EP1656064A1

EP1656064A1 - Vacuum cleaner comprising a pivotal handle

Info

Publication number: EP1656064A1
Application number: EP04763972A
Authority: EP
Inventors: Silvio Hamm; Roland Illig; Albert Kleinhenz
Original assignee: BSH Bosch und Siemens Hausgeraete GmbH
Current assignee: BSH Hausgeraete GmbH
Priority date: 2003-08-11
Filing date: 2004-08-10
Publication date: 2006-05-17
Anticipated expiration: 2024-08-10
Also published as: DE10336829B4; EP1656064B1; DE10336829A1; CN1835707B; CN1835707A; WO2005016109A1; ATE532450T1; ES2374401T3

Abstract

The invention relates to a vacuum cleaner comprising a housing (1) and a carrying arched element (7) mounted in a manner that, by means of at least one pivot bearing (8), which has a first pivot bearing part (9) and a second pivot bearing part (10) that can rotate relative to the first pivot bearing part (9) about a common rotation axis, enables it to pivot relative to the housing (1) between two end positions of an operational pivot angle. The aim of the invention is to create a vacuum cleaner whereby a carrying arched element (7) that can pivot relative to the housing (1) between two end positions of an operational pivot angle is securely mounted in an simple manner. To this end, the pivot bearing (8) is designed for joining or separating the first pivot bearing part (9) to or from the second pivot bearing part (10) in a mounting angular position located outside of the operational pivot angle. This enables the pivot bearing parts (9, 10) of the pivot bearing (8) to be mounted and detached solely in a mounting angular position. The pivot bearing parts (9, 10) cannot be detached when the carrying arched element (7) is located in an operational pivot angle. This makes it possible to eliminate separate parts that would otherwise be necessary for preventing an unwanted detaching of the carrying arched element (7) from the vacuum cleaner.

Description

Vacuum cleaner with a swivel handle

The invention relates to a vacuum cleaner according to the preamble of claim 1.

From DE-AS 12 89 628 a generic vacuum cleaner is known, in which a handle is pivotally mounted in a disc concentric to its axis of rotation. One end of the handle which is bent around a tube is provided with a stop. The groove continues locally up to the outer edge of the pane, so that two stops are formed, between which the carrying handle can pivot freely with respect to the pane. By means of this solution, the carrying handle can be pivoted between two end positions of an operating pivot angle with respect to the housing. However, it is disadvantageous that the structure there is very complicated and has a large number of individual parts.

The object of the invention is to provide a vacuum cleaner in which a support bracket which can be pivoted between two end positions of an operating pivoting angle with respect to the housing is securely mounted in a simple manner. In particular, it is an object of the invention to simplify the mounting of the carrying handle in such a way that the vacuum cleaner can be manufactured inexpensively and the carrying handle can be assembled easily and in a safe manner with little expenditure of time. A safe storage of the handle should be achieved in particular with simple means.

According to the invention, this object is achieved in that the pivot bearing is designed to assemble or separate the first pivot bearing part from the second pivot bearing part in an assembly angular position lying outside the operating pivot angle.

The fact that the pivot bearing parts of the pivot bearing can only be assembled or disassembled in a mounting angular position that lies outside the operating pivoting angle ensures that the pivoting bearing parts, when the carrying handle is in an angular position, that is within the operating pivoting angle is not removable. As a result, it is possible to dispense with separate components that would otherwise be necessary in order to prevent the unwanted dismantling of the To prevent carry handle from vacuum cleaner. An additional axial locking pin, for example, for axially fixing a bearing journal in a bearing seat of the rotary bearing can be omitted. This leads to lower production costs due to the reduced number of parts and the elimination of an additional assembly step. According to the invention, the first and the second pivot bearing part are designed and matched to one another such that an axial and / or radial locking mechanism on the pivot bearing is only active in the operating angular positions and is not active in the mounting angular positions. In an angular mounting position, the axial and / or radial locking mechanism therefore does not work and the handle can be separated from the vacuum cleaner or inserted into it. After the carrying handle is pivoted into an operating angular position, the axial and / or radial locking mechanism is effective, the carrying handle is locked on the vacuum cleaner and the carrying handle cannot therefore be separated from the vacuum cleaner or inserted into the operating position. Reliable axial and / or radial securing is thus achieved without additional components to be assembled.

