EP2467214B1 - Surface cleaning head - Google Patents

Description

The invention relates to a surface cleaning head for cleaning a surface, with a hood-shaped, downwardly open housing, in which at least one spray arm is rotatably mounted about an axis of rotation, wherein the spray arm at a distance from the axis of rotation carries a nozzle which can be acted upon with pressurized cleaning liquid and rotates together with the spray arm about the axis of rotation to act on the surface to be cleaned with a liquid jet, and with a protective disc covering the at least one spray arm to the open bottom of the housing and an annular, characterized by holding webs liquid passage defined for passage of the liquid jet, wherein the at least one spray arm is rotatable relative to the protective disk.

Such a surface cleaning head is from the US 3,832,069 known. It is suitable for example for cleaning hard surfaces, such as patio floors, garage entrances and garage doors. To clean the hard surfaces, the pressure line of a high-pressure cleaning device can be connected to the surface cleaning head. Pressurized cleaning fluid may then be supplied to the nozzle located at the at least one spray arm. With the help of the nozzle, the cleaning liquid can be applied to the surface to be cleaned. The nozzle undergoes a recoil, under the effect of the spray arm is rotated about the rotation axis in rotation. This makes it possible to apply a relatively large area within a short time with cleaning liquid.

In order to prevent that arranged on the surface to be cleaned objects, such as pebbles, reach the area of the at least one Sprüharms, is in the from the US 3,832,069 known surface cleaning head below the spray arm arranged a protective screen. This defines a liquid passage so that the jet of liquid emanating from the nozzle can reach the surface to be cleaned. The fluid passage is penetrated by a plurality of retaining webs, which extend to a side wall of the housing and thereby stabilize the protective disk.

The liquid jet, which rotates about the axis of rotation, strikes a holding web at intervals, which passes through the liquid passage. As a result, the protective pane is vibrated, which leads to a clearly audible noise.

Object of the present invention is to develop a surface cleaning head of the type mentioned in such a way that it has a lower noise.

This object is achieved in a surface cleaning head of the generic type according to the invention that the holding webs are arranged distributed unevenly in the circumferential direction.

In the surface cleaning head according to the invention, the holding webs that pass through the liquid passage are distributed unevenly in the circumferential direction. This has the consequence that the liquid jet emanating from the nozzle at irregular intervals on a holding web meets. Due to the temporally irregular loading of adjacent retaining webs with pressurized liquid, no vibration resonance can form in the protective disk and this in turn means that the noise development of the surface cleaning head according to the invention is relatively low.

In order to increase the cleaning effect, two diametrically opposite spray arms are rotatably mounted about the axis of rotation in an advantageous embodiment of the surface cleaning head according to the invention in the housing, each carrying a nozzle at a distance from the axis of rotation. As a result, at the same time a first liquid jet and a second liquid jet can be directed to the surface to be cleaned, which rotate around the axis of rotation and are arranged offset in the circumferential direction by 180 ° to each other. In such an embodiment, it is advantageous if the holding webs are not diametrically opposed to each other in pairs, as this ensures that not simultaneously meet both liquid jets on a holding web, but rather occurs when hitting the first liquid jet on a holding web of the second liquid jet unhindered through the liquid passage , It has been shown that thereby the noise can be kept low even with the use of two diametrically opposed spray arms.

Preferably, an odd number of retaining webs is used, for example, three, five, seven or nine retaining webs may be provided which are arranged distributed unevenly in the circumferential direction.

The holding webs are preferably aligned radially to the axis of rotation of the spray arms.

The protective disc forms in an advantageous embodiment of the invention, a central shield, which is arranged below the at least one spray arm and which is connected via the holding webs with a protective shield surrounding in the circumferential direction retaining ring. It has been shown that the use of the retaining ring makes it possible to mechanically stabilize the central protective shield, particularly in its outer edge region adjoining the fluid passage.

In order to keep the weight of the shield and thus the mechanical stress of the surface cleaning head low, it is advantageous if the shield has a plurality of openings.

It may be provided, for example, that the protective shield is configured in a grid or net shape.

It is particularly advantageous if the protective shield is integrally connected to the retaining ring via the retaining webs. The shield can form a one-piece plastic molding in combination with the retaining webs and the retaining ring.

Conveniently, the shield includes a plurality of reinforcing ribs that mechanically stabilize the shield.

Preferably, at least some of the reinforcing ribs are arranged in the radial direction in alignment with a holding web, via which the protective shield is connected to the outer retaining ring.

