KR20090004802U - Intellectual bulb set application of socket controlled by box frame switch - Google Patents

Abstract

The present invention provides an intelligent bulb set that is applied to a conventional socket controlled by a wall switch.

There is a bypass line connected in parallel to the wall switch, and when the wall switch is turned off thereon, a potential difference or a power phase difference is generated. There is an intelligent bulb in which a resistor or diode is installed and mounted in a conventional socket, and the intelligent bulb is a power supply located inside the bulb body and the bulb body. It consists of a circuit, a detection switch, a charging circuit, a charging battery, a driving circuit, a microprocessor, and a light source, and is switched on and off in a state where power is normally supplied to a wall switch. At the same time, the light source of the intelligent bulb can be controlled to be turned on or off, and the emergency lighting is realized by the electric power supplied immediately by the rechargeable battery and driven immediately at the time of power failure.

Bulb, Diode, Microprocessor

Description

Intelligent bulb set application of socket controlled by box frame switch

The present invention relates to bulbs and, in particular, to intelligent bulb sets applied to conventional sockets controlled by wall switches.

Conventional conventional bulbs are the most widely used bulbs, which are widely used and in particular controlled by wall switches, and are used for lighting in houses, offices or at each venue.

Conventional conventional bulbs are only used for the lighting required around them, and have no other uses or functions, and sometimes their basic lighting functions are not exerted when the power is cut off, and emergency lighting is not used. It is necessary to mount it as extra construction, so the cost of lighting and construction is high, and it is aesthetically bad, and emergency lighting is not normally applied to lighting or other uses. In case of accidents such as power interruption or fire due to disasters, there is no emergency lighting equipment available, which causes danger.

The control of the place where the wall switch according to the present invention is located is the conventional socket, and the intelligent bulb set is the potential difference when the wall switch is off. ) Or power phase difference.

There is a bypass circuit that is connected in parallel to the wall switch, and a resistor or diode is installed on the wall switch, and the power processing circuit is located inside the bulb body and the bulb body. It is an intelligent bulb composed of a detection switch, a charging circuit, a charging battery driving circuit, a microprocessor, and a light source and mounted on a conventional socket.

The intelligent bulb set according to the present invention controls the light source of the intelligent bulb when it is turned on and off when the wall switch normally supplies power, and turns on or turns off the bulb when a power failure occurs. The light source of the bulb is immediately driven and powered by the rechargeable battery to obtain the effect of providing emergency lighting.

Referring to FIG. 1, the present invention is a better embodiment than an intelligent bulb set applied to a conventional socket controlled by a wall switch, and the intelligent bulb set is mainly bypassed. by pass line 10 and intelligent bulb 20 whereby the intelligent bulb set is controlled by a conventional socket 40 controlled by a wall switch 30. The main power source 50 is connected to the wall switch 30, and supplies AC power to the wall switch 30 from the main power source 50, and switches on the wall switch 30. (bulb) 20, the power supply circuit 22, the detection switch (23), the charging circuit ( 24, the rechargeable battery 25, the driving circuit 26, the microprocessor 27 and the light source 28 is equipped and bypassed 10 is connected in parallel to the wall switch 30, the electronic element is installed thereon, the electronic element is a resistor 11 or diode (12) and the wall switch (switch) as shown in FIG. When the power supply 30 is switched on, the main power supply 50 conducts the wall switch 30 so that the AC power of the normal voltage is transmitted to the socket 40 and the wall switch 30 is connected. Is switched to the off state, the wall switch 30 forms an open circuit and the main power supply 50 passes through and passes the bypass circuit 10 connected in parallel to the wall switch 30. When one by-pass line 10 is in the resistor 11, a step-down potential difference occurs, and the bypass circuit 10 that passes therethrough is a diode 12. Power supply phase difference occurs while the AC power supply is generated and a stepped voltage or phase difference is transmitted to the socket 40. The bulb body 21 has a permeable casing 211 without casing AC power from the main power supply 50 to the socket 40 during a power failure. ) 211 is a receiving space 212 is formed therein and is mounted in a conventional socket 40 at one end. A joint 213 is connected and is electrically connected to a socket 40, whereby the joint 213 is connected to a socket at the wall switch 30. Receive AC power of normal voltage supplied by inserting 40) or AC power of abnormal voltage supplied by abnormal voltage supplied by inserting socket 40 on the bypass line 10 And instructs an AC power source having a step-down or an AC power source having a phase difference by the bypass circuit 10 supplied from the main power source 50 described above, and the power source processing circuit 22. ) Is mounted in the accommodating space 212 of the bulb body 21 and connected to the joint 213 of the bulb body 21, whereby the power processing circuit 22 is connected to the joint. (joint) Receives AC power of normal voltage or normal voltage supplied by (213) and changes it to DC power of normal voltage or abnormal voltage. In addition, the detection switch 23 is mounted in the storage space 212 of the bulb body 21 and connected to the power supply processing circuit 22 to thereby supply the DC power supplied by the power supply processing circuit 22. When the DC power supply detects a DC power supply with a normal voltage or an abnormal voltage, the detection switch 23 transmits a normal signal, the detection switch 23 is in an open circuit state, and the DC power supply voltage is zero. When detecting that there is a transmission, an electrostatic signal is transmitted and the detection switch 23 is brought into a conductive state, and the charging circuit 24 stores the storage space 212 of the bulb body 21. ) Is connected to the power supply processing circuit 22 and thereby receives the DC power supplied by the power supply processing circuit 22 to provide a DC power source for charging, and the rechargeable battery 25 is a bulb body ( 21 is mounted in the storage space 212 and connected to the charging circuit 24, thereby charging When the DC power supplied by the furnace 24 is charged and the detection switch 23 is connected to the charging battery 25, and the detection switch 23 is brought into the conduction state by the detection switch 23. Supply DC power from).

