This application is based on, and claims the benefit of priority to, UK application GB 0616168.1, filed 15 Aug. 2006, which priority application is hereby incorporated by reference.
1. Field of the Invention
The invention relates to a mechanically operated proportional flow control valves with a valve spool movement which has a non-indexed regulating range, a neutral position, which is automatically assumed if the actuating force applied to the spool is released, and at least one so-called “locked in” position at one at least of the two end limits of the regulating range in which the spool is locked in a fixed position. Hereinafter such a valve is referred to as “a valve of the type described”.
In agricultural operations a variety of attachments are used for different work. Each of these pieces of equipment makes individual demands on the vehicle-borne hydraulics and in particular on the functions of the vehicle-borne hydraulic valves and their control. Thus, there are attachments, the use of which requires hydraulic valves, which are designed to “lock-in” automatically in a certain operating position, so that the operator does not have to apply the actuating force continuously. This automatic locking may not be desired for some applications and can even lead to safety-critical operating errors. For example, with regard to the operation of a front loader some professional associations prescribe that the lifting of the front loader rocker must be interrupted if the operator is no longer operating the lever in order to prevent injury to humans and damage to equipment as a result of the lift movement continuing without conscious control by the operator. This so-called dead man circuit, can only be guaranteed with a hydraulic valve with a “locked-in” position if the “locked-in” position is disabled (or “locked-out”) for this particular application. This causes problems when it is desired to be able to use the same hydraulic valve to also control another attachment where the “locked-in” position of the hydraulic valve is required.
Controls for front loaders are known from practice, which have their own control unit only to be used for the front loader. This can be fitted in the driving cab and contains vehicle-borne controls and hydraulic valves, which on the manufacturer's side meet the requirements mentioned for “locking out” or “locking in” functions. This execution, however, has the disadvantage that, particularly for use of the front loader, control elements must be placed in the driving cab and bowden cables to the control valves on the vehicle must be routed through the cab. As a result leakages arise, which increase the sound and noise level in the cab, and high expenditure of time is required for conversion. The use of a separate command and control unit for the front loader further leads to high ancillary costs, which can be avoided by using the vehicle-borne command and control mechanics, that is to say the control valves, of the agricultural tractor.
2. Description of Related Art
Similar hydraulic control equipment for hydraulics, wherein the “lock-in” of the valve spool of a mechanically operated proportional directional control valve is switched off via hydraulic control equipment if the operating pressure is exceeded is known from German Patent DE 3801072 C1. For this purpose the control lines of the “lock-in” control are connected via a hydraulic timer to the pressure circuit. If a certain operating pressure in the circuit is exceeded the pressure is passed on via the control line and timer to a hydraulic cylinder, which releases the mechanical “lock-in” device, so that the valve control gate returns to its neutral position and therefore no pressure flows to the consumers.
From German Patent DE 3733371 A1 it is also known, instead of a hydraulically operated locking device, to use an electrohydraulic locking device, wherein the control of the locking operation is effected when a certain operating pressure is reached to actuate an electrical switch via a barometric cell, which passes on this signal via an electrical timer, here a relay, to a solenoid 2-way valve, which then operates the hydraulic cylinder of the locking device via a control line.
With both the above prior art arrangements the control of the locking device depends on the operating pressure in the system. Deliberate switching of the locking device on or off by the operator is not possible as a result. Although a device can be derived from these solutions, in which the locking can be deliberately switched on or off, this requires purely hydraulic or electrohydraulic control of a locking device and thus the use of quite costly structural parts. Moreover, major interference with the vehicle hydraulics or electrical equipment is necessary for retrofitting or for optional installation of such a locking device. Sometimes commercial valves cannot be used for installing this locking function and have to be replaced by valves which must be adapted for installing the locking device and are therefore substantially more expensive.
It is an object of the invention to provide a proportional flow control valve of the type described which overcome the above problems.
The object is achieved by providing the flow control valve with a device for selectively limiting the regulating range of the valve.
The structural parts needed for the device are simple, mechanical components of low manufacturing and assembly cost, which can be fitted if necessary to existing vehicle-borne valves. By using the existing vehicle-borne valves the operator controls of the valves fitted in the cab can also be used, whereby the operation of different attachments is standardized and the costs of operating these attachments can be kept to a minimum. In addition, the device can be retrofitted in simple way without interfering with the valve itself or with the pressure circuit. This is very advantageous if the operational use of the agricultural tractor is changed by fitting other attachments and the device is not always or is no longer required. Moreover, with each attachment the operator can decide himself whether the locking device is necessary and very simply to switch this on or off and therefore to control several attachments with one hydraulic valve.
As a result the possible applications of an agricultural tractor, which is equipped with this device, are substantially increased and the change-over of attachments simplified for the operator. This leads to more economic use of the agricultural tractor.
An embodiment of the present invention will now be described, by way of example only, with reference to the accompanying drawings in which:
The front loader attachment 4 (here illustrated as a bulk material shovel) is rotatably connected to the front loader arms 3 in the plane of projection. So that the front loader attachment 4 can pivot relative to arm 3, an operating cylinder 7, which has two cylinder chambers A2, B2, is connected between the arms 3 and the front loader attachment 4. The stroke of the operating cylinder 7 for the front loader attachment 4 and the pivoting angle β of the front loader attachment are controlled by the supply and discharge of the pressure in the cylinder chambers A2 and B2.
