DE102021131266A1 - Control arrangement for controlling a hydraulic cylinder for adjusting a harvesting attachment - Google Patents

Abstract

A hydraulic control arrangement (116) for controlling a hydraulic cylinder (114) for adjusting a header (20) relative to a harvesting machine (10) comprises an electronic control unit (70), a tank (202) for receiving hydraulic fluid, a pump (110) for providing pressurized hydraulic fluid, a first valve assembly and a second valve assembly. The control unit (70) is signal-connected to the valve assemblies and configured to selectively connect the pump (110) or the tank (202) to the hydraulic cylinder (114) via the first valve assembly in a first mode of operation and to selectively connect the pump in a second mode of operation (110) or to connect the tank (202) to the hydraulic cylinder (114) via the second valve arrangement. In addition, the control unit (70) is configured to additionally connect the pump (110) or the tank (202) to the hydraulic cylinder (114) via the second valve arrangement in the first operating mode and/or to connect the pump (110) in the second operating mode or to additionally connect the tank (202) to the hydraulic cylinder (114) via the first valve arrangement.

Description

The invention relates to a hydraulic control arrangement for controlling a hydraulic cylinder for adjusting a harvesting attachment in relation to a harvesting machine, comprising an electronic control unit, a tank for receiving hydraulic fluid, a pump for providing pressurized hydraulic fluid, a first valve arrangement and a second valve arrangement, the control unit is signal-transmittingly connected to the valve arrangements and configured to selectively connect the pump or the tank to the hydraulic cylinder via the first valve arrangement in a first operating mode and to selectively connect the pump or the tank to the hydraulic cylinder via the second valve arrangement in a second operating mode, and a harvester equipped with it.

State of the art

Self-propelled harvesters include not only the body of the actual harvester, which is supported on ground engagement means such as wheels and/or tracks on the ground, but also a header with which they pick up the crop to be processed from a field. The header is connected to the harvester body by an intake conveyor. Actuators in the form of hydraulic cylinders (usually arranged on both sides of the intake conveyor) are used to adjust the height of the header, which rotate the intake conveyor and thus the header about a horizontal axis oriented transversely to the forward direction. This axis usually coincides with the axis of rotation of a conveyor or a crop processing device (e.g. tangential threshing drum of a combine harvester or chopper drum of a forage harvester) of the harvesting machine.

In the prior art, various operating modes are provided for controlling the height of the header, which usually include a contact pressure control and a position control. With the contact pressure control, the cylinders are subjected to a specific pressure (usually specifiable by the operator of the harvesting machine or automatically based on the respective harvesting attachment) so that the harvesting attachment rests on the ground with a desired contact force. With position control, the cylinders are moved to a specified position in order to guide the header at a desired height above the ground. In position control, the desired height of the header above the ground can be specified by an operator, or detected by a look-ahead sensor, or read from a map and the actual value is measured by the header's height sensor and is used as a feedback value for the height control ( EP 1 269 823 A1 , WO 2008/088916 A2 ).

Details of the hydraulics of such a height control are regarded as generic EP 2 520 152 A1 described. There, a pump is connected via a proportional valve to the piston chamber of the single-acting hydraulic cylinder, which is opened in a position control mode for raising the header. A valve is opened to lower the header. Furthermore, a valve that can be switched on and off and a proportional pressure control valve connected in series with it are provided for controlling the contact pressure, which provide an adjustable pressure in the piston chamber of the hydraulic cylinder in the operating mode for contact pressure control.

Task

In said prior art, the three valves mentioned are each associated with a single mode of operation (contact pressure and position control) and are only opened when the associated mode of operation is active. This means that the valves must be sized sufficiently large to be able to raise and lower in a reasonable time even the largest and hence heaviest headers to be used with a particular harvester. This applies in particular to the lowering process in the active contact pressure control, as there the pressure control valve only works with a small pressure difference between the contact pressure to be regulated and the load pressure in the cylinder, and in this operating state the flow rate is smaller than with a large pressure difference due to the design. This is more common when fitting a relatively light header, such as a pick-up on a forage harvester. However, it also applies to heavy attachments when lowering in the headland.

