DE1186535B - Receiver for remote switching systems that work according to the audio frequency pulse interval method - Google Patents

Description

Receiver for audio frequency pulse spacing Remote switchgear The invention relates to the formation of a receiver for after Remote switching systems using the audio frequency pulse interval method, in which a Drive synchronously running with the transmitter by the start impulse for a certain Time put into operation and the useful circuit only by one in a certain temporal Distance following command pulse is switched on. This has the effect that the receiver only responds to a second pulse representing a command pulse only responds to a certain time interval from the pre-pulse. They are remote switchgears became known who work with audio frequency transmission and where a synchronous motor is switched on and switched on by a cam contact for one revolution remain. The pulse selection for control purposes takes place in this known version by one or more cam disks. Among these are recipients became known for remote switchgear, in which audio frequency impulses the normal Light or heavy current network are superimposed and according to the known pulse spacing method work in such a way that all switching elements are addressed synchronously with a pre-pulse, but the desired switching commands are only effective for those receivers that fixed on the receipt of one or more at a precise time interval from the pre-pulse incoming switching impulses are set. Others of the known recipients are said to be a specific combination from a large number of combinations of switching pulses can be selected and thus used for a wide range of switching tasks can find. However, these known designs are for the subject The scope of the invention provided for too complicated and cumbersome, moreover they do not offer any guarantee for timely work.

The subject matter of the invention was compared to these known designs the special task underlying the receiver with a pulse spacing method to train operating remote switchgear so that the audio frequency signals given over the network both for arbitrary tax tasks and for hourly adjustment of Synchronous clocks can be used, with the adjustment signals for the clocks do not interfere with the arbitrary control signals for the receivers according to the invention are allowed to influence. A preferred area of application for switchgears with receivers according to the invention, for. B. the switching on and off of heating and air conditioning devices in the different classrooms of schools via the light network, via that too the signals for the hourly readjustment of the synchronous clocks in the classrooms walk. The individual receivers arranged in a light or high-voltage network according to the invention must therefore be selectively adjustable, i. H. at the time of their Effect be independent of each other and also be operationally reliable in a simple manner can be adjusted to the respective needs, not to mention that such receivers, which occur in a large number, are inexpensive to manufacture meant to be.

According to the invention, this is the case with the individual, for one after the other Pulse spacing method working receiver achieved in that one on the with the synchronous motor coupled drive axle seated, rotatable against it, key disc with a cylindrical rim selecting the command pulses and a notch is provided in it, through which when the command pulse arrives from the receiving magnet actuated lever with its approach passes through the after the command impulse has ceased, it rests on the inside of the edge of the key washer and to one that is independent of the command pulse and has a fixed relationship to the start pulse standing later point in time by a also sitting on the drive axle Switching element taken along for a specific duration that can be selected by its training and during this time it switches on the utility circuit by means of its lever. To the Prevention of interference pulses of insufficient duration takes place according to a development of the invention, the switching on of the synchronous motor on the part of the receiving magnet with the assistance of a two-armed lever, one of which is an arm in a section of a carrier disk that is also seated on the drive axle intervenes and taken along for the duration of the normal start impulse must, so that the motor switch is switched on even after the receiving magnet has dropped remain.

The switching element rotating synchronously with the transmitter control, which the duration of the switch actuation is determined after a further training of the Subject of the invention provided with approaches for the purpose of switching duration selection, which can be canceled for the purpose of defining a certain switching duration.

The following description describes an embodiment of the receiver explained in more detail according to the invention with reference to the drawings. In the drawings shows Fig. 1 the front view of the receiver in the rest position, i.e. before Reception of pulses, F i g. 2 the recipient according to FIG. 1 just before quitting of the start pulse, F i g. 3 the receiver in the position shortly after the end of the Start pulse, F i g. 4 the front view of the receiver at the time of the command pulse, F i g. 5 the same front view after actuation of the contacts for the utility circuit, F i g. 6 shows a partial section along line 6-6 in FIG. 1, Fig. 7 the timing diagram for the audio frequency pulses.

