WO2019140799A1 - 一种电梯运行状态监测系统及方法 - Google Patents

一种电梯运行状态监测系统及方法 Download PDF

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Publication number
WO2019140799A1
WO2019140799A1 PCT/CN2018/083841 CN2018083841W WO2019140799A1 WO 2019140799 A1 WO2019140799 A1 WO 2019140799A1 CN 2018083841 W CN2018083841 W CN 2018083841W WO 2019140799 A1 WO2019140799 A1 WO 2019140799A1
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Prior art keywords
elevator
floor information
serial port
speed
running
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PCT/CN2018/083841
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English (en)
French (fr)
Inventor
曹建民
孙瑞泽
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深圳技术大学(筹)
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Publication of WO2019140799A1 publication Critical patent/WO2019140799A1/zh

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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B66HOISTING; LIFTING; HAULING
    • B66BELEVATORS; ESCALATORS OR MOVING WALKWAYS
    • B66B5/00Applications of checking, fault-correcting, or safety devices in elevators
    • B66B5/0006Monitoring devices or performance analysers
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B66HOISTING; LIFTING; HAULING
    • B66BELEVATORS; ESCALATORS OR MOVING WALKWAYS
    • B66B5/00Applications of checking, fault-correcting, or safety devices in elevators
    • B66B5/0006Monitoring devices or performance analysers
    • B66B5/0018Devices monitoring the operating condition of the elevator system
    • B66B5/0031Devices monitoring the operating condition of the elevator system for safety reasons

Definitions

  • the invention relates to the field of elevators, and in particular to an elevator operating state monitoring system and method.
  • the main object of the present invention is to provide an elevator operating state monitoring system and method, aiming at solving the problems of the existing elevator centralized monitoring system having many fault nodes, high installation cost and incompatible interfaces.
  • a first aspect of the present invention provides an elevator operating condition monitoring system for monitoring an elevator including an elevator controller and a signal processing board, the elevator operating state monitoring system including remote monitoring Platform, network system and data collector;
  • the remote monitoring platform is connected to the network system, and the network system is wirelessly connected to the data collector;
  • the serial port pin of the elevator controller is connected to a serial port pin of the signal processing board, and a part of the serial port pin of the elevator controller is also connected to a serial port pin of the data collector.
  • the data collector includes a single chip microcomputer and a global mobile communication system GSM communication circuit, and the single chip microcomputer is connected to the elevator controller through a serial line, and the GSM communication circuit is connected to the single chip through another serial port line. Connected, the GSM communication circuit is also wirelessly coupled to the network system.
  • model of the single chip microcomputer is STC89C52RC.
  • model of the GSM communication circuit is TC35i.
  • a second aspect of the present invention provides a method for monitoring an operation state of an elevator, the method being applicable to the elevator operation state monitoring system of the first aspect, the method comprising:
  • the actual running speed is analyzed, and the running state of the elevator is determined according to the analysis result.
  • the determining the actual running speed of the elevator according to the startup floor information, the stop floor information, and the running time includes:
  • t represents the running time of the elevator
  • a represents the elevator braking acceleration
  • v actually represents the actual running speed of the elevator to be determined
  • t ⁇ represents the elevator crawling time
  • x ⁇ represents the elevator crawling distance
  • N 1 represents the starting floor information
  • N 2 represents The floor information is stopped
  • H represents a single storey building height
  • H(N 2 -N 1 ) represents the running distance of the elevator.
  • the method further includes:
  • v Actually represents the actual running speed of the elevator to be determined, H represents a single storey height, and t represents the actual running time of the elevator.
  • the analyzing the actual running speed, and determining the running state of the elevator according to the analysis result including:
  • the elevator running state is a fault state
  • the first elevator running speed condition is:
  • v rating represents the rated operating speed of the elevator, and v actually represents the actual operating speed of the elevator to be determined.
  • the analyzing the actual running speed, and determining the running state of the elevator according to the analysis result including:
  • the elevator running state is a fault state
  • the second elevator running speed condition is:
  • H means single-story height
  • t ⁇ means elevator crawl time
  • the determining the startup floor information and the stop floor information of the elevator includes:
  • the data collector is used to monitor whether the elevator controller sends a first light control signal including an elevator start signal and a startup floor information within a preset time period;
  • the stop floor information is determined from the second lamp control signal.
  • the invention provides an elevator running state monitoring system, and an elevator running state monitoring system is used for monitoring an elevator including an elevator controller and a signal processing board.
  • the elevator running state monitoring system comprises a remote monitoring platform, a network system and a data collector, and a remote monitoring platform.
  • the network system is wirelessly connected with the data collector, and the serial port pin of the elevator controller is connected with the serial port pin of the signal processing board, and part of the serial port pin of the elevator controller is also connected with the serial port pin of the data collector. connection.
  • the data collector is used to collect the elevator data from the serial port pin of the elevator controller, and the collected data is sent to the remote monitoring platform to monitor the running state of the elevator, because a large number of The sensor collects the data of the elevator, so the installation cost is reduced, and the faulty node is reduced; because the data collector wirelessly connects the network system and the remote detection platform, the installation is further simplified; since the data is directly read from the serial port pins of the elevator controller, Only the supervisor does not control, it will not affect the operation of the original system; and because each manufacturer's elevator has a serial port pin, the serial port pin can be used to regulate the data monitoring interface of the elevator running state monitoring system, and the interface is solved.
  • the problem of incompatibility is convenient for the wide range of elevator operation condition monitoring systems.
  • FIG. 1 is a schematic structural diagram of an elevator running state monitoring system according to a first embodiment of the present invention
  • FIG. 2 is a schematic diagram showing the refinement structure of the data collector in the first embodiment of the present invention.
  • FIG. 3 is a schematic flow chart of a method for monitoring an operating state of an elevator according to a second embodiment of the present invention
  • FIG. 4 is a schematic flow chart of a method for monitoring an operating state of an elevator according to a third embodiment of the present invention.
  • FIG. 5 is a ladder type speed model according to a third embodiment of the present invention.
  • FIG. 6 is a schematic diagram showing the refinement flow of determining the startup floor information and the stop floor information of the elevator in step 401 shown in FIG. 4.
  • FIG. 1 is a schematic structural diagram of an elevator operating state monitoring system according to a first embodiment of the present invention.
  • the elevator operating state monitoring system is configured to monitor an elevator including an elevator controller 40 and a signal processing board 50.
  • the elevator operating condition monitoring system includes a remote monitoring platform 10, a network system 20, and a data collector 30;
  • the remote monitoring platform 10 is connected to the network system 20, and the network system 20 is wirelessly connected to the data collector 30;
  • the serial port pin of the elevator controller 40 is connected to the serial port pin of the signal processing board 50, and a part of the serial port pin of the elevator controller 40 is also connected to the serial port pin of the data collector 30.
