CN117543814A - Multi-shunt power supply intelligent switch management method of indoor distribution system - Google Patents

Abstract

The invention discloses a multi-branch power intelligent switch management method of an indoor distribution system, wherein a power intelligent switch is configured at an alternating current distribution end of the indoor distribution system, and the multi-branch power intelligent switch management method comprises the following steps: s1, detecting whether setting of necessary parameters of a power intelligent switch is completed; s2, calculating the utilization index of the back-end wireless equipment, sorting the utilization index from large to small, and selecting the back-end wireless equipment sorted in front of a preset rank to be started in the daytime or in a business time period. According to the tidal effect of the indoor distribution scene people flow and the traffic, the intelligent switch is configured to take the energy-saving measure of remote hard turn-off, and the remote control is realized by sending the message to the intelligent switch through the remote centralized monitoring server platform, so that the energy-saving effect is greatly improved, the labor cost is saved, in addition, the on/off control function of the switch is realized, and meanwhile, the automatic address allocation function is realized, so that the intelligent switch is simple, convenient and efficient.

Description

Multi-shunt power supply intelligent switch management method of indoor distribution system

Technical Field

The invention belongs to the technical field of indoor distribution systems, and relates to a multi-branch power supply intelligent switch management method of an indoor distribution system.

Background

For iron tower companies and telecom operators, indoor distribution systems are required to be deployed in large space areas such as convention centers, stadiums, large commercial complexes and the like so as to solve the problems of network coverage and capacity requirements. In indoor distribution systems like public communication networks, because network equipment adopts alternating current power supply nearby, an alternating current ammeter and a power distribution switch are required to be installed at a power taking end. The indoor distribution sites are numerous, and the remote meter reading of the electric meters at the installation points of the indoor distribution system equipment is realized by adopting a technical means.

In addition, part of indoor distribution systems also need to configure intelligent switches to take energy-saving measures of remote hard turn-off according to tidal effects of indoor distribution scene people flow and traffic. For places such as a convention center and an indoor gym, the gathering convention activities or sports events do not occur every day, and on days of non-convention or no sports events, the states of '0' people flow and '0' traffic are basically the states, so that the demand for network services is very low, and more flexible network energy saving management needs to be implemented.

Disclosure of Invention

The invention aims to provide the intelligent switch management method for the multi-branch power supply of the indoor distribution system, which realizes the power supply control of the indoor distribution system without manual station-up operation, thereby greatly improving the energy-saving effect and saving the labor cost.

In order to achieve the above purpose, the basic scheme of the invention is as follows: the intelligent switch management method of the multi-branch power supply of the indoor distribution system comprises the steps that at an alternating-current distribution end of the indoor distribution system, intelligent switches of the power supply are configured in a one-to-one correspondence mode according to the number of wireless devices at the rear end, the intelligent switches of the power supply are connected with a monitoring unit, and the monitoring unit is connected with a remote centralized monitoring server platform;

the intelligent switch management method of the multi-shunt power supply comprises the following steps:

s1, detecting whether the setting of the necessary parameters of the intelligent power switch is completed, if not, rejecting the connection with a remote centralized monitoring server platform by a monitoring unit, and continuously detecting whether the setting of the necessary parameters of the intelligent power switch is completed; if the setting is completed, executing step S2;

s2, according to indoor distribution scenes, people flow and traffic data, a remote centralized monitoring server platform calculates utilization indexes of rear-end wireless devices of an indoor distribution system, sorts the utilization indexes from large to small, and selects the rear-end wireless devices sorted in front of a preset rank to be started in the daytime or in a business time period;

for the back-end wireless devices which are sequenced after the preset ranking, when the residence time of a person in the working radiation range exceeds the preset time T1, closing a power intelligent switch, and enabling the back-end wireless devices to work; after the personnel leave the preset time T2, the power supply intelligent switch is turned off.

