CN117394511A

CN117394511A - Elevator standby electricity distribution method and related device

Info

Publication number: CN117394511A
Application number: CN202311242913.XA
Authority: CN
Inventors: 王树晓; 陈亚梯
Original assignee: SHENZHEN HANQIANG TECHNOLOGY CO LTD
Current assignee: SHENZHEN HANQIANG TECHNOLOGY CO LTD
Priority date: 2023-09-22
Filing date: 2023-09-22
Publication date: 2024-01-12

Abstract

The application provides an elevator standby electricity distribution method and a related device, which are applied to management equipment in an elevator gravity power generation system, wherein the method comprises the following steps: receiving a standby electricity transmission request from the target control device, wherein the standby electricity transmission request is sent when the target control device detects that the target elevator fails; acquiring power consumption information of other standby power supplies except for the target standby power supply in the plurality of standby power supplies, wherein the power consumption information comprises at least one of the following: the standby power supply comprises a standby power supply and a standby power supply, wherein the standby power supply comprises a standby power supply and a standby power supply; determining a power supply to be called from other standby power supplies according to the power consumption information and the target required power quantity of the other standby power supplies; and sending a standby electricity calling request to a to-be-called control device corresponding to the to-be-called power supply in the plurality of elevator control devices. The embodiment of the application is beneficial to improving the utilization efficiency of the standby electricity of the elevator and the use safety of the elevator.

Description

Elevator standby electricity distribution method and related device

Technical Field

The application relates to the technical field of equipment energy management, in particular to an elevator standby electricity distribution method and a related device.

Background

In order to cope with the situation that sudden power failure of the elevator possibly threatens the safety of personnel in the elevator, the elevator can be provided with a corresponding standby power supply, and the standby power supply can supply power for the elevator in an emergency mode when the elevator fails. However, at present, when the elevator fails, the situation that standby electricity stored in the standby power supply of each elevator cannot be reasonably distributed, so that power supply in the elevator requiring power consumption is insufficient, the problem that the standby electricity of the elevator without power consumption cannot be used is solved, the utilization rate of the standby electricity of the elevator is affected, and the use safety of the elevator with power supply deficiency is not guaranteed.

Disclosure of Invention

The embodiment of the application provides an elevator standby electricity distribution method and a related device.

In a first aspect, an embodiment of the present application provides an elevator backup power distribution method, applied to a management device in an elevator gravity power generation system, where the elevator gravity power generation system includes the management device, a plurality of gravity power generation devices, a plurality of elevator control devices, and a plurality of backup power sources, where the plurality of gravity power generation devices include a target gravity power generation device, the plurality of elevator control devices include a target control device, and the plurality of backup power sources include a target backup power source, where the target gravity power generation device is configured to obtain electric energy based on potential energy of a target elevator operation, and store the obtained electric energy to the target backup power source, the method includes:

Receiving a standby electricity transmission request from the target control device, wherein the standby electricity transmission request is sent when the target control device detects that the target elevator fails, the standby electricity transmission request is used for indicating target required electric quantity, and the target required electric quantity is determined according to the residual electric quantity of the target standby power supply;

acquiring electricity consumption information of other standby power supplies except the target standby power supply in the plurality of standby power supplies, wherein the electricity consumption information comprises a using state of the standby power supply and/or a residual electric quantity of the standby power supply, and the using state comprises in-use or unused state;

determining a power supply to be called from the other standby power supplies according to the power consumption information of the other standby power supplies and the target required power quantity;

and sending a standby electricity calling request to a to-be-called control device corresponding to the to-be-called power supply in the plurality of elevator control devices, wherein the standby electricity calling request is used for giving an instruction for controlling the to-be-called power supply to output electric energy to the target standby power supply, and the total amount of the electric energy output by the to-be-called power supply is not smaller than the target required electric quantity.

In a second aspect, an embodiment of the present application provides an elevator backup power distribution method, applied to a target control device in an elevator gravity power generation system, where the elevator gravity power generation system includes a management device, a plurality of gravity power generation devices, a plurality of elevator control devices, and a plurality of backup power sources, where the plurality of gravity power generation devices include a target gravity power generation device, the plurality of elevator control devices include the target control device, and the plurality of backup power sources include a target backup power source, where the target gravity power generation device is configured to obtain electric energy based on potential energy of a target elevator operation, and store the obtained electric energy to the target backup power source, the method includes:

When a power failure of a target elevator is detected, a standby electricity transmission request is sent to the management equipment, the standby electricity transmission request is used for indicating target required electric quantity, the target required electric quantity is determined according to the residual electric quantity of the target standby power supply, and the standby electricity transmission request is used for the management equipment to execute the following steps: acquiring electricity consumption information of other standby power supplies except the target standby power supply in the plurality of standby power supplies, wherein the electricity consumption information comprises a using state of the standby power supply and/or a residual electric quantity of the standby power supply, and the using state comprises in-use or unused state; determining a power supply to be called from the other standby power supplies according to the power consumption information of the other standby power supplies and the target required power quantity; and sending a standby electricity calling request to a to-be-called control device corresponding to the to-be-called power supply in the plurality of elevator control devices, wherein the standby electricity calling request is used for giving an instruction for controlling the to-be-called power supply to output electric energy to the target standby power supply, and the total amount of the electric energy output by the to-be-called power supply is not smaller than the target required electric quantity.

In a third aspect, an embodiment of the present application provides an elevator backup power distribution apparatus, which is characterized by being applied to a management device in an elevator gravity power generation system, where the elevator gravity power generation system includes the management device, a plurality of gravity power generation devices, a plurality of elevator control devices, and a plurality of backup power sources, where the plurality of gravity power generation devices include a target gravity power generation device, where the plurality of elevator control devices include a target control device, where the plurality of backup power sources include a target backup power source, where the target gravity power generation device is configured to obtain electric energy based on potential energy of a target elevator operation, and store the obtained electric energy to the target backup power source, where the apparatus includes:

A receiving unit, configured to receive a backup power transmission request from the target control device, where the backup power transmission request is sent when the target control device detects that the target elevator fails, and the backup power transmission request is used to indicate a target required power, and the target required power is determined according to a remaining power of the target backup power supply;

an obtaining unit, configured to obtain electricity consumption of other standby power sources except the target standby power source in the plurality of standby power sources, where the electricity consumption includes a usage state of the standby power source and/or a remaining power of the standby power source, and the usage state includes in-use or unused;

the determining unit is used for determining a power supply to be called from the other standby power supplies according to the power utilization information of the other standby power supplies and the target required power quantity;

the sending unit is used for sending a standby electricity calling request to a standby electricity calling control device corresponding to the standby electricity source in the plurality of elevator control devices, the standby electricity calling request is used for giving an instruction for controlling the standby electricity source to output electric energy to the target standby electricity source, and the total amount of the electric energy output by the standby electricity source is not smaller than the target required electric quantity.

