DE1087242B - Group selection receiving device for remote control systems working according to the pulse interval method, especially for ripple control systems in networks for the distribution of electrical energy - Google Patents

Description

Group selection receiving device for remote control systems working according to the pulse interval method, in particular for ripple control systems in networks for the distribution of electrical energy The subject of patent 1066 265 is a group selection receiving device for remote control systems operating according to the pulse interval method, in particular for ripple control systems in networks for distributing electrical energy, in which receiving devices operate the remotely operated switches by servomotors , in which the synchronous motor for driving the receiver selector and for the servomotor actuation of the switches to be remotely operated is installed in a drum that can be rotated about its axis, on which drum at least for each remotely actuated switch to different group dial numbers, as well as to the different command numbers adjustable selection and actuating organs are arranged are.

The embodiments described in the main patent relate to group dial receiving devices for simple group selection, in which after the start pulse per revolution of the encoder device only a single group dialing impulse can be given. It is now in and of itself known that by multi-digit group selection the number of independent Double commands can be enlarged.

It is also known that the security of central control systems in terms of faultless switching can be increased by removing the receiving apparatus Equipped with organs that only allow effective switch actuation when very specific combinations of active pulses and pulse gaps at the receiver arrive.

The invention now relates to an extension of the main patent known group dial receiving device with which the above listed, to and advantages that are also known per se can be realized in the simplest possible manner. The invention is that in the group dial receiving device after Main patent on the drum at least one adjustable to certain pulse intervals Locking device is arranged, which blocks the function of all other preselection devices, provided that a control pulse occurs during the time interval to which the blocking element is set arrives at the recipient.

Advantageously, the locking member is designed as a ring on the the drum is fixed tangentially adjustable and the one with one pivotable mounted cradle attached U-shaped, deflectable locking spring interacts.

The invention is explained in more detail, for example, with reference to the drawings. 1 shows a mechanical embodiment of the locking members attached to the drum in the neutral position; Fig. 2 shows the same locking members, seen from A-A; 3 shows the locking members in the locking position; Fig. 4 shows the same locking members in the locked position, seen from A-A, and Fig. 5 shows a pulse-time diagram for multi-digit group selection.

1 shows the drum 227 of a group selection receiver, which is rotatable about its axis 256 and in which a synchronous motor with gear is installed in a known manner for driving this drum. The selection ring 251 and the group selection ring 291 sit on the drum, each individually tangentially displaceable. This means that the switching pin is locked in its neutral plane 1V and that the associated main switch (not shown) cannot be operated even if the drum 227 rotates, unless the aforementioned lock is released. As has been described in detail in the main patent, this lock can be released by a so-called group selection pulse, in that this group selection pulse excites the relay 214 (see Fig. 2), whereby the relay armature 216 releases the lock 217, 231 with the pivotable control rake 218, so that the latter pivots under the influence of the tension spring 219 in the direction of the arrows a drawn by a few degrees. As a result, the nose 39 of the control rake 218 comes to lie directly in front of the cam 39 'fastened on the group selection ring 291 (see FIG. 3). When the drum 227 continues to rotate, the cam 39 'strikes the nose 39, as a result of which the locking of the switching pin 271 with the arm 34 is released. Under the influence of the bronze spring 261, the switch pin in this case moves from the neutral plane N to the switch-off plane A. The actual switch actuation can now take place, as described in the main patent, when the switch pin 271 is triggered by the actuation pulses arriving at the receiver with the aid of the relay 214 , the control rake 218 and its deflecting nose 281 are left in the switch-off level A or steered into the switch-on level E, as desired.

The locking members 151, 152 mounted on the drum 227 and on the control rake 218 can now prevent the unlocking of the actuating pin 271 of the boom 34 when locking pulses arrive, even if the group dialing pulse reaches the receiver correctly. The prevention of this unlocking means, however, according to the explanations given above, a complete prevention of any switch actuation. The mechanical design and the mode of operation of the locking elements 151, 152 is described below: A ring 151 is fastened to the drum 1227 with four screws 153, for example. This ring 151 is kept smaller from p to q in relation to the outer diameter than from q via y to p. At q the ring is equipped with a curved nose 154. The control rake 218 carries a U-shaped curved locking spring 152 on a bracket 155. This locking spring 152 is tensioned so that its free end 156 lies on the side of the arrow f of the ring 151 in the receiver zero position. On the other hand, the free end 156 is still in the area of the bent nose 154, but only when the control rake 218 is not locked on the relay 214, that is, when it is in the position shown in FIG.

