum for the link 86, a reduction in hydrostatic pressure at the oumps/ motors 29 and 30 will occur. This is because the curvature of the vehicle's turning path will be governed by the ratio of the capacities of the two pumps/motors, while the steering torque exerted at the relevant sun wheel 25 (Figure 4) will effectively be the sum of the braking torque and the torque corresponding to the hydrostatic pressure at the pumps/motors. Such a reduction in the hydrostatic pressure will cause the point 85 to become the fulcrum for movement of the link 86 once again, and will allow the displacement of the pump/motor 30 to be reduced. When the hydrostatic pressure again rises to the point where the preload of the spring 84 can be overcome, the point 87 will return to being the fulcrum, and soon.Thus, once normal maximum hydrostatic pressure has been reached, the operating member 88 will in effect move both the input member 38 of the control unit 35 and the spool 68 of the valve 37 together in response to further steering demand, with the appropriate brake 28 being applied progressively and the hydrostatic pressure at the pumps/motors 29 and 30 remaining at its normal maximum value.
As in the previous embodiment, in the event of the hydrostatic pressure exceeding the safe maximum, the spring 40 in the control unit 35 will collapse sufficiently to reduce the pressure to a safe value.
Although the above description refers to steering of the vehicle to the left, it is to be appreciated that steeering of the vehicle to the right will be performed in an exactly analagous manner, with the operating member 88 being moved leftward instead of rightward. Figure 6 shows the control module when the operating member 88 has been moved to obtain maximum steering to the right.
In a modification of the system shown in Figures 4 to 6, the hydrostatic pressure at the pumps/motors 29 and 30 is fed back to the valve unit 37 in addition to the control unit 35. This can be performed by extending the ends of the spool 68, providing suitable housings to cover the ends thus extended, and making fluid connections from the passages 80 to these housings such that a force tending to centre the spool is created whenever the spool is moved in either direction from its neutral position.
In both of the embodiments described above, steering is designed to take place while the vehicle is either in motion (forwards or backwards) or stationary. The steering thus provided is sufficient for all normal vehicle requirements. However, in certain applications it may be desirable for the vehicle to be capable of executing a turn from stationary, by driving one track forwardly and the other track rearwardly at equal speeds. This can be achieved by incorporating a suitable gear train between the casing of the differential gearing 11 and the shaft 18, this gear train being clutched in while the gear wheels 14to 17 are clutched out.
In a further embodiment, should loss of hydrostatic pressure occur for any reason in units 29 and 30, application of steer demand will cause input member 38 to abut against a mechanical stop, having travelled to maximum stroke, thus allowing the pivot point 87 to become the fulcrum for application of brakes to accomplish at least a reduced level of steering until the fault can be traced and rectified. On the other hand should loss of brake pressure occur for any reason then hydrostatic steering is still available from units 29 and 30. Thus a measure of fail-safe protection is built into the system. Furthermore, the linkage is arranged so that whenever the driver's steering control is in its maximum steer demand position, the appropriate steering brake valve delivers full pressure to the appropriate brake to ensure its being totally arrested irrespective of the hydrostatic transmission pressure.
In the embodiment of Figures 4 to 6, the valve unit 37 is of the open centre type: however, this unit may equally well be of the closed centre type, as depicted in Figure 7. The closed centre valve unit comprises a spool 90 which is axially slidable within a configurated cylinder 91,the cylinder being formed in the block 49 of the control unit 35, as before. The spool 90 has at its middle a portion 92 of relatively large diameter which, when the spool occupies the neutral position illustrated, obstructs a passage 93 to which the source 36 of pressurised fluid is connected.
