DE8015030U1 - DEVICE FOR WATER SURFACE DRAWING FOR AQUARIUMS - Google Patents

Description

Patent attorneys - 5 -
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··· ··· ···, Dipl.-Ing. Volkhard Kratzsch Scratchy eyes Siülfeergerstr. ^ 5 · · Dipl.-Ing. Klaus Schulz Schulz D-7300 Esslingen Deutsche Bank Esslingen 210906 Telephone Stuttgart (0711) 35 99 92 Post office Stuttgart 10004-701 cable «krapatent» esslingenneckar

Günther Eheim Company May 23, 1980

7301 Deizisau attorney's file 3096

Device for water surface extraction for aquariums

jf The invention relates to a device for water | /.· surface deduction for aquariums in the preamble of the claim 1 mentioned Art.

A known device (DE-GM 79 11 267) contains within of the standpipe an approximately telescopic retractable or extendable, Pipe movable relative to the standpipe, which is provided with a float at the upper end and is similar to a float should set about so in relation to the water surface that the inlet edge of the movable telescopic tube Remains only just below the water level, so that due to the so-called gullet effect in the movable telescopic tube water can run in with surface removal. This water surface withdrawal is intended to open the water surface and the gas exchange through the water surface are facilitated. The area of the standpipe below the lower water drainage is closed by means of a closure body adjustable by hand in the axial direction, the Wall of the standpipe is provided with slots in the closure area, which depending on the set axial position of the closure body are more or less wide open and a corresponding suction also from the lower area of the pelvis should allow forth through these slots in the pipe interior.

The extraction device described is ^{inadequate in terms of:} the upper, telescope-like tube. Inadequate during operation. On the one hand, there are problems caused by the floating tube-like swimming of the movable tube. The pipe depends on the surface movement of the water in the pool. Depending on the turbulence or the course of turbulence and the associated up and down movement of the movable telescopic tube, water and, disadvantageously, air are introduced into the interior of the standing pipe not continuously self-priming centrifugal pump is designed, extremely detrimental. When air is sucked in, the suction collapses, so that a standstill is formed in the pipe system with air sacs at various points Bearings through the water. The bearings run hot to the point of seizing up, which leads to the destruction of the pump with standstill and of course also to the termination of the filter effect. Another disadvantage of this system with a floating body-like movable telescopic tube is that the smooth sliding movement of the telescopic tube within of the standpipe is by no means guaranteed in the long term. On the one hand, there is a high level of intrinsic friction, reinforced by transverse forces that act in the transverse direction on the movable telescopic tube and can thus lead to jamming. There is also the risk that dirt and other foreign particles will get into the gap between the standpipe and the movable telescopic tube and block the sliding movement of the movable telescopic tube. In this design, special hydrostatic parameters have also been introduced, which raised additional problems for the surface extraction. Whenever the surface extraction desired by the movable telescopic tube is interrupted or

with regard to the suction flow is reduced, "this leads to disadvantages, which can only be achieved by appropriate, sensitive could prevent manual adjustment of the closure body explained above in adaptation to it. However, this would require constant observation and manual adjustment, which is the case with continuous operation Aquarium is completely illusory. So it consists in high risk of damage or even destruction for the pump of the suction filter and standstill of the Filter effect. It is known that with increasing operating time and increasing contamination of the aquarium filter the pump output also drops. So there is a lower suction power. This would also have to be the case with the known trigger device by continuous observation and sensitive readjustment of the breech block take into account what cannot happen in practice. So does this mean that as pollution increases? degree and decreasing filter performance also the suction · conditions in the known device inadequate will. In addition, the device has to be manually adapted to each particular one with regard to said closure body Pump and tank size of the aquarium can be adapted and set. So the known device does it not possible without manual intervention and sensitive adaptation of the device for an entire range of pumps as well as different sized aquariums. There is also an adjustment by manual adjustment to fresh water or sea water is necessary in the aquarium.

In contrast, the invention is based on the object of providing a device as defined in the preamble of claim 1 To create genus that eliminates the disadvantage described and with simple and cheaper design and reliable operating behavior an automatic setting of the suction conditions depending on the different parameters.

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The object is in a device of the type defined in the preamble of claim 1 according to the invention solved by a self-regulating hydrostatic valve, which is preferably located below the lower water drainage is detachably connected to the standpipe.