This can lead to crops being left on the field because the header is being guided too high. Similar problems can occur with the position control, since the lowering valve provided for lowering the harvesting attachment also has to be adapted there to the lightest harvesting attachment that can be coupled to the harvesting machine. In order to avoid these problems, the experienced operator controls a pressure-controlled pick-up in addition, and in some cases also in advance, manually to the lowering valve in order to accelerate the lowering process. When using a heavy grass cutterbar with pressure control, there is also the problem that the lowering process is too slow, especially in the last few centimetres. This leads to delays in lowering of the header when driving into the crop to be mowed or at a cut position that is too high.

The object on which the invention is based is seen as providing a height control for a harvesting attachment of a harvesting machine, in which the disadvantages mentioned are not to be expected or are to be expected to a reduced extent.

Solution

According to the invention, this object is achieved by the teaching of patent claims 1 and 7, with the further patent claims listing features which further develop the solution in an advantageous manner.

A hydraulic control arrangement for controlling a hydraulic cylinder for adjusting a harvesting attachment in relation to a harvesting machine comprises an electronic control unit, a tank for holding hydraulic fluid, a pump for providing pressurized hydraulic fluid, a first valve arrangement and a second valve arrangement. The control unit is signal-connected to the valve assemblies and is configured to selectively (i.e. sequentially) connect the pump or tank to the hydraulic cylinder via the first valve assembly in a first mode of operation, and in a second mode of operation selectively (i.e. sequentially connect the pump or tank via the to connect the second valve arrangement to the hydraulic cylinder It is proposed that the control unit is configured to additionally connect the pump or the tank to the hydraulic cylinder via the second valve arrangement in the first operating mode and/or to additionally connect the pump or the tank in the second operating mode to be connected to the hydraulic cylinder via the first valve arrangement.

In this way, one avoids the disadvantages mentioned without much effort, namely only by reprogramming the control, by using the other (first or second) valve arrangement in each case in order to increase the hydraulic flow through the control arrangement and thus the harvesting attachment faster if necessary to be adjusted than before.

The first mode may be a pad pressure control mode while the second mode may be a position control mode.

The first valve arrangement can thus comprise a pressure control valve and an on and off valve, the on and off valve being connected between the hydraulic cylinder and a first connection of the pressure control valve and the pressure control valve being arranged, the first connection optionally with the tank or an outlet of the pump connect to.

The second valve arrangement may comprise a raising valve and a lowering valve, the raising valve being connected between the outlet of the pump and the hydraulic cylinder and the lowering valve being connected between the hydraulic cylinder and the tank.

The pressure in the hydraulic cylinder can be detected by a sensor and the controller can be configured to activate the second valve arrangement in the contact pressure control mode if a difference between a detected desired and actual value of the pressure in the hydraulic cylinder exceeds a threshold value. Similarly, the position of the header can be detected by a sensor and the controller can be configured to activate the first valve arrangement in the position control mode if a difference between a detected setpoint and actual value of the position of the header exceeds a threshold value.

The control arrangement described can be used on any harvesting machine, such as forage harvesters and combine harvesters, in conjunction with any harvesting attachments. A harvesting attachment within the meaning of the present invention can also be viewed as a mowing device that is connected via the described control arrangement to a carrier vehicle, e.g. The crop does not necessarily have to be conveyed into the harvesting machine. In other words, the control arrangement can generally be used on agricultural machines and devices that use pressure and position controls for actuating processes of functional elements or attachments.

character list

• 1 eine schematische seitliche Ansicht einer Erntemaschine mit einem Erntevorsatz, und
• 2 ein Schema der Kontrollanordnung zur Auflagedruck- bzw. Höhensteuerung des Emtevorsatzes der Erntemaschine der 1.

An exemplary embodiment of the invention is explained with reference to the illustrations. Show it:

• 1 a schematic side view of a harvesting machine with a header, and
• 2 a diagram of the control arrangement for contact pressure or height control of the harvesting attachment of the harvesting machine 1 .