  • the remote monitoring platform 10 includes a monitoring platform used by the management and maintenance department, an elevator manufacturer, and a monitoring platform used by the quality inspection organization.
  • the serial port pins of the elevator controller 40 include a clock serial port pin CLOCK, a synchronous output serial port pin SYNCO, a call serial port pin DI, a synchronous input serial port pin SYNCI, and a lamp control serial port pin DO, and a signal processing board 50.
  • the serial port pins include the clock serial port pin CLOCK, the synchronous input serial port pin SYNCI(n), the summoning serial port pin DO, the synchronous output serial port pin SYNCO(n), and the lamp control serial port pin DI.
  • serial connection between the serial port pin of the elevator controller 40 and the serial port pin of the signal processing board 50 is as follows: the clock serial port pin CLOCK of the elevator controller 40 is connected with the clock serial port pin CLOCK of the signal processing board 50, and the elevator controller
  • the synchronous output serial port pin SYNCO of 40 is connected with the synchronous input serial port pin SYNCI(n) of the signal processing board 50, and the lamp control serial port pin DO of the elevator controller 40 and the lamp control serial port pin DI of the signal processing board 50 are connected.
  • the call serial port pin DI of the elevator controller 40 is connected to the call serial port pin DO of the signal processing board 50, and the synchronous input serial port pin SYNCI of the elevator controller 40 and the synchronous output serial port pin SYNCO of the signal processing board 50 are connected. (n) Connected.
  • the serial port pins of the data collector 30 include a clock serial port pin CLOCK, a synchronous input serial port pin SYNCI, and a lamp control serial port pin DI.
  • the specific serial connection between the serial port pin of the elevator controller 40 and the serial port pin of the data collector 30 is as follows: the clock serial port pin CLOCK of the data collector 30 is connected with the clock serial port pin CLOCK of the elevator controller 40, and data acquisition is performed.
  • the synchronous input serial port pin SYNCI of the device 30 is connected to the synchronous output serial port pin SYNCO of the elevator controller 40, and the lamp control serial port pin DI of the data collector 30 is connected to the lamp control serial port pin DO of the elevator controller 40.
  • the signal processing board 50 may be the signal processing board 50 of the elevator control box or the signal processing board 50 of the elevator call box.
  • the signal processing board 50 first sends a call signal to the serial port pin of the elevator controller 40 by using its own serial port pin. Specifically, the signal processing board 50 calls the serial port pin DO to send a call signal. .
  • the elevator controller 40 After receiving the call signal sent by the signal processing board 50, the elevator controller 40 sends a synchronous output signal to the serial port pin of the signal processing board 50 through its serial port pin.
  • the synchronous output serial port pin of the elevator controller 40 SYNCO sends a synchronous output signal.
  • the signal processing board 50 feeds back the synchronous output signal to the elevator controller 40. Specifically, the synchronous output serial port pin SYNCO(n) feedback signal informs the elevator controller 40.
  • a signal processing board 50 is summoning the elevator.
  • the elevator controller 40 receives the feedback signal of the signal processing board 50, determines which processing board is called, and the elevator controller 40 sends a light control signal through the serial port pin. Specifically, the elevator controller 40 controls the serial port through the light control.
  • the foot DO issues a light control signal, including a start signal, a floor signal, a stop signal, a fault code signal, and the like. Because part of the serial port pins of the elevator controller 40 are also connected to the serial port pins of the data collector 30, the data collector 30 can receive the clock signals, synchronous output signals and lights fed back by the serial port pins of the elevator controller 40.
  • the control signal, the data collector 30 wirelessly transmits the received signal to the network system 20, and the network system 20 transmits the received signal to the remote monitoring platform 10 in real time through corresponding communication means to provide analysis data for the remote monitoring platform 10. In order to complete the monitoring of the operating state of the elevator.
  • the call signal generally includes a layer selection signal or a direction signal of the elevator control box or the elevator call box;
  • the light control signal generally includes an elevator start signal, a startup floor information, an elevator stop signal, a stop floor information, a fault code, etc.;
  • the output signal and the synchronous input signal are a pair of strobe signals, and the elevator controller 40 sequentially accesses the signal processing board 50 by sequentially shifting the synchronous output signals, and the signal processing board 50 confirms the signal processing board 50 and the elevator by synchronizing the input signals.
  • the controller 40 is in communication; the clock signal ensures time synchronization of the elevator controller 40 and the signal processing board 50.
  • the data collector 30 only monitors the clock signal, the synchronous output signal and the lamp control signal sent by the elevator controller 40, and does not monitor the call signal received by the elevator controller 40.
  • the synchronous input signal reflecting that the elevator operating state monitoring system only monitors the effect of no control, and does not affect the operation of the original elevator.
  • an elevator operating state monitoring system is provided.
  • the elevator operating state monitoring system is configured to monitor an elevator including an elevator controller 40 and a signal processing board 50.
  • the elevator operating state monitoring system includes a remote monitoring platform 10 and a network system. 20 and the data collector 30, the remote monitoring platform 10 is connected to the network system 20, the network system 20 is wirelessly connected to the data collector 30, and the serial port pins of the elevator controller 40 are connected to the serial port pins of the signal processing board 50, and the elevator control A portion of the serial port pins of the device 40 are also coupled to the serial port pins of the data collector 30.
  • the data collector 30 is used to collect the elevator data from the serial port pin of the elevator controller 40, and the collected data is sent to the remote monitoring platform 10 to monitor the running state of the elevator, because it is not required
  • a large number of sensors are used to collect the data of the elevator, so the installation cost is reduced and the faulty node is reduced; because the data collector 30 wirelessly connects the network system 20 and the remote detection platform, the installation is further simplified; since the serial port is directly connected from the elevator controller 40 Reading data in the foot, only monitoring, will not affect the operation of the original system; and because each manufacturer's elevator has a serial port pin, you can use the serial port pin to specify the data of the elevator operating condition monitoring system.
  • the monitoring interface solves the problem of incompatibility of the interface, and facilitates the wide application of the elevator running state monitoring system for promotion.
  • FIG. 2 is a schematic diagram showing the detailed structure of the data collector 30 according to the first embodiment of the present invention.
  • the data collector 30 includes a single chip microcomputer 60 and a global mobile communication system GSM communication circuit 70.
  • the single chip microcomputer 60 is connected to the elevator controller 40 through a serial line, and the GSM communication circuit 70 passes through another set of serial cable lines.
  • the microcontroller 60 is connected, and the GSM communication circuit 70 is also wirelessly connected to the network system 20.
