JP2002040156A - Sensor unit and safety lamp using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make a sensor unit operate normally for a long time to efficiently focus and apply heat rays emitted from a human body onto a sensor, thereby detecting human bodies with high sensitivity. SOLUTION: The sensor unit comprises a sensor 2 for detecting heat rays, a base 4 for holding the sensor 2, and a printing board 3 for coupling the base 4 and electrically connecting output terminals 8 of the sensor 2. The base 4 has support legs 9 for holding a space between the sensor 2 and the printed board 3 in the sensor unit.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sensor having a sensor for detecting heat rays, and a security light device for turning on a light when a human body approaches at night.

[0002]

2. Description of the Related Art A security light device for detecting the approach of a human body and turning on a light at night is already on the market. This type of security light device is provided, for example, on a staircase or a corridor in a building. It is also provided outdoors. The security light device includes a sensor that detects the approach of a human body by a heat ray such as infrared rays. The sensor outputs a control signal when a human body approaches. The output control signal controls the lighting circuit to light the light source. The sensor is fixed to a printed circuit board and stored in a case.

[0003]

It is extremely difficult to reliably operate the security light device having this structure for a long period of time. This is because a weak signal output from the sensor cannot be normally detected due to leakage of the output terminal of the sensor. Since the output signal from the sensor that detected the approach of the human body is an extremely weak signal, and the output impedance of the sensor is extremely high,
Extremely slight leakage at the output terminals makes it impossible to detect the output signal of the sensor. Therefore, dust adheres to or condenses on the output terminal of the sensor, or when the dust absorbs moisture, it leaks electricity and malfunctions.

[0004] Further, the security light device is provided with a cover lens in order to efficiently focus heat rays radiated from the human body and make the heat rays incident on the sensor. The cover lens focuses the heat rays by the lens and makes it incident on the sensor. The cover lens needs to be fixed with extremely high precision in order for the focused heat ray to be accurately incident on the sensor.

[0005] In the conventional security light device, it is difficult to fix the cover lens and the sensor to the printed board with high accuracy and high accuracy. This is because the sensor is fixed to the printed board via the output terminal, and the cover lens is fitted and fixed in the mounting hole provided in the printed board. It is difficult to fix the sensor with extremely high accuracy in the structure in which the sensor is fixed via the output terminal. If the fixed position of the sensor shifts, the relative position between the sensor and the cover lens shifts, and the heat ray focused by the cover lens cannot be efficiently incident on the sensor. This weakens the heat rays incident on the sensor, causing a reduction in detection sensitivity.

[0006] The present invention has been developed with a view to solving such a drawback. An important object of the present invention is to provide a sensor body that can operate normally for a long period of time, efficiently focus heat rays radiated from the human body, enter the sensor, and detect the human body with high sensitivity, and a security using the same. A lighting device is provided.

[0007]

The sensor body of the present invention comprises:
It includes a sensor 2 for detecting heat rays, a pedestal 4 for holding the sensor 2, and a printed circuit board 3 for connecting the pedestal 4 and electrically connecting an output terminal 8 of the sensor 2. Further, in the sensor body, the pedestal 4 has the support leg portions 9 so that a space is provided between the sensor 2 and the printed board 3.

Further, in the sensor body of the present invention, preferably, the pedestal 4 has a portion for mounting a cover lens 5 for focusing a heat ray incident on the sensor 2 at a fixed position.

The security light device according to the present invention is provided with a sensor body having a sensor 2 for detecting a heat ray, a cover lens 5 for focusing a heat ray incident on the sensor 2, and switching with a control signal output from the sensor 2. A lighting circuit 7;
The light source 6 is turned on and off by the lighting circuit 7, and the sensor body, the light source 6, and the case 1 containing the lighting circuit 7 are provided.
The sensor body includes a sensor 2 for detecting a heat ray radiated from a human body, a pedestal 4 for holding the sensor 2, and a pedestal 4
And a printed circuit board 3 for electrically connecting the output terminal 8 of the sensor 2. The pedestal 4 has support legs 9 for providing a space between the sensor 2 and the printed circuit board 3.

