The invention relates to a launcher for a slide as well as a method for launching a slide run in a slide chute for at least one user, in particular in a water slide chute.
A water slide is known from DE 10 2006 062 349 in which a slide chute has a run-up section and an outlet section flowing into an outlet, wherein at least one loop section is provided between the run-up section and the outlet section which has a circumferential angle of at least 270° and is inclined by 5° to 80° compared to a vertical at least between a launch point and an apex of the loop section. Such a looping slide is used in water parks or adventure parks and increases the attraction of such parks.
The requirements for the attraction of such parks, in particular the slides thereof, are constantly increasing.
The object of the invention is to create a further attraction for slides, in particular water slides.
This object is solved by a launcher for a slide, in particular a water slide, having the features of claim 1.
Using a launch ramp of the launcher, it is enabled that a person is able to be transferred from a loading position of the launch ramp in which a slide surface is arranged to be substantially horizontal or slightly inclined, into a launch position from which the user experiences increased acceleration due to the incline of the slide surface in the launch position after the release of the launch position by the blocking device. The blocking device releases the slide surface after assumption of the launch position, whereby the impression of increased acceleration or even a free fall depending on the incline can be imparted to the user in a first launch phase. The attraction of such a slide is thereby increased even in the launch phase. Such a launcher can be used both for a slide in which the user slides in his clothes on the slide surface or with aids such as, for example, a mat, and for water slides which can be used with and without tyres.
Preferably, the launch ramp and/or the first slide element or the slide element allocated to the outlet-side end of the launch ramp is formed to be tubular. The tubular design is advantageous, in particular in the case of a high launch incline of the slide surface in the launch phase of the launch ramp in order to keep the user safely within the slide chute. Preferably, the launch ramp and/or the first slide element can be formed to be transparent or at least partially transparent.
A further preferred embodiment of the launcher provides that, in a loading position of the launch ramp, an outlet-side end of the launch ramp is arranged separately to the inlet-side end of the first slide element of the slide chute which is allocated to the launch ramp. Therefore, the launch ramp is received to be pivotable around a pivot axis which is arranged separately to the slide element. Such an arrangement can have advantages for the control of the pivot movement as lower pivot forces can be required.
Preferably, in the case of the embodiment above, the slide surface of the outlet-side end of the slide element of the launch ramp is set back compared to an upper section of the slide element. An outlet-side end of the launch ramp which runs at an angle is thereby created which corresponds to a complementarily-formed inlet-side end of the slide element. This enables a simple pivoting together of the outlet-side end of the launch ramp to the fixedly-arranged first slide element.
An alternative embodiment of the launcher provides that an outlet-side end of the launch ramp and an inlet-side end of the first slide element allocated to the launch ramp are connected to each other with an articulated joint, preferably adjacent in or on the slide surface. This arrangement enables a firm connection between the fixed first slide element and the pivotable slide section of the launch ramp with respect to each other and therefore a simple folding mechanism.
Advantageously, the slide section of the launch ramp and the first slide element are formed and are allocated to each other in such a way that a closed transition is formed during the positioning of the launch ramp in the launch position between the two. Safe sliding can thereby be enabled, wherein at the same time a larger angular range between the positioning of the slide surface of the launch ramp in the loading position and in the launch position is enabled.
Preferably, the closed transition between the slide section of the launch ramp in the launch position and the first slide element is detected using a monitoring device which emits a release signal to control the blocking device only after proper assumption of the launch position. It can thereby be ensured that the blocking device only then releases the slide surface when the transition is closed. Alternatively it can be provided that the user located in the loading zone can manually trigger the launch procedure, so the opening of the blocking device from an initial position into a release position, himself, wherein this self-triggering is only then possible after the monitoring device has emitted a release signal.
The outlet-side end of the slide section of the launch ramp is adapted to the inlet-side region of the first slide element at least in the region of the slide surface or overlaps this. An injury-free transition can thereby be formed. Additionally, a loss-free water supply in the case of the design of a water slide is also provided without a liquid supporting the slide run escaping at the junction.
Furthermore, preferably, the slide surface of the launch ramp is able to be transferred into the incline of the slide surface of the first slide element. A particularly good launch phase having a high acceleration can thereby be achieved.
