RU54112U1 - RADIAL FAN - Google Patents

Abstract

Application: radial fans in a spiral case. Effect: increased efficiency and aerodynamic characteristics of the fan. The fan comprises a spiral casing 1, an impeller 2 with blades 8 and a cover disk 7, an input manifold 4 with a cylindrical section 9, an output manifold 5 equal to the width L of the housing 1, an annular gap 11 between the curved outer surface 9 of the collector 4 and the inner surface of the disk 7 , the swirl plate 12, connected to the surface 9 of the collector 4 between the position of the maximum opening of the spiral section of the housing 1 in the direction of the tongue 14 in the range 0 ... 45 degrees. The width of the casing is L = (0.9 ... 1.1) D, the length of the pipe 4 - L _IN = (0.48 ... 0.63) D, the diameter at the entrance to the wheel 2 D _IN = (0.66 ... 0.69) D, where D is the diameter of the wheel 2. Plate 12 inhibits the toroidal flow in the chamber 10, which forms a jet in the gap 11, directed along the surface of the disk 5 and together with the flow entering the cylindrical section 17 increases the zone of continuous flow around the disk 7 and blades 8.

Description

The utility model relates to the field of fan engineering, namely, to radial fans in a spiral case and their input devices.

The prior art radial fans with a guide apparatus at the entrance to the impeller.

In the description of the invention, “Centrifugal fan”, protected by RF patent No. 2132970, IPC F 04 D 17/08, priority 01/21/1998, publication date 10/07/1999, [1], a radial fan is presented, containing a spiral case equipped with tongue, an impeller installed in the housing on the shaft with backward-curved blades and with a conical cover disc, an inlet manifold with sections of a curved profile in diametric section, the outer surface of which forms a circumferential gap with the inner surface of the cover disc at the inlet of the impeller, vortex an object made in the form of at least one plate located on the outside of the suction pipe in front of the circumferential gap in the zone of the greatest distance of the impeller from the spiral section of the casing, the outlet pipe is equal in width to the fan casing.

In the description of the invention, “Centrifugal fan”, protected by RF patent No. 2215195, IPC F 04 D 17/08, priority 04/27/2002, publication date 10/27/2003, [2] presents a radial fan containing a spiral casing installed in it on the shaft there is an impeller with backward curved blades and with a conical cover disc, an input manifold with sections of a curved profile in a diametrical section, the outer surface of which forms with the inner

the surface of the cover disk at the entrance to the impeller is a circumferential gap, a vortex suppressor made in the form of at least one plate placed on the outside of the suction pipe in front of the circumferential gap in the zone of the greatest distance of the impeller from the spiral section of the housing, the outlet pipe is equal in width the fan casing, and the width of the casing L is 0.9 ... 1.1 of the diameter D of the impeller, the inlet manifold contains a cylindrical section, the length of the suction pipe L _BX is 0.48 ... 0.63 of the diameter D of the impeller es, and the diameter of the input D _BX into the impeller is 0.66 ... 0.69 of the diameter D of the impeller. The invention [2] is taken as the closest analogue.

Placing the vortex suppressor plate in the inventions [1, 2] in the zone of the greatest distance of the impeller from the spiral section of the casing provides high aerodynamic characteristics of the fan, however, studies have shown the possibility of their improvement.

Solved technical problem is to increase the efficiency of the fan. The technical result consists in increasing the efficiency and pressure-flow characteristics of the fan in the area of its high performance.

Disclosure of a utility model.

The radial fan, as in the closest analogue [2], contains a spiral housing equipped with a tongue, an impeller installed in the housing on the shaft with backward curved blades and with a conical cover disk, an inlet manifold with sections of a curvilinear profile in the diametric section, the outer surface of which forms a circumferential gap with the inner surface of the casing disk at the entrance to the impeller, a vortex suppressor made in the form of at least one plate placed on the outside of the suction pipe in front of ruzhnym gap in the greatest area

the distance of the impeller from the spiral section of the casing, the outlet pipe, the width of which is equal to the width of the spiral casing, but in contrast to the closest analogue [2], the indicated vortex suppressor plate is located between the planes passing through the axis of rotation of the impeller, one of which crosses the line of the greatest opening section of the body, and the other is located at an angle of 45 degrees. towards the tongue of the spiral case.

