DE3219955A1 - SUCTION BLOWER HOUSING FOR VACUUM CLEANERS - Google Patents

Description

Suction fan housing for vacuum cleaners

The invention relates to electrically operated blowers for generating negative pressure for a vacuum cleaner, in particular an improvement on the device described in the corresponding European patent application 81105056.6 is.

Said European patent application discloses one vertically arranged cylindrical container with an electrically operated fan, whose pancake-shapedr Rotor is arranged axially in the upper region of the container for generating negative pressure within the container. Included upper and lower housing areas accommodate bearings for the output shaft of the fan motor. The lower case section is molded from plastic and one is also molded from plastic Assigned to supporting member; these two form a chamber in which the fan rotor rotates. The ring wall the chamber has a relatively narrow slot through

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which the air flow generated by the rotation of the propeller can escape; the dimensions of the slot ensure that there is no accidental contact with the rotor. To protect the rotor, a metal one has already been made existing molded housing with punched openings used.

According to the invention, a series of vanes are provided to create an outer boundary of the chamber in which the rotor rotates. As will be shown below, these blades are constructed and arranged in such a way that impacts and diffusion losses are reduced, and thus a smoother and more streamlined flow is obtained, whereby the efficiency of the entire fan is improved. The vanes or guide vanes are designed in one piece with a plastic housing part which partially forms the rotor chamber.

The invention has for its object to improve the device of the type mentioned in that the Vacuum-generating unit for a vacuum cleaner receives a higher efficiency, can be produced more cheaply and is more reliable. Particular attention is paid to a more streamlined air flow. Farther the vacuum generating unit of this type is provided with a plurality of guide vanes around the circumference a pancake-like rotor are arranged around; the guide vanes are constructed in this way and with regard to their Effect arranged to reduce shocks and diffusion losses.

The invention is explained in more detail with reference to the drawing. The following is shown in detail:

Fig. 1 shows in an axial section a negative pressure generating unit designed according to the invention is.

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Pig. Figure 2 is a wiring diagram of the Pig motor part. 1.

Pig. 3 depicts a rear or top view

of the lower housing part. This also includes caps or lids of the electrical brush holder of the lower Housing recognizable.

Fig. 4 shows in elevation a partial view of the lower housing, in the direction of arrows 4-4 in Fig. 3 f * «^

FIG. 5 is a bottom view of the lower housing looking in the direction of arrows 5-5 in FIG.

Figure 6 is a front elevational view of the engine stand. ^{|.! i} 7 is an elevational view of the rotor.

Is'■> FIG. 8 is a view of the rotor from the front.

\ Fig. 9 is a cross-sectional view along section line 9-9 I in Fig. 7, seen in the direction of arrows 9-9-

Fig.lo is a front elevational view of the lower housing, I as in Fig. 5, with the addition of the rotor.

f The negative pressure shown as a whole in Fig. 1 generating

Unit 20 comprises an electric motor with an armature 21 and a stator 22, the electric field generating ^ As is well known and not further shown here, are stator ψ windings 23, 24 (see Fig. 2) magnetically coupled to the pole piece. The axis of rotation of the armature 21 is defined by vertical a- 1 shaft 25 extending across the two ends of the armature> addition, and is superimposed dreii'oar overall i in the upper bearings 26 and 27 respectively. The magnetic frame or the field piece: 22 is 1 between the upper and lower housing sections 28 and. 29 sand-I clamped like a jig; the two sections are through two

Screws 31 clamped together, which extend vertically through corresponding openings in the frame 22.

As already explained in detail in the aforementioned European patent application 81105056.6, the upper housing section 28 has the shape of an inverted U with vertical legs 32 and 33 which extend downwards from opposite ends of the web 34. The free ends of the legs 32 and 33 are provided with respective outwardly facing eyes 38, 39 , through whose corresponding bores the screws 31 are passed. The outer end of the eye 38 is equipped with a further bore 41 in order to receive a grounding screw, not shown here. The lower side of the web 34 has a concave seat surface in which the upper bearing 26 engages. The circumference of an annular spring holder 43 sits on a shoulder on the underside of the web 34 and is secured on the upper housing 28 by means of a protruding part 47 of the web 34. The spring element 43 is equipped with an upwardly facing seat 44 which is in engagement with the upper bearing 2.6. Spring 43 pushes the upper bearing 26 up against the seat surface 42, and the seat surfaces 42, 44 allow the upper bearing 26 to pivot as needed. As a result, the bearing 26 is able to support the upper end of the shaft 25, which in turn extends into an axial bore of the bearing 26.

