JP5893860B2 - sensor - Google Patents

Description

The present invention relates to a sensor for detecting fire by detecting smoke and heat generated by a fire.

  2. Description of the Related Art Conventionally, for example, a scattered light type smoke detector is known as a fire detector that detects a fire by detecting smoke due to a fire. Scattered light type smoke detectors have a smoke chamber through which smoke from the outside flows into the detector, and the smoke chamber is used as a smoke detection space to receive the scattered light of the smoke from the light emitting element by the light receiving element. To detect a fire. In addition, a labyrinth structure that suppresses the incidence of ambient light while allowing outside air (smoke) to be introduced into the smoke detection space in the chamber is also provided.

  There are two methods for installing the sensor on the ceiling, such as a method using a sensor base and a method for directly mounting the sensor without using the sensor base. The method of using the sensor base is to fix the sensor base at the position of the mounting hole opened in the ceiling, connect the sensor line routed around the back of the ceiling, and connect the sensor body to the fitting on the sensor base By inserting and turning the fitting terminal provided on the connector, it is mechanically and electrically connected.

  The direct mounting method is to pull out the lead wire from the back side of the sensor body, pull out the sensor line from the mounting hole opened in the ceiling without using the sensor base, and connect the lead wire of the sensor body here. For example, the connection is made using a crimp terminal, and the sensor main body is directly fixed to the ceiling surface using a screw or the like while the connected lead wire and sensing line are pushed into the back of the ceiling through the mounting hole.

  Here, for example, in the case of a sensor having a thin structure, it is conceivable to adopt the latter installation method in which the sensor base is not used so as not to impair the advantages and design properties even in the installed state. For example, the latter method can also be applied to a waterproof sensor in which a lead is pulled out from a circuit of a sensor main body and a circuit housing portion is sealed with an epoxy resin or the like.

  FIG. 18 shows an example of installation work when such a conventional sensor base is not used. First, as shown in FIG. 18A, a smoke detector 200 to be attached is prepared. In the smoke detector 200, two lead wires 202a and 202b are drawn from the back side.

  A through hole 206 is formed in the ceiling 204, and the sensor lines 208a, 208b, 210a, 210b routed to the back side of the ceiling through the through hole 206 are taken out. Here, the sensor lines 208a and 208a are signal lines from the upstream side (receiver side), and the sensor lines 210a and 210b are signal lines to the downstream side (termination side).

Subsequently, as shown in FIG. 18 (B), the lead wire 202a of the sensor 200 and the tips of the sensor lines 208a and 210a are peeled off so that the core wires are exposed, and the core wire is exposed, and a crimp terminal with an insulating tube is provided there. 212a is inserted and crushed by a crimping tool to be connected. Similarly, the ends of the lead wire 202b and the sensor lines 208b and 210b are peeled off and the core wires are exposed, and the core wires are exposed, and a crimp terminal 212b with an insulating tube is fitted therein and is crushed by a crimping tool and connected. . By sequentially making such a connection from the upstream side to the downstream side of the sensor line drawn from the receiver, a plurality of sensors can be connected to the sensor line. By connecting a terminating resistor or terminator on the most downstream side, it is possible to monitor disconnection of the sensor line.

When the connection work between the lead wire and the sensing line is completed, as shown in FIG. 18C, the connected lead wires 202a and 202b and the sensor lines 208a, 208b, 210a and 210b are passed through the through hole 206. It is pushed into the back side of the ceiling, and is fixed by using screws 214 in a state where the sensor 200 is aligned under the through hole 206 (on the sensor side).

JP-A-6-109631 Japanese Patent Laid-Open No. 7-12724 Japanese Patent Laid-Open No. 2001-325684 Japanese Patent No. 4347296

  However, in such a conventional sensor directly attached to the ceiling surface, when the sensor is attached to the ceiling surface, as shown in FIG. While holding the instrument 200 with one hand, first, the complicated work of passing the three core wires of the lead wire 202a and the sensor lines 208a and 210a through the crimp terminal 212a and crushing them with a tool is necessary. There is a problem that it takes time and effort, and since the work is performed at a high place near the ceiling 204, there is a concern about a safety problem.

  In order to solve this problem, the inventor of the present application provides a through hole in the sensor body to allow the sensor line to be temporarily inserted, and when the sensor is attached to the installation surface of the monitoring area, The sensor line installed on the back is pulled out from the ceiling passage hole, and the lead wire drawn from the sensor and the sensor line drawn from the installation surface insertion hole are inserted into the through hole provided in the sensor body. After fixing the sensor at the installation position on the installation surface with screws, etc., strip the sensor lead wire and the sensor line covering that are inserted through the through hole and pulled out to the monitoring area side, and remove the core wire. For example, it can be inserted into a crimping terminal and crimped, and then returned to the back side of the installation surface through the through hole so that the connection work can be performed. Even safely Ukoto proposes the sensor to be able to.

  On the other hand, the sensor is installed on the ceiling surface near the center of the room overlooking the monitoring area, which can be said to be an ideal place as a display place, lighting place or wireless communication position, etc. The utility value can be further enhanced if other functions can be provided at the same time without being occupied only by the container.

The present invention provides a sensor that can be multi-functionalized by providing a function other than the sensor simply and easily using a structure provided with a through-hole that allows a sensor line to be temporarily inserted. For the purpose.

The present invention provides a sensor,
Wiring connection after work signal lines laid on an installation surface back when the wiring connection work a can be inserted in the monitoring region side has a through hole penetrating vertically capable reversed the signal line to the installation surface back, placed A disc-shaped sensor body that is fixedly attached to the surface ;
A lead wire that is pulled out from the sensor body and connected to a signal line installed on the back of the installation surface;
A sensor unit provided in the sensor body for detecting a physical phenomenon associated with a fire;
A signal processing unit that is built in the sensor body and executes predetermined sensor processing based on a detection signal output from the sensor unit;
A unit having a predetermined function detachably provided in the through hole of the sensor body;
It is provided with.