The launch ramp is preferably arranged to be pivotable in a region from 0° to 90° around a bearing axis. On the one hand, a simple loading and on the other hand, a maximum acceleration in the launch phase can thereby be achieved. Preferably, the pivot region is formed between 5° and 85°.
Furthermore, preferably the slide surface of the launch ramp is able to be transferred from a loading position with an incline from 0° to 15° compared to the horizontal, into a launch position from 15° to 89°, preferably 45° to 90°, and in particular 60° to 85°.
The blocking element provided in the launch ramp is formed as a pivotable or displaceable blocking element which is controlled and monitored by a control device and is actuated by a drive element. Preferably, a valvular element or a trapdoor, or even a double trapdoor, is used.
The blocking element is preferably arranged to be pivotable and/or displaceable outside of the slide surface. The slide surface can thereby be formed without interruption such that there are optimal slide ratios during the launch phase and a direct sliding of persons on the slide surface is also enabled.
In the event of use of the launch ramp for a launcher for water slides, a front side of the blocking element of the blocking device is preferably arranged at a short distance to the slide surface. The blocking element thereby fulfils a type of water accumulation function. This means that a water film can accumulate on the slide surface, whereby in turn the launch conditions are supported.
A further advantageous embodiment of the method provides that a conveyance device is allocated to the loading zone of the launch ramp which is formed as a slide surface, as a roller belt or as a transport conveyor belt. A quick and safe filling of the loading zone of the launch ramp can thereby be enabled in order to achieve a short cycle time for the slide runs. Preferably, a separation device is provided between the conveyor device and the launch ramp or in the conveyor device. This is used in particular in the case of a tyre slide.
The object on which the invention is based is furthermore solved by a method according to the features of claim 15. In the method for launching a slide run in a slide chute having at least one user having a launcher of the type referred to above, the blocking device in the launch ramp is released only after the secure transfer of the launch ramp from a loading position into a launch position in order to be begin the slide run. This enables a controlled and monitored use of such a slide chute having increased attraction even in the launch phase of the slide run.
The invention as well as further advantageous embodiments and developments of the same are described and explained in more detail below by means of the examples depicted in the drawings. The features to be gleaned from the description and the drawings can be applied individually or together in any combination according to the invention. Here are shown:
In
The launcher 11 comprises at least one launch ramp 16 which comprises a slide section 17 having a slide surface 18. Furthermore, the launch ramp 16 can comprise a first slide element 19 which is adapted to an outlet-side end 22 of the launch ramp 16 with the inlet-side end 21 thereof.
The launch ramp 26 furthermore comprises a pivot device 30 with a bearing axis 31 around which the slide section 17 is arranged to be able to pivot. For the control of the pivot movement, the pivot device 30 comprises a drive and an actuator, such as, for example a lifting cylinder 32 which is depicted symbolically. This lifting cylinder 32 can be controlled hydraulically, pneumatically or in another way by a corresponding drive device 33 which is in turn controlled and monitored by a control device 35. Alternatively to the lifting cylinder 32, an electromotor, electromagnetic drive as well as a drive by means of a gear can also be provided which initiates a pivot movement of the bearing axis 31 and therefore of the slide section 17, whereby the slide section 17 is pivoted around the bearing axis 31.
A conveyor device 24 is allocated to an inlet-side end 23 of the launch ramp 16, said conveyor device 24 having a transport plane which is inclined slightly at an angle β compared to the horizontal. In this case, the conveyor device 24 is formed as a slide surface or roller belt. The conveyor device 24 can also be formed as a transport conveyor device having a driven transport belt. In this embodiment, the incline angle β can also be equal to zero.
The conveyor device 24 can comprise a separating device 26 using which controlled access into a loading zone 28 of the launch ramp 16 can be controlled. Alternatively to the separation device 26, a signal device can also be provided which is controlled via sensors which are provided at the inlet-side end 23 of the launch ramp 16 and/or on the conveyor device 24.
The slide section 17 of the launch ramp 16 is preferably formed as closed tubes. A loading zone 28 extends from an inlet-side end 23 to the blocking device 37. This loading zone 28 can extend in length in such a way that only one user, in particular with a tyre, can be received therein. Likewise, the loading zone 28 can also be formed for a double tyre or other slide aids, in particular for two, three or more people sliding together.
