DE271318C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- JV * 271318 - CLASS 21 e. GROUP

Patented in the German Empire on July 2, 1912.

The present invention relates to a device for registering the phase status when connecting alternating current machines in parallel and essentially consists of that at the moment of parallel switching by the control switch of the main switch a Spark registration device attached to a synchronism indicator is activated will.

ίο In the drawing is an advantageous embodiment of the invention illustrated schematically, namely shows:

Fig. Ι a view of part of the recording disk with the perforations, and Fig. 2 shows the circuit diagram of the synchronism indicator and the connections intended for the connection of two or more alternating current generators to be switched in parallel.
Each recording disk advantageously carries, as FIG. 1 shows, the marks "slow, fast" and is provided with arrow directions through which the direction of movement of the pointer 27 indicated in FIG Indicator acts, is smaller or larger than the number of periods of the electromotive force with which it is to be compared. When using an induction coil to generate the registration sparks, the primary circuit is closed at the moment in which the phase difference between the electromotive forces is to be registered and this short circuit causes an electrical spark to jump from the pointer 27 to a contact sheet 26 through the registration disc 31, so that the latter is perforated and gives an angular representation of the phase relationship. If the primary circuit of the induction coil remains closed, the recordings produced are in the form of a number of holes, the mutual distance of which depends on the number of current interruptions in the induction coil in the unit of time.

In the circuit diagram of FIG. 2, conductors 39 and 40 lead from the main busbars 37 and 38 to the contacts 41, 42 of a main switch S, through the intermediary of which the conductors 39 and 40 can be connected to the alternator G. From the main busbars 37 and 38, conductors 43 and 44 also lead to the contacts 45 and 46 of a main switch S ¹ , which serves to connect these conductors to the alternating current generator G ^1. Furthermore, the primary winding 47 of a voltage converter 48 is applied to the main busbars 37 and 38, the secondary winding 49 of which is connected to the synchronizing busbars 50 and 51. The field windings 3 of the synchronism indicator are connected to the synchronizing strips 51 and 52 by conductors 53 and 54. The wire 53 is connected by a conductor 55 to the common terminal of a non-inductive resistor 56 and an inductive resistor 57 and the other terminals of these resistors are connected to the two armature coils 10, which on the other hand are connected to each other and by a conductor 58 to a synchronizing rail 59 are. The wire 58 is in communication

60

65

70

with a phase lamp 60, the other end of which is connected to the synchronizing rails by conductors 61 62 is connected.

To produce the recording, an induction coil 63 is connected to the synchronism indicator, the primary winding of which is denoted by 64 and the secondary winding by 65. The terminal common to both windings is connected by a wire 66 to the shaft 12 and in this way to the pointer 27, while the other terminal of the secondary winding 65 is connected to the bow section 26 by conductor 67. The wire 66, like the secondary line of the transformer 48, is grounded to protect the operating personnel from high voltages. The other terminal of the primary winding 64 is connected to a vibrating contact arm 68, the mating contact of which is connected by wire 69 to a direct current busbar 70 which is supplied by any power source such as, for. B. is supplied with power from the generator G ^2. The wire 66 is connected to the synchronizing rail 72 through a resistor R by means of conductor 71.

The generator G is connected to the contacts 75 and 76 of the main switch S by conductors 73 and 74. Contact strips 77 and 78 are arranged with respect to the main contacts of this switch S so that they connect the contact 41 with 75 and the contact 42 with 76 when the closing coil 79 is excited, whereupon the operating mechanism of the switch S moves the contact strip 80 such that the Contacts 81 and 82 are connected to one another. The main contacts are closed against the action of a spring which, when the lifting coil 83 is energized, serves to move the contact strips 77 and 78 into the open position indicated in FIG 85, as can be seen in FIG.

The switch C is used for the electromagnetic control of the main switch S. It is equipped with a pair of contacts 86, 87, which can be closed or opened for any position of the switch C.

The contact piece 87 is connected by conductors 88 to a busbar 89 which is connected to the direct current generator G ² , while the other contact 86 is connected to a contact piece 90 of the switch C in connection. Another contact 91 of switch C is connected by wire 92 to one end of closing coil 79 of switch S and the other end of this coil is connected to contact 84 by wire 93. Another contact 94 of the control switch C is connected by line 95 to one end of the lifting coil 83 of the main switch S, while the other end of this coil is applied to the contact 81. Contacts 82 and 85 are connected to each other and to DC bus 70 by wire 96. The control switch C is provided with a contact strip 97 which serves to connect the contacts 90 and 91 when the switch is moved into one position and with a second contact strip 98 which connects the contacts 90 and 94 together when the switch is in is moved in the opposite direction, these positions of the control switch being used to close or open the main switch S. Contact 86 of switch C is connected by line 99 to the common terminal of two lamps 100 and 101, the other terminals of which are connected to conductors 92 and 95, respectively.

