SU1368570A1 - Injection-type gas burner - Google Patents

Abstract

Invention m. used in heating and smelting glass furnaces. The purpose of the invention is the extension of the range of adjustment of the parameters of the torch. The shell 7 is placed in the cavity of the cylindrical mixer 1, the inside diameter D of the cut is 0.7-0.85 of the diameter D, the output slice is the central nozzle nozzle 2. At the inlet of the gas supply nozzle 4, the center nozzle 8 is axially displaced the diameter d to-ry is 0.7-0.9 of the inner diameter of the nozzle 4. The nozzles 2 are also mounted for axial displacement, which ensures the control of the length and luminosity of the torch. 1 il. with

Description

The invention relates to burners for burning gaseous fuels and can be used in heating and smelting, for example, glass melting furnaces.

The purpose of the invention is the expansion of the range of regulation of the parameters of the torch.

The drawing shows a burner, th longitudinal section.

The burner contains a cylindrical mixer 1, located in front of the central nozzle nozzle 2 and in communication with the gas line 3 coaxial with the mixer 1, the gas supply pipe 4, and with the environment - holes 5 made in the side wall 6 of the mixer 1. Inside the mixer 1 is coaxially placed with it shell 20

7. Nozzles 2 mounted with the possibility of axial movement. In the drawing, nozzles 2 are shown in the extreme right position. In front of the pipe 4, coaxially with the last and with the possibility of axial movement 25, a central nozzle 8 connected with the gas pipeline 3 with holes 9 in its side wall is installed. In the drawing, the nozzle 8 is shown in the extreme left position. Axial movement 30 of the nozzle 8 is carried out by a thrust 10.

The burner operates as follows. .

Natural gas is supplied through gas line 3 to nozzle 4, and also through _3ί) openings 9 to nozzle 8. Gas flowing out of nozzle 4 at high speed into mixer 1 creates a lower pressure in the latter with respect to the environment and, therefore, injects air mixing with it. The amount of air injected under otherwise equal conditions is dependent on the speed of gas flowing from the nozzle 4 into the mixer 1, displacement _4E Niemi nozzle 8 to the rightmost position close tem.samym pipe 4 and due to the smaller diameter of the nozzle 8 is increased velocity of gas flowing into the mixer 1 and the number of ing- _{() of the} air injected into it. Thus, the length and luminosity of the torch are regulated. The latter are also regulated by changing the initial diameter of the gas-air jet g, at the nozzle section 2 by axial movement of the latter.

In the extreme right position of the nozzle 2, the diameter of the jet is equal to the diameter D of the nozzle of the latter. Moving the nozzle 2 to the left (with respect to the depicted position in the drawing) reduces the initial diameter of the jet. Accordingly, the length of the torch decreases and its luminosity decreases. In the extreme left position of the nozzle 2, the initial diameter of the jet is equal to the diameter D of the shell 7, i.e. takes the smallest value. In this case, the length of the torch and its luminosity are also minimal.

The specified ratio of the diameters of the shell 7 and the nozzle nozzle 2 is optimal for the following reasons. When the value of this ratio is less than 0.7, a further decrease in the length of the flame occurs and a sharp increase in the velocity of the jet expiration, which is practically not accompanied by a decrease in the temperature of the combustion products of the fuel. The high speed of the torch negatively affects the operation of the furnace, since as a result the ablation of the charge increases, the masonry of the furnace is destroyed more intensively. An increase in diameter ratio is greater. 0.85 is practically not accompanied by an increase in the length of the torch, but leads to an increase in the temperature of the combustion products of the fuel. The ratio of the diameters of the nozzle 8 and the nozzle 4 is taken equal to 0.75-0.9 based on the condition of providing approximately the same injection coefficient with a decrease in gas flow.

The design of the burner with the lower values of the ratio of the diameters of the shell 7 and the nozzle nozzle 2, as well as the central nozzle 8 of the nozzle 4, respectively 0.7 and 0.7, makes it possible to form a torch with the smallest length and low luminosity, i.e., to create a torch for the most intense short-flare gas burning, The gas pressure in front of the burner is maximum and its margin for adjusting the gas flow is minimal.

Execution of the burner with the upper values of the above ratios of the diameters of 0.85 and 0.90, respectively, results in the formation of long the Optional ¹ Cel with sufficiently high levels of luminance, the gas pressure upstream of the burner is small and the stock it is sufficient to change the gas flow rate within wide limits. Range of regulation of the torch length at a small (or predetermined) flow rate due to the small position of the nozzle position).

»The gas is insufficiently influenced by the change (look at its edge-

Claims (1)

Claim Injection gas burner containing a cylindrical mixer with a gas supply pipe at the inlet end and nozzle nozzle at the outlet, characterized in that, in order to expand the range 1368570. for controlling the torch parameters, the burner additionally contains a shell with an inner diameter D = (0.70.85) D ₍ located in the cavity of the mixer, and a central nozzle with an outlet diameter d = (O, 7-O, 9) d, installed on the entrance to the gas supply pipe with the possibility of axial movement, where D <is the diameter of the outlet cut of the nozzle, d ₍ is the inner diameter of the gas supply pipe, and the nozzle is also installed with the possibility of axial movement.