The lead wire is drawn to the outside from the installation surface side of the sensor body, and can be stored behind the installation surface without going through the through hole after wiring connection work with the signal line laid on the back of the installation surface.
Unit having a predetermined function, after the wiring work, Ru retractable der the through hole in a state where the signal line and the lead wire was reversed the installation surface back is housed in installation surface back.

  Here, a display unit for displaying desired information is provided in the through hole of the sensor body. The display unit provided in the through hole of the sensor body displays time, temperature, humidity, photograph, character, or color pattern.

  An illumination unit for illuminating all or part of the monitoring area is provided in the through hole of the sensor body. The illumination unit provided in the through hole of the sensor body is a downlight or an emergency light.

  A sensor unit for detecting a physical phenomenon in the monitoring area is provided in the through hole of the sensor body. The sensor unit provided in the through hole of the sensor body is a thermal sensor, a CO sensor, a gas leak sensor, a theft sensor, or a human sensor.

  An acoustic conversion unit that outputs sound to the monitoring area is provided in the through hole of the sensor body. The acoustic conversion unit provided in the through hole of the sensor body includes a speaker or a buzzer.

A communication unit is provided in the through hole of the sensor body. Communication unit provided in the through hole of the sensor body is a radio relay unit for relaying a radio signal. The communication unit provided in the through hole of the sensor body is an access point unit that converts and connects a wireless LAN line and a wired LAN line.

The sensor part
A light emitting opening and a light receiving opening provided on the outer surface of the sensor body;
A transparent cover mounted on the outer surface of the sensor body and covering at least the light emitting opening and the light receiving opening;
A light-emitting element built in the detector body that emits light through a light-emitting opening with respect to a smoke detection point set in an open smoke-detecting space located outside the transparent cover,
A light receiving element built in the detector body that receives scattered light from the light emitting element through the light emitting opening to the smoke detection point and outputs a light receiving signal corresponding to the amount of light received through the light receiving opening. When,
The signal processing unit determines whether or not a fire has occurred based on the light reception signal output from the light receiving element.

  A light emitting opening and a light receiving opening are provided on the outer surface of the sensor body located on the lower side in a ceiling mounted state, and a transparent cover is attached to the sensor body so as to cover the light emitting opening, the light receiving opening, and the through hole opening. A transparent cover is detachably provided on the sensor body.

  The sensor unit includes a temperature detection element on the outer surface of the sensor body, and the signal processing unit determines whether or not a fire has occurred based on the temperature detection signal output from the temperature detection element.

The smoke detection of the present invention may further include a fitting terminal that is mechanically and electrically detachably connected to a sensor base fixed to the ceiling surface.

  The sensor of the present invention uses a through-hole that allows a sensor line to be temporarily inserted in the sensor body in order to simplify and facilitate the mounting work of the sensor, and has a predetermined function in the through-hole. By detachably mounting the unit having, it is possible to easily and easily realize multi-functionality of the sensor.

The units to be installed in the sensor through-holes are display units, lighting units, sensor units, acoustic conversion units, communication units, etc. For example, it is possible to construct a use environment optimized for the functions added by sharing the sensor installation location on the central ceiling surface of the room with other units.

Explanatory drawing which showed the embodiment of the smoke detector by this invention in the cross section and the plane seen from the lower side The perspective view which showed the smoke detector in the embodiment of FIG. FIG. 1 is a block diagram showing a detector circuit built in the smoke detector of FIG. Explanatory drawing which showed the installation operation | work with respect to the ceiling hole of the smoke detector by this invention in order. Explanatory drawing which showed the mode of the attachment work with respect to the ceiling attachment hole of the smoke detector by this invention Explanatory drawing which showed the state which fixed the smoke detector by this invention to the ceiling mounting hole Explanatory drawing which showed other embodiment of the smoke detector by this invention which provided the display unit which displays time, temperature, and humidity in a through-hole. Explanatory drawing which showed the other example of the attachment structure of the display unit with respect to the through-hole of a smoke sensor Explanatory drawing which showed other embodiment of the smoke detector by this invention which provided the illumination unit in the through-hole. Explanatory drawing which showed other embodiment of the smoke detector by this invention which provided the CO sensor unit in the through hole Explanatory drawing which showed other embodiment of the smoke detector by this invention which provided the speaker unit in the through-hole. Explanatory drawing which showed other embodiment of the smoke detector by this invention which provided the wireless relay unit in the through hole Explanatory drawing which showed other embodiment of the smoke detector by this invention which provided the access point unit in the through hole Explanatory drawing which showed other embodiment of the smoke detector by this invention which has arrange | positioned the light emission opening and the light reception opening in the wall surface of a through-hole. Sectional drawing which showed other embodiment of the smoke detector by this invention which provided the fitting terminal attached to or detached from a sensor base. The explanatory view which showed the embodiment of the heat sensor by the present invention in the section seen from the section and the lower side The block diagram which showed the sensor circuit incorporated in the heat sensor of FIG. Explanatory drawing which showed installation work to ceiling installation hole of conventional smoke detector in order

  FIG. 1 is an explanatory view showing the structure of a smoke detector according to the present invention, in which FIG. 1 (A) shows a sectional view and FIG. 1 (B) shows a plan view seen from below.

  In FIG. 1, the smoke detector 10 of the present embodiment is generally configured by a detector body 12, a light emitting element 16, a light receiving element 18, a transparent cover 20, a back cover 24, and a circuit board 26.

  The sensor body 12 has a cylindrical donut shape with an opening at the top, and a cylindrical through hole 14 is formed in the center of the sensor body 12 so as to pass through the sensor line temporarily. The side outer surface is a flat detection surface 12a.

  The through-hole 14 provided in the smoke detector 10 of the present embodiment is used for wiring connection work for attaching and fixing the smoke detector 10 to the ceiling attachment hole, thereby simplifying the installation work of the smoke detector. It can be easy and safe.

