DE660567C - Electric screw drive for multi-screw ships controlled by Leonard circuit - Google Patents

Description

The invention relates to an electric screw drive controlled by a Leonard circuit for multi-screw vessels, in which the number of generator units by the number the screw motors is not divisible.

There is an AC screw drive known, in which the number of existing Generators cannot be divided by the number of screw motors. This arrangement however, has the disadvantage that during maneuvering one of the other independent Regulation of screw motors is difficult and only possible at great cost.

Furthermore, a direct current drive is separate from each other with two at each load condition of the system separate generator circuits known in which the number of generators divisible by the number of screw motors is. A double motor is provided on each screw shaft, one of which is an armature each motor is in one circuit and the other motor armature in the other circuit. This well-known drive It also enables the state of equilibrium to be maintained in the event of a generator failure the screw torques, however, is an independent control of the screw motors not possible due to independent regulation of the generator voltages.

In addition, it is known per se for vehicle drives, and more for greater loads Connect generators in series with machines that are already in operation.

According to the invention, there is only the same number of generators as the number of screw motors or Generatorgruppe.n of the existing units each assigned a control regulator, the during maneuvering the speed control and reversal of each by a generator or a generator group fed motor independently of the other motors, and it will be at full speed the motors connected in series from the remaining generators, to which no control regulator is assigned is in series with the first generators or generator groups connected in series fed.

The invention enables one from one another in a simple manner during maneuvering independent control of the screw motors and use of all generator units during full travel of the system for feeding the screw motors, the during maneuvering Generators not connected to the screw motors, which do not have a control regulator is assigned, in series with the voltage controlled generator units and the Screw motors can be switched.

Further, the invention allows the mapping of a ¹ the same number of voltage-controlled generators to each of the coil motors M during the proceedings when the energization of a

Generators below a certain value si | or the generator itself or its prime mover fails. The invention also has the advantage that the number of ίο the generators to be switched on do not need to match the number of screws. It So there will be greater freedom of movement in the number of people required depending on the performance needs Achieved additional generators and significantly limited the number of control regulators.

The invention is illustrated in the drawing, for example.

The three expediently from one engine each, ζ. Β. from a steam engine or diesel engine, driven generators are labeled 1, 2 and 3. These Generators can be operated with screw motors 4 and 5 via switches 6, 7 and 8 and Switching relays 9, 10 and 11 are connected. By flipping the switch 6 from the illustrated position to the left, the Generator 1 can be connected to the screw motor 4 via the switch 7. Of the related circuit consists of lines 12, 13, 14, 15, 16, 17 and 18. In in the same way the generator 3 can be switched to the screw motor 5 by turning the Switch 8 can be switched to the left via lines 19, 20, 21, 22, 23, 24 and 25. If for any reason the generator ι or its prime mover fails, so can the generator 2 with the motor 4 by flipping the switch 6 to the right over the Lines 26, 27, 13, 14, 15, 16, 17, 28 and 29 can be connected. If the generator 3 or its prime mover fails, so can by moving the switch 8 to the right, the generator 2 with the screw motor 5 can be connected via lines 26, 30, 20, 21, 22, 23, 24, 31 and 29.

Provided that the switches 6 and 8 are in their left switch positions, can through Turning the switch 7 to the left, the generator 2 in a suitable polarity imperfect series connection with generators 1 and 3 and the screw motors 4 and 5 are switched on. By closing the contacts of relay 9 the series connection can be fully established. It then consists of the following connections:

Generatori, line 12, switch 6, line 13, screw motor 4, line 14, contacts 32 and 33 of the switching relay 9, line 23, screw motor 5, line 24, switch 8, line 25, generator 3, line 19, switch 8, line 20, switch 7, line

■ 39, generator 2, line 26, switch 7, power 17, switch 6 and line 18. ·; * -. Due to the remaining provisions

■ lais 10 and 11 can establish the connection between " see the generator 1 and the motor 4 or the generator 3 and the motor S, too can be produced independently of the switch 7. The connections between the generator ι and the motor 4 or the generator 3 and the motor 5 are as described above, with the exception that the circuit in question takes place through the switch 7 is closed by the switching relays 10 and 11, respectively. The generator 2 can can be connected to the auxiliary network 34, 35 by moving the switch 7- to the right.

Each of the generators 1 and 3 is provided with a control regulator, which is an independent Regulation of the voltage of the relevant generator according to size and direction allowed. The field winding 36 of the generator ι is on the lines 37 and 38, the switch 39, the lines 40 and 41, the control regulator 42 and the lines 43 and 44 connected to the network 45,46. By turning the control drum of the control regulator 42 to the left, the generator 9 "is tensioned in the direction" ahead "and through Turning the control drum of the control regulator 42 to the right in the "back" direction is increased. The field winding 47 of the generator 3 is via the lines 48 and 49, the switch 50, the lines 51 and 52, the control regulator 53 and the lines 54 and 55 with the network 45, 46 connected. Otherwise, the mode of operation of the control regulator 53 is shown in FIG with respect to the generator 3 the same as the operation of the control regulator 42 with respect to on generator 1.

The field winding 56 of the generator 2 is connected to the switch 57, the lines 58 and 59, the three lower contacts of the automatic Switch 60 and lines 61 and 62 on the network 45,46. The automatic one Switch 60 only serves to reduce the excitation of generator 2 from zero to its operating value bring to. The speed of increase no the excitation is achieved by setting an air brake or a suitable time delay device 63 determined.

