DE669053C - Remote control device for controlling adjustable organs - Google Patents

Description

Remote control device for controlling adjustable organs There are already Remote control devices for controlling adjustable organs have been proposed, which can only be actuated if two are consecutive at a precisely defined distance and various currents are sent over the trunk and onto a locking member act. These proposed bodies are direct with individual bodies assembled.

The invention relates to an advantageous embodiment of such Remote control devices and consists in that that of the two different Flow-affected limb is common to a plurality of adjustable organs and when it is properly operated, the connection to the adjustment of the Organs serving actuating coils with the associated control switches manufactures. This ensures that unwanted organs are triggered accidentally current pulses occurring on the control lines are avoided with certainty, since the control lines are only switched through when the locking element has been actuated. At low cost, the device according to the invention retrofitted even with existing remote control devices will. The use of such remote control devices is particularly advantageous, where a special line is used to control each of the adjustable organs is provided. In this case, the second rush current can not only connect of the actuating coils to the corresponding control lines, but rather it can also serve as an actuation impulse for that organ at the same time whose control line it was transmitted.

The invention is to be explained in more detail with reference to the drawing.

FIGS. Z, a and 3 show three exemplary embodiments.

In all of these figures, H denotes the main unit and N denotes the auxiliary unit of a remote control system. 1i to 1, are the trunk lines. The line 1i belongs to the actuating devices for an organ, 1, for the second organ, 13 for the third organ, which is remotely operated via a so-called single-wire remote control. The return e is common to all organs. It connects the two busbars of the main and auxiliary units, which are provided between the plus and minus bars. The plus, minus and zero rails are fed in the main unit by a battery BH, in the auxiliary unit by a battery BN. The adjustable organs, such as oil switches, are not shown. Only their actuating coils Ei and Al, E2 and A2, Es and A3 are shown. Of these Coils is in each case the closing coil E over;. a contact a with the positive rail, the A Switching coil A via a contact e with d Minus rail connected. In the main office: the control switch S is provided which, in its central position, connects the polarized relay P connected to the neutral rail with the long-distance line. The polarized relay P is designed so that it remains in the position in which it was last energized until it is switched to the other position by a reversely polarized current surge. In the position shown, the polarized relay F1 indicates that the associated switch is switched off, since its pointer points to ä. When this switch is on, its pointer points to e '. Of the two outer fixed contacts of the control switch S, one is connected to the plus bar, the other to the minus bar. When one of the control switches is turned upwards, the associated switch-on coil E is excited and the switch is switched on with closed contacts k1 to kg and closed contact k. When the switch is turned on, the associated contact a is opened and the corresponding contact e is closed. When switch S1 returns to its central position, the associated polarized relay P is energized in such a way that its pointer points to e '. In an analogous manner, when one of the control switches S is flipped down, the opening coil A in the auxiliary unit is connected to voltage. The contact a is thereby closed again, the contact e is opened. When the control switch S returns to its central position, the polarized relay P1 points to e '. So far the arrangement for single-wire control is known.

The novelty of the invention is that in FIG. The contacts hl to k3 are jointly controlled by the switching lever 2 rotatably mounted about i. The shift lever can only be activated when the locking disk 3 is in the appropriate position and the DC coil is excited -q. be operated. The locking disk 3 is driven by an alternating current motor 5 via the gears 6, 7 against the force of the weight B. Only when the groove 9 is located in front of the nose is it possible to close the control lever 2 in this way kchalten that, as a result of the excitation of the coil 4. Contacts hl to k3 and k can operate. Actuation of the control lever 2 is in the äuptstelle the switch ii provided, the on a contact 12, the alternating current source 13 connected to the line e with the control line 1q. connects. If the switch ii is on the contact 12, a circuit for the alternating current motor 5, which extends over the capacitor 15, is closed. The choke coil 16, which is in the circuit of the DC coil q. lies, blocks the passage of alternating current and thereby prevents premature excitation of the direct current coil q .. As a result of its excitation, the alternating current motor 5 starts to run and rotates the disk 3 in the direction of the arrow. As a result, the weight 8 provided on the disk is lifted. The control switch ii remains on contact 12 until the weight 8 comes to the position 8 'shown in dashed lines. Only now is switch ii brought to contact 17. As a result, the plus and minus rails are connected to lines e and 14. Since the capacitor 15 blocks the path of the direct current, the choke coil 16, on the other hand, opens the path to the direct current, the direct current magnet .4 is excited instead of the motor 5. The connection of the switch ii with contact 17 takes place at the moment when the groove 9 is located in front of the nose io. The control lever is thus actuated. As a result, the contacts k1 to k3 and) a, are closed, and control by means of one of the switches S is therefore possible in a known manner.

Once the control has taken place, the switch i i must return to its Starting position to be postponed. This causes the current for the coil q. interrupted. The control lever 2 returns to the position shown and opens all of them Contacts hl to k3 and k. the pipeline. The long-distance line is therefore switched off. The return of the disc 3 to its original position takes place under the action of Weight B.

The return of the operating lever i i to its starting position can be done automatically, for example by a drive mechanism that is also used when Turn on the sequential connection of contacts 12 and 17 with the Switch lever causes. It can also be an electrical or mechanical connection be provided between the control switches S and the switch ii, such that for example in the event of withdrawal of the relevant switch S in the Middle position also the switch i i is returned to its starting position. as well can also at the beginning of the actuation of one of the switches S on mechanical or electrical Ways at the same time the actuation of the switch i i can be initiated.

