EP4180660A1 - System and method for operating a system - Google Patents

Abstract

The invention relates to a system (1) comprising: - a building and/or thick material movement system (2), wherein the building and/or thick material movement system (2) is designed for moving building and/or thick material (BDS), - an internal combustion engine drive system (3), wherein the internal combustion engine drive system (3) is designed to drive the construction and/or thick matter moving system (2) and has a mechanical speed controller (4), and- an actuator system (5), wherein the actuator system (5) is designed for mechanical movement of the speed controller (4).

Description

FIELD OF APPLICATION AND PRIOR ART

The invention relates to a system comprising a construction and/or thick material movement system and a method for operating such a system.

TASK AND SOLUTION

It is an object of the invention to provide a system having a building and/or thick material movement system and a method for operating such a system, each of which has improved properties.

The invention solves this problem by providing a system with the features of claim 1 and a method with the features of claim 15. Advantageous developments and/or refinements of the invention are described in the dependent claims.

The system of the present invention includes a building and/or sludge movement system, an internal combustion engine drive system, and an actuator system. The construction and/or thick material movement system is designed for, in particular direct, movement of construction material and/or thick material. The internal combustion engine drive system is designed to drive, in particular indirectly, the construction and/or thick material movement system. Furthermore, the internal combustion engine drive system has, in particular only or purely, mechanical speed control. The actuator system is designed for, in particular indirect, mechanical movement of the speed controller.

This, in particular the internal combustion engine drive system having the mechanical speed control, enables a robust and/or, in particular, reliable drive under the usually rough conditions of the movement of building material and/or thick material. Additionally or alternatively, this enables, in particular the actuator system, an, in particular indirect, electrical control of a speed, in particular a value of the speed, of the internal combustion engine drive system. Thus, this enables an optimal operation of the internal combustion engine drive system, in particular automated, efficient and/or, in particular, therefore, fuel-saving.

In particular, the term “comprises” and/or “has” can be used synonymously for the term “has”. Additionally or alternatively, the term “configured” can be used synonymously for the term “trained”. Furthermore, additionally or alternatively, the term "directly" can be used synonymously for the term "directly". Furthermore, additionally or alternatively, the term "indirect" can be used synonymously for the term "indirectly".

The building and/or thick matter moving system can have, in particular be, a building and/or thick matter conveying system, in particular a building and/or thick matter pump system. Additionally or alternatively, the movement can include, in particular be, a promotion.

The movement, propulsion and/or movement can be automatic.

The building material can be, in particular, mortar, cement, screed, concrete, plaster and/or structural bulk material such as sand, trickle and/or gravel. Additionally or alternatively, thick matter can include, in particular be, sludge.

The internal combustion engine drive system can, in particular, have only one, in particular single, internal combustion engine, in particular internal combustion drive engine and/or reciprocating piston engine, in particular with internal combustion. Additionally or alternatively, the speed can be a speed of the internal combustion engine. Further additionally or alternatively, the speed control can be an engine speed control. Furthermore, additionally or alternatively, the terms “control” and/or “adjustment” can be used synonymously for the term “control”. Furthermore, additionally or alternatively, the internal combustion engine drive system does not need or can have, in particular directly, an electric speed control.

The actuator system can be different from the mechanical speed control, in particular the internal combustion engine drive system. Additionally or alternatively, the actuator system can be controlled or monitored electrically, in particular electronically. Furthermore, additionally or alternatively, the term "adjustment" can be used synonymously for the term "movement".

The system can be mobile, in particular a car system or a car construction pump and/or thick matter pump. Additionally or alternatively, the system can be an excavator, a crane and/or a conveyor belt.

In a development of the invention, the internal combustion engine drive system has a diesel engine, an Otto engine and/or a gas engine. Electrical control of the speed is particularly advantageous for such a motor. In particular, the term "compression ignition engine" can be used synonymously for the term "diesel engine". Additionally or alternatively, the term "spark ignition engine" can be used synonymously for the term "gasoline engine".