An inverted, cup-like cover 50 is attached to the upper housing 28 by means of two screws 49 which are inserted into threaded bores 48 are screwed into web 34 after they have been through-appropriate Bores are passed in the disc-like upper surface 52 of the lid. Area 52 is furthermore with a plurality Equipped with ventilation openings, not shown here, through which the air is drawn down by means of rotor blades 55 which in turn is located inside cover 50 and at the top of shaft 25 just below the upper bearing is attached. A bushing 54 on the top of the shaft

positioned wing 55 * The air moved by the latter is used to cool the motor 21, 22.

As can best be seen from FIGS. 3 and 4, the lower housing 29 is a cast insulating part which is equipped with a cylindrical main part 6l, which in turn is designed concentrically to the motor shaft 25. Flange 62, which extends radially inward from the lower end of the main part 61, is provided with a central bore 63 through which the lower end of the shaft 25 is passed. An upwardly extending lip 64, which surrounds the bore 6 ^> , positions the lower bearing 27. The latter is a ball bearing, the inner ring of which sits tightly on the shaft 25. A corrugated tolerance ring 65 is provided between the lip 64 and the outer ring of the bearing 27 (see also FIG. 1). The flange extends radially outward from the main part 61 and, together with the flange 62, forms the upper, plate-shaped delimitation for an only slightly deep recess or chamber 67 in which a suction fan motor 70 is arranged. The lower housing 29 further includes pegs 71 in the vicinity of the inner surface of the main part 61. The pins 71 are equipped with upwardly open threaded bores 72 into which the screws 31 are screwed.

Brush holders 73, 73 are formed with Hauptteil.6l and extend radially through main part 6l. Each holder 73 is of substantially rectangular cross-section with a through-hole 76 which contains a brass holder 74 for a carbon brush records. The latter is pressed against a commutator 77, which in turn sits on the shaft 25 and electrically is connected to the winding of the armature 21. The brass holders are electrically connected to the field windings 23,24. One Helical spring, not shown here, which is arranged inside the holder 74, presses brush 75 radially inward in good electrical contact with commutator 77. The outer end of the bore 76 is through, not shown here, inward

cranked plugs on opposite sides of the brass holder J ^ closed »plastic cover 78 closes the outer end of holder 75; they are held in their active position by four snap fingers 79. Below and to the side of the brush carrier 75, the cylindrical main part is equipped with a bore 81, which represent outlets for the air flow generated radially by the upper fan blade 55, with which the motor 21, 22 is cooled.

The end of the field winding 25 facing away from the brush 75 is connected to the electrical line 151 (see Figure 2); , Remote from the other brush end 75 of the field winding 2> is connected to an electrical line 152nd The conductors 151, 152 extend radially outside the lower housing through slots 155 (FIG. 5) in the lower edge area of the main part 6l and are at the bottom of the slot 155 (or the groove) by a molded plastic clamping element ( not shown here) held; this in turn is held in place by field piece 22 from above. A sponge-like ring 200 is glued to the upper surface of the flange 66 and forms a seal for a cover, not shown here, which in turn can be slipped over the motor 21, 22.

From flange 66 , three further pins 82 extend downward, their free ends in corresponding individual recesses

84 in the upper surface of the plate-shaped motor support element

85 of the molded plastic part 99 extend into it. Support part 85 forms a lower limit for the flat chamber Screws, not shown here, extend upwards through corresponding bores in support part 85 and are in threaded bores 86 of the pin 82 is screwed in in order to mechanically fasten the lower housing 29 to the support part 85. Support part 85 also has an upwardly extending very short annular lip 85 slightly outside the lower rotor wall 105 is arranged in order to limit a leakage air flow to the front region of the rotor 70 (from below). Support part is also equipped with a central bore 88 which is enclosed by a skirt 91 extending downwards.

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Skirt 91 is used to guide the air flow axially, which in the fan rotor 70 is sucked in.

Rotor 70 sits on shaft 25, which extends down through the central bore 98 (see FIG. 9) in there? disc-shaped top wall 95 of rotor 70 extends therethrough. A nut 92 is screwed onto the lower end of the shaft 25. A spacer ring 93 provided with a flange is pushed onto the shaft 25 between the rotor wall 95 and the ring face of the bearing 27. Wall section 95 of rotor 70 is clamped between spacer 93 and lower washer 96 when nut 92 is tightened. In a manner known per se, the motor support element 99 x is mounted on the upper part of a suction container 97, which is only shown in outline in FIG. The annular seal 200 is glued to the upper surface of the flange 66 in order to carry a protective cover (not shown here) of the motor 21, 22 which is removable if possible.

