This application is a United States National Phase Application of International Application, PCT/EP2018/070968, filed Aug. 2, 2018, and claims the benefit of priority under 35 U.S.C. § 119 of European Application 17 184 776.7, filed Aug. 3, 2017, the entire contents of which are incorporated herein by reference.
The invention relates to a circulation pump assembly as well as to a heating system with such a circulation pump assembly.
In heating systems, circulation pump assemblies are used in order to circulate a fluid heat-transfer medium or a heating medium, in particular water, through the heating system. If in heating systems one uses heating circuits which require different feed temperatures, it is common to provide mixers which can reduce the feed temperature for certain heating circuits, for example heating circuits of a floor heating. Such mixers are often applied in combination with compact heating boilers which apart from a heat source such as a heating boiler with a primary heat exchanger, also already comprise a circulation pump assembly for circulating the heat-transfer medium through the heating system. This circulation pump assembly provides a residual delivery head which is adapted such that it is sufficient for a conventional heating circuit with radiators and thermostat valve. As a rule, a second circulation pump assembly which is arranged downstream of a mixing valve, via which valve the heated heat transfer medium is injected out of the heating boiler into a heating circuit with a lower feed temperature, is then used for this further heating circuit with a reduced feed temperature. Here, it is necessary to reduce the preliminary pressure which is provided in the boiler by the circulation pump assembly, in the mixing valve or a valve arranged upstream, to the pressure level at the inlet side of the circulation pump assembly in the second heating circuit. I.e. the residual delivery head which is provided in the heating boiler by the circulation pump assembly is destroyed and an energy loss occurs.
The circulation pump assembly according to the invention in particular is designed as a heating circulation pump assembly for application in a heating facility, wherein a heating facility in the context of this invention is also to be understood as an air-conditioning facility which does not serve for heating but for cooling. Very generally, the circulation pump assembly according to the invention can be used for circulating a fluid heat transfer medium or heating medium for the temperature adjustment of a building or a facility.
The circulation pump assembly according to the invention comprises a first inlet, i.e. a first suction inlet, as well as an outlet. The outlet is a delivery outlet, through which the fluid exits out of the circulation pump assembly. The circulation pump assembly moreover comprises an electrical drive motor which rotatingly drives at least one impeller (an impeller arrangement comprising at least one impeller) which is provided in the circulation pump assembly. I.e. the circulation pump assembly is a centrifugal pump assembly. The electrical drive motor is particularly preferably configured as a wet-running electrical drive motor, i.e. as a motor with a can or can pot between the rotor and the stator. The at least one impeller is arranged in the circulation pump assembly in a connection or flow connection between the first inlet and the outlet. The impeller comprises at least one flow path in this flow connection and serves for the pressure increase of a fluid. The impeller can therefore deliver a fluid, e.g. a fluid heating medium, from the first inlet and to the outlet and increase the pressure of the fluid between the inlet and outlet. The at least one flow path through the impeller can be formed for example by way of the usual channels between the impeller blades.
According to the invention, the circulation pump assembly comprises a second inlet, wherein a second flow connection from this second inlet to the outlet is formed in the circulation pump assembly. The second inlet thus forms a second suction inlet or suction branch, wherein a different pressure level than at the first inlet can prevail at the second inlet on operation of the circulation pump assembly. The at least one impeller moreover comprises at least one second flow path with a pressure increase of a fluid such as a fluid heating medium, wherein this second flow path lies in the described flow connection between the second inlet and the outlet. This means that the circulation pump assembly according to the invention comprises two separate flow paths in the at least one impeller, via which paths a pressure increase can be accomplished. This design permits fluids, such as e.g. two flows of a fluid heating medium which are from the two inlets and which have a different inlet pressure or preliminary pressure at the two inlets, to be increased to the same end pressure at the outlet. I.e. the at least one impeller with the two flow paths is configured such that it produces two different pressure differences on its rotation.
