This invention relates to monitoring systems for elevators, escalators, moving walks, and similar devices. In particular, this invention relates to a system for remotely monitoring and diagnosing the operation and status of a single elevator or a group of elevators, escalators, moving walks, or the like.
Elevators, escalators, moving walks, and similar devices are relied upon by building owners and the public to provide reliable and safe operation to move people and supplies. A malfunction by an elevator, escalator, moving walk, or similar device can result in immediate inconvenience to the riders. Further, malfunctions can result in unanticipated repair costs incurred by building owners, the loss of value to buildings, and the loss of prospective or existing building tenants. Often, malfunctions may be short lived problems that are easily identified, diagnosed, and resolved. However, some malfunctions are not easily diagnosed and identified. These malfunctions may be intermittent problems or problems that appear only for a brief period of time or under very specific conditions.
Malfunctions may occur due to the complexity and nature of the control systems for elevators, escalators, moving walks, and similar devices. Typically, control systems may include various electrical systems and components, including wiring, relays, resistors, terminals, contacts, sensors, etc. The control systems are configured for elevator functions, such as starting, stopping, communications, leveling, positioning, lighting, signaling, sensors, alarms, and the like. More modern control systems may also include microprocessor or computer-based systems for data acquisition, decision making, error analysis, scheduling maintenance tasks, communicating, and informational displays. Control systems may also include pumps, motors, clutches, selectors, brakes, motor-generator sets, verniers, silicon controlled rectifiers, belts, digital encoders, and sensors of all types, including optical and magnetic.
Malfunctions may also occur due to the age of the control equipment. While many elevator control systems have been modernized every 20 to 25 years with sophisticated computer based controls, many existing elevator control systems have not been modernized and are still functioning long after the useful life of the original control system has been exceeded. These obsolete control systems will incur malfunctions due to the age, brittleness, and obsolescence of the electrical controls.
When a malfunction occurs, service personnel are faced with diagnosing the problem or problems and implementing a timely repair. Diagnosing minor malfunctions can often be accomplished on-site through the experience and expertise of service personnel without the use of sophisticated or complex diagnostic equipment. However, many malfunctions cannot be diagnosed and corrected as easily. If the cause of the malfunction is not readily apparent or if the service personnel is not on-site to observe the cause of the malfunction, the diagnosis can be difficult and the resolution elusive.
Older control systems typically do not have diagnostic equipment incorporated with the control systems. More modern control systems often have diagnostic equipment incorporated within the control system to aid in the diagnostic effort. However, the diagnostic equipment incorporated within more modern control systems often provide limited information and only for pre-defined control circuits or control points. Additionally, modern control systems often provide information for other purposes, such as maintenance tasks, which do not assist the service personal in diagnosing and resolving malfunctions. When the control system does not have diagnostic equipment incorporated within the control system or the incorporated diagnostic does not have the capacity to address the malfunction, the service personnel may have difficulty diagnosing the malfunctions on a timely and efficient basis.
For all of these reasons, it would be advantageous to provide a diagnostic system that is capable of being easily adapted to all forms and vintages of elevators, escalators, moving walks, and other similar devices, and further that provides the user with many capabilities to monitor user selected circuits and control points to easily diagnose malfunctions.
This invention relates to a diagnostic system for a transportation device that includes an analyzer unit. The analyzer unit includes a user defined sequence logic map. The sequence logic map defines a sequence for a plurality of name inputs. The analyzer unit is configured to monitor the operating condition of the plurality of named inputs and compare the operating condition of the plurality of named inputs with the user defined sequence logic map. The analyzer unit communicates the comparison in a notification.
This invention also relates to a method for diagnosing control system malfunctions. The method includes the steps of: selecting and naming a plurality of control system points, providing an analyzer unit, the analyzer unit including a user defined sequence logic map defining a sequence for the plurality of named control system points, the analyzer unit being configured to monitor the operating condition of the plurality of named control system points and communicate the comparison in a notification, providing a host computer connected to the analyzer unit and configured to display the notification communicated by the analyzer unit, operating the control system, collecting actual sequence data from the plurality of named control system points, comparing the collected actual sequence data with the user defined sequence logic map, and communicating the results of the comparison in a notification to the host computer.
Various objects and advantages of this invention will become apparent to those skilled in the art from the following description of the preferred embodiments, when read in light of the accompanying drawings.
Referring now to the drawings there is illustrated in
As shown generally in
As shown in
The analyzer unit 16 is electrically connected to the controller 14 by electrical wiring 18. A first end of the electrical wiring 18 is connected to the analyzer unit 16 at input terminals (not shown) located within the analyzer unit 16. The second end of the electrical wiring 18 is connected to user selected circuit points 20 located within each controller 14. The user selected circuit points 20 can include any point in any circuit that can provide a voltage or a state condition (on/off or high/low for example). Examples of selected circuit points 20 include “car start” relays, “leveling” Sensors, and “over speed” contacts. The electrical wiring 18 is sized to correspond with the electrical voltage and current found in the selected circuit points 20.
