EP1369598A1 - Electro-hydraulic lifting control device for industrial use vehicles - Google Patents

Abstract

The device has a lifting branch with a three way flow regulator (R1) that is provided between a pressure source and a hydraulic cylinder to lift control. A lowering branch with a two-way flow regulator (R2) has a proportional magnet and a pressure balance (10). A redundancy-switching unit provided between the pilot pressure circuits of the regulators and a reservoir is actively operated between the closed and open positions.

Description

The invention relates to an electro-hydraulic stroke control device in the preamble of claim 1 specified Art.

In the electrohydraulic stroke control device known from DE 42 39 321 C. are only the proportional pressure control valves for electrically operated components the lifting control and the lowering control are available. The security requirements are particularly high for industrial trucks, especially forklift trucks. contamination in the hydraulic medium, e.g. Chips or the like, can not be with Avoid 100% security. Such contaminants can cause for example the proportional pressure control valve of the lowering control or the lifting control hangs and can no longer be adjusted, so that the hydraulic cylinder carried load drops or runs uncontrollably. The proportional magnet creates a force that is then insufficient, the increased resistance to movement to overcome in the valve. This means an increased security risk that it did not exist in previous mechanically operated hydraulic lift control devices, since only the mechanical force needed to be increased accordingly in order to to overcome such resistance.

In the electrically controllable lifting module known from DE 100 10 670 A (FIG. 1) the three-way flow controller in the lower branch on the downstream side with the tank and for energy recovery connected to the suction side of the pump. In the lifting line is because the Speed of the hydraulic cylinder is controlled by the speed of the pump, only one black / white 2/2-way solenoid valve provided. One branches off the lifting strand Drain line with a 2/2-way solenoid valve to the tank, which at Utility sink is switched electrically to continuity if there is no additional consumer is to be supplied. Should the three-way current controller in the Lowering operation gets stuck, then the lifting cylinder retracts uncontrollably.

In the stroke control device known from DE 41 40 408 A, lifting and Lowering control two proportional pressure control valves are provided. Should be in lowering mode the proportional pressure control valve gets stuck due to contamination the lifting cylinder turns on uncontrollably under load.

Further prior art is contained in EP 0 546 300 A, EP 0 893 607 A, US 5,701,618 A.

With electrically controlled lift trucks, regardless of whether they are motor-operated or are electrically operated, there is a trend towards increased security from, for the failure of an electrically controlled regulating or control element at least the lifting cylinder further electrically actuated safety devices to provide the, among others for personal protection, to prevent the load from falling. Secondary consumers supplied by the same pressure source often work with one lower pressure than the main lift cylinder. These demands can be met with Electrically operated at various points in the control device Valves meet, however, this requires additional effort on valves and actuating magnets or expensive proportional magnets with complex wiring.

The invention has for its object an electrohydraulic stroke control device of this type to indicate their operational safety against malfunctions due to contamination of the hydraulic medium or developing mechanical Damage to hydraulic switching elements is increased with minimal effort.

As a side aspect in the context of this task should also at the Lowering control an additional activatable braking function may be possible, or is a deliberate active activation of one or both current controllers desirable, or should the supply pressure for at least one other hydraulic consumer easy to set lower with minimal effort than e.g. for the Lifting control. The effort mentioned relates mainly to magnets as a valve actuator.

The object is achieved according to the invention with the features of claim 1 solved.

The operational safety of the electrohydraulic stroke control device is increased because the redundancy switching element then actively intervenes when at least one other is electrically actuable switching element should no longer function properly. By The active intervention of the redundancy switching element is primarily uncontrolled Avoid load movements or an unwanted lowering of the load. For example, remains the proportional pressure control valve for lowering control or lifting control hang, so that it is no longer due to its proportional magnet can be adjusted (the lifting hydraulic cylinder would then either retract under the load or extend against the load), then this brings effective redundancy switching element in the open position either the pressure compensator of the two-way flow controller in the load-holding shut-off position (stopping the descending lifting hydraulic cylinder) or the pressure compensator of the three-way flow controller in the open position (Deriving the current to the tank so that the lifting hydraulic cylinder stops). If the proportional pressure control valve functions properly, the redundancy switching element takes over no influence in the respective pilot circuit, since it is powered of the respective proportional magnet is energized and holds its closed position. The redundancy switching element is an easy to integrate safety component and requires minimal effort. For this function is for the control electronics only the solenoid of the switching element and hydraulically a simple, small valve required for the pilot oil.