This design according to the invention permits the circulation pump assembly to be used in a heating circuit with a mixer and to feed fluid at a preliminary pressure, i.e. at a residual delivery head, to the second inlet of the circulation pump assembly. This preliminary pressure can be provided for example by a circulation pump in a heating boiler or in a compact heating facility. With this arrangement, the mixing point of the mixer is then situated in the described circulation pump assembly and it is no longer necessary to reduce the preliminary pressure or the residual delivery head at the inlet side of the mixer, in order to achieve the same suction pressure at the suction side of the circulation pump assembly in the heating circuit which is to be supplied via the mixer. In contrast, fluids at two different pressure levels can be fed to the circulation pump assembly according to the invention. The fluid which is to be circulated in the heating circuit to be supplied is fed at the first inlet, whereas the fluid which is with a higher pressure level and which is to be admixed is admixed via the second inlet. The circulation pump assembly according to the invention therefore permits the reduction of energy losses on operation of a mixer. Since the floor heating usually accounts for the greatest share with modern heating systems, energy savings in the region of the circulation pump assemblies of up to 30% can be realized in this manner.
The two separate flow paths in the at least one impeller are preferably configured such that they have a fixed, non-changing cross-sectional ratio to one another. I.e. for changing a mixing ration one preferably does not envisage changing a cross-sectional ratio of the two flow paths. This simplifies the construction since no corresponding valve devices and also no displaceablity of the impeller are necessary. In contrast, a change of the mixing ratio is particularly preferably achieved by a speed change of the at least one impeller, as is described further below.
Preferably, the at least one flow path and the at least one second flow path are arranged in a common impeller. I.e. a pressure increase of the fluid flowing through the two flow paths is effected over these flow paths on rotation of the impeller with these two flow paths. Alternatively, it is possible to use two impellers which are arranged to one another in a rotationally fixed manner and which rotate together. These can be formed as one piece with one another or be rotationally fixedly connected to one another in another manner. For example, an impeller with two blade rings can also be used, wherein a first blade ring defines the first flow paths and a second blade ring defines the second flow paths. Such an impeller can be configured such that the run-ins or inlets for both flow paths are situated at the same axial side, seen in the direction of the rotation axis or also at sides which are opposed to one another in the axial direction. Also on using two impellers, these could be arranged such that the inlet sides or suction openings are directed opposite one another. Such an arrangement has the advantage that the occurring axial forces at least partly cancel one another out.
According to a further preferred embodiment of the invention, it is possible for the at least one second flow path to be formed by a section of the at least one first flow path. Here, the first flow path then comprises a first section, in which only the fluid flowing through the first flow path undergoes a pressure increase. The second inlet runs out into a second section of the first flow path, in which section the fluid which is fed from the second inlet as well as the fluid which exits from the first section of the first flow path then undergoes a pressure increase. I.e., the fluid flow from the first inlet as well as the fluid flow from the second inlet undergoes a pressure increase in the second flow path. If fluid with a preliminary pressure is fed at the second inlet, then this has the advantage that the fluid which is fed at a lower preliminary pressure via the first inlet undergoes a first pressure increase in the first section of the first flow path, so that the fluids from the first and second inlet have essentially the same pressure level at that point, at which the flow runs out from the second inlet into the first flow path.
Further preferably, the at least one impeller comprises a suction port as a first inlet opening, departing from which the at least one first flow path extends to an outlet side of the impeller. The suction port as a first inlet opening is in connection with a first inlet of the circulation pump assembly and the outlet side of the impeller is in connection with the outlet of the circulation pump assembly. The impeller preferably comprises at least one second inlet opening which in the direction of the flow through the impeller is situated between the mentioned suction port and the outlet side. This at least one second inlet opening is connected to the second inlet of the circulation pump assembly. A fluid flow at a greater pressure level can therefore be introduced into the impeller via a second inlet opening, at a position, at which the fluid which is fed through the suction port has already undergone a certain pressure increase in the impeller. On using this circulation pump assembly in a mixer or as a mixer, the mixing point of the two flows therefore lies in the impeller. Thus two fluid flows with a different preliminary pressure can be mixed at a mixing point with an essentially equal pressure level without the greater pressure in one of the two fed fluid flows firstly having to be reduced. The energy loss can be minimized by way of this.
