Abstract:
A wireless system is provided which enables a remotely located equipment monitor to control the equipment in the event that more than one alert or alarm for the same fault condition, at the equipment have been ignored by the equipment operator. Control options include instructing the operator to shut equipment down, automatically shutting the equipment down and putting the equipment in a safe mode of operation.

Description:
RELATED APPLICATIONS  
       [0001]     This application claims priority to U.S. Provisional Application No. 60/688,626, filed on Jun. 7, 2005. 
     
    
     BACKGROUND  
       [0002]     Monitoring and managing equipment in remote locations presents a challenging task, particularly for equipment leasing companies. This task becomes even more challenging for mobile equipment such as heavy construction vehicles. Notification in real time of problems which occur in the field can prove to be very useful in scheduling maintenance. Operation of equipment in such a manner which may create additional equipment problems or which may exacerbate existing problems remains problematic.  
         [0003]     There are currently systems which monitor the operation of a remotely located piece of equipment including its location. In instances where the machine is operating outside of a designated geographical area, there exist disclosure of security systems which serve to shut down a piece of equipment. See U.S. Published Patent Application 200040073468 to Vyas et al. Additionally, while it is known that existing systems can give alerts or alarms to equipment operators in case of equipment malfunction, until now, no systems currently exist which allow the equipment owner or leasing entity to take control of equipment when those alerts or alarms are ignored so as to prevent equipment damage. 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0004]      FIG. 1  illustrates a block diagram of an equipment management system.  
         [0005]      FIG. 2  is a block diagram illustrating how each sensor and/or controller on a piece of equipment is used to monitor or control a piece of equipment or system or function on a piece of equipment. 
     
