AT522820B1 - Pumping device - Google Patents

Abstract

A pumping device (1), in particular for pumping water, comprises at least a first cylinder (2A) and a second cylinder (2B), in each of which a piston (3) with a piston rod (4) connected to it is displaceably guided. Each of the cylinders (2A, 2B) has a front end (5) and a rear end (6). The piston rods (4) emerge from the cylinders (2A, 2B) at the rear end (6). A coupling of the piston rods causes the piston (3) of the other cylinder (2B, 2A) to move when the piston (3) of one of the cylinders (2A, 2B) is moved towards the rear end (6) of this cylinder (2A, 2B). towards the front end (5) and vice versa. In each case in the area of the rear end (6), at least one line connection (17) leads into each of the cylinders (2A, 2B). A working fluid (9), to which heat can be supplied in the area of the front end (5) via a heating device (11), is accommodated in the cylinders (2A, 2B) between the piston (3) and the front end (5). The heat is supplied by a control device (25) which is set up in such a way that the supply of heat to the working fluid (9) of one cylinder (2A, 2B) is interrupted, while the supply of heat to the working fluid (9) of the other cylinder (2B, 2A) is interrupted ) Heat is supplied, and vice versa, controlled.

Description

description

The invention relates to a pumping device, in particular for pumping water, with at least a first cylinder and a second cylinder, in each of which a piston with an associated piston rod is slidably guided, each of the cylinders having a front end and a rear end wherein the piston rods emerge from the cylinders at the rear end, a coupling of the piston rods (4) when the piston of one of the cylinders is displaced towards the rear end of this cylinder causes the piston of the other cylinder to be displaced towards its front end and vice versa, and with at least one line connection leading into each of the cylinders in the region of the rear end.

[0002] Double piston pumps are generally known and, unlike single piston pumps, ensure a substantially continuous flow of liquid when pumping a liquid. Since the pistons are displaced in opposite directions in two cylinders, the pump fluid is alternately sucked into one of the cylinders, while the pump fluid contained therein is pressed out of the other cylinder.

In conventional double piston pumps, the piston rods connected to the piston are moved back and forth in the opposite direction via a drive. The drive can be done manually, for example by a hand lever mechanism, or by a motor, for example an electric motor.

Pumps that can be operated independently, i.e. without being connected to a power grid, are used in a wide variety of areas. For example, they are used in irrigation systems in which the pumps are used to suck in water from a reservoir, e.g. a tank, a lake or the groundwater, via a pipe system and to deliver it to plants via a distribution device or to distribute it over an area.

Hand-operated pumps are essentially self-sufficient, the operation of such pumps is physically strenuous and requires the presence of a person operating the pump on site.

Autarkic pumps operated by motors such as electric motors or internal combustion engines require an independent power supply, which makes them relatively unsuitable for continuous operation over several days or weeks. In addition, such motors are prone to failure and must therefore be serviced at regular intervals.

The invention is therefore based on the object of providing a pump device of the type mentioned at the outset which does not have the disadvantages of the prior art. In particular, a pump that is suitable for continuous operation is to be provided which can be operated in an automated manner, but without the use of a fault-prone motor.

This object is achieved according to the invention with a pump device which has the features of claim 1.

Preferred and advantageous embodiments of the invention are the subject of the subclaims.

According to the invention it is provided that in each cylinder between the piston and the front end, a working fluid, which can be supplied in the region of the front end via a heating device, is received, and that the supply of heat by a control device that is set up so that the supply of heat to the working fluid of one cylinder is interrupted, while heat is supplied to the working fluid of the other cylinder, and vice versa, is controlled.

The fact that the working fluid of one of the cylinders heat is supplied, this expands, so that the piston of the cylinder is pushed from the front end to the rear end

will. By coupling the pistons, the piston of the other cylinder is pushed from the rear to the front end at the same time. By alternately only supplying heat to the working fluid of one of the cylinders, while the supply of heat to the other cylinder is interrupted, the double pump can be operated without the aid of an additional motor or a person operating the pump.

