DEVICE FOR EXTRACTION OF SWIMMING POOL CLEANING DEVICE

Abstract

The invention relates to a device for extraction of a swimming pool cleaning robot. The device comprises: a support frame; a plate which can be deployed beyond the support frame and below the latter; means for controlling the deployment of the said plate.

Claims

1. Device for extraction of a swimming pool cleaning robot, characterized in that the device comprises: a support frame; a plate which can be deployed beyond the support frame and below the latter; means for controlling the deployment of the said plate.

2. Extraction device according to claim 1, characterized in that the plate which can be deployed is a plane, and in that the device comprises: means for moving the said plate between a retracted position, in which the said plate is substantially horizontal, and is placed above a support frame, and a deployed position, in which the plate extends from the frame and is inclined towards the exterior of the latter.

3. Extraction device according to claim 1, characterized in that the plate forms a curved path, such that the angle between the surfaces tangent to its two ends is between approximately 15 and 100°.

4. Extraction device according to claim 2, characterized in that the device comprises means for guiding the plate during its displacement between its retracted position and its deployed position.

5. Extraction device according to claim 1, corresponding to the case of a swimming pool cleaning robot of the type which is supplied with energy by a flexible cable attached to the body of the robot, characterized in that the device also comprises a cable winder, and means for controlling the cable winder.

6. Extraction device according to claim 5, characterized in that the extraction device comprises means for controlling the return of the cleaning robot to the extraction area.

7. Extraction device according to claim 5, characterized in that the plate is detachable, and the device comprises a frame which supports the cable winder, and means for moving the plate between a retracted position, in which the plate is substantially horizontal, and is placed above the frame, and a deployed position, in which the plate extends from the frame and is inclined towards the exterior of the latter.

8. Extraction device according to claim 5, characterized in that the frame supports the cable winder, and the device comprises means for guiding the plate when it is displaced between its retracted position and its deployed position.

9. Extraction device according to claim 5, characterized in that the cable winder permits the output of an end of the cable during winding by the hub of the said winder.

10. Swimming pool cleaning device, characterized in that it comprises a cleaning robot and an extraction device according to claim 1.

Description

PRESENTATION OF THE FIGURES

[0031] The characteristics and advantages of the invention will become more apparent from the following description which describes the characteristics of the invention by means of a non-limiting example of application.

[0032] The description is based on the appended figures, in which:

[0033] FIG. 1 illustrates a view in perspective of a swimming pool cleaning device according to the prior art;

[0034] FIG. 2 is a highly schematised side view of the elements of the device, including a cleaning robot, the latter being placed in the swimming pool;

[0035] FIG. 3 is a view in perspective of the elements which constitute a device for extraction of a swimming pool robot, without the cleaning robot or winding cable;

[0036] FIG. 4 is a schematic representation of the kinematics of displacement of the plate on the support frame;

[0037] FIG. 5 is a view in perspective of the same elements, with the cleaning robot and the winding cable being represented.

DETAILED DESCRIPTION OF AN EMBODIMENT OF THE INVENTION

[0038] The context of the invention is within a swimming pool environment, for example a sunken swimming pool of the family type.

[0039] As can be seen in FIG. 1 already referred to, a swimming pool cleaning robot 100 as envisaged here in a non-limiting manner comprises a body 101, means for displacement 102 (wheels, caterpillar bands, etc.), at least one cleaning brush 103, and a water filtering and suction circuit (not shown in the figure) comprising at least one helical wheel driven by a motor (also riot shown in the figure). The means for displacement 102 can be controlled independently from one another, such as to make it possible to orient the cleaning robot freely on the walls of the swimming pool, in forward or reverse running. The running/stopping of the motor of the filtration circuit can also be controlled, and optionally so can the suction power.

[0040] For the continuation of the description, a reference X.sub.rY.sub.rZ.sub.r fis defined relative to this robot, wherein: [0041] a longitudinal axis X.sub.r is defined as the axis of displacement of the robot when the displacement wheels 102 are commanded to move identically; [0042] a transverse axis Y.sub.r is defined as perpendicular to the longitudinal axis X.sub.r, and is situated on a plane parallel to the support plane of the means for displacement 102 of the robot, this lateral axis Y.sub.r thus being parallel to the axis of rotation of the wheels; [0043] a vertical axis Z.sub.r is defined as perpendicular to the two other axes.

[0044] The concepts of front, rear, left, right, top, bottom, upper, lower, etc. relating to the cleaning robot are defined relative to this reference X.sub.rY.sub.rZ.sub.r.

[0045] In the present embodiment, the cleaning robot 100 concerned comprises an output shaft of the water filtration circuit oriented in a manner which is inclined relative to the vertical Z.sub.r. Thus, the flow of water which is driven at the output of the filtration circuit tends to assist the advance of the robot during its displacements. According to a variant, the water output shaft is oriented according to the vertical axis Z.sub.r.