The redundancy switching element, however, offers further advantageous thanks to its arrangement Possibilities, but it must be assumed that in modern industrial trucks Electronic control provided contains a microprocessor that offers many possibilities for individual program routines or functions. By adjusting of the redundancy switching element in the open position during the lowering control For example, the lowering movement can also be braked individually by the pressure compensator of the two-way flow controller to the closed position in another way is brought in as by the pressure difference of the proportional pressure control valve. A similar individual braking could also be done with the lift control via the Pressure balance of the three-way current regulator. Furthermore, the redundancy switching element Activate the two-way current controller or the three-way current controller actively, i.e. the respective pressure compensator in the closed position or full open position bring. Finally, the redundancy switching element can be used as a variable pressure relief valve the pilot pressure of the pressure compensator of the three-way flow controller change the supply pressure for at least one other hydro consumer that is lower than that of the lift hydraulic cylinder. It opens that up Redundancy switching element in interaction with the control electronics a more universal control of the industrial truck, the given per se Performance of the higher-level electronics is used without additional effort.

The redundancy switching element should be between the tank and either the opening pilot side the pressure compensator of the two-way flow controller and / or the closing pilot side the pressure compensator of the three-way flow controller. In this Position, the redundancy switching element relieves the pilot pressure when it is activated for the respective pressure compensator, so that it is forced into its closed position or through position.

For a sensitive regulation of the pressure relief by the redundancy switching element To be able to adjust, it is advisable to use this as a 2/2-way control valve with pressure pilot control in the opening direction and a proportional magnet as an actuator for Adjust in the closing direction. This interpretation is advantageous if the redundancy switching element as the variable pressure relief valve the pilot pressure has to be adjusted individually. However, it is sufficient for the desired security aspect off, the redundancy switching element only between one opening and one To be able to change the closed position (black / white function).

For this reason, redundancy switching elements are only sufficient for increased safety requirements a 2/2-way valve with pressure pilot control in the opening direction and one Black / white magnets as actuators for adjustment in the closing direction. A 2/2-way valve this design is inexpensive and reliable. Conveniently, the redundancy switching element here is a poppet valve that is characterized by a leak-free Distinguished closed position.

The pressure pre-control of the redundancy switching element with which the Redundancy switching element is brought into its open position, with the opening pilot side the pressure compensator of the two-way flow controller or the closing pilot side the pressure compensator of the three-way flow controller. As long as pilot pressure is present at the respective pressure compensator, the redundancy switching element in the direction of its open position, which it only then is able to take if it is not actively electrically adjusted to its closed position is.

A further increase in operational safety can be achieved if the redundancy switching element is assigned to both current regulators and its function for the respective Current regulator fulfilled depending on the pressure. That is, the shuttle valve connects each the working pressure compensator with the redundancy switching element, the then selected pilot pressure or the higher pilot pressure is present. The redundancy switching element thus works automatically with the lifting control with the three-way current regulator, on the other hand, together with the two-way current controller for lowering control.

The redundancy switching element can expediently be connected in parallel with a control pressure pressure relief valve be arranged. This offers structural advantages because anyway a pilot pressure channel via the pressure relief valve to the tank or to the return line runs. If the redundancy switching element than by a proportional magnet Actuatable pressure control valve is formed, which with varying current supply the function of a pressure relief valve, the pressure relief valve can may be omitted.

The redundancy switching element, guided by the control electronics and, as mentioned, when designed as a proportional pressure control valve, the function of an electrical adjustable pressure relief valve to meet the pressure compensator of the three-way flow regulator sets a lower supply pressure for other hydraulic consumers. All of the above functions can be done with a small valve and a Achieve magnets.