Further, the security light device according to the present invention includes
However, a structure having a sensor fitting portion 11 for connecting the sensor 2 at a fixed position and a cover fitting portion 12 for fitting the cover lens 5 at a fixed position may be adopted. In this security light device, the sensor 2 and the cover lens 5 are mounted on the printed circuit board 3 via the pedestal 4.

Further, in the security light device of the present invention, the sensor fitting portion 11 can be the peripheral wall 13 whose inner shape is substantially equal to the outer shape of the sensor 2. Further, in the security light device, the cover fitting portion 12 can be an annular groove 15 into which the opening edge of the cover lens 5 can be inserted. Furthermore, the security light device is provided between the base 4 and the cover lens 5.
An opening 18 for ventilation can be provided.

[0012]

Embodiments of the present invention will be described below with reference to the drawings. However, the embodiments described below illustrate a sensor body for embodying the technical idea of the present invention and a security light device using the same, and the present invention describes the sensor body and the security light device as follows. Not specific.

Further, in this specification, in order to make it easier to understand the claims, the numbers corresponding to the members shown in the embodiments will be referred to as “claims” and “ In the column of “means”.
However, the members described in the claims are not limited to the members of the embodiments.

FIG. 1 is a perspective view, FIG.
The security light device shown in the cross-sectional view of FIG.
A sensor body including a sensor 2 for detecting a heat ray, a cover lens 5 for focusing a heat ray incident on the sensor 2,
A lighting circuit 7 that is turned on and off by a control signal output from the sensor 2, a light source 6 such as a white LED that is blinked by the lighting circuit 7, a case 1 including a sensor body, a light source 6, and the like; A light-transmitting cover that is connected to the case and transmits light from the light source; The sensor body includes a sensor 2 for detecting heat rays such as infrared rays radiated from a human body, a printed circuit board 3 on which the sensor 2 is fixed, and a sensor disposed between the printed circuit board 3 and the sensor 2. And a pedestal 4 for holding.

The sensor 2 is a pyroelectric heat ray sensor, and a detection element 2A for detecting infrared rays as heat rays radiated from a human body is housed in a metal case 2B. Metal case 2B
Open the upper part, and make the three output terminals 8 protrude insulated from the lower end. The sensor 2 causes infrared rays, which are heat rays radiated from a human body, to enter the detection element 2A from an opening above the metal case 2B.

The printed circuit board 3 is fixed at a fixed position in the case 1. 2 and 3, the printed circuit board 3 has the sensor 2 fixed to the front surface. Sensor 2 is
The output terminal 8 is fixed to the printed circuit board 3 by soldering. Further, the printed circuit board 3 is also fixed with an electronic component for realizing a lighting circuit and a light source 6 by soldering.

The pedestal 4 is manufactured by molding plastic. The plastic pedestal 4 is characterized in that the output terminal 8 of the sensor 2 can be connected to the printed circuit board 3 while insulating the output terminal 8 in an ideal state. However, the pedestal can be manufactured by pressing or casting metal. The metal pedestal widens the space between the sensor and the printed circuit board,
The distance between the pedestal and the output terminal is also widened so that the output terminal of the sensor has a sufficient insulation structure.

The pedestal 4 is connected by a fitting structure so as to be connected to a fixed position of the printed circuit board 3. The fitting structure between the pedestal 4 and the printed circuit board 3 includes, for example, a connecting hole of the printed circuit board and a convex portion of the pedestal, or a connecting portion of the convex portion of the printed circuit board and the pedestal. Is connected to a fixed position on the printed circuit board.