The working principle and the beneficial effects of the basic scheme are as follows: according to the technical scheme, according to tidal effects of indoor distribution scene people flow and traffic, an intelligent switch is configured to take energy-saving measures of remote hard turn-off. At the AC distribution end of the indoor distribution system of the public communication network, the intelligent power switch is configured one to one according to the number of the rear-end wireless devices, and functions of remote networking communication, electricity metering, on-off control, equipment network access and renting management and the like are integrated. Calculating the utilization index of the equipment, selecting part of the equipment to be started at a specific time, saving energy and ensuring smooth operation of the system. The power supply intelligent switch is started when the preset time T1 and T2 are set to ensure that the personnel use, and meanwhile, the power supply intelligent switch is cut off in time after the personnel leave, so that the use and energy-saving requirements are met, and the operation is flexible. In addition, the automatic address allocation function is realized while the on/off control function of the switch is realized, and the method is simple, convenient and efficient.

Further, the necessary parameters include a communication address, user allocation information, and network load allocation information.

Setting the necessary parameters of the intelligent power switch is beneficial to controlling the intelligent power switch. Under the condition that setting of the necessary parameters is not completed, the communication gateway and the monitoring unit refuse to access to the remote centralized monitoring platform in a networking mode, so that field installation and debugging quality is controlled, and construction cost is saved.

Further, when the power intelligent switch is turned on, the method further comprises an address setting step, specifically one of the following modes:

mode one:

the intelligent switch of the power supply to be turned on sequentially displays and indicates;

operating a key switch configured by the intelligent switch for displaying the power supply to be turned on to enter an address configuration mode;

the monitoring unit checks the communication address allocation condition of each power intelligent switch and allocates a communication address for each power intelligent switch;

after the communication address allocation is completed, carrying out configuration modes of other parameters on the intelligent power switch;

mode two:

the remote centralized monitoring server platform sends an address configuration instruction to the intelligent power switch to be turned on;

entering an address configuration mode, and checking communication address allocation conditions of all the power intelligent switches by a monitoring unit to allocate an address for each power intelligent switch;

after the communication address allocation is completed, the power intelligent switch is subjected to a configuration mode of other parameters.

Addresses are allocated to the power intelligent switches, so that one-to-one management of the power intelligent switches is realized.

Further, the monitoring unit allocates addresses to each power supply intelligent switch according to the order from small to large or according to the principle that the addresses are not repeatedly allocated in the allocatable address table.

The monitoring unit distributes addresses for the intelligent power switch according to a set mode, is simple to operate, can be automatically implemented, can be manually matched and implemented, and improves applicability.

Further, each power intelligent switch is provided with a display device for displaying the communication address of the power intelligent switch;

based on the communication address of the power intelligent switch, the terminal is used for connecting the monitoring unit, and the real-time operation parameters of the corresponding power intelligent switch are obtained.

The display equipment is selected according to the requirement to display the communication address of the intelligent switch of the power supply, so that the staff can acquire corresponding information, and management is facilitated.

Further, the method for calculating the utilization index of the back-end wireless device of the indoor distribution system is as follows:

where i is the serial number of the communication device, θ _i For the utilization index of the ith communication equipment, S _i For the working radiation area of the ith communication equipment in the room, S _s For standard radiating area of communication equipment in room, N _i For radiating traffic in 24 hours in range for the ith communication device, N _e Total people flow in 24 hours of the indoor scene; e (E) _i For the day average data volume in one month when the ith communication device is started, the day average data volume comprises the sum of uplink data and downlink data; t is t _i For the number of balance connections within one month when the ith communication device is turned on.

And calculating the utilization index of the corresponding equipment so as to judge the importance of the equipment and facilitate the subsequent energy-saving regulation and control.

Drawings

Fig. 1 is a schematic diagram of a multi-shunt power intelligent switch management method of an indoor distribution system.

Detailed Description

Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the invention.

In the description of the present invention, it should be understood that the terms "longitudinal," "transverse," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present invention and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present invention.

In the description of the present invention, unless otherwise specified and defined, it should be noted that the terms "mounted," "connected," and "coupled" are to be construed broadly, and may be, for example, mechanical or electrical, or may be in communication with each other between two elements, directly or indirectly through intermediaries, as would be understood by those skilled in the art, in view of the specific meaning of the terms described above.

