DE29822442U1 - Fluid clock - Google Patents

Description

98 0337 005 » ··

Liquid clock

The present innovation concerns a liquid clock that makes it possible to measure the passage of time based on the change in the liquid level in two communicating containers.

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to represent visually.

The state of the art includes a wide variety of forms of timepieces and clocks that serve to display the passage of time. Depending on the application, optical or acoustic displays are possible, with the structure of the various timepieces being determined essentially by the desired accuracy and reproducibility of the display of a period of time.

There are also applications where high accuracy is not important, as only the principle of time measurement is to be clarified. Even today, hourglasses are still used when relatively short periods of time are to be measured with moderate accuracy. For example, the well-known hourglasses can be used to explain to children the passage of time and its representation in controllable processes. However, hourglasses have the problem that the sand (or other fine-grained material) contained in two containers can quickly clump together due to the absorption of moisture, which blocks the trickle channel and the function of the hourglass is no longer guaranteed. Another disadvantage of well-known hourglasses is that when the sand trickles through the lower container, a

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conical elevation and possibly a complementary depression in the upper container, which do not allow an accurate reading of the fill level. It can also be disadvantageous that, with the necessary use of very fine-grained material, almost no noise is generated when the hourglass is running, since an acoustic control of the hourglass's function is not possible.

There are also attempts to use other materials in hourglasses, although this has so far led to structures that are technically difficult to implement and expensive.

One object of the present innovation is therefore to provide a device on which the passage of time can be demonstrated, whereby the disadvantages of the prior art are to be avoided.

This object is achieved by providing a liquid meter comprising a frame; a first and a second funnel-shaped, at least partially transparent container, each of which has an opening and is fastened in the frame with openings facing one another; liquid contained in the containers; a connecting element which extends between the two openings and connects the two containers to one another in a liquid-tight manner; a separating plate which is arranged in the connecting element; and two short, approximately equally long pipe sections which extend through the separating plate with an axial offset into both containers and through which the liquid can flow from one container into the other.

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A key advantage of this liquid meter is that clumping of the operating medium contained in the containers is prevented. At the same time, during operation of the liquid meter, an essentially flat liquid level is visible in both the upper and lower containers, and the change in this level can be used to clearly show the passage of time. The arrangement of the short, approximately equal-length pipe sections within the connecting element ensures that the liquid meter functions reliably. The axial offset of the two pipe sections means that the liquid only flows through one of these pipe sections from the upper container to the lower one, while the gas (usually air) displaced by the liquid in the lower container can reach the upper container via the other pipe section.

The liquid clock can be easily manufactured by using two conventional bottles as containers, with the corresponding screw caps glued to their lid surfaces and forming the connecting element.

Another embodiment uses a cork or similar plug as a connecting element, which is inserted into the openings of the two containers. The pipe sections then only need to be guided through this plug. Additional sealing measures can be omitted.

It is particularly advantageous if the pipe sections have an internal diameter that is individually tailored to the liquid used, so that the liquid only flows through one of the pipe sections drop by drop. Since the drops in the lower container are mixed with the liquid that has already flowed through,

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fall, and individual air bubbles rise through the other pipe section in the upper container, constant dripping noises are produced during operation, which on the one hand serve as an acoustic control of the liquid timer and on the other hand can have a calming effect on the user of the liquid timer.

One embodiment of the liquid meter has two bases on the frame, so that the liquid meter can be set up in two positions in which the two containers are arranged essentially vertically one above the other.

A modified version also has a bearing arranged approximately at the center of gravity for rotating the frame. This means that the liquid clock can be attached to a wall so that it can rotate.

It is advantageous to use a colored liquid, especially colored water, as this makes the current liquid level easier to read and also creates a visually appealing effect for the liquid clock.

In order to be able to determine individual time periods more precisely, markings can be attached to both the frame and the containers.

In a modified version, the two pipe sections have different internal diameters. The flow rate and speed are therefore different depending on which of the two containers is in the upper position. This allows different time periods to be measured if the containers are at the respective flow speed.

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have markings assigned to the liquid level for reading the liquid level.

Further advantages, details and developments of the present innovation emerge from the following description of a preferred embodiment, with reference to the drawing. They show:

Fig. 1 is a perspective view of a liquid clock;

Fig. 2 shows a detailed view of a sectional view of a connecting element.