Because the redundancy switching element arranged in the pilot control circuit, for example, in the event of a fault of the three-way current controller when lowering is in its open position goes as soon as the proportional magnet of the three-way current controller is de-energized, the lifting hydraulic cylinder could operate via the pilot control circuit despite the load holding function give in to the pressure compensator very slowly. For this reason, it is advisable the redundancy switching element as a 4/2-way switching valve with a switching magnet as Train actuator and the pilot line to the lowering branch at least forklift-tight shut off while opening the pilot side of the pressure compensator directly to the tank is relieved. This results in a perfect load holding function of the pressure compensator, so that the lifting hydraulic cylinder even with a stuck proportional directional pressure control valve remains reliably stopped.

In order to be able to guarantee this high security standard even if that Redundancy switching element the function of pressure reduction for other consumers it is advisable to execute the redundancy switching element even as a 4/3-way proportional pressure control valve with a proportional magnet as an actuator and the two pilot lines from the lowering branch and from the closing pilot side the pressure compensator of the two-way flow controller separately. If the 4/3-way proportional pressure control valve is canceled when lowering control is canceled de-energized, then it assumes its switch-off position, in which the opening pilot side the pressure compensator of the two-way flow regulator to the tank and the pressure compensator is set for load holding. This switch position is also assumed when the lifting control is canceled. Then the closing pre-tax side is the Pressure balance of the three-way flow regulator to the tank is relieved, so that the pressure balance, if supply pressure is present, set to the closed position. As soon as Lifting control or lowering control of one of the proportional magnets of the current regulator the proportional solenoid of the 4/3-way proportional pressure control valve is energized fully energized. The switching position thus created provides the pilot line from the lowering branch to the opening pilot side of the pressure compensator of the two-way current controller on continuity and interrupts the connection of the Pilot line to the closing pilot side of the pressure compensator of the three-way flow controller to the tank. In contrast, is another consumer in the lifting control switched on, then the proportional solenoid of the 4/3-way proportional pressure control valve according to the desired pressure reduction against the control spring and the pilot pressure with a current value, with which a control function to reduce the pilot pressure for the pressure compensator of the three-way current controller is executed. All of these features come with one single valve and only a single proportional magnet.

The 4/2-way switching valve or the 4/3-way proportional pressure control valve is useful designed as a slide valve in a forklift-tight design. This means, that the valve meets the requirement for the forklift tightness criterion.

In order to be as small as possible and weak and therefore inexpensive Switching magnets or proportional magnets for the redundancy switching element, it is expedient in the slide valve with respect to the tank pressure to provide pressure-balanced valve spool. If the redundancy switching element it also controls the pressure limitation for other consumers, it is special expedient, the pilot pressure against which the proportional magnet works, only on a small part of the valve spool.

With this design, the electro-hydraulic stroke control device is suitable for both Lift trucks with an internal combustion engine and an electric motor can be used. The lift control device can be used with an electric motor-driven lift truck can be used with or without energy recovery (utility sinks). For lowering operation, where the electric motor is operated as a generator via the pump, it is only necessary to place the lower branch upstream of the pressure compensator of the two-way flow regulator to connect to the suction side of the pump via a useful line, and Place a check valve between the pump and the tank. At high Load pressure and without additional hydraulic consumers switched on can handle the full amount (controlled by the pressure compensator of the two-way flow controller) by the pump be promoted. If another hydraulic consumer is switched on, then it regulates Pressure compensator of the two-way current regulator when sinking a current through the Pump that corresponds to the current demand. The redundancy switching element does not intervene if it functions properly, but only if there is a fault, and occasionally when reducing the pressure for other consumers.

The electrically active actuable components of the stroke control device should be included an electronic containing a microprocessor or logic circuit Control connected to the different actuation routines as needed, as chosen, or according to an automated scheme.

Fig. 1

ein Blockschaltbild einer elektrohydraulischen Hubsteuervorrichtung mit einem Redundanz-Schaltglied, das der Senksteuerung zugeordnet ist,

Fig. 2

ein Blockschaltbild einer elektrohydraulischen Hubsteuervorrichtung mit einem Redundanz-Schaltglied, das der Hebesteuerung zugeordnet ist,

Fig. 3

ein Blockschaltbild einer elektrohydraulischen Hubsteuervorrichtung mit weiteren Hydroverbraucher, mit einem Redundanz-Schaltglied, das der Hebesteuerung und der Senksteuerung zugeordnet ist, und bei Zuordnung zur Hebesteuerung zusätzlich als elektrisch verstellbares Druckbegrenzungsventil zur Druckminderung für die weiteren Hydroverbraucher dient,

Fig. 4

ein Blockschaltbild einer weiteren Ausführungsvariante, und

Fig. 5

ein Blockschaltbild einer noch weiteren Ausführungsvariante.