When moving the piston towards the rear end, an overpressure arises in the part of the cylinder between the rear end and the piston. Pump liquid that is located in this section of the cylinder is pressed out of the line connection or one of the line connections. When the piston is moved towards the front end, a negative pressure is created between the rear end and the piston. As a result, pumping liquid is sucked into the cylinder through the line connection or one of the line connections.

In the context of the invention, an embodiment is particularly preferred in which the control device is coupled to the piston or piston rods such that in each of the cylinders when the piston guided therein is moved to the rear end, the supply of heat to the working fluid of this cylinder is interrupted and when moving the piston to the front end, the heat supply is released. By means of such a control, the pumping device can be operated in an essentially continuous pumping mode.

It is also possible within the scope of the invention that the control of the supply of heat is independent of the position of the piston. For example, the supply of heat can change between the cylinders periodically, i.e. following a specific time cycle.

Embodiments are particularly preferred in which the heating device provides the heat with the aid of solar energy. As a result, the pumping device can be operated completely self-sufficiently over long periods of time. It is particularly favorable when the pump device according to the invention is used in an irrigation system, since a lot of irrigation has to be carried out in strong sunlight, but at the same time enough solar energy is available to cover the necessary energy requirements.

Embodiments are also possible within the scope of the invention in which the heating device provides the heat instead or in addition with the aid of wind power, e.g. via a wind turbine, and / or water power, e.g. via a water wheel, and / or geothermal energy. The advantage of all these embodiments is the independence from the power grid and the resulting possible uses in different geographical locations.

According to an advantageous embodiment it is provided that the heating device has an electrically operated heating element arranged at the front end of the respective cylinder, and that the power supply to the heating element can be interrupted or produced by the control device. This has the advantage that the supply of electricity and thus also of heat, for example via switches, can be interrupted quickly and without great structural effort or additional moving components. Heating elements can heat up very quickly and also cool down again quickly, so that a pumping device according to this embodiment can be operated with a relatively high pumping frequency.

For example, the heating element has a heating coil arranged at or in the front end, which is fed with electrical current from outside the cylinder (e.g. generated with the help of solar cells) and which protrudes into the inner region of the cylinder filled with the working fluid.

In the context of the invention, it is also possible for the heating element to supply heat to the working fluid with the aid of high-frequency vibration / s (in particular ultrasound). For this purpose, the heating element has, for example, an oscillating element which can be arranged in the area of the working fluid or can be brought into contact with the working fluid and which can be made to oscillate in such a way that heat is supplied to the working fluid. With such heating elements, the working fluid can be heated very effectively and quickly, for example by supplying electrical current obtained from solar energy.

According to a further advantageous embodiment it is provided that the heating device has a movable heating element which can be arranged at the front end or removed from the front end by the control device. The working fluid can thus be supplied with heat from the heating element via the front end, wherein the supply of heat can be interrupted by removing the heating element. The heating element of a pump device designed in this way can be heated, for example, electrically (in particular via solar power) or thermally (in particular via water warmed up with sun rays). The advantage of this embodiment is that the heating element does not have to be specially heated and cooled, and that the working fluid can be supplied with heat or the supply of heat can be interrupted very quickly by arranging and removing the heating element at the front end.

According to yet another advantageous embodiment it is provided that the heating device of each cylinder has at least one collecting element with which the sun's rays can be fed to the front end in a bundled or concentrated form. As a result, the cylinder is heated in the area of its front end and heat is supplied to the working fluid. The supply of sun rays - and thus the provision of heat to the working fluid - can be interrupted by the control device. It is particularly advantageous that such an embodiment only rarely needs to be serviced, since it is hardly prone to errors or defects.

The collecting element is, for example, a concave mirror that focuses the sun's rays on the front end. It is also conceivable that the collecting element is a lens that focuses the sun's rays on the front end. To interrupt the supply of heat, the control device can place a screen or screen between the mirror or lens and the front end, e.g. by pivoting the screen. However, it is also conceivable that the mirror or the lens itself is adjusted, e.g. pivoted, so that the sun's rays are not directed towards the front end.

