Fountain shutter

Abstract

This invention discloses an ornamental fountain wherein a fountain nozzle is made to discharge a pressurized stream of liquid, and a shutter prevents or allows the stream to exit.

Description

I FIELD OF THE INVENTION

This invention discloses an ornamental fountain wherein a fountain nozzle is made to discharge a pressurized stream of liquid, and a shutter prevents or allows the stream to exit.

II BACKGROUND OF THE INVENTION

U.S. Pat. No. 5,160,086 granted Nov. 3, 1992 is directed to a lighted laminar flow nozzle for use in decorative water fountains and industrial applications. It includes fluid flow through a double-walled bladder-like fluid supply hose 32 into a fluid chamber 10 and through a diffuser material 20 , past trapped air pockets 18 and exiting through a knife edged orifice 12 . The fluid nozzle is mounted upon one or more stages of vibration dampening springs 30 , and the outlet orifice 12 is located off center from the walls 11 of the fluid chamber so that pump surges and vibrations are greatly dampened and the output fluid stream 14 is sufficiently laminar that light is conducted through the length of the output fluid stream 14 similar to a fiber optic cable.

U.S. Pat. No. 5,641,120 granted Jun. 24, 1997 is an improvement on the first described U.S. Pat. No. 5,160,086. This U.S. Pat. No. 5,641,120 includes an improved method and apparatus for obtaining a laminar stream of fluid flow including providing a generally cylindrical outer wall 13 a, a generally cylindrical inner wall 14 defining a generally cylindrical outer chamber 13 ; introducing fluid into the outer chamber 13 tangentially at 12 , directing fluid flow within the outer chamber circumferentially through chamber 13 , providing an inner chamber 36 defined by the generally cylindrical inner wall located within or below the outer chamber 13 . An opening 33 is formed in the lower portion of the inner cylindrical wall 14 , which causes fluid to flow downwardly through the opening 33 from the outer chamber 13 into the inner chamber 36 . Located within the inner chamber is a diffuser material having a plurality of parallel fluid flow paths. Fluid is caused to flow through the diffuser material to dampen major currents of fluid velocity. The diffuser material has an arcuate upper surface 84 . Fluid is caused to flow radially inwardly from the arcuate surface through an orifice 20 located above the diffuser material to form a laminar fluid stream.

U.S. Pat. No. 5,678,617 granted Oct. 21, 1997, discloses a device located below a bar or counter whereby when the patron or guest orders a drink, the bartender or host places the drinking glass upon a designated location on the top of the bar or counter. Unknown to the patron or guest, the bartender activates a hidden control. The drink then appears to hop from some remote spot on the bar, take one or more leaps, and ultimately lands in the patron or guest's glass.

In FIGS. 1-1B a shutter is used to control the flow of a water stream with a solenoid controlled shutter.

III SUMMARY OF THE INVENTION

This invention discloses an ornamental fountain wherein a fountain nozzle 11 is made to discharge a pressurized stream of water, 12 . The nozzle is placed behind a cover 10 with an exit aperture 1 , and a shutter 2 prevents or allows the stream, 12 , to exit, according to its rotational position around shaft, 9 , and bearing, 15 . The opening and closing of said shutter, 2 , is controlled by armature, 3 , with its tip, 14 , composed of iron or other magnetic material. The armature, 3 , is affixed to the rotational shaft, 9 . The armature magnetic tip, 14 , is positioned in close proximity to electromagnets 4 , 5 , 6 and 7 with their magnetic cores, 13 , mounted on cover 10 , such that the armature, 3 , stays positioned against bumper, 8 , whenever electromagnet, 4 , remains activated.

