The invention relates to a water amusement ride comprising a watercraft which is moved in a body of water and which has a float borne by the water.
Such a water amusement ride is known from DE 10 2004 062 315 A1. The float borne by the water is connected in an articulated manner to a chassis, which is guided on rails situated at the bottom of the water, in such a way that the float is able to perform limited transverse or lifting motions with respect to the chassis. The chassis is preferably pulled through the body of water by means of a traction cable led over guide rollers.
A water amusement ride, referred to as a round boat ride, is known from DE 20 2005 018 045 U, in which floats having a circular horizontal projection move through a channel. The floats which carry passengers are moved by flow pumps or by flow generated by the natural hydraulic gradient of the channel. Contact with the channel walls imparts angular momentum to the floats which results in an uncontrolled, random rotation of the watercraft.
Proceeding from this prior art, the object of the present invention is to provide a water amusement ride in which the described rotational motion is produced without contacting channel walls.
This object is achieved according to the present invention by the fact that on a frame a float is provided which is rotatable with respect to the frame and has seats for accommodating passengers, and on the underside of the float a blade wheel is fixedly connected thereto in such a way that the float is set in rotational motion as it travels through the body of water.
According to the proposal stated in claim 2, the float has a circular platform similar to the watercraft known from DE 20 2005 018 046 U. The blade wheel connected to this platform is oriented coaxially thereto, the blades of the blade wheel projecting perpendicular to the direction of travel.
When the watercraft is moved through the body of water, the resulting flow imparts a rotational motion to the blade wheel and thus to the float.
Advantageous designs of the blades of the blade wheel are stated in claims 3 and 4.
According to the proposal stated in claim 5, a displaceable guide plate is associated with the blade wheel, by means of which the rotational direction and/or rotational speed of the blade wheel may be influenced. As stated in claim 6, the guide plate may be composed of a panel that is rotatably mounted parallel to the periphery of the blade wheel, and according to claim 7 the panel is connected to an actuator shaft which coincides with the blade wheel axis and which on its end situated in the passenger compartment has a handle, preferably a control lever or control wheel, for manually adjustment by a passenger.
According to the proposal stated in claim 8, however, the guide plate may also be automatically adjusted as a function of the path of the watercraft, for example according to claim 9, by use of a control curve associated with the path.
The rotational direction and optionally also the rotational speed of the blade wheel are modified by rotating the guide plate in one direction or the other.
As known in principle from DE 10 2004 062 315 A1, either the traction cable conveying device characterized in claim 10 or the flow drive characterized in claims 11 through 13 is provided for driving the watercraft.
The flow pumps proposed in claim 11, in the form of injection pumps according to claim 14, may also be used for controlling the rotational direction and rotational speed of the blade wheel and thus of the float connected thereto.
The subject matter of the invention is explained in detail below with reference to one preferred exemplary embodiment illustrated in the drawings, which show the following:
On the underside of the platform 24, located in the water, is provided a blade wheel 30 which is connected to the platform in a rotationally fixed manner and which has a design as shown in
To move the watercraft through the body of water 1 a traction cable 40 is provided in the body of water and is led via guide rollers (not illustrated), anchored at the water bottom 2, corresponding to the planned route for the watercraft. The traction cable 40 is driven by a geared motor 42 via the cable pulley 41. The frame 10 of the watercraft is connected to this traction cable 40 via cable couplings 13 and connecting cables 14. When the watercraft moves by means of the traction cable 40 in the direction of the arrow A, the resulting flow sets the blade wheel 30 and thus the float connected thereto in rotation.
Transverse braces 12 and a longitudinal brace 15 are provided for stabilizing the frame 10, as shown in greater detail in the bottom view according to
The design of the rotatable float 20 together with seats 21 and spray guns 22 is shown in detail in
Two structural designs illustrated in
The blade wheel 30 according to
For influencing the rotational direction and rotational speed of the blade wheel 30, a panel 32 is provided which extends over a sector of approximately 80° on the exterior of the blade wheel 30. This panel covers a portion of the chambers of the blade wheel. The panel is connected via the panel support 34 to the actuator shaft 33, which is guided upward into the passenger compartment through the center axis 36 of the blade wheel 30 and of the float 20, and which on its outer end has a control lever 35. By use of this control lever 35 the passengers 22 may change the position of the panel, for example by swiveling it from the position illustrated in
Number | Date | Country | Kind |
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10 2006 053 664 | Dec 2006 | DE | national |
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Number | Date | Country | |
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20080139328 A1 | Jun 2008 | US |