WO2017000104A1 - Energy-saving control method, apparatus and system for station device - Google Patents

Abstract

Provided are an energy-saving control method, apparatus and system for a station device. An energy-saving management system receives operation state information about a base station main device reported by a station controller and operation state information about a companion device related to the base station main device in a station device; the energy-saving management system acquires a first energy-saving control parameter for the base station main device and acquires a second energy-saving control parameter for the companion device according to the operation state information about the base station main device and/or the operation state information about the companion device; and the energy-saving management system sends the first energy-saving control parameter and the second energy-saving control parameter to the station controller.

Description

Energy-saving control method, device and system for site equipment Technical field

The embodiments of the present invention relate to the field of communications, and in particular, to a method, an apparatus, and a system for controlling energy saving of a site device.

Background technique

In the communication network, the site equipment in the equipment room includes the base station main equipment, ventilation/cooling equipment, and power supply equipment. The power consumption of the site equipment has always been a hot spot in the communication field. How to reduce the energy consumption of the site equipment and improve the energy efficiency of the entire wireless network has begun to be mentioned by the operators on the agenda.

Among them, the power consumption of the base station main equipment and the ventilation/cooling equipment accounts for about 95% of the total power consumption of the entire station equipment. Generally, the power consumption of the base station main equipment is slightly higher than that of the ventilation/cooling equipment. In recent years, base station energy-saving technologies have made great progress. For example, high-efficiency RF power amplifiers, high-integration baseband processing chips, and software energy-saving management applications are maturing, and the power consumption of base station main equipment can be reduced to several hundred watts, and capacity. And the performance has also been significantly improved, greatly improving the energy efficiency of the base station's main equipment.

At present, there are several power consumption reduction solutions in the power reduction technology of the site equipment, such as room temperature heating and battery single point temperature control. However, these energy-reducing solutions are independent of each other and have no correlation with each other. As a result, the power consumption of the base station main equipment and the supporting equipment in the site equipment is not significantly reduced, and the power consumption of the station equipment cannot be greatly reduced. The power consumption of equipment and ancillary equipment still accounts for a large proportion of the energy consumption of the entire site equipment. Therefore, it is still necessary to reduce the energy consumption of the wireless network, but how to reduce the energy consumption of the site equipment still has no excellent solution.

Summary of the invention

Embodiments of the present invention provide a method, a device, and a system for controlling energy saving of a site device, which can reduce energy consumption of the site device.

In a first aspect, an embodiment of the present invention provides a method for controlling energy saving of a site device, including:

The energy-saving management system receives the running state information of the base station master device reported by the site controller and the running state information of the accessory device associated with the base station master device in the site device;

The energy-saving management system acquires a first energy-saving control parameter for the base station master device according to the operating state information of the base station master device and/or the running state information of the accessory device, and the matching The device acquires the second energy saving control parameter;

The energy saving management system transmits the first energy saving control parameter and the second energy saving control parameter to the site controller.

With reference to the first aspect, in a first possible implementation manner of the first aspect, the operating state information of the base station master device includes: a power saving state of the base station master device, where the power saving state of the base station master device includes: The base station master device turns on or off the energy saving mode;

The operation status information of the accessory device includes: a backup energy state of the accessory device and a power saving state of the accessory device, and the energy-saving state of the accessory device includes: the accessory device turning on or off the energy-saving mode;

The energy-saving management system acquires a first energy-saving control parameter for the base station master device and a second energy-saving control parameter for the accessory device, according to the running state information of the base station master device and/or the running state information of the accessory device. ,include:

When the energy-saving management system determines that the base station master device is in the power-saving mode according to the operating state information of the base station master device, the energy-saving management system determines whether the standby energy state of the accessory device meets the preset first condition. If the backup energy state of the accessory device does not meet the first condition, the energy-saving management system acquires, for the base station master device, a first energy-saving control parameter that needs to extend the service time of the base station master device, If the backup energy state of the accessory device does not meet the first condition and the accessory device turns off the energy-saving mode, the energy-saving management system acquires a second energy-saving control parameter that changes the energy-saving state for the accessory device;

When the energy-saving management system determines that the base station master device is in the energy-saving mode according to the operating state information of the base station master device, the energy-saving management system determines whether the standby power state of the accessory device meets the preset second condition. If the backup energy state of the accessory device meets the second condition, the energy-saving management system acquires, for the base station master device, a first energy-saving control parameter that changes a power-saving state, and if the backup device has the backup energy When the state meets the second condition and the accessory device turns on the energy-saving mode, the energy-saving management system acquires the second energy-saving control parameter that changes the energy-saving state for the accessory device.

With reference to the first aspect, in a second possible implementation manner of the first aspect, the operating state information of the base station master device includes: a power saving state of the base station master device, where the power saving state of the base station master device includes: The base station master device turns on or off the energy saving mode;

The running status information of the accessory device includes: an energy saving state of the accessory device, and the accessory The energy-saving state of the device includes: the accessory device turns the energy-saving mode on or off;

The energy-saving management system acquires a first energy-saving control parameter for the base station master device and a second energy-saving control parameter for the accessory device, according to the running state information of the base station master device and/or the running state information of the accessory device. ,include:

When the energy-saving management system determines that the base station master device is in the energy-saving mode according to the operating state information of the base station master device, if the accessory device starts the energy-saving mode, the energy-saving management system acquires the energy-saving change for the accessory device. a second energy saving control parameter of the state;

When the energy-saving management system determines that the base station master device is in the energy-saving mode according to the operating state information of the base station master device, if the accessory device turns off the energy-saving mode, the energy-saving management system obtains the energy-saving change for the accessory device. The second energy saving control parameter of the state.

With reference to the first aspect, in a third possible implementation manner of the first aspect, the supporting device includes: a ventilation device, a cooling device, and a power device;

The operating status information of the accessory device includes: an outdoor temperature of the power device and the equipment room where the base station is located, and an indoor working environment temperature of the power device;

The energy-saving management system acquires a first energy-saving control parameter for the base station master device and a second energy-saving control parameter for the accessory device, according to the running state information of the base station master device and/or the running state information of the accessory device. ,include:

When the indoor working environment temperature of the power supply device is higher than a preset temperature threshold, and the outdoor temperature is lower than the indoor working environment temperature, the energy saving management system acquires and operates the ventilation device to extract an outdoor cold air lowering station. a second energy-saving control parameter for the indoor working environment temperature;

When the indoor working environment temperature of the power supply device is higher than a preset temperature threshold, and the outdoor temperature is higher than the indoor working environment temperature, the energy saving management system acquires and operates the refrigeration device to reduce the indoor working environment The second energy saving control parameter of the temperature.

With reference to the first aspect, in a fourth possible implementation manner of the first aspect, the energy-saving management system receives, by the site controller, operation state information of the base station master device and related to the base station master device in the site device. After the running status information of the accessory device, the method further includes:

If the running status information of the base station master device includes the traffic volume carried by the base station primary device, the energy saving management system obtains energy saving indication information according to the traffic volume carried by the base station primary device and the preset energy saving policy, where the energy saving The indication information includes: the energy saving management system determines whether the base station master device is allowed to enable or disable the energy saving mode;

The energy-saving management system sends the energy-saving indication information to the site controller, and the site controller sends the energy-saving indication information to the base station master device.

With reference to the first aspect, in a fifth possible implementation manner of the first aspect, the energy-saving management system receives the running state information of the base station master device reported by the site controller and the running of the accessory device related to the base station master device After the status information, the method further includes:

If the running status information of the base station master device includes power consumption information of the base station master device, and the running state information of the accessory device includes power consumption information of the accessory device, the energy saving management system visualizes the presentation by using a chart Decoding power consumption information of the base station master device and power consumption information of the accessory device;

The energy-saving management system obtains an energy-saving effect according to the power consumption information of the base station master device and the power consumption information of the accessory device, and presents the energy-saving effect through a chart visualization.

In a second aspect, an embodiment of the present invention provides a method for controlling energy saving of a site device, including:

The site controller acquires running state information of the base station master device, and acquires running state information of the accessory device related to the base station master device in the site device;

The site controller reports the running state information of the base station master device and the running state information of the accessory device to the energy saving management system;

The site controller receives the first energy-saving control parameter and the second energy-saving control parameter sent by the energy-saving management system, where the first energy-saving control parameter is the operating state information of the energy-saving management system according to the base station master device And the operating state information of the accessory device is obtained by the base station master device, and the second energy saving control parameter is that the energy saving management system is configured according to the operating state information of the base station master device and/or the accessory device. The running status information is obtained by the accessory device;

The site controller sends the first energy saving control parameter to the base station master device, and sends the second power saving control parameter to the accessory device.

With reference to the second aspect, in a first possible implementation manner of the second aspect, the site controller acquires the running state information of the base station master device, and acquires the accessory device related to the base station master device in the site device. Operation status information, including:

The site controller receives, by using a site control unit in the site controller, operational status information reported by the base station master device, where the site control unit is connected to the base station master device through an input/output I/O interface; or The site controller receives, by the site control unit in the site controller, operation state information reported by the baseband processing unit BBU in the base station master device, where the site control unit is connected to the BBU through an I/O interface;

The site controller receives, by using a site control unit in the site controller, operational status information collected by the accessory device control unit from the accessory device, where the site control unit controls through the I/O interface and the accessory device. Unit connection.

With reference to the second aspect, in a second possible implementation manner of the second aspect, the site controller acquires running state information of the base station master device, and acquires the accessory device related to the base station master device in the site device. Operation status information, including:

The site controller receives the operating state information reported by the radio remote unit RRU in the base station master device by using the control unit in the site controller and the BBU in the base station master device, and the control unit passes the I/ An O interface is connected to the RRU;

The site controller receives the running state information reported by the accessory device by using a control unit in the site controller, and the control unit is connected to the accessory device through an I/O interface.

With reference to the second aspect or the first possible or the second possible implementation manner of the second aspect, in a third possible implementation manner of the second aspect, the operating state information includes at least one of the following information The power consumption status, the temperature information, the energy saving state, and the standby energy state, the power saving state includes: the base station master device, the accessory device, or the power saving mode is turned on or off.

In a third aspect, the embodiment of the present invention further provides a method for controlling energy saving of a site device, including:

The base station master device reports the running status information of the base station master device to the site controller;

Receiving, by the base station master device, a first energy saving control parameter sent by the site controller;

The base station master device determines, according to the first energy-saving control parameter, whether to change the energy-saving state of the base station master device, where the power-saving state includes: the base station master device turns on or disables the energy-saving mode.

In conjunction with the third aspect, in a first possible implementation manner of the third aspect, the method further includes:

Determining, by the base station master device, a power saving state of the base station master device according to the traffic volume carried by the base station master device and a preset energy saving policy, or the base station master device according to the energy saving indication information received from the site controller Determining a power saving state of the base station master device;

The base station master device reports the running status information of the base station master device to the site controller, specifically:

The base station master device carries the determined energy-saving state in the operating state information and sends the energy-saving state to the site controller, and the site controller sends the energy-saving state to the energy-saving management system.

With reference to the third aspect, in a second possible implementation manner of the third aspect, the determining, by the base station, the base station, the determining, by the base station, the energy saving state of the base station, is:

If the first power saving control parameter indicates that the base station primary device service time needs to be extended and the base station primary device currently turns off the power saving mode, the base station master device changes the current power saving mode to the power saving mode;

If the first power saving control parameter indicates that the base station master device turns off the power saving mode and the base station master device currently turns on the power saving mode, the base station master device changes the current power saving mode to the power saving mode.

With reference to the third aspect or the first possible or the second possible implementation manner of the third aspect, in a third possible implementation manner of the third aspect, the operating state information includes at least one of the following information The power consumption state, the temperature information, and the power saving state, where the power saving state includes: the base station master device turns on or off the energy saving mode.

In a fourth aspect, an embodiment of the present invention provides a method for controlling energy saving of a site device, including:

The accessory device reports the running status information of the accessory device to the site controller, where the accessory device is one or more devices associated with the base station master device in the site device;

Receiving, by the accessory device, a second energy saving control parameter sent by the site controller;

The accessory device determines, according to the second energy-saving control parameter, whether to change the energy-saving state of the accessory device, where the power-saving state includes: the accessory device turns the energy-saving mode on or off.

With reference to the fourth aspect, in a first possible implementation manner of the fourth aspect, the method further includes:

Determining, by the accessory device, an energy-saving state of the accessory device according to the standby energy state, the temperature information, and the preset energy-saving policy of the accessory device;

The accessory device reports the running status information of the accessory device to the site controller, specifically:

The supporting device carries the determined energy-saving state in the operating state information and sends the energy-saving state to the site controller, and the site controller sends the energy-saving state to the energy-saving management system.

With reference to the fourth aspect, in a second possible implementation manner of the fourth aspect, the accessory device determines, according to the second energy-saving control parameter, whether to change an energy-saving state of the accessory device, including:

If the second energy-saving control parameter indicates that the accessory device is in the power-saving mode, and the accessory device is currently enabled in the power-saving mode, the accessory device changes the current power-on mode to the power-off mode;

If the second energy-saving control parameter indicates that the accessory device is in the energy-saving mode and the accessory device is currently in the energy-saving mode, the accessory device changes the current power-off mode to the power-saving mode.

With reference to the fourth aspect, in a third possible implementation manner of the fourth aspect, the supporting device includes: a ventilation device, a cooling device, and a power device;

Determining, according to the second energy-saving control parameter, whether the energy-saving state of the accessory device is changed, including:

If the second energy-saving control parameter indicates that the ventilation device is operated to extract the outdoor cold air to reduce the indoor working environment temperature, the ventilation device turns off the energy-saving mode, and then extracts the outdoor cold air to the power device and the base station main device. engine room;

If the second energy saving control parameter indicates that the cooling device is operated to reduce the indoor working environment temperature, the cooling device turns off the energy saving mode, and then starts to generate cold air to be delivered to the power device and the equipment room where the base station master device is located.

In a fifth aspect, an embodiment of the present invention further provides an energy-saving management system, including:

a receiving module, configured to receive operation state information of the base station master device reported by the site controller, and operation state information of the accessory device related to the base station master device in the site device;

An energy-saving control parameter obtaining module, configured to acquire a first energy-saving control parameter for the base station master device and acquire a second power-saving control parameter for the base station master device according to the operating state information of the base station master device and/or the running state information of the accessory device Energy saving control parameters;

And a sending module, configured to send the first energy saving control parameter and the second power saving control parameter to the site controller.

With reference to the fifth aspect, in a first possible implementation manner of the fifth aspect, the operating state information of the base station master device includes: a power saving state of the base station master device, where the power saving state of the base station master device includes: The base station master device turns on or off the energy saving mode;

The operation status information of the accessory device includes: a backup energy state of the accessory device and a power saving state of the accessory device, and the energy-saving state of the accessory device includes: the accessory device turning on or off the energy-saving mode;

The energy saving control parameter obtaining module includes:

a first control module, configured to determine, when the energy-saving management system determines, according to the operating state information of the base station master device, that the base station master device is in a power-saving mode, determining whether the standby energy state of the accessory device meets a preset a condition, if the standby energy state of the accessory device does not satisfy the first condition, acquiring, by the base station master device, a first energy-saving control parameter that needs to extend the service time of the base station master device, if the accessory device The backup energy state does not satisfy the first condition and the accessory device When the energy saving mode is turned off, the second energy saving control parameter that changes the energy saving state is obtained for the accessory device;

a second control module, configured to determine, when the energy-saving management system determines, according to the operating state information of the base station master device, that the base station master device starts the energy-saving mode, whether the standby energy state of the accessory device meets a preset And the second energy-saving control parameter for changing the energy-saving state of the base station master device, if the standby power state of the accessory device meets the second condition, if the standby device energy state of the accessory device meets When the second condition is described and the accessory device turns on the energy-saving mode, the second energy-saving control parameter that changes the energy-saving state is obtained for the accessory device.

With reference to the fifth aspect, in a second possible implementation manner of the fifth aspect, the operating state information of the base station master device includes: a power saving state of the base station master device, where the power saving state of the base station master device includes: The base station master device turns on or off the energy saving mode;

The operation status information of the accessory device includes: the energy-saving state of the accessory device, and the energy-saving state of the accessory device includes: the accessory device turns the energy-saving mode on or off;

The energy-saving control parameter obtaining module is specifically configured to: when the energy-saving management system determines, according to the operating state information of the base station master device, that the base station master device turns off the energy-saving mode, if the accessory device starts the energy-saving mode, The supporting device obtains the second energy-saving control parameter that changes the energy-saving state; when the energy-saving management system determines that the base station master device turns on the energy-saving mode according to the operating state information of the base station master device, if the accessory device turns off the energy-saving mode, And acquiring, by the accessory device, a second energy-saving control parameter that changes a power-saving state.

With reference to the fifth aspect, in a third possible implementation manner of the fifth aspect, the accessory device includes: a ventilation device, a cooling device, and a power device, and the running status information of the accessory device includes: the power device and The outdoor temperature of the equipment room where the base station is located and the indoor working environment temperature of the power supply device;

The energy-saving control parameter obtaining module is specifically configured to: when the indoor working environment temperature of the power supply device is higher than a preset temperature threshold, and the outdoor temperature is lower than the indoor working environment temperature, acquire and operate the ventilation device Extracting, by the outdoor cold air, a second energy-saving control parameter for reducing the temperature of the indoor working environment; when the indoor working environment temperature of the power supply device is higher than a preset temperature threshold, and the outdoor temperature is higher than the indoor working environment temperature Obtaining a second energy-saving control parameter for operating the refrigeration device to reduce the temperature of the indoor working environment.

With reference to the fifth aspect, in a fourth possible implementation manner of the fifth aspect, the energy-saving management system further includes: an energy-saving indication module, configured to receive, by the receiving module, a base station that is reported by the site controller After the running state information of the standby base station and the running state information of the associated device in the site device, the operating state information of the base station master device includes the traffic volume carried by the base station master device, according to the Obtaining the energy saving indication information, where the energy saving management system determines whether the base station master device is allowed to enable or disable the energy saving mode;

The sending module is further configured to send the energy saving indication information to the site controller, where the site controller sends the energy saving indication information to the base station master device.

