JP2014007035A - Lamp - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lamp in which, when receiving vibration, a light-emitting diode is automatically lightened, and automatically extinguished after lighting for a constant time period, and that is configured by a simple electronic circuit.SOLUTION: A lamp is configured by a positive electrode connection terminal 2, a negative electrode connection terminal 3, a light-emitting diode 4, a vibration sensor 5, an electrolytic capacitor 6, a resistor 7, and a bipolar NPN-type transistor 8. The light-emitting diode 4 has an anode terminal and a cathode terminal. The vibration sensor 5 has a vibration sensor first terminal and a vibration sensor second terminal. The electrolytic capacitor 6 has an electrolytic capacitor positive electrode terminal, and an electrolytic capacitor negative electrode terminal. The resistor 7 has a resistor first terminal and a resistor second terminal. The bipolar NPN-type transistor 8 has a base terminal, a collector terminal, and an emitter terminal.

Description

  The present invention relates to a lamp that automatically turns off after a light-emitting diode is automatically turned on for a certain period of time when subjected to vibration.

  In some electric lamps, a light emitting diode, a lamp, and the like are automatically turned on, turned on for a certain period of time, and then automatically turned off.

  Background art includes Patent Document 1 and Patent Document 2.

  The toilet lamp shown in Patent Document 1 can be automatically turned off after the toilet lamp is automatically turned on and turned on for a certain period of time, but the toilet lamp is automatically turned on and turned on for a fixed period of time. Later, in order to turn off automatically, an alternate switch device must be installed on the toilet door.

The illumination device disclosed in Patent Document 2 is configured by a complicated electronic circuit, which can automatically turn off the lamp after being turned on automatically for a certain period of time when it receives vibration.
Patent Publication 2005-302480 Japanese Patent Publication No. 9-163628

  An object of the present invention is to provide an electric lamp including a simple electronic circuit that automatically turns off after a light emitting diode is automatically turned on for a certain period of time when subjected to vibration.

  In order to solve the above problems, the electric lamp of the present invention includes a positive electrode connection terminal, a negative electrode connection terminal, a light emitting diode, a vibration sensor, an electrolytic capacitor, a resistor, and a bipolar NPN transistor.

The light emitting diode has an anode terminal and a cathode terminal.
The vibration sensor has a vibration sensor first terminal and a vibration sensor second terminal.
The electrolytic capacitor has an electrolytic capacitor positive terminal and an electrolytic capacitor negative terminal.
The resistor has a first resistor terminal and a second resistor terminal.
The bipolar NPN transistor has a base terminal, a collector terminal, and an emitter terminal.
The positive electrode connection terminal is connected to the vibration sensor first terminal and the anode terminal.
The vibration sensor second terminal is connected to the electrolytic capacitor positive terminal and the resistance first terminal.
The electrolytic capacitor negative electrode terminal is connected to the negative electrode connection terminal.
The resistor second terminal is connected to the base terminal.
The collector terminal is connected to the cathode terminal.
The emitter terminal is connected to the negative electrode connection terminal.

In order to light the light emitting diode of the electric lamp of the present invention, current must be supplied from the power source to the electric lamp of the present invention.
The power source has a power source positive electrode and a power source negative electrode.
In order to supply current from the power supply to the lamp of the present invention, the power supply positive electrode and the positive electrode connection terminal must be connected, and the power supply negative electrode and the negative electrode connection terminal must be connected.

  When the electric lamp of the present invention receives vibration after being supplied with current from the power source, it operates as follows.

When the electric lamp of the present invention receives vibration, the vibration sensor senses the vibration, so that the current can be passed between the vibration sensor first terminal and the vibration sensor second terminal.
When energization is enabled between the vibration sensor first terminal and the vibration sensor second terminal, a current flows from the power supply positive electrode to the electrolytic capacitor positive electrode terminal and the resistor first terminal, and a current flows from the resistor second terminal to the base terminal.
When current flows from the power supply positive electrode to the electrolytic capacitor positive electrode terminal, electric charge is accumulated in the electrolytic capacitor.
When the vibration sensor no longer senses vibration, current cannot flow between the vibration sensor first terminal and the vibration sensor second terminal, so no current flows from the power supply positive electrode to the electrolytic capacitor positive terminal and the resistance first terminal. No current flows from the resistor second terminal to the base terminal.