The heating device can also have several mirrors or lenses or a combination of mirrors and lenses. Furthermore, the sun's rays do not necessarily have to be fed directly to the front end, but can, for example, heat a liquid in a liquid circuit connected to the front end.

In the context of the invention, the control device can be mechanically coupled to the pistons or piston rods, in particular via a linkage and / or gears and / or belts and / or a cable pull. Such connections are particularly robust against environmental influences and have a long service life.

However, it is preferred - especially when the heat is generated via electrical energy - if the control device is electrically or electronically coupled to the pistons or piston rods. Such connections react particularly quickly, can be regulated precisely and do without additional, moving parts, which wear out more quickly and require additional energy.

The control device can also drive servomotors that, for example, switch switches on or off or fold in or out shields.

In particular, within the scope of the invention, an embodiment is preferred in which a cooling device is arranged at a distance from the front end at or around each of the cylinders, with which heat can be extracted from the working fluid. Preferably, the cooling device is at least a quarter or a third of the total length of the cylinder from the front end thereof. As a result, the piston first has to travel a certain distance in the direction of the rear end before the working fluid comes into contact with the section of the cylinder wall cooled by the cooling device. The cooling device allows heat to be withdrawn particularly quickly from the heated and thus expanded working fluid, so that it cools down more quickly and contracts more quickly or can be compressed with less effort.

The cooling device of each cylinder has, for example, at least one of the respective

Cylinder enclosing line through which a cooling liquid is passed. This cooling liquid can be part of the pump liquid which is passed through the cooling devices when the pump liquid is pressed out of the cylinders. In addition or instead, the cooling device can have cooling fins.

Embodiments are preferred in which the working fluid is at least partially gaseous when the heat is supplied and at least partially liquid when the heat is withdrawn. For example, the working fluid can be a substance which is liquid at room temperature and which evaporates when heat is supplied and changes to a gaseous state. Such fluids have a high thermal expansion and can easily be poured into the cylinders or stored in the cylinders in the liquid state.

Embodiments are also preferred in which the working fluid is essentially liquid when the heat is supplied and withdrawn, or in which the working fluid is substantially gaseous when the heat is supplied and withdrawn.

In the context of the invention, the working fluid can be a pure substance, for example an essentially pure substance that is liquid at room temperature, a pure gas or a mixture of two or more substances (gas mixture, dispersion, liquid mixture).

Preferably there is a negative pressure in the cylinder between the piston and the front end when the piston of the respective cylinder is arranged in an end position in the region of the front end and the working fluid is in an unexpanded state. If a liquid is used as the working fluid, this lowers the boiling point of the liquid. In addition, the negative pressure supports the movement of the piston towards the front end. If, in such a pumping device, heat is withdrawn from the heated and therefore expanded working fluid of one cylinder, it contracts (for example when changing from a gaseous to a liquid state of aggregation). The pressure formed in the working chamber of this cylinder is thereby reduced further and further until a negative pressure arises in the working chamber. The piston of this cylinder is then not only caused by the compressive force of the expanding working fluid of the other cylinder (transmitted to it via the piston of the other cylinder and the coupled piston rods), but also by the ambient pressure (which is higher than the negative pressure in the working chamber of the cylinder is) moved from the rear to the front end of the cylinder. The pumping device can therefore be used to pump faster and more effectively.

So that a chamber is formed between the piston and the front end of the cylinder, the piston is in its end position in the region of the front end - that is, in a position in the cylinder in which the piston cannot be moved further in the direction of the front end - not directly at the front end. For this purpose, for example, an inner shoulder can be provided in the cylinder, against which the piston rests in its end position. However, it is also possible within the scope of the invention that the piston rod (e.g. due to a transverse flange arranged on it) can only be retracted into the cylinder up to a certain length. In this embodiment it is possible to first fill the working fluid into the cylinder, then to pull the piston rod a little out of the cylinder in order to create a negative pressure between the piston and the front end, and then to secure the piston rod against a possible retraction into the cylinder.