With reference to the fifth aspect, in a fifth possible implementation manner of the fifth aspect, the energy-saving management system further includes: a display processing module, configured to receive, by the receiving module, operation state information of the base station master device reported by the site controller And the running state information of the base station master device includes the power consumption information of the base station master device, and the running state information of the accessory device includes the The power consumption information of the accessory device is used to visualize the power consumption information of the base station master device and the power consumption information of the accessory device, and obtain the power consumption information of the base station master device and the power consumption information of the accessory device. Energy saving effect, and the energy saving effect is presented through a chart visualization.

In a sixth aspect, an embodiment of the present invention further provides a site controller, including:

An acquiring module, configured to acquire running state information of a base station master device, and obtain running state information of the accessory device related to the base station master device in the site device;

a first sending module, configured to report, to the energy-saving management system, operation state information of the base station master device and running state information of the accessory device;

a receiving module, configured to receive a first energy saving control parameter and a second power saving control parameter sent by the energy saving management system, where the first energy saving control parameter is an operating state information of the energy saving management system according to the base station master device And the operating state information of the accessory device is obtained by the base station master device, and the second energy saving control parameter is that the energy saving management system is configured according to the operating state information of the base station master device and/or the accessory device. The running status information is obtained by the accessory device;

And a second sending module, configured to send the first power saving control parameter to the base station master device, and send the second power saving control parameter to the accessory device.

With reference to the sixth aspect, in a first possible implementation manner of the sixth aspect, the acquiring module is configured to receive, by using a site control unit in the site controller, operation state information reported by the base station master device, The site control unit is connected to the base station master device through an input/output I/O interface Or the site controller receives the running status information reported by the baseband processing unit BBU in the base station master device by using the site control unit in the site controller, and the site control unit passes the I/O interface and the a BBU connection; receiving, by the site control unit in the site controller, operation state information collected by the accessory device control unit from the accessory device, where the site control unit passes the I/O interface and the accessory device control unit connection.

With reference to the sixth aspect, in a second possible implementation manner of the sixth aspect, the acquiring module is configured to receive, by using, a control unit in the site controller and a BBU in the base station master device The operating state information reported by the radio remote unit RRU in the master device, the control unit is connected to the RRU through the I/O interface, and the operating state information reported by the accessory device is received by the control unit in the site controller. The control unit is connected to the accessory device through an I/O interface.

With reference to the sixth aspect or the first possible or the second possible implementation manner of the sixth aspect, in a third possible implementation manner of the sixth aspect, the operating state information includes at least one of the following information The power consumption status, the temperature information, the energy saving state, and the standby energy state, the power saving state includes: the base station master device, the accessory device, or the power saving mode is turned on or off.

In a seventh aspect, the embodiment of the present invention further provides a base station master device, including:

a sending module, configured to report, to the site controller, operation state information of the base station master device;

a receiving module, configured to receive a first energy saving control parameter sent by the site controller;

The energy-saving control module is configured to determine, according to the first energy-saving control parameter, whether to change a power-saving state of the base station master device, where the power-saving state includes: the base station master device turns on or disables a power-saving mode.

With reference to the seventh aspect, in a first possible implementation manner of the seventh aspect, the power saving control module is further configured to determine, according to the traffic volume carried by the base station master device and the preset energy saving policy, the base station master device The energy-saving state of the base station, or the base station master device determines the energy-saving state of the base station master device according to the energy-saving indication information received from the site controller;

The sending module is configured to carry the determined energy saving state in the running state information and send the information to the site controller, where the site controller sends the energy saving state to the energy saving management system.

With reference to the seventh aspect, in a second possible implementation manner of the seventh aspect, the power saving control module is specifically configured to: if the first power saving control parameter indicates that the base station primary device service time needs to be extended, and the base station The main device is currently powered off, then the current power off mode is turned on. a power saving mode; if the first power saving control parameter indicates that the base station master device turns off the power saving mode and the base station master device currently turns on the power saving mode, the current power saving mode is changed to the power saving mode.

With reference to the seventh aspect, or the first possible or the second possible implementation manner of the seventh aspect, in a third possible implementation manner of the seventh aspect, the operating state information includes at least one of the following information The power consumption state, the temperature information, and the power saving state, where the power saving state includes: the base station master device turns on or off the energy saving mode.

The eighth aspect, the embodiment of the present invention further provides an accessory device, where the accessory device is one or more devices associated with the base station master device in the site device, and the accessory device includes:

a sending module, configured to report, to the site controller, operation status information of the accessory device;

a receiving module, configured to receive a second energy saving control parameter sent by the site controller;

The energy-saving control module is configured to determine, according to the second energy-saving control parameter, whether to change the energy-saving state of the accessory device, where the power-saving state includes: the accessory device turns the energy-saving mode on or off.

With reference to the eighth aspect, in a first possible implementation manner of the eighth aspect, the energy-saving control module is further configured to determine, according to the standby energy state, the temperature information, and the preset energy-saving policy of the accessory device, Energy-saving status of the supporting equipment;

The sending module is configured to carry the determined energy saving state in the running state information and send the information to the site controller, where the site controller sends the energy saving state to the energy saving management system.

With reference to the eighth aspect, in a second possible implementation manner of the eighth aspect, the energy-saving control module is configured to: if the second energy-saving control parameter indicates that the accessory device is in a power-saving mode, and the accessory device is currently If the energy-saving mode is enabled, the current energy-saving mode is changed to the power-saving mode; if the second energy-saving control parameter indicates that the accessory device is in the energy-saving mode and the accessory device is currently in the energy-saving mode, the current mode is turned off. The energy saving mode is changed to the energy saving mode.

With reference to the eighth aspect, in a third possible implementation manner of the eighth aspect, the supporting device includes: a ventilation device, a cooling device, and a power device;

The energy-saving control module is specifically configured to: if the second energy-saving control parameter indicates that the ventilation device is configured to extract outdoor cold air to reduce the indoor working environment temperature, turn off the energy-saving mode of the ventilation device, and then extract the outdoor cold air to the The power equipment and the equipment room where the base station is located; if the second energy-saving control parameter indicates that the cooling equipment is operated to reduce the indoor working environment temperature, the office is shut down The energy saving mode of the refrigeration device is then started to generate cold air delivery to the power room and the equipment room where the base station master device is located.

The ninth aspect, the embodiment of the present invention further provides an energy-saving control system for a site device, comprising: the energy-saving management system according to any one of the fifth aspects, the site controller according to any one of the sixth aspects The base station master device according to any one of the seventh aspect, wherein the accessory device is any one of the eighth aspects.

In the embodiment of the present invention, the energy-saving management system monitors, processes, and analyzes the running status information of the base station main equipment and the running status information of the supporting equipment, respectively, and formulates energy-saving control parameters for the base station main equipment and the supporting equipment, respectively, Energy-saving linkage control between devices can reduce the overall energy consumption of site equipment.

DRAWINGS

1 is a schematic diagram of a network architecture of a method for controlling energy saving of a site device according to an embodiment of the present invention;

2 is a schematic block diagram of a method for controlling energy saving of a site device according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of an energy-saving linkage state transition according to an embodiment of the present invention; FIG.

FIG. 3 is a schematic diagram of another embodiment of energy-saving linkage state transition according to an embodiment of the present invention; FIG.

4 is a schematic block diagram showing another method for controlling energy saving of a site device according to an embodiment of the present invention;

FIG. 5 is a schematic block diagram of another method for controlling energy saving of a site device according to an embodiment of the present disclosure;

FIG. 6 is a schematic block diagram of another method for controlling energy saving of a site device according to an embodiment of the present disclosure;

7-a is a schematic structural diagram of an implementation of energy saving linkage of a site device based on SON according to an embodiment of the present invention;

7-b is a flow chart of a method for controlling energy-saving linkage of a site device according to an embodiment of the present invention;

FIG. 7-c is a schematic diagram of another implementation architecture of a SON-based site device energy-saving linkage according to an embodiment of the present invention;

FIG. 7-d is a schematic diagram of another implementation architecture of a SON-based site device energy-saving linkage according to an embodiment of the present invention;

FIG. 8-a is a schematic structural diagram of an energy-saving management system according to an embodiment of the present invention;

FIG. 8-b is a schematic structural diagram of an energy-saving control parameter obtaining module according to an embodiment of the present invention;

FIG. 8-c is a schematic structural diagram of another energy-saving management system according to an embodiment of the present invention;

FIG. 8-d is a schematic structural diagram of another energy-saving management system according to an embodiment of the present invention;

FIG. 9 is a schematic structural diagram of a structure of a site controller according to an embodiment of the present invention;

FIG. 10 is a schematic structural diagram of a base station master device according to an embodiment of the present disclosure;

FIG. 11 is a schematic structural diagram of a structure of a site device according to an embodiment of the present disclosure;

FIG. 12 is a schematic structural diagram of a structure of an energy-saving control system for a site device according to an embodiment of the present invention;

FIG. 13 is a schematic structural diagram of another energy-saving management system according to an embodiment of the present invention;

FIG. 14 is a schematic structural diagram of another station controller according to an embodiment of the present disclosure;

FIG. 15 is a schematic structural diagram of another base station master device according to an embodiment of the present disclosure;

FIG. 16 is a schematic structural diagram of another station device according to an embodiment of the present invention.

detailed description

Embodiments of the present invention provide a method, a device, and a system for controlling energy saving of a site device, which can reduce energy consumption of the site device.

In order to make the object, the features and the advantages of the present invention more obvious and easy to understand, the technical solutions in the embodiments of the present invention will be clearly and completely described below in conjunction with the accompanying drawings in the embodiments of the present invention. The described embodiments are only a part of the embodiments of the invention, and not all of the embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present invention are within the scope of the present invention.

The terms "first", "second" and the like in the specification and claims of the present invention and the above drawings are used to distinguish similar objects, and are not necessarily used to describe a particular order or order. It is to be understood that the terms so used are interchangeable as appropriate, and are merely illustrative of the manner in which the objects of the same. In addition, the terms "comprises" and "comprises" and "comprises", and any variations thereof, are intended to cover a non-exclusive inclusion so that a process, method, system, product, or device comprising a series of units is not necessarily limited to those elements, but may include Other units listed or inherent to these processes, methods, products or equipment.

The following is a description of the overall implementation architecture of the energy-saving control method for the site device in the present invention. Please refer to FIG. 1 , which is a schematic diagram of the network architecture of the energy-saving control method for the site device in the present invention, and implement energy-saving of the site device based on the energy-saving management system. Linkage control can make full use of the ability and advantages of the upper-layer software of the network to calculate and process the information reported by the site equipment, and realize the adaptive optimization management of the energy consumption of the site equipment. The site equipment includes: the base station main equipment and the supporting equipment, and the supporting equipment refers to One or more devices associated with the base station master device in the site device, and the accessory device may be a power device, a ventilation device, and a cooling device. The site controller may be an entity that implements a control function for the site device. The site controller is connected to the base station master device through an input/output (I/O, Input/Output) interface, and the site controller is also connected to the accessory device through the I/O interface. . The base station master device and the accessory device report their respective states to the site controller respectively. After the site controller obtains the respective operating states of the base station master device and the accessory device, the site controller reports the base station master device and the accessory device to the energy-saving management system. Their respective status information. The energy-saving management system monitors, processes, and analyzes the status information of the primary and secondary devices of the base station, and formulates energy-saving plans for the primary and secondary devices of the base station. After that, the energy-saving management system sends the energy-saving control parameters of the base station master device and the accessory device to the site controller, and the station controller then distributes the parameters to the base station master device or the accessory device, and finally the base station master device and the accessory device respectively follow the energy-saving management system. The control parameters are set to run, so that the energy-saving linkage control of the base station master device and the accessory device in the site device can be realized. In the present invention, the energy-saving algorithm of the upper layer is formulated by the energy-saving management system, and the main equipment of the base station and the supporting equipment perform energy-saving linkage, so that the linkage control between the upper-layer energy-saving algorithm and the underlying device can be realized, and the site equipment of different manufacturers can be easily facilitated. Flexible application of site equipment energy management and energy-saving linkage scheme.

Next, the main body will be described in detail in a single method.

An embodiment of the energy saving control method of the site device of the present invention can be applied to an energy saving management system, as shown in FIG. 2 . The method for controlling energy saving of a site device provided by an embodiment of the present invention may include the following steps:

201. The energy-saving management system receives the running state information of the base station master device reported by the site controller and the running state information of the accessory device related to the base station master device in the site device.

In the embodiment of the present invention, the energy-saving management system is the main body of the energy-saving scheme, and is independent of the site controller. The site controller is the control entity of the site device, and the energy-saving management system and the site controller are connected. Wherein, the connection may refer to establishing a wireless connection or a wired connection of the communication, and the site controller is respectively connected with the base station master device and the accessory device in the site device; the site controller acquires the base station master device The running status information of the running status information of the base station and the running status information of the supporting equipment are reported to the energy saving management system; the energy saving management system acquires the base station main equipment from the station controller. Operation status information and running status information of the accessory equipment. In the present invention, the energy-saving management system needs to acquire the running state information of the site device as the input information necessary for formulating the energy-saving scheme; the running state information includes the state data generated by the device body during the working process. The running status information of the site device is obtained according to the status information specified by the energy-saving management system. The running status information that needs to be reported for each device included in the site device may be the same or different, and the site device and the energy-saving management system need to be combined. The actual situation to determine the specific content of the operating status information.

Specifically, in the embodiment of the present invention, the running status information may include at least one of the following information: power consumption information, temperature information, energy saving state, and standby energy state, and the energy saving state includes: whether the base station master device or the accessory device is Turn energy saving mode on or off. The energy-saving mode refers to a state in which the main body of the device enters a state of being turned off or hibernating. When the energy-saving mode is turned on, the main body of the device is in a state of being turned off or hibernating, and the power consumed by the device itself is lower than that of the normal operating mode. less. For the base station master device, the running status information may include: power consumption information of the base station master device, temperature information of the base station master device, and energy saving status of the base station master device. The energy-saving state of the base station master device refers to that the base station master device currently has the power-saving mode enabled or the power-saving mode is currently turned off. For the accessory device, the running status information includes: the power consumption information of the accessory device, the temperature information of the accessory device, and the energy-saving status of the accessory device. The energy-saving state of the accessory device indicates that the accessory device is currently enabled with the energy-saving mode or is currently closed. Energy saving mode.

It should be noted that, in the present invention, the running status information reported by the base station master device and the running status information reported by the accessory device may include one or more pieces of information of the foregoing content, and the content included in the running status information may also be managed according to energy saving. The system develops the energy-saving scheme and adds other information content. The base station master device and the supporting device can still report according to the information that the energy-saving management system needs to report. For example, the running status information of the base station master device may further include: the traffic volume carried by the base station master device, that is, the base station master device reports the traffic carried by the base station to the site controller, and the energy-saving management system may acquire the base station master device bearer from the site controller. Therefore, the energy-saving management system can separately formulate energy-saving schemes for the base station main equipment and the supporting equipment according to the traffic carried by the base station main equipment, and the site energy-saving technical solutions in the prior art are not based on the change of the base station traffic volume. The need to study the management and control of site equipment energy consumption. The present invention can be collected by the base station master device at different times of the day. The amount of traffic carried by the primary equipment of the segment base station, and the primary device of the base station can also enable/disable the energy-saving mode according to the change of the traffic carried by the base station. The energy-saving scheme formulated by the energy-saving management system for the supporting equipment can also consider the factors that change the amount of traffic carried by the base station, thereby establishing energy-saving linkage between the primary equipment and the supporting equipment of the base station. Therefore, the energy-saving management system can adjust the energy consumption of the supporting device according to the busy and idle working state of the base station main device, so as to achieve the optimal energy efficiency of the entire site device.

The energy-saving management system acquires the first energy-saving control parameter for the base station master device and the second energy-saving control parameter for the accessory device according to the running state information of the master device of the base station and/or the running state information of the accessory device.

In the embodiment of the present invention, after the energy-saving management system acquires the running state information of the base station master device and the running state information of the accessory device from the site control, the energy-saving management system may use the obtained running state information as the base station master device and the supporting device. Develop energy-saving plans separately. When the energy-saving management system formulates the energy-saving scheme, the running status information of the base station master device can be used, or the running state information of the supporting device can be used, and the state running information of the base station master device and the state running information of the supporting device can be simultaneously used. In addition, the energy-saving management system may further set an energy-saving policy in advance, and the energy-saving management system may be the base station master device according to the preset energy-saving policy combined with the operation state information acquired from the base station master device and/or the operation state information acquired from the accessory device. Develop energy-saving plans separately with supporting equipment. Specifically, the energy-saving management system acquires the first energy-saving control parameter for the master device of the base station, and the energy-saving management system obtains the second energy-saving control parameter for the accessory device, and respectively carries the energy-saving management system for each device body in each energy-saving control parameter. . The energy-saving scheme implemented by the master device of the base station and the energy-saving scheme implemented by the accessory device are uniformly formulated by the energy-saving management system, and the master device and the accessory device of the base station can perform energy-saving linkage operation under the unified control of the energy-saving management system to solve the prior art. The problem of energy saving effect caused by energy saving by each device body in the site device is not ideal, and the overall energy consumption of the site device is reduced.

It should be noted that, in the embodiment of the present invention, the energy-saving management system may use the running state information of the base station master device when the energy-saving scheme is determined by the base station master device, and may also use the running state information of the accessory device, and may also use the base station master device at the same time. Status operation information and status operation information of the accessory device. Similarly, when the energy-saving management system formulates an energy-saving scheme for the supporting equipment, the operating state information of the base station master device can be used, and the running state information of the supporting device can also be used, and the state running information of the base station master device and the state running information of the supporting device can be simultaneously used. . The energy-saving management system obtains energy-saving control parameters for the master device and the accessory device of the base station to meet the energy-saving linkage between the master device and the accessory device. Need to improve the energy saving effect of the base station main equipment and supporting equipment.

