FI88538B - Centrifugal fan - Google Patents

Description

Centrifugal Blower

Centrifugal fläkt, n Γ _ cob t 8 5

The present invention relates to a centrifugal fan, the rotor of which consists of radial tubes of circular cross-section, the rotor of which can be assembled and mounted inside a fixed housing of the fan. In particular, the invention relates to a centrifugal fan comprising a rotor formed of annular hub-10 wheels to which rotor tubes of circular cross-section are attached, the centrifugal fan further comprising a shaft for rotating the rotor, a shaft-mounted flange rotating with the shaft, and a front cover .

A rotor assembled from radial tubes is known, for example, from DE IS 261322 27c. In all known structures, as well as in the above, a uniform rotor has been sought for strength-technical reasons. In this case, the whole structure of the fan becomes complicated due to the fact that the fan housing must be openable for mounting the rotor. Many applications, such as steam compressors used to develop the pressure difference of distillates, require a large gas flow-20 ground with a reasonably small pressure difference, less than 1 Bari. In this case, the dimensions of the fan become large, so that the requirement for the assembly of the fan housing leads to cumbersome ·: ··: solutions.

: The pressure increase of the centrifugal fan is determined by the circumferential speed of the rotor (πηϋ) 25 as follows:

p - a p n2 D2 W

: ...: where ·: ··: 30 p = pressure increase caused by the fan, 2 £ 8 528 a = experimental constant due to structure, p = gas density, n = rotor speed and D = rotor diameter.

5 The output of a fan based on radial tubes, in turn, can be projected: Q = bnDd2 (2) where 10 Q = fan output, ie flow, b = experimental constant due to the structure and d = diameter of the rotor tube.

The power required to rotate the rotor, in turn, can be projected: 15 P = c p n3 D * d where P = the power required to rotate the rotor, ie the power dissipated, and c = the experimental constant due to the structure.

20

Since the net power of the fan is the output times the pressure difference, the efficiency can be calculated by combining (1) - (3), where: η = -i- (4) 1 + k Did 25 where 3? 3,538 η = fan efficiency and k = experimental constant due to structure = c / a / b.

It follows from the above that in order to achieve good efficiency with a pressure difference of 5, the diameter of the fan must be chosen as small as possible, i.e. the rotational speed as high as possible. This, in turn, requires the rotor to be as light as possible, to have as little moment of inertia as possible, to retain its shape well due to strict balancing requirements, and to be structurally advantageous in construction.

10

On the other hand, the rotor tube cannot be shorter than 2.5 times the diameter of the rotor tube because the flow would not otherwise be parallel to the rotor tubes. Likewise, the structure of the hub and the attachment of the rotor tubes limit the reduction of the rotor diameter.

15 When the circumferential speed is limited to 200 m / s for welded structures and 270 m / s for machined structures due to strength reasons, it would be technically desirable to reach a sound speed of 330 m / s or more, whereby the pressure rise would be more than 50% higher. A radial rotor tube linearly thinned towards the tip is subjected only to:. A tensile stress of 20 σ = p v2 / 3 (4) where a = tensile stress of the rotor tube, .25 p = density of the rotor tube and:. : v = circumferential speed = »rnD.

The strength of the rotor thus depends only on the ratio of the allowable stress to the density of the rotor tube. For example, with a permissible stress of 150 N / mm2 for aluminum and a density of 4: 35-3 2700 kg / m3, a maximum permissible circumferential speed of 408 m / s is obtained from (4) and for steel with a stress of 450 N / mm2 and a density of 7800 kg / m3 416 m / s. Thus, it is found that aluminum and steel are equally equivalent materials in the rotor tube, but aluminum is much lighter due to its lower moment of inertia.

The above strength test is only valid if the rotor structure is such that it has no welded joints, notches or other discontinuities that reduce the radial strength. This determines the connections of the rotor tubes to the rotor hub.

10

The centrifugal fan according to the invention is mainly characterized by what is stated in the characterizing parts of the independent claims.

