The invention relates to a metering system for metering a liquid.
Toxic exhaust gases and nitrogen oxides (NOx) occur in the context of the combustion process in diesel engines. To eliminate or break down these nitrogen oxides, it is known to inject a urea solution, by means of a metering pump, into the previously purified exhaust gas stream. The ammonia that is thereby released converts up to 80% of the nitrogen oxides into harmless nitrogen and water in a downstream SCR catalytic converter.
Because a urea solution is a chemically aggressive and very low-viscosity medium that has a tendency to crystallize, special pumps, in which the urea solution does not come into contact with the drive equipment of the metering pump, are used to deliver it. The delivery space is separated from the equipment space by, for example, a membrane or another flexible part.
The pump runs constantly during vehicle operation, establishing a pressure of, for example, 5 bar. Urea is present in the lines and systems. If the ambient temperature drops below the freezing point after the vehicle is shut off, the system would completely freeze up. Since not all components can withstand freezing, the urea solution must be pumped back into a reservoir container after the vehicle is shut off. In known systems, this occurs by means of a 4/2-way valve that reverses the delivery direction.
It is an object of the invention to make a novel metering system available.
According to the invention, this object is achieved by using a reversible variable-speed electric motor to drive the eccentric pump rotor, the rotor including an elastomeric ring, a portion of which forms a seal against the opposite wall of the pump chamber. It is thereby possible to make available a metering system that has a very compact construction and that, in the one rotation direction of the electric motor, draws the liquid to be metered out of the reservoir container and transports it to the consumption point, and, in the other rotation direction, draws that liquid out of the lines of the system and transports it back to the reservoir container.
The problems that have arisen in practice when a 4/2-way valve is used are thereby avoided, i.e. after the internal combustion engine is shut off, the rotation direction of the electric motor is reversed for a predetermined time period. Because said motor has no contact with the urea solution, reversal of the flow direction using the motor is robust, since such motors have a very long service life. The result is to prevent the urea solution from freezing in cold weather, since with such a motor it is very easy to pump the pump, lines, injection valves, etc. largely to an empty state when no urea solution is being injected, i.e. for example after the engine is shut off.
Further details and advantageous refinements of the invention are evident from the exemplifying embodiment, in no way to be understood as a limitation of the invention, that is described below and depicted in the drawings.
To drive it, the metering system has a multi-phase collectorless external-rotor motor 32 whose rotation speed behavior can be controlled by means of a PWM control signal, as is known e.g. from EP 1 413 045 B1 and corresponding U.S. Pat. No. 7,068,191, KUNER & SCHONDELMAIER. This makes it possible to control the rotation speed and rotation direction of the motor, in accordance with the rotation speed and power demand of the vehicle on which metering system 30 is located. The elements for this are defined by the manufacturer of the engine controller, depending on the requirements of the particular vehicle, and can differ greatly, depending on the type of vehicle (passenger car, truck, aircraft, helicopter, ship, etc.). An advantage of the present invention is that metering system 30 is suitable for very different applications.
Motor 32 has an electronic drive system, e.g. a three-phase inverter. This electronic system is in turn controlled by an arrangement that serves to decode the pulse duty factor pwm of a PWM signal that is delivered via a lead, and thereby to control the motor in terms of its rotation direction and rotation speed. If the pulse duty factor is referred to as “pwm,” the following correspondences then result (as a non-binding example):
An example of a corresponding decoding circuit is described in detail in EP 1 413 045 B1 and U.S. Pat. No. 7,068,191, to whose content reference is made, in order to avoid excessive length. All known circuits can of course be used to modify the rotation speed of an electric motor.
System 30 here has a base 40 on which is arranged, on the right, a first support 42 which carries a bearing element 44 that is depicted here as a ball bearing.
Arranged at a distance from support 42 is a second support 46 that, according to
As
Mounted on eccentric bushing 52 is inner ring 54 of an eccentric bearing 56 whose outer ring 58 is mounted on the inner side of a ring 60 that serves as a support for a pump ring 62.