  • the model number of the single chip microcomputer 60 is STC89C52RC
  • the model number of the GSM communication circuit 70 is TC35i.
  • an elevator operating state monitoring system is provided.
  • the data of the elevator is collected from a part of the serial port pins of the elevator controller 40 by using the single-chip microcomputer 60, and the single-chip microcomputer 60 collects the elevator through the serial line.
  • the data is sent to the GSM communication circuit 70, and the data of the elevator is wirelessly transmitted by the GSM communication circuit 70 to the remote monitoring platform 10 to monitor the running state of the elevator. Since a large number of sensors are not required to collect the data of the elevator, the installation is lowered.
  • the serial port pin can be used to regulate the data monitoring interface of the elevator running state monitoring system, which solves the problem of interface incompatibility and facilitates the elevator.
  • a wide range of operational condition monitoring systems are used for promotion.
  • FIG. 3 is a schematic flowchart of a method for monitoring an operating state of an elevator according to a second embodiment of the present invention.
  • the method is applicable to an elevator operating state monitoring system according to the first embodiment of the present invention.
  • Methods include:
  • Step 301 Determine startup floor information, stop floor information, and running time of the elevator
  • the data collector 30 in the elevator running state monitoring system is used from the elevator controller 40 in the elevator running state monitoring system.
  • Part of the serial port pin collects the data of the elevator, and transmits the collected data to the remote monitoring platform 10, and the remote monitoring platform 10 determines the startup floor information, the stop floor information and the running time of the elevator from the received data.
  • Step 302 Determine an actual running speed of the elevator according to the startup floor information, the stop floor information, and the running time.
  • a speed algorithm is preset in the remote monitoring platform 10, and the algorithm is used to calculate the startup floor information, the stop floor information, and the running time, and determine the actual running speed of the elevator.
  • Step 303 Analyze the actual running speed, and determine an elevator running state according to the analysis result.
  • the actual running speed of the elevator is analyzed. If the actual running speed of the elevator meets the preset elevator running speed condition, the elevator is faultless, if the actual running speed of the elevator does not meet the preset elevator running. The speed condition, the elevator is not working properly (fault).
  • a method for monitoring an elevator operating state which determines an elevator floor information, a stop floor information, and a running time, and determines an actual running speed of the elevator according to the startup floor information, the stop floor information, and the running time.
  • the actual running speed is analyzed, and the running state of the elevator is determined according to the analysis result. Because the actual running speed of the elevator is not analyzed in the prior art, and the user cannot subjectively judge whether the actual running speed of the elevator is the normal speed of the elevator running, the technical solution is compared with the prior art by performing the actual running speed.
  • the analysis can more accurately determine whether the elevator running state is a normal working state or an abnormal working state (fault state), and is consistent with the user experience of using the elevator.
  • FIG. 4 is a schematic flowchart diagram of a method for monitoring an operation state of an elevator according to a third embodiment of the present invention, where the method includes:
  • Step 401 Determine startup floor information, stop floor information, and running time of the elevator
  • step 401 is consistent with the content described in step 301 in the second embodiment, and details are not described herein again.
  • Step 402 Calculate a difference between the startup floor information and the stop floor information.
  • Step 403 If the absolute value of the difference is greater than a preset threshold, determine a real running speed of the elevator by using a preset first speed formula
  • t represents the running time of the elevator
  • a represents the elevator braking acceleration
  • v actually represents the actual running speed of the elevator to be determined
  • t ⁇ represents the elevator crawling time
  • x ⁇ represents the elevator crawling distance
  • N 1 represents the starting floor information
  • N 2 represents The floor information is stopped
  • H represents a single storey building height
  • H(N 2 -N 1 ) represents the running distance of the elevator.
  • a threshold is set in the remote monitoring platform 10 in advance.
  • the preset threshold is 1.
  • the ladder speed model calculates the actual running speed of the elevator. The specific process is as follows:
  • the elevator start acceleration time is t 1
  • the uniform motion time is t 2
  • the brake deceleration time is t 3
  • the elevator crawl time is constant t ⁇
  • the elevator start acceleration and the brake deceleration acceleration are constant a.
  • the multi-layer elevator running time is calculated as:
  • t is the total running time of the elevator, which is constant
  • a represents the elevator braking acceleration, which is constant
  • v actually represents the actual running speed of the elevator to be determined
  • t ⁇ represents the elevator creep time
  • x ⁇ represents the elevator crawling distance
  • N 1 denotes start floor information
  • N 2 denotes stop floor information
  • H denotes a single storey building height
  • H(N 2 -N 1 ) denotes an elevator running distance.
  • the same type of elevator has the same braking acceleration a, and the same model of the elevator crawling time t ⁇ and the elevator crawling distance x ⁇ are also the same.
  • the elevator crawling time t ⁇ is 2 seconds, and the elevator crawling distance x ⁇ is 1.5 meters. .
  • the formula (4) is solved, the solution can actually run the actual speed v.
  • Step 404 If the actual running speed does not satisfy the first elevator running speed condition, the elevator running state is a fault state;
  • the first elevator running speed condition is:
  • v rating represents the rated operating speed of the elevator, and v actually represents the actual operating speed of the elevator to be determined.
  • the elevator operating state is non- Normal working state (fault condition)
  • the elevator running state is normal working state
  • the first elevator operating speed condition can be appropriately adjusted in consideration of the calculated error.
  • Step 405 If the absolute value of the difference is equal to the preset threshold, determine a real running speed of the elevator by using a preset second speed formula;
  • v Actually represents the actual running speed of the elevator to be determined, H represents a single storey height, and t represents the actual running time of the elevator.
  • the elevator travel time can be expressed as:
  • v max represents the maximum speed at which the elevator starts to accelerate when the length of the single layer is long
  • H represents a single floor height
  • a represents the elevator braking acceleration
  • t ⁇ represents the elevator crawling time
  • H is the single-story height
  • a represents the elevator braking acceleration
  • t ⁇ represents the elevator creep time
  • the same type of elevator has the same braking acceleration a, and the same type of elevator crawling time t ⁇ is also the same.
  • the elevator crawling time t ⁇ is 2 seconds.
  • Step 406 If the actual running speed does not meet the second elevator running speed condition, the elevator running state is a fault state;
  • the second elevator running speed condition is:
  • H is the single-story height and t ⁇ is the elevator crawl time. Indicates the elevator crawl speed.
  • the crawling speed of the elevator indicates the slowest speed of the normal operation of the elevator.
  • the single-layer running speed of an elevator is less than the crawling speed of the elevator, it indicates that the elevator is faulty.
