Produktai skirti apdorojimo užsakymų grąžinimas (784)

These are the accessories used in Hydraulic valve assembly.

Le pliage de tôle est une méthode de traitement commune pour plier une feuille de métal dans la forme désirée. , des pièces automobiles aux matériaux de construction et aux appareils ménagers, sont très importants.Coupe: tout d’abord, utilisez une cisaille ou une découpeuse laser pour couper la feuille de métal dans les dimensions et les trous souhaités. Réglage des matrices et des poinçons: choisissez les matrices et poinçons appropriés dans la presse à cintrer. La forme de la filière doit correspondre au profil de flexion souhaité, tandis que la forme et la taille du poinçon doivent être compatibles. Parfois, des moules personnalisés sont nécessaires, en particulier pour les pliages complexes. Alignement de la feuille: assurez-vous que la feuille est correctement alignée avant de plier. Il faut s’assurer que la flexion se produit à l’angle correct par rapport à l’axe neutre. Force de flexion appliquée: pendant le processus de flexion, le poinçon de la machine presse la tôle dans le m

Ce sont les pièces utilisées dans les accessoires de machines.

These parts are used for printer accessories.

These parts are milled by aluminum,which used in architectural decoration industry.

Grandes pièces usinées en plastique noir.

The J1939 protocol stack offers the complete functionality for integration of the SAE J1939 standard into your devices. Versatile configuration options facilitate individual customization to a target product. Example codes facilitate the startup phase, enabling the user to focus on the implementation of their own application. The open CAN driver (CANpie) provides the flexibility to use any CAN controller available on the market. The bridge function to the CANopen Slave protocol stack facilitates realization of devices with multi protocol capability. In addition, less development time is needed for the implementation of parameters as these are addressed by all protocols in the same way.

The µCAN.explorer is a universal monitor used to supervise data streams within a CAN network. The single messages are assigned individual names (symbols) in order to ensure a clear and simple classification The integrated data logger facilitates the data stream being acquired and saved onto the bus.Display of all received messages with indication of ID, length and data bytes Display of all received remote-frames as well as indication of their number and reception interval Storing and loading of compiled sender lists for emulating different CAN nodes Errors of the CAN bus and the controller are indicated, including error-frame-counter Supports various file formats, incl. Float according to IEEE754 and enumerations (Enums), byte order adjustable to Intel and Motorola format

The sensor module µCAN.1.ti-SENSOR can be joined with any sensor and is designed to acquire an analogue temperature signal. It can be integrated directly in the sensor head (18 mm in diameter). Sensor tolerances can be adjusted with the module already built in. The sensor signal is linearized and monitored directly in the hardware.Temperature Thermo type J, K, L Temperature Pt100, Pt1000 (2-wire) Accuracy ± 0.5 K (Thermo) Accuracy ± 0.2 K (Pt100) Resolution up to 16-bit (0.1 K) Sampling rate up to 1 kHz Signal type freely configurable Sampling rate adjustable Operating temperatures -40 °C … +85 °C Power supply voltage 9 V DC … 36 V DC Fieldbus CAN classic / CAN FD Protocols CANopen / CANopen FD / J1939

Until a vehicle gets road-permission, a number of measurement taske have to be fulfilled along the development chain. During vehicle testing in extreme conditions – in prototyping and pilot series e.g. – MicroControl systems offer the necessary performance and often are an efficient alternative to expensive measurement technology. A variety of different measurement spots in a car can be realized as well as modular test facilities for motors using the 19″ slide-in units.

The decentralized module µCAN.6.ai-SNAP is designed to acquire up to 6 analogue current / voltage signals and converts them into digital CAN signals. Voltage +/- 10 V:Current 0(4)…20 mA Accuracy 0.02 % (FS):Resolution 16-bit (1 mV / 1 µA) Sampling rate 20 ms / 50 Hz:Screw connection via plug-in connectors Fieldbus CAN:Protocol CANopen / Raw CAN

You would like to get to know the performance options of the µMIC.200? Our starter kit facilitates a quick start into programming the control unit µMIC.200. Just unpack, get connected and start programming with Node-RED or in C/C++.Control unit µMIC.200 Mains adapter Digital CANopen I/O module Connecting cable Quickstart

The CANopen / CANopen FD Slave protocol stack has been optimized for low resource requirements and is, thus, well suited for intelligent sensors and actuators. The protocol stack offers the complete functionality for integration of the CANopen standards CiA 301 (FD: CiA 1301) and CiA 305 into your devices. The following CANopen services are supported

