JP3728779B2 - Night light - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a night light that lights up when a person approaches at night or the like.
[0002]
[Prior art]
BACKGROUND ART Conventionally, there has been provided a lighting device called a night light which is arranged below a wall facing a corridor or the like so as to illuminate a foot. Night lights are usually turned on and off by manual switches, but this type of lighting fixtures are turned on and off by manual switches, although the purpose can be achieved if the lights are turned on only when people pass by. In such a case, the light may be turned on even when a person does not pass, which results in wasteful power consumption.
[0003]
Therefore, the present inventor previously proposed a night light that is turned on only when a person passes by incorporating a heat ray sensor that detects a heat ray radiated from a human body into the instrument body.
[0004]
[Problems to be solved by the invention]
By the way, in general, it is sufficient to light only during the passage of a person, but the illumination range does not always match the detection area of the heat ray sensor, and the output of the heat ray sensor is always obtained during the passage of a person. Therefore, even if the detection output generated when a person is detected by the heat ray sensor is stopped, it is necessary to keep the lighting state for a certain period of time. That is, after the detection output of the heat ray sensor is stopped, a timed operation is performed for a certain time, the lighting state is maintained during the timed operation, and the timed operation is reset if the detection output is generated again during the timed operation. However, if the time for the timed operation is fixed, there may be inconveniences such as the lighting time being too short depending on the installation conditions.
[0005]
The present invention has been made in view of the above circumstances, and its purpose is to adjust the lighting time according to the installation conditions while automatically turning on the light according to the passage of a person. It is to provide a night light that can.
[0006]
[Means for Solving the Problems]
According to the first aspect of the present invention, an appliance main body including a plug blade that can be inserted into an outlet of a commercial power supply, a lamp that emits illumination light on the front side of the appliance main body, a brightness sensor that detects ambient illuminance, and A secondary battery that is charged when connected, and a power supply switching unit that supplies power to the lamp using the secondary battery as a power source when the voltage from the commercial power supply is no longer detected, Provided are a diode inserted between the commercial power source and the secondary battery, and a switch having a switching contact connected to both ends of the diode and a common contact connected to the brightness sensor. When supplying power from commercial power Only to When the ambient illuminance falls below the specified value, the lamp is lit and when the power is supplied from the secondary battery, the lamp is lit regardless of the ambient illuminance. And the quotient Select whether to turn on the lamp when the ambient illuminance is below a predetermined value when power is supplied from either the power supply or the secondary battery Thing The
[0014]
With this configuration, the lamp can be turned on when the commercial power fails or is disconnected from the outlet, and the lamp is turned on only when the ambient illuminance is reduced according to the setting of the switch, regardless of the state and the ambient illuminance. The state in which the lamp is lit can be selected. That is, when connected to an outlet, the power is linked to the ambient illuminance, so that useless power consumption can be suppressed. Also, if power is selected from the secondary battery so that it is linked to the ambient illuminance, even if a power failure occurs, if the ambient illuminance is high, the secondary battery is not discharged and unnecessary consumption of the secondary battery is reduced. Can be prevented.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
(Embodiment 1)
As shown in FIGS. 2 and 3, the instrument body 1 is composed of a box-shaped body 1A made of a synthetic resin molded article having high heat resistance and having an open surface, and a cover 1B attached to the opening of the body 1A. Be composed. The body 1A and the cover 1B are coupled and fixed by engaging coupling claws 56, 57 projecting from the rear surfaces on both sides of the cover 1B into coupling holes 58, 59 provided in the body 1A to form the instrument body 1. The device main body 1 has a dimension approximately six times as large as a unit size of an embedded wiring device called a large square which is standardized in JIS standards as a whole. In other words, this corresponds to a dimension in which three wiring devices of unit dimensions are arranged in two rows of three. In addition, a locking claw 54 is formed as a connecting portion for connecting to the mounting frame 50.