The first pivot bearing part preferably has a bearing journal and the second pivot bearing part has a bearing seat with a clearance, through which the bearing journal can be inserted into the bearing seat.

The cutout preferably extends in the radial direction, so that, for example, an arc-shaped carrying bracket with two opposing bearing journals can be inserted radially into the bearing seats. This is particularly useful if the carrying handle has a high degree of rigidity, so that the bearing journals facing each other on the carrying handle cannot be bent away from one another by bending the carrying handle in order to be able to insert them axially into the bearing seats. However, if the carrying handle has sufficient flexibility, it may be useful to provide axial clearance instead of radial clearance, by means of which the bearing pins can be inserted axially into the bearing seats.

The bearing journal can have a projection which extends radially outward and which is aligned with the cutout in the mounting angular position. The radially outwardly extending projection can serve as a securing mechanism for axially securing the bearing journal in the bearing seat. The bearing seat then has a recess that extends over the mounting angular position. The bearing seat has no clearance in the operating angular positions. The mounting bracket can be mounted in the axial direction, the bearing journal being insertable into the bearing seat having the cutout, analogously to a key in a keyhole. The protrusion formed on the bearing journal forms the beard of the key. If the protrusion is inserted into the recess on the bearing seat, this corresponds to inserting the key into the lock via the keyhole cover. If the trunnion is turned with the projection into an operating angular position, the trunnion can no longer be pulled out axially, just as a key turned in the lock cannot be pulled out, since the beard of the key is behind the keyhole cover. The projection is supported for axially securing the bearing journal in the bearing seat on an end face of the second rotary bearing part.

Advantageously, the clearance of the second pivot bearing part is radially open to the edge and has a clear width which is adapted to the diameter of the bearing journal in such a way that the bearing journal can be inserted into the bearing seat in a radial direction in the mounting angular position.

In this variant, the carrying handle can preferably be mounted in the radial direction. Due to the radial clearance on the bearing seat, the bearing journal can be inserted radially into the bearing seat without hindrance. In this variant, the radial protrusion does not have to be adapted to the clearance, but only in its size and extent so that the protrusion is wider than the clear width of the bearing seat receiving the bearing journal. The axial securing of the bearing journal is provided in any angular position from the handle to the vacuum cleaner. All that is required is a radial securing of the bearing journal in the bearing seat after assembly.

For this purpose, the housing has a first housing part on which the radially open cutout is formed and a second housing part on which a locking section is formed for closing the cutout. The formation of the locking section on a housing part has the advantage that a separate component for radially securing the bearing journal in the bearing seat can be dispensed with. Since there is no separate component for radial locking, it cannot be lost as a separate part.

The locking section can be designed as a wedge-shaped housing projection of the second housing part which engages in the radially open cutout of the first housing part. Thus, the locking section can be produced in one piece with the housing part, preferably in a plastic injection molding process, at low cost.

If the projection is an axially extending extension on the first rotary bearing part, which is arranged at a radial distance from the axis of rotation, then this extension can engage in an annular channel on the second rotary bearing part which runs coaxially to the axis of rotation.

As an alternative or in addition to the locking section described above, this design variant can provide radial securing for the bearing journal in the bearing seat. Such a projection can only be inserted into the ring channel in an assembly angular position, or can be pulled out of the ring channel. In an operating angular position deviating from the mounting angular position, the projection slides behind an inner peripheral wall and an outer peripheral wall of the ring channel. These peripheral walls delimit a guideway for the attachment in such a way that the attachment is locked behind the outer peripheral wall in the operating angular positions. A radial disassembly of the handle is not possible in these operating angular positions. Only when the carrying handle is swiveled into a mounting angle position, does the shoulder come to lie flush with the cutout, which is open at the radial edge, and the bearing journal can be removed radially from the bearing seat.