The invention discloses a multi-branch power intelligent switch management method of an indoor distribution system, as shown in figure 1, power intelligent switches are configured at an alternating current distribution end of the indoor distribution system according to the number of rear-end wireless devices in a one-to-one correspondence manner, and are electrically connected with a monitoring unit, and the monitoring unit is electrically connected with a remote centralized monitoring server platform;

the intelligent switch management method of the multi-branch power supply comprises the following steps:

s1, detecting whether the setting of the necessary parameters of the intelligent power switch is completed, if not, rejecting the connection with a remote centralized monitoring server platform by a monitoring unit, and continuously detecting whether the setting of the necessary parameters of the intelligent power switch is completed; if the setting is completed, executing step S2; the necessary parameters include communication address, user allocation information, and network load allocation information.

In the energy consumption management scene of the multi-branch power supply intelligent switch of the communication carrier base station and the indoor distribution system, because the unattended operation is relatively scattered, the monitoring unit can require on-site personnel to set the necessary parameters (such as RS485 address, user definition, network definition and the like) appointed by each branch switch in the process of initializing configuration debugging, and under the condition that the setting of the necessary parameters is not completed, the communication gateway and the monitoring unit refuse to access to the remote centralized monitoring platform in a networking way, so that the on-site installation and debugging quality is managed and controlled, and the construction cost is saved.

S2, according to indoor distribution scenes, people flow and traffic data, a remote centralized monitoring server platform calculates utilization indexes of rear-end wireless devices of an indoor distribution system, sorts the utilization indexes from large to small, and selects the rear-end wireless devices sorted in front of a preset rank to be started in the daytime or in a business time period;

for the back-end wireless devices which are sequenced after the preset ranking, when the residence time of a person in the working radiation range exceeds the preset time T1, closing a power intelligent switch, and enabling the back-end wireless devices to work; after the personnel leave the preset time T2, the power supply intelligent switch is turned off.

According to the technical scheme, at an alternating-current power distribution end of an indoor distribution system of a public communication network, power intelligent switches are configured one to one according to the number of rear-end wireless devices, and functions of remote networking communication, electricity metering, on-off control, equipment network access and renting management and the like are integrated. Calculating the utilization index of the equipment, selecting part of the equipment to be started at a specific time, saving energy and ensuring smooth operation of the system. The power supply intelligent switch is started when the preset time T1 and T2 are set to ensure that the personnel use, and meanwhile, the power supply intelligent switch is cut off in time after the personnel leave, so that the use and energy-saving requirements are met, and the operation is flexible.

In a preferred scheme of the invention, when the intelligent power switch is turned on, the method further comprises an address setting step, and specifically comprises one of the following modes:

mode one:

the intelligent switch of the power supply to be turned on sequentially performs display indication (such as display by a display screen or an indicator light);

the intelligent power switch to be turned on is displayed, and a key switch configured by the intelligent power switch is manually operated to enter an address configuration mode;

the monitoring unit checks the communication address allocation condition of each power intelligent switch and allocates a communication address for each power intelligent switch;

after the communication address allocation is completed, carrying out configuration modes of other parameters on the intelligent power switch;

mode two:

the remote centralized monitoring server platform sends an address configuration instruction to the intelligent power switch to be turned on;

entering an address configuration mode, and checking communication address allocation conditions of all the power intelligent switches by a monitoring unit to allocate an address for each power intelligent switch;

after the communication address allocation is completed, the power intelligent switch is subjected to a configuration mode of other parameters.

Addresses are allocated to the power intelligent switches, so that one-to-one management of the power intelligent switches is realized.

More preferably, the monitoring unit allocates addresses to each power intelligent switch according to the order of addresses from small to large or according to the principle that addresses are not repeatedly allocated in the allocatable address table. The monitoring unit distributes addresses for the intelligent power switch according to a set mode, and the operation is simple.