[0016]
On the inner bottom surface of the body 1A, a piece parallel to the side wall (the left front wall in FIG. 2) that becomes a bottom wall when the instrument body 1 is attached to the wall surface at a predetermined interval, and a right side when attached to the wall surface An L-shaped partition wall 2 composed of a piece parallel to a side wall (a wall on the right front side in FIG. 2) which is a wall is a space in which the internal space of the body 1A is opened in a rectangular shape. It is divided into a storage room 3A and a circuit board storage room 3B which is a space opened in an L shape.
[0017]
In the lamp storage chamber 3A, a lamp socket 4 and an E12 type incandescent lamp 5 attached to the lamp socket 4 are stored. As shown in FIG. 2, the lamp socket 4 has a shaft portion 11 at both ends in the upper end of one end portion, and is provided at an upper end portion of a pair of ribs 12 formed along one side wall of the lamp housing 3A. Both end portions of the shaft portion 11 are supported by the bearing recess 13 so as to be able to be turned upside down. That is, the lamp socket 4 can be tilted between a position where it is stored in the lamp storage chamber 3A and a position where a part of the lamp socket 4 protrudes from the lamp storage chamber 3A to the front side of the body 1A. When replacing the lamp socket 4, the lamp socket 4 can be projected to the front side of the body 1A with the shaft portion 11 as the center. In the lamp housing 3A, a support spring 15 bent substantially in an L shape is fixed to the side of the lamp socket 4 using a fixing screw 14. In a state where the lamp socket 4 is stored in the lamp storage chamber 3 </ b> A, the tip end portion of the support spring 15 is prevented from elastically contacting the side surface of the lamp socket 4 and the lamp socket 4 is prevented from rotating unnecessarily. The lead wire 23 connected to the lamp socket 4 is housed in a groove 31 provided in a base 30 formed at the bottom of the lamp housing 3A and via a groove 32 formed in the partition wall 2 in a circuit board housing. Introduced in 3B.
[0018]
The circuit board storage chamber 3B includes terminal storage chambers 16a and 16b at both ends on one side, and a pair of quick-connecting terminals each including a terminal plate 17, a locking spring 18, and a release button 19 in each of the terminal storage chambers 16a and 16b. Each terminal is housed. Each quick-connecting terminal clamps the electric wire between the terminal plate 17 and the lock spring 18 by the elastic force of the lock spring 18 and releases the clamped state of the electric wire by bending the lock spring 18 by the release button 19. It is of a well-known configuration that can be used. Each terminal board 17 is soldered by inserting a protruding piece 17 a protruding upward in FIG. 2 into an insertion hole 20 provided in the circuit board 6, and is electrically connected to a circuit formed on the circuit board 6. . As shown in FIG. 6, an operation hole 22 for operating the wire insertion hole 21 and the release button 19 corresponding to each quick connection terminal is opened in the bottom wall of each terminal storage chamber 16a, 16b. The quick connection terminal in one terminal storage chamber 16a constitutes the power supply terminal 33 shown in FIG. 1, and the quick connection terminal in the other terminal storage chamber 16b is a changeover switch for selecting between continuous lighting and automatic lighting shown in FIG. SW ₁ The terminal 34 for connecting is configured.
[0019]
Circuit elements constituting the circuit shown in FIG. 1 are mounted on the circuit board 6 and lead wires 23 from the lamp socket 4 are connected thereto. The circuit board 6 is placed on a step 3C formed at the opening edge of the circuit board storage chamber 3B, and provided on a rib 9 formed in the circuit board storage chamber 3B through a notch 8 formed at a side edge of the circuit board 6. It is fixed to the body 1A using fixing screws 7 screwed into the holes 10.
