Surface image data relating to an upper cover rubber is continuously and successively captured by a surface camera device and input to a computation device. Each piece of surface image data is stored in a database in association with data on the circumferential position of that surface image data on a conveyor belt and data on the time at which that surface image data was captured. An input unit is used to display any piece of surface image data on a monitor, register surface image data in which a predetermined defect is present on the surface of the upper cover rubber in the database as data to be monitored, and automatically register in the database surface image data having the same circumferential position data as the data to be monitored as related data to be monitored. Such monitoring system determines the state of damage of a cover rubber surface.

In addition to the amount of wear of a rubber comprising at least an upper cover rubber of a conveyor belt installed at a use site, data of at least one input item from six input items consisting of an impact force acting on the conveyor belt, a tensile force, an indicator indicating a state of a core, an indicator indicating a state of an endless portion, an indicator indicating a state of a belt conveyor device, and an indicator indicating a use environment of the conveyor belt is input into a server via an input unit, and a calculation unit calculates a remaining service life of the conveyor belt based on the data input and, stored in a storage unit, a belt specification database and a tolerance range database in which a tolerance range for each of the input items is input in advance per belt specification.

A conveyor apparatus (1) can include a control mechanism to permit automatic monitoring of a conveyor belt (7) and automatically actuate adjustment of the belt (7). In some embodiments, at least two sensors (31) can be utilized to detect an operational condition of the belt (7) indicating an undesirable alignment of the belt as the belt moves to convey material. Upon such a detected operational condition, a control mechanism can automatically actuate adjustment of at least one belt support device to adjust motion of the belt (7) in response to the detected operational condition.

A conveyor apparatus (1) can include a control mechanism to permit automatic monitoring of a conveyor belt (7) and automatically actuate adjustment of the belt (7). In some embodiments, at least two sensors (31) can be utilized to detect an operational condition of the belt (7) indicating an undesirable alignment of the belt as the belt moves to convey material. Upon such a detected operational condition, a control mechanism can automatically actuate adjustment of at least one belt support device to adjust motion of the belt (7) in response to the detected operational condition.

A system for continuously monitoring an apron feeder in real-time, the apron feeder having a plurality of units. The system includes a plurality of sensor modules of different types, wherein each sensor module includes at least one sensor configured to measure an individual condition of a unit of the apron feeder, to generate sensor data representing the measured individual condition, and to transmit the generated sensor data. A base station is configured to collect the sensor data from the plurality of sensor modules, and to transmit outbound data, which is based on the collected sensor data. A processing unit receives the outbound data from the base station, analyses the outbound data for determining whether or not any of the unit of the apron feeder needs to be replaced or readjusted based on its individual condition, and generates a result of the determination for continuously indicating an overall state of the apron feeder.

A wear detection device for a conveyor belt (1) includes magnet members (12a and 12b) buried in a conveyor belt (11) having an endless belt shape, a magnetic sensor (13j) which is arranged opposite to an outer circumferential surface of the conveyor belt (11) and is configured to detect magnetic fields from the magnet members (12a and 12b) to generate an output signal, and a calculation unit (141) which is configured to calculate the thickness of the conveyor belt (11) according to the output signal generated by the magnetic sensor (13j). The wear detection device for a conveyor belt (1) further includes a storage unit (142) which is configured to store the thickness calculated by the calculation unit (141), and a processing unit (143) which is configured to calculate the decrease amount of the thickness per a predetermined moving load amount of the conveyor belt (11) according to the thickness stored in the storage unit (142) and determine whether or not this value exceeds a threshold value set in advance.

Provided are an abnormality detection system, an abnormality detection device, an abnormality detection method, a computer program, and a chain that enable detecting of an abnormality not only in a chain but also in equipment using the chain while distinguishing the location at which the abnormality occurs. The abnormality detecting system comprises a sensor unit comprising a sensor, to be fixed to a chain that is to be attached to equipment, and transmitting an output from the sensor, a detection section which detects an abnormality of the chain or the equipment based on the output, and a determining section which determines a location of the abnormality in the equipment, based on a position of a part fixed with the sensor unit in the equipment, the position changes in each time point with moving of the chain.

A conveyor belt management system is capable of determining in detail the state of a conveyor belt, more reliably preventing the conveyor belt becoming unusable, determining a suitable replacement period, and lowing the running costs of the conveyor belt. A state of the conveyor belt is monitored by a calculation unit and an expected service life before use is calculated based on data of an indicator indicating a status of a belt conveyor device and an indicator indicating a use environment of the conveyor belt; at least one data from an amount of wear, an impact force, a tensile force, a state of a core, and an indicator indicating a state of an endless portion; and a belt specification database and a tolerance range database in which a tolerance range for each of the input items in input in advance per belt specification stored in a storage unit.

A conveyor belt management system is capable of determining a suitable replacement period of the conveyor belt. Data of an amount of wear of an upper cover rubber of the conveyor belt installed at a use site is input into a server via an input unit. A calculation unit is configured to calculate a remaining service life of the conveyor belt based on the input data and, stored in a storage unit, a belt specification database and a tolerance range database in which a tolerance range is input in advance for the amount of wear per belt specification; and calculate an expected service life of the conveyor belt before use of the conveyor belt based on a correlation between a use condition and belt specifications of the conveyor belt used up until present, the use condition of the conveyor belt, and the specifications of the conveyor belt.

In order to improve control of a long-stator linear motor, a first measured value is ascertained in a first measurement section and a second measured value is ascertained in a second measurement section, in each case along a transport path in a movement direction. The first measurement section overlaps, in the movement direction, the second measurement section in an overlap region, and the first measured value and the second measured value represent the same actual value of a physical quantity. An operating parameter of the long-stator linear motor determined based on a deviation occurring between the first measured value and the second measured value.