NO158389B - LIGHT LIGHT CONTROL DEVICE. - Google Patents

Description

The present invention comprises a device of the kind stated in the introduction to patent claim 1, for controlling light sources, particularly in indoor lighting systems.

With such a control unit, the aim is to achieve that the individual light source or groups of light sources are dimmed or switched off when the required lighting level in the relevant part of the room is maintained by a sufficient supply of daylight/sunlight. This will have a beneficial effect on the indoor climate, particularly in periods of high outside temperatures. Switched off light sources can mean a direct saving in energy costs, and can in many cases reduce maintenance costs.

To achieve this, it is previously known to use local or central control units which switch on and off, possibly dimmers, light sources or groups of light sources based on photocell measurement of the illuminance at a reference location, and/or by means of timer switches. (It is described in Elektro - Elektro-teknisk Tidsskrift 91, no. 7, pp. 12-15, 11 April 1978, Lampetten no. 3, 1977, as well as brochure material from Notika A/S, DK-9400 Nørresundby, regarding .the product LUXSTAT (trademark)).

There are also manual remote control units based on the transmission of control signals via IR radiation for local switching on and off or dimming of light sources or groups of light sources (Such a device is described in Siemens Elektrodienst 26 (1984) Heft 3, p.23 ). Such units are also found in combination with the automatic control systems mentioned above, e.g. Philips Technical Information "Light": "Integrated Function System".

The previously known automatic control systems use a single detector (photocell) to register at a selected reference location, either the sum of the contributions from daylight/sunlight and the artificial lighting in the room, or the illuminance outside the building.

From GB patent 2,123,751, a control system for controlling all the light sources in a room in one is known. The light detector captures light from a large angle of incidence. A similar control system is described in US patent 4,236,101.

In all rooms with daylight access, the illuminance for daylight alone varies greatly from place to place, and also over time due to changes in the position of the sun combined with the room's architectural design. The need for additional artificial lighting will vary from place to place, and over time in the room. It is thus a significant problem to find a reference location for the detector that can be said to be representative of the room as a whole.

It is a further problem that the need for illuminance can vary from one workplace to another.

It is also a disadvantage that the existing technical solutions for automatic control require additional installations of control signal conductors or separate power courses for the lighting installations. This entails additional installation costs for new facilities, and costly additional installations when using existing facilities.

The main purpose of the invention is to create a control system which, to a greater extent than previously, takes into account the fact that the access to daylight varies from place to place and over time in the premises, so that the illuminance requirement at the individual workplace is maintained to the greatest extent possible by incident daylight/sunlight alone. Individual automatic control of the individual light sources is desired in such a way that the control of the individual light source does not affect the corresponding control of other light sources in the room, so that instability occurs. The individual light source's control unit must be able to be calibrated individually in h.h. to the lighting level that is appropriate for the part of the room in question.

This can be achieved by designing the device in accordance with the characterizing part of patent claim 1. or 2.

The invention enables local control of the light sources in new or existing facilities without additional costs associated with the introduction of control signal conductors or separate power courses for the lighting installations.

Further advantageous features of the invention will be apparent from sub-claims 3-6.

The invention will be described in more detail below with reference to the drawings, where: Fig. 1 shows an example of the geometrical conditions of a ceiling-mounted light fitting,

fig. 2 schematically shows curves for the various components of the light flux, which can be measured in the working area in fig. 1,

fig. 3 schematically shows the electrical circuit for a luminaire with a fluorescent tube, which is provided with a device in accordance with the invention, while

fig. 4 schematically shows the optical and electronic components of an embodiment of the invention.

In fig. 1 shows a fixture 11 with a light tube placed under a ceiling 12 to illuminate a work table 13.

The armature 11 is provided with a device 14 designed in accordance with the invention to control the switching on and off. The details of this device will be described in more detail below. Only its optical system 15 with a detector 16, which captures light from the workplace, will be described here. The detector 16 is placed in a tubular baffle 17 which is also covered with an optical filter 18. The baffle 17 delimits an opening angle for light that falls on the detector 16.

Fig. 2 shows curves for the illuminance variation at the measurement location, depending on the time. A fixed daylight/sunlight component Ep originates from a window not shown up to the workplace in fig. 1. In addition, there is the illuminance due to the electric light, E . This will vary with the electrical signal, i.e. with twice the frequency of the mains frequency, i.e. 100 Hz, between the values EAmax °<9>E„ .. There will therefore also be a certain illuminance

Amen

when the electrical signal is zero, due to the inertia of the lighting system with fluorescent tubes.

It will be described below in more detail how the device according to the invention reacts to composite light signals falling on the detector 16.

In fig. 3, the electrical components of a fluorescent tube fixture 11 are firstly illustrated. The main element here is a fluorescent tube 20 with a starter 21, a reactor 22 and a phase capacitor 23. These components are connected in a manner known per se and to an input terminal 24.

The device according to the invention, which is designated generally by reference number 14, comprises an electrical part 25 which is connected in series between the mains and the fluorescent fixture 11, and an optical part 15 with the detector 16.

In fig. 4 shows an embodiment of a light unit 25 for on-off switching. It comprises an electronic switch 27 which is connected in series between a mesh passage and the fluorescent fixture 11. The electronic switch 27 is controlled on and off through a signal from a comparator circuit 28. In this, an input signal from the detector 16 is compared via a circuit 29, which will be described in more detail below with a reference signal which is controlled with a potentiometer 30. The electronic circuit 29 comprises an electronic filter, a time delay and an amplifier. The function of these parts will be described in more detail below, as the circuit is assumed to be constructed in a generally known manner from available components.