Consequently shutter 2 continues to block the exit port 1 and no water is discharged. By de-activating electromagnet, 4 , and then sequentially activating electromagnet 5 , then, 6 , and then 7 , the armature, 3 , is made to rotate upon shaft, 9 , and the shutter, 2 , which is affixed to shaft 9 at 2 a will move so that it is no longer blocking exit orifice, 1 , and the stream will traverse through exit aperture 1 in the direction, 12 . So long as pressurized water is made to flow from nozzle 11 and electromagnet, 7 , remains energized, then the armature, 3 , will remain positioned against bumper, 16 , FIG. 3 , and water will continue flowing in direction, 12 . In order to stop the flow 12 , electromagnet, 7 , is deenergized and electromagnets 6 , 5 and 4 are energized in sequence to move the armature, 3 , in the direction of bumper, 8 , to close shutter 2 . In an alternate embodiment shown in FIGS. 4 and 5 , the exit aperture, 1 , the shutter, 2 , and the rotating shaft, 9 , are the same as in the previous embodiment. However, the means of rotating the shaft and opening the shutter utilize a plunger type electrical solenoid, 17 , which retracts a plunger, 18 , which is attached by a pin, 21 , to a lever, 19 , to overcome the force of a tension spring, 20 , whenever the solenoid is electrically actuated as shown in FIG. 4 . Upon de-activating the solenoid, as shown in FIG. 5 , the force of the tension spring, 20 , pulls the lever, 19 , to withdraw the plunger, 18 , rotate the shaft, 9 , and close the shutter, 2 .

IV THE DRAWINGS

FIG. 1 is a perspective view of a prior art flow stream shutter used in a different environmoment in the closed position.

FIG. 1A is a perspective view of a prior art flow stream shutter used in a different environmoment in the open position.

FIG. 1B is a perspective view of a prior art flow stream shutter used in a different environmoment in the closed position.

FIG. 1C is a front view of the fountain shutter of the present invention in the closed position.

FIG. 2 is side elevation view of the fountain shutter of the present invention.

FIG. 3 is a front view of the fountain shutter of the present invention in the open position.

FIG. 4 is a front view of a second embodiment the of the present invention, with the shutter in the closed position.

FIG. 5 is a side elevation view of the second embodiment the of the present invention, with the shutter in the open position.

FIG. 6 is a view of the second embodiment the of the present invention, looking in the direction of the arrows along the line 6 — 6 in FIG. 4 .

DESCRIPTION OF PREFERRED EMBODIMENTS

This invention discloses an ornamental fountain wherein a fountain nozzle 11 is made to discharge a pressurized stream of water, 12 , in a manner well known in the fountain industry for example in accordance with U.S. Pat. Nos. 5,160,086 and 5,641,120 discussed above, and in Doc. Nos WW-11 entitled Minature Fountain and Doc. No. WW-12 Improved Laminar Nozzle, each hereby incorporated into the present application by this reference as if fully set forth herein.

The nozzle is placed behind a cover, 10 , with an exit aperture, 1 , and a shutter, 2 , which prevents or allows the stream, 12 , to exit, according to its rotational position around shaft, 9 , and bearing, 15 . The opening and closing of said shutter, 2 , is controlled by armature, 3 , with its tip, 14 , composed of iron or other magnetic material. The armature, 3 , is affixed to the rotational shaft, 9 . The armature magnetic tip, 14 , is positioned in close proximity to electromagnets 4 , 5 , 6 and 7 with their magnetic cores, 13 , mounted on cover 10 , with fasteners 24 such that the armature, 3 , stays positioned against bumper, 8 , whenever electromagnet, 4 , remains activated and consequently shutter, 2 , continues to block the exit port 1 and no water is discharged.

By de-activating electromagnet, 4 , and then sequentially activating electromagnet 5 , then, 6 , and then 7 , the armature, 3 , is made to rotate upon shaft, 9 , and the shutter, 2 , which is affixed to shaft, 9 , will move so that it is no longer blocking exit orifice, 1 , and the stream will traverse through exit aperture, 1 , in the direction, 12 . So long as pressurized water is made to flow from nozzle, 11 , and electromagnet, 7 , remains energized, then the armature, 3 , will remain positioned against bumper, 16 , FIG. 3 , and water will continue flowing in direction, 12 .