To operate the receiver according to the invention are the one Phase of a normal high-voltage network at certain time intervals 3500 hertz pulses, which are also used to set clocks, superimposed.

The time sequence of the signal pulses to which the connected Addressing the recipient is shown in FIG. 7 shown. The process is repeated periodically, namely the duration of a complete period is 1 minute. To the Actuation of a receiver are two signal impulses with a certain minimum duration and a certain time interval required. Are on a signal line If several receivers are connected, each one speaks to its own command pulse at. The "A" start impulse has a duration of 3.4 seconds. This impulse guides you Working cycle of all connected receivers. The "B" to "H" command pulses each have a duration of 3 seconds, and the distance between the starting points of two Impulse is 5 seconds. The "K", "L" and "M" symbols indicate the duration of the Closing time of the utility circuit assigned to the receiver, namely begins this closing time 50 seconds after the onset of the start impulse and can open a duration of 3.5 or 8 seconds is set in the receiver according to the invention will.

The mechanical structure of the receiver according to the invention is shown in FIGS. 1 to 6 shown. As an essential component, it contains a key disc 10 provided with a cylindrical edge which, after receiving a start pulse, executes a full revolution in one minute. A switching lever 20 controlled by a magnet 26 interacts with the key disc. Through a notch 10 a in the edge of the key disc, namely the approach 20 a of the lever 20 can pass if the lever is moved clockwise by the magnet 26 during a command pulse received at the same time. With the key disc rotates together with a cam provided switching member 30 which engages the shoulder 20a of the shift lever when the same is within the edge of the key disc. As a result, the switching lever 20 is carried along and the switch 40 in the circuit associated with the receiver is actuated by it. The angular position of the notch of the key disc 10 relative to the approach of the lever 20 in the initial position of the receiver determines which command pulse it responds to. Since the key disc is adjustable with respect to the switching element, but the latter is fixed with respect to the extension 20a, the associated useful circuit can only be closed 50 seconds after the start of the start pulse.

The receiver also has a base plate 11 to which the pivot pins 12, 13 and 14 and the synchronous motor 15 are attached (FIG. 6). A toggle lever 16 is rotatably seated on the pin 12 , on the arm of which a spring 17 is attached to the right, in order to preload the toggle lever in the counterclockwise direction (FIG. 1). The lever 18 following the toggle lever 16 on the pivot 12 has two angled lugs 18a and 18b. The downwardly extended lever arm of the lever 18 carries a bearing pin 18 c on which the intermediate gear 19 is rotatably mounted. Subsequent to the levers 16 and 18, a carrier disk-gear combination 21, 21 a is arranged on the pivot pin 12. Their gear 21a is in engagement with the intermediate gear 19. The carrier disk 21 itself has a cutout 21b. The key washer 10 and the switching element 30 are placed on the hub of the carrier disk. All parts mounted on the pin 12 are held on it by a knurled nut 22 . As already mentioned, the key disc has a notch 10 a in its upwardly bent edge. Furthermore, a plurality of radially arranged adjustment holes 10 b are provided in the inner surface of the key washer. A rearwardly bent nose 30 a of the switching element 30 can engage in these perforations 10 b. This penetrating nose engages in a bore 21 c on the front side of the carrier disk 21, whereby the position of the key disk 10 and of the switching element 30 and the carrier disk - gear - combination is fixed to one another. By loosening the knurled nut 22 on the pivot pin 12 there is the possibility of loosening the key disc 'from the carrier disc 21 and bringing it into a new angular position, the individual angular positions being determined by the distance between the holes 10 b. The nose of the switching element 30 also defines its position in relation to the carrier disk gear 21. Since the command pulses are separated from one another by 5 seconds and the key disc 10 moves at a speed of one revolution per minute, the perforations are provided at an interval of 30 °. The position of the holes opposite the notch 10a in the edge of the key washer is chosen so that the notch can be adjusted depending on the setting of the key link 90, 120, 150, 180, 210, 240 or 270 ° away from the point at which the Approach 20 a of the shift lever 20 can fall into the notch 10 a. The individual angular positions correspond to the respective key combination for receiving the command impulses.

