DE1615077B1 - DEVICE FOR RECEIVING ROUND CONTROL COMMANDS - Google Patents

Description

3 4

direction can be seen in the fact that beer contains the receiving cam 253 , the nose 225 of a control relay is only performed on the start pulse and 217 in addition.

only responds to such control commands that are effective The turning of the bell 223 now causes a Auflich for the remote control receiver in question skids of the nose 224 of the contact spring 220 on which are intended. With all other control commands 5 outer diameter of the bell 223. As a result, however, the receiving relay remains at rest and the contact 219, 220 remains closed, even then, thus causing neither corresponding noises if the nose 225 of the control rake later nor wear. 217 also on a cam 226 of a switching

Another advantage can be seen in the fact that the disk 227 runs up . This last-mentioned accumulation of trouble-free operating time of ripple control receivers has the consequence that the nose 215 of the control rake can be increased many times over compared to the previously usual operating time to 217 in a section 251 of the armature 214 of the now. no longer energized relay 212 can intervene.

Finally, the device described enables the storage arrangement 208 to be discharged

processing by reducing the response time through the relay 212 via a glow lamp 211 gears of the receiving relay also an increase in the 15 can occur during the duration of a control operational reliability pulse, for example 102 (FIG. 1), a or

The following is an exemplary embodiment in which several discharge current surges occur, depending on the invention explained in more detail with reference to the figures. speed of the amplitude of the incoming tax shows signals. As a result of the locking of the relay armature

1 shows a pulse-time diagram, 20 214 through the nose 215 of the control rake 217

Fig. 2 schematically shows a circuit and the effect already after the first discharge current surge through the selection elements of the ripple control winding of the relay 212 , but the other receiver, possible current surges remain ineffective. There is no need

. F i g. 3 the structural arrangement of the selection - ie a special device that prevents the flow organs, receiving relays and switches, sometimes more than one discharge current surge.
Section, the switching disk 227 with switching cam 226 is

4 and 5, a switch in one possible rotatably arranged on the bell 223; by means of the switch position, partly in section. switching grooves 301 fixedly arranged on the bell

Fig. 1 shows a pulse-time diagram. Up to 322 , the switching disk 227 with its series of detent pulses, as in a round spring 252 known per se, can be locked in one of the 22 grooves 301 to 322 fixed control systems for command transmission from one control system.

Transmitter sent out and the power network in The 22 possible positions of the switching ring

Form of audio-frequency impulses are superimposed. coincide in time with the pulse-time

In its left half, FIG. 2 shows a reception diagram according to FIG. 1. If, for example, in the catcher circuit 203 that is suitable for the command 2 to be evaluated at the receiver, then terminals 201, 202 connected high-voltage network is the switching disk 227 with detent spring 252 to evaluate superimposed audio-frequency pulses. Turn it and snap it into place so that the arrow d of the command can be used to designate such receiver circuits is opposite the number 2. There are now that when audio-frequency commands are received, the transmitter at the time of pulse interval 2, impulses a relay 212 to pick up. Such 40 after the arithmetic end 228 after contacting the receiver circuits are described in detail, for example, in the arithmetic nose 225 on the cam 226 by Swiss patents 325 984 or 357106 nose 215 in the relay armature 214 , a detailed description. ON command, i.e. a switch-on command for the

The discharge of the storage capacitor 208 according to the switch with command number 2, the charge is charged by a control pulse (start capacitor 208 until the ignition pulse or command pulse is reached) via the relay 212 voltage of the glow tube 211 . Causes thereto a tightening of the movably mounted takes place abruptly discharging the Ladekonden relay armature 214, whereby its neck 251 crystallizer 208. The nose 215 of the is attached to the leaf spring 216 through the coil of the relay 212. The relay armature attracted 214 again, the Steuerrechens 217 unlocked so that the latter ₅₀ cutout 251 releases the rake end 228 and under the influence of the pretensioned leaf spring 216 the rake 217 bends under the spring force in the direction of the arrow α , the pretensioned leaf spring 216 can move in the direction of the. With the control rake 217 , an arrow α moves into the position shown in dashed lines.
Isolation piece 218 in the direction of the

