DE1628361B2 - CENTRIFUGAL FAN - Google Patents

Description

The invention relates to a centrifugal fan according to the preamble of claim 1.

With the miniaturization of electronic components, there has been an increasing need for a small, powerful cooling fan. It is well known that electronic circuit arrangements, in particular Semiconductor components must be kept at temperatures within certain limits so that they work flawlessly. Through the spatial reduction of the individual components and through the microcircuit technology one is to a higher packing density, i. H. a larger number of electronic Components arrives within a given spatial volume. Often used for cooling Such arrangements centrifugal fans, as they are well suited to the 'cooling air against considerable To circulate pressure gradient. Because of the high packing density, however, you have to use fans that one Promote airflow with high initial pressures. On the other hand, the fan should be as small and light as possible be and have a compact shape.

As is well known, the performance of a centrifugal fan depends largely on the size of the rotating one The impeller. Therefore, in order to reduce the overall size of the fan without sacrificing output, must to increase the efficiency of the fan. Achieved by such an increase in efficiency it also means that a smaller motor can be used to drive the impeller.

From GB-PS 7 51 906 a centrifugal fan with a spirally wound flow channel is known in which the air enters axially, and whose cross-section is elliptical and one that increases from the inside to the outside Has area. The major major axis of the cross-sectional ellipse is at least approximately constant ratio to the small main axis over the entire course of the channel parallel to the axis of rotation of the impeller, whereby relatively small radial dimensions can be achieved. The well-known blower is for the above explained purposes too bulky in the axial direction, if only because the fan motor is spatially separated from the impeller is.

A centrifugal fan is also known in which the fan is arranged on the circumference of the impeller The flow channel partially encloses the fan motor (FR-PS 7 45 615), but the flow channel has here a constant, roughly semicircular cross-section. Apart from the relatively large radial In the case of such a shape of the flow channel, the dimension over the entire fan circumference is the outlet cross-section and thus the performance of the fan is too small for the purposes explained above. In addition, an auxiliary air flow must be generated to cool the motor.

The object of the invention is to create a small but powerful fan, in particular requires less space in the axial direction than a known fan with comparable cooling capacity.

The invention solves this problem with the fan characterized in claim 1. The invention has the advantage that the fan has a very small footprint. For a given total volume the fan unit including the motor can be used on the other hand for the flow channel Provide its outlet end with an optimally large cross-sectional area, which means that the fan is more powerful is known as a blower with the same space requirements. The good cooling effect allows in many Cases the use of a smaller and lighter motor than before. So overall it is a particularly small and light blower with a high flow rate.

A preferred embodiment of the invention is explained below with reference to the drawing. It shows

F i g. 1 is a partially sectioned front view of the fan;

F i g. 2 shows a partially cut-away side view of the fan according to FIG. 1,

3 is a view seen from the other side of the fan according to Fig. 1,

Fig.4A to 4D sections of the fan housing, unc, although generally along the lines AA, BB, CC and D-Dm Fig.3, and

Fig. 5 shows the performance diagram of a typical fan design according to the invention.

The capacity of a centrifugal fan is how mentioned, mainly the size of the wheel; proportional. The extent to which the radial and the axial dimensions of the impeller in the interest of de: compactness of the overall structure is reduced can, is therefore due to the required size de impeller and the required efficiency de Fan limited. With conventional blowers, the total radial dimension cannot be without loss a: Efficiency or delivery rate is reduced. In the case of the fan shown in FIGS. 1 and 2, we on the other hand, the radial dimension of the fan due to the special cross-sectional shape of the spiral channel 15, the noc

is described in more detail, scaled down without sacrificing performance. Additionally, it increases the size of the fan reduces the motor 12 being partially built into the housing 14. The motor 12 drives an impeller 10, the in the housing 14 rotates. The housing 14, which can be made of lightweight polyester resin can, forms the mentioned spiral channel 15, so a spirally wound flow chamber with generally elliptical cross-section. As can be seen in Fig. 1, the Inner circumferential part 17 of the spiral channel open to allow the air conveyed from the circumference of the impeller 10 to flow in permit. The impeller 10 sucks air into an inlet opening 17 at an inlet channel 16 at the rotation Side of the housing 14 with an edge 16a, the contour of which is adapted to the intake flow. The impeller ι j blades 10a convert the axial suction flow into a centrifugal flow that flows into the inlet opening, ie the open inner part of the spiral channel flows.

As best seen in Fig. 1, the spiral channel 15 at the junction between the Diffuser section 19 and the winding part of the housing 14 a constriction or throat 18. The lower edge 18a of this groove located in the direction of the impeller rotation runs at an angle to the Impeller blades 10a and spans or bridges two successive blades 10a (whereby a Fluttering and pulsation noises are prevented, which would otherwise be caused by the flow of between successive blades 10a of trapped air as the blades move past the throat would). From the inlet end of the spiral channel 15, immediately below the throat 19 (Figure 2), the takes The turn radius of the spiral channel 15 gradually increases in the direction of the impeller rotation. At the same time takes how can best be seen from FIG. 4A through 4D see the ratio of dimension 20a to dimension 206 of the elliptical Cross-section of the spiral channel gradually increases until this ratio is reached at its outlet to the diffuser section 19 is greater than 1. That is, the axis of the elliptical cross section parallel to the axis of the motor 12, which forms the major main axis of the ellipse in the small-area parts of the turn (FIG. 4A), gradually goes into the minor major axis at the outlet of the spiral channel over (Figs. 1 and 4D), where the major major axis in a to Motor axis runs in the vertical plane. At all points along the spiral channel 15, the cross-sectional area is dimensioned in such a way that optimal air flow properties are achieved result. As is readily apparent from the drawings, the described results Formation of a combination of optimal flow properties with minimal axial and radial properties Dimensions.