  • FIG. 6 is a schematic diagram of a refinement process for determining the startup floor information and the stop floor information of the elevator in step 401 shown in FIG. 4 , including:
  • Step 601 Monitor floor display information of the elevator. If the floor display information is displayed on the floor display, use the data collector 30 to monitor whether the elevator controller 40 sends the elevator start signal and the startup floor information in the preset time period. a light control signal;
  • the floor display information of the elevator is first monitored by the elevator running state monitoring system. If there is no floor display information on the floor display, it indicates that the elevator is faulty. If the floor display information is detected on the floor display, the data collector 30 is used to monitor whether the elevator controller 40 issues a first light control signal including an elevator start signal and start floor information within a preset time period.
  • the signal processing board 50 of the elevator control box or the elevator call box sends a call signal and a synchronous input signal to the elevator controller 40, wherein
  • the call signal includes a layer selection signal or a direction signal of the elevator control box or the elevator call box.
  • the elevator controller 40 receives the layer selection signal or the direction signal, the lamp control signal is output, and the elevator starts to start operation.
  • the elevator control signal includes the elevator start signal and the startup floor information during the elevator start operation phase. If the elevator controller 40 sends a first light control signal including an elevator start signal and start floor information within a preset time period, it indicates that the elevator can be started. If the first light control signal is not detected within the preset time period, it indicates that the elevator has failed.
  • the preset time period can be modified according to actual conditions. Generally, the preset time period is set to 24 hours.
  • Step 602 If the first light control signal is detected, determine the startup floor information from the first light control signal, and monitor whether the elevator controller 40 sends an elevator stop signal and a stop floor information. a second light control signal;
  • the elevator controller 40 after detecting the first light control signal, indicating that the elevator can be started, determining the starting floor information from the first light control signal, and monitoring whether the elevator controller 40 sends an elevator stop signal and stopping the floor.
  • the second light control signal of the information After detecting the first light control signal, indicating that the elevator can be started, determining the starting floor information from the first light control signal, and monitoring whether the elevator controller 40 sends an elevator stop signal and stopping the floor.
  • the operation after the elevator is started, the operation must be stopped within a certain period of time.
  • the second lamp control signal including the elevator stop signal and the stop floor information is normally issued. If the elevator stop signal sent by the elevator controller 40 is not monitored for a long time, it indicates that the elevator has a serious fault, for example, the elevator fails when it does not reach the designated floor, and stops running.