The interface µCAN.pc.USB provides an easy and cost-saving connection of a CAN network to a PC. The CAN-to-USB converter is equipped with a plastic casing and due to its small size ideally suited to be used with laptops and notebooks.Bit rate setting up to 1 MBit/sec Space saving adaptor casing with USB cable and 9-pole D-Sub for CAN CAN plug D-Sub 9-poles Complies with CAN-specifications 2.0A (11-Bit ID) and 2.0B (29-Bit ID)

The decentralized module µCAN.4.ao-BOX features four analogue outputs which optionally provide a voltage signal (+/- 10 V) or a current signal (0…20 mA). The CAN interface supports the protocols protocols CANopen and J1939. Voltage +/- 10 V:Current 0(4)…20 mA Accuracy 0.05 % (FS):Resolution 16-bit (1 mV / 1 µA) Signal output 1 ms / 1 kHz:Signal type freely configurable Fieldbus CAN:Protocol CANopen / Raw CAN / J1939

The µCAN.1.ti-BOX is the single channel solution for the acquisition of temperature signals. Resistance sensors as well as thermocouples may be connected to the module. The CAN interface supports the protocol CANopen. Temperature Thermo type J, K, L:Temperature Pt100 (2- / 4-core) Accuracy +/- 0.5 K (Thermo):Accuracy +/- 0.1 K (Pt100) Resolution 16-bit (0.1 °C):Sampling rate 20 ms / 50 Hz Fieldbus CAN:Protocol CANopen / Raw CAN

This pioneering controller goes far beyond the functionality of conventional PLC controllers. As an all in one IoT gateway, CANopen automation controller and top-hat rail PC, the µMIC.200 offers an end-to-end solution. Operating temperature range:-40 °C ... +85 °C Memory:FRAM (battery-free) Power supply voltage:9 ... 36 V DC Operating system:Real-time Linux Programming:Node-RED, C/C ++

Every company is a world of its own and has its specific challenges. Based on our 25 years of expertise and in close liaison with you, we will analyse the current situation and future requirements to set up a specific training programme on ICA, BUS and control technology issues – tailored to your requirements and level of knowledge. Alternatively, we also offer standard training courses on CAN-bus basics, CANopen and J1939 for your company either as online webinar or as an in-house workshop at your site.

At its eight outputs the µCAN.8.pwm-BOX provides pulse width modulated signals (PWM) within a range of 0% to 100% for controlling of actuators (valves etc.). The outlets are overload and short circuit protected. The µCAN.8.pwm-BOX is connected with the central control unit via CAN bus. PWM output:Basic frequency 40 Hz … 5 kHz Mark-to-space ratio 0.0 % … 100.0 %:Each output to be charged with max. 1.4 A 3-wire connector terminal:Output drivers supplied separately Fieldbus CAN:Protocol CANopen / Raw CAN

The sensor module µCAN.1.ai-SENSOR is designed to acquire an analogue signal. It can be integrated directly in the sensor head (18 mm in diameter). Sensor tolerances are adjustable. The sensor signal is linearized and monitored directly in the hardware.Voltage ± 10 V Current 0 mA … 20 mA Accuracy 0.005% (FS) Resolution 16-bit (1 mV / 1 µA) Sampling rate up to 1 kHz Scaling adjustable Sampling rate adjustable Measurement range adjustable Operating temperatures -40°C to +85 °C Supply voltage 9 V DC to 36 V DC Fieldbus CAN Classic / CAN FD Protocol CANopen / CANopen FD / J1939

4-channel temperature acquisition module for PT100 or thermocouple with CAN - The µCAN.4.ti-F1 is the universal measurement module for mobile acquisition of temperature data. Depending on the module type, resistance sensors as well as any kind of thermocouple can be polled at an overall sample rate of 4 kHz. Temperature thermo type K:Temperature Pt100, Pt200 (2- / 4-wire) Temperature Pt500, Pt1000 (2- / 4-wire):Accuracy +/- 0.05 K Resolution 24-bit (0.001 °C):Sampling rate 1.25 ms / 800 Hz Parameterized via set-up software:Equipped with cold-junction compensation Casing powder coated Fieldbus CAN:Protocol Raw CAN

The cable transmitter module µCAN.1.ai-TRS is designed to acquire one analogue measurement signal. The TRS module is integrated directly in the measurement line where the analogue signals are digitized and transmitted to the processing unit via CAN interface. Voltage:± 10 V Current:0 mA - 20 mA Resolution:16-bit (1 mV / 1 µA) Sampling rate:up to 1 kHz Fieldbus:CAN classic / CAN FD Protocol:CANopen / CANopen FD / J1939