  A housing hole in which the light emitting element 16 is disposed and a housing hole in which the light receiving element 18 is disposed are formed in the sensor body 12 so as to face obliquely downward, and the optical axes of the light emitting element 16 and the light receiving element 18 are below the detection surface 12a. A scattered light type smoke detection structure having a smoke detection space in the external space is realized as a sensor unit by being arranged so as to intersect at a smoke detection point P set in the external space on the side.

  A light emitting opening 16a and a light receiving opening 18a are formed on the detection surface 12a of the sensor body 12 so as to correspond to the receiving holes of the light emitting element 16 and the light receiving element 18, and the light from the light emitting element 16 is smoked through the light emitting opening 16a. A scattered light emitted from the smoke detection space centered at the point P and scattered by the smoke particles existing in the smoke detection space is incident on the light receiving element 18 through the light receiving opening 18a, and a light reception signal corresponding to the received light scattering amount is obtained. I am trying to output. Thus, by setting the smoke detection point P of the scattered light type smoke detection mechanism outside the sensor main body 12, it is not necessary to form a smoke detection space inside as in the conventional scattered light type smoke sensor.

  A thin transparent cover 20 is disposed on the detection surface 12a provided with the light emitting opening 16a and the light receiving opening 18a of the sensor body 12, and the light emitting opening 16a and the light receiving opening 18a are closed to prevent dust from entering inside. . The transparent cover 20 is detachably attached to the sensor main body 12, and a boss 21 protrudes inside the outer peripheral portion, and is fitted into a boss hole formed on the outer peripheral surface of the sensor main body 12 to prevent the transparent cover 20 from coming off. .

  If a boss hole is provided on the sensor body 12 side corresponding to the boss 21 of the transparent cover 20, positioning is required when the transparent cover 20 is mounted. Instead, alignment can be eliminated by forming an annular groove.

  In this embodiment, the transparent cover 20 is provided so as to cover the entire detection surface 12a. However, the transparent cover may be fitted only in the light emitting opening 16a and the light receiving opening 18a.

A circuit housing part 22 having an opening on the back side is formed in the interior of the sensor body 12 and a circuit board 26 is incorporated therein. A sensor circuit for determining a fire based on the scattered light type smoke detection in the circuit board 26. Has been implemented. A lead wire 28 is drawn out from the circuit board 26, and a back cover 24 is attached to the back surface of the circuit housing portion 22 .

  As shown in FIG. 1 (B), recessed portions 32 are formed at two locations on the outer periphery of the detection surface of the sensor body 12, and screw mounting holes 34 are provided there, and screw mounting holes 34 are used as ceiling mounting holes. The direct smoke detector 10 can be attached and fixed.

  FIG. 2 is a perspective view of the smoke detector shown in FIG. 1, with the detection surface side upside down. As shown in FIG. 2, a through hole 14 is opened at the center of the detection surface 12 a of the doughnut-shaped sensor body 12 in the smoke sensor 10, and a light emitting opening 16 a and a light receiving opening are opposed to each other across the through hole 14. 18a is formed. In addition, recessed portions 32 provided with screw mounting holes 34 are formed at two locations on the outer periphery of the sensor body 12.

  A transparent cover 20 is detachably attached to the detection surface 12a of the sensor body 12, and the light emitting opening 16a and the light receiving opening 18a are closed. Further, an alarm indicator lamp 36 is provided on the outer peripheral portion of the detector main body 12 on the detection surface 12 a side and protrudes through the through hole of the transparent cover 20. The notification indicator lamp 36 may have a flat structure embedded in the detection surface 12a, and the transparent cover 20 may be attached to the outside thereof.

  FIG. 3 is a block diagram showing a detector circuit built in the smoke detector of FIG. In FIG. 3, the detector circuit of the smoke detector 10 includes a signal processing unit 38 using a microprocessor (MPU) known as a one-chip CPU. The signal processing unit 38 includes a storage unit 40 and a light emission control unit. 42, an amplifier circuit 44, and a notification circuit 46, and a fire determination unit 48 is provided in the signal processing unit 38 as a function realized by executing a program.

  The light emission control unit 42 drives the light emitting element 16 using the infrared LED to emit light intermittently at a predetermined period. The amplifying circuit 44 amplifies the received light signal of the scattered light due to the smoke existing in the smoke detection area centered on the smoke detection point P received by the light receiving element 18 such as a photodiode and inputs the amplified signal to the signal processing unit 38.

  For example, the fire determination unit 48 outputs a light emission pulse signal from the light emission control unit 42 at a cycle of 1 second to drive the light emitting element 16 to emit light. In this case, the light emission drive of the light emitting element 16 is performed by continuously outputting, for example, 5 light emission pulses of 3 kHz, for example, from the light emission control unit 42.

  In synchronization with the output of the light emission drive pulse signal from the light emission control unit 42 by the fire determination unit 48, the amplified signal of the received light signal of the scattered light received by the light receiving element 18 from the amplifier circuit 44 is read as received light data by AD conversion. When the amount of scattered light received based on the received light data exceeds a predetermined fire judgment threshold, for example, a fire detection signal is output to the alarm circuit 46.

  When receiving a fire detection signal from the signal processing unit 38, the alarm circuit 46 turns on the built-in switching element and causes an alarm current to flow to the sensor line via the lead wire 28 drawn from the terminals L and C. Thus, the alarm signal is transmitted to the receiver side.

  In addition, the fire determination by the fire determination unit 48 can use an appropriate fire determination such as determining a fire from the rate of increase in the amount of received light per unit time in addition to the threshold value comparison of the amount of scattered light received.

  FIG. 4 is an explanatory view showing in sequence the installation work of the smoke detector according to the present invention with respect to the ceiling hole, FIG. 5 shows a state in the middle of the operation of attaching the smoke detector to the ceiling attachment hole, and FIG. The state after the installation work with respect to the ceiling mounting hole of a sensor is completed is shown.