FIG. 5 is a top perspective view, FIG. 6 is a bottom perspective view, and FIG. 7 is a plan view of the pedestal 4. 5 is disclosed as a cross section of the pedestal in FIG.
A cross section taken along line D is disclosed as a cross section of the pedestal in FIG. The pedestal 4 in these figures is provided with a plurality of support legs 9 protruding from the lower surface, and the insertion portion 9A of the support leg 9 is inserted into the connection hole 3a provided in the printed circuit board 3 to print the pedestal 4. It is connected to a fixed position of the substrate 3. Therefore,
The pedestal 4 has a fitting structure formed of support legs 9, and the support legs 9 are inserted into the connection holes 3 a of the printed circuit board 3 to connect the pedestal 4 to a fixed position. The support leg 9 is provided with a connecting hole 3a.
The insertion portion 9A to be inserted into the
A is made thin, and the rear end face of the insertion portion 9A is brought into contact with the surface of the printed circuit board 3 to make the insertion depth of the support leg 9 constant.

The pedestal 4 is connected to the printed circuit board 3 by supporting legs 9. Therefore, the bottom surface of the pedestal 4 has a non-contact portion 10 that is separated from the surface of the printed circuit board 3 and does not contact. The output terminal 8 of the sensor 2 penetrates the non-contact portion 10 and is connected to the printed circuit board 3. The gap between the non-contact portion 10 of the pedestal 4 and the surface of the printed circuit board 3 is
Preferably, it is about 5 mm. However, this gap is
It can be 10 mm. If this gap is widened, the insulation state of the output terminal 8 can be improved, but the noise induced at the output terminal 8 increases, and it becomes difficult to firmly fix the sensor 2 to the printed circuit board 3. Therefore,
The gap between the non-contact portion 10 and the printed circuit board 3 is
The above-mentioned range is taken into consideration in consideration of the insulation and the mounting strength. Since the pyroelectric heat ray sensor 2 is provided with the metal case 2B, it easily forms dew on this metal part, and when dew forms due to high humidity or the like, a conduction state occurs between the output terminals 8 to cause a short circuit. Operation becomes difficult. However, in this embodiment, since the pedestal 4 includes the support leg 9, a space is formed between the metal case 2B of the sensor 2 and the printed circuit board 3, air is ventilated, and dew condensation can be prevented. .

The pedestal 4 has on its upper surface a sensor fitting portion 11 for connecting the sensor 2 at a fixed position and a cover fitting portion 12 for fitting the cover lens 5 at a fixed position. The pedestal 4 shown in FIGS. 2, 3 and 7 is provided with a sensor fitting portion 11 with a peripheral wall 13 whose inner shape is substantially equal to the outer shape of the sensor 2. The sensor 2 in the figure has a columnar outer shape. Therefore, the circular ring-shaped peripheral wall 13
Is provided so that the sensor 2 is fitted inside the peripheral wall 13 so that the sensor 2 can be mounted at a fixed position. Furthermore, the peripheral wall 13
Is provided with a notch 14, and the sensor 2 has a projection 2 a on a part of its outer periphery. Therefore, the sensor 2 is inserted by inserting the projection 2 a of the sensor 2 into the notch 14 of the peripheral wall 13. Can be fixed in place. Sensor fitting part 1
1 can be of any shape that allows the sensor 2 to be arranged in a fixed position on the pedestal 4. Therefore, the sensor fitting portion has a structure in which a concave portion in which the sensor can be fitted is provided on the upper surface of the pedestal, and further, a convex portion that supports the outer periphery of the sensor at three or more points is provided, and the sensor is disposed inside the plurality of convex portions. It can also be a structure that does.

The cover lens 5 is manufactured by molding a transparent plastic, for example, an acrylic resin, through which heat rays radiated from the human body are transmitted. The cover lens 5 shown in the perspective view of FIG. 8 is formed into a spherical shape and the opening edge is formed into a cylindrical shape. The part shaped into a spherical shape is shaped into a Fresnel lens capable of converging heat rays and entering the sensor 2.

