CN215419739U - Building intelligent power supply monitoring control system - Google Patents

Abstract

The utility model discloses a building intelligent power supply monitoring control system, which comprises an illumination control unit, an air conditioner control unit, a power distribution cabinet unit and a centralized control platform, wherein the power distribution cabinet unit is used for providing electric energy for the illumination power supply unit and the air conditioner control unit and collecting the power consumption; the air conditioner control unit comprises an air conditioner electric control box and a plurality of air control valves and pressure regulating valves which are electrically connected with the air conditioner electric control box, the air control valves and the pressure regulating valves are both electric control valves, the air control valves are used for regulating air inlet flow, and the pressure regulating valves are used for regulating water path flow; the air conditioner electric cabinet is wirelessly connected with the centralized control platform. The utility model provides an intelligent building power supply monitoring control system which can independently collect and monitor the power consumption for building illumination and the power consumption for air conditioning.

Description

Building intelligent power supply monitoring control system

Technical Field

The utility model relates to the technical field of building control systems, in particular to a building intelligent power supply monitoring control system.

Background

The building control system mainly comprises an air conditioning unit, a power transformation and distribution unit, a lighting unit and the like, all electromechanical equipment is centrally managed and monitored through the whole set of building automatic control system, a built-in optimized control program and a preset time program in the whole building range, comprehensive energy conservation is realized on the premise of meeting the control requirement, the control function of the controller replaces the work of daily operation and maintenance, and the equipment out of control or equipment damage caused by the working errors of maintenance personnel is reduced. However, the existing building control system has a problem that independent collection and monitoring of the lighting power consumption and the air conditioning unit power consumption in the whole building range cannot be realized, so that subsequent energy-saving design can be performed according to the lighting power consumption and the air conditioning unit power consumption in each time period.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a building intelligent power supply monitoring control system which can independently collect and monitor the building lighting power consumption and the air conditioner power consumption.

In order to achieve the purpose, the utility model provides the following technical scheme: a building intelligent power supply monitoring control system comprises an illumination control unit, an air conditioner control unit, a power distribution cabinet unit and a centralized control platform, wherein the power distribution cabinet unit is used for respectively providing electric energy for the illumination power supply unit and the air conditioner control unit and independently collecting power consumption;

the air conditioner control unit comprises an air conditioner electric control box and a plurality of air control valves and pressure regulating valves which are electrically connected with the air conditioner electric control box, the air control valves and the pressure regulating valves are both electric control valves, the air control valves are used for regulating air inlet flow, and the pressure regulating valves are used for regulating water path flow; the air-conditioning electric control box is wirelessly connected with the centralized control platform and is used for enabling the centralized control platform to remotely send control signals to the air-conditioning electric control box.

Preferably, the power distribution cabinet unit comprises an illumination power supply end and an air conditioner power supply end which are mutually independent, a first electric quantity interface, a first output voltage interface and a first output current interface are led out from the illumination power supply end, and a second electric quantity interface, a second output voltage interface and a second output current interface are led out from the air conditioner power supply end.

Preferably, a first switch fault tripping interface and a first running state interface are led out from the lighting power supply end, and a second switch fault tripping interface and a second running state interface are led out from the air conditioner power supply end.

Preferably, the first power consumption interface, the first output voltage interface, the first output current interface, the first switch fault tripping interface, the first operation state interface, the second power consumption interface, the second output voltage interface, the second output current interface, the second switch fault tripping interface, and the second operation state interface are electrically connected to the centralized control platform and are respectively used for monitoring the power consumption, the power supply voltage, the power supply current, the fault state, and the operation state of the lighting control unit and the air conditioner control unit.

Preferably, the air conditioner control unit is including installing temperature sensor and the humidity transducer on the air conditioner pipeline, temperature sensor is used for gathering return air temperature, humidity transducer is used for gathering return air humidity.

Preferably, the air conditioner control unit comprises a pressure alarm installed on an air conditioner pipeline, and the pressure alarm is used for detecting the pressure difference value on two sides of the air conditioner filter screen.

Preferably, the pressure alarm comprises a plurality of pressure difference transmitters distributed at different positions of the air conditioner filter screen, the pressure difference transmitters are electrically connected with the pressure alarm and used for transmitting the collected pressure difference signals to the pressure alarm, and the pressure alarm is electrically connected with the air conditioner electric cabinet.