  • Step 603 If the second lamp control signal is detected, determining the stop floor information from the second lamp control signal.
  • the floor display information is not displayed on the display, or the first light control signal that the elevator controller 40 sends the included elevator start signal and the startup floor information is not detected within the preset time period, or after the startup
  • the second lamp control signal including the elevator stop signal and the stop floor information sent by the elevator controller 40 is not monitored, or the calculated speed does not satisfy the elevator running speed condition, indicating that the elevator is faulty, and all faults will enter the elevator fault code.
  • the monitoring process if the corresponding fault code is displayed, according to the elevator manufacturer's fault code table, the fault type can be clearly identified and the corresponding repair is instructed. If the fault code is not displayed, the fault is unknown, and the maintenance personnel are required to go to the site to check and judge, and repair accordingly.
  • the fault code generally includes common faults such as speed change, misalignment, door state, topping, and bottoming.
  • the fault codes of each manufacturer are set in the elevator running state monitoring system, and the fault code of the elevator running state monitoring system is improved, and the elevator running state monitoring is gradually formed.
  • Standard convenient for elevator maintenance and recovery.

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Abstract

公开了一种电梯运行状态监测系统及方法,电梯运行状态监测系统用于监测包括电梯控制器(40)及信号处理板(50)的电梯,该电梯运行状态监测系统包括远程监测平台(10)、网络系统(20)及数据采集器(30),远程监测平台(10)与网络系统(20)连接,网络系统(20)与数据采集器(30)无线连接,电梯控制器(40)的串口引脚与信号处理板(50)的串口引脚相连接,电梯控制器(40)的部分串口引脚还与数据采集器(30)的串口引脚相连接。该系统利用数据采集器从电梯控制器的部分串口引脚采集电梯的数据,并将采集到的数据发送至远程监测平台,以对电梯运行状态进行监测,从而起到了减少故障节点,降低安装成本,不影响原有电梯系统的效果,且解决了数据采集接口不兼容的问题。

Description

一种电梯运行状态监测系统及方法 技术领域
本发明涉及电梯领域,尤其涉及一种电梯运行状态监测系统及方法。
背景技术
目前,电梯已成为人们生活出行必不可少的交通工具,然而,随着电梯的广泛使用,电梯事故也逐渐增多,因此,需要对电梯运行状态进行实时监测,目前,对电梯运行状态进行实时监测的常用手段是建立包含多个传感器的电梯集中监测系统,而该电梯集中监测系统存在着故障节点多、安装成本高及接口不兼容的问题。
发明内容
本发明的主要目的在于提供一种电梯运行状态监测系统及方法,旨在解决现有的电梯集中监测系统存在的故障节点多、安装成本高及接口不兼容的问题。
为实现上述目的,本发明第一方面提供一种电梯运行状态监测系统,所述电梯运行状态监测系统用于监测包括电梯控制器及信号处理板的电梯,所述电梯运行状态监测系统包括远程监测平台、网络系统及数据采集器;
所述远程监测平台与所述网络系统连接,所述网络系统与所述数据采集器无线连接;
所述电梯控制器的串口引脚与所述信号处理板的串口引脚相连接,所述电梯控制器的部分串口引脚还与所述数据采集器的串口引脚相连接。
进一步的,所述数据采集器包括单片机及全球移动通信系统GSM通信电路,所述单片机通过串口线与所述电梯控制器相连接,所述GSM通信电路通 过另外一组串口线与所述单片机相连接,所述GSM通信电路还与所述网络系统无线连接。
进一步的,所述单片机的型号为STC89C52RC。
进一步的,所述GSM通信电路的型号为TC35i。
为实现上述目的,本发明第二方面提供一种电梯运行状态监测方法,所述方法适用于第一方面所述的电梯运行状态监测系统,所述方法包括:
确定电梯的启动楼层信息、停止楼层信息及运行时间;
根据所述启动楼层信息、所述停止楼层信息及所述运行时间确定电梯的实际运行速度;
对所述实际运行速度进行分析,并根据分析结果确定电梯运行状态。
进一步的,所述根据所述启动楼层信息、所述停止楼层信息及所述运行时间确定电梯的实际运行速度,包括:
计算所述启动楼层信息与所述停止楼层信息的差值;
若所述差值的绝对值大于预设阈值,则利用预设的第一速度公式确定电梯的实际运行速度;
其中,所述第一速度公式为:
Figure PCTCN2018083841-appb-000001
t表示电梯的运行时间,a表示电梯制动加速度,v 实际表示待确定的电梯的实际运行速度,t κ表示电梯爬行时间,x κ表示电梯爬行距离,N 1表示启动楼层信息,N 2表示停止楼层信息,H表示单层楼高,H(N 2-N 1)表示电梯的运行距离。
进一步的,所述方法还包括:
若所述差值的绝对值等于所述预设阈值,则利用预设的第二速度公式确定电梯的实际运行速度;
其中,所述第二速度公式为:
Figure PCTCN2018083841-appb-000002
v 实际表示待确定的电梯的实际运行速度,H表示单层楼高,t表示电梯的实际运行时间。
进一步的,所述对所述实际运行速度进行分析,并根据分析结果确定电梯运行状态,包括:
若所述实际运行速度不满足第一电梯运行速度条件,则所述电梯运行状态为故障状态;
其中,所述第一电梯运行速度条件为:
-8%*v 额定<v 实际-v 额定<5%*v 额定
v 额定表示电梯额定运行速度,v 实际表示待确定的电梯的实际运行速度。
进一步的,所述对所述实际运行速度进行分析,并根据分析结果确定电梯运行状态,包括:
