CH710504A2 - Garage pool robot. - Google Patents

Abstract

The invention relates to a garage for a pool robot (1) in conjunction with a reel mechanism in the form of a cable drum (5) with a drive motor (9) for a power cable (8) which extends under a cover housing (4) or in the pool robot (1). is located and the power cable (8) as a train and guide means for the pool robot (1), as well as power (S), and and a glass fiber and water and (W) leads, as well as the cleaning of the filter (11) in the pool robot (1) or on an external filter manually or automatically and the pool robot (1) in sleep mode at the waterline (WL) vertically or above the waterline (WL) remains in the horizontal position and also protected when not in use under the cover housing (4) is parked.

Description

Technical area

The invention is based on a device to safely guide a pool robot by means of a cable or hose reel in a covered parking position on the waterline, there automatically or manually perform the filter cleaning and ready as a launch pad for the next cleaning cycle in the swimming pool according to the preamble of the first claim.

State of the art

Devices for automatic cleaning of surfaces in a swimming pool are called pool robots, as they automatically the soil and often the walls from dirt, which may be deposits from the environment, but also eliminate algae and similar to a vacuum cleaner dirt in a filter collect, which is later taken out on land from the pool robot and cleaned manually. Pool robots are powered by power cables or are wirelessly powered by battery or solar power. A cable-connected as well as a wireless solution is described in US Pat. No. 6,294,081 B1, a system which performs an automatic filter change and has an underwater charging station is described in patent PCT / IL2013 / 051055. A robotic swimming pool cleaning, which acts only by means of a hinged suction lance and which is supplied at the edge of the pool, is described in US Pat. No. 3,289,216.

Presentation of the invention

The invention relates to a pool robot, which is housed on the wall of a swimming pool in a protective housing and can be activated by means of an electric cable or hose and backed back by means of the windable electric cable or hose back into the protective housing. There, at the same time, the filter can also be cleaned manually or automatically, or the debris forwarded, according to the preamble of the first claim.

Pool robots have the distinct advantage that they clean the bottom of a swimming pool of sand, earth, insects mechanically, by means of rotating brushes and similar to a vacuum cleaner, soak up this debris from the ground and transport it into a filter bag or by means of a hose of the debris directly lead to the pool filter. The debris can later be disposed of from the filter. In addition, many pool robots can also run up the walls, mechanically clean them as well, and preempt such heavy algae deposits. Such pool robots not only save time for the users of a pool, who want to bathe and swim as much as possible in their free time, instead of having to clean it, at the same time reducing the amount of water circulation required in the pool, because the water is due to the pre-cleaning performance of the pool robot has a better water quality, so less chemistry has to be used to keep the swimming pool clean. Studies show that the speed reduction of the circulation pump due to the better water quality represents a much higher power saving than the additional power consumption of a pool robot.

A major disadvantage of a pool robot is the handling of such a device. It requires a storage room, which is usually located at a certain distance from the swimming pool, so that usually a wheelbarrow is needed to transport the pool robot, the long cable or the suction hose and the controller. Thereafter, the pool robot must be lifted from the wheelbarrow and let into the water and finally brought out of the water after a defined time, the approximately 10 kg for older people already represent a decent weight, but also younger people can pinch at least one nerve, it is sufficient for a herniated disc because the device must be lifted extremely unfavorable and contrary to the recommendations of accident prevention organizations, the back is not in the lot to the weight of the pool robot, otherwise the person would fall into the water.

The invention solves this problem by the pool robot permanently remains on the pool edge, at the same time elegantly covered by a cover, with easy access to the filter, respectively. a suction device, which automatically removes the debris from the filter. Furthermore, there may be mounted under the filter flap and the controller so that only when needed for the command input the filter flap must be opened, otherwise the controller is hidden from view or operation of third parties. As is customary today, the pool robot can be programmed via smartphone or manually started or stopped at any time.

Furthermore, a winding mechanism is mounted in the cover or in the pool robot, so on the one hand, the power supply to the pool robot is guaranteed, as well as after the cleaning work of the pool robot, which usually stops somewhere in the pool, by means of the winding mechanism after work done back automatically and can be pulled into the parking position of the cover. Ideally, the winding takes place electrically and automatically as soon as the cleaning process is finished, so that the swimming pool user does not have to worry about the device or a specific time, has no lifting work, does not have to issue control commands and is easily and inexpensively ensured by the cable management that the Pool robot finds his way back in the pool to his parking position, which is not a matter of course, especially in L-shaped or a kidney-shaped swimming pool. The cover also ensures that the pool robot is protected even in waves and does not slip, as well as bathers are protected from the device.

In order not to have to dispense with a convenient and automatic cleaning of a pool robot even with smaller Aufstellpools, the pool robot can park outside the water in a horizontal position, which also simplifies the removal of the debris and cleaning needs, the pool robot in the vertical and then start the cleaning tour.