If the generator 1 or 3 fails, the field winding 56 of the generator 2 can be connected to the control regulator 42 or 53 via the switches 39, 57 and 50. If the generator 1 fails, the Field winding 56 by flipping switch 39 to the right and switch 57 to iao connected to the control regulator 42 on the left. The relevant circuit continues

then together as follows: field winding 56, switch 57, lines 64 and 65 and switch 39.

Between the switches 39 and 50 there is a lock 66 so that, if the Switch 39 is in the right position, switch 50 is not in the left position brought, d. H. the control regulator 53 cannot be connected to the field winding 56 can. In the same way, when the control regulator 53 is connected to the field winding 56 of the Generator is connected via switches 57 and 50, as a result of the latch 66 of the Control regulator 42 cannot be connected to field winding 56.

The mode of operation of the arrangement according to the invention will now be explained in more detail below.

When maneuvering begins, the screw motor 4 is switched to the generator 1 and the screw motor 5 to the generator 3 by turning the switches 6 and 8 to the left. By changing the voltage of the generator 1 with the help of the control regulator 42 and of the generator 3 with the help of the control regulator 53 according to size and direction, the speed and the direction of rotation of the screw motors 4 and 5 can be determined clearly and independently of one another. Since a high torque at low speed is mainly required during maneuvering in restricted fairways, the power of a single prime mover is sufficient for each screw motor. In this case, the switch 7 can be in the position shown or it can be turned to the right to connect the generator 2 to the auxiliary network 34, 35. Furthermore, at this speed, the coils of the switching relays 9, 10 and 11 are de-energized and the switches of these relays are in the illustrated position. In the circuit between the generators and the screw motors, there are therefore no control elements at this speed that would make the system complex and unreliable. If the ship has reached clear waters, so full speed is possible and additional power is required, the generator 2 is switched on in the imperfect series circuit described above by turning the switch 7 to the left. This switching operation can expediently take place in the machine room. The circuit of the series connection is closed by the switching relay 9 when the control regulator 42 assigned to the generator 1 and the control regulator 53 assigned to the generator 3 are in the "full ahead" position (S toi

fio ment c) are, because in this case the coil of the switching relay 9 is energized and thus the switch of this relay is closed. The circuit of the excitation coil of the switching relay 9 is then composed as follows:

Mains line 45, lines 43 and 67, contact 68, segment 69 and contact 70 of control regulator 42, line 71, contact J2, segment 73 and contact 74, line 75, coil 76, line 7 /, contacts 78, switch blade 79, line 80 , Power line 46 .. Simultaneously with the excitation of the coil 76 of the switching relay 9, the coil 81 of the switching relay 60 connected in parallel to the excitation circuit of the coil y6 is excited and the field winding 56 of the generator 2 is thus connected to the network 45, 46. In this way, the control regulators 42 and 43 are connected in the "fully ahead" position and the generators 1, 2 and 3 are connected in series with the screw motors 4 and 5 in the left position of the switch 7.

In this exemplary embodiment, the generator 2 is excited by means of the time delay device 63 step by step '. However, it could of course also be the excitation of the generator 2 in a single stage take place.

If the control regulator 42 or 53 is moved from the "full ahead" position (position c) , the excitation circuits 9 ″ of the coils of the switching relays 9 and 60 are interrupted at the same time de-energized to zero. At the same time, the excitation circuit of switching relays 10 and 11 is closed.

Power line 45, line 43, contact 82, segment 83 or 84 and contact 85 of the Control regulator 42 (or power line 45, line 54, contact 86, segment 87 or 88 and Contact 89 of the control regulator 53), lines 90 and 91, contacts 92, line 93, excitation coils 94 and 95, line 80 and power line 46. By closing the switches, the switching relays 10 and 11 become independent from the switch 7, the circuits between the generator 1 and the screw motor 4 or the generator 3 and the screw motor 5 are closed. That way will So even when the generator 2 through the switch 7 with the other generators and the screw motors is connected in series, always when removing one of the Control regulator 42 or 53 established the Maiiövrierschaltung from the position "full ahead", d. H. the screw motors are connected to the voltage-regulated generators in such a way that they are independent of each other can be controlled, and the non-voltage regulated generators are turned off the supply circuit for the screw

motors switched off. As soon as the control regulators 42 and S3 are back in position Are "fully ahead", the coils of the switching relays 9 and 60 are energized again and thus all generators in turn connected in series with the screw motors.

In the embodiment described above there are three generators and two screw motors. Of course, there could also be five generators and two screw motors may be provided. It is essential that the number of generators is not divisible by the number of screw motors.

Claims (2)

P-ATENTAN LANGUAGES: i. Electric screw drive for multi-screw ships controlled by Leonard circuit, in which the number of generator units is not divisible by the number of screw motors, characterized in that the number of screw motors same number of generators or generator groups of the existing ones Units each have a control regulator assigned to them during maneuvering the speed regulation and reversal of each of a generator or a generator group supplied motor independently of the other motors, and that at full speed the remaining generators, to which no control regulator is assigned is in series with the first generators or generator groups connected in series that are also in Feed motors connected in series. 2. Screw drive according to claim 1, characterized by a lock, which the series connection of the Leonard generators with the other generator or generators and the maintenance this circuit is only permitted if all control regulators are set to "full ahead" are set. For this purpose ι sheet of drawings