DE293881C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- JVi 293881 - CLASS 21c. GROUP

Automatic starting device with contactors. Patented in the German Empire on July 9, 1914.

Starting devices have already begun in which a number of series resistors are automatic is gradually switched off to avoid a sudden increase in the current in the main circuit to prevent. It was switched off by a series of relays that came into effect in a specific sequence, most of them cooperate with a specially controlled limit switch.

The invention now relates to an automatic starter in which means of contactors stepwise parallel resistors in the main circuit are switched in such a way that in a particularly simple way a perfectly controlled gradual increase of the current is achieved to full operational strength. Thereupon are provided by the circuit all contactors except one are de-energized, which is then only when the disconnection part or interruption of the main circuit, the original rest position of the entire starter is restored brings about. This last contactor is now, according to the invention, by an electromagnet controlled whose armature contact is mechanically closed by the penultimate contactor and in this state remains until the above-mentioned interruption of the main circuit. It is achieved that on the one hand any damage the contactor is impossible due to excessive current and, on the other hand, the starter immediately restores in a completely reliable manner can respond when the main circuit is closed. The invention also includes Another contactor controlled by the last contactor, via whose armature contacts the Excitation current is performed for all other contactors except the last one, so that when Excitation the other contactors are de-energized.

In the drawing, the invention is shown in perspective and partially in a scheme. the Resistance units are all easily recognizable, as are the various ones Working or open positions of the individual parts.

A number of solenoids 12, 13, 14, 15 and 16 are mounted on the board 11. The solenoids 12 to 15 can have any resistance, but the solenoid 16 has such a high resistance that any undesirable current loss is prevented at the voltage used in each case. On a base plate 17, a magnet 18 is fastened with also high resistance, and below the same an armature 19 with a contact 20. With 21, 22, 23 and 24, the required terminals are designated. All parts located on the plate 17 together with this form a relay. A magnet 25, which can be connected in series with the solenoid 16 and influences an armature lever 26 ^, is seated on a further plate 24 a. The lever is provided with a resilient end .27, which is at the outermost end

Points one eye 28 carries. On the plate 24® there is also a pin 29 which limits the deflection of the armature lever 26. One contact 30 is controlled by the lever and opens or closes a circuit in the following described manner.

A terminal 31 is connected on the one hand to one contact half 30 and on the other hand through the line 32 to the solenoid 16. Another terminal 33 on the plate 24 ^s is connected to the winding of the magnet 25, which can also be connected to the terminal 31 . The parts arranged on the base plate 24 together again form a relay with it.

For the solenoids 12 to 16 are used as anchors movable cores 34, 35, 36, 37, 38 are provided which slide in guides 39 and each one Carry disk 40 of poorly conductive material. The disks sitting on the cores 34 to 37 40 all have a high resistance, while the disk 40 on the core 38 compared to the maximum value of the ^

^a 5 deten operating current has relatively little resistance.

Below each solenoid are two holders 4o and arranged ^a 41, the fixed contact portions 42, 43, wear advantageously in the form of carbon rods. Further, the solenoids 12, 13, 14 and 16 have movable arms 44, 45, 46, 47 with contact halves 48, 49, 50, 51 which come into contact with the disks 40 made of carbon, for example, each time the solenoid cores go up to be pulled.

At 52 a transformer is designated, which has a primary winding 53 and a secondary Winding 54 has; the latter is due to the place of electricity consumption or work leading lines 55, 56. From the primary winding 53, the wire 57 leads to the main power line 58, to which at the same time Line piece 59 is connected, of which a wire 60 leads to the solenoid ιό. At the line piece 59 and wire 60 then join a piece 61 with the junction 62 to the solenoid 15. The line 63 then follows the piece 61 and the branch 62 of junction 64 to solenoid 14. Lines 63 and 64 are connected via the Line piece 65 the piece 66, and with these lines the solenoid 13 is through the Wire 67 connected. A line 68 also connects the solenoid 12 to the line piece 66, from which finally a wire 69 to the terminal 21 of the relay 18 leads down.

Terminal 23 of relay 18 is connected to the solenoid by an upward running line 70 12 connected. From the movable arm 44, the line 71 goes to the next Solenoid 13 and correspondingly from the arm 45, the line 72 to the solenoid 14 and a further line 73 from arm 46 to solenoid 15.

The movable arm 47 is through the wire 74 to the terminal 22 of the relay .18 tied together. At the terminal 24 is the line 75, from which a branch 76 to the Terminal 33 of relay 25 leads. The wire 77. then connects the two lines 75 and 76 with the main line 78; a wire 79 is also connected to this, which over the line 80 is connected to the holder 41 below the solenoid 16. ■

To the wires 79, 80 and the line leading to the holder 41 below the solenoid 15 82 the wire 81 is connected, and from the junction of 81 with "82 goes the wire 83, 84 to the holder 41 under the solenoid 14. The wires 83, 84 are connected to the Line 85 connected, from which again a wire 86 upwards to the holder 41 below of the solenoid 13 leads. A line 87 also goes from the wires 85, 86 to the Holder 41 below the solenoid 12.