The conductors 73 and 74 emanating from the generator G are connected to the primary winding 102 of a voltage transformer 103, the secondary winding 104 of which is connected by wires 105, 106 on the one hand to the synchronizing rail 51 and on the other hand to the contact 107 of a synchronizing plug switch P , the latter being the control switch C is assigned. The switch P consists of three sets of contacts, which are independently influenced by guide rings. One contact set consists of the contacts 107, 108, 109, which can be connected to one another by a line 110. Similarly, the contacts in, 112 of the second set are connected to one another by a ring 113, while the contacts 114, 115 of the third set can be connected to one another by a ring 116. The rings 110, 113 and 116 are mounted on an insulating body, and are operated with the aid of a suitable handle connected to the same. '',

The contact 108 of the switch P is connected to the synchronizing rail 52, while the contact 109 is connected to the synchronizing rail 62 via a control lamp 118. The contacts in 13, 112 and 114 are individually connected to the synchronizing rails 59, 50 and 72. The contact 115 is connected by wire 119 to a contact 120 of the switch C and can be connected to the contact 90 of this switch through the contact strip 97 when the latter is switched over to connect the contacts 90 and 91 accordingly.

The generator G ¹ is equipped with a main switch S ¹ , a control ^{switch C 1} and a synchronizing plug ^{switch P 1} , the device of which is the same as that of the switch

5, C and P and which are similarly applied to the main busbars, the synchronizing bars and the DC bus bars.

In order to connect any of the generators to the bus bars 37 and 38, the plug of the synchronizing switch P is first inserted, whereby the contacts in and 112, the account clocks 107, 108 and 109 and the contacts 114 and 115 are connected as described above. For this state, the voltage converters 48 and 103 are connected to the windings of the synchronism indicator as follows: From the secondary winding 49 via rail 50, contact 112, contact in, rail 59, wire 58, armature winding 10, resistors 56 and 57 to wire 55, conductor 53 and back via rail 51 to winding 49. A circuit is closed by the transformer 103 in the following way: Via winding 104, conductor 106, contact 107, contact 108, busbar 52 .. wire 54, field coil 3, conductor 53, busbar 51, wire 105 back to the winding

104. The two windings of the armature 10 are offset at right angles to one another and the non-inductive resistor 56 and the inductive resistor 57 are dimensioned so that the currents flowing through the two windings are shifted by approximately 90 °, creating a rotating field in the armature and the latter in effectively rotates with all the parts it carries. By closing the circuits described above, the windings of the synchronism indicator are energized, so that the pointer 27 rotates at a speed which corresponds to the alternation number difference of the electromotive forces emanating from the windings 49 and 104, assuming that at this point in time the Main busbars 37 and 38 an alternating electromotive force is applied. At this point, the plug of the synchronizing switch P also connects the lamp 118 to the lamp 60 by the wire 61 and these two lamps connected in series are connected to each other with the wires 58 and 106 so that they act as control lamps and the phase relationship between those of indicate the electromotive forces emanating from the windings 49 and 104. The plug in the synchronization switch P. By connecting the contacts 114 and 115, it also serves to connect the primary winding 64 of the induction coil 63 to the contact 120 of the control switch C.

For the state of the apparatus described above, the activity of the pointer 27 ■ is a sign for the supervisor for the regulation which must be carried out in the generator G in order to bring the electromotive force of the transformer 104 with that of the transformer 48 in phase agreement, and if so this is achieved, he actuates the control switch C. The operating mechanism of this switch is so arranged that it first closes the contacts 86 and 87, whereupon the contact strip 97 is brought into contact with the contacts 90, 91 and 120; This closes the following circuits: From the direct current source G ² via rail 89, wire 88, contacts 87, 86, 90, contact strip 97, contact 91, closing coil 79, wire 93, contact 84, contact strip 80, contact 85, wire 96, Busbar 70 back to generator G ² . In parallel with this circuit, the following circuit is closed at the same time: Via contact 86, contact 90, bar 97, contact 120, wire 119, contact piece 115, contact 114, conductor 71, resistor R, primary winding 64, breaker 68, wire 69, rail 70 back to generator G ² . Under the influence of this last-mentioned circuit, the induction coil 63 comes into effect and at the same moment the electrical spark formation between the pointer 27 and the arc 26 is caused by the following circuit: Via secondary winding 65, conductor 67, arc 26, pointer 27, wire 66 back to the secondary winding 65. Before the control switch C is actuated, a recording disk 31 has of course been suitably inserted into the apparatus, which is now pierced at suitable points by the electric sparks mentioned and shows the position of the pointer over the disk at the moment the control switch C closes , while through the holes made in the disk itself the direction of movement of the pointer and the speed of this movement (by the distance between the holes) are continuously recorded, provided that the operating speed of the oscillator 68 is known.