Such a self-regulating hydrostatic valve makes an automatic adjustment arr changing Operating conditions possible without the need for monitoring and manual intervention by the user. For example, the valve adjusts itself automatically to the respective pump output, e.g. when the degree of contamination increases the pump output also decreases in the filter. The valve adapts itself automatically. Also is the trigger with the valve suspected the need a special manual adjustment suitable for a whole range of pumps with different capacities, E.g. a performance range of 2 l / min, up to 12 l / min The filter performance of the suction filter used would have to be adapted. The adjustment is done by yourself employed. The valve adjusts itself automatically. The same applies to the operation of pools with fresh water or sea water .. The valve adjusts itself automatically, so that there is a manual regulation not required. Above all, it is ensured that changing suction conditions are detected by the valve and automatically be implemented in an obvious valve adjustment. If e.g. the surface deduction with a throat effect interrupted for whatever reason, the valve adjusts itself automatically in dependence thereon so that now a suction not from the upper part of the pelvis, but happens from the lower pelvic area, so a continuous suction flow is maintained without the There is a risk of air formation with the associated risk of damage or even destruction of the pump.

A particularly advantageous embodiment results from claim 2 and van be the height of the liquid i ^f keitssäule dependent. Under the action of this

Forces the valve closure member in the respective

Jl equilibrium position automatically-moved., It can

I 'the weight by adjusting the dead weight

'? of the valve closure member and thus the control

behavior.

Further advantageous embodiments result from

[: ■ the other claims 3-19.

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κ The full wording of the claims is above

not only to avoid unnecessary repetitions reproduced, but only referred to by naming the claim number, which, however, all Claim features are to be considered as expressly disclosed at this point and as being essential to the invention.

Further details, in particular the advantages achieved, emerge from the following description. In particular on the advantages detailed there are expressly referred to here in order to avoid repetition .

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The invention is explained below with reference to in the drawings illustrated embodiments explained in more detail. Show it:

Fig. 1 is a schematic axial longitudinal section of part of a device for water surface deduction with connected valve, · in an operating position when the valve is closed Valve,

FIG. 2 shows a section corresponding to that in FIG. but in a different operating position and with the valve open,

3 shows a schematic axial longitudinal section of part of the device with valve, in particular constructive design,

Fig. 4

and 5 each a schematic plan view in arrow direction IV and V in Fig. 3,

FIG. B is a schematic, perspective view of the valve closure member of the valve in FIG Fig. 3.

In Fig. 1 and 2, for the sake of a better overview, a greatly simplified and purely schematic representation lower part of a device for water drainage shown for aquariums. With dash-dotted lines a part of a basin 10 is indicated, which up to to the water level 11 is filled with water. Within the basin 10 there is a substantially vertical fixed thereto Aligned standpipe 12, e.g. made of plastic, which is already attached to the lower part of the water surface extraction device heard. For the sake of clarity, the upper part of this device is not shown. A design of this type results e.g. from DE-GM 79 11 267, if this also has certain deficiencies. The upright tube 12 has an only schematically indicated upper water

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inlet 13, from the upper part, not shown further the trigger is fed so that from the basin 10 in the surface area of water through the sag. Gullet effect is withdrawn and passed through the upper water inlet 13 into the interior of the standpipe 12. at For stable operation, a water level is established inside the standing pipe 12, which is shown schematically at 14 in FIG. 1 is indicated. The upper part of the extraction device, not shown further, is movable relative to the standpipe 12 and can e.g. be similar to a floating body or in some other way in relation to the water surface in the Adjust basin 10 so that a gullet is formed just below the water level, over which the gullet acts the surface extraction and the introduction into the standpipe 12 takes place.

At a distance from the upper water inlet, which is only indicated schematically 13, the standpipe 12 is provided with a lower water drain 15, only indicated schematically, with which the standpipe 12 via a z, B. attachable, no further The suction line shown can be connected to a suction filter, not shown, of the aquarium.

In a special design, the trigger device is with equipped with a self-regulating hydrostatic valve 16, which is located below the lower water drainage 15 is preferably detachably connected to the standpipe 12.

In contrast to the design according to FIG. 3 - B, the valve 16 in FIG. 1 is only shown in a greatly simplified, schematic diagram table design shown. The valve 16 has a in the lower area. Valve chamber 17 on the outside is open and can communicate with the water in the pool 10. The valve chamber 17 is coaxial with the standpipe 12 Tube extension formed and in the tube wall 18 and at the lower end each with openings 19 in the form of slots, bores or other breakthroughs

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- 12 provided. ;

Above the valve chamber 17, the valve 16 has a Valve chamber 20, which is open to the interior of the standpipe 12. The valve chamber 17 and the valve space are connected to one another via a valve opening 21, which is dominated by a valve closure member 22 shown schematically. The valve closure member 22 is in its closed state in the illustration according to FIG. 1, but in the illustration according to FIG. 2 in an open position.