Pool robots which constantly remain in the water can be removed and cleaned by means of an opening at the rear of the pool robot and opening on the cover of the filter or connect to a suction device. In pool robots which have the top of the filter removal, the pool robot can be swung by means of an actuating cylinder or a buoyancy body and a rotatably mounted parking rack for the convenient removal of the filter in the horizontal position.

For pool robots that have no filter bag and perform the cleaning work together with the main swimming pool pump by means of negative pressure or pressure, the debris thus e.g. direct into the large cleaning system of the swimming pool, a power cable or a fiber optic cable in the larger suction hose may be integrated to allow the pool robot underwater lighting or actuate a drive or Zusatzsaug- or rotary brush motor.

Elegant is also the embodiment in which in the hose, a current-carrying coating is attached, which forwards the current by means of a corresponding contact pickup.

This is achieved by the features of the first claim according to the invention.

Core of the invention is integrated by means of a winding mechanism for cable or hose in the cover at the edge of a swimming pool or in the pool robot, on the one hand the pool robot with power or pressure, resp. On the other hand, in the return of the pool robot the winding mechanism serves as a navigation aid, and that in the cover a filter flap is attached, which simplifies the filter change or that the filter is automatically cleaned and under the cover also finds the controller for the pool robot ,

Further advantageous embodiments of the invention will become apparent from the dependent claims.

Brief description of the drawings

In the following, embodiments of the invention will be explained in more detail with reference to the drawings. The same elements are provided in the various figures with the same reference numerals.

Show it:

[0016] <Tb> FIG. 1 <SEP> a schematic side view of a pool robot mounted on the inside wall of a swimming pool with a cover housing the cable drum with the rotary plug, the pulley for a power cable, and the drive motor with the drive belt, an extendable filter basket on the pool robot, one in the Cover housing mounted flap with a control unit, as well as under protection and in the distance to the swimming pool a current transformer <Tb> FIG. 2 <SEP> a schematic side view of a pool robot mounted on the inner wall of a swimming pool with a cover housing and pool robot mounted cable drum with the rotary plug for a power cable, as well as the drive motor with the drive belt, a cable clamping set, a glass cylinder, a retractable filter basket, an im Cover housing mounted flap, a cable stretchers, as well as under protection and in the distance to the swimming pool a current transformer <Tb> FIG. 3 <SEP> A schematic side view of a pool robot mounted on the inside wall of a swimming pool with a cover housing and a cable drum mounted in the pool robot, a suction bell, a filter basket to be opened, a cleaning system, a cover mounted in the cover housing, and protected and spaced from the swimming pool a current transformer <Tb> FIG. 4 <SEP> A schematic side view of a swimming pool robotic pool robot with a detective mechanism mounted in a protected space, a power cable, a current transformer, command input, remote control shelf and a watertight plug on the pool robot <Tb> FIG. FIG. 5 shows a schematic side view of a pool robot on a set-up basin, which is positioned on an adjustable platform and, if necessary, the platform can be tilted by means of a pivot bearing and an actuator <Tb> FIG. FIG. 6 is a schematic side view of a pool robot attached to an adjustable platform and for removing the debris the platform is tiltable by means of a pivot bearing and an actuator or buoyancy body with locking <Tb> FIG. 7 <SEP> A schematic side view of a pool robot in two positions on and in the swimming pool, with a submersible pump and a hose, and a hinged opening for a waterfall and lighting.

Only the essential elements for the immediate understanding of the invention are shown schematically.

Way to carry out the invention

Fig. 1 shows a schematic side view of a pool robot 1, attached to the inner wall 2 of a swimming pool 3 with a cover housing 4 with an edge protection 4a in which the cable drum 5 with the rotary plug 6, the guide roller 7 is attached to the power cable 8, and the drive motor 9 with the drive belt 10, an extendable filter 11 on the pool robot 1, a flap 12 mounted in the cover 4 with a control unit 13, and in the shelter 14 and at a distance from the swimming pool 3, a current transformer 15th

The pool robot 1, contrary to other pool robots does not leave the pool 3 after use, but is parked at the top R on the inner wall 2 of the swimming pool 3, either partially submerged under the waterline WL or can be at an overflow swimming pool also completely below the waterline WL be appropriate. For this purpose, it requires a lifting means in the form of a cable drum 5 and advantageously a deflection roller 7, which is attached to a support 22 and this is connected to the inner wall 2 of the swimming pool 3. At this support 22, the cover housing 4 is fixed in the future, which covers the technology and serves as a parking garage for the pool robot 1, this also stabilized, and protects the users of the swimming pool 3 from injury in connection with the technology, as well as the technique from damage Third preserved. On the open side of the cover 4 is an edge protection, which additionally protects the float. Also, the cover housing 4 can take the shape of the pool robot 1, be completed to the inner wall 2 formally, so when using the pool robot 1, the cover 4 must be opened so that the pool robot 1 can drive out of the case down. In addition, the cover 4 has a flap 12 which can be opened for service and filter replacement and on the inside of the flap 12 can be a controller 13 attach to the pool robot 1 to control.