若所述实际运行速度不满足第二电梯运行速度条件,则所述电梯运行状态为故障状态;
其中,所述第二电梯运行速度条件为:
Figure PCTCN2018083841-appb-000003
H表示单层楼高,t κ表示电梯爬行时间,
Figure PCTCN2018083841-appb-000004
表示电梯爬行速度。
进一步的,所述确定电梯的启动楼层信息、停止楼层信息包括:
监测电梯的楼层显示信息,若楼层显示器上显示有所述楼层显示信息,则利用数据采集器监测在预设时段内电梯控制器是否发出包含电梯启动信号及启动楼层信息的第一灯控制信号;
若监测到所述第一灯控制信号,则从所述第一灯控制信号中确定所述启动楼层信息,并监测所述电梯控制器是否发出包含电梯停止信号及停止楼层信息的第二灯控制信号;
若监测到所述第二灯控制信号,则从所述第二灯控制信号中确定所述停止楼层信息。
本发明提供一种电梯运行状态监测系统,电梯运行状态监测系统用于监测包括电梯控制器及信号处理板的电梯,电梯运行状态监测系统包括远程监测平台、网络系统及数据采集器,远程监测平台与网络系统连接,网络系统与数据采集器无线连接,电梯控制器的串口引脚与信号处理板的串口引脚相连接,电梯控制器的部分串口引脚还与数据采集器的串口引脚相连接。与现有技术相比,利用数据采集器从电梯控制器的串口引脚采集电梯的数据,并将采集到的数据发送至远程监测平台,以对电梯运行状态进行监测,因不需要采用大量的传感器采集电梯的数据,所以降低了安装成本,减少故障节点;因为数据采集器无线连接网络系统和远程检测平台,进一步简化了安装;因为直接从电梯控制器的部分串口引脚中读取数据,只监不控,不会对原有系统的运行产生影响;并且因为每个厂家的电梯都有具有串口引脚,则可以利用串口引脚规范电梯运行状态监测系统的数据监测接口,解决了接口不兼容的问题,方便电梯运行状态监测系统的大范围应用于推广。
附图说明
为了更清楚地说明本发明实施例或现有技术中的技术方案,下面将对实施例或现有技术描述中所需要使用的附图作简单地介绍,显而易见地,下面描述中的附图仅仅是本发明的一些实施例,对于本领域技术人员来讲,在不付出创造性劳动的前提下,还可以根据这些附图获得其他的附图。
图1为本发明第一实施例提供的一种电梯运行状态监测系统的结构示意图;
图2为本发明第一实施例中的数据采集器的细化结构示意图。
图3为本发明第二实施例提供的一种电梯运行状态监测方法的流程示意图;
图4为本发明第三实施例提供的一种电梯运行状态监测方法的流程示意图;
图5为本发明第三实施例提供的梯型速度模型;
图6为图4所示的步骤401中的确定电梯的启动楼层信息、停止楼层信息的细化流程示意图。
具体实施方式
为使得本发明的发明目的、特征、优点能够更加的明显和易懂,下面将结合本发明实施例中的附图,对本发明实施例中的技术方案进行清楚、完整地描述,显然,所描述的实施例仅仅是本发明一部分实施例,而非全部实施例。基于本发明中的实施例,本领域技术人员在没有做出创造性劳动前提下所获得的所有其他实施例,都属于本发明保护的范围。
为了说明本发明的技术方案,下面通过具体实施例来进行说明。
请参阅图1,图1为本发明第一实施例提供的一种电梯运行状态监测系统的结构示意图,所述电梯运行状态监测系统用于监测包括电梯控制器40及信号处理板50的电梯,所述电梯运行状态监测系统包括远程监测平台10、网络系统20及数据采集器30;
所述远程监测平台10与所述网络系统20连接,所述网络系统20与所述数据采集器30无线连接;
所述电梯控制器40的串口引脚与所述信号处理板50的串口引脚相连接,所述电梯控制器40的部分串口引脚还与所述数据采集器30的串口引脚相连接。
其中,远程监测平台10包括管理维护部门使用的监测平台、电梯厂家及质检机构使用的监测平台等。
其中,电梯控制器40的串口引脚包括时钟串口引脚CLOCK、同步输出串口引脚SYNCO、招唤串口引脚DI、同步输入串口引脚SYNCI,及灯控制串口引脚DO,信号处理板50的串口引脚包括时钟串口引脚CLOCK、同步输入串口引脚SYNCI(n),召唤串口引脚DO、同步输出串口引脚SYNCO(n)、 及灯控制串口引脚DI。电梯控制器40的串口引脚与信号处理板50的串口引脚的具体连接方式为:电梯控制器40的时钟串口引脚CLOCK与信号处理板50的时钟串口引脚CLOCK相连接,电梯控制器40的同步输出串口引脚SYNCO与信号处理板50的同步输入串口引脚SYNCI(n)相连接,电梯控制器40的灯控制串口引脚DO与信号处理板50的灯控制串口引脚DI相连接,电梯控制器40的招唤串口引脚DI与信号处理板50的召唤串口引脚DO相连接,电梯控制器40的同步输入串口引脚SYNCI与信号处理板50的同步输出串口引脚SYNCO(n)相连接。
其中,数据采集器30的串口引脚包括时钟串口引脚CLOCK、同步输入串口引脚SYNCI及灯控制串口引脚DI。电梯控制器40的部分串口引脚与数据采集器30的串口引脚的具体连接方式为:数据采集器30的时钟串口引脚CLOCK与电梯控制器40的时钟串口引脚CLOCK相连接,数据采集器30的同步输入串口引脚SYNCI与电梯控制器40的同步输出串口引脚SYNCO相连接,数据采集器30的灯控制串口引脚DI与电梯控制器40的灯控制串口引脚DO相连接。
其中,信号处理板50可以是电梯操控箱的信号处理板50,也可以是电梯招唤箱的信号处理板50。
在本发明实施例中,首先信号处理板50利用自身的串口引脚向电梯控制器40的串口引脚发送招唤信号,具体的,信号处理板50的招唤串口引脚DO发送招唤信号。电梯控制器40接收到信号处理板50发送的招唤信号后,通过自身的串口引脚向信号处理板50的串口引脚发送同步输出信号,具体的,电梯控制器40的同步输出串口引脚SYNCO发送同步输出信号。信号处理板50接收到电梯控制器40发送的同步输出信号后,反馈同步输出信号给电梯控制器40,具体的,通过同步输出串口引脚SYNCO(n)反馈信号,告知电梯控制器40是哪一个信号处理板50在召唤电梯。电梯控制器40收到信号处理板50的反馈信号,确定了是哪一块处理板在召唤后,电梯控制器40通过串口引脚发出灯控 信号,具体的,电梯控制器40通过灯控制串口引脚DO发出灯控信号,包括启动信号、楼层信号、停止信号、故障码信号灯等。因为电梯控制器40的部分串口引脚还与数据采集器30的串口引脚相连接,所以数据采集器30可以接收到电梯控制器40的部分串口引脚反馈的时钟信号、同步输出信号及灯控制信号,数据采集器30并将接收到的信号无线发送至网络系统20,网络系统20通过相应的通讯方式实时将接收到的信号传输给远程监测平台10,为远程监测平台10提供分析数据。以完成对电梯运行状态的监测。
其中,招唤信号一般包括电梯操控箱或电梯招唤箱的选层信号或方向信号等;灯控制信号一般包括电梯启动信号、启动楼层信息、电梯停止信号、停止楼层信息、故障码等;同步输出信号和同步输入信号是一对选通信号,电梯控制器40通过同步输出信号顺序移位来实现对信号处理板50逐个访问,信号处理板50通过同步输入信号来确认信号处理板50和电梯控制器40连通;时钟信号保证了电梯控制器40和信号处理板50的时间同步。
需要注意的是,为了不影响原有的电梯系统的工作,数据采集器30只监测电梯控制器40发出的时钟信号、同步输出信号及灯控制信号,不监测电梯控制器40接收的招唤信号和同步输入信号,体现电梯运行状态监测系统只监测不控制的效果,不会对原有电梯的运行产生影响。
在本发明实施例中,提供一种电梯运行状态监测系统,电梯运行状态监测系统用于监测包括电梯控制器40及信号处理板50的电梯,电梯运行状态监测系统包括远程监测平台10、网络系统20及数据采集器30,远程监测平台10与网络系统20连接,网络系统20与数据采集器30无线连接,电梯控制器40的串口引脚与信号处理板50的串口引脚相连接,电梯控制器40的部分串口引脚还与数据采集器30的串口引脚相连接。与现有技术相比,利用数据采集器30从电梯控制器40的串口引脚采集电梯的数据,并将采集到的数据发送至远程监测平台10,以对电梯运行状态进行监测,因不需要采用大量的传感器采集 电梯的数据,所以降低了安装成本,减少故障节点;因为数据采集器30无线连接网络系统20和远程检测平台,进一步简化了安装;因为直接从电梯控制器40的部分串口引脚中读取数据,只监不控,不会对原有系统的运行产生影响;并且因为每个厂家的电梯都有具有串口引脚,则可以利用串口引脚规范电梯运行状态监测系统的数据监测接口,解决了接口不兼容的问题,方便电梯运行状态监测系统的大范围应用于推广。