The valve closure member 22 is in the valve opening direction according to arrow 23 in Fig.'2 at least on the buoyancy force acted upon, the in the lower valve chamber 17 on the Valve closure member 22 acts. The buoyancy is in Fig. 1 illustrates with schematic, upwardly directed arrows.

In the opposite direction to arrow 23, so in the valve closing direction (arrow 25, Fig. 1 ^, the valve closure member 22 is to one from its own weight and the other, in addition to its own weight, from the respective hydrostatic pressure of the A column of liquid which is located within the standpipe 12 is acted upon. The hydrostatic pressure of this The liquid column is illustrated by arrows 26 in FIG.

In the state according to FIG. 1, the buoyancy force (arrow 24) less than the sum of the weight of the valve closure member 22 on the one hand and the hydrostatic one on the other Pressure (arrows 26) of the liquid column within the standpipe 12.

On the other hand, it increases the height of the liquid column in the standpipe 12 from, so the water level 14 of Fig. 1 is reduced by Δ h to the water level 14 'in Fig. 2, so

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predominates that acting in the valve opening direction (arrow 23) Buoyancy force (arrows 24) is therefore greater than the sum of the hydrostatic pressure on the one hand and the dead weight of the valve closure member 22 on the other hand. The result is that the valve closure member 22 is automatic in the opening direction according to arrow 23 in a state of equilibrium is moved, while releasing the valve opening 21, whereby by the shape of the valve closure member 22 depending on the open position according to an assigned Quantity control can be made possible.

This control behavior of the hydrostatic valve 16 is primarily for the suction filter pump, not shown any further of the aquarium advantageous. In the closed valve state (Fig. 1) the inserted into the standpipe 12, Water withdrawn from the surface in the direction of arrow 27 through the lower water drainage from the pump of the suction filter, ers sucked off. Since the valve 16 is closed, there is no suction from below. Take now within the standpipe 12 from the height of the liquid column, this is due to the fact that the upper part of the Extraction device, which is supposed to extract surface water through the effect of the gullet, is no longer functional. It air is introduced into the standpipe 12, which when entering the pump, not shown, which is usually called centrifugal pump that is not self-priming, leads to a standstill of the water suction. The pump continues to run without suction, although due to the lack of suction, the effect caused by the water at the same time There is no bearing lubrication. As a result, the bearings run hot to the point of blocking, resulting in destruction leads with standstill of the pump. Apart from this considerable damage, a non-functional vein is effective Depending on the biological equilibrium in the basin 10, even a stationary pump can of course also have a disadvantageous effect the pool water, which also has an adverse effect on the fish and possibly also plants it contains.

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- 14 damage or damage.

The self-regulating hydrostatic valve 16 in the lower On the other hand, the area of the extraction device prevents the pump of the suction filter draws in air and, in the manner described, the pump and the aquarium Get damaged. Rather, when the valve 16 opens more or less automatically, in order to avoid the Air intake, then additionally only water from the lower area of the basin 10 through the valve chamber 17, the valve opening 21 and the valve chamber 20 sucked into the lower water drainage 15. This suction flow is indicated schematically in FIG. 2 by arrows 20.

From Fig. 1 and 2 it can be seen that the valve chamber 20 is arranged in the foot region of the Standrbhres 12 and there directly connects to the standpipe 12. The valve opening 21 is within a special transverse partition included in the foot area of the standpipe 12. If the diameter of the valve opening 21 is large, the transverse partition is reduced 29 to a ring with an axially or radially or somewhat e.g. frustoconically shaped valve seat surface 30.

The valve closure member 22 has in the schematic design according to FIGS. 1 and 2 a closure cone 31 in the Head area on «In an embodiment not shown, a locking plate, a Closure ball or a differently designed varnishing member may be provided.

The valve closure member 22 is in any case designed as a closure body freely playing in the valve 16, the on the one hand the buoyancy force (arrows 24) and on the other hand its own weight + the hydrostatic pressure of the Water column in the standpipe 12 is exposed and each taking a state of equilibrium thereafter automatically in valve opening direction or valve closing

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direction is adjusted. The valve closure member 22 is designed as a plastic body and under elevation its own weight weighed down to a specified value.

As is not particularly shown, the Design also be made so that the valve closure member 22 in addition to its own weight and to the respective hydrostatic pressure (arrows 2B) of the liquid column by means of an adjustable closing spring is acted upon in the valve closing direction (arrow 25). Likewise, the valve closure member 22, in the valve opening direction according to arrow 23, in addition to the buoyancy force acting on it in the valve chamber 17 (Arrows 24) can still be acted upon by means of a special adjustable opening spring.