In a fourth aspect, an embodiment of the present application provides an elevator backup power distribution apparatus, which is applied to a target control device in an elevator gravity power generation system, the elevator gravity power generation system including a management device, a plurality of gravity power generation devices including a target gravity power generation device, a plurality of elevator control devices including the target control device, and a plurality of backup power sources including a target backup power source, the target gravity power generation device being configured to acquire electric energy based on potential energy of a target elevator operation, and store the acquired electric energy to the target backup power source, the apparatus comprising:

the sending unit is used for sending a standby electricity transmission request to the management equipment when the power failure of the target elevator is detected, wherein the standby electricity transmission request is used for indicating target required electric quantity which is determined according to the residual electric quantity of the target standby power supply, and the standby electricity transmission request is used for the management equipment to execute the following steps: acquiring electricity consumption information of other standby power supplies except the target standby power supply in the plurality of standby power supplies, wherein the electricity consumption information comprises a using state of the standby power supply and/or a residual electric quantity of the standby power supply, and the using state comprises in-use or unused state; determining a power supply to be called from the other standby power supplies according to the power consumption information of the other standby power supplies and the target required power quantity; and sending a standby electricity calling request to a to-be-called control device corresponding to the to-be-called power supply in the plurality of elevator control devices, wherein the standby electricity calling request is used for giving an instruction for controlling the to-be-called power supply to output electric energy to the target standby power supply, and the total amount of the electric energy output by the to-be-called power supply is not smaller than the target required electric quantity.

In a fifth aspect, embodiments of the present application provide a management apparatus, including:

one or more processors;

one or more memories for storing programs,

the one or more memories and the program are configured to control, by the one or more processors, the apparatus to perform the steps in the method as described in the first aspect.

In a sixth aspect, embodiments of the present application provide an elevator gravity power generation system comprising a powered device and a management device in a method according to the first aspect.

In a fifth aspect, embodiments of the present application provide a target control apparatus, including:

one or more processors;

one or more memories for storing programs,

the one or more memories and the program are configured to control, by the one or more processors, the device to perform the steps in the method as described in the second aspect.

In a seventh aspect, embodiments of the present application provide a computer-readable storage medium, wherein the computer-readable storage medium stores a computer program for electronic data exchange, wherein the computer program causes a computer to perform part or all of the steps as described in the first aspect or the second aspect of the embodiments of the present application.

In an eighth aspect, the present application provides a computer program product, wherein the computer program product is operable to cause a computer to perform some or all of the steps as described in any of the methods of the first or second aspects of the embodiments of the present application. The computer program product may be a software installation package.

It can be seen that, in this embodiment of the present application, after receiving a standby power transmission request sent by a target control device when a target elevator fails, the management device first obtains power consumption information of other standby power sources except for the target standby power source in a plurality of standby power sources, where the power consumption information includes a use state of the standby power source that is being used or not being used, and/or a remaining power of the standby power source, and then determines a power to be invoked from the other standby power sources according to the power consumption information of the other standby power sources and a target required power quantity determined according to the remaining power of the target standby power source indicated by the received standby power transmission request, and then sends a standby power invocation request to a control device to be invoked corresponding to the power to be invoked, where an instruction for controlling the power to be invoked to output power to the target standby power source is given by the standby power invocation request, and the total amount of power output power to be invoked is not less than the target required power quantity. Therefore, the management equipment can determine a proper power to be called from other standby power sources except the standby power source of the power failure elevator based on the target required power amount and the power consumption information of the other standby power sources, and output electric energy to the target standby power source of the power failure elevator through the power to be called, so that the utilization efficiency of the standby power of the elevator and the use safety of the elevator are improved.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1a is a schematic architecture diagram of an elevator gravity power generation system provided in an embodiment of the present application;

fig. 1b is a schematic structural diagram of an electronic device according to an embodiment of the present application;

fig. 2a is a schematic flow chart of an elevator backup power distribution method according to an embodiment of the present application;

fig. 2b is a schematic diagram of a power outage reminding information display interface according to an embodiment of the present application;

fig. 3a is a schematic view of the composition structure of an elevator standby electricity distribution device according to an embodiment of the present application;

fig. 3b is a schematic view of the composition of another elevator backup power distribution apparatus provided in an embodiment of the present application;

fig. 4a is a schematic view of the composition of another elevator backup power distribution apparatus provided in an embodiment of the present application;

Fig. 4b is a schematic view of the composition of another elevator backup power distribution apparatus provided in an embodiment of the present application.

Detailed Description

In order to make the present application solution better understood by those skilled in the art, the following description will clearly and completely describe the technical solution in the embodiments of the present application with reference to the accompanying drawings in the embodiments of the present application, and it is apparent that the described embodiments are only some embodiments of the present application, not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments herein without making any inventive effort, are intended to be within the scope of the present application.

The terms first, second and the like in the description and in the claims of the present application and in the above-described figures, are used for distinguishing between different objects and not for describing a particular sequential order. Furthermore, the terms "comprise" and "have," as well as any variations thereof, are intended to cover a non-exclusive inclusion. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those listed steps or elements but may include other steps or elements not listed or inherent to such process, method, article, or apparatus.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment may be included in at least one embodiment of the present application. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. Those of skill in the art will explicitly and implicitly appreciate that the embodiments described herein may be combined with other embodiments.

The electronic device according to the embodiments of the present application may include various handheld devices, vehicle-mounted devices, wearable devices, computing devices, or other processing devices connected to a wireless modem, and various forms of User Equipment (UE), mobile Station (MS), terminal devices (terminal devices), and so on. For convenience of description, the above-mentioned devices are collectively referred to as electronic devices.

The embodiment of the application provides an elevator standby electricity distribution method and a related device, and the embodiment of the application is described in detail below with reference to the accompanying drawings.

Referring to fig. 1a, an embodiment of the present application provides an elevator gravity power generation system 10, the elevator gravity power generation system 10 including a management device 100, a plurality of elevator control devices 300, a plurality of gravity power generation devices 200, and a plurality of backup power sources 400. As shown by the dashed boxes in fig. 1a, the plurality of elevator control apparatuses 300, the plurality of gravity power generation apparatuses 200, and the plurality of standby power supplies 400 may correspond to the plurality of elevators, respectively.

Each gravity power generation device 200 can generate electric energy based on potential energy in operation of its corresponding elevator, and store the electric energy in the same standby power supply 400 as the corresponding elevator, when the elevator fails, i.e. the elevator cannot obtain electric energy from the utility power grid, the standby power supply 400 can provide electric energy for the corresponding elevator to supply emergency use, and the electric energy provided by the standby power supply 400 for the elevator can be used for maintaining operation requirements of each basic device in the elevator, supporting communication requirements of devices in the elevator and other devices, such as maintaining power supply of ventilation devices, emergency call devices and power devices in the elevator, and supplying power to the elevator control device 300. In addition, the backup power supply 400 and the gravity power generation device 200 may be controlled by the same elevator control device 300 as the corresponding elevator during the operation thereof.

The management device 100 may be, for example, a designated device in a property management platform of a building area corresponding to the plurality of gravity power generation devices 200, the plurality of elevator control devices 300, and the plurality of standby power sources 400, for example, a server in the property management platform, or a terminal device of the property management platform.