Furthermore, it can be provided within the scope of the invention that the cylinders are aligned in the same way, in particular arranged next to one another. Aligned in the context of the invention means that the front end of one cylinder is arranged on the same side as the front end of the other cylinder. With such an arrangement, heat only has to be supplied to the cylinders from one side, for example.

It can also be provided within the scope of the invention that the cylinders are aligned in opposite directions, in particular arranged in a line. With such an arrangement, the piston rods can be coupled to one another particularly easily (e.g. directly).

It is preferred if the piston rods via a movable linkage and / or toothed

wheels and / or belts and / or a cable are coupled to one another. Such a coupling enables the pistons or piston rods to be moved in opposite directions in a simple manner, particularly in the case of cylinders arranged next to one another.

In a further embodiment, the piston rods are coupled directly to one another via an essentially rigid coupling or a rigid linkage, or in each case a partial section of a single piston rod connecting the pistons of both cylinders. In particular, when the cylinders are arranged in a line, a coupling mechanism with additional moving parts can be dispensed with.

In the context of the invention it can be provided that a single line connection is present per cylinder, to which an intermediate line is connected. The intermediate line can be connected (e.g. via a flow switch) to a supply line, via which a pump liquid can be sucked in, and a discharge line via which the pump liquid can be discharged. However, it can also be provided that at least two line connections are present. In such an embodiment, one of the line connections can be connected to a supply line via which a pump liquid can be sucked in, and the other of the line connections can be connected to a discharge line via which the pump liquid can be discharged.

Preferably, a first check valve blocks the feed line when the piston is moved to the rear end, and a second check valve blocks the discharge line when the piston is moved to the front end. Such check valves are cheaper and require less maintenance than controlled valves. The valves can for example - if present - be arranged in the intermediate line, in the discharge and supply line or, if necessary, in the line connections.

In the context of the invention, embodiments are also conceivable in which the piston rods are mechanically connected to at least one further device in such a way that this further device can be driven or operated by the movement of the piston rods. The further device can, for example, be a rod pump, with the aid of which water or another liquid can be conveyed to the surface from a great depth (for example from a depth of more than 100 m). It is also conceivable that the further device is a generator for generating electrical current.

The invention also relates to an irrigation device which has at least one pumping device according to the invention. Furthermore, the irrigation device has at least one supply line via which the pump device (s) can be connected to a water reservoir, at least one water distribution device and at least one outlet via which the pump device (s) is / are connected to the water distribution device (s).

The water reservoir can be, for example, a pond, a lake, the groundwater or an artificial tank or a basin.

It is preferred if the irrigation device has at least one solar panel for generating electrical power. The electricity thus obtained can be used in particular to operate the control device and / or the heating device, but also for monitoring or monitoring. Control electronics and / or can be used to charge a buffer current store.

In the context of the invention, a method for operating a pumping device can also be provided, this method being able to have selected or all features of a pumping device according to the invention - as described above.

Further details, features and advantages of the invention emerge from the following description with reference to the attached drawings, in which preferred embodiments are shown. It shows:

1 shows a side view of the pump device according to the invention according to a first embodiment,

FIG. 2 shows a plan view of the pump device according to the invention of FIG. 1 cut along the sectional plane II-II,

3 shows a side view of the pump device according to the invention according to a second embodiment,

4 shows a plan view of the pump device according to the invention of FIG. 3 cut along the sectional plane IV-IV,

5 shows a side view of the pump device according to the invention in accordance with a third embodiment, and FIG

FIG. 6 shows a longitudinal section through the pumping device according to the invention from FIG. 5 with additional details.

1 and 2 show a pump device 1 according to the invention according to a first embodiment, in which the heat required to operate the pump device 1 is provided with the aid of solar power.

The pumping device 1 has a first cylinder 2A and a second cylinder 2B, which are essentially aligned in the same way and are arranged to run parallel next to one another. A piston 3 is guided in each of the cylinders 2A, 2B and is connected to an associated piston rod 4.