  The procedure of the mounting operation will be described with reference to FIG. First, as shown in FIG. 4A, a ceiling mounting hole 52 is formed in advance at a predetermined position of the ceiling 50 in the warning area. When the smoke detector 10 is attached to the lower side of the ceiling mounting hole 52, the sensor lines 56a and 56b and the sensor lines 58a and 58b routed to the back side of the ceiling 50 are pulled out from the ceiling mounting hole 52 to the lower side. Keep it.

  Here, the sensor lines 56a and 56b are sensor lines from the receiver or an adjacent smoke sensor located on the receiver side, while the sensor lines 58a and 58b are the next smoke sensor located on the filter side. Is a sensor line for. When the smoke sensor 10 is connected to the end of the sensor line, only the sensor lines 56a and 56b from the receiver side are pulled out from the ceiling mounting hole 52.

  Next, as shown in FIG. 4B, the sensor lines 56a and 56b and the sensor lines 58a and 58b drawn from the ceiling mounting hole 52, and the lead wire 28 drawn to the back side of the smoke detector 10, While passing through the through hole 14 of the smoke detector 10, the smoke detector 10 is screwed and fixed to the lower side of the ceiling mounting hole 52 with a screw 54.

  The details of FIG. 4B are shown in FIG. In FIG. 5, the sensor lines 56 a and 56 b and the sensor lines 58 a and 58 b drawn from the ceiling mounting hole 52 are passed through the through hole 14 of the smoke sensor 10, and the back side of the smoke sensor 10. Similarly, the lead wire 28 taken out is passed through the through hole 14. For the lead wire 28, the sensor lines 56a and 56b, and the sensor lines 58a and 58b, it is desirable to peel off the tip coating and expose the new lines in advance as shown.

After passing the lead wire 28 and the sensor lines 56a and 56b and the sensor lines 58a and 58b through the through hole 14 of the smoke sensor 10, the smoke sensor 10 is aligned below the ceiling mounting hole 52. In this state, the smoke detector 10 is directly attached and fixed to the ceiling 50 with the screw 54 through the screw attachment hole 34 formed in the recessed portion 32.

  Subsequently, as shown in FIG. 4 (C), connection work between the lead wires 28a and 28b drawn downward through the through hole 14 of the smoke detector 10, the sensor lines 56a and 56b, and the sensor lines 58a and 58b. I do. This connection operation is performed by crushing with a tool in a state where the lead wires 28a, the sensor line 56a, and the sensor line 58a are inserted into the crimp terminal 60a with an insulating tube. Similarly, the other lead wire 28b, the sensor line 56b, and the sensor line 58b are connected by being inserted into another crimp terminal 60b with an insulating tube and crushed by a tool.

  The operation of connecting these three signal lines together with the crimp terminals is performed after the smoke detector 10 is already connected and fixed to the ceiling 50, and the signal lines of the conventional smoke detector shown in FIG. Holding and supporting the smoke detector 10 without the need to perform complicated operations such as connecting and fixing the three signal wires with the crimp terminals while supporting the smoke detector 200 by hand as in the connection operation. In addition, it is possible to easily perform the operation of bringing together the three signal lines drawn from the through hole 14 into one and connecting them with the crimp terminals.

  In particular, the signal line connection work is a high place work close to the ceiling 50, but since the smoke detector 10 has already been mounted and fixed, it is only necessary to connect the wires together. And can be performed safely even at high places.

  Subsequently, as shown in FIG. 4D, the lead wires 28a and 28b, the sensor lines 56a and 56b, and the sensor lines 58a and 58b connected by using the crimp terminals 60a and 60b are connected from the through hole 14 to the ceiling mounting hole. The installation work is completed by pushing the back side of the ceiling 50 through 52.

  The details of the attachment completion state of FIG. 4D are shown in FIG. When the mounting work and the wiring connection work for the ceiling mounting hole 52 are completed in this way, the transparent cover 20 removed from the smoke detector 10 prior to the mounting work is fitted to the lower side as shown in FIG. The installation work is completed by mounting it together.

  FIG. 7 is an explanatory view showing another embodiment of the smoke detector according to the present invention provided with a display unit for displaying time, temperature and humidity using a through hole provided for facilitating the mounting operation. 7A shows a cross section, and FIG. 7B shows a plane viewed from below.

In the embodiment of FIG. 7A, the structure of the smoke detector 10 is the same as that of the embodiment of FIG. 1, but a display unit 64 is provided in the through hole 14. The display unit 64 is a cylindrical body that matches the shape of the through hole 14, and a positioning rib 68 is formed on the upper side of the through hole 14, and the lower side of the through hole 14 with the transparent cover 20 removed. Then, the display unit 64 is inserted and positioned by the rib 68. In this state, the transparent cover 20 is mounted from the lower side, and the display unit 64 is stored and held in the through hole 14.

  As shown in FIG. 7B, the display unit 64 includes a display surface 66 using a liquid crystal display or the like on the lower side. In this embodiment, the time “15:00” and the temperature “20 ° C.” And the humidity “65% RH” is displayed. For this reason, the display unit 64 houses a clock unit, a temperature detection circuit having a temperature sensor, and a humidity detection circuit having a humidity sensor.

  As described above, in the embodiment of FIG. 7, the through hole 14 used for the work for mounting and fixing the smoke detector 10 shown in FIGS. 4 to 6 to the ceiling mounting hole is unnecessary after the mounting. Therefore, by providing, for example, the display unit 64 using the empty space of the through hole 14, multi-functionalization by the smoke detector 10 and the display unit 64 can be easily realized.

  In the embodiment of FIG. 7, the time, temperature, and humidity are integrally displayed on the display unit 64, but a display unit that individually displays each may be provided. As the display contents of the display unit 64, a display unit suitable for an appropriate use such as a photo frame, a photograph, a character, and a color changed according to an installation place can be provided as necessary.

  Further, the display unit 64 may be interlocked with the smoke detector 10 so that, for example, the notification display lamp 36 is turned on when a fire is detected, and at the same time, a red display color indicating the occurrence of fire is displayed on the display unit 64.

