RU2215195C1 - Centrifugal fan - Google Patents

Abstract

FIELD: mechanical engineering; fans and ventilators. SUBSTANCE: invention relates to centrifugal fans and their intake devices. Proposed fan contains scroll housing 1, shaft 2, impeller 3 with blades 4 and cover disk 5, suction branch pipe 6 with cylindrical section 7, outlet branch pipe 8 equal to width L of housing 1, circulation clearance 11 between branch pipe 6 and disk 5, guide vane assembly made in form of plate 13 connected with surface 9 of branch pipe 6 in zone of maximum opening of housing. Width of housing 1 is L= (0.0-1.1)D, length of branch pipe 6 is L_in = (0,40...0,63)D, diameter at inlet into impeller 3 is D_in = (0,66...0,69)D, where D is diameter of impeller 3. Plate 13 brakes toroidal flow in chamber 10, thus forming stream in clearance 11 directed along surface 12 of disk 5. this increases zone of flow over disk 5 and blades 4 together with inlet leveled flow on section 7 without separation. EFFECT: enlarged range of flow coefficient φ and pressure coefficient φ. at large values of coefficient ψ. 6 cl, 4 dwg

Description

 The invention relates to the field of fan engineering, namely to centrifugal fans and their input devices.

 Centrifugal fans with a guiding apparatus at the entrance to the impeller are known in the art.

 In the description of the invention, "Centrifugal Fan", protected by RF patent 2135837, IPC F 04 D 17/08, priority 06.02.1998, [1], a centrifugal fan is presented, comprising a spiral casing, an impeller mounted thereon with backward curved blades and with a conical cover disk, a suction pipe with sections of a curved profile in a diametric section, the outer surface of which forms a circulation gap at the entrance to the impeller with a circulation gap, a guiding device placed on the outside us suction nozzle before the circulation gap outlet, equal in width of the fan housing.

A disadvantage of the known fan is the uneven flow at the entrance to the impeller, which leads to a loss of the pressure coefficient ψ = 2P / ρu ² for large values of the flow coefficient φ = 4Q / πD ² u (narrowing the working characteristic of the fan on the right), where Q is the fan flow rate, cube m / s; P - full or static pressure. Pa; D is the diameter of the impeller of the fan, m; u is the peripheral speed of the blades on the outer diameter of the fan impeller, m / s; ρ is the density of the pumped air, kg / cu. m

 In the description of the invention according to the application of Germany 4025006 A1, "Ventilatoreinheit", priority 07.08.1990, publication date 02.13.1992, [2] a fan is provided comprising a spiral case, an impeller mounted thereon with backward curved blades on the shaft and with a conical cover disk, a suction pipe with a cylindrical section and with an impeller diameter equal to 0.7 ... 0.9 of the diameter of the impeller, and sections of a curved profile in a diametric section, the outer surface of which forms with the inner surface of the cover disk at the entrance to Static preparation circulating wheel gap.

 The disadvantage of the invention [2] is the implementation of the outlet pipe with a width smaller than the width of the housing, and approximately equal to the width of the impeller, which leads to a decrease in the pressure coefficient ψ at lower flow coefficients φ in comparison with the invention [1].

 The invention [1] is taken as the closest analogue.

 The technical task to be solved is to ensure continuous flow around the cover disk and impeller blades at high flow rates φ of the fan. The technical result consists in expanding the working area of the fan in the direction of large flow coefficients φ, in comparison with the closest analogue [1], as well as reducing the difference between the total and static pressure, which reduces aerodynamic losses on the conversion of the high-speed head of the fan.

 The invention consists in the following.

The centrifugal fan, as in the closest analogue [1], contains a spiral casing, an impeller mounted on it on the shaft with backward curved blades and with a conical cover disk, a suction pipe with sections of a curved profile in a diametric section, the outer surface of which forms with the inner the surface of the cover disk at the entrance to the impeller, a circulation gap, a guide apparatus located on the outside of the suction pipe in front of the circulation gap, an output pipe equal in width not the fan casing, but in contrast to the closest analogue, the casing width L is 0.9 ... 1.1 of the impeller diameter D, the suction pipe contains a cylindrical section, the suction pipe L _BX is 0.40 ... 0.63 of the impeller diameter D, and the diameter of the input D _ВХ into the impeller is 0.66 ... 0.69 of the diameter D of the impeller, the guiding apparatus is made in the form of at least one plate, one of which is installed in the zone of the greatest opening of the spiral casing.

 A centrifugal fan is characterized in that at least one plate of the guide apparatus is made flat.