In order to achieve a very large operating angular range, it is advantageous if the peripheral walls extend all the way to the radial clearance. The carrying handle can only be assembled or disassembled in a small angular range that corresponds to the size of the clearance. A small angular range for the mounting angular position increases the security against loss, since the carry handle is then locked in the bearing seat in most of the angular positions. At least one counter-stop element on the second pivot bearing part is preferably assigned to at least one stop element arranged on the first pivot bearing part, in such a way that pivoting of the handle from the region of the operating pivot angle into the mounting angular position is prevented.

According to the invention, it is advantageous if the at least one bearing seat is located on a housing part of the vacuum cleaner and the carrying handle has the bearing journal. The bracket can be preassembled on the housing part and the assembly of the housing part and bracket can be supplied for further assembly as a pre-assembled assembly for further assembly. In order to prevent unwanted loosening of the preassembled connection between the carrying handle and the housing part, a stop device is provided which prevents a mounted carrying handle which has already been pivoted into an operating angular position from being able to pivot back into an assembly angular position. Preventing the carrying handle from pivoting back into a mounting angular position prevents the preassembled unit from carrying handle and housing part from unintentionally coming loose.

The first rotary bearing part can have an in particular disk-shaped shield element, from the disc center of which the bearing pin extends perpendicularly out of the plane of the shield element, the at least one stop element being arranged on the shield element at a radial distance from the bearing pin.

The design of the first pivot bearing part as a disk-shaped shield element offers extensive support of the first pivot bearing part on the second pivot bearing part, as a result of which the carrying handle is mounted on the vacuum cleaner in a very stable manner and thus high forces can also be introduced into the vacuum cleaner via the carrying handle. This results in a very precise and stable storage for the handle on the vacuum cleaner. The arrangement of the stop element at the greatest possible radial distance from the bearing journal reduces the forces acting on the stop element and on the counter stop elements when the carrying handle strikes at the end of its swivel angle range. This prevents damage to the stop elements or counter-stop elements. The stop element is preferably designed as a wedge-shaped locking lug that rises in the circumferential direction and faces the second rotary bearing part. Due to the wedge-shaped design of the locking lug, the handle can be pivoted from a mounting angular position into an operating angular position with little effort. Swiveling back from an operating angular position into an assembly angular position is possible without damaging the locking lug, at best with considerable effort.

The stop element and the approach can be formed by the same projection. This projection combined in this way serves on the one hand to prevent the pivot bearing against radial removal of the bearing journal from the bearing seat in an operating angular position and on the other hand to prevent a handle that is pivoted into an operating angular position cannot be pivoted back neither into an assembly angular position , The stop element and extension are preferably integrally formed on the first pivot bearing part in the plastic injection molding process.

In a special design, the second rotary bearing part is designed as a cup-shaped drum element in particular, in the center of which the bearing seat is arranged and on which the at least one counter-stop element is arranged at a radial distance from the bearing seat. The counter-stop element can be arranged in the region of a first and / or a second end of the ring channel delimited by the peripheral walls.

The angular position of the counter stop elements determines the maximum angular range for the operating angular positions. As an alternative to the counter-stop elements formed on the second pivot bearing part, an effective angular stop can also be realized if the carrying handle or the housing part of the vacuum cleaner carrying the carrying handle is shaped in such a way that an angular stop is achieved by the carrying handle on the housing part in its at least one end position pending. An additional counter-stop element is then no longer required at this end position.

In a simple embodiment, the counter-stop element is designed as a web which extends radially between the inner peripheral wall and the outer peripheral wall. Such a web, which is preferably between the inner and outer The peripheral wall is formed in one piece, forms a reliable stop for the stop element and additionally stabilizes the inner and outer peripheral walls.

The first pivot bearing part is preferably connected to the carrying handle and the second pivot bearing part to the housing. The bracket has the trunnions and the bearing seats are attached to the housing. This variant simplifies the production of housing parts which are produced as plastic injection molded parts and the production of the carrying handle, which is preferably blow-molded from plastic using the internal water pressure method. In special applications, however, the journals can also be formed on the housing parts and the bearing seats on the carrying handle.