The pool robot 1 is advantageously vertically parked and in the start position, i. E. as soon as the device is ready for use, it can extend down the inner wall 2 and take up the corresponding cleaning work. The pool robot 1 has wheels 16 or caterpillars 17, which face the inner wall 2 and has a cable design 18 at the rear of the pool robot 1, which can also be articulated and so the power cable 8, which floats and thus optimally in the water W can swim , The pool robot 1 has one or more suction openings 19 and a Saugwasseraustritt 20 on which the filter 11 is mounted in the form of a collecting basket or bag and has a corresponding mesh size, so that the water flow through W but the collected debris in the filter 11 is stopped. Such a filter 11 represents the state of the art.

Now launches the pool robot 1 his cleaning work and drives the inner wall 2 down to the bottom 21, see Fig. 4, starts at the same time moored to the carrier 22 drive motor 9 to which a Pulley 23 is mounted and connected to the drive belt 10 , which in turn acts with the pulley 23, which is mounted on the cable drum 5, so that at the same time the power cable 8 is electrically handled by the cable drum 5 by means of the drive motor 9 with the drive shot of the pool robot 1 and in such a way that no braking effect on the pool robot. 1 exists and the device thus free as all other pool robots 1 otherwise, can do its job. The function of the guide roller 7, which is mounted angled and possibly a second required next to create space for the pool robot 1, so this are raised higher namely directly to the cable drum 5 and the power cable 8 so the pool robot 1 vertically to Cable version 18 stops. The pool robot 1 can also be rail-guided within the cover housing 4.

If the cleaning process is completed, the pool robot 1 is not as usual simply from the power and does not have to be retrieved by a person to the edge of the swimming pool 3 by pulling on the power cable 8, but the electric drive motor 9 now rotates in the opposite direction and rolls the power cable 8, wherein the pool robot 1 keeps his wheels 16 or caterpillars 17 in operation, in the direction of cable drum 5, the power cable 8 ultimately forced way leads into the cover 4, even if the wheels may be in certain moments in To steer in a different direction, so that extremely simple, fast and reliable find the parking position and parked. In addition, the pool robot 1 remains suspended in the sleep mode on the power cable 8. The drive motor 9 has a brake or a transmission with self-locking, so that the pool robot 1 remains securely held when not in use in the cover 4.

The wireless solution described in the patent PCT / IL 2013/051 055 is complex and complex, especially for larger swimming pools 3 with L or kidney-shaped design. If such a wireless pool robot strikes 1, someone has to jump into the water W, dive and bring the device ashore, or have a pole with a corresponding pickup hook ready. In the inventive solution, the pool robot 1 can be obtained in case of power failure or other failure by means of a crank which is inserted into the crank hole 24, but also with pulling on the power cable 8, the device can be brought to land at any time.

The pool robot 1 and the cover housing 4 are coated with an antimicrobial glaze or the antimicrobial pigments, which are e.g. Nano-silver particles or silver ions or based on copper, are mixed according to the plastic, so they do not require special cleaning. The cover housing 4 can be solved by means of quick release at any time and additionally cleaned on land, this also applies to the pool robot 1. Basically, such biocide coatings have a lifetime of 10 years and more.

Not shown is the slip clutch between the drive motor 9 and the pulley 23 or a train sensor between power cable 8 and pool robot 1, so is stopped in the case of the pool robot 1 on the way back from an object, the drive motor 9 is not overloaded and timed off automatically , triggers an alarm, be it visually, acoustically or by radio to a smartphone. Furthermore, the drive motor 9 can be driven by means of water pressure, which takes place from the water supply into the swimming pool 3 or is obtained by means of negative pressure from the pool circulation pump. The rotation conversion takes place at the end stop of the cable drum 5 by means of a mechanical reversing valve or by means of an electrically controlled valve.

The stream S is discharged from the household, e.g. 220V AC in a current transformer 15 which is spaced from the swimming pool in the shelter 14 in e.g. 24 V DC converted, then by means of the inflow line 25, the current S from the current transformer 15 via the inner wall 2, respectively. Carrier 22 led to the rotary plug 6. The waterproof rotary plug 6 is introduced into the cable drum 6 centrally mounted in the power socket 6a and the current S is then guided via the power cable 8 to the cable version 18 of the pool robot 1 and distributed there to the appropriate consumers.

If the pool robot 1 designed as a pressure or suction device, thus no power supply to the pool robot 1, so can be housed in the cover 4, the corresponding power pump and thus the system is independent of the pool system and placement of a corresponding skimmer. In such a hose, instead of the power cable 8, a glass fiber can be inserted, so that by means of a light source in the cover 4, the pool robot has an "electroless" lighting.