For controlling the supply of the pressure to the respective cylinder chambers of the two operating cylinders, two mechanically operated proportional directional control valves 8 each with a valve spool 9 are used, the basic function of which is described with the help of
In the “locked-in” position RH to the right of the neutral position N the valve spool 9 remains in this position, even though the actuating force no longer prevails, and the pressure flows to the consumer on port A, while the pressure is discharged via port B on the valve from the consumer into the tank port T. The left “locked-in” position F is a so-called free floating position, that is to say ports A, B and the port to the tank T are hydraulically connected by the valve spool and separated from the pump at port P; the pressure can thus circulate between the consumer ports, if outside forces affect a hydraulic cylinder for example. This is called pressure-free pump circulation.
Since the regulating range of the valve spool 9 only amounts to 19 mm in total and therefore the proportioning ability of the operating movement is not sufficient, the operating movement is translated by means of a pivotable lever 11, which is pivotally mounted about the axis Z on a mounting bracket 13 by means of a pin 12. The bracket 13 is detachable connected to the valve housing 10 by the fixing bolts 14. The operating movement of the control lever (not illustrated) is transmitted to the lever 11 via a connecting rod 15 and a connecting ball joint 16.
For transforming the pivot movement of the lever 11 to a linear movement of the valve spool 9 a pin 17 is non-rotatably connected to the lever 11, which moves the valve spool 9 via a forked rod 18, which is connected with spool 9 via a further pin 19. The positions FI SI NI HI and RHI of the lever 11 therefore correspond to the positions F, S, N, H and RH of the valve spool.
The locking bar control 21 essentially consists of a locking bar rod 31 which is connected non-detachably to a locking bar lever 32 at one end of the locking bar rod 31. The lever 32 is pivoted via a bowden cable (not illustrated) by the locking bar control mechanism (not illustrated). The locking bar rod 31 is rotatably mounted on the mounting bracket 13 via a bearing bore (not illustrated) and a bore in a support 33. A reset spring 34 is attached to the locking bar lever 32 and to the support 33 and guarantees resetting of the locking bar control 21 to the disengaged position. A locking bar driver 35 on rod 31 has a driver groove 36 which engages the driver pin 30 of the locking bar 20 and, when the locking bar control 21 pivots, moves the locking bar 20 into the path of the catch pin 22.
If clamping screws 27 are slightly loosened, the catch plate 26 can be moved by rotating the set screw 38, in order to adjust the catch edge 29 of the catch plate 26 in such a way that the lever 11 still just reaches the position H1 but does not lock in the position RH1. As a result, the catch plate 26 is adjusted in such a way that the position of the lever 11 and the valve spool 9 permits maximum flow rate of the pressure through the valve 8, before the pivot angle of the lever 11 and thus the gate travel of the valve gate 9 are limited, in order to block the locked position RH and RH1.
If the lever 11 and thus the catch pin 22 pivot to the left, the catch pin 22 contacts the catches 28 on the edges of the front and rear locking bar plates 24 and 25, so that when the lever 11 reaches the position SI it cannot swing out further to the left, in order to attain the locked-in position F1. If the actuating force fails, the lever 11 returns to the position NI.
This device arrangement is used to control the front loader attachment 4 in
This device arrangement is used to control the front loader arms 3 in
The devices for locking out valves, illustrated in
If instead of a front loader 2 in
Naturally, the invention is not limited to the exemplary embodiments mentioned above. Thus, for example, it may be necessary to implement the locking bar 20 in such a way that the position F, but not the position RH, of the valve gate is blocked. For this purpose the locking bar 20 with a catch edges 28 in the front and rear locking bar plates 24 and 25 is arranged on the left side, while on the right side the catch plate 26 and its catch edge 29 are omitted. The invention can also be applied to valves which have different or no locked-in positions on the end limits of the regulating range provided by the manufacturer. Moreover, it is conceivable that if a plurality of valves 8 and devices, which are equipped with locking bars 20 are used, each locking bar 20 is operated separately, so that the locking device can be switched on and off separately for each valve 8.
Number | Date | Country | Kind |
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0616168.1 | Aug 2006 | GB | national |
Number | Name | Date | Kind |
---|---|---|---|
2877798 | Hansen | Mar 1959 | A |
3143894 | Tennis | Aug 1964 | A |
3400790 | Ruhl et al. | Sep 1968 | A |
3509701 | Clarke | May 1970 | A |
3759333 | Rivinius | Sep 1973 | A |
4526055 | Batchelor et al. | Jul 1985 | A |
4966518 | Kourogi et al. | Oct 1990 | A |
5622199 | Pieper | Apr 1997 | A |
6286696 | Van Gorp et al. | Sep 2001 | B1 |
20050274831 | Burdick | Dec 2005 | A1 |
Number | Date | Country |
---|---|---|
3733371 | Apr 1989 | DE |
3801072 | Jun 1989 | DE |
3925771 | Feb 1991 | DE |
20212458 | Feb 2004 | DE |
Entry |
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European Search Report for corresponding European Application No. EP 07013745 dated Dec. 14, 2007. |
Number | Date | Country | |
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20080041458 A1 | Feb 2008 | US |