Each of the cylinders 2A, 2B has a front end 5 and a rear end 6, a working chamber 7 being formed between the piston 3 and the front end 5 and a pump chamber 8 being formed between the piston 3 and the rear end 6 is.

In the working chamber 7 of each cylinder 2A, 2B, a working fluid 9 is accommodated, which expands when heat is supplied, shifts the respective piston 3 towards the rear end 6 and thus increases the volume of the working chamber 7.

In the area of the front end 5, an inner shoulder 10 is formed in the cylinder 2A, 2B, on which the piston 3 in its end position - in which it cannot be pushed further towards the front end 5 - rests. The working chamber 7 of a cylinder 2A, 2B thus has the smallest possible volume when the piston 3 is in the end position.

The working fluid 9 can be supplied with heat via a heating device 11 provided for this purpose in the region of the front end 5 of each cylinder 2A, 2B. In the embodiment shown, the heating devices 11 have electrical heating elements, the heating coils 12 of which protrude into the working chambers 7. The heating devices 11 - and thus the heating coils 12 - are supplied with electrical current via power connections 13, so that the heating coils 12 through which the current flows feed heat to the working fluid 9.

The power connections 13 are connected via power lines 14 to a solar panel 15 which generates solar power.

The piston rods 4 of the cylinders 2A, 2B are coupled to one another via a pivotable linkage 16 in such a way that when one piston rod 4 is extended, the other piston rod 4 is automatically retracted and vice versa. Correspondingly, the piston 3 of the first cylinder 2A also moves towards the front end 5 when the piston 3 of the second cylinder 2B is displaced by the expanding working fluid 9 to the rear end 6 and vice versa.

The pump chamber 8 of each cylinder 2A, 2B has two line connections 17. One of the line connections 17 is connected via a feed line 18 to a liquid reservoir, in particular a water reservoir 19, of a pump liquid 20. The other line connection 17 is each connected via a discharge line 21 to a liquid distribution device, in particular a water distribution device 22, for distributing or dispensing the pumped liquid 20.

The line connection 17 connected to the supply line 18 has a non-return valve which prevents pump liquid 20 from flowing out of the pump chamber 8 into the supply line 18. In contrast to this, the line connection 17 connected to the discharge line 21 has a non-return valve which prevents pump liquid 20 from flowing out of the discharge line 21 into the pump

chamber 8 can be sucked.

Each of the cylinders 2A, 2B is encased by a cooling device 23 which is spaced from the front end 5 of the cylinder 2A, 2B. Thus, the piston 3 must first be moved a certain distance from the front end 5 to the rear end 6 of the cylinder 2A, 2B so that the working chamber 7 extends to the cooling device 23 and can be cooled by this.

The cooling devices 23 are connected to the discharge line 21 via a cooling line 24 or are integrated directly into the discharge line 21.

An electrical control device 25 is coupled to the piston 3 or piston rod 4, so that the power supply for the heating device 11 of each cylinder 2A, 2B is interrupted as soon as the piston 3 of this cylinder 2A, 2B in the area of the rear end 6 is shifted. For example, the control device 25 can have sensors in order to measure how far the respective piston rod 4 has moved out of the cylinder 2A, 2B.

A pumping process with the pumping device according to the invention takes place, for example, as follows:

The piston 3 of the first cylinder 2A is arranged in its end position at the front end 5 of the first cylinder 2A and rests against the inner shoulder 10. The working fluid 9 is in a liquid, essentially unexpanded state in which it does not exert any pressure on the piston.

Via the heating device 11 of the first cylinder 2A, heat is supplied to the working fluid 9 of the first cylinder 2A, so that it at least partially evaporates and expands.

The piston 3 of the first cylinder 2A is displaced in the direction of the rear end 6 of the first cylinder 2A due to the overpressure in the working chamber. As a result, the pumping liquid 20 received in the pumping chamber 8 is pressed out of the pumping chamber 8 through the line connection 17 connected to the discharge line 21, and passed via the discharge line 21 and the cooling devices 23 to the water distribution device 22.

