阅读说明：本技术 用于清洗设备的刷子 (Brush for cleaning equipment ) 是由 L·法瓦格罗萨 于 2018-09-27 设计创作，主要内容包括：一种用于车辆清洗系统的刷子，该刷子包括：柔性元件(2)，该柔性元件旨在与车辆接触而用以进行清洁和/或抛光和/或干燥；中心环形支承件(3)，柔性元件(2)从中心环形支承件延伸；绕其自身的旋转轴线(40)旋转的轴(4)，所述轴(4)与所述中心支承件(3)交叉并使所述中心支承件(3)绕所述旋转轴线(40)旋转。中心支承件(3)包括侧表面(35)，柔性元件(2)从该侧表面延伸，该侧表面相对于轴(4)的旋转轴线(40)倾斜。(A brush for a vehicle washing system, the brush comprising: a flexible element (2) intended to be in contact with a vehicle for cleaning and/or polishing and/or drying; a central annular support (3) from which the flexible element (2) extends; -a shaft (4) rotating about its own axis of rotation (40), said shaft (4) crossing said central support (3) and rotating said central support (3) about said axis of rotation (40). The central support (3) comprises a lateral surface (35) from which the flexible element (2) extends, which is inclined with respect to the rotation axis (40) of the shaft (4).)

1. A brush for a vehicle washing system, the brush comprising:

-a flexible element (2) intended to be in contact with the vehicle for cleaning and/or drying and/or polishing;

-a central annular support (3) from which said flexible element (2) extends;

-rotating a shaft (4) around its own axis of rotation (40), said shaft (4) crossing said central support (3) and rotating said central support (3) around said axis of rotation (40);

characterized in that said central support (3) comprises a lateral surface (35) from which said flexible element (2) extends, said lateral surface being inclined with respect to said rotation axis (40) of said shaft (4).

2. Brush according to claim 1, characterized in that, starting from the central support (3), a first group (21) of the flexible elements (2) in a projecting and rectilinear configuration extends upwards and a second group (22) of the flexible elements (2) in a projecting and rectilinear configuration extends downwards; said first group (21) and said second group (22) of flexible elements (2) are located in diametrically opposite positions.

3. Brush according to any one of the preceding claims, characterized in that the support (3) defines a longitudinal axis (300) about which the support (3) extends annularly, the longitudinal axis (300) being incident and inclined with respect to the rotation axis (40) of the shaft (4).

4. Brush according to any one of the preceding claims, characterized in that the lateral surface (35) comprises a first portion (351) tapering downwards and a second portion (352) tapering upwards, which are continuous along the lateral surface (35) in the direction of rotation of the support (3).

5. Brush according to any of claims 1-3, characterized in that the central support (3) comprises an annularly folded flexible strip (39).

6. Brush according to claim 5, characterized in that the flexible element (2) comprises a longitudinal string; the belt (39) comprises a plurality of housings (390) distributed around the shaft (4); the longitudinal cords of the corresponding bundle protrude from a plurality of said housings (390).

7. Brush according to any of claims 1-4, characterized in that the flexible element (2) comprises a longitudinal strip (20).

8. Brush according to claim 7, characterized in that the central support (3) comprises retaining means (30) for retaining a strip folded about its own transverse axis to form two of the strips (20) flanking each other; the holding device (30) comprises a fastening rod (31) having a main direction of extension (310):

i) the fastening rod is inclined with respect to a direction (400) determined by the rotation axis (40) of the shaft (4);

ii) such that an imaginary extension of the fastening rod (31) along the main extension direction (310) extends towards the shaft (4) or along the rotation axis (40) towards an imaginary extension of the shaft (4).

9. Brush according to claim 7 or 8, characterized in that the end of the strip (20) at the support (3) extends along a line inclined with respect to the rotation axis (40).

10. Brush according to any one of the preceding claims, characterized in that it comprises a plurality of toroidal supports (3) continuous with each other along said axis (4) and crosswise to the same axis (4).

