CN114429700A - Alarm for fire safety based on Internet of things - Google Patents

Abstract

The invention is suitable for the technical field of alarms, and provides an alarm for fire safety based on the Internet of things, which comprises a detection mechanism, wherein the detection mechanism comprises a ventilation assembly arranged on a detection shell, and a plurality of smoke alarms arranged in the detection shell; the detection mechanism also comprises a limit support piece arranged in the detection shell; the monitoring mechanism is fixedly arranged on a camera on one side of the monitoring shell, and the orientation of the camera is adjusted through a driving motor; monitoring mechanism still include with spacing support piece matched with installation mechanism, installation mechanism rotates the dress on the control shell, stretches into installation mechanism in the detection shell carries out spacing fixedly through spacing support piece. The alarm provided by the invention can be used for independently realizing the quick connection between the monitoring mechanism and the detection mechanism, is convenient to install and use and has the advantage of convenience in use.

Description

Alarm for fire safety based on Internet of things

Technical Field

The invention belongs to the technical field of alarms, and particularly relates to an alarm for fire safety based on the Internet of things.

Background

In the construction process of decorative fire engineering, fire alarm equipment, namely automatic fire alarm electrical equipment, needs to be installed in a building, and common fire alarm equipment comprises various fire detectors, manual alarm buttons, fire hydrant pump starting buttons, alarms, field execution modules and the like, and all the equipment are connected to a fire alarm host to carry out centralized monitoring and control.

The fire alarm is an alarm which can generate an alarm when a fire disaster is caused by detecting a large amount of smoke, heat and the like, is generally arranged at places where people often exist, such as a walkway, a stair entrance and the like, can give out sound alarm when the fire disaster occurs, and sends a flashing light to flash to remind people in the field to pay attention. Nowadays, with the continuous enhancement of the national fire protection consciousness, fire alarms are basically installed in many public places.

However, in the current fire alarm, most of the smoke detectors with single structures are adopted, when the smoke detectors detect smoke, the action of the sound-light alarm is triggered to realize the fire alarm effect, timely feedback on the video pictures of the scene cannot be timely carried out, although part of the alarms can realize video monitoring, the video monitoring part and the smoke sensor detection part are in a screw fixed connection or an integrated structure, quick connection between the monitoring part and the detection part cannot be realized, the alarm is not convenient to install and use, and the use requirements cannot be met.

Disclosure of Invention

The invention aims to provide an alarm for fire safety based on the Internet of things, and aims to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions.

An alarm for fire safety based on thing networking includes:

the detection mechanism comprises a ventilation assembly arranged on the detection shell, and the detection mechanism further comprises a plurality of smoke alarms arranged in the detection shell; the detection mechanism also comprises a limit support piece arranged in the detection shell;

the monitoring mechanism is fixedly arranged on a camera on one side of the monitoring shell, and the orientation of the camera is adjusted by a driving motor; monitoring mechanism still include with spacing support piece matched with installation mechanism, installation mechanism rotates the dress on the control shell, stretches into installation mechanism in the detection shell carries out spacing fixedly through spacing support piece.

In an embodiment provided by the invention, the mounting mechanism comprises a mounting column rotationally connected with the monitoring shell, an upper cone is fixedly mounted at the end of the mounting column, a lower cone is slidably sleeved on the mounting column, and a fixed support ring for limiting the stroke of the lower cone is further arranged on the mounting column; the inclined surface of the upper cone faces upwards, and the inclined surface of the lower cone faces downwards.

In one embodiment provided by the invention, the limiting support comprises a fixed cylinder fixedly installed in the detection shell, a rectangular sliding block is supported and slidably arranged in the fixed cylinder through a support spring, and a square block is fixedly installed on the rectangular sliding block.

In an embodiment of the present invention, the end of the square block has a downward guiding inclined surface, and when the supporting spring is in an unstressed state, the supporting spring pushes the square block to move to the guiding inclined surface to abut against the mounting mechanism, specifically, the guiding inclined surface abuts against the inclined surface of the upper cone.

In one embodiment of the invention, the bottom of the detection shell is provided with a mounting channel matched with the mounting mechanism, and the mounting mechanism extends into the detection shell through the mounting channel.

In one embodiment provided by the invention, one side of the detection shell is provided with an air inlet window, and an air inlet machine is arranged in the air inlet window; the smoke alarm comprises a detection shell, wherein the detection shell is provided with an air inlet and an air outlet, the detection shell is provided with an air outlet window, and the air inlet and the air outlet are matched with each other.