In order to stop the flow 12 , electromagnet, 7 , is deenergized and electromagnets 6 , 5 and 4 are energized in sequence to move the armature, 3 , in the direction of bumper, 8 , to close shutter 2 .

FIGS. 1 , 2 and 3 disclose four electromagnets but this embodiment may be made to work just as well with two or three or any number of electromagnets.

In an alternate embodiment shown in FIGS. 4 and 5 , the exit aperture, 1 , the shutter, 2 , and the rotating shaft, 9 , are the same as in the previous embodiment. However, the means of rotating the shaft and opening the shutter utilize a plunger type electrical solenoid, 17 , which retracts a plunger, 18 , which is attached by a pin, 21 , to a lever, 19 , to overcome the force of a tension spring, 20 , whenever the solenoid is electrically actuated as shown in FIG. 5 . The solenoid, 17 , is mounted to the cover, 10 , by means of a pivot, 22 , which permits the solenoid and plunger to maintain proper alignment with pin 21 , by rotation of a few degrees around pin 21 to compensate for the rotation of lever 19 .

FIG. 4 shows solenoid 17 in deactivated position which consequently has allowed tension spring 20 to retract and withdraw plunger 8 from solenoid 17 . This action has rotated lever 19 around shaft 9 to which it is affixed, and has rotated shutter 2 , also affixed to shaft 9 , into the closed position. Angle A shows the rotational position of the solenoid relative to the centerline 23 , around pin 22 .

FIG. 5 shows the solenoid 17 in an actuated condition, which has withdrawn plunger 18 , and stretched spring 20 to rotate lever 19 , pin 9 and shutter 2 , through C. degrees to uncover aperature 1 , while the solenoid has rotated slightly around pin 22 to the extent of the angle B.

As an example, the angle A may be about 10 to about 45 degrees, the angle B may be about 5 to about 30 degrees and the angle B may be about 30 to about 60 degrees.

While solenoid plunger 18 has been described in the extended position when the shutter is in the blocking position, obviously this could be reversed and the plunger could be in the retracted position when the shutter is in the blocking position.

Claims

1. A control shutter assembly for a water fountain comprising:a fountain nozzle having means to discharge a pressurized stream of water; a shutter located adjacent said nozzle which prevents or allows said stream to exit said shutter integrally connected to a rotatable shaft; means for rotating said shaft and opening said shutter comprising an electrical solenoid mounted on a fixed support having a plunger mechanically connected to lever by a pin said lever in turn mechanically connected to said shutter; said lever adapted to overcome the force of a tension spring mounted on a fixed support adjacent to said lever; whereby upon de-activating said solenoid, the force of said tension spring pulls said lever to withdraw said plunger from said solenoid, rotates said shaft, and closes said shutter to block fluid flow; and whereby when said solenoid is in an actuated condition said plunger is withdrawn into said solenoid, stretching said spring and rotating said lever, rotating said pin and rotating said shutter to uncover said aperature.

2. A control shutter assembly according to claim 1 wherein said solenoid is mounted upon a fixed cover means of a pivot, which permits said solenoid and said plunger to maintain proper alignment with said pin.

3. A control shutter assembly for a water fountain comprising:a fountain nozzle having means to discharge a pressurized stream of water; a shutter located adjacent said nozzle which prevents or allows said stream to exit, said shutter integrally connected to a rotatable shaft means for rotating said shaft and opening said shutter comprising an electrical solenoid mounted on a fixed support having a plunger mechanically connected to a lever by a pin said lever in turn mechanically connected to said shutter; said lever adapted to overcome the force of a resilient means mounted on a fixed support adjacent to said lever; whereby upon de-activating said solenoid, the force of said resilient means pulls said lever, and closes said shutter to block flow, and whereby when said solenoid is in actuated condition, said resilient means rotates said lever, and moves said shutter to uncover said aperature.

4. A control shutter assembly according to claim 3 wherein said resilient means comprises a mechanical spring.