UA20915U - Centrifugal burner - Google Patents

Abstract

A centrifugal burner contains a cylindrical chamber with tangential input channel and a nozzle for discharge of liquid made of truncated cone connected with the cylinder, in this case the truncated cone is set first in the direction of motion of liquid discharge and connected with the cylinder by its smaller basis. The ratio of the area of basis of the cylinder of nozzle for discharge of liquid to the cross-sectional area of tangential input channel makes 2.4 ? 12.0 and it makes 0.15 ? 0.3 to the cross-sectional area of cylindrical chamber. The nozzle for discharge of liquid is connected with the additional truncated cone, larger basis of which is connected with cylindrical chamber, and smaller basis is connected with the larger basis of truncated cone of the nozzle for discharge of liquid. The generatrix of the surface of additional truncated cone makes the angle ? = 1 ? 25 DEGREE with horizontal axis of burner. Axially to the nozzle for discharge of liquid is located an air nozzle, which is made in the direction of motion of air from truncated cone, the internal surface of generatrix of which makes ? + 0 ? 60 DEGREE with vertical axis, which penetrates the centers of nozzles, andconnected with the cylinder connected with the second additional truncated cone. The angle between the surface of generatrix of which and horizontal axis of sprayer makes ? - 1 ? 25 DEGREE . The larger basis of the second additional truncated cone is connected with cylindrical chamber of burner.

Description

Description of the invention

A useful model relates to thermal power engineering, in particular nozzles for spraying and cooling liquid, and can be applied, for example, in cooling towers, as well as on other industrial facilities where spraying and cooling of water or other liquids is required.

A well-known centrifugal nozzle for cooling water | see A.S. USSR Mo1376326, MKV4 VO581/34, 1985|, containing a cylinder chamber with a tangential inlet channel, a nozzle, a sleeve with blades and a vane wheel, and the sleeve with vanes is mounted on a bearing, and the vane wheel is fixed in the hole of the sleeve. 70 The disadvantage of the known nozzle is the complexity of the design, which has a significant number of elements that create additional resistance to the formation of a droplet flow of liquid, such as a vane wheel, a sleeve with vanes, which leads to large losses of liquid speed and pressure.

The closest in terms of technical essence and the technical result achieved to the claimed useful model is a centrifugal nozzle for cooling a liquid containing a cylindrical chamber with a tangential 72 inlet channel and a nozzle for liquid outflow, on the end wall of which, located opposite the nozzle, is made an opening whose area is smaller than the area of the nozzle, the nozzle consists of a truncated cone connected to the cylinder, the cone being installed first in the direction of the liquid exit and connected to the cylinder by its smaller base, and the center of the nozzle is displaced relative to the axis passing through the center of the cylinder chamber. see OA patent

Mo13242, IPC VO581/34, Industrial property. Official bulletin Mo3, 2006 |.

The essential features of the closest analogue, which coincide with the essential features of the claimed utility model, are: a cylindrical chamber with a tangential inlet channel and a nozzle for the outflow of liquid, made of a truncated cone connected to the cylinder, the truncated cone being installed first in the flow of the liquid and connected to the cylinder by its smaller base.

The disadvantage of the nozzle is its sufficiently high resistance to the movement of liquid and air, which leads to large losses 29 of the speed and pressure of the liquid. what

This is explained by the fact that when the swirling flow of liquid exits the cylinder chamber into the nozzle located on the end wall, "stagnant" zones and boundary laminar flows are formed in the cylinder chamber, which creates a large resistance to the movement of liquid and air and leads to pressure and speed losses cooling liquid flow. at

This also leads to the fact that when the air flow enters the cylinder chamber, there is a loss of "-- the speed of the air flow, which reduces the air cavity and worsens the conditions of swirling and crushing of the liquid flow. Me.

The basis of the useful model is the task of improving the oddental nozzle by improving its design, namely: the implementation of a water nozzle composed of three elements, the equipment of the nozzle with an air nozzle, as well as providing the design with an optimal ratio of the areas of the inlet opening of the tangential inlet channel, the nozzle for outflow liquid and the cross-section of the cylinder chamber, which reduces the resistance to the movement of the liquid.