  FIG. 8 is an explanatory view showing another example of the structure for attaching the display unit to the through hole of the smoke detector. In FIG. 8, two inverted L-shaped fitting grooves 71 are formed in the two positions inside the through-hole 14 of the smoke detector 10 so as to open downward and correspond to the fitting grooves 71. Thus, the bosses 70 are projected at two locations on the outer periphery of the display unit 64 having a cylindrical shape. The display unit 64 is attached to the through hole 14 of the smoke detector 10 by pushing the boss 70 upward in a state in which the boss 70 is aligned with the fitting groove 71 and turning counterclockwise. It is fixed at the end of the letter shape to prevent it from coming off.

  In addition, as a detachable mounting structure of the display unit 64 with respect to the through hole 14 of the smoke detector 10, other appropriate detachable mounting structures can be applied.

  In addition, a power source required to operate a unit having a predetermined function provided in the through hole 14, for example, the display unit 64, can be obtained by arranging contact fittings in the built-in battery, the fitting groove 71 and the boss 70 in the unit. For example, the sensor main body 12 and the unit are connected to supply power from the sensor main body 12 to the unit, or a power line is wired to the unit.

  FIG. 9 is an explanatory view showing another embodiment of the smoke detector according to the present invention in which a lighting unit is provided in a through hole. FIG. 9 (A) shows a cross section, and FIG. Shows a flat surface.

  9A, the smoke detector 10 is the same as that of the embodiment of FIG. 1, but an illumination unit 72 is provided in the through hole 14 of the detector body 12. In FIG. The illumination unit 72 includes a plurality of white LEDs 74 as light sources, for example, in an illumination cover 72b provided on the lower side of the unit body 72a. An illumination signal line 76 is taken out from the upper part of the unit main body 72a.

  The unit main body 72a has a stepped structure with a large diameter on the lower side and a small diameter on the upper side, and a hole corresponding to the small diameter portion is formed on the ceiling surface side of the through hole 14 in accordance with the stepped structure. The illumination unit 72 can be housed and held in the through hole 14 by fitting the transparent cover 20 in this state by removing the bracket and inserting the transparent cover 20 into the through hole 14 from below.

  Further, as shown in the plan view of FIG. 9B, the illumination unit 72 has, for example, five white LEDs 74 arranged in the illumination cover 72b, so that a sufficient amount of illumination light can be secured with low power consumption. I have to.

  9 is performed as shown in FIGS. 4 to 6 with the transparent cover 20 and the illumination unit 72 removed, with respect to the ceiling mounting hole of the smoke detector 10 in the embodiment of FIG. When the installation of the smoke detector 10 to the ceiling mounting hole is completed, an illumination signal line is pulled out from the back side of the ceiling through the ceiling mounting hole and the through hole 14 and output with the illumination signal line 76 of the illumination unit 72. After connecting with a terminal or the like, the lighting unit 72 is inserted into the through hole 14 as shown in FIG. Installation is complete.

  The lighting unit 72 provided in the through-hole 14 of the smoke detector 10 may be used as a downlight used in daily life or may be used as an emergency light that is turned on during a power failure. Further, by providing a human sensor in the lighting unit 72, it is possible to provide a lighting unit that detects and lights a person.

  In addition, when the illumination unit 72 is provided in the through-hole 14, the light by lighting of the illumination unit 72 is irradiated to the external smoke detection space centering on the smoke detection point P, and when smoke exists, the scattered light Is incident on the light receiving element 18 and is received, but the wavelength of the light output from the light emitting element 16 is a specific wavelength, for example, 450 mn.

  Further, the light emission of the light emitting element 16 and the light reception of the light receiving element 18 are performed intermittently synchronously, for example, at a cycle of 1 minute, and the influence when the white LED 74 is lit can be sufficiently reduced. On the contrary, since the amount of light received when smoke is present upon receiving the amount of light from the white LED 74, it can be expected to increase the sensitivity as a smoke detector.

  In the embodiment of FIG. 9, the white LED 74 is used as the light source. However, the present embodiment is not limited to this, and an appropriate light source may be used.

  9A, the space of the through hole 14 of the smoke detector 10 is limited by the thickness of the sensor body 12 and the diameter of the through hole 14, and the unit size that can be accommodated in this portion is as follows. Although limited, the upper part of the through hole 14 is open to the back side of the ceiling through the ceiling mounting hole, so that a unit is required from the upper part of the through hole 14 as in the lighting unit 72 of FIG. Therefore, even if there is a restriction on the installation space by the through hole 14, it is possible to effectively use the space extending to the back side of the ceiling without being restricted by this restriction. Thus, a sufficiently large unit exceeding the size of the through hole 14 can be provided.

  FIG. 10 is an explanatory view showing another embodiment of a smoke detector according to the present invention in which a CO sensor unit is provided in a through hole. FIG. 10 (A) shows a cross section, and FIG. It shows the plane seen.

  The smoke sensor 10 of FIG. 10A is the same as that of the embodiment of FIG. 1, but a CO sensor unit 78 is provided in the through hole 14 in this embodiment. The CO sensor unit 78 accommodates a CO detection element 80 therein, and a ventilation slit 84 is formed on the lower surface of the unit shown in FIG. Ventilation opening 20b is formed so that the atmosphere in the warning area can come into contact with the built-in CO detection element 80.

Further, the CO sensor unit 78 has a small diameter portion on the ceiling surface side, and an opening hole is formed in the upper portion of the through hole 14 of the sensor body 12 in accordance with the small diameter portion, and the transparent cover 20 is removed to form the through hole 14. The CO sensor unit 78 can be housed and held in the through hole 14 by mounting the transparent cover 20 after inserting and positioning the CO sensor unit 78 from the lower side. A sensor signal line 82 is drawn from the upper part of the CO sensor unit 78 to the ceiling back surface side.