Instead of using direct current for single-wire control you can an alternating current source grounded at its neutral point can also be used. The .frequency this alternating current must in this case differ from the frequency of the current source 13 differentiate generated alternating current. Instead of the choke coil 16 and possibly Instead of the capacitor 15, filter circuits are to be provided in this case, which are in such a way act so that they only let through the alternating currents with the corresponding frequency.

Fig. 2 shows a further embodiment of the invention. Parts corresponding to the arrangement according to FIG. 1 are provided there with corresponding reference numerals. Unlike in FIG. As a result, the control switch ii of FIG. I can be dispensed with. One terminal of the AC motor 5 is connected to the long-distance lines 11, 12, 13 via a line i9 and the lines 2o, 21, 22. The other terminal of the AC motor 5 is connected via the line 24 to the long-distance line e. A capacitor 25 is provided in the long-distance line e, and capacitors 26, 27, 28 are also connected in the lines 2o, 21, 2a. In this embodiment, the control switches S are moved at a very specific speed, for example influenced by a timer. If one of the control switches S is on the middle adjacent contact, the circuit for the AC motor is first closed via the capacitor 25 and one of the capacitors 26 to 28. The disc 3 begins to rotate until the weight 8 comes into the position shown in dashed lines. At this point in time, the relevant control switch is switched.

In this embodiment, a contact piece 29 is provided on the disk 3, which is connected to the long-distance line e via the line 30. A contact piece 31, which is connected to the long-distance line e via the line 32, works together with this contact piece. The line 3o is connected to the long-distance line e before the line 32 behind the condenser. When the contacts 29, 31 are touched, the capacitor is bridged. At this point in time the control switch S must have reached its control contact; as a result of the bridging of the capacitor 25, a direct current pulse can flow over the long-distance line and the associated actuating coil. In this case too, the long-distance line is normally interrupted by the interposition of the capacitor 25, so that the actuating coil e cannot be undesirably influenced by induced voltages or currents. In order to exclude with certainty an influence by alternating current, a choke coil 33 is expediently switched into the line e.

The feedback is given by a correspondingly slow ZuiTickpunkt of the control switch in its middle position. If the control switch touches the AC contact, thus, for the second time, the disc, which has meanwhile returned to its original position, becomes 3 rotated so that the weight 8 comes in the dashed line position 8 '. at the contact of the contacts 28 and 31 is then over in its middle position returned switch carried out the feedback.

As can be seen, in this embodiment, the control line 14 and the switch 1i of FIG. I saved.

Fig. 3 shows a further embodiment of the invention. Also at In this embodiment, parts are given the same reference numerals in FIG. In the remote control system shown in Figure 3, the lever 2 is with a switching arm 34 connected, which consists of conductive material and in the position shown short-circuits the connecting lines 3 5 to 37 leading to the long-distance lines 11 to 1, 3. This means that all control lines are short-circuited. The control switches are in this case designed similarly as in Fig.2. You have five fixed Contacts, of which the middle one for the feedback, the two outer ones for the Control and those in between for connecting the AC motor 5 to the AC power source 13. For this purpose are the in-between Contacts connected via line i8 to one terminal of the alternating current source 13, the other terminal of the AC power source is on line 38 on the trunk line e connected. The line 39 branches off from the long-distance line e, which passes through the capacitor 4o leads to one terminal of the AC motor 5, the other terminal of the AC motor is across the capacitor 41 and line 42 with one of the long-distance lines, for example via the auxiliary line 35 connected. Is one of the control switches S on its intermediate contact, the motor 5 is connected to the associated Long-distance line i, lines 42, line 39 and line e to the AC voltage 18 laid. The motor 5 begins to rotate and drives the disc 3 into it Position in which the weight 8 is in the illustrated position 8 '. Now the control switch S is brought to its external contact. This will make the energizes a coil 43 of the control lever z actuating DC solenoid, and since this happens just at the moment in which the groove 9 is in front of the nose io of the control lever 2 is located, the control lever 2 is thrown. The one through the contact arm 34 caused 'short circuit of the remote control lines is canceled and for it at contacts k1 to k3 and k, the connection of the long-distance lines to the actuating coils manufactured. So that the solenoid actuating the control lever 2 is not already through the Alternating current is excited, the inductor 44 is in the circuit of the coil 43 switched on. In the long-distance line e, the other winding 45 is also the Double coil switched on, which is now the control lever 2 in its attracted position holds. 1 control lever 2 is held in its tightened position until when the circuit is closed by one of the control switches S. Will this one Circuit opened as a result of taking back the control switch S, so also returns Control lever: 2 and also the disc 3 back to the starting position. Even with this one Embodiment is the actuation circuit for the coils E and A normally interrupted and only switched on during a control process. Instead of a control lever a toggle relay can also be used. Furthermore, instead of a double coil also other means, for example delay devices, ratchets, use to keep the control lever z in the tightened position as long as the Control process takes.

Claims (2)

PATENT CLAIMS: i. Remote control device for controlling adjustable Organs that can only be operated when two are at a precisely defined distance successive and diverse currents sent over the pipeline and act on a locking member, characterized in that the member (2, 3) of a plurality influenced by the two different currents common of adjustable organs and in its proper operation the connection of the actuating coils (E, A) used to adjust the organs with the associated control switches (S). 2. Device according to claim i, characterized in that when using a special line for the control each of the adjustable organs (e.g. i via El) not only receive the second current surge the connection of all actuating coils (E, A) to the corresponding control lines caused, but also at the same time as an actuation impulse for that organ (El) serves, via whose control line (1l) it has been transmitted.