DE2944724A1 - Water level indicator e.g. for hydroculture - has stand-pipe connected via membrane and fluid to viewer - Google Patents

Abstract

The water level indicator for hydrocultures has a stand pipe (10) with a lever opening placed in the culture container and connected via separating fluid at its top to a viewing pipe (14) with a top opening. A flexible membrane (28) separates the fluid (36) from the stand pipe. The viewing pipe is sealed at the top by a second flexible membrane (46). The stand pipe snap-fits coaxially inside an expanded end section (22) of the viewing pipe so that the first membrane is clamped with the edge between the pipes. It has a beaded edge (30) which seals the pipe connection. The upper membrane is clamped by a cap (42) with a hold. The arrangement is simple and cheap, operates reliably and can be used in low water levels.

Description

Water level indicator especially for hydroponics

The invention relates to a water level indicator in particular for Hydroponics according to the preamble of claim 1.

The water supply in hydroponic vessels is sufficient depending on the vessel and the plant often up to a few weeks. Fertilizers have been created for hydroponics, which last a few months and sometimes even up to six months. at A suitable control agent is necessary for such large watering and fertilizing intervals to have on hand to water the plants in good time and in as uniform a manner as possible Fertilize at intervals.

To ensure timely watering, the water level must monitored in the hydroponic vessel.

This is easily possible with transparent vessels.

However, such vessels have the disadvantage that the entire root system the 'plant is visible, which is an unpleasant sight, and also the Exposure to daylight, which prevents the plant from thriving.

There are also known water level indicators that consist of a float exist, which is guided in a tubular cage inserted into the hydroponics vessel will. A stick attached to the float and protruding above the vessel wall shows the existing amount of water. The function of this water level indicator is unreliable, since the movement of the swimmer is often caused by roots penetrating the guide cage, is hindered by algae, limescale deposits or the like. At low water levels the water level indicator does not work because the float only switches on when the water level is high 1.5 to 2.5 cm immersed in the water so far that it has the necessary buoyancy receives.

In hydroponics, however, the water level is usually not too high aimed so that the water level indicator with float just in the important Areas of low water level are not operational.

Finally, it is used to display the water level in tanks and boilers known, a liquid-filled U-tube with its downward one Thigh below the water level and with his other one led upwards Thigh above the water level with the tank or boiler associate. The difference in the liquid columns in the U-tube serves as an indicator the water level. There are no such water level indicators in hydroponic vessels to use because they would have to be attached to the outside of the vessel.

The invention is based on the object of a water level indicator to create for hydroponics that is easy and cheap that works reliably and which can also be used at low water levels.

In the case of a water level indicator, this task is the one mentioned at the beginning Genus solved according to the invention by the features of the characterizing part of the Claim 1.

Advantageous embodiments and developments of the invention are specified in the subclaims.

The water level indicator according to the invention consists of a few individual parts, which are inexpensive to manufacture and can be assembled in a simple manner. Of the The water level indicator is placed in the hydroponic container with the standpipe, whereby its open lower end is just above the bottom of the hydroponic container is located. Even at the lowest heights of the water level, the water comes out into the standpipe so that the air in the standpipe is compressed and the Pushes up the liquid of the water level indicator in the sight tube.

Even the smallest water heights from around 3 to 5 mm can therefore be displayed will.

Since the water level indicator has no moving parts and in particular does not have a swimmer, its functionality is impaired by penetrating roots, Algae growth and the like. Not hindered. For the functionality of the water level indicator it is sufficient if the standpipe is only minimal for the penetration of the Water has sufficient patency.

As the liquid of the water level indicator passes through the standpipe a membrane is separated, the standpipe and sight tube can be connected coaxially to each other, so that the entire water level indicator is bar-shaped with a minimal diameter and takes up an extremely small amount of space in the hydroponic container. As a result, the upper end of the viewing tube is also closed by a membrane is, the liquid of the water level indicator is enclosed on all sides, see above that the water level indicator is removed e.g. to clean the hydroponic container and can be placed horizontally without its liquid oozing out. as well are not measures to contain the liquid for storage and transport necessary. Finally there is evaporation of the liquid enclosed on all sides locked out.