Fig. 2 shows a schematic side view of a pool robot 1, attached to the inner wall 2 of a swimming pool 3 with a cover housing 4 and mounted in the pool robot 1 cable drum 5 with the rotary plug 6 for a power cable 8, and the drive motor 9 with the drive belt 10th , a cable clamping set 8a, a glass cylinder 26, an extendable filter 11, a cover 12 mounted in the cover 4, a cable expander 27, and a shelter 14 and at a distance from the swimming pool 3, a current transformer 15th

In this configuration, the cable drum 5 is in the pool robot 1, also driven by a drive motor 9, to which also a pulley 23 is fixed, which acts by means of the Antriebriemens 10 on the second Pulley 23, which is connected to the pressure roller 28 and a part of the cable clamping set 8a, by two pressure rollers 28 act on the power cable 8. When extending the cable clamping set 8a exerts a train on the part of the power cable 8, which is still on the cable drum 5, thus ensuring that the power cable 8 extends neatly. When the power cable 8 is retracted again, the pulley 23, which is fastened to the drive motor 9, enters a freewheeling mode, so that the cable clamping set 8a is not active and there is no risk that the power cable 8 will retract faster than it does on the cable drum 5 can be wound up.

In this case too, the flow S is discharged from the household, e.g. 220V AC in a current transformer 15, in e.g. 24 V DC and converted by means of the feed line 25, the current S over the edge R to the carrier 22, where there is a moored cable connector 27. The power cable 8 is connected to the cable connector 27 and a strain relief 29 ensures that the weight of a pool robot 1 can be easily carried. The power cable 8 is ultimately wound on the cable drum 5 and the current S is guided from the power socket 6a in the rotary connector 6 and from there the current S via power distributor 30 goes to the various consumers. In this way, the power cable 8 can be easily extended by a motor as soon as the pool robot 1 is in motion and after cleaning the pool 3, the power cable 8 is retracted by a motor and the pool robot 1 follows the power cable 8, respectively. to the beginning of the power cable 8 to the strain relief 29 high. A sensor or limit switch, not shown here, stops the pool robot 1 at the desired location. The drive motor 9 may be provided with a lock or e.g. a self-locking worm gear be equipped so that without rotation of the drive motor 9, the pool robot 1 can not move. The advantage of a cable connector 27 is, which is logically waterproof, that in the case of the pool robot 1 needs a land service, this can be decoupled without much effort and the device is free to move.

The pool robot 1 can thus easily drive in and out of the cover 4 and is not visible in the parking division. After cleaning work done the user of the swimming pool 3 can easily open the flap 12 and remove the filter 11 from the pool robot 1 with a handle - according to arrow T - and dispose of the debris at a suitable location, wash the filter 11, this again in the pool robot 1 use , close the flap 12 and have provided for the next cleaning process. A sensor ensures that without the filter 11 inserted, the pool robot 1 can not be sent on the cleaning tour, since it would only uselessly consume power S. Also not shown is a sensor which indicates when the filter 11 is full.

In the interior of the pool robot 1 is further a glass cylinder 26. This emits UV light, e.g. the 254 Nm and 185 Nm class and helps the water flowing through, but especially the debris in the filter 11, germ-free.

The UV light source 31 is located in the shelter 14, which may be a secured room in the house, and is by means of a glass fiber, which in a hybrid cable - a cable which carries electricity and light or a hybrid tube, which carries electricity and light - Is fed and carried out accordingly on the cable drum 5 and connected to the glass cylinder 26. Such a glass cylinder 26, this can also be made of plastic, is sanded on the desired sides, so that there the UV light can escape. Of course, the light output decreases over the distance in the hybrid cable, but the UV light source 31, which is operated on land with 220 V AC, can provide a high performance and is turned on only during the cleaning process and is turned on during the parking position of the pool robot 1, ie The power consumption is low, the germ killing but effective. It is also conceivable that such a UV light source 31, operated at 24 V, is attached to the flap 12 and, after each cleaning operation, the filter 11 is automatically irradiated with UV light. If the flap 12 is opened during the irradiation, the UV light source 31 extinguishes immediately in order to prevent eye damage. The fiber-optic cable integrated in the power cable 8 or in the hose can also be used to illuminate the pool robot 1 in that the housing is transparent and, instead of the UV lamp, LED lighting is mounted. In place of the power cable 8, a hose may be mounted, which transports water W and in the case of the pool robot 1 has no own filter 11, the debris is sucked up and fed directly to the standard cleaning system of the swimming pool 3 or the filter 11 is fastened to the cover 4 ,

3 shows a schematic side view of a pool robot 1, attached to the inner wall 2 of a swimming pool 3 with a cover housing 4 and cable drum 5 mounted in the pool robot 1, power cable 8, suction motor 32, a suction bell 33, a filter 11 to be opened, a cleaning system 34, a cover 12 mounted in the cover 4, shelter 14 and at a distance from the swimming pool 3, a current transformer 15th

This configuration is the same as that in Fig. 2, in that the cable drum 5 is fixed in the pool robot 1. Only the cleaning of the filter 11 is different. The debris is sucked in as usual together with the water W from the suction motor 32 by means of the suction port 19 as indicated by arrow S and then forwarded to the filter 11, the debris hanging there and the water W is directed to the Saugwasseraustritt 20 in the swimming pool 3.