Fig. 1 shows a perspective view of a liquid meter 1. The liquid meter 1 has a frame 2, a first container 3 and a second container 4. In the embodiment shown, the containers 3, 4 are conventional disposable bottles made of glass or plastic, which are at least partially transparent so that the current liquid level can be read. However, any other containers can also be used. In the operating situation shown, the first container 3 is located essentially vertically above the second container 4, with the two bottle openings directly opposite each other. The containers 3, 4 are each attached to the frame 2 using a holding plate 5.

In the embodiment shown, the frame 2 has two base surfaces 6, which are arranged essentially perpendicular to the axis of the containers 3, 4. The base surfaces 6 are arranged so that the containers 3, 4 rest with their base surface on

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rest on the inside of the base surfaces, thereby ensuring a secure fit in the holding plates 5.

Each container 3, 4 has a screw cap 9 on its opening, which together act as a connecting element. The containers contain a liquid 7, for example colored water. Markings 8 are attached to the rear wall of the frame 2, which make it easier to read the current liquid level.

Fig. 2 shows the connecting element in a detailed view, whereby a sectional view was chosen here. The two screw caps 9 are glued to their cover surfaces so that a separating plate 10 is formed there. Two holes 11 run through the separating plate 10, into which two pipe sections 12 of essentially the same length are glued. The two pipe sections 12 are offset from one another in the axial direction and each extend with one end into the first container 3 and with the opposite end into the second container 4. The two containers 3, 4 are thus connected to one another via the pipe sections 12. The containers contain the liquid 7 (see Fig. 1), which runs from the upper container into the lower container through one of the two pipe sections 12 depending on the position of the two containers. The gas displaced from the lower container, i.e. usually air, can flow into the upper container through the other pipe section. The gas bubbles will break off at the upper end of the pipe section 12 and rise upwards through the liquid still in the upper container.

If water is used as the liquid, the pipe sections 12 can, for example, have an inner diameter of one

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up to three millimeters, whereby in this case the liquid flows drop by drop into the lower container. In the simplest case, the two screw caps can be glued to the lid surface with a silicone adhesive and drinking straw pieces can be used as pipe sections, which can also be glued into the holes 11 with silicone adhesive.

If a cork or similar stopper is used as a connecting element, no additional precautions need to be taken to seal the containers.

As shown above, by using different pipe sections, the special effect can be achieved that the flow velocity is different in the two flow directions.

Claims (11)

98 0337 004 Protection claims 1. Liquid meter (1) consisting of: • a frame (2); · a first (3) and a second (4) funnel-shaped, at least partially transparent container, each having an opening and being fastened in the frame (2) with opposite openings; • liquid contained in the containers (7); · a connecting element which extends between the two openings and connects the two containers (3, 4) to one another in a liquid-tight manner; • a separating plate (10) arranged in the connecting element; and · two short, approximately equal-length pipe sections (12) which extend through the separating plate (10) with an axial offset into both containers (3, 4) and through which the liquid (7) can flow from one container into the other. 2. Liquid clock according to claim 1, characterized in that two bottles (3, 4) are used as containers. 3. Liquid meter according to claim 2, characterized in that the connecting element is formed by two on the bottles (3, 4) is formed by screw caps (9) glued to their cover surfaces, wherein the short tube sections (12) are glued into two bores (11) penetrating the cover surfaces.
30 98 0337 004 4. Liquid meter according to claim 1 or 2, characterized in that the connecting element is a stopper inserted into the openings of the containers (3, 4), in particular a cork, through which the two tube sections (12) penetrate. 5. Liquid meter according to one of claims 1 to 4, characterized in that the tube sections (12) have an inner diameter adapted to the liquid (7) in such a way that the liquid only runs drop by drop through each of the tube sections. 6. Liquid meter according to claim 5, characterized in that the liquid is colored water (7) and the inner diameter of the tube sections (12) is 1 to 3 mm. 7. Liquid meter according to one of claims 1 to 6, characterized in that the frame (2) has two bases (6) so that it can be set up in two positions in which the two containers (3, 4) are arranged substantially vertically one above the other. 8. Liquid clock according to one of claims 1 to 7, characterized in that a bearing for rotating the frame (2) is arranged approximately at the center of gravity. 9. Liquid meter according to one of claims 1 to 8, characterized in that markings (8) are attached to the frame (2), the distance between which is selected such that the liquid level rises or falls within a predetermined time between two of these markings. a
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a 10. Liquid meter according to one of claims 1 to 9, characterized in that markings are applied to one or both containers (3, 4), the distance between which is selected such that the liquid level rises or falls within a predetermined time between two of these markings. 11. Liquid meter according to one of claims 1 to 10, characterized in that the two tube sections have different inner diameters.