Specifically, in fig. 1a, the correspondence between different elevator control apparatuses 300, the gravity power generation apparatus 200, and the standby power supply 400 and different elevators is marked with a dotted line frame, and referring to the dotted line in fig. 1a, the management apparatus 100 may be communicatively connected to the elevator control apparatuses 300 corresponding to a plurality of different elevators, and each elevator control apparatus 300 may also be communicatively connected to the standby power supply 400 and the gravity power generation apparatus 200 corresponding to the same elevator. As shown by a solid line in fig. 1a, an electric energy transmission path may be provided between the gravity power generation device 200 and the standby power supply 400 corresponding to the same elevator, the gravity power generation device 200 may transmit electric energy obtained based on potential energy of elevator operation to the standby power supply 400 for storage based on the electric energy transmission path, and similarly, electric energy transmission may be performed between the standby power supplies 400 of different elevators based on the electric energy transmission path.

In a specific implementation, based on the architecture of the above-mentioned gravity power generation system 10 for an elevator, after receiving a standby power transmission request sent by a target control device when a target elevator fails, a management device may first obtain power consumption information of other standby power sources except for the target standby power source in a plurality of standby power sources, where the power consumption information includes a use state of the standby power source that is being used or not used, and/or a remaining power of the standby power source, and then determine, according to the power consumption information of the other standby power sources and a target required power quantity determined according to the remaining power of the target standby power source and indicated by the received standby power transmission request, a to-be-called power source from the other standby power sources, and then send a standby power calling request to a to-be-called control device corresponding to the to-be-called power source, where an instruction for controlling the to-be-called power source to output power to the target standby power source is given by the standby power calling request, and the total amount of the to be-called power source to output power is not less than the target required power.

The target control device may be any one of the plurality of elevator control devices 300, and correspondingly, the target standby power source is a standby power source of the same target elevator corresponding to the target control device in the plurality of standby power sources 400, and the target gravity power generation device is a gravity power generation device of the same target elevator corresponding to the target control device and the target standby power source in the plurality of gravity power generation devices 200.

Therefore, the management device can determine the proper power to be called from other standby power sources except the standby power source of the power-off elevator based on the target required power amount and the power consumption information of other standby power sources, and output electric energy to the target standby power sources of the power-off elevator through the power to be called, namely, the electric energy of the standby power sources of a plurality of elevators is integrated and distributed, the standby power is distributed to the elevators needing to be needed for use, the utilization efficiency of the standby power of the elevators is improved, and for the power-off elevators, the electric energy can be obtained from the standby power sources of the other elevators for emergency use, the safety problem caused by sudden power failure of the elevators is avoided, and the use safety of the elevators is improved.

It should be noted that, in practical applications, the number of devices in the elevator gravity power generation system 10 may be more and less than that in fig. 1a, and is not particularly limited herein, for example, the number of standby power sources 400 in fig. 1a may be greater than or less than 3, for example, the number of standby power sources 400 may be 10.

The composition of any electronic device in the present application, such as a management device and an elevator control device, may be as shown in fig. 1b, the electronic device may comprise a processor 110, a memory 120, a communication interface 130, and one or more programs 121, wherein the one or more programs 121 are stored in the memory 120 and configured to be executed by the processor 110, and the one or more programs 121 comprise instructions for executing any step in the above method embodiments performed by the electronic device, such as the management device or the target control device. Wherein the communication interface 130 is used to support communication of an electronic device, such as a management device or a target control device, with other devices. In a specific implementation, the processor 110 is configured to perform any step performed by an electronic device, such as a management device or a target control device, in the method embodiment described below, and when performing data transmission, such as sending, the communication interface 130 is optionally invoked to complete a corresponding operation. It should be noted that the above schematic structural diagram of the electronic device is merely an example, and more or fewer devices may be specifically included, which is not limited only herein.

Referring to fig. 2a, fig. 2a is a schematic flow chart of an elevator backup power distribution method provided in an embodiment of the present application, where the elevator backup power distribution method may be applied to a management device and a target control device in an elevator gravity power generation system shown in fig. 1a, the elevator gravity power generation system including the management device, a plurality of gravity power generation devices including the target gravity power generation device, a plurality of elevator control devices including the target control device, and a plurality of backup power sources including the target backup power source, the target gravity power generation device being configured to obtain electric energy based on potential energy of a target elevator operation, and store the obtained electric energy to the target backup power source, as shown in fig. 2a, the elevator backup power distribution method includes the steps of:

in step 201, when the target control device detects that the target elevator fails, a backup electricity transmission request is sent to the management device, where the backup electricity transmission request is used to indicate a target required power, and the target required power is determined according to the residual power of the target backup power.

The management device may be, for example, a designated device in a property management platform of a building area corresponding to the plurality of gravity power generation devices, the plurality of elevator control devices and the plurality of standby power sources, for example, a server in the property management platform, or a terminal device of the property management platform.

In the specific implementation, after the target control device detects that the target elevator fails, whether the electric quantity of the target standby power supply corresponding to the target elevator is sufficient can be further confirmed, under the condition that the electric quantity of the target standby power supply is sufficient, the electric quantity of the target standby power supply can be directly used for emergency use of all devices in the target elevator, under the condition that the electric quantity of the target standby power supply is insufficient, the target required electric quantity is determined based on the residual electric quantity of the target standby power supply, and a standby electricity transmission request is generated according to the target required electric quantity and is sent to the management device.

Specifically, when determining whether the electric quantity of the target standby power supply is sufficient, for example, the residual electric quantity of the target power supply can be directly compared with a preset value to determine the electric quantity, or whether the electric quantity of the target standby power supply is sufficient can also be determined based on whether passengers are carried in the target elevator, for example, the elevator carried by no passengers is corresponding, after the power failure, even if the residual electric quantity of the standby power supply of the elevator is lower than the preset value, the electric quantity of the elevator can be considered to be sufficient, and further, the electric energy is not required to be acquired from the standby power supplies corresponding to other elevators, so that the resource waste is reduced. The specific numerical value of the preset value can be set according to the needs, and the preset value can be specifically set to meet the following requirements: the power device of the elevator can stop the elevator to the nearest floor within the specific time period, and the preset values corresponding to the standby power supplies of different elevators can be different.

In step 202, the management device receives a request for transmission of backup power from the target control device.

In step 203, the management device obtains the power consumption of the other standby power sources except the target standby power source in the plurality of standby power sources.

Wherein the electricity consumption information comprises at least one of the following: and a use state of the standby power, including being used or not used, the remaining power of the standby power.

In a specific implementation, the standby power supply can be used only when the elevator fails, namely the elevator cannot acquire electric energy from a commercial power grid, namely the elevator corresponding to the standby power supply is defaulted to have no power failure when the use state of the standby power supply is unused.

And 204, the management device determines a power supply to be invoked from the other standby power supplies according to the power consumption of the other standby power supplies and the target required power quantity.

In a specific implementation, when receiving a standby power transmission request sent by an elevator with power failure, the property system management device may send power failure prompt information first, where the power failure prompt information may show a usage state and a residual power of standby power supplies of all elevators capable of supplying power to each other, and may receive a user operation to manually select a power supply to be called and set an electric power required to be output by each power supply to be called to a target standby power supply, and execute step 204 when the user selection operation is not detected in a preset time, and the management device automatically determines the device to be called based on the power utilization information and the target required electric power of other standby power supplies.