In some embodiments of the present invention, the operating state information of the base station master device includes: a power saving state of the base station master device, for example, the base station master device turns the power saving mode on or off; and the running state information of the accessory device includes: the standby power state of the accessory device. And the energy-saving status of the accessory device, for example, the accessory device turns the energy-saving mode on or off. In this case, the energy saving management system of step 202 acquires the first energy saving control parameter for the base station master device and the second power saving control parameter for the accessory device according to the running state information of the base station master device and/or the running state information of the accessory device. Specifically, the method may include the following steps:

A1. When the energy-saving management system determines that the base station master device is in the energy-saving mode according to the running state information of the master device of the base station, the energy-saving management system determines whether the standby energy state of the accessory device meets the preset first condition. If the backup energy state of the accessory device does not meet the first condition, the energy-saving management system acquires, for the base station master device, the first energy-saving control parameter that needs to extend the service time of the base station master device; if the backup device energy state of the accessory device does not satisfy the first condition When the accessory device turns off the energy-saving mode, the energy-saving management system obtains the second energy-saving control parameter that changes the energy-saving state for the accessory device.

A2. When the energy-saving management system determines, according to the running status information of the master device of the base station, that the power-on mode of the base station is enabled, the energy-saving management system determines whether the state of the standby energy of the accessory device meets the preset second condition. If the backup energy state of the accessory device meets the second condition, the energy-saving management system obtains the first energy-saving control parameter for changing the energy-saving state of the base station master device; if the backup energy state of the accessory device meets the second condition and the accessory device turns on the energy-saving mode The energy-saving management system acquires the second energy-saving control parameter that changes the energy-saving state for the accessory device.

In the implementation scenarios of the foregoing A1 to A2, as shown in FIG. 3-a, a schematic diagram of the energy-saving linkage state transition provided by the embodiment of the present invention is shown. In the energy-saving linkage dynamic conversion in Figure 3-a, the supporting device is the primary device and the primary device is the secondary device. The energy-saving management system obtains the energy-saving status of the primary device of the base station. The energy-saving management system can determine whether the primary device of the base station is currently enabled with the energy-saving mode. The power save mode is turned off. The energy-saving management system obtains the energy-saving status of the supporting equipment and the standby energy status of the supporting equipment. The energy-saving management system can also determine whether the supporting equipment is currently enabled with the energy-saving mode or the energy-saving mode; the standby energy state of the supporting equipment is specifically the power supply device. The state of the backup energy. In the present invention, the power supply equipment included in the site equipment may be various power supply devices that are mixed with wind, light, varnish, and wind oil, and may also be various power supply devices for power supply, oil machine, fan, and solar power. Power devices are also known as power devices. The standby energy state of the power supply device refers to the remaining state of energy stored in the power supply device for the base station main device and the ventilation device, the refrigeration device, and the like. Specifically, the power state of the power supply device It can also be measured by how long it can support the site device to work properly.

In the implementation scenario described in step A1, the base station master device is in the energy-saving mode, that is, the base station master device is in the normal working mode, and the energy-saving management system determines whether the standby device energy state of the accessory device meets the first condition, and the first condition may be One of the energy saving strategies set in the energy management system, for example, it may be an energy threshold of the backup energy. If the backup energy status of the accessory device meets the first condition, it indicates that the energy reserve of the accessory device is sufficient to ensure the normal operation of the master device of the base station; if the backup energy state of the accessory device does not meet the first condition, the accessory device is The energy reserve is small, which is not enough to ensure the normal operation of the base station master device. The energy-saving management system needs to instruct the base station master device to extend the base station master device service time. The first condition may also be a duration threshold for supporting the operation of the base station master device according to the backup power determined by the base station master device for the power consumption value of the power consumption.

If the backup energy status of the accessory device does not meet the first condition, it indicates that the backup device has less backup energy, and the base station master device is in the power-saving mode. The energy-saving management system needs to extend the base station master device for the base station master device. The first energy saving control parameter of the service time. Therefore, the base station master needs to switch the power saving mode to delay the service time of the base station master device. If the backup energy status of the accessory device does not meet the first condition and the accessory device turns off the energy-saving mode, indicating that the backup device has less power for backup, the energy-saving management system obtains the second energy-saving control parameter for changing the energy-saving state for the accessory device, thereby enabling The supporting equipment changes the energy saving state to save the energy consumption of the power supply equipment.

In the implementation scenario described in step A2, the base station master device starts the energy-saving mode, that is, the base station master device is in a state of being powered off or sleeping. The energy-saving management system determines whether the standby energy state of the accessory device satisfies the second condition, and the second condition may be one of the energy-saving policies set in the energy-saving management system, for example, it may be an energy threshold of the backup energy. If the backup energy status of the accessory device meets the second condition, it indicates that the energy reserve of the accessory device is sufficient to ensure the normal operation of the master device of the base station; if the backup energy state of the accessory device does not meet the second condition, the accessory device is The energy reserve is small, which is not enough to ensure the normal operation of the base station master device. In addition, the second condition may further be a duration threshold for supporting the operation of the base station master device according to the backup power determined by the base station master device for the power consumption value of the power consumption. It should be noted that the thresholds set in the first condition and the second condition set in the energy saving management system may be the same value, or may be different values respectively set according to specific situations.

If the backup energy status of the accessory device meets the second condition, it indicates that the backup device has sufficient backup energy, and the base station master device is in the energy-saving mode, the energy-saving management system obtains the first energy-saving state for the base station master device to change the energy-saving state. Control parameters, so the base station master needs to switch energy-saving mode, Into the normal working mode. Because the power supply of the power supply device is sufficient, the base station master device does not need to turn on the energy-saving mode, so that it can work normally. If the backup energy status of the accessory meets the second condition and the accessory device is powered on, indicating that the backup device has sufficient backup energy, the energy-saving management system obtains the second energy-saving control parameter that changes the energy-saving state for the accessory device, thereby enabling the accessory device. Change the power saving state to enter the normal working mode.

In some embodiments of the present invention, the operating state information of the base station master device includes: a power saving state of the base station master device, for example, the base station master device turns the power saving mode on or off; and the running state information of the accessory device includes: the energy saving state of the accessory device, for example, The accessory device turns the energy saving mode on or off. In this case, the energy saving management system of step 202 acquires the first energy saving control parameter for the base station master device and the second power saving control parameter for the accessory device according to the running state information of the base station master device and/or the running state information of the accessory device. Specifically, the method may include the following steps:

B1, when the energy-saving management system determines, according to the running status information of the master device of the base station, that the energy-saving mode of the base station is turned off, if the energy-saving mode is enabled, the energy-saving management system acquires the second energy-saving control parameter that changes the energy-saving state for the accessory device;

B2. When the energy-saving management system determines that the power-on mode of the base station is enabled according to the running status information of the master device of the base station, if the accessory device turns off the energy-saving mode, the energy-saving management system acquires the second energy-saving control parameter that changes the energy-saving state for the accessory device.

In the implementation scenario of the foregoing B1 to B2, as shown in FIG. 3-b, another schematic diagram of the energy-saving linkage state transition provided by the embodiment of the present invention is provided. In the energy-saving linkage dynamic conversion of Figure 3-b, the supporting device is the secondary device and the primary device is the primary device. The energy-saving management system obtains the second energy-saving control parameter for the supporting device according to the running status information of the primary device and the running status information of the supporting device. Specifically, the second energy-saving control parameter of the accessory device may be set according to the energy-saving state of the master device of the base station, and the second energy-saving control parameter set by the energy-saving management system for the accessory device may implement energy-saving linkage control between the base station master device and the accessory device.

In some embodiments of the present invention, the accessory device includes: a ventilation device, a refrigeration device, and a power supply device, and the running status information of the accessory device includes: an outdoor temperature of the power device and the room where the base station is located, and an indoor working environment temperature of the power device. . In this implementation scenario, the energy saving management system of step 202 acquires the first energy-saving control parameter for the base station master device and the second energy-saving control parameter for the accessory device according to the running state information of the master device of the base station and/or the running state information of the accessory device. include:

C1, when the indoor working environment temperature of the power supply device is higher than a preset temperature threshold, and the outdoor temperature When the temperature is lower than the indoor working environment temperature, the energy-saving management system acquires the second energy-saving control parameter that the operating ventilation device extracts the outdoor cold air to reduce the indoor working environment temperature;

C2. When the indoor working environment temperature of the power supply device is higher than a preset temperature threshold, and the outdoor temperature is higher than the indoor working environment temperature, the energy-saving management system acquires a second energy-saving control parameter for operating the refrigeration device to reduce the indoor working environment temperature.

In the above embodiment of the present invention, the energy-saving management system can implement intelligent ventilation and intelligent cooling for the second energy-saving control parameter acquired by the accessory device, and the site controller can collect the outdoor temperature and power device of the power room and the base station where the base station is located. The indoor working environment temperature, or the supporting equipment control unit, needs to collect the outdoor temperature and the indoor working environment temperature of the power supply device to report to the site controller, and the site controller sends the outdoor temperature and the indoor working environment temperature of the power supply device to the energy saving management system. Further, in the scenario of step C1 and step C2 in the present invention, the supporting device control unit can collect the outdoor temperature and the indoor working environment temperature in real time, and then the energy saving management system can obtain each set of outdoor temperature and indoor working environment temperature. Steps C1 and C2 are performed once, so the energy-saving management system can acquire the second energy-saving control parameter in real time according to the temperature information of the accessory device. In the existing energy-saving technical solutions of the base station main equipment or ancillary equipment, the control parameters for turning on and off the energy-saving function (such as the threshold of the air conditioner on/off, the condition of the oil on/off, etc.) are usually after the initial configuration. It is unchanged and cannot be adjusted according to the traffic fluctuation and the external climate change application scenario. In the present invention, the temperature information of the accessory device can be collected in real time, and the power consumption of the base station master device and the accessory device can be adaptively adjusted. Realize dynamic optimization management of site equipment energy consumption.

It should be noted that, in the foregoing content of the present invention, after the step 201 is performed, the energy-saving management system performs step 202. In some embodiments of the present invention, the step 201 energy-saving management system receives the operation of the base station master device reported by the site controller. After the status information and the running status information of the associated device related to the base station main device in the site device, the energy saving control method of the site device provided by the present invention may further include the following steps:

D1. If the running status information of the primary device of the base station includes the traffic carried by the primary device of the base station, the energy-saving management system obtains the energy-saving indication information according to the traffic carried by the primary device of the base station and the preset energy-saving policy, and the energy-saving indication information includes: determining by the energy-saving management system Whether to allow the base station master device to enable or disable the energy saving mode;

D2. The energy-saving management system sends the energy-saving indication information to the site controller, and the site controller sends the energy-saving indication information to the base station master device.

If the running status information of the primary device of the base station further includes the traffic carried by the primary device of the base station, the energy saving management system indicates whether the base station primary device is allowed to enable or disable the energy saving mode according to the traffic volume carried by the primary device of the base station and the preset energy saving policy. The management system obtains the traffic that is currently carried by the primary device of the base station, and determines whether the traffic carried by the primary device of the base station exceeds a preset threshold or is smaller than a preset threshold, and the energy-saving management system determines the base station. The service volume carried by the master device is too large or too small. If the energy-saving management system determines that the traffic carried by the master device of the base station is too large, the energy-saving management system instructs the master device of the base station not to enable the energy-saving mode to meet the needs of the service. The management system determines that the traffic carried by the primary device of the base station is too small, and the energy-saving management system instructs the primary device of the base station not to disable the energy-saving mode to meet the needs of energy saving.

In some embodiments of the present invention, after the step 201 is performed, the energy saving management system performs step 202. In some embodiments of the present invention, the step 201 energy saving management system receives the running status information of the base station master device reported by the site controller and After the operating state information of the associated device in the site device is related to the base device, the energy saving control method of the site device provided by the present invention may further include the following steps:

E1. If the running status information of the primary device of the base station includes the power consumption information of the primary device of the base station, and the running status information of the supporting device includes the power consumption information of the supporting device, the energy saving management system visualizes the power consumption information and the supporting device of the primary device of the base station. Power consumption information of the device;

E2. The energy-saving management system obtains the energy-saving effect according to the power consumption information of the base station main device and the power consumption information of the accessory device, and displays the energy-saving effect through the chart visualization.

In step E1, if the base station master device and the accessory device both send their own power consumption information to the site controller, the energy-saving management system visualizes the power consumption information of the base station master device and the power consumption information of the accessory device through the chart visualization, thereby The power consumption information of the base station main device and the power consumption information of the supporting device can be visually displayed. In step E2, the energy saving effect can be further monitored by the energy saving management system, and the multiple power consumption information of the base station main device is compared, and the comparison is performed. A plurality of power consumption information of the accessory device can obtain energy-saving effects, and finally, the energy-saving effect can be visualized through the chart.

203. The energy saving management system sends the first energy saving control parameter and the second energy saving control parameter to the site controller.

In the embodiment of the present invention, after the energy-saving management system acquires the first energy-saving control parameter for the base station master device and the second energy-saving control parameter for the accessory device, the energy-saving management system sends the first energy-saving control parameter and the second energy-saving control parameter to the site. Controller, the first energy-saving control parameter and the site controller The second energy-saving control parameters are respectively sent to the base station master device and the accessory device, and the base station master device and the accessory device can respectively implement the energy-saving schemes formulated by the energy-saving management system, thereby reducing the energy consumption of each device body itself.

It should be noted that, in the embodiment of the present invention, the energy-saving management system is connected to the site controller, and receives the running state information of the base station master device and the running state information of the accessory device from the site controller, and the energy-saving management system is respectively the base station master device. And the supporting equipment obtains the energy-saving control parameter, and finally distributes the first energy-saving control parameter and the second energy-saving control parameter to the site controller, and the energy-saving management system can have multiple implementation manners, and one feasible energy-saving management system as a functional entity There is a site controller interaction to complete the determination and distribution of the foregoing energy saving solution. Another possibility is that the energy saving management system can implement the determination and distribution of the foregoing energy saving solution by using multiple functional entities. For example, the energy saving management system may include a network management system. And an energy-saving control system, the network management system is responsible for interaction with the site controller, the energy-saving control system is responsible for formulating energy-saving schemes, and the energy-saving management system can also realize the determination and distribution of energy-saving schemes through other entities.

According to the description of the present invention, the base station master device and the accessory device in the site device respectively report the respective running state information to the site controller, and the site controller obtains the running state information of the base station master device and the running state of the accessory device. After the information, the site controller reports the running status information of the base station master device and the running state information of the supporting device to the energy saving management system, and the energy saving management system receives the running state information of the base station master device reported by the site controller and the running state information of the supporting device. After that, the energy-saving management system obtains the first energy-saving control parameter for the base station master device and the second energy-saving control parameter for the accessory device according to the running state information of the base station master device and/or the running state information of the accessory device, and the energy-saving management system will be the first energy-saving management system. The control parameter and the second energy-saving control parameter are sent to the site controller, and the site controller sends the first energy-saving control parameter to the base station master device, and sends the second energy-saving control parameter to the accessory device. In the present invention, the energy-saving management system monitors, processes, and analyzes the running status information of the base station main equipment and the running status information of the supporting equipment, respectively, and establishes energy-saving control parameters for the base station main equipment and the supporting equipment, respectively, and can implement multiple devices in the station equipment. The energy-saving linkage control between the two can greatly reduce the overall energy consumption of the site equipment and realize the intelligent management of energy efficiency of the site equipment.

The foregoing embodiment describes the energy-saving control method of the site device provided by the present invention from the perspective of the energy-saving management system. Next, another embodiment of the energy-saving control method of the site device of the present invention is introduced, which can be applied to the site controller, see the figure. 4 shows a section of a site device provided by an embodiment of the present invention The control method can include the following steps:

401. The site controller acquires running state information of the base station master device, and acquires running state information of the accessory device related to the base station master device in the site device.

In the embodiment of the present invention, the energy-saving management system is the main body of the energy-saving scheme, independent of the site controller, the site controller is the control entity of the site device, and the energy-saving management system is connected with the site controller, wherein the connection may be established. The wireless connection or the wired connection of the communication, the site controller is respectively connected with the base station master device and the accessory device in the site device, and the site controller first obtains the running state information of the base station master device and the running state information of the accessory device.

Specifically, in the embodiment of the present invention, the running status information may include at least one of the following information: power consumption information, temperature information, energy saving state, and standby energy state, and the energy saving state includes: the base station master device and the accessory device are enabled. Or turn off the power save mode. The energy-saving mode refers to a state in which the main body of the device enters a state of being turned off or hibernating. When the energy-saving mode is turned on, the main body of the device is in a state of being turned off or hibernating, and the power consumed by itself is less than the normal operating mode. . For the base station master device, the running status information may include: power consumption information of the base station master device, temperature information of the base station master device, and energy saving state of the base station master device, and the power saving state of the base station master device refers to that the base station master device is currently enabled. The energy-saving mode or the energy-saving mode is currently disabled. For the supporting device, the running status information may include: the power consumption information of the supporting device, the temperature information of the supporting device, and the energy-saving state of the supporting device. The energy-saving state of the supporting device refers to the supporting device. The power save mode is currently turned on or the power save mode is currently turned off.

It should be noted that, in the present invention, the running status information reported by the base station master device and the running status information reported by the accessory device may include one or more pieces of information of the foregoing content, and the content included in the running status information may also be managed according to energy saving. The system establishes the energy-saving scheme and adds other information content. The base station master device and the accessory device can still report the information that the energy-saving management system needs to report. For example, the operation status information of the base station master device may further include: the base station master device bearer The amount of traffic, that is, the base station master device reports the traffic carried by the base station controller to the site controller, and the energy-saving management system can obtain the traffic carried by the base station master device from the site controller, so the energy-saving management system can according to the traffic carried by the base station master device. To save energy-saving schemes for the base station main equipment and the supporting equipment, the site energy-saving technical solutions in the prior art do not study the management and control of the energy consumption of the station equipment according to the demand for energy consumption of the base station traffic. The present invention can collect the traffic carried by the base station master device in different time periods in the day by the base station master device, and the base station master device can also change the traffic volume carried by the base station master device. When the energy-saving mode is enabled or disabled, the energy-saving scheme developed by the energy-saving management system for the supporting device can also consider the factors that change the amount of traffic carried by the base station, so as to establish the energy-saving linkage between the master device and the accessory device. Adjust the energy consumption of the supporting equipment as needed to achieve the best energy efficiency of the entire site.