The blocking device 37 comprises a blocking element 36 which preferably extends completely over the cross-section of the tubular slide section 17, such that the slide section 17 is completely closed. A front-side end of the blocking element 36 which points towards the slide surface is preferably arranged at a short distance to the slide surface, such that a minimum quantity of liquid can enter in the case of use with a water slide.
The blocking element 36 can be pivoted upwards around a pivot axis arranged on the upper section of the slide section 17 and is preferably formed as a pivotable flap or trapdoor which is driven using the control device via a drive 38.
The slide section 17 of the launch ramp 16 and/or the first slide element 19 can, for example, be formed as a sliding surface or flat surface. Likewise, the slide surface 18 can be formed by rollers or a transport or roller belt. Likewise, alternatively, a trough-shaped slide surface 18, 20 can also be provided which is open upwardly. In this instance, however, the lateral edges are formed to be superelevated compared to the slide surface 18, 20 in order to guide the sliding person along the slide surface 18, 20. A water supply, in the case of a water slide, can occur directly into the first slide element 19 at the beginning of the slide surface 20 or already before this in the launch ramp 16, such that water flows into the slide element 19, wherein the first slide element 19 can also be additionally supplied with water.
The conveyor device 24, in the case of the design as a slide surface, can be adapted to the previously described alternative embodiment of the slide section 17. The same applies for the first slide element 19.
If the conveyor device 24 and/or the slide surfaces 18, 20 comprise rollers or a conveyor belt, sliding aids, such as, for example, mats, tyres or similar, are preferably used.
In
In the case of the design of a tubular slide section 17 and a tubular first slide element 19 according to
The slide element 19 is arranged at an angle γ compared to the horizontal which is formed, for example, to be smaller than 89°, wherein preferably an angle is set which ranges from greater than 45°, in particular greater than 60°, and in particular in the range from 75° to 85°. A particularly high acceleration can thereby be achieved.
The loading position 29 of the launch ramp 16 is monitored by sensors 39 which are coupled to the control device 35. These sensors 39 can also detect the loading of the loading zone 28. After a loading of the loading zone 28 by means of at least one user has occurred in the loading position 29, the control device 35 receives a corresponding signal. Alternatively, this can also be triggered manually by the user in the loading zone 28. Subsequently, the launch ramp 16 can be transferred from the loading position 29 into a launch position 41 according to
After the transfer of the launch ramp 16 from the loading position 29 into the launch position 41 according to
After the user has left the launch ramp 16 due to the transfer of the blocking device 37 into the release position 50, the sliding out from the launch ramp 16, for example by sensors in the slide section 17 of the launch ramp 16 or by sensors in the first slide element 19, can be detected or can be detected by a predetermined time expiry after transfer of the blocking device 37 from the initial position 48 into the release position 50, such that, in connection to this, the launch ramp 16 is guided back into the loading position 29 and the blocking element 36 is guided back into the initial position 48 via the control device 35. Subsequently, the loading procedure of the launcher 11 can occur again, after the sensors 39 have detected the assumption of the loading position 29 of the launch ramp 16.
In the case of the launcher 11 according to
In
In
In
The features referred to previously are each significant features of the invention alone or in any combination.
Number | Date | Country | Kind |
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10 2013 102 945 | Mar 2013 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/054541 | 3/10/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/146918 | 9/25/2014 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5167321 | Brodrick, Sr. | Dec 1992 | A |
5183437 | Millay et al. | Feb 1993 | A |
5704294 | Van Winkle | Jan 1998 | A |
7833107 | Garcia-Morales | Nov 2010 | B1 |
20050288113 | Langford | Dec 2005 | A1 |
Number | Date | Country |
---|---|---|
202590349 | Dec 2012 | CN |
20120561 | Mar 2002 | DE |
102006062349 | Jun 2008 | DE |
2500070 | Sep 2012 | EP |
0154783 | Aug 2001 | WO |
Entry |
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International Preliminary Report on Patentability dated Sep. 22, 2015, in PCT Application No. PCT/EP2014/054541. |
Number | Date | Country | |
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20160059138 A1 | Mar 2016 | US |