Arrow b, with him the contact spring 219 below the 55 interval 2 no pulse, the loading influence will follow its own spring force. As a result, capacitor 208 is not charged, the starting contact 219, relay 212 , which is now closed, does not pick up, and the control rake 217 220 of the synchronous motor 221 to the mains voltage remains in the locked position shown,
placed. Be of the synchronous motor 221 Fig begins to Since the switching disc gen 227 in 22 possible adjusting and deer and drives, via a in the figure, only reasonable 60, the time, indicated with the pulse-time diagram of the reduction gear 222, a bell 223 according to. 1 coincide, brought made of insulating material in the direction of arrow c . can, the process described can be carried out on any This bell has tracks of the 22 possible positions on its outer surface,
with different diameters. On a The further, purely mechanical mode of operation of the

The first path slides a nose 224 of a contact spring 65 receiver, ie the actual actuation of the 220. This first path is interrupted by a notch 254 controlling the switch, later referring to the per, which shows the starting position of the bell. 3 explained. For the time being it is only fixed. On a second track, which held one that the tax rake 217th when arriving

after an ON command, the dropping of its nose 225 via the cam 226 can rotate up to the position shown in dashed lines and that, on the other hand, in the absence of ON commands by the relay armature, it remains locked so that it only moves up to the position shown in solid lines can turn back.

Shortly before the bell 223 has completed a full rotation of 360 °, the nose 225 of the control rake 217 runs onto the cam 253 of the bell 223 and the rake end 228 of the control rake 217 is locked again by the nose 215 in the cutout 251 of the relay armature 214 as long as it has previously dropped out due to an ON command. Upon completion of a full revolution of the bell, the nose 224 of the contact spring 220 falls into the notch 254 of the bell. Since the rake end 228 remains locked, the contact spring 219 is blocked by the insulating piece 218 , so that the start contact 219, 220 is opened and the synchronous motor 221 is de-energized. Thus, the bell 223 is in its rest position. The whole process is only repeated when the start pulse 100 of a next command series arrives.

The mechanical structure and the mechanical action of the receiver will now be explained with reference to FIG. One recognizes the bell 223 and the switching disk 227 which can be latched onto it by means of detent spring 252 on 22 different commands. The respective set command is clearly indicated by counting on the switching disk 227 in relation to a pointer 255.

Below the bell 223 , a switch 256 is fastened with a screw 257 on a base plate 250. On the switching disk 227 there is a riveted spring 258 which is mechanically pretensioned so that its switching pin 259 rests firmly on the cam 226 of the switching disk 227. The switching pin 259 can be deflected upwards by an external force. Such a deflection can take place through the nose 260 of the control rake 217 .

If the latter is in its locked position by the relay 212 (as shown in full line in FIG. 2), the switching pin 259 passes the control rake 217 without being influenced by its nose 260 . The switching pin 259 is not deflected in this case and thus passes the switch 256 below its partition wall 261. On the other hand, if the control rake 217 - as described earlier - has been unlocked by an incoming ON command from the energized relay 212 and thus into the position shown in FIG 2 reaches the position shown in dashed lines, the switching pin 259 passing the control rake at this time hits the flank of the nose 260 . The switching pin 259 is deflected laterally, so that it now has to pass the switch 256 above its partition 261.

If the switch pin 259 wanders under the computing nose 260, then - since no ON command has been received - the switch 256 is placed in the OFF position or left in the OFF position. It initially prevents the control rake 217 from pivoting in the event that an ON command arrives at this point in time. The nose 260 leans against the face of the switching pin 259 until it has moved away from under the nose.

Meets a following ON command until after this time interval to which the switching disk is set 227, the control rake 217 is released from the anchor 214 and is incident on the running surface of the bell 223. At the same time, the armature 214 through the nose 215 in the computing 228 pressed against the relay 212 and held in this position, so that any subsequent excitations of the relay 212 cannot attract the armature 214 again and thus no noises are generated. Only when the bell 223 approaches the end of its full rotation does the cam 253 lift the nose of the control rake and thus release the locking of the relay armature 214. At this point in time, however, all 22 time intervals of the pulse program have already passed and the receiver will not have to receive any more pulses until it returns to the starting position.