The pedestal 4 shown in FIGS. 5 and 7 has an annular groove 15 into which the opening edge of the cover lens 5 can be inserted, as the cover fitting portion 12. The annular groove 15 of the cover fitting portion 12 has a circular ring shape, is provided outside the sensor fitting portion 11, and is arranged concentrically with the peripheral wall 13 of the sensor fitting portion 11. This is for disposing the sensor 2 at the center of the cover lens 5 attached to the cover fitting portion 12. The cover lens 5 is connected to the pedestal 4 so that the cylindrical opening edge is inserted into the annular groove 15 which is the cover fitting portion 12 without any gap, and is not displaced. The opening edge of the cover lens 5 has a structure in which the thickness is equal to the width of the annular groove 15 and can be inserted without any gap. As shown in FIG. 8, the cover lens 5 has a projection 5a for specifying a direction protruding from an opening edge. The pedestal 4 has a fitting recess 16 for guiding the protrusion 5 a in the annular groove 15. The fitting recess 16 has an opening shape, and is painted black in FIG. 7 for easy understanding.

In the illustrated pedestal 4, the cover fitting portion 12 is an annular groove 15, but this structure can connect the cover lens 5 to the precise position of the pedestal 4 with extremely high accuracy. further,
The cover lens 5 connected to the pedestal 4 is fitted in the annular groove 15 and can reliably prevent deformation. The non-deformed cover lens 5 has a feature that the heat rays radiated from the human body can be effectively focused and incident on the sensor 2. Further, the cover lens 5, which is prevented from being deformed by the pedestal 4, has a feature that it can be formed at a low cost by forming it thin, increasing the transmittance of heat rays.

However, the pedestal is not limited to the cover fitting portion being an annular groove, but has any shape capable of connecting the cover lens to a specific position, for example, a plurality of protrusions are provided at the opening edge of the cover lens. It is also possible to adopt a structure in which the cover lens is connected to a fixed position of the pedestal by opening a hole or a concave portion for inserting the lens into the upper surface of the pedestal and making a protrusion in the hole or the concave portion.

With the insertion portion 9A of the support leg 9 of the pedestal 4 inserted into the connection hole 3a of the printed circuit board 3, the output terminal 8 of the sensor 2 is soldered to the wiring pattern on the back surface of the printed circuit board 3. And the sensor 2 is fixed to the printed circuit board 3 with the pedestal 4 interposed therebetween. This mounting structure
There is no need to provide a fixing mechanism on the pedestal 4, and the pedestal 4 only needs to be provided with the printed circuit board 3 and a coupling mechanism using the above-described insertion portion 9A disposed at a fixed position. Therefore, the pedestal 4 can be easily connected and fixed to the printed circuit board 3. With such a mechanism, the sensor 2 set on the pedestal 4 is fixed to the printed circuit board 3, and both the pedestal 4 and the sensor 2 are fixed.

The pedestal 4 is provided with a cover fitting portion 12 for connecting the cover lens 5 to a fixed position, but the cover lens 5 is prevented from coming off the pedestal 4 by the front case 1A. . Therefore, the cover lens 5 does not need to be provided with a mechanism for preventing the cover lens 5 from coming off with the pedestal 4, and can have a simple connection structure. In order to prevent the cover lens 5 from coming off, the front case 1A has an inner shape of the opening window 17 for exposing the cover lens 5 to the outside, and makes the inner surface of the opening window 17 cover lens. 5 is in contact with the upper surface. The cover lens 5 may be bonded to the base 4 so as not to come off.

Further, the pedestal 4 shown in FIG. 2 has an opening 18 for ventilation between the pedestal 4 and the cover lens 5. As shown in FIGS. 5 to 7, the pedestal 4 is provided with a cutout portion 4A by partially cutting out a circular main body portion and a ring-shaped cover fitting portion 12, and the cover lens 5 is provided on the upper surface. An opening 18 that connects the cutout 4A and the inside of the cover lens 5 is provided in the mounted state. Thus, the opening 18 provided between the pedestal 4 and the cover lens 5 can ventilate the air in the cover lens 5 and effectively prevent dew condensation.

