CN215891735U - Building environment automatic monitoring system - Google Patents

Abstract

The invention discloses an automatic building environment monitoring system, which relates to the field of intelligent buildings and comprises a monitoring device arranged on a building and a sliding plate arranged on the building, wherein a camera is connected on the sliding plate in a sliding manner, the camera is connected with the sliding plate in a sliding manner along the length direction of the sliding plate, and the building is provided with a sliding mechanism for driving the camera to slide. The purpose of clearly shooting the building position can be achieved.

Description

Building environment automatic monitoring system

Technical Field

The invention relates to the technical field of intelligent buildings, in particular to an automatic building environment monitoring system.

Background

With the development of information technology, building automatic monitoring systems are receiving more and more attention, and have been developed from single-function monitoring to multi-type simultaneous monitoring.

The related technology can refer to the Chinese utility model patent with the publication number of CN203745896U, and discloses a building automation monitoring system, which comprises a plurality of groups of cameras and modulators connected in sequence; the modulator is connected to the mixer; the output end of the mixer is connected with an optical transmitter; the optical transmitter-receiver is matched with the optical transmitter-receiver; the optical receiving terminal is connected to the control center through a demodulator; a strain device is arranged behind the multiple groups of cameras; the strain device comprises a power supply detection device, a pyroelectric switch, an auxiliary power supply and a miniature camera; the input end of the power supply detection device is electrically connected with a power supply line of the camera; the output end of the power supply detection device is electrically connected to the auxiliary power supply after being connected with the pyroelectric switch in parallel; the auxiliary power supply is electrically connected with the micro camera.

In view of the above-described related art, the inventors consider that the following drawbacks exist: in practical applications, the position of the camera is usually fixed, and for some images far away, the camera cannot clearly shoot.

SUMMERY OF THE UTILITY MODEL

In order to realize the purpose of clearly shooting the building position, the application provides a building environment automatic monitoring system.

The utility model provides a building environment automatic monitoring system, is including installing in the monitoring device of building to and including installing the slide on building, sliding connection has the camera on the slide, the length direction and the slide sliding connection of slide are followed to the camera, the building is equipped with and is used for driving the gliding sliding mechanism of camera.

Through adopting above-mentioned technical scheme, the building is in the control process, and through the slip of slide mechanism drive camera, realize carrying out the purpose monitored to the building through the slip of camera on the slide to the realization is to the clear purpose of shooing in building position.

Optionally, slide mechanism includes the lead screw, the lead screw extends the setting along the length direction of slide, the lead screw rotates with the slide to be connected, the building is provided with the motor, the motor is with the coaxial fixed connection of lead screw, mount pad and lead screw threaded connection are passed through to the bottom of camera, mount pad and camera fixed connection.

Through adopting above-mentioned technical scheme, the motor starts the back, can drive the lead screw and rotate, can drive the mount pad when the lead screw rotates and slide, realizes driving the gliding purpose of camera through the slip of mount pad, slides the purpose of in-process to building position clear shooting at the camera.

Optionally, one surface of the mounting seat, which is close to the sliding plate, is rotatably connected with a pulley, sliding grooves are respectively formed in two sides of the sliding plate, the sliding grooves are formed in the length direction of the sliding plate, and the pulley is located in the sliding grooves.

Through adopting above-mentioned technical scheme, when the mount pad slided under the drive of lead screw, the pulley was located the spout, through the roll of pulley in the spout, can realize the spacing purpose of mount pad to improve the stability when the mount pad slided, and then improve the camera and can be more steady at the slip process.

Optionally, the top of building has the limiting plate through bolted connection, the limiting plate level sets up, the limiting groove has been seted up along its length direction to the limiting plate, the up end fixedly connected with gag lever post of mount pad, the one end that the mount pad was kept away from to the gag lever post is located the limiting groove, the gag lever post is to the slip along the groove of limiting groove.

Through adopting above-mentioned technical scheme, the mount pad when sliding, send and with the gag lever post that sets up on the spacing groove that sets up on the building, the gag lever post slides along with the slip synchronization of mount pad in the spacing inslot, realizes the further spacing purpose of mount pad, the stationarity when improving the mount pad and sliding.

Optionally, one end of the limiting rod, which is far away from the mounting seat, is provided with a limiting ball, and the limiting ball is located in the limiting groove.

Through adopting above-mentioned technical scheme, spacing ball is located the spacing inslot, and when the mount pad was in the slip, spacing ball set up the possibility that can reduce gag lever post and spacing groove and break away from to stability when improving the gag lever post and sliding.