In the 1 a self-propelled harvesting machine 10 in the form of a forage harvester is shown in a schematic side view. Harvester 10 is built upon a frame 12 supported by front driven wheels 14 and steerable rear wheels 16 . The service The harvesting machine 10 is carried out from a driver's cab 18 from which a header 20 in the form of a pick-up (so-called pick-up) can be seen. Crops picked up from the ground by means of the header 20, e.g. B. Grass or the like is fed via a feed conveyor 22 with feed rollers, which are arranged inside a feed housing 24 on the front side of the harvesting machine 10, to a chopper drum 26 arranged below the driver's cab 18, which, in cooperation with a shearbar 102, chops it into small pieces and it gives up a conveyor device 28 . The crop leaves the harvesting machine 10 to a transport vehicle driving alongside via an ejection chute 30 that can be rotated about an approximately vertical axis and whose inclination can be adjusted the 1 runs to the right.

Chopping drum 26 is driven from a belt pulley 48, which is connected to an internal combustion engine 32 via an angular gear, via a drive belt 50, which has a belt pulley 54 for driving chopping drum 26 and a belt pulley 52 for driving conveyor device 28. A grinding device 100 serves to grind the chopper knives of the chopper drum 26. In addition, a metal detector 108 is provided in the lower, front feed roller, which may be used to quickly stop the intake conveyor 22, and an operator input device 98 coupled to an electronic control unit 70 (ECU) in the driver's cab 18.

The intake housing 24 with the intake conveyor 22 can be pivoted as a whole about the axis of rotation of the chopper drum 26 . For this purpose, a hydraulic cylinder 114 is articulated on each of its two sides with one end on the frame 12 of the harvesting machine 10 and with the other end on the front area of the intake housing 24 .

A hydraulic control arrangement 116 of the hydraulic cylinders 114 is in FIG 2 shown, which according to the prior art EP 2 520 152 A1 is based, the disclosure of which is incorporated by reference into the present documents. The hydraulic control assembly 116 is configured to supply pressurized hydraulic fluid to the piston chambers of the hydraulic cylinders 114 so as to extend them. When the hydraulic cylinders 114 extend, the feeder housing 24 pivots upwardly and further raises the header 20 above the ground. Similarly, when the control assembly 116 releases hydraulic fluid from the piston chambers of the hydraulic cylinders 114 into a tank 202, the hydraulic cylinders 114 retract and the intake housing 24 pivots downward and the header 20 lowers toward the ground.

The 2 12 shows a closed loop hydraulic control assembly 116 for raising and lowering the retractor housing 24. A hydraulic pump 110 is driven by the engine 32 to rotate. The pump 110 has an adjustable displacement and for this purpose has a control connection 112 which is connected to a hydraulic control line 200 which controls the pressure build-up of the pump 110 depending on the pressure present at the control line 200 . The greater the pressure on the control line 200, the greater the adjusted pressure of the pump 110. The hydraulic flow provided by the pump 110 is determined by the cross section opened by the controlled valves.

The inlet of the pump 110 is in fluid communication with a tank 202 for withdrawing fluid therefrom. The outlet of the pump 110 is in fluid communication with the input port of a pressure relief valve 204 . A hydraulic lift valve 206 is positioned between the cylinders 114 and the pressure relief valve 204 . A check valve 208 is disposed in the line connecting the outlet of the lift valve 206 and the piston chambers of the hydraulic cylinders 114, which allows passage of hydraulic fluid from the lift valve 206 into the cylinders 114 and prevents backflow from the cylinders 114 into the lift valve 206.

A second check valve 210 connects a line connecting the inlet of the check valve 208 and the outlet of the lift valve 206 to a sensing port of the pressure compensating valve 204 to the hydraulic control line 200. The second check valve 210 allows hydraulic fluid to flow from the outlet of the lift valve 206 and prevents flow from the control line 200 into the inlet of the check valve 208, the sensing port of the pressure equalizing valve 204 and the outlet of the lift valve 206.