A centrifugal fan is characterized in that at least one plate of the guide apparatus is mounted on the outer surface of the inlet pipe radially and perpendicular to the cylindrical surface of the pipe along the axis of the impeller within an angle of 10 ^o relative to the axis of the impeller from the point of greatest opening of the spiral casing in the direction of decreasing spiral opening corps.

 A centrifugal fan is characterized in that the outer edge of at least one plate is in contact with the inlet pipe.

 The centrifugal fan is characterized in that the guide vane is made in the form of a single plate located in the zone of greatest opening of the spiral casing, and in the diametric section at an angle of 0 ... 45 degrees to the suction pipe with a countdown towards the direction of rotation of the impeller and at an angle of ± 10 degrees to the axis of rotation of the impeller.

A centrifugal fan is characterized in that the angle γ in the diametrical section between the generatrices of the conical part of the inner surface of the casing disk and the outer surface of the suction pipe from the entrance to the impeller is 0 ... 10 ^o .

 The presented features are essential for solving the task and achieving the claimed technical result, and form a set, with the exception of which one of the signs of the technical result is not achieved.

 Indeed, the implementation of a centrifugal fan containing, as in the closest analogue [1], a spiral casing, an impeller mounted on it on the shaft with backward curved blades and with a conical cover disk, a suction pipe with sections of a curved profile in a diametrical section, the outer surface of which forms a circulation gap with the inner surface of the casing disk at the entrance to the impeller, a guiding apparatus placed on the outside of the suction pipe in front of the circulation gap, the inlet nozzle, equal in width L to the fan casing, provides a fairly good pressure and speed characteristic of a fan known from the closest analogue. The increase in the width of the spiral casing and the outlet with the parameters proposed in the present invention leads, as shown in the graph in figure 4, to the displacement and expansion of the aerodynamic characteristics of the fan in the direction of higher flow coefficients compared to existing with the closest analogue [1], and to reduce the difference between the curves of the coefficients of full and static pressure, which is significantly useful when using a fan in ventilation systems, since it helps to reduce aerodynamics physical losses on the conversion of the fan speed head.

The above technical result is achieved due to the fact that when performing a centrifugal fan, in contrast to the closest analogue [1], with a suction pipe of length L _BX = 0.40 ... 0.63 of the diameter D of the impeller due to the inclusion of a cylindrical section with an inlet diameter D _BX in the impeller, equal to 0.66 ... 0.69 of the diameter D of the impeller, provides an increase in the uniformity of the flow entering the impeller, which delays the separation of the boundary layer from the surface of the casing disk and the impeller blades during its rotation. This makes it possible to increase the width of the housing L to 0.9. ..1.1 the diameter D of the impeller and provides, as shown in figure 4, an increase in the flow rates φ and pressure ψ compared with the closest analogue.

 The implementation of the guide apparatus of the centrifugal fan in the form of at least one plate, one of which is installed in the zone of the greatest opening of the spiral casing, reduces the thickness of the boundary layer on the cover disk of the impeller during its rotation, which allows to increase the width b of the impeller blades due to the delayed flow separation .

 The implementation of the guide apparatus in the form of at least one plate with an outer edge in contact with the surface of the inlet pipe prevents air from flowing between the plate and the inlet pipe, which helps to reduce the aerodynamic losses of the fan as a whole.

 The implementation of the guide apparatus in the form of one flat plate installed in the zone of the greatest opening of the spiral casing simplifies the manufacturing technology of the fan when the claimed technical result is achieved.

When you install one of the plates on the outer surface of the inlet pipe radially (perpendicular to the cylindrical surface of the pipe) along the axis of the impeller in the place of greatest opening of the spiral casing or within an angle of 10 ^o from this position in the direction of reducing the opening of the spiral casing (relative to the axis of the impeller) is optimal with point of view of aerodynamics. The height of the plate in the radial direction is limited by the diameter of the impeller.

The execution of the plate is flat, in a diametrical section located at an angle α = 0.. .45 ^o to the suction nozzle with a count towards the direction of rotation of the impeller and at an angle within β = ± 10 ^o to the axis of rotation of the impeller is optimal to reduce losses in the inlet nozzle, and reduces the requirements for the accuracy of installation of the plate.

The implementation of the angle in the diametrical section between the generatrices of the conical part of the inner surface of the casing disk and the outer surface of the suction pipe from the entrance to the impeller, equal to γ = 0 ... 10 ^o provides the formation and pressing of the jet leaving the area of high pressure from the outside of the casing disk to the inner surface of the cover disk, which also helps to reduce aerodynamic losses and increase the efficiency of the fan due to the reduction of the separation zone of the flow from the cover disk.