In a preferred embodiment, the carrying handle extends in an arc over the contour of the vacuum cleaner, each of the two ends of the curved carrying handle having a first pivot bearing part which engages in one of two corresponding second pivot bearing parts formed opposite one another on the vacuum cleaner. The handle forms a C-shaped handle on which the vacuum cleaner can be carried swinging freely, similar to a shopping basket.

The invention also relates to a method for mounting a handle on a

Housing part of a vacuum cleaner and includes in particular the following process steps:

- Aligning the carrying handle with respect to the housing part by aligning the positioning of a projection arranged on a first pivot bearing part for radial clearance of a second pivot bearing part;

Inserting the carrying handle into the housing part of the vacuum cleaner by radially inserting at least one bearing pin of the first pivot bearing part into the radial clearance of the second pivot bearing part;

- Swiveling the inserted handle from an assembly angular position into an operating angular position until a stop element arranged on the first pivot bearing part latches behind a counter stop element arranged on the second pivot bearing part;

- Fasten the assembly formed from the handle and housing part to the vacuum cleaner. The assembly method according to the invention is characterized in particular in that the carrying handle can be preassembled on a housing part of the vacuum cleaner. No additional assembly work is required during pre-assembly to secure the handle on the housing part. Separate securing elements are omitted and can be saved. The preassembled unit of carrying handle and housing part can be fed in a simple manner to the further assembly of the vacuum cleaner. In particular, the preassembled structural unit can no longer fall apart due to a locked securing of the carrying handle on the housing part and can therefore be handled reliably and safely during the further assembly.

A preferred embodiment of a vacuum cleaner according to the invention is explained in more detail below with reference to FIGS. 1 to 5.

Show it:

Figure 1 is a front view of a vacuum cleaner according to the invention with a carrying bracket pivotally mounted on the housing;

FIG. 2 shows a partial view of a housing part of the vacuum cleaner from FIG. 1 with a second rotary bearing part arranged on the housing part and a first rotary bearing part arranged on the carrying handle;

Figure 3 is a partial sectional view of the first and second pivot bearing part of Figure 2 in an angular assembly position of the housing part and handle;

FIG. 4 shows a partial sectional view of the first and second pivot bearing part from FIG. 2 in an operating angular position of the housing part and the carrying handle in which a stop element of the first pivot bearing part is in contact with a counter stop element of the second pivot bearing part;

Figure 5 is a partial sectional view of the first and second pivot bearing part of Figure 2 in an operational rest position of the handle. An embodiment of a vacuum cleaner according to the invention is shown in Figure 1. The vacuum cleaner has a multi-part housing 1, in which functional components (not shown) of the vacuum cleaner are accommodated. A first housing part 2 forms an upper shell, which is placed on a second housing part 3 forming a lower shell. On an outer bottom side 4 of the housing part 3, rollers 5 are rotatably and pivotally mounted. The housing part 3 has a rigidly attached handle 6. In addition to the handle 6, an additional handle 7 is provided. The carrying handle 7 is pivotally connected to the first housing part 2 by means of two pivot bearings 8 arranged opposite one another. The carrying handle 7 extends from a side of the vacuum cleaner shown on the left in FIG. 1 to an opposite side of the vacuum cleaner shown on the right in FIG. 1. The handle 7 is bent in a U-shape, extends over the top of the vacuum cleaner at a distance from the first housing part 2 and has a first pivot bearing part 9 at each of its two ends, which together with corresponding second pivot bearing parts 10, which on the first housing part 2 are attached opposite to form the pivot bearing 8. In the position shown in Figure 1, the handle 7 is in an operating swivel angle position in which the vacuum cleaner can be carried by a user. In a rest position, not shown in FIG. 1, the handle 7 rests on the surface of the first housing part 2.