A proportional hydraulic lowering valve 212 is positioned between the piston chambers of the cylinders 114 and the tank 202 to allow hydraulic fluid from the cylinders 114 into the tank 202 when the lowering valve 212 is energized. The header 20 is then lowered solely by the action of gravity. When the lowering valve 212 is not energized, it blocks the flow of hydraulic fluid from the cylinders 114 into the tank.

The lowering valve 212 and the raising valve 206 are electrically connected to the controller 70 which in turn is connected to the operator input device 98 in the operator's cab 18 . The operator can thus use the operator input device 98 (in a position control mode) to raise and lower the header 20, for which purpose the controller 70 opens the lifting valve 206 or the lowering valve 212 and the header 20 is thus raised or lowered.

A control valve 216 is positioned between the hydraulic control line 200 and the tank 202 . Control valve 216, shown here as an orifice, drains control line 200 when lift valve 206 is closed (i.e., when the operator is not attempting to raise header 20) until the pressure in control line 200 is near zero. As long as the pressure in the control line 200 is near zero, the control signal present at the control port 112 of the pump 110 is essentially gone and the specific displacement of the pump 110 is reduced to near zero in response. Since the pump 110 is not required to raise the header 20, the pump 110 still provides a low pressure, but requires only little drive energy.

When the operator, via operator input 98 and controller 70, raises header 20, lift valve 206 opens which then applies the low pressure fluid provided by pump 110 to second check valve 210 which in turn applies that low pressure to the control line 200 creates. As a result, the pressure in the control line 200 increases slightly and the specific displacement of the pump 110 increases slightly. As a result, the pressure at the outlet of the pump 110 increases, as a result of which the pressure in the control line 200 also increases via the lifting valve 206 and the second check valve 210 . This pressure feedback loop through the second check valve 210 progressively increases the specific displacement of the pump 110 until the pressure at its output reaches the static pressure in the cylinders 114 and the check valve 208 opens and the cylinders 114 fill. This results in a certain time delay between the actuation of the operator input device 98 and the raising of the header 20.

The hydraulic control arrangement after 2 includes further elements that allow contact pressure regulation and activation of the pump 110 via a check valve 306 in order to shorten the reaction time when the lifting valve 206 is activated. These are an on/off valve 302, a pressure control valve 304, the check valve 306 and a pressure sensor 308. The controller 70 is connected to the on/off valve 302 to open or close it. The controller 70 is connected to the pressure regulator valve 304 to achieve a controllable desired pressure at its output. In addition, the controller 70 is connected to a pressure sensor 308 that provides a signal indicative of the pressure in the cylinder 114 .

The on/off valve 302 is connected to the cylinder 114 and the check valve 208 on one side and to the pressure control valve 304 on the other side. Second and third ports of the pressure regulator valve 304 are selectively connected to a first port of the pressure regulator valve 304 depending on whether the pressure commanded by the controller 70 is greater or less than the actual pressure at the first port of the pressure regulator valve 304 . The controller 70 controls the pressure control valve 304 such that when the pressure present at the first port is less than a commanded pressure, the first port of the pressure control valve 304 is connected to the pump 110 via a check valve 324 and a line 320 until one of the Control 70 commanded pressure is present at the first port. Similarly, the first port is connected to the tank 202 via a line 322 as long as the pressure at the first port is greater than a pressure commanded by the controller 70 . The first port of the pressure control valve 304 is coupled to the inlet of the check valve 306 whose outlet is connected to the hydraulic control line 200 . The pressure at the first connection of the pressure control valve 304 is therefore also present at the control line 200 when the check valve 306 is open. This adjusts the displacement of the pump 110 such that the pressure at its outlet is slightly greater than the pressure in the control line 200 .

In the pad pressure regulation mode (which could also be referred to as the floating mode), the hydraulic control arrangement 116 is set up to provide a substantially constant pressure in the hydraulic cylinders 114 . This mode of operation is used when the header 20 is to be guided over the ground with a specific tracking force. This constant pressure is achieved by the controller 70 energizing the on/off valve 302 and thus connecting the cylinders 114 directly to the pressure control valve 304 . In this case, additional fluid is supplied from the pump 110 by the pressure control valve 304 via the on/off valve 302 when the header 20 moves upwards on uneven ground which rises in the forward direction. Similarly, if the ground is uneven and descending in a forward direction, causing the cylinders 114 to retract, the pressure control valve 304 will bleed excess hydraulic fluid from cylinders 114 via on/off valve 302 to tank 202 via line 322 to maintain pressure. The non-return valve 306 and the control line 200 ensure that the pump 110 only provides the pressure required in each case, without a time delay when lifting.