[0020]
In the circuit formed on the circuit board 6, as shown in FIG. 1, both ends of the AC power supply AC connected to the power supply terminal 33, a power cutoff switch SW that is turned off when the lamp is replaced. ₂ And the diode D ₁ And the current limiting resistance R ₁ And operation indicator LED consisting of light-emitting diode ₁ The diode bridge DB is connected via ₁ And current limiting resistance R ₁ And operation indicator LED ₁ And the incandescent lamp 5 is connected in parallel to the series circuit. The diode bridge DB has a switching element S composed of a thyristor connected in parallel between both output terminals. When the switching element S is triggered by the control circuit 40 to be turned on, the incandescent lamp 5 is connected to the diode bridge DB and the switch. It is lit by being connected to the AC power source AC through the element S.
[0021]
Diode D ₁ The half-wave rectified pulsating current is converted into a stable predetermined DC voltage by the power supply circuit unit 41 including a three-terminal regulator IC. The power supply circuit section 41 supplies power to the control circuit 40, ₂ And a brightness sensor 42 made of CdS for detecting ambient illuminance.
The control circuit 40 monitors the voltage across the brightness sensor 42, and monitors the ambient illuminance based on the voltage across the brightness sensor 42. That is, when the ambient illuminance is high (bright), the voltage across the brightness sensor 42 decreases, so that the ambient illuminance can be detected according to the voltage across the brightness sensor 42. The control circuit 40 is connected to a heat ray sensor 43 composed of a pyroelectric infrared sensor. When a heat ray from a human body enters the visual field of the heat ray sensor 43, the brightness is increased when a detection output is generated from the heat ray sensor 43. If the ambient illuminance detected by the sensor 42 is less than or equal to a predetermined value, the control circuit 40 validates the detection output and gives a trigger signal to the switch element S. Further, a time constant circuit 44 is connected to the control circuit 40, and the control circuit 40 stops the trigger signal to the switch element S after a fixed time set by the time constant circuit 44 after the detection output stops. ing. The time constant circuit 44 includes a variable resistor VR that can change the time constant. ₁ Is provided as a time setting unit. The control circuit 40 is also connected to a CR circuit 45 that determines the oscillation frequency of the internal clock oscillation circuit.
[0022]
On the other hand, a terminal 34 is connected to the input terminal of the diode bridge DB, and the switch SW described above is connected between the two terminals 34. ₁ Can be connected. Therefore, changeover switch SW ₁ When the is turned on, the incandescent lamp 5 is switched to the selector switch SW. ₁ The incandescent lamp 5 can be lit continuously regardless of whether the switch element S is on or off. Also, a changeover switch SW ₁ When the switch is turned off, the incandescent lamp 5 can be automatically turned on / off according to the on / off of the switch element S based on the control of the control circuit 40.
[0023]
By the way, the heat ray sensor 43, the brightness sensor 42, and the operation indicator LED ₁ And variable resistor VR ₁ Is located on the surface on one side of the circuit board 6 as shown in FIG. ₂ Is disposed on the surface on the other side of the circuit board 6, and when the cover 1 </ b> B is attached to the body 1 </ b> A, the light-receiving window 28 provided on the cover 1 </ b> B is provided near the detection surface of the heat ray sensor 43 and near the heat ray sensor 43. Operation indicator LED ₁ , The light receiving surface of the brightness sensor 42 faces the light receiving window 27 separately provided on the cover 1B, and the variable resistor VR is inserted into the insertion hole 25 provided on the cover 1B. ₁ Of the power cutoff switch SW is inserted through the operation hole 26 provided in the cover 1B. ₂ The actuator of this type comes to face.
[0024]
Here, the cover 1 </ b> B includes a protrusion 51 that fits in the central opening of the synthetic resin mounting frame 50 or the metal mounting frame, and has shoulders 52 that protrude from both side surfaces of the protrusion 51. The shoulder 52 is provided with two pairs of locking claws 54 which are removably engaged with locking holes 53 provided in a synthetic resin mounting frame 50. Further, two locking recesses 55 into which the locking portions of the metal mounting frame are engaged are provided at the bases on both side surfaces of the projecting stand 51, and a synthetic resin is provided in the same manner as a general embedded wiring device. It can be attached to a switch box or an embedding hole embedded in a wall surface using a mounting frame 50 made of metal (or a metal mounting frame).