On the second pin 13 attached to the base plate 11 , the two-armed lever 23 rotates, which is biased counterclockwise by the spring 24 and cooperates with the cutout 21 b in the carrier disk 21 or serves as a pawl. The upper end of the lever 23 lies in the area of action of the angled extension 18 a of the lever 18. The lever 18 and also the toggle lever 16 are rotated clockwise when the armature 25 of the magnet 26 is tightened by pulling it against the edges of the upper arms of the toggle lever 16 and the lever 18 pushes. The anchor is always attracted when a signal is given on the line. As a result of the clockwise rotation of the lever 18, its approach 18 b acts on the switch 27 and also brings the intermediate gear 19 into engagement with the gear 28 on the shaft of the synchronous motor 15. The rotation of the toggle lever 16 is clockwise via the connected articulated arm 29 the shift lever 20 transferred so that it also rotates clockwise. The resilient articulated connection 31 between the articulated arm 29 and the switching lever 20 allows the latter to follow the movement of the articulated arm only as long as the pivoting movement of the lever 20 is not stopped. The switch 27 brings the synchronous motor 15 to run.

Since the synchronous motor 15 is switched on with the excitation of the magnet 26, a drive of the gear 21 a of the carrier disk combination 21 takes place from the gear 28 via the intermediate gear 19, whereupon it rotates in the counterclockwise direction. During the start signal, the carrier disk 21, the key disk 10 and the switching element 30 rotate into the positions shown in FIG. 2 position shown. During this time, the magnet is excited, the motor 15 rotates, and the lever 23 moving around the pin 13 has emerged from the recess 21 b of the carrier disk 21 . The lever 23 is rotated clockwise so that it presses against the shoulder 18 a of the lever 18 and holds and secures this in its position assumed in the clockwise direction. As a result, the motor switch 27 actuated by the lever 18 remains closed and the motor circuit is maintained; the gears 19 and 28 likewise remain in mesh with one another. With the lever 18 , the toggle lever 16 as well as the switching lever 20 have been moved, the extension 20 a of which lies resiliently against the outer edge of the key washer 10. In this position, the finger 20 b of the switching lever 20 cannot yet act on the switch 40 assigned to it, which is also in the useful circuit of the receiver.

When the start pulse is interrupted, the parts take the parts shown in FIG. 3 position shown. Although the armature 25 has fallen off, the switch 27 is kept closed by the action of the lever 23 on the lever 18, so that the motor circuit is maintained. The gear wheel connection 19, 28 is also maintained. Upon receipt of a command pulse to which the receiver is timed, the key disc 10 has moved to the position shown in FIG. 4. moves, in which the notch 10 a is opposite the approach 20a, so that when the magnet 26 responds, the shift lever approach moves under the action of the toggle 16 clockwise so far that it passes through the notch and counteracts when the key disc is turned further the inside of its edge lays. With further rotation of the key disc of the approach of the shift lever therefore grinds on the inside initially still without through his fingers 20 b to close the switch 40th

As the rotation continues, the cam 30 b finally engages the switching element 30 under the shoulder 20 a of the switching lever and pivots the latter inward about its pivot point 14 (FIG. 5). During this pivoting movement, the switch 40 is closed by the finger 20 b. When this is closed, the useful circuit assigned to the receiver becomes effective.

In order to be able to change its closing duration, the action of the cam 30b is lengthened by separate projections 30c and 20d. These approaches can be broken away individually, so that a variable fall time for the lever 20 is created. The cam 30b alone corresponds in its effect on the shift lever to a duration of 3 seconds. The two tabs 30 c and 30d together correspond to a duration of 5 seconds so that the complete cam 30 b, 30 c and 30d together results in a period of 8 seconds. The useful circuit is always closed 50 seconds after the key disc 10 has started to rotate. When the key disc is turned further, the receiver is finally returned to its starting position (FIG. 1). The shift lever 20 sliding on the inside of the key disk emerges from the notch at a given time, and as soon as the cutout 21 b of the carrier disk 21 is opposite the lever 23 , it can be moved counterclockwise by its spring 24 and thereby reaches the front his neckline. This frees the lever 18 and allows it to move counterclockwise so that the gears 19 and 28 are separated from one another.