Preferably, the illumination control unit comprises a manual switch group and an automatic switch group, the manual switch group is used for controlling the on-off of the power supply loop of the office area illuminating lamp, and the automatic switch group is used for controlling the on-off of the power supply loop of the corridor area illuminating lamp.

Preferably, the manual switch group comprises an office regional layer control switch and a plurality of regional switches connected in series with the office regional layer control switch.

Preferably, the automatic switch group includes light sense normally closed switch and the sound control switch of mutual series connection, the acoustic control switch disposes first threshold value, works as when the acoustic control switch detects that the sound decibel is greater than first threshold value, the acoustic control switch is closed, the light sense normally closed switch disposes the second threshold value, works as when the light sense normally closed switch detects that light luminance is greater than the second threshold value, the light sense normally closed switch disconnection.

Compared with the prior art, the utility model has the beneficial effects that:

the building intelligent power supply monitoring control system comprises a power distribution cabinet unit, wherein the power distribution cabinet unit is used for respectively providing electric energy for an illumination power supply unit and an air conditioner control unit and independently collecting the power consumption, and is electrically connected with a centralized control platform, so that the collected data can be transmitted to the centralized control platform for monitoring, and the independent collection and monitoring of the illumination power consumption and the air conditioner unit power consumption in the whole building range are realized; and only a plurality of air control valves and pressure regulating valves electrically connected with the air-conditioning electric control box are arranged, and the air-conditioning electric control box is wirelessly connected with the centralized control platform, so that the function of remotely controlling the opening degrees of the air control valves and the pressure regulating valves by the centralized control platform is realized.

The air conditioner control unit comprises a temperature sensor and a humidity sensor which are arranged on an air conditioner pipeline, wherein the temperature sensor is used for collecting return air temperature, and the humidity sensor is used for collecting return air humidity, so that the return air temperature and the return air humidity of the air conditioner unit are monitored; the air conditioner control unit also comprises a pressure alarm arranged on an air conditioner pipeline, the pressure alarm is used for detecting the pressure difference value of two sides of the air conditioner filter screen, and can send an alarm signal to the centralized control platform when the pressure difference value of two sides of the filter screen is too large.

The illumination control unit comprises a manual switch group and an automatic switch group, wherein the manual switch group is used for controlling the on-off of a power supply loop of an illumination lamp in an office area, and the automatic switch group is used for controlling the on-off of a power supply loop of an illumination lamp in a corridor area; the manual switch group comprises office regional layer control switches and a plurality of regional switches connected with the office regional layer control switches in series, so that the illumination lamps of the whole floor of the office regional switches can be uniformly controlled, and the condition that the illumination lamps in certain regions are not turned off and extra electric energy loss is generated can be avoided;

the automatic switch group comprises a light sensation normally closed switch and a sound control switch which are connected in series, the sound control switch is provided with a first threshold, when the sound control switch detects that the sound decibel is greater than the first threshold, the sound control switch is closed, the light sensation normally closed switch is provided with a second threshold, and when the light sensation normally closed switch detects that the light brightness is greater than the second threshold, the light sensation normally closed switch is opened; therefore, the automatic control of the illumination of the corridor area can be realized, the automatic switch group can be opened only under the condition of dark light on the premise of opening, and the electric energy can be effectively saved.

Drawings

FIG. 1 is a schematic diagram of a connection box of an intelligent building power supply monitoring control system according to the present invention;

FIG. 2 is a schematic connection diagram of a lighting control unit in the building intelligent power supply monitoring control system according to the present invention;

FIG. 3 is a schematic connection diagram of a hollow controller unit in the building intelligent power supply monitoring control system according to the present invention;

fig. 4 is a schematic connection diagram of power distribution cabinet units in the building intelligent power supply monitoring control system according to the present invention.