The excitation of the coil 79 causes the switching of the contact strips 77 and 78 in such a way that the contact 41 is connected to the contact 75 and the contact 42 is connected to the contact 76, the vibrating strips 80 being switched from the contact 84 to the contacts 81 and 82 at the same time will. As a result, the generator G is connected to the main collector rails 37 and 38 in the following way: To the rail 37 via conductor 39, contact 41, bar 77, contact 75, conductor 73, generator G, wire 74 ', contact 76, bar 78, contact 42, wire 40, rail 38. The connection of the contacts 81 and 82 by the strip 80 brings the lamp 101 to fol-

The same path to lighting: From generator G ² via rail 89, conductor 88, contacts 87, 86, wire 99, lamp 101, wire 95, lifting coil 83, contact 81, bar 80, contact 82, wire 96, rail 70 back to the generator G ² . The lighting of the lamp 101 caused in this way indicates that the main switch S has been actuated correctly in order to close the circuit from the generator G to the main busbars 37 and 38. The current flowing through the lifting coil at this time is too weak due to the resistance occurring in the lamp 101 to attract the coil core and thereby cancel the main switch lock, which is effected by a pawl on the coil core. It can be seen that when the control switch C is closed before the main switch S comes into operation, a considerable current flows from the generator G ² via the control switch, since at this time the closing coil 79 and the induction coil 63 are both in operation. As soon as the main switch S comes into operation, the circuit of the closing coil 79 is opened, so that the current flow in the rails 70 and 89 changes. This change has the effect of lowering the voltage drop in these rails. The result is a small increase in the voltage of the induction coil 63 and a corresponding change in the recording produced thereby. This is illustrated in Fig. Ι. In this figure, the perforation 31 ″ indicates the position of the pointer and therefore the phase difference between the electromotive forces when the control switch is closed, while the subsequent perforations 31 * indicate the period during which the control coil 79 was traversed by current.

When the main switch came into operation, the disk was provided with the perforations 31 ^s , the nature of which is different from that of the holes 31 ^b , because the movement of the pointer 27 is delayed when the mains and machine G are connected in parallel. The relatively large hole 31 ^rf , which was made when the synchronism was achieved, indicates the passage of successive sparks during the duration of the synchronism and that the speed of this generator was subsequently increased somewhat in order to bring it into synchronous gear.

As soon as the person in charge of the lamp 101 recognizes that the main switch S has been operated correctly, he brings the control switch C into that position in which the 'contacts 86 and 87 are opened and, if desired, the contact strip 97 takes an intermediate position, so that the contacts of the control switch are all switched off. When it is desired to switch off the generator G from the main busbar 37 and 38, the control switch C is placed in such a position that the contacts 86 and 87 are closed and the bar 98 is applied against the contacts 90 and 94, in which state the Lamp 101 is short-circuited by the strip 98 and the wires 99 and 95, while the circuit going through the lamp 100 is interrupted due to the disconnection of the contact 84 from the conductor 96. In this case, the coil 83 is excited in the following way: From the generator G ² via rail, 89, wire 88, contacts 87, 86, 90, contact strip 98, contact 94, wire 95, coil 83, contact 81, contact strip 80, contact 82, conductor 96, rail 70 back to generator G ² . The coil 83 excited in this way triggers the spring mechanism in the main switch S, whereby the contact strips 77 and

78 can be brought into that position in which the generator G is switched off by the busbars 37 and 38 and at the same time the contact rod 80 is moved from the contact 81 to the contact 84 in order to produce a circuit through the lamp 100 in the following way: From the generator G ² via busbar 89, wire 88, contacts 87, 86, wire 99, lamp 100, closing coil 79, wire 93, contact 84, contact rod 80, contact 85, conductor 96, bar 70 back to generator G ² . This causes the lamp 100 to light up and indicates that the main switch is open while the closing coil is activated

79 as a result of the resistance of the lamp 100 does not receive enough current to switch the main switch to close again.

As already mentioned, the generator G ¹ is also equipped with a synchronizing plug switch, a control switch, a main switch and a voltage converter of the same device and the connection of these elements to the various busbars is also carried out in the same way as described above. It will be understood, therefore, that the insertion of any synchronizing plug in this device will connect the voltage converter 48 to the voltage converter of the desired generator as well as to the synchronism indicator. It goes without saying that any desired number of generators can be connected to the busbars in the same way, in that the connections of the individual generators are completely identical to one another. If with the main busbars 37 and

If no alternating current source J is connected from the outset, the generator G can, if desired, be connected directly to the busbars with the aid of the control switch C and the generator G ^{1 can} be connected in parallel with it in the manner described above.

Claims (2)

Patent Claims: ίο I. Device for monitoring the Parallel switching of alternating current machines, characterized in that an induction apparatus (63) is switched on by the control switch (C) of the main switch (S) at the moment of parallel switching, through which a spark transfer between the pointer (27) in a known manner to the one to be connected in parallel Circuits connected synchronism indicator and an opposite pole (26) is caused so that the positions of the synchronism indicator are registered from the moment of parallel switching. 2. Device according to claim 1, in which the main switch closes and interrupts the circuits of its switch-on coil and switch-off coil, characterized in that a lamp is switched on in each of the two control circuits, the switch-on coil, (79) in the open position and the switch-off coil as a result of current weakening (83) in the closed position of the main switch ineffective until one or the other lamp is short-circuited by changing the control switch (C). For this purpose ι sheet of drawings.