Embodiments of the subject matter of the invention are explained with the aid of the drawing. Show it:

Fig. 1

2 shows a block diagram of an electrohydraulic lift control device with a redundancy switching element which is assigned to the lowering control,

Fig. 2

2 shows a block diagram of an electrohydraulic lift control device with a redundancy switching element which is assigned to the lift control,

Fig. 3

2 shows a block diagram of an electrohydraulic stroke control device with further hydraulic consumers, with a redundancy switching element which is assigned to the lifting control and the lowering control and, when assigned to the lifting control, also serves as an electrically adjustable pressure relief valve for reducing the pressure for the further hydraulic consumers,

Fig. 4

a block diagram of another embodiment, and

Fig. 5

a block diagram of yet another embodiment.

In the electrohydraulic stroke control device S in Fig. 1, a hydraulic cylinder Z for lifting control from a pressure source P (hydraulic pump), which e.g. is driven by an electric motor or diesel engine M and, if no other hydraulic consumers are to be supplied when lowering the hydraulic cylinder Z can stand, or (Fig. 4) then runs for energy recovery as a motor. The hydraulic pump sucks in from a tank T and acts on a lifting strand 1, in which a three-way current regulator R1 is provided. The three-way current regulator R1 consists of a proportional pressure control valve 3, with which the lifting speed is set by a proportional magnet 4, and a pressure compensator 5 between the lifting line 1 and the tank T. The pressure control valve 3 is spring loaded acted towards the shut-off position. Between the hydraulic cylinder Z and the pressure control valve 3 branches a pilot line 6 to the closing pilot side (on which a control spring also acts) the pressure compensator 5. From the lifting strand 1 branches a further pilot line 7 upstream of the pressure control valve 3 Opening pilot side of the pressure compensator 5 from.

From the lifting line 1 branches between the pressure control valve 3 and the hydraulic cylinder Z a lowering line 2 to the tank, in which a two-way flow controller for lowering control R2 is included. The two-way flow controller R2 consists of a pressure control valve 8, with which the lowering speed by means of a proportional magnet 9 can be set, and a pressure compensator 10. The pressure control valve 8 is by Spring force is applied towards the shut-off position, in which there is the load pressure is able to keep leak-free. Between the pressure control valve 8 and the hydraulic cylinder Z branches from the lower leg 2 a pilot line 11 to the closing pilot pressure side 22 of the pressure compensator 10, while between the pressure compensator 10 and the Pressure control valve 8 from the lower branch 2 a pilot line 12 to the opening pilot side 19 of the pressure compensator 10 leads. On the opening pilot pressure side a control spring also works. A pilot line branches from the pilot line 12 12a to the tank T, in the z. B. a pressure relief valve 13 is included.

In addition to the two actively electrically operated components (proportional magnets 4, 9) the two-way current regulator R2 is an electrically actuated redundancy switching element Assigned to A, which energizes when the proportional magnet 9 is energized becomes. In the embodiment shown, this is a 2/2-way valve 14 in seat valve construction, i.e. with a leak-free closed position by a black and white magnet 15 against the on its opening pilot side 21 of the pilot pressure in the pilot line 12a derived pressure can be brought into the closed position shown is. The redundancy switching element A is e.g. parallel to the pressure relief valve 13 in whose wiring harness is arranged.

Function:

Before the lowering control begins, the load pressure is held by the pressure control valve 8. Now the proportional magnet 9 receives current, the strength of which is the desired one Lowering speed corresponds. At the same time, a not shown parent control of the black / white magnet 15 energized, so that the redundancy switching element A assumes its shut-off position (as shown). The pressure control valve 8 allows the proportional magnet 9 to be energized via an orifice opening Pressure medium flow out, the pressure compensator 10 using the pressure difference keeps the orifice aperture and thus the lowering speed constant. The Pressure compensator 10 sets itself in a position that depends on the pilot pressures in the pilot lines 11 and 12 and its control spring (load independence).

Should cancel the lowering movement due to contamination or mechanical damage the pressure compensator 10 get stuck, then through De-energizing the proportional magnet 9, the pressure control valve 8 in its closed position brought so that the hydraulic cylinder Z stops. The disturbance of the Pressure compensator 10 is therefore irrelevant. However, should the pressure control valve 8 itself get stuck due to contamination or mechanical damage, and do not come into the closed position despite de-excitation of the proportional magnet 9, then the hydraulic cylinder Z would drop further under the load, because with the proportional magnet 9 can no longer be acted on the pressure control valve 8 actively can and the pressure compensator 10 remains open. In this case, with de-excitation of the proportional magnet 9 also the black / white magnet 15 of the redundancy switching element A de-energized, so that the redundancy switching element A by the pilot pressure in the pilot line 12a suddenly goes into its open position and the Releases pilot pressure to the tank. The pressure compensator 10 is in from the pilot pressure the pilot line 11 brought into its closed position and holds the load pressure. The Hydraulic cylinder Z comes to a standstill. The redundancy switching element A could in If the pressure compensator 10 gets stuck, it is also energized once or several times and be de-energized to make the pressure compensator 10 run again.

In the electrohydraulic stroke control device S in FIG. 2, the redundancy switching element is A assigned to the three-way current regulator R1 for lifting control. that is, the redundancy switching element A is in one of the pilot line 6 to the closing pilot side 20 of the pressure compensator 5 branching pilot line 6a to the tank and offers a possibility to actively intervene in the event of a malfunction. For example, the pressure compensator 5 should be in a middle position due to a fault get stuck, this could cause the hydraulic cylinder Z to extend further be prevented that the pressure control valve 3 by means of the proportional magnet 4 in its closed position is brought. However, if the pressure control valve 3 is stuck should remain, then the hydraulic cylinder Z would at most by switching off Motors M can be stopped gradually, but then not reliably, if other hydraulic consumers are also supplied from the pressure source Need to become. In this case, the proportional magnet is de-energized 4 also de-energized black / white magnet 15, the 2/2-way valve 14 from the pilot pressure brought quickly into its open position in the pilot line 6, 6a, see above that the pilot pressure is suddenly reduced to the tank and the pressure compensator 5 by the pressure prevailing in the lifting line 1 via the pilot line 7 into the is brought to the full open position, in which the pressure medium from the lifting strand 1 to the tank and the hydraulic cylinder Z is brought to a standstill. The Redundancy switching element A could be used with repeated energization and de-excitation to make the stuck pressure compensator 5 common again.

In Fig. 3 the electro-hydraulic stroke control device S is combined with additional controls SH, SH 'for other hydraulic consumers of the industrial truck with a common Supply from the pressure source P is present. The control SH serves, for example for actuating a further hydraulic consumer Z ', for example one Tilt cylinder or a gripper cylinder that has a lower supply pressure needs as the hydraulic cylinder Z. The supply of the other hydraulic consumers Z 'takes place via a pressure line 1', which is upstream of the pressure control valve from the lifting line 1 3 of the three-way current regulator R1 branches. In order to be load-independent in the SH control system to work, the load pressure becomes a pilot line 6b to the pilot line 6 and then brought to the closing pilot side 20 of the pressure compensator 5, namely via a shuttle valve 16, which the higher control pressure to the Closing pilot control side 20 of the pressure compensator 5 transmits. The pressure compensator 5 regulates the required pressure.

The redundancy switching element A is functionally alternating in this embodiment both the two-way current regulator R2 and the three-way current regulator R1 assigned, namely via a shuttle valve 17 (or, as shown in Figs. 4 and 5 via two separate pilot lines). From the pilot line 12 of the two-way current regulator R2 branches off a pilot line 12 'to the shuttle valve 17. The other On the side of the shuttle valve 17, a pilot line 6 'leads from the pilot line 6 of the three-way current regulator R1 branches. The higher the pilot pressure is transferred to the pilot line 18, in which the pressure relief valve, if applicable 13 and the redundancy switching element A are arranged.

