CN112432202B

CN112432202B - Injection type fire detection air cooling device

Info

Publication number: CN112432202B
Application number: CN202011359335.4A
Authority: CN
Inventors: 马振方; 葛春雷; 刘虎; 杨伟辉; 李鹏; 程光达
Original assignee: Hangzhou E Energy Electric Power Technology Co Ltd
Current assignee: Hangzhou E Energy Electric Power Technology Co Ltd
Priority date: 2020-11-27
Filing date: 2020-11-27
Publication date: 2022-12-06
Anticipated expiration: 2040-11-27
Also published as: CN112432202A

Abstract

The invention discloses an injection type fire detection air cooling device. The ejector comprises a cold air flow channel, a hot primary air inlet pipe section, a tapered pipe section, a throat pipe section, a diffusion pipe section and a straight pipe section, wherein the tapered pipe section, the throat pipe section, the diffusion pipe section and the straight pipe section are sequentially connected into a whole; one end of the cold air flow channel is connected with the fire detection probe, the other end of the cold air flow channel enters the tapered pipe section and extends to the throat pipe section, and an annular hot air channel is formed among the cold air flow channel, the tapered pipe section and the throat pipe section; an air filter screen and an electromagnetic valve are arranged on a cold air flow channel between the fire detection probe and the tapered pipe section. The invention utilizes the mode of hot primary air suction cold air to cool the fire detection probe, thereby avoiding that a large amount of cold air is directly blown into a combustion area to reduce the combustion efficiency of the combustor.

Description

Injection type fire detection air cooling device

Technical Field

The invention belongs to the field of boiler combustion monitoring, and relates to an injection type fire detection air cooling device.

Background

The flame detection system is an important component of a furnace safety monitoring system. Accurate timely fire detection signal direct relation is gone to the safety and stability operation of furnace and whole unit, and many thermal power plants still appear at present that the intensity is weak, the fire is examined the cooling untimely burning loss fire and is examined probe deposition scheduling problem is examined to the fire, causes the production accident, leads to great loss.

The traditional method generally adopts the fire to examine cooling blower cooling fire and examines the probe, and the fire is examined cooling blower basis and is installed on the steel framework, and when long-time operation, the vibration of fire is examined cooling blower and is grow gradually, seriously leads to even that the fire is examined cooling blower and breaks down, therefore more and more power plants begin to adopt cold wind to examine the probe and cool off.

When the fire detection probe is cooled by cold primary air, the outlet of the fire detection probe is over against the combustion area, and the temperature of the fire detection cooling air is lower, so that the fire detection probe is not beneficial to the combustion process.

Disclosure of Invention

In order to make up the defects of the prior art, the invention provides the injection type fire detection air cooling device, so that the combustion process of a boiler is optimized, and meanwhile, the fire detection probe is ensured to be cooled in time.

The technical scheme adopted by the invention is as follows: an injection type fire detection air cooling device comprises a fire detection probe, an air filter screen, an electromagnetic valve, an injector and a secondary air box;

the ejector comprises a cold air flow channel, a hot primary air inlet pipe section, a reducing pipe section, a throat pipe section, a diffusion pipe section and a straight pipe section, wherein the reducing pipe section, the throat pipe section, the diffusion pipe section and the straight pipe section are sequentially connected into a whole;

one end of the cold air flow channel is connected with the fire detection probe, the other end of the cold air flow channel enters the tapered pipe section and extends to the throat pipe section, and an annular hot air channel is formed among the cold air flow channel, the tapered pipe section and the throat pipe section; and an air filter screen and an electromagnetic valve are arranged on a cold air flow channel between the fire detection probe and the reducing pipe section.

When the invention is used, hot primary air is used as active air flow, the flow speed is accelerated when the hot primary air flows through the reducing pipe, a low-pressure area is formed at the cold air outlet, so that cold air is pumped into the throat pipe section through the air filter screen, and finally mixed air is sent into the hearth after being decelerated and pressurized through the diffusion pipe section.

The invention utilizes the mode of hot primary air suction cold air to cool the fire detection probe, thereby avoiding that a large amount of cold air is directly blown into a combustion area to reduce the combustion efficiency of the combustor.