It is favorable if the reinforcing ribs protrude from the protective shield on the upper side and / or on the underside. This increases the stabilizing effect of the reinforcing ribs.

It is particularly advantageous if the height of the reinforcing ribs increases or decreases with increasing radial distance from the axis of rotation. The reinforcing ribs extend transversely to the shield, wherein their height varies depending on the radial distance from the axis of rotation. In particular, it may be provided that the height of the reinforcing ribs continuously increases or decreases with increasing distance to the axis of rotation.

It has proved to be advantageous if the regions of the reinforcing ribs projecting upwards or downwards from the protective shield form a triangular shape relative to a radial plane.

It can be provided, for example, that all reinforcing ribs both have an upwardly protruding from the shield reinforcing portion and a projecting downwardly from the shield reinforcing portion, wherein the height of one of the two reinforcing portions, preferably the height of the upper reinforcing portion, with increasing radial portion continuously reduced in the same way, as the height of the other reinforcing portion, preferably the lower reinforcing portion, increases with increasing radial distance.

The reinforcing ribs form a mechanical reinforcement of the protective shield. The latter is preferably produced as a plastic molding in an injection molding process. During the injection molding process, the upwardly and downwardly projecting from the shield reinforcing portions flow channels, which ensure that sufficient plastic material can flow to the outer edge regions of the injection mold. The reinforcing ribs thus also have an injection molding function in addition to their reinforcing function.

The retaining ring can be arranged on the housing of the surface cleaning head. In particular, it can be provided that an edge portion of the housing forms the retaining ring.

In a preferred embodiment, the retaining ring is arranged at a distance from the housing. The distance of the retaining ring to the housing in the radial direction is preferably less than the radial extent of the liquid passage.

It is particularly advantageous if the retaining ring in the axial direction with respect to the axis of rotation of the at least one Sprüharms has an upper end portion which is disposed within the housing, and a lower end portion which projects beyond the lower edge of the housing. The upper end portion of the retaining ring is thus circumferentially surrounded by the housing. This allows the housing form a guide for the retaining ring in the Assembly of the protective disk by the protective disk, whose outer edge region is formed by the retaining ring, is inserted from below into the housing. The lower end portion of the retaining ring may protrude from the housing in the axial direction. The retaining ring can thereby form a shock protection, which protects the housing against damage in an unintentional approach of the surface cleaning head to the surface to be cleaned, since in such an approach, the retaining ring with its axially projecting area touches the surface to be cleaned, even before the housing on can open the area.

It when at the bottom of the housing, a flexible splash guard is arranged, which protrudes in the axial direction over the lower edge of the retaining ring is particularly advantageous. As a flexible splash guard, for example, a rubber lip or a bristle ring can be used. Thus, the flexible splash guard surrounds the lower end portion of the retaining ring in the circumferential direction, and as the surface cleaning head passes along the surface to be cleaned, the splash guard may contact the surface without causing the retaining ring to contact the surface.

Conveniently, the material thickness of the retaining ring is less than its axial extent. The retaining ring thus forms a kind of pipe section or sleeve. The sleeve surrounds the central shield of the protective disk in the circumferential direction and forms a mechanical stabilization.

The protective disk is held in an advantageous embodiment of a bearing shaft on which the at least one spray arm is rotatably mounted. It can be provided that the protective disk relative to the bearing shaft is rotatable. Alternatively, the protective disk can be fixed in rotation in or on the housing, for example on the bearing shaft.

It may be provided that the surface cleaning head has only nozzles, which are each held on a rotating about the axis of rotation spray arm. These can be arranged in the region of the liquid passage of the protective disk, so that the radially outer ends of the holding webs have a greater distance from the axis of rotation than the nozzles.

However, it can also be provided that, in addition to nozzles, which are held on a rotatable spray arm, the surface cleaning head comprises at least one further nozzle, which is arranged radially offset from the shield, that is, a greater radial distance from the axis of rotation than the outer edge of the protective disk. The additional nozzle can be rotatably held in the housing and used, for example, for cleaning corner areas of a surface used.

Figur 1:

eine perspektivische Darstellung einer ersten Ausführungsform eines erfindungsgemäßen Flächenreinigungskopfes;

Figur 2:

eine Längsschnittansicht des Flächenreinigungskopfes aus Figur 1;

Figur 3:

eine Unteransicht des Flächenreinigungskopfes aus Figur 1;

Figur 4:

eine perspektivische Darstellung eines Schutzschildes des Flächenreinigungskopfes aus Figur 1 schräg von oben;

Figur 5:

eine perspektivische Darstellung des Schutzschildes aus Figur 4 schräg von unten;

Figur 6:

eine perspektivische Darstellung einer zweiten Ausführungsform eines erfindungsgemäßen Flächenreinigungskopfes und

Figur 7:

eine Längsschnittansicht des Flächenreinigungskopfes aus Figur 6.