The invention is shown in more detail in Figure 1, which shows one preferred principle structure of the solution according to the invention 15.

The fan is formed by a housing 10, inside which the rotor formed by the impeller is placed. The rotor consists of a drive hub ring 11, a hub ring 12 and rotor tubes 13. The rotor is attached to a shaft 15 driven by the motor 14. The speed is adjusted, for example by a V-belt drive 16. The gas to be blown is sucked into the hub through the suction port 17 and the centrifugal force drives The flow is subjected to a rotational movement on the circumference 18 of the housing 10, the speed of which is determined by the rotational speed of the rotor. The kinetic energy of the gas filing at the circumference 18 of the housing is finally converted into a pressure difference in the diffuser 19.

25

The clearance between the housing 10 and the rotor tubes 13 has not proved to be critical in experiments, but can be selected from 10-50% of the rotor tube diameter. Likewise, the distance of the rotor tubes 13 from the outer circumference of the housing 10 can vary from one to two times the diameter of the rotor tube without substantially changing the performance of the fan. For this reason, the housing 10 30 does not have any particularly high accuracy requirements, but can be manufactured, for example, by welding, whereby a cost-effective structure is obtained. Due to the loose tolerance requirements of the above, the structural deformation in welding is not critical in manufacturing. An essential point in terms of manufacturing costs is that the housing, which is by far the largest single part of the fan, does not need to be machined at all.

5

A preferred hub structure according to the invention is shown in Figure 2. The rotor tube 20 is attached to the drive hub ring 21 and the hub ring 22 by means of shoulders 23 so that a thin chip is machined from the hub ring connecting surface 24 before assembly. Thus, the rotor tubes 10 have no discontinuities and no welded joints to impair the strength properties.

The outer surface 25 of the mouth of the hub ring 22 is grooved to prevent gas from escaping from the inside of the fan back to the suction side, the groove acting as a labyrinth seal.

15

The mouthpiece 26 of the suction opening is adjusted so that the clearances of the seal 25 are correct. The outer diameter of the mouthpiece is dimensioned so that the hub rings 21 and 22 and the circumferential tubes 20 can be inserted from the opening 27 during the assembly step. Alternatively, the assembly can be performed on the drawhead side by dimensioning the drawbar plate 28 so that the hub rings 21 and 22 fit in the opening 29. make an opening of the outer diameter of the rotor tubes 13 from which the rotor tubes can be pushed into the housing during the assembly step.

The structure of the rotor is very advantageous from a manufacturing point of view, since all parts can be made by turning. Because of the high rotor speed, the rotor must be both statically and dynamically balanced. Good special dimensional accuracy is obtained for turning parts without special measures, so the presented structure is easy to balance. The rotor is balanced when assembled and assembled in exactly the same order inside the housing. Thus, even a large fan and its rotor can be assembled from relatively small parts 30 inside a housing made by welding.

6; · 8 52 8

One preferred embodiment of the invention is a steam compressor steam compressor. In this case, the fan absorbs steam from the vacuum side of the distiller. The problem is to seal the fan shaft to the outside air so that the necessary vacuum is developed in the distiller. Figure 3 shows one preferred fan sealing solution. Attached to the rotating shaft 32 S is a flange 31 to which, for example, a seal 30, which is a flexible material, for example rubber, is glued. The seal 30 seals against the fixed flange 33. When the seal 34 on the vacuum pressure is reduced, the seal 30 is pressed more tightly against the flange 33, the greater is the negative pressure. The sealing surface of the flange 33 is naturally ground.

10 When the fan is started, the seal 30 initially acts as a normal lip seal until it is detached from the flange 33 by centrifugal force. Therefore, a second seal is required on the suction side 34 of the seal 30, which operates when the fan is running. Such is, for example, the known water ring seal obtained by introducing the hot steam of the distiller into a cooled groove where it condenses into a water ring.

15

The fan according to the invention can also be formed as a compressed air compressor by connecting several fans to Saija. One preferred solution for such a compressor is shown in Figure 4. The gas to be compressed is sucked from the inlet 40 to the first stage rotor 41. Inside the hood there is a helical diffuser 42 from which the gas is discharged 20 to the second stage inlet 43. Of course there can be any number of stages. .