In a preferred embodiment of the present invention, each power intelligent switch is configured with a display device, such as an LCD liquid crystal display, an LED nixie tube, or a set of address indicator lights, for displaying the communication address of the power intelligent switch;

based on the communication address of the power intelligent switch, the terminal is used for connecting the monitoring unit, and the real-time operation parameters of the corresponding power intelligent switch are obtained.

The display equipment is selected according to the requirement to display the communication address of the intelligent switch of the power supply, so that the staff can acquire corresponding information, and management is facilitated. If the shunt switch is configured as an LED nixie tube or a group of indicator lamps, besides the address for displaying the shunt switch correspondingly, the nixie tube or the indicator lamps can also indicate other parameters which are agreed corresponding to the shunt switch by setting different combinations of lighting time periods and intervals (such as 12S for one period, lighting 1S for RS485 addresses, lighting 3S for user definition, lighting 5S for network definition, and lighting 1S for each interval).

In a preferred embodiment of the present invention, the method for calculating the utilization index of the back-end wireless device of the indoor distribution system is as follows:

where i is the serial number of the communication device, θ _i For the utilization index of the ith communication equipment, S _i For the working radiation area of the ith communication equipment in the room, S _s For standard radiating area of communication equipment in room, N _i For radiating traffic in 24 hours in range for the ith communication device, N _e Total people flow in 24 hours of the indoor scene; e (E) _i For the day average data volume in one month when the ith communication device is started, the day average data volume comprises the sum of uplink data and downlink data; t is t _i For the number of balance connections within one month when the ith communication device is turned on.

And calculating the utilization index of the corresponding equipment so as to judge the importance of the equipment and facilitate the subsequent energy-saving regulation and control.

The invention also provides a multi-branch power intelligent switch management system of the indoor distribution system based on the method, which is shown in figure 1 and comprises a power intelligent switch, a monitoring unit and a remote centralized monitoring server platform, wherein the power intelligent switch is electrically connected with the monitoring unit, and the monitoring unit is electrically connected with the remote centralized monitoring server platform. By using the system, energy-saving management of system power consumption is realized through management of the intelligent power switch.

In a preferred scheme of the invention, the power intelligent switch is connected with the monitoring unit through the northbound RS485 address bus, and the monitoring unit is electrically connected with the remote centralized monitoring server platform through a wireless data transmission module (such as 4G wireless data transmission) or an optical fiber networking. The connection structure is simple, and the information transmission is convenient. In each power intelligent switch, a key signal switch can be configured, so that the on/off control function of a manual switch is realized, and the automatic allocation function of an initialized RS485 address is realized.

The intelligent power switch is connected to the monitoring unit through the RS485, and the key switch is pressed in a set mode (such as single pressing of the switch, or continuous twice pressing of the switch, or long pressing of the switch for a plurality of times) to apply for entering an address configuration mode, at this time, the monitoring unit checks the address allocation condition on the RS485 bus, and allocates an RS485 communication address to the shunt switch according to the address sequence from small to large or according to the principle that addresses are not repeatedly allocated in an allocable address table.

After the distribution of the RS485 address is completed, the shunt power supply intelligent switch enters the configuration mode of other parameters through the monitoring unit, including but not limited to user definition, network definition, overvoltage and undervoltage setting, overcurrent setting, overtemperature setting and the like.

In a preferred embodiment of the present invention, each power intelligent switch is configured with an LCD liquid crystal display, an LED nixie tube, or a set of address indicator lights for displaying the communication address of the power intelligent switch.

Based on the low-cost principle and the field application convenience principle, after the monitoring unit finishes address setting of each power intelligent switch, the RS485 address of the shunt switch is clearly displayed through an LCD (liquid crystal display) screen, an LED nixie tube or a group of address indicator lamps configured by each power intelligent switch, so that the state of completing address allocation of the shunt switch is conveniently confirmed, and the subsequent maintenance and operation of field personnel are facilitated.

Based on the displayed address of each shunt switch, the on-site operation and maintenance personnel can be connected with the monitoring unit through an upper computer, a mobile phone APP and the like to correspondingly display the real-time operation parameters of each shunt switch, or each user or each network.