In an embodiment of the present invention, the monitoring mechanism further includes a protection shell matched with the detection housing, when the mounting mechanism extends into the detection housing, the protection shell is sleeved on the detection housing, and the side wall of the protection shell is further provided with a vent hole, so that when the monitoring mechanism is mounted on the detection mechanism, the air flowability inside the alarm is ensured.

In an embodiment provided by the present invention, a storage battery and an intelligent controller are further respectively disposed in the monitoring housing, the storage battery is used for supplying power to an electric component in the monitoring mechanism, a control signal input end of the intelligent controller is electrically connected to the smoke alarm, a control signal output end of the intelligent controller is electrically connected to the driving motor, when the smoke alarm detects the existence of smoke, the intelligent controller is triggered to control the driving motor to start, and the driving motor drives the monitoring housing to rotate, so as to adjust the orientation of the camera, thereby providing a real-time image for the remote terminal.

In an embodiment provided by the invention, the monitoring mechanism further comprises an induced draft fan arranged at the bottom of the monitoring shell, the induced draft fan corresponds to the air inlet net, and the air flow rate in the monitoring shell can be increased through the mutual matching of the heat dissipation mesh, the air inlet net and the induced draft fan, so that the camera, the storage battery and the intelligent controller can be cooled.

In an embodiment provided by the present invention, the mounting column has a limiting channel, a limiting guide rod matched with the limiting channel is fixedly mounted in the detection housing, and when the mounting mechanism extends into the detection housing through the mounting channel, the limiting guide rod extends into the limiting channel.

Compared with the prior art, in the specific using process of the alarm provided by the invention, the monitoring shell is aligned with the detection shell, then the installation mechanism extends into the detection shell, because the upper cone is positioned at the top end of the mounting column, the inclined plane of the upper cone faces downwards and is matched with the orientation of the guide inclined plane, when the mounting mechanism extends into the detection shell, the inclined plane of the upper cone can relatively slide on the guide inclined plane, and the square block is displaced in the horizontal direction, and the upper cone is further made to pass over the square block, at this time, the square block is positioned below the upper cone, at the moment, the lower plane of the upper cone is propped against the upper plane of the square block, the square block plays a supporting effect on the upper cone, therefore, the effect of supporting and installing the installation mechanism in the detection shell is realized, namely, the monitoring mechanism is installed on the detection mechanism, and the installation is very convenient;

when the monitoring mechanism installed on the detection mechanism needs to be separated, the mounting mechanism is continuously pushed to move upwards in the detection shell at the moment, the guide inclined plane is further abutted to the top plane of the lower cone, therefore, the square block can easily cross the lower cone when the mounting mechanism continuously moves upwards is matched with the guide inclined plane, after the square block crosses the lower cone, the monitoring mechanism is pulled downwards to enable the mounting mechanism to move downwards, at the moment, the corresponding inclined plane of the lower cone is abutted to the top plane of the square block, further, at the moment, a cylinder with the upper inclined plane and the lower inclined plane is formed due to the fact that the upper cone and the lower cone are in a fit state, at the moment, the mounting mechanism rapidly moves downwards can enable the square block to continuously cross the cylinder formed by the upper cone and the lower cone, namely, the mounting mechanism at the moment is separated from the detection shell, namely, the separation between the monitoring mechanism and the detection mechanism is realized.

In conclusion, the alarm provided by the invention can be used for independently realizing the quick connection between the monitoring mechanism and the detection mechanism, is convenient to install and use and has the advantage of convenience in use.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention.

FIG. 1 is a block diagram of an alarm for fire safety based on the Internet of things;

FIG. 2 is a block diagram of a detection mechanism in the alarm provided by the present invention;

FIG. 3 is a schematic view of a portion of the enlarged structure at A in FIG. 2;

FIG. 4 is a block diagram of a monitoring mechanism in the alarm provided by the present invention;

FIG. 5 is a partial perspective view of a mounting assembly in the monitoring mechanism of the present invention.

In the accompanying fig. 1-5: 100. detecting the shell; 101. an air inlet window; 102. an air inlet machine; 103. an exhaust fan; 104. a smoke alarm; 105. installing a channel; 106. an air exhaust window; 200. monitoring the housing; 201. radiating meshes; 202. an air inlet net; 203. a vent hole; 204. a protective shell; 300. mounting a plate; 301. mounting holes; 302. a limiting guide rod; 400. a spacing support member; 401. a fixed cylinder; 402. a rectangular slider; 403. a support spring; 404. a square block; 405. a guide slope; 500. an installation mechanism; 501. mounting a column; 502. an upper cone; 503. a lower cone; 504. a limiting channel; 505. fixing the support ring; 600. a camera; 601. a drive motor; 700. a storage battery; 800. an intelligent controller; 900. an induced draft fan.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention. Specific implementations of the present invention are described in detail below with reference to specific embodiments.