Since one stage doubles the pressure, the compressor according to Fig. 4 gives a sufficient pressure of 8 bar for industrial use. The number 25 of rotor tubes is selected for different stages so that the pressure rise and the volume flow are in balance. Likewise, the wall thickness of the axial alignment rings 47 of the rotors is selected so that the volume flows in the suction openings 43 are in equilibrium. Since only the numbers of rotor tubes vary in the different stages, all the rotor tubes 41 of the compressor are similar, as are the hub rings 45 and 46 in each stage except for the number of radial holes in the circumference. In this case, too, a large part of the compressor parts 7 08528 can be manufactured by turning even so that the parts of the different stages or their blanks are identical to each other.

Since the solution shown only two bearing lubrication is needed is a compressor 5 on the suction side of the bearing easy to summarize, in the sense that produced by the compressed air is pure.

Claims (6)

8 f 8 52 8 A centrifugal fan comprising a rotor formed of annular hub wheels (11,12; 22,21) to which are attached rotor tubes S (13; 20) of circular cross-section, the centrifugal fan further comprising a shaft (15; 32) for rotating the rotor, a shaft ( 15; 32) a housing (10) with a front plate (26) and / or a rear plate (28) of a fixed flange (31) rotating with the shaft (15; 32), characterized in that the front plate of the centrifugal fan housing (10) (26) and / or the rear plate (28) are dimensioned so that when the front plate (26) and / or the rear plate (28) are out of place there is an opening / opening (27,29) in the fan housing (10) which through the rotor tubes (13; 20) are insertable inside the housing (10), that the rotor is assembled inside the housing (10) so that the hub rings (11, 12; 22, 21) are connected to each other by axial connections, and that the rotor tubes (13; 20) are ) is attached to the hub rings (11.12; 22.21). IS 2. A centrifugal fan comprising a rotor formed of annular hub wheels (11,12; 22,21) to which are mounted rotary tubes (13; 20) of circular cross-section, the centrifugal fan further comprising a shaft (15; 32) for rotating the rotor, the shaft ( 15; 32) a housing (10) with a front plate (26) and / or a rear plate (28) of a flange (31) rotating with the shaft (15; 32), characterized in that the housing (10) of the centrifugal exhaust 20 the outer circumference has an opening slightly larger in diameter than the diameter of the rotor tube (13,20), from which opening the rotor tubes (13; 20) can be inserted into the housing (10) with the opening closing flange out of place so that the rotor is assembled inside the housing (10) that the hub rings (11,12; 22,21) are connected to each other by axial connections and that the rotor tubes (13; 20) are attached to the hub rings 25 (11,12; 22,21). Centrifugal fan according to Claim 1 or 2, characterized in that the rotor tubes (13; 20) are fastened to the hub rings (11, 12; 22, 21) by means of shrink joints which are secured by means of shoulders (23). 30 9 88528 A centrifugal fan according to any one of claims 1 to 3, characterized in that the centrifugal fan further comprises a clearance formed between the housing (10) and the rotor of 10-50% of the rotor tube diameter, and that the outer ends of the centrifugal fan rotor tubes (13; 20) and the distance between the housing (10) is 5 times the diameter of the rotor tube (13; 20). Centrifugal fan according to one of Claims 1 to 4, characterized in that the fan further comprises a resilient seal (30) attached to the rotating flange (31) with the fan shaft (32) against the pressure difference, which seals against the rear plate (28; 33) 10 that when the suction is on the side of the rear plate (28; 33) the seal (30) is adapted to be absorbed more tightly against the rear plate (28; 33) the greater the pressure difference and which seal (30) is adapted to detach from the flange (33) as the shaft (32) rotates ) due to centrifugal force. Use of a centrifugal fan according to any one of the preceding claims 1 to 5, wherein a plurality of centrifugal fans are connected to Saija, the fan group thus formed being used as a pressure compressor. 10 38528