11. A brush for a vehicle washing system, the brush comprising:

-a flexible element (2) intended to be in contact with the vehicle for cleaning and/or drying and/or polishing;

-a central annular support (3) from which said flexible element (2) extends;

-rotating a shaft (4) around its own axis of rotation (40), said shaft (4) crossing said central support (3) and rotating said central support (3) around said axis of rotation (40);

characterized in that said central support (3) defines an upper surface which encloses a circle or another figure intersecting said axis (4); a line passing through the geometric centre of gravity of the circle or other figure and orthogonal to the circle or other figure is inclined with respect to the axis of rotation (40) of the shaft (4).

Technical Field

The present invention relates to a brush for a vehicle washing system (of cars, trains, public transport means, etc.). It can be used for cleaning and/or drying and/or polishing the bodywork of a vehicle. It may be used in particular in automatic cleaning systems used for example, but not exclusively, in roadside service stations.

Background

Known brush types include:

-a drive shaft;

-an annular support to which the flexible strip is constrained; during operation, the strips are aligned in radial and horizontal directions and are in contact with the vehicle due to the effect of centrifugal force; these supports are stacked on top of each other and crossed, supported and rotated by a shaft.

Suitably, the strap extending from one of the central supports is at a distance from the strap extending from a central support immediately above or below it. This is due both to size constraints and to prevent the strips of two adjacent supports from overlapping, thus penalizing the correct functioning of the brush. A disadvantage of this solution is that at such distances the washing of the vehicle is less effective and therefore less uniform.

Each central annular support may have a height, referenced between 8 and 35 centimeters. As previously mentioned, the aim is to exert its effect on the entire side of the vehicle, so that a large number of central annular supports must be stacked on top of one another. This has an effect on the weight, resulting in higher energy consumption. The high weight also requires a suitable structural size of the system. All this implies higher costs.

By rotating brushes of the various types described above, cleaning and automatic washing of the vehicle bodywork is achieved in that, when water and/or washing solutions or emulsions are introduced, the strips, which are pushed by centrifugal force, hit the bodywork.

Disclosure of Invention

Against this background, the technical task on which the present invention is based is to provide a brush which eliminates the drawbacks of the prior art described above.

In particular, the object of the present invention is to provide a brush that allows to improve the cleaning effect, the washing uniformity and the breadth of the surface to be treated, while allowing to reduce the noise and to produce a more delicate effect on the paint of the vehicle.

The technical task and the specific objects are substantially achieved by a brush comprising the technical features set forth in one or more of the appended claims.

Drawings

Other characteristics and advantages of the invention will become better apparent from the following description, which is illustrative and not restrictive, of a preferred but not exclusive embodiment of a brush, as illustrated in the accompanying drawings, wherein:

figures 1a and 1b show a brush according to the invention at two different moments during rotation;

figure 2 shows a detail of the brush according to the invention;

figures 3a and 3b show a brush according to the invention in place of the brush in figure 1 at two different moments in rotation;

figure 4 shows an exploded view of a brush according to the invention;

figures 5 and 6 show parts according to the invention and alternative to the brushes of the previous examples;

figure 7 shows a detail view of a brush according to another alternative;

figure 8 shows a cross-section along the plane a-a in figure 7;

figure 9 shows a cross-section along the plane B-B in figure 7;

figure 10 shows a cross-section along the plane C-C in figure 7;

figure 11 shows a schematic cross-section of another version of the brush according to the invention;

figure 12 shows a schematic top view of the component shown in figure 11 resting on a horizontal plane;

figure 13 shows a schematic cross-section of another version of the brush according to the invention;

figure 14 shows a schematic top view of the component shown in figure 13 resting on a horizontal plane;

figure 15 shows a schematic cross-section of another version of the brush according to the invention;

figure 16 shows a schematic top view of the component shown in figure 15 resting on a horizontal plane.

Detailed Description

In the drawings, reference numeral 1 denotes a brush for an automatic vehicle washing system.