Due to the connection of the standpipe, which allows mutual rotation and viewing tube, it is also possible to adjust a scale on these mutually adjustable and attach a mark. By attaching a date scale it is possible note the date on which the next fertilization is necessary.

Further features and advantages of the invention emerge from the following Description of an embodiment shown in the drawing. 1 shows a side view of the water level indicator, and FIG. 2 shows an axial section of the upper part of this water level indicator and FIG. 3 is a plan view of the Water level indicator.

The water level indicator has a standpipe 10, with which it is placed in the hydroponic container.

At its lower open end, the standpipe 10 has a projection 12, which protrudes over this lower end and ensures that between the ground of the hydroponic vessel and the opening of the standpipe 10 a gap for entry of the water remains free.

At the upper end of the standpipe 10 closes in a coaxial extension a viewing tube 14. The viewing tube 14 has two diametrically arranged, radially protruding, axially extending ribs 16 bearing a scale mark.

The upper end portion of the standpipe 10 is expanded and has two cylindrical, coaxial walls 18 and 20, one up between them Form an open ring groove.

The lower end portion of the viewing tube 14 is also widened and forms a cylindrical wall 22 which fits into the annular groove between the walls 18 and 20 is inserted. On the outer surface of the wall 22 of the lower End section of the viewing tube 14 runs around a recess 26 in the circumferential direction. At the inner Jacket surface of the outer wall 20 of the enlarged upper end portion of the standpipe 10 runs around a corresponding projection 24 in the circumferential direction. The protrusion 24 and the recess 26 together form a snap connection that the standpipe 10 and the shear tube 14 holds together.

Between the standpipe 10 and the viewing tube 14 is a thin-walled, flexible, liquid-tight membrane 28 is used. This can, for example, be a be thin rubber membrane.

The circular membrane 28 has a bead 30 on its edge. This bead 30 is between the upper edge of the inner wall 18 of the upper end portion of the standpipe 10 and the almost horizontally widening area 32 of the lower End section of the viewing tube 14 inserted.

The snap connection 24, 26 holds the bead 30 clamped, wherein an axial annular projection 34 of the lower end portion of the viewing tube 14 prevents the bead 30 from being pulled inward from its position.

The bead 30 serves not only to attach the membrane 28, but also to seal the connection between standpipe 10 and viewing tube 14 to the outside.

A liquid 36 is filled into the viewing tube 14, which is preferably is colored. The weight of the liquid 36 causes the membrane 28 to move downward bulging, being taken up by the enlarged chamber formed by the Interconnected end sections of the standpipe 10 and the viewing tube 14 are formed will.

The upper end 38 of the viewing tube 14 is also in diameter expanded. In the widened end 38 is a cover provided with openings 40 42 used. The lid 42 is snap-fitted to the enlarged End 38 attached. Between the end 38 and the cover 42, the edge bead 44 is one second flexible membrane 46 clamped.

The flexible membrane 46 corresponds to the membrane 28.

On the outer periphery of the outer wall 20 of the enlarged upper end portion A date scale 48 is attached to the standpipe 10. On the expanding, almost horizontal part 32 of the lower end portion of the viewing tube 14 is a Mark 50 provided. A knurling 52 allows easy rotation of the Standpipe and thus the date scale 48 opposite the viewing tube 14 and thus the Marker 50.

The standpipe 10 with its upper end section is made of plastic manufactured as a one-piece injection molded part.

Likewise, the viewing tube 14 with its lower end portion and the upper end 38 made as a one-piece injection molded part made of plastic. At least In the area of the scale 16, the plastic material of the viewing tube 14 must be transparent be. The plastic material used must have sufficient elasticity for the Snap connections between standpipe 10 and viewing tube 14 or between the upper one Have the end 38 of the viewing tube 14 and the cover 42.