If the cleaning process in the swimming pool 3 completed, the pool robot 1 moves back to its parking position in the cover 4. Instead now manually clean the filter 11, located in the cover 4 a suction bell 33 to which a filter opener 35 is attached, which at Retracting the pool robot 1 so that individually or in several parts the filter 11 opens at the rear. The opening takes place e.g. by the filter 11 is folded in one or more parts or pushed to the side, positively controlled or electrically or hydraulically acts. If the filter 11 is open, the collected debris in the filter 11 by means of the standard circulating pump of the standard cleaning system of the swimming pool 3 in cooperation with the suction bell 33 and the tube 36, which leads to the standard circulation pump, sucked, as indicated by arrow V. Thereafter is taken with the water pipe 37, which is located at the edge of the Absaugglocke 33, fresh water or water W from the swimming pool 3 and pressed under pressure in the double-walled cleaning cylinder 34 a, by means of inwardly toward filter 11, mounted nozzles 38, the filter 11 also remove small dirt and supply by means of the suction bell 33, the contaminated water W of the standard circulating pump to clean this in the standard cleaning system of the swimming pool 3. Of course, a UV light source 31 can also be mounted in this system within the pool robot 1.

4 shows a schematic side view of a pool robot 1 in the swimming pool 2, with a cable drum 5 mounted in a protected space, a power cable 8, a current transformer 15, control unit 13, remote control 40 and a watertight cable plug 27 on the pool robot 1.

In this version, the cover 4 is spaced from the swimming pool 3 on land and in the shelter 14, which is a box or room and, according to the legal standards is at a distance from the swimming pool 3 where 220 V AC are allowed and at the same time When the cleaning process is called, the pool robot 1 moves horizontally over land, at the same time the drive motor 9 unwinds the cable drum 5 with the power cable 8 and the pool robot 1 at the point, eg at the same time represents a rubbing strip 39 or the power cable 8 has a scraper, which withstands the rubbing friction, the device tilts itself into the water W and starts its work The pool robot 1 has for this purpose a water sensor 51, which the cleaning activity of the pool robot 1 only then allows, when the pool robot 1 is immersed in the swimming pool 3 and also serves for applications as shown in Fig. 5. Such a water sensor 51 operates e.g. so that it measures the conductivity of the water W or there is a hydro-barometer installed at the corresponding pressure triggers the contact or it is a small air ball, a kind of table tennis ball, which pushes against contactors in a buoyancy and in this way the contact to Cleaning activity triggers. After cleaning, the command of the return and the drive motor 9 is spooling the cable drum 5 with the power cable 8 and ultimately the pool robot 1 reaches the edge R vertically and requires at this edge of the power cable 8, respectively. the electrically driven cable drum 5, a little more train, the wheels 16 or caterpillars 17 of the pool robot 1 continue to turn until the pool robot 1 tilts under train in the horizontal and so the device ultimately moves back into the parking position in the shelter 14. The pool robot 1 has a cable plug 27 directly on the device, which e.g. is screwed and does not open automatically on rotations of the pool robot 1 about the longitudinal axis and the tensile forces during rewinding of the pool robot 1 in the parking position easily survives.

In the shelter 14, the control unit 13 can be installed at the same time, as well as a storage location for the remote control 40, which is equipped by means of piezotaves and radio transmission, so they need no battery and can be hermetically sealed.

Due to the automatic pathfinding into the swimming pool 3, as well as the safe return to the cover 4 by means of rolling up the power cable 8, the control unit 13 also has a programmable timer, which makes it possible e.g. at night to clean the surfaces in the swimming pool 3, because the noise of a pool robot 1 under water is anyway very low and thus benefits from the night tariff.

Fig. 5 shows a schematic side view of a pool robot 1 at a Aufstellbecken 3a, with a mounted on the pelvis Ra parking frame 41 for the pool robot 1, with a cover 4 and a door 42 attached thereto, and a pivot bearing 43 with an actuator 44th , as well as cable drum 5, power cable 8, current transformer 15.