Such a brush 1 may comprise a flexible element 2 intended to be in contact with a vehicle for cleaning and/or drying and/or polishing. The flexible element 2 may for example be made of expanded plastic, EVA or another flexible expanded material with or without closed cells, or a fabric, a non-woven fabric, or even a combination of materials.

In the solution shown for example in fig. 1a, 1b, 2, 3a, 3b, 4, 7-10, the flexible element 2 comprises/coincides with a strip 20.

In a preferred embodiment, the strip 20 is fringed. In other words, there is a longitudinal cut at least at the most radially outer end of the strip 20. Such cuts may affect all or part of the longitudinal extension of the strip 20.

The flexible element 2 may comprise/coincide with the longitudinal threads. They have a linear extension. This may be the case, for example, using the components shown in fig. 5 and 6, as will be explained more clearly below.

The brush 1 comprises a central annular support 3 around which the flexible element 2 is applied. In the solutions shown in fig. 1a, 1b, 2, 3a, 3b, 4, 7-10, the support 3 is preferably rigid. Suitably, the central support 3 is made of plastic. The support 3 is preferably a cylindrical tube. As mentioned above, the flexible element 2 used with the rigid support 3 is a strap 20.

In the solution shown by way of example in fig. 5 and 6, the support 3 comprises/coincides with the flexible band 39 folded in a loop. Fig. 5 shows such a belt 39 in an extended (unfolded) configuration, and fig. 6 shows such a belt 39 in an operating configuration, in which it is folded annularly.

The belt 39 preferably comprises a plurality of housings 390 distributed around the axis 4 (for simplicity, only some of such housings 390 are shown in figures 5 and 6; these housings 390 are advantageously distributed along the surface of the belt 39). In the solution illustrated in fig. 5 and 6, such housing 390 may be cavities, from each of which said longitudinal cords (not shown) of the corresponding bundle protrude.

In an alternative not shown, the flexible strip 39 may comprise a slot from which the corresponding strip protrudes. The strips are retained in the slots by corresponding retaining bars. These bars at least partially obstruct the slot, leaving two lateral slits to let two edges of the same strip exit transversely to the predominant extension direction (thus, although in a different context in fig. 4, a solution similar to that shown is obtained and better described below).

The brush 1 comprises a shaft 4, which shaft 4 is rotatable about its axis of rotation 40. Advantageously, the axis 40 extends between the top and the bottom, in particular the axis 40 is vertical. Possibly (solution not shown), the axis 40 may be oriented horizontally.

Indeed, typically in a washing system, there is a combination of at least two brushes and at least one horizontal brush rotating about respective axes extending between the top and the bottom.

The shaft 4 intersects the central support 3 and rotates the central support 3 about the rotation axis 40. Thus, the shaft 4 is constrained to the support 3. The shaft 4 and the support 3 are thus firmly constrained to each other. In this connection, the central support 3 and the shaft 4 comprise connection means 42 realized by interference/interlocking (in the alternative, such connection may be realized by screw connection means or another type of connection means). The connecting means 42 advantageously comprise a shape provided on the surface of the shaft 4 and/or on the surface of the central support 3 facing the shaft 4.

The central support 3 comprises a lateral surface 35 from which the flexible element 2 extends (in this document, the description with reference to the lateral surface 35 may be repeated with reference to the lateral wall 350 of the support 3 incorporating this surface 35). In a preferred version, the portion of the lateral surface 35 from which the flexible element 2 extends is at least partially inclined with respect to the rotation axis 40 of the shaft 4. Thus, the directrix of surface 35 is not parallel to axis 40. In this connection, the connecting means 42 may comprise a wedge-shaped element (not shown) interposed between the shaft 4 and the lateral surface 35 of the support 3 (solution of fig. 1a, 1b, 2, 3a, 3b, 4, 5, 6). Advantageously, such wedge-shaped elements may be made integral with the support 3 (solution not shown), or may be coupled to the shaft 4 or to the support 3. The wedge shape thus allows no coaxiality (misalignment) between the shaft 4 and the support 3.