[0046] In the present example, the cleaning robot 100 is supplied with energy and commands by means of a flexible cable 104. This flexible cable 104 is in this case attached to the body 101 of the robot 100 in its upper front part. This flexible cable 104 is connected at its other end to a supply and programming unit (not illustrated in FIG. 1), placed on the exterior of the pool, this supply and programming unit itself being connected to the electric current at the mains supply.

[0047] The cleaning robot 100 emits, and optionally also receives data, from and to the supply and programming unit.

[0048] The flexible cable 104, with a length of approximately 10 m or so, usually has a diameter of approximately 1 cm, and its rigidity is sufficient to allow a user to use the said flexible cable 104 in order to bring the cleaning robot 100 towards him when the robot needs to be extracted from the swimming pool.

[0049] In the present example, the cleaning robot 100 additionally comprises a grasping handle 105 which is designed to allow a user to remove the robot from the water. According to a particular embodiment, the cleaning robot comprises means which permit rapid emptying of the water contained in its inner filtration chamber when it is extracted from the water.

[0050] The cleaning robot 100 comprises, in this case in its upper part, a cover 106 which opens to allow a user to access the filter of the filtration chamber, in order to clean the filter when necessary.

[0051] The cleaning robot 100 concerned in this case has a width of approximately 40 cm, a length which is substantially equal to this, and a height of approximately 20 cm. Its weight when empty is approximately 10 kg, and approximately 25 kg when it is removed from the water with its filtration chamber not emptied.

[0052] All these dimensions and values are given here by way of non-limiting example, in order to make it possible to perceive the dimensions of an extraction/deployment device of this cleaning robot 100.

[0053] As can be seen illustrated in a simplified manner in a non-limiting embodiment in FIGS. 2 and 3, an extraction device 200 of a swimming pool cleaning robot 100 comprises firstly a support frame 201, which is designed to be supported on the rim 202 of a swimming pool. In the present example, which is in no way limiting, this support frame 201 is a rectangular plate 203 which is 60 to 80 cm in length, provided with two, substantially vertical lateral guide edges 204. In this case, these lateral guide edges 204 have a height of approximately 15 cm.

[0054] Also in the continuation of the description, a reference XYZ is defined relating to this frame, wherein: [0055] a longitudinal axis X is defined as parallel to the length of the frame 201; [0056] a transverse axis Y is defined as perpendicular to the longitudinal axis, and situated on the plane of the ground around the frame 201; [0057] a vertical axis Z is defined as perpendicular to the two other axes.

[0058] The concepts front, rear, left, right, top, bottom, upper, lower, etc. relating to the support frame 201 are defined relative to this reference XYZ.

[0059] This support frame 201 receives a substantially flat rectangular plate 205, with a length which is less than the length of the frame, but is close to that length.

[0060] The width of the plate 205 is less than, or equal to, the width of the support frame 201, but is close to that width. The plate 205 can thus be placed above the frame.

[0061] The plate 205 is mobile between two positions. 1/In a first position (not illustrated in the figures), known as the retracted position, the plate 205 is positioned above the support frame 201, substantially parallel to it.

[0062] 2/In a second position, known as the deployed position, the plate 205 is on the other hand placed, relative to the frame 201, overhanging the closest end of the swimming pool. In this deployed position, the plate 205 is inclined by approximately 30° relative to the horizontal. This value is non-limiting, and gradient values of 10 to 100° can be envisaged. As can be seen in FIGS. 2 and 3, in this deployed position, the plate 205 is placed such that one of its longitudinal edges is placed 10 to 20 cm below the surface of the water in the swimming pool. The inclination of the plate 205 relative to the vertical is adjustable between 0 and 100° in the present example.

[0063] In the present embodiment, the plate 205 is provided with slides 206 on its lateral edges, the said slides cooperating with lugs which form guides (not shown in the figures) fitted on the inner face of the lateral edges 204 of the frame.

[0064] The kinematics of the plate 205 relative to the support frame 201 are then illustrated in FIG. 4. As can be seen in this figure, provided here by way of non-limiting example, the plate 205 is rendered integral by means of a rotary connection 207 with a carriage 208 which is mobile along an endless screw 209 oriented approximately 10° above the longitudinal axis X. This endless screw 209 is driven by an electric motor 210. The distance D1 between the endless screw and the rotary connection 207 is less than the distance D2 between the endless screw and the lateral guide lugs of the plate 205. The distance between the guide lugs and the rotary connection according to the axis of the endless screw 209 is indicated as L.

[0065] Thus, when the endless screw 209 is rotated by the electric motor 210, it gives rise to the longitudinal displacement of the carriage 208, and consequently to the advance of the plate 205 out of the support frame 201.