When no current flows from the power supply positive electrode to the electrolytic capacitor positive electrode terminal, the electrolytic capacitor is discharged.
When the electrolytic capacitor is discharged, a current flows from the electrolytic capacitor positive terminal to the first resistor terminal, and a current flows from the second resistor terminal to the base terminal.
When a current flows through the base terminal, current can be passed between the collector terminal and the emitter terminal.
When the collector terminal and the emitter terminal can be energized, a current flows from the power supply positive electrode to the anode terminal, so that the light emitting diode is turned on.
When there is no charge stored in the electrolytic capacitor, no current flows from the positive electrode terminal to the first resistor terminal, and no current flows from the second resistor terminal to the base terminal. It becomes impossible to energize.
When the current cannot flow between the collector terminal and the emitter terminal, no current flows from the power supply positive electrode to the anode terminal, and the light emitting diode is turned off.

  The electric lamp of the present invention operates in such a manner when it receives vibration from a power supply, and therefore the light emitting diode of the present invention automatically lights up for a certain period of time when it receives vibration. After turning on, it can be turned off automatically.

The toilet lamp shown in Patent Document 1 can be automatically turned off after the toilet lamp is automatically turned on and turned on for a certain period of time, but the toilet lamp is automatically turned on and turned on for a fixed period of time. Later, in order to turn off automatically, an alternate switch device must be installed on the toilet door.
In the electric lamp of the present invention, when the vibration sensor senses vibration, the light emitting diode automatically turns on and accumulates in the electrolytic capacitor by allowing the current between the vibration sensor first terminal and the vibration sensor first terminal to be energized. The light of the present invention automatically turns off the light emitting diode without installing a switch on the door or wall. It can be turned off automatically after being turned on and turned on for a certain period of time.

The illumination device disclosed in Patent Document 2 is configured by a complicated electronic circuit, which can automatically turn off the lamp after being turned on automatically for a certain period of time when it receives vibration.
Since the electric lamp of the present invention is composed of a positive electrode connection terminal, a negative electrode connection terminal, a light emitting diode, a vibration sensor, an electrolytic capacitor, a resistor, and a bipolar NPN transistor, it is composed of a simple electronic circuit, but receives vibration. Then, after the light emitting diode is automatically turned on and turned on for a certain period of time, it can be turned off automatically.

  When the vibration sensor senses vibration, the light of the present invention can automatically turn off the light-emitting diode after turning it on for a certain period of time.

  The best mode for carrying out the invention will be described with reference to the drawings.

  As shown in FIG. 1, the lamp 1 according to the first embodiment includes a positive electrode connection terminal 2, a negative electrode connection terminal 3, a light emitting diode 4, a vibration sensor 5, an electrolytic capacitor 6, a resistor 7, and a bipolar NPN transistor 8.

As shown in FIG. 1, the light-emitting diode 4 has an anode terminal 4a and a cathode terminal 4b.
As shown in FIG. 1, the vibration sensor 5 has a vibration sensor first terminal 5a and a vibration sensor second terminal 5b.
As shown in FIG. 1, the electrolytic capacitor 6 includes an electrolytic capacitor positive terminal 6a and an electrolytic capacitor negative terminal 6b.
As shown in FIG. 1, the resistor 7 has a resistor first terminal 7a and a resistor second terminal 7b.
As shown in FIG. 1, the bipolar NPN transistor 8 has a base terminal 8a, a collector terminal 8b, and an emitter terminal 8c.
As shown in FIG. 1, the positive electrode connection terminal 2 is connected to the vibration sensor first terminal 5a and the anode terminal 4a.
As shown in FIG. 1, the vibration sensor second terminal 5b is connected to the electrolytic capacitor positive terminal 6a and the resistance first terminal 7a.
The electrolytic capacitor negative electrode terminal 6b is connected to the negative electrode connection terminal 3 as shown in FIG.
The resistance second terminal 7b is connected to the base terminal 8a as shown in FIG.
As shown in FIG. 1, the collector terminal 8b is connected to the cathode terminal 4b.
The emitter terminal 8c is connected to the negative electrode connection terminal 3 as shown in FIG.