Flanking the portion 92, the spool 90 has respective portions 94 of relatively small diameter which cooperate with the cylinder 91 to define annular spaces 95 with which respective passages 96 communicate, each of these passages being connected to a respective one of the brakes 28. A shoulder 97 between each portion 94 and the portion 92 co-operates with a corresponding shoulder 98 on the cylinder 91 to define a variable constriction between the passage 93 and a respective one of the passages 96, the shoulder 97 being provided with grooves or notches 99 at spaced locations around its periphery.
Afurthervariable constriction is provided between each passage 96 and a respective further passage 100 which is connected to drain, the constriction being defined between a shoulder 101 on the spool 90 and a corresponding shoulder 102 on the cylinder 91. Like the shoulders 97, each shoulder 101 is provided with grooves or notches 103 at spaced intervals around its periphery.
In the neutral position of the spool 90, the source 36 of pressurised fluid is isolated by the middle portion 92, and both brakes 28 are open to drain via the respective passage 96, annular space 95 and passage 100. When the vehicle is steered to the left in the manner described previously, upon increasing steering demand the spool 90 will be moved from its neutral position to the right as viewed in the drawing. This will cause the constriction between the left-hand shoulders 97 and 98 to open progressively and the constriction between the left-hand shoulders 101 and 102 to close progressively, thereby opening communication between the left-hand brake 28 and the source 36 while at the same time closing communication between that brake and drain. At the same time, the right-hand brake 28 will remain in communication with drain via the constriction between the right-hand 101 and 102.Thus, the left-hand brake will be progressively actuated as the spool 90 moves further to the right.
During steering of the vehicle to the right, the valve unit 37 will operate in an exactly analogous manner to actuate the right-hand brake 28, the spool 90 in this case being moved to the left.
Although not shown, the valve unit 37 will be provided with spring means to oppose movement of the spool 90 in either direction from its neutral position. Moreover, provision can be made for brake cylinder pressure to be fed to suitable areas at the ends of the spool to give the valve unit a suitable operational "feel".
From the above description, it will be manifest that the use of a closed centre valve requires no flow from the source 36 until the pressure in the hydrostatic transmission reaches a predetermined level, in the manner explained previously. To this end, the source 36 can comprise an hydraulic pump and an accumulator, with a valve being provided automatic allyto unload the pump when the pressure of the fluid in the accumulator reaches a preset level.
The principle of utilising a closed centre valve can of course equally well be applied to the embodiment shown in Figures 1 to 3, wherein a separate valve unit is provided for each brake.
The vehicle steering systems described above have the following significant advantages: (1) As mentioned previously, the braking action is achieved in a progressive manner which avoids the instabilities experienced with previous systems of this type.
(2) The fluid source for the brakes is independent of the hydrostatic system which operates the pumps/ motors 29 and 30, and accordingly it is not necessary to provide reversing valves to cater for the vehicle being driven backwards.
(3) In the case of the system shown in Figures 4to 7, only one valve unit is required to operate both brakes.
(4) The pumps/motors 29 and 30 are not interlocked for inverse operation, which means that both pumps/motors can be operated at maximum displacement for straight ahead driving of the vehicle.
(5) Should loss of pressure occur in the pump/ motor 29 and/or in the pump/motor 30, emergency steering is available by means of the brakes 28.
Conversely, if the brakes should fail, then emergency steering is available through the hydrostatic units.