The second inlet opening preferably runs out into a first flow path, wherein the section of the at least one first flow path simultaneously forms the at least one second flow path between the at least one second inlet opening and the outlet side. I.e. the second flow path forms a common flow path, through which the fluid flow from the first inlet as well as the fluid flow from the second inlet are led, wherein the fluid flow from the first inlet of the circulation pump assembly has already undergone a pressure increase in a first section of the first flow path upstream of the at least one second inlet opening independently of the flow from the second inlet.
Particularly preferably, the impeller comprises a plurality of second inlet openings. The flow cross section can be enlarged by way of this and the hydraulic resistance in the second flow path can therefore be minimized.
Preferably, several first flow paths are formed between impeller blades of the at least one impeller and at least one second inlet opening runs out into each of the first flow paths between the impeller blades. The sections of the first flow paths between the suction port and the second inlet openings then form the described first flow paths, through which only the fluid fed through the first inlet is delivered. The second sections of the first flow paths with the second inlet openings form a second flow path downstream of these second inlet openings, through which second flow path the fluid which is fed through the second inlet is also delivered. A maximum flow cross section for the second flow paths in the impeller is provided due to the fact that second inlet openings are arranged in each of the first flow paths.
Further preferably, the at least one second inlet opening is formed in a shroud which surrounds the suction port. I.e. the impeller is configured as a closed impeller which comprises a shroud which closes the flow paths between the impeller blades in the periphery of the centrally arranged suction port. The suction port forms the first inlet opening for the first flow paths. The second inlet openings are configured as holes or a gap in the shroud, said holes or gap running out into these flow paths between the impeller blades, so that the flow paths radially at the outer side of the second inlet openings form the second flow paths according to the preceding description.
The suction port of the at least one impeller is preferably in engagement with a stationary ring element, into the inside of which a flow connection from the first inlet runs. A flow connection from the first inlet into the inside of the impeller and into the first flow paths of the impeller is therefore created. The ring element is further preferably in an essentially sealed engagement with the suction port, i.e. a suction port seal or sealing is formed between the suction port and the ring element, in order to reduce or avoid leakages in this region.
Further preferably, an annular space, into which a flow connection from the second inlet runs out is formed at the outer periphery of the described ring element, wherein the at least one second inlet opening of the impeller faces this annular space. In this design, the ring element thus forms a separating wall between the first and the second flow connection, wherein the flow connection from the first inlet runs towards the impeller at the inner side of the ring wall and the flow connection from the second inlet towards the impeller runs at the outer side of the ring element.
According to a further preferred embodiment of the invention, the impeller radially outside the at least one second inlet opening is in sealing engagement with a part of the surrounding pump casing. This sealing engagement forms a seal between the suction side and the delivery side of the impeller, so that the outlet side of the impeller is sealed with respect to the flow connection to the at least one second inlet opening.
According to a particular embodiment of the invention, a valve can be arranged at least in the flow connection between the second inlet and the at least one impeller, for adjusting the flow rate through this flow connection. This valve can form a mixing valve, via which the fed fluid quantity from the second inlet can be regulated (closed-loop controlled), for example in to be able to regulate the temperature of the mixed flow at the outlet of the circulation pump assembly. For this, the valve can preferably comprise an electrical drive for changing the valve position, wherein the electrical drive is preferably a stepper motor. The valve can then be activated by a control device which adjusts the valve position for example in a temperature-dependent manner, in dependence on the temperature at the outlet side of the circulation pump assembly, i.e. in dependence on the temperature of the mixed flow. A mixer with a temperature regulation is therefore created. However, flow regulation valves which are to be actuated manually can also be arranged in one or both flow connections, in order for example to be able to carry out a presetting of the flow rates.
Particularly preferably, the circulation pump assembly comprises a control device which is configured for adjusting/setting the speed of the drive motor. The control device can be configured for example such that carries out a pressure regulation and/or flow rate regulation (closed-loop control), in order to maintain the pressure and/or the flow rate in the range of predefined setpoints. Alternatively, a temperature-dependent speed regulation is also possible, concerning which the speed is adjusted in dependence of a temperature signal such that a temperature value is held in the region of predefined setpoints. Thus for example the temperature at the outlet side of the circulation pump assembly, i.e. at the outlet or in the fluid flow which flows through the outlet, can be regulated by way of speed regulation or speed change of the circulation pump assembly.