In the description of the present specification, a description referring to terms "one embodiment," "some embodiments," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the present invention have been shown and described, it will be understood by those of ordinary skill in the art that: many changes, modifications, substitutions and variations may be made to the embodiments without departing from the spirit and principles of the invention, the scope of which is defined by the claims and their equivalents.

Claims (6)

1. The intelligent switch management method for the multi-branch power supply of the indoor distribution system is characterized in that intelligent switches of the power supply are configured at an alternating-current distribution end of the indoor distribution system in a one-to-one correspondence mode according to the number of wireless devices at the rear end, the intelligent switches of the power supply are connected with a monitoring unit, and the monitoring unit is connected with a remote centralized monitoring server platform;

the intelligent switch management method of the multi-shunt power supply comprises the following steps:

s1, detecting whether the setting of the necessary parameters of the intelligent power switch is completed, if not, rejecting the connection with a remote centralized monitoring server platform by a monitoring unit, and continuously detecting whether the setting of the necessary parameters of the intelligent power switch is completed; if the setting is completed, executing step S2;

s2, according to indoor distribution scenes, people flow and traffic data, a remote centralized monitoring server platform calculates utilization indexes of rear-end wireless devices of an indoor distribution system, sorts the utilization indexes from large to small, and selects the rear-end wireless devices sorted in front of a preset rank to be started in the daytime or in a business time period;

for the back-end wireless devices which are sequenced after the preset ranking, when the residence time of a person in the working radiation range exceeds the preset time T1, closing a power intelligent switch, and enabling the back-end wireless devices to work; after the personnel leave the preset time T2, the power supply intelligent switch is turned off.

2. The method for intelligent switch management of multiple branch power supply of indoor distribution system according to claim 1, wherein the necessary parameters include communication address, user allocation information and network load allocation information.

3. The method for managing the intelligent switch of the multi-branch power supply of the indoor distribution system according to claim 2, wherein when the intelligent switch of the power supply is turned on, the method further comprises an address setting step, in which one of the following modes is adopted:

mode one:

the intelligent switch of the power supply to be turned on sequentially displays and indicates;

operating a key switch configured by the intelligent switch for displaying the power supply to be turned on to enter an address configuration mode;

the monitoring unit checks the communication address allocation condition of each power intelligent switch and allocates a communication address for each power intelligent switch;

after the communication address allocation is completed, carrying out configuration modes of other parameters on the intelligent power switch;

mode two:

the remote centralized monitoring server platform sends an address configuration instruction to the intelligent power switch to be turned on;

entering an address configuration mode, and checking communication address allocation conditions of all the power intelligent switches by a monitoring unit to allocate an address for each power intelligent switch;

after the communication address allocation is completed, the power intelligent switch is subjected to a configuration mode of other parameters.

4. The intelligent switch management method for multiple branch power supplies of indoor distribution system according to claim 3, wherein the monitoring unit allocates addresses to each intelligent switch of power supplies according to the order of addresses from small to large or according to the principle that addresses are not repeatedly allocated in the allocatable address table.

5. A multi-branch power intelligent switch management method of an indoor distribution system according to claim 3, wherein each power intelligent switch is provided with a display means for displaying a communication address of the power intelligent switch;

based on the communication address of the power intelligent switch, the terminal is used for connecting the monitoring unit, and the real-time operation parameters of the corresponding power intelligent switch are obtained.

6. The intelligent switch management method for multiple branch power supplies of indoor distribution system according to claim 1, wherein the method for calculating the utilization index of the back-end wireless device of indoor distribution system is as follows:

where i is the serial number of the communication device, θ _i For the utilization index of the ith communication equipment, S _i For the working radiation area of the ith communication equipment in the room, S _s For standard radiating area of communication equipment in room, N _i For radiating traffic in 24 hours in range for the ith communication device, N _e Total people flow in 24 hours of the indoor scene; e (E) _i For the day average data volume in one month when the ith communication device is started, the day average data volume comprises the sum of uplink data and downlink data; t is t _i For the number of balance connections within one month when the ith communication device is turned on.