Aufstellbecken 3a are usually smaller than the embedded in the terrain swimming pools 3, but need the same water care and still have the disadvantage no pool robot 1 can use convenient, because this first lifted above the pool edge Ra, then lowered on the inside into the water W. must become. After cleaning work, the same work is done in reverse order, namely the pool robot 1 using the robot power cable to pick up, the trapped water W flow out of the device and then outside the Aufstellbeckens 3a on the stone floor or lawn, respectively. put on the wheelbarrow and finally to provide the whole thing in a shed. The solution for above-ground pools 3a, which already have less space inside, is to put the pool robot 1 on a parking stand 41, which is connected by means of a carrier 22 with the pool edge Ra of the Aufstellbeckens 3a. Between the parking stand 41 and the carrier 22, a pivot bearing 43 is mounted and an actuator 44, e.g. an electric cylinder with spindle drive can be, but can also be operated manually. The parking frame 41 has a cover 4, which has a gate 42 on the front, which can be opened by gravity, motor or positively controlled and in the cover 4, the cable drum 5 is also integrated with the drive motor 9.

Of course, the cable drum 5 can also be moored next to the pool robot 1 or mounted flat lying, this is an additional guide pulley 7 for the power cable 8 necessary, even with this parking device, the cover 4 can do without cable drum 5 by the pool robot. 1 carries the cable drum 5 itself. So that the pool robot 1 does not suck outside of the water W, an odometer or protractor is attached to the cable drum 5 by e.g. after 0.5 m cable to start the suction motor 32 only.

If a cleaning cycle to be started, the control unit 13 first issued the command to the actuator 44, the parking frame 41 to pivot from the stationary horizontal position to the active vertical position, according to arrow K. Once the vertical position is taken, starts the pool robot 1 does its work and moves down, whereby previously motor or due to gravity already, the gate 42 is unfolded and thus the way for the pool robot 1 is free. At the same time, the electrically driven cable drum 5 starts to unwind the power cable 8 so that the pool robot 1 never has to pull on the power cable 8. The cleaning of the inner surfaces of the Aufstellbeckens 3a takes place only after contact of the water sensor 51 on the pool robot 1. After work, the pool robot 1 automatically moves back into the cover 4, at the same time the power cable 8 is wound by the cable drum 5 and also serves as safe guidance in the parking position. Above the waterline WL, the pool robot 1 resets its cleaning activity or does so with a time delay so that the tracks 17 or wheels 16 remain active until they stop in the cover housing 4. Thereafter pivots the parking rack 41 driven by the actuator 44, together with the cover 4 in the parking position, which is the horizontal position or the entire Schwenkprozedere done manually. The gate 42 is closed by gravity, motor or positively controlled, so that the pool robot 1 is invisibly supplied in a form-fitting garage on the top of the pool 3a, the cover 4 also serves as a springboard or seat or as a basis for the water feature 45, as in Fig. 7 is shown.

Fig. 6 is a schematic side view of a pool robot 1 to a swimming pool 3, which is mounted on an adjustable parking rack 41 and the storage rack 41 by means of a pivot bearing 43 and an actuator 44 or a buoyancy body 53 with lock 54 is tilted to remove the debris ,

A large number of pool robots 1 on the market has an opening for the filter cleaning, respectively. its replacement, which is located at the top of the device. So that such devices do not need to be rebuilt for the garage version, the tilting version already shown in Fig. 5 is offered for Aufstellpools for built-in tools, in which case the cable drum 5 respectively. Hose reel is not shown, and not the power or water supply.

The pool robot 1 acts like the versions described in Fig. 1 or Fig. 2, except that the removal of the filter 11 is not at the end of the device but on the top of the pool robot 1. For this purpose, the entire garage ie the parking frame 41 together with the cover 4, the guide elements and cable guide not shown here for the safe and accurate retrieve the pool robot 1 from the water W, pivoted by means of the actuator 44 and the pivot bearing 43 from the vertical position to the horizontal position. The actuator 44 may act electrically or by means of a gas, metal or plastic spring and serves to ensure that as soon as the lock 54 is released, e.g. by means of the handle 54a, the whole device automatically pivots. Because the pool robot 1 contains a hydrodynamic lift over a large part of the pivoting stroke K itself, the actuator 44 has to perform its full power only after the pool robot 1 has dived out above the waterline WL. This can also be supported manually by a gripping recess 55 is attached to the cover housing, so that the whole thing can be brought into the horizontal position without great forces and is also locked there automatically. As an alternative to the actuator 44, a buoyancy body 53 can be attached laterally by the pool robot 1, which generates a hydrodynamic lift by means of a hinged linkage 56 and a guide 57, which acts over the entire swing stroke K and in this way the parking frame 41 together with the cover housing 4 and Pool robot 1 lifts. The lowering takes place by manual pressing against the cover 4, since the buoyancy forces are relatively low and only slightly exceed the weight of the device.

In the horizontal position of the cover 4 is thus at the now above-sided point the flap 12, which can be opened so that the filter 11 in the pool robot 1 according to arrow T by a person is easily removed. The free and unused end of the cover 4 in this case can be attached at this point the controller 13 or at least one display which is connected by means of Bluetooth or WIFI to the controller 13 and in the vertical position of the cover 4, e.g. the water temperature, pH and similar data can be conveniently seen from the swimming pool edge R.