As best seen in Figures 8, 8 and 9, the rotor 70 has six curved blades 102 arranged on edge and clamped between the upper and lower circular parallel walls 95 and 105, respectively. The lower wall 105 is provided with a relatively large central air intake opening 106. The blades 102 are arranged with their convex surfaces downstream, seen in the direction of rotation of the rotor shown by arrow A in FIGS. 8, 9 and 10.

A plurality of guide vanes 110, the lower ends of which rest on the upper surface of the support part 83, are formed integrally with the lower housing 29 and extend around the lower flange 66. In general, between two and ten guide vanes are assigned to each rotor blade. In the exemplary embodiment shown, six guide vanes 110 per rotor blade 102 can be seen. The guide vanes 110 are arranged in the region of the circumferential edge of the rotor 70 and are evenly distributed around the one illustrated by the arrows B in FIG. To direct air flow and thereby reduce the turbulence.

Each vane 110 is inclined such that its downstream end is radially outside of the upstream end. Except for those vanes that extend within the three tenons 82, each vane 110 has an interior surface 111 and an outer surface 112. When viewed in cross section, the greater part 113 of the outer surface 112, the extends towards the downstream end, parallel to inner surface 111. The other portion 114 · of surface 112 is in Inclined with respect to face 111 at the upstream end and is closest to face 111 at the upstream end. this results particularly well from the detail in FIG. 10. The arrangement of the guide vanes 110 is such that between the upstream end of one vane 110 and the downstream end of an adjacent vane is a distance through which a true radial line is passed to a point outside of the vane 110 can be without one of the two adjacent guide vanes 110 being cut thereby.

19-05.1982
DrW / MJ

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Claims (1)

PATENT CLAIMS Fan rait a first, a flat chamber defining means, a cake-shaped rotor, which is arranged within the chamber, an electric motor for driving the rotor in a first direction about its axis, a number of guide vanes within the chamber, the outside ^; of the rotor and are arranged around its circumference, the motor having a plurality of rotor blades which are designed and arranged in such a way that they convey the air ■ radially outwards and through the spaces formed between the guide vanes, characterized in that the guide vanes extend upstream with respect to the direction of rotation of the rotor and are inclined radially inward. A fan according to claim I, characterized in that the guide vanes are arranged such that there is a narrow gap between the inward end of each guide vane and the outward end of the adjacent upstream guide vane through which a radial is laid from a point outside the rotor can. 3. Blower according to claim 1, 'characterized in that each of the guide vanes has an inclined portion at the inward end (inner end) of the guide vanes on the next is. Blower according to claim j5, characterized in that each The guide vane has a first planar surface which extends over substantially the entire distance between the inwardly igen and the outward end of the guide vane extends A fan according to claim K, characterized in that each of the guide vanes has a second surface opposite the first-mentioned surface, that part of the second surface extends only partially from the inward end to the outward end, and that said portion with respect to the first surface is inclined and comes closest to this at the inner end ^ second surface. Blower according to Claims 1 to 6, characterized in that the rotor has a plurality of rotor blades arranged at angular intervals, and that between two and ten guide blades are assigned to each rotor blade Ύ '. Blower according to Claim 6, characterized in that the respective outer end of the rotor blades is arranged upstream of the (radially) inner end, and that each rotor blade is curved between its two ends in such a way that the surface facing downstream is convex. 8. Blower according to claim β or 7, characterized in that at least approximately six guide vanes are assigned to each rotor blade (rotor blade). 9 · Blower according to one of claims 1 to 8, characterized in that that the rotor is arranged between two walls which have surfaces essentially parallel to one another, extend perpendicular to the central axis and are defined by said first means that the rotor has a front and a rear circular wall that a plurality of blades are arranged between the walls that P · I an annular lip extends slightly from said front surface to the rear of the front Plate and extends close to this and is designed in such a way as to prevent the leakage air flow to the front area of the Limit rotor. 10. Fan according to one of claims 1 to 9> characterized in that the first and the second element each other, respectively having facing first and second surfaces, which are perpendicular to said central axis, and enclose the rotor between them, and that the first element of molded There is plastic and that the guide vanes are integrally formed on it. 05/19/1982
DrW / MJ