In order to turn on the light emitting diode 4 of the lamp 1 of the first embodiment, current must be supplied from the power source 9 to the lamp 1 of the first embodiment as shown in FIG.
As shown in FIG. 2, the power source 9 includes a power source positive electrode 9a and a power source negative electrode 9b.
In order to supply current from the power source 9 to the lamp 1 of the first embodiment, as shown in FIG. 2, the power source positive electrode 9a and the positive electrode connection terminal 2 are connected, and the power source negative electrode 9b and the negative electrode connection terminal 3 are connected. There must be.

  The capacitance of the electrolytic capacitor 6, the resistance value of the resistor 7, and the model number of the bipolar NPN transistor 8 in the lamp 1 of Example 1 can be considered as various, but the capacitance of the electrolytic capacitor 6 is 470 μF, and the resistance The resistance value of 7 may be 100 kΩ, and the model number of the bipolar NPN transistor 8 may be 2SC1815.

Although there are various types of vibration sensors 5 of the electric lamp 1 of the first embodiment, the vibration sensor 5 having a built-in metal ball may be used as the vibration sensor 5 of the electric lamp 1 of the first embodiment.
Further, the vibration sensor 5 with a built-in metal sphere includes a first metal sphere built-in vibration sensor 5c as shown in FIGS. 3A, 3B, 3C, 3D, and 3E, and FIG. (b) There is a second metal ball built-in vibration sensor 5d as shown in (c), (d) and (e).
The first metal ball built-in vibration sensor 5c and the second metal ball built-in vibration sensor 5d are respectively shown in FIGS. 3 (a) (b) (c) (d) (e) and FIGS. 4 (a) (b) (c). (d) As shown in (e), a box 5ea, a metal ball 5eb, a metal ball built-in vibration sensor first terminal 5ec, a metal ball built-in vibration sensor second terminal 5ed, a metal ball built-in vibration sensor first metal wire 5ee, A metal ball built-in vibration sensor second metal wire 5ef is provided.

As shown in FIGS. 3 (a) (b), 4 (a) (b), the box body 5ea has a box body first side face 5eaa, a box body second side face 5eab, a box body third side face 5eac, The box body has a fourth side surface 5ead, the upper surface has a box body upper surface 5eae, the lower surface has a box body lower surface 5aef, and the box body first side surface 5eaa has a box body opening 5eag.
The metal ball built-in vibration sensor first terminal 5ec and the metal ball built-in vibration sensor second terminal 5ed are arranged in a box as shown in FIGS. 3 (c) (d) (e) and 4 (c) (d) (e). It is installed in the body opening 5eag.
As shown in FIGS. 3 (c) (d) (e) and 4 (c) (d) (e), the metal ball built-in vibration sensor first metal wire 5ee is connected to the metal ball built-in vibration sensor first terminal 5ec. Extending from the metal ball built-in vibration sensor first terminal 5ec toward the inside of the box 5ea, the metal ball built-in vibration sensor second metal wire 5ef is a metal ball built-in vibration sensor second. From the terminal 5ed toward the inside of the box 5ea, it extends from the metal ball built-in vibration sensor second terminal 5ed and is formed in a substantially linear shape.
The metal ball built-in vibration sensor first terminal 5ec, the metal ball built-in vibration sensor second terminal 5ed, the metal ball built-in vibration sensor first metal wire 5ee, and the metal ball built-in vibration sensor second metal wire 5ef are formed of metal.
Metals include iron, aluminum, and stainless steel.

The metal sphere 5eb is made of metal and has a substantially spherical shape as shown in FIGS. 3 (c) (d) (e) and FIGS. 4 (c) (d) (e). .
Further, as shown in FIGS. 3 (c) (d) (e) and FIGS. 4 (c) (d) (e), the metal ball 5eb is built in the box 5ea, and has a built-in metal ball vibration. The sensor is in contact with the second metal wire 5ef.