The module µCAN.4.ci-SNAP is equipped with 4 fast counters of up to 100 kHz. Additional four I/O terminals can be configured individually as digital inputs or outputs. Counter input / frequency measurement:A/B signal Max. input frequency 500 kHz:High precision frequency measurement Signal type freely configurable:Up and down counter Fieldbus CAN:Protocol CANopen / Raw CAN

Equipped with CAN or CANopen interfaces and a 19″ slide-in casing, the MicroControl µLAB is particulary suitable for measuring electric, thermal and mechanic signals in engine or components testing facilities. The signal wires are connected to the module by plug-in connectors in the front plate. Temperature Pt100, Pt200 (2- / 4-wire):Temperature Pt500, Pt1000 (2- / 4-wire) Accuracy +/- 0.5 K:Resolution 16-bit (0.1 °C) Sampling rate 10 ms / 100 Hz:Signal type freely configurable Operating temperatures -40…+85 °C:Power supply voltage 9…36 V DC Fieldbus CAN:Protocol CANopen / Raw CAN

CAN FD (CAN flexible data rate) is an expasion of the “classical” CAN bus (CAN classic) and is defined by the standard ISO 11898-1:2015. CAN FD facilitates not only sending of larger data volumes (payload): the limit of 8 bytes with CAN classic has been increased to 64 bytes with CAN FD. Also, it provides the possibility of a higher bit rate within the data phase, even going beyond the previous limit of 1 MBit/s.

CANopen has been developed by the members of the international user and producer assosiation CAN in Automation (CiA). The CANopen application layer defines different communication services and protocols (e.g. process and service data) as well as a network management. CANopen is mainly used as an embedded network in machinery, but also as a general industrial communications system. It is based on the international standards ISO 11898-1 (CAN protocol) and ISO 11898-2 (fast physical layer). The CANopen application layer has been standardized by the CENELEC and is defined in the European standard EN 50325-4.

The sensor module µCAN.1.sg-SENSOR can be combined with all common pressure sensors and is designed to acquire an analogue sensor signal. It can be integrated directly in the sensor head (18 mm in diameter). Sensor tolerances can be adjusted with the module already built in. The sensor signal is linearized and monitored directly in the hardware.Strain gauge full bridge Voltage ± 20 mV Supply voltage 4.5 V Accuracy 0.2% (FS) Resolution up to 16-bit (1 mV / 1 µA) Sampling rate up to 1kHz Supply of the strain gauge full bridge Scaling / sampling rate adjustable Measurement range adjustable Operating temperatures -40°C … +85 °C Supply voltage 9 V DC … 36 V DC Fieldbus CAN classic / CAN FD Protocol CANopen / CANopen FD / J1939

Real-time Linux, Ethernet, CAN, USB plus custom electronics in a space-saving metal top-hat rail casing. In its µMIC.200 family, MicroControl integrates the best of the world of automation for IoT/Industry 4.0. The unit is equipped with COMBICON® connectors and offers versatile connection facilities for digital signals, CAN bus and RS-232. I/O modules with CAN interface can be connected to the unit via the integrated CANopen FD Master library. An even higher flexibility is offered through its customizable electronics. Two boards perfectly matched. CPU board and high performance standard board or – alternatively – a CPU board and a custom board tailored to your specific needs. The metal casing is able to withstand extreme operating environments. And all this at most favourable terms.2 Ethernet interfaces 2 CAN interfaces (isolated) 2 x RS-232 (isolated) CANopen Master function Cortex-A8 CPU with USB interface of 1 GHz frequency 4 GByte Flash and 512 MByte DDR3 RAM

The module µCAN.1.ti-SNAP is designed to acquire temperature signals via Pt100 or J, K and L type thermocouples. Temperature Thermo type J, K, L:Temperature Pt100 (2- / 4-wire) Accuracy +/- 0.5 K (Thermo):Accuracy +/- 0.1 K (Pt100, Pt1000) Resolution 16-bit (0.1 °C):Sampling rate 20 ms / 50 Hz Signal type freely configurable:Protocol CAN / CANopen / Raw CAN

The CAN driver CANpie FD (Controller Area Network Programming Interface Environment) is an open interface for the development of CAN-based applications. The CAN driver forms the basis for higher layer protocols (CANopen / J1939) and may be used for manufacturer-specific CAN communication between embedded systems. CANpie FD is avaliable for a wide range of microcontrollers (more than 160 at the moment). A variety of configuration options facilitates adjustment to individual target systems. The CAN physical layer (data link layer) comprises two protocols: the classical CAN standard and CAN FD. The protocols are described in the ISO 11898-1:2015 specification. The CANpie FD API defines 19 functions to allow manufacturer independend access to the CAN controller to entirely support ISO specifications. The API is based on the concept of dedicated message buffers (mailboxes) in combination with acceptance masks to minimize the application