RU74691U1 - SYSTEM OF AUTOMATIC REGULATION, CONTROL, TECHNOLOGICAL PROTECTION AND SIGNALING OF BOILER UNIT - Google Patents

Abstract

1. A system for automatic regulation, control, technological protection and alarm of the boiler unit, containing a rarefaction control circuit in the boiler furnace, consisting of a selectively connected device, an impulse line, a rarefaction sensor in the boiler furnace, a rarefaction regulator and an actuator installed in the boiler chimney, circuit regulating the fuel-air ratio, consisting of a series-connected selective device on the air supply pipe to the boiler furnace, whether pulse AI, an air pressure sensor, a ratio regulator and an actuator installed on the air supply pipe to the boiler furnace, connected in series to a select device on the fuel supply pipe to the boiler furnace, a pulse line, a fuel pressure sensor, the output of which is connected to the second input of the ratio controller, showing rarefaction devices in the boiler furnace, air pressure supplied to the boiler furnace, fuel pressure in the fuel supply pipe to the boiler furnace, connected via impulse lines appropriate selective devices, as well as warning vacuum devices in the boiler furnace, air pressure supplied to the boiler furnace, fuel pressure in the fuel supply pipe to the boiler furnace, connected via pulse lines to selected devices, a torch control device in the boiler furnace, technological protection unit and alarms, the inputs of which are connected to the outputs of signaling devices and the torch control device, and the outputs - to the inputs of the audible alarm device and the safety shut-off valve on the pipe

Description

The utility model relates to boiler equipment, specifically to systems for automatic regulation, control, technological protection and alarm of a boiler unit.

Known systems for automatic regulation, control, technological protection and alarm of a boiler unit (RU 21949, class., 2002; RU 53413, class F23N 5/00, 2006; RU 61845, class F23N 5/00, 2007; Handbook of gasified boiler houses exploiters. Edited by E. B. Stolper. -L .: Nedra, 1988, p. 344-378), containing a block of sensors for the technological parameters of the boiler, connected directly to the control system for supplying the fuel mixture to the furnace of the boiler, and through the block of threshold devices - with alarm system.

The closest known system is the automatic control, monitoring, technological protection and alarm of the boiler unit (Handbook of the exploitation of gasified boiler houses. Edited by E.B. Stolper. - L .: Nedra, 1988, p. 344-378), containing a rarefaction control loop in the furnace of the boiler, consisting of a series-connected selective device, an impulse line, a vacuum sensor in the furnace of the boiler, a vacuum regulator and an actuator installed in the chimney of the boiler, the ratio control loop Pliva-air ", consisting of series connected devices for selective air supply line to the furnace, a pulse line, an air pressure sensor, and the ratio controller actuator mounted on the air supply line to the boiler, connected in selective device

on the fuel supply pipe to the boiler furnace, a pulse line, a fuel pressure sensor, the output of which is connected to the second input of the ratio regulator, showing the vacuum devices in the boiler furnace, the air pressure supplied to the boiler furnace, the fuel pressure in the fuel supply pipe to the boiler furnace, connected through impulse lines with appropriate selective devices, as well as signaling rarefaction devices in the boiler furnace, air pressure supplied to the boiler furnace, fuel pressure in the fuel supply pipe in t boiler monitoring, connected via pulsed lines to selected devices, a torch monitoring device in the boiler furnace, a technological protection and alarm unit, the inputs of which are connected to the outputs of signaling devices and a torch monitoring device, and the outputs are connected to the inputs of an audible alarm device and a safety shut-off (cut-off) valves on the fuel supply pipe to the boiler furnace.

A disadvantage of the known automatic control system for control, technological protection and signaling is the lack of reliability associated with the presence of random pulsations of rarefaction and air pressure in the pulse lines caused by fluctuations in the boiler furnace during fuel combustion, especially fuel oil, which impair the quality of the process control process boiler unit, lead to an increase in the frequency of operation of regulators and actuators, premature wasp mechanical elements of automatic control systems, reduce their reliability, to unjustified tripping process protection system, emergency shutdown of the boiler and having to restart it difficult visual control of process parameters from the maintenance personnel using showing devices. Attempts to reduce the influence of random pulsations of the controlled parameters of the boiler in a known automatic control system by increasing the zone

the insensitivity of the regulators or an increase in the time constant of smoothing filters (RC chains) that are part of the regulators lead to a deterioration in the static and dynamic accuracy of regulation.