The sensor signal line 82 is connected to the receiving side of a gas leak monitoring system or an environmental system (not shown), for example. When CO detection exceeding a predetermined concentration is performed by the CO sensor unit, a CO detection signal is output and an alarm is displayed. It will be.

  In the embodiment of FIG. 10, the case where the CO sensor unit 78 is provided in the through hole 14 of the smoke detector 10 is taken as an example. However, as another embodiment of the present invention, other than the CO sensor unit is used. Appropriate sensor units such as a thermal sensor unit with a temperature detection element, a sensor unit with a sensor for detecting gas leakage such as city gas, a sensor unit with a theft sensor, a sensor unit with a human sensor, etc. Can be provided.

  FIG. 11 is an explanatory view showing another embodiment of the smoke detector according to the present invention in which a speaker unit is provided in the through hole 14, FIG. 11 (A) shows a cross section, and FIG. It shows the plane seen.

The smoke detector 10 in FIG. 11A is the same as the embodiment in FIG. 1, but a speaker unit 86 is provided in the through hole 14 in the present embodiment. The speaker unit 86 houses a speaker 88 therein, and is driven by an acoustic signal from the speaker signal line 87 drawn to the upper surface side to perform appropriate sound output. The speaker unit 86 is stored and held in the through hole 14 by providing a positioning rib 68 on the upper opening side of the through hole 14 and mounting the transparent cover 20 in a state where the speaker unit 86 is inserted so as to contact the rib 68. Can be stored and held.

  As shown in FIG. 11B, the transparent cover 20 has an acoustic hole 90 formed at a position facing the speaker unit 86 so that sound from the speaker 88 can be sufficiently emitted to the outside.

  The sound output by the speaker unit 86 of the present embodiment may be, for example, a district sound output including a message and a warning sound linked with the smoke detector 10, or an emergency emergency broadcast by an emergency broadcast facility. It is also possible to use music on a daily basis.

  Note that the speaker unit 86 in FIG. 11 is basically a kind of acoustic conversion unit, and the acoustic conversion unit may be a unit provided with an acoustic conversion element such as a buzzer in addition to the speaker unit.

  FIG. 12 is an explanatory view showing another embodiment of the smoke detector according to the present invention in which a wireless relay unit is provided in the through hole, and FIG. 12 (A) shows a cross section, and FIG. It shows the plane seen.

  In FIG. 12A, the smoke detector 10 is the same as that of the embodiment of FIG. 1, and the wireless relay unit 100 is provided in the through hole 14 in this embodiment. The wireless relay unit 100 has a stepped structure including a large diameter portion and a small diameter portion, and is positioned by contacting the large diameter step portion with a rib 68 formed in the upper portion of the through hole 14, and the lower side is attached with the transparent cover 20. The positioning is held at. The small-diameter step portion of the wireless relay unit 100 extends to the back side of the ceiling, and the battery 104 is accommodated therein. An antenna 102 is taken out below the wireless relay unit 100.

  As shown in the plan view of FIG. 12B, the antenna 102 is provided at a position 90 ° different from the optical axis of the scattered light type smoke detection mechanism connecting the light emitting opening 16a and the light receiving opening 18a. The smoke detection space is not disturbed.

  The radio relay unit 100 provided in the through hole 14 is an appropriate radio relay system used in the monitoring area where the smoke detector 10 is installed, for example, a repeater in a radio system adopting a standard of a specific low power radio station. Can be used as

  FIG. 13 is an explanatory view showing another embodiment of the smoke detector according to the present invention in which an access point unit is provided in the through hole. FIG. 13 (A) shows a cross section, and FIG. It shows the plane seen.

  In FIG. 13A, the smoke detector 10 is the same as the embodiment of FIG. 1, and in this embodiment, the access point unit 105 is provided in the through hole 14. The access point unit 105 functions as an access point in the wireless LAN system, and has a function of mutually converting and connecting a wireless LAN line and a wired LAN line.

  That is, the access point unit 105 is connected to the LAN cables 108 and 110 from the back side of the ceiling for connection to a wired LAN line, and an antenna 106 for connecting to the wireless LAN line is provided below the through hole 14. Yes. As in the embodiment of FIG. 13, the antenna 106 has a smoke detection space that is 90 ° shifted from the optical axis connecting the light emitting opening 16a and the light receiving opening 18a in the scattered light smoke detection mechanism, as shown in FIG. 13B. It is provided in a position that does not interfere.

  Here, in the wireless relay unit 100 provided in the smoke detector 10 in FIG. 12 and the access point unit 105 provided in the smoke detector 10 in FIG. 13, the smoke detector 10 is an emergency on the ceiling surface of the room in the warning area. Therefore, it is possible to secure a good radio wave environment with the wireless terminal equipment in the warning area by providing a communication unit that performs wireless communication in the through hole 14 of the smoke detector 10. Therefore, it is possible to construct a high-performance wireless line.

  FIG. 14 is an explanatory view showing another embodiment of the smoke detector according to the present invention in which the through hole is a rectangular hole. FIG. 14 (A) shows a cross section, and FIG. 14 (B) shows the lower side. A plane is shown.

  14, the basic structure of the smoke detector 10 is the same as that of the embodiment of FIG. 1. However, in the present embodiment, a through hole provided vertically through the center of the detector body 12 is used. A rectangular through hole 114 that is rectangular when viewed from above is formed. By providing the rectangular through hole 114, various units housed in the rectangular through hole 114 have a rectangular shape.

  In FIG. 14, a rectangular through hole 114 having a rectangular shape is taken as an example, but an appropriate polygonal through hole other than a rectangle may be used, or a special shape such as a star shape may be used. It is good also as a through hole with.

  FIG. 15 is a cross-sectional view showing another embodiment of the smoke detector according to the present invention in which a fitting terminal attached to and detached from the detector base is provided. In FIG. 15, the smoke detector 10 includes a detector body 12 and a chamber base 11 that is fitted and fixed to the lower side of the detector body 12.