The radial fan is characterized in that the casing width is 0.9 ... 1.1 of the diameter of the impeller, the inlet manifold contains a cylindrical section, the length of the inlet manifold is 0.48 ... 0.63 of the diameter of the impeller, and the diameter of the entrance to the impeller the wheel is 0.66 ... 0.69 of the diameter of the impeller.

The radial fan is characterized in that the outer edge of at least one vortex damper plate is in contact with the input manifold.

A radial fan is characterized in that at least one vortex suppressor plate in a diametrical section is located at an angle of ± 10 degrees. to the input manifold with a count from the radial direction towards the direction of rotation of the impeller, and at an angle of ± 10 degrees. to the plane passing through the axis of rotation of the impeller.

The radial fan is characterized in that at least one plate of the vortex suppressor is made flat.

The utility model is illustrated by drawings.

Figure 1 shows the fan when viewed from above.

Figure 2 shows a section aa in figure 1.

Figure 3 shows a section bB in figure 2.

Figure 4 shows the remote element In figure 3.

Figure 5 is a section GG in figure 1.

Figure 6 shows a view of D in figure 4.

7 shows a view of E in figure 4.

On Fig presents a graph of the pressure coefficient of the proposed fan from the location of the vortex plate.

Figure 9 presents a graph of the efficiency of the proposed fan from the location of the vortex suppressor plate.

Figure 10 presents a graph of the dependence of the pressure coefficient on the coefficient of performance of the known and proposed fans.

Radial fan is arranged as follows.

The radial fan contains a spiral casing 1 (Fig. 1, 2, 3), an impeller 2 installed in it, a shaft 3 of which is kinematically connected with an electric drive, for example, an electric motor (Fig. 3), an input manifold 4 with a curved profile in a diametrical section , and the output manifold 5 over the entire width of the housing 1 (Fig.1, 3). The impeller 2 includes a main 6 and a cover 7 disks and blades installed between them 8. Between the outer surface 9 of the inlet manifold 4, the cover disk 5 and the walls of the housing 1, a circulation chamber 10 is formed.

At the entrance to the impeller 2 between the outer surface of the cover disk 7 and the inner surface 9 of the input manifold 4, a circumferential gap 11 is formed (Figs. 3, 4). A circumference on the outside of the input manifold 4 is a vortex suppressor made in the form of at least one plate, for example, a plate 12 mounted in a sector between conventional planes passing through the axis of rotation of the impeller 2, while one of the planes intersects the line of greatest the disclosure of the spiral section of the housing 1, and the other is located at an angle of 45 degrees. towards the tongue 14 of the spiral casing 1 (in the coordinate system in Fig. 5, δ = 0 ...- 45 °). In this case, under the line

the greatest disclosure of the spiral section of the housing 1 is understood as the line connecting the walls 15 of the output manifold 5 with the spiral surface 16 of the housing 1.

The inner edge of the plate 12 is connected to the surface of the inlet manifold 4. The plate 12 in diametric section can be installed at an angle α = 0 ± 10 ° to the inlet 4 with a countdown towards the direction of rotation of the impeller 2 (Fig.6) and at an angle β = ± 10 ° relative to the axis of rotation 13 of the impeller 2 (Fig.7), and the outer edge of the plate 12 can be performed as rectilinear (Fig.4), and curvilinear (Fig. Not shown).

In a preferred embodiment of the radial fan, the vortex suppressor contains one flat plate 12, which is in contact with the outer surface of the suction pipe 4 and is installed at angles α = 0 ° and β = 0 °, the inlet manifold 4 is made with a cylindrical insert 17, the input manifold length L _BX 4 is 0.48 ... 0.63 of the diameter D of the impeller 2 (equal to the diameter of the circle described by the ends of the blades 8), the diameter D of the _{BX of the} suction pipe 4 at the entrance to the impeller 2 is 0.66 ... 0.69 of the diameter D impeller 2, width N of the working wheel 2 is equal to at least 0.25 of the diameter D of the impeller 2, the width L of the fan housing 1 is 0.9 ... 1.1 of the diameter D of the impeller 2: L _BX = (0.48 ... 0.63) D ; D _BX = (0.66 ... 0.69) D; H≥0.25D; L = (0.9 ... 1.1) D.