进一步的,请参阅图2,图2为本发明第一实施例中的数据采集器30的细化结构示意图,具体的:
所述数据采集器30包括单片机60及全球移动通信系统GSM通信电路70,所述单片机60通过串口线与所述电梯控制器40相连接,所述GSM通信电路70通过另外一组串口线与所述单片机60相连接,所述GSM通信电路70还与所述网络系统20无线连接。
其中,单片机60的型号为STC89C52RC,GSM通信电路70的型号为TC35i。
在本发明实施例中,提供一种电梯运行状态监测系统,与现有技术相比,利用单片机60从电梯控制器40的部分串口引脚采集电梯的数据,单片机60通过串口线将采集的电梯的数据发送至GSM通信电路70,由GSM通信电路70将电梯的数据无线发送至远程监测平台10,以对电梯运行状态进行监测,因不需要采用大量的传感器采集电梯的数据,所以降低了安装成本,减少故障节点;因为数据采集器30无线连接网络系统20和远程检测平台,进一步简化了安装;因为直接从电梯控制器40的部分串口引脚中读取数据,只监不控,不会对原有系统的运行产生影响;并且因为每个厂家的电梯都有具有串口引脚,则可以利用串口引脚规范电梯运行状态监测系统的数据监测接口,解决了接口不兼容的问题,方便电梯运行状态监测系统的大范围应用于推广。
请参阅图3,图3为本发明第二实施例提供的一种电梯运行状态监测方法的流程示意图,所述方法适用于本发明第一实施例提供的一种电梯运行状态监 测系统,所述方法包括:
步骤301、确定电梯的启动楼层信息、停止楼层信息及运行时间;
在本发明实施例中,在电梯从开始运行到结束运行的过程中,会产生相应的数据,利用电梯运行状态监测系统中的数据采集器30从电梯运行状态监测系统中的电梯控制器40的部分串口引脚采集电梯的数据,并将采集到的数据传送至远程监测平台10,远程监测平台10从收到的数据中确定电梯的启动楼层信息、停止楼层信息及运行时间等。
步骤302、根据所述启动楼层信息、所述停止楼层信息及所述运行时间确定电梯的实际运行速度;
在本发明实施例中,在远程监测平台10中预置了速度算法,利用该算法对启动楼层信息、停止楼层信息及运行时间进行计算,确定电梯的实际运行速度。
步骤303、对所述实际运行速度进行分析,并根据分析结果确定电梯运行状态。
在本发明实施例中,对电梯的实际运行速度进行分析,若电梯的实际运行速度满足预设的电梯运行速度条件,则电梯是无故障,若电梯的实际运行速度不满足预设的电梯运行速度条件,则电梯运行不正常(出现故障)。
在本发明实施例中,提供了一种电梯运行状态监测方法,确定电梯的启动楼层信息、停止楼层信息及运行时间,根据启动楼层信息、停止楼层信息及运行时间确定电梯的实际运行速度,对实际运行速度进行分析,并根据分析结果确定电梯运行状态。因现有技术中没有对电梯的实际运行速度进行分析,而用户也无法主观判断电梯的实际运行速度是否是电梯运行的正常速度,本技术方案与现有技术相比,通过对实际运行速度进行分析,可以更加准确的判断电梯运行状态是否是正常工作状态还是非正常工作状态(故障状态),和使用电梯的用户体验是一致的。
进一步的,请参阅图4,图4为本发明第三实施例提供的一种电梯运行状 态监测方法的流程示意图,所述方法包括:
步骤401、确定电梯的启动楼层信息、停止楼层信息及运行时间;
在本发明实施例中,上述步骤401与第二实施例中的步骤301描述的内容一致,此处不再赘述。
步骤402、计算所述启动楼层信息与所述停止楼层信息的差值;
步骤403、若所述差值的绝对值大于预设阈值,则利用预设的第一速度公式确定电梯的实际运行速度;
其中,所述第一速度公式为:
Figure PCTCN2018083841-appb-000005
t表示电梯的运行时间,a表示电梯制动加速度,v 实际表示待确定的电梯的实际运行速度,t κ表示电梯爬行时间,x κ表示电梯爬行距离,N 1表示启动楼层信息,N 2表示停止楼层信息,H表示单层楼高,H(N 2-N 1)表示电梯的运行距离。
其中,预先在远程监测平台10中设置一个阈值,优选的,该预设阈值为1。
在本发明实施例中,若上述差值的绝对值大于预设阈值,则表示电梯的运行距离足够长(运行的长度为两层或两层以上的长度),则使用如图5所示的梯型速度模型,计算出电梯的实际运行速度,具体过程如下:
在图5中,设电梯启动加速时间为t 1,匀速运动时间为t 2,制动减速时间为t 3,电梯爬行时间为常数t κ,电梯启动加速度和制动减速加速度都为常数a,则
Figure PCTCN2018083841-appb-000006
Figure PCTCN2018083841-appb-000007
Figure PCTCN2018083841-appb-000008
根据公式(1)、公式(2)及公式(3),计算出电梯多层运行时间为:
Figure PCTCN2018083841-appb-000009
其中,t表示电梯总的运行时间,为常数,a表示电梯制动加速度,为常数,v 实际表示待确定的电梯的实际运行速度,t κ表示电梯爬行时间,x κ表示电梯爬行距离,N 1表示启动楼层信息,N 2表示停止楼层信息,H表示单层楼高,H(N 2-N 1)表示电梯的运行距离。
其中,同一型号的电梯的制动加速度a相同,同一型号的电梯爬行时间t κ和电梯爬行距离x κ也相同,优选的,电梯爬行时间t κ为2秒,电梯爬行距离x κ为1.5米。
在本发明实施例中,对公式(4)进行求解,可以解出实际运行速度v 实际
步骤404、若所述实际运行速度不满足第一电梯运行速度条件,则所述电梯运行状态为故障状态;
其中,所述第一电梯运行速度条件为:
-8%*v 额定<v 实际-v 额定<5%*v 额定
v 额定表示电梯额定运行速度,v 实际表示待确定的电梯的实际运行速度。
在本发明实施例中,若利用公式(4)计算出的电梯的实际运行速度v 实际不满足-8%*v 额定<v 实际-v 额定<5%*v 额定,则电梯运行状态为非正常工作状态(故障状态),若满足-8%*v 额定<v 实际-v 额定<5%*v 额定,则电梯运行状态为正常工作状态。
考虑到计算的误差,第一电梯运行速度条件可以进行适当的调整。
步骤405、若所述差值的绝对值等于所述预设阈值,则利用预设的第二速度公式确定电梯的实际运行速度;
其中,所述第二速度公式为:
Figure PCTCN2018083841-appb-000010
v 实际表示待确定的电梯的实际运行速度,H表示单层楼高,t表示电梯的实际运行时间。
在本发明实施例中,若上述差值的绝对值等于预设阈值,则表示电梯的运行距离较短(运行的长度为单层长度),则由于单层长度一般小于电梯的启动加速距离和制动减速距离,因此一般单层长度不存在超速现象,单层长度时电梯行车时间可以表示为:
Figure PCTCN2018083841-appb-000011
其中,v max表示单层长度时电梯启动加速的最大速度,H表示单层楼高,a表示电梯制动加速度,t κ表示电梯的爬行时间。
则电梯的实际运行速度v 实际为:
Figure PCTCN2018083841-appb-000012
其中,H表示单层楼高,a表示电梯制动加速度,t κ表示电梯爬行时间。
其中,同一型号的电梯的制动加速度a相同,同一型号的电梯爬行时间t κ也相同,优选的,电梯爬行时间t κ为2秒。
步骤406、若所述实际运行速度不满足第二电梯运行速度条件,则所述电梯运行状态为故障状态;
其中,所述第二电梯运行速度条件为:
Figure PCTCN2018083841-appb-000013
其中,H表示单层楼高,t κ表示电梯爬行时间,
Figure PCTCN2018083841-appb-000014