The following description of preferred embodiments of the invention is used in conjunction with the drawings for further explanation. Show it:

FIG. 1:

a perspective view of a first embodiment of a surface cleaning head according to the invention;

FIG. 2:

a longitudinal sectional view of the surface cleaning head FIG. 1 ;

FIG. 3:

a bottom view of the surface cleaning head FIG. 1 ;

FIG. 4:

a perspective view of a protective shield of the surface cleaning head FIG. 1 diagonally from above;

FIG. 5:

a perspective view of the shield FIG. 4 diagonally from below;

FIG. 6:

a perspective view of a second embodiment of a surface cleaning head according to the invention and

FIG. 7:

a longitudinal sectional view of the surface cleaning head FIG. 6 ,

In the FIGS. 1 to 5 shows a first embodiment of a total occupied by the reference numeral 10 surface cleaning head according to the invention. This includes a hood-shaped, downwardly open housing 12 with an annular in plan view, self-contained cylinder wall 14 which carries at its lower edge 15 a circumferential flexible splash guard in the form of a bristle ring 17. The cylinder wall 14 is covered by a ceiling wall 19. On the outside, a substantially V-shaped attachment part 21 is attached to the cylinder wall 14, to which a cover 22 covering the ceiling wall 19 in a central area adjoins above the ceiling wall 19. Laterally next to the cover 22 above the ceiling wall 19, a first handle 23 and a second handle 24 are arranged, which can be encompassed by the user for supporting the surface cleaning head 10th

The cover 22 defines above the ceiling wall 19 a distribution chamber 26, and the cylinder wall 14 surrounds below the ceiling wall 19 a spray chamber 28. The attachment part 21 defines an additional space 30th

In the distribution chamber 26, a central distributor part 32 is arranged, in which a supply pipe 34 opens, which is mounted about a transversely to the pipe axis 35 aligned pivot axis 36 pivotally mounted in the distributor part 32. At its free end remote from the distributor part 32, the supply pipe 34 carries a connecting element 38, so that a pressure line, which is known per se and therefore not shown in the drawing, of a high-pressure cleaning device can be connected to the supply pipe 34.

The central distributor part 32 is connected via a first supply line 40 with two diametrically opposed spray arms 42, 44 in fluid communication, each having a flow channel 46 and 48 and carry at its free end a nozzle 50 and 52, respectively. The flow channels 46, 48 extend through the spray arms 42 and 44, respectively. In FIG. 2 the flow channels 46, 48 are only partially shown. The nozzles 50, 52 are acted upon by the supply pipe 34 and the distributor part 32 and the first supply line 40 and the flow channels 46 and 48 with pressurized cleaning liquid and produce an obliquely downwardly directed liquid jet of a cleaning liquid. Upon exiting the nozzles 50, 52, the liquid jets exert a torque on the spray arms 42, 44 by reaction forces and cause them to rotate about a rotation axis 54 aligned coaxially with the longitudinal axis of the first lead 40. Thus, by means of the orbiting Nozzles 50, 52 a first liquid jet and a second liquid jet are directed to a surface to be cleaned.

Starting from the central distributor part 32 extends within the distribution chamber 26, a second supply line 56, which dips on the upper side in the additional space 30 and carries at its free end an additional nozzle 58. The additional nozzle 58 is designed in the form of a spray nozzle and held in the housing 12 in a fixed manner in contrast to the rotating nozzles 50, 52. From the additional nozzle 58, pressurized cleaning fluid can be dispensed, for example for cleaning a corner region of a surface to be cleaned.

The supply of cleaning liquid from the supply pipe 34 via the distributor part 32 is carried out selectively either only to each of a spray arm 52, 54 arranged nozzles 50, 52 or to the additional nozzle 58. For this purpose, the distributor part 32 has a switching device 60 shown only schematically in the drawing which in a first switching position releases the flow path between the supply pipe 34 and the first supply line 40 and in a second switching position the flow path between the supply pipe 34 and the second supply line 56.