The pedestal 4 having this structure is assembled as follows to fix the sensor 2 and the cover lens 5 at fixed positions. (1) With the sensor 2 set on the pedestal 4, the output terminal 8 of the sensor 2 is set on the printed board 3, and the pedestal 4 is fixed at a fixed position on the printed board 3. (2) The cover lens 5 is attached to the annular groove 15 which is the cover fitting portion 12 of the pedestal 4, and the cover lens 5 is connected to a fixed position of the pedestal 4. (3) By connecting the front case 1A to the rear case 1B, the inner surface of the opening window 17 of the front case 1A supports the cover lens 5 so as not to come off.

Next, a circuit block diagram of the present embodiment shown in FIG. 4 will be described. As shown in FIG. 4, the lighting circuit 7 includes an amplifier 19 for amplifying the output of the sensor 2, a comparator 20 for comparing the output of the amplifier 19 with a reference voltage, and a light source 6 controlled by an output from the comparator 20 to keep the light source 6 constant. A timer circuit 21 that keeps the lighting state for a time; a switching element 22 that is turned on and off by the timer circuit 21 to blink the light source 6; and an illuminance circuit 23 that detects external brightness and outputs a signal to the timer circuit 21. And The illuminance detector of the illuminance circuit 23 is provided on the left side of the case 1 in FIG. Furthermore, the lighting circuit 7 of this figure
In order to turn on the light source 6 when a power failure occurs, a power failure detection circuit 24 for detecting a power failure is also provided.

In the lighting circuit 7, when the sensor 2 detects a human body, the sensor 2 detects a heat ray and outputs a control signal. This control signal is amplified by the amplifier 19 and input to the comparator 20. The amplifier 19 amplifies the control signal of the sensor 2 from several thousand times to about 10,000 times and inputs the amplified signal to the comparator 20. The comparator 20 compares a signal input from the amplifier 19 with a reference voltage, and outputs an ON signal when a signal of a predetermined level is input. When an ON signal is input, the timer circuit 21
An on signal is output to turn on. However, the timer circuit 21 does not output the ON signal when the “bright” signal indicating that the surroundings are bright is input from the illuminance circuit 23,
An ON signal is output only when a “dark” signal indicating that the surroundings are dark is input. After that, the timer circuit 21
Outputs an ON signal for a certain period of time after the ON signal is no longer input, for example, several seconds to several tens of seconds. When an ON signal is output from the timer circuit 21, the switching element 22 is turned on and the light source 6 is turned on.

Further, when a power failure occurs, a power failure detection circuit 24
Detects a power failure and turns on the switching element 22 to turn on the light source 6. The power failure detection circuit 24 turns on the light source 6 continuously during a power failure.

The illustrated security light device has a built-in secondary battery 25 which is charged by a commercial power supply, and uses this secondary battery 25 as a power supply. The commercial power is stepped down by the transformer 26 and rectified by the rectifier circuit 27 to charge the secondary battery 25. The output of the secondary battery 25 is boosted by the DC / DC converter 28. The security light device incorporating the DC / DC converter 28 can reduce the output voltage of the secondary battery 25 by reducing the number of the incorporated secondary batteries 25. This is because the DC / DC converter 28 boosts the voltage.

A changeover switch 29 is connected to the power supply. The changeover switch 29 is a switch at three positions: an automatic position, a continuous / blackout position, and an off position. The automatic position is
When the sensor 2 detects a human body, the light source 6 is turned on.
This is a switching position where the light source 6 is not turned on during a power failure. Continuous /
The power failure light position is a switching position where the light source 6 is turned on when a power failure occurs, when the power supply is disconnected from an outlet and used as a flashlight, or when a human body is detected. The off position is a position where the light source 6 is not turned on. When the security light device of this embodiment is used as a flashlight after being unplugged from the outlet, the power plug 36 can be folded and used as shown by the arrow in FIG.