Radial fan operates as follows.

When the impeller 2 rotates due to the gaps between the blades 8 and the walls of the spiral casing 1, as well as the input manifold 4 and the rotating external surface of the cover disk 7, a swirling toroidal (vortex) flow occurs in the circulation chamber 10, which increases aerodynamic losses that reduce the efficiency of the fan. The installation of a vortex suppressor containing at least one plate 12 provides braking of the toroidal

(vortex) flow, which is accompanied by an increase in pressure in the circulation chamber 10. Due to the pressure difference in the circulation chamber 10 and at the entrance to the impeller 2 through the circumferential gap 11, an annular jet is blown onto the inner surface of the cover disk 7. As a result, the momentum of the jet formed in the circumferential gap 11 increases, which creates an additional vacuum on the inner surface of the cover disk 7, which reduces the vortex intensity and, therefore, reduces aerodynamic losses not only at the entrance to the impeller 2, but also the fan as a whole.

The implementation of the input manifold 4 with a length L _BX = (, 48 ... 0.63) D due to the cylindrical section 17 with the diameter of the entrance to the impeller 2 equal to D _BX = (0.66 ... 0.69) D provides an increase uniformity of the flow entering the impeller 2, which delays the separation of the boundary layer from the surface of the cover disk 7 and from the blades 8 of the impeller 2 during its rotation. As a result, it is possible to increase the width H of the blades 8 to 0.35 and above the diameter D of the impeller 2: H≥0.25 D. This makes it possible to increase the width L of the casing to L = (0.9 ... 1.1) D, as a result of which the dynamic flow pressure at the outlet of the output manifold 5 decreases and the static pressure of the fan increases.

Dependence of the coefficient of total pressure ψ = 2Р / ρu ² and the efficiency η _В (efficiency) of the fan at constant values of the coefficient of performance φ = 4Q / πD ² u (where Q is the fan capacity, P is the static pressure, D is the impeller diameter 2 fan, u is the peripheral speed of the ends of the blades 8 of the impeller 2 of the fan, ρ is the air density) from the installation site of the vortex suppressor plate 12 obtained in the experiments, is presented in Figs. 8 and 9, respectively. In accordance with the graphs in Figs. 8, 9 c range of angles δ is set the swirl plate 12 of the vortex suppressor from 0 ° to 45 ° in the direction of the tongue 14 (in the coordinate system shown in Fig. 5, the angle range is 0 ° ...- 45 °) there are maxima of the efficiency η _V and

total pressure coefficient ψ, and these maxima are achieved at different positions of the vortex suppressor plate 12. With an increase in the fan performance factor φ, the maxima become more pronounced, and as the distance from the maximum at the boundary of the indicated ranges increases, the intensity of the change in the coefficients ψ and η _{B of the} total pressure along the installation angle δ of the eddy suppressor decreases until the sign changes. This confirms the significance of the feature relating to the selected boundaries of the installation of the vortex suppressor. The comparison of the aerodynamic characteristics of fans with the same impellers, collectors, and housings, but with a different position of the eddy damper containing one plate 12, shown in Fig. 10, shows that when the plate 12 is installed at an angle δ = -22 ° corresponding to the zone with maximum values ψ and η _В , (the proposed RADIVEY fan) and the fan adopted as the closest analogue [2] (BP-5), have higher total pressure coefficients ψ for large values of the performance coefficient φ.

When performing plate 12 curved aerodynamic losses are less than when performing plate 12 flat. The installation angles of the curved plate 12 and the angle in the circumferential gap 11 should be optimized depending on the parameters and operating conditions of the fan. However, the coupling of the plate 12 with the outer surface 9 of the inlet manifold 4 has a complex spatial contour, which complicates the manufacturing technology of the guide apparatus of the centrifugal fan.