The objective of the utility model is to increase the reliability of the system of automatic control regulation, technological protection and alarm. The technical result that provides the solution of this problem is the mechanical damping of random pulsations of the measured fluid supplied to the signal inputs of the sensors for monitoring the technological parameters of the boiler.

Achievement of the claimed technical result and, as a consequence, the solution of the problem by the fact that the automatic control system, control, technological protection and alarm of the boiler unit, containing a rarefaction control circuit in the boiler furnace, consisting of a selectively connected device, an impulse line, a vacuum sensor in the boiler furnace , a rarefaction regulator and an actuator installed in the chimney of the boiler, the fuel-air ratio control loop, consisting of a series of connected to a selective device on the pipeline for supplying air to the boiler furnace, impulse line, air pressure sensor, ratio regulator and actuator installed on the pipeline for supplying air to the boiler furnace, in series connected to a selective device on the pipeline for supplying fuel to the furnace, pulse line, sensor fuel pressure, the output of which is connected to the second input of the ratio regulator, showing rarefaction devices in the boiler furnace, air pressure supplied to the boiler furnace and the fuel pressure in the fuel supply line to the boiler, connected via control lines with respective selective devices, and signaling devices underpressure in the boiler furnace, the air pressure supplied to the boiler, the fuel pressure in the fuel supply conduit

into the furnace of the boiler, connected via impulse lines to selective devices, the torch control device in the furnace of the boiler, the technological protection and alarm unit, the inputs of which are connected to the outputs of signaling devices and the torch control device, and the outputs are connected to the inputs of the sound alarm device and safety shut-off (shut-off ) valves on the fuel supply pipe to the boiler furnace, according to a utility model, it additionally contains at least one damper installed in impulse lines in front of the inputs of the discharge sensor Indicating and signaling devices underpressure in the boiler furnace and at least one damper mounted in the impulse lines to inputs of the pressure sensors indicating and signaling devices for air pressure air supply line to the furnace.

At the same time, the damper is made in the form of a variable-capacity tank made of elastic material, in the form of a pipe with an automatically changing passage section and / or in the form of a noise muffler — pipes with double walls and resonant chambers interconnected by calibration holes. The elastic material of the tank of variable volume of the damper is made of spring brass or rubber. The damper pipe with automatically changing passage section is equipped with internal spring-loaded partitions. The damper muffler is made with an absorption spectrum band that overlaps the region of high-frequency oscillations of the medium flowing through the damper.

Introduction to the system of at least one damper installed in impulse lines in front of the inlet of the vacuum gauge, showing and signaling rarefaction devices in the boiler furnace and at least one damper installed in impulse lines in front of the inlet of pressure sensors, showing and signaling air pressure gauges in the air supply pipe into the furnace of the boiler allows to suppress spurious fluctuations of the current medium supplied to the sensors of the technological parameters of the furnace of the boiler unit, showing and signaling

devices, eliminate their false operation and, thereby, increase the reliability of the proposed system. The implementation of the dampers in the form of a variable-capacity tank of elastic material, in the form of a pipe with an automatically changing passage section and / or in the form of a noise suppressor — pipes with double walls and resonant chambers interconnected by calibration holes allows implementing the proposed system with the claimed technical result with multivariate performance of its dampers. It allows you to choose a damper with rational frequency characteristics for use in the system of automatic regulation, control, technological protection and alarm for a specific boiler unit.

Figure 1 presents a block diagram of a system of automatic regulation, control, technological protection and alarm boiler, and figure 2 and figure 3 are graphs illustrating the effectiveness of its operation compared with the known system.