The redundancy switching element A is a 2/2-way proportional pressure control valve in FIG. 3 14 ', which is due to the pilot pressure in the pilot line 18 in the opening direction its opening pilot side 21 is acted upon, and by a proportional magnet 15 'in the direction of the closed position shown.

The proportional magnet 15 'is energized simultaneously with the lifting control with the energization of the proportional magnet 4, however with the lowering control simultaneously with the energization of the proportional magnet 9. With the proportional magnet 15 'is not only the closed position of the redundancy switching element Set A, but can also be adjusted depending on a weaker one Power supply with sole or additional actuation of the hydraulic cylinder Z 'intermediate positions adjust the pilot pressure in the pilot line 18 for the Lower pressure compensator 5. So the redundancy switching element fulfills the function of a electrically adjustable pressure relief valve for setting the pilot pressure on the closing pilot side 20 of the pressure compensator 5, e.g. around for the other hydro consumer Z 'to set a lower supply pressure. It could be the redundancy switching element A with this design also for the intended reduction of the pilot pressure level can be used for lifting and / or lowering control.

Function:

In the lifting control, the shuttle valve 17 is in its left position, so that in the pilot line 18 the pilot pressure prevails from the pilot line 6. Should the pressure control valve 3 remains stuck although the proportional magnet 4 is de-energized, the proportional magnet 15 'is also de-energized, so that the redundancy switching element A Abruptly its opening position via the pilot pressure in the pilot line 18 takes and reduces the pilot pressure to the tank. The pressure compensator 5 goes abruptly into its open position, in which the pressure medium is discharged directly to the tank is and the hydraulic cylinder Z stops its extension movement, the Load pressure from a check valve downstream of the pressure control valve 3 and the Pressure control valve 8 is held. If necessary, the proportional magnet 15 ' then only de-energized after a program routine, in which it is determined that the Lift cylinder Z did not stop properly.

With the lowering control, the shuttle valve 17 assumes the position shown, so that the pressure of the pilot line 12 or 12 'prevails in the pilot line 18. Should the pressure control valve 8 get stuck, then, as explained at the beginning, in its opening position going redundancy switching element A the pressure compensator 10 in their Bring closed position and thus the load pressure of the hydraulic cylinder Z is maintained.

To a lower supply pressure when the hydraulic consumer Z 'is actuated is set by the higher-level electronic control CU, which is expedient contains a microprocessor or other logic circuit that Proportional magnet 15 'only so strongly energized that the pressure control valve 14' an intermediate position occupies and regulates part of the pressure medium from the pilot pressure line 18 drains to the tank to the pilot pressure on the closing pilot side 20 to reduce the pressure compensator 5, so that the pressure compensator 20 now controls relatively more pressure medium to the tank and the supply pressure in the pressure line 1 'decreased.

To ensure that when the redundancy switching element is set to the open position A after canceling the lowering control with the proportional pressure control valve stuck 8 no very slow lowering movement of the hydraulic cylinder Z takes place, a redundancy switching element A is provided in FIGS. 4 and 5, the with de-energized switching magnet 15 or proportional solenoid 15 'the pilot line 12 to lower branch 2 and the opening pilot side 19 of the pressure compensator 10 Relieved directly to the tank via a pilot line 12b.

In Fig. 4, the redundancy switching element A is a 4/2-way switching valve 14 "with a Switching magnet 15 as an actuator against a spring 26. The redundancy switching element A does not serve to set a lower supply pressure for other hydraulic consumers, but to protect the current regulator R1, R2 in the event of a Fault and, if necessary, for the arbitrary activation of the respective pressure compensator for other reasons, e.g. for individual braking or from others security reasons.

The 4/2-way switching valve 14 "is a slide valve with a valve slide 27, the is pressure balanced with respect to the tank pressure. The switching valve 14 "is between the two pilot lines 12 (from the lower leg 2) and 6a (from the closing pilot side 20) the pressure compensator 5 and, if necessary, the shuttle valve 16 and the tank T and the pilot line 12b to the opening pilot side 19 of the Pressure compensator 10 arranged. With deenergized switching magnet 15 (this can be a simple one Black / white switching magnet) there is the switching position shown, in which the Pilot lines 12, 12b separated from one another and pilot lines 6a and 12b jointly relieved to the tank T in a bypass 24 in the valve slide 27 are. When the switching magnet 15 is excited, a switching position is set in which the Pilot line 6a separated from tank T and pilot lines 12, 12b with each other are connected.