In a specific implementation, the manner in which the management device automatically determines the device to be invoked based on the electricity information of other standby power supplies and the target required electricity amount may be, for example, that the elevator that is not used by the standby power supply is preferentially determined to be the power supply to be invoked, when the total amount of electric energy that can be output to the target elevator by the elevator that is not used by the standby power supply is lower than the target required electricity amount, the elevator that is not used by the standby power supply but no passenger preferentially outputs the standby power of itself outwards is continuously determined until the total amount of electric energy that can be output to the target power supply by all determined power supplies to be invoked is not lower than the target required electricity amount. The power of the standby power supply of the uninterrupted elevator can be preferentially called, and when the power of the standby power supply of the uninterrupted elevator is insufficient, the power of the uninterrupted elevator without passengers can be continuously called.

The total amount of electric energy that each standby power supply can output to other standby power supplies may be, for example, all the remaining electric energy of the standby power supply, or a minimum stored electric energy threshold may be set for each standby power supply, that is, the minimum stored electric energy may be a preset value with sufficient electric energy in step 201, and the electric energy that each standby power supply can output to other standby power supplies outwards may be a part of the remaining electric energy that exceeds the minimum stored electric energy threshold, that is, the electric energy stored by each standby power supply under any condition is guaranteed to ensure the emergency use requirement of the elevator.

And 205, the management device sends a standby electricity calling request to a to-be-called control device corresponding to the to-be-called power supply in the plurality of elevator control devices.

The standby power calling request is used for giving an instruction for controlling the power to be called to output electric energy to the target standby power, and the total amount of the electric energy output by the power to be called is not smaller than the target required electric quantity.

In a specific implementation, the standby power call request may further include a power value of the power to be output by each power to be called.

In one possible example, the backup electrical transmission request includes: a plurality of backup power transmission requests corresponding to a plurality of target control devices, each of the backup power transmission requests carrying a response priority determined from biometric information of the target elevator and/or a remaining power of the target backup power source, the biometric information including: a type of organism and/or a number of organisms, the biometric information being detected by the in-target elevator organism detection device; and determining a power supply to be called from the other standby power supplies according to the power consumption information of the other standby power supplies and the target required power quantity, wherein the power supply to be called comprises: determining the processing sequence of the plurality of standby electric transmission requests according to the response priority, wherein the processing sequence of the standby electric transmission requests with higher response priority is more advanced; and sequentially determining a plurality of standby power transmission requests respectively corresponding to the power to be invoked from front to back according to the processing sequence.

In a specific implementation, the biological detection device may include a thermal imager, a camera, and the like, and the type and the number of the biological bodies may be determined by analyzing data acquired by the thermal imager or the camera. The organism types may include, for example: humans, animals, etc., the number of organisms may be as accurate as the specific number of each organism type.

In a specific implementation, the manner of determining the response priority according to the biometric information and/or the remaining power of the target backup power source may be, for example: the response priority is determined according to the organism characteristic information, specifically, the response priority of the organism existing in the elevator can be set to be higher than the response priority of the organism not existing in the elevator, further, the response priority of the organism type including the human being existing in the organism can be set to be higher than the response priority of the organism type not including the human being, further, the response priority corresponding to the elevator with more organisms in different elevators with the same existing organism type can be set to be higher.

In addition, the response priority for a first number of elevators, which is not included in the organism type but is less than the preset number of elevators, is lower than the response priority for a second number of elevators, which is not included in the organism type but is greater than the preset number of organisms. The first number may be 2, the second number may be 10, and may be set according to practical situations, for example, the first number and the second number may be determined according to the capacity of the elevator, so as to ensure that the first number of living beings is relatively stable in the elevator even if waiting for a long time in the elevator during power failure of the elevator, and the values of the first number and the second number are not specifically limited.

Or, the response priority may be determined according to the remaining power of the target standby power supply, and specifically, the remaining power of the target standby power supply may be set to determine the response priority, where the lower the remaining power is, the higher the response priority is. Alternatively, in combination with the preset value for determining that the electric quantity is sufficient in the foregoing step 201, the target standby power supply with a larger ratio of the difference value between the remaining electric quantity and the preset value to the preset value may be set, and the corresponding response priority is higher.

Alternatively, the response priority may be determined jointly in combination with the biometric information and the remaining power of the target backup power source, for example, based on the predicted amount of power consumption of the ventilation device and the emergency communication device of the elevator for a period of time after the biometric information is predicted, the smaller the difference between the predicted amount of power consumption and the remaining power, the higher the response priority.

The method comprises the steps of sequentially determining power sources to be called corresponding to a plurality of standby power transmission requests from front to back according to a processing sequence, namely determining equipment to be called which needs to transmit electric energy to a target standby power source corresponding to a transmission request with high response priority according to target required electric quantity indicated by the standby power transmission request with high response priority and the electric energy consumption information of each other standby power source, and updating the electric energy consumption information of each other standby power source, for example, updating the residual electric quantity which is determined to be the equipment to be called previously to be: the method comprises the steps of determining equipment to be called for a target standby power supply corresponding to a transmission request with lower priority based on updated information after the residual power is transmitted to the target standby power supply corresponding to the transmission request with higher priority.

After determining the power to be invoked corresponding to the standby electric transmission request corresponding to the last higher response priority, two steps can be executed simultaneously, namely, determining the equipment to be invoked corresponding to the standby electric transmission request corresponding to the next lower response priority, and sending the standby electric invocation request to the power to be invoked corresponding to the standby electric transmission request corresponding to the determined last higher priority to a standby electric invocation control device, wherein the standby electric invocation request is processed in parallel, so that the standby electric distribution efficiency is improved.

In this example, the standby electric transmission request includes a response priority determined according to the biological feature information and/or the remaining power of the target standby power supply, and the management device determines the processing order of the multiple standby electric transmission requests according to the response priority, and determines the power to be invoked corresponding to the multiple standby electric transmission requests sequentially from front to back according to the processing order, which is beneficial to improving the flexibility and intelligence of the allocation of the standby electric of the elevator.

In one possible example, the power consumption information of the backup power source includes: the method for determining the power to be invoked from the other standby power supplies according to the power information of the other standby power supplies and the target required power quantity comprises the following steps: determining a candidate standby power supply with an unused use state from the standby power supplies; when the number of the candidate standby power supplies is multiple, determining the calling priority of the multiple candidate standby power supplies according to the residual electric quantity of the multiple candidate standby power supplies, wherein the more the residual electric quantity of the candidate standby power supplies is, the higher the calling priority of the candidate standby power supplies is; and determining N candidate standby power supplies with highest calling priority in the plurality of candidate standby power supplies as the power supplies to be called, wherein the sum of the residual electric quantity of the power supplies to be called is not smaller than the target required electric quantity, and N is a positive integer.

In a specific implementation, for the case that the candidate standby power supply is one, the one candidate standby power supply can be directly determined as the power supply to be invoked. The determining of the calling priority of the plurality of candidate standby power supplies according to the remaining power quantities of the plurality of candidate standby power supplies may specifically be performed under the condition that the total amount of the remaining lighting of the plurality of candidate standby power supplies is not less than the target required power quantity, and if the remaining power quantities of the plurality of candidate standby power supplies are less than the target required power quantity, the plurality of candidate standby power supplies are directly determined to be the power supplies to be called.

