1. Field of the Invention
The present invention relates to a decoration lamp, and more particularly to a decoration lamp for producing matched sound and illumination effects.
2. Description of Related Art
In order to decorate the amusement places for delightful atmosphere, the places may be decorated with figurines and posters. For example, a pumpkin figurine is common at Halloween parties. The pumpkin figurine substantially has a figurine body and a lamp.
The figurine body can be carved with a face pattern. The lamp is hung in the figurine body. A user can decorate the party place with the pumpkin figurines. At night, the lamp is lighted up to shine the pattern of the figurine body outward to create the Halloween atmosphere.
The conventional pumpkin figurine has a simple structure and is a static decoration figurine. Nowadays a pumpkin figurine displays only one pattern at a time. Therefore, the pumpkin figurine is boring with very little variation. The conventional pumpkin figurine does not effectively attract the viewer's attention.
An objective of the present invention is to provide a decoration lamp for producing matched sound and illumination effects. The decoration lamp can be lighted up to display multiple patterns and make corresponding voices at a same time. The attraction of the decoration lamp of the present invention gets enhanced.
The decoration lamp of the present invention comprises a decoration body, multiple fixtures, multiple illumination units, a translucent cover, a speaker and a control device.
The decoration body has a front surface and a back surface.
The fixtures are mounted on the decoration body and respectively have a first connector and a second connector. The first connector is mounted on the front surface of the decoration body and has an opening. The second connector is mounted on the back surface of the decoration body and engages with the first connector.
The illumination units are respectively mounted in the fixtures and are exposed in the openings of the first connectors.
The translucent cover is mounted on the front surface of the decoration body to cover the illumination units.
The speaker makes different voices according to different sound signals.
The control device stores the sound signals, is electrically connected to the illumination units and the speaker, and sequentially executes multiple modes. Each mode is applied to activate a part of the illumination units to show a certain pattern through the translucent cover and to output one of the voices corresponding to the certain pattern by the speaker.
A user can use a flexible fabric as the decoration body and defines multiple patterns on the decoration body. The control device has sound signals respectively corresponding to the patterns. When the control device is not at work, viewers only see the surface of the translucent cover and cannot see the illumination units behind the translucent cover. When the control device is activated, the control device sequentially activates the part of the illumination units for changing the patterns and activates the speaker to make corresponding voices for the patterns, so that viewers can see the light patterns on the translucent cover. The decoration lamp of the present invention has both visual and acoustic effects. Therefore, the decoration lamp of the present invention is more interesting, lively and attractive than the conventional one.
With reference to
The decoration body 10 can be a flexible fabric, cloth or a figurine. The decoration body 10 has a front surface, a back surface and multiple holes 11. The front surface is a demonstration surface for defining patterns. The holes 11 are formed on the outlines of the patterns and formed through the front surface and the back surface of the decoration body 10. With reference to
The fixtures 20 are securely mounted through the holes 11 of the decoration body 10. Each fixture 20 has a first connector 21 and a second connector 22.
With reference to
The illumination units 30 are respectively mounted in the fixtures 20 and are exposed in the openings 23 of the first connectors 21 to form the patterns.
With reference to
The first sheet 211 has the opening 23 and a back surface. The buckles 212 are formed on the back surface of the first sheet 211. Each buckle 212 has a lock portion 213 extending inward.
The second connector 22 has a base 221 and a second sheet 222. The base 221 has a front terminal and multiple abutting surfaces 223. The second sheet 222 laterally extends from the front terminal of the base 221 and has a front surface and multiple notches 224. The positions of the notches 224 correspond to the positions of the abutting surfaces 223.
The illumination unit 30 is mounted on the front terminal of the base 221. The illumination unit 30 can be a light emitting diode (LED) device. With reference to
The translucent cover 100 is mounted on the front surface of the decoration body 10 to cover the illumination units 30. The translucent cover 100 can be a translucent fabric or cloth.
With reference to
The first sheet 241 has the opening 23, a first engaging portion 243 and a back surface. The first engaging portion 243 is formed on the back surface of the first sheet 241 and can be a protrusion or an indentation.
The tube 242 is formed on the back surface of the first sheet 241 and has an outer surface, a space 244, multiple buckles 245 and a positioning rib 246. The space 244 communicates with the opening 23 of the first sheet 241. Each buckle 245 has a lock portion 247 extending outward. The positioning rib 246 is formed on the outer surface of the tube 242.
The second connector 22 has a base 251 and a second sheet 252.
The base 251 has a front terminal, a bottom terminal, a space 253, a positioning groove 254 and multiple apertures 255. The space 253 has a front opening formed in the front terminal of the base 251. The positioning groove 254 is laterally formed through the base 251 and extends from the front terminal to the bottom terminal of the base 251. The apertures 255 are formed between the front terminal and the bottom terminal of the base 251 and communicate with the space 253 of the base 251. The positions of the apertures 255 correspond to the positions of the buckles 245. The position of the positioning groove 254 corresponds to the position of the positioning rib 246.