Let us now assume that the receiver has been started by a start pulse 100 so that the drum 227 rotates in the direction of arrow C. The control rake 218 has already been returned to the position shown in dashed lines in FIG. 2 by the cam 301 of the drum 227 and has been locked in this position by the relay 214. Immediately after the start pulse, the transmitter emits a blocking pulse s1 (see FIG. 5). The relay 214 is energized in a known manner by this blocking pulse, which unlocks the control rake 218, so that, under the influence of the tension spring 219, it moves into the position shown in FIG. In this way, the free end 156 of the U-shaped locking spring 152 was steered into the area of the bent nose 154. As the drum 227 continues to rotate, the free end 156 of the locking spring 152 is caught on the lug 154, and it is directed to the other side of the locking ring 151 in the direction of arrow g. Since the diameter of the locking ring 151 increases again at q, the free end 156 of the locking spring 152 remains locked on this other side of the locking ring 151, regardless of the current position of the control rake 218, which has already been returned to the dashed line by the cam 302 Drawn position (Fig. 2) has been brought.

This so-called blocking position of the blocking spring 152 is clear in FIG. 3 recognizable. It has the consequence that with all now arriving control pulses the relay 214 probably energized and the lock 217/213 of the control rake 218 released will. On the other hand, the control rake 218 cannot rotate in the direction of the arrows a, because the free end 156 of the locking spring 153 in each case on one of the cams 301, 302 etc. sits on. This seating on the cam 307 is clear in FIGS. 3 and 4 recognizable. As a result of this call sitting, the nose 39 can despite the arrival of a the group dialing pulse matched to the group dialing ring 291 does not enter the area of the cam 39 'arrive (see. Fig. 3). As a result, the switching ring 271 remains locked in the neutral plane N. That means it can be used during the im Once the drum has started rotating, no main switch operations are carried out.

Finally the point p of the locking ring 151 reaches the locking spring 152. This has the consequence that the free end 156 of the same moves under its own spring force again in the direction of the arrow f, whereby the locking is canceled. It is essential that the point p of the locking ring 151 is arranged so that no more group dialing pulses are sent during one encoder cycle of the transmission system when the point p of the locking ring 151 has released the locking spring 152, 156 again during the corresponding rotation of the drum 227. After this release, any control pulses that may still arrive cause the control rake 218 to pivot, but no switch actuation because the switch pins 271 on the group selector ring 291 are locked in the neutral plane N and this locking occurs during the described drum rotation due to the action of the locking elements 151, 152 could not be resolved.

It is assumed that when the transmitter device of the transmitter system runs the next time the described group dialing receiver has to operate a switch effectively. For this purpose, a start pulse 100 causes the drum 227 to start up in a known manner. During the time interval immediately following the start pulse, the transmitter does not give any pulse this time (pulse gap). Furthermore, no interference pulse arrives at the receiver during this time interval.

This has the consequence that the control rake 218 wiedere immediately after starting of the drum 227 by the cam 301 returned to the dashed lines in FIG. 2 drawn position and is locked in this position by the relay 214th Since during the pulse interval that immediately follows the start pulse, this time no control or interference pulse arrives at the receiver, the aforementioned locking of the control rake 218 remains on the relay 214 at least until the nose 154 of the locking ring 151 has passed the locking spring 152. Because the locking spring 152 is in the position shown in dashed lines in FIG. 2 when it passes the lug 154, the free end 156 of the locking spring does not strike the lug 154. It is therefore not deflected to the other side of the locking ring 151, but remains on the side of the arrow f of the locking ring 151 during the entire following drum rotation. Since the drum 227 has no cams 301, 302 etc. on this side of the locking ring 151, the pivoting movements of the control rake 218 are not inhibited by the locking spring 152. That is, the recipient can normally receive a following group dial pulse. This time he works exactly like the group dial recipient described in the main patent.

In the description so far, the action of a blocking pulse is s1 has been described on the group dial recipient. It was assumed that the blocking pulse s1 immediately follows the start pulse.

With reference to Fig. 5 will now be shown that the blocking pulse can also be sent during other time intervals.

For example, out of a total of 22 pulse intervals, five can be provided for blocking pulses, seven for group selection pulses and ten for actuation pulses. This results in a total of 5 - 7 - 10 = 350 independent double commands. In the pulse-time diagram shown in FIG. 5, the start pulse 100 can be seen, which causes the synchronous motors and thus the drums 227 to start up in all receiving apparatus. This is followed by five pulse intervals s1, S2. . . s5 for five blocking pulses 141, 142 ... 145. Of these five blocking pulses, at least four blocking pulses must always be given per encoder cycle so that only those recipients who are assigned to the same blocking group with regard to the blocking pulses can evaluate a subsequent group selection pulse. In the example described, five different blocking groups are possible in that one of the five blocking pulses is not sent in each case. The blocking pulses are followed, for example, by seven time intervals a, b, c, d, e, f and g for group selection pulses 131, 132 ... 137, through which seven normal groups can be distinguished in a known manner within each of the five blocking groups. So there are a total of 5 - 7 = 35 groups. With the help of the ten following time intervals 1, 2, 3 ... 10 for the actuation pulses, ten double commands can finally be distinguished from one another in a known manner within each of the 35 groups, so that finally the 350 mutually independent double commands result.