It is advantageous in the explained device with valve 16 according to the invention that this is without the respective If an adjustment adjustment is necessary, it is suitable for a wide range of pumps, e.g. for a range of such pumps Pumps that range from 2 l / min to 12 l / min in terms of filter performance. The device with valve 16 automatically adjusts to any type of pump without the need for any special setting or regulation. Likewise, the device with a self-regulating valve is suitable for both fresh water and sea water, as well without the need for a special adjustment adjustment. It is known that in the course of operation of a suction filter the suction power decreases with increasing filter contamination. The valve 16 is also positioned on this automatically without the need for manual monitoring and readjustment. As already explained, the self-regulating valve 16 reacts automatically when in the upper area of the trigger device the trigger is disturbed or completely blocked, so there is a risk that the pump of the suction filter after

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Emptying the standing pipe 12 or already during this Phase sucks in air and the damage already explained occurs. In this case, the valve 16 opens automatically, so that then, while avoiding air suction and pump damage, pool water flows through from below the valve chamber 10 is sucked in. Furthermore, the valve 16 adjusts itself by assuming an equilibrium position, depending on the parameters involved, so that that a partial flow through the interior of the standpipe 12 and another partial flow through from below the valve chamber 17 and the opened valve opening '21 be sucked through.

The simple and inexpensive design of the valve 16 and its reliability are also advantageous operational.

The special structural design according to Fig. 3 - 6 is explained below. The valve closure member 22 is designed as an at least slightly conical hollow body 32, which is closed in the upper area by means of a removable cover cap 33. The interior of the hollow body 32 forms a board of appeal, which has a weighting filling 34, indicated schematically in FIG. 3, e.g. a or more lead bodies.

Furthermore, a special anti-rotation device is provided for the valve closure member 22, which vibrates during operation and prevents noise. The anti-rotation device consists, for example, of approximately slot-shaped recesses 35 in the ring 29 and furthermore from webs 36 which each engage in a recess 35 and which on the hollow body 32 are formed in the same way as axial longitudinal ribs. The relationships can also be reversed kinematically. Included are enough two webs or, as shown in Fig. 3-6, three arranged at the same circumferential angular distances from one another Bridges and three in a corresponding design

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Recesses 35. This is how the valve gate member is 22 always held against rotation, regardless of whether the valve closure member 22 is in its closed position (Fig. 1) or in a more or less open Position CFig. 2). Is located.

In the foot area of the standpipe 12, namely at an axial distance above the valve opening 21, there is also an axial stop 37, for example in the form of three radially aligned ribs or webs which are grouped in a star shape; This Axial stop 37 limits the opening movement of the valve closure member 22 in the valve opening direction (arrow 23, Fig. 2), so that, for example, when the suction force suddenly acts on the valve closure member 22, the latter does not move any further moved than in the axial direction up to the axial stop 37, the webs 36 still in positive engagement with the associated recesses 35 remain. The webs 36 and recesses 35 thus also serve as axial guides during valve movement.

The valve chamber 17 is formed as a pipe extension of the standpipe 12 - and thereby as an attached basket 3S, its Wall is provided with a plurality of slots 39. This design is particularly simple. Upon acceptance of the Basket 38 is from below the valve opening 21 and

the valve closure member 22 accessible. The basket can also be omitted entirely.

The valve opening 2-1 and the valve chamber 20 above containing part is designed according to FIG. 3 as a separate tubular part 40, which is attached and exchangeable as well is rotatable. The part containing the axial stop 37 is also a special, axially aligned Rahrteil 41 formed, which is also attached and exchangeable and rotatable. In the same way is also the part which carries the lower water drainage 15, as a separate one Tubular part 42 designed, which is also attached and exchangeable and rotatable. The pipe part 42 carries, a

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lumpy so, a connecting pin with a hole for "the lower water drainage 15 and further, at an angle to it, another RohranschluB 43 with a hole therein for an alternative connection of the suction line 44, the leads to the suction filter, not shown any further. In this case the outer end is the one that runs roughly horizontally Bore closed by means of a cover cap 45, which is connected to the suction line 44 on the horizontal bore - Then serves to close the Rahr connection 43. In addition, both holes are easy to clean.