At the same time, the piston rod of the first cylinder 2A moves out of the first cylinder 2A, so that the control device 25 interrupts the power supply to the heating device 11 of the first cylinder 2A and thus also the supply of heat to the working fluid 9 of the first cylinder 2A.

By moving out the piston rod 4 of the first cylinder 2A, the piston rod 4 of the second cylinder 2B is moved into the second cylinder 2B via the pivotable linkage 16.

By retracting the piston rod 4 of the second cylinder 2B, the piston 3 in the second cylinder 2B is displaced in the direction of the front end 5 of the second cylinder 2B, as a result of which a negative pressure is created in the pumping chamber 8 of the second cylinder 2B. Due to this negative pressure, the pump liquid 20 is sucked from the water reservoir 19 into the pump chamber 8 of the second cylinder 2B via the supply line 18, which is connected to one of the line connections 17.

When the piston 3 of the second cylinder 2B is in its end position in the region of the front end 5 of the second cylinder 2B, the control device 25 restores the previously interrupted power supply for the heating device 11 of the second cylinder 2B.

As a result, the working fluid 9 of the second cylinder 2B is now supplied with heat and the described pumping process takes place in the same way as described, only in the reverse order.

So that the working fluid 9 in the cylinders 2A, 2B cools more quickly in the expanded state and the respective piston 3 can be moved more quickly back to the front end 5 of the respective cylinder 2A, 2B, heat is extracted from the working fluid 9 via the cooling devices 23 as soon as the respective working chamber 7 has reached a predetermined volume or a predetermined size.

3 and 4 show the pump device 1 according to the invention according to a second embodiment, in which the heat required to operate the pump device 1 is generated with the aid of solar rays 26.

The pump devices 1 of the first and the second embodiment are essentially constructed in the same way, but differ in the design of the heating device 11 and the control device 25.

The heating devices 11 of the pump device 1 shown in FIGS. 3 and 4 have lenses 27, with the aid of which sun rays 26 can be focused onto the front ends 5 of the cylinders 2A, 2B. For this purpose, at least one lens 27 is assigned to each cylinder 2A, 2B.

In this embodiment, the front end 5 of the cylinders 2A, 2B has a particularly high thermal conductivity, so that the working fluid 9 in the cylinders 2A, 2B can be supplied with a large part of the heat generated by the bundling of the sun rays 26.

In the embodiment shown in FIGS. 3 and 4, the control device 25 has a control mechanism 28 coupled to the piston rods 4 and a pivotable shield 29 for each cylinder 2A, 2B. When the piston rod 4 extends out of the cylinder 2A, 2B, the respective shield 29 is pivoted between the front end 5 of the cylinder 2A, 2B and the associated lens 27 so that no sun rays 26 can hit the front end 5 and heat it. The supply of heat to the working fluid 9 of the cylinder 2A, 2B concerned is thus prevented.

The control mechanism 28 of each cylinder 2A, 2B comprises in the embodiment shown a linkage 28 coupled to the piston rods 4, which is moved with the aid of rack rails 31 and a gear 32 counter to the piston rod 4 of the corresponding cylinder 2A, 2B.

In the embodiments shown in FIGS. 1 to 4, the pumping device 1 is shown as part of an irrigation device. However, it is also possible that the pumping device 1 is part of another fluid system, e.g. a drinking water supply, an oil circuit, a bathing water circuit, etc.

5 and 6 show the pump device 1 according to the invention according to a third embodiment. In this embodiment, too, the heat required to operate the pump device 1 is provided - as in the embodiment shown in FIGS. 1 and 2 - with the aid of solar power that is obtained via a solar panel 15.

In this embodiment, the cylinders 2A, 2B of the pumping device 1 are aligned in a line and opposite to one another, so that the rear end 6 of each cylinder 2A, 2B points towards the rear end of the other cylinder 2B, 2A.

The piston rods 4 of the pistons 3 guided in the cylinders 2A, 2B are connected to one another and form a single common piston rod 4.