In the figure: 1. a power distribution cabinet unit; 11. an illumination power supply terminal; 1101. a first power interface; 1102. a first output voltage interface; 1103. a first output current interface; 1104. a first switch fault trip interface; 1105. a first operating state interface; 12. an air conditioner power supply terminal; 1201. a second electric quantity interface; 1202. a second output voltage interface; 1203. a second output current interface; 1204. a second switch fault trip interface; 1205. a second operating state interface; 2. a manual switch group; 201. office area layer control switches; 202. an area switch; 3. an automatic switch group; 301. a light-sensitive normally closed switch; 302. a voice-operated switch; 4. a pneumatic control valve; 5. a pressure regulating valve; 6. a temperature sensor; 7. a humidity sensor; 8. a pressure alarm; 9. an air-conditioning electric cabinet.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1, a first embodiment provided by the present invention is a building intelligent power supply monitoring control system, which includes an illumination control unit, an air conditioner control unit, a power distribution cabinet unit 1 and a centralized control platform, where the power distribution cabinet unit 1 is used to provide electric energy to the illumination power supply unit and the air conditioner control unit respectively and collect the power consumption independently, and the power distribution cabinet unit 1 is electrically connected to the centralized control platform and used for data interaction; the power distribution cabinet unit 1 is arranged to provide electric energy for the lighting power supply unit and the air conditioner control unit respectively and independently collect power consumption, the power distribution cabinet unit 1 is electrically connected with the centralized control platform, collected data can be transmitted to the centralized control platform to be monitored, and basis is provided for energy-saving design of subsequent whole buildings.

As shown in fig. 1 and fig. 2, the lighting control unit includes a manual switch group 2 and an automatic switch group 3, the manual switch group 2 is used for controlling on/off of a power supply circuit of an office area lighting lamp, and the automatic switch group 3 is used for controlling on/off of a power supply circuit of a corridor area lighting lamp; the control of the illumination lamps in office areas and the control of the illumination lamps in corridor areas are separated and controlled independently;

the manual switch group 2 comprises an office regional layer control switch 201 and a plurality of regional switches 202 which are connected with the office regional layer control switch 201 in series, so that the illumination lamps of the whole floor of the office regional switch 202 can be uniformly controlled, and the condition that the illumination lamps of certain regions are not turned off and extra electric energy loss is generated can be avoided;

the automatic switch group 3 comprises a light sense normally closed switch 301 and a sound control switch 302 which are connected in series, the sound control switch 302 is configured with a first threshold, when the sound control switch 302 detects that the sound decibel is greater than the first threshold, the sound control switch 302 is closed, the light sense normally closed switch 301 is configured with a second threshold, and when the light sense normally closed switch 301 detects that the light brightness is greater than the second threshold, the light sense normally closed switch 301 is opened; from this can realize the automatic control of the regional illumination of corridor, just can open under the darker condition of light when automatic switch group 3 opens the prerequisite, when light was darker, light sense normally closed switch 301 did not move, keeps the closure state, and this is real if detect when the sound decibel is greater than first threshold value, and acoustic control switch 302 is closed, just can put through corridor lighting lamp control circuit smoothly from this, can effectively save the electric energy.

As shown in fig. 1 and 3, the air-conditioning control unit includes an air-conditioning electric cabinet 9, and a plurality of air control valves 4 and a pressure regulating valve 5 electrically connected to the air-conditioning electric cabinet 9, wherein the air control valves 4 and the pressure regulating valve 5 both adopt electric control valves, the air control valves 4 are used for regulating the flow of intake air, and the pressure regulating valve 5 is used for regulating the flow of a water path; the air-conditioning electric control box 9 is wirelessly connected with the centralized control platform and is used for enabling the centralized control platform to remotely send a control signal to the air-conditioning electric control box 9; the function that the opening degrees of the wind control valve 4 and the pressure regulating valve 5 can be remotely controlled by the centralized control platform is realized.

Preferably, the air conditioner control unit is including installing temperature sensor 6 and humidity transducer 7 on the air conditioner pipeline, temperature sensor 6 is used for gathering return air temperature, humidity transducer 7 is used for gathering return air humidity, just temperature sensor 6 and humidity transducer 7 all with air conditioner electric cabinet 9 electricity is connected for the return air temperature and the return air humidity information transfer that gather for air conditioner electric cabinet 9, monitoring to centralized control platform via air conditioner electric cabinet 9 wireless transmission.

Preferably, the air conditioner control unit comprises a pressure alarm 8 arranged on an air conditioner pipeline, and the pressure alarm 8 is used for detecting the pressure difference value on two sides of the air conditioner filter screen; the pressure alarm 8 comprises a plurality of pressure difference transmitters distributed at different positions of an air conditioner filter screen, the pressure difference transmitters are connected in parallel and then connected in series with the pressure alarm 8, and are used for transmitting pressure difference signals acquired by the pressure alarm 8 to the pressure alarm 8, and the pressure alarm 8 is electrically connected with the air conditioner electric cabinet 9; because a plurality of the pressure difference signal transmitters are connected in parallel and then connected in series with the pressure alarm 8, when one pressure difference signal transmitter arranged at any position of the air conditioner filter screen detects that the pressure at two sides of the air conditioner filter screen is greater than a preset value, the pressure alarm 8 sends an alarm signal to the centralized control platform, and the condition that any part of the air conditioner filter screen is blocked seriously can be detected.