[0025]
An opening window 60 corresponding to the lamp housing chamber 3A of the body 1A is provided in the protruding base 51 of the cover 1A, and a shade 61 shown in FIG. 3 formed of a translucent resin is detachably attached to the opening window 60. And the illumination light of the incandescent lamp 5 goes out through the shade 61 to the outside.
The sail 61 engages a locking claw 62 projecting from the back surface of one side into a locking hole 63 opened on a corresponding inner surface of the opening window 60, and a locking provided on the outer surface of the other side of the shade 61. The protrusion 68 is fixed to the cover 1 </ b> B by elastically engaging a locking recess (not shown) provided on the corresponding inner surface of the opening window 60. To remove the sail 61 from the cover 1B, insert a jig such as the tip of a flathead screwdriver through a groove 65 provided at the opening edge of the opening window 60 into a removal groove 64 provided on the outer surface of the other side of the shade 61, The jig is removed and locked in the groove 64, and the other side of the shade 61 is lifted using the jig as a lever to release the locking projection 63 from the locking recess. By removing the shade 61 in this way, the incandescent lamp 5 in the lamp storage chamber 3A can be replaced.
[0026]
On the back surface of one end of the shade 61, when it is attached to the opening window 60, it is inserted into the operation hole 26 provided in the cover 1B and the power cutoff switch SW in the body 1A. ₂ Switch for power shutdown by pushing the actuator ₂ A push-in protrusion 66 for turning on is projected. Therefore, when the shade 61 is removed, the power cutoff switch SW ₂ Is turned off, and in this state, power is not supplied to the incandescent lamp 5, so that the danger of electric shock is prevented and the incandescent lamp 5 is not unnecessarily turned on. The shade 61 is also provided with a pressing projection 67 for pressing the front surface of the lamp socket 4 in the lamp storage chamber 3A of the body 1A to fix the lamp socket 4 in a fixed position.
[0027]
The above-described light receiving windows 27 and 28 and the insertion hole 25 are opened in the protruding base 51 of the cover 1B, and the lens portion 71 of the light receiving cover 70 attached to the inside of the cover 1B is fitted into the light receiving window 27, 71 allows external light to be collected on the light receiving surface of the brightness sensor 42. An optical block 76 composed of a lens body 73 integrally formed with a number of condensing lenses and a mirror support 75 provided with a reflection mirror 74 is mounted on the light receiving window 28.
[0028]
The mirror support 75 has a rectangular frame shape, and a V-shaped reflection mirror 74 is supported and arranged above the center of the opening. On the other hand, the lens body 73 is a synthetic resin molded product formed in a box shape having inclined surfaces on both sides and having an open rear surface, and a condenser lens is integrally formed on the inclined surface and the front surface. The lens body 73 is fitted into the light receiving window 28 from the back side, and the periphery of the lens body 73 is provided in a recess (not shown) provided inside the protruding wall 77 formed to protrude from the front surface opening of the light receiving window 28. In this state, the reflecting mirror 74 of the mirror support 75 is inserted into the lens body 73 from the rear surface side, and the upper end of the reflecting mirror 74 is brought into contact with the lens body 73 to hold the lens body 73. Thus, the lens body 73 and the mirror indicating band 75 are fixed to the cover 1B by fixing the mirror support 75 to the back surface of the cover 1B with the fixing screw 79.
[0029]
Here, each condenser lens of the lens body 73 has an optical axis passing through the effective detection field of view of the heat ray sensor 43, and focuses on the detection surface of the chip of the heat ray sensor 43. On the other hand, the reflection mirror 73 reflects the heat rays transmitted through the condenser lens that do not pass through the effective field of view of the heat ray sensor 43 to pass through the effective field of view of the heat ray sensor 43, and condenses the light on the light receiving surface of the heat ray sensor 43. It has a function of expanding the detection area of the heat ray sensor 43. That is, the combination of the reflection mirror 74 and the lens body 73 allows the heat rays to be condensed at a wide angle even when the amount of protrusion of the cover 1B to the front side is reduced, and a person who is far from the installation position of the instrument body 1 The heat rays from the sensor can also be focused on the heat ray sensor 43, and the detection distance can be extended.