As shown in fig. 1, in an embodiment provided by the present invention, an alarm for fire safety based on the internet of things includes:

the detection mechanism comprises a ventilation assembly arranged on the detection shell 100, and further comprises a plurality of smoke alarms 104 arranged in the detection shell 100, airflow outside the alarms is led into the detection shell 100 by using the ventilation assembly, whether the airflow contains smoke or not is further detected by the smoke alarms 104, and if the airflow contains smoke, the smoke alarms 104 perform sound reminding through a buzzer arranged on the smoke alarms 104; the detection mechanism further comprises a spacing support 400 mounted within the detection housing 100;

the monitoring mechanism is fixedly arranged on the camera 600 on one side of the monitoring shell 200, and the orientation of the camera 600 is adjusted by the driving motor 601; the monitoring mechanism further comprises an installation mechanism 500 matched with the limiting support piece 400, wherein the installation mechanism 500 is rotatably arranged on the monitoring shell 200 and extends into the detection shell 100, and the installation mechanism 500 is limited and fixed through the limiting support piece 400.

Specifically, as shown in fig. 1, 4 and 5, in a preferred embodiment of the present invention, the mounting mechanism 500 includes a mounting column 501 rotatably connected to the monitoring housing 200, an upper cone 502 is fixedly mounted at an end of the mounting column 501, a lower cone 503 is slidably sleeved on the mounting column 501, and a fixed support ring 505 for limiting a stroke of the lower cone 503 is further disposed on the mounting column 501; the inclined surface of the upper cone 502 faces upward and the inclined surface of the lower cone 503 faces downward.

It is understood that in the embodiment of the present invention, the lower cone 503 can slide freely on the mounting post 501, specifically, when the lower cone 503 slides upwards along the mounting post 501, the lower cone 503 can be attached to the upper cone 502 to form a column with an inclined surface at the top and bottom, whereas when the lower cone 503 slides downwards along the mounting post 501, the lower cone 503 is separated from the upper cone 502.

Referring to fig. 1-3, in the preferred embodiment of the present invention, the position limiting support 400 includes a fixed cylinder 401 fixedly installed in the detection housing 100, a rectangular sliding block 402 is slidably supported in the fixed cylinder 401 through a support spring 403, and a square block 404 is fixedly installed on the rectangular sliding block 402, it can be understood that the square block 404 can be displaced relative to the fixed cylinder 401, for example, when the square block 404 is stressed and displaced in a direction approaching the fixed cylinder 401, the support spring 403 is in a gradually compressed state, when the square block 404 is released to be in an unstressed state, the square block 404 is reset under the elastic support force of the support spring 403, and the reset is specifically represented as the square block 404 is far from the fixed cylinder 401.

Further, in the preferred embodiment of the present invention, the square block 404 has a downward guiding slope 405 at the end, and when the supporting spring 403 is in the non-stressed state, the supporting spring 403 pushes the square block 404 to move until the guiding slope 405 abuts against the mounting mechanism 500, specifically, the guiding slope 405 abuts against the slope of the upper cone 502.

Further, in the embodiment of the present invention, the bottom of the testing housing 100 has a mounting channel 105 that is matched with the mounting mechanism 500, and the mounting mechanism 500 extends into the testing housing 100 through the mounting channel 105.

In the specific use process of the alarm provided by the embodiment of the present invention, the monitoring housing 200 is aligned with the detection housing 100, then the mounting mechanism 500 is inserted into the detection housing 100, since the upper cone 502 is located at the top end of the mounting post 501, the inclined surface of the upper cone 502 faces downward, and the orientation of the guiding inclined surface 405 is matched, when the mounting mechanism 500 is inserted into the detection housing 100, the inclined surface of the upper cone 502 slides relatively on the guiding inclined surface 405, and the square block 404 generates displacement in the horizontal direction, and further the upper cone 502 passes over the square block 404, at this time, the square block 404 is located below the upper cone 502, at this time, the lower plane of the upper cone 502 abuts against the upper plane of the square block 404, at this time, the square block 404 plays a supporting role on the upper cone 502, thereby achieving the effect of supporting and mounting the mounting mechanism 500 in the detection housing 100, the monitoring mechanism is installed on the detection mechanism, and the installation is very convenient.

