NL1034288C1 - Lighting system used for Christmas tree, has transmitter which is arranged in between lamps, and which generates additional signal that can be received by receivers - Google Patents

Abstract

The lighting system has lamps (1) each being provided with light source, power source and receiver for electromagnetic or acoustic signals. A remote control (3) is provided with transmitter (7) for generating electromagnetic or acoustic signals. The lighting system also comprises transmitter which is arranged in between the lamps, and which generates an additional signal that can be received by receiver. An independent claim is included for a lamp, remote control or transmitter.

Description

Lighting system as well as light, remote control or additional element as part of this system

The invention relates to a lighting system, comprising a group of lamps suitable for, for example, being placed in a Christmas tree, wherein each lamp is provided with a light source, a current source and a receiver for electromagnetic or acoustic signals, and a remote control provided with transmitting means for emitting electromagnetic or acoustic signals.

A lighting system of this type is known from DE 41 20 849. This is a Christmas tree lighting in which each Christmas tree lamp is equipped with a photocell and in which the photocells are controlled simultaneously with the aid of a transmitter which emits light signals.

A drawback of the known system is that signals emitted by a remote control of one system can operate the lights of another system. It is of course possible to produce different types of lamps with associated remote controls, but this is not very attractive logistically.

The present invention obviates this drawback and is characterized in that the lighting system also comprises an additional element placed at least substantially centrally between the lamps in a position of use, suitable for outputting an additional signal that can be received by the receivers. It is then sufficient to produce different types of additional elements.

A favorable embodiment is characterized in that the transmitting means are adapted to provide an RF signal, that the receivers comprise RF receivers, each provided with a mixing stage and that the additional element 1034 2 88 2 comprises an RF oscillator for delivering an RF signal. Preferably, the RF signal output from the transmitting means and the RF signal output from the additional element have different frequencies, so that the receivers then actually have to process a relatively low-frequency mixing signal obtained from the RF signal of the remote control and the RF signal of the additional element, which may increase the sensitivity of the receivers. It is of course also possible to provide each receiver with an oscillator, but as a result the lighting system becomes relatively expensive. Nor can it be excluded that the different receivers will then disturb each other.

A further favorable embodiment is characterized in that each receiver is provided with a filter, for transmitting signals with a frequency which corresponds to the frequency difference of the RF signal emitted by the transmitting means and the RF signal emitted by the additional element 20.

A further favorable embodiment is characterized in that the frequency difference is at least 300 kilohertz and at most 30 megahertz. Good and inexpensive filters are available for this frequency range 25, which can be used in the receivers, whereby the receivers become more sensitive and the receivers will only respond to signals from the remote control.

A favorable alternative embodiment of the invention is characterized in that the transmitting means are adapted to provide an RF signal, that the receivers comprise acoustic receivers and that the additional element comprises an RF receiver and an acoustic transmitter.

The additional element can then be conveniently placed, so that the RF signal 3 transmitted by the remote control can always be received even with a low transmission power.

A low power is also sufficient for the signal transmitted by the acoustic transmitter, because the lights are all in the immediate vicinity of the additional element 5.

A further favorable embodiment is characterized in that the RF receiver is a super-regenerative receiver. Such a receiver is cheap and sensitive, while also the power consumption is low.

A further alternative embodiment is characterized in that the transmitting means are adapted to provide an optical signal, that the receivers comprise acoustic receivers and that the additional element comprises an optical receiver and an acoustic transmitter. The additional element can then be conveniently placed, so that the optical signal transmitted by the remote control can always be received even with a low transmission power. A low power is also sufficient for the signal transmitted by the acoustic transmitter, because the lights are all in the immediate vicinity of the additional element.

A further alternative embodiment is characterized in that the transmitting means are adapted to provide an optical signal, that the receivers comprise RF receivers and that the additional element comprises an optical receiver and an RF transmitter. The additional element can then be conveniently placed, so that the optical signal transmitted by the remote control can always be received even with a low transmission power. A low power is also sufficient for the signal transmitted by the RF transmitter, while the sensitivity of the RF receivers can be low because the lights are all in the immediate vicinity of the additional element.

4

The invention also relates to a lamp, a remote control or an additional element as part of a lighting system as described in the preceding paragraphs.