[0030]
By the way, the back surface of the projecting stand 51 of the cover 1B is a double that blocks the space between the lamp housing chamber 3A and the portion where the heat ray sensor 43 is accommodated by contacting the upper end of the partition wall 2 when it is attached to the body 1A. A partition wall 80 having a structure is provided, and the partition wall 80, the partition wall 2 of the body 1A, and the circuit board 6 are insulated so that heat from the incandescent lamp 5 does not affect the heat ray sensor 42.
[0031]
Further, in order to release the heat of the incandescent lamp 5, an air discharge hole 81 is formed on the side wall of the lamp storage chamber 3A, which becomes the upper wall when the fixture body 1 is disposed on the wall surface, to communicate the inside and the outside. An air inflow hole 82 (see FIG. 6) is opened in the rear wall and at the lower part of the lamp housing 3A. In other words, the convection generated by the heat generated by the incandescent lamp 4 causes cold outside air from the air inlet 82 to flow into the lamp housing 3A and hot air to flow out from the air outlet 81, thereby suppressing a rise in the temperature of the lamp housing 3A. It has become.
[0032]
At the time of actual construction, the instrument body 1 may be attached to the attachment frame 50 and the attachment frame 50 may be attached to a switch box or the like. A decorative cover 83 is attached to the front side of the attachment frame 50. The decorative cover 83 is attached to the front side of the mounting frame 50 by engaging a locking claw 84 projecting from the rear surface of the peripheral portion into the locking portion 85 of the mounting frame 50.
However, in the night light according to the present embodiment, when the ambient temperature is lower than a predetermined value and the ambient temperature is dark and the heat ray from the human body is detected by the heat ray sensor 43 and a detection signal is generated, the control circuit 40 turns on the switch element S. The incandescent lamp 5 is connected to the AC power supply AC through the diode bridge DB and the switch element S, and is turned on. When the detection signal from the hot-wire sensor 43 stops, the control circuit 40 turns off the switch element S after a certain time set by the time constant circuit 44 to stop energizing the incandescent lamp 5 and turn off the light. Here, the time from the stop of the detection output to the turning off of the incandescent lamp 5 is determined by the variable resistor VR. ₁ Can be adjusted by the variable resistor VR ₁ Since the operation part is exposed on the front side of the instrument body 1, the time can be adjusted according to the installation conditions.
[0033]
(Embodiment 2)
The present embodiment has the same appearance as the first embodiment, but a variable resistor VR for adjusting the time constant of the time constant circuit 44. ₁ Instead, as shown in FIG. 7, the brightness sensor 42 includes a variable resistor VR as a brightness setting unit. ₂ Are connected in series. This variable resistor VR ₂ Is adjusted, the voltage at both ends of the brightness sensor 42 changes, so that it is possible to adjust the ambient illuminance when the detection output of the heat ray sensor 43 is enabled.
[0034]
That is, in the first embodiment, the ambient illuminance when the incandescent lamp 5 is turned on is fixedly set. However, depending on the installation conditions and the sense of the user, it is necessary to adjust the ambient illuminance when the incandescent lamp 5 is turned on. May be done. In this embodiment, the variable resistor VR ₂ By satisfying this requirement, this requirement is satisfied. Variable resistor VR ₂ Is the variable resistor VR of the first embodiment. ₁ Since it is mounted on the circuit board 6 instead of the above, the appearance is the same as that of the first embodiment, but in this embodiment, there is no function for adjusting the time constant. Other configurations and operations are the same as those of the first embodiment.