In a development of the invention, the speed control is designed for mechanical control, in particular only or purely, of a fuel supply quantity, in particular a value of the fuel supply quantity, in particular a fuel injection quantity, in particular a value of the fuel injection quantity. Additionally or alternatively, the speed control has an injection pump that can be controlled or adjusted mechanically, in particular only or purely, in particular an in-line injection pump, and/or a throttle element or element that can be controlled or adjusted mechanically, in particular only or purely a throttle, on. This makes it possible to control or adjust an in particular output or generated torque and/or an in particular output or generated power of the internal combustion engine drive system, in particular of the internal combustion engine, and thus the rotational speed. In particular, the fuel supply quantity can be supplied, in particular the fuel injection quantity can be injected, into a combustion space or a combustion chamber of the internal combustion engine drive system, in particular the internal combustion engine. Additionally or alternatively, the fuel injection quantity can be injected into the diesel engine. In addition or as an alternative, the injection pump can be for the diesel engine. In addition or as an alternative, the throttle element can be for the Otto engine. Furthermore, additionally or alternatively, the rotational speed control does not need or can be designed for an, in particular direct, electrical control of a fuel supply quantity, in particular a fuel injection quantity. Furthermore, in addition or as an alternative, the speed controller does not need or can have an injection valve that can be controlled electrically, in particular directly. Additionally or alternatively, the term “volume flow” can be used synonymously for the term “quantity”. Otherwise, reference is made to the specialist literature.

In a development of the invention, the system has at least one movement transmission mechanism, in particular at least one lever mechanism, in particular a reversing lever, a linkage and/or a Bowden or cable pull. The actuator system is movement-connected or coupled by means of the movement transmission mechanism to the rotational speed controller, in particular directly. This allows freedom when arranging the actuator system. In particular, the term “mechanism” can be used synonymously for the term “mechanics”.

In one development of the invention, the actuator system has a linear actuator with a movement path of at least 1 cm (centimeter), in particular at least 2 cm, in particular at least 5 cm, in particular at least 10 cm, and/or a rotary actuator, in particular with a movement angle, in particular movement angle range , of at least 22.5° (degrees), in particular at least 45°, in particular at least 90°. This allows for sufficient and/or appropriate movement. In particular, the term “translational actuator” can be used synonymously for the term “linear actuator”. Additionally or alternatively, the term "adjustment stroke" can be used synonymously for the term "movement path". Furthermore, additionally or alternatively, the movement path can be a maximum of 100 cm, in particular a maximum of 50 cm, in particular a maximum of 20 cm. Furthermore, additionally or alternatively, the movement angle can be a maximum of 180°, in particular a maximum of 135°.

In particular, the actuator system does not or cannot have a piezo actuator.

In one development of the invention, the actuator system has an electric motor, in particular an electric cylinder, and/or a hydraulic and/or pneumatic actuator, in particular an electrohydraulic and/or pneumatic actuator. This allows for sufficient and/or appropriate movement. In particular, the term "electric lifting cylinder" can be used synonymously for the term "electric cylinder". Additionally or alternatively, the electrohydraulic and/or pneumatic actuator can have an electrically, in particular electronically, controllable or controllable hydraulic and/or pneumatic valve. Furthermore, additionally or alternatively, the linear actuator and/or the rotary actuator can have, in particular be, the electric motor, in particular the electric cylinder, and/or the hydraulic and/or pneumatic actuator, in particular the electrohydraulic and/or pneumatic actuator. Otherwise, reference is made to the specialist literature.

In a development of the invention, the system has a control device, in particular an engine control device. The control device is designed for, in particular direct, control of the actuator system, in particular for the mechanical movement of the speed controller. This allows the, in particular indirect, electrical control of the speed. In particular, the control device can be electrical, in particular electronic. Additionally or alternatively, the term component “device” can be used synonymously for the term component “facility”. Furthermore, additionally or alternatively, the control device can have a microprocessor, in particular a digital microprocessor and/or have, in particular, microcontrollers and/or memory. Further additionally or alternatively, the control can be automatic and/or electric.