Like the schematic representation according to FIG. 1 and, in particular, the special structural design 3-6 show, the valve closure member 22 has a relatively pronounced truncated cone shape, in the design 1 and 2 only in the case of the head piece 31, but in the case of the design according to FIGS. 3-6 via essentially the entire length of the valve closure member 22. This truncated cone shape leads to the fact that when the valve closure member opens 22, a flow rate determined by the opening path and increasing in the opening direction through the valve opening 21 is reached. At the same time, the flow rate is therefore dependent on the opening travel or closing travel of the valve closure member 22 changed, namely.aufgrund thereby changing the opening cross-section of the valve opening 21.

Claims (19)

Protection claims 1. Device for water surface deduction for aquariums, with a standpipe with an upper water inlet and a lower water outlet at a distance from it, with which the Standpipe connected to a suction filter via a suction line can be marked by a self-regulating hydrostatic valve (16), preferably below the lower water drain (15) is detachably connected to the standpipe (12). 2. Device according to claim 1, characterized in that that the valve (16) has a valve chamber (17) which is open to the outside and with the pool water can communicate, and has a valve chamber (20) which is open towards the interior of the standpipe (12) and which has a Valve opening (21) are connected to each other, which of a valve closure member (22) is controlled in the valve opening direction (arrow 23) at least from that in the Valve chamber (17) acting on the valve closure member (22) buoyancy force (arrows 24) and in opposite directions thereto in the valve closing direction (arrow 25) at least from its own weight and ■ additionally from the respective hydrostatic pressure (arrows 26) the liquid column within the standing pipe (12) can be acted upon. 3. Device according to claim 2, characterized in that that the valve chamber (20) is arranged in the foot area of the standing pipe (12) and is directly connects to the standpipe (12). 4. Device according to one of claims 1 -. 3, thereby characterized in that the valve opening (21) is arranged within a transverse partition (29) in the foot area of the standpipe (12). 5. Device according to one of claims 1 -4, characterized characterized in that the valve opening (21) surrounded by a ring that forms the valve seat surface (30) is. 6. Device according to one of claims 1-5, characterized by an in particular farm-locking anti-twist device for the valve closure member (22, 32). 7. Apparatus according to claim 6, characterized in that that the valve seat forming ring (29) and the valve closure member (22i32) have recesses (35) on the one hand and in each case in a recess (35) engaging webs (36) on the other hand, wherein the recesses (35) in the ring (29) and the webs (36) on the valve closure member (22, 32), or vice versa, are arranged. 8. Device according to one of claims 1-7, characterized by an axial stop (37) in the foot area of the Sfandrahres (12) at an axial distance above the valve opening (21), which controls the opening movement of the Valve closure member (22,32) in the valve opening direction (Arrow 23). 9. The device according to claim 18, _as: - characterized by that the valve chamber (17) formed as (20) coaxial tube extension to the valve space, in the tube wall (18) 'and / or at the lower end of the pipe with openings (19) is provided. 10. Apparatus according to claim 9, characterized draws that the pipe extension from one attached, provided with slots (39) in the wall Basket (38) is formed. 11. Device according to one of claims 1-10, characterized in that the Valve opening (21) and the one above it Valve chamber (20}) containing part as a separate, attached part and replaceable and rotatable tubular part (40) is formed. 12. The device according to claim 8, characterized in that the axial stop (37) containing Part is designed as a separate, attached and replaceable ble and rotatable tubular part (41). 13. Device according to one of claims 1 - 12, characterized in that the valve closure member (22) a locking cone (31), plate, locking ball or the like. having. 14. The apparatus according to claim 13, characterized in that the valve closure member (22) as freely playing Verachlußkörper is formed. 15. Device according to one of claims 1 - 14, characterized in that the valve closure member (22) in addition to its own weight and the respective hydrostatic pressure (arrows (2B) of Liquid column by means of an adjustable closing spring applied in valve closing direction [arrow 25] 16. Device according to one of claims 1-15, da- | characterized in that the valve & Closing member (22) with an increase in its own weight I is weighted to a predetermined value. · | 1 17. Device according to one of claims 1 - 16, da- | characterized in that the valve | Closure member (22) as by means of an upper cover cap (33) f | closed hollow body (32) is formed, the 1 interior of which forms a weighting chamber and a loaded | contains heavy filling (34). f 18. Device according to one of claims 1 - 17, characterized if indicates that the valve closure member (22) in addition to it in the valve chamber (17) acting buoyancy force (arrow 24) by means of an adjustable opening spring in valve opening | direction (arrow 23) is applied. ^v | 19. Device according to one of claims 1-13, da- '. j | characterized in that the valve | closure member (22) designed as a plastic body | is. ■ I