As the light source 6, a light emitting diode or a light bulb can be used, but the light emitting diode is optimal because it has no filament and has a very long life and high reliability. The most suitable light emitting diode is a light emitting diode whose emission color is white with a phosphor. The white light-emitting diode cannot be lit with sufficient brightness due to low voltage of two nickel-hydrogen batteries or nickel-cadmium batteries. The illustrated security light device incorporates two nickel-hydrogen batteries or nickel-cadmium batteries, and the voltage of these batteries is boosted by the DC / DC converter 28 to light the light emitting diodes.

Further, the security light device shown in FIG. 1 and FIG.
A light-transmitting cover 30 that transmits light from the light source 6 is connected to the upper part of the case 1. The translucent cover 30 is manufactured by molding a transparent plastic, for example, acrylonitrile styrene, acrylic, or the like. The light-transmitting cover 30 transmits the light emitted from the light source 6 and diffuses the light to the outside for irradiation.

[0037]

The sensor body of the present invention and the security light device using the same have the advantage that they can be operated normally for a long period of time. That is, the sensor body of the present invention includes a sensor for detecting a heat ray, a pedestal for holding the sensor, and a printed circuit board for connecting the pedestal and electrically connecting an output terminal of the sensor. This is because the support legs are provided on the pedestal so that the space is provided. In the sensor body of this structure and the security light device using this, the space is formed between the printed circuit board and the sensor by the support leg of the pedestal, so that air is less likely to be condensed due to air ventilation, There is no conduction between the output terminals due to condensation. Therefore, it is possible to effectively prevent operation failure due to electric leakage or the like, and to reliably operate for a long period of time. Further, in the sensor body of the present invention and the security light device using the same, the sensor is fixed to the printed circuit board via the pedestal without fixing the sensor directly to the printed circuit board as in the related art. Therefore, there is a feature that the sensor can be accurately arranged at a predetermined position away from the printed circuit board by the sensor at a fixed position, particularly, by the support leg of the pedestal.

Further, the sensor body according to the second aspect of the present invention and the security light device according to the fourth aspect are characterized in that the heat rays radiated from the human body can be efficiently focused and incident on the sensor to detect the human body with high sensitivity. is there. This is because the sensor body and the security light device are provided with a portion for mounting a cover lens for focusing heat rays incident on the sensor at a fixed position on the pedestal holding the sensor. In the sensor body and the security light device having this structure, the cover lens can be disposed at an accurate position, so that the heat ray focused by the cover lens can be efficiently incident on the sensor to reliably detect the heat ray.

In particular, the security light device according to claim 4 of the present invention has a sensor mounting portion for connecting the sensor to a fixed position on a pedestal holding the sensor, and a cover for mounting the cover lens at a fixed position. Since the fitting portion is provided and the sensor and the cover lens are mounted on the printed circuit board via the pedestal, these can be fixed to the printed circuit board with high precision and high accuracy. Therefore, it is possible to reliably prevent the relative position between the sensor and the cover lens from being shifted, and to efficiently input the heat rays focused by the cover lens to the sensor, thereby reliably detecting the human body without lowering the detection sensitivity. .

[Brief description of the drawings]

FIG. 1 is a perspective view of a security light device according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view taken along line AA of the security light device shown in FIG.

FIG. 3 is a sectional view taken along line BB of the security light device shown in FIG. 1;

FIG. 4 is a block diagram showing a circuit configuration of the security light device shown in FIG. 1;

FIG. 5 is a perspective view of a pedestal according to the embodiment of the present invention.

FIG. 6 is a bottom perspective view of the base shown in FIG. 5;

FIG. 7 is an enlarged plan view showing a state where a sensor is mounted on the pedestal shown in FIG. 5;

FIG. 8 is a bottom perspective view of a cover lens.

