Patent Application
20240344507
Exemplary embodiments of the present invention relate to a high-pressure plunger pump according and to the use of such a high-pressure plunger pump.
A generic high-pressure plunger pump is known, for example, from DE 10 2016 124 422 A1.
Generic high-pressure plunger pumps are used to generate working pressures of up to 4000 bar. For this purpose, the high-pressure plunger pump has one or more oscillatingly drivable plungers, wherein each of the plungers draws a volume of fluid into a working chamber of the plunger pump via a control valve designed as a suction valve and discharges it under high pressure through an outlet valve. The plunger is driven by a driveshaft that can be driven by a drive device, for example by an electric motor.
Such high-pressure plunger pumps have proven themselves in practice.
Exemplary embodiments of the present invention are directed to adapting a generic high-pressure plunger pump for a further field of application.
The high-pressure plunger pump according to the invention has at least one plunger arrangement with a working chamber and a plunger arranged to move axially back and forth in the working chamber.
The high-pressure plunger pump also has at least one first control valve and at least one second control valve, wherein the two control valves are connected to a valve housing having at least one high-pressure line and at least one low-pressure line.
The high-pressure line is connected to the working chamber in a sealable manner by the first control valve. The low-pressure line is connected to the working chamber in a sealable manner by the second control valve. The valve housing has a high-pressure connection that opens into the high-pressure line.
The at least one first control valve and the at least one second control valve can be actuated via a control unit in such a way that a fluid, which is supplied via the high-pressure connection of the valve housing and is under high pressure, can be supplied to the working chamber and can be discharged via a low-pressure connection of the at least one second control valve after the plunger has been driven, wherein the at least one plunger is coupled to a generator via a driveshaft.
With the high-pressure plunger pump according to the invention, the design of the control valves as separately controllable control valves via the control unit makes it possible to use the high-pressure plunger pump for energy recovery.
Instead of, or in addition to, providing a fluid under high pressure, the control of the control valves according to the invention can be used to virtually reverse the mode of operation of the high-pressure plunger pump, so that a fluid under high pressure can be fed via the high-pressure line into the working chamber of the high-pressure plunger pump, thereby driving the at least one plunger, which in turn is coupled via a driveshaft to a generator, via which at least some of the expansion energy generated during pressure-reducing processes can be recovered.
According to an advantageous embodiment variant, at least three, in particular five, plunger arrangements are provided, each with one plunger, wherein each of the plungers is assigned a first control valve and a second control valve.
The arrangement of at least three plunger arrangements with separately controllable control valves enables simple and reliable operation of the high-pressure plunger pump to drive the generator.
According to a further embodiment variant, the at least one first control valve and the at least one second control valve can be operated by the control unit both as an inlet valve and as an outlet valve. The generator can preferably also be operated as a motor.
This allows the high-pressure plunger pump to be used in a pressure regulation system, for example, in which the high-pressure plunger pump generates the necessary working pressure in the working fluid and provides a process assembly and, secondly, is able to absorb excess high pressure from the process assembly and convert the expansion energy into electrical energy instead of discharging the expansion energy unused to the outside via a drain valve.
According to an advantageous embodiment variant, the control valves can be actuated pneumatically, electrically, or hydraulically.
According to a preferred embodiment variant, the control unit is coupled to one or more sensors, each of which provides one or more operating parameter data of the high-pressure plunger pump, in particular the rotational position of the driveshaft, a pressure of a fluid in the high-pressure line and/or the low-pressure line.
Providing these operating parameters ensures improved control of the control valves by the control unit.
According to a preferred embodiment, the control unit has at least one data interface for recording external operating parameter data, in particular of a process assembly upstream of the high-pressure plunger pump.
Such external operating parameter data can be, for example, the system pressure of the upstream process.
According to a further embodiment variant of the high-pressure plunger pump, this has a second plunger arrangement with a working chamber and a plunger arranged to move axially back and forth in the working chamber, as well as at least one pressure valve and at least one suction valve, which are connected to a valve housing with at least one high-pressure line and at least one low-pressure line.
The high-pressure line is connected to the working chamber in a sealable manner by the pressure valve and the low-pressure line is connected to the working chamber in a sealable manner by the suction valve, wherein the at least one plunger is coupled to a third driveshaft via a second driveshaft, wherein the third driveshaft is also coupled to the first driveshaft.
This design of the high-pressure plunger pump enables the pressure of the working fluid to be increased in use by the second plunger arrangement, wherein the energy for driving the plungers of the second plunger arrangement can be at least partially or completely taken from the expansion of the high-pressure working fluid introduced into the first plunger arrangement, which drives the first driveshaft and can be transmitted to the second driveshaft by coupling via the third driveshaft.
The use according to the invention of a high-pressure plunger pump for pressure regulation in a hydraulic process assembly is characterized in that the high-pressure plunger pump is designed according to one of the embodiments above, wherein the high-pressure plunger pump is coupled to the process assembly such that in pumping operation the high-pressure plunger pump supplies a fluid at a predetermined high pressure to the process assembly, wherein the control valves are controlled via the control unit such that the at least one plunger is driven by a motor-driven driveshaft.