The central support 3 comprises retaining means 30 for retaining the folded strip (sheet) 30 (transversely to the main direction of extension). In this way, two of said strips 20 are formed, flanking each other (on either side, respectively) (see for example the strips indicated by the reference numerals 20a and 20b in fig. 4). Advantageously, all the strips 20 are obtained in pairs in this way. The retaining device 30 comprises a fastening rod 31, the fastening rod 31 having a main extension direction 310 (in the alternative, the connection may be made by means of screws, rivets, plugs, (velcro) fasteners, seams, etc.). The fastening rod 31 is removably connected to the rest of the central support 3. The strips forming the pair of straps 20 are folded around the fastening rods 31. Suitably, the fastening rod 31 is inserted in a bayonet manner into the rest of the support 3. In particular, the fastening rod 31 is inserted in one of the slots 38 provided along the lateral surface 35 of the support 3. Such slots 38 are preferably oriented along a directrix of the side surface 35 of the support 3 (however, in the alternative, they may be inclined with respect to this directrix). In particular, each pair of straps 20 is constrained by a corresponding fastening rod 31.

The generatrix of the side surface 35 is not necessarily a straight line, but may be a curved line. Furthermore, the inclined surface 35 may have valleys and/or protrusions (relief), for example due to the presence of the slots 38 closed by the fastening rods 31 (creating uneven side surfaces 35).

Suitably, the end of the belt 20 located at the support 3 extends along a line (preferably a straight line) inclined with respect to the rotation axis 40.

The fastening rod 31 is inclined with respect to a direction 400 determined by the rotation axis 40 of the shaft 4.

The fastening rod 31 extends along an imaginary extension of its main extension direction 310 towards the shaft 4 or an imaginary extension of the shaft 4. The fastening rods 31 and/or corresponding slots may be linear or curved (e.g., defining a segment of a spiral).

Starting from the central support 3, a first group 21 of said flexible elements 2, in a projecting and rectilinear configuration, extends upwards and a second group 22 of said flexible elements 2, in a projecting and rectilinear configuration, extends downwards. In an alternative not shown, the flexible elements 2 of one of the first 21 and second 22 sets can extend horizontally in an extended and straight configuration. In this way, a series of flexible elements 2 hit the vehicle at different heights, simulating an oscillating movement that optimizes the washing. This is a result of the side surface 35 being inclined with respect to the axis 40. Suitably, the central support 3 comprises two opposite bases 36, 37, between which two opposite bases 36, 37 the lateral surface 35 extends. Suitably, any strap 20 extends at least 50%, preferably at least 75%, of the distance between the two opposing bases 36, 37.

Reference will now be made, by way of example, to fig. 1a, 1b, 2, 3a, 3b, 4, 5, 6. The first set 21 and the second set 22 of strips 20 are at least partially located at diametrically opposite positions.

Suitably, the central support 3 is not coaxial with the axis of rotation 40 of the shaft 4.

In this regard, the support 3 defines a longitudinal axis 300, the support 3 extending annularly about the longitudinal axis 300. The longitudinal axis 300 is incident (incident) and inclined with respect to the axis of rotation 40 of the shaft 4. In fig. 1a, 1b, 2, 3a, 3b, 6, this inclination may even be considered as "exaggerated", but is done in order to better highlight it. Suitably, the angle between axis 300 and axis 40 is less than 45 °, advantageously less than 25 °, preferably less than 15 °. At the same time, the angle is preferably greater than 5 °.

Suitably, at least one of the two bases 36, 37 lies on a plane extending transversely, but not orthogonally, to the axis of rotation 40 of the shaft 4 (see for example fig. 1a, 1b, 2, 6). Advantageously, this may be the case for both bases 36, 37.