In a specific implementation, the remaining power of the candidate standby power supply may be the actual total remaining power of the candidate standby power supply, or may be a difference obtained by subtracting the preset value in the case of sufficient power in the foregoing step 201 from the actual total remaining power of the candidate standby power supply.

In this example, the management device determines the candidate standby power supplies whose usage status is unused from the standby power supplies, determines the calling priorities of the candidate standby power supplies according to the remaining power quantities of the candidate standby power supplies when the candidate standby power supplies are multiple, and then determines N candidate standby power supplies with highest calling priorities among the candidate standby power supplies as power supplies to be called, which is beneficial to improving the accuracy of power supply allocation and avoiding unnecessary influence on other elevators.

In one possible example, the method further comprises: acquiring target position information of the target elevator and other position information of other elevators corresponding to the other standby power supplies; the determining the calling priority of the plurality of candidate standby power supplies according to the residual capacity of the plurality of candidate standby power supplies comprises the following steps: determining the reference priority of a plurality of candidate standby power supplies according to the residual electric quantity of the candidate standby power supplies; and determining the calling priorities of the plurality of candidate standby power supplies according to the target position information, the other position information and the reference priority, wherein the calling priorities corresponding to the candidate standby power supplies are higher as the distance between the other position information corresponding to the candidate standby power supply and the target position information is smaller under the condition that the reference priorities are the same.

It can be seen that, in this example, for the candidate standby power supply with the same reference priority, the smaller the position of the candidate standby power supply and the target position of the target standby power supply, the higher the calling priority of the candidate standby power supply is, which is beneficial to further improving the timeliness of the standby power distribution.

In one possible example, the standby electricity transmission request is sent when the target control device detects that the target elevator has failed and the remaining capacity of the target standby power supply is not higher than a preset capacity, when the remaining capacity of the target standby power supply is higher than the preset capacity, the remaining capacity of the target standby power supply is used to power the ventilation device, the emergency communication device and the power device of the target elevator, and the target control device stops the target elevator at the nearest floor through the power device of the target elevator.

In a specific implementation, the preset electric quantity may be a preset value with sufficient electric quantity in step 201, when the target elevator fails, if the remaining lighting of the target standby power supply is higher than the preset electric quantity, the target standby power supply does not need to output electric energy to the target standby power supply through other standby power supplies, and the target standby power supply can supply power to the ventilation equipment, the emergency communication equipment and the power equipment of the elevator, and stop the target elevator at the nearest floor through the power equipment of the target elevator.

In addition, in practical application, after the target calling device sends a standby electricity transmission request, the residual electric quantity of the target standby power supply can be periodically detected, when the residual electric quantity is detected to be higher than the target required electric quantity or the preset value in step 201, the power device of the target elevator can be controlled to stop the target elevator to the nearest floor, otherwise, the power supply to the ventilation device and the emergency communication device of the elevator is still kept, and the power device is not controlled to stop the elevator to the nearest floor.

In this example, the standby power transmission request is sent to the management device only when the remaining power is insufficient, so that the management device is requested to determine and notify other power sources to be called to output power to the target standby power source, which is beneficial to avoiding resource waste.

In one possible example, the standby electricity transmission request is sent when the target control device detects that the target elevator has failed and the remaining power of the target standby power supply is not higher than a preset power amount and the presence of an organism in the target elevator is detected by the organism detection device of the target elevator, the method further comprising: receiving power outage notification information from the target control device, wherein the power outage notification information is transmitted when the target control device detects that the target elevator has a power outage and the organism detection device of the target elevator detects that no organism exists in the target elevator; outputting power failure reminding information, wherein the power failure reminding information comprises at least one of the following: audio, text, images; and sending power supply stopping notification information to the target control equipment in response to the confirmation operation of the power failure reminding information, wherein the power supply stopping notification information is used for giving an instruction for controlling the target standby power supply to cancel power supply to the ventilation equipment and the emergency communication equipment of the target elevator.

The target control device can not control the power device to stop to the nearest floor or send a standby electricity transmission request to the management device when the residual electric quantity of the target standby power supply is not higher than the preset electric quantity but no organism exists in the target elevator, the power supply of the ventilation device and the emergency communication device in the elevator is maintained, the management device can send out reminding information after receiving the power failure notification, a worker affiliated to the management device can conveniently know the power failure information and go to the site of the target elevator to confirm, and after the worker confirms that no organism exists in the elevator manually, the management device can send power supply stopping notification information to inform the target standby power supply to cancel the power supply to the ventilation device and the emergency communication device of the target elevator.

The power failure reminding information can specifically comprise monitoring images collected by the camera in the target elevator, so that a worker can conveniently confirm whether organisms exist in the target elevator.

In the specific implementation, for the situation that the residual electric quantity of the target standby power supply is higher than the preset electric quantity, the target control device does not send a standby electric transmission request, the power supply of the target ventilation device and the emergency communication device can be always kept, the target elevator can be stopped at the nearest floor through the power device when the organism in the target elevator is detected, stopping at the nearest floor is not needed when the organism is not detected, or stopping at the nearest floor no matter whether the organism is detected or not.

In addition, the management equipment can automatically send the notification information carrying the position of the target elevator to specific equipment in the fire platform or specific equipment of an elevator maintenance enterprise no matter receiving a standby electricity transmission request or power failure notification information of the target elevator, and notify workers to go to maintenance or rescue.

For example, the management device may display, on the display screen, a power outage notification interface such as that shown in fig. 2b, in which text notification information such as "there is a power outage of an elevator, please go to check" may be displayed, basic information such as an elevator number, an elevator model number, and an elevator position of a target elevator may be displayed, and in a position area shown in image 1 in fig. 2b, an intra-elevator monitoring image of the target elevator may be displayed, a confirmation control may be displayed, and prompt information prompting a user to click a confirmation button after confirming a person in the power outage elevator may be displayed. It should be noted that, fig. 2b is only an exemplary illustration, and the display content of the power outage reminding information display interface in practical application may be different from that of fig. 2b, for example, only the text reminding information may be displayed, but no image is displayed, or the displayed text reminding information may be replaced by any other text content, and the present invention is not limited in particular.

It can be seen that, in this example, after the management device receives the power outage notification information sent when the target control device detects that the target elevator has a power outage and the organism detection device of the target elevator detects that there is no organism in the target elevator, the management device may output the power outage notification information including at least one of audio, text and image, and may send the power outage notification information to the target control device in response to the confirmation operation for the power outage notification information, so as to control the target standby power supply to cancel the power supply to the ventilation device and the emergency communication device of the target elevator, which is beneficial to avoiding unnecessary waste of the standby power of the elevator.