In motor operation of the high-pressure plunger pump, the fluid is supplied at the predetermined high pressure via the high-pressure line and the control valves are controlled via the control unit in such a way that the driveshaft is driven by the at least one plunger, wherein the driveshaft is coupled to a generator to generate electricity.
In a further use of a high-pressure plunger pump for pressure regulation in a hydraulic process assembly, in which the high-pressure plunger pump is designed as described above, the high-pressure plunger pump is coupled to the process assembly such that the fluid is supplied to the high-pressure plunger pump at a high pressure predetermined by the hydraulic process assembly via the high-pressure line and the control valves are controlled via the control unit in such a way that the driveshaft is driven by the at least one plunger, wherein the driveshaft is coupled to a generator to generate electricity.
One such use is provided as a replacement for a pressure relief valve, for example, wherein the excess high pressure in such a pressure relief valve is released unused into the environment, while the use of the high-pressure plunger pump means that this excess pressure is used for energy recovery via the high-pressure plunger pump.
In the following, preferred exemplary embodiments are explained in more detail with reference to the accompanying drawings, wherein:
In the following description of the figures, terms such as top, bottom, left, right, front, rear, etc. refer exclusively to the exemplary representation and position of the high-pressure plunger pump, plunger, working chamber, valve housing, control valve, generator and the like selected in the respective figures. These terms are not to be understood restrictively, i.e., these references may change due to different working positions or the mirror-symmetrical design or the like.
In
The central component of this energy recovery arrangement 1 is a high-pressure plunger pump 2, which is coupled to a generator 11 via a first driveshaft, preferably with the interposition of a clutch 12. A frame 13 of the energy recovery arrangement 1 serves to secure the high-pressure plunger pump 2, the clutch 12, and the generator 11.
In the exemplary embodiment shown, the high-pressure plunger pump 2 has five plunger arrangements 3, each with a working chamber 31 and a plunger 32 arranged to move axially back and forth in the working chamber 31, as shown as an example in the sectional view in
In principle, a high-pressure plunger pump 2 with only one such plunger arrangement 3 is also conceivable.
A first control valve 5 and a second control valve 6, which are connected to a valve housing 4, are provided for each of the plunger arrangements 3.
The valve housing 4 has a high-pressure line 41 for each of the first control valves 5 and a low-pressure line 42 for each of the second control valves.
The high-pressure line 41 and the low-pressure line 42 are connected to the working chamber 31 of the plunger arrangement 3 at their end remote from the respective control valve 5, 6.
The valve housing 4 also has a high-pressure connection 43 that opens into the high-pressure line(s) 41 and is used to supply or discharge a fluid under high pressure.
A further fluid connection 61 is provided on each of the second control valves 6, as shown in
The at least one first control valve 5 and the at least one second control valve 6 can be actuated via a control unit 7 in such a way that a high-pressure fluid supplied via the high-pressure connection 43 of the valve housing 4 can be supplied to the working chamber 31 and can be discharged via a low-pressure connection 61 of the at least one second control valve 6 after the plunger 32 has been driven.
The at least one plunger 32 is coupled to a generator 11 via the driveshaft 9, as explained above.
The high-pressure plunger pump 2 is also characterized in that the control valves 5, 6 can be operated by the control unit 7 both as an inlet valve and as an outlet valve.
This allows the high-pressure plunger pump 2 to be operated both for energy recovery and to provide a fluid under high pressure.
The control valves 5, 6 are preferably pneumatically actuatable. It is also conceivable to actuate the control valves 5, 6 using an electric or hydraulic drive.
Equipping the high-pressure plunger pump 2 with control valves 5, 6 that can be controlled both as an inlet valve and as an outlet valve makes it possible to use a high-pressure plunger pump 2 for energy recovery.
This type of energy recovery is currently known for turbines used in hydropower or pumped storage power plants, for example, or for axial piston motors used in seawater reverse osmosis systems. These above-mentioned applications usually take place in pressure ranges of up to 100 bar.
Such pump systems are not suitable for use at higher pressures of over 200 bar.
For improved actuation of the control valves 5, 6, the control unit 7 is preferably coupled with one or more sensors, each of which provides one or more operating parameters of the high-pressure plunger pump 2, in particular the rotational position of the driveshaft 9, a pressure of a fluid in the high-pressure line 41 and/or the low-pressure line 42.
In a preferred further development, the control unit 7 also has at least one data interface for recording external operating parameter data. Such external operating parameter data is data from a process assembly upstream of the high-pressure plunger pump 2.
If the expansion of a pressurized fluid is necessary in such a process assembly, the pressurized fluid can be fed to the high-pressure plunger pump 2 via the high-pressure connection 43.
A sensor in the upstream process assembly sends a signal to the control unit 7, which then opens the control valve 5 so that the fluid under high pressure passes through the high-pressure line 41 into the working chamber 31 of the plunger 32, where it presses the plunger 32 from a compression position into an expansion position.
At the same time, the first driveshaft, which is coupled to the generator 11, is rotated so that the introduction of the fluid under high pressure into the working chamber 31 of the plunger arrangement 3 causes electricity to be generated and thus energy to be recovered in the generator.