As shown in fig. 1 and 4, the power distribution cabinet unit 1 includes an illumination power supply terminal 11 and an air conditioner power supply terminal 12 that are independent of each other, a first power interface 1101, a first output voltage interface 1102 and a first output current interface 1103 are led out from the illumination power supply terminal 11, and a second power interface 1201, a second output voltage interface 1202 and a second output current interface 1203 are led out from the air conditioner power supply terminal 12; a first switch fault tripping interface 1104 and a first running state interface 1105 are led out from the lighting power supply end 11, and a second switch fault tripping interface 1204 and a second running state interface 1205 are led out from the air-conditioning power supply end 12; the first power consumption interface 1101, the first output voltage interface 1102, the first output current interface 1103, the first switch fault trip interface 1104, the first operation state interface 1105, the second power consumption interface 1201, the second output voltage interface 1202, the second output current interface 1203, the second switch fault trip interface 1204, and the second operation state interface 1205 are all electrically connected to the centralized control platform, and are respectively used for monitoring power consumption, power supply voltage, power supply current, fault state, and operation state of the lighting control unit and the air conditioning control unit.

A detection element or a detection circuit matched with the power consumption interface, the voltage interface, the output current interface, the switch fault tripping interface and the running state interface is arranged in the power distribution cabinet unit 1, the power consumption can be detected through an ammeter, the power supply voltage can be detected through a voltmeter, the power supply current can be detected through an ammeter, the running state can be represented by detecting whether the running switch is in a closed state or not, and a switch fault tripping signal can be detected through a fault tripping detection assembly; the fault tripping detection assembly comprises a relay coil connected in series on a main power supply circuit, and then a normally closed contact of the relay coil and a normally open contact which represents the starting of the running state are connected in series to a first fault tripping interface and a second fault tripping interface.

The working principle is as follows: the building intelligent power supply monitoring control system comprises a power distribution cabinet unit 1, wherein the power distribution cabinet unit 1 is used for respectively providing electric energy for an illumination power supply unit and an air conditioner control unit and independently collecting power consumption, and the power distribution cabinet unit 1 is electrically connected with a centralized control platform and can transmit collected data to the centralized control platform for monitoring, so that independent collection and monitoring of illumination power consumption and air conditioner unit power consumption in the whole building range are realized; the air-conditioning electric control box 9 is wirelessly connected with the centralized control platform, so that the function of remotely controlling the opening degrees of the air-conditioning valve 4 and the pressure regulating valve 5 by the centralized control platform is realized; the temperature sensor 6 and the humidity sensor 7 are arranged on the air conditioning pipeline, the temperature sensor 6 is used for collecting the return air temperature, and the humidity sensor 7 is used for collecting the return air humidity, so that the return air temperature and the return air humidity of the air conditioning unit can be monitored; the air conditioner control unit also comprises a pressure alarm 8 arranged on an air conditioner pipeline, the pressure alarm 8 is used for detecting the pressure difference value of two sides of the air conditioner filter screen, and can send an alarm signal to the centralized control platform when the pressure difference value of two sides of the filter screen is too large; the illumination control unit comprises a manual switch group 2 and an automatic switch group 3, wherein the manual switch group 2 is used for controlling the on-off of a power supply loop of an office area illumination lamp, and the automatic switch group 3 is used for controlling the on-off of a power supply loop of a corridor area illumination lamp; the manual switch group 2 comprises an office regional layer control switch 201 and a plurality of regional switches 202 connected with the office regional layer control switch 201 in series, so that the illumination lamps of the whole floor of the office regional switch 202 can be uniformly controlled, and the condition that the illumination lamps in certain regions are not turned off and extra electric energy loss is generated can be avoided; the automatic switch group 3 comprises a light-sensitive normally closed switch 301 and a sound-controlled switch 302 which are connected in series, the sound-controlled switch 302 is configured with a first threshold, when the sound-controlled switch 302 detects that the sound decibel is greater than the first threshold, the sound-controlled switch 302 is closed, the light-sensitive normally closed switch 301 is configured with a second threshold, and when the light-sensitive normally closed switch 301 detects that the light brightness is greater than the second threshold, the light-sensitive normally closed switch 301 is opened; from this can realize the regional automatic control of illumination of corridor, just can open under the darker condition of light when automatic switch group 3 opens the prerequisite, can effectively save the electric energy.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (10)