[0035]
(Embodiment 3)
In this embodiment, as shown in FIG. ₁ , VR ₂ Switch and switch SW ₁ Is not provided, but a state in which the incandescent lamp 5 is automatically turned on / off according to the detection output of the heat ray sensor 43, a state in which the incandescent lamp 5 is always turned on, and a state in which the incandescent lamp 5 is always turned off Selection switch SW for selecting the state to be activated _Three Is provided. That is, the selection switch SW is connected to one end of the incandescent lamp 5. _Three Are connected to the common contact, and the continuous contact point r ₁ Is connected to one power supply terminal 33, and the automatic lighting contact r ₂ Is connected to one input terminal of the diode bridge DB, and the contact r which is continuously turned off. _Three Is not connected anywhere. That is, the contact r ₁ Is selected, the changeover switch SW in the first embodiment is selected. ₁ The incandescent lamp 5 is continuously lit regardless of the output of the brightness sensor 42 or the heat ray sensor 44, and the contact point r. ₂ Is selected, the changeover switch SW in the first embodiment is selected. ₁ The incandescent lamp 5 is turned on when the detection output of the heat ray sensor 43 is obtained when the ambient illuminance is equal to or less than a predetermined value. Also, contact r _Three Is selected, power is not supplied to the incandescent lamp 5, so that the incandescent lamp 5 continues to be turned off regardless of the output of the brightness sensor 42 or the heat ray sensor 43.
[0036]
The basic appearance is the same as that of the first embodiment, but the variable resistor VR is ₁ There is no selection switch SW _Three 9 and 10, the projecting base 51 of the cover 1B is formed with a window hole 24 that opens in a rectangular shape instead of the insertion hole 25. Select switch SW _Three Is a slide switch, and the peripheral rear surface of the window hole 24 and the selection switch SW _Three Select switch SW between _Three A knob 35 for operating is held. A part of the knob 35 protrudes from the window hole 24, and if necessary, the selection switch SW _Three Can be operated easily. In addition, the selection switch SW is connected to the instrument body 1. _Three By providing the switch SW having the same function as in the first embodiment ₁ It is not necessary to provide the outside, and labor is saved in construction and space is saved. Other configurations and operations are the same as those of the first embodiment.
[0037]
(Embodiment 4)
As shown in FIG. 11, the present embodiment is a night light which does not have a heat ray sensor and turns on and off the incandescent lamp 5 only by the output of the brightness sensor 42, and is used by being inserted into an outlet. A night light that can supply power to the incandescent lamp 5 by the built-in secondary battery B when the AC power supply AC is out of power and can be used as a flashlight when removed from the outlet is illustrated.
[0038]
As shown in FIG. 12, the night light according to the present embodiment includes a rectangular parallelepiped appliance main body 100, and a pair of plug blades 101 that can be inserted into an outlet protrude from a rear surface of the appliance main body 100. A lens body 102 for extracting light from the incandescent lamp 5 is detachably mounted on the front surface of the instrument body 100. The lens body 102 has an engaging claw (not shown) protruding rearward, and is coupled to the instrument body 100 by engaging the engaging claw with the instrument body 100. Also, by pressing the projections 103 protruding from both sides of the lens body 102, the engagement state between the engaging claw and the apparatus main body 100 is released, and the lens body 102 can be detached from the apparatus main body 100. It is.
[0039]
A light receiving window 104 for introducing external light to the brightness sensor 42 is formed on the side surface of the instrument body 100 (upper surface when plugged into an outlet). Further, as shown in FIG. 13, the circuit shown in FIG. 11 is provided inside the apparatus main body 100 in addition to the incandescent lamp 5, and when the lens body 102 is removed, a switch SW described later is provided. _Four The operation part is exposed.