The two spray arms 42, 44 are rotatably mounted on a bearing shaft 62 which is held on the first supply line 40 and flow channels for establishing the flow connection between the first supply line 40 and the flow channels 46, 48 of the two spray arms 42, 44. In the axial direction that is, in the direction of the axis of rotation 54, the bearing shaft 62 protrudes downwards over the spray arms 42, 44. In its outstanding range, the bearing shaft 62 carries a protective element in the form of a protective screen 64, whose constructive structure in particular from the FIGS. 4 and 5 becomes clear. The protective screen 64 comprises a central, circular shield 66, which is configured in the form of a lattice and has a multiplicity of perforations 68. It is divided by radially extending reinforcing ribs 70 into a plurality of sectors 71 to 77, each extending over a different angular range in the circumferential direction.

The reinforcing ribs 70 each have an upper-side reinforcing portion 70a and a lower-side reinforcing portion 70b. The upper-side reinforcing section 70a protrudes from the protective shield 66 on the upper side, that is to say it is oriented perpendicular to it, its height being reduced with increasing distance from the axis of rotation 54. In a radial plane, the upper-side reinforcing section forms a triangular shape. The lower-side reinforcing portion 70b protrudes from the shield 66 on the lower side and is also aligned perpendicular thereto. As the distance from the rotation axis 54 increases, the height of the lower-side reinforcing portion increases in the same manner as the height of the upper-side reinforcing portion 70a decreases. In a radial plane, the lower-side reinforcing section 70b also defines a triangular shape. The reinforcing ribs 70 form a mechanical reinforcement of the protective shield 66 with their top and bottom reinforcing portions 70a and 70b. The latter is made of a plastic material by an injection molding process. During the injection molding process, the liquid plastic material reinforcement sections provide flow channels that ensure that sufficient plastic material can flow to the outer periphery of the molding tool.

In the circumferential direction of the central shield 66 is surrounded by a retaining ring 78 which is integrally connected via aligned with the reinforcing ribs 70 retaining webs 80 with the shield 66. Between the retaining ring 78 and the outer edge of the shield 66, an annular fluid passage 82 extends, which is penetrated by the retaining webs 80.

The retaining ring 78 is designed in the manner of a very short piece of pipe or in the manner of a sleeve by its material thickness is considerably less than its extension in the axial direction with respect to the axis of rotation 54 of the spray arms 42, 44. An axial upper end portion 84 of the retaining ring 78 is within of the housing 12 is arranged by being circumferentially surrounded by the free end portion of the cylinder wall 14, whereas an axial lower end portion 86 projects downwardly beyond the lower edge 15 of the cylinder wall 14 and thus over the housing 12. However, the lower end region 86 is circumferentially surrounded by the flexible splash guard, namely the bristle ring 17, which in turn protrudes in the axial direction down over the lower end portion 86 of the retaining ring 78. This is especially true FIG. 2 clear.

When mounting the surface cleaning head 10, the protective plate 64 can be inserted from below into the housing 12. In this case, the lower end region of the cylinder wall 14 forms a guide for the protective disk 64. After mounting the protective disk 64 on the bearing shaft 62, the annular fluid passage 82 is arranged in alignment with the nozzles 50 and 52, so that the liquid jets emanating from the nozzles 50, 52 through the Liquid passage 82 can pass to act on the surface to be cleaned.

As already explained, the nozzles 50, 52 rotate about the axis of rotation 54 when they are subjected to pressurized liquid. They each release a liquid jet. During the circulation of the nozzles 50, 52 about the axis of rotation 54, the respective liquid jet strikes a holding web 80 at irregular intervals, but it is ensured that two holding webs can not be acted on at the same time by the two liquid jets coming from the nozzles 50, 52 out. This is ensured by the fact that the holding webs 80 are not aligned in pairs diametrically opposite each other, as is the case with the two spray arms 42, 44. At the moment when a first liquid jet strikes a holding web 80, the second liquid jet can pass through the liquid passage 82 unhindered.

Since the holding webs 80 are distributed unevenly in the circumferential direction, the protective disk 64 can not be put into resonant oscillation by the circulating liquid jets, since the holding webs 80 are acted on at irregular intervals by a liquid jet. This uneven arrangement of the holding webs ensures that the noise of the surface cleaning head 10 can be kept low.

A second inventive embodiment of a surface cleaning head according to the invention is in the FIGS. 6 and 7 represented and in total occupied by the reference numeral 90. The surface cleaning head 90 is designed substantially identical to the above with reference to the characters 1 to 5 explained surface cleaning head 10. For identical components are therefore in the FIGS. 6 and 7 the same reference numerals as in the FIGS. 1 to 5 and to avoid repetition, reference is made to the above explanations with respect to these components.