 The invention is illustrated by drawings.

 Figure 1 shows a longitudinal section of a fan.

 Figure 2 shows a section 1-1 in figure 1.

 Figure 3 shows a view of B in figure 1.

 In FIG. 4 shows a graph of the pressure coefficient versus flow coefficient ψ = f (φ) for the proposed fan and the closest analogue.

 Centrifugal fan is arranged as follows.

 The centrifugal fan contains a spiral housing 1 (Fig. 1, 2), an electric drive mounted on it on the shaft 2, for example, an electric motor (not shown in Fig.), An impeller 3, including blades 4 and a cover disk 5, a suction pipe 6 with a curved profile in a diametrical section and a cylindrical insert 7, and an outlet pipe 8 over the entire width of the housing 1 (Fig. 1). Between the outer surface 9 of the suction pipe 6, the cover disk 5 and the walls of the housing 1, a circulation chamber 10 is formed.

The output of the suction pipe 6 forms with a cover disk 5 at the entrance to the impeller 3 a circulation gap 11 formed by the inner surface 12 of the cover disk 5 and the outer surface 9 of the suction pipe 6. A guide device is arranged around the circumference on the outside of the suction pipe 6, which is made in the form several (not shown) plates. At the same time, at least one plate 13 is installed in the zone 14 of the greatest opening of the spiral casing 1 (figure 2) in the range of angles ± 25 ^o from the diametrical section with the greatest opening. The inner edge of at least one plate 13 is connected to the surface of the suction pipe 6. The plates 13 in diametric section can be installed at an angle α = 0. ..45 ^o to the suction pipe 6 with a count towards the direction of rotation of the impeller 3 (Fig.2 ) and at an angle within β = ± 10 ^o relative to the axis of rotation of the impeller 3 (Fig.3), and the outer edge of the plate 13 can be made both rectilinear and curvilinear.

The length L _{BX of the} suction pipe 6 is L _BX = (0.40 ... 0.63) D, the diameter D _{BX of the} suction pipe 6 at the entrance to the impeller 3 is D _BX = (0.66 ... 0.69) D. With the width b of the impeller 3 equal to b≥0.27D, the width L of the fan casing 1 will be L == (0.9 ... 1.1) D, where D is the diameter of the impeller 3.

In a preferred embodiment, the centrifugal fan inlet pipe 6 has a length L _BX = 0.5D, a cylindrical section 7 of the inlet section has a length L _CU = 0.6L _BX , the diameter of the suction pipe 6 at the entrance to the impeller 3 D _BX = 0.68D and the width of the housing 1 equal to the diameter of the impeller of the fan L = 1.0D. The guide apparatus contains one plate 13, which is made with a flat, outer edge in contact with the outer surface of the suction pipe 6 and with a height in radial section limited by the diameter of the impeller 3. The plate 13 is mounted radially (perpendicular to the cylindrical surface of the section 7 of the suction pipe 6) along the axis the impeller 3 at an angle of 0 ... 10 ^o from the cross section with the largest opening of the housing 1 in the direction of reducing the opening of the spiral housing 1, and at angles α = 0 ^o and β = 0 ^o . The angle γ between the generatrices of the conical part of the inner surface 12 of the cover disk 5 and the outer surface 9 of the suction pipe of a diametrical section from the entrance to the impeller 3 is γ = 0 ... 10 ^o .

 Centrifugal fan operates as follows.

 When the impeller 3 rotates, the flow passing through the inlet pipe 6 in the cylindrical section 7 becomes more uniform, which helps to tighten the separation of the boundary layer from the blades 3 and the cover disk 5 of the impeller 3. When the impeller 3 rotates due to the flow at the wheel outlet, Due to disk friction on the outer surface of the cover disk 5, a swirling toroidal flow occurs in the circulation chamber 10, which increases aerodynamic losses, which reduces the fan efficiency. The installation of a guiding apparatus containing at least one plate 13 converts the kinetic energy of the toroidal flow into the potential energy of the braking pressure of the toroidal flow. As a result of the pressure difference in the circulation chamber 10 and at the entrance to the impeller 3, an annular jet is blown onto the inner surface 12 of the casing disk 5 through the circulation gap 11, leading to a decrease in the separation zone of the flow from the inner surface 12 of the casing disk 5. The interaction formed in the circulation gap 11 a jet with a stream aligned in a cylindrical insert 7 provides a delay in flow separation, which is manifested, in comparison with the closest analogue [1], as shown in the graph in Fig. 4, in an increase in pazona flow coefficient φ values and increase the pressure coefficient ψ at high flow coefficient φ. In addition, with this embodiment of the fan, it is possible to increase the width b of the blades 4 of the impeller 3 to 0.42 of the diameter of the impeller, increase the length of the suction pipe and increase the width of the casing L to 0.9 ... 1.1D of the diameter of the impeller 3 with the width of the output pipe 8 equal to the width corps.