It is understood that the upper cone 502 and the lower cone 503 are in a state of being separated from each other when the monitoring mechanism is mounted on the detecting mechanism.

Further, when the monitoring mechanism installed on the detection mechanism needs to be separated, at this time, the mounting mechanism 500 is continuously pushed to move upwards in the detection housing 100, and the guiding inclined plane 405 is further abutted against the top plane of the lower cone 503, so that the square block 404 can easily cross over the lower cone 503 under the operation of the mounting mechanism 500 which continuously moves upwards in cooperation with the guiding inclined plane 405, after the square block 404 crosses over the lower cone 503, the monitoring mechanism is pulled downwards, so that the mounting mechanism 500 moves downwards, at this time, the inclined plane of the lower cone 503 is abutted against the top plane of the square block 404, further, at this time, because the upper cone 502 and the lower cone 503 are in a fit state, a cylinder with inclined planes both above and below is formed, at this time, the mounting mechanism 500 which moves downwards quickly can enable the square block 404 to continuously cross over the cylinder formed by the upper cone 502 and the lower cone 503, that is, the mounting mechanism 500 is disengaged from the detection housing 100 at this time, i.e., the monitoring mechanism and the detection mechanism are separated from each other.

With continued reference to fig. 1-2, in the preferred embodiment of the present invention, the detecting mechanism comprises a detecting housing 100 fixedly mounted on a mounting plate 300, the mounting plate 300 has a mounting hole 301, so that the detecting mechanism can be mounted on the ceiling of the building construction by using a screw matched with the mounting hole 301.

Further, one side of the detection shell 100 is provided with an air inlet window 101, and an air inlet fan 102 is arranged in the air inlet window 101; the air exhaust window 106 is arranged on the other side of the detection shell 100, the exhaust fan 103 is arranged in the exhaust window 106, and air outside the alarm is guided through the mutual matching of the air inlet fan 102 and the exhaust fan 103, so that air flow can rapidly enter the detection shell 100, and whether smoke exists in the air or not can be detected timely by using the smoke alarm 104.

Further, as shown in fig. 1, fig. 4 and fig. 5, in the embodiment of the present invention, the monitoring mechanism further includes a protective shell 204 matched with the detection housing 100, when the mounting mechanism 500 extends into the detection housing 100, the protective shell 204 is sleeved on the detection housing 100, and the side wall of the protective shell 204 is further provided with a vent hole 203, so that when the monitoring mechanism is mounted on the detection mechanism, air fluidity inside the alarm is ensured.

Further, please refer to fig. 4, in the embodiment of the present invention, a storage battery 700 and an intelligent controller 800 are further respectively disposed in the monitoring housing 200, the storage battery 700 is used for supplying power to the power consumption component in the monitoring mechanism, a control signal input end of the intelligent controller 800 is electrically connected to the smoke alarm 104, a control signal output end of the intelligent controller 800 is electrically connected to the driving motor 601, when the smoke alarm 104 detects the existence of smoke, the intelligent controller 800 is triggered to control the driving motor 601 to start, and the driving motor 601 drives the monitoring housing 200 to rotate, so as to adjust the orientation of the camera 600, so that a real-time image can be provided for the remote terminal.

Further, in the embodiment of the present invention, the intelligent controller 800 is further configured to obtain a real-time picture of the camera 600, and send the real-time picture to the remote terminal. Preferably, the remote terminal may be a mobile phone, a computer, or the like, and is not limited specifically.

Further, in the embodiment of the present invention, the monitoring mechanism further includes an induced draft fan 900 disposed at the bottom of the monitoring housing 200, the monitoring mechanism further includes a heat dissipation mesh 201 and an air intake net 202 disposed at the bottom of the monitoring housing 200, the induced draft fan 900 corresponds to the air intake net 202, and by the mutual cooperation of the heat dissipation mesh 201, the air intake net 202 and the induced draft fan 900, the air flow rate in the monitoring housing 200 can be increased, so as to dissipate heat of the camera 600, the storage battery 700 and the intelligent controller 800.

Further, as shown in fig. 1 and 4, in the embodiment of the present invention, the mounting post 501 has a limiting channel 504, a limiting guide 302 matching with the limiting channel 504 is fixedly mounted in the detection housing 100, and when the mounting mechanism 500 extends into the detection housing 100 through the mounting channel 105, the limiting guide 302 extends into the limiting channel 504.