The system of automatic regulation, control, technological protection and alarm of the boiler unit consists of selected devices 1,2,3 rarefaction, air pressure and fuel pressure, respectively installed at the outlet of the furnace 4, on the air supply pipe 5 and the fuel supply pipe 6 to the furnace. The output of the rarefaction selection device 1 in the furnace 4 of the boiler is connected to the inputs of the pulse lines 7 ÷ 9, the output of the air pressure selection device 2 at the inlet to the furnace 4 is connected to the inputs of the pulse lines 10 ÷ 12, and the output of the device 3 for the pressure measurement of fuel at the entrance to the furnace 4 - with inputs of impulse lines 13 ÷ 15. At the ends of lines 7, 8, 9, respectively, dampers 16, 17, 18 are installed to smooth out pulsations of the measured air discharge in the furnace 4 of the boiler. At the ends of lines 10, 11, 12, respectively, dampers 19, 20, 21 are installed to smooth out pulsations of the measured air pressure at the inlet of the furnace 4 of the boiler. The output of the damper 16 is connected through a vacuum sensor 22 in the furnace 4 of the boiler and the vacuum regulator 23 with the actuator 24 - a rotary valve

installed in the chimney 25 of the furnace 4. The output of the damper 17 is connected to the indicating vacuum device 26 in the furnace 4 of the boiler. The output of the damper 18 through the signaling vacuum device 27 is connected to the first 28. 1 signal input of the block 28 technological protection and alarm. The second 28.2 signal input of block 28 is connected to the output of the torch control device 29 of the burner 31 of boiler 4. The third 28.3 signal input of block 28 is connected via the air pressure sensor 32 to the output of the damper 19 installed at the output of the pulse line 10. The fourth 28.4 signal input of block 28 is connected with the output of the pressure sensor 33 in the pipe 6 for supplying fuel to the burner 31 of the furnace 4. The first 28.6 output of the block 28 is connected to the control input of the safety shut-off (shut-off) valve 34 installed on the pipe 6 for supplying fuel to the burner 31 of the furnace 4 of the boiler. The second 28.7 output of block 28 is connected to the input of the sound alarm device 35. The valve device 35 for controlling the air supply to the burner 31 installed on the pipeline 5 is connected to the outputs of the air-fuel ratio sensor 37 with the outputs of the air pressure sensor 37 and the fuel pressure sensor 38 through the control input. The air pressure sensor 37 is installed at the output of the damper 21, and the fuel pressure sensor 38 is at the output of the pulse line 13. The damper 20 installed in the pulse line 11 is connected at the output to the indicating device 39 of the air pressure in the air supply pipe 5 to the burner 31 of the furnace 4. At the output of the pulse line 11, a showing device 40 of air pressure is installed in the pipeline 6 for supplying fuel to the burner 31 of the furnace 4. Dampers 16 ÷ 21 for smoothing the pulsations of the medium flowing through them are made in the form of a container of variable volume from an elastic material, in the form of pipes s with automatically changing passage section and / or in the form of a noise suppressor - pipes with double walls and resonant chambers connected by calibration holes. The elastic material of the tank of variable volume of dampers 16 ÷ 21 is made of spring brass or rubber. Damper pipe 16 ÷ 21 s

automatically changing passage section is equipped with internal spring-loaded partitions. The silencers of the dampers 16 ÷ 21 are made with a band of the absorption spectrum that covers the region of high-frequency oscillations of the medium flowing through the damper. The design of the system for automatic regulation, control, technological protection and alarm of the boiler unit is not limited to the above example of its implementation. Within the framework of this utility model, its other execution is possible without going beyond the scope of this description. In particular, the number of dampers 16 ÷ 21 in the system can be reduced. For an example of the design of the system shown in Fig. 1, the number of dampers 16 ÷ 21 can be reduced from six to two units when installing one damper, for example 16, on a common pipeline 40 of impulse lines 7-9 and one damper, for example 119, on a common pipeline 41 impulse lines 10 ÷ 12. However, damping quality and system reliability may be somewhat impaired. That is, in each control loop (according to the discharge in the furnace 4 and the air pressure at the inlet of the furnace 4), it is desirable to use at least one damper.

