WO2006111536A1

WO2006111536A1 - Flexible suction hose for a vacuum cleaner

Info

Publication number: WO2006111536A1
Application number: PCT/EP2006/061651
Authority: WO
Inventors: Michael Krammer
Original assignee: BSH Bosch und Siemens Hausgeräte GmbH
Priority date: 2005-04-20
Filing date: 2006-04-19
Publication date: 2006-10-26
Also published as: EP1885228A1; CN101163435A; DE102005018373A1

Abstract

The invention relates to a flexible suction hose for a vacuum cleaner with peripheral bellows waves (14) that form successive depressions (18) and elevations (20) in the direction of flow (24) on the inside (16) of the hose. In order to improve the flexible suction hose regarding the flow behavior thereof, at least one planar element (22, 30) which extends substantially in the circumferential direction and in the direction of flow (24) while at least partly covering the depressions (18) is disposed on the inside (16) of the hose.

Description

Description FLEXIBLE SUCTION TUBE OF A VACUUM CLEANER

The invention relates to a flexible suction hose according to the preamble of claim 1 and a vacuum cleaner with a flexible suction hose according to the invention.

Suction hoses for vacuum cleaners can be prepared by extrusion according to the prior art. In this case, we created a channel-shaped elongated element and subsequently wound spirally, so that a suction hose with spirally encircling bellows waves arises. These give the hose the necessary flexibility and stability with low weight. The channel-shaped element can also already have a plurality of parallel bellows shafts. Such a flexible hose has the disadvantage of whistling noises, especially at today's high flow velocities of the sucked-in air. Also accumulates in the Balgwellentätern inside the tube in an undesirable manner dirt, which represents an allergy and hygiene risk.

A suction hose is known from EP 1 099 894 B1, in which a special geometry of the hose inside elevations and depressions is proposed to eliminate annoying whistling noises and to improve the flow resistance when flowing through air. In particular, a special relationship between the extent of the elevations in the flow direction and the expansion of the recesses in the flow direction is considered to be advantageous. The disadvantage, however, is that the structure described in EP 1 099 894 B1 is complicated and that dirt deposits are not avoided.

The invention has for its object to overcome the disadvantages of the prior art and in particular to provide a flexible suction hose with improved flow behavior.

This object is solved with the features of the independent claim.

Advantageous embodiments and modifications of the invention will become apparent from the dependent claims.

The invention is based on the generic device in that at least one substantially flat in the flow direction and extending in the circumferential direction element is arranged on the tube inside, which covers the wells at least partially. Such a planar element lowers the specific flow resistance of the suction hose. As it flows through the suction hose is prevented from flowing into the wells. Thus, flows propagating perpendicular to the preferential flow direction are prevented, and a laminar air flow is promoted. By reducing a tendency to form turbulence, the flow resistance is significantly reduced. At the same time, the deposition of dust or the like in the depressions is effectively reduced by the at least partial covering of the depressions. Furthermore, the arrangement of such a sheet-like element, the previous extrusion-based manufacturing process substantially with only minor changes to be kept. Furthermore, the weight of the suction hose is only slightly increased and its flexibility is substantially maintained. It is to be regarded as particularly advantageous if the planar element completely covers the recesses, in particular even with particularly small bending radii of the suction hose.

A particularly preferred embodiment provides that in

Circumferential direction and in the flow direction extending planar element overlaps at least partially in the flow direction. Due to the arrangement of the planar element in such a way that it partially overlaps itself in the direction of flow, the air moving in the direction of flow is provided with an almost closed surface on the inside of the tube. Instead of a previously swirled by the rib-like structure air flow now a substantially laminar flow can take place. It can be provided in particular that the overlap takes place so far that even with small bending radii of the suction hose sufficient overlap and thus improved air flow is achieved.

A preferred embodiment of the invention results from the fact that a plurality of extending in the circumferential direction and in the flow direction planar elements are provided. The arrangement of a plurality of planar elements on the inner side of the tube may be preferred in the context of an existing manufacturing method, in particular if the manufacturing process provides for the winding of a trough-shaped structure with a plurality of bellows shafts.