Optionally, the monitoring device includes a sensing component, a comparing component and a control component;

the sensing assembly is used for sensing a temperature value, a humidity value and an illumination intensity value in the building; and outputting an induction signal;

the comparison assembly is electrically connected to the signal output end of the sensing assembly and used for receiving the sensing signal, when the sensing signal is received, the comparison assembly is used for comparing whether the temperature value in the building is higher than a preset temperature value, whether the comparison humidity value is higher than a preset humidity value and whether the illumination intensity value is higher than a preset illumination value, and when the judgment result is yes, the comparison assembly outputs a control signal;

and the control component is electrically connected with the signal output end of the comparison component and used for receiving the control signal, and outputting a driving signal when receiving the control signal and used for controlling the action of the control system.

Through adopting above-mentioned technical scheme, respond to temperature, humidity and illumination intensity in the building through the response subassembly, will sense signal output to the comparison subassembly, the comparison subassembly is judged the sensing signal, if the voltage value that the sensing signal corresponds is greater than the default, then output control signal to control assembly, adjust temperature, humidity and illumination intensity in the building through control assembly to keep the environment in the building to be in and let the comfortable state of people.

Optionally, the sensing assembly includes a first sensing device, a second sensing device, and a third sensing device:

the first sensing device comprises a temperature sensor and a second sensing device, wherein the temperature sensor is used for sensing a temperature value in a building and outputting a first sensing signal;

the second sensing device comprises a humidity sensor and is used for sensing a humidity value in the building and outputting a second sensing signal;

the third sensing device comprises an illumination intensity sensor and is used for sensing an illumination intensity value in the building and outputting a third sensing signal;

the comparison component comprises a first comparison device, a second comparison device and a third comparison device:

the first comparison device comprises a first comparator, is electrically connected to the signal output end of the first sensing device and is used for receiving a first sensing signal, when the first sensing signal is received, the first comparison device compares whether a pressure value corresponding to the first sensing signal is larger than a preset temperature value or not, and if yes, outputs a first control signal;

the second comparison device comprises a second comparator, is electrically connected to the signal output end of the second sensing device and is used for receiving a second sensing signal, comparing whether the pressure value corresponding to the second sensing signal is greater than the preset humidity value or not when the second sensing signal is received, and outputting a second control signal if the pressure value corresponding to the second sensing signal is greater than the preset humidity value;

the third comparison device comprises a third comparator, the third comparator is electrically connected to the signal output end of the third sensing device and is used for receiving a third sensing signal, when the third sensing signal is received, the third comparator compares whether a pressure value corresponding to the third sensing signal is larger than a preset illumination intensity value or not, and if yes, a third control signal is output;

the control assembly comprises a first control device, a second control device and a third control device;

the first control device comprises an air conditioner controller, is electrically connected to the signal output end of the first comparison device and is used for receiving a first control signal and controlling the air conditioner controller to act when receiving the first control signal;

the second control device comprises a humidity controller which is electrically connected with the signal output end of the second comparison device and is used for receiving a second control signal and controlling the humidity controller to act when receiving the second control signal;

and the third control device comprises an illumination intensity controller which is electrically connected with the signal output end of the third comparison device and is used for receiving a third control signal and controlling the illumination intensity controller to act when receiving the third control signal.

Through adopting above-mentioned technical scheme, through temperature in the temperature sensor response building, humidity in the humidity sensor response building, illumination intensity in the illumination intensity sensor response building, the relation between the voltage value that rethread comparison component comparison received sensing signal corresponds and the default, if be greater than the default, then the environment in the control module regulation building.

Optionally, the monitoring device further includes an alarm component, the alarm component is electrically connected to the signal output end of the control component, and is configured to receive the driving signal, and output an alarm signal when receiving the driving signal.

By adopting the technical scheme, when the control group is used for adjusting the environment in the building, the alarm assembly outputs the alarm signal, and the alarm signal is used for reminding people in the building of abnormal environment and adjusting the environment.

In summary, the present application has at least one of the following beneficial technical effects:

1. in the monitoring process of the building, the sliding mechanism drives the camera to slide, and the aim of monitoring the building is fulfilled by the sliding of the camera on the sliding plate, so that the aim of clearly shooting the position of the building is fulfilled;

2. after the motor starts, can drive the lead screw and rotate, can drive the mount pad when the lead screw rotates and slide, realize driving the gliding purpose of camera through the slip of mount pad, the purpose of the clear shooting in-process of camera slip to building position.