The invention will now be further elucidated with reference to the following figures, wherein:

FIG. 1 schematically represents a possible embodiment of a lighting system according to the invention;

FIG. 2 schematically represents a possible embodiment of a Christmas tree lamp according to the invention;

FIG. 3 schematically represents an alternative embodiment of a Christmas tree lamp according to the invention; FIG. 4 schematically represents a further alternative embodiment of a Christmas tree lamp according to the invention;

FIG. 5 schematically represents a possible embodiment of an additional element; FIG. 6 schematically represents an alternative embodiment of an additional element;

FIG. 7 schematically represents a possible embodiment of an RF receiver.

FIG. 1 schematically shows a possible embodiment of a lighting system according to the invention, consisting of a number of lights 1 that can be mounted in a Christmas tree 2, and a remote control 3 with which the light intensity of the lights can be controlled. Remote control 3 is provided with push buttons 4a, 4b for switching on or switching off the lights 1 or for increasing or decreasing the intensity of lights 1. The lighting system operates wirelessly. Therefore, remote control 3 is provided with a transmitter 5 and an antenna 6 or with a light-emitting diode or with an acoustic radiator for controlling lights 1. According to the invention, the lighting system is furthermore provided with an additional element 7 which controls the reception of Supports 3 broadcast signals. This makes sense because the distance between Christmas tree 2 and remote control 3 can be large, while the distance between additional element 7 and lights 1 is small.

FIG. 2 schematically shows a possible embodiment of a Christmas tree lamp 1 according to the invention, consisting of a tubular housing 8 with a top 9 which is in the form of a candle flame and a shell 10, to which a clamp 12 is attached via a ball joint 11 with which Christmas tree lamp 1 can be attached to a branch. Housing 8 accommodates a receiver 13, provided with an antenna 14 that can receive RF control signals from remote control 3, as shown in Figs. 1 and which can switch on a light-emitting diode 15, energy being supplied by two batteries 10 included in scale 10a, 16a. Top 9 is made of a transparent plastic, for example polycarbonate, in which small metal particles or air bubbles 17 are embedded, which results in light from light-emitting diode 15 being diffused, as a result of which virtually the entire volume 30 of top 9 appears to diffuse light.

FIG. 3 schematically shows an alternative embodiment of a Christmas tree lamp 1 according to the invention, consisting of a tubular housing 8 with a top 9 which is in the form of a candle flame and a shell 10, to which a clamp 12 is attached via a ball joint 11 with which Christmas tree lamp 1 can be attached to a branch. Housing 8 accommodates a receiver 13 provided with a photo diode 18 which can receive optical control signals from remote control 3, as shown in FIG. 1 and which can switch on a light-emitting diode 15, energy being supplied by two batteries 16a, 16b included in shell 10. Top 9 is made of a transparent plastic, for example polycarbonate, in which small metal particles or air bubbles 17 are embedded, which results in light from light-emitting diode 15 being diffused, as a result of which virtually the entire volume of top 9 appears to diffuse light.

FIG. 4 schematically shows a further alternative embodiment of a Christmas tree lamp 1 according to the invention, consisting of a tubular housing 8 with a top 9 in the form of a candle flame and a shell 10, to which a clamp 12 is attached via a ball joint 11 with which Christmas tree lamp 1 can be mounted on a branch. Housing 8 accommodates a receiver 13 provided with a microphone 19 that can receive acoustic control signals from remote control 3, as shown in Figs. 1 and which can switch on a light-emitting diode 15, energy being supplied by two batteries 16a, 16b included in scale 10. Top 9 is made of a transparent plastic, for example polycarbonate, in which small metal particles or air bubbles 17 are embedded, which results in light from light-emitting diode 15 being diffused, whereby virtually the entire volume of top 9 appears to diffuse light.

