DE20313360U1 - Pond pump with adjustable suction volume - Google Patents

Description

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Pond pump with adjustable suction volume

The present invention relates to a pond pump with a housing, with a suction connection to which a suction region of a housing shell formed with through slots is assigned, with a pressure connection which is in fluid communication with the suction connection via a pump device arranged in the housing, with a motor for driving the pump device and with a control device for controlling the pump device and the motor.

Such pond pumps are well known in the art. They are positioned at the bottom of a pond or basin. The housing of the pond pump is designed as a coarse filter and has slots through which water can penetrate into the housing, but not leaves, small branches and other coarser particles.

The water is sucked into a suction connection behind the coarse filter bowl by a pumping device arranged in the housing and pressed into a pressure line via a pressure connection, which releases the water at a free end. In such pond pumps, only water from the bottom of the pond or basin is sucked in for regular cleaning. With such a pump, it is not possible to suck water from the pond surface in order to clean it as well.

The object of the present invention is to provide a pond pump with which water can be sucked in optionally from the bottom area of a pond or basin and/or from the water surface thereof at a given suction volume.

The object is achieved according to the invention in that the intake connection is additionally assigned an intake nozzle which is arranged adjustable in relation to the intake connection in such a way that an intake volume of the intake connection can be divided between the intake nozzle and the intake area.

With the pond pump according to the invention, a suction line can now be attached to the pond pump via the suction nozzle, which ends in the upper area of a water level, so that water can be sucked in from this area, whereby the suction volume of the suction connection can be distributed as required to the bottom area of the pond and the water surface.

A further advantage of the present invention is that the intake manifold is adjustable between a first end position and a second end position, wherein in the first end position the proportion of the intake volume at the intake manifold is 100% and at the intake area is 0% and in the second end position the proportion of the intake volume at the intake manifold is 0% and at the intake area is 100%.

This adjustability of the suction volume makes it possible to suck in water either only from the water surface or only from the bottom area, or to divide the suction volume between these extreme positions.

A further advantage is that the intake manifold and the intake connection are arranged with a longitudinal axis in a plane and the intake manifold is rotatable about an axis of rotation perpendicular to the longitudinal axis between the first end position and the second end position.

This measure allows the pond pump to be built in a very compact manner. By turning the intake nozzle, the setting of the intake volume can also be visually seen from the outside.

In this context, a further advantage is that the longitudinal axes of the intake port and the intake nozzle coincide in the first end position and enclose an angle in every other position between the first end position and the second end position.

If the pressure connection also has a pressure port for connecting a pressure line, which is usually the case, the angular position between the pressure port and the intake port also changes by the adjustment angle. This means that the adjustment can also be visually perceived from a distance. 5

Further advantages result from the features of the further subclaims.

An embodiment of the present invention is described below with reference to

Drawing described in more detail. Shown are:
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Fig. 1 is a schematic perspective view of a pond pump showing an upper housing shell designed as a filter cover, a pressure port and an adjustable intake port according to the present invention.;

Fig. 2 is a schematic perspective view of the pond pump from Fig. 1 with the filter cover removed;

Fig. 3 is a schematic plan view of the pond pump from Fig. 2, with the filter cover removed, in a second end position in which the intake nozzle is not in fluid communication with the intake connection and the suction takes place exclusively via a suction area of the housing;

Fig. 4 is a schematic plan view of the pond pump from Fig. 2, with the filter cover removed, in a first end position in which the intake port is in full fluid communication with the suction connection and the suction takes place exclusively via the intake port;

Fig. 5 is a schematic, perspective side view of the pond pump according to the invention with the filter cover removed;

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Fig. 6 is a schematic plan view of the pond pump from Fig. 5;

Fig. 7 is a schematic sectional view through a typical garden pond, with the pond pump according to the invention installed on the bottom, to show the two spatially distant suction points on the pond bottom and on the water surface.

Fig. 1 shows a schematic representation of a pond pump 1. The pond pump 1 has a housing 3, the upper housing shell of which is designed as a filter cover 3.1. The filter cover 3.1 has small openings or slots 3.2 that serve as coarse filters. A pressure connection 5 and an intake connection 7 protrude from the circumference of the housing 3.

In Fig. 2, the pond pump from Fig. 1 is shown without the filter cover 3.1. A pumping device 9 is arranged inside the housing 3, which is of a conventional design and is not described further here. In the rear part of the lower half of the housing 3, the so-called lower shell, small openings or slots 3.2 are also designed as coarse filters. Water can also be sucked in from a pond through these openings or small slots 3.2, so that these openings and small slots 3.2 on the housing 3 form a suction area, which is also assigned the reference number 3.2 as a synonym below. An electric motor 11 is arranged behind the pumping device 9 in a watertight manner.

Fig. 3 shows a schematic top view of the pond pump 1 without the filter cover 3.1. A suction connection 17 is formed in the housing 3 in fluid communication with the pump device 9. A pressure connection 15 with the pressure nozzle 5 is formed at an angle to the suction connection 17, preferably perpendicular to the suction connection 17. The suction connection 17 and the pressure connection 15 each have a longitudinal axis, which in the present embodiment lie in a common plane. In an operating position of the pond pump 1, this common plane is preferably a horizontal plane. In other versions

Depending on the design, this plane can also be a vertical plane in the operating position or a plane between a horizontal and a vertical plane. It is also conceivable that the two longitudinal axes of the intake connection 17 and the pressure connection 15 do not lie in a common plane. 5

The intake nozzle 7 is arranged in the housing 3 so as to be adjustable in relation to the intake connection 17. In Fig. 3, the intake nozzle 7 is in a second end position which brings the intake nozzle 7 out of fluid communication with the intake connection 17. There is therefore no fluid connection between the intake nozzle 7 and the connection 17. In this position, the intake connection 17 sucks in 100% of its intake volume through the intake area or the slots 3.2 of the filter cover 3.1 or the lower shell. The intake nozzle 7 can be brought into the end position shown in Fig. 4 continuously or via intermediate positions. In the end position shown in Fig. 4, the pump device 9 sucks in 100% of the intake volume via the intake connection 17 and the pressure nozzle 7. In this first end position in Fig. 4, no water is sucked in through the suction area 3.2.