When the first metal ball built-in vibration sensor 5c and the second metal ball built-in vibration sensor 5d sense vibrations in the major axis direction of the box 5ea, the metal ball 5eb becomes the metal ball built-in vibration sensor second metal line 5ef. As shown in FIGS. 3 (d) and 4 (d), the metal ball built-in vibration sensor first metal wire 5 ee and the metal ball built-in vibration sensor first metal wire 5 ee come into contact with the metal ball built-in vibration sensor first metal wire 5 ee. It becomes possible to energize between the ball built-in vibration sensor second metal wire 5ef.
When energization is possible between the metal ball built-in vibration sensor first metal line 5ee and the metal ball built-in vibration sensor second metal line 5ef, the metal ball built-in vibration sensor first terminal 5ec and the metal ball built-in vibration sensor second terminal 5ed are connected. Can be energized.

When the first metal sphere built-in vibration sensor 5c and the second metal sphere built-in vibration sensor 5d no longer sense vibration, the metal sphere 5eb is a metal sphere as shown in FIGS. 3 (e) and 4 (e), respectively. Since the built-in vibration sensor does not come into contact with the first metal wire 5ee, it becomes impossible to energize between the metal ball built-in vibration sensor first metal wire 5ee and the metal ball built-in vibration sensor second metal wire 5ef.
When energization is possible between the metal ball built-in vibration sensor first metal line 5ee and the metal ball built-in vibration sensor second metal line 5ef, the metal ball built-in vibration sensor first terminal 5ec and the metal ball built-in vibration sensor second terminal 5ed are connected. Becomes impossible to energize.

  When the first metal ball built-in vibration sensor 5c and the second metal ball built-in vibration sensor 5d are installed in the lamp 1 according to the first embodiment with the major axis direction of the box 5ea parallel to the horizontal line, the vibration is not detected. However, since the metal ball 5eb contacts the metal ball built-in vibration sensor first metal wire 5ee, it becomes possible to energize between the metal ball built-in vibration sensor first terminal 5ec and the metal ball built-in vibration sensor second terminal 5ed. Sometimes.

When the first metal ball built-in vibration sensor 5c is installed in the electric lamp 1 of the first embodiment, the metal ball built-in vibration sensor first terminal 5ec and the metal ball built-in vibration sensor second terminal 5ed can be used without sensing vibration. In order to prevent the gap from being energized, the first metal ball built-in vibration sensor 5c has the box body second side surface 5eab or the box body fourth side surface 5ead upward, as shown in FIG. As shown in the figure, the long axis direction of the box 5ea may be installed in the electric lamp 1 of the first embodiment with the angle θ from the horizon being about −5 degrees to −15 degrees.
In FIG. 5A, the first metal ball built-in vibration sensor 5c is installed in the electric lamp 1 of the first embodiment with the box body fourth side surface 5lead facing up. The box body second side surface 5eab may be placed on the electric lamp 1 of the first embodiment.

  When the second metal ball built-in vibration sensor 5d is installed in the electric lamp 1 of the first embodiment, the metal ball built-in vibration sensor first terminal 5ec and the metal ball built-in vibration sensor second terminal 5ed do not sense vibration. In order to prevent the gap from being energized, the second metal ball built-in vibration sensor 5d has a box top surface 5eae facing upward, as shown in FIG. May be installed in the electric lamp 1 of the first embodiment with an angle θ from the horizon of about −5 degrees to −15 degrees.

If any one of the first metal ball built-in vibration sensor 5c or the second metal ball built-in vibration sensor 5d is installed in the lamp 1 of the first embodiment, the lamp 1 of the first embodiment is installed in the lamp 1 of the first embodiment. When either one of the first metal ball built-in vibration sensor 5c or the second metal ball built-in vibration sensor 5d senses vibration in the major axis direction of the box 5ea, the metal ball built-in vibration sensor first terminal 5ec Since it becomes possible to energize between the metal ball built-in vibration sensor second terminal 5ed, the light emitting diode 4 can be turned on automatically.
However, since both the first metal ball built-in vibration sensor 5c and the second metal ball built-in vibration sensor 5d have low ability to sense the vibration in the short axis direction of the box 5ea, When only one of the vibration sensor 5c with one metal sphere or the vibration sensor 5d with the second metal sphere is installed, the vibration sensor 5c with the first metal sphere installed in the lamp 1 of the first embodiment, or Even if any one of the second metal ball built-in vibration sensors 5d senses vibration in the short axis direction of the box 5ea, the metal ball built-in vibration sensor first terminal 5ec and the metal ball built-in vibration sensor second terminal During 5ed, the light emitting diode 4 may not be automatically turned on by not being energized.