The in the FIGS. 6 and 7 surface cleaning head 90 shown differs from the above-described surface cleaning head 10 in that it has only the two nozzles 50, 52, which are respectively held at the free end of a spray arm 42 and 44 and rotate upon application of pressurized cleaning fluid about the axis of rotation 54. A non-rotatable additional nozzle is not used in the surface cleaning head 90.

The surface cleaning head 90 also has a protective screen 64, as described above with reference to FIG. 4 was explained. The protective plate 64 has a central shield 66 which is circumferentially surrounded by a retaining ring 78, wherein between the shield 66 and the retaining ring 78, a fluid passage 82 is arranged, which is penetrated by retaining webs 80, wherein the retaining webs 80 also in the surface cleaning head 90 in Circumferentially arranged distributed unevenly. The uneven arrangement of the holding webs 80 also ensures the surface cleaning head 90 that the noise when exposed to pressurized cleaning fluid can be kept relatively low, since a resonant vibration of the protective plate 64 by the impinging in time irregular order on the holding webs 80 liquid jets not can train.

Claims (14)

1. Surface cleaning head (10; 90) for cleaning a surface, with a dome-shaped, downwardly open housing (12) in which at least one spray arm (42, 44) is mounted for rotation about an axis of rotation (54), the at least one spray arm (42, 44) carrying at a distance from the axis of rotation (54) a nozzle (50, 52) which can be subjected to pressurized cleaning fluid and revolves together with the spray arm (42, 44) around the axis of rotation (54) for the purpose of acting on the surface to be cleaned with a stream of fluid, and with a protective disk (64) which covers the at least one spray arm (42, 44) towards the open underside of the housing (12) and defines a ring-shaped fluid passage (82), penetrated by retaining bars (80), for the stream of fluid to pass therethrough, the at least one spray arm (42, 44) being rotatable relative to the protective disk (64), characterized in that the retaining bars (80) are arranged in an unevenly distributed manner in the circumferential direction.
2. Surface cleaning head in accordance with claim 1, characterized in that two spray arms (42, 44) located diametrically opposite each other are mounted in the housing (12) for rotation about the axis of rotation (54) and each carry a nozzle (50, 52) at a distance from the axis of rotation (54), and in that the retaining bars (80) are not located diametrically opposite each other in pairs.
3. Surface cleaning head in accordance with claim 1 or 2, characterized in that the protective disk (64) forms a central protective shield (66) arranged beneath the at least one spray arm (42, 44) and connected by the retaining bars (80) to a retaining ring (78) surrounding the protective shield (66) in the circumferential direction.
4. Surface cleaning head in accordance with claim 3, characterized in that the protective shield (66) has a plurality of through-openings (68).
5. Surface cleaning head in accordance with claim 3 or 4, characterized in that the protective shield (66) is of grating-like or net-like configuration.
6. Surface cleaning head in accordance with claim 3, 4 or 5, characterized in that the protective shield (66) is integrally connected to the retaining ring (78) by the retaining bars (80).
7. Surface cleaning head in accordance with any one of claims 3 to 6, characterized in that the protective disk (64) has reinforcing ribs (70) projecting from the protective shield (66) on the upper side and/or on the underside and extending in the radial direction in alignment with the retaining bars (80).
8. Surface cleaning head in accordance with claim 7, characterized in that the height of the reinforcing ribs (70) increases or decreases as the radial distance from the axis of rotation (54) increases.
9. Surface cleaning head in accordance with claim 7 or 8, characterized in that the areas (70a, 70b) of the reinforcing ribs (70) projecting upwards or downwards from the protective shield (66) form a triangular shape in relation to a radial plane.
10. Surface cleaning head in accordance with any one of claims 3 to 9, characterized in that the retaining ring (78) is arranged at a distance from the housing (12).
11. Surface cleaning head in accordance with any one of claims 3 to 9, characterized in that the retaining ring (78) has in the axial direction in relation to the axis of rotation (54) of the at least one spray arm (42, 44) an upper end area (84) arranged within the housing (12) and a lower end area (86) projecting beyond the lower edge (15) of the housing (12).
12. Surface cleaning head in accordance with claim 11, characterized in that a flexible spray protection element (17) is arranged at the lower edge (15) of the housing (12) and projects in the axial direction beyond the lower end area (86) of the retaining ring (78).
13. Surface cleaning head in accordance with any one of claims 3 to 12, characterized in that the material thickness of the retaining ring (78) is less than its axial extent.
14. Surface cleaning head in accordance with any one of the preceding claims, characterized in that the protective disk (64) is held on a bearing shaft (62) on which the at least one spray arm (42, 44) is mounted for rotation.

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