If the swimming pool operator wishes to cover the swimming pool 3 and thus no cleaning activity takes place by means of the pool robot 1, then by means of the actuator 44 the whole apparatus, i. E. Pool robot 1 are driven together with the cover 4 in the horizontal to make room for the pool cover.

Fig. 7 shows a schematic side view of a pool robot 1, in the position at or in the swimming pool 3, with a submersible pump 46 below the waterline WL and a water hose 47, and a hinged opening 48 with a water feature 45 and a LED illumination 49th ,

The embodiment here shows the placements of a pool robot 1 in the swimming pool 3 or the Aufstellbecken 3a. The space required a cover housing 4 for parking a pool robot 1, can also be ideally used as a water feature 45 in various versions by the cover 4 a hinged opening 48 is located, which has underneath a water guide 50, which, for. as a cross tube is equipped with a number of nozzles and thus generates a wide fountain pattern or is an adjustable nozzle, which serves as a surge shower or a transverse narrow trough is mounted, thus generating a waterfall, with a LED illumination 49 is mounted before the exiting water flow, so that in the dark the outflowing water W is illuminated. The water W for the water feature 45 is advantageously sucked directly from the pool 3 or 3 Aufstellbecken of the submersible pump 46 and then with appropriate, possibly adjustable pressure, through the water hose 47 to the water guide 50 promote. Once the attraction of a water feature 45 is no longer desired, the hinged opening 48 can close again, the power to the submersible pump 46 is also turned off and the cover 4 is again a simple case on the edge R, Ra a swimming pool 3 or Aufstellbeckens 3a. Of course, not necessarily a hinged opening 48 may be appropriate, there may also be a slot in the cover 4 and by means of the water pressure springs from there from the corresponding water feature 45th

Furthermore, the cover housing 4, in the vertical embodiment, have further technical means, which has the advantage that no additional holes in the swimming pool mounted and possibly must be sealed by these technical means are attached to the cover 4 , such as a staircase or ladder 52, a control unit 13, display, as well as a separate pool lighting by means of the LED illumination 49a or a camera 58 with possibly a microphone that monitors the pool. With regard to pool monitoring, this is the subject of another patent.

In addition, a deflector 59 can be attached to the cover housing 4, which forcibly guided at some pool robots control means, which also serve as handles when driving into the parking position fold down to generate the smallest possible space requirements.

Of course, the invention is not limited to the embodiments shown and described.

LIST OF REFERENCE NUMBERS

[0055] <Tb> 1 <September> Pool robots <Tb> 2 <September> inner wall <Tb> 3 <September> Swimming <Tb> 3 <September> ground pools <Tb> 4 <September> cover housing <Tb> 4 <September> edge protection <Tb> 5 <September> cable reel <Tb> 6 <September> turning connector <Tb> 6 <September> Power Port <Tb> 7 <September> guide roller <Tb> 8 <September> Power Cable <Tb> 8 <September> cable clamping set <Tb> 9 <September> drive motor <Tb> 10 <September> Transmission belts <Tb> 11 <September> Filters <Tb> 12 <September> flap <Tb> 13 <September> Control Unit <Tb> 14 <September> shelter <Tb> 15 <September> current transformer <Tb> 16 <September> Wheels <Tb> 17 <September> Crawler <Tb> 18 <September> cable outlet <Tb> 19 <September> suction ports <Tb> 20 <September> Saugwasseraustritt <Tb> 21 <September> Floor <Tb> 22 <September> carrier <Tb> 23 <September> Pulley <Tb> 24 <September> crank hole <Tb> 25 <September> influx line <Tb> 26 <September> glass cylinder <Tb> 27 <September> Cable stretcher <Tb> 28 <September> pressure roller <Tb> 29 <September> strain relief <Tb> 30 <September> Power Distributors <Tb> 31 <September> light source <Tb> 32 <September> naturally aspirated <Tb> 33 <September> Containment Cap <Tb> 34 <September> cleaning system <Tb> 34 <September> Cleaning cylinder <Tb> 35 <September> Filteröffner <Tb> 36 <September> Pipe <Tb> 37 <September> Water pipe <Tb> 38 <September> Nozzles <Tb> 39 <September> skirting board <Tb> 40 <September> Remote Control <Tb> 41 <September> parking stand <Tb> 42 <September> Tor <Tb> 43 <September> pivot <Tb> 44 <September> Actuator <Tb> 45 <September> Water Game <Tb> 46 <September> submersible pump <Tb> 47 <September> water hose <Tb> 48 <September> opening <tb> 49 <SEP> LED lighting water feature <tb> 49a <SEP> LED lighting pool <Tb> 50 <September> Water management <Tb> 51 <September> Water Sensor <Tb> 52 <September> Head <Tb> 53 <September> float <Tb> 54 <September> locking <Tb> 54 <September> handle <Tb> 55 <September> grip <Tb> 56 <September> Rails <Tb> 57 <September> Leadership <Tb> 58 <September> Camera <Tb> 59 <September> deflector <tb> Arrow V <SEP> Extracting to the standard cleaning system <tb> Arrow P <SEP> Aspirate in filter 11 <tb> K <SEP> Swing Stroke Parking Frame 41 <Tb> W <September> Water <Tb> WL <September> waterline <Tb> L <September> Klappenöffnungsweg <Tb> S <September> Power <tb> R <SEP> edge pool 3 <Tb> T <September> filter change <Tb> Ra <September> Poolside

