RU203151U1 - COMPLETE LOW-VOLTAGE DISTRIBUTION AND CONTROL DEVICE WITH BUILT-IN MONITORING, CONTROL AND DIAGNOSTIC SYSTEMS - Google Patents

Abstract

The utility model relates to devices designed for input and distribution of electricity to consumers for their own needs, protection and control of electric drives of actuators for various purposes from modules of the input / output station and diagnostics of electric drive valves. A complete low-voltage distribution and control device with built-in monitoring, control and diagnostics systems contains 11 modules, including an input unit, an input-output station, functional blocks and a switch. 2 c.p. f-ly, 5 dwg

Description

The utility model refers to devices designed for the input and distribution of electricity to consumers for their own needs, protection and control of electric drives of actuators for various purposes from modules of the input / output station (hereinafter referred to as SVV) and diagnostics of electric drive valves.

Known low-voltage complete switchgear (hereinafter - LVD) with the ability to work as part of an automated process control system (hereinafter - APCS) produced by JSC "Cheboksary Electroapparat", which allows automated diagnostics, monitoring and control of equipment from the dispatch center.

Known intelligent low-voltage switchgear manufactured by NPO Gaztekhnomash, designed to receive and distribute electrical energy in AC and / or DC networks with voltage up to 1000 V, remote, automated and manual control, monitoring, signaling and protection of equipment against short-circuit currents and overloads, protection personnel from electric shock, consisting of functional retractable and stationary units.

The prototype of the proposed technical solution, which is similar in functionality and design, is a low-voltage switchgear type MNS iS manufactured by ABB on the basis of retractable modules, designed to receive and distribute three-phase alternating current electrical energy, as well as shields for electric motor control stations. Integration of intelligence into an ASSEMBLY at the structural level allows using a wide range of control, protection and monitoring functions, communication with the upper-level control system is carried out via the field bus using open industrial protocols Profibus, Modbus and Ethernet.

The disadvantages of the described technical solutions are the lack of a diagnostic function for electric actuated valves.

The purpose of this technical solution is to create a low-voltage complete device, which will have a control system for actuators, allowing for the automation of the technological process, monitoring the state of automation equipment and realizing the functions of diagnosing electric actuator valves.

This goal is achieved due to the design of this device.

A complete low-voltage distribution and control device with built-in monitoring, control and diagnostics systems contains 11 modules, each 1M in height (M = 150 mm), and 1/3, 1/2, 1 in width. At levels 1M, 2M, there is an introductory block 1, designed for power input and distribution of electricity inside the GCC cabinet. Input-output station (SVV) 2 - crate with discrete modules - controls functional blocks 3 and 4.
At levels 3M, 4M, 11M, there are 3 blocks of standard size 1/3,
at levels 5M, 7M, 8M, 9M, 10M there are 4 blocks of standard size 1/2.
At the 6M level, switch 5 is installed (Fig. 1).

SVV 2 implements the functions of control and signal acquisition using discrete modules:

1. Two power connection modules 6, providing power supply to the modules installed in the SVV 2.

2. Two interface modules 7, providing:

communication of SVV 2 with the automation processor located in the external control rack of the ACS;

synchronization of timers of the current time with the external control rack of the ACS;

implementation of operational software self-control and diagnostics;

loading of applied parameters into the external control rack of the ACS;

presentation of information about malfunctions of the interface module and channels of connection to it.

3. Discrete control modules for 8 functional blocks, providing:

input of discrete signals from sensors of the state of technological processes (sensors of pressure, temperature, etc.) with possible diagnostics of the sensor connection circuits;

output of discrete signals from sensors of the state of technological processes with control of the values of output signals and protection against short circuit;

control of actuators by commands received via digital communication (issuing hardware control commands and receiving feedback signals);

diagnostics of the technical condition of the GCC cabinet by using one of the control modules 8.

The SVV compartment 2 is equipped with a door position sensor 9 to implement the security function - the control personnel are given a signal about unauthorized access to the internal equipment of the cabinet (Fig. 2).