In this context, it is preferred that the plurality of planar elements extending in the circumferential direction and in the flow direction overlap each other at least partially in the flow direction. Thus, the advantages of a lower tendency to turbulence and a predominantly laminar flow are also achieved.

A likewise particularly preferred embodiment results from the fact that the extending in the circumferential direction and in the flow direction planar element forms an inner tube. The formation of the planar element as a continuous inner tube reduces the flow resistance of the suction hose at least almost to that of a smooth hose. In this way, turbulences caused by the geometry of the suction hose are further avoided. The accumulation of airborne dirt particles and a possibly associated odor development or bacterial load are further reduced. This may also be advantageous in the use of the suction tube in the environment of people suffering from allergies. Such a continuous inner tube is preferably arranged in a production step subsequent to the production process of the suction hose.

It may be particularly advantageous that between the

Suction hose and the inner hose at least one electrical line is located. On the one hand, such an Incord solution makes possible an arrangement of the electrical line within the suction hose which is favorable in terms of manufacturing technology and offers protection at the same time the advantages of a fluidically smooth inner surface of the suction hose.

A further advantageous embodiment results from the fact that the material of the extending in the circumferential direction and in the flow direction planar element differs from that of the suction hose. The choice of different materials for the suction hose and the flat element arranged therein means a further degree of freedom in optimizing the internal flow resistance of the suction hose. The material for the planar element can be chosen so that results in a favorable flow behavior of the sheet-like element. At the same time, the flexibility and stability of the suction hose can be set independently.

In particular, it can be provided that the material of the extending in the circumferential direction and in the flow direction planar element is more flexible than that of the suction hose. If the planar element is designed to be more flexible than the suction hose itself, the planar element can adapt to the flow direction during a curvature of the outer suction hose taking place and cover the depressions. Furthermore, the flexibility of the suction hose is only slightly changed by the presence of the planar element.

The invention further relates to a vacuum cleaner with a flexible suction hose according to one of the preceding claims.

The invention is based on the finding that flexible scales on

Elevations of a suction hose encircling bellows shafts that cover the depression following the survey, or a thin flexible inner tube within a suction hose provided with bellows waves significantly reduce the flow resistance of the suction hose. Such a suction hose is easily produced in the context of existing manufacturing processes, and it has an improved flow guidance.

The invention will now be described with reference to the attached

Drawings exemplified with reference to preferred embodiments.

[0018] FIG.

Figure 1 is a cross-sectional view of a first embodiment of the invention and

Figure 2 is a cross-sectional view of a second embodiment of the invention.

FIG. 1 shows a cross-sectional view of a first embodiment according to the invention. In this case, a section 10 of a suction hose for a vacuum cleaner is shown in a schematic representation. The suction hose is made by continuous extrusion. The wall 10 of the suction hose has spiral-shaped circumferential bellows shafts 14. These can, seen from the interior 16 of the tube section 10, in depressions 18 and elevations 20 subdivide. Sheds 22 are attached to the elevations 20. These extend from a survey 20 away in the flow direction 24 to over the next survey 20. The material of the scale 22 is compared to the material of the wall 12 softer. The scale 22 is in the manufacturing process the outer wall 12 extruded. With regard to the illustrated size ratios, it should be noted that this is merely a schematic representation intended to explain the mode of operation.

In operation, the functionality of the scale 22 is designed as follows: The air flowing in the following direction 24 incoming air is passed through the scale 22 substantially. Since the scale 22 from one elevation 20 to the next the fluidically unfavorable undercut, that is, the recess 18, covered, the air flow follows substantially the predetermined by the scale 22 main direction 24. An otherwise common turbulence formation is suppressed. The air is mainly guided laminar and swirling through the recesses 18 is avoided. At the same time, the existing advantages of the suction hose produced by extrusion, such as high flexibility and stability, are preserved. The weight of the suction hose increases only slightly by the attached scales 22. The flexibility or the mobility of the scale 22 can be adjusted by their geometry and by the choice of material within certain limits, regardless of the properties of the wall 12 of the suction hose. Depending on the flow rate used, the geometry of the scales can also be adapted. Likewise, a shortening of the scale 22 can be realized by a fluidic modeling of the scale. Further advantages of the invention result from the fact that accumulation of dirt in the recesses 18 is reduced. In addition, unpleasant noises can be reduced by the extensive laminar flow of the air.