Claims (14)

1. pool robot (1), characterized the pool robot (1) is parked and stabilized vertically or horizontally in the cover housing (4) in rest mode and is connected to the power cable (8) on the cable drum (5) which is in the cover housing (4) when the pool robot (1) is returned. serves as a tension and guide means and in the rest position as a detent, the Schwenkhub (K) by means of an actuator (44) or a buoyancy body (53), as well as the pivot bearing (43) and parking frame (41) and the filter (11) Opening the flap (12) on the cover housing (4) manually changed or this automatically cleaned by a cleaning device (33,34,36,37,38) or without filter (11) in the pool robot (1), by means of a water-carrying power cable (8) to the filter (11) on the cover housing (4) is cleaned or the cleaning in the main filter system of the swimming pool (3) and the cable drum (5) directly or indirectly by a drive motor (9) with a brake or transmission with self-locking or e Ines fluids or manually operated. 2. pool robot (1) according to claim 1, characterized in that the pool robot (1) in the cover housing (4) is parked horizontally on the waterline (WL) vertically, on land or completely above the waterline (WL) and in the horizontal parked version the pool robot (1) is controlled by a water sensor (51 ) or a displacement or angle sensor is attached to the cable drum (5). 3. pool robot (1) according to one of the preceding claims, characterized that the cable drum (5) for winding and unwinding the power cable (8) and if necessary has a crank with crank hole (24) for manual use and for emergency has a slip clutch. 4. pool robot (1) according to one of the preceding claims, characterized in the pool robot (1), which has a cable drum (5), a cable clamping set (8a) is mounted and a pulley (23) has a freewheel or and that a pull sensor is attached to the power cable (8). 5. pool robot (1) according to one of the preceding claims, characterized the power cable (8) supplies the pool robot (1) with power (S) or light by means of a glass fiber as a hybrid cable, and also serves as a water-conducting hose. 6. pool robot (1) according to one of the preceding claims, characterized that the pool robot (1) active means of driving the wheels (16) or caterpillars (17) purposefully in the cover housing (4) or in the shelter (14) mitfährt but not faster than the Aufwickeltempo the cable drum (5). 7. pool robot (1) according to one of the preceding claims, characterized in that the glass cylinder (26) emits a UV light from a UV light source (31) by means of integrated glass fiber in the power cable (8) and is active for a certain time during travel of the pool robot (1) or only after the cleaning process or instead of UV light source (31) a LED light source for internal and external illumination of the pool robot (31) is used. 8. pool robot (1) according to one of the preceding claims, characterized in that for comprehensive automatic cleaning of the filter (11) a filter opener (35) for automatic opening of the filter (11), and a cleaning device (33, 34a, 36, 37, 38), consisting of the suction bell (33), with cleaning cylinder ( 34a), nozzles (38), pipe (36) and water pipe (37). 9. pool robot (1) according to one of the preceding claims, characterized that the pool robot (1) in the rest position on a by means of an actuator (44) and a pivot bearing (43) and support (22) connected parking rack (41) is parked horizontally and must be placed vertically for cleaning to activate this for cleaning , 10. pool robot (1) according to one of the preceding claims, characterized that the pool robot (1) and the cover housing (4) has an antimicrobial glaze or that it is mixed with the plastic. 11. pool robot (1) according to one of the preceding claims, characterized that the antimicrobial additives are based on copper or silver in the form of nanoparticles or ions. 12. pool robot (1) according to one of the preceding claims, characterized in that the control unit (13) has a programmable timer or external parameters are included in the control unit (13) in order to submerge the pool robot (1), emerge and move it back into the cover housing (4). 13. pool robot (1) according to one of the preceding claims, characterized in that the cover housing (4) has a foldable opening (48) for water features (45), with a water hose (47), a water guide (50) and optionally an illumination (49) and a submersible pump (46) mounted on the water hose (47) is. 14. pool robot (1) according to one of the preceding claims, characterized the pool robot (1) has technical means which are fastened to the cover housing (4), which are control unit (13), display, ladder (52), LED lighting (49a), camera (58), deflector (59) ,