In Fig. 3 and Fig. 4 it is shown that the intake nozzle 7 can be rotated on a circular path about an axis of rotation which is perpendicular to the longitudinal axis of the intake nozzle 7. By adjusting the intake nozzle 7 to an optional intermediate position between the first end position in Fig. 4 and the second end position in Fig. 3, the intake volume of the pump device 9 can be distributed to the intake nozzle 7 and to the slots 3.2 of the filter cover 3.1. 25

By freely positioning the intake port 7 in relation to the intake connection 17, the intake volume of the pump device 9 can be set between 0% and 100% via the intake port. The respective difference in the intake volume to 100% is then supplied via the intake area 3.2. 30

In Fig. 5, the pond pump according to the invention can be seen schematically and in perspective from the side. On the right-hand side in Fig. 5, the suction slots 3.2 and the suction area 3.2 formed by them are shown.

Fig. 6 shows a top view of the pond pump 1 from Fig. 5. The top view from Fig. 6 is somewhat more detailed than the top views from Fig. 3 and Fig. 4. The intake nozzle 7 can also be adjustable in steps. For this purpose, locking points 19 are formed in Fig. 6 at which the intake nozzle 7 can be positioned. The intake nozzle 7 has a thread 21, preferably an external thread, to which a suction line can be connected. The pump device can be provided with an anti-freeze device (not shown) which protects it from freezing. The pressure nozzle 5 also has a thread 23, preferably also an external thread, to which a pressure line (not shown) can be connected. A cable connection 25 for an electrical supply line is also provided in the housing 3.

The angle enclosed by the intake port 7 and the pressure port 5 is 90° in the first end position, i.e. at 100% suction power through the intake port 7. The angle between the pressure port 5 and the intake port 7 in the second end position is between approximately 90° and 180°. The angle of the intake port 7 in relation to the longitudinal axis of the intake connection 17 is 0° in the first end position and approximately 0 to 90° in the second end position.

In Fig. 7, a system sketch is shown that shows a pond cross-section. The pond pump 1 according to the invention is positioned at the bottom of the pond shown. A pressure line 35 is attached to the pressure port 5, which leads to a pond filter outside the pond. A suction line 37 is attached to the suction port 7, which leads to a skimmer 47 in the area of the water surface of the pond. Depending on the positioning of the suction port 7 in relation to the suction connection 17, the suction of soil dirt can be varied between 0 and 100% of the total pump output. Accordingly, the

Suction of surface dirt can be varied between 0 and 100%. For example, it is possible to direct 70% of the total pump power to the suction area by positioning the suction nozzle 7 in relation to the connection 17.
3.2 and to suck up soil dirt accordingly and 30% of the total
Direct the pump power to the intake port 7 and suck up surface dirt accordingly.

Claims (10)

1. Pond pump with a housing, with a suction connection to which a suction region of a housing shell formed with through slots is assigned, with a pressure connection which is in fluid communication with the suction connection via a pump device arranged in the housing, with a motor for driving the pump device and with a control device for controlling the pump device and the motor, characterized in that the suction connection ( 17 ) is additionally assigned a suction nozzle ( 7 ) which is arranged adjustably in relation to the suction connection ( 17 ) in such a way that a suction volume of the suction connection ( 17 ) can be divided between the suction nozzle ( 7 ) and the suction region ( 3.2 ). 2. Pond pump according to claim 1, characterized in that the intake nozzle ( 7 ) is adjustable between a first end position and a second end position, wherein in the first end position the proportion of the intake volume at the intake nozzle ( 17 ) is 100% and at the intake area ( 3.2 ) is 0% and in the second end position the proportion of the intake volume at the intake nozzle ( 7 ) is 0% and at the intake area ( 3.2 ) is 100%. 3. Pond pump according to claim 2, characterized in that the suction nozzle ( 7 ) is continuously adjustable between the first end position and the second end position. 4. Pond pump according to claim 2, characterized in that the suction nozzle ( 7 ) is stepwise adjustable between the first end position and the second end position. 5. Pond pump according to one of claims 2 to 4, characterized in that the intake nozzle ( 7 ) has a maximum flow cross-section which, in the first end position, is in fluid communication with a maximum flow cross-section of the intake connection ( 17 ), wherein the flow cross-sections in fluid communication are reduced by the adjustment of the intake nozzle ( 7 ) and are out of fluid communication in the second end position. 6. Pond pump according to one of the preceding claims 2 to 5, characterized in that the suction nozzle ( 7 ) and the suction connection ( 17 ) are arranged with a longitudinal axis in one plane and the suction nozzle is rotatable about an axis of rotation perpendicular to the longitudinal axis between the first end position and the second end position. 7. Pond pump according to claim 6, characterized in that the longitudinal axes of the suction connection ( 17 ) and the suction nozzle ( 7 ) coincide in the first end position and enclose an angle in every other position between the first end position and the second end position. 8. Pond pump according to claim 7, characterized in that the included angle is between 0° and 90°. 9. Pond pump according to one of the preceding claims, characterized in that the suction nozzle ( 7 ) is manually adjustable. 10. Pond pump according to one of claims 1 to 8, characterized in that the suction nozzle ( 7 ) is adjustable by the control device.