On the door 10 of the SVV 2 compartment, to ensure normal temperature conditions, there is a compartment cooling system, consisting of four fans 11 and a block 12 that distributes power to them and collects data on the failure of fans 11. Door 10 is attached to the cabinet body on hinges 13, lock 14 it is locked with a key, which excludes unauthorized access to the SVV 2, the door 10 has a viewing window 15 located in the center, made of a transparent material (for example, polycarbonate) for visual monitoring of the state of the modules included in the SVV 2 (Fig. 3).

To implement the diagnostic function, the functional blocks of 3 standard sizes 1/3 of the LVCD cabinet accommodate the measuring modules of the built-in system of electric drive fittings (hereinafter - TS VSDEA), consisting of:

block of voltage converters 16 (BPN), designed to match the AC power of the electric drive with the parameters of the analog-to-digital converter of the processing and storage unit 18;

block of current converters (DCT) 17, designed to match the AC voltage level of the three phases of the power supply of the electric drive with the parameters of the analog-to-digital converter of the processing and storage unit 18;

a processing and storage unit (PCB) 18 designed to convert analog signals from the BPN and BPT into a digital code; for processing, recording and storing measurement results on a microSD card (inside the BOX); to generate a "Fault" signal of the "dry contact" type upon detection of an open circuit in the power supply of the shut-off valve drive; to provide communication with an external computer via a local area network or USB;

circuit breaker 19, providing protection of power circuits from voltage surges and short-circuit currents;

contactor 20, which allows you to remotely turn on and off the power electrical circuits (Fig. 4).

Functional blocks of 4 standard sizes 1/2 of the low-voltage switchgear cabinet accommodate TS VSDEA, consisting of:

block of voltage converters 16 (BPN), designed to match the AC power of the electric drive with the parameters of the analog-to-digital converter of the processing and storage unit 18;

block of current converters (DCT) 17, designed to match the AC voltage level of the three phases of the power supply of the electric drive with the parameters of the analog-to-digital converter of the processing and storage unit 18;

a processing and storage unit (PCB) 18 designed to convert analog signals from the BPN and BPT into a digital code; for processing, recording and storing measurement results on a microSD card (inside the BOX); to generate a "Fault" signal of the "dry contact" type upon detection of an open circuit in the power supply of the shut-off valve drive; to provide communication with an external computer via a local area network or USB;

circuit breaker 19 providing protection of power circuits against voltage surges and short-circuit currents;

contactless starter 21, which serves to switch power circuits at multiple frequency of actuation of actuators (enhanced mode of circuit control) (Fig. 5).

The power supply of the TS VSDEA equipment of functional blocks 3 and 4 is implemented using PoE (Power over Ethernet) technology, which allows the device to transmit electrical energy along with data via a twisted pair in an Ethernet network, which makes it possible to exclude additional power supplies from the cabinet and simplify the cabinet design.

To combine all the VSDEA TSs located in functional blocks 3 and 4 into a common data transmission network at the 6M level, a VSDEA 5 switch is installed. The VSDEA 5 switch is connected by patchcords to all blocks 3 and 4. An optical patchcord is laid from the VSDEA 5 switch to the crossover optical box.

The use of the described technical solutions made it possible to create a device with a control system for actuators, which allows for the automation of the technological process, monitoring the state of automation equipment and realizing the functions of diagnosing electric actuated valves in one construct.

Claims (3)

1. A complete low-voltage distribution and control device with built-in monitoring, control and diagnostic systems, containing at least 11 modules, including an input unit, an input-output station, functional blocks and a switch, characterized in that functional blocks are located measuring modules of the built-in system of electric actuator valves. 2. The device according to claim 1, characterized in that the measuring modules of the built-in system of electric actuator valves allow processing, recording, storage of measurement results and provide communication with an external computer via a local area network or USB in order to diagnose the technical condition of the electric actuator valves. 3. The device according to claim 1, characterized in that the power supply of the measuring modules of the built-in system of electric drive valves is implemented using Power over Ethernet technology, which makes it possible to exclude additional power supplies from the cabinet and to simplify the cabinet design.

Images