The driving circuit 26 is mounted in the storage space 212 of the bulb body 21, and the power supply processing circuit 22 and the detection switch 23 are connected to each other, whereby the power supply processing circuit 22 Is supplied with DC power of the normal voltage or the abnormal voltage supplied by the power supply, or the DC power supplied by the charging battery 22 by inserting the detection switch 23, and the microprocessor 27 is charged with the charging circuit 24, respectively. ) And the charging battery 25 and the detection switch 23 is connected and instructs the charging circuit 24 to charge the charging battery 25 when the normal signal from the detection switch 23 is received. When receiving the electrostatic signal at 23, the detection switch 23 is inserted into the charging battery 25 to instruct the driving circuit 26 to supply DC power, and the light source 28 is a bulb body 21. ) Is mounted in the storage space 212 and connected to the driving circuit 26, thereby powering the light source 28. DC power supplied by the driving circuit 26 when the normal voltage supplied by inserting the driving circuit 26 in the furnace 22 receives DC power and is illuminated or inserted by the detection switch 23 in the rechargeable battery 25. It is automatically driven when receiving the light or turns off when receiving the DC voltage of abnormal voltage supplied by inserting the driving circuit 26 in the power processing circuit 22.

Next, the power processing circuit 22, the detection switch 23, the charging circuit 24, the charging battery 25, the driving circuit 26, and the microprocessor of the intelligent bulb 20 described above. (27) may be provided in a circuit board (not shown) and may be provided in the storage space 212 of the bulb body 21.

As shown in FIG. 2, the intelligent bulb 20 of the other embodiment of the present invention is a human body detector 291, an earthquake detector 292, a fire detector, as required by the microprocessor 27. Any one selected from 293 and alarm 294 or any combination thereof and any one selected from human body detector 291, earthquake detector 292, fire detector 293 and alarm 294 The human body detector 291, the earthquake detector 292, the fire detector 293, and the alarm 294 are located outside the bulb body 21 and mounted at an appropriate position on the ceiling or wall. I) By this, when the human body has elapsed or when an earthquake or fire has occurred, it is rapidly detected and detected, and an alarm is generated at an optimum position to obtain an optimum alarm effect.

By the following examples will be described in detail according to the structure, features or technical means and effects of the present invention.

Fig. 1 shows an embodiment in which an intelligent bulb set of a better embodiment of the present invention is mounted, which is conventionally controlled by an appropriate wall switch 30 according to the needs of a user. Select 40 and mount the intelligent bulb 20 of the present invention in a conventional socket 40 and the bypass line 10 of the present invention in a wall switch 30. By connecting in parallel, the bypass line 10 is the resistor 11, whereby the mounting work of the intelligent bulb 20 is simply completed.

Hereinafter will be described in detail the state of use of the intelligent bulb (bulb) (20).

When the main power supply is normally supplied,

[1] When the user switches the wall switch 30 to the on state, the main power supply 50 is fitted with the wall switch 30 to supply AC power of a normal voltage to the socket 40 and further to install a bulb body. The joint 213 of 21 is inserted to be transferred to the power supply processing circuit 22 and converted to DC power, whereby the detection switch 23 detects the DC power at a normal voltage and then enters into an open circuit state. And transmits a normal signal to the microprocessor 27, instructs the charging circuit 24 to charge the charging battery 25 by the microprocessor 27, 22 simultaneously supplies DC power to the drive circuit 26 and thus drives and illuminates the light source 28 in the drive circuit 26. Also, the intelligent bulb 20 of the present invention detects a fire or an earthquake immediately by a fire detector 293 or an earthquake detector 292 when a detection circuit such as a fire or an earthquake is mounted as shown in FIG. The detection signal is transmitted to the microprocessor 27, whereby the microprocessor 27 alerts the alarm circuit 294 by flashing or voice.

