NO147371B - MEASURES TO PROTECT WOODWOOD AGAINST SUSPENSION, AND USE OF THE AGENT - Google Patents

Description

Stage lighting system.

The present invention relates to a stage lighting system preferably for television or film studios, but also applicable for theater stages.

In stage lighting systems, one of the most important parts is the control equipment. Various systems have been used here, such as mechanically driven induction regulators (turn transformers) which are often rather bulky and bulky, or transformers with outlets (tap transformers) which offer poor possibilities for continuous variation of the brightness. When the transducers arrived, it became possible to provide a very convenient regulation by means of potentiometers connected to the transducers' control circuits, and by doubling the potentiometers and the use of so-called overblenders, a satisfactory continuous regulation was achieved and possibilities for producing the different light acts. However, the current from the transducer is not a pure sine current, the sine waves being cut off; this means that acoustic overtones arise in the lamps' filaments, which are focused on the stage by the spotlights' reflectors. In the case of normal theater facilities, this is of no importance, as the overtones are however so weak that they are not audible in the audience seats. In television studios, on the other hand, where the microphones are located directly above the stage and the spotlights close by, such acoustic noise can be very annoying.

The invention relates to a stage lighting system which is based on tap transformers which provide pure sinusoidal voltages and currents for feeding the spotlights and at the same time an equally convenient and perfect regulation option as a transducer system.

The stage lighting system according to the invention is distinguished by the fact that each light group is connected between the outlets of two series-connected outlet transformers which are connected in parallel with a so-called over-mixer for continuous switching on and off of one or the other of the transformers, and that switching means controlled by the over-mixer are arranged for short circuits -ning of the transformers' output sides in such a way that one of the two transformers is short-circuited both on the primary side and on the secondary side when the overmixer is set in an extreme position.

The combination of two transformers

and an overmixer allows presetting of light effects and continuous transition between such light effects, and the coupling means means that the light group is only fed from a transformer when the overmixer is in its final position; thereby it is achieved that the pre-setting of the second transformer can be carried out without disturbing flashes of light occurring.

Appropriately, the light groups are connected to the outlets via binary relay systems, which provides a convenient structure for the regulation system and at the same time makes the system well suited for automatic operation controlled from a long-term memory, such as by means of a punch card system.

Admittedly, in stage lighting systems it is known both to use tap-off transformers and to connect the light groups with these by means of binary relay systems which are controlled by punch card systems, but the previously known constructions are based on principles which do not allow continuous regulation.

The invention will be explained in more detail with reference to the drawing, where fig. 1 shows a schematic diagram of a control circuit for a light group according to the invention, while fig. 2 shows the more complete design of such a regulation system which is suitable for automatic operation.

Fig. 1 shows a light group 1 which is fed from an alternating voltage source 6 via two transformers 3 and 3' which in the example shown are spare-connected transformers. Instead of spare-coupled transformers, any other form of transformer can of course be used, but the spare-coupled transformers enable a very simple solution in this case. The light group's connecting terminals are connected to outlets on each of the transformers 3 and 3', which are connected in parallel with a so-called overmixer 4 in the form of a potentiometer, whose movable contact 5 is connected to the connection point between the two transformers. In the drawing, the connector 5 is shown in a half-turn position; the light group 1 is impressed by the sum of the secondary voltages from the two transformers which in turn are fed from the AC voltage source 6 with voltages that relate to each other in the same way as the two parts of the potentiometer 4. When the movable contact 5 is in the end position, it is corresponding transformer short-circuited; lighting group 1 is then only fed by the secondary voltage from the other transformer which in turn is supplied with the full alternating voltage 6.

Pre-setting of the transformer, i.e. the connection of one terminal of the light group 1 with the desired outlet on the transformer, should take place when the contact 5 is in the corresponding end position and the transformer is thus short-circuited.

In order to avoid disturbing flashing when the light group clamp is moved from one outlet to another, contacts 2 and 2' are connected, which are controlled by the movable contact 5 in such a way that in its end positions it closes the relevant contact 2 or 2'. When contact 5 is in one of its end positions, the lighting group will thus be connected to one transformer partly over the outlet on this transformer and partly over the respective contacts 2 or 2', while the other transformer is completely disconnected both on the primary and on the secondary side. In this way, you can freely operate with the thus disconnected transformer without disturbing the lighting system. The transformer preset in this way is then switched on continuously by moving the movable contact 5 from its end position to the other, during which the brightness changes linearly from the setting on one transformer to the setting on the other.

