DE4001811A1 - Controlling intensity of individual halogen lamps in installation - using IR radiation to carry digital addresses and commands to receivers in lamps - Google Patents

Abstract

Several halogen lamps are connected in parallel at a common cable pair and supplied from the same central power source. A central transceiver is also connected to the cable and uses infra-red radiation to send serial digital address and command data to decentralised receives at the lamps. A lamp's receiver decodes the data and uses the commands to control the power delivered to its lamp by a power regulator. Address and command data may be sent from lamp to lamp along the chain using decentralised transceivers in the lamps. The nearest lamp receives the commands first and the most remote, last. A lamp's transmitter turns on after its receiver has turned off.

Description

The invention relates to a method in the preamble of claim 1 Art.

Halogen lamp lighting systems have been used for some time steme an increasing spread, being disadvantageous it is felt that all lamps of a lighting systems can only be controlled together, d. H. on or off are switchable and their brightness can be regulated.

It is therefore the task of a process for indi visual control of the brightness of the individual lamps at least one halogen lamp lighting system create.

This object is achieved according to the invention by a method according to claim 1.

This procedure becomes simple and reliable individual control of the brightness of the individual lam halogen lamp lighting system, without a separate power supply for each lamp or own, complex wiring would be required. Due to the miniaturization of the elec  tronic circuits which are necessary for the implementation of the Procedures are needed, these can be easily in the housing of the individual halogen lamps integrated the. The additionally required central broadcast and Receiver unit can also be made very small the and therefore occurs within the lighting system not disturbing in appearance.

Preferred refinements and developments of Ver driving are specified in subclaims 2 to 11.

The characteristics of one for performing the procedure suitable device arise logically from the ver driving claims and from the following description Exercise two embodiments with reference to the accompanying Drawing.

The figures in the drawing show:

Fig. 1 (block diagram 1 ) a first device for performing the method and

Fig. 2 (block diagram 2 ) a second device for performing the method.

Like the FIG. 1 is removed, which consists here Darge presented embodiment of the apparatus for imple out the process of two parallel steel cables which constitute a wire pair, which to an opposite wall ver runs from one wall bounding a space. The two wire ropes are supplied at their right end in FIG. 1 by a power supply unit with the voltage required for operation, usually a low voltage of 12 V. Connected to the wire rope pair are, on the one hand, a central transmission and reception unit ZSEE and several decentralized transmission and reception units SEE 1 , SEE 2 , SEE N. The central transmission and reception unit ZSEE are connected via a control line e.g. B. from a microprocessor from information that is required for the individual control of the brightness of individual halogen lamps. Within the central transmission and reception unit ZSEE, this information is processed and emitted as serial digital address and command data via a first transmission diode SD as an infrared beam to the first, nearest decentralized transmission and reception unit SEE1. This first decentralized transmission and reception unit SEE1 receives the incoming infrared beam via a suitable infrared sensor EE, decodes the address and command data contained therein and, in response, transmits the decoded command to a power controller assigned to the associated halogen lamp. This Lei power controller, the associated halogen lamp and the associated decentralized transmitting and receiving unit SEE 1 are preferably combined in a common housing to form a structural unit and, as known from previous halogen lamp lighting systems, can be connected to the wire rope pair at practically any point.

Regardless of whether the first decentralized transmission and reception unit SEE 1 has been addressed or not, it continues to perform an intermediate amplification of the received address and command data and, after a predeterminable time delay, also emits this as an infrared beam via its own transmission diode the second decentralized transmission and reception unit SEE 2 . This process is repeated in this second decentralized transmitting and receiving unit SEE 2 and in all other decentralized transmitting and receiving units SEE N, so that little by little the address sent by the central transmitting and receiving unit ZSEE - and command data to all decentralized transmit and receive units of the lighting system. To avoid feedback within a transmitting and receiving unit, it is provided that the associated infrared sensor is switched off during the transmission operation. Alternatively, polarized infrared radiation can be used to avoid feedback, in which case the direction of polarization changes from transmission path to transmission path.

Since suitable circuits for processing, the Codie sending, receiving, delaying time and converting such address and command data per se are not known on these details here discussed in more detail.

Referring to FIG. 2, a second embodiment of a pre also apparatus for carrying out the method of a tensioned wire pair with a central power supply, a central transmission and reception unit ZSEE as well as several decentralized transmission and receiving units A SEE 1 to SEE N Here, too, the central transmission and reception unit ZSEE and the central transmission and reception units SEE 1 to SEE are connected to the common wire rope pair. In contrast to the above-described embodiment, the central transmitter and receiver unit ZSEE not only has a transmitter diode but an arrangement of several transmitter diodes which form a diode chain, the length of which corresponds approximately to the distance between the wire cables of the wire cable pair. An infrared beam with a considerable width is thus generated here, which extends in the direction of the associated decentralized transmitting and receiving units SEE 1 to SEE N. In order to avoid the fact that the more remote decentralized transmit and receive units are shadowed by the decentralized transmit and receive units closer to the central transmit and receive unit ZSEE, the decentralized ones are in this embodiment Transmitting and receiving units SEE 1 to SEE N are designed as bodies that are transparent to infrared radiation. This ensures that even the most distant decentralized transmitting and receiving units can still be achieved with a sufficient strength of infrared radiation from the central transmitting and receiving unit ZSEE.