[2] Bypass that the AC power of the main power supply 50 is connected in parallel to the wall switch 30 because the wall switch 30 is in an open circuit state when the user switches the wall switch 30 to the off state. by supplying the circuit (10) to the socket (40) to supply an alternating current of an abnormal voltage generated by the voltage drop, and to the joint (213) of the bulb body (21). Is transferred to the power supply processing circuit 22 and converted into a DC power supply, whereby the detection switch 23 detects the DC power supply of the step-down voltage and enters an open circuit state, and the microprocessor 27 The normal signal is transmitted, and the microprocessor 27 instructs the charging circuit 24 to charge the charging battery 25, and the power processing circuit 22 simultaneously depresses the driving circuit 26. DC power of emergency voltage is generated. This to the light source 28 in the drive circuit 26 is turned off by the off (消 燈).

In addition, the fire detector 293 or the earthquake detector 292 is normally operated and detected when a detection circuit such as a fire or earthquake of the shape as shown in FIG. 2 is mounted on the intelligent bulb 20 of the present invention. Keep doing.

A mains power source is a power outage caused by, for example, a fire or some kind of natural disaster (for example, a typhoon or an earthquake or a tornado ...).

[1] If a power failure occurs when the wall switch 30 is in the on state, the main power supply 50 is inserted into the bypass switch 10 connected to the wall switch 30 or the parallel socket. Since no AC power is supplied to the socket 40, the detection switch 23 is in a conductive state without detecting the DC power, and transmits an electrostatic signal to the microprocessor 27, The microprocessor 27 instructs the driving circuit 26 to supply DC power by inserting a detection switch 23 which is conducted to the rechargeable battery 25, and the light source 28 in the driving circuit 26. And the light source 28 is automatically driven at the moment of power failure, provides emergency lighting, and automatically returns to the state [1] of claim 1 when power is restored. In addition, when a detection circuit such as a fire or an earthquake is mounted on the intelligent bulb 20 according to the present invention, a fire detector 293 or an earthquake detector 292 is also required by the rechargeable battery 25. Power is supplied, it operates normally and keeps detecting.

[2] When the wall switch 30 is in the off state, the AC power is supplied to the socket 40 because the main power supply 50 does not transmit the AC power when a power failure occurs. Is brought into a conductive state by not detecting a DC power supply, and transmits an electrostatic signal to the microprocessor 27. At this time, the microprocessor 27 is charged with a rechargeable battery 25. Instructs the drive circuit 26 to supply the DC power supply by inserting the detection switch 23 which is turned on. In addition, the drive circuit 26 automatically drives the light source 28, thereby causing the light source 28 to lose power. It is automatically charged by the bypass line 10 of the wall switch 30 to be driven automatically at the moment of occurrence, to provide emergency lighting, and to recover power when the rechargeable battery 25 is depleted. Sufficient at any time Keep an electric power.

In addition, when a detection circuit such as fire or earthquake is mounted on the intelligent bulb 20 of the present invention, a fire detector 293 or an earthquake detector 292 is also required by the rechargeable battery 25. Power is supplied, thereby operating normally to maintain detection.

Since the intelligent bulb 20 of the present invention is directly mounted in a conventional socket 40 controlled by a general wall switch 30, it is possible to wire an extra new line. It is necessary to modify the original line, but at the same time, by connecting the bypass line 10 having the resistor 11 or the diode 12 in parallel to the wall switch 30, the whole mounting work is simple and quick. In addition, since the intelligent bulb 20 is used for dual use between ordinary lighting and emergency lighting in case of power failure, it is more functional than ordinary conventional socket or emergency lighting. However, it is applied to the conventional socket 40 which is practical and is controlled by the wall switch 30 in various environments, whereby the emergency lighting is more pervasive and intelligent bulb. 20 human body examination When the machine 291, the earthquake detector 292, the fire detector 293, or the alarm 294 is mounted, a function of detecting a human body or various kinds of disasters and generating an alarm is realized. In addition, it is possible to protect the safety of people, which greatly improves the added value of the product.