Drawings

Fig. 1 is a schematic overall structure diagram of an embodiment of the present application.

FIG. 2 is a sectional view showing the position relationship between the stop lever and the stop ball according to the embodiment of the present application.

FIG. 3 is a cross-sectional view showing the positional relationship between the pulley and the groove according to the embodiment of the present application.

FIG. 4 is a block diagram of a highlight sensing component, a comparison component, and a control component according to an embodiment of the present application.

Description of reference numerals:

1. a slide plate; 11. a chute; 2. a motor; 21. a lead screw; 3. a mounting seat; 31. a pulley; 32. a limiting rod; 33. a limiting ball; 34. a limiting groove; 341. a limiting plate; 35. a camera; 4. an inductive component; 41. a first sensing device; 42. a second sensing device; 43. a third inductive device; 5. a comparison component; 51. a first comparing device; 52. a second comparison device; 53. a third comparison device; 6. a control component; 61. a first control device; 62. a second control device; 63. a third control device; 7. and an alarm component.

Detailed Description

The present application is described in further detail below with reference to the accompanying drawings.

The embodiment of the application discloses an automatic monitoring system for building environment.

Referring to fig. 1, an automatic monitoring system for building environment comprises a monitoring device installed on a building and a sliding plate 1 installed on the building, wherein the sliding plate 1 is horizontally arranged, two ends of the sliding plate 1 respectively extend to two sides of the building, the sliding plate 1 is fixedly connected with the building, a camera 35 is arranged on the sliding plate 1, and the monitoring purpose is achieved by shooting under the condition of the camera 35 in the building.

Referring to fig. 1, the camera 35 is slidably connected to the slide board 1 along the longitudinal direction of the slide board 1, and the building is provided with a sliding mechanism for driving the camera 35 to slide. The camera 35 is driven to slide through the sliding mechanism, so that the purpose of monitoring the building is achieved, and the purpose of clearly shooting the position of the building is achieved.

Referring to fig. 1 and 2, drive slide mechanism and include motor 2, motor 2's base and the side fixed connection of building, motor 2's output shaft fixedly connected with lead screw 21, lead screw 21 level sets up, lead screw 21 is located the top of slide 1, lead screw 21 rotates with slide 1 to be connected, slide 1's top is equipped with mount pad 3, mount pad 3 and lead screw 21 threaded connection, mount pad 3 and slide 1 sliding connection, camera 35 is located the one side that slide 1 was kept away from to mount pad 3. The motor 2 is used for starting the driving screw 21 to rotate, the screw 21 drives the mounting seat 3 to slide when rotating, the mounting seat 3 slides to drive the camera 35 to slide synchronously, and the purpose of clearly shooting the building position is achieved.

Referring to fig. 2 and 3, a sliding groove 11 is formed in one side of the sliding plate 1, which is close to the mounting seat 3, a groove direction of the sliding groove 11 is consistent with a length direction of the sliding plate 1, a pulley 31 is rotatably connected to the bottom end of the mounting seat 3, the pulley 31 is located in the sliding groove 11, when the mounting seat 3 slides, the pulley 31 rolls in the sliding groove 11, friction between the mounting seat 3 and the sliding plate 1 can be reduced, meanwhile, when the mounting seat 3 slides, the pulley 31 and the sliding groove 11 are used, the mounting seat 3 can be limited, so that the camera 35 is limited, stability when the camera 35 shoots is improved, and possibility of shaking is reduced.

Referring to fig. 2 and 3, the one side that slide 1 was kept away from to mount pad 3 has set firmly gag lever post 32, the vertical setting of gag lever post 32, and gag lever post 32 is located the both sides of mount pad 3, spacing groove 34 has been seted up on the top of building, the groove of spacing groove 34 is to unanimous with the groove of spout 11, the one end that mount pad 3 was kept away from to gag lever post 32 is located spacing groove 34, gag lever post 32 slides in spacing groove 34, drive gag lever post 32 synchronous sliding when mount pad 3 slides, the realization is with mount pad 3 further spacing purpose.

Referring to fig. 2 and 3, the one side that spacing groove 34 is close to mount pad 3 is equipped with limiting plate 341, the equal level of two limiting plate 341 sets up, and two limiting plate 341 extend the setting to the one side that is close to each other, through the setting of two limiting plate 341, can reduce the notch of spacing groove 34, the one end that mount pad 3 was kept away from to gag lever post 32 is equipped with spacing ball 33, spacing ball 33 and gag lever post 32 fixed connection, spacing ball 33 is located spacing groove 34, can further reduce the possibility that gag lever post 32 and spacing groove 34 break away from through spacing ball 33, stability when improving mount pad 3 and slide.