[0040]
As shown in FIG. 11, the night light circuit according to the present embodiment is connected to an AC power supply (commercial power supply) AC by inserting a plug blade 101 into an outlet, and after the AC power supply AC is stepped down by a transformer T, a diode bridge DB is provided. ₂ Rectified with a smoothing capacitor C ₁ The power of the internal circuit is obtained by smoothing with. The brightness sensor 42 made of CdS has a resistance R _Three Switch SW _Four Through the smoothing capacitor C ₁ It is connected to both ends. Brightness sensor 42 and resistance R _Three Transistor Q ₁ Is connected to the transistor Q ₁ The collector-emitter of the transistor Q ₂ Connected between the base and the emitter. Transistor Q ₂ Is based on a diode D _Four , Zener diode ZD ₁ Smoothing capacitor C ₁ Connected to the positive electrode of the smoothing capacitor C ₁ Zener diode ZD ₁ Becomes conductive and transistor Q ₂ To forward bias. Here, the transistor Q ₁ When turned on, transistor Q ₂ Between the base and emitter of the transistor Q ₁ Transistor Q ₂ Turns off. That is, when the ambient illuminance detected by the brightness sensor 42 is not more than a predetermined value and the resistance value of the brightness sensor 42 is high, the transistor Q ₂ Turns on and diode D _Three The incandescent lamp 5 is supplied with power through a part of the diode bridge DB, and the incandescent lamp 5 is turned on.
[0041]
If the voltage of the AC power supply AC is normal with the plug blade 101 plugged in, the diode bridge DB ₂ Output is diode D _Four Is also used for charging the secondary battery B via the.
By the way, the smoothing capacitor C ₁ Is the resistance R _Four , R _Five Is divided by the transistor Q _Three Is applied to the base. This transistor Q _Three The collector-emitter of the capacitor C ₂ And resistance R ₆ Is connected in parallel to a series circuit with a capacitor C ₂ And resistance R ₆ Series circuit with the resistor R ₇ Is connected to the secondary battery B. Capacitor C ₂ And resistance R ₆ Is connected from the secondary battery B to the transistor Q ₂ Thyristor S to give bias to ₂ Connected to the gate of transistor Q _Three Is turned off, capacitor C ₂ Thyristor S by the current flowing from secondary battery B through ₂ Is supposed to turn on. That is, the voltage of the AC power supply AC decreases and the transistor Q _Three Is turned off, thyristor S ₂ Turns on and transistor Q ₂ Is made conductive. Zener diode ZD ₁ Is conductive, transistor Q _Four Since the base potential of transistor Q is low, transistor Q _Four Is off, and the transistor Q inserted between the secondary battery B and the incandescent lamp 5 _Five Is also off, but the voltage of the AC power supply AC drops and the Zener diode ZD ₁ When the transistor stops conducting, the transistor Q _Four Has Thyristor S ₂ Forward bias through transistor Q _Four And transistor Q _Five Is turned on. That is, power can be supplied to the incandescent lamp 5 from the secondary battery B.
[0042]
Thyristor S ₂ Has Thyristor S ₁ Are connected in parallel, and this thyristor S ₁ Is the switch SW _Five Is connected to the positive electrode of the secondary battery B via the switch SW ₆ Is connected to the negative electrode of the secondary battery B. Therefore, switch SW _Five Turn on the thyristor S ₁ Is turned on, power can be supplied to the incandescent lamp 5, and the switch SW ₆ Turn on the thyristor S ₁ Is turned off, and the power supply to the incandescent lamp 5 is stopped. Here, switch SW _Five , SW ₆ Is used only when the pressing operation is performed. The voltage of the AC power supply AC is normal and the Zener diode ZD ₁ Is conductive, transistor Q ₂ Is the smoothing capacitor C ₁ Switch SW _Five , SW ₆ The operation of becomes invalid.
[0043]
Furthermore, diode D _Four The above-mentioned switch SW _Four Switching contacts a and b are connected to the switch SW. _Four These common contacts are connected to the brightness sensor 42. Then, switch SW _Four Is connected to the contact a side, the output of the brightness sensor 42 is effective only when the power is supplied from the AC power supply AC. _Five , SW ₆ Thus, the incandescent lamp 4 can be turned on and off. Further, the incandescent lamp 5 is turned on by power supply from the secondary battery B when the voltage of the AC power supply AC is lowered, such as during a power failure, regardless of the ambient illuminance.