In Fig. 1, the motor 12 is schematically illustrating its positional relationship to the fan shown. The motor includes a stator 21 and a rotor 22 supported by bearings 24 and 25 on the shaft 23 is stored. Due to the construction described here, the stator windings 21a and 21a are parts of the rotor 22 is exposed to the air flow generated in the housing 14 by the rotating impeller 10. Of the Partial incorporation of the motor 12 into the housing 14 serves two purposes. The first thing it does is axial length of the fan is considerably reduced and, secondly, by dissipating the heat from the windings 21a and the rotor 22 by the cooling effect of the circulating air the use of a smaller one Motor possible. The latter naturally results in a further reduction in the axial length of the fan arrangement as well as a reduction in power requirements.

The impeller 10 is connected to the rotor 22 by a generally cylindrical rotor end ring and hub arrangement 27 made of aluminum or another suitable material of high thermal conductivity. The hub 27 forms a continuation of the rotor and stands with a considerable area 276 in thermal contact with the metal parts of the impeller 10. This training enables a good Heat transfer from the rotor 22 to the impeller 10, which because of the strong air flow penetrating it as Heat sink works.

A motor housing 30 with a flange 31 at its inner end supports and encloses the motor shaft 23 the outside or left end of the motor 12. The flange 31 has in its surface 33 near his The outer circumference is a circumferential groove 32 which receives a cylindrical extension 34 on the housing 14. Through this the housing 14 can be rotated in a sliding manner relative to the motor housing 30. When the blower by attaching the motor housing 30 to an external bracket (not shown), for example by means of screw bolts screwed through the holder and the threaded holes 36 at the bottom of the motor housing 30, is to be mounted, so you can rotate the housing 14 relative to the outer bracket so that the conveyed air flow can be changed in its direction over an angle of 360 °. One can but the unit can also be attached to a plate or wall with a suitable opening for the outlet end of the Assemble diffuser section 19, for which purpose the flange 48 of the diffuser with holes 48a for suitable Fastening means is provided. To attach the motor housing to the fan housing 14 are used Number of clamping blocks 40 with an inclined surface 40 a at one end, the longitudinal flat surfaces on a the same number of ribs 42 arranged radially on the motor housing 30 are slidable. Each clamping block 40 is gripped by a clamping screw 44 penetrating a slot 45 in the motor housing.

The flange 31 on the motor housing 30 may also have an axial extension 31 a so that a to the Space 50 running around motor 12 is created. This space, through which the total radial dimension of the Fan is not enlarged, can be used for the installation of electrical components, such as the im Starting capacitor 51, switches, overload relays, etc. shown in the upper part of the room 50 are used will. A suitable interference fit ring 52 can be provided to seal off the space 50.

The characteristics of the described blower can be seen from the performance diagram of Figure 5, which was obtained with a blower whose dimensions were approximately 28 × 30 × 19 cm and which weighed 6.4 kg. The upper curve shows the static pressure (in Torr * 1.87) as a function of the air volume conveyed (in M ³ * 0.028 per minute), while the lower curve shows the corresponding power consumption (in watts). As can be seen from the diagram, this fan can deliver more than 8.4 m ³ per minute at a static pressure of 5.6 Torr. The invention thus creates a centrifugal fan which is superior to the known fans in terms of its performance with optimal size and weight dimensions.

For this purpose 4 sheets of drawings

Claims (3)

Patent claims: 1. Centrifugal fan, the housing of which has a spirally wound flow channel with generally elliptical cross-section and from the inside to the outside increasing cross-sectional area forms the one has inlet opening extending in its circumferential direction, the major axis of which is the Cross-sectional ellipse at an inner end of the spiral channel parallel to the axis of rotation of the impeller runs, characterized in that the spiral channel (15) around a within the Housing arranged part of the motor (12) of the fan is wound, and that the ratio of small main axis (20a in Fig. 4A) to the major main axis of the symmetrical with respect to the main axes Cross-sectional ellipse of the spiral channel progressive outward from the inner end increases and the major major axis (20a in Fig. 4D) of the cross-sectional ellipse is attached to the spiral channel subsequent, also elliptical pressure port (19) is perpendicular to the axis of rotation. 2. Centrifugal fan according to claim 1, characterized in that the inlet opening (17) of the Spiral channel (15) is located on its inner circumference. 3. Centrifugal fan according to claim 2, characterized in that the motor (12) so from Spiral channel (15) is surrounded, that it is through the inlet opening (17) on the inner circumference of the spiral channel flowing main air stream of the fan is cooled.