In one possible example, after the receiving the backup power transmission request, the method further includes: acquiring the ambient temperature at the current moment; determining an adjustment rule for adjusting the working parameters of the ventilation equipment according to the ambient temperature, wherein the adjustment rule comprises the corresponding relation between the working parameters of the ventilation equipment and the oxygen concentration and/or the air humidity, and the working parameters comprise at least one of the following: a start state and a ventilation wind speed, wherein the start state comprises the starting of ventilation equipment or the closing of ventilation equipment; and sending a ventilation fan adjusting rule to the target control equipment.

In a specific implementation, the target control device may pre-store the adjustment rule of the ventilation device in advance, where the adjustment rule may be, for example: when the oxygen concentration is detected to be lower than the first preset concentration and/or the temperature is detected to be higher than the first preset temperature, starting the ventilation equipment; closing the ventilation equipment when the oxygen concentration is detected to be not lower than the first preset concentration and/or the temperature is detected to be not higher than the first preset temperature; when the oxygen concentration is detected to be continuously reduced in the preset time period and/or the temperature is detected to be continuously increased in the preset time period, the ventilation wind speed of the ventilation equipment is adjusted to be higher than the current preset wind speed and the preset wind speed with the smallest difference value with the current wind speed in a plurality of preset wind speeds; when the oxygen concentration is detected to be lower than a second preset concentration and/or the temperature is detected to be higher than a second preset temperature, the ventilation wind speed of the ventilation device is adjusted to be the highest value of a plurality of preset wind speeds, the first preset concentration is higher than the second preset concentration, and the first preset temperature is lower than the second preset temperature.

The management device determines an adjustment rule for adjusting the working parameters of the ventilation device according to the environmental information, and may directly query the corresponding relation between a plurality of environmental temperature threshold ranges and a plurality of groups of working parameters pre-stored in the management device according to the real-time outdoor temperature of the region where the target elevator is located, which is acquired from the weather platform, find a preset working parameter value corresponding to the current real-time outdoor temperature, and send the preset working parameter value as the adjustment rule to the target control device.

Specifically, the preset working parameter value includes a specific value of a first preset concentration and/or a specific value of a first preset temperature, and includes a specific value of a second preset concentration and/or a specific value of a second preset temperature, after receiving the working parameter, the target control device directly replaces the working parameter stored in the local end with the working parameter, and if the target control device does not receive an adjustment rule sent by the management device, the target control device does not need to adjust the working parameter, and directly adjusts the working parameter according to the adjustment rule stored in the local end.

In particular, for example, the first preset concentration stored in the local end of the target control device may be 19.5%, and the second preset concentration may be any value from 15% to 19%.

It can be seen that, in this example, the management device obtains the ambient temperature at the current moment, and then determines, according to the ambient temperature, an adjustment rule for adjusting the operating parameter of the ventilation device, where the adjustment rule includes a correspondence relationship between the operating parameter of the ventilation device and the oxygen concentration and/or the air humidity, and the operating parameter includes at least one of: the starting state, the ventilation wind speed and then the ventilation fan adjusting rule are sent to the target control equipment, so that the elevator safety is improved, and meanwhile, unnecessary resource consumption is reduced.

Referring to fig. 3a, fig. 3a is a schematic view of a composition structure of an elevator backup power distribution apparatus provided in an embodiment of the present application, which is applicable to a management device in an elevator gravity power generation system shown in fig. 1a, the elevator gravity power generation system including the management device, a plurality of gravity power generation devices including a target gravity power generation device, a plurality of elevator control devices including a target control device, and a plurality of backup power sources including a target backup power source, the target gravity power generation device being configured to obtain electric energy based on potential energy of a target elevator operation, and store the obtained electric energy to the target backup power source, the elevator backup power distribution apparatus 30 includes:

a receiving unit 301, configured to receive a backup power transmission request from the target control device, where the backup power transmission request is sent when the target control device detects that the target elevator fails, and the backup power transmission request is used to indicate a target required power, where the target required power is determined according to a remaining power of the target backup power supply;

an obtaining unit 302, configured to obtain electricity consumption of other standby power sources than the target standby power source from the plurality of standby power sources, where the electricity consumption includes a usage state of the standby power source and/or a remaining power of the standby power source, and the usage state includes being used or not used;

A determining unit 303, configured to determine a power supply to be invoked from the other standby power supplies according to the power consumption information of the other standby power supplies and the target required power quantity;

and the sending unit 304 is configured to send a standby power calling request to a to-be-called control device corresponding to the to-be-called power supply in the plurality of elevator control devices, where the standby power calling request is used to give an instruction for controlling the to-be-called power supply to output electric energy to the target standby power supply, and the total amount of electric energy output by the to-be-called power supply is not less than the target required electric quantity.

In one possible example, the backup electrical transmission request includes: a plurality of backup power transmission requests corresponding to a plurality of target control devices, each of the backup power transmission requests carrying a response priority determined from biometric information of the target elevator and/or a remaining power of the target backup power source, the biometric information including: a type of organism and/or a number of organisms, the biometric information being detected by the in-target elevator organism detection device; the determining unit 303 is specifically configured to: determining the processing sequence of the plurality of standby electric transmission requests according to the response priority, wherein the processing sequence of the standby electric transmission requests with higher response priority is more advanced; and sequentially determining a plurality of standby power transmission requests respectively corresponding to the power to be invoked from front to back according to the processing sequence.

In one possible example, the power consumption information of the backup power source includes: the determining unit 303 is specifically configured to: determining a candidate standby power supply with an unused use state from the standby power supplies; when the number of the candidate standby power supplies is multiple, determining the calling priority of the multiple candidate standby power supplies according to the residual electric quantity of the multiple candidate standby power supplies, wherein the more the residual electric quantity of the candidate standby power supplies is, the higher the calling priority of the candidate standby power supplies is; and determining N candidate standby power supplies with highest calling priority in the plurality of candidate standby power supplies as the power supplies to be called, wherein the sum of the residual electric quantity of the power supplies to be called is not smaller than the target required electric quantity, and N is a positive integer.

In one possible example, the elevator backup power distribution device 30 is specifically configured to: acquiring target position information of the target elevator and other position information of other elevators corresponding to the other standby power supplies; the determining the calling priority of the plurality of candidate standby power supplies according to the residual capacity of the plurality of candidate standby power supplies comprises the following steps: determining the reference priority of a plurality of candidate standby power supplies according to the residual electric quantity of the candidate standby power supplies; and determining the calling priorities of the plurality of candidate standby power supplies according to the target position information, the other position information and the reference priority, wherein the calling priorities corresponding to the candidate standby power supplies are higher as the distance between the other position information corresponding to the candidate standby power supply and the target position information is smaller under the condition that the reference priorities are the same.

In one possible example, the standby electricity transmission request is sent when the target control device detects that the target elevator has failed and the remaining power of the target standby power supply is not higher than a preset power amount and the presence of a living body in the target elevator is detected by the living body detection device of the target elevator, and the elevator standby electricity distribution device 30 is further configured to: receiving power outage notification information from the target control device, wherein the power outage notification information is transmitted when the target control device detects that the target elevator has a power outage and the organism detection device of the target elevator detects that no organism exists in the target elevator; outputting power failure reminding information, wherein the power failure reminding information comprises at least one of the following: audio, text, images; and sending power supply stopping notification information to the target control equipment in response to the confirmation operation of the power failure reminding information, wherein the power supply stopping notification information is used for giving an instruction for controlling the target standby power supply to cancel power supply to the ventilation equipment and the emergency communication equipment of the target elevator.