It will be appreciated that when the stop guide 302 extends into the stop channel 504, the stop guide 302 is a square rod, so that the mounting mechanism 500 will not rotate, and thus the monitoring housing 200 can be more stable when driven to rotate by the driving motor 601.

According to the scheme provided by the specific embodiment, the alarm provided by the invention can independently realize the quick connection between the monitoring mechanism and the detection mechanism, is convenient to install and use and has the advantage of convenience in use.

The above embodiments are merely illustrative of a preferred embodiment, but not limiting. When the invention is implemented, appropriate replacement and/or modification can be carried out according to the requirements of users. The number of apparatuses and the scale of the process described herein are intended to simplify the description of the present invention. Applications, modifications and variations of the present invention will be apparent to those skilled in the art.

While embodiments of the invention have been disclosed above, it is not intended to be limited to the uses set forth in the specification and examples. It can be applied to all kinds of fields suitable for the present invention. Additional modifications will readily occur to those skilled in the art. It is therefore intended that the invention not be limited to the exact details and illustrations described and illustrated herein, but fall within the scope of the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides an alarm for fire safety based on thing networking which characterized in that, the alarm includes:

the detection mechanism comprises a ventilation assembly arranged on the detection shell, and the detection mechanism further comprises a plurality of smoke alarms arranged in the detection shell; the detection mechanism also comprises a limit support piece arranged in the detection shell;

the monitoring mechanism is fixedly arranged on a camera on one side of the monitoring shell, and the orientation of the camera is adjusted through a driving motor; monitoring mechanism still include with spacing support piece matched with installation mechanism, installation mechanism rotates the dress on the control shell, stretches into installation mechanism in the detection shell carries out spacing fixedly through spacing support piece.

2. The alarm for fire safety based on the internet of things as claimed in claim 1, wherein the mounting mechanism comprises a mounting column rotatably connected with the monitoring shell, an upper cone is fixedly mounted at the end of the mounting column, a lower cone is slidably sleeved on the mounting column, and a fixed support ring for limiting the stroke of the lower cone is further arranged on the mounting column; the inclined surface of the upper cone faces upwards, and the inclined surface of the lower cone faces downwards.

3. The alarm is used to fire safety based on thing networking of claim 2, characterized in that, spacing support piece includes the solid fixed cylinder of fixed mounting in detecting the shell, be provided with the rectangle slider through supporting spring support slip in the solid fixed cylinder, fixed mounting has square piece on the rectangle slider.

4. The alarm for fire safety based on the internet of things as claimed in claim 3, wherein the square block has a downward-facing guiding slope at the end, and when the supporting spring is in an unstressed state, the supporting spring pushes the square block to move to the guiding slope to abut against a mounting mechanism.

5. The alarm for fire safety based on internet of things as claimed in claim 2, 3 or 4, wherein the bottom of the detection shell is provided with a mounting channel matched with a mounting mechanism, and the mounting mechanism extends into the detection shell through the mounting channel.

6. The alarm is used to fire safety based on thing networking of claim 2 or 3 or 4, characterized in that, one side of the detection shell has an air inlet window, there is an air inlet machine in the air inlet window; and an exhaust window is arranged on the other side of the detection shell, and an exhaust fan is arranged in the exhaust window.

7. The alarm is used to fire safety based on thing networking of claim 4, characterized in that, monitoring mechanism still include with detect shell matched with protecting crust, when installation mechanism stretches into and detects the shell in, on the detecting crust was located to the protecting crust cover, still had the ventilation hole on the lateral wall of protecting crust.

8. The alarm is used to fire safety based on thing networking of claim 7, characterized in that still is provided with battery and intelligent control ware in the control shell respectively, the battery is used for supplying ground to the power consumption part in the monitoring mechanism, the control signal input of intelligent control ware and smoke alarm ware electric connection, the control signal output and the driving motor electric connection of intelligent control ware.

9. The alarm is used to fire safety based on thing networking of claim 8, characterized in that, monitoring mechanism still includes the draught fan of setting in control shell bottom, monitoring mechanism still includes the heat dissipation mesh and the air inlet net of seting up in control shell bottom, the draught fan with the air inlet net is corresponding.

10. The alarm is used to fire safety based on thing networking of claim 4 or 7 or 8, characterized in that, spacing passageway has on the erection column, fixed mounting has with spacing guide arm of spacing passageway matched with in the detection shell, when installation mechanism stretches into through the installation passageway in the detection shell, spacing guide arm stretches into in the spacing passageway.

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