As a supplement to the technical scheme, the fire detection probe is an external peeping type fire detection probe and is in threaded connection with the cold air flow channel.

As a supplement to the technical scheme, the air filter screen is cylindrical and covers the outer side of the cold air flow channel, cold air enters the cold air flow channel from the air filter screen, the air filter screen is made of melt-blown fabric, and the resistance is not more than 20Pa.

As a supplement to the technical scheme, when the hot primary air pressure reaches 5kpa, the electromagnetic valve is opened, the fire detection probe starts to work at the moment, and when the furnace is shut down, the electromagnetic valve is closed first, and then the hot primary air supply is stopped.

As a supplement to the technical scheme, the ejector ejects the cold air to the hot primary air active airflow with the ejection ratio of 0.2-0.5.

As a supplement to the above technical solution, the diameter of the primary hot air inlet pipe section is 100-140mm, the diameter of the inlet end of the tapered pipe section is 140-160mm, the diameter of the outlet end is equal to the diameter of the throat pipe section, and the ratio of the length of the tapered pipe section to the diameter of the inlet end thereof is greater than 2.

As a supplement to the technical scheme, the length of the throat section is 40-80mm, and the ratio of the diameter of the cold air flow channel to the diameter of the throat section is 1.2-1.

As a supplement to the technical scheme, one end of the diffusion pipe section is connected with the throat pipe section, the diameter of the diffusion pipe section is equal to that of the throat pipe section, the diameter of the other end of the diffusion pipe section is equal to that of the inlet end of the gradually-reduced pipe section, the diffusion pipe section extends into the secondary air box, the length of the diffusion pipe section is 300-800mm, and the outlet end of the diffusion pipe section is connected with the straight pipe section.

As a supplement to the technical scheme, hot primary air enters the fire detection cooling air main pipe from the hot primary air main pipe, and is distributed to each hot primary air inlet pipe section from the fire detection cooling air main pipe, and the diameter of the fire detection cooling air main pipe is 240-260mm.

As the supplement of the technical scheme, the fire detection cooling fan is adopted as a standby fan and connected to a fire detection cooling air main pipe. The fire detection cooling fan is used as a standby, and the auxiliary power is saved.

The invention has the following beneficial effects:

1. no movable parts are used in normal operation, and the service life is long.

2. And redundant hot primary air is used as cooling air for fire detection, so that the power consumption of a plant is saved.

3. The outlet area of the burner is prevented from being blown by a large amount of cold air, and the combustion process is facilitated.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the description of the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic structural view of an injection type fire detection air cooling device according to the present invention;

FIG. 2 isbase:Sub>A cross-sectional view taken along line A-A of the cold air screen of the present invention;

FIG. 3 is a cross-sectional view B-B of the eductor of the present invention;

in the figure, 1-fire detection probe, 2-air filter screen, 3-electromagnetic valve, 4-hot primary air inlet pipe section, 5-reducing pipe section, 6-secondary air box, 7-diffusion pipe section, 8-cold air flow channel, 9-cold air outlet, 10-throat pipe section and 11-hearth.

Detailed Description

The present invention will be described in detail below with reference to examples to provide those skilled in the art with a better understanding of the present invention, but the present invention is not limited to the following examples.

Unless otherwise defined, terms (including technical and scientific terms) used herein should be construed to have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. It will be further understood that terms used herein should be interpreted as having a meaning that is consistent with their meaning in the context of this specification and the relevant art, and should not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

Examples

The embodiment is an injection fire detection air cooling device, including fire detection probe 1, air screen 2, solenoid valve 3, ejector and secondary bellows 6, wherein fire detection probe 1 is the peep formula, and air screen 2 is the cylinder and arranges. The structure of the ejector comprises a cold air flow channel 8, a hot primary air inlet pipe section 4, a reducing pipe section 5, a throat pipe section 10, a diffusion pipe section 7 and a straight pipe section. The reducing pipe section 5, the throat pipe section 10, the diffusion pipe section 7 and the straight pipe section are sequentially connected into a whole, the throat pipe section 10 is located between the reducing pipe section 5 and the diffusion pipe section 7, the hot primary air inlet pipe section 4 is arranged on one side of the large end portion of the reducing pipe section 5, and the straight pipe section penetrates through the secondary air box 6 to enter the outlet of the hearth combustor.