1. The building intelligent power supply monitoring control system is characterized by comprising an illumination control unit, an air conditioner control unit, a power distribution cabinet unit (1) and a centralized control platform, wherein the power distribution cabinet unit (1) is used for respectively providing electric energy for the illumination control unit and the air conditioner control unit and independently collecting the power consumption, and the power distribution cabinet unit (1) is electrically connected with the centralized control platform and used for data interaction;

the air conditioner control unit comprises an air conditioner electric control box (9) and a plurality of air control valves (4) and pressure regulating valves (5) which are electrically connected with the air conditioner electric control box (9), the air control valves (4) and the pressure regulating valves (5) are both electric control valves, the air control valves (4) are used for regulating air inlet flow, and the pressure regulating valves (5) are used for regulating water path flow; the air-conditioning electric control box (9) is in wireless connection with the centralized control platform and is used for enabling the centralized control platform to remotely send control signals to the air-conditioning electric control box (9).

2. The building intelligent power supply monitoring control system of claim 1, wherein: the power distribution cabinet unit (1) comprises an illumination power supply end (11) and an air conditioner power supply end (12) which are mutually independent, a first electric quantity interface (1101), a first output voltage interface (1102) and a first output current interface (1103) are led out from the illumination power supply end (11), and a second electric quantity interface (1201), a second output voltage interface (1202) and a second output current interface (1203) are led out from the air conditioner power supply end (12).

3. The building intelligent power supply monitoring control system of claim 2, wherein: a first switch fault tripping interface (1104) and a first running state interface (1105) are led out from the lighting power supply end (11), and a second switch fault tripping interface (1204) and a second running state interface (1205) are led out from the air conditioner power supply end (12).

4. The building intelligent power supply monitoring control system of claim 3, wherein: the first power consumption interface (1101), the first output voltage interface (1102), the first output current interface (1103), the first switch fault trip interface (1104), the first operation state interface (1105) and the second power consumption interface (1201), the second output voltage interface (1202), the second output current interface (1203), the second switch fault trip interface (1204) and the second operation state interface (1205) are all electrically connected with the centralized control platform and are respectively used for monitoring the power consumption, the power supply voltage, the power supply current, the fault state and the operation state of the lighting control unit and the air conditioner control unit.

5. The building intelligent power supply monitoring control system of claim 1, wherein: the air conditioner control unit comprises a temperature sensor (6) and a humidity sensor (7) which are installed on an air conditioner pipeline, wherein the temperature sensor (6) is used for collecting the temperature of return air, and the humidity sensor (7) is used for collecting the humidity of the return air.

6. The building intelligent power supply monitoring control system of claim 5, wherein: the air conditioner control unit comprises a pressure alarm (8) installed on an air conditioner pipeline, and the pressure alarm (8) is used for detecting the pressure difference value of two sides of an air conditioner filter screen.

7. The building intelligent power supply monitoring control system of claim 6, wherein: the pressure alarm (8) comprises a plurality of pressure difference signal transmitters distributed at different positions of an air conditioner filter screen, the pressure difference signal transmitters are electrically connected with the pressure alarm (8) and used for transmitting pressure difference signals acquired by the pressure alarm to the pressure alarm (8), and the pressure alarm (8) is electrically connected with an air conditioner electric cabinet (9).

8. The building intelligent power supply monitoring control system of claim 1, wherein: the illumination control unit comprises a manual switch group (2) and an automatic switch group (3), the manual switch group (2) is used for controlling the on-off of a power supply loop of an office area illuminating lamp, and the automatic switch group (3) is used for controlling the on-off of a power supply loop of a corridor area illuminating lamp.

9. The building intelligent power supply monitoring control system of claim 8, wherein: the manual switch group (2) comprises office regional layer control switches (201) and a plurality of regional switches (202) which are connected with the office regional layer control switches (201) in series.

10. A building intelligent power supply monitoring control system as claimed in claim 8 or 9, wherein: automatic switch group (3) are including light sense normally closed switch (301) and sound control switch (302) of mutual series connection, sound control switch (302) dispose first threshold value, work as sound control switch (302) detect when the sound decibel is greater than first threshold value, sound control switch (302) are closed, light sense normally closed switch (301) dispose the second threshold value, work as light sense normally closed switch (301) detect when light luminance is greater than the second threshold value, light sense normally closed switch (301) disconnection.

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