表示电梯爬行速度。
在本发明实施例中,电梯爬行速度表示电梯正常运行的最慢速度,当某电梯的单层运行速度小于电梯爬行速度,则表示该电梯有故障。
进一步的,请参阅图6,为图4所示的步骤401中的确定电梯的启动楼层信息、停止楼层信息的细化流程示意图,包括:
步骤601、监测电梯的楼层显示信息,若楼层显示器上显示有所述楼层显示信息,则利用数据采集器30监测在预设时段内电梯控制器40是否发出包含电梯启动信号及启动楼层信息的第一灯控制信号;
在本发明实施例中,首先通过电梯运行状态监测系统监测电梯的楼层显示信息,若监测到楼层显示器上没有楼层显示信息,则表明电梯有故障。若监测到楼层显示器上有楼层显示信息,则利用数据采集器30监测在预设时段内电梯控制器40是否发出包含电梯启动信号及启动楼层信息的第一灯控制信号。
在本发明实施例中,当用户操作电梯操控箱或电梯招唤箱的时候,电梯操控箱或电梯招唤箱的信号处理板50会发送招唤信号和同步输入信号到电梯控制器40,其中,招唤信号包括电梯操控箱或电梯招唤箱的选层信号或方向信号。当电梯控制器40接收到选层信号或方向信号后,会输出灯控制信号,电梯开始启动运行,其中,在电梯启动运行阶段,灯控制信号包括电梯启动信号、启动楼层信息。若监测在预设时段内电梯控制器40发出包含电梯启动信号及启动楼层信息的第一灯控制信号,则表明电梯可以启动。若在预设时段内没有监测到第一灯控制信号,则表明电梯出现故障。
其中,预设时段内可根据实际情况进行修改,通常情况下,将预设时段内设置成24小时。
步骤602、若监测到所述第一灯控制信号,则从所述第一灯控制信号中确定所述启动楼层信息,并监测所述电梯控制器40是否发出包含电梯停止信号及停止楼层信息的第二灯控制信号;
在本发明实施例中,在监测到第一灯控制信号后,表明电梯可以启动,从上述第一灯控制信号中确定启动楼层信息,并监测电梯控制器40是否发出包含电梯停止信号及停止楼层信息的第二灯控制信号。
在本发明实施例中,电梯启动后,必须要在一定时间段内停止运行,当电梯即将到达指定楼层的时候,正常情况下会发出包含电梯停止信号及停止楼层信息的第二灯控制信号,若长时间没有监测电梯控制器40发出包含的电梯停止 信号,则表明电梯出现严重故障,例如电梯在没有到指定楼层时发生故障,停止运行。
步骤603、若监测到所述第二灯控制信号,则从所述第二灯控制信号中确定所述停止楼层信息。
需要注意的是,无论是在显示器上没有显示楼层显示信息,或在预设时段内没有监测到电梯控制器40发出包含的电梯启动信号及启动楼层信息的第一灯控制信号,或在启动后没有监测到电梯控制器40发出的包含电梯停止信号及停止楼层信息的第二灯控制信号,或计算出来的速度不满足电梯运行速度条件,都表示电梯出现故障,所有的故障都会进入电梯故障码监测流程,若显示相应的故障码,则根据电梯厂家的故障码表,可以明确查出故障类型,并指示进行相应的修复。若没有显示故障码,则故障不明,需要维修人员到现场检查判断,并进行相应的修复。
其中,故障码一般包括换速、错位、门状态、冲顶、蹲底等常见故障。
在本发明实施例中,通过电梯运行状态监测系统的集中运行管理,将各个厂家的故障码设置在电梯运行状态监测系统中,对电梯运行状态监测系统进行故障码完善,逐渐形成电梯运行状态监测标准,方便电梯的维修和恢复。
在上述实施例中,对各个实施例的描述都各有侧重,某个实施例中没有详述的部分,可以参见其它实施例的相关描述。
以上为对本发明实施例所提供的一种电梯运行状态监测系统及方法的描述,对于本领域的技术人员,依据本发明实施例的思想,在具体实施方式及应用范围上均会有改变之处,综上,本说明书内容不应理解为对本发明的限制。

Claims (10)

  1. 一种电梯运行状态监测系统,所述电梯运行状态监测系统用于监测包括电梯控制器及信号处理板的电梯,其特征在于,所述电梯运行状态监测系统包括远程监测平台、网络系统及数据采集器;
    所述远程监测平台与所述网络系统连接,所述网络系统与所述数据采集器无线连接;
    所述电梯控制器的串口引脚与所述信号处理板的串口引脚相连接,所述电梯控制器的部分串口引脚还与所述数据采集器的串口引脚相连接。
  2. 根据权利要求1所述的电梯运行状态监测系统,其特征在于,所述数据采集器包括单片机及全球移动通信系统GSM通信电路,所述单片机通过串口线与所述电梯控制器相连接,所述GSM通信电路通过另外一组串口线与所述单片机相连接,所述GSM通信电路还与所述网络系统无线连接。
  3. 根据权利要求2所述的电梯运行状态监测系统,其特征在于,所述单片机的型号为STC89C52RC。
  4. 根据权利要求2所述的电梯运行状态监测系统,其特征在于,所述GSM通信电路的型号为TC35i。
  5. 一种电梯运行状态监测方法,所述方法适用于如权利要求1至4任意一项所述的电梯运行状态监测系统,其特征在于,所述方法包括:
    确定电梯的启动楼层信息、停止楼层信息及运行时间;
    根据所述启动楼层信息、所述停止楼层信息及所述运行时间确定电梯的实际运行速度;
    对所述实际运行速度进行分析,并根据分析结果确定电梯运行状态。
  6. 根据权利要求5所述的方法,其特征在于,所述根据所述启动楼层信息、所述停止楼层信息及所述运行时间确定电梯的实际运行速度,包括:
    计算所述启动楼层信息与所述停止楼层信息的差值;
    若所述差值的绝对值大于预设阈值,则利用预设的第一速度公式确定电梯的实际运行速度;
    其中,所述第一速度公式为:
    Figure PCTCN2018083841-appb-100001
    t表示电梯的运行时间,a表示电梯制动加速度,v 实际表示待确定的电梯的实际运行速度,t κ表示电梯爬行时间,x κ表示电梯爬行距离,N 1表示启动楼层信息,N 2表示停止楼层信息,H表示单层楼高,H(N 2-N 1)表示电梯的运行距离。
  7. 根据权利要求6所述的方法,其特征在于,所述方法还包括:
    若所述差值的绝对值等于所述预设阈值,则利用预设的第二速度公式确定电梯的实际运行速度;
    其中,所述第二速度公式为:
    Figure PCTCN2018083841-appb-100002
    v 实际表示待确定的电梯的实际运行速度,H表示单层楼高,t表示电梯的实际运行时间。
  8. 根据权利要求6所述的方法,其特征在于,所述对所述实际运行速度进行分析,并根据分析结果确定电梯运行状态,包括:
    若所述实际运行速度不满足第一电梯运行速度条件,则所述电梯运行状态为故障状态;
    其中,所述第一电梯运行速度条件为:
    -8%*v 额定<v 实际-v 额定<5%*v 额定
    v 额定表示电梯额定运行速度,v 实际表示待确定的电梯的实际运行速度。
  9. 根据权利要求7所述的方法,其特征在于,所述对所述实际运行速度进行分析,并根据分析结果确定电梯运行状态,包括:
    若所述实际运行速度不满足第二电梯运行速度条件,则所述电梯运行状态 为故障状态;
    其中,所述第二电梯运行速度条件为:
    Figure PCTCN2018083841-appb-100003
    H表示单层楼高,t κ表示电梯爬行时间,
    Figure PCTCN2018083841-appb-100004
    表示电梯爬行速度。
  10. 根据权利要求5所述的方法,其特征在于,所述确定电梯的启动楼层信息、停止楼层信息包括:
    监测电梯的楼层显示信息,若楼层显示器上显示有所述楼层显示信息,则利用数据采集器监测在预设时段内电梯控制器是否发出包含电梯启动信号及启动楼层信息的第一灯控制信号;
    若监测到所述第一灯控制信号,则从所述第一灯控制信号中确定所述启动楼层信息,并监测所述电梯控制器是否发出包含电梯停止信号及停止楼层信息的第二灯控制信号;
    若监测到所述第二灯控制信号,则从所述第二灯控制信号中确定所述停止楼层信息。
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