Apart from the aforementioned circulation pump assembly, the subject-matter of the invention is also a heating system with such a circulation pump assembly, wherein the previously described circulation pump assembly forms a first circulation pump assembly in the heating system. The heating system according to the invention moreover comprises a second circulation pump assembly which is situated upstream of the second inlet of the first pump assembly. The second circulation pump assembly thus leads a fluid flow with a preliminary pressure which is produced by the second circulation pump assembly to the inlet of the first pump assembly. The second circulation pump assembly is preferably a circulation pump assembly which is adjustable in its speed via a control device. This centrifugal pump assembly preferably likewise comprises an electrical drive motor which further preferably can be configured as a wet-running drive motor. The preliminary pressure or flow rate can be adjusted or regulated via the speed adaptation. The speed regulation of the second circulation pump assembly is preferably effected such that the flow rate and/or the pressure is maintained in the range of desired, predefined setpoints or follows a predefined characteristic curve. The first circulation pump assembly as well as the second circulation pump assembly can be configured such that they comprise a frequency converter for speed regulation.
Further preferably, a control device is provided in the heating system according to the invention, said control device being configured in a manner such that it controls the first circulation pump assembly and/or the second circulation pump assembly and/or a valve which is situated in the flow path from the second inlet to the at least one impeller, in order to adjust a mixing ratio of the fluid flows from the first inlet and the second inlet in the first circulation pump assembly. Here, the speed control is preferably effected in a temperature-dependent manner. I.e. the control device is preferably connected to at least one temperature sensor and controls the speeds of the circulation pump assembly or of the circulation pump assemblies such that the temperature which is detected by the temperature sensor is kept to a desired setpoint or approximates a desired setpoint. The temperature sensor is preferably arranged at the outlet side of the first circulation pump assembly, so that it detects the temperature of the mixed fluid flow which flows through the outlet of the first circulation pump assembly. The quantity of the fluid which is fed to the second inlet can therefore be changed if the control device varies the speed of the second circulation pump assembly. The same can be achieved by way of adjusting a valve upstream of the second inlet of the first circulation pump assembly. It is likewise possible to change the mixing ratio by way of the speed change of the first circulation pump assembly when the flow rate ratio and/or the pressure ratio of the flows through the first and the second flow path changes in a speed-dependent manner. This can be achieved by way of a suitable geometric design of the first flow path and of the second flow path, in particular if the first and the second flow path for example end at different outer diameters of the impeller. Different pressure increases are therefore accomplished at the same speed. Changes of the pressure ratio can moreover be achieved by way of the fluid being fed to the second inlet at a preferably constant preliminary pressure. If the flow connection from the second inlet runs out into a first flow path of the impeller, as is described above, then the pressure at the run-out point in the inside of the impeller changes given a speed change, so that the mixing ratio in the inside of the impeller is changed by way of changing the pressure rations in the two flow paths.
The invention is hereinafter described by way of example and by way of the attached figures. The various features of novelty which characterize the invention are pointed out with particularity in the claims annexed to and forming a part of this disclosure. For a better understanding of the invention, its operating advantages and specific objects attained by its uses, reference is made to the accompanying drawings and descriptive matter in which preferred embodiments of the invention are illustrated.
In the drawings:
Referring to the drawings,
Concerning the three solutions according to the invention which are described by way of example and are schematically represented in
In the embodiment example according to
The drive motor 30 is controlled or regulated by a control device 34 which serves for speed regulation or speed control of the drive motor 30 and is configured such that it can change the speed of the drive motor 30. For this, the control device 34 comprises a speed controller, in particular amid the application of a frequency converter. The control device 34 can be integrated directly into the drive motor 30 or be arranged in an electronics casing directly on the drive motor and in particular on the motor casing of this motor. The control device 34 is moreover connected to a temperature sensor 36 or communicates with a temperature sensor 36. The temperature sensor 36 is situated downstream of the mixing point 20 on or in the feed conduit 38 which connects the mixing point 20 to the floor heating circuit 2. Here, the temperature sensor 36 can be integrated into the mixing device 22 or into the circulation pump assembly 24. The connection of the temperatures sensor 36 to the control device 34 can be provided in an arbitrary manner, for example connected by wire or also in a wireless manner. A wireless connection can be realized for example via a radio connection such as Bluetooth or W-LAN.