In some embodiments of the present invention, the step 401, the site controller acquires the running state information of the base station master device, and obtains the running state information of the accessory device related to the base station master device in the site device, which may include the following steps:

The site controller receives the running status information reported by the base station master device through the site control unit in the site controller, and the site control unit connects to the base station master device through the I/O interface; or the site controller passes the site in the site controller. The control unit receives the running status information reported by the base station processing unit (BBU) in the base station master device, and the station control unit is connected to the BBU through the I/O interface;

F2. The site controller receives the operation status information collected by the accessory device control unit from the accessory device through the site control unit in the site controller, and the site control unit is connected to the accessory device control unit through the I/O interface.

In the implementation manner of step F1 of the present invention, a site control unit may be set in the site controller, and the site control unit is connected to the base station master device through one I/O interface, and is connected to the accessory device control unit through another I/O interface. In this case, the station control unit is directly connected to the base station master device. In another implementation scenario, the base station master device includes: a BBU and a plurality of radio remote units (RRUs), and the station control unit directly The BBU is connected through an I/O interface. In the implementation manner of the step F2 of the present invention, the site control unit and the accessory device control unit are connected, and the accessory device control unit is configured to obtain the running state information of the accessory device, and the accessory device control unit sends the running state information of the accessory device through the site control unit. Give the site controller.

In some embodiments of the present invention, the step 401, the site controller acquires the running state information of the base station master device, and obtains the running state information of the accessory device related to the base station master device in the site device, which may include the following steps:

G1, the site controller receives the running status information reported by the RRU in the base station master device by using the control unit in the site controller and the BBU in the base station master device, and the control unit is connected to the RRU through the I/O interface;

G2. The site controller receives the operation reported by the accessory device through the control unit in the site controller. Status information, the control unit is connected to the accessory device through the I/O interface.

In the implementation manner of the step G1 of the present invention, a control unit may be set in the site controller. The base station master device includes: a BBU and multiple RRUs, and the BBU in the base station master device may be set in the site controller, and the control in the site controller The unit is connected to the BBU, and the control unit is directly connected to the multiple RRUs through the external I/O interface. The BBU obtains the running status information of the base station master device, and the BBU sends the base station master device by connecting with the control unit in the site controller. Running status information. In the implementation manner of the step G2 of the present invention, the control unit is connected to the accessory device through the I/O interface, and the control unit is not separately set in the accessory device, but the control function is implemented by the control unit set in the site controller, and the control unit directly The control unit obtains the running status information of the accessory device by connecting the I/O interface to the accessory device.

402. The site controller reports the running state information of the base station master device and the running state information of the accessory device to the energy saving management system.

In the embodiment of the present invention, the site controller obtains the running status information of the base station master device and the running state information of the accessory device, and the site controller reports the running state information of the base station master device and the running state information of the accessory device to the energy saving management system. The energy-saving management system acquires the running state information of the base station master device and the running state information of the accessory device from the site controller. In the present invention, the energy-saving management system needs to obtain the running state information of the site device as the information necessary for formulating the energy-saving solution, and the running state information refers to the state data generated by the device body during the working process, and the running state information of the site device may be based on The status information that needs to be obtained by the energy-saving management system may be the same or different for each of the multiple devices included in the site device. The actual status of the site device and the energy-saving management system is used to determine the running status information. Specific content.

403. The site controller receives the first energy saving control parameter and the second energy saving control parameter sent by the energy saving management system.

The first energy-saving control parameter is obtained by the energy-saving management system according to the running state information of the base station master device and/or the running state information of the accessory device, and the second energy-saving control parameter is the energy-saving management system according to the running state of the base station master device. The running status information of the information and/or supporting equipment is obtained by the supporting equipment.

In the embodiment of the present invention, after the energy-saving management system acquires the running state information of the base station master device and the running state information of the accessory device from the site control, after the energy-saving management system obtains the running state information from the base station master device and the accessory device, the energy-saving management The system can obtain the above operational status letter according to the obtained The energy saving scheme is set for the main equipment and the supporting equipment of the base station. When the energy saving management system formulates the energy saving scheme, the operating status information of the main equipment of the base station can be used, and the running status information of the supporting equipment can also be used, and the state of the main equipment of the base station can also be used simultaneously. Information about the status of the information and the running status of the supporting equipment. In addition, the energy saving management system can also preset the energy saving policy. The energy saving management system combines the running status information acquired from the base station master device with the preset energy saving policy and/or obtained from the supporting device. The running status information can be used to formulate energy saving schemes for the base station master device and the supporting device. Specifically, the energy saving management system obtains the first energy saving control parameter for the base station master device, and the energy saving management system obtains the second energy saving control parameter for the supporting device, in each energy saving control. The parameter carries the energy-saving scheme separately formulated by the energy-saving management system for each device body, and after the energy-saving management system obtains the first energy-saving control parameter and the second energy-saving control parameter, the energy-saving management system sets the first energy-saving control parameter and the second energy-saving control system. Parameter Send it to the site controller.

404. The site controller sends the first energy-saving control parameter to the base station master device, and sends the second energy-saving control parameter to the accessory device.

In the embodiment of the present invention, after receiving the first energy-saving control parameter and the second energy-saving control parameter, the site controller sends the first energy-saving control parameter and the second energy-saving control parameter to the base station master device and the accessory device respectively. The base station master device and the accessory device can separately implement the energy-saving schemes formulated by the energy-saving management system, thereby reducing the energy consumption of each device body itself.

According to the description of the present invention, the base station master device and the accessory device in the site device respectively report the respective running state information to the site controller, and the site controller obtains the running state information of the base station master device and the running state of the accessory device. After the information, the site controller reports the running status information of the base station master device and the running state information of the supporting device to the energy saving management system, and the energy saving management system receives the running state information of the base station master device reported by the site controller and the running state information of the supporting device. After that, the energy-saving management system obtains the first energy-saving control parameter for the base station master device and the second energy-saving control parameter for the accessory device according to the running state information of the base station master device and/or the running state information of the accessory device, and the energy-saving management system will be the first energy-saving management system. The control parameter and the second energy-saving control parameter are sent to the site controller, and the site controller sends the first energy-saving control parameter to the base station master device, and sends the second energy-saving control parameter to the accessory device. In the present invention, the energy-saving management system monitors, processes, and analyzes the running status information of the base station main equipment and the running status information of the supporting equipment, respectively, and establishes energy-saving control parameters for the base station main equipment and the supporting equipment, respectively, and can implement multiple devices in the station equipment. The energy-saving linkage control between the two can greatly reduce the overall energy consumption of the site equipment and realize the intelligent management of energy efficiency of the site equipment.

The foregoing embodiment describes the energy-saving control method of the site device provided by the present invention from the perspective of the energy-saving management system and the site controller. Next, another embodiment of the energy-saving control method of the site device of the present invention is introduced, which can be applied to the base station master device. Referring to FIG. 5, a method for controlling energy saving of a site device according to an embodiment of the present invention may include the following steps:

501. The base station master device reports the running status information of the base station master device to the site controller.

In the embodiment of the present invention, the energy-saving management system is the main body of the energy-saving scheme, independent of the site controller, the site controller is the control entity of the site device, and the energy-saving management system is connected with the site controller, wherein the connection may be established. The wireless connection or the wired connection of the communication, the site controller is respectively connected with the base station master device and the accessory device in the site device, and the base station master device first obtains its own running state information, and then the base station master device passes the relationship with the site controller. The I/O interface reports the obtained running status information to the site controller. In the present invention, the energy-saving management system needs to obtain the running state information of the site device as the information necessary for formulating the energy-saving solution, and the running state information refers to the state data generated by the device body during the working process, and the running state information of the site device may be based on The status information that needs to be obtained by the energy-saving management system may be the same or different for each of the multiple devices included in the site device. The actual status of the site device and the energy-saving management system is used to determine the running status information. Specific content.

Specifically, in the embodiment of the present invention, the running status information may include at least one of the following information: power consumption information, temperature information, and energy saving state, and the power saving state includes: the base station master device turns on or off the energy saving mode. The energy-saving mode refers to the state in which the base station master device enters a shutdown or sleep state. When the energy-saving mode is enabled, the base station master device is in a state of being shut down or sleeping, and the power consumed by the base station is compared with the normal working mode. less. For the base station master device, the running status information may include: power consumption information of the base station master device, temperature information of the base station master device, and energy saving state of the base station master device, and the power saving state of the base station master device refers to that the base station master device is currently enabled. The energy-saving mode or the energy-saving mode is currently disabled. For the supporting device, the running status information may include: the power consumption information of the supporting device, the temperature information of the supporting device, and the energy-saving state of the supporting device. The energy-saving state of the supporting device refers to the supporting device. The power save mode is currently turned on or the power save mode is currently turned off. For example, the temperature information reported by the primary device of the base station is used to determine whether the operating temperature of the board is too high and the alarm generated when the working temperature of the board is too high. The temperature information of the supporting device mainly refers to the power device and the base station. The outdoor temperature of the equipment room where the main equipment is located, the indoor working environment temperature of the power supply equipment, the outdoor temperature and Indoor working environment temperature information is mainly used to control the starting or closing of ventilation equipment and refrigeration equipment.

It should be noted that, in the present invention, the running status information reported by the base station master device and the running status information reported by the accessory device may include one or more pieces of information of the foregoing content, and the content included in the running status information may also be managed according to energy saving. The system establishes the energy-saving scheme and adds other information content. The base station master device and the accessory device can still report the information that the energy-saving management system needs to report. For example, the operation status information of the base station master device may further include: the base station master device bearer The amount of traffic, that is, the base station master device reports the traffic carried by the base station controller to the site controller, and the energy-saving management system can obtain the traffic carried by the base station master device from the site controller, so the energy-saving management system can according to the traffic carried by the base station master device. To save energy-saving schemes for the base station main equipment and the supporting equipment, the site energy-saving technical solutions in the prior art do not study the management and control of the energy consumption of the station equipment according to the demand for energy consumption of the base station traffic. The present invention can collect the traffic carried by the base station master device in different time periods in the daytime by the base station master device, and the base station master device can also enable/disable the energy-saving mode according to the change of the traffic volume carried by the base station, and the energy-saving management system is formulated for the supporting device. The energy-saving scheme can also consider the factors that change the amount of traffic carried by the base station, thereby establishing the energy-saving linkage between the master device and the accessory device. Therefore, the energy consumption of the accessory device can be adjusted according to the busy and idle working state of the master device of the base station to reach the entire site. The equipment is optimal in energy efficiency.

In some embodiments of the present invention, before the base station master device reports the operation status information of the base station master device to the site controller, the method for saving energy of the site device provided by the present invention may further include the following steps:

The base station master device determines the energy-saving state of the base station master device according to the traffic volume carried by the base station master device and the preset energy-saving policy, or the base station master device determines the energy-saving state of the base station master device according to the energy-saving indication information received from the site controller.

In the implementation scenario of the step H1, the base station master device determines the current energy-saving state of the base station master device according to the traffic volume of the bearer and the preset energy-saving policy. According to the foregoing embodiment, the energy-saving state of the master device of the base station may refer to the base station master. The device enables or disables the energy-saving mode. The master device of the base station obtains the traffic carried by the master device of the base station, and determines whether the traffic carried by the master device of the base station exceeds a preset threshold or is less than a preset threshold. For example, the base station master device determines that the service volume carried by the base station master device is too large or too small. If the base station master device determines that the service volume carried by the base station master device is too large, the base station master device does not enable the energy-saving mode, and if the energy-saving management system determines If the traffic carried by the primary device of the base station is too small, the energy-saving management system instructs the primary device of the base station to enable the energy-saving mode. In addition, the amount of traffic carried by the base station master device used by the base station master device to determine the energy-saving state of the base station master device may refer to the traffic volume carried by the current base station master device, and may also refer to the current and previous historical time period of the base station master device. The amount of traffic carried by the carrier.

In the implementation scenario of the foregoing step H1, in further, in step 501, the base station master device reports the running state information of the base station master device to the site controller, which is specifically as follows:

The base station master device carries the determined energy-saving state in the running state information and sends it to the site controller, and the site controller sends the energy-saving state to the energy-saving management system.

Specifically, in the second type of determining the energy-saving state of the base station, the base station master device sends the traffic carried by the base station to the site controller, and the site controller reports the energy-saving management system to the energy-saving management system. The system can obtain the energy-saving indication information according to the traffic carried by the primary device of the base station and the preset energy-saving policy. Therefore, the energy-saving management system can separately formulate energy-saving solutions for the primary device and the supporting device according to the traffic carried by the primary device of the base station. The site energy-saving technical solutions in the technology do not study the management and control of the energy consumption of the site equipment according to the demand for energy consumption of the change of the base station traffic. The present invention can collect the traffic carried by the base station master device in different time periods in the daytime by the base station master device, and the base station master device can also enable/disable the energy-saving mode according to the change of the traffic volume carried by the base station, and the energy-saving management system is formulated for the supporting device. The energy-saving scheme can also consider the factors that change the amount of traffic carried by the base station, thereby establishing the energy-saving linkage between the master device and the accessory device. Therefore, the energy consumption of the accessory device can be adjusted according to the busy and idle working state of the master device of the base station to reach the entire site. The equipment is optimal in energy efficiency.

502. The base station master device receives the first energy-saving control parameter sent by the site controller.

In the embodiment of the present invention, after the site controller receives the running status information reported by the base station master device, the site controller reports the running state information of the base station master device to the energy saving management system, and the energy saving management system obtains the first time for the base station master device. The energy-saving control parameter, the site controller acquires the first energy-saving control parameter from the energy-saving management system, and then the site controller sends the first energy-saving control parameter to the base station master device.

503. The base station master device determines, according to the first energy-saving control parameter, whether to change the energy-saving state of the base station master device, where the power-saving state includes: the base station master device turns on or disables the energy-saving mode.

In the embodiment of the present invention, the site controller sends the first energy-saving control parameter and the second energy-saving control parameter to the base station master device and the accessory device respectively, and the base station master device may perform the energy-saving solution formulated by the energy-saving management system according to the first energy-saving control parameter. , thereby reducing the energy consumption of the base station master device itself.

In some embodiments of the present invention, the base station master device in step 503 is determined according to the first energy saving control parameter. Whether the energy saving state of the base station master device is changed may include the following steps:

I1. If the first energy-saving control parameter indicates that the base station primary device service time needs to be extended and the base station master device currently turns off the power-saving mode, the base station master device changes the current power-off mode to the power-saving mode.

I2. If the first energy-saving control parameter indicates that the base station master device turns off the power-saving mode and the base station master device currently turns on the power-saving mode, the base station master device changes the current power-on mode to the power-off mode.

In the implementation scenario described in step I1, the base station master device is in the power-saving mode, that is, the base station master device is in the normal working mode, and the energy-saving management system determines whether the standby device energy state of the accessory device satisfies the first condition, and if the standby device has the backup energy The state meets the first condition. This indicates that the energy reserve of the supporting device is sufficient to ensure the normal operation of the primary device of the base station. If the standby energy state of the supporting device does not satisfy the first condition, the energy reserve of the supporting device is less than sufficient. To ensure normal operation of the primary device of the base station, the energy-saving management system obtains, for the primary device of the base station, the first energy-saving control parameter that needs to extend the service time of the primary device of the base station, and after receiving the first energy-saving control parameter from the site controller, the primary device of the base station You can change the current power saving state and change the current power saving mode to the energy saving mode.

In the implementation scenario described in step I2, the base station master device starts the energy-saving mode, that is, the base station master device is in a state of being shut down or sleeping, and the energy-saving management system determines whether the standby power state of the accessory device satisfies the second condition, and the second condition It may be a condition in the energy saving policy set in the energy saving management system. If the standby energy state of the supporting device satisfies the second condition, this indicates that the energy reserve of the supporting device is sufficient, and the normal operation of the base station master device can be ensured. In the case that the energy-saving management system acquires the first energy-saving control parameter for changing the energy-saving state of the base station master device, after the base station master device receives the first energy-saving control parameter from the site controller, the base station master device may change the current energy-saving state, and the current Turn on the power save mode to turn off the power save mode.

According to the description of the present invention, the base station master device and the accessory device in the site device respectively report the respective running state information to the site controller, and the site controller obtains the running state information of the base station master device and the running state of the accessory device. After the information, the site controller reports the running status information of the base station master device and the running state information of the supporting device to the energy saving management system, and the energy saving management system receives the running state information of the base station master device reported by the site controller and the running state information of the supporting device. After that, the energy-saving management system obtains the first energy-saving control parameter for the base station master device and the second energy-saving control parameter for the accessory device according to the running state information of the base station master device and/or the running state information of the accessory device, and the energy-saving management system will be the first energy-saving management system. Control parameters and second energy saving control parameters are sent to the site The controller, the site controller sends the first energy-saving control parameter to the base station master device, and sends the second energy-saving control parameter to the accessory device. In the present invention, the energy-saving management system monitors, processes, and analyzes the running status information of the base station main equipment and the running status information of the supporting equipment, respectively, and establishes energy-saving control parameters for the base station main equipment and the supporting equipment, respectively, and can implement multiple devices in the station equipment. The energy-saving linkage control between the two can greatly reduce the overall energy consumption of the site equipment and realize the intelligent management of energy efficiency of the site equipment.

The foregoing embodiment describes the energy-saving control method of the site device provided by the present invention from the perspectives of the energy-saving management system, the site controller, and the base station master device. Next, another embodiment of the energy-saving control method of the site device of the present invention is introduced, which can be applied to For the supporting device associated with the base station master device in the site device, refer to FIG. 6 , the method for controlling the energy saving of the site device provided by the embodiment of the present invention may include the following steps:

601. The accessory device reports the running status information of the accessory device to the site controller, where the accessory device is one or more devices associated with the base station master device in the site device.

