Disclosures of the present invention describe a machine failure analyzing system. In the machine failure analyzing system, a wearable electronic device is for a user to wear, and a controlling and processing device is provided with a machine history data base and a failure causes analyzing unit. When a specific machine is malfunctioning or in a failure status, the controlling and processing device utilizes a machine status data collecting unit to collect machine status data from the specific machine. Subsequently, based on the machine status data, the failure causes analyzing unit can find relative failure causes from the machine history data base, thereby generating at least one troubleshooting solution. As such, under instructions of the troubleshooting solution, a field engineer who wears the wearable electronic device can achieve the troubleshooting of the specific machine rapidly and precisely, without needing to spend time finding the failure causes.

Disclosed are a control information interaction method and a smart robot, falling within the technical field of smart devices. The method comprises: step S1, a user inputting control information to a user end; step S2, the user end forming alternative information having a preset form according to the control information and outputting same; step S3, the smart robot receiving the alternative information, and performing parsing according to the alternative information to obtain corresponding parsed information; and step S4, the smart robot performing restoration according to the parsed information to obtain the control information, and executing a corresponding operation according to the control information. The beneficial effects of the technical solution are: being capable of making human-machine interaction between a user and a smart robot more convenient and rapid, and ensuring the accuracy of information interaction.

A portable safety control device for use with a portable electronic device to communicate with an industrial machine. The control device includes a body having gripping portion for engagement by a human hand and a supporting portion for engagement with the portable electronic device. In one example, separate enabling and emergency stop switches are positioned on the body proximate the gripping portion within reach of the hand engaged with the gripping portion, and is configured for ease of use by left or right-handed users. The supporting portion is configured and oriented to rest on the forearm of an operator. A control circuit is used to communicate with both the portable electronic device and the industrial machine controller.

A method of scheduling a robotic device enables the device to run autonomously based on previously loaded scheduling information. The method consists of a communication device, such as a hand-held remote device, that can directly control the robotic device, or load scheduling information into the robotic device such that it will carry out a defined task at the desired time without the need for farther external control. The communication device can also be configured to load a scheduling application program into an existing robotic device, such that the robotic device can receive and implement scheduling information from a user.

A convertible power tool that can operate in first and second configurations. The tool includes a base unit configured to receive at one time either a first module or a second module. The different modules provide for different levels of functionality. The first module includes one or more components that provide for a first level of functionality. The second module includes one or more components that provide for an advanced second level of functionality. Each of the base unit and first and second modules may include interfaces that provide for physical engagement as well as power/data engagement. In use, one of the first and second modules is connected to the base unit to provide for the desired functionality incorporated with the tool. The tool may also be reconfigured by removing the attached module and replacing it with the other module thus providing for a different functionality level.

An example method of performing maintenance on an aircraft includes receiving a vehicle data-signature-map of an interior of an aircraft for at least one parameter of the aircraft, and the vehicle data-signature-map is based on sensor outputs received from sensors of mobile devices positioned at locations in the interior of the aircraft. The method also includes comparing the vehicle data-signature-map with a previous vehicle data-signature-map, based on differences of the vehicle data-signature-map as compared to the previous vehicle data-signature-map making a determination for maintenance, and generating and outputting a recommendation for inspection of an identified portion of the aircraft based on the distribution of the at least one parameter in the vehicle data-signature-map for the identified portion of the aircraft being substantially different than the distribution of the at least one parameter in the vehicle data-signature-map for other portions of the aircraft to assist with the maintenance of the aircraft.

A portable safety control device for use with a portable electronic device to communicate with an industrial machine. The control device includes a body having gripping portion for engagement by a human hand and a supporting portion for engagement with the portable electronic device. In one example, separate enabling and emergency stop switches are positioned on the body proximate the gripping portion within reach of the hand engaged with the gripping portion, and is configured for ease of use by left or right-handed users. The supporting portion is configured and oriented to rest on the forearm of an operator. A control circuit is used to communicate with both the portable electronic device and the industrial machine controller.

An accelerator comprises: an accelerometer (100), configured to detect an acceleration of a motion of a carrier and output a corresponding electrical signal; a sampling and low-pass filter (200), coupled to the accelerometer (100), and configured to sample the electrical signal regularly and filter a noise from the electrical signal; an amplifier (300), configured to amplify the electrical signal after filtering the noise; an analog-to-digital converter (400), configured to convert the amplified electrical signal into a digital signal; a function control module (500), configured to process the digital signal and output a control signal to control the analog-to-digital converter (400), the amplifier (300), and the sampling and low-pass filter (200); and an oscillator module (600), configured to output, according to the control signal, a sampling signal to the sampling and low-pass filter (200), so as to control the sampling and low-pass filter (200) to sample the electrical signal regularly.

An operating system for a container handling machine, including an operating device for the container handling machine having a screen and a data transmitter for transmitting information and at least one separate additional screen having a data receiver for receiving information, with the operating device designed for selecting the information and the additional screen designed for displaying the selected information.

A method and system detect and remotely manage sensors and/or devices for feeding textile and/or metallic yarns on textile machines. Each textile machine includes an electronic control unit electrically connected to the sensors and/or feeding devices for receiving identifiers associated with a sensor and/or feeding device, and data and operating parameters representing a sensor and/or feeding device operating state. A first communication system is associated with the electronic control unit. Wireless communication between the electronic control unit and a portable electronic device is by a second wireless communication system with a display interface. The electronic control unit transmits the identifiers to the portable electronic device. The portable electronic device processes the identifiers to generate menus with selectable entries associated with the textile machines. Each menu represents the number/type of sensors and/or feeding devices installed. The main menu is displayed with selectable entries on the portable electronic device display interface.