When the common piston rod 4 is displaced out of one of the cylinders 2A, it is pushed directly into the other cylinder 2B and vice versa, without the need for a pivotable linkage 16.

The control device 25 has a common control mechanism 28 which is coupled to the piston rod 4 and which is connected to the heating devices 11 of both cylinders 2A, 2B.

The heating device 11, which is assigned to that cylinder 2A, 2B, from which the common piston rod 4 is pushed out, is removed from the cylinder 2A, 2B, in particular lowered. Thus, the supply of heat to the working fluid 9 of this cylinder 2A, 2B is prevented. At the same time, the heating device 11 assigned to the other cylinder 2B, 2A is brought up to this other cylinder 2B, 2A into which the common piston rod 4 is pushed, in particular raised. The heating device 11 can thus heat to the working

release fluid 9 of the other cylinder 2b, 2A.

In the embodiment shown, the common control mechanism 28 of the cylinders 2A, 2B comprises a linkage 30 with chains coupled to the common piston rod 4, which is moved in opposite directions to the common piston rod 4 with the aid of toothed rails 31 and a toothed wheel 32.

The invention is not limited to the illustrated embodiments. In particular, further embodiments are conceivable which combine certain features of the pump devices 1 shown in FIGS. 1 to 6.

For example, a pump device 1 according to the invention, in which the cylinders 2A, 2B, as in the embodiment shown in FIGS shown have. In such a pump device 1, the heating devices 11 are preferably arranged permanently on the front ends 5 of the cylinders 2A, 2B. The power supply to the heating devices 11 is interrupted or released by the electrical control device 25 - depending on the position of the common piston rod 4.

Austrian

REFERENCE LIST

10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32

Pumping device

(A, B) cylinder (first, second) piston

Piston rod

front end

rear end working chamber pumping chamber working fluid inner shoulder heating device heating coil power connection power line solar panel pivotable linkage line connection supply line water reservoir pumping liquid discharge water distribution device cooling device cooling line control device solar radiation

lens

Control mechanics shield

Linkage of the control device rack rails

gear

AT 522 820 B1 2021-07-15

Claims (20)