In the embodiment of the present invention, the energy-saving management system is the main body of the energy-saving scheme, independent of the site controller, the site controller is the control entity of the site device, and the energy-saving management system is connected with the site controller, wherein the connection may be established. The wireless connection or the wired connection of the communication, the site controller is respectively connected with the base station master device and the accessory device in the site device, and the accessory device first obtains its own running state information, and then the accessory device passes the I/ between the site controller and the site controller. The O interface reports the obtained running status information to the site controller. In the present invention, the energy-saving management system needs to obtain the running state information of the site device as the information necessary for formulating the energy-saving solution, and the running state information refers to the state data generated by the device body during the working process, and the running state information of the site device may be based on The status information that needs to be obtained by the energy-saving management system may be the same or different for each of the multiple devices included in the site device. The actual status of the site device and the energy-saving management system is used to determine the running status information. Specific content.

Specifically, in the embodiment of the present invention, the running status information may include at least one of the following information: power consumption information, temperature information, energy saving state, and standby energy state, and the energy saving state includes: the supporting device turns on or off the energy saving mode. . The energy-saving mode means that the accessory device enters a state of shutdown or hibernation. When the energy-saving mode is enabled, the accessory device is in a state of being shut down or sleeping, and the power consumed by itself is less than the normal operation mode. . For the supporting device, the running status information may include: power consumption information of the supporting device, temperature information of the supporting device, and energy saving of the supporting device. State, the energy-saving status of the supporting equipment refers to the energy-saving mode of the supporting equipment currently being turned on or the energy-saving mode is currently turned off.

It should be noted that, in the present invention, the running status information reported by the base station master device and the running status information reported by the accessory device may include one or more pieces of information of the foregoing content, and the content included in the running status information may also be managed according to energy saving. The system establishes the energy-saving scheme and adds other information content. The base station master device and the accessory device can still report the information that the energy-saving management system needs to report. For example, the running status information of the accessory device may also include: the indoor working of the power device. Ambient temperature and outdoor temperature at the site's equipment room.

In some embodiments of the present invention, the energy saving control method of the site device provided by the present invention may further include the following steps: Before the accessory device reports the running state information of the accessory device to the site controller.

J1. The supporting equipment determines the energy-saving status of the supporting equipment according to the standby energy status, temperature information and preset energy-saving strategies of the supporting equipment.

In the implementation scenario of the step J1, the standby energy state of the accessory device refers specifically to the standby energy state of the power device. The accessory device determines the power state, temperature information, and preset energy-saving policies of the power device. According to the foregoing embodiments, the energy-saving state of the power device can be related to the energy-saving mode of the device, and the control device of the device obtains the power-off state of the power device, and is determined by combining the preset energy-saving policies. Whether the backup device of the power device exceeds the preset threshold or is less than the preset threshold. For example, the control device determines whether the backup device's backup energy is too much or too little. If the power supply device is powered off, the power supply device turns on the power-saving mode. The supporting device control unit obtains the indoor working environment temperature and the outdoor temperature of the power equipment and the equipment room where the base station main equipment is located, and combines a preset energy saving strategy to determine whether the indoor working environment temperature exceeds a preset threshold, or is less than a preset threshold, and Determine whether the indoor working environment temperature is greater than the outdoor temperature. For example, if the supporting equipment control unit determines that the outdoor temperature is lower than the indoor working environment temperature, the ventilation device needs to turn off the energy saving mode, and the cooling device can turn on the energy saving mode if the outdoor temperature is higher than the indoor temperature. In the working environment temperature, the cooling device needs to turn off the energy saving mode, and the ventilation device can turn on the energy saving mode.

In the implementation scenario of the foregoing step J1, the device in step 601 reports the running status information of the accessory device to the site controller, which is specifically as follows:

The supporting device carries the determined energy saving state in the running status information and sends it to the site controller, and the site controller sends the energy saving state to the energy saving management system.

After the accessory device determines its own energy-saving status, the accessory device sends its current energy-saving status to the site controller, or the accessory device sends its current energy-saving status to the accessory device control unit, and the accessory device control unit sends the message to the site. The controller is reported to the energy-saving management system by the site controller. The energy-saving management system can determine whether the energy-saving state of the accessory device needs to be changed according to the current energy-saving state of the accessory device, and the energy-saving management system indicates the accessory device by using the second energy-saving control parameter. .

602. The accessory device receives a second energy-saving control parameter sent by the site controller.

In the embodiment of the present invention, after the site controller receives the running status information reported by the accessory device, the site controller reports the running state information of the accessory device to the energy saving management system, and the energy saving management system obtains the second energy saving control parameter for the supporting device. The site controller obtains the second energy-saving control parameter from the energy-saving management system, and then the site controller sends the second energy-saving control parameter to the accessory device, or the site controller sends the second energy-saving control parameter to the accessory device through the accessory device control unit.

603. The supporting device determines, according to the second energy-saving control parameter, whether to change the energy-saving state of the accessory device, and the energy-saving state includes: the accessory device turns the energy-saving mode on or off.

In the embodiment of the present invention, the site controller sends the first energy-saving control parameter and the second energy-saving control parameter to the base station main device and the accessory device respectively, and the accessory device may perform the energy-saving solution formulated by the energy-saving management system according to the second energy-saving control parameter. Thereby reducing the energy consumption of the supporting equipment itself.

In some embodiments of the present invention, the step 603 determines whether to change the energy-saving state of the accessory device according to the second energy-saving control parameter, and specifically includes the following steps:

K1. If the second energy-saving control parameter indicates that the accessory device is in the energy-saving mode and the accessory device is currently enabled with the energy-saving mode, the accessory device changes the current energy-saving mode to the power-saving mode.

K2. If the second energy-saving control parameter indicates that the accessory device is in the energy-saving mode and the accessory device is currently in the energy-saving mode, the accessory device changes the current power-off mode to the energy-saving mode.

In the implementation scenarios of the steps K1 and K2, the energy-saving management system performs the steps B1 and B2 in the foregoing embodiment, as shown in FIG. 3-b, which is another schematic diagram of the energy-saving linkage state transition provided by the embodiment of the present invention. In Figure 3-b, the energy-saving linkage dynamic conversion is supplemented by the supporting equipment, and the primary equipment of the base station is the main. The energy-saving management system obtains the second energy-saving control parameter for the supporting equipment according to the running status information of the primary equipment of the base station and the running status information of the supporting equipment. , specific, the second energy-saving control parameters of the supporting equipment It can be set according to the energy-saving state of the master device of the base station, and the second energy-saving control parameter set by the energy-saving management system for the accessory device can implement energy-saving linkage control between the base station master device and the accessory device.

In some embodiments of the present invention, the supporting device includes: a ventilation device, a cooling device, and a power supply device. In this implementation scenario, the accessory device determines, according to the second energy-saving control parameter, whether to change the energy-saving state of the accessory device. It can include the following steps:

L1. If the second energy-saving control parameter indicates that the operating ventilation device extracts the outdoor cold air to reduce the indoor working environment temperature, the ventilation device turns off the energy-saving mode, and then extracts the outdoor cold air to the power equipment and the equipment room where the base station main device is located;

L2. If the second energy-saving control parameter indicates that the operating refrigeration device reduces the indoor working environment temperature, the cooling device turns off the energy-saving mode, and then starts to generate cold air to be delivered to the power device and the equipment room where the base station master device is located.

In the above embodiment of the present invention, the energy-saving management system can implement intelligent ventilation and intelligent cooling for the second energy-saving control parameter acquired by the accessory device, and the accessory device control unit needs to collect the outdoor temperature and the indoor working environment temperature and report to the site controller, the site. The controller then sends the outdoor temperature and the indoor working environment temperature to the energy-saving management system. Further, in the scenario of step L1 and step L2 in the present invention, the accessory device control unit can collect the outdoor temperature and the indoor working environment temperature in real time, then the ventilation device The refrigeration equipment can perform steps L1 and L2 once after each set of outdoor temperature and indoor working environment temperature is acquired, so the ventilation equipment and the refrigeration equipment need to execute the second energy-saving control parameters in real time. In the existing energy-saving technical solutions of the base station main equipment or ancillary equipment, the control parameters for turning on and off the energy-saving function (such as the threshold of the air conditioner on/off, the condition of the oil on/off, etc.) are usually after the initial configuration. It is unchanged and cannot be adjusted according to the traffic fluctuation and the external climate change application scenario. In the present invention, the temperature information of the accessory device can be collected in real time, and the power consumption of the base station master device and the accessory device can be adaptively adjusted. Realize dynamic optimization management of site equipment energy consumption.

According to the description of the present invention, the base station master device and the accessory device in the site device respectively report the respective running state information to the site controller, and the site controller obtains the running state information of the base station master device and the running state of the accessory device. After the information, the site controller reports the running status information of the base station master device and the running state information of the supporting device to the energy saving management system, and the energy saving management system receives the running state information of the base station master device reported by the site controller and the running state information of the supporting device. After that, the energy-saving management system obtains the first energy-saving control parameter for the base station master device and the second energy-saving for the accessory device according to the running state information of the master device of the base station and/or the running state information of the accessory device. The control parameter, the energy-saving management system sends the first energy-saving control parameter and the second energy-saving control parameter to the site controller, and the site controller sends the first energy-saving control parameter to the base station master device, and sends the second energy-saving control parameter to the accessory device. . In the present invention, the energy-saving management system monitors, processes, and analyzes the running status information of the base station main equipment and the running status information of the supporting equipment, respectively, and establishes energy-saving control parameters for the base station main equipment and the supporting equipment, respectively, and can implement multiple devices in the station equipment. The energy-saving linkage control between the two can greatly reduce the overall energy consumption of the site equipment and realize the intelligent management of energy efficiency of the site equipment.

To facilitate a better understanding and implementation of the foregoing solutions of the embodiments of the present invention, the following application scenarios are specifically illustrated.

The energy-saving control method of the site device provided by the present invention can solve the problem of how the site device can implement the energy-saving linkage with reference to the change of the service volume, so that the site device can adjust the energy consumption of the accessory device according to the energy-saving state of the base station master device, so as to reach the entire site device. The best energy efficiency. It can solve the automatic adjustment of the working parameters of the site device according to the application scenario of traffic fluctuation and external climate change, or trigger the base station master device to enable the energy-saving mode to achieve adaptive optimization management of the site device energy consumption. Next, the energy-saving management system specifically includes: a self-organizing network (SON, Self Organization Network) energy-saving control system and an operation support system (OSS) network management system, and then an example of SON-based site equipment energy-saving linkage control is illustrated. The network upper-layer software can be fully utilized to calculate and process the information and advantages of the site equipment, so as to realize the adaptive optimization management of the energy consumption of the site equipment. FIG. 7 is a schematic diagram of an implementation architecture of a SON-based site device energy-saving linkage according to an embodiment of the present invention, which may include: a SON energy-saving control system, an OSS network management system, a site controller, an accessory device, and a base station. Master device.

Among them, the main functions of each device body shown in Figure 7-a are as follows:

1) Set the site control unit in the site controller. The site control unit is connected to the base station master device through the I/O interface. The site control unit is connected to the accessory device control unit through the I/O interface. The main functions of the site controller are as follows: The operating status information of the base station master device and the accessory device, including: power consumption information, temperature information, and backup power state (for example, power and oil amount information); and transmitting the first energy saving control parameter and the second energy saving control parameter in the second The energy saving control parameter and the second energy saving control parameter include energy saving linkage control information.

2) The OSS network management system is connected to the site controller. The main functions of the OSS network management system are as follows: Processing and analysis of operational status information (including energy consumption data) of the primary and secondary equipment of the base station; visual presentation of energy consumption of the station equipment; status monitoring of the primary equipment and supporting equipment of the base station; sharing of information about the equipment of the station with the SON energy-saving control system .

3), SON energy-saving control system and OSS network management system connection, SON energy-saving control system main functions are as follows: the first energy-saving control parameters and the second energy-saving control parameters calculation and optimization; site equipment energy-saving linkage process control; site equipment energy consumption Adaptive management strategy; big data analysis and intelligent optimization of energy consumption.

4) The supporting device control unit is connected to the site controller through the I/O interface. The main functions of the supporting device control unit are as follows: collecting the running status information of the supporting device (including: power consumption data); interacting with the site controller; receiving SON The second energy-saving control parameter issued by the energy-saving control system; sending a control signal to the accessory device. The supporting equipment may include: a power supply device, a ventilation device, and a refrigeration device, and the power supply device includes one or more of the following: a solar power supply device, a wind power supply device, an oil machine power supply device, a utility power supply device, a scenery, a wind oil, Lubricating oil and wind oil hybrid power supply equipment.

Based on the composition structure as described above, refer to FIG. 7-b, which is a flow chart of the energy-saving linkage control algorithm of the site device provided by the embodiment of the present invention, and the work of the energy-saving control method of the site device of the present invention is performed by using the example of the process. The principle is explained:

The master device sends the traffic of the load to the site controller, and the accessory device sends the standby energy state to the site controller. The OSS network management system/SON energy-saving control system determines the service load change status or the preset energy-saving policy of the base station master device. Whether the base station master device is allowed to enable the energy-saving mode, and the power consumption data reported by the site device is presented in a visual form such as a chart. After determining whether the base station master device is in the power-saving mode, if the base station master device is in the power-saving mode, if the power-off state of the power-supply device can support the power-on request of the base station master device, the SON energy-saving control system triggers the base station. The master device turns on the power-saving mode to extend the service time of the base station master device. If the base station master device is in the power-saving mode, the SON energy-saving control system starts the energy-saving linkage control function, and calculates the first energy-saving control parameter of the base station master device and the second energy-saving control parameter of the accessory device, and then sends the adjustment support to the site controller. The control information of the working energy parameter of the device, the site controller sends the first energy saving control parameter and the second energy saving control parameter to the interface of the base station main device or the supporting device according to the device address in the SON energy saving control system. The site controller sends an energy consumption control signal to the corresponding device device, and the base station master device determines whether to convert the current working mode according to the received first energy saving control parameter, thereby determining whether to enter the energy saving linkage working mode, or the base station receives the SON energy saving control system request Delay The long service time instruction turns on the power saving mode and enters the low power state. The OSS network management system detects the running status information reported by the site device, and displays the power consumption changes of all the devices of the site device. At the same time, the related data is transmitted to the SON energy-saving control system, so that it can recalculate the energy-saving control parameters of the site device, or evaluate the energy-saving linkage. Effect. SON energy-saving control system adopts big data statistics and analysis method to continuously optimize the calculation model and control algorithm of site equipment energy-saving linkage parameters, so as to realize adaptive optimization management of site equipment energy consumption. Specifically, SON energy-saving control system can collect longer The running status information of the site equipment is calculated for a period of time.

FIG. 7 is a schematic diagram of another implementation architecture of the SON-based site device energy-saving linkage according to the embodiment of the present invention, which may include: a SON energy-saving control system, an OSS network management system, a site controller, and an accessory device. Base station master device.

Among them, the main functions of each device body shown in Figure 7-c are as follows:

1) The site control unit is set in the site controller, and the site control unit is connected to the BBU in the base station master device through the I/O interface, the base station master device is a distributed base station, and the BBU is connected with RRU1, RRU2, ..., RRUn, and site control. The unit is connected to the control unit of the accessory device through the I/O interface. The main functions of the site controller are as follows: report the running status information of the master device and the accessory device, including: power consumption information, temperature information, and backup energy status (such as power and The oil quantity information is transmitted; the first energy saving control parameter and the second energy saving control parameter are distributed, and the energy saving linkage control information is included in the first energy saving control parameter and the second energy saving control parameter.

2) The OSS network management system is connected to the site controller. The main functions of the OSS network management system are as follows: processing and analyzing the operational status information (including energy consumption data) of the base station primary equipment and supporting equipment; and visualizing the energy consumption of the station equipment; Status monitoring of the primary and secondary equipment of the base station; information about the site equipment is shared with the SON energy-saving control system.

3), SON energy-saving control system and OSS network management system connection, SON energy-saving control system main functions are as follows: the first energy-saving control parameters and the second energy-saving control parameters calculation and optimization; site equipment energy-saving linkage process control; site equipment energy consumption Adaptive management strategy; big data analysis and intelligent optimization of energy consumption.

4) The supporting device control unit is connected to the site controller through the I/O interface. The main functions of the supporting device control unit are as follows: collecting the running status information of the supporting device (including: power consumption data); interacting with the site controller; receiving SON The second energy-saving control parameter issued by the energy-saving control system; sending a control signal to the accessory device. Among them, the supporting equipment may include: power equipment, ventilation equipment, refrigeration Equipment, power equipment includes one or more of the following: solar power equipment, wind power equipment, oil power equipment, utility power equipment, wind, wind, varnish, wind oil hybrid power supply equipment.

FIG. 7 is a schematic diagram of another implementation architecture of the SON-based site device energy-saving linkage according to the embodiment of the present invention, which may include: a SON energy-saving control system, an OSS network management system, a site controller, and an accessory device. Base station master device.

Among them, the main functions of each device body shown in Figure 7-d are as follows:

1) The control unit is set in the site controller, and the BBU in the base station master device is directly integrated into the base station controller, and the BBU is connected to the control unit in the base station controller, and the control unit passes the I/O interface and the RRU in the base station master device. Connected, the base station master device is a distributed base station, and the BBU is connected to RRU1, RRU2, ..., RRUn. The control unit is connected to the supporting device through the I/O interface, which is different from the foregoing implementation manners of FIG. 7-a and FIG. 7-c. In the implementation manner of Figure 7-d, the control unit in the supporting device control unit and the site controller is integrated into a control unit, and the control unit in the site controller directly obtains the running status information of the supporting device through the supporting device I/O interface. The main functions of the site controller are as follows: report the running status information of the base station master device and the accessory device, including: power consumption information, temperature information, backup power state (such as power and oil amount information); and distribute the first energy-saving control parameter And the second energy saving control parameter, the energy saving linkage control information is included in the first energy saving control parameter and the second energy saving control parameter.