It goes without saying that all time intervals are also divided up differently possible in blocking, group selection and actuation impulses. Practically particularly advantageous are in this regard two blocked groups and ten normal groups with ten double commands each, because a decimal system can be realized with this division.

If certain receivers are to be set to a blocking group other than blocking group s1 (as shown in FIGS. 1 to 4), the blocking ring 151 is to be rotated clockwise after loosening the four screws 153 relative to the drum 227 until the curved nose 154 is located behind the corresponding cam 302, 303, 304, etc. (for locking group s2 behind the cam 302, for locking group s3 behind the cam 303, etc.). With the aid of the holes 153 'pre-drilled in the locking ring 151, the locking ring 151 can be screwed tight again in the desired position.

The functions are exactly the same as for the locking grip s1 is described in detail. The locking ring 151 can also use instead of screws 153 Locking springs are attached to the drum 227, with which the setting of the Lock ring is simplified to different lock groups.

Receivers equipped with the locking device described are also advantageous because they do not respond to so-called continuous glitches with faulty switching react. A continuous glitch can start the receiver, it causes but shortly afterwards a deflection of the locking spring 152, causing further glitches can no longer cause the receiver to execute circuits, too then not if these glitches stop while the drum is rotating.

It is also possible to equip one and the same receiver with several locking rings 151. These can be carried out independently of one another and can be set to specific time intervals. All conceivable combinations can be implemented in this regard. One of these should be explicitly mentioned as an example. If one sees five pulse intervals for blocking pulses in the pulse-time diagram and one equips the receiver with two blocking rings 151 'and 151 ", the blocking spring 152 can through the lugs 154' and 154" of the Both locking rings are guided in such a way that a receiver is only ready to switch in the event of a group dialing pulse following the locking pulse if there are two precisely timed pulse gaps after the start pulse. In this way, with five pulse intervals for blocking pulses instead of just five blocking groups there are ten, namely for the following pulse gap combinations: S1 S2 S1 $ 3 S2 S3 S S4 S S3 S4 Si 3 5 S2 S5 S3 S5 S4 S5

Claims (7)

PATENT CLAIMS: 1. Group selection receiving device according to patent 1066265, characterized in that at least one blocking element (151, 152) which can be adjusted to specific pulse intervals and which blocks the function of all preselection elements (34, 39, 39 ', 291), is arranged on the drum (227) provided that a pulse arrives at the receiver during the time interval to which the blocking element is set. 2. Device according to claim 1, characterized in that the functions of all preselection bodies (34, 39, 39 ', 291) are blocked if control pulses during the time intervals to which the locking devices are set arrive at the recipient. 3. Device according to claim 1, characterized in that that the functions of all preselection organs (34, 39, 39 ', 291) are blocked, provided that interference pulses occur during the time intervals to which the blocking devices are set arrive at the recipient. 4. Device according to claim 1, characterized by a on the drum (227) tangentially adjustable locking ring (151), which has a deflecting nose (154) carries which deflecting nose (154) with a cradle (218) that can be swiveled arranged locking spring (152) cooperates in such a way that on the one hand when timely Arrival of a blocking pulse the Lock spring (152) through a this blocking pulse caused pivoting of the cradle (218) in the area of the Auslenknase (154) arrives and that the locking spring (152) through this Auslenknose (154) is deflected so that further pivoting of the cradle (218) by the locking spring (152) can be prevented mechanically, and on the other hand if the timely Locking pulse, the locking spring (152) does not reach the area of the deflecting lug (154), whereby it is not deflected and thus the further swiveling of the cradle (218) not prevented. 5. Device according to claims 1 and 4, characterized in that the locking spring (152) reaches the area of the drum (227) mounted cams (301, 302, 303 etc.) after the deflection by the deflecting lug (154) and each time the cradle (218) is unlocked for the reception of a group selection pulse by a relay (214), it hits a cam (301, 302,...), whereby an effective pivoting of the cradle (218) for actuating the preselection members (34, 39, 39 ' and 291) is prevented. 6. Device according to claim 1, characterized characterized in that the adjustable locking member (151) is designed as a ring, to adjust to different blocking impulses in different angular positions the drum (227) can be screwed tight. 7. Device according to claim 1, characterized characterized in that the adjustable locking member (151) is designed as a ring, which is attached to the drum (227) with at least one detent spring, and in such a way that it is used to adjust to different blocking pulses in different Angular positions on the drum, (227) can be locked. Considered Publications: German Patent No. 653 842.