[0044]
On the other hand, switch SW _Four When the contact b is selected, power is supplied to the brightness sensor 42 from both the AC power supply AC and the secondary battery B, so that the surrounding illuminance does not decrease even when the voltage of the AC power supply AC decreases such as during a power failure. The incandescent lamp 5 does not turn on and the switch SW _Five Is operated, the incandescent lamp 5 is not turned on unless the ambient illuminance is low. In other words, when power is supplied from the secondary battery B to the incandescent lamp 5, the switch SW is used to turn on the lamp according to the ambient illuminance or regardless of the ambient illuminance. _Four Can be selected.
[0045]
【The invention's effect】
The invention according to claim 1 provides an appliance body having a plug blade that can be inserted into an outlet of a commercial power supply, a lamp that emits illumination light on the front side of the appliance body, a brightness sensor that detects ambient illuminance, and a commercial power supply. A secondary battery that is charged when connected, and a power supply switching unit that feeds the lamp as a power source when the voltage from the commercial power supply is no longer detected, Provided are a diode inserted between the commercial power source and the secondary battery, and a switch having a switching contact connected to both ends of the diode and a common contact connected to the brightness sensor. When supplying power from commercial power Only to When the ambient illuminance falls below the specified value, the lamp is lit and when the power is supplied from the secondary battery, the lamp is lit regardless of the ambient illuminance. And the quotient Select whether to turn on the lamp when the ambient illuminance is below a predetermined value when power is supplied from either the power supply or the secondary battery Rumo Therefore, the lamp can be turned on when the commercial power supply is interrupted or the power is removed from the outlet, and the lamp is turned on only when the ambient illuminance is reduced according to the switch setting. Can be selected. That is, when connected to an outlet, the power is linked to the ambient illuminance, so that useless power consumption can be suppressed. Also, if power is selected from the secondary battery so that it is linked to the ambient illuminance, even if a power failure occurs, if the ambient illuminance is high, the secondary battery is not discharged and unnecessary consumption of the secondary battery is reduced. Can be prevented.
[Brief description of the drawings]
FIG. 1 is a circuit diagram showing a first embodiment.
FIG. 2 is an exploded perspective view showing the first embodiment.
FIG. 3 is an exploded perspective view showing the first embodiment.
FIG. 4 is a front view of the first embodiment.
FIG. 5 is a side view of the first embodiment.
FIG. 6 is a rear view of the first embodiment.
FIG. 7 is a circuit diagram showing a second embodiment.
FIG. 8 is a circuit diagram showing a third embodiment.
FIG. 9 is an exploded perspective view showing a third embodiment.
FIG. 10 is an exploded perspective view showing a third embodiment.
FIG. 11 is a circuit diagram showing a fourth embodiment.
FIG. 12 is a perspective view of a fourth embodiment.
FIG. 13 is a perspective view illustrating a state where a lens body according to a fourth embodiment is removed.
[Explanation of symbols]
1 instrument body
5 Incandescent lamp
40 control circuit
42 Brightness Sensor
43 Heat ray sensor
VR ₁ Variable resistor
VR ₂ Variable resistor

Claims (1)

Charged when connected to a commercial power source, a fixture body with a plug blade that can be plugged into a commercial power outlet, a lamp that emits illumination light on the front side of the fixture body, a brightness sensor that detects ambient illumination Secondary battery, a power supply switching unit that supplies power to the lamp using the secondary battery as a power source when the voltage from the commercial power source is no longer detected, a diode inserted between the commercial power source and the secondary battery, A switch with switching contacts connected to both ends and a common contact connected to the brightness sensor is provided, and the switch turns on the lamp when the ambient illuminance falls below a predetermined value only when power is supplied from a commercial power source. during feeding and state for lighting the lamp Notwithstanding the ambient illumination, and a state where the surrounding illuminance is to light the lamp when the predetermined value or less even when feeding from either the commercial power supply and rechargeable battery selection Night Light characterized by and to Turkey.

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