2) The OSS network management system is connected to the site controller. The main functions of the OSS network management system are as follows: processing and analyzing the operational status information (including energy consumption data) of the base station primary equipment and supporting equipment; and visualizing the energy consumption of the station equipment; Status monitoring of the primary and secondary equipment of the base station; information about the site equipment is shared with the SON energy-saving control system.

3), SON energy-saving control system and OSS network management system connection, SON energy-saving control system main functions are as follows: the first energy-saving control parameters and the second energy-saving control parameters calculation and optimization; site equipment energy-saving linkage process control; site equipment energy consumption Adaptive management strategy; big data analysis and intelligent optimization of energy consumption.

4) The I/O interface of the supporting device is connected with the site controller. The main functions of the I/O interface of the supporting device are as follows: collecting the running status information of the supporting device (including: power consumption data); interacting with the site controller; receiving SON energy saving The second energy-saving control parameter delivered by the control system; the control signal is sent to the accessory device. The supporting equipment may include: a power supply device, a ventilation device, and a refrigeration device, and the power supply device includes one or more of the following: a solar power supply device, a wind power supply device, an oil machine power supply device, Mains power supply equipment, scenery, wind oil, varnish, wind oil hybrid power supply equipment.

It should be noted that, for the foregoing method embodiments, for the sake of simple description, they are all expressed as a series of action combinations, but those skilled in the art should understand that the present invention is not limited by the described action sequence. Because certain steps may be performed in other sequences or concurrently in accordance with the present invention. In addition, those skilled in the art should also understand that the embodiments described in the specification are all preferred embodiments, and the actions and modules involved are not necessarily required by the present invention.

In order to facilitate the implementation of the above solution of the embodiments of the present invention, related devices for implementing the above solutions are also provided below.

Referring to FIG. 8-a, an energy-saving management system 800 according to an embodiment of the present invention may include: a receiving module 801, an energy-saving control parameter obtaining module 802, and a sending module 803, where

The receiving module 801 is configured to receive operation state information of the base station master device reported by the site controller, and operation state information of the accessory device related to the base station master device in the site device;

The energy-saving control parameter obtaining module 802 is configured to acquire the first energy-saving control parameter for the base station master device and obtain the first power-saving control parameter for the base station master device according to the running state information of the base station master device and/or the running state information of the accessory device. Second energy saving control parameters;

The sending module 803 is configured to send the first power saving control parameter and the second power saving control parameter to the site controller.

In some embodiments of the present invention, the operating state information of the base station master device includes: a power saving state of the base station master device, and the power saving state of the base station master device includes: the base station master device turning on or off the power saving mode;

The operation status information of the accessory device includes: a backup energy state of the accessory device and a power saving state of the accessory device, and the energy-saving state of the accessory device includes: the accessory device turning on or off the energy-saving mode;

Referring to FIG. 8-b, the energy-saving control parameter obtaining module 802 includes:

The first control module 8021 is configured to determine, when the energy-saving management system determines, according to the operating state information of the base station master device, that the base station master device is in the power-saving mode, whether the standby power state of the accessory device meets a preset a first condition, if the standby energy state of the accessory device does not meet the first condition, acquiring, by the base station master device, a first energy-saving control parameter that needs to extend the service time of the base station master device, if the accessory If the backup energy state of the device does not meet the first condition and the accessory device turns off the energy-saving mode, the second energy-saving control parameter that changes the energy-saving state is obtained for the accessory device. number;

The second control module 8022 is configured to determine, when the energy-saving management system determines, according to the operating state information of the base station master device, that the base station master device starts the energy-saving mode, whether the standby energy state of the accessory device meets a preset And the second condition, if the standby energy state of the accessory device meets the second condition, obtaining, by the base station master device, a first energy-saving control parameter that changes a power-saving state, if the standby energy state of the accessory device meets When the second condition is that the accessory device is in the energy-saving mode, the second energy-saving control parameter that changes the energy-saving state is obtained for the accessory device.

In some embodiments of the present invention, the operating state information of the base station master device includes: a power saving state of the base station master device, and the power saving state of the base station master device includes: the base station master device turning on or off the power saving mode;

The operation status information of the accessory device includes: the energy-saving state of the accessory device, and the energy-saving state of the accessory device includes: the accessory device turns the energy-saving mode on or off;

The energy-saving control parameter obtaining module 802 is specifically configured to: when the energy-saving management system determines, according to the operating state information of the base station master device, that the base station master device turns off the energy-saving mode, if the accessory device starts the energy-saving mode, The accessory device obtains a second energy-saving control parameter that changes the energy-saving state; when the energy-saving management system determines that the base station master device starts the energy-saving mode according to the operating state information of the base station master device, if the accessory device turns off the energy-saving mode And obtaining, for the accessory device, a second energy-saving control parameter that changes a power-saving state.

In some embodiments of the present invention, the accessory device includes: a ventilation device, a cooling device, and a power supply device, and the running status information of the accessory device includes: the outdoor temperature of the power supply device and the equipment room where the base station is located And an indoor working environment temperature of the power supply device;

The energy-saving control parameter obtaining module 802 is specifically configured to: when the indoor working environment temperature of the power supply device is higher than a preset temperature threshold, and the outdoor temperature is lower than the indoor working environment temperature, obtain the operating ventilation The device extracts the second energy-saving control parameter that the outdoor cold air reduces the temperature of the indoor working environment; when the indoor working environment temperature of the power device is higher than a preset temperature threshold, and the outdoor temperature is higher than the indoor working environment temperature And acquiring a second energy-saving control parameter that runs the refrigeration device to reduce the temperature of the power device.

In some embodiments of the present invention, as shown in FIG. 8-c, the energy-saving management system 800 further includes: an energy-saving indication module 804, where the receiving module 801 receives the base station master device reported by the site controller. Operation status information and associated equipment associated with the base station master device in the site device After the running state information, if the running state information of the base station master device includes the traffic volume carried by the base station master device, the energy saving indication information is obtained according to the traffic volume carried by the base station master device and the preset energy saving policy, The energy saving indication information includes: the energy saving management system determines whether the base station master device is allowed to enable or disable the energy saving mode;

The sending module 803 is further configured to send the energy saving indication information to the site controller, where the site controller sends the energy saving indication information to the base station master device.

In some embodiments of the present invention, as shown in FIG. 8-d, the energy-saving management system 800 further includes: a display processing module 805, configured to receive, by the receiving module 801, a base station master device reported by the site controller. After the operating state information and the running state information of the associated device related to the base station master device, if the operating state information of the base station master device includes power consumption information of the base station master device, and the running state information of the accessory device The power consumption information of the accessory device is displayed, and the power consumption information of the base station master device and the power consumption information of the accessory device are visualized by a graph; and the power consumption information of the base station master device and the function of the accessory device are The information consumption obtains the energy saving effect, and the energy saving effect is presented through the chart visualization.

According to the description of the present invention, the base station master device and the accessory device in the site device respectively report the respective running state information to the site controller, and the site controller obtains the running state information of the base station master device and the running state of the accessory device. After the information, the site controller reports the running status information of the base station master device and the running state information of the supporting device to the energy saving management system, and the energy saving management system receives the running state information of the base station master device reported by the site controller and the running state information of the supporting device. After that, the energy-saving management system obtains the first energy-saving control parameter for the base station master device and the second energy-saving control parameter for the accessory device according to the running state information of the base station master device and/or the running state information of the accessory device, and the energy-saving management system will be the first energy-saving management system. The control parameter and the second energy-saving control parameter are sent to the site controller, and the site controller sends the first energy-saving control parameter to the base station master device, and sends the second energy-saving control parameter to the accessory device. In the present invention, the energy-saving management system monitors, processes, and analyzes the running status information of the base station main equipment and the running status information of the supporting equipment, respectively, and establishes energy-saving control parameters for the base station main equipment and the supporting equipment, respectively, and can implement multiple devices in the station equipment. The energy-saving linkage control between the two can greatly reduce the overall energy consumption of the site equipment and realize the intelligent management of energy efficiency of the site equipment.

Referring to FIG. 9 , a site controller 900 provided by an embodiment of the present invention may include: an obtaining module 901, a first sending module 902, a receiving module 903, and a second sending module 904, where

The obtaining module 901 is configured to acquire running state information of the base station master device, and acquire the site setting Running state information of the accessory device related to the base station master device;

The first sending module 902 is configured to report the running state information of the base station master device and the running state information of the accessory device to the energy saving management system;

The receiving module 903 is configured to receive the first energy-saving control parameter and the second energy-saving control parameter sent by the energy-saving management system, where the first energy-saving control parameter is the operating state of the energy-saving management system according to the base station master device The information and/or the running status information of the supporting device is acquired by the base station master device, and the second energy saving control parameter is that the energy saving management system is based on the operating state information of the base station master device and/or the supporting device. The running status information is obtained by the accessory device;

The second sending module 904 is configured to send the first power saving control parameter to the base station master device, and send the second power saving control parameter to the accessory device.

In some embodiments of the present invention, the acquiring module 901 is specifically configured to receive, by using a site control unit in the site controller, operation state information reported by the base station master device, where the site control unit passes the input and output I. The O/O interface is connected to the base station master device; or the site controller receives the running status information reported by the baseband processing unit BBU in the base station master device by using a site control unit in the site controller, the site The control unit is connected to the BBU through an I/O interface; and receives, by the station control unit in the site controller, operational status information collected by the accessory device control unit from the accessory device, and the site control unit passes the I/ The O interface is connected to the supporting device control unit.

In some embodiments of the present invention, the acquiring module 901 is specifically configured to receive, by using a control unit in the site controller and a BBU in the base station master device, a radio remote unit RRU in the base station master device. The operating status information is reported, the control unit is connected to the RRU through an I/O interface, and the operating status information reported by the accessory device is received by the control unit in the site controller, and the control unit passes the I/O The interface is connected to the accessory device.

In some embodiments of the present invention, the operating state information includes at least one of the following information: power consumption information, temperature information, energy saving state, and backup energy state, where the power saving state includes: a base station master device, and a matching The device turns the power save mode on or off.

According to the description of the present invention, the base station master device and the accessory device in the site device respectively report the respective running state information to the site controller, and the site controller obtains the running state information of the base station master device and the running state of the accessory device. After the information, the site controller reports the running status information of the base station main device and the running status information of the supporting device to the energy saving management system, and the energy saving management system is connected. After receiving the running status information of the base station master device and the running status information of the accessory device, the energy-saving management system obtains the first base station master device according to the running state information of the base station master device and/or the running state information of the accessory device. The energy-saving control parameter and the second energy-saving control parameter are obtained for the accessory device, and the energy-saving management system sends the first energy-saving control parameter and the second energy-saving control parameter to the site controller, and the site controller sends the first energy-saving control parameter to the base station master device The second energy saving control parameter is sent to the accessory device. In the present invention, the energy-saving management system monitors, processes, and analyzes the running status information of the base station main equipment and the running status information of the supporting equipment, respectively, and establishes energy-saving control parameters for the base station main equipment and the supporting equipment, respectively, and can implement multiple devices in the station equipment. The energy-saving linkage control between the two can greatly reduce the overall energy consumption of the site equipment and realize the intelligent management of energy efficiency of the site equipment.

Referring to FIG. 10, a base station main device 1000 according to an embodiment of the present invention may include: a sending module 1001, a receiving module 1002, and an energy saving control module 1003, where

The sending module 1001 is configured to report, to the site controller, operation state information of the base station master device;

The receiving module 1002 is configured to receive a first energy saving control parameter sent by the site controller.

The energy-saving control module 1003 is configured to determine, according to the first energy-saving control parameter, whether to change a power-saving state of the base station master device, where the power-saving state includes: the base station master device turns on or disables a power-saving mode.

In some embodiments of the present invention, the energy-saving control module 1003 is further configured to determine, according to the traffic volume carried by the base station master device and a preset energy-saving policy, a power-saving state of the base station master device, or the base station master The device determines, according to the energy saving indication information received from the site controller, a power saving state of the base station master device;

The sending module 1001 is specifically configured to carry the determined energy saving state in the operating state information and send the information to the site controller, where the site controller sends the energy saving state to the energy saving management system.

In some embodiments of the present invention, the energy saving control module 1003 is specifically configured to: if the first energy saving control parameter indicates that the base station primary device service time needs to be extended, and the base station primary device currently turns off the energy saving mode, Changing the current power-saving mode to the power-saving mode; if the first power-saving control parameter indicates that the base station master turns off the power-saving mode and the base station master currently enables the energy-saving mode, then the current power-on mode is changed to Turn off the power save mode.

In some embodiments of the present invention, the operating state information includes at least one of the following information: power consumption information, temperature information, and a power saving state, where the power saving state includes: the base station master device is turned on. Turn the energy saving mode on or off.

According to the description of the present invention, the base station master device and the accessory device in the site device respectively report the respective running state information to the site controller, and the site controller obtains the running state information of the base station master device and the running state of the accessory device. After the information, the site controller reports the running status information of the base station master device and the running state information of the supporting device to the energy saving management system, and the energy saving management system receives the running state information of the base station master device reported by the site controller and the running state information of the supporting device. After that, the energy-saving management system obtains the first energy-saving control parameter for the base station master device and the second energy-saving control parameter for the accessory device according to the running state information of the base station master device and/or the running state information of the accessory device, and the energy-saving management system will be the first energy-saving management system. The control parameter and the second energy-saving control parameter are sent to the site controller, and the site controller sends the first energy-saving control parameter to the base station master device, and sends the second energy-saving control parameter to the accessory device. In the present invention, the energy-saving management system monitors, processes, and analyzes the running status information of the base station main equipment and the running status information of the supporting equipment, respectively, and establishes energy-saving control parameters for the base station main equipment and the supporting equipment, respectively, and can implement multiple devices in the station equipment. The energy-saving linkage control between the two can greatly reduce the overall energy consumption of the site equipment and realize the intelligent management of energy efficiency of the site equipment.

Referring to FIG. 11 , an accessory device 1100 is provided in the embodiment of the present invention. The accessory device 1100 is one or more devices associated with a base station master device in a site device, and may include: a sending module 1101. a receiving module 1102, an energy saving control module 1103, wherein

The sending module 1101 is configured to report the running status information of the accessory device to the site controller.

The receiving module 1102 is configured to receive a second energy saving control parameter sent by the site controller.

The energy-saving control module 1103 is configured to determine, according to the second energy-saving control parameter, whether to change the energy-saving state of the accessory device, where the power-saving state includes: the accessory device turns the energy-saving mode on or off.

In some embodiments of the present invention, the energy-saving control module 1103 is further configured to determine, according to the standby energy state, temperature information, and a preset energy-saving policy of the accessory device, an energy-saving state of the accessory device;

The sending module 1101 is specifically configured to carry the determined energy saving state in the operating state information and send the information to the site controller, where the site controller sends the energy saving state to the energy saving management system.

In some embodiments of the present invention, the energy-saving control module 1103 is specifically configured to: if the second energy-saving control parameter indicates that the accessory device is in the power-saving mode, and the accessory device is currently enabled. In the energy-saving mode, the current energy-saving mode is changed to the power-saving mode; if the second energy-saving control parameter indicates that the accessory device is in the energy-saving mode and the accessory device is currently in the energy-saving mode, the current energy-saving mode is turned off. Change to turn on power save mode.

In some embodiments of the present invention, the accessory device includes: a ventilation device, a refrigeration device, and a power supply device;

The energy-saving control module 1103 is specifically configured to: if the second energy-saving control parameter indicates that the ventilation device is configured to extract outdoor cold air to reduce the indoor working environment temperature, turn off the energy-saving mode of the ventilation device, and then extract the outdoor cold air delivery. To the equipment room where the power supply device and the base station main device are located; if the second energy saving control parameter indicates that the cooling device is operated to reduce the indoor working environment temperature, the energy saving mode of the cooling device is turned off, and then the cold air delivery is started to be The power room and the equipment room where the base station is located.

According to the description of the present invention, the base station master device and the accessory device in the site device respectively report the respective running state information to the site controller, and the site controller obtains the running state information of the base station master device and the running state of the accessory device. After the information, the site controller reports the running status information of the base station master device and the running state information of the supporting device to the energy saving management system, and the energy saving management system receives the running state information of the base station master device reported by the site controller and the running state information of the supporting device. After that, the energy-saving management system obtains the first energy-saving control parameter for the base station master device and the second energy-saving control parameter for the accessory device according to the running state information of the base station master device and/or the running state information of the accessory device, and the energy-saving management system will be the first energy-saving management system. The control parameter and the second energy-saving control parameter are sent to the site controller, and the site controller sends the first energy-saving control parameter to the base station master device, and sends the second energy-saving control parameter to the accessory device. In the present invention, the energy-saving management system monitors, processes, and analyzes the running status information of the base station main equipment and the running status information of the supporting equipment, respectively, and establishes energy-saving control parameters for the base station main equipment and the supporting equipment, respectively, and can implement multiple devices in the station equipment. The energy-saving linkage control between the two can greatly reduce the overall energy consumption of the site equipment and realize the intelligent management of energy efficiency of the site equipment.

Referring to FIG. 12, an energy-saving control system 1200 for a site device according to an embodiment of the present invention may include: any one of the foregoing FIG. 8-a, FIG. 4-b, FIG.-c, and FIG. 8-d. The energy-saving management system 800, such as the site controller 900 described in FIG. 9, is the base station master device 1000 as described in FIG. 10, and the accessory device 1100 as described in FIG.