The second sheet 252 laterally extends from the front terminal of the base 251 and has a front surface, a second engaging portion 256 and a through groove 257. The second engaging portion 256 is formed on the front surface of the second sheet 252 and matches the first engaging portion 243 to be an indentation or a protrusion. The through groove 257 extends from an edge of the second sheet 252 to the positioning groove 254 and communicates with the positioning groove 254.
The illumination unit 30 is mounted in the fixture 20 and can be an LED device. With reference to
When a user connects the first connector 21 with the second connector 22, the user can insert the positioning rib 246 into the positioning groove 254 to align the apertures 255 with the buckles 245 such that the positions of the apertures 255 correspond to the positions of the buckles 245, and the position of the positioning groove 254 corresponds to the position of the positioning rib 246.
With reference to
The first connector 21 has a box 271 and a first engagement pillar 272.
The box 271 has the opening 23 and a back surface. The first engagement pillar 272 is formed on the back surface of the box 271 and has an outer engagement portion 273 and an inner engagement portion 274.
The second connector 22 has a bottom piece 281 and a second engagement pillar 282. The bottom piece 281 has a front surface. The second engagement pillar 282 is formed on the front surface of the bottom piece 281 and has an inner engagement portion 283.
The illumination unit 30 is mounted in the opening 23 of the box 271 and has a substrate 31 and an LED die 32. The substrate 31 has a front surface. The LED die 32 is mounted on the front surface of the substrate 31.
With reference to
With reference to
The first sheet 611 has the opening 23, a back surface and two wire grooves 613. The wire grooves 613 are formed in the back surface of the first sheet 611. The buckles 612 are formed on the back surface of the first sheet 611. Each buckle 612 has a lock portion 614 extending outward.
The second connector 22 is a sheet having a front surface, two wire grooves 621 and two apertures 622. The wire grooves 621 are formed in the front surface of the second connector 22 and respectively correspond to the wire grooves 613 of the first sheet 611. The apertures 622 are formed through the second connector 22.
The illumination unit 30 can be an LED package and is mounted on the front surface of the second connector 22. Two adjacent illumination units 30 are connected in series by two wires 63.
With reference to
With reference to
With reference to
The light driver circuit 51 has multiple electric switches Q1-Q13 respectively and electrically connected to the illumination units 30. The illumination units 30 are LEDs as an example, wherein each LED has a cathode and an anode. The electric switch Q1-Q13 can be an NPN bipolar junction transistor (BJT) having a base, a collector and an emitter. The emitter is grounded. The collector is electrically connected to the cathode of the illumination unit 30.
The sound driver 52 can be an NPN BJT having a base, a collector and an emitter. The emitter is grounded. The collector is electrically connected to the signal input pin V− of the speaker 40.
The light-controlled circuit 53 has a first PNP BJT Q37, a second PNP BJT Q38, a photoresistor (COS) and a resistor R52. The base of the first PNP BJT Q37 is grounded through the photoresistor (COS). The collector of the second PNP BJT Q38 is connected to the micro controller 56 and is grounded through the resistor R52.
The voice-controlled circuit 54 has a first NPN BJT Q34, a second NPN BJT Q35, a PNP BJT Q36 and an acoustic resistor (BZ). The base of the first NPN BJT Q34 is grounded through the acoustic resistor (BZ). The collector of the PNP BJT Q36 is connected to the micro controller 56 and is grounded through the resister R52 of the light-controlled circuit 53. The second NPN BJT Q35 is connected between the first NPN BJT Q34 and the PNP BJT Q36.
The overload protection circuit 55 has a PNP BJT Q16, a first NPN BJT Q15, a second NPN BJT Q17 and a voltage divider 550.
The PNP BJT Q16 has a base, a collector and an emitter. The emitter is electrically connected to a DC power supply to receive a working voltage VCC. The collector is electrically connected to the micro controller 56, the anodes of the illumination units 30, the power pin V+ of the speaker 40, emitters of the first and the second PNP BJT Q37, Q38 and the photoresistor (COS) of the light-controlled circuit 53 and an emitter of the PNP BJT Q36 and the acoustic resistor (BZ) of the voice-controlled circuit 54.
The first NPN BJT Q15 has a base, a collector and an emitter. The emitter is grounded. The base and the collector of the first NPN BJT Q15 are respectively and electrically connected to the emitter and the base of the PNP BJT Q16.
The voltage divider 550 has a first resistor R36 and a second resistor R37. The first resistor R36 is electrically connected to the collector of the PNP BJT Q16. The second resistor R37 is electrically connected to the first resistor R36 in series. The resistance of the second resistor R37 is lower than that of the first resistor R36.
The second NPN BJT Q17 has a base, a collector and an emitter. The emitter is grounded. The base is electrically connected to a node between the first resistor R36 and the second resistor R37. The collector is electrically connected to the emitter of the PNP BJT Q16.
When the DC power supply works normally, the voltage drop of the second resistor R37 is lower than a threshold voltage of the second NPN BJT Q17. Then the NPN BJT Q17 is inactivated and operates in a cutoff region. The first NPN BJT Q15 and the PNP BJT Q16 are activated and operate in a forward active region. When the PNP BJT Q16 is activated, the working voltage VCC is conveyed from the emitter to the collector of the PNP BJT Q16 for supplying the micro controller 56, the light-controlled circuit 53, the voice-controlled circuit 54, the speaker 40 and the illumination units 30.
