3BHL000396P0001 Interface Controller

Product parameters

Model: 3BHL000396P0001

Brand: ABB

Size: 10cm x 10cm x 30cm

Weight: 1.2KG

Color: White Black

Working voltage: 5V

Working temperature: -10 ℃ to 50 ℃

Communication interface: RS232, RS485, CAN

Product specifications

Support for MODBUS protocol

Support hardware flow control

Using high-speed CMOS devices

Support for data caching

application area

3BHL000396P0001 is mainly used in the field of industrial automation, such as DCS PLCs, industrial controllers, robots, etc.

3BHL000396P0001 is mainly used in steel manufacturing, thermal power generation, hydroelectric power generation, glass manufacturing, paper mills, cement factories, petrochemicals

Chemical fiber, pharmaceutical manufacturing, rubber, plastics, ferrous metal food, machine tools, specialized equipment, transportation vehicles, mechanical equipment

Electronic communication equipment, instruments and beverages, tobacco processing, clothing, textiles, leather, wood processing, furniture, printing, etc

Model: 3BHL000396P0001 Brand: ABB Archive Function: Communication Function Product Certification: Qualified

Working voltage: 24V Internal variable: No pattern Type: Vector diagram Applicable range: Industrial type

Number of screens: 4 Imported or not: Yes Customized for processing: No

Alarm function: Product name: Module Input voltage: 24V Rated current: 5A

Special service: including postage. Remarks: one-year warranty. Operation method: remote control

Applicable motor: servo motor system memory: 8MB Display color: 99.9 color gamut

Power voltage: 220V Input method: Current Input Material code: 65218

Communication interface: HDMI interface Working temperature: 60 Material number 26854 Other functions Analog communication

Output frequency: 50HZ Rated voltage: 24V Alarm type: Light alarm

Disconnect capacity: 0.01 Vector graph support: Minimum number of packages supported: 1

Display type: IPS USB interface quantity: 2 interfaces Memory card slot: 2

Panel protection level: 3 Memory expansion capacity: 128MB User script support: supported

Speed response frequency: 1MS Working environment temperature: -40 to 100 Insulation withstand voltage test: Passed

Third party communication products: ABB controllers available for sale in: nationwide

Product Instructions

Please install 3BHL000396P0001 correctly on the device and connect the communication interface cable properly.

Please refer to the user manual for operating 3BHL000396P0001 to ensure proper use.

Product Introduction

3BHL000396P0001 is a high-performance industrial automation communication module that uses high-speed CMOS devices, supports MODBUS protocol, and supports
hardware flow control. It is an ideal choice in the field of industrial automation.

(2) Data collection and traceability issues. Data collection issues often occur, and many assembly lines lack “end-to-end traceability.”
In other words, there are often no unique identifiers associated with the parts and processing steps being produced.
One workaround is to use a timestamp instead of an identifier. Another situation involves an incomplete data set. In this case, omit
incomplete information parts or instances from the forecast and analysis, or use some estimation method (after consulting with manufacturing experts).

(3) A large number of features. Different from the data sets in traditional data mining, the features observed in manufacturing analysis
may be thousands. Care must therefore be taken to avoid that machine learning algorithms can only work with reduced datasets (i.e.
datasets with a small number of features).

(4) Multicollinearity, when products pass through the assembly line, different measurement methods are taken at different stations
in the production process. Some of these measurements can be highly correlated, however many machine learning and data mining
algorithm properties are independent of each other, and multicollinearity issues should be carefully studied for the proposed analysis method.

(5) Classification imbalance problem, where there is a huge imbalance between good and bad parts (or scrap, that is, parts that do not
pass quality control testing). Ratios may range from 9:1 to even lower than 99,000,000:1. It is difficult to distinguish good parts from scrap
using standard classification techniques, so several methods for handling class imbalance have been proposed and applied to manufacturing analysis [8].

(6) Non-stationary data, the underlying manufacturing process may change due to various factors such as changes in suppliers
or operators and calibration deviations in machines. There is therefore a need to apply more robust methods to the non-stationary
nature of the data. (7) Models can be difficult to interpret, and production and quality control engineers need to understand the analytical
solutions that inform process or design changes. Otherwise the generated recommendations and decisions may be ignored.

Excitation system ABB module IMFEC11
Excitation system ABB module IMFEC11
Excitation system ABB module IMFCS01
Excitation system ABB module IMFCS01
Excitation system ABB module IMFBS01
Excitation system ABB module IMFBS01
Excitation system ABB module IMFBM01
Excitation system ABB module IMFBM01
Excitation system ABB module IMFAI02
Excitation system ABB module IMFAI02
Excitation system ABB module IMFAI01
Excitation system ABB module IMFAI01
Excitation system ABB module IMDSO15
Excitation system ABB module IMDSO15
Excitation system ABB module IMDSO14
Excitation system ABB module IMDSO14
Excitation system ABB module IMDSO14
Excitation system ABB module IMDSO14
Excitation system ABB module IMDSO05
Excitation system ABB module IMDSO05
Excitation system ABB module IMDSO04
Excitation system ABB module IMDSO04
Excitation system ABB module IMDSO03
Excitation system ABB module IMDSO03
Excitation system ABB module IMDSO02
Excitation system ABB module IMDSO02
Excitation system ABB module IMDSO01
Excitation system ABB module IMDSO01
Excitation system ABB module IMDSM05
Excitation system ABB module IMDSM05
Excitation system ABB module IMDSM04
Excitation system ABB module IMDSM04
Excitation system ABB module IMDSM04
Excitation system ABB module IMDSM04
Excitation system ABB module IMDSM04
Excitation system ABB module IMDSI22-ABX
Excitation system ABB module IMDSI22-ABX
Excitation system ABB module IMDSI22
Excitation system ABB module IMDSI22
Excitation system ABB module IMDSI22
Excitation system ABB module IMDSI22
Excitation system ABB module IMDSI15
Excitation system ABB module IMDSI14
Excitation system ABB module IMDSI14
Excitation system ABB module IMDSI14
Excitation system ABB module IMDSI13
Excitation system ABB module IMDSI13
Excitation system ABB module IMDSI12
Excitation system ABB module IMDSI02
Excitation system ABB module IMDSI02
Excitation system ABB module IMDS014
Excitation system ABB module IMDS014
Excitation system ABB module IMDS004
Excitation system ABB module IMDER02
Excitation system ABB module IMDER01
Excitation system ABB module IMCPM02
Excitation system ABB module IMCPM01
Excitation system ABB module IMCOM04
Excitation system ABB module IMCOM03
Excitation system ABB module IMCKN02
Excitation system ABB module IMCKN01
Excitation system ABB module IMCIS22
Excitation system ABB module IMCIS22
Excitation system ABB module IMCIS22
Excitation system ABB module IMCIS22
Excitation system ABB module IMCIS12
Excitation system ABB module IMCIS02
Excitation system ABB module IMCIS02
Excitation system ABB module IMCIS02
Excitation system ABB module IMBLK01
Excitation system ABB module IMBLK01
Excitation system ABB module IMASO11
Excitation system ABB module IMASO11