According to the description of the present invention, the base station master device and the accessory device in the site device respectively report the respective running state information to the site controller, and the site controller acquires the base station master device. After the running status information and the running status information of the supporting device, the site controller reports the running status information of the base station main device and the running status information of the supporting device to the energy saving management system, and the energy saving management system receives the base station main device reported by the site controller. After the running status information and the running status information of the supporting device, the energy saving management system obtains the first energy saving control parameter for the base station master device and the second energy saving device for the accessory device according to the running state information of the base station master device and/or the running state information of the accessory device. The control parameter, the energy-saving management system sends the first energy-saving control parameter and the second energy-saving control parameter to the site controller, and the site controller sends the first energy-saving control parameter to the base station master device, and sends the second energy-saving control parameter to the accessory device. . In the present invention, the energy-saving management system monitors, processes, and analyzes the running status information of the base station main equipment and the running status information of the supporting equipment, respectively, and establishes energy-saving control parameters for the base station main equipment and the supporting equipment, respectively, and can implement multiple devices in the station equipment. The energy-saving linkage control between the two can greatly reduce the overall energy consumption of the site equipment and realize the intelligent management of energy efficiency of the site equipment.

It should be noted that the information interaction between the modules/units of the foregoing device, the execution process, and the like are based on the same concept as the method embodiment of the present invention, and the technical effects thereof are the same as the embodiment of the method of the present invention. Referring to the description in the foregoing method embodiments of the present invention, details are not described herein again.

The embodiment of the present invention further provides a computer storage medium, wherein the computer storage medium stores a program, and the program executes some or all of the steps described in the foregoing method embodiments.

Next, another energy-saving management system provided by the embodiment of the present invention is introduced. Referring to FIG. 13, the energy-saving management system 1300 includes:

The input device 1301, the output device 1302, the processor 1303, and the memory 1304 (wherein the number of the processors 1303 in the energy saving management system 1300 may be one or more, and one processor in FIG. 13 is taken as an example). In some embodiments of the present invention, the input device 1301, the output device 1302, the processor 1303, and the memory 1304 may be connected by a bus or other means, wherein the bus connection is taken as an example in FIG.

The processor 1303 is configured to perform the foregoing energy saving control method of the site device as shown in FIG. 2, for example, the processor 1303, configured to perform the following steps:

Receiving operation state information of the base station master device reported by the site controller and running state information of the accessory device related to the base station master device in the site device;

According to the operating state information of the base station master device and/or the running state information of the accessory device Acquiring a first energy-saving control parameter for the base station master device and acquiring a second energy-saving control parameter for the accessory device;

The energy saving management system transmits the first energy saving control parameter and the second energy saving control parameter to the site controller.

In some embodiments of the present invention, the operating state information of the base station master device includes: a power saving state of the base station master device, and the power saving state of the base station master device includes: the base station master device turning on or off the power saving mode;

The operation status information of the accessory device includes: a backup energy state of the accessory device and a power saving state of the accessory device, and the energy-saving state of the accessory device includes: the accessory device turning on or off the energy-saving mode;

The processor 1303 is specifically configured to perform the following steps:

When the energy-saving management system determines that the base station master device is in the power-saving mode according to the operating state information of the base station master device, the energy-saving management system determines whether the standby energy state of the accessory device meets the preset first condition. If the backup energy state of the accessory device does not meet the first condition, obtain, by the base station master device, a first energy-saving control parameter that needs to extend the service time of the base station master device, if the accessory device is configured If the electrical energy state does not satisfy the first condition and the accessory device turns off the energy-saving mode, obtaining, by the accessory device, a second energy-saving control parameter that changes a power-saving state;

When the energy-saving management system determines that the base station master device is in the energy-saving mode according to the operating state information of the base station master device, the energy-saving management system determines whether the standby power state of the accessory device meets the preset second condition. And if the standby energy state of the accessory device meets the second condition, obtaining, by the base station master device, a first energy-saving control parameter that changes a power-saving state, if the standby energy state of the accessory device meets the foregoing And the second energy-saving control parameter that changes the energy-saving state is obtained for the accessory device.

In some embodiments of the present invention, the operating state information of the base station master device includes: a power saving state of the base station master device, and the power saving state of the base station master device includes: the base station master device turning on or off the power saving mode;

The operation status information of the accessory device includes: the energy-saving state of the accessory device, and the energy-saving state of the accessory device includes: the accessory device turns the energy-saving mode on or off;

The processor 1303 is specifically configured to perform the following steps:

Determining, by the energy saving management system, the base station according to operating state information of the base station master device When the main device is in the energy-saving mode, if the accessory device is in the energy-saving mode, the second energy-saving control parameter for changing the energy-saving state is obtained for the accessory device;

When the energy-saving management system determines that the base station master device is in the energy-saving mode according to the operating state information of the base station master device, if the accessory device turns off the energy-saving mode, obtaining the second energy-saving state for changing the energy-saving state for the accessory device Control parameters.

In some embodiments of the present invention, the accessory device includes: a ventilation device, a refrigeration device, and a power supply device;

The operating status information of the accessory device includes: an outdoor temperature of the power device and the equipment room where the base station is located, and an indoor working environment temperature of the power device;

The processor 1303 is specifically configured to perform the following steps:

When the indoor working environment temperature of the power supply device is higher than a preset temperature threshold, and the outdoor temperature is lower than the indoor working environment temperature, acquiring and operating the ventilation device to extract outdoor cold air reduces the indoor working environment temperature Second energy saving control parameter;

When the indoor working environment temperature of the power supply device is higher than a preset temperature threshold, and the outdoor temperature is higher than the indoor working environment temperature, obtaining a second energy saving operation of the cooling device to reduce the indoor working environment temperature Control parameters.

In some embodiments of the present invention, the processor 1303 is further configured to: perform operation of receiving, by the site controller, operation status information of the base station master device and operation of the accessory device related to the base station master device in the site device. After the status information, if the running status information of the base station master device includes the traffic volume carried by the base station master device, the energy saving indication information is obtained according to the traffic volume carried by the base station master device and the preset energy saving policy, and the energy saving indication The information includes: the energy-saving management system determines whether the base station master device is allowed to enable or disable the power-saving mode; and sends the energy-saving indication information to the site controller, where the site controller sends the energy-saving indication information to The base station master device.

In some embodiments of the present invention, the processor 1303 is further configured to: after receiving operation state information of the base station master device reported by the site controller and running state information of the accessory device related to the base station master device, If the operating state information of the base station master device includes power consumption information of the base station master device, and the running state information of the accessory device includes power consumption information of the accessory device, visualizing the base station master device by using a graph Power consumption information and power consumption information of the accessory device; obtaining energy saving effect according to power consumption information of the base station master device and power consumption information of the accessory device And, the energy saving effect is presented through a chart visualization.

Next, another site controller provided by the embodiment of the present invention is introduced. Referring to FIG. 14, the site controller 1400 includes:

The input device 1401, the output device 1402, the processor 1403, and the memory 1404 (wherein the number of the processors 1403 in the site controller 1400 may be one or more, and one processor in FIG. 14 is taken as an example). In some embodiments of the present invention, the input device 1401, the output device 1402, the processor 1403, and the memory 1404 may be connected by a bus or other means, wherein the bus connection is taken as an example in FIG.

The processor 1403 is configured to execute the foregoing energy saving control method of the site device as shown in FIG. 4 . For example, the processor 1403 is configured to perform the following steps:

Obtaining running state information of the base station master device, and acquiring running state information of the accessory device related to the base station master device in the site device;

Reporting, to the energy-saving management system, operation state information of the base station master device and running state information of the accessory device;

Receiving, by the energy-saving management system, a first energy-saving control parameter and a second energy-saving control parameter, where the first energy-saving control parameter is that the energy-saving management system is configured according to the operating state information of the base station master device, and/or The operation status information of the accessory device is obtained by the base station master device, and the second energy-saving control parameter is that the energy-saving management system is based on the running state information of the base station master device and/or the running state information of the accessory device. Said supporting equipment acquisition;

And transmitting the first energy saving control parameter to the base station master device, and sending the second power saving control parameter to the accessory device.

In some embodiments of the present invention, the processor 1403 is specifically configured to perform the following steps:

Receiving, by the station control unit in the site controller, operation state information reported by the base station master device, where the site control unit is connected to the base station master device through an input/output I/O interface; or The station control unit in the device receives the running status information reported by the baseband processing unit BBU in the base station master device, and the station control unit is connected to the BBU through an I/O interface;

And receiving, by the station control unit in the site controller, operation state information collected by the accessory device control unit from the accessory device, where the site control unit is connected to the accessory device control unit by using an I/O interface.

In some embodiments of the present invention, the processor 1403 is specifically configured to perform the following steps:

Receiving, by the control unit in the site controller, the BBU in the base station master device, the operating state information reported by the radio remote unit RRU in the base station master device, where the control unit passes the I/O interface and the RRU connection;

The operating status information reported by the accessory device is received by the control unit in the site controller, and the control unit is connected to the accessory device through an I/O interface.

In some embodiments of the present invention, the operating state information includes at least one of the following information: power consumption information, temperature information, energy saving state, and backup energy state, where the power saving state includes: a base station master device, and a matching The device turns the power save mode on or off.

Next, another base station master device provided by the embodiment of the present invention is introduced. Referring to FIG. 15, the base station master device 1500 includes:

The input device 1501, the output device 1502, the processor 1503, and the memory 1504 (wherein the number of the processors 1503 in the base station main device 1500 may be one or more, and one processor in FIG. 15 is taken as an example). In some embodiments of the present invention, the input device 1501, the output device 1502, the processor 1503, and the memory 1504 may be connected by a bus or other means, wherein the bus connection is taken as an example in FIG.

The processor 1503 is configured to execute the foregoing energy saving control method of the site device as shown in FIG. 5. The processor 1503 is specifically configured to perform the following steps:

Reporting, to the site controller, operation status information of the base station master device;

Receiving a first energy saving control parameter sent by the site controller;

Determining, according to the first energy saving control parameter, whether to change a power saving state of the base station master device, where the power saving state includes: the base station master device turning on or off the power saving mode.

In some embodiments of the present invention, the processor 1503 is further configured to perform the following steps:

Determining, according to the traffic volume carried by the base station master device and the preset energy saving policy, a power saving state of the base station master device, or determining, by the base station master device, the base station master according to the energy saving indication information received from the site controller Energy saving status of the device;

The determined energy saving state is carried in the operating state information and sent to the site controller, and the energy saving state is sent by the site controller to the energy saving management system.

In some embodiments of the present invention, the processor 1503 is specifically configured to perform the following steps:

If the first energy saving control parameter indicates that the base station primary device service time needs to be extended and When the base station master device currently turns off the power saving mode, the current power saving mode is changed to the power saving mode.

If the first power saving control parameter indicates that the base station master device turns off the power saving mode and the base station master device currently turns on the power saving mode, the current power saving mode is changed to the power saving mode.

In some embodiments of the present invention, the operating status information includes at least one of the following information: power consumption information, temperature information, and a power saving state, where the power saving state includes: the base station master device turns on or off the power saving mode. .

Next, another accessory device provided by the embodiment of the present invention is introduced. Referring to FIG. 16, the accessory device 1600 includes:

The input device 1601, the output device 1602, the processor 1603, and the memory 1604 (wherein the number of the processors 1603 in the companion device 1600 may be one or more, and one processor in FIG. 16 is taken as an example). In some embodiments of the present invention, the input device 1601, the output device 1602, the processor 1603, and the memory 1604 may be connected by a bus or other means, wherein the bus connection is taken as an example in FIG.

The processor 1603 is configured to execute the foregoing energy saving control method of the site device as shown in FIG. 6. For example, the processor 1603 is configured to perform the following steps:

The accessory device reports the running status information of the accessory device to the site controller, where the accessory device is one or more devices associated with the base station master device in the site device;

Receiving, by the accessory device, a second energy saving control parameter sent by the site controller;

The accessory device determines, according to the second energy-saving control parameter, whether to change the energy-saving state of the accessory device, where the power-saving state includes: the accessory device turns the energy-saving mode on or off.

In some embodiments of the present invention, the processor 1603 is further configured to perform the following steps:

Determining, according to the standby energy state, the temperature information, and the preset energy saving policy of the accessory device, the energy saving state of the accessory device;

The determined energy saving state is carried in the operating state information and sent to the site controller, and the energy saving state is sent by the site controller to the energy saving management system.

In some embodiments of the present invention, the processor 1603 is specifically configured to perform the following steps:

If the second energy-saving control parameter indicates that the accessory device is in the power-saving mode, and the accessory device is currently enabled in the power-saving mode, the current power-on mode is changed to the power-saving mode.

If the second energy-saving control parameter indicates that the accessory device turns on the energy-saving mode and the accessory device currently turns off the energy-saving mode, the current power-saving mode is changed to the power-saving mode.

In some embodiments of the present invention, the accessory device includes: a ventilation device, a cooling device, and a power supply device; and the processor 1603 is configured to perform the following steps:

If the second energy-saving control parameter indicates that the ventilation device is operated to extract the outdoor cold air to reduce the indoor working environment temperature, then the ventilation device is controlled to turn off the energy-saving mode, and then the outdoor cold air is extracted and sent to the power device and the base station main device. Computer room

If the second energy saving control parameter indicates that the cooling device is operated to reduce the indoor working environment temperature, the cooling device is controlled to turn off the energy saving mode, and then the cold air is started to be sent to the power device and the equipment room where the base station master device is located.

It should be further noted that the device embodiments described above are merely illustrative, wherein the units described as separate components may or may not be physically separated, and the components displayed as units may or may not be Physical units can be located in one place or distributed to multiple network elements. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of the embodiment. In addition, in the drawings of the device embodiments provided by the present invention, the connection relationship between the modules indicates that there is a communication connection between them, and specifically, one or more communication buses or signal lines can be realized. Those of ordinary skill in the art can understand and implement without any creative effort.

Through the description of the above embodiments, those skilled in the art can clearly understand that the present invention can be implemented by means of software plus necessary general hardware, and of course, dedicated hardware, dedicated CPU, dedicated memory, dedicated memory, Special components and so on. In general, functions performed by computer programs can be easily implemented with the corresponding hardware, and the specific hardware structure used to implement the same function can be various, such as analog circuits, digital circuits, or dedicated circuits. Circuits, etc. However, for the purposes of the present invention, software program implementation is a better implementation in more cases. Based on the understanding, the technical solution of the present invention, which is essential or contributes to the prior art, can be embodied in the form of a software product stored in a readable storage medium, such as a floppy disk of a computer. , U disk, mobile hard disk, read-only memory (ROM, Read-Only Memory), random access memory (RAM, Random Access Memory), disk or optical disk, etc., including a number of instructions to make a computer device (may be A personal computer, server, or network device, etc.) performs the methods described in various embodiments of the present invention.

In conclusion, the above embodiments are only used to explain the technical solutions of the present invention, and are not limited thereto; although the present invention has been described in detail with reference to the above embodiments, those skilled in the art should understand that they can still The technical solutions described in the above embodiments are modified, or part of them The technical features are equivalent to those of the embodiments of the present invention.

Claims (37)

1. A method for controlling energy saving of a site device, comprising:

   The energy-saving management system receives the running state information of the base station master device reported by the site controller and the running state information of the accessory device associated with the base station master device in the site device;

   The energy-saving management system acquires a first energy-saving control parameter for the base station master device and a second energy-saving control parameter for the accessory device, according to the running state information of the base station master device and/or the running state information of the accessory device. ;

   The energy saving management system transmits the first energy saving control parameter and the second energy saving control parameter to the site controller.
2. The method according to claim 1, wherein the operating state information of the base station master device comprises: a power saving state of the base station master device, and the power saving state of the base station master device comprises: the base station master device is turned on or Turn off the power save mode;

   The operation status information of the accessory device includes: a backup energy state of the accessory device and a power saving state of the accessory device, and the energy-saving state of the accessory device includes: the accessory device turning on or off the energy-saving mode;

   The energy-saving management system acquires a first energy-saving control parameter for the base station master device and a second energy-saving control parameter for the accessory device, according to the running state information of the base station master device and/or the running state information of the accessory device. ,include:

   When the energy-saving management system determines that the base station master device is in the power-saving mode according to the operating state information of the base station master device, the energy-saving management system determines whether the standby energy state of the accessory device meets the preset first condition. If the backup energy state of the accessory device does not meet the first condition, the energy-saving management system acquires, for the base station master device, a first energy-saving control parameter that needs to extend the service time of the base station master device, If the backup energy state of the accessory device does not meet the first condition and the accessory device turns off the energy-saving mode, the energy-saving management system acquires a second energy-saving control parameter that changes the energy-saving state for the accessory device;

   When the energy-saving management system determines that the base station master device is in the energy-saving mode according to the operating state information of the base station master device, the energy-saving management system determines whether the standby power state of the accessory device meets the preset second condition. If the backup energy state of the accessory device meets the second condition, the energy-saving management system acquires, for the base station master device, a first energy-saving control parameter that changes a power-saving state, and if the backup device has the backup energy The state meets the second condition and the accessory device is turned on In the energy saving mode, the energy saving management system acquires, for the accessory device, a second energy saving control parameter that changes the energy saving state.
3. The method according to claim 1, wherein the operating state information of the base station master device comprises: a power saving state of the base station master device, and the power saving state of the base station master device comprises: the base station master device is turned on or Turn off the power save mode;

   The operation status information of the accessory device includes: the energy-saving state of the accessory device, and the energy-saving state of the accessory device includes: the accessory device turns the energy-saving mode on or off;

   The energy-saving management system acquires a first energy-saving control parameter for the base station master device and a second energy-saving control parameter for the accessory device, according to the running state information of the base station master device and/or the running state information of the accessory device. ,include:

   When the energy-saving management system determines that the base station master device is in the energy-saving mode according to the operating state information of the base station master device, if the accessory device starts the energy-saving mode, the energy-saving management system acquires the energy-saving change for the accessory device. a second energy saving control parameter of the state;

   When the energy-saving management system determines that the base station master device is in the energy-saving mode according to the operating state information of the base station master device, if the accessory device turns off the energy-saving mode, the energy-saving management system obtains the energy-saving change for the accessory device. The second energy saving control parameter of the state.
4. The method according to claim 1, wherein the accessory device comprises: a ventilation device, a refrigeration device, and a power supply device;