In the second position control operating mode (height control) of the header 20 already described above, the on/off valve 302 is closed. The pressure control valve 304, which also provides a certain pressure on the control line 200 via the non-return valve 306 in the height control operating mode, even when the lifting valve 206 is closed, has the above-mentioned disadvantage of the time delay of the arrangement made up of only the valves 204 and 206 when lifting the Harvesting attachment 20 avoided. When the valve 302 is closed, the pressure control valve 304 is used to set a pressure that is slightly lower than the load pressure. The pump 110 will set the pressure to this value - as an elevated standby pressure - and then be faster on a lift because the time to build up pressure from the normal low standby or other lower load pressure from another consumer is reduced. It might be possible to dispense with this procedure for the pressure regulation for lighter harvesting attachments and the position regulation for heavy harvesting attachments, at least for lifting the harvesting attachment into the transport position, since it causes unnecessary hydraulic power loss.

Up to this point, the description corresponds to the state of the art EP 2 520 152 A1 , except that according to the 2 the raise valve 206 and the lowering valve 212 are also connected to the controller 70 and are controlled by it. Again, the prior art only opens on/off valve 302 and closes lift valve 206 and lowering valve 212 in the first (pressure control) mode of operation, and closes the on/off valve in the second (position control) mode of operation 302 is always closed and, if necessary, the lifting valve 206 or the lowering valve 212 can be opened. This has the disadvantage that, for example, the dimensioning of the passage opening of the valve 212 determines how quickly a header 20 can be lowered. Since the lowering valve 212 is usually dimensioned so large that a relatively heavy harvesting attachment 20 is lowered at an appropriate speed, with lighter harvesting attachments 20, such as that in 1 shown pick-up, the disadvantage that the harvesting attachment 20 sinks too slowly, since the pressure resulting from its weight in the cylinders 114 is quite low. The passage opening of the valve 212 could now be enlarged, but this has the disadvantage of higher production costs. In addition, heavy harvesting attachments 20, such as corn harvesting attachments with 12 rows (9 m working width), would sink too quickly and hit the ground almost unchecked, which is also undesirable. Analogous problems can occur in the position control mode of lifting through the lift valve 206, as well as in the bearing pressure control mode through the pressure control valve 304.

It is therefore proposed that the controller 70 be configured and programmed, in the position control mode, when the header 20 is lowered with a command, not only to open the lowering valve 212, but also to open the on/off valve 302 and switch the pressure control valve 304 to the in 2 to spend position shown, in which it connects the on and off valve 302 via the line 322 to the tank 202. As a result, said problem can be avoided and a relatively light harvesting attachment 20 can be lowered sufficiently quickly.

Furthermore, the controller 70 can be configured and programmed not only to open the lifting valve 204 when the header 20 is raised in the position control mode, but also to open the on/off valve 302 and switch the pressure control valve 304 to the position shown in 2 to spend position not shown, in which it connects the on and off valve 302 to the pump 110. As a result, the problem mentioned can be avoided and a relatively heavy harvesting attachment 20 can be lifted sufficiently quickly.

In the position control mode, the controller 70 can operate as a closed loop control. For this purpose, a sensor 310 is provided for detecting the height of the harvesting attachment 20 above the ground (cf., for example, EP 1 911 342 A2 for a corn header) which feeds back to the controller 70 an actual value of the height of the header 20 above the ground. The operator input device 98 or another sensor that detects, for example, the height of the harvested crop and/or the ground contour in advance is used by the controller 70 as a target value for the height or the angle of rotation of the intake housing 24 about its axis of rotation. In a manner known per se, the controller 70 then controls the lowering valve 212 or the lifting valve 206 in order to control the hydraulic cylinder 114 in the sense of an adjustment of the actual value to the desired value. If the difference between the setpoint and the actual value is greater or greater than a certain (first or second) threshold value, which indicates that the lowering valve 212 or the lifting valve 206 alone is not able to fill the hydraulic cylinder 114 sufficiently quickly or to drain, the controller 70 would open the on/off valve 302 and turn the pressure control valve 304 to an appropriate position in the manner described above gene, ie connect the on and off valve 302 to the outlet of the pump 110 or the tank 202.