[Explanation of symbols]

1: Case 1A: Surface case 1
B: rear case 2: sensor 2A: detecting element 2
B: Metal case 2a ... Projection 3 ... Printed circuit board 3a ... Connection hole 4 ... Pedestal 4A ... Cutout part 5 ... Cover lens 5a ... Projection 6 ... Light source 7 ... Lighting circuit 8 ... Output terminal 9 ... Support leg 9A ... Insertion part 10 ... non-contact portion 11 ... sensor fitting portion 12 ... cover fitting portion 13 ... peripheral wall 14 ... cutout portion 15 ... annular groove 16 ... fitting concave portion 17 ... opening window 18 ... opening portion 19 ... amplifier 20 ... comparator 21 ... timer circuit DESCRIPTION OF SYMBOLS 22 ... Switching element 23 ... Illuminance circuit 24 ... Power failure detection circuit 25 ... Secondary battery 26 ... Transformer 27 ... Rectifier circuit 28 ... DC / DC converter 29 ... Changeover switch 30 ... Translucent cover 36 ... Power plug

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI theme coat ゛ (reference) // G01J 5/02 G01V 9/04 A F term (reference) 2G065 AA04 AB02 BA13 BB06 BB48 CA27 CA29 CA30 DA20 2G066 AC13 BA01 BA22 BB13 BB15 BB20 CA08 3K073 AA12 AA16 AA87 AA98 BA25 BA28 CF13 CF18 CG02 CG15 CG25 CJ11 CJ17 CJ19 CJ22 CL03

Claims (7)

[Claims] 1. A sensor (2) for detecting a heat ray, a pedestal (4) for holding the sensor (2), and the pedestal (4) are connected and an output terminal (8) of the sensor (2) is electrically connected. A printed circuit board (3), and a pedestal (4) having supporting legs (9) so as to provide a space between the sensor (2) and the printed circuit board (3). . 2. The sensor body according to claim 1, wherein the pedestal (4) has a portion for mounting a cover lens (5) for focusing a heat ray incident on the sensor (2) in a fixed position. 3. A sensor body having a sensor (2) for detecting a heat ray, a cover lens (5) for focusing a heat ray incident on the sensor (2), and switching by a control signal output from the sensor (2). Lighting circuit (7) and this lighting circuit
A light source (6) blinking in (7), a sensor body, a light source (6), and a case (1) containing a lighting circuit (7) are provided, and the sensor body emits heat rays radiated from a human body. A sensor (2) to be detected, a pedestal (4) holding the sensor (2), and a printed circuit board (3) for connecting the pedestal (4) and electrically connecting an output terminal (8) of the sensor (2). And a pedestal (4) having a support leg (9) for providing a space between the sensor (2) and the printed circuit board (3). 4. A sensor body having a sensor (2) for detecting a heat ray, a cover lens (5) for focusing a heat ray incident on the sensor (2), and switching by a control signal output from the sensor (2). Lighting circuit (7) and this lighting circuit
A light source (6) blinking in (7), a sensor body, a light source (6), and a case (1) containing a lighting circuit (7) are provided, and the sensor body emits heat rays radiated from a human body. A sensor (2) to be detected, a pedestal (4) holding the sensor (2), and a printed circuit board (3) for connecting the pedestal (4) and electrically connecting an output terminal (8) of the sensor (2). The pedestal (4) has a sensor fitting part (11) for connecting the sensor (2) at a fixed position and a cover fitting part (12) for fitting the cover lens (5) at a fixed position. ) And a sensor (2)
And the cover lens (5) via the pedestal (4)
(3) A security light device characterized by being attached to (3). 5. The sensor fitting part (11) has an inner shape as a sensor.
The security light device according to claim 4, further comprising a peripheral wall (13) substantially equal to the outer shape of (2). 6. The cover fitting portion (12) includes a cover lens (5).
The security light device according to claim 4, further comprising an annular groove (15) into which an opening edge of the light emitting device can be inserted. 7. The security light device according to claim 4, wherein a ventilation opening (18) is provided between the pedestal (4) and the cover lens (5).