A line 88 is connected to the winding 53 of the transformer 52, one of which is Wire 89 to holder 40 "below the Solenoids 12 goes. With the holder 40 ° unteiv Half of the solenoid 13 is connected a wire 90 running downward and to the line 91 is connected, which in turn leads to the wires 88, 89. To wires 90, 91 is a Line 92 connected by the upward wire 93 with the holder 40 ° connected below the solenoid 14.

A wire 94 is connected to wires 92, 93 and 95, the latter leading up to the holder 40® below the solenoid 15. A line 96 extends from the junction of wires 94 and 95 to holder 40 ^s below solenoid 16.

A rod 97 is attached to the lower end of the core 37 and a button 98 at the bottom and also wears a collar 99 at a small height above it. The one between these two The part of the rod 97 lying against the stops goes loosely through the eye 28, so that the rod no can perform a certain deflection in the vertical direction without the lever 26 moves, which is only after a certain game has been completed by the movement the rod 97 is affected.

Incidentally, the use of the transformer 52 is not essential for the invention, but of course desirable when using alternating current. Lines 57 and 88 can just as well be directly connected to a number of resistors or with the motor or the other with electricity

machine to be provided. The latter will probably always be the case when it comes to the Using direct current.

The mode of operation of the new device is now as follows:

Assume first that the device is out of service and the main lines 58 and 78 are disconnected from the power source. The weight of the individual kernels 34; 35) 36, 37 and 38 holds - then the same in their lowest position. Likewise, the armature 19 and the armature lever 26 are in their lowest position, so that the contact 20 is closed and the contact 30 is open.

The main lines 58, 78 are now provided with power or to the power source connected, the following flow occurs:

From the current source, not shown, the current flows via the main line 78, wire 77 to the terminal 24, via the armature 19, the closed contact 20, terminal 23, line 70, to the solenoid

12, via wires 68, 66, 65, 63, 61, 59 and main line 58 back to the power source. The solenoid 12 is now excited and as a result the core 34 is raised to the highest position, so that the disk 40 is in contact with the contact parts 42, 43 and 48 _:

comes.

This closes another circuit: From the power source to the Main line 78, wires 79, 81, 83, 85, 87 to holder 41, contact part 43, carbon disc 40, Contact part 48, arm 44, line 71, solenoid 13 and wires 67, 65, 63, 61, 59 and main line 58 back to the power source. The solenoid 13 is excited and the core 35 so Raised far, that the mounted on this disk 40 with the corresponding Contact parts 42, 43 and 49 on the solenoid 13 comes into contact.

The following circuit is now closed: From the power source via the Main line 78, the wires 79, 81, 83, 85, 86-to Contact part 43 below the solenoid

13, carbon disc 40 on the associated core 35, contact part 49, arm 45, line 72 to solenoid 14 and via wires 64, 63, 61, 59 and trunk 58 to the power source return. The solenoid 14 is energized and its core 36, according to how explained in the case of solenoid 13, also indicated

'raised.

This also creates the following circuit: From the power source to the Main line 78, wires 79, 81, 83, 84 to the contact part 43 next to the core 36,. to the Disc 40, contact part 50, line 73, to solenoid 15 and via wires 62,61,59 and main line 58 back to the power source.

The solenoid 15 is energized and its core 37 is raised. As a result, the rod 97 also rises, the button 98 pushes against the eye 28 and rotates the armature lever 26 upwards until the contact 30, 31 is closed. Characterized further following circuit will now be made: from the power source via the main line 78, wires 77,76, solenoid winding 25, armature 26, connection terminal 31, line 32, solenoid 16 and the wires 60, 59 and the Häuptleitung 58 to the power source. Both the magnet 25 and the solenoid 16 are excited by this current flow, so that the contact 30 is independent. of the lifting movement of the. Rod 79 is held closed by the attraction of magnet 25.

From the foregoing, it can be seen that the solenoids 12, 13, 14, 15 and 16 are faster Succession to be excited and each one; individual, when it is excited, by particular ones Switching devices closes a circuit through the next following solenoid until all solenoids are in operation at the same time. After the solenoid 12 at the beginning is excited to work, its individual moving parts take quite appropriate Settings like those of the other solenoids 13, 14, 15 and 16 in their successive excitation.

Each of the solenoids now also closes a branched circuit which influences the transformer 52 when it is excited. If, for example, the core 34 of the solenoid 12, as explained above, is raised to its highest position, the following circuit is established: From the power source via the main line 78 and wires 79, 81, 83, 87 to the contact part 43 below the Solenoids 12, via the adjacent contact disk 40 and contact part 42 to the holder 4O ^a , lines 89, 88 to the primary winding 53 of the transformer and via wire 57 and main line 58 back to the power source. As a result, the primary winding 53 is supplied with current to the extent that the ohmic resistance of the carbon disk 40 on the core 34 permits.