In one possible example, the elevator backup power distribution apparatus 30 is further configured to obtain an ambient temperature at a current time after the receiving of the backup power transmission request; determining an adjustment rule for adjusting the working parameters of the ventilation equipment according to the ambient temperature, wherein the adjustment rule comprises the corresponding relation between the working parameters of the ventilation equipment and the oxygen concentration and/or the air humidity, and the working parameters comprise at least one of the following: a start state and a ventilation wind speed, wherein the start state comprises the starting of ventilation equipment or the closing of ventilation equipment; and sending a ventilation fan adjusting rule to the target control equipment.

In case of an integrated unit, another elevator backup power distribution apparatus provided in an embodiment of the present application is schematically illustrated in fig. 3 b. In fig. 3b, the elevator backup electricity distribution device comprises: a processing module 310 and a communication module 311. The processing module 310 is used for controlling and managing the actions of the elevator backup power distribution device, e.g. the steps performed by the receiving unit 301, the obtaining unit 302, the determining unit 303 and the transmitting unit 304, and/or for performing other procedures of the technology described herein. The communication module 311 is used to support the interaction between the elevator backup power distribution apparatus and other devices. As shown in fig. 3b, the elevator backup power distribution apparatus may further comprise a memory module 312, the memory module 312 being for storing program codes and data of the elevator backup power distribution apparatus.

The processing module 310 may be a processor or controller, such as a central processing unit (Central Processing Unit, CPU), a general purpose processor, a digital signal processor (Digital Signal Processor, DSP), an ASIC, an FPGA or other programmable logic device, a transistor logic device, a hardware component, or any combination thereof. Which may implement or perform the various exemplary logic blocks, modules, and circuits described in connection with this disclosure. The processor may also be a combination that performs the function of a computation, e.g., a combination comprising one or more microprocessors, a combination of a DSP and a microprocessor, and the like. The communication module 311 may be a transceiver, an RF circuit, a communication interface, or the like. The memory module 312 may be a memory.

All relevant contents of each scenario related to the above method embodiment may be cited to the functional description of the corresponding functional module, which is not described herein. The above-mentioned elevator backup power allocation apparatus can perform the steps performed by the management device in the above-mentioned elevator backup power allocation method shown in fig. 2 a.

Referring to fig. 4a, fig. 4a is a schematic view of a composition structure of an elevator standby power distribution device provided in an embodiment of the present application, which is applicable to a target control device in an elevator gravity power generation system shown in fig. 1a, the elevator gravity power generation system including a management device, a plurality of gravity power generation devices including a target gravity power generation device, a plurality of elevator control devices including a target standby power source, and a plurality of standby power sources including a target standby power source, the target gravity power generation device being configured to acquire electric energy based on potential energy of a target elevator operation, and store the acquired electric energy to the target standby power source, the elevator standby power distribution device 40 includes:

A sending unit 401, configured to send, when it is detected that the target elevator fails, a backup electricity transmission request to the management device, where the backup electricity transmission request is used to indicate a target required power, where the target required power is determined according to a remaining power of the target backup power, and the backup electricity transmission request is used by the management device to perform the following steps: acquiring electricity consumption information of other standby power supplies except the target standby power supply in the plurality of standby power supplies, wherein the electricity consumption information comprises a using state of the standby power supply and/or a residual electric quantity of the standby power supply, and the using state comprises in-use or unused state; determining a power supply to be called from the other standby power supplies according to the power consumption information of the other standby power supplies and the target required power quantity; and sending a standby electricity calling request to a to-be-called control device corresponding to the to-be-called power supply in the plurality of elevator control devices, wherein the standby electricity calling request is used for giving an instruction for controlling the to-be-called power supply to output electric energy to the target standby power supply, and the total amount of the electric energy output by the to-be-called power supply is not smaller than the target required electric quantity.

In case of an integrated unit, another elevator backup power distribution apparatus provided in an embodiment of the present application is schematically illustrated in fig. 4 b. In fig. 4b, the elevator backup electricity distribution device comprises: a processing module 410 and a communication module 411. The processing module 410 is used for controlling and managing the actions of the elevator backup power distribution device, e.g. the steps performed by the sending unit 401, and/or for performing other processes of the technology described in the present application. The communication module 411 is used to support the interaction between the elevator backup power distribution apparatus and other devices. As shown in fig. 4b, the elevator backup power distribution apparatus may further comprise a memory module 412, the memory module 412 being used to store program codes and data of the elevator backup power distribution apparatus.

The processing module 410 may be a processor or controller, such as a central processing unit (Central Processing Unit, CPU), a general purpose processor, a digital signal processor (Digital Signal Processor, DSP), an ASIC, an FPGA or other programmable logic device, a transistor logic device, a hardware component, or any combination thereof. Which may implement or perform the various exemplary logic blocks, modules, and circuits described in connection with this disclosure. The processor may also be a combination that performs the function of a computation, e.g., a combination comprising one or more microprocessors, a combination of a DSP and a microprocessor, and the like. The communication module 411 may be a transceiver, an RF circuit, or a communication interface, etc. The storage module 412 may be a memory.

All relevant contents of each scenario related to the above method embodiment may be cited to the functional description of the corresponding functional module, which is not described herein. The above-described elevator backup power distribution apparatus can perform the steps performed by the target control device in the above-described elevator backup power distribution method shown in fig. 2 a.

The embodiment of the application also provides a computer storage medium, wherein the computer storage medium stores a computer program for electronic data exchange, and the computer program makes a computer execute part or all of the steps of any one of the methods described in the embodiment of the method, and the computer includes a management device or a target control device.

Embodiments of the present application also provide a computer program product comprising a computer program product operable to cause a computer to perform part or all of the steps of any of the methods as described in the method embodiments above.

The computer program product may be a software installation package, said computer comprising a management device or a target control device.

It should be noted that, for simplicity of description, the foregoing method embodiments are all expressed as a series of action combinations, but it should be understood by those skilled in the art that the present application is not limited by the order of actions described, as some steps may be performed in other order or simultaneously in accordance with the present application. Further, those skilled in the art will also appreciate that the embodiments described in the specification are all preferred embodiments and that the acts and elements referred to are not necessarily required in the present application.

In the foregoing embodiments, the descriptions of the embodiments are emphasized, and for parts of one embodiment that are not described in detail, reference may be made to related descriptions of other embodiments.

In the several embodiments provided in this application, it should be understood that the disclosed apparatus may be implemented in other ways. For example, the above-described apparatus embodiments are merely illustrative, such as the above-described division of units, merely a division of logic functions, and there may be additional manners of dividing in actual implementation, such as multiple units or components may be combined or integrated into another system, or some features may be omitted, or not performed. Alternatively, the coupling or direct coupling or communication connection shown or discussed with each other may be an indirect coupling or communication connection via some interfaces, devices or units, or may be in electrical or other forms.