Referring to fig. 4, the monitoring device comprises a sensing component 4, a comparing component 5, a control component 6 and an alarm component 7;

the sensing component 4 is used for sensing a temperature value, a humidity value and an illumination intensity value in a building and outputting a sensing signal;

the comparison component 5 is electrically connected to the signal output end of the sensing component 4 and used for receiving the sensing signal, comparing whether the temperature value in the building is higher than the preset temperature value, the comparison humidity value is higher than the preset humidity value and the comparison illumination intensity value is higher than the preset illumination value when the sensing signal is received, and outputting a control signal when the judgment result is yes;

the control component 6 is electrically connected to the signal output end of the comparison component 5 and used for receiving a control signal, and outputting a driving signal for controlling the action of a control system when receiving the control signal;

and the alarm component 7 is electrically connected with the signal output end of the control component 6 and used for receiving the driving signal and outputting an alarm signal when receiving the driving signal. Wherein, the alarm component 7 comprises a buzzer, and when receiving the driving signal, the buzzer is electrified to send out alarm sound.

Wherein, the sensing component 4 includes:

a first sensing device 41 including a temperature sensor for sensing a temperature value in the building and outputting a first sensing signal;

a second sensing device 42 including a humidity sensor for sensing a humidity value in the building and outputting a second sensing signal;

the third sensing device 43, which includes an illumination intensity sensor, is used for sensing an illumination intensity value in the building and outputting a third sensing signal.

The comparison component 5 comprises:

the first comparison device 51 comprises a first comparator, electrically connected to the signal output end of the first sensing device, and configured to receive the first sensing signal, compare whether a pressure value corresponding to the first sensing signal is greater than a preset temperature value when the first sensing signal is received, and output a first control signal if the pressure value is judged to be greater than the preset temperature value;

the second comparing device 52, including a second comparator, is electrically connected to the signal output end of the second sensing device 42, and is configured to receive the second sensing signal, compare whether a pressure value corresponding to the second sensing signal is greater than the preset humidity value when the second sensing signal is received, and output a second control signal if the pressure value is judged to be greater than the preset humidity value;

the third comparing device 53, which includes a third comparator, is electrically connected to the signal output end of the third sensing device 43, and is configured to receive the third sensing signal, compare whether a pressure value corresponding to the third sensing signal is greater than the preset illumination intensity value when the third sensing signal is received, and output a third control signal if the third sensing signal is judged to be greater than the preset illumination intensity value.

The control assembly 6 comprises:

the first control device 61 comprises an air conditioner controller, is electrically connected to the signal output end of the first comparison device 51, and is used for receiving a first control signal and controlling the action of the air conditioner controller when receiving the first control signal;

a second control device 62, including a humidity controller, electrically connected to the signal output terminal of the second comparison device 52, for receiving the second control signal, and controlling the humidity controller to operate when receiving the second control signal;

the third control device 63 includes a light intensity controller, electrically connected to the signal output terminal of the third comparing device 53, for receiving the third control signal, and controlling the light intensity controller to operate when receiving the third control signal.

The temperature in the building is adjusted through the air conditioner controller, the humidity in the building is adjusted through the humidity controller, and the illumination that the illumination intensity controller gathers the building is slightly controlled to keep the environment in the building in a comfortable range.

The implementation principle of the building environment automatic monitoring system in the embodiment of the application is as follows: through the slip of camera 35, the realization carries out the purpose of clear shooting to the position in the building, simultaneously, can adjust temperature, humidity and illumination intensity in the building through air conditioner controller, humidity controller and illumination intensity controller for environment in the building keeps letting the comfortable state of people.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a building environment automatic monitoring system which characterized in that: including installing in the monitoring device of building to and including installing slide (1) on the building, sliding connection has camera (35) on slide (1), the length direction and slide (1) sliding connection of slide (1) are followed in camera (35), the building is equipped with and is used for driving the gliding sliding mechanism of camera (35).

2. The automatic building environment monitoring system of claim 1, wherein: slide mechanism includes lead screw (21), the length direction of slide (1) is followed to lead screw (21) extends the setting, lead screw (21) rotates with slide (1) and is connected, the building is provided with motor (2), motor (2) and the coaxial fixed connection of lead screw (21), mount pad (3) and lead screw (21) threaded connection are passed through to the bottom of camera (35), mount pad (3) and camera (35) fixed connection.