After the solenoid 13, as described above, is excited and its core 35 has been raised so far that the contact disk 40 located on it comes to an end with the contact parts 42, 43 and 49 arranged above it, the following circuit is established: ^J1 5 From the Power source via the main line 78, wires 79, 81, 83, 85, 86 to the holder 41 and contact part 43 below the solenoid 13, the adjacent contact disk 40, contact part 42, holder 40 °, wires 90, 91 and 88 to the primary winding 53 of the transformer , and from there over the wire 57 and the

Main line 58 back to the power source. It should be noted that the winding 53 only receives as much current as goes over two disks 40, which are related to the primary winding are connected in parallel to each other. In the same way, the solenoid 14 is energized and its core 36 is raised to its highest position, creating a further parallel circuit just like the two previously described, closed over the next disk 40 will. There are then three successive discs parallel to each other in the circuit of the transformer winding . 53 switched.

As soon as the solenoid 15 is energized and its core 37 is raised, an electric circuit corresponding to the last three is created by means of the disc 40 of this solenoid 15 through the transformer winding 53, so that now four discs 40 are connected in parallel with each other in relation to this. When the solenoid 16 is then finally energized and its core 38 lifts, a circuit is completed via another disk 40 and the transformer winding 53 so that all five disks 40 are connected in parallel to one another as as many resistance units are connected in parallel to the transformer and the power source.

However, this operating status of the individual parts only lasts for a moment. When the core 38 is lifted by the solenoid 16 and the contact disk 40 sitting on it is brought into contact with the contact part 51 located above it, the following circuit is created at the same time: From the power source via the main line 78, wires 79, 80, the connected holder 41, Contact part 43, contact washer 40, contact part 51, arm 47, line 74, terminal 22, solenoid 18, terminal 21 and via wires 69, 66, 65, 63, 61, 59 and main line 58 back to the power source. This circuit excites the magnet 18, attracts its armature 19 and breaks the contact 20. As soon as this has taken place, no more current can flow through the solenoid 12 , which consequently becomes ineffective and no longer keeps its core 34 raised, but in drops its lowest position. In the process, the disk 40 sitting on it is separated from the contact part 43 and the circuit through the solenoid 13 is thus interrupted. ; This is now in the same way ineffective, lets its core 35 fall and interrupts the circuit via the solenoid 14, which in turn is also de-energized and the

^{k The} circuit via the solenoid 15 is interrupted. The core 37 then falls into its lowest position and no longer supports the armature lever 26. However, as described above, this is held in its highest position by the attractive force of the magnet 25, so that the contact 30 still remains closed. The solenoids 12, 13, 14 and 15 ⁶ S then become ineffective one after the other and no longer have any influence on the power supply to the primary winding 53, but the control circuit is now established as follows: From the power source via the main line and wires 79 , 80 to the holder 41 next to the core 38, to the contact part 43 via the discs 40 to the contact part 51, arm 47, line 74, connection terminal 22, solenoid 18, connection terminal 21 and via the wires 69, 66, 65, 63, 61, 59 and main line 58 back to the power source. This circuit keeps the contact 20 open and thus prevents excitation of the solenoid 12 , as a result of which none of the other solenoids 13, 14 and 15 can be excited either. Now the power circuit, which has only low resistance and is relatively simple, can run in the following way: From the power source via the main line 78, wires 79, 80 to the holder 41, contact part 43, carbon disc 40, contact part 42, holder 40 ″, via wires 96, 94, 92, 91 and 88 to primary winding 53 and from there back through wire 57 and trunk 58 to the power source.

The solenoid 16 and magnet 25 are in series with one another and remain energized for the duration of the power circuit. However, since the solenoid and magnet windings are wound with a resistor suitable for the voltage in the power circuit, the current loss caused by their permanent excitation can easily be neglected. ■ '

When the device is in the last-described operating state, i. H. Solenoid 16. and magnet 25 energized and all other parts in their corresponding Normal position, it can be permanent or. can also be used for any length of time to use the Transformer 52 to provide power or the power controlled by the device to a number of resistors or directly to the workplace. .

As soon as the power supply in the main lines 58 and 79 is interrupted, the solenoid 16 and the magnet 25 are ineffective, so that the armature lever 26 falls into its lowest position until it rests on the limit stop 29. With the simultaneous dropping of the core 38, the contact disk 40 sitting on it is separated from the contact part 51 , the circuit via the magnet 18 is interrupted, its armature 19 drops and closes the contact 20.

This brings all of the various moving parts back into their respective ones Unused positions. And then the circuit is closed via lines 58, 79 the whole process can be repeated in the same order.

The idea of the invention is limited of course not to the application of the device to any particular type of electric current, nor to the type illustrated as an exemplary embodiment.

Claims (2)

Patent Claims: i. Automatic starting device with ^X 5 contactors, which gradually switch parallel resistors in the HauptstiOmkkreis, and of which only the last, the lowest resistance level switching contactor remains energized during operation, characterized in that the excitation of the last contactor (16) from a special, in series with him lying contactor. (25) whose armature contacts (30, 31), via which the excitation current is routed for both contactors, are mechanically closed by the penultimate contactor. 2. Automatic starting device according to claim i, characterized in that a contactor (18) is controlled by the last contactor (16) via its armature contacts (20,23) the excitation current for all others (except the last one) Contactors (12 to 15) is guided, so that when it is excited the other contactors (12 to 15) are de-energized. 1 sheet of drawings.