DE1403081A1 - Impeller for radial fan or pump - Google Patents

Description

Impeller for centrifugal fan or pump. The design of the inlet nozzle according to the main patent with the resulting reduction in flow losses when the axial flow direction is deflected into the radial one gives the possibility, in addition to the reduction in gap and housing losses achieved by the Me inlet nozzle, also the To reduce impeller losses , # ( and therefore especially to achieve high fan efficiency with a simple design.

Centrifugal fans with efficiencies of up to approx. 85% are generally referred to as high-performance fans. It is also möglichp the Vlirkungsgrad down to the optimal reach of approximately 90% to erhöheng when particularly large volute applies and pays attention to a very careful preparation of the wheels CD, fluted smallest Laufradspaltg --- and smoothed welds an d painted surfaces. However, such a production is very expensive and only worthwhile with very high performances such as from Grubenlüfterny.

It is also known to have vortex losses prior to the manifold flow Impeller at the transition from the axial inlet direction to the radial impeller inlet to be reduced by accelerating the flow of the river, but you step into it Acceleration higher speeds and higher conversion losses in the Blade channel on.

It is also known to delay the inlet flow to the impeller, without the disadvantages mentioned, to achieve a considerable delay in the manifold flow before the impeller inlet and to achieve a low speed in the blade channel and thus to reduce the conversion losses in the impeller to such an extent that the fan -Efficiency levels of approx. 90% can be achieved.

The impeller losses arise in addition to the friction essentially. chen thereby. that the flow of the flow rate-es through the Blade channels and at the outlet is not uniform XI-and According to Bernoullil's equation, static pressure differences result in the channels, which adversely affect the energy conversion in the impeller.

These static pressure differences are proportionally dependent on the differences in the squares of the velocities of the conveying flow, so they become smaller, the lower the velocity in the blade channel. A channel with a large blade width is therefore favorable for energy conversion, but upper limits are set in this regard because when the axial flow direction is deflected into the radial direction, vortices occur in the manifold flow and detachments occur on the impeller cover disk.

The inlet nozzle according to the main patent accelerates the one entering Flow down to its smallest cross-section and creates a velocity field equal velocity vectors in this cross-section right up to the edge there. This is the prerequisite for this given the flow rate in the on it following part of the duck with her determined by the string and the height of the arrow generating circular arc diverges and evenly on all sides during the deflection and is very strongly delayed without significant losses.

This success can be achieved in blade channels of medium length, which is characterized essentially by the ratio of the inlet diameter d i of the impeller to the outlet diameter d2 (d i / d 2).

The limits of the length of the vane duct are given by the fact that with longer vane ducts (d 1 / d2 --- o? 45) the absolute exit velocity is greater than that of the casing flow rotating between casing wall and impeller cover disk around the inlet nozzle and a Carnot when the casing flow occurs 's shock loss causes the large housing losses result. Greater gap losses also occur due to the higher pressure jump in the impeller. With shorter blades (d 1 '/ d 2' :::: _ o 963), on the other hand, the exit angle becomes the absolute exit speed, and thus the difference between this angle and that of the rotier% - # nden "7># o-, rosszl that through shear forces a rolling up - -, - # I U t: ' - of the housing current and thus large housing losses are caused.

According to what has been said, the invention relates to a radial fan or Pu # ipe with an inlet nozzle according to the main patent and with an impeller with non-profiled blades, the inlet diameter d i of which, in relation to the outlet diameter d, is between 0.45 and 0.63 (0 , 45 "#d ' - o, 63) 2 1 / d2: 5 and is characterized by the fact that the ring cross-section F 1 in the blade inlet of the impeller 2114 is up to 3 times as large as the smallest circular cross-section F 0 of the. Inlet nozzle (2,4 # - # Fi / FO 3) e and - that the blade angle β from the blade inlet to the blade outlet is greater than 23 0 and less than 27 0 (23 0 #: - 27 0) Drawing explained.

Fig. 1 shows the impeller and the inlet nozzle in cross section.

Fig. 2 shows the triangle of the velocity vectors at the impeller inlet in a meridional plane and in a normal axial plane the vector of the entry speed in the smallest nozzle cross-section.

Fig. 1 shows the inlet nozzle with the smallest ' diameter d 0 and the smallest cross section F 0 (F 0 = d 0 i / 4) .q up to which the incoming flow is accelerated . The inlet nozzle is shaped in accordance with the main patent and generates a velocity field of equally large velocity vectors in the cross-section F 0 up to close to the periphery.

Subsequent to the cross section F 0 , the flow rate diverges evenly on all sides until it enters the blades 2 of the impeller 3. The inlet diameter of the. The blades are marked with d ' and the outlet diameter with d be-1 2. The delivery flow enters the blades 2 with the width b through the annular cross-section F i (F db . According to the invention, the cross-section F is up to 3 times as large as the cross-section F (2.4 L- 'F * IF "- # - 3) 9 0 1 0 and the speed in the smallest nozzle cross-section F 0 is strongly decelerated to a value 2t4 to 3 times smaller in the manifold flow with the transition from the axial to the radial direction with almost no loss velocity in the blade inlet, and particularly in the blade channel as small # daso ein.Minimum losses of implementation and also friction 'occurs * T he boundary layer flow encounters the transition von.der fixed Bintrittadüse 1 at an obtuse angle -on the rotating with the impeller 3 nozzle 4 of the impeller cover 5 and receives an energy supply through the nozzle 4, which maintains the speed profile, which drops evenly towards the edge.

The stated limits of the optimal speed deceleration are determined by the fact that if the deceleration is too low, greater conversion and friction losses occur in the blade channel and if the deceleration is too great, boundary layer detachments occur at the impeller nozzle 4. , FIG. 2 shows the velocity vectors in two planes 6 and 7 normal to one another. The delivery stream flows through the nozzle cross-section F 0 in the axial direction at the speed c 0 and is strongly decelerated in the Krämmerstrom to the meridional speed elm. Through investigations, the low speed was festgestelltg that of 0 lm a minimum of losses ergibtp impeller when the relative; -. 0 Geschinr speed w in a Winke10 of about 65 to the meridional direction of the velocity el, flowing into the blade channel. As a result, the complete angle is a blade inlet angle of approx. 25 0 t, which, as is known, prevents shock losses at the inlet. In order to avoid unfavorable local accelerations and decelerations which could occur on the blades in the blade channel, this angle is maintained until the blade outlet. The blades are shaped as logarithmic spirals for this purpose.

The advantage of the invention is that the impeller losses are reduced and that, in conjunction with the reduction in the gap and housing losses according to the main patent, fans can be produced in normal, simple series production, and their efficiencies reach the optimum of approx. 90% .

Claims (1)

Patent claim Hadial ventilator or pump with outlet nozzle according to 2atent .... (patent application P 18 131 Ia / 270) and an impeller with non-profiled blades whose inlet diameter d in relation to the outlet diameter d 2 is between ot45 and 0.63 (or45 n-7d i / d 2: -5- oe63) e characterized in that the ring cross section (P i ) in the blade inlet of the impeller 2P4 is up to 3 times as large as the smallest circular cross section (FO ) of the inlet nozzle: 5 3) 9, and -that the blade angle (2 9 4 F '/ F 1 0 from the blade inlet to the blade outlet is greater than> 23 0 and less than 27 0 (23 0 2 7o