RU51134U1 - CENTRIFUGAL FAN - Google Patents

Abstract

The utility model relates to fan building, in particular to centrifugal fans with a spiral housing of the “snail” type with low specific speed and a small number of blades bent backward. The technical result from the use of the claimed utility model is to increase the fan performance by increasing the parameters for the flow rate and the generated air flow pressure. The technical result is achieved due to the fact that the centrifugal fan consists of an impeller I with blades 2, with an inner diameter of 3 and an outer diameter of 4, rotating relative to axis 5. In this case, the wheel I is installed in a spiral case 6 of the "snail" type with inlet pipe 7 and an outlet pipe 8 A cone 9 is installed in the inner diameter hole of the wheel I, and its height / h / coincides with the axis of rotation 5 of the impeller and is equal to its width at the inlet pipe 7, and the diameter of the base of the cone / C / is 0.9-1, 0 of inner diameter RA 3 wheels. In addition, the width of the impeller / in ₂ / is 0.35-0.4 of the outer diameter of the impeller, not the output cut, and on the inlet pipe its width / in ₁ / is 0.55-0.6 of the outer diameter of the working the wheel.

Description

The utility model relates to fan building, in particular to centrifugal fans with a spiral housing of the "snail" type with low specific speed and a small number of blades bent back.

Known centrifugal fan containing a blade impeller mounted in a spiral casing / cm textbook for universities, M.P. Kalinushkin, Moscow, Higher School. 1987, p148 /.

The disadvantage of this design is the uneven distribution of air flow rates at the inlet and outlet nozzles, due to the presence of air turbulence at the inlet nozzle and the insufficient width of the impeller. Typical geometric parameters posledneo on the inlet pipe are as follows: width - ₁ -0.35 outer diameter of the wheel, and the outlet conduit width is 0.25 to ₂ from the outer diameter of the wheel. In addition, this design has unsatisfactory performance in noise, which limits their scope.

The closest in technical essence is the technical solution / cm. A.S. No. 773317, class F 04 D 17/08, 1980 /, comprising a rotor impeller installed in a spiral case with inlet and outlet nozzles equipped with concave valves.

In this design, due to the establishment of flaps in the nozzles, the problem of uniform distribution of high-speed air flow at the outlet nozzle is solved. However, the problem of the uniform distribution of high-speed air flow at the inlet nozzle due to the presence of turbulences in it, which leads to a decrease in pressure / pressure / air flow to the impeller, and

negatively affects the performance of the centrifugal fan.

The technical result from the use of the claimed utility model is to increase the fan performance by increasing the parameters of the flow rate and the created air flow pressure and ensuring an even distribution of air flow velocities both at the inlet pipe and at the fan outlet pipe.

The technical result is achieved due to the fact that the centrifugal fan contains a blade impeller installed in a spiral case with inlet and outlet nozzles, and a cone is installed in the inner diameter hole of the impeller, and its height coincides with the axis of rotation of the impeller and is equal to its width, and the diameter of the base of the cone is 0.9-1.0 of the inner diameter of the impeller, while the width of the impeller is 0.55-0.6 of the outer diameter of the impeller at the inlet pipe, and at the output pat ubke impeller width is from 0.35-0.4 outer diameter of the impeller.

The geometric parameters of the cone installed in the impeller and the geometric parameters of the width of the latter are determined experimentally and selected optimal to achieve the maximum effect.

The technical essence is illustrated by the drawing / presents a fan in a section schematically /.

The centrifugal fan consists of an impeller I with blades 2, with an inner diameter of 3 and an outer diameter of 4, rotating relative to axis 5. Moreover, the wheel I is installed in a spiral case 6 of the “snail” type with inlet pipe 7 and outlet pipe 8. Into the inner diametrical the hole of the wheel I is installed cone 9. and its height / h / coincides with the axis of rotation 5 of the working

wheel and equal to its width at the inlet pipe 7, and the diameter of the base of the cone / C / is 0.9-1.0 of the inner diameter of the 3 wheels. In addition, the width of the impeller / in ₁ / is 0.55-0.6 of the outer diameter of the impeller at the inlet pipe, and at the output pipe the width of ₂ impellers is 0.35-0.4 of the outer diameter of the impeller.

Centrifugal fan operates as follows. The air flow through the inlet pipe 7 falling onto the blades 2 of an increased width (in ₁ ) of the impeller I eliminates the turbulence and stall of the air stream at the edge of the wheel I, while the resistance of the inlet pipe 7 due to the cone 9 installed in the diametrical hole 3 decreases. in this way, a uniform distribution of air flow velocities is achieved in the inlet 7. A wider impeller with a width of / ₂ / on the outlet 8 provides greater head / pressure / air flow, and therefore greater production fan speed. Thus, the geometric parameters of the wheel together with the cone provide an increase in the parameters of flow and pressure of the air flow, while the created pressure increases by 1.2-1.4 times in comparison with the prototype, and the fan performance increases by 1.2-1.8 times in the zone of efficiency not lower than 0.9 of the maximum.

In addition, it should be noted that with a constant installed electric motor power (the last one is not shown in the drawing), a decrease in power consumption in I, I-I, 25 times is observed compared with the prototype, which leads to significant energy savings.

Claims (1)

A centrifugal fan containing a blade impeller installed in a spiral casing with inlet and outlet nozzles, characterized in that a cone is installed in the inner diameter hole of the impeller, and its height coincides with the axis of rotation of the impeller and is equal to its width, and the diameter of the base of the cone is 0.9-1.0 of the inner diameter of the impeller, while the width of the impeller is 0.55-0.6 of the outer diameter of the impeller at the inlet pipe, and at the output pipe the width of the impeller 0.35-0.4 leaves from the outer diameter of the impeller.