Should the proportional pressure control valve 8 hang when canceling the lowering control remain, then the opening pilot side 19 is in the switching position shown relieves the pressure compensator 10 to the tank, so that the pressure compensator 10 is in its closed position goes and holds the load. The hydraulic cylinder stops. The function at the lifting control is the same as explained with reference to FIG. 2.

A useful lowering line 2a is shown in dash-dotted lines between the proportional pressure control valve 8 and the pressure compensator 10 branches off from the lower strand 2 and to the Suction side of pump P is connected. Between the connection of the utility line 2a and the tank a check valve V is indicated, which in the direction of The tank locks the pressure medium pushed out by the pump when the utility is lowered P to promote and this as a motor for the electric motor then working as a generator to drive for energy recovery. The pressure medium then flows over the pressure compensator 20 to the tank, or if other hydraulic consumers are connected and be cared for, further. If a variable speed pump P is used, when lowering the pressure compensator 10 in the case of the connection of additional hydraulic consumers set the required quantity by pump P. The The option of lowering the usefulness can be easily achieved in every embodiment shown integrate.

5, the redundancy switching element A is a 4/3 proportional pressure control valve 14 "' with the proportional magnet 15 'as an actuator of the valve slide 27' against the Force of a spring 26 and the pilot pressure in a pilot line 6c by the Pilot line 6a branches. The further connection corresponds to that shown in FIG. 4 and already explained. The valve spool 27 'is related to the tank pressure via the pilot line 25 pressure-balanced, expediently over the entire surface, while the pilot pressure from the pilot line 6c expediently only a partial area of the surface of the valve slide 27 against the proportional magnet 15 ', a weak and compact or inexpensive proportional magnet 15 'to be able to use.

To reduce the pilot pressure on the closing pilot side 20 of the pressure compensator 5 when lifting controls or when controlling other hydraulic consumers in order to reduce their supply pressure, e.g. the proportional magnet 15 ' weaker in accordance with the desired pilot pressure in the pilot line 6a energized than in the protection of the respective current regulator to between To take end positions with a clear overlap, regulating intermediate switching positions, in which both the pilot lines 12, 12b are connected to one another and also the pilot line 6a is connected directly to the tank.

Claims (14)

