DE29617537U1 - Chromatokinetic object for the generation and visible display of moving liquid images - Google Patents

Description

Description

Devices of a conventional design for the creation and visible representation of liquid images already exist in the play and decoration sector. The liquid images are essentially created by manually or mechanically generated movements of the container (e.g. "Diva wave" by rocking the container, rotating and shaking devices operated manually) or by heating the container and thus the liquids filled into it (e.g. "lava lamps") or by an impeller rotating in the container.

The device described is driven by a motor so that the characteristic rotary movement of the container can be maintained for any length of time. The container itself can be circular in shape, but this does not necessarily have to be the case by using a circular guide rail, so that containers of any shape can be set in a rotary movement.

The flow deflection elements between the inner walls of the container make it possible to determine the liquid paths and "transport" the liquids or air in the container. During the rotation of the container, an unlimited number of different, new, moving liquid images can be created.

The different liquid and air/liquid patterns result from the shape, size, number and arrangement of the deflection elements as well as from the possible different distances between the inner walls of the container, its shape, its rotation speed and the different viscosities and colors of the filling.

The storage of the container itself is initially free within the scope of the invention. However, it is particularly advantageous if the storage and guidance of the container is either transparent or takes place in the edge area of the container, as the viewer's view of the liquid images is not obstructed by a recognizable horizontally aligned axis. In addition, an axis running through the container would impair the liquid paths.

In the following description, three exemplary embodiments are explained in a basic representation using three drawings.

Drawing I shows the described device for sinking liquid images with a bearing and guide in the base.

Drawing II shows the described device for rising liquid images with a bearing and guidance by a horizontally aligned axis in the container.

Drawing III shows the described device for rising air/fluid images.

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Drawing I fsinkeridg FJitesiqKeasBildfer.&jfsiner storage and guidance in the base)

Container B is filled with liquids F1 and F2. Liquid F1 has a higher specific weight than liquid F2, so it is heavier than F2 and therefore collects in the lower part of the container. Liquid F2 has a lower specific weight than liquid F1, so it is lighter than F1 and therefore collects in the upper part of the container.

The motor M transmits the rotary movement to the guide roller R1, which is rotatably mounted like the guide roller R2 and holds the guide rail FS in its upright position.
The rotary motion of the guide roller R1 is transferred to the circular guide rail FS, in the center of which the container B is mounted. This causes the container B to rotate with the guide rail FS. The flow deflection element SE1 now "scoops" the liquid F1 from the lower container area by rotating in the direction of rotation upwards, where the liquid F2 is located. Little by little, the flow element SE1 "tips" the "scooped up" liquid F1 into the liquid F2 by increasing the change in the angle in the upper container area. Due to its higher specific weight than that of the liquid F2, the liquid F1 sinks through this in droplets into the lower container area, where the liquid F1 collects again to be "scooped" upwards again by the flow deflection element SE2 and following and the process described is repeated.

The additional rollers ZR1 and ZR2 on the guide roller R2 are rotatably mounted and prevent the guide rail from wandering off the guide roller.

Drawing &Pgr; (rising fluid images with a storage and guidance through a

horizontally aligned axis on the container)

Container B is filled with liquids F1 and F2. The liquids have the same
Features as described in Drawing I.

The motor M transmits its rotary motion to the rotatably mounted container B through the drive wheel AR. The axle knuckles A1 and A2 each have a holder for the axle pins S1 and S2, which are attached to the outer wall of the container in such a way that they form a horizontal, rotatable axis when fitted together. Due to the rotary motion of the container B in the direction of rotation DR, the flow deflection element SE1 "scoops" the liquid F2 from the upper container area downwards, where the liquid F1 is located. Little by little, the flow deflection element SE1 releases the scooped liquid F2 into the liquid F1 in the lower container area through the changing angle. Due to its lower specific weight than that of the liquid F1, the liquid F2 rises through it in droplet form into the upper container area, where the liquid F2 collects, to then be "scooped" downwards again through the flow deflection element SE2 and following and the process described is repeated.

The steering knuckles A1 and A2 are firmly connected to the base in which the motor M and the light source L are housed.

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Drawing III (rising air bubbles with a bearing and guide in the base )

The container B is filled with a liquid F1 and with air L2.

The motor M transfers its rotary motion to the guide roller R1, which is rotatably mounted like the guide roller R2 and holds the guide rail FS in its upright position. R1 transfers its rotary motion to the circular guide rail FS, in the center of which the container B is mounted. This causes the container B to rotate with the guide rail FS. Now the flow deflection element SE1 "scoops" the air L from the upper container area by rotating in the direction of rotation downwards, where the liquid F1 is located. Little by little, the flow deflection element SE2 releases the "scooped" air to the liquid F2 through the changing angle, where the air L2 then rises through the liquid F1 in air bubbles into the upper container area, collects there, and is then "scooped" downwards again by the following flow deflection elements and the process described is repeated.

The additional roller ZR is rotatably mounted and thus prevents the guide rail from wandering
from the leadership role.

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•x uu-u ZR - additional role

B - Liquid container ^ _ _Base

&Xgr; F1 - Liquid 1 _L . _Light source

: F 2 - Liquid 2 _FS . Guide rail

- M " - M° ^tor · _&Lgr; &kgr;_=&Ggr;&eegr;!&idiagr;&rgr; DR - Direction of rotation ■ ■

R1 - Guide and drive roller _ flow direction-

R.2 - Guide roller 2 ♦

SE - flow deflection element _._

+ + - F 1 1 F 2 2 B M AR A A

Liquid 1 S - Socket

Liquid 2 S 1 - Axle pin 1

Fluid container S 2 - Axle pin 2

Motor . . SE 1 - Flow deflection element.1

Drive wheel DR . - Direction of rotation

Steering knuckle 1 SR- flow direction

Steering knuckle 2 L- light source

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B - Container

F 1 - Liquid 1

L 2 - Air

M - Engine

R 1 - Guide roller 1

R 2 - Leadership role 2

FS - Guide rail

S - Base

SE 1 - Flow diversion element

t - flow direction

LQ - Light source

ZR - additional role

DR - Direction of rotation

Claims (6)

1. Device for generating and visually displaying moving liquid images, consisting of a substantially transparent container which can be filled with two liquids which have a different specific gravity and do not mix with one another, characterized in that it is in an upright position and is rotatably mounted. 2. Device according to claim 1, characterized in that the rotary movement of the container can be generated by a motor. 3. Device according to claims 1-2, characterized in that flow deflection elements are provided in the container. 4. Device according to claims 1-3, characterized in that at least one opening is provided in the container which can be closed leak-proof. 5. Device according to claims 1-4, characterized in that at least one of the two liquids can be colored. 6. Device according to claims 1-5, characterized in that the container can be illuminated by a light source which can be accommodated with the motor in a base. -1-