FIG. 5 schematically shows a possible embodiment of an additional element 7, consisting of a tubular housing 20 and a shell 21, in which two batteries 16a, 16b are accommodated and to which via a 7 ball hinge 11 a clamp 12 is mounted with which Christmas tree lamp 1 is mounted on a branch can be attached. Housing 20 accommodates a receiver 22, as well as an amplifier 23 and a transmitter 24. Receiver 22 receives 5 signals from remote control 3, amplifier 23 amplifies these signals and transmitter 24 retransmits these signals in such a way that Christmas tree lights 1 can receive them . In addition, receiver 22 may be adapted to receive RF signals, while transmitter 24 is adapted to provide acoustic signals, but other combinations are also conceivable, depending on the circumstances. In the aforementioned combination, receiver 22 can be formed by a super-regenerative receiver, while transmitter 24 can consist of a simple ultrasonic radiator. Christmas tree lights 1 can then be provided with a microphone, as described with reference to Figs. 4.

FIG. 6 schematically shows an alternative embodiment 20 of an additional element 7, consisting of a tubular housing 20 and a shell 21, in which two batteries 16a, 16b are accommodated and to which a clamp 12 is attached via a ball joint 11 with which Christmas tree lamp 1 is mounted on a branch can be confirmed. Housing 20 includes an RF oscillator 25, which is connected to an antenna 26. This alternative embodiment can advantageously be used if remote control transmits 3 RF signals. RF oscillator 25 has a frequency that is, for example, 10 MHz. differs from the RF frequency transmitted by remote control 3. The first stage of the receivers of lights 1 is then a mixing stage which has a signal of 10 MHz. when remote control 3 is switched on. The receivers are in fact superheterodyne receivers, with RF 35 oscillator 25 forming the oscillator for all receivers. This has the result that the receivers can be manufactured in a simpler and cheaper way. Moreover, for the combination of the remote control and the additional element, different frequencies can be chosen, as a result of which a remote control cannot disturb a neighboring, different Christmas tree lighting.

FIG. 7 schematically shows a possible embodiment of an RF receiver 13 for a Christmas tree lamp 1, such as that in combination with an additional element according to FIG. 10 6 can be used. Receiver 13 consists of a mixer 27, known per se, which is connected to antenna 14, in which RF signals from remote control 3 and RF oscillator 25 are mixed. The mixing signal is then passed through a per se known filter 28, amplified in amplifier stage 29 and rectified in detector stage 30. This signal is then used to switch light-emitting diode 15 on or off in a manner known per se.

1 034288

Claims (10)

A lighting system, comprising a group of lights suitable for, for example, being placed in a Christmas tree, each light being provided with a light source, a power source and a receiver for electromagnetic or acoustic signals, and a remote control provided with transmitting means for emitting electromagnetic or acoustic signals, characterized in that the lighting system also comprises an additional element placed at least substantially centrally between the lights in a position of use, suitable for outputting an additional signal that can be received by the receivers. 15 2. Lighting system as claimed in claim 1, characterized in that the transmitting means are adapted to provide an RF signal, that the receivers comprise RF receivers, each provided with a mixing stage and that the additional element comprises an RF oscillator for delivering an RF signal. 3. Lighting system as claimed in claim 2, characterized in that the RF signal supplied by the transmitting means and the RF signal supplied by the additional element have different frequencies. 4. Lighting system as claimed in claim 3, characterized in that each receiver is provided with a filter, for transmitting signals with a frequency corresponding to the frequency difference of the RF signal emitted by the transmitting means and the RF emitted by the additional element signal. 5. Lighting system according to claim 4, characterized in that the frequency difference is at least 300 kilohertz and at most 30 megahertz. 6. Lighting system as claimed in claim 1, characterized in that the transmitting means are adapted to provide an RF signal, that the receivers comprise acoustic receivers and that the additional element comprises an RF receiver and an acoustic transmitter. 7. Lighting system according to claim 6, characterized in that the RF receiver is a super-regenerative receiver. 8. Lighting system as claimed in claim 1, characterized in that the transmitting means are adapted to provide an optical signal, that the receivers comprise acoustic receivers and that the additional element comprises an optical receiver and an acoustic transmitter. 9. Lighting system as claimed in claim 1, characterized in that the transmitting means are adapted to provide an optical signal, that the receivers comprise RF receivers and that the additional element comprises an optical receiver and an RF transmitter. 25 10. Light bulb, remote control or additional element as part of a lighting system according to one of claims 1 to 9. 1 0 3 4 2 88 J