The water level indicator has the following function: at the assembly are first the lower end portion of the viewing tube 14 and the upper End portion of the standpipe 10 locked together, the membrane 28 being clamped will. Then the liquid is in the vertical position of the water level indicator 36 filled into the viewing tube 14, the membrane 28 bulging downwards, until the liquid level has reached the 0 mark on the scale 16. Then it will be the second membrane 46 is inserted and clamped by means of the cover 42. The water level indicator is ready for use. The liquid 36 is also through the membranes 28 and 46 tightly enclosed so that the water level indicator can be in any position can be stored and transported.

If the water level indicator is placed in a hydroponic container, so the lower end of the standpipe 10 is immersed in the water. The water comes in from down into the standpipe 10 up to the height of the water level in the hydroponic vessel a. Dabe.i the air column in the standpipe 10 is compressed because the standpipe 10 is sealed at the top by the membrane 28 and the edge bead 30 thereof.

Due to the increasing air pressure in the standpipe 10, the Membrane 28 pressed upwards, as indicated by dashed lines in Fig. 2, and the Liquid 36 rises in the viewing tube 14. Since the membrane 46 is freely after can bulge out at the top, as is also indicated by dashed lines in FIG. 2, the Air column in the standpipe 14 is not compressed and the liquid 36 can be in the Ascend viewing tube 14 just as if it were open at the top. The height of the liquid column in the viewing tube 14 thus shows the water level in the hydroponic vessel. This water level can be read on the scale 16.

The diameter of the standpipe 10 can be selected to be relatively large to avoid clogging and clogging of the standpipe 10 by algae or the like. safely to exclude.

The inner diameter of the viewing tube 14, however, should be selected to be smaller so that only a small amount of the liquid 36 is required.

After each hydroponic fertilization, the date scale is set to 48 using the knurling 42 rotated so that the marking 50 points to the date on which the next fertilization is necessary.

Claims (10)

P A T E N T A N S P R U C H E 1. Water level indicator in particular for hydroponics with an open at the bottom to be inserted into the hydroponic container Standpipe, with an upwardly projecting one that is connected to the standpipe Sight tube and with a standpipe and sight tube separating liquid, thereby characterized in that a first flexible membrane (28) removes the liquid (36) from the Standpipe (10) separates and that the viewing tube (14) at its upper end (38) a second flexible membrane (46) is closed. 2. Water level indicator according to claim 1, characterized in that connect the standpipe (10) and the viewing tube (14) coaxially to one another. 3. Water level indicator according to claim 2, characterized in that the standpipe (10) with its upper end in an enlarged lower end section (22) of the viewing tube (14) is inserted and that the first membrane (28) is clamped with its edge between the standpipe (10) and viewing tube (14). 4. Water level indicator according to claim 3, characterized in that the stano tube (10) and the viewing tube (14) with one another by a snap connection (24, 26) are locked. 5. Water level indicator according to claim 3 or 4, characterized in that that the membrane (28) has an edge bead (30) between the standpipe (10) and viewing tube (14) is clamped and seals its connection. 6. Water level indicator according to one of the preceding claims, characterized characterized in that the standpipe (10) has an upper end portion with zze coaxial Walls (18 and 20), between which the lower end portion (22) of the viewing tube (14) intervenes. 7. Water level indicator according to claim 6, characterized in that the outer wall (20) of the upper end portion of the standpipe (10) on its outer circumference carries a scale (48) with which a mark (50) on the lower end portion of the viewing tube (14) cooperates. 8. Water level indicator according to one of the preceding claims, characterized characterized in that the second membrane (46) with its edge between the viewing tube (14) and one in its upper end (38) inserted, preferably snapped openwork cover (42) is clamped. 9. Water level indicator according to one of the preceding claims, characterized characterized, the standpipe (10) and viewing tube (14) each one-piece plastic parts are. 10.Water level indicator according to one of the preceding claims, characterized characterized in that the standpipe (10) at its lower open end one over this end has protruding projection (12).