1 is an internal structure of the intelligent bulb (bulb) of the embodiment of the present invention

       Conceptual view of mounting

Figure 2 is a conceptual diagram of the internal structure of the intelligent bulb (bulb) of another embodiment of the present invention

3 is a bypass (by pass) connected in parallel to the wall switch of the present invention

       Other conceptual diagram of line

<Description of the symbols for the main parts of the drawings>

(10) bypass circuit (11) resistance

(12) diode (20) bulb

(21) Bulb body (211) Casing

(212) storage space (213) joint

(22) Power supply processing circuit (23) Detection switch

(24) Charging Circuit (25) Rechargeable Battery

(26) driving circuit

(27) microprocessor (28) light source

(291) Human Body Detectors (292) Earthquake Detectors

(293) Fire Detectors (294) Alarm Detectors

(30) Wall switch (40) Socket (50) Main power source

Claims (7)

An electronic element and a permeable casing 211 for converting AC power connected in parallel to the wall switch 30 and passing through to AC power having an abnormal voltage and supplying the same to the socket 40 are provided. And a storage space 212 is formed inside the casing 211, a joint 213 is connected, and is mounted in a conventional socket 40, and a socket 40 And AC circuits of normal voltage, which are electrically connected to a joint 213 and supplied by inserting a socket 40 into a wall switch 30. Bypass line 10 and the bulb body (bulb) body 21 is installed by receiving the AC power supply of an abnormal voltage supplied by inserting the socket (socket) and the socket ( The normal voltage mounted in the storage space 212 of the 21 and connected to the joint 213 of the bulb body 21 and supplied from the joint 213 It is mounted in the accommodating space 212 of the power supply circuit 22 and the bulb body 21 that receives AC power of normal voltage and converts it into DC power of normal or abnormal voltage, and is connected to the power processing circuit 22. When the DC power supplied from the power processing circuit 22 is detected, and when the DC power is detected to be the DC power of the normal voltage or the abnormal voltage, it transmits the normal signal and enters the open circuit state, and the voltage of the DC power is zero. ) Is mounted in the accommodating space 212 of the detection switch 23 and the bulb body 21 in a conductive state by transmitting an electrostatic signal and connected to the power supply processing circuit 22. It is mounted in the storage circuit 212 of the charging circuit 24 and the bulb body 21 that receives the DC power supplied from the power processing circuit 22 and supplies the charged DC power, and is connected to the charging circuit 24. And charge the battery by receiving the DC power supplied with the charging circuit 24 and further connecting to the detection switch 23 and supplying the DC power by inserting the detection switch 23 when the detection switch 23 is in a conductive state. 25 and a bulb are mounted in the receiving space 212 of the main body 21, and the power supply processing circuit 22 and the detection switch 23 are connected to each other and supplied by the power supply processing circuit 22, respectively. A driving circuit 26 receiving a direct current power of a voltage or an abnormal voltage or receiving a direct current power supplied by inserting a detection switch 23 in the charging battery 25, and the charging circuit 24 and the charging battery 25, respectively. And when the detection switch 23 is connected and receives the normal signal transmitted by the detection switch 23, the charging circuit 24 charges the charging battery 25. And a microprocessor for instructing to supply DC power to the drive circuit 26 by inserting the detection switch 23 into the charging battery 25 when the detection switch 23 receives the electrostatic signal. The normal voltage mounted in the storage space 212 of the microprocessor 27 and the bulb body 21 and connected to the driving circuit 26 and supplied by the power processing circuit 22 by inserting the driving circuit 26. Illuminate when receiving a DC power supply or the rechargeable battery 25 illuminates when receiving a supplied DC power supply by inserting the detection switch 23 and the driving circuit 26 or driving circuit 26 in the power processing circuit 22. Intelligent bulb set applied to a conventional socket controlled by a wall switch, characterized in that it comprises a light source 28 which is extinguished when receiving a DC voltage of an abnormal voltage supplied by inserting the ). The set of intelligent bulbs applied to a conventional socket controlled by a wall switch, characterized in that the light source 28 consists of at least one LED bulb 20. (bulb set). 2. The wall switch switch according to claim 1, characterized in that the socket 40 receives an alternating current power generating a step-down when the wall switch 30 is switched off. Intelligent bulb sets applied to conventional sockets. 2. The wall switch according to claim 1, wherein the socket 40 receives an AC power source which generates a phase difference when the wall switch 30 is switched off. Intelligent bulb set applied to a conventional socket controlled by a. 2. An intelligent bulb set according to claim 1, wherein the electronic element is a resistor (11) which generates a step-down, which is applied to a conventional socket controlled by a wall switch. An intelligent bulb applied to a conventional socket controlled by a wall switch, wherein the electronic device is a diode 12 generating a phase difference. Bulb set. The microprocessor 27 further includes a combination of any one selected from the human body detector 291, the earthquake detector 292, the fire detector 293, and the alarm 294. An intelligent bulb set that is applied to a conventional socket controlled by a wall switch.

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