The readiness of the recipient to evaluate a pulse is thus limited to the command number assigned to it. It begins at the moment in which the rake 217 has been locked by the rake end 228 after the nose 225 has hit the cam 226 through the nose 215 on the relay armature 214 and ends at the point in time when the switching pin 259 of the switching disk 227 is locked Bell 223 has turned so far that, when the relay 212 is unlocked, it no longer comes to rest in front of the computing nose 260 , so it can no longer be deflected by it.

By setting the stop disk 227 (by hand) to a specific command number, the switching pin 259 was brought into the following precisely defined position relative to the bell 223 : If, after the arrival of a start pulse 100, the bell 223 - driven by the synchronous motor 221 - begins to rotate, the switching pin 259 arrives directly in front of the control nose 260 at the moment at which the receiver receives the control command whose order number corresponds to the digit set on the switching disk 227.

The following should now be recapitulated:

1. If the switch 256 to be remotely controlled is to be switched on with a specific command number or left in the ON position, the transmitter emits a pulse during the time interval assigned to this command. The receiver set in motion by the start pulse 100 receives this pulse in its memory device and transmits it to the relay 212 at the moment when the switching pin 259 is in front of the control nose -260 * . The relay 212 is energized and releases the control rake 217 so that the latter rotates into the position shown in broken lines in FIG. The switching pin 259 consequently strikes the flank of the nose 260 of the control rake 217 and is thereby deflected upwards, so that it has to pass the switch 256 above the partition 261. It will be shown in detail later that this passage above the partition wall 261 results in a switch-on operation. If the switch 256 is already in the ON position, it is left in the ON position.

2. If, on the other hand, switch 256 should have a certain Command number are switched off, the transmitter issues this command during this assigned time interval does not emit a pulse. So the storage device cannot charging, the relay 212 is thus not energized. The tax rake 217 thus remains through the Lug 215 locked to armature 214 (i.e., in the position shown in full in Figure 2). Consequently the switching pin 259 remains unaffected by the computing nose 260. The switch pin 259 is so it is not deflected upwards and it passes the switch 256 below the partition wall 261. As will be shown later, this always has to be switched off or left in the OFF position of switch 256 result.

With reference to FIGS. 4 and 5, it will now be explained how the actuation of the remotely controlled Switch 256 takes place: The in F i g. 4 in perspective, the switch shown is in the OFF position. It has two fixed contacts 262 and 263 which are inserted into a housing 264. Between there is the movable contact 265, its arm 266, which can be tilted in two positions, in a cutting edge 267 of the contact pick-up 268 is pivotably mounted. The tilting arm 266 is folded over through the short arm 269 of the actuating lever 270 via the omega-shaped toggle spring 271. Here The actuation lever 270 can either be driven manually or remotely controlled by the switch pin 259. When switching by hand, the operating lever 270 on its arm 272 be easily grasped and thrown down. Together with the switch housing, the arm 272 serves at the same time as an easily recognizable position indicator of the switch position (Fig. 3).

When operated remotely, the switching pin 259 happens according to the recapitulation made is known to use the switch during an ON switching operation above the partition wall 261. The switching pin 259 detects the auxiliary lever 273, the is rotatably mounted about the axis 264 and with its extension 275 on the operating lever 270 attached pin 276 is coupled to the operating lever 270.

The Sc _t haltstift259 presses the auxiliary shift lever 273 to the left and thus via said clutch

ίο the part 277 of the actual operating lever 270 to the right, into the ON position shown in FIG.

Special attention should be paid to the fact that messages may arrive at the recipient

is ON commands for the main switch 256, which is the switch pin is already in the ON position 259 again passed the switch above the partition wall 261. He cannot do any switching operations so that switch 256 remains in the ON position. To switch OFF, i. H. whenever there is no ON command in the time interval corresponding to the set command number has been received, the switch pin 259 passes the switch 256, as is known, always below the Partition wall 261. The switch pin 259 detects the part 277 of the arm and pushes it to the left, see above that the switch flips back to the OFF position. Of course, the switch pin 259 happens to be his Switch in the absence of an ON pulse as well without changing anything when the switch is already in the OFF position. Since the Switch 256 can be designed as a changeover switch, it is of course easily possible to use a to connect a remotely controlled consumer or a remotely controlled device to its switch in such a way, that an OFF switch is assigned to a pulse and with each switch cycle an ON position takes place without a corresponding pulse.