When the invention is used, hot primary air is used as active air flow, the flow speed is accelerated when the hot primary air flows through the reducing pipe, a low-pressure area is formed at a cold air outlet, so that cold air is pumped into the throat pipe section through the air filter screen, and finally mixed air is sent into the hearth 11 after being decelerated and boosted through the diffusion pipe section.

The peep-type fire detection probe 1 is connected with the cold air flow channel 8 through threads.

One end of the cold air flow channel 8 is connected with the fire detection probe 1, the other end of the cold air flow channel extends into the tapered pipe section 5 and extends to the throat pipe section 10, and an annular hot air channel is formed between the cold air flow channel 8 and the tapered pipe section 5 and between the cold air flow channel and the throat pipe section 10.

An air screen 2 and a solenoid valve 3 are provided in a cold air flow path 8 between the fire detection probe 1 and the tapered pipe section 5. The cold air flow channel 8 has a diameter of 40-60mm and extends into the convergent section 5 at a distance of 10-20mm from the throat section 10.

The air screen 2 covers the outside of the cool air flow passage, from which the cool air can enter the cool air flow passage 8. And the material of the air filter screen 2 is melt-blown cloth, and the resistance is not more than 20Pa.

Hot primary air enters the fire detection cooling air main pipe from the hot primary air main pipe, and is distributed to each hot primary air inlet pipe section from the fire detection cooling air main pipe, and the diameter of the fire detection cooling air main pipe is 240-260mm. The fire detection cooling fan is used as a standby fan and can also be connected to a fire detection cooling air main pipe.

When the hot primary air pressure reaches 5kpa, the electromagnetic valve is allowed to be opened, the fire detection starts to work, and when the furnace is shut down, the electromagnetic valve is closed first, and then the supply of the hot primary air is stopped.

The ratio of the injected cold air to the active hot primary air flow is 0.2-0.5 due to the pressure fluctuation of the hot primary air: 1, and fluctuates between.

The diameter of the primary hot air inlet pipe section 4 is 100-140mm, the length of the tapered pipe section 5 is at least 2 times of the diameter of the inlet end of the tapered pipe section, in addition, the diameter of the inlet end of the tapered pipe section 5 is set to be 140-160mm, and the diameter of the outlet end of the tapered pipe section 5 is equal to the diameter of the throat pipe section 10.

The length of the throat section 10 is 40-80mm, and the ratio of the diameter of the cold air flow passage 8 to the diameter of the throat section 10 is 1.2-1.

One end of the diffusion pipe section 7 is connected with the throat section 10, the diameter of the diffusion pipe section is equal to that of the throat section 10, the diameter of the other end of the diffusion pipe section 7 is equal to that of the inlet end of the tapered pipe section 5, the diffusion pipe section extends into the secondary air box 6, and the length of the diffusion pipe section is 300-800mm. The outlet end of the diffuser section 7 is connected with the straight section.

Application example

When the invention is applied to a certain 660MW unit, the diameter of the hot primary air inlet pipe section 4 is set to be 120mm, the temperature of the hot primary air is 340 ℃, the pressure is 9.3kPa, the diameter of the inlet of the reducing pipe section 5 is set to be 160mm, and the diameter of the throat pipe section 10 is set to be 100mm.

The velocity of the hot primary air passing through the throat section is as high as 35m/s, creating a low pressure region at the cold air outlet 9. The cold air is sucked into the cold air flow channel 8 by the air filter screen 2 and flows out from the cold air outlet 9 to be mixed with the hot primary air, and the temperature of the mixed air is not lower than 280 ℃.