When the DC power supply provides abnormally high working voltage, the voltage drop of the second resistor R37 increases to be higher than the threshold voltage of the second NPN transistor Q17, such that the second NPN BJT Q17 is activated. When the second NPN BJT Q17 is activated, the DC power supply is grounded by the second NPN BJT Q17. Hence, the abnormally high working voltage cannot be conveyed to the micro controller 56, the speaker 40 and the illumination units 30. The micro controller 56, the speaker 40 and the illumination units 30 are protected from being damaged by the abnormally high working voltage.
The micro controller 56 has a power pin VDD, a sound output pin PWM+, a voice-light input pin P10 and multiple light output pins P20-P23, P30-P33, P40-P43, P50-P53. The micro controller 56 stores the sound signals and executes multiple modes sequentially. The sound signals are pulse width modulation (PWM) signals.
The power pin VDD is electrically connected to the collector of the PNP BJT Q16 of the overload protection circuit 55 to receive the working voltage VCC.
The sound output pin PWM+ is electrically connected to the base of the sound driver 52. The micro controller 56 provides the sound signals to the sound driver 52 via the sound output pin PWM+, such that the micro controller 56 drives the speaker 40 speaking through the sound driver 52.
The voice-light input pin P10 is electrically connected to the light-controlled circuit 53 and the voice-controlled circuit 54. The micro controller 56 is activated by the light-controlled circuit 53 or the voice-controlled circuit 54.
The voice-light input pin P10 is connected to the collector of the second PNP BJT Q38 of the light-controlled circuit 53 and the collector of the PNP BJT Q36 of the voice-controlled circuit 54. The micro controller 56 can be activated by the light-controlled circuit 53 and the voice-controlled circuit 54.
In the light-controlled circuit 53, when the photoresistor (COS) detects light, the impedance of the photoresistor (COS) decreases. The first PNP BJT Q37 is then turned ON. When the first PNP BJT Q37 is turned ON, the collector of the first PNP BJT Q37 is maintained in a low potential, so that the second PNP BJT Q38 is turned ON. When the second PNP BJT Q38 is turned ON, a current flows through the resistor R52. The voltage drop on the resistor R52 then activates the micro controller 56.
In the voice-controlled circuit 54, when the acoustic resistor (BZ) detects sound waves, the impedance of the acoustic resistor (BZ) decreases. The first NPN BJT Q34 is then turned OFF, so that the base of the second NPN BJT Q35 is maintained in a high potential and the second NPN BJT Q35 is turned ON. When the second NPN BJT Q35 is turned ON, the base of the PNP BJT Q36 is maintained in a low potential, so that the PNP BJT Q36 is turned ON. When the PNP BJT Q36 is turned ON, a current flows through the resistor R52 of the light-controlled circuit 53. The voltage drop on the resistor R52 then activates the micro controller 56.
The user can remotely activate the micro controller 56 by making sounds to the acoustic resistor (BZ) or shining a flash light on the photoresistor (COS). When the micro controller 56 is activated by sounds or light, the micro controller 56 outputs the sound signals and the control signals to the speaker 40 and the illumination units 30 to activate the speaker 40 and the illumination units 30.
The light output pins P20-P23, P30-P33, P40-P43, P50-P53 are respectively and electrically connected to the bases of the electric switches Q1-Q13 of the light driver circuit 51. The micro controller 56 provides control signals to the part of the electric switches Q1-Q13 via the light output pins to activate the part of the electric switches Q1-Q13 to form the pattern. When the electric switches Q1-Q13 are activated, the illumination units 30 receive the working voltage VCC to be lighted up.
The micro controller 56 executes the modes sequentially. Each mode is adapted to activate a part of the illumination units 30 for a certain pattern and to output a corresponding voice by the speaker 40.
For example, the patterns of the
The patterns and the voices change synchronously. When the micro controller 56 executes a first mode, the micro controller 56 activates the part of the illumination units 30 for the first pattern and activates the speaker 40 by a first sound signal. When the micro controller 56 executes a second mode, the micro controller 56 activates the part of the illumination units 30 for the second pattern and activates the speaker 40 by a second sound signal. The rest may be deduced by analogy.
Hence, the patterns can be designed to be on display in a preset time order or in random. When the patterns are changed sequentially, the patterns are displayed as an animation. In addition, the speaker 40 makes a corresponding voice for the pattern. The decoration body 10, such as the pumpkin figurine, resembles a person in figure. The decoration lamp of the present invention can be lighted and speaks like a person to surprise and amuse the users who see and hear the decoration lamp. The conventional figurine is unable to be lighted and speaks.
In addition, when the holes 11 of the decoration body 10 are formed, the first connector 21, the second connector 22 and the illumination unit 30 are easily to be mounted on the decoration body 10 through the holes. To realize the design and assembly of the decoration lamp of the present invention is simple.
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