Reference should now be made instead to the schematic and alternative solutions shown in fig. 7-10. For simplicity, the flexible element 2 is not shown in fig. 7, but the flexible element 2 is schematically highlighted in the cross-sectional views of fig. 8-10.

The central support 3 comprises a lateral surface 35, the lateral surface 35 comprising a first portion 351 tapering downwards and a second portion 352 tapering upwards, the first portion 351 and the second portion 352 being continuous along the lateral surface 35 in the direction of rotation of the support 3. In this case, the flexible elements 2 extending from the first portion 351 hit a lower part of the vehicle than those extending from the second portion 352. This alternation of the strip 20 striking the vehicle at the lower and upper parts simulates an oscillating movement of the brush 1.

In this case, the axis 300 of the support 3 and the rotation axis 40 of the rotation shaft 4 extend in the same direction. Instead, the side surface 35 remains inclined with respect to the rotation axis 40 (at least for 75% of its angular extension around the axis 300%; it is pointed out in fig. 10 that, in such a particular section, the generatrix is parallel to the axis 40).

As shown in fig. 1a, 1b, 2, 3a, 3b, the brush 1 comprises a plurality of toroidal supports 3, which are continuous with each other along said axis 4 and intersect the same axis 4.

The subject of the invention is also a brush 1 for a vehicle washing system (see for example figures 11-16).

The brush 1 includes:

a flexible element 2 intended to be in contact with a vehicle for cleaning and/or drying and/or polishing;

a central annular support 3 from which the flexible elements 2 extend; as illustrated in fig. 11 and 13, suitably, the central support 3 and the flexible element 2 are a single whole;

a shaft 4 rotating about its own axis of rotation 40; the shaft 4 intersects the central support 3 and rotates the central support 3 about the rotation axis 40.

The central support 3 defines an upper surface 356, the upper surface 356 enclosing a circle 357 or other pattern intersecting the axis 4 (the upper portion of the bore intersects the central support 3; the bore generally intersects the axis 4); a line passing through the geometric centre of gravity of said circle 357 (or other figure) and orthogonal to said circle 357 (or other figure) is inclined with respect to the axis of rotation 40 of the shaft 4. The inclination (pitch) is fixed during operation. The inclination is advantageously between 5 ° and 25 °.

For one segment of the circumference (perimeter) of said circle 357 (or other geometry), the central support 3 extends upwards from the shaft 4, while for the (other) segment of the circumference (perimeter) of said circle 357 (or other geometry), the central support 3 extends downwards from the shaft 4 (see fig. 11 and 13). Suitably, the support 3 extends upwards over at least one third (or even one half) of the circumference (perimeter) of said circle 357 (or other figure). Over at least one third (or even one half) of the circumference (perimeter) of said circle 357 or other figure, the support 3 extends downwards. In fact, the support 3 is inclined with respect to the horizontal plane, so that the support 3 projects partly upwards and partly downwards.

Suitably, the brush 2 comprises a plurality of central supports 3 stacked in a direction 358 inclined with respect to the rotation axis of the shaft 4 (such inclination is advantageously comprised between 5 ° and 25 ° as previously described; fig. 11 and 13 and 15 exaggerate such inclination in order to better highlight it). The thickness of the support 3 extends in the stacking direction. As illustrated in fig. 11 and 13, each of said supports 3 is integral with a plurality of flexible elements 2 extending in a spoke manner. The interface between each support 3 and the flexible element 2 extending therefrom defines a side surface 35 of the support 3 (see the double-dashed line in fig. 12).

Reference is now made to the scheme of fig. 15 and 16. In this case, the central support 3 also acts as a spacer ring (separating the two-layer stacked flexible elements 2). The flexible element 2 extends from the support 3 (see fig. 15). In particular, the flexible elements 2 extend away from the central support 3 in a spoke manner. Such flexible element 2 is connected to the superposed central support 3, for example by gluing.