1 sheet of drawings

209 524/266

Claims (7)

1 2 heavy current network are superimposed, with a receiving relay that responds to the claims: '... pulses and with a control relay that interacts with this relay 1. Device for receiving ripple control pulse selection device. command which in pulse trains after the 5 Such devices are already known. The pulse-liter-interval principle is coded, each of which is already known to a ripple control receiver, starting with a start pulse and then with at least one synchronizer in a predetermined time assignment, the rotating switching arm driven by a motor contains the individual control pulses and a strong one - remotely controlled switches are mechanically operated werstromnetz superimposed with a on the io den (Swiss patent 304518). There pulses responding receiving relay as well as the. Allocation of the command numbers for the 'remotely operated switch interacting with this relay in such a way that control pulse selection device, "characterized by means of a contact spring controlled by cams, that a device controlled by a relay at the end of those time intervals, pulse train controlled device ( 215, 217) to 15 which the desired command numbers according to BlocMerung of the receiving relay (212) provided, excited by the relevant control pulses and designed so that the relay can be through them, which relay then a deflecting member (212) only during the Times is released in to control the actuating member of the remote switch for the receiving device certain to be actuated switches released or not released. Control pulses can occur 2. Device according to claim 1, characterized in that the contact also has the task of bridging the blocking device of the memory arrangement in those time intervals to the receiving relay (212) as a control rake (217) during which no control pulses are formed, the at least one deflecting nose one characteristic of a pulse interval method (260) by means of which at least one pulse series is to be evaluated. The switch pin (259) when the control is unlocked closes and rake (217) when the control is unlocked, and when it passes it, it opens this contact and prevents it from being deflected towards the steering lug (260). ; the receipt of the start impulse a false one 3. Apparatus according to claim 1 or 2, charging of the storage arrangement and the nachdakter characterized in that the following discharge through the blocking 30 via the relay. Only when the device (215, 217) of the armature (214) of the time interval begins that corresponds to the command to be evaluated . Receiving relay (212) is blocked ... corresponds, the contact is made by the cam 4. Device opened after one of the previous targets and with it a loading and unloading Claims, characterized in that charging is made possible via the relay. the control rake (215, 217) on a leaf spring 35 is also from the Swiss patent is attached, through which the control rake 325 984 a ripple control receiver known in welin Direction of rotation is biased. chem a tax bill depending on the 5. Device according to one of the previous position of the relay armature \ temporarily in a defining claims, characterized in that th position is held (Swiss patent of the tax rake (215, 217) on his one 40 font 325984). In the Emp-end (228) described there is angled and that the anchor catcher is, however, the actual receiving relay (214) of the receiving relay (212) with an off not only actuated by the start pulse, but is equipped with a recess (251) which a rather also through all subsequent command ^ _, Nose (215) of the tax rake in the unlocking pulse. This has the consequence that the receiving relay ment occurs. · -...-. 45 through all following the start impulse 6. Device according to one, the preceding control command pulses excited and the relay armature in the claims, characterized .gekisiert that each control command pulse is actuated, namely the control rake (215, 217) by a on a regardless of whether the control command in question rotatable disc ( 223) arranged cam pulse is intended for the relevant ripple control (226) to unlock the armature (214) receiver or not. When is known. The receiving relay therefore reacts to the ten arrangement 7. Device according to one of the preceding- a large number of control pulses, whereby the claims, characterized in that, on the one hand, disturbing .noises .causes and on the other hand Receiving relay (212) both on the start side and on the other side, a high level of wear and tear on the moving parts is also generated in the case of command pulses via a glow tube 55. (211) is actuated, which in the relay circuit The invention is based on the object of a is arranged. Device for receiving ripple control commands of the type mentioned so that with associated with the operation of the receiving device 60 Noise and wear phenomena are particularly effectively suppressed. This task will according to the invention solved in that one of the The invention relates to a device for pulse train controlled device for blocking reception of ripple control commands, which are provided in the pulse of the receiving relay and so designed trains according to the pulse-interval principle encoded 65 is that through them the relay is only during the times begin with a start pulse and is enabled, in which certain control pulses can subsequently occur for the receiving device in a predetermined time allocation,
contain the individual control impulses and a major advantage of the described