In Figure 2, the first housing part 2 and the handle 7 is shown in a partial view. One of the two rotary bearings 8 from FIG. 1 is shown in the disassembled state. The first pivot bearing part 9 is shown folded away from the second pivot bearing part 10 into the plane of the drawing in order to show the inside of the first pivot bearing part 9 and the second pivot bearing part 10. The first pivot bearing part 9 has a disk-shaped shield element 11 which is molded directly onto the carrying handle 7. An annular peripheral wall 12 is formed around the outer circumference of the shield element 11. Starting from this circumferential wall 12, a plurality of stiffening ribs 14 extend in a star shape to the inside of a disk center 13. In the area of the disk center 13, the stiffening ribs 14 converge on a cylindrical bearing journal 15. The bearing pin 15 is formed on the shield element 11, extending vertically out of the plane of the shield element 11. At an axial distance A from the plane of the shield element 11 is in the region of a free end 16 of the journal 15 Projection 17 integrally formed. The projection 17 is designed as a dovetail-shaped tongue which extends in the radial direction away from the bearing journal 15 and parallel to the plane of the shield element 11. Below the projection 17, a space segment 18 delimited by two stiffening ribs 14 is filled in full material. A stop element 19 is formed on a surface of the space segment 18 facing the second pivot bearing part 10 in the assembled state. The stop element 19 is arranged at a radial distance B from the bearing journal 15 and is wedge-shaped. The wedge-shaped stop element 19 has a flank 19a which rises gently in the clockwise direction in FIG. 2 and a flank 19b which falls steeply in the counterclockwise direction in FIG. The stop element 19 and the projection 17 are aligned with one another on the first pivot bearing part 9 such that they lie in the region of the same space segment 18 of the disk-shaped shield element 11.

The second rotary bearing part 10 formed on the first housing part 2 is designed as a cup-shaped drum element 20. The drum element 20 has a circular disk-shaped bottom surface 21, which at the same time forms a side wall 22 of the first housing part 2. A cylindrical jacket wall 23 of the drum element 20 extends perpendicular to the side wall 22 along the edge of the circular disk-shaped bottom surface 21. A bearing seat 24 is arranged in the center of the drum element 20 coaxially with the cylindrical jacket wall 23. The bearing seat 24 has an annular wall 25 on which the pivot pin 15 of the first pivot bearing part 9 is rotatably mounted in the assembled state of the pivot bearing 8. The ring wall 25 does not run closed over the entire circumference, but only over part of the circumference.

The clear width over which the annular wall 25 is provided with a radial cutout 26 and is thus designed to be open is somewhat wider than the diameter of the bearing journal 15 on the first rotary bearing part 9. The radial cutout 26 extends not only over the annular wall 25 but also over it the bottom surface 21 up to the casing wall 23, shown in FIG. 2, starting from the center of the second rotary bearing part 10, running vertically downwards. In an angular assembly position of the first pivot bearing part 9 and the second pivot bearing part 10, the projection 17 is aligned with the radial clearance 26, so that the first pivot bearing part can be inserted into the second pivot bearing part in the axial or radial direction until the bearing journal 15 is inserted in the bearing seat 24 and is held. If the handle 7 or the first pivot bearing part is now removed from the assembly Rotated angular position into an operating angular position, the projection 17 slides behind an end face 27 of the side wall 22 or the bottom surface 21 facing the interior of the vacuum cleaner. If the projection 17 is no longer aligned with the radial clearance 26, an axial separation of first pivot bearing part 9 and second pivot bearing part 10 prevented. In order to radially secure the bearing journal 15 in the bearing seat 24, a locking section 28 is formed on the second housing part 3. The locking section 28 is designed as a housing projection molded onto the second housing part, which corresponds in shape and size to the radial cutout 26.