Fig. 2 shows a more detailed design of a plant according to the invention. The designations 1-6 have the same meaning as in fig. 1. The lighting group 1 is connected to the transformers 3 and 3' via binary relay systems which include the relays 7, 8, 9 respectively. 7', 8', 9' which can be push-button controlled, such as the relays 7', 8' and 9' which are controlled by a contact system 12'. It is more convenient, however, to use a system of sliding contacts 12. This consists partly of a contact arm 121 with three contact pieces 125 and partly of a contact rail 122 for each relay, and corresponding contact points 123. From the figure it appears that the relay system 7, 8, 9 re- runs through all its possible settings if the contact arm 121 is moved from below upwards. On the right side of fig. 2 shows how the transformer 3' is connected if all the relays 7', 8' and 9' are in their lower position, i.e. disconnected. Instead, the light group is connected to the AC voltage source 6 via a sliding resistor 11'. The disconnection of the relays can, as shown, occur independently of the contact system 12' by opening the contacts 10'. By the fact that the resistor 11' is connected via two connection terminals 111 and 112, it is implied that the resistor 11' can be common to several circuits, i.e. that a smaller number of resistors 11' are available for connection in the circuits where they are desired.

On the left side of fig. 2 shows how this principle can be further developed by the resistor 11 being remote-controlled. Here, the resistor is connected across the terminals 113 and 114 and is provided with control terminals 115 and 116 which are connected to a potentiometer 124 which is integrated with the contact system 12. In this case, the contact system 10 becomes a necessity to connect the relays 7, 8 and 9 from the voltage source 13 regardless of the contact arm's 121 position. By suitable dimensioning of the resistor 11 and the potentiometer 124 in relation to the outputs of the transformer 3, it can be achieved that the setting of the resistor at

using the potentiometer 124 will correspond

the one obtained by means of the binary relay system and the contact system 12. On this

way, a continuous setting can be made using the potentiometer 124,

while the contact system 10 is open, after which by closing the contacts 10 you can

connect the light group across from resistor 11

to the corresponding outlet on the transformer 3 without any appreciable being seen

change in brightness. In this connection, it should be noted that the supply of the light group via the resistor 11 is not loss-free, so that the supply via the resistor 11

should only be used briefly for setting.

The device according to the left side of fig.

2 is particularly suitable for automatic operation of

the plant, for which purpose the clamps 14

is arranged for the extraction of the voltages on

relay coils 7, 8 and 9. For this, a punch card system can be suitably used,

in that the clamps 14 are connected to the punch card system in such a way that during programming the clamps 14 are connected to the punch card system's punching device, while during the performance they are connected to the punch card system's scanning contacts.

Also in this case the resistance can

11 be of importance, as one by opening

the contacts 10 can disconnect the automatic regulation and switch to manual control using the potentiometer 124 and

the contact arm 121 and in that way grip

into a prearranged light variation program.

Appropriately, the punch card system can

record a code for controlling the overlays,

so that cross-fading can also occur

automatic.

Claims (6)

1. Stage lighting system, characterized by the fact that each lighting group is let between outlets on two series-connected outlet transformers which are connected in parallel with a so-called overmixer (i.e. a potentiometer, whose movable outlets are connected to the connection point between the transformers), and that the lighting group's two clamps over contacts are connected to the connection point between the secondary sides of the transformers, which contacts are controlled of the overmixer in such a way that it closes the relevant contact in its end circuits. 2. Installation according to claim 1, characterized in that the lighting groups are connected to the transformers via binary relay systems. 3. System according to claim 2, characterized by a long-term memory, preferably a punch card system, which is connected to the binary relay systems for programming from, respectively control of the relay systems. 4. Installation according to claim 1, characterized by an additional outlet in connection to each outlet transformer for connecting the lighting circuit with the network via a variable resistance. 5. Installation according to claims 2 and 4, characterized in that the control of the binary relay systems is synchronized with the setting of the corresponding variable resistors for analog setting of the aforementioned pair of components, and that for each such pair of components a contact system is arranged for alternative connection of the lighting circuit in question to one of the components. 6. Plant according to claim 3, characterized in that the long-term memory contains a code for controlling the overmixers.