[0066] The relative position of the guide lugs and the carriage determines the angle of the plate 205 relative to the axis of the endless screw 209 according to tan(α)=(D2-D1)/L. It will be appreciated that the maximum and minimum angles of inclination of the plate 205 relative to the support frame 201 can thus be determined during the design of the extraction device 200.

[0067] As can be seen in FIG. 3, in the present embodiment the extraction and/or deployment device in fact comprises two endless screws 209, each placed along a lateral edge 204 of the frame. These two endless screws 209 are driven by a single motor 210, by means of a drive belt 214.

[0068] In the present example, the plate 205 also comprises a stop 216 perpendicular to its main plane, placed in the middle of its end which is closest to the rotary connection 207. This stop 216 is designed to form a displacement limit for the cleaning robot 100 on the said plate 205.

[0069] The support frame 201 additionally comprises a cable winder 211. This winder 211 comprises a reel 212 and a drive motor 213. The reel 212 is oriented according to the transverse axis Y.

[0070] This winder 211 permits the output of the flexible cable 104 along its axis, such that the cable can be connected at its end distant from the cleaning robot 100 to a supply and programming unit of the said cleaning robot.

[0071] This winder 211 is rendered integral with the plate 203 of the support frame 201 at its edge which is furthest from the pool.

[0072] At its longitudinal edge which is closest to the rotary connection 207, the plate 205 supports a cable guide 215, which is placed according to the longitudinal axis X, in the alignment of the centre of the reel 212. In the present example, this cable guide 215 has a height above the plate 205 of approximately 15 cm, this dimension being close to the height of the point of attachment of the flexible cable 104 at the level of the body 101 of the cleaning robot 100. The cable guide 215 is designed to orient the flexible cable 104 towards the reel 212 during the winding of the said flexible cable.

[0073] The extraction device 200 also comprises means for controlling the drive motor 210 of the endless screws 209 and the winder 211.

[0074] The dimensions and choice of materials which constitute the various elements previously described are determined by the forces to be absorbed, and by the conditions of the swimming pool environment.

[0075] Operating Mode

[0076] The extraction of the robot can be triggered either automatically at the end of the cleaning cycle, or manually by the user by action on the supply and control unit of the extraction system.

[0077] The supply and control unit of the extraction system is connected to the supply and programming unit of the robot, so that the motors of the extraction system and the motors of the robot are controlled in a coordinated manner.

[0078] According to a particular embodiment, the supply and control unit of the extraction system and the supply and programming unit of the robot are combined.

[0079] When a swimming pool cleaning robot 100 must be extracted from the pool, the extraction process comprises the following steps:

[0080] If the plate 205 is not initially in the deployed position, with its outer edge submerged by approximately 10 cm or so, the system commands its deployment by starting up the motor 210 which drives the endless screws 209.

[0081] Then, the winder 211 is started up, and starts to wind the flexible cable 104 which is connected to the cleaning robot 100 onto the reel 212. The robot 100 is thus brought progressively in the direction of the plate 205, with its front face oriented in the direction of the plate.

[0082] When the robot 100 reaches the immediate vicinity of the plate 205, its wheels 102 are supported on the plate, and the robot advances by itself, or is drawn by the flexible cable 104 which is being wound, until it is totally supported on the said plate. It is blocked against the stop 216 of the said plate 205.

[0083] At this moment, the wheels 102 of the robot are stopped (if its movement was still being commanded).

[0084] The situation is then that in FIG. 5.

[0085] Then, the motor 210 which drives the endless screws 209 is started up, such as to return the plate 205 into the support frame 201. During this time, the winder 211 maintains tension on the flexible cable such as to retain the robot 100 on the plate 205.

[0086] At the same time, if the cleaning robot 100 is provided with a rapid emptying device, the latter is activated in order to reduce the weight of the water in the filtration chamber, and thus the forces exerted on the plate by the endless screws 209.

[0087] When the plate is completely retracted within the frame 201, the motors of the endless screws 209 and the winder 211 are stopped. The robot is then available for handling by the user, for example for cleaning of the filter, or simply to remain thus in the storage position before a future use. Because of the mobility of the plate and its retraction inside the device, this storage position clears the extraction device as well as the cleaning robot from the pool, without active intervention by the user. Thus, the user can have all the space available for swimming, whilst reducing the risks of injury caused by the presence of submerged elements.

[0088] Particularly advantageously, the time for extraction of the robot is relatively short, i.e. advantageously 5 minutes or less, and preferably 2 minutes or less, the user thus being able to have the pool available for swimming very quickly.

[0089] The procedure for putting the cleaning robot into the water is exactly the inverse of what has just been described, and it will be appreciated that the extraction device also acts as a device for putting into the water.