The system of automatic regulation, control, technological protection and alarm boiler operates as follows. When the air pressure exceeds the dead zone Δ of the ratio controller 36, a signal is generated at the output of the latter, which causes the actuator 34 to operate in the direction that restores the violated fuel-air ratio. Random short-term fluctuations in air pressure, which do not require regulatory influences, are suppressed (smoothed) by a variable-volume damper 21, which eliminates unreasonable, excessive operation of the ratio controller 36 and, accordingly, activation of the actuator 34. The automatic pressure control circuit in the furnace 4 of the boiler functions in the same way. Block 28 technological protection and alarm, not responding to

short-term random fluctuations in the values of the monitored parameters, which are smoothed out by dampers 23 and 32, are triggered in the event of the appearance of stable, systematic deviations from their limit (emergency) values, generating output signals that lead to the inclusion of an audible alarm device 35 and through a safety shut-off (shut-off) valve 34 - to the cessation of fuel supply to the furnace 4 of the boiler.

The proposed system of automatic regulation, control, technological protection and alarm of the boiler unit has been successfully tested at the Tver Center for Metrology and Standardization. The test results are presented in figure 2 ÷ 3. As the dampers 16–21 during the tests, we used membrane blocks of indicating measuring devices (weight gauges that had exhausted their life or had damage to the mechanical part of the measuring system), which, after minor modifications, were placed in a separate housing. At the same time, the additional costs for one control loop or channel for measurement and control did not exceed 1300 rubles. The greatest effect, from the point of view of increasing the reliability of automatic control of the fuel combustion process and technological protection (excluding cases of unjustified operation of the safety shut-off valve 34 and emergency shutdown of the boiler), was observed on boilers operating on liquid fuel (fuel oil).

Claims (5)

1. A system for automatic regulation, control, technological protection and alarm of the boiler unit, containing a rarefaction control circuit in the boiler furnace, consisting of a selectively connected device, an impulse line, a rarefaction sensor in the boiler furnace, a rarefaction regulator and an actuator installed in the boiler chimney, circuit regulating the fuel-air ratio, consisting of a series-connected selective device on the air supply pipe to the boiler furnace, whether pulse AI, an air pressure sensor, a ratio regulator and an actuator installed on the air supply pipe to the boiler furnace, connected in series to a select device on the fuel supply pipe to the boiler furnace, a pulse line, a fuel pressure sensor, the output of which is connected to the second input of the ratio controller, showing rarefaction devices in the boiler furnace, air pressure supplied to the boiler furnace, fuel pressure in the fuel supply pipe to the boiler furnace, connected via impulse lines appropriate selective devices, as well as warning vacuum devices in the boiler furnace, air pressure supplied to the boiler furnace, fuel pressure in the fuel supply pipe to the boiler furnace, connected via pulse lines to selected devices, a torch control device in the boiler furnace, technological protection unit and alarms, the inputs of which are connected to the outputs of signaling devices and the torch control device, and the outputs - to the inputs of the audible alarm device and the safety shut-off valve on the pipe a fuel supply to the boiler furnace, characterized in that it further comprises at least one damper installed in the impulse lines in front of the inputs of the vacuum sensor, showing and signaling the vacuum devices in the furnace of the boiler and at least one damper installed in the impulse lines in front of the pressure sensor inputs showing and signaling air pressure devices on the air supply pipe to the boiler furnace. 2. The system according to claim 1, characterized in that the damper is made in the form of a capacitance of variable volume from an elastic material, in the form of a pipe with an automatically changing passage section and / or in the form of a noise muffler - pipes with double walls and resonant chambers interconnected calibration holes. 3. The system according to claim 2, characterized in that the elastic material of the tank of variable volume of the damper is made of spring brass or rubber. 4. The system according to claim 2, characterized in that the damper pipe with automatically changing passage section is equipped with internal spring-loaded partitions. 5. The system according to claim 2, characterized in that the damper silencer is made with an absorption spectrum band that overlaps the region of high-frequency oscillations of the medium flowing through the damper.