CN202453111U - Power station boiler water cooled wall fire side wall temperature on-line monitoring system - Google Patents

Abstract

The utility model belongs to the technical field of water cooled wall temperature on-line monitoring, and particularly relates to a power station boiler water cooled wall fire side wall temperature on-line monitoring system. An acoustic wave transceiving system consisting of an acoustic wave guide pipe, a power-driven loudspeaker and a specially-made electret-type microphone is installed on the cross section of a hearth, and a transceiving measuring point is configured on a heated surface at the same side of a water cooled wall; the power-driven loudspeaker sends signals, at the same time, the signals are received by an enhancement-mode microphone and are converted into voltage signals; after the voltage signals are input into a signal conditioner by a cable, the voltage signals enter a data collecting card and are converted into digital signals; the flying time is obtained again through generalized mutual correlation time delay estimation; and finally, the water cooled wall fire side wall surface temperature is calculated through a computer and software. The system is not restricted by severe environments of high temperature in the furnace, corrosion, multi-dust and the like, the water cooled wall fire side wall surface temperature is reflected truly, the booster phenomenon is prevented from occurring, the accident rate is reduced, and the operation cost is lowered.

Description

The water-cooling wall of power boiler sidewall temperature on-line monitoring system that warms oneself in front of a fire

Technical field

The utility model belongs to water-cooling wall on-line temperature monitoring technical field, particularly a kind of water-cooling wall of power boiler sidewall temperature on-line monitoring system that warms oneself in front of a fire.

Background technology

At present, the measuring method of water-cooling wall of power boiler temperature is a lot, generally mainly contains dual mode: the side pipe wall temperature of waring oneself in front of a fire is measured in (1), and the back-fire side pipe surface temperature is measured in (2).

The measurement side pipe wall temperature of waring oneself in front of a fire is in stove, to warm oneself in front of a fire the thermocouple measurement end is installed on the side pipe wall, and then imposes technology such as spraying coverings, can improve the correctness of wall temperature measurement like this, and the while can prolong the serviceable life of thermopair.But thermopair receives the influence of mal-conditions such as furnace high-temperature, the many dirt of burn into all the time, and serviceable life is short, generally is no more than one month.

Measuring the back-fire side pipe surface temperature is that the thermocouple measurement end is installed on the stove outer tube wall.Than being easier to, and operation life is long on this methods engineering, and cost is lower.But what measure is the back-fire side tube wall temperature, is not the side pipe wall temperature of waring oneself in front of a fire.Need just can extrapolate the side towards the fire pipe surface temperature through Theoretical Calculation, its data validity is affected.

Side joint receives the burner hearth hyperthermia radiation more than 1200 ℃ because water-cooling wall warms oneself in front of a fire; And the interior flow media temperature of pipe is generally at 320～380 ℃; The pipe surface temperature graded is very big, and the temperature difference of the side of waring oneself in front of a fire and back-fire side tube wall will have about 100 ℃, so point position is chosen particularly important.Though above-mentioned first method is measured the sidewall temperature of waring oneself in front of a fire, serviceable life is short; And second method is measured is back-fire side, can not truly reflect the sidewall temperature of waring oneself in front of a fire in the stove.Therefore, it is just very necessary to develop new water-cooling wall wall temperature monitoring method.

Summary of the invention

Not high in order to overcome existing water-cooling wall wall temperature on-Line Monitor Device precision, can not adapt to the deficiency of rugged surroundings such as high temperature, the many dirt of burn into, the utility model provides a kind of water-cooling wall of power boiler sidewall temperature on-line monitoring system that warms oneself in front of a fire.

The utility model solves the technical scheme that its technical matters takes: the water-cooling wall that two groups of sound wave transceivers of being made up of acoustic waveguide tube, dynamic loudspeaker and electret formula microphone are arranged in burner hearth one side warms oneself in front of a fire on the same aspect of side heating surface; Said dynamic loudspeaker is connected to power amplifier, and power amplifier is connected with the terminal box output terminal; Special electret formula microphone is connected to signal conditioner, and signal conditioner is connected with the input end of terminal box; Terminal box through with the double channel data acquisition card connection, double channel data acquisition links receives industrial computer, forms a cover wall temperature on-line monitoring system.

The utility model also provides a kind of simultaneously and has used said monitoring system that the water-cooling wall of power boiler sidewall temperature of waring oneself in front of a fire is carried out the method for on-line monitoring, is specially:

Acoustic signals is sent by one group of sonic generator, and another group sound wave receiving trap that is disposed in same wall receives, and flies over the time through measurement of sound, confirms the average velocity of sound wave on travel path:

$c=\frac{L}{\mathrm{\τ}}=\sqrt{\frac{\mathrm{\γR}}{m}(t+273.15)}=Z\sqrt{t+273.15}$

In the formula: τ is the time of flying over; L is the measuring point distance; C is the velocity of propagation of sound wave in the medium; R is the ideal gas universal constant; T is a gas temperature; γ is the adiabatic exponent of gas; M is a molecular weight gas;

is a constant; Wherein, sound-source signal is the swept-frequency signal of frequency sweep cycle 0.1S, frequency range 500-3000Hz;

Draw the temperature computation formula by following formula:

The beneficial effect of the utility model is:

Utilize the variation of sound wave velocity of propagation in the burner hearth flue gas, calculate the height of the adherent flue-gas temperature of burner hearth,, measure the water-cooling wall adherent temperature of side of waring oneself in front of a fire then through heat balance principle.The utility model does not receive the restriction of rugged surroundings such as furnace high-temperature, the many dirt of burn into, truly reflects temperature in the stove, avoids the generation of booster phenomenon, reduces accident rate, has reduced operation cost.