The arrangement of a sensor, for example on the first driveshaft, further improves the control of the individual control valves 5, 6 via the control unit 7.
Thus, in a high-pressure plunger pump 2 with a plurality of plunger arrangements 3, the respective rotational position of the driveshaft 9 can be detected to determine which of the first control valves 5 is opened first after an energy recovery signal is triggered in order to pressurize precisely the one of the plungers 32 of the arrangement of several plunger arrangements 3 that is in a drive position corresponding to the optimum compression position in pump operation.
Two applications for the use of such a high-pressure plunger pump 2 are explained below.
In a first use of the high-pressure plunger pump 2 for pressure regulation in a hydraulic process assembly, the high-pressure plunger pump is coupled to the process assembly in such a way that in pumping mode, i.e. when the high-pressure plunger pump 2 is used in the classic way, the high-pressure plunger pump 2 supplies the process assembly with a fluid at a predetermined high pressure.
This is done by driving the plunger 32 by the generator 11, which can also be operated as a motor, and an energy source that drives it.
Via the low-pressure connection 61 of the second control valve 6, which in this case functions as an inlet, a fluid under low pressure is sucked into the working chamber 31 of the plunger arrangement 3 by moving the plunger 32 from a compression position into an expansion position and, with the plunger 32 subsequently driven by the external motor 10, compressed back into the displacement position and passed on to the process assembly via the high-pressure line 41 and the high-pressure connection 43, into which the high-pressure line 41 opens.
The sequence of opening and closing of the control valves 5, 6 takes place in this known manner, wherein the first control valves are connected as outlet valves and the control valves 6 as inlet valves in pumping mode.
If pressure has to be released from the hydraulic process assembly, the control valves 5, 6 of the high-pressure plunger pump 2 are switched to an energy recovery mode in which the high-pressure plunger pump 2 acts as a motor, so to speak.
In this motor operation of the high-pressure plunger pump 2, the fluid under high pressure is fed into the working chamber 31 of the plunger arrangement 3 at the predetermined high pressure via the high-pressure connection 43 and the high-pressure line 41 when the first control valve 5 is open.
This causes the plunger 32 to be driven, wherein this drive movement is transmitted to the first driveshaft 9, which in turn generates electricity in the generator 11 by coupling it to the generator 11.
In a second use of the high-pressure plunger pump 2, it serves as an expansion valve, in particular as a pressure relief valve.
In this case, the high-pressure plunger pump 2 does not function as a classic pump.
The high-pressure plunger pump 2 is inserted here as an expansion valve, so to speak, in an upstream process assembly, so that a high pressure to be discharged is fed into the high-pressure plunger pump 2 in the manner described above as motor operation of the high-pressure plunger pump 2, which effects energy recovery by generating electricity in the generator 11 via the plunger(s) 32 and the driveshaft 9.
In addition to the input parameters already described above for controlling the control unit 7, it is also conceivable to record the system pressure of the upstream process or the inlet pressure of the fluid when it enters the upstream process as control parameters.
It is also conceivable to detect the speed of the driveshaft 9, the volume flow of the fluid in the high-pressure line 41 or the low-pressure line 42.
The further embodiment variant of a high-pressure plunger pump according to the invention shown in
Preferably, as shown in
As shown in
The high-pressure line 410 is connected to the working chamber 310 by the pressure valve 500 and the low-pressure line 420 is connected to the working chamber 310 by the suction valve 600 so that it can be closed.
The at least one plunger 320 is coupled to a third driveshaft 9 via a second driveshaft, wherein the third driveshaft 9 is also coupled to the first driveshaft.
The third driveshaft 9 is preferably designed as a pinion shaft. The first and second driveshafts are preferably designed as crankshafts.
In addition to the parallel arrangement of the first plunger arrangement 3 to the second plunger arrangement 300 shown in
The second plunger arrangement 300 and the associated valves are used here exclusively to increase the pressure of a working fluid, so that this area of the high-pressure plunger pump operates as a pump, with the high-pressure working fluid being available at a high-pressure connection 430 shown as an example in
The energy required to operate this section is provided partially or even completely via the coupling of the three driveshafts through the other section of the high-pressure plunger pump with the first plunger arrangement and the associated control valves.
Although the invention has been illustrated and described in detail by way of preferred embodiments, the invention is not limited by the examples disclosed, and other variations can be derived from these by the person skilled in the art without leaving the scope of the invention. It is therefore clear that there is a plurality of possible variations. It is also clear that embodiments stated by way of example are only really examples that are not to be seen as limiting the scope, application possibilities or configuration of the invention in any way. In fact, the preceding description and the description of the figures enable the person skilled in the art to implement the exemplary embodiments in concrete manner, wherein, with the knowledge of the disclosed inventive concept, the person skilled in the art is able to undertake various changes, for example, with regard to the functioning or arrangement of individual elements stated in an exemplary embodiment without leaving the scope of the invention, which is defined by the claims and their legal equivalents, such as further explanations in the description.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2021 119 690.6 | Jul 2021 | DE | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2022/062195 | 5/5/2022 | WO |