This provides a reduction in the loss of kinetic energy of the moving water, an improvement in the conditions for crushing the flow of liquid by the sucked air, an increase in its speed at the exit from the nozzle for the liquid to flow out, and a significant increase in the dispersity of the sprayed liquid flow. no) c The problem is solved by the fact that in a centrifugal nozzle containing a cylinder chamber c

I" by a tangential inlet channel and a nozzle for the outflow of liquid, made composed of a truncated cone connected to the cylinder, and with the truncated cone installed first in the flow of liquid and connected to the cylinder by its smaller base, according to a useful model, the ratio of the area of the base of the cylinder, the nozzle for liquid outflow to the cross-sectional area of the tangential inlet channel is 2.4-12.0, and to the cross-sectional area of the cylinder chamber is 0.15.0.3, while the liquid outflow nozzle is connected to (ав) an additional truncated cone, the larger base of which is connected to the cylinder chamber, and the smaller base is connected to the larger base of the truncated cone of the liquid outflow nozzle, and the generating surface of the additional truncated cone makes an angle of 4-1-:2592 with the horizontal axis of the nozzle, at the same time, the coaxial nozzle for the outflow of liquid is a located air nozzle, which is made in the direction of the air movement from a truncated cone, the inner surface of which is formed by Dr-0-:609 with ve vertical axis passing through the centers of the nozzles, and connected to the cylinder connected to the second additional truncated cone, the angle between the surface of which and the horizontal axis of the nozzle is y-1-:259, and the larger base of the second additional truncated cone connected to the cylinder chamber of the nozzle.

In addition, the ratio of the height of the truncated cone of the liquid outflow nozzle to the diameter of its smaller base c is 0.03-0.15, and the ratio of the height of the cylinder of the air nozzle to the height of the truncated cone of the air nozzle is 0.2-1.

The causal relationship between the essential features of the claimed invention and the technical result achieved is as follows.

Execution of a centrifugal nozzle with a ratio of the area of the nozzle for liquid outflow to the cross-sectional area of the tangential inlet channel equal to 2.4.12.0, and to the cross-sectional area of the cylinder chamber equal to 0.15-.0.3, ensures a balanced inflow to the nozzle and outflow from the nozzle of the cooled liquid, which in combination with the minimum resistance of the cylinder chamber to the movement of the liquid ensures minimal losses of its kinetic energy, i.e. the maximum speed of liquid outflow, which increases the fragmentation of the liquid flow and,

after all, its spraying.

When the ratio of the area of the nozzle for liquid outflow to the cross-sectional area of the tangential inlet channel equal to 2.4-12.0, the maximum rotational speed at the radius of the nozzle for liquid outflow is ensured, as a result of which the maximum use of kinetic energy for spraying the liquid is achieved, i.e. it is provided smaller spraying

When the ratio of the area of the nozzle for liquid outflow to the cross-sectional area of the tangential inlet channel is equal to or less than 2.4, the flow of water through the nozzle is unreasonably reduced, while the maximum rotational speed is created inside the liquid film, as a result of which there are losses of 70 creation of rotational speed, which is not used to break the flow of liquid into small drops and thereby deteriorates the quality of its spraying.

When the ratio of the area of the nozzle for liquid outflow to the cross-sectional area of the tangential inlet channel is greater than 12.0, the maximum rotational speed is reached before exiting the nozzle for liquid outflow, as a result of which the speed of liquid outflow from the nozzle is less than optimal, which also reduces the quality of spraying 75 liquid, decreases dispersion of the liquid flow, and therefore the intensity of its cooling.

Equipment for the discharge nozzle with an additional truncated cone, the larger base of which is connected to the cylinder chamber and the smaller base is connected to the large base of the truncated cone of the liquid discharge nozzle, and the generating surface of the additional truncated cone makes an angle of 5-1-259 with the horizontal axis of the nozzle, reduces the resistance to the movement of water at the outlet of the nozzle, the speed of the moving water at the outlet increases, the discharge in the central part of the nozzle increases and, accordingly, the suction of air increases, in addition, the resistance to the suctioned air from the outer and inner cavity of the nozzles decreases, which leads to increasing the speed of the cooled liquid and its better atomization.