The implementation of the plate 12 flat with the outer edge in contact with the outer surface 9 of the suction pipe 4 and the location of the plate 12 along the generatrix in the diametrical section of the inlet manifold 4 at an angle α = ± 10 ° towards the direction of rotation of the impeller 2 provides manufacturability

vortex suppressor and fan as a whole. The placement of the plate 12 at an angle β = ± 10 ° is due to a decrease in the accuracy of the connection of the plate 12 with the outer surface 9 of the input manifold 4, and has little effect on the technical result.

The radial fan in the spiral case described in the description can be manufactured at any specialized enterprise. The implementation of the utility model ensures the achievement of the claimed technical result. The parameters of the vortex suppressor, made in the form of a plate 12, and the size of the circumferential gap 11 can be optimized depending on the operating conditions and characteristics of the fan.

LIST OF POSITIONS AND DESIGNATIONS FOR THE DESCRIPTION OF THE USEFUL MODEL “RADIAL FAN”

1 - spiral case;

2 - impeller;

3 - shaft drive, for example an electric motor;

4 - input collector;

5 - output collector;

6 - the main disk;

7 - cover disk;

8 - blades of the impeller 2;

9 - the outer surface of the inlet manifold 6;

10 - circulation chamber;

11 - circumferential clearance;

12 - vortex suppressor plate, installed in the zone of greatest opening of the housing 1;

13 - axis of rotation of the impeller 2;

14 - the language of the spiral casing;

15 - wall of the output manifold 5;

16 - spiral surface of the housing 1;

17 is a cylindrical section of the inlet manifold 4.

δ - installation plate 12 of the vortex suppressor;

α is the angle of inclination of the plate to the suction pipe 6 with a count towards the direction of rotation of the impeller 2;

β is the angle of inclination of the plate 12 to the axis 13 of rotation of the impeller 2;

L _IN - the length of the input manifold 4;

D is the diameter of the impeller 2;

D _IN - the diameter of the inlet manifold 4 at the entrance to the impeller 2;

H - the width of the impeller 2;

L is the width of the fan housing 1.

η _B - fan efficiency (Efficiency);

ψ = 2P / ρu ² - coefficient of total pressure of the fan;

φ = 4Q / πD ² u - fan performance coefficient;

Q - fan performance;

P - static pressure of the fan;

u is the peripheral speed of the ends of the blades 8 of the impeller 2 of the fan;

ρ is the density of air.

Claims (5)

1. A radial fan comprising a spiral casing, equipped with a tongue, an impeller mounted on the shaft of the impeller with backward curved blades and with a conical cover disc, an inlet manifold with sections of a curved profile in a diametrical section, the outer surface of which forms with the inner surface of the cover disc at the input in the impeller there is a circumferential gap, a vortex suppressor made in the form of at least one plate located on the outside of the suction pipe in front of the circumferential gap in the zone of greatest th opening of the spiral section of the housing, the outlet pipe, the width of which is equal to the width of the spiral housing, characterized in that the said vortex suppressor plate is located between the planes passing through the axis of rotation of the impeller, one of which crosses the line of maximum opening of the housing, and the other is located at an angle of 45 ° side of the tongue of the spiral casing. 2. The radial fan according to claim 1, characterized in that the housing width is 0.9 ... 1.1 of the diameter of the impeller, the inlet manifold contains a cylindrical section, the length of the inlet manifold is 0.48 ... 0.63 of the diameter of the working wheels, and the diameter of the entrance to the impeller is 0.66 ... 0.69 of the diameter of the impeller. 3. The radial fan according to claim 1 or 2, characterized in that the outer edge of the at least one plate is in contact with the input manifold. 4. The radial fan according to claim 1 or 2, characterized in that at least one vortex suppressor plate in diametric section is located at an angle of ± 10 ° to the inlet manifold, counting from the radial direction towards the direction of rotation of the impeller and at an angle of ± 10 ° to the plane passing through the axis of rotation of the impeller. 5. The radial fan according to claim 1 or 2, characterized in that at least one plate of the vortex suppressor is made flat.