FIG. 2 shows a cross-sectional view of a second embodiment according to the invention. The section 10 of the illustrated suction hose for a vacuum cleaner is identical in its external configuration to that of the embodiment described for FIG. It also has an outer wall 12 made by extrusion which exhibits spirally revolving bellows shafts 14. These can also be seen from the inner tube 16 of 16 divided into depressions 18 and elevations 20. Instead of the attached in Figure 1 at the elevations 20 scales 22 a continuous second inner tube 30 is introduced in this embodiment. This can either be extruded in with a corresponding inner diameter or can be introduced as a smaller tube which is inflated. The inner tube 30 constitutes a thin, flexible sheath of material that, unlike the material of the outer wall 12, has been selected for fluidic considerations.

In this second embodiment, the flow direction 24 following air is guided exclusively through the inner tube 30. This thus has a nearly ideal cross-sectional geometry, which offers a significantly reduced flow resistance compared to conventional hoses. The advantages of the first embodiment also apply here; The deposition of dirt and the formation of unpleasant background noise are even better suppressed due to the closed inner wall. As an additional advantage, it follows that the between the outer wall of the inner tube 30th and the inner surface of the outer wall 12 of the Saugschlauchabschnitts 10 cavities formed can be used for example for the accommodation of electrical lines or the like. Due to the complete separation of outer tube 10 and inner tube 30, both materials can be selected relatively independently. At the same time, the manufacturing process for the outer tube 10 remains unchanged, while the introduction of the inner tube 30 represents an additional manufacturing step. Under certain circumstances, by a suitable selection of the geometries and materials, an overall lower use of materials can be achieved.

The disclosed in the foregoing description, in the drawings and in the claims features of the invention may be essential both individually and in any combination for the realization of the invention.

[0026] List of Reference Numerals

10 suction hose section

12 Saugschlauchwandung

[0029] 14 bellows shaft

16 suction hose interior

18 depression

20 survey

22 scale

24 flow direction

30 inner tube

Claims

claims

1. Flexible suction hose for a vacuum cleaner with circumferential bellows shafts (14) on the hose inside (16) in the flow direction (24) successive recesses (18) and elevations (20) form, characterized in that on the hose inner side (16) at least a planar element (22, 30) extending essentially in the flow direction (24) and in the circumferential direction is arranged, which at least partially covers the depressions (18).

2. Flexible suction hose according to claim 1, characterized in that in the circumferential direction and in the flow direction (24) extending planar element (22, 30) overlaps at least partially in the flow direction (24).

3. Flexible suction hose according to claim 1 or 2, characterized in that several in the circumferential direction and in the flow direction (24) extending planar elements (22, 30) are provided.

4. Flexible suction hose according to claim 3, characterized in that the plurality of circumferentially and in the flow direction (24) extending planar elements (22, 30) overlap each other at least partially in the flow direction (24).

5. Flexible suction hose according to claim 1, characterized in that in the circumferential direction and in the flow direction (24) extending planar element (22, 30) forms an inner tube (30).

6. Flexible suction hose according to claim 5, characterized in that there is at least one electrical line between the suction hose and the inner tube (30).

7. Flexible suction hose according to one of the preceding claims, characterized in that the material of the circumferentially and in the flow direction (24) extending flat element (22, 30) differs from that of the suction hose.

8. Flexible suction hose according to claim 7, characterized in that the material of the circumferentially and in the flow direction (24) extending planar element (22, 30) is more flexible than that of the suction hose.

9. Vacuum cleaner with a flexible suction hose according to one of the preceding claims.