When the ratio of the area of the nozzle for the end of the liquid to the cross-sectional area of the cylinder chamber is equal to 0.15-0.3, the kinetic energy of the atomized liquid flow is maximally used, the degree of swirling of the atomized liquid flow reaches the greatest value, at which the opening angle of the torch is reached, which provides its maximum surface, i.e., the surface area for the removal of steam from the drops increases and thereby intensifies their cooling.

If the ratio of the area of the nozzle for liquid outflow to the cross-sectional area of the cylinder chamber is less than 0.15 or more than 0.3, the opening angle of the torch does not ensure the necessary intensity of liquid cooling, and IF) also stable operation of the nozzle. -

Execution of the end walls of the cylinder chamber of the nozzle in the form of nozzles formed by additional truncated cones, connected to the nozzle for liquid outflow on one side and to the air nozzle on the other side, where Ge) the surface of the additional truncated cones makes an angle of 1-2592 with the horizontal axis nozzle, reduces the resistance to the movement of the liquid in the cylinder chamber, thereby increasing the rotational speed of the liquid flow, increases the discharge in the central part of the cylinder chamber of the nozzle, and accordingly, increases the suction of air, which increases the dispersion of the sprayed liquid flow.

At the same time, the taper of the additional cut cones of the air and water nozzles can be different, but within the limits specified above, that is, the additional cones can be asymmetrical, which is determined by the performance of the nozzle.

In addition, the movement resistance of the sucked-in air from the outer and inner sides of the nozzles is reduced, which leads to an increase in the speed of the cooled liquid and better atomization of it. y" When the angle between the horizontal axis of the nozzle and the forming surface of the second additional truncated cone of the air nozzle is equal to and less than 12, the maximum resistance to the movement of the rotating water is observed, and, accordingly, the minimum air suction is observed, and when the value of this angle is less than 252 , the resistance to the rotating water decreases and, accordingly, the discharge in the area of the nozzles increases and the amount of sucked air increases. o When the value of this angle is greater than 252, the productivity of drops increases), the discharge increases, (а) the amount of sucked air increases. The design of a nozzle for liquid outflow, in which the ratio of the height of the truncated cone of the liquid outflow nozzle to its smaller diameter is 0.03-0.15, reduces the loss of kinetic energy of the cooled liquid - 70 when it flows out of the nozzle, increases the area and opening angle of the torch spraying This range is optimal, since there is a deterioration of the nozzle performance beyond its limits.

The nozzle is equipped with an air nozzle consisting (in the direction of air movement) of a truncated cone, the inner surface of which is 0 609 with a vertical axis passing through the centers of the nozzles, connected to a cylinder connected to a second additional truncated cone, which has a minimum coefficient resistance, creates conditions under which the sucked air easily penetrates into the nozzle cavity. Mixing of liquid with air occurs in the cavity of the nozzle, i.e., the liquid flow begins to break down.

The angle between the inner surface of the truncated cone of the air nozzle and the vertical axis passing through the centers of the nozzles equal to 0-60 is optimal, because outside this range the pressure loss of the cooled liquid increases and, as a result, the atomization of the liquid deteriorates.

The ratio of the height of the cylinder of the air nozzle to the height of the truncated cone of the air nozzle, equal to 0.2-1.0, provides it with a minimum coefficient of resistance to the movement of the air flow.

The functional relationship of all elements of the nozzle and their parameters ensures the swirling of the liquid in it with minimal loss of kinetic energy along the entire trajectory of its movement inside the nozzle: from the inlet hole 65 of the tangential channel to the cut of the nozzle for the outflow of liquid, thus ensuring the maximum dispersion of the flow of the cooled liquid.

This set of essential features of the formula of the useful model provides the nozzle with a reduction in the resistance to the movement of the cooled liquid, increases the opening angle of the spray torch, increases the dispersion of the liquid flow, due to which its cooling capacity increases.

The inner diameter of the air nozzle is formed by the ratio of the diameters of the air nozzle and the nozzle for the outflow of liquid.

If these diameters are equal, the air nozzle works as a liquid discharge nozzle, that is, the nozzle forms two spray torches and works as a two-torch nozzle.