Description of drawings

Fig. 1 a and Fig. 1 b are water-cooling wall wall temperature monitoring device synoptic diagram.

Fig. 2 is a furnace wall cooling wall temperature on-Line Monitor Device arrangenent diagram.

Fig. 3 is a water-cooling wall wall temperature on-line monitoring measuring point synoptic diagram.

Label among the figure:

10-sound wave transceiver; The 11-industrial computer; The 12-data collecting card; The 13-terminal box; The 14-power amplifier; The 15-dynamic loudspeaker; The 16-acoustic waveguide tube; 17-electret formula microphone; The 18-signal conditioner; The 19-boiler furnace; The 21-water-cooling wall; 22-water-cooling wall wall temperature on-line monitoring layer; 33-water-cooling wall wall.

Embodiment

The utility model provides a kind of water-cooling wall of power boiler sidewall temperature on-line monitoring system that warms oneself in front of a fire, and below in conjunction with accompanying drawing and embodiment the utility model is described further.

Fig. 1 a and Fig. 1 b are water-cooling wall wall temperature monitoring system figure.The water-cooling wall that two groups of sound wave transceivers 10 of being made up of acoustic waveguide tube 16, dynamic loudspeaker 15 and electret formula microphone 17 are arranged in burner hearth one side warms oneself in front of a fire on the same aspect of side heating surface.Dynamic loudspeaker 15 is connected to power amplifier 14, and power amplifier 14 is connected with terminal box 13 output terminals; Special electret formula microphone 17 is connected to signal conditioner 18, and signal conditioner 18 is connected with the input end of terminal box 13; Terminal box 13 is through being connected with double channel data acquisition card 12, and double channel data acquisition card 12 is connected to industrial computer 11, forms a cover wall temperature monitoring system.

Fig. 2 is a furnace wall cooling wall temperature on-Line Monitor Device arrangenent diagram.The furnace wall cooling sound wave transceiver 10 that acoustic waveguide tube 16, dynamic loudspeaker 15 and electret formula microphone 17 in the sidewall temperature on-Line Monitor Device formed that warms oneself in front of a fire, its transmitting-receiving measuring point are arranged on the heating surface of water-cooling wall 21 1 sides of water-cooling wall wall temperature on-line monitoring layer 22.

Fig. 3 is a water-cooling wall wall temperature on-line monitoring measuring point synoptic diagram.The sonic generator 31 that acoustic signals is arranged by water-cooling wall wall 33 sends, and the sound wave receiving trap 32 that is disposed in same wall measures, and through the fly over measurement of time of sound wave, can be used for confirming the average velocity of sound wave on travel path.Sound wave is propagated in flue gas, and the relation that can derive acoustic wave propagation velocity and temperature according to the equation of motion, wave equation and the equation of gas state of plane wave is following:

$c=\frac{L}{\mathrm{\τ}}=\sqrt{\frac{\mathrm{\γR}}{m}(t+273.15)}=Z\sqrt{t+273.15}$

In the formula: τ is the time of flying over, s; L is the measuring point distance, m; C is the velocity of propagation of sound wave in the medium, m/s; R is the ideal gas universal constant, J/molk; T is a gas temperature, ℃; γ is the adiabatic exponent (ratio of specific heat at constant pressure and specific heat at constant volume) of gas; M is a molecular weight gas, kg/mol.For given gaseous mixture; is a constant, so sound wave velocity of propagation therein depends on the temperature of gas.Draw the temperature computation formula by following formula:

$t={\left(\frac{L}{\mathrm{\τZ}}\right)}^2-273.15.$

The sound-source signal that the utility model adopted is the swept-frequency signal of frequency sweep cycle 0.1S, frequency range 500-3000Hz.

During said device work; Sonic generator produces signal; Detected by the sound wave receiving trap of the same side water-cooling wall wall 33 through acoustic waveguide tube 16; Convert acoustical signal into voltage signal, and through signal conditioner 18 filtering and amplification, the input end of process terminal box 13 is obtained by double channel data acquisition card 12; Software in the industrial computer 11 carries out cross-correlation analysis with the signal of two passages; Draw two acoustic transit times between the microphone; Owing to the fixed distance between two microphones and known; Calculate the velocity of propagation of sound wave between two microphones, obtain the furnace wall cooling wall temperature, provide temperature value at the software display window of computer.

Each wall, each aspect at boiler furnace all can be installed this equipment, to realize the wall temperature on-line monitoring to diverse location.

Claims (1)

1. water-cooling wall of power boiler sidewall temperature on-line monitoring system that warms oneself in front of a fire; It is characterized in that the water-cooling wall that two groups of sound wave transceivers (10) of being made up of acoustic waveguide tube (16), dynamic loudspeaker (15) and electret formula microphone (17) are arranged in burner hearth one side warms oneself in front of a fire on the same aspect of side heating surface; Said dynamic loudspeaker (15) is connected to power amplifier (14), and power amplifier (14) is connected with terminal box (13) output terminal; Special electret formula microphone (17) is connected to signal conditioner (18), and signal conditioner (18) is connected with the input end of terminal box (13); Terminal box (13) is through being connected with double channel data acquisition card (12), and double channel data acquisition card (12) is connected to industrial computer (11), forms a cover wall temperature on-line monitoring system.

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