Claims (25)

1. A steering system for a vehicle having tracks or sets of wheels on opposite sides thereof, comprising a differential drive for saidtracks or wheel sets which includes a hydrostatic transmission, control means operative in response to a steering demand to cause the hydrostatic transmission to drive the tracks or wheel sets at different relative speeds and thereby steer the vehicle, and brake means which when the pressure in the hydrostatic transmission rises above a predetermined level causes a baking effect to be applied to the appropriate side of the system and thereby supplement the steering action, said braking effect increasing progressively with increasing steering demand.
2. A steering system as claimed in claim 1, wherein the control means includes an input member which is moved in accordance with said steering demand, an output member which moves in re sponge to movement of the input member to cause the hydrostatic transmission to drive the tracks or wheel sets at different speeds, spring means which operatively interconnects the input and output members, and override means applying to the output member in opposition to the spring means a force which is dependent upon the pressure in the hydrostatic transmission, the spring means having a preload which is set so as to be overcome by the override means in the event that the pressure in the hydrostatic transmission exceeds a predetermined maximum safe level.
3. A steering system as claimed in claim 1 or 2, wherein the hydrostatic transmission includes a respective variable displacement pump/motor oper atively coupled to each track or wheel set, and the control means is operative in response to said steering demand to alter the displacement of an appropriate one of the pumps/motors while maintaining the displacement of the other pump/motor substantially constant.
4. A steering system as claimed in claim 3, wherein, each pump/motor has a control member which is movable to alter its displacement, and the control means includes a linkage which interconnects the control members and which is moved in response to said steering demand, the link occupying a neutral position when there is no steering demand wherein the displacements of both pumps/ motors are equal, and being moved in one or the opposite direction when a steering demand is applied to the control unit to alter the displacement of said appropriate one of the pumps/motors.
5. A steering system as claimed in claim 4, wherein the link is connected to the control members by respective pin-and-slot connections.
6. A steering system as claimed in any preceding claim, wherein the brake means includes fluid pressure-operated brakes associated with the hydrostatic transmission and valve means operatively connected between the brakes and a source of pressurised fluid, the valve means being operated to increase the fluid pressure supplied to the appropriate brake in response to said increasing steering demand.
7. A steering system as claimed in claim 6, wherein the valve means is responsive to the pressure in the hydrostatic transmission.
8. A steering system as claimed in claim 6 or 7, wherein said source of pressurised fluid is independent of the hydrostatic transmission.
9. A steering system as claimed in claim 6,7 or 8, wherein the control means includes an input member which is moved in accordance with said steering demand, and means operative to apply a force to the input member which opposes such movement thereof to a degree dependent upon the pressure in the hydrostatic transmission, and the valve means includes a valve member which is moved in one or the opposite direction from a neutral position to increase the fluid pressure applied to one or the other of said brakes respectively, the valve member and the input member of the control means being pivotally connected to a common link to which said steering demand is applied.
10. A steering system as claimed in claim 9, wherein said steering demand is applied to the common link by way of an operating member which is pivotally connected to the link at a point intermediate the pivotal connections to the valve and input members.
11. A steering system as claimed in claim 9 or 10, wherein said means operative to apply a force to the input member is a pressurised fluid obtained from the hydrostatic transmission and passed through at least one pressure-reducing constriction.
12. A steering system as claimed in claim 9, 10 or 11, wherein the valve member is axially movable within a cylinder to vary the size of one or the other of two constrictions in respective fluid paths from the pressurised fluid source.
13. Asteering system as claimed in claim 12, wherein each constriction is normally open and is provided in a respective fluid path between the pressurised fluid source and drain, and each brake is connected to a point between the source and a respective one of the constrictions.
14. Asteering system as claimed in claim 12, wherein each constriction is normally closed and is provided in a respective fluid path between the pressurised fluid source and a respectice one of the brakes, and the valve means includes two further constrictions whose size can be varied by axial movement of the valve member within the cylinder, each of the further constrictions being provided between a respective one of the brakes and drain, and being normally open but being closed when the valve member moves to open the constriction between the respective brake and the source.
15. A steering system as claimed in claim 13 or 14, wherein each constriction is defined between opposed shoulders on the valve member and the cylinder respectively.
16. A steering system as claimed in claim 15, wherein one of the shoulders is grooved or notched at spaced points on its periphery.
17. A steering system as claimed in claim 16, wherein said one of the shoulders is the shoulder on the valve member.
18. A steering system as claimed in claim 6,7 or 8, wherein the hydrostatic transmission includes a respective hydrostatic pump/motor operatively coupled to each track or wheel set, the two pumps/ motors being connected together by hydraulic lines so as to form a closed hydraulic circuit, and the valve means comprises a pair of valves each of which is responsive to the pressure in a respective one of said hydrostatic lines to operate a respective one of said brakes.
19. A steering system as claimed in claim 18, wherein each valve includes a valve member which is axially movable within a cylinder to vary the size of a constriction in a fluid path from the pressurised fluid source, the valve member being moved in dependence upon the pressure in the hydrostatic transmission to reduce the size of the constriction with increasing pressure.
20. A steering system as claimed in claim 19, wherein the constriction is defined between opposed shoulders on the valve member and the cylinder respectively.
21. A steering system as claimed in claim 20, wherein one ofthe shoulders is grooved or notched at spaced points on its periphery.
22. A steering system as claimed in claim 21, wherein said one of the shoulders is the shoulder on the valve member.
23. A steering system as claimed in any one of claims 9 to 22, wherein the valve member is acted upon in opposite axial directions by the fluid whose pressure is dependent upon the pressure in the hydrostatic transmission and by a spring having a pre-load which can be overcome by said fluid pressure when the pressure in the hydrostatic transmission reaches said predetermined level.
24. A steering system as claimed in claim 23, wherein said fluid pressure is obtained by connecting the valve to the hydrostatic transmission through at least one pressure-reducing constriction.
25. A steering system for a vehicle having tracks or sets of wheels on opposite sides thereof, substantially as hereinbefore described with reference to Figures 1 to 3, or Figures 4 to 6, or Figures 4 to 6 as modified by Figure 7 of the accompanying drawings.
GB08400120A 1983-01-08 1984-01-04 Vehicle differential drive steering system Expired GB2135256B (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
GB08400120A GB2135256B (en) 1983-01-08 1984-01-04 Vehicle differential drive steering system