And if the diameter of the air nozzle is smaller than the diameter for the outflow of liquid, then the nozzle forms only one 7/0 spray torch.

Fig. 1 shows a centrifugal nozzle, a vertical section, and Fig. 2 shows a view along arrow A in Fig. 1, and Fig. 3 shows node 1 in Fig. 1.

The centrifugal nozzle contains a cylindrical chamber 1 with a tangential inlet channel 2 and a nozzle C for /5 Liquid outflow, the profile of which is formed by a truncated cone 4 connected to the cylinder 5, while the truncated cone 4 is installed first along the flow of liquid and connected to the cylinder 5 by its smaller basis

The nozzle C for the outflow of liquid is connected to an additional 6 truncated cone, the larger base of which is connected to the cylinder chamber 1, and the smaller base is connected to the larger base of the truncated cone 4 of the nozzle C for the outflow of liquid, and the generating surface 7 of the additional 6 truncated cone is an angle of 54-1 -:259 with a horizontal nozzle axis. An air nozzle 8 is located on the same vertical axis as the nozzle C for the flow of liquid, which consists (in the direction of air movement) of a truncated cone 9, the inner surface of which forms 10 D-0-609 with a vertical axis passing through the centers of the nozzles. The truncated cone 9 is connected to the cylinder 11, connected to the second additional truncated cone 12, the angle between the generating surface 13 of which and the horizontal axis of the nozzle is В-О--6059,

The larger base of the second additional cone 12 is connected to the cylinder chamber of the nozzle 1, while the ratio of the height of the cylinder 11 of the air nozzle 8 to the height of the truncated cone 9 of the air nozzle 8 is 0.2-1.

The Widcdent injector works like this.

The cooled liquid is fed through the fitting 14 under pressure into the tangential inlet channel 2 and further into the M space between the additional truncated cone 6 of the nozzle Z for liquid outflow and the second additional truncated cone - 12, which connects the cylinder chamber 1 of the nozzle with the air nozzle 8.

The mixed flows of liquid and air, combining into a common flow in the area of the location of the air nozzle 8, (o) create the maximum discharge for a given pressure of the liquid entering the nozzle, where through the air nozzle 8, o located on the same axis as the nozzle C for outflow of liquid, air enters, which, mixing with the liquid flow at the exit from the nozzle, creates a spray torch with maximum kinetic energy, transforms the sub-liquids of SM and air into a torch of optimal crushing of the liquid flow, creates an optimal surface of the sprayed water, and in turn, provides the maximum effect liquid cooling.

Claims (2)

"The formula of the invention sho - 1. Centrifugal nozzle containing a cylindrical chamber with a tangential inlet channel and a nozzle for liquid outflow, made of a truncated cone connected to the cylinder, while the truncated cone is installed first in the flow of liquid and connected to the cylinder by its smaller base, which is distinguished by the fact that the ratio of the area of the base of the cylinder of the nozzle for liquid outflow to the cross-sectional area of the tangential inlet channel is la to the cross-sectional area of 2.1 - 12.0 o A sh A A ' of the cylinder chamber is ; at the same time, the nozzle for outflow of liquid is connected to an additional one; 0.15-0.3 -l 20 truncated cone, the larger base of which is connected to the cylinder chamber, and the smaller base is connected to the larger base of the truncated cone of the nozzle for liquid outflow, and the generating surface of the additional truncated cone sl is the angle | two with the horizontal axis of the nozzle, while the air nozzle is located coaxially with the nozzle for the outflow of a -Z 1 liquid, which is made in the direction of air movement from a truncated cone, the inner surface 29 of which is created by o bo? with a vertical axis passing through the centers of the nozzles, and from d-o- connected to a cylinder connected to the second additional truncated cone, the angle between the surface of which and the horizontal axis of the nozzle is the larger base of the second additional truncated in 1- 25 cone is connected to the cylinder chamber of the nozzle. 2. The nozzle according to claim 1, which differs in that the ratio of the height of the truncated cone of the liquid outflow nozzle to the diameter of its smaller base is . 0.03-0.15 bo Z. Nozzle according to claim 1, which differs in that the ratio of the height of the cylinder of the air nozzle to the height