The temperature sensor 36 transmits a temperature value of the heating medium downstream of the mixing point 20 to the control device 34, so that this can carry out a temperature regulation. According to the invention, the drive motor 30 and therefore the circulation pump assembly 34 is not regulated in a pressure-dependent or flow-rate-dependent manner, but in a temperature-dependent manner. I.e. the control device 34 adapts the speed of the drive motor 30 such that a desired temperature of the heating medium is reached downstream of the mixing point 20. The desired temperature is defined by a temperature setpoint which can be set in a fixed manner, can be manually adjusted or can be specified depending on the outer temperature by a heating curve which is stored in the control device 34 or a superordinate control. The control device 34 varies the speed of the drive motor 30, by which means, as described hereinafter, the mixing ratio of the heating medium flows which are mixed at the mixing point 20 changes, so that the temperature downstream of the mixing point 20 changes. This temperature is detected by the temperature senor 36, so that the control device 34 can carry out a temperature regulation by way of speed variation of the drive motor 30, in order for the temperature value downstream of the mixing point 20 to approximate the temperature setpoint.
The variation of the mixing ratio at the mixing point 20 via the speed change is explained in more detail by way of
The embodiment example according to
With this configuration too, the mixing ratio between the heating medium flow from the return conduit 16 and the heating medium flow from the feed conduit 18 can be changed by way of a speed change, as is described in more detail by way of
This arrangement has the advantage that the pressure ΔPpre which is produced by the circulation pump assembly 6 does not have to be reduced, since the mixing of the two heating medium flows takes place at a greater pressure level, specifically at the level of the pressure ΔP1. Energy losses in the mixing device 44 are reduced by way of this.
The design construction of the mixing devices 22 and 44 are hereinafter described in more detail by way of the
The embodiment example according to
In this embodiment example, the impeller 68 is configured as a double impeller and unifies the impellers 26 and 28, as has been described by way of
The pump casing 78 is connected to the motor casing 58 in the usual manner. The delivery chamber 76 in the inside of the pump casing 78 runs out into delivery pipe connection 80, onto which the feed conduit 38 to the floor heating circuit 2 would connect in the embodiment examples according to
The first suction port 70 of the impeller 68, in the pump casing 78 is in connection with a first suction conduit 82 which begins at a first suction pipe connection 84. This first suction pipe connection 84 lies in a manner in which it is axially aligned to the delivery pipe connection 80 along an installation axis which extends normally to the rotation axis X. In the embodiment examples according to
A first flow connection through the pump casing 78 is defined from the suction pipe connection 84 which forms a first inlet, via the suction conduit 82, the suction port 70, the first impeller 26, the delivery chamber 76 and the delivery pipe connection 80. The pump casing 78 moreover comprises a second suction pipe connection 86 which forms a second inlet. In the inside of the pump casing 78, the second suction pipe connection is connected to an annular space 90 at the suction side of the impeller 68 via a connection channel 88. The annular space 90 surrounds a ring element 92 at the outer periphery. The ring element 92 is inserted into the suction chamber of the pump casing 78 and with its annular collar is in engagement with the collar which surrounds the suction port 70, so that a sealed flow connection is created from the suction channel 82 into the suction port 70. The ring element 92 is surrounded by the annular space 90 at the outer periphery, so that the ring element 92 separates the flow path to the suction port 70 from the flow path to the second suction port 74. An annular sealing element 94 which bears on the inner periphery of the pump casing 78 and comes into sealing bearing contact with the outer periphery of the impeller 68 is inserted into the pump casing. Here, the sealing element 94 is in sealing bearing contact with the impeller 68 in the outer peripheral region of the second suction port 74, so that in the pump casing it separates the suction region from the delivery chamber 76 at the inlet side of the suction port 74.