As an alternative or in addition, in the individual decentralized transmitting and receiving units SEE 1 to SEE N, the infrared sensors EE can also be spatially staggered, which also ensures reliable reception of the infrared radiation in all decentralized transmitting and receiving units SEE 1 to SEE N is guaranteed. A further supplementary or alternative measure can consist in designing the bodies or housings of the individual decentralized transmitting and receiving units SEE 1 to SEE to be optically effective in such a way that the refraction, diffraction and / or scattering of the central transmitting and receiving units and receiving unit ZSEE incoming infrared radiation safely reaches all infrared sensors EE of the decentralized units.

The application of the procedure is not straightforward Arrangements of the decentralized receiving units be limits; Changes in direction can be made by inserting small mirrors in the course of the infrared beam problem going to be taken into account.

Furthermore, in both figures at the central broadcast and receiving unit ZSEE still indicated that this also used for more than one lighting system that can be done by not just infrared radiation in one direction is sent out, but in several directions, d. H. each in the direction in which the decentralized Transmitting and receiving units of each lighting systems are arranged. This is with the central sen de- and receiving units by one in their lower Part indicated further transmitter diode SD indicated.

Finally, it can be provided that a feedback  from the decentralized sending and receiving units one or more lighting systems to the central Sending and receiving unit is done with the latter by an In drawn in their upper part infrared sensor EE is indicated.

Claims (11)

1. A method for individually controlling the brightness of the individual lamps of at least one halogen lamp lighting system, wherein a plurality of lamps are connected in parallel to one another to a common wire rope pair and are fed together from a central power supply, characterized in that one is also attached to the wire rope pair closed central transmitting and receiving unit from serial digital address and command data by means of infrared rays essentially parallel to the wire pair to the individual lamps each assigned to the central receiving units and decoded in the latter and that in response to the decentralized receiving unit in question, the decoded command data to one the associated lamp upstream power regulator are passed on. 2. The method according to claim 1, characterized in that that from the central sending and receiving unit Address and command data first to the decentralized Em unit of the first, nearest lamp above will wear that from this lamp by means of egg ner assigned additional decentralized sen de unit the address and command data after intermediate amplification also by means of infrared beam to de central receiving unit of the second, next sequence the lamp are transmitted u. s. w., to the last one, most distant lamp. 3. The method according to claim 2, characterized in that in each case between receiving the address and loading incorrect data by the decentralized receiving unit ei ner lamp and the relaying of these address and loading  incorrect data by the decentralized transmission unit of the same lamp to the decentralized receiving unit of the a time delay is inserted in the next lamp and that the receiving unit after receiving a Se sequence of address and command data for a predefined re time is switched off, the transmitter unit ei ner lamp only becomes active after receiving the same lamp has been switched off. 4. The method according to claim 2, characterized in that for the transmission of address and command data from the central sending and receiving unit to first decentralized transmitter and receiver unit and between the individual decentralized broadcasting and Receiver units polarized infrared radiation is used, the polarization direction of Transmission section to transmission section changes. 5. The method according to claim 1, characterized in that the infrared rays through the sufficient Permeability to Ge having infrared rays housing of the individual lamps are passed through. 6. The method according to at least one of claims 1 and 5, characterized in that the infrared beam generated with such a width or on a sol che width is expanded to include several decent le receiving units illuminated, the self or de Ren infrared sensor offset against each other are arranged. 7. The method according to at least one of claims 1, 5 and 6, characterized in that the infrared ray from the central sending and receiving unit by refraction, diffraction and / or scatter in or on the correspondingly designed lamp housing for their  decentralized receiving units is performed. 8. The method according to at least one of claims 1 to 7, characterized in that a central transmission and receiving unit multiple lighting systems controls that the address and command data for each time-division lighting systems are broadcast and that the decentralized Receiving units only during fixed times are active, within which the be agreed data to be broadcast. 9. The method according to at least one of claims 1 to 8, characterized in that for the control the brightness of the individual lamps in a central control unit and from there via cables to the central sen de- and receiving unit are transmitted. 10. The method according to claim 9, characterized in that the information is entered manually via an input peri The central control unit is entered the. 11. The method according to claim 9, characterized in that the information on an interface of a higher-level control computer to the central Control unit are handed over.