In one embodiment of the invention, the system has a speed sensor, in particular an incremental encoder. The speed sensor is designed for, in particular directly, detecting a speed variable, in particular a value of the speed variable, of the internal combustion engine drive system. The control device is designed to control the actuator system as a function of the detected speed variable. This enables an, in particular indirect, electrical control of the speed. In particular, the speed sensor can be electrical. Additionally or alternatively, the term “incremental rotary encoder” can be used synonymously for the term “incremental encoder”. Further additionally or alternatively, the detection can be automatic. Furthermore, additionally or alternatively, the speed variable can be characteristic of the speed, in particular the speed. Furthermore, additionally or alternatively, the speed sensor does not need or can be designed for, in particular directly, picking up the speed variable on a crankshaft and/or a camshaft of the internal combustion engine drive system.

In one embodiment of the invention, the internal combustion engine drive system has an alternator. The speed sensor is designed, in particular and arranged, for, in particular directly, picking up the speed variable on the alternator. This allows freedom in the arrangement of the speed sensor.

In one embodiment of the invention, the control device for controlling the actuator system is in a speed control mode when there is a high deviation, in particular a high value of the deviation, between the detected speed variable or a variable based on this and a target speed variable, in particular a value of the target - Speed variable, and a precision control mode different from the speed control mode, in the case of a low deviation, in particular a low value of the deviation, between the detected speed variable or a variable, in particular the variable based on this, and a, in particular the, target speed variable, in particular a value of the setpoint speed variable. This enables an optimal minimization of the deviation by means of the actuator system. In particular, at one time the controller can control in either the speed control mode or the precision control mode. Additionally or alternatively, the term "precision control type" can be used synonymously for the term "accuracy control type". Furthermore, additionally or alternatively, the term “actual speed variable” can be used synonymously for the term “detected speed variable”. Furthermore, additionally or alternatively, the setpoint speed variable be dependent on and/or predetermined by a specification, in particular by a user or machine operator. Furthermore, additionally or alternatively, the precision control type and/or the speed control type can have a waiting or non-movement cycle of the actuator system.

In one embodiment of the invention, a movement cycle time duration, in particular a value of the movement cycle time duration, of the actuator system is shorter in the precision control mode than in the speed control mode. Additionally or alternatively, a waiting cycle time duration, in particular a value of the waiting cycle time duration, of the actuator system is longer in the precision control mode than in the speed control mode.

In a further development, in particular an embodiment, of the invention, the building and/or thick material movement system, in particular the building and/or thick material pump system, is for the variable movement, in particular conveying, of building material and/or thick material with a variably adjustable building and/or or amount of thick matter, in particular a variably adjustable value of the build and/or amount of thick matter. The internal combustion engine drive system is designed to variably adjust its speed, in particular the value of the speed, to variably drive the construction and/or thick material movement system, in particular for the variable movement of construction material and/or thick material with the variably adjustable quantity of construction material and/or thick material. In particular, the control device is designed for variable control of the actuator system for variable setting of the speed. This enables an, in particular indirect, electrical and variable adjustment or control of the build and/or thick matter quantity. In particular, the build and/or thick matter quantity can depend on the speed, in particular be proportional to the speed. Additionally or alternatively, the build and/or thick matter quantity can be dependent on and/or predetermined by a specification, in particular by the user. Furthermore, additionally or alternatively, the speed can be set to achieve the, in particular predetermined, build and/or thick matter quantity. Furthermore, additionally or alternatively, can mean variably adjustable to at least three different values or even infinitely adjustable. Furthermore, additionally or alternatively, the term "adjustable" can be used synonymously for the wording "variably adjustable".

In a development of the invention, the system has a hydraulic pump drive system. The hydraulic pump drive system is designed for, in particular variable and/or direct, delivery of hydraulic fluid for, in particular variable and/or direct, driving of the construction and/or thick material moving system, in particular for moving construction material and/or thick material. The internal combustion engine drive system is for, in particular variable and/or direct, rotation of at least part of the Hydraulic pump drive system for, in particular variable and/or direct, drive of the hydraulic pump drive system, in particular for pumping hydraulic fluid. In particular, the conveyance, the drive and/or the rotation can be automatic. In addition or as an alternative, the hydraulic fluid can contain oil, in particular it can be oil.

In one embodiment of the invention, the hydraulic pump drive system has an axial piston pump. The axial piston pump has a swashplate or sliding disk with a variably adjustable swivel angle, in particular a variably adjustable value of the swivel angle, for the variable, in particular direct, delivery of hydraulic fluid with a variably adjustable quantity of hydraulic fluid, in particular a variably adjustable value of the quantity of hydraulic fluid. The control device is designed for variable, in particular direct and/or electrical, control of the hydraulic pump drive system for setting the swivel angle in such a way that the swivel angle increases to increase the volume and/or thick matter quantity, in particular from a swivel angle minimum value, in particular zero, and/or up to a swivel angle maximum value and/or the speed, in particular the target speed value, does not increase, in particular is constant, and to further increase the build and/or thick matter quantity, the speed, in particular the target speed value, increases, in particular from a minimum speed value, in particular greater than zero, and/or up to a maximum speed value and/or the swivel angle does not increase, in particular is constant. This enables maximum efficiency of the system and thus optimal or efficient, in particular fuel-saving, operation of the system. In particular, the hydraulic pump drive system can be controlled or monitored electrically, in particular electronically. Additionally or alternatively, the delivery and/or the control may be automatic. Furthermore, additionally or alternatively, the swivel angle and the speed can be independent of one another, in particular adjustable. Furthermore, additionally or alternatively, the swivel angle can increase over a range of the amount of building material and/or thick matter of at least 10% (percent), in particular at least 20%, in particular at least 30%. Furthermore, additionally or alternatively, the speed can increase over a range of the build and/or thick matter quantity of at least 10%, in particular at least 20%, in particular at least 30%. Furthermore, additionally or alternatively, the minimum speed value can be an idle speed value. Furthermore, additionally or alternatively, the part can be the axial piston pump, in particular the swash plate.

• Bewegen, insbesondere automatisches Bewegen und/oder Fördern, von Bau- und/oder Dickstoff mittels des Bau- und/oder Dickstoffbewegungssystems,
• Antreiben, insbesondere automatisches Antreiben, des Bau- und/oder Dickstoffbewegungssystems mittels des Verbrennungsmotorantriebssystems, und
• mechanisches Bewegen, insbesondere automatisches Bewegen, der Drehzahlsteuerung mittels des Aktorsystems.

The method according to the invention, in particular automatic, for operating a system, in particular the system as described above, has:

• Moving, in particular automatically moving and/or conveying, building and/or thick material by means of the building and/or thick material moving system,
• Driving, in particular automatically driving, the building and/or thick matter moving system by means of the internal combustion engine drive system, and
• mechanical movement, in particular automatic movement, of the speed control by means of the actuator system.

In particular, the method can include: Controlling, in particular automatic controlling, of the actuator system by means of the control device.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1

einen schematischen Schaltplan eines erfindungsgemäßen Systems und eines erfindungsgemäßen Verfahrens zum Betreiben des Systems,

Fig. 2

schematisch ein Verbrennungsmotorantriebssystem, ein Aktorsystem, eine Bewegungsübertragungsmechanik, eine Steuerungseinrichtung und einen Drehzahlsensor des Systems der Fig. 1, und

Fig. 3

einen schematischen Graphen eines Schwenkwinkels einer Schrägscheibe einer Axialkolbenpumpe eines Hydraulikpumpenantriebssystems des Systems der Fig. 1 angetrieben mittels des Verbrennungsmotorantriebssystems und einer Drehzahl des Verbrennungsmotorantriebssystems über einer Hydraulikflüssigkeitsmenge von Hydraulikflüssigkeit gefördert mittels des Hydraulikpumpenantriebssystems für eine Bau- und/oder Dickstoffmenge von Bau- und/oder Dickstoff gefördert mittels eines Bau- und/oder Dickstoffbewegungssystems des Systems der Fig. 1 angetrieben mittels des Hydraulikpumpenantriebssystems gesteuert mittels der Steuerungseinrichtung.

Further advantages and aspects of the invention result from the claims and from the description of exemplary embodiments of the invention, which are explained below with reference to the figures. show:

1

a schematic circuit diagram of a system according to the invention and a method according to the invention for operating the system,

2

schematically an internal combustion engine drive system, an actuator system, a motion transmission mechanism, a controller and a speed sensor of the system of FIG 1 , and

3

FIG. 12 is a schematic graph of a pivot angle of a swash plate of an axial piston pump of a hydraulic pump drive system of the system of FIG 1 driven by means of the internal combustion engine drive system and a speed of the internal combustion engine drive system via a hydraulic fluid quantity of hydraulic fluid conveyed by means of the hydraulic pump drive system for a construction and/or thick matter quantity of construction and/or thick matter conveyed by means of a construction and/or thick matter movement system of the system of 1 driven by the hydraulic pump drive system controlled by the controller.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

1 shows a system 1 according to the invention and a method according to the invention for operating the system 1. The system 1 has a building and/or thick matter moving system 2, an internal combustion engine drive system 3 and an actuator system 5, as in 2 shown. The building and/or thick material movement system 2 is designed to move building material and/or thick material BDS, in particular moving it. The internal combustion engine drive system 3 is designed to drive the construction and/or thick material movement system 2, in particular drives it. Furthermore, the internal combustion engine drive system 3 has a mechanical speed controller 4 . The actuator system 5 is designed, in particular moved, for the mechanical movement of the speed controller 4 .

• Bewegen Bau- und/oder Dickstoff BDS mittels des Bau- und/oder Dickstoffbewegungssystems 2,
• Antreiben des Bau- und/oder Dickstoffbewegungssystems 2 mittels des Verbrennungsmotorantriebssystems 3, und
• mechanisches Bewegen der Drehzahlsteuerung 4 mittels des Aktorsystems 5.

The procedure shows:

• Move building and/or thick material BDS by means of the building and/or thick material moving system 2,
• driving the building and/or thick matter moving system 2 by means of the internal combustion engine drive system 3, and
• mechanical movement of the speed controller 4 by means of the actuator system 5.

In detail, the internal combustion engine drive system 3 has a diesel engine 6a, an Otto engine 6b and/or a gas engine 6c.

In addition, the speed controller 4 is designed for mechanical control of a fuel supply quantity KZM, in particular a fuel injection quantity KEM. Additionally or alternatively, the speed controller 4 has a mechanically controllable injection pump 7a, in particular an in-line injection pump 7a', and/or a mechanically controllable throttle element 7b, in particular a throttle valve 7b'.

Furthermore, the system 1 has at least one movement transmission mechanism 8, in particular at least one lever mechanism 8a, in particular a deflection lever 8a', a linkage 8b and/or a Bowden cable 8c. The actuator system 5 is movement-connected to the speed controller 4 by means of the movement transmission mechanism 8 .

In addition, the actuator system 5 has a linear actuator 9a with a movement path 9aL of at least 1 cm and/or a rotary actuator 9b, in particular with a movement angle 9bR of at least 22.5°.

Furthermore, the actuator system 5 has an electric motor 10a, in particular an electric cylinder 10a′, and/or a hydraulic and/or pneumatic actuator 10b, in particular an electrohydraulic and/or pneumatic actuator 10b′.

In addition, the system 1 has a control device 11 . The control device 11 is designed to control, in particular controls, the actuator system 5 .

In detail, the system 1 has a speed sensor 12, in particular an incremental encoder 12'. The speed sensor 12 is designed to detect, in particular, detect a speed variable nG of the internal combustion engine drive system 3 . The control device 11 is designed to control the actuator system 5 as a function of the detected rotational speed variable nG.

The internal combustion engine drive system 3 also has an alternator 13 . The speed sensor 12 is designed to pick up the speed variable nG on the alternator 13, in particular picks it up.

In addition, the control device 11 for controlling the actuator system 5 in a speed control mode SRA when there is a large deviation ΔnG between the detected speed variable nG or a variable based on this and a target speed variable nGS and a speed control mode SRA that differs from the precision control mode GRA formed at a low deviation ΔnG between the detected speed variable nG or the size based on this and the target speed variable nGS, in particular controls.

In the exemplary embodiment shown, the control device 11 is for control in the speed control mode SRA if the deviation ΔnG is greater than a deviation limit value ΔnGlimit, and in the accuracy control mode GRA if the deviation ΔnG is equal to or smaller than the deviation limit value ΔnGlimit is designed, in particular controlled.

In detail, a movement cycle duration BZZD of the actuator system 5 is shorter in the precision control type GRA than in the speed control type SRA. Additionally or alternatively, in the precision control mode GRA, a waiting cycle duration WZZD of the actuator system 5 is longer than in the speed control mode SRA.

Furthermore, the building and/or thick material movement system 2 is designed, in particular moved, for the variable movement of building material and/or thick material BDS with a variably adjustable building and/or thick material quantity BDSM. The internal combustion engine drive system 3 is designed for the variable setting of its speed n for the variable drive of the construction and/or thick matter moving system 2, in particular drives. In particular, the control device 11 is designed for the variable control of the actuator system 5 for the variable adjustment of the rotational speed n, in particular controls and thus adjusts.

The system 1 also has a hydraulic pump drive system 14 . The hydraulic pump drive system 14 is designed for the, in particular variable, delivery of hydraulic fluid HF for the, in particular variable, drive of the construction and/or viscous material movement system 2, in particular delivering and thus driving. The internal combustion engine drive system 3 is designed for, in particular variable, rotation of at least one part 15 of the hydraulic pump drive system 14 for the, in particular variable, drive of the hydraulic pump drive system 14, in particular rotates and thus drives.

In detail, the hydraulic pump drive system 14 has an axial piston pump 16 . The axial piston pump 16 has a swash plate 17 with a variably adjustable swivel angle SW for variably conveying hydraulic fluid HF with a variably adjustable hydraulic fluid quantity HFM. The control device 11 is designed for the variable control of the hydraulic pump drive system 14 for setting the swivel angle SW in such a way, in particular controls it, that to increase the building and/or thick matter quantity BDSM, in 3 from 0% to 60%, the swivel angle SW increases, in particular from a swivel angle minimum value SWmin, in 3 0% and/or up to a maximum swivel angle value SWmax, in 3 100%, and/or the speed n does not increase, and to further increase the amount of build and/or thick matter BDSM, in 3 from 60% to 100%, the speed n increases, in particular from a minimum speed value nmin, in 3 1400 1 /min (revolutions per minute), and/or up to a maximum speed value nmax, in 3 2300 1 /min, and/or the swivel angle SW does not increase.

In the exemplary embodiment shown, the system 1 has a user-actuable operating device 51 for specifying, in particular for selecting, the build and/or thick matter quantity BDSM and/or the rotational speed n. In particular, determined or determined and the control device 11 controls the speed n, in particular and the swivel angle SW, as a function of or based on the specified build and/or thick matter quantity BDSM, in particular automatically and/or without further, in particular manual, specification and/or control and/or adjustment by a user. In other words: The user only needs to specify the building and/or thick matter quantity BDSM, in particular and to do nothing else, in particular to control and/or adjust nothing manually.

This enables an optimal, in particular automatically efficient and/or, in particular therefore, fuel-saving operation of the internal combustion engine drive system and/or, in particular thus, a maximum efficiency of the system and thus an optimal or efficient, in particular fuel-saving, operation of the system.

In particular, the user can specify the build and/or thick matter quantity and the system moves in the optimized (overall) degree of efficiency. In other words: the user can specify or activate an energy saving function.

Additionally or alternatively, the system 1 has a radio remote control. The radio remote control has the operating device 51 . Additionally or alternatively, the operating device 51 has a pushbutton and/or rotary knob, in particular the pushbutton and/or rotary knob.

Furthermore, the control device 11 has a signal connection, in particular an electrical one, with the actuator system 5, the rotational speed sensor 12, the hydraulic pump drive system 14 and/or the operating device 51, in particular in each case, as shown in FIG 1 and 2 shown by dotted lines.

In addition, the construction and/or thick matter movement system 2 has at least one, in the exemplary embodiment shown two, delivery cylinders 62a, 62b and at least one, in the exemplary embodiment shown two, delivery pistons 63a, 63b. The delivery cylinder 62a, 62b is designed for, in particular direct, receiving and for, in particular direct, releasing building material and/or thick material BDS, in particular receiving and releasing. The delivery piston 63a, 63b is in the, in particular assigned, delivery cylinder 62a, 62b for the, in particular direct, suction of building material and/or thick matter BDS into the delivery cylinder 62a, 62b and for the, in particular direct, displacement of sucked building and/or or thick material BDS out of the conveying cylinder 62a, 6 2b, in particular for conveying building material and/or thick material BDS, movable, in particular longitudinally movable, designed, in particular and arranged, in particular moves and sucks in and displaces.

Furthermore, the hydraulic pump drive system 14 has at least one, in the exemplary embodiment shown two, drive cylinders 73a, 73b and at least one, in the exemplary embodiment shown two, drive pistons 78a, 78b, in particular and at least one piston rod, in the exemplary embodiment shown two piston rods 79a, 79b , on. The drive cylinder 73a, 73b is designed to, in particular directly, receive hydraulic fluid HF, in particular receives. The drive piston 78a, 78b is designed to be movable, in particular longitudinally movable, in the, in particular, assigned, drive cylinder 73a, 73b, in particular for driving the building and/or thick matter moving system 2 or for moving the, in particular, assigned, delivery piston 63a, 63b and arranged, in particular moves. In particular, the piston rod 79a, 79b is attached to the, in particular, assigned, drive piston 78a, 78b, in particular, and the, in particular, assigned, delivery piston 63a, 63b for, in particular, direct, movement coupling with or movement transmission to the delivery piston 63a, 63b.

In addition, the axial piston pump 16 for conveying hydraulic fluid HF is designed, in particular conveys, for the, in particular direct, movement of the drive piston 78a, 78b and/or, in particular, for the in particular indirect movement of the feed piston 63a, 63b.

In particular, in the exemplary embodiment shown, the hydraulic pump drive system 14 has a swing line 74, in particular for hydraulic fluid HF.

The axial piston pump 16 and the two drive cylinders 73a, 73b form a, in particular closed, drive circuit for hydraulic fluid HF by means of the swing line 74.

Additionally or alternatively, the two drive pistons 78a, 78b, in particular and thus the two piston rods 79a, 79b and thus the two delivery pistons 63a, 63b, are coupled at least temporarily, in particular permanently over time, by means of the swing line 74, in particular in phase opposition, in particular 180° in phase opposition, or to the opposite movement.

The system 1 also has an adjustable line switch system 80 .

In addition, the system 1 has a delivery line 90 and a construction and/or thick matter feed 95 .

The line switch system 80 is designed to connect the delivery cylinder 62a, 62b, in particular either to the delivery line 90 in one position or to the construction and/or thick material supply 95 in another position for conveying construction material and/or thick material BDS, in particular connecting .

In 1 the line switch system 80 connects the delivery cylinder 62a to the delivery line 90 and the delivery cylinder 62b to the construction and/or thick matter feed 95.

Furthermore, the delivery piston 63b sucks building material and/or thick material BDS, in particular out of the, in particular connected, building material and/or thick material supply 95 into the delivery cylinder 62b. In particular at the same time, the delivery piston 63a displaces building material and/or thick matter BDS that has been sucked in out of the delivery cylinder 62a, in particular into the delivery line 90, which is connected in particular.

As the exemplary embodiments shown and explained above make clear, the invention provides an advantageous system comprising a building and/or thick matter moving system and an advantageous method for operating such a system, each having improved properties.

Claims (15)

System (1) comprising: - a building and/or thick matter movement system (2), wherein the building and/or thick matter moving system (2) is designed for moving building and/or thick matter (BDS), - an internal combustion engine drive system (3), wherein the internal combustion engine drive system (3) is designed to drive the building and/or thick matter moving system (2) and has a mechanical speed controller (4), and - An actuator system (5), wherein the actuator system (5) for mechanical movement of the speed controller (4) is designed. System (1) according to the preceding claim, - Wherein the internal combustion engine drive system (3) has a diesel engine (6a), an Otto engine (6b) and/or a gas engine (6c). System (1) according to one of the preceding claims, - wherein the speed controller (4) is designed for a mechanical control of a fuel supply quantity (KZM), in particular a fuel injection quantity (KEM), and/or - wherein the speed controller (4) has a mechanically controllable injection pump (7a), in particular an in-line injection pump (7a'), and/or a mechanically controllable throttle element (7b), in particular a throttle valve (7b'). System (1) according to any one of the preceding claims comprising: - at least one movement transmission mechanism (8), in particular at least one lever mechanism (8a), in particular a deflection lever (8a'), a linkage (8b) and/or a Bowden cable (8c), the actuator system (5) being activated by means of the movement transmission mechanism (8) is movement-connected to the speed controller (4). System (1) according to one of the preceding claims, - wherein the actuator system (5) has a linear actuator (9a) with a movement path (9aL) of at least 1 cm and/or a rotary actuator (9b), in particular with a movement angle (9bR) of at least 22.5°. System (1) according to one of the preceding claims, - wherein the actuator system (5) has an electric motor (10a), in particular an electric cylinder (10a'), and/or a hydraulic and/or pneumatic actuator (10b), in particular an electrohydraulic and/or pneumatic actuator (10b') , having. System (1) according to any one of the preceding claims comprising: - A control device (11), wherein the control device (11) is designed to control the actuator system (5). System (1) according to the preceding claim comprising: - a speed sensor (12), in particular an incremental encoder (12'), the speed sensor (12) being designed to detect a speed variable (nG) of the internal combustion engine drive system (3), and - Wherein the control device (11) for controlling the actuator system (5) depending on the detected speed variable (nG) is formed. System (1) according to the preceding claim, - Wherein the internal combustion engine drive system (3) has an alternator (13), wherein the speed sensor (12) is designed to pick up the speed variable (nG) on the alternator (13). System (1) according to one of the two preceding claims, - Wherein the control device (11) for controlling the actuator system (5) in a speed control mode (SRA) in the event of a high deviation (ΔnG) between the detected speed variable (nG) or a variable based on this and a target speed variable (nGS) and an accuracy control type (GRA) different from the speed control type (SRA) when there is a low deviation (ΔnG) between the detected speed variable (nG) or a variable based on this and a target speed variable (nGS). System (1) according to the preceding claim, - wherein in the precision control mode (GRA) a movement cycle duration (BZZD) of the actuator system (5) is shorter than in the speed control mode (SRA), and/or - Wherein the precision control mode (GRA) a waiting cycle time (WZZD) of the actuator system (5) is longer than in the speed control mode (SRA). System (1) according to one of the, in particular five, preceding claims, - wherein the construction and/or thick material movement system (2) is designed for the variable movement of construction material and/or thick material (BDS) with a variably adjustable construction and/or thick material quantity (BDSM), and - wherein the internal combustion engine drive system (3) is designed to variably adjust its speed (n) for variably driving the building and/or thick matter moving system (2), - In particular and wherein the control device (11) for variable control of the actuator system (5) for variable adjustment of the speed (n) is designed. System (1) according to any one of the preceding claims comprising: - a hydraulic pump drive system (14), wherein the hydraulic pump drive system (14) is designed for, in particular variably, conveying hydraulic fluid (HF) for, in particular variably, driving the construction and/or thick matter moving system (2), and - The internal combustion engine drive system (3) being designed for, in particular variable, rotation of at least part (15) of the hydraulic pump drive system (14) for, in particular variable, driving of the hydraulic pump drive system (14). System (1) according to the two preceding claims, - wherein the hydraulic pump drive system (14) has an axial piston pump (16), wherein the axial piston pump (16) has a swash plate (17) with a variably adjustable swivel angle (SW) for variably conveying hydraulic fluid (HF) with a variably adjustable hydraulic fluid quantity (HFM). , and - wherein the control device (11) for the variable control of the hydraulic pump drive system (14) for setting the swivel angle (SW) is designed in such a way that the swivel angle (SW) increases to increase the volume of construction and/or thick matter (BDSM), in particular up to one Swivel angle maximum value (SWmax) and/or the speed (n) does not increase, and to further increase the construction and/or thick matter quantity (BDSM), the speed (n) increases, in particular up to a maximum speed value (nmax) and/or the Swivel angle (SW) does not increase. Method for operating a system (1) according to one of the preceding claims, comprising: - moving building and/or thick matter (BDS) by means of the building and/or thick matter moving system (2), - driving the building and/or thick matter moving system (2) by means of the internal combustion engine drive system (3), and - Mechanical movement of the speed control (4) by means of the actuator system (5).

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