  The chamber base 11 is formed with a through hole 14a penetrating vertically in the center, and the light emitting element 16 and the light receiving element 18 are inclined downward so as to set the smoke detection point P in the external space below the detection surface 11a. Thus, the light emitting opening 16a and the light receiving opening 18a are provided on the detection surface 11a.

  The sensor main body 12 has a circuit housing portion 22 that opens downward, and the partition wall at the top of the circuit housing portion 22 is used as a terminal block 116. The center of the sensor body 12 is connected to the through hole 14a of the chamber base 11 and opens up and down. The formed through hole 14b is formed. Fitting fittings 118 and 120 are fixed to the terminal block 116 of the sensor main body 12, and are connected to the circuit board 26 housed in the circuit housing portion 22 through the connection fittings 122 and 124.

  The fitting terminals 118 and 120 are electrically and mechanically connected to the smoke detector 10 by turning around the fitting terminals 118 and 120 according to a pair of fitting fittings provided on the sensor base fixed to the lower side of the ceiling mounting hole. .

  Since the embodiment of FIG. 15 is detachably provided on the sensor base provided in the ceiling mounting hole, the wiring connection at the time of installation shown in FIGS. 4 to 6 using the through holes 14a and 14b provided in the center. Although it does not facilitate the work, by providing the through holes 14a and 14b, it is possible to achieve multiple functions by mounting the various units shown in the embodiments of FIGS.

  FIG. 16 is an explanatory view showing the structure of the heat sensor according to the present invention, where FIG. 16A shows a cross-sectional view and FIG. 16B shows a plan view seen from below.

In FIG. 16, the heat sensor 111 of the present embodiment is generally configured by a sensor body 112, a temperature detection element 130, a protective cover 131 , a back cover 124, and a circuit board 126.

The sensor main body 112 has a cylindrical donut shape opened at the top, and a cylindrical through hole 14 is formed in the center of the sensor main body 112 so as to penetrate vertically and allow a sensor line to be inserted. . As shown in FIG. 4, the through hole 14 is used for wiring connection work for attaching and fixing the heat sensor 111 to the ceiling attachment hole, so that the heat sensor 111 can be easily and easily attached. And it can be safe.

  On the right side of the lower surface of the sensor body 12, a temperature detection element 130 as a sensor portion protrudes downward, and a protective cover 131 having a frame structure that covers the periphery and allows the passage of a hot air current is disposed. The temperature detecting element 130 is a thermistor, a semiconductor element or the like, and generates a resistance change or a voltage change corresponding to the temperature when receiving a hot air current due to a fire.

  A circuit housing part 122 having an opening on the back surface side is formed inside the sensor body 112 and a circuit board 126 is incorporated, and a temperature detection signal is generated on the circuit board 126 from a resistance change or a voltage change of the temperature detection element 130. A sensor circuit that judges fire is implemented. A lead wire 128 is drawn out from the circuit board 126, and a back cover 124 is attached to the back surface of the circuit housing portion 126.

As shown in FIG. 16B, recessed portions 132 are formed at two locations on the outer periphery of the detection surface of the sensor main body 112, and screw mounting holes 134 are provided there, and screw mounting holes 134 are used to form ceiling mounting holes. The heat sensor 111 can be directly attached and fixed.

As in the embodiment of FIG. 7, the display unit 64 is inserted into the through hole 14 of the sensor main body 112 from the lower side and positioned by the rib 68. For example, the structure shown in FIG. The display unit 64 is housed and held.

  As shown in FIG. 16B, the display unit 64 includes a display surface 66 using a liquid crystal display or the like on the lower side. In this embodiment, the time “15:00” and the temperature “20 ° C.” And the humidity “65% RH” is displayed. For this reason, the display unit 64 houses a clock unit, a temperature detection circuit having a temperature sensor, and a humidity detection circuit having a humidity sensor.

In the heat sensor 111 of FIG. 16, the display unit 64 is stored and held in the through hole 114 as an example, but other units are similarly stored and held as shown in FIGS. You may do it.

FIG. 17 is a block diagram showing a sensor circuit built in the heat sensor of FIG. In FIG. 17, the sensor circuit of the heat sensor 111 includes a signal processing unit 138 using a microprocessor (MPU) known as a one-chip CPU. The signal processing unit 138 includes a storage unit 140, a temperature detection circuit. 150 and the alarm circuit 146 are provided, and the signal processing unit 138 is provided with a fire determination unit 148 as a function realized by executing the program.

  The temperature detection circuit 150 generates a temperature detection signal from a resistance change or a voltage change corresponding to the temperature of the temperature detection element 130 and inputs it to the signal processing unit 138. The fire determination unit 148 AD-converts the temperature detection signal and reads it as temperature detection data. When the temperature detection data exceeds, for example, a predetermined fire determination threshold value, the fire determination signal is output to the alarm circuit 146.

  Upon receiving the fire detection signal from the signal processing unit 138, the alarm circuit 146 turns on the built-in switching element and causes the alarm current to flow to the sensor line via the lead wire 128 drawn from the terminals L and C. Thus, the alarm signal is transmitted to the receiver side. Here, the fire determination by the fire determination unit 148 can use an appropriate fire determination such as determining a fire from the increasing rate of the detected temperature per unit time, in addition to the threshold comparison of the temperature detection data.

  In the smoke detector 10 of the above embodiment, as shown in FIG. 1B, the light emitting opening 16a and the light receiving opening 18a are arranged on the detection surface 12a at opposing positions passing through the center. However, it may be arranged so as to be offset by a predetermined angle instead of the opposed position.

Further, in the heat sensor shown in FIG. 16 , the temperature detecting element 130 protrudes downward from the lower surface of the sensor main body 112. The temperature detecting element 130 can be provided at the position.

Further, as another embodiment of the present invention, the smoke detector 10 shown in FIG. 1, a temperature detection element 130 provided for the heat detector 111 in FIG. 16 the protective cover 131, the light scattering type smoke detector By providing it in a position that does not obstruct the space, it may be a combined sensor that detects smoke and heat to determine a fire.