In fig. 4 also shows the design in more detail

of a telescopic, tubular baffle 17, which is attached to a housing 31 outside the detector 16. In the example, the optical filter 18 is mounted over the inner opening in the baffle 17.

The housing 31 can be used for mounting on already existing fittings, for independent mounting or for installation.

In order to achieve the purpose of the invention, it is necessary that the measurement of the light and the processing of the signal that is registered take place in one or more of the following ways: 1. The optical filter 18 is designed to transmit light in a part of the spectrum where the ratio between the optical the intrinsic signal and the main optical signal, namely created by extraneous light, are a minimum. In one example, this could mean that a filter is used that lets through light close to the infrared range. 2. The detector 16 has a light-sensitive element with high spectral sensitivity in the range mentioned above. This also contributes to primarily measuring extraneous light incident in the measurement area. 3. The electronic circuit 29 contains components which calculate the main signal, i.e. the component of extraneous light, E^ on the basis of the recorded variation of the illuminance during the alternating current period as shown in fig. 2.

According to the invention, it is possible with a control unit to . ensure a correct illuminance in the luminaire's lighting area by an individual calibration. This means that only the number of luminaires necessary to maintain this correct illuminance is in operation at any given time.

A more detailed description of the signal processing in the control circuit 29 will now be given.

The electrical signal from the detector contains an approximately constant proportion which can be related to the daylight/sunlight component E^in the illuminance at the measurement location, and a proportion which can be related to the illuminance Eft which is due to electric light sources. This is illustrated in fig. 2.

The electrical signal is amplified. On the assumption of a characteristic value for the ratio E,.. /E* the proportion can

Amin Amax

E, is filtered out, and the remaining part of E.. is made

A y Amin yj

as little as possible, in principle removed completely. So that the final electrical signal contains information only about the component ED and any residual E^. This is further processed in the comparator.

The amplifier circuit's time delay prevents random short-term variations in the illuminance at the measuring point from switching the luminaire on or off.

The final electrical signal is compared in the comparator circuit with manually adjustable levels for illuminance and hysteresis. The level for the hysteresis is set with a potentiometer 32. The hysteresis works so that the level of the illuminance that leads to the switch-off of the luminaire is higher than the corresponding level that leads to switch-on. This avoids the occurrence of mutual influence and instability for the individual fixture and the fixtures in between. The signal from the comparator circuit 28 then activates the electronic switch 27 out or in.

The invention can be modified in various ways in relation to the example. The electronic switch 27 can be replaced with a circuit that can control the lighting fixture continuously or in steps, e.g. a phase controlled triac. In this way, an even more precise adjustment of the illumination intensity can be made.

The invention will basically be suitable for use with individual lighting fixtures. In principle, however, it can also be used for groups of two or more luminaires that are controlled together. In this case, the device will have a central location in the combined light field from the luminaires. For example a series of luminaires along a window wall can be controlled separately, and luminaires placed further into the room can be controlled separately.

The control system according to the invention can also be combined with a system for switching on and off using an IRT transmitter, which corresponds to what is described under the description of prior art.

Claims (6)

1. Device for controlling the effects of lighting fixtures in a room with several such fixtures and with varying access to daylight, where a light detector is used with an associated control circuit that particularly registers the daylight's contribution to the light level in the room, and which controls the effect supplied to the lighting fixtures, to reduce energy consumption when daylight is available, characterized in that each individual lighting fixture to be controlled is associated with a separate light detector (16) with an associated control circuit (29), that each light detector is provided with a variable dimming device (17) that delimits a limited reference area within this luminaire's operating area and that the light detector includes optical means to ensure that it mainly registers incident light in the part of the spectrum where the ratio between the optical intrinsic signal, caused by the luminaire's own light, and the main optical signal, caused by daylight and any other light sources, is a minimum. 2. Device for controlling the effect of lighting fixtures in a room with several such fixtures and with varying daylight access, where a light detector is used with an associated control circuit that particularly registers the daylight's contribution to the light level in the room, and which controls the effect supplied to the lighting fixtures, to reduce energy consumption when daylight is available, characterized in that each individual lighting fixture to be controlled is associated with a separate light detector (16) with an associated control circuit (29), that each light detector is provided with a variable dimming device (17) that delimits a limited reference area within this luminaire's operating range, and that the electronic control circuit is designed to calculate a main signal corresponding to the optical main signal on the basis of the recorded variation of the illuminance during an alternating current period and use this main signal as a basis for controlling the effect of the luminaire. 3. Device in accordance with patent claim 1 or 2, characterized in that the glare shield (17) is designed to delimit a reference area which constitutes a fraction of the lighting fixture's operating area. 4. Device in accordance with one of patent claims 1-3, characterized in that the glare shield (17) is designed as a telescopic tube. 5. Device in accordance with one of the patent claims 1-4, characterized in that the control circuit (29) is placed in or in immediate connection with the lighting fixture. 6. Device in accordance with patent claim 1, characterized in that the light detector (16) has a light-sensitive element with high spectral sensitivity in the area where the ratio between the optical eigensignal and the main optical signal is a minimum.