Reference is now made to the arrangements of fig. 11 and 12. In that case, the central support 3 and the flexible element 2 are integrated in a single entity (integrated into a single entity); the central support 3 is thus an integral inner part. In this case, a plurality of central supports 3, each associated with a respective flexible element 2 extending in spoke manner, are stacked on top of one another.

Refer to the schemes of fig. 13 and 14. This solution differs from the previous one in that in this case the central supports 3 are glued to each other to form an assembly (in these figures, the glue layer is indicated by the reference 359).

The subject of the invention is also a method for operating a brush 1 of an automatic vehicle washing system. Conveniently, such a brush 1 may be of the type having one or more of the features described above. Suitably, the method comprises the steps of: rotating the shaft 4 about the axis of rotation 40. The shaft 4 passes through and rotates the central annular support 3, around which central annular support 3 flexible elements 2 are applied, these flexible elements 2 being intended to be in contact with the vehicle for cleaning and/or drying and/or polishing.

The central support 3 comprises a lateral surface 35, from which lateral surface 35 the flexible element 2 extends (projects), which lateral surface 35 is inclined with respect to the rotation axis 40 of the shaft 4. The side surface 35 is suitably annular.

The central support 3 comprises two opposite bases 36, 37, between which two opposite bases 36, 37 the lateral surface 35 extends. The flexible element 2 may advantageously be a strip 20. Advantageously, in that case, the strip 20 extends for at least 50%, preferably at least 75%, of the distance between the two opposite bases 36, 37.

The first pair 21 of strips 2 is adjacent to each other and, at least at a predetermined rotation speed of the shaft 4, its orthogonal projection on the rotation axis 40 is closer to the first axial end 41 of the brush 1 with respect to at least a second pair of said strips 2 (which are also adjacent to each other). This occurs during the entire rotation (360 °) about the axis 40 of the shaft 4. For example, in the case of fig. 2, point H representing the upper strip 20 is closer to the first end 41 of the shaft 4 than point K representing the lower strip 20.

Adjacent strips 20 refer to two strips 20a, 20b which extend from the same central support 3 and are adjacent and successive with respect to rotation about the axis 40 of the support 3.

Further, still referring to fig. 2, when the strip 20 is tilted, the distance between points Y and H is shorter than the distance between points Y and Z. In other words, if the strip 20 is taut and straight, the distance of the point at the end of the strip 20 from the axis 40 is shorter if evaluated in the radial direction rather than in the longitudinal extension of the strip 20.

Suitably (see the solution of fig. 1a, 1b, 2, 3a, 3b, 6), the axis of rotation 40 of the shaft 4 and the longitudinal axis 300 of the central support 3 extend in two different directions.

In the alternative (see fig. 7-10), the lateral surface 35 of the support 3 comprises a first portion 351 tapering downwards and a second portion 352 tapering upwards, the first portion 351 and the second portion 352 being continuous (successive) along the lateral surface 35 in the direction of rotation of the support 3.

When the shaft 4 is rotated, the strap 20 extending from the first portion 351 contacts the vehicle at a lower portion (at a lower position) than the strap 20 extending from the second portion 352. In this case, the axis of rotation 40 of the shaft 4 and the longitudinal axis 300 of the central support 3 advantageously extend in the same direction, in particular they coincide.

The invention achieves important advantages.

Firstly, the flexible element 2, which extends from an inclined surface with respect to the rotation axis 40, allows the brush 1 to obtain a rotational movement, but also simulates a wave motion. Moreover, this inclination solves the problems related to the axial distance existing between the flexible elements 2 placed at the junction area of two consecutive supports 3. This allows for increased cleaning force and friction surface and allows for more uniform cleaning. The tilting elements 2 also gradually impact the surfaces, thereby having a more delicate effect on the coating (paint) and reducing noise.

The invention as conceived is susceptible of numerous modifications and variations, all of which fall within the scope of the inventive concept as characteristic of the present invention. Moreover, all the details may be replaced with technically equivalent elements. In practice, all materials used, as well as the dimensions, may be any according to requirements.