In order to make it easy for the light-emitting diode 4 to automatically turn on regardless of the direction of vibration, the lamp 1 of the first embodiment includes a lamp 1 shown in FIG. As shown in FIG. 5, both the first metal ball built-in vibration sensor 5c and the second metal ball built-in vibration sensor 5d may be installed such that the major axis direction of the box 5ea is substantially perpendicular to each other.
As shown in FIG. 6A, both the first metal ball built-in vibration sensor 5c and the second metal ball built-in vibration sensor 5d are substantially perpendicular to each other in the long axis direction of the box 5ea. When the electric lamp 1 according to the first embodiment receives the vibration in the short axis direction of the box 5ea of the first metal ball built-in vibration sensor 5c, the box of the second metal ball built-in vibration sensor 5d is installed. When receiving vibration in the short axis direction of the box 5ea of the second metal ball built-in vibration sensor 5d, the box 5ea of the first metal ball built-in vibration sensor 5c is subjected to vibration in the long axis direction of the body 5ea. The lamp 1 of the first embodiment is limited to the horizontal vibration, but the light emitting diode 4 is automatically turned on regardless of the vibration in any direction. It becomes easy.

As shown in FIG. 6A, both the first metal ball built-in vibration sensor 5c and the second metal ball built-in vibration sensor 5d are substantially the same in the long axis direction of the box 5ea. Even when installing at a right angle, either one of the vibration sensor 5c built in the first metal sphere and the vibration sensor 5d built in the second metal sphere 5d or both without sensing vibration. In order to prevent energization between the metal ball built-in vibration sensor first terminal 5ec and the metal ball built-in vibration sensor second terminal 5ed, the first metal ball built-in vibration sensor 5c has a box body second side surface 5eab. Or, with the box fourth side surface 5ead up, the major axis direction of the box 5ea is set to an angle θ from the horizontal line of -5 degrees to -15 degrees as shown in FIG. 6 (b). Installed in the electric lamp 1 of Example 1 and a vibration sensor 5d with a second metal ball As shown in FIG. 6 (c), with the box upper surface 5eae facing upward, the long axis direction of the box 5ea is set to an angle θ from the horizontal line of about −5 degrees to −15 degrees, Must be installed in 1.
In FIG. 6B, the first metal ball built-in vibration sensor 5c is installed in the electric lamp 1 of the first embodiment with the box body fourth side surface 5lead facing up. The box body second side surface 5eab may be placed on the electric lamp 1 of the first embodiment.

As shown in FIG. 7, the first metal sphere built-in vibration sensor 5c and the second metal sphere built-in vibration sensor 5d include a metal sphere built-in vibration sensor first terminal 5ec and a second metal sphere built-in vibration sensor 5c. The vibration sensor 5d built-in metal ball vibration sensor first terminal 5ec is connected, the metal ball built-in vibration sensor first terminal 5ec of the first metal ball built-in vibration sensor 5c and the metal ball built-in vibration of the second metal ball built-in vibration sensor 5d. By connecting the sensor second terminal 5ed, they are connected in parallel.
Since the first metal sphere built-in vibration sensor 5c and the second metal sphere built-in vibration sensor 5d are connected in parallel as shown in FIG. 7, the first metal sphere built-in vibration sensor 5c or the second metal sphere built-in vibration sensor 5d is built in. Either one or both of the vibration sensors 5d sense vibration, and either one or both of the first metal sphere built-in vibration sensor 5c and the second metal sphere built-in vibration sensor 5d are detected. If current can be passed between the metal ball built-in vibration sensor first terminal 5ec and the metal ball built-in vibration sensor second terminal 5ed, current can be passed between the positive electrode connection terminal 2, the electrolytic capacitor positive electrode terminal 6a, and the resistor first terminal 7a. become.

  When the vibration sensor 5 is one or both of the first metal ball built-in vibration sensor 5c and the second metal ball built-in vibration sensor 5d, the vibration sensor first terminal 5a is a metal ball. The built-in vibration sensor first terminal 5ec and the vibration sensor second terminal 5b are the metal ball built-in vibration sensor second terminal 5ed.