  In the above-described embodiment, an on / off type sensor that sends a fire detection signal to the receiver by sending an alarm current to the sensor line when a fire is judged is taken as an example. Analog sensor that sends analog data of smoke density and temperature to polling connected and specified address from receiver to detect fire on receiver side, smoke density and temperature detected by batch AD conversion command from receiver However, the present invention can be applied to an appropriate sensor such as an addressable sensor that sends an interrupt signal to a receiver when a fire is judged and receives a search process from the receiver and responds to the fire signal.

The present invention is not limited to the above-described embodiment, includes appropriate modifications without impairing the object and advantages thereof, and is not limited by the numerical values shown in the above-described embodiment.

10: Smoke detector 11: Chamber base 12, 112: Sensor main body 14 : Through hole 16: Light emitting element 16a: Light emitting opening 18: Light receiving element 18a: Light receiving opening 20: Transparent cover 22, 122: Circuit housing parts 24, 124 : Back cover 26, 126: Circuit board 28, 128: Lead wire 32, 132: Recess 34, 134: Screw mounting hole 36, 136: Alarm indicator lamp 38, 138: Signal processing unit 40, 140: Storage unit 42 : Light emission control unit 44: Amplifying circuit 46 and 146 : Alarm circuit 48 and 148 : Fire judgment unit 50: Ceiling 52: Ceiling mounting hole 54: Screws 56a, 56b, 58a, 58b: Sensor lines 60a, 60b: Crimp terminals 64: Display unit 66: Display surface 68: Rib 70: Boss 71: Fitting groove
72: Lighting unit 74: White LED
76: Illumination signal line 78: CO sensor unit 80: CO detection element 82: Sensor signal line 84: Ventilation slit 86: Speaker unit 88: Speaker 90: Acoustic hole 100: Radio relay unit 102, 106: Antenna 104: Battery 105: Access point unit 108, 110: LAN cable
111: Heat sensor 114: Rectangular through hole 130: Temperature detection element 131: Protective cover 150: Temperature detection circuit

Claims (17)

Have a through hole wherein after wiring connection work through the signal lines in the vertical as possible placed back on the back the installation surface of the signal line laid to the installation surface back when the wiring connection work a can be inserted in the monitoring area side And a disc-shaped sensor body that is fixedly mounted on the installation surface ,
A lead wire that is pulled out from the sensor body and connected to a signal line laid behind the installation surface;
A sensor unit provided in the sensor body for detecting a physical phenomenon associated with a fire;
A signal processing unit built in the sensor body and executing a predetermined sensor process based on a detection signal output from the sensor unit;
A unit having a predetermined function detachably provided in the through hole of the sensor body;
A sensor characterized by comprising:
The sensor according to claim 1, wherein
The lead wire is drawn outside from the installation surface side of the sensor body, and can be stored behind the installation surface without passing through the through hole after the wiring connection work with the signal line laid on the installation surface back. ,
It said unit, after the wiring work, detector characterized by stowable der Rukoto the through hole in a state in which the signal line is returned encased and the lead wire to the installation surface back is housed in installation surface back.
2. The sensor according to claim 1, wherein a display unit for displaying desired information is provided in a through hole of the sensor body.
4. The sensor according to claim 3, wherein the display unit provided in the through hole of the sensor body displays time, temperature, humidity, a photograph, a character, or a color pattern.
2. The sensor according to claim 1, wherein an illumination unit for illuminating all or part of the monitoring area is provided in the through hole of the sensor body.
6. The sensor according to claim 5, wherein the illumination unit provided in the through hole of the sensor body is a downlight or an emergency light.
The sensor according to claim 1, wherein a sensor unit for detecting a physical phenomenon in the monitoring area is provided in a through hole of the sensor body.
8. The sensor according to claim 7, wherein the sensor unit provided in the through hole of the sensor body includes a thermal sensor, a CO sensor, a gas leak sensor, a theft sensor, or a human sensor. sensor.
The sensor according to claim 1, wherein an acoustic conversion unit that outputs sound to the monitoring area is provided in a through hole of the sensor body.
The sensor according to claim 9, wherein the acoustic conversion unit provided in the through hole of the sensor body includes a speaker or a buzzer.
The sensor according to claim 1, wherein a communication unit is provided in a through hole of the sensor body.
In claim 11, wherein the sensor, the communication unit provided in the through hole of the sensor body, sensor, which is a radio relay unit for relaying a radio signal.
12. The sensor according to claim 11, wherein the communication unit provided in the through hole of the sensor body is an access point unit for converting and connecting a wireless LAN line and a wired LAN line to each other. .
The sensor according to claim 1, wherein the sensor unit includes:
A light emitting opening and a light receiving opening provided on the outer surface of the sensor body;
A transparent cover that is attached to the outer surface of the sensor body and covers at least the light emitting opening and the light receiving opening;
A light emitting element built in the detector body that emits light through the light emitting opening with respect to a smoke detecting point set in an open smoke detecting space located outside the transparent cover,
Scattered light for light emitted from the light emitting element to the smoke detection point through the light emitting opening is received through the light receiving opening and outputs a light receiving signal corresponding to the amount of received light to the sensor body. A built-in light receiving element;
And the signal processing unit determines whether or not a fire has occurred based on a light reception signal output from the light receiving element.
The sensor according to claim 14, wherein
The light emitting opening and the light receiving opening are provided on the outer surface of the sensor body located on the lower side in a ceiling-mounted state,
The sensor is characterized in that the transparent cover is attached to a sensor body so as to cover the light emitting opening, the light receiving opening and the through hole opening.
16. The sensor according to claim 15, wherein the transparent cover is detachably provided on the sensor body.
The sensor according to claim 1, wherein
The sensor unit is provided with a temperature detection element on the outer surface of the sensor body,
The sensor, wherein the signal processing unit determines whether or not a fire has occurred based on a temperature detection signal output from the temperature detection element.

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