The units described above as separate components may or may not be physically separate, and components shown as units may or may not be physical units, may be located in one place, or may be distributed over a plurality of network units. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, each functional unit in each embodiment of the present application may be integrated in one processing unit, or each unit may exist alone physically, or two or more units may be integrated in one unit. The integrated units may be implemented in hardware or in software functional units.

The integrated units described above, if implemented in the form of software functional units and sold or used as stand-alone products, may be stored in a computer readable memory. Based on such understanding, the technical solution of the present application may be embodied in essence or a part contributing to the prior art or all or part of the technical solution in the form of a software product stored in a memory, including several instructions for causing a computer device (which may be a personal computer, a server or a network device, etc.) to perform all or part of the steps of the above-mentioned method of the various embodiments of the present application. And the aforementioned memory includes: a U-disk, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), a removable hard disk, a magnetic disk, or an optical disk, or other various media capable of storing program codes.

Those of ordinary skill in the art will appreciate that all or a portion of the steps in the various methods of the above embodiments may be implemented by a program that instructs associated hardware, and the program may be stored in a computer readable memory, which may include: flash disk, read-Only Memory (ROM), random access Memory (Random Access Memory, RAM), magnetic disk or optical disk.

The foregoing has described in detail the embodiments of the present application, wherein specific examples are employed to illustrate the principles and embodiments of the present application, and the description of the above embodiments is only for the purpose of aiding in the understanding of the methods and core ideas of the present application; meanwhile, as those skilled in the art will have modifications in the specific embodiments and application scope in accordance with the ideas of the present application, the present description should not be construed as limiting the present application in view of the above.

Claims

1. An elevator backup power distribution method, characterized by being applied to a management device in an elevator gravity power generation system including the management device, a plurality of gravity power generation devices including a target gravity power generation device, a plurality of elevator control devices including a target control device, and a plurality of backup power sources including a target backup power source for acquiring electric energy based on potential energy of a target elevator operation, and storing the acquired electric energy to the target backup power source, the method comprising:

2. The method of claim 1, wherein the backup electrical transmission request comprises: a plurality of backup power transmission requests corresponding to a plurality of target control devices, each of the backup power transmission requests carrying a response priority determined from biometric information of the target elevator and/or a remaining power of the target backup power source, the biometric information including: a type of organism and/or a number of organisms, the biometric information being detected by the in-target elevator organism detection device; and determining a power supply to be called from the other standby power supplies according to the power consumption information of the other standby power supplies and the target required power quantity, wherein the power supply to be called comprises:

Determining the processing sequence of the plurality of standby electric transmission requests according to the response priority, wherein the processing sequence of the standby electric transmission requests with higher response priority is more advanced;

and sequentially determining a plurality of standby power transmission requests respectively corresponding to the power to be invoked from front to back according to the processing sequence.

3. The method according to claim 1 or 2, wherein the power consumption information of the backup power source includes: the method for determining the power to be invoked from the other standby power supplies according to the power information of the other standby power supplies and the target required power quantity comprises the following steps:

determining a candidate standby power supply with an unused use state from the standby power supplies;

when the number of the candidate standby power supplies is multiple, determining the calling priority of the multiple candidate standby power supplies according to the residual electric quantity of the multiple candidate standby power supplies, wherein the more the residual electric quantity of the candidate standby power supplies is, the higher the calling priority of the candidate standby power supplies is;

and determining N candidate standby power supplies with highest calling priority in the plurality of candidate standby power supplies as the power supplies to be called, wherein the sum of the residual electric quantity of the power supplies to be called is not smaller than the target required electric quantity, and N is a positive integer.

4. A method according to claim 3, characterized in that the method further comprises:

acquiring target position information of the target elevator and other position information of other elevators corresponding to the other standby power supplies;

the determining the calling priority of the plurality of candidate standby power supplies according to the residual capacity of the plurality of candidate standby power supplies comprises the following steps:

determining the reference priority of a plurality of candidate standby power supplies according to the residual electric quantity of the candidate standby power supplies;

and determining the calling priorities of the plurality of candidate standby power supplies according to the target position information, the other position information and the reference priority, wherein the calling priorities corresponding to the candidate standby power supplies are higher as the distance between the other position information corresponding to the candidate standby power supply and the target position information is smaller under the condition that the reference priorities are the same.

5. The method according to claim 1, characterized in that the backup power transmission request is sent when the target control device detects that the target elevator has failed and the remaining power of the target backup power supply is not higher than a preset power level, when the remaining power of the target backup power supply is higher than the preset power level, the remaining power of the target backup power supply is used to power the ventilation device, the emergency communication device and the power device of the target elevator, and the target control device is used to stop the target elevator at the nearest floor by the power device of the target elevator.

6. The method of claim 5, wherein the backup power transmission request is transmitted when the target control device detects that the target elevator has failed and the remaining power of the target backup power source is not higher than a preset power amount and the presence of an organism within the target elevator is detected by an organism detection device of the target elevator, the method further comprising:

receiving power outage notification information from the target control device, wherein the power outage notification information is transmitted when the target control device detects that the target elevator has a power outage and the organism detection device of the target elevator detects that no organism exists in the target elevator;

outputting power failure reminding information, wherein the power failure reminding information comprises at least one of the following: audio, text, images;

and sending power supply stopping notification information to the target control equipment in response to the confirmation operation of the power failure reminding information, wherein the power supply stopping notification information is used for giving an instruction for controlling the target standby power supply to cancel power supply to the ventilation equipment and the emergency communication equipment of the target elevator.

7. The method of claim 5 or 6, wherein after the receiving the backup power transmission request, the method further comprises:

Acquiring the ambient temperature at the current moment;

determining an adjustment rule for adjusting the working parameters of the ventilation equipment according to the ambient temperature, wherein the adjustment rule comprises the corresponding relation between the working parameters of the ventilation equipment and the oxygen concentration and/or the air humidity, and the working parameters comprise at least one of the following: a start state and a ventilation wind speed, wherein the start state comprises the starting of ventilation equipment or the closing of ventilation equipment;

and sending a ventilation fan adjusting rule to the target control equipment.

8. A method of allocating backup power for an elevator, characterized by being applied to a target control device in an elevator gravity power generation system including a management device, a plurality of gravity power generation devices including the target gravity power generation device, a plurality of elevator control devices including the target control device, and a plurality of backup power sources including a target backup power source for acquiring electric energy based on potential energy of a target elevator operation, and storing the acquired electric energy to the target backup power source, the method comprising:

9. An elevator backup power distribution apparatus characterized by being applied to a management device in an elevator gravity power generation system including the management device, a plurality of gravity power generation devices including a target gravity power generation device, a plurality of elevator control devices including a target control device, and a plurality of backup power sources including a target backup power source for acquiring electric power based on potential energy of a target elevator operation, and storing the acquired electric power to the target backup power source, the apparatus comprising:

10. An elevator backup power distribution apparatus characterized by being applied to a target control device in an elevator gravity power generation system including a management device, a plurality of gravity power generation devices including the target gravity power generation device, a plurality of elevator control devices including the target control device, and a plurality of backup power sources including a target backup power source for acquiring electric energy based on potential energy of a target elevator operation, and storing the acquired electric energy to the target backup power source, the apparatus comprising: