DE1205837B - Device for speed control of prime movers working on a common shaft - Google Patents

Description

The invention relates to a device for controlling the speed of at least two heat or internal combustion engines working on a common output shaft, in which an actual speed sensor, a control actuator and an indicator as well as a target speed sensor and for the overall system are provided for each machine further target speed transmitter and a switching device are provided, depending on the setting of the switching device either any selectable machine is operated as the main machine, while the other machines work as secondary machines or each machine can be controlled separately.

For speed control of heat or internal combustion engines, e.g. B. diesel engines, it is common to set the desired speed on a setpoint generator to set and to couple a tachometer and transducer to the machine, in order to carry out a target / actual value comparison. The difference becomes one Derived controlled variable that controls the fuel supply in the event of deviations from the target speed accordingly reduced or enlarged. The preferred regulators here are so-called centrifugal regulator in question, in which the setpoint is determined by appropriate dimensioning the spring preload is introduced. These regulators are characterized by a large Operational safety, which is why their use in many cases for safety reasons is prescribed to ensure a so-called "runaway" of the machine in any case to prevent. In addition, electrohydraulic control elements are also used which z. B. the control of the fuel supply by an inertial centrifugal regulator or an electromagnet is affected.

With different drives, e.g. B. in marine vessels with only one Propeller, it is necessary to have several machines running at the same speed to let work a common output shaft. The usual centrifugal governors are used for this not suitable because they cannot be produced as precisely with a reasonable amount of effort or can be arranged so that one revolution of the spindle to generate the bias affects the speed to the same extent for each controller.

It is already one with special characteristics in terms of its characteristics adjustable regulators working arrangement known in the case of a main machine off the controllers of the other machines can be changed one after the other so that with one certain speed, all machines are loaded equally. By a switching device the machine to be used as the main machine can be selected. Of that of the main machine but initially only the controller of the next machine is set and only then is the controller of the following machine changed by this, etc., it takes a certain amount of time for all the machines in the system to run at a certain speed are equally heavily loaded. In systems, e.g. B. ship propulsion, where the speed must be changed frequently and strong load fluctuations occur, is then one even load is no longer guaranteed. This arrangement is for ship propulsion systems also not suitable because the individual machines are not separate for themselves are adjustable.

For the synchronization of ship propulsion facilities are known, in which each machine can also be individually controlled by the the measured values supplied to the setpoint generators of the individual machines with those of the associated Actual value transmitter compared and the resulting difference values as a control variable are fed to the corresponding actuators. With these arrangements can achieve a synchronous running of the machine shafts, however, the load is of the individual machines are not the same over the entire speed range. A steady one However, load is a prerequisite for a perfectly functioning control system.

Finally there is an isodrome control for prime movers from several electrical generators connected in parallel known in which the with an isodrome device provided control of a drive machine via a Remote control of the speed adjustment devices not with an isodrome device the controller of the other machines at the same time. A synchronous one Adjustment of the filling can be done here with strong Load fluctuations likewise cannot be achieved, so that here too the load is not evenly distributed all machines is distributed.

The invention is based on the object of an arrangement with several machines of the same speed working on a common output shaft, each of which can optionally operate as a main machine to be trained so that a fast and synchronous control of all machines is possible and besides that all machines can be controlled independently of one another.

According to the invention, this is achieved in that with separate The controllability of each machine in a manner known per se, the output variables the setpoint and actual speed sensor of each machine via the switching device are switched against each other and the resulting difference value is used as a manipulated variable is on the respective control actuator, while in operation any selected one Machine as the main machine in a manner also known per se that of that of the Additional target speed encoder assigned to the entire system via the output variable supplied the switching device of the output variable of the actual speed sensor of the selected Main machine is connected in the opposite direction and the resulting difference value is fed to the control actuator of the main engine. This is for the purpose of being more synchronous Control of all secondary machines the output of the indicator of the main machine via the switching device, with the one working as a slave controller in this case Control actuators of the auxiliary machines connected, with the output variables of the indicators of these machines for the purpose of closing the control loops of the output variable of the indicator the main machine are switched against via the changeover switch.

The invention is particularly suitable for ship propulsion systems in which two or more diesel engines work on a ship's shaft via magnetic clutches and in which only one operating lever should be provided for regulation in the normal case. In normal operation, one motor works as the main and the other motors as Secondary machine. If the main machine fails, each of the secondary machines can through Switching work as the main motor. The invention is particularly useful for Systems with controllable pitch propellers and single-lever operation, otherwise a large number of controls would have to be provided.

Another possible application is for those connected in parallel Diesel generator gate with synchronous generator, because here too, in addition to exact compliance the speed, especially in the rated load area, an equal load distribution is required is.

In the case of ship propulsion systems, the separate controllability of the machines for maneuvering, i.e. H. to quickly reverse the direction of rotation of the ship's shaft.

In ships with fixed propellers, some of the motors run in one direction and some of the motors in the other direction. So there are two separately controllable motors or motor groups used. The ship's shaft itself is reversed by switching the magnetic couplings on and off alternately. The same is the case with ships with controllable pitch propeller systems if damage has occurred to the adjusting device, since work is then carried out in the same way as with fixed propeller drives. In the figure, an embodiment of the invention is shown. For the sake of clarity, only two diesel engines 1 and 2 are provided, o, but it is of course easily possible to develop a system that works with several machines according to the same principle. The diesel engines can also be replaced by other thermal or internal combustion engines. In the case of systems working with two motors, these will generally have the same nominal power, but machines of different power can of course also be used if necessary.

The filling regulating rods 3 are coupled via toggle levers 4 each with a Ferrari motor 5, 6 acting as a regulating actuator, which simultaneously adjust an indicator in the form of a rotary transformer 7 and 8 , which in turn act on display elements 9, 10 in the usual way. The additional centrifugal regulators 11, 12 provided for safety reasons are set so that they only come into operation when a certain speed is exceeded. A tachometer machine 13, 14 is coupled to each motor shaft as an actual value transmitter. The motors operate over aetrennt operated clutches 15, 16, 17 on the ship's drive shaft The intended to control the entire system, operating according to the rotary transformer principle setpoint generator 18 serves to control the respective current as the main machine motor, while the command unit, likewise designed as a rotary transformer 19, 20 serve to control the two machines separately.

The connection of the individual control and display elements takes place via a two-pole changeover switch 21 with three switch positions. The two switching arms 22, 23 coupled to one another connect two contacts to one another in each switching position. In the first switch position the contacts a and b as well as g and h, in the second position the contacts c and d and 1 and k and in the third switch position the contacts e and f and 1 and m are connected to one another. A connecting line leads from the switching arms 22, 23 via two measurement amplifiers 24, 25 to the Ferrari motors 5 and 6, respectively.

In the illustrated position of the switching arms 22, 23 , the two machines 1 and 2 can be controlled separately, namely the motor 1 by the transmitter 19 and the motor 2 by the transmitter 20. The setpoint generator 18 serving for common control is with the contacts that are now free b and 1 of the switch 21 connected and thus not effective. The speed setpoint set at the encoder 19 is switched against the actual value supplied by the tachometer machine 13 via the contact d, the connecting element of the switching arm 22 and the contact c. The voltage difference occurring in the event of a deviation of the actual speed from the setpoint value controls the Ferrari motor 5 as a control voltage via the amplifier 24 until the setpoint speed is reached.

The same is the case in analogy with machine 2. The output variable of the tachometer machine 14 is compared at the input of the amplifier 25 with the setpoint value set on the transmitter 20 and the difference is fed to the Ferrari motor 6 as a control variable.

As already stated, the switch 21 is set to this middle position when maneuvering, and the machines can rotate in any direction. The actuation devices for the magnetic clutches 15, 16, which, if necessary, can of course also be replaced by clutches that can be adjusted mechanically or hydraulically, are not shown.

If the switching arms 22, 23 are adjusted downwards in the illustration shown and thus the contacts e and f as well as 1 and m are connected to one another, the motor 2 works as the main machine and the motor 1 as the secondary machine. By means of the switching arm 23 , the output voltages of the setpoint generator 18 and the tachometer machine 14 acting as an actual value generator are switched against one another. As long as there is a deviation of the actual speed from the setpoint, the amplifier 25 supplies a control variable corresponding to the voltage difference, which is fed to the Ferrari motor 6 , which works as a charge regulator and controls the charge regulator linkage 3 via a reduction gear (not shown) and the toggle lever 4. At the same time the rotary transformer 8 is adjusted, the output voltage of which immediately readjusts the Ferrari motor 5 acting as a slave controller via the contact f, the switching arm 22 and the amplifier 24, so that there is always a synchronous filling adjustment on the auxiliary machines. For this purpose, the output value of the rotary transformer 7 as a result of the connection of the contacts e and f is compared with that of the rotary transformer 8 .

If, on the other hand, contacts a and b as well as g and h are connected to one another, motor 1 works as the main machine and motor 2 as a secondary machine. The control circuit for the main machine then comprises the tachometer machine 13, the Ferrari motor 5, the setpoint generator 18 and the amplifier 24. The slave control circuit consists of the Ferrari motor 6, the rotary transformers 7 and 8 and the amplifier 25.

The invention is not limited to electrical control circuits, it can also work mechanically or hydraulically with the appropriate training Attachments are applied.

Claims (2)

1. A device for speed control of at least two to a common output shaft working Wärine- or internal combustion engines, in which for each machine a Istdrehzahlgeber, a control actuator in addition to an indicator and a target rotational speed sensor and provided for the entire system, a further target rotational speed transmitter as well as a switching device, said each after setting the switching device either any selectable machine is operated as the main machine while the other machines work as secondary machines or each machine can be controlled separately, characterized in that with separate controllability of each machine (1, 2) in itself As is known, the output variables of the setpoint (19, 20) and actual value speed transmitter (13, 14) of each machine are switched against each other via the switching device (21) and the resulting difference value is as a manipulated variable on the respective control actuator (5, 6) , while when operating an arbitrarily selected machine as the main machine in a manner which is also known per se, the output variable supplied by the further setpoint speed sensor (18) assigned to the overall system via the switching device (21) of the output variable of the actual speed sensor (13 or 14) of the selected main machine (1 or 14) . 2) and the resulting difference value is fed to the control actuator (5 or 6) of the main machine (1 or 2), and that the output of the indicator (7 or 8) of the main machine for the purpose of synchronous control of all the auxiliary machines (1 or 2) is connected via the switching device (21) to the control actuators (6 or 5) of the auxiliary machines (2 or 1) , which in this case work as slave controllers, the output variables of the indicators (8 and 7) of these Machines for closing the control loops of the output variable of the indicator (7 or 8) of the main machine (1 or 2) are connected in the opposite direction via the changeover switch (21). 2. Device for speed control according to claim 1, characterized by its use in a ship propulsion system known per se which operates with diesel engines. 3. Device for speed control according to claim 1 and 2, characterized by the use of per se known Ferrari motors as control actuators (5, 6). 4. Device for speed control according to claim 1 to 3, characterized by the use of rotary transformers known per se as indicators and target speed sensors (7, 8, 18,19,20). 5. Device for speed control according to claim 1 to 4, characterized by the use of known tachometer machines as actual speed sensors (13, 14). 6. Device for speed control according to claim 1 to 5, characterized by additionally provided centrifugal governor (11, 12) which are known per se and which are adjusted so that they only come into operation when a certain speed is exceeded. Contemplated booklet German Patent No. 1,054,276, the 551,099th; Article by Dr. W. B enz, "The synchronization of ship machines", Shipbuilding Society, 40th Ord. Hauptvers. v. November 23, 1939.