The power source 9 may be a 9.0V battery or a DC power source.
Even if the power source 9 is a battery of 9.0V or less or a direct current power source and a current is supplied to the lamp 1 of the first embodiment, the light emitting diode 4 can be lit, but the power source 9 is a 9.0V battery or When the current is supplied to the lamp 1 of the first embodiment by using a DC power source, the light generated when the light emitting diode 4 is turned on becomes brighter.

  When the electric lamp 1 of Example 1 is subjected to vibration with the electrolytic capacitor 6 having a capacitance of 470 μF, the resistance value of the resistor 7 being 100 kΩ, the bipolar NPN transistor 8 having a model number of 2SC1815, and the power source 9 being a 9.0V battery. The light emitting diode 4 is lit for about 90 to 120 seconds.

The usage method of the electric lamp 1 of Example 1 is demonstrated.
The electric lamp 1 of Example 1 is installed in the storage case 10, as shown to Fig.8 (a).
As shown in FIG. 8A, the storage case 10 is provided with a storage case opening 11 so that a string 12 can be passed therethrough.
The storage case 10 must be at least partially transparent or translucent, as shown in FIG. 8A, so that the outside can be illuminated when the light-emitting diode 4 is lit. .
Although only one light emitting diode 4 is installed in FIG. 8A, two or more light emitting diodes 4 may be installed.
The door 13 has a door knob 14 as shown in FIGS.
As shown in FIGS. 8B and 8C, the storage case 10 is hung on the door knob 14 by hooking the string 12 on the door knob 14.
The door 13 may be opened and closed or moved in the lateral direction.
The electric lamp 1 according to the first embodiment may be hung on a hook or the like installed on the door 13 in addition to the door knob 14.

When the door 13 is opened, as shown in FIG. 9A, the vibration sensor 5 senses vibration. Therefore, the vibration sensor first terminal 5a and the vibration sensor second terminal 5b can be energized.
When the vibration sensor first terminal 5a and the vibration sensor second terminal 5b can be energized, a current flows from the power source positive electrode 9a to the electrolytic capacitor positive electrode terminal 6a and the resistor first terminal 7a, and the resistor second terminal 7b to the base terminal 8a. Current flows through
When current flows from the power supply positive electrode 9 a to the electrolytic capacitor positive electrode terminal 6 a, electric charge is accumulated in the electrolytic capacitor 6.
When the vibration sensor 5 no longer senses vibration, the current cannot be passed between the vibration sensor first terminal 5a and the vibration sensor second terminal 5b, so that the power supply positive electrode 9a changes to the electrolytic capacitor positive electrode terminal 6a and the resistance first terminal 7a. No current flows, and no current flows from the resistance second terminal 7b to the base terminal 8a.

When no current flows from the power supply positive electrode 9a to the electrolytic capacitor positive electrode terminal 6a, the electrolytic capacitor 6 is discharged.
When the electrolytic capacitor 6 is discharged, a current flows from the electrolytic capacitor positive terminal 6a to the resistance first terminal 7a, and a current flows from the resistance second terminal 7b to the base terminal 8a.
When a current flows through the base terminal 8a, the collector terminal 8b and the emitter terminal 8c can be energized.
When the collector terminal 8b and the emitter terminal 8c can be energized, a current flows from the power supply positive electrode 9a to the anode terminal 4a, so that the light emitting diode 4 is lit.
When there is no charge accumulated in the electrolytic capacitor 6, no current flows from the electrolytic capacitor positive terminal 6a to the first resistor terminal 7a, and no current flows from the second resistor terminal 7b to the base terminal 8a. And the emitter terminal 8c cannot be energized.
When the current cannot flow between the collector terminal 8b and the emitter terminal 8c, no current flows from the power supply positive electrode 9a to the anode terminal 4a, and the light emitting diode 4 is turned off.

  The lamp 1 according to the first embodiment operates in such a manner when it receives vibration from the power source 9 and is subjected to vibration. Therefore, after the light emitting diode 4 is automatically turned on and turned on for a predetermined time, Can be turned off.

  If the light emitting diode 4 does not light even when the door 13 is opened, the light 1 of the first embodiment senses the vibration and the light emitting diode 4 lights up if the door 13 is shaken, beat or strongly closed. .

  As shown in FIGS. 9B and 9C, when the storage case 10 is affixed to the door 13 with the tape 15, the electric lamp 1 according to the first embodiment can more easily sense vibration.