3. The automatic building environment monitoring system of claim 2, wherein: one surface of the mounting seat (3) close to the sliding plate (1) is rotatably connected with a pulley (31), sliding grooves (11) are formed in two sides of the sliding plate (1) respectively, the sliding grooves (11) are formed in the length direction of the sliding plate (1), and the pulley (31) is located in the sliding grooves (11).

4. The automatic building environment monitoring system of claim 2, wherein: the building limiting device is characterized in that the top end of the building is connected with a limiting plate (341) through a bolt, the limiting plate (341) is horizontally arranged, a limiting groove (34) is formed in the limiting plate (341) along the length direction of the limiting plate, a limiting rod (32) is fixedly connected to the upper end face of the mounting seat (3), one end, far away from the mounting seat (3), of the limiting rod (32) is located in the limiting groove (34), and the limiting rod (32) slides along the groove of the limiting groove (34).

5. The building environment automatic monitoring system according to claim 4, characterized in that: one end of the limiting rod (32) far away from the mounting seat (3) is provided with a limiting ball (33), and the limiting ball (33) is located in a limiting groove (34).

6. The automatic building environment monitoring system of claim 1, wherein: the monitoring device comprises a sensing component (4), a comparison component (5) and a control component (6);

the sensing assembly (4) is used for sensing a temperature value, a humidity value and an illumination intensity value in a building; and outputting an induction signal;

the comparison component (5) is electrically connected to the signal output end of the sensing component (4) and is used for receiving the sensing signal, comparing whether the temperature value in the building is higher than a preset temperature value, the humidity value is higher than a preset humidity value and the illumination intensity value is higher than a preset illumination value when the sensing signal is received, and outputting a control signal when the judgment result is yes;

and the control component (6) is electrically connected to the signal output end of the comparison component (5) and is used for receiving the control signal, and outputting a driving signal for controlling the action of the control system when receiving the control signal.

7. The building environment automatic monitoring system of claim 6, wherein: the inductive component (4) comprises a first inductive device (41), a second inductive device (42) and a third inductive device (43):

a first sensing device (41) including a temperature sensor for sensing a temperature value in the building and outputting a first sensing signal;

a second sensing device (42) comprising a humidity sensor for sensing a humidity value in the building and outputting a second sensing signal;

a third sensing device (43) comprising an illumination intensity sensor for sensing an illumination intensity value in the building and outputting a third sensing signal;

the comparison assembly (5) comprises a first comparison device (51), a second comparison device (52) and a third comparison device (53):

the first comparison device (51) comprises a first comparator, is electrically connected to the signal output end of the first sensing device (41) and is used for receiving the first sensing signal, comparing whether the pressure value corresponding to the first sensing signal is larger than a preset temperature value or not when the first sensing signal is received, and outputting a first control signal if the pressure value is judged to be larger than the preset temperature value;

the second comparison device (52) comprises a second comparator, is electrically connected to the signal output end of the second sensing device (42) and is used for receiving a second sensing signal, comparing whether the pressure value corresponding to the second sensing signal is larger than the preset humidity value or not when the second sensing signal is received, and outputting a second control signal if the pressure value is judged to be larger than the preset humidity value;

the third comparison device (53) comprises a third comparator, is electrically connected to the signal output end of the third sensing device (43) and is used for receiving a third sensing signal, comparing whether a pressure value corresponding to the third sensing signal is larger than a preset illumination intensity value or not when the third sensing signal is received, and outputting a third control signal if the third sensing signal is judged to be larger than the preset illumination intensity value;

the control assembly (6) comprises a first control means (61), a second control means (62) and a third control means (63);

the first control device (61) comprises an air conditioner controller, is electrically connected to the signal output end of the first comparison device (51), is used for receiving a first control signal, and controls the action of the air conditioner controller when receiving the first control signal;

the second control device (62) comprises a humidity controller, is electrically connected with the signal output end of the second comparison device (52), and is used for receiving a second control signal and controlling the humidity controller to act when receiving the second control signal;

and the third control device (63) comprises an illumination intensity controller which is electrically connected with the signal output end of the third comparison device (53) and is used for receiving a third control signal and controlling the illumination intensity controller to act when receiving the third control signal.

8. The building environment automatic monitoring system of claim 6, wherein: the monitoring device further comprises an alarm component (7), wherein the alarm component (7) is electrically connected to the signal output end of the control component (6) and used for receiving the driving signal, and when the driving signal is received, the alarm component outputs an alarm signal.

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