As an alternative or in addition to a radial securing of the bearing journal 15 in the bearing seat 24 by means of the locking section 28 formed on the second housing part, a second projection is provided on the first pivot bearing part 9. This second projection is designed as an axially extending projection 29 formed on the segment 18 of the first rotary bearing part 9 at a radial distance from the axis of rotation. The radial securing takes place by the engagement of the projection 29 in a recess which is designed as an annular ring channel 30 which is open in the axial direction when the carrying handle 7 or the first rotary bearing part 9 is in an operating angular position. The ring channel 30 extends in the form of an annular segment coaxially with the bearing seat 24 and is delimited by an inner circumferential wall 31 and an outer circumferential wall 32. The inner circumferential wall 31 and the outer circumferential wall 31 extend by leaving the radial recess 26 free by less than the total circumference of the second rotary bearing part 10. The inner circumferential wall 31 and the outer circumferential wall 31 are evenly distributed over the circumference to stabilize their shape by means of a plurality of radially aligned Ribs 33 supported. The ribs 33 are formed between the circumferential walls 31 and 32 and have a height which is chosen to be sufficiently small so that the stop element 19 or the shoulder 29 can slide over the ribs 33 when the pivot bearing 8 is in the assembled state.

However, at least one rib extends over the entire height of the peripheral walls 31 and 32 and thereby forms a counter stop element 34 for the stop element 19. The counter stop element 34 is arranged in the region of one end of the annular channel 30 delimited by the peripheral walls 31 and 32. In an assembly angular position (FIG. 3) of the first pivot bearing part 9 and the second pivot bearing part 10, the stop element 19 is located within the radial clearance 26 on a radial circumference of the ring channel 30. By pivoting the carrying handle 7 in a direction running counterclockwise in FIG. 3, the first pivot bearing part 9 is rotated relative to the fixed second pivot bearing part 10 into an operating angular position. The stop element 19 moves counterclockwise from below towards the counter stop element 34. The gently rising flank 19a of the stop element 19 slides over a ramp 35 upstream of the counterstop element 34 and snaps into the ring channel 30 behind the counterstop element 34. If the carrying handle 7 is pivoted back clockwise from this operating angular position reached (FIG. 4), the stop element 19 with its steeply falling flank 19b comes to rest on a side of the counterstop element 34 opposite the ramp 35. Due to the steeply falling flank 19b and the lack of a ramp on this side, the stop element 19 cannot slide over the counter-stop element 34 and pivoting of the carrying handle 7 from the operating angular position into the mounting angular position (FIG. 3) is reliably prevented. In a direction of rotation opposite to the stop direction from FIG. 4, for example counterclockwise (FIG. 5), a separate second counterstop element can be dispensed with if pivoting of the handle 7 beyond the operating angle into an assembly angle position is prevented because the carrying handle 7 comes to rest against the contour of the first housing part 2 before the mounting angular position is reached. The first housing part 2 forms the counter-stop element which acts directly on the carrying handle 7. In the position shown in Fig. 5, the handle is in an operational rest position on the vacuum cleaner.

Claims

claims

1. Vacuum cleaner with a housing (1) and a carrying handle (7), which by means of at least one pivot bearing (8), the first pivot bearing part (9) and a relative to the first pivot bearing part (9) rotatable about a common axis of rotation second pivot part (10 ), between two end positions of an operating pivot angle with respect to the housing (1), is pivotally mounted, characterized in that the pivot bearing (8) for joining or separating the first pivot bearing part (9) from the second pivot bearing part (10) in one outside the operating swivel angle is formed mounting angle position.

2. Vacuum cleaner according to claim 1, characterized in that the first pivot bearing part (9) has a bearing journal (15) and the second pivot bearing part (10) has a bearing seat (24) with a recess (26) through which the bearing journal (15) in the bearing seat (24) can be used.

3. Vacuum cleaner according to claim 2, characterized in that the bearing pin (15) has a radially outwardly extending projection (17) which is aligned with the recess (26) in the mounting angular position.

4. Vacuum cleaner according to claim 3, characterized in that the projection (17) for axially securing the bearing journal (15) in the bearing seat (24) is supported on an end face (27) of the second rotary bearing part (10).

5. Vacuum cleaner according to one of claims 2 to 4, characterized in that the cutout (26) of the second pivot bearing part (10) is radially open to the edge and has a clear width which is adapted to the diameter of the bearing journal (15) such that the bearing journal (15) can be used in the mounting angular position in a radial direction in the bearing seat (24).