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
GB838300483A GB8300483D0 (en) 1983-01-08 1983-01-08 Vehicle steering system
GB8302418 1983-01-28
GB08400120A GB2135256B (en) 1983-01-08 1984-01-04 Vehicle differential drive steering system

Publications (3)

Publication Number Publication Date
GB8400120D0 GB8400120D0 (en) 1984-02-08
GB2135256A true GB2135256A (en) 1984-08-30
GB2135256B GB2135256B (en) 1986-07-09

Family

ID=27261912

Family Applications (1)

Application Number Title Priority Date Filing Date
GB08400120A Expired GB2135256B (en) 1983-01-08 1984-01-04 Vehicle differential drive steering system

Country Status (1)

Country Link
GB (1) GB2135256B (en)

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB2224790A (en) * 1988-09-26 1990-05-16 Honda Motor Co Ltd Torque distribution control using continuously variable transmission in parallel with differential
US5076380A (en) * 1988-10-19 1991-12-31 Honda Giken Kogyo Kabushiki Kaisha Apparatus for controlling the distribution of drive power in motor vehicle
GB2332182A (en) * 1997-12-10 1999-06-16 Caterpillar Inc Method for controlling steering in a hydrostatic drive system having differential steer
EP1433979A3 (en) * 2002-12-26 2004-11-17 Fuji Jukogyo Kabushiki Kaisha Differential rotation control apparatus for vehicle

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114313003B (en) * 2022-01-21 2023-04-28 江苏英拓动力科技有限公司 Electric control hydrostatic steering power system of unmanned tracked vehicle

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB2224790A (en) * 1988-09-26 1990-05-16 Honda Motor Co Ltd Torque distribution control using continuously variable transmission in parallel with differential
US5076380A (en) * 1988-10-19 1991-12-31 Honda Giken Kogyo Kabushiki Kaisha Apparatus for controlling the distribution of drive power in motor vehicle
GB2332182A (en) * 1997-12-10 1999-06-16 Caterpillar Inc Method for controlling steering in a hydrostatic drive system having differential steer
US5975224A (en) * 1997-12-10 1999-11-02 Caterpillar Inc. Method for controlling steering in a hydrostatic drive system having differential steer
GB2332182B (en) * 1997-12-10 2001-09-19 Caterpillar Inc Method for controlling steering in a hydrostatic drive system having differential steer
EP1433979A3 (en) * 2002-12-26 2004-11-17 Fuji Jukogyo Kabushiki Kaisha Differential rotation control apparatus for vehicle
US7044878B2 (en) 2002-12-26 2006-05-16 Fuji Jukogyo Kabushiki Kaisha Differential rotation control apparatus for vehicle

Also Published As

Publication number Publication date
GB8400120D0 (en) 1984-02-08
GB2135256B (en) 1986-07-09

Similar Documents

Publication Publication Date Title
US4505168A (en) Vehicle steering system
US4317331A (en) Hydraulic circuit for a hydraulically driven vehicle
US3900075A (en) Hydrostatic propulsion system
KR0127146B1 (en) Hydraulic control circuit for continuously variable ratio transmission
US3349860A (en) Hydrostatic transmission
US3053043A (en) Hydraulic apparatus
US3477225A (en) Hydrostatic transmission control system
US3033333A (en) Transmission
US3994353A (en) Vehicle having a mechanical drive, a pump, a variable-displacement motor and a method of driving the vehicle
US4621702A (en) Four-wheel steering apparatus of a vehicle
US2964017A (en) Power steering mechanism
GB1122268A (en) A driving and steering system for vehicles
SU1263201A3 (en) Auxiliary traction drive for one or several driven wheels of vehicle with main drive for at least one pair of wheels
US5293956A (en) Four wheel drive working vehicle
EP0006690B1 (en) Control circuit for a continuously variable ratio transmission
US3125201A (en) Transmission
JP4704938B2 (en) Work vehicle
US3306385A (en) Vehicle drive and steering system
US2996136A (en) Servo steering mechanism for motor vehicles
US2961057A (en) Steering system for track-type tractors
GB2135256A (en) Vehicle differential drive steering system
US3049884A (en) Hydraulic transmission
US2826258A (en) Valve and valve-actuating mechanism for hydraulic steering system
US3554089A (en) Servosteering system
US3822765A (en) Planetary power steer cross drive transmission and control system with lubrication passages in planet carriers

Legal Events

Date Code Title Description
PCNP Patent ceased through non-payment of renewal fee

Effective date: 19990104