  The electric lamp 1 according to the first embodiment is installed at the entrance or the door 13 of the room, and when it comes home at night, it looks dark and looks for the light switch of the entrance and the room. It can also be used to illuminate the interior of the room with the light emitting diode 4.

The light emitting diode 4 includes a general light emitting diode and a high intensity light emitting diode.
When the general light emitting diode is turned on, light having a luminous intensity of 20 mcd or more and less than 1500 mcd is generated.
When the high intensity light emitting diode is turned on, light having a luminous intensity of 1500 mcd or more is generated.
When a high light emitting diode is used for the light emitting diode 4 of the lamp 1 of the first embodiment, the light emission of the lamp 1 of the first embodiment is greater than when a general light emitting diode is used for the light emitting diode 4 of the lamp 1 of the first embodiment. Bright light can be generated from the diode 4.

  As shown in FIGS. 10A, 10B, 10C, and 10D, the door 13 according to the second embodiment includes a storage space 16, and the electric lamp 1 according to the first embodiment is built in the storage space 16. doing.

  As shown in FIGS. 10 (a), (b), (c), and (d), the door 13 must be partially transparent or semi-transparent so that the light emitting diode 4 can illuminate the outside. I must.

  As shown in FIGS. 10A, 10B, 10C, and 10D, the door 13 of the second embodiment is provided with an installation space 16, and the electric lamp 1 of the first embodiment is built in the storage space 16. 8 (a) (b) (c) and FIGS. 9 (a) (b) (c), the lamp 1 of the first embodiment is installed in the storage case 10 and the door knob 14 is attached. Even if it is not suspended, if the door 13 of the second embodiment is opened and closed, the lamp 1 of the first embodiment is vibrated, so that the entrance and the room can be illuminated with the light generated from the light emitting diode 4.

1 is a circuit diagram of an electric lamp 1 of Example 1. FIG. It is a circuit diagram in the state where the power supply 9 was connected to the electric lamp 1 of Example 1. FIG. (a) It is the figure which looked at the 1st metal ball built-in vibration sensor 5c from the box 1st side surface 5eaa side. (b) It is the figure which looked at the vibration sensor 5c with a built-in 1st metal ball from the box body 2nd side surface 5eab side. (c) It is sectional drawing which looked at the vibration sensor 5c with 1st metal ball | bowl from the box body 2nd side surface 5eab side. (d) It is sectional drawing of the 1st metal ball built-in vibration sensor 5c which shows the state which the metal ball 5eb contacted the metal ball built-in vibration sensor 1st metal wire 5ee. (e) It is sectional drawing of the 1st metal ball built-in vibration sensor 5c which shows the state which the metal ball 5eb stopped contacting with the metal ball built-in vibration sensor 1st metal wire 5ee. (a) It is the figure which looked at the vibration sensor 5d with a 2nd metal ball | bowl from the box 1st side surface 5eaa side. (b) It is the figure which looked at the vibration sensor 5d with 2nd metal ball | bowl from the box body 2nd side surface 5eab side. (c) It is sectional drawing which looked at the vibration sensor 5d with 2nd metal ball | bowl from the box 2nd side surface 5eab side. (d) It is sectional drawing of the 2nd metal ball built-in vibration sensor 5d which shows the state which the metal ball 5eb contacted the metal ball built-in vibration sensor 1st metal wire 5ee. (e) It is sectional drawing of the 2nd metal ball built-in vibration sensor 5d which shows the state which the metal ball 5eb stopped contacting with the metal ball built-in vibration sensor 1st metal wire 5ee. (a) It is the figure which showed the state which installs the 1st metal ball built-in vibration sensor 5c in the electric lamp 1 of Example 1. FIG. (b) It is the figure which showed the state which installs the vibration sensor 5d with 2nd metal ball | bowl in the electric lamp 1 of Example 1. FIG. (a) First state in which the first metal ball built-in vibration sensor 5c and the second metal ball built-in vibration sensor 5d are installed in the lamp 1 of the first embodiment with the major axis direction of the box 5ea being substantially perpendicular to each other. It is the figure seen from the box body 4th side 5ad side of box 5ea of metal ball built-in vibration sensor 5c. (b) A state where the first metal ball built-in vibration sensor 5c and the second metal ball built-in vibration sensor 5d are installed in the lamp 1 of the first embodiment so that the major axis direction of the box 5ea is substantially perpendicular to each other. It is the figure seen from the box body 3rd side surface 5eac side of the box 5ea of the metal ball built-in vibration sensor 5d. (c) The second state in which the first metal ball built-in vibration sensor 5c and the second metal ball built-in vibration sensor 5d are installed in the lamp 1 of the first embodiment so that the major axis direction of the box 5ea is substantially perpendicular to each other. It is the figure seen from the box side 2nd side 5eab side of box 5ea of metal ball built-in vibration sensor 5d. It is a circuit diagram of the state where the 1st metal ball built-in vibration sensor 5c and the 2nd metal ball built-in vibration sensor 5d were connected in parallel. (a) It is the figure which looked at the storage case 10 from the front. (b) The storage case 10 is suspended from the door knob 14 of the door 13. (c) It is an enlarged view of the vicinity of the door knob 14 and the door knob 14 of (b). (a) It is a figure which shows the state which the door 13 opened. (b) It is a figure which shows the state which affixed the storage case 10 on the door 13 with the tape 15. FIG. (c) It is an enlarged view of the vicinity of the door knob 14 and the door knob 14 of (b). (a) It is the figure which looked at the door 13 of Example 2 from the front. (b) It is the enlarged view of the vicinity of the storage space 16 and the storage space 16 of (a). (c) It is the figure which looked at the door 13 of Example 2 of the state which the door 13 opened from the diagonal direction. (d) It is an enlarged view of the vicinity of the storage space 16 and the storage space 16 of (c).