The device can ensure that the fire detection probe is at the ambient temperature of 25 ℃, the amount of cold air injected by each ejector is 0.08t/h, and the amount of consumed hot primary air is 0.23t/h. The 36 burners comprise 72 fire detection probes for oil fire detection and coal fire detection, and the total consumed primary hot air volume is 16.56t/h and accounts for 5.6 percent of the total hot primary air volume. When the 660MW unit is fully loaded, the total amount of the primary hot air is 294t/h, and the residual amount of the primary hot air is 10%, so that the air volume requirement of fire detection cooling can be met.

Claims

1. An injection type fire detection air cooling device is characterized by comprising a fire detection probe (1), an air filter screen (2), an electromagnetic valve (3), an injector and a secondary air box (6);

the ejector comprises a cold air flow channel (8), a hot primary air inlet pipe section (4), a reducing pipe section (5), a throat pipe section (10), a diffusion pipe section (7) and a straight pipe section, wherein the reducing pipe section (5), the throat pipe section (10), the diffusion pipe section (7) and the straight pipe section are sequentially connected into a whole, the throat pipe section (10) is positioned between the reducing pipe section (5) and the diffusion pipe section (7), the hot primary air inlet pipe section (4) is arranged on one side of the large end part of the reducing pipe section (5) and communicated with the large end part of the reducing pipe section (5), and the straight pipe section penetrates through a secondary air box (6) to enter the outlet of a hearth combustor;

one end of the cold air flow channel (8) is connected with the fire detection probe (1), the other end of the cold air flow channel enters the tapered pipe section (5) and extends to the throat pipe section (10), and an annular hot air channel is formed among the cold air flow channel (8), the tapered pipe section (5) and the throat pipe section (10); an air filter screen (2) and an electromagnetic valve (3) are arranged on a cold air flow channel between the fire detection probe and the tapered pipe section; the air filter screen (2) is coated outside the cold air flow channel (8), and cold air enters the cold air flow channel (8) from the outside.

2. The injection type fire detection air cooling device according to claim 1, wherein the fire detection probe (1) is an external peep type fire detection probe and is in threaded connection with the cold air flow passage (8).

3. The air cooling device for fire detection of the injection type according to claim 1 or 2, wherein the diameter of the cold air flow passage (8) is 40-60mm.

4. The air cooling device is characterized in that the air filter screen (2) is cylindrical, and the material of the air filter screen (2) is melt-blown cloth.

5. The injection type fire detection air cooling device as claimed in claim 1 or 2, wherein when the hot primary air pressure reaches 5kPa, the electromagnetic valve is opened, the fire detection probe starts to work, and when the furnace is shut down, the electromagnetic valve is closed first, and then the supply of the hot primary air is stopped.

6. The injection type fire detection air cooling device as claimed in claim 1 or 2, wherein the injection ratio of the injection cold air to the hot primary air active airflow of the injector is 0.2-0.5.

7. The injection type fire detection air cooling device as claimed in claim 1 or 2, wherein the diameter of the hot primary air inlet pipe section (4) is 100-140mm, the diameter of the inlet end of the tapered pipe section (5) is 140-160mm, the diameter of the outlet end is equal to the diameter of the throat pipe section (10), and the ratio of the length of the tapered pipe section (5) to the diameter of the inlet end is greater than 2.

8. The induction type fire detection air cooling device as claimed in claim 1 or 2, wherein the length of the throat section (10) is 40-80mm, and the ratio of the diameter of the cold air flow passage (8) to the diameter of the throat section (10) is 1.2-1.

9. The air cooling device for the induction type fire detection according to claim 1 or 2, wherein one end of the diffusion pipe section (7) is connected with the throat pipe section (10) and has the same diameter as the throat pipe section (10), the other end of the diffusion pipe section (7) has the same diameter as the inlet end of the tapered pipe section (5) and extends into the secondary air box (6) and has the length of 300-800mm, and the outlet end of the diffusion pipe section (7) is connected with the straight pipe section.

10. The injection type fire detection air cooling device as claimed in claim 1 or 2, wherein the primary hot air enters the primary fire detection cooling air main pipe from the primary hot air main pipe, and is distributed to each primary hot air inlet pipe section from the primary fire detection cooling air main pipe, and the diameter of the primary fire detection cooling air main pipe is 240-260mm.