Claims 1. Pump device (1), in particular for pumping water, with at least one first cylinder (2A) and a second cylinder (2B), in each of which a piston (3) with an associated piston rod (4) is displaceably guided, wherein each of the cylinders (2A, 2B) has a front end (5) and a rear end (6), the piston rods (4) emerging from the cylinders (2A, 2B) at the rear end (6), a coupling of the Piston rods (4) when the piston (3) of one of the cylinders (2A, 2B) is displaced towards the rear end (6) of this cylinder (2A, 2B), the piston (3) of the other cylinder (2B, 2A) is displaced its front end (5) and vice versa, and in each case in the region of the rear end (6) at least one line connection (17) leads into each of the cylinders (2A, 2B), characterized in that in the cylinders (2A, 2B ) in each case between the piston (3) and the front end (5) a working fluid (9), the one in the area of the front end (5) heat can be supplied via a heating device (11), and that the supply of heat by a control device (25) which is set up in such a way that the supply of heat to the working fluid (9) of one cylinder (2A, 2B ) is interrupted while the working fluid (9) of the other cylinder (2B, 2A) heat is supplied, and vice versa, is controlled. 2. Pump device according to claim 1, characterized in that by coupling the control device (25) with the piston (3) or piston rods (4) in each of the cylinders (2A, 2B) when moving the piston (3) guided therein for rear end (6) the supply of heat to the working fluid (9) of this cylinder (2A, 2B) is interrupted and the supply of heat is released when the piston (3) is moved to the front end (5). 3. Pump device according to claim 1 or 2, characterized in that the heating device (11) provides the heat with the aid of solar energy. 4. Pump device according to one of claims 1 to 3, characterized in that the heating device (11) has an electrically operated heating element arranged at the front end (5) of the respective cylinder (2A, 2B), and that the control device (25) the power supply to the heating element can be interrupted or produced. 5. Pump device according to claim 4, characterized in that the heating element (11) has a heating coil (12) which can be heated with the aid of electrical current or a vibrating element which can be set in vibration with the aid of electrical current. 6. Pump device according to one of claims 1 to 3, characterized in that the heating device (11) has a movable heating element which can be arranged by the control device (25) at the front end (5), so that heat from the heating element via the front end (5) the working fluid (9) can be supplied, or the supply of heat can be interrupted by removing the heating element. 7. Pump device according to one of claims 1 to 3, characterized in that the heating device (11) has at least one collecting element, such as a concave mirror or a lens (27), with which the front end (5) sun rays (26) can be supplied so that the front end (5) is heated and gives off heat to the working fluid (9), and that the control device (25) can interrupt the supply of sun rays (26), in particular by means of the control device (25) between the front end (5) and the collecting element placeable shield (29). 8. Pump device according to one of claims 1 to 7, characterized in that the control device (25) mechanically, in particular via a linkage (39) and / or gears (32) and / or belts and / or a cable, or electrically or is electronically coupled to the piston (3) or piston rod (4). 9. Pump device according to one of claims 1 to 8, characterized in that spaced from the front end (5) on or around each of the cylinders (2A, 2B) a cooling device (23) is arranged with which the working fluid (9) heat can be extracted is. 10. Pump device according to one of claims 1 to 9, characterized in that the working fluid (9) is at least partially gaseous when the heat is supplied and at least partially liquid when the heat is withdrawn, or that the working fluid (9) is essentially gaseous when the heat is supplied and withdrawn or that the working fluid (9) is essentially liquid when the heat is supplied and withdrawn. 11. Pump device according to one of claims 1 to 10, characterized in that a negative pressure prevails in each of the cylinders (2A, 2B) between the piston (3) and the front end (5) when the piston (3) of the respective cylinder (2A, 2B) arranged in an end position in the region of the front end (5) and the working fluid (9) is in an unexpanded state. 12. Pump device according to one of claims 1 to 11, characterized in that the cylinders (2A, 2B) are aligned in the same way, in particular arranged next to one another, or aligned in opposite directions, in particular arranged in a line. 13. Pump device according to one of claims 1 to 12, characterized in that the piston rods (4) are coupled to one another via a movable linkage (16) and / or gears and / or belts and / or a cable pull. 14. Pump device according to one of claims 1 to 12, characterized in that the piston rods (4) are coupled directly to one another via a substantially rigid coupling or a rigid linkage, or that the piston rods (4) each have a section of a single piston rod (4 ) are. 15. Pump device according to one of claims 1 to 14, characterized in that a single line connection (17) per cylinder (2A, 2B) is present, to which an intermediate line is connected, with a feed line (18) through which a pump liquid (20) can be sucked in, and can be connected to a discharge line (21) via which the pump liquid (29) can be discharged. 16. Pump device according to one of claims 1 to 14, characterized in that at least two line connections (17) are present, one of the line connections (17) having a supply line (18) through which a pump liquid (20) can be sucked, and the other the line connections (17) can be connected to a discharge line (21) via which the pump liquid (20) can be discharged. 17. Pump device according to one of claims 1 to 16, characterized in that a check valve blocks the supply line (18) when moving the piston (3) to the rear end (6), and that another check valve blocks the discharge line (21) when moving the Piston (3) blocked towards the front end (5). 18. Pump device according to one of claims 1 to 17, characterized in that by a mechanical connection of the piston rods (4) with at least one further device, such as a rod pump or a generator, this further device can be driven by the movement of the piston rods (4) or is operable. 19. Irrigation device consisting of at least one pumping device (1), at least one feed line (18) via which the pumping device (s) (1) can be connected to a water reservoir (19), at least one water distribution device (22) and at least one discharge line ( 21), via which the pump device (s) (1) is / are connected to the water distribution device (s) (22), characterized in that the pump device (s) (1) is / are designed according to one of claims 1 to 18. 20. Irrigation device according to claim 19, characterized in that it has at least one solar panel (15) for generating electrical power. In addition 3 sheets of drawings