SU958772A1 - Method of regulating torch parameters - Google Patents

Description

The invention relates to fire heat engineering, in particular, can be used in burner devices when controlling the parameters of the torch, gas flows.

A known method of controlling the direction of flow of a hot mixture at the exit of the burner in two planes by changing the angle of inclination of the movable elements with respect to the longitudinal and transverse axis of the burner [1].

The disadvantage of this Method is the inability to regulate · the direction of the swirling gas stream,

Closest to the proposed is a method of controlling the parameters of the torch by feeding into the periphery of the swirling stream of primary gas a controlled stream of secondary gas in the form of radial pairs of oncoming jets [2].

However, with the known method, efficient regulation of the flame parameters is not ensured due to the arbitrarily selected flow rates of the primary and secondary gas.

The purpose of the invention is the expansion of regulation ranges.

This goal is achieved by the fact that the regulation of the secondary gas flow is carried out by redistributing the costs in each pair of oncoming jets in the range of their ratios 0.5-2.0 and changing its total flow rate in the range 0.1-1.5 of the total primary gas flow .

. The drawing shows a burner device in which the proposed method is implemented.

The burner device comprises a housing 1, an air conduit 2 with a swirl 3, a top15 discharge pipe 4 is placed along the axis 4. housing 1 between the swirl 3 and the embrasure is made with through channels 5 and is equipped with an air supply pipe 6. Regulating bodies 7 are installed in the pipe 6. 20 The pipe b can be divided by a partition 8 into compartments with installation in each compartment of the regulatory body 7.

The regulatory process is as follows.

A primary swirling gas flow (air) is fed through the duct 2 in the housing, which flows into the working space in the form of a vortex flow symmetric with respect to the axis of the burner. To control the angle of deviation of the axis of the vortex flow from the axis of the burner, a secondary gas stream is supplied through the pipe 6, which flows in the housing 1 through the through channels 5. Using the regulating bodies 7, the necessary ratio of the flow rates 5 is established in each pair of oncoming radial jets within 0.5-2.0. The total * * · total flow rate of the secondary gas stream must be within O ', 1-1.5.

Leaving the total amount of the gas medium supplied to the device unchanged, the total flow rate of the secondary gas stream is changed, and also, by changing the ratio of the radial oncoming jets flow rates, the deflection of the vortex jet in any direction of the working volume is controlled by an angle reaching 20 *.

The ranges for adjusting the angle of inclination of the outgoing gas stream are determined by the nature of the distribution of the total pressure over the cross section of the burner body (channel). With respect to the total. The flow rate of the secondary gas flow to the flow rate of the first gas flow is less than 0.1, due to the insignificance of the annular zone of full pressure, it is displaced, and a pressure difference arises inside the channel on diametrically opposite sides, leading to radial overflows in a swirling flow. In this case, the effect of deviation of the gas stream is not observed.

With an increase in the flow ratio of more than 1.5, the resistance of the permeable wall of the casing increases for the passage of the secondary gas flow, while the vortex flow of the secondary gas increases, the effect of current deviation begins to decrease.

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If the indicated values of the flow ratio of a pair of radial oncoming jets are not observed, the annular flow zone is displaced; when the lehter, a pressure drop arises from diametrically opposite sides, causing radial flows in the swirling gas flow, which reduces the effect of the latter deflection.

Using the proposed method for controlling the parameters of the torch allows for simpler regulation without the use of complex mechanical elements in front of the burner embrasure, save the parameters 15 of the twist of the primary gas stream, and improve the completeness of fuel combustion. When using the method in steam generators, the range of load changes is expanded, and in metallurgical furnaces, metal heating is improved.

Claims (1)

Claim A method for controlling the parameters of a torch by supplying to the periphery of a swirling primary gas stream a controlled secondary gas stream in the form of radial pairs of oncoming jets, with the exception that, ^1, in order to expand the control range, regulating the secondary flow gas is carried out by redistributing the costs in each pair of oncoming jets in the range of their respective i ratios of 0.5-2.0 and changing its total flow rate in the range 0.1-1.5 of the total flow rate of the Primary gas. ''