 Placing the plate 13 in the zone 14 of the greatest opening of the spiral casing provides the most effective braking of the toroidal flow and local increase in pressure in front of the circulation gap 11. As a result, the impulse of the jet formed in the circulation gap 11 increases, which creates additional rarefaction on the inner surface 12 of the cover disk 5, which prevents the formation of separation, and, therefore, reducing aerodynamic losses not only at the entrance to the impeller 3, but also the fan as a whole.

The implementation of the plate 13 with the outer edge in contact with the outer surface 9 of the suction pipe 6 and the location of the plate 13 along the generatrix in the diametrical section of the suction pipe 6 at an angle α opposite the direction of rotation of the impeller 3 ensures the manufacturability of the guide apparatus and the fan as a whole. Moreover, the angle α depends on the characteristics of the fan, and varies in the range α = 0 ... 45 ^o , and the contour of the outer edge is set depending on the parameters of the fan. The placement of the plate 13 at an angle within β = ± 10 ^o is due to a decrease in the requirements for the technology of connecting the plate 13 with the outer surface 9 of the suction pipe 6, and has little effect on the technical result.

When forming a circulation gap 11 with an angle γ in the diametrical section between the generatrices of the conical part of the inner surface 11 of the cover disk 5 and the outer surface 8 of the suction pipe 6 from the entrance to the impeller 3, equal to γ = 0 ... 10 ^o , conditions are created for creating high-speed jet, increasing the area of the inner surface 12 of the cover disk 5 with continuous flow around, which allows to increase the width of the blades 4 of the impeller 3.

 The centrifugal fan described in the description of the invention can be manufactured in any specialized enterprise. The implementation of the invention ensures the achievement of the claimed technical result. The parameters of the guide apparatus, made in the form of a plate 13, and the dimensions of the circulation gap 11 can be optimized depending on the operating conditions and characteristics of the fan.

Claims (6)

 1. A centrifugal fan, comprising a spiral casing, an impeller mounted thereon on a shaft with backward curved blades and with a conical cover disc, a suction pipe with sections of a curved profile in a diametric section, the outer surface of which forms with the inner surface of the cover disc at the entrance to the impeller circulation gap, a guide vane located on the outside of the suction pipe in front of the circulation gap, an output pipe equal in width to the fan casing The fact that the width of the body is 0.9. . . 1.1 of the diameter of the impeller, the suction pipe contains a cylindrical section, the length of the suction pipe is 0.40. . . 0.63 of the diameter of the impeller, the diameter of the entrance to the impeller is 0.66. . . 0.69 of the diameter of the impeller, the guiding apparatus is made in the form of at least one plate, one of which is installed in the zone of greatest opening of the spiral casing.  2. The centrifugal fan according to claim 1, characterized in that at least one plate of the guide apparatus is made flat. 3. The centrifugal fan according to claim 1 or 2, characterized in that at least one plate of the guide apparatus is installed on the outer surface of the inlet pipe radially and perpendicular to the cylindrical surface of the pipe along the axis of the impeller within an angle of 10 ^o relative to the axis of the impeller from places of the greatest opening of the spiral casing in the direction of reducing the opening of the spiral casing.  4. A centrifugal fan according to claim 1, 2, or 3, characterized in that the outer edge of at least one plate is in contact with the inlet pipe. 5. Centrifugal fan according to any one of paragraphs. 1-4, characterized in that the guide apparatus is made in the form of a single plate located in the zone of greatest disclosure of the spiral casing, and in a diametrical section at an angle of 0. . 45 ^o to the suction pipe with a countdown towards the direction of rotation of the impeller and at an angle of ± 10 ^o to the axis of rotation of the impeller. 6. Centrifugal fan according to any one of paragraphs. 1-5, characterized in that the angle in the diametrical section between the generatrices of the conical part of the inner surface of the casing disk and the outer surface of the suction pipe from the entrance to the impeller is 0.. . 10 ^o .

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