At the same time, the motor circuit for the synchronous motor is interrupted by opening switch 27. The lever 23 cooperating with the cutout 21 b is blocked at the same time, so that the released and moving levers can return to their initial position.

An important task of the lever 23 and the lever mechanism interacting with it is to render interference pulses ineffective. If z. B. an interference pulse with the signal frequency is received as long as the receiver is in the initial position, the magnet 26 is indeed excited and its armature 25 is attracted. This means that the receiver begins to run, whereby the lever 23 is moved clockwise. However, since an interfering pulse has a shorter duration than the minimum duration of 3.4 seconds required for the receiver, the lever 23 has not yet been moved so far that it can act on the lever 18 as soon as the excitation of the magnet 26 ceases . The cutout 21 b in the carrier disk 21 for the lever 23 is designed in such a way and the cooperation of the same with the lever 18 also takes place in such a way that the magnet 26 must be excited for at least 3.4 seconds in order to achieve that the carrier disks gearwheel Combination 21 rotates through a sufficient angle to move the lever 23 out of the cutout 21 b. Accordingly, the receiver can only be set in continuous rotation by a start signal of a minimum duration of 3.4 seconds and is immediately returned to its starting position when a signal of a shorter minimum duration is stopped.

When a start pulse is received, all receivers are first addressed and set in motion in the manner explained. They complete their rotation within a minute. Only those receivers whose key disc is set to one of the intended command pulses are ready to receive and close the utility circuits assigned to them at a given time. For all other, unselected recipients, the notch 10 a of the key disc is in a different angular position to the approach 20 a of the control lever 20 when the command pulse is received. In such a case, the control of the shift lever acting on the switch 40 cannot take effect. Should anyway (as a result of an interference pulse) of the neck 20a for a short time to pass through the notch of the key plate so 31 of the erroneously permeated projection 20 returned a of the lever 20 from the inside to the outside of the edge of the key washer under the pressure of the resilient hinge connection, so that an interaction n-it the switching element 30 for closing the switch 40 cannot come about.

Claims (4)

Claims: 1. Receiver for remote switchgear operating according to the audio frequency pulse spacing method, in which a drive that runs synchronously with the transmitter is put into operation by the start pulse for a certain time and the utility circuit is only switched on by a command pulse following at a certain time interval, marked thereby et that one on the drive shaft (12) coupled to the synchronous motor, seated against it, rotatable against it, the command pulses selecting key disc (10) is provided with a cylindrical edge and a notch (10 a) through which when the command pulse arrives a from Receiving magnet (26) actuated switching lever (20) with its approach (20 a) passes, which after the command pulse has ceased, initially rests on the edge of the key disc inside and at a later point in time that is independent of the command pulse and has a fixed relationship to the start pulse through a also on the Drive axle seated shift g Song (30) is taken along for a certain duration, which can be selected by its training, and during this time it switches on the utility circuit by means of its lever. 2. Receiver according to claim 1 with structural measures to prevent interference pulses from taking effect of shorter duration than the start pulse, characterized in that the switching on of the synchronous motor (15) on the part of the receiving magnet (26) takes place with the assistance of a two-armed lever (23), one of which Arm engages in a cutout ( 21b) of a carrier disk (21 ) also sitting on the drive shaft (12) and has to be taken along by this for the duration of the normal start impulse so that the motor switch (27) remains switched on even after the receiving magnet has dropped. 3. Receiver according to claim 1, characterized in that if the duration of the command pulse is not sufficient, the shift lever attachment (20 a) is returned under the pressure of the resilient articulation (31) from the inside to the outside of the edge of the key washer. 4. Receiver according to claim 1, characterized in that the switching element (30) on its cam (30 b) lugs (30 c, 30 d) which determine the duration of its action on the switching lever (20) and for the purpose of fixing a certain switching duration can be interrupted., Publications considered: German Patent Nos. 815 662, 877 342; Austrian Patent Nos. 167 803, 176 899; Swiss Patent No. 194 016.