In the illustrated embodiment, the selected circuit points 20 are located within the controller 14 and have been selected by the user of the diagnostic system 10 to diagnose a malfunction. In one embodiment, the selected circuit points 20 include any point in an electrical or electronic circuit having a measurable current or voltage. Alternatively, the selected circuit point 20 can be any device such as, for example, a pressure or temperature sensor, that generates a measurable signal. In this embodiment, the circuit points 20 can be located in another device associated with the transportation device, such as for example motors, motor-generator sets, governors, power supply panels, etc.
As previously mentioned, the analyzer unit 16 collects signals generated at the selected circuit points 20. In one embodiment, the signals generated at the selected circuit points 20 and collected by the analyzer unit 16 are analog signals. In another embodiment, the signals generated at the selected circuit points 20 and collected by the analyzer unit 16 are digital signals. In yet another embodiment, the signals at the selected circuit points 20 and collected by the analyzer unit 16 can be another type of signal sufficient to communicate the operating condition of the selected circuit point 20.
In the illustrated embodiment, the selected circuit points 20 are individually wired to the analyzer unit 16. In this embodiment, a maximum of sixteen circuit points 20 can be selected. In another embodiment, the circuit points 20 are wired to the analyzer unit 16 via wiring modules (not shown). In this embodiment, each module can accommodate up to sixteen circuit points and an unlimited number of modules can be used. In yet another embodiment, the selected circuit points 20 are wired to a communications bus (not shown). The communications bus is configured to communicate with desired analyzer units 16, thereby allowing specific analyzer units 16 to analyze pre-selected malfunctions.
As will be explained later in more detail, the selected circuit points 20 are named by the user of the diagnostic system 10. The user also pre-defines the operating conditions for each selected circuit point 20. As the transportation device operates, the analyzer unit 16 monitors the actual operating conditions of the selected circuit points 20 and compares the actual operating conditions with the pre-defined conditions. The results of the comparison can be sent via a notification to the user for further analysis.
As further shown in
The host computer 22 is configured to enable the host computer 22 to communicate with the analyzer unit 16 through a variety of communication means. In the illustrated embodiment, the host computer 22 is connected to the analyzer unit 16 by hard wire plug-in connection. Alternatively, the host computer 22 can communicate with the analyzer unit 16 by other methods, such as for example modem-based telephone line, cellular telephone, Ethernet, micro wave, radio and WiFi. In yet another embodiment, the analyzer unit 16 can communicate with the host computer 22 over telephone lines shared with other communication devices such as, for example, emergency telephones. As will be explained in more detail later, as the host computer 22 communicates with the analyzer unit 16, the host computer 22 receives information that can be displayed and stored in memory.
As further illustrated in
The host computer 22 includes software configured to perform several diagnostic system 10 functions. The first function of the host computer 22 is to configure the analyzer units 16. Each analyzer unit 16 is configured for the specific manufacturer, model, and type of transportation device. The second function of the host computer 22 is to configure each analyzer unit 16 for a user developed sequence logic map 28 using a Sequence Editor 29, such as shown in
The sequence logic map 28 is configured by the user using an Input and Event Definition Editor 40, as shown in
Referring again to the Sequence Editor 29 as shown in
Using the Sequence Editor 29, the user is also able to set additional notification parameters 34, including notification on complete or incomplete sequencing. The user is also able to set additional sequential states 36 for each named input 21, including timing parameters, pre- and post-sequenced times.
Referring again to
In addition to sending a notification to the host computer 22, the analyzer unit 16 can also provide additional information to the host computer 22. The additional information includes data displayed by the host computer 22 in the form of an oscilloscope type display 50, as shown in
In another embodiment of the diagnostic system 10, the analyzer unit 16 can be equipped with a rechargeable battery back-up (not shown). The optional battery back-up allows the analyzer unit 16 to continue operation in the event the primary source of power to the analyzer unit 16 is interrupted. While operating on battery back-up, the analyzer unit 16 will continue to operate as previously described, including having the ability to send notifications of the power loss and will continue to record pre-determined operating information. In one embodiment of the diagnostic system 10, the rechargeable battery back-up is configured to provide power to the analyzer unit 16 for a period of time of up to approximately twenty-four hours. In another embodiment, the rechargeable battery back-up can provide power to the analyzer unit 16 for more than twenty-four hours. The rechargeable battery back-up ensures that the diagnostic system 10 will continue to function in the event of a power failure.
Referring again to
In accordance with the provisions of the patent statutes, the principle and mode of operation of this invention have been explained and illustrated in its preferred embodiments. However, it must be understood that this invention may be practiced otherwise than as specifically explained and illustrated without departing from its spirit or scope.
This application claims the benefit of U.S. Provisional Application No. 60/799,867, filed May 12, 2006, the disclosure of which is incorporated herein by reference.
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