DESCRIPTION OF SYMBOLS 1 Lamp 2 Positive electrode connection terminal 3 Negative electrode connection terminal 4 Light emitting diode 4a Anode terminal 4b Cathode terminal 5 Vibration sensor 5a Vibration sensor 1st terminal 5b Vibration sensor 2nd terminal 5c 1st metal ball built-in vibration sensor 5d 2nd metal ball built-in vibration sensor 5ea Box 5eaa Box first side 5eaab Box second side 5eac Box third side 5ead Box fourth side 5eae Box upper surface 5eaf Box lower surface 5eag Box opening 5eb Metal ball 5ec Metal ball built-in vibration sensor No. One terminal 5ed Metal ball built-in vibration sensor second terminal 5ee Metal ball built-in vibration sensor first metal wire 5ef Metal ball built-in vibration sensor second metal wire 6 Electrolytic capacitor 6a Electrolytic capacitor positive terminal 6b Electrolytic capacitor negative terminal 7 Resistance 7a Resistance first Terminal 7b Resistor second terminal 8 Bipolar NPN transistor 8a Base terminal 8b Collect Terminal 8c emitter terminal 9 Power 9a supply positive 9b power anode 10 accommodating case 11 accommodating case opening portion 12 string 13 door 14 door knob 15 tape 16 installation space θ angle

Claims (2)

When it receives vibration, the light-emitting diode automatically lights up, lights up for a certain period of time, and then automatically turns off.
A positive electrode connection terminal, a negative electrode connection terminal, the light emitting diode, a vibration sensor, an electrolytic capacitor, a resistor, and a bipolar NPN transistor,
The light emitting diode has an anode terminal and a cathode terminal,
The vibration sensor has a vibration sensor first terminal and a vibration sensor second terminal,
The electrolytic capacitor has an electrolytic capacitor positive terminal and an electrolytic capacitor negative terminal,
The resistor has a first resistor terminal and a second resistor terminal,
The bipolar NPN transistor has a base terminal, a collector terminal, and an emitter terminal,
The positive electrode connection terminal is connected to the vibration sensor first terminal and the anode terminal,
The vibration sensor second terminal is connected to the electrolytic capacitor positive terminal and the resistance first terminal,
The electrolytic capacitor negative electrode terminal is connected to the negative electrode connection terminal,
The resistor second terminal is connected to the base terminal,
The collector terminal is connected to the cathode terminal;
The lamp characterized in that the emitter terminal is connected to the negative electrode connection terminal. A door with a storage space,
The door characterized by incorporating the electric lamp according to claim 1 in the storage space.

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