   The operating status information of the accessory device includes: an outdoor temperature of the power device and the equipment room where the base station is located, and an indoor working environment temperature of the power device;

   The energy-saving management system acquires a first energy-saving control parameter for the base station master device and a second energy-saving control parameter for the accessory device, according to the running state information of the base station master device and/or the running state information of the accessory device. ,include:

   When the indoor working environment temperature of the power supply device is higher than a preset temperature threshold, and the outdoor temperature is lower than the indoor working environment temperature, the energy saving management system acquires and operates the ventilation device to extract an outdoor cold air lowering station. a second energy-saving control parameter for the indoor working environment temperature;

   When the indoor working environment temperature of the power supply device is higher than a preset temperature threshold, and the outdoor temperature is higher than the indoor working environment temperature, the energy saving management system acquires and operates the refrigeration device to reduce the indoor working environment The second energy saving control parameter of the temperature.
5. The method of claim 1 wherein said energy management system receiving station After the operation status information of the base station master device and the running status information of the associated device in the site device related to the base station master device, the method further includes:

   If the running status information of the base station master device includes the traffic volume carried by the base station primary device, the energy saving management system obtains energy saving indication information according to the traffic volume carried by the base station primary device and the preset energy saving policy, where the energy saving The indication information includes: the energy saving management system determines whether the base station master device is allowed to enable or disable the energy saving mode;

   The energy-saving management system sends the energy-saving indication information to the site controller, and the site controller sends the energy-saving indication information to the base station master device.
6. The method according to claim 1, wherein the energy-saving management system receives the operating state information of the base station master device reported by the site controller and the operating state information of the associated device associated with the base station master device, The method also includes:

   If the running status information of the base station master device includes power consumption information of the base station master device, and the running state information of the accessory device includes power consumption information of the accessory device, the energy saving management system visualizes the presentation by using a chart Decoding power consumption information of the base station master device and power consumption information of the accessory device;

   The energy-saving management system obtains an energy-saving effect according to the power consumption information of the base station master device and the power consumption information of the accessory device, and presents the energy-saving effect through a chart visualization.
7. A method for controlling energy saving of a site device, comprising:

   The site controller acquires running state information of the base station master device, and acquires running state information of the accessory device related to the base station master device in the site device;

   The site controller reports the running state information of the base station master device and the running state information of the accessory device to the energy saving management system;

   The site controller receives the first energy-saving control parameter and the second energy-saving control parameter sent by the energy-saving management system, where the first energy-saving control parameter is the operating state information of the energy-saving management system according to the base station master device And the operating state information of the accessory device is obtained by the base station master device, and the second energy saving control parameter is that the energy saving management system is configured according to the operating state information of the base station master device and/or the accessory device. The running status information is obtained by the accessory device;

   The site controller sends the first energy saving control parameter to the base station master device, and sends the second power saving control parameter to the accessory device.
8. The method according to claim 7, wherein the site controller acquires running state information of the base station master device, and acquires a matching device related to the base station master device in the site device. Information about the running status of the device, including:

   The site controller receives, by using a site control unit in the site controller, operational status information reported by the base station master device, where the site control unit is connected to the base station master device through an input/output I/O interface; or The site controller receives, by the site control unit in the site controller, operation state information reported by the baseband processing unit BBU in the base station master device, where the site control unit is connected to the BBU through an I/O interface;

   The site controller receives, by using a site control unit in the site controller, operational status information collected by the accessory device control unit from the accessory device, where the site control unit controls through the I/O interface and the accessory device. Unit connection.
9. The method according to claim 7, wherein the site controller acquires running state information of the base station master device, and acquires running state information of the accessory device related to the base station master device in the site device, including:

   The site controller receives the operating state information reported by the radio remote unit RRU in the base station master device by using the control unit in the site controller and the BBU in the base station master device, and the control unit passes the I/ An O interface is connected to the RRU;

   The site controller receives the running state information reported by the accessory device by using a control unit in the site controller, and the control unit is connected to the accessory device through an I/O interface.
10. The method according to any one of claims 7 to 9, wherein the operating state information comprises at least one of the following information: power consumption information, temperature information, energy saving state, and standby energy state. The energy saving state includes: the base station master device and the accessory device turn on or off the energy saving mode.
11. A method for controlling energy saving of a site device, comprising:

    The base station master device reports the running status information of the base station master device to the site controller;

    Receiving, by the base station master device, a first energy saving control parameter sent by the site controller;

    The base station master device determines, according to the first energy-saving control parameter, whether to change the energy-saving state of the base station master device, where the power-saving state includes: the base station master device turns on or disables the energy-saving mode.
12. The method of claim 11 wherein the method further comprises:

    Determining, by the base station master device, a power saving state of the base station master device according to the traffic volume carried by the base station master device and a preset energy saving policy, or the base station master device according to the energy saving indication information received from the site controller Determining a power saving state of the base station master device;

    The base station master device reports the running status information of the base station master device to the site controller, where for:

    The base station master device carries the determined energy-saving state in the operating state information and sends the energy-saving state to the site controller, and the site controller sends the energy-saving state to the energy-saving management system.
13. The method according to claim 11, wherein the determining, by the base station master device, whether to change the energy saving state of the base station master device according to the first power saving control parameter comprises:

    If the first power saving control parameter indicates that the base station primary device service time needs to be extended and the base station primary device currently turns off the power saving mode, the base station master device changes the current power saving mode to the power saving mode;

    If the first power saving control parameter indicates that the base station master device turns off the power saving mode and the base station master device currently turns on the power saving mode, the base station master device changes the current power saving mode to the power saving mode.
14. The method according to any one of claims 11 to 13, wherein the operating state information comprises at least one of the following information: power consumption information, temperature information, and energy saving state, and the power saving state includes: The base station master device turns the energy saving mode on or off.
15. A method for controlling energy saving of a site device, comprising:

    The accessory device reports the running status information of the accessory device to the site controller, where the accessory device is one or more devices associated with the base station master device in the site device;

    Receiving, by the accessory device, a second energy saving control parameter sent by the site controller;

    The accessory device determines, according to the second energy-saving control parameter, whether to change the energy-saving state of the accessory device, where the power-saving state includes: the accessory device turns the energy-saving mode on or off.
16. The method of claim 15 wherein the method further comprises:

    Determining, by the accessory device, an energy-saving state of the accessory device according to the standby energy state, the temperature information, and the preset energy-saving policy of the accessory device;

    The accessory device reports the running status information of the accessory device to the site controller, specifically:

    The supporting device carries the determined energy-saving state in the operating state information and sends the energy-saving state to the site controller, and the site controller sends the energy-saving state to the energy-saving management system.
17. The method according to claim 15, wherein the supporting device determines whether to change the energy saving state of the accessory device according to the second energy saving control parameter, including:

    If the second energy-saving control parameter indicates that the accessory device is in the power-saving mode, and the accessory device is currently enabled in the power-saving mode, the accessory device changes the current power-on mode to the shutdown node. Energy mode

    If the second energy-saving control parameter indicates that the accessory device is in the energy-saving mode and the accessory device is currently in the energy-saving mode, the accessory device changes the current power-off mode to the power-saving mode.
18. The method according to claim 15, wherein the accessory device comprises: a ventilation device, a refrigeration device, and a power supply device;

    Determining, according to the second energy-saving control parameter, whether the energy-saving state of the accessory device is changed, including:

    If the second energy-saving control parameter indicates that the ventilation device is operated to extract the outdoor cold air to reduce the indoor working environment temperature, the ventilation device turns off the energy-saving mode, and then extracts the outdoor cold air to the power device and the base station main device. engine room;

    If the second energy saving control parameter indicates that the cooling device is operated to reduce the indoor working environment temperature, the cooling device turns off the energy saving mode, and then starts to generate cold air to be delivered to the power device and the equipment room where the base station master device is located.
19. An energy saving management system, comprising:

    a receiving module, configured to receive operation state information of the base station master device reported by the site controller, and operation state information of the accessory device related to the base station master device in the site device;

    An energy-saving control parameter obtaining module, configured to acquire a first energy-saving control parameter for the base station master device and acquire a second power-saving control parameter for the base station master device according to the operating state information of the base station master device and/or the running state information of the accessory device Energy saving control parameters;

    And a sending module, configured to send the first energy saving control parameter and the second power saving control parameter to the site controller.
20. The energy-saving management system according to claim 19, wherein the operating state information of the base station master device comprises: a power saving state of the base station master device, and the power saving state of the base station master device comprises: the base station master device Turn energy saving mode on or off;

    The operation status information of the accessory device includes: a backup energy state of the accessory device and a power saving state of the accessory device, and the energy-saving state of the accessory device includes: the accessory device turning on or off the energy-saving mode;

    The energy saving control parameter obtaining module includes:

    a first control module, configured to: when the energy saving management system is in accordance with an operating state of the base station master device Determining, when the base station master device is in the power-saving mode, determining whether the standby energy state of the accessory device meets the preset first condition, and if the backup energy state of the accessory device does not satisfy the first condition, Obtaining, by the base station master device, a first energy-saving control parameter that is required to extend the service time of the base station master device, if the backup energy state of the accessory device does not meet the first condition and the accessory device turns off the energy-saving mode, Obtaining, for the accessory device, a second energy-saving control parameter that changes a power-saving state;

    a second control module, configured to determine, when the energy-saving management system determines, according to the operating state information of the base station master device, that the base station master device starts the energy-saving mode, whether the standby energy state of the accessory device meets a preset And the second energy-saving control parameter for changing the energy-saving state of the base station master device, if the standby power state of the accessory device meets the second condition, if the standby device energy state of the accessory device meets When the second condition is described and the accessory device turns on the energy-saving mode, the second energy-saving control parameter that changes the energy-saving state is obtained for the accessory device.
21. The energy-saving management system according to claim 19, wherein the operating state information of the base station master device comprises: a power saving state of the base station master device, and the power saving state of the base station master device comprises: the base station master device Turn energy saving mode on or off;

    The operation status information of the accessory device includes: the energy-saving state of the accessory device, and the energy-saving state of the accessory device includes: the accessory device turns the energy-saving mode on or off;

    The energy-saving control parameter obtaining module is specifically configured to: when the energy-saving management system determines, according to the operating state information of the base station master device, that the base station master device turns off the energy-saving mode, if the accessory device starts the energy-saving mode, The supporting device obtains the second energy-saving control parameter that changes the energy-saving state; when the energy-saving management system determines that the base station master device turns on the energy-saving mode according to the operating state information of the base station master device, if the accessory device turns off the energy-saving mode, And acquiring, by the accessory device, a second energy-saving control parameter that changes a power-saving state.
22. The energy-saving management system according to claim 19, wherein the accessory device comprises: a ventilation device, a refrigeration device, and a power supply device, and the running status information of the accessory device comprises: the power supply device and the base station master The outdoor temperature of the equipment room where the equipment is located and the indoor working environment temperature of the power supply equipment;

    The energy-saving control parameter obtaining module is specifically configured to: when the indoor working environment temperature of the power supply device is higher than a preset temperature threshold, and the outdoor temperature is lower than the indoor working environment temperature, acquire and operate the ventilation device Extracting, by the outdoor cold air, a second energy-saving control parameter for reducing the temperature of the indoor working environment; when the indoor working environment temperature of the power supply device is higher than a preset temperature threshold, and the room When the external temperature is higher than the indoor working environment temperature, obtaining a second energy-saving control parameter that runs the refrigeration device to reduce the temperature of the indoor working environment.
23. The energy-saving management system according to claim 19, wherein the energy-saving management system further comprises: an energy-saving indication module, configured to receive, by the receiving module, operation state information of the base station master device reported by the site controller and the site device After the running status information of the supporting device related to the base station master device, if the running state information of the base station master device includes the traffic carried by the base station master device, according to the traffic volume and the pre-loaded by the base station master device The energy saving policy obtains the energy saving indication information, where the energy saving indication information includes: determining, by the energy saving management system, whether the base station master device is allowed to enable or disable the energy saving mode;

    The sending module is further configured to send the energy saving indication information to the site controller, where the site controller sends the energy saving indication information to the base station master device.
24. The energy-saving management system according to claim 19, wherein the energy-saving management system further comprises: a display processing module, configured to receive, by the receiving module, operation state information of the base station master device reported by the site controller, and the After the running status information of the associated device of the base station master device, if the running state information of the base station master device includes power consumption information of the master device of the base station, and the running state information of the accessory device includes the function of the accessory device The power consumption information of the base station master device and the power consumption information of the accessory device are obtained by using the chart, and the energy saving effect is obtained according to the power consumption information of the base station master device and the power consumption information of the accessory device, and The energy saving effect is presented by chart visualization.
25. A site controller, comprising:

    An acquiring module, configured to acquire running state information of a base station master device, and obtain running state information of the accessory device related to the base station master device in the site device;

    a first sending module, configured to report, to the energy-saving management system, operation state information of the base station master device and running state information of the accessory device;

    a receiving module, configured to receive a first energy saving control parameter and a second power saving control parameter sent by the energy saving management system, where the first energy saving control parameter is an operating state information of the energy saving management system according to the base station master device And the operating state information of the accessory device is obtained by the base station master device, and the second energy saving control parameter is that the energy saving management system is configured according to the operating state information of the base station master device and/or the accessory device. The running status information is obtained by the accessory device;

    a second sending module, configured to send the first power saving control parameter to the base station master device, to And sending the second energy saving control parameter to the accessory device.
26. The site controller according to claim 25, wherein the acquiring module is configured to receive, by using a site control unit in the site controller, operation state information reported by the base station master device, where the site control is performed. The unit is connected to the base station master device through an input/output I/O interface; or the station controller receives an operation status reported by the baseband processing unit BBU in the base station master device by using a site control unit in the site controller Information, the site control unit is connected to the BBU through an I/O interface; and receiving, by the site control unit in the site controller, operational status information collected by the accessory device control unit from the accessory device, the site The control unit is connected to the associated device control unit through an I/O interface.
27. The site controller according to claim 25, wherein the acquiring module is specifically configured to receive, by a control unit in the site controller, a BBU in the base station master device, in the base station master device The operation status information reported by the radio remote unit RRU, the control unit is connected to the RRU through an I/O interface, and the operation status information reported by the accessory device is received by the control unit in the station controller, where the control is performed. The unit is connected to the accessory device through an I/O interface.
28. The site controller according to any one of claims 25 to 27, wherein the operating state information comprises at least one of the following information: power consumption information, temperature information, energy saving state, and standby energy state. The energy-saving state includes: the base station master device and the accessory device turn on or off the energy-saving mode.
29. A base station master device, comprising:

    a sending module, configured to report, to the site controller, operation state information of the base station master device;

    a receiving module, configured to receive a first energy saving control parameter sent by the site controller;

    The energy-saving control module is configured to determine, according to the first energy-saving control parameter, whether to change a power-saving state of the base station master device, where the power-saving state includes: the base station master device turns on or disables a power-saving mode.
30. The base station master device according to claim 29, wherein the energy saving control module is further configured to determine, according to the traffic volume carried by the base station master device and the preset energy saving policy, the energy saving state of the base station master device, Or the base station master device determines, according to the energy saving indication information received from the site controller, a power saving state of the base station master device;

    The sending module is configured to carry the determined energy saving state in the running state information and send the information to the site controller, where the site controller sends the energy saving state to energy saving management system.
31. The base station master device according to claim 29, wherein the energy saving control module is specifically configured to: if the first energy saving control parameter indicates that the base station primary device service time needs to be extended, and the base station primary device is currently closed In the energy saving mode, the current power saving mode is changed to the power saving mode; if the first power saving control parameter indicates that the base station master device turns off the power saving mode and the base station master device currently turns on the power saving mode, the current Turn on the power save mode to turn off the power save mode.
32. The base station master device according to any one of claims 29 to 31, wherein the operation state information includes at least one of the following information: power consumption information, temperature information, energy saving state, and the energy saving state. The method includes: the base station master device turns on or disables a power saving mode.
33. The accessory device is characterized in that: the accessory device is one or more devices associated with the base station master device in the site device, and the accessory device includes:

    a sending module, configured to report, to the site controller, operation status information of the accessory device;

    a receiving module, configured to receive a second energy saving control parameter sent by the site controller;

    The energy-saving control module is configured to determine, according to the second energy-saving control parameter, whether to change the energy-saving state of the accessory device, where the power-saving state includes: the accessory device turns the energy-saving mode on or off.
34. The accessory device according to claim 33, wherein the energy-saving control module is further configured to determine, according to the standby energy state, the temperature information, and the preset energy-saving policy of the accessory device, the energy-saving state of the accessory device. ;

    The sending module is configured to carry the determined energy saving state in the running state information and send the information to the site controller, where the site controller sends the energy saving state to the energy saving management system.
35. The accessory device according to claim 33, wherein the energy-saving control module is specifically configured to: if the second energy-saving control parameter indicates that the accessory device turns off the energy-saving mode, and the accessory device currently turns on the energy-saving mode, And changing the current energy-saving mode to the power-saving mode; if the second energy-saving control parameter indicates that the accessory device is in the energy-saving mode, and the accessory device is currently in the energy-saving mode, the current power-saving mode is changed to be enabled. Energy saving mode.
36. The accessory device according to claim 33, wherein the accessory device comprises: a ventilation device, a refrigeration device, and a power supply device;

    The energy saving control module is specifically configured to: if the second energy saving control parameter indicates that the ventilation is performed After the device extracts the outdoor cold air to reduce the indoor working environment temperature, the energy saving mode of the ventilation device is turned off, and then the outdoor cold air is extracted and sent to the equipment room where the power supply device and the base station main device are located; if the second energy saving control parameter indicates the operation The cooling device reduces the indoor working environment temperature, then turns off the energy saving mode of the cooling device, and then starts to generate cold air delivery to the power device and the equipment room where the base station main device is located.
37. An energy-saving control system for a site device, comprising: the energy-saving management system according to any one of claims 19 to 24, the site controller according to any one of claims 25 to 28, such as The base station master device according to any one of claims 29 to 32, wherein the accessory device according to any one of claims 33 to 36.

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