A check valve 96 which prevents a backflow of fluid into the feed conduit 18 is moreover arranged in the flow path from the second suction pipe connection 86 to the connection channel 88. The feed conduit 18, as is shown in
A temperature adjustment of the heating medium which is fed to the floor heating circuit 2 can be achieved with the shown circulation pump assembly 24 with the integrated mixing device 22 by way of a speed change of the drive motor 30, as was described by way of
A presetting can be carried out via the flow regulation valves Rcold and Rhot, as described by way of
In the second embodiment example, an impeller 100 is connected to the rotor shaft 66. This impeller 100 comprises a central suction port 102 whose peripheral edge is sealingly engaged with the ring element 92, so that a flow connection is created from the first suction pipe connection 84 into the impeller 100. The impeller 100 comprises only one blade ring which defines a first flow path departing from the suction port 102 which forms a first inlet opening, to the outer periphery of the impeller 100. This first flow path runs out into the delivery chamber 76 which is connected to the delivery pipe connection 80. An annular space 90, into which the connection channel 88 runs out from the second suction pipe connection 86 is again present surrounding the ring element 92. The impeller 100 comprises a front shroud 104. Openings 106 which form second inlet openings are formed in this shroud. These openings 106 run out into the flow channels 108 between the impeller blades. Here, the openings 106, seen radially with respect to the rotation axis X, run out into the flow channels 108 in a region between the suction port 102 and the outer periphery of the impeller 100. I.e. the openings 106 run out into a radial middle region of the first flow path through the impeller 100. The openings 106 and the flow channels 108 with their sections radially outside the openings 106 form second flow paths which correspond to the impeller part 50 as has been described by way of
The impeller 100 on its outer periphery, i.e. on the outer periphery of the shroud 104 comprises an axially directed collar 110 which bears on the inner periphery of the pump casing 78′ and therefore seals the annular space with respect to the delivery chamber 76. A temperature regulation of the heating medium flow which is fed to the floor heating circuit 2 can be carried out as is described by way of
Concerning the three solutions according to the invention which are described by way of example, a regulation of the temperature has been described by way of adjusting the mixing ratio solely by way of speed change. However, it is to be understood that such a feed temperature regulation could also be realized in combination with an additional valve Rhot in the feed conduit 18 and/or a valve Rcold in the return conduit 16. Here, the valves Rhot and Rcold can possibly be coupled to one another or be commonly formed as a three-way valve. An electrical drive of these valves could be activated by a common control device 34 which also controls or regulates the speed of the drive motor 30. The mixing ratio and thereby the temperature in the feed conduit for the floor heating can therefore be regulated or controlled by way of the control of the valves together with the control of the speed of the drive motor 30. On the one hand a greater range of regulation can be achieved by way of this, and on the other hand losses can be reduced by way of larger valve opening degrees. Hence for example the speed only needs to be briefly increased, in order to admix an increased quantity of heated heat transfer medium.
The invention was described by way of the example of a heating facility. However, it is to be understood that the invention can also be applied in a corresponding manner in other applications, in which two fluid flows are to be mixed. One possible application for example is a system for adjusting the service water temperature as is common in booster pumps for service water supply, in so-called shower booster pumps.
While specific embodiments of the invention have been shown and described in detail to illustrate the application of the principles of the invention, it will be understood that the invention may be embodied otherwise without departing from such principles.
Number | Date | Country | Kind |
---|---|---|---|
17184776 | Aug 2017 | EP | regional |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2018/070968 | 8/2/2018 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2019/025525 | 2/7/2019 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4678409 | Kurokawa | Jul 1987 | A |
5246336 | Furukawa | Sep 1993 | A |
5713729 | Hong | Feb 1998 | A |
6257177 | Lehmann | Jul 2001 | B1 |
20130183137 | Murray | Jul 2013 | A1 |
20170356449 | Blad | Dec 2017 | A1 |
Number | Date | Country |
---|---|---|
11 19 485 | Dec 1961 | DE |
1119485 | Dec 1961 | DE |
21 07 000 | Aug 1972 | DE |
690 04 616 | May 1994 | DE |
10 2004 059567 | Jun 2006 | DE |
102004059567 | Jun 2006 | DE |
2 871 420 | May 2015 | EP |
Number | Date | Country | |
---|---|---|---|
20200340684 A1 | Oct 2020 | US |