Electrohydraulic lift control device (S) for industrial trucks, in particular forklift trucks, with a lifting strand (1) between a pressure source (P) and a hydraulic cylinder that contains a three-way flow regulator (R1) that can be operated electrically at least for lifting control, with a proportional magnet and a pressure compensator (5) (Z), and a lowering branch (2) branching off from the lifting strand (1) to the tank, which contains an electrically operable two-way current regulator (R2) with a proportional magnet and a pressure compensator (10) for lowering control, characterized in that between the Pilot pressure circuit of the two-way current regulator (R2) and / or the pilot pressure circuit of the three-way current regulator (R1) and the tank (T) an redundancy switching element (A) which is actively electrically operable between closed and open positions is provided. Electrohydraulic stroke control device according to claim 1, characterized in that the redundancy switching element (A) between the tank (T) and an opening pilot side (19) of the pressure compensator (10) of the two-way flow regulator (R2) and / or a closing pilot side (20 ) the pressure compensator (5) of the three-way flow controller (R1) is arranged. Electrohydraulic stroke control device according to claim 1, characterized in that the redundancy switching element (A) is a 2/2-way control valve (14 ') with pressure pilot control (21) in the opening direction and with a proportional magnet (15') as an actuator for the closing direction is. Electrohydraulic stroke control device according to claim 1, characterized in that the redundancy switching element (A) is a 2/2-way valve (14) with pressure pilot control (21) in the opening direction and with a black / white magnet (15) as an actuator for the closing direction , Electro-hydraulic stroke control device according to claim 3 or 4, characterized in that the pressure pilot control (21) of the redundancy switching element (A) with the opening pilot control side (19) of the pressure compensator (10) of the two-way flow regulator (R2) or the closing pilot control side (20) the pressure compensator (5) of the three-way flow controller (R1) is connected. Electrohydraulic stroke control device according to claim 5, characterized in that the pressure pilot control (21) of the redundancy switching element (A) via a shuttle valve (17) is pressure-dependent with the opening pilot control side (19) of the pressure compensator (10) of the two-way flow regulator (R2) or the closing pilot side (20) of the pressure compensator (5) of the three-way flow controller (R1) can be connected. Electrohydraulic stroke control device according to claim 2, characterized by, that the pressure compensator (5) of the three-way flow controller (R1) is in addition to the load-independent one Control of at least one other, from the same pressure source (P) supplied hydraulic consumer (Z ') is arranged, and that via the redundancy switching element (A) and the pressure compensator (5) of the three-way current regulator (R1) a lower one Supply pressure for the further hydraulic consumer (Z ') is adjustable as at least for lifting control of the hydraulic cylinder (Z). Electrohydraulic stroke control device according to claim 2, characterized in that the redundancy switching element (A) connects between separate pilot lines (12, 6a) to the lower leg (2) and to the closing pilot side (20) of the pressure compensator (5) of the three-way current regulator (R1) and 4/2-way switching valve (14 ") with a black / white magnet (15) inserted into the tank (T) and a pilot line (12b) to the opening pilot side (19) of the pressure compensator (10) of the two-way flow regulator (R2) as an actuator for a switching direction that separates the pilot line (6a) from the tank (T) in one switch position and connects the pilot lines (12, 12b), and separates the pilot lines (12, 12b) in another switch position and the pilot lines (6a , 12b) connects to the tank. Electro-hydraulic stroke control device according to claim 2 and 7, characterized in that the redundancy switching element between separate pilot lines (12, 6a) to the lower leg (2) and the closing pilot side (20) of the pressure compensator (5) of the three-way flow controller (R1) and the Tank (T) and a pilot line (12b) to the opening pilot side (19) of the pressure compensator (10) of the two-way flow regulator (R2) 4/3-way proportional pressure control valve (14 "') with a proportional magnet (15' ) as an actuator for a switching direction against the force of a spring (26) and the pilot pressure in the pilot line (6a), which in a limit switch position separates the pilot line (6a) from the tank (T) and connects the pilot lines (12, 12b), in a different limit switch position, the pilot lines (12, 12b) are separated and the pilot lines (6a, 12b) are connected to the tank (T), and by energizing the proportional magnet in accordance with the pilot pressure in the pilot line (6a) variable intermediate switch positions between the limit switch positions for pilot pressure setting, the pilot lines (12, 12b) with each other and the pilot line (6a) with the tank (T). Electro-hydraulic stroke control device according to claim 8 or 9, characterized in that the 4/2-way switching valve (14 ") or the 4/3-way proportional pressure control valve (14"') is a slide valve in a stack-tight design. Electro-hydraulic stroke control device according to claim 8, characterized in that the 4/2-way switching valve (14 ") contains a valve slide (27) which is pressure-balanced at both ends over a large area of the tank (T). Electrohydraulic stroke control device according to claim 9, characterized in that the 4/3-way proportional pressure control valve (14 "') contains a valve slide (27') which is pressure-balanced across the entire surface of the tank (T) and which is controlled by the pilot pressure in the pilot line (6a). is only partially applied against the proportional magnet (15 '). Electro-hydraulic stroke control device according to at least one of claims 1 to 12, characterized in that the pressure source (B) has a speed-controllable pump with an electric motor (M) which can be operated via the pump in the lowering control for energy recovery as a generator that between the pump and the tank (T) is provided with a check valve (V) which blocks the tank, and that a useful lowering line (2a) branching upstream of the pressure compensator (10) of the two-way flow regulator (R2) from the lower branch (2) downstream of the check valve (V) to the Pump is connected. Electro-hydraulic stroke control device according to at least one of the preceding claims, characterized in that the electrically actively actuable components (4, 9, 15, 15 ', M) of the stroke control device (S) are connected to an electronic control (CU) containing a microprocessor or a logic circuit ,

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