If the header 20 does not have a suitable sensor for detecting the height above the ground, as shown in 1 As shown in the pick-up, the sensor 310 can also detect the angle of the intake housing 24 with respect to the frame 12. In this way, the height of the header 20 can be adjusted at a predetermined or fixed speed, regardless of its weight, and if necessary open the on/off valve 302 in the manner described above and spend the pressure control valve 304 in a suitable position, ie the on - and shut-off valve 302 to the outlet of the pump 110 or the tank 202.

Similarly, in the contact pressure control mode, based on the pressure in hydraulic cylinders 114 detected by pressure sensor 308, it is possible for controller 70 to open lowering valve 212 upwards if a threshold value of a deviation from the desired pressure is exceeded and/or if a threshold value of a deviation from the desired pressure is exceeded desired pressure down by the controller 70 to open the lift valve 206. As a result, situations in which the header 20 is subject to a sudden change in position, e.g. when driving over a bump or driving through a depression, can be compensated for more quickly than before

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• EP 1269823 A1 [0003]
• WO 2008/088916 A2 [0003]
• EP 2520152 A1 [0004, 0020, 0032]
• EP 1911342 A2 [0035]

Claims (7)

Hydraulic control arrangement (116) for controlling a hydraulic cylinder (114) for adjusting a header (20) relative to a harvesting machine (10), comprising an electronic control unit (70), a tank (202) for receiving hydraulic fluid, a pump (110) for Providing pressurized hydraulic fluid, a first valve assembly and a second valve assembly, wherein the control unit (70) is signal-connected to the valve assemblies and is configured to selectively include the pump (110) or the tank (202) in a first mode of operation via the first valve assembly to connect to the hydraulic cylinder (114) and in a second operating mode to optionally connect the pump (110) or the tank (202) to the hydraulic cylinder (114) via the second valve arrangement, characterized in that the control unit (70) is configured to to connect the pump (110) or the tank (202) to the hydraulic cylinder (114) in the first operating mode additionally via the second valve arrangement and/or to connect the pump (110) or the tank (202) additionally via the first valve arrangement in the second operating mode to be connected to the hydraulic cylinder (114). Control arrangement (116) after claim 1 , wherein the first operating mode is a bearing pressure control mode and/or the second operating mode is a position control mode. Control arrangement (116) after claim 2 , wherein the first valve arrangement comprises a pressure control valve (304) and an on and off valve (302), the on and off valve (302) is connected between the hydraulic cylinder (114) and a first connection of the pressure control valve (304) and the pressure control valve ( 304) is arranged to connect the first connection either to the tank (202) or to an outlet of the pump (110). Control arrangement (116) after claim 2 or 3 , wherein the second valve arrangement comprises a lifting valve (206) and a lowering valve (212), the lifting valve (206) being connected between the outlet of the pump (110) and the hydraulic cylinder (114) and the lowering valve being connected between the hydraulic cylinder (114) and the Tank (202) is connected. Control arrangement (116) according to one of claims 2 until 4 , wherein the position of the header (20) can be detected by a sensor (310) and the controller (70) is configured to activate the first valve arrangement in the position control mode if a difference between a detected target and actual value of the position of the header ( 20) exceeds a threshold. Control arrangement (116) according to one of claims 2 until 5 , wherein the pressure in the hydraulic cylinder (114) can be detected by means of a sensor (308) and the controller (70) is configured to activate the second valve arrangement in the support pressure control mode if there is a difference between a detected setpoint and actual value of the pressure in the hydraulic cylinder ( 114) exceeds a threshold. A harvesting machine (10) having a control arrangement (116) according to any one of the preceding claims.

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