6. Vacuum cleaner according to claim 5, characterized in that the housing (1) has a first housing part (2) on which the radially open-cut recess (26) is formed and has a second housing part (3) on which a locking section (28 ) is designed to close the recess (26).

7. Vacuum cleaner according to claim 6, characterized in that the locking section (28) is designed as a wedge-shaped, in the radially open cutout (26) of the first housing part (2) engaging housing projection of the second housing part (10).

8. Vacuum cleaner according to one of claims 2 to 7, characterized in that the projection is an axially extending at a radial distance from the axis of rotation arranged approach (29) on the first rotary bearing part (9) which in a coaxial to the axis of rotation annular channel (30) engages on the second pivot bearing part (10).

9. Vacuum cleaner according to claim 8, characterized in that the annular channel (30) forms a guide path for the extension (29) delimited by an inner peripheral wall (31) and an outer peripheral wall (32).

10. Vacuum cleaner according to claim 9, characterized in that the peripheral walls (31, 32) extend to the radial clearance (26).

11. Vacuum cleaner according to one of the preceding claims, characterized in that at least one stop element (19) arranged on the first pivot bearing part (9) is assigned to at least one counter stop element (34) on the second pivot bearing part (10), such that pivoting of the handle (7 ) is prevented from the area of the operating swivel angle into the mounting angular position.

12. Vacuum cleaner according to claim 11, characterized in that the first rotary bearing part (9) has a particularly disc-shaped shield element (11), from the disc center of which the bearing pin (15) extends vertically out of the plane of the shield element (11) and on the shield element (11) the at least one stop element (19) is arranged at a radial distance from the bearing journal (15).

13. Vacuum cleaner according to claim 11 or 12, characterized in that the stop element (19) is designed as a wedge-shaped, rising in the circumferential direction locking lug facing the second rotary bearing part (10).

14. Vacuum cleaner according to one of claims 11 to 13, characterized in that the stop element (19) and the projection (29) are formed by the same projection.

15. Vacuum cleaner according to one of claims 11 to 14, characterized in that the second rotary bearing part (10) is designed as an in particular cup-shaped drum element (20), in the center of which the bearing seat (24) is arranged, and at which at a radial distance Bearing seat (24) which is arranged at least one counter stop element (34).

16. Vacuum cleaner according to one of claims 9 to 15, characterized in that the counter-stop element (34) is arranged in the region of a first and / or a second end of the annular channel (30) delimited by the peripheral walls (31, 32).

17. Vacuum cleaner according to claim 16, characterized in that the counter abutment element (34) is designed as a web extending radially between the inner peripheral wall (31) and the outer peripheral wall (32).

18. Vacuum cleaner according to one of the preceding claims, characterized in that the first pivot bearing part (9) with the bracket (7) and the second pivot bearing part (10) is connected to the housing (1).

19. Vacuum cleaner according to one of the preceding claims, characterized in that the carrying bracket (7) is arcuate over the contour of the vacuum cleaner and each of the two ends of the Arc-shaped carrying handle (7) has a first pivot bearing part (9) which engages in one of two corresponding pivot pivot parts (10) formed opposite one another on the vacuum cleaner.

20. A method for mounting a handle (7) on a housing part (1, 2, 3) of a vacuum cleaner with the following steps:

- Aligning the carrying bracket (7) with respect to the housing part (1, 2, 3) by aligning a projection (17, 19, 29) arranged on a first pivot bearing part (9) to provide radial clearance (26) for a second pivot bearing part (10) ;

- Inserting the carrying handle (7) into the housing part (1, 2, 3) of the vacuum cleaner by radially inserting at least one bearing pin (15) of the first rotary bearing part (9) into the radial recess (26) of the second rotary bearing part (10); - Swiveling the inserted support bracket (7) from an angular mounting position into an operating angular position until a stop element (19) arranged on the first pivot bearing part (9) latches behind a counter stop element (34) arranged on the second pivot bearing part (10); - Fasten the assembly formed from the handle (7) and housing part (1, 2, 3) to the vacuum cleaner.