    
       [0006]     Applicable reference numbers have been carried forward.  
       DETAILED DESCRIPTION  
       [0007]     A wireless equipment management system  2  is provided for managing equipment  4 , e.g., mobile or non-mobile machines.  
         [0008]      FIG. 1  illustrates a block diagram of equipment management system  2 .  FIG. 1  shows a plurality of monitored equipment  4  (coupled to data processing center  6  through wireless communications link  8  represented by arrows). Equipment  4  can represent heavy equipment, office equipment, surface, land and air vehicles, etc. This includes engines, automobiles, trucks, construction, agricultural or earthmoving equipment, computers, consumer electronics, copiers, printers, facsimile machines, et cetera (communications link  8  can include a satellite data link, an analog cellular telephone communications link (using, for instance, frequency division multiple access (FDMA), a digital cellular communications link (using e.g., code division multiple access (CDMA), time division multiple access (TDMA), etc.) a radio link, Bluetooth, Wi-fi(802.11a, 802.11b, 802.11g etc.), or a combination thereof. Data processing center  6  receives status information related to monitored equipment  4 . In one aspect, each monitored piece of equipment  4  can include one or more sensors  12  for measuring equipment usage or operating characteristics. In one embodiment, data processing center  6  receives signals, via communications link  8  from the one or more sensors  12 , containing data relating to equipment usage and/or operating characteristics. The received data is stored at data processing center  6  which can adaptively track the operation of each piece of monitored equipment  4  based on data from sensors  12 . For example, one of equipment  4  shown could represent an engine wherein a sensor  12  measures odometer mileage. Another sensor  12  can measure, for instance, ambient operating temperatures. An oil change maintenance schedule and an oil type can be calculated at data processing center  6  based upon the data supplied by sensors  12 . For instance under predominantly and relatively high ambient temperatures, a higher weight oil and more frequent oil change scheduling at shorter odometer mileage intervals between scheduled oil changes may be prescribed to reduce engine wear. Predominantly cooler ambient temperatures over longer odometer readings may dictate a lower weight oil with more miles between oil changes. Consequently, an engine or piece of heavy equipment operating in area near the Sahara Desert in Africa could have an entirely different maintenance schedule from the same engine operating in Iceland as determined by processing center  6 . Alternatively, in the case of a copier or facsimile machine sensor  12  can measure toner levels and copier usage hours to adaptively determine toner cartridge replacement scheduling and/or ordering. In addition, should a fault condition occur at the monitored equipment, such as no oil sensed in the engine, an alarm or alert can be processed to the equipment operator.  
         [0009]     Data processing center  6  can contain one or more servers which operate to run computer programs that manage alerts and/or prepare equipment maintenance schedules for a plurality of equipment  4 . Equipment operating data, historical usage data, maintenance schedules and equipment location information can also be tracked and maintained by one or more servers at data processing center  6 .  
         [0010]     Equipment manager  14  within data processing center  6  can be implemented as a server programmed to calculate operation recommendations in the case of alerts and servicing schedules for each monitored piece of equipment  4 . Data on each monitored piece of equipment can be maintained in memory storage represented by functional block  16  as accomplished, for instance, in the same server as that for equipment manager  14  or in a separate server therefrom for storage of collected data. This data includes equipment specifications, and operating data including historical usage data. For instance, information relating to repair histories, in-service hours, fuel consumption, location information and operating costs can be stored in memory storage  16 .  
         [0011]     Wireless equipment system  2  is preferably a computer-based system that uses the Transmission Control Protocol/Internet Protocol (TCP/IP) networking protocol. Further this system  2  is particularly suitable for the Internet, particularly with broadband Internet. Wireless system  2  is accessible from multiple sources concerning maintenance scheduling. Different levels of security can be meted out to each system user depending on information needs et cetera.  
         [0012]     Wireless equipment system  2  can be implemented using a combination of wireless technology, data handling functionality construction industry constructs as provided, for example, by an equipment management solution such as GlobalTRACS® by QUALCOMM®. An equipment management solution automatically collects, organizes and transmits vital information concerning how the equipment is being used, how much equipment is being used as well as the location of that equipment. This information is especially useful to entities renting, distributing, contracting or owning equipment-particularly construction equipment. The equipment management solution can track equipment use such as engine hour use as reported by a sensor tracking usage hours of a system on a piece of equipment, such as an engine. Further, the equipment management solution can provide global positioning system (GPS)-based equipment location information including data indicating when a piece of equipment has moved outside of a pre-set boundary.  
         [0013]      FIG. 2  is a block diagram of illustrating how each sensor  12  and/or controller  20  on a piece of equipment  4  is used to monitor or control equipment  4  or system or function on equipment  4 . In one embodiment, each sensor  12  and controller  20  on equipment  4  is connected through a controller area network (CAN).  
         [0014]     In one embodiment each sensor  12  and controller  20  on the same piece of equipment can act as a CAN slave device connected to a CAN master controller  5 . Master controller  5  includes antenna  21  which is used in connection with transmitting and receiving Code Division Multiple Access (CDMA) signals. However, other communications systems for use in connection with antenna  21  are contemplated, e.g., Time Division Multiple Access, et cetera.  
         [0015]     In one aspect of an embodiment, a J1939 higher layer protocol is used for the CAN. The SAE (Society of Automotive Engineers published the J1939 set of specifications supporting SAE class A, B, and C communication functions. A J1939 network connects electronic control units (ECU) within a truck and trailer system. The J1939 specification which pertains to engine, transmission, and brake message definitions is especially useful for diesel engine applications. Alternatively, the SAE J1708 specification, “Serial Data Communications between Microcomputer Systems in Heavy Duty Vehicle Applications,” can be used.  
         [0016]     Data received by each sensor  12  on a piece of equipment  4  is sent to CAN master controller  5  where it is stored until downloaded by system controller  22  through wireless communications link  8 .  
         [0017]     Operator controller  24  receives alerts in the form of warning messages, instructions, alarms, etc. to warn an equipment operator (not shown) of conditions (faulty operation, etc.) sensed on equipment  4  by a sensor  12 , thereby allowing the operator to take or institute corrective or preventative action.  
         [0018]     Equipment manager  14  in conjunction with data processing center  6  analyzes data received from each CAN master controller  5 . As a result thereof, equipment manager  14  issues, inter alia, maintenance recommendations, alerts, alarms to system controller  22  which in turn forwards the same to a user control/monitoring site  26 . A control/monitoring site  26  can represent, for instance, the owner of rental equipment. Through link  36 , communications can be had between each control/monitoring site  26  and equipment manager  14  through system controller  22  pertaining to a specified piece of equipment  4 . Communications over link  36  can occur by numerous ways. For instance, these communications can occur over the Internet, via e-mail, text messages, etc. Equipment manager  14  function can adapt to inputs, requests, etc. from control/monitoring sites  26 . For instance, a maintenance step can be moved up ahead of schedule at the request of a control/monitoring site  26 .  
         [0019]     Although the invention herein has been described with reference to particular embodiments, it is to be understood that these embodiments are merely illustrative of the principles and applications of the present invention. It is therefore to be understood that numerous modifications may be made to the illustrative embodiments and that other arrangements may be devised without departing from the spirit and scope of the present invention as defined by the appended claims.