Pump ring 62 is manufactured from a suitable synthetic rubber (elastomer) and is mounted by plastic injection molding in an annular groove 64 of ring 60 so that it follows the motions of ring 60. The latter can be manufactured e.g. from steel, nickel, or bronze.
In experiments, a synthetic rubber referred to by the abbreviation PEDM (polyester-ethylene-diene monomer) has proved advantageous as an elastomer.
As shown, for example, in
As
A support tube 90 through which shaft 50 extends (see
Motor 32 also has a circuit board 102 on which electronic components of motor 32 are located. Circuit board 102 is connected via a cable 104 to a plug connector 106. Motor 32 is supplied via cable 104 with energy, usually with DC voltage from a battery, and a control lead through which the rotation speed and rotation direction of motor 32 are controlled is also located in cable 104.
A great advantage of a collectorless motor, in particular in a vehicle, is the high efficiency that can be achieved with such an arrangement.
Motor 32 drives eccentric bushing 52 via shaft 50, and said bushing imparts an eccentric motion to eccentric bearing 54, so that said eccentric motion is likewise imparted to ring 60.
A pump chamber 120 is located between the radial outer side of pump ring 62 and the radial inner side 80 of holding portion 78 (see
Because pump ring 62 is in continuous rolling contact with its outer side 80 on the inner side of holding part 78, pump chamber 120 is constantly changing shape and thereby transports the metered fluid, that is present in pump chamber 120, from an inlet to an outlet.
To prevent this liquid from simply circulating in pump chamber 120, two connectors 122, 124, that are connected to the portions there of pump chamber 120, are provided at a suitable site (see
When shaft 50 is rotating clockwise, as shown by arrow 128 of
When shaft 50 is rotating oppositely to the direction of arrow 128, i.e. counterclockwise, the processes occur in the reverse direction, i.e. in this case, liquid is pushed out of connector 124 and liquid is drawn in through connector 122. The same pump 53 can thus be used to meter liquid and also to pump liquid out.
a) It spreads or distends pump ring 62 in a radial direction so that it constantly abuts sealingly with its spread outer portion 142 against inner side 80 of stationary ring 70, thus preventing pumped fluid from flowing directly back to the suction side.
b) It “pegs” or prevents pump ring 62 from rotating relative to stationary ring 70, so that pump chamber 120 (between stationary ring 70 and pump ring 62) is sealed and no fluid can escape from it.
As shown, for example, by
Pressure plates 151, 152 are pressed toward one another by bolts 150, one of which is depicted in
For illustration, a position pointer 170 is shown in each Figure, indicating the position of the maximum of eccentric bushing 52 in the context of a clockwise rotation, as follows:
Eccentric bearing 56 thus causes pump ring 62 to be compressed, continuously in a circumferential direction and successively at the locations (for example) 12:00 (
In the context of a counterclockwise rotation, connector 122 becomes the suction connector and connector 124 becomes the discharge connector; this is not depicted, since it corresponds simply to a mirror image of
Metering system 30 described above is very maintainable, since pump 53 can easily be replaced. Many variants and modifications are, of course, possible in the context of the present invention.
Number | Date | Country | Kind |
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10 2011 015 110 | Mar 2011 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2012/000147 | 1/14/2012 | WO | 00 | 8/9/2013 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2012/126544 | 9/27/2012 | WO | A |
Number | Name | Date | Kind |
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249285 | Allen | Nov 1881 | A |
2544628 | Copping | Mar 1951 | A |
3408947 | McMillan | Nov 1968 | A |
4332534 | Becker | Jun 1982 | A |
5988998 | Glover | Nov 1999 | A |
6019582 | Green | Feb 2000 | A |
7068191 | Kuner et al. | Jun 2006 | B2 |
8403656 | Fromm | Mar 2013 | B2 |
20070020123 | Meyer et al. | Jan 2007 | A1 |
20080063542 | Oguma | Mar 2008 | A1 |
20120027622 | Ashburn | Feb 2012 | A1 |
Number | Date | Country |
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102004-011123 | Mar 2005 | DE |
102007-000538 | May 2008 | DE |
202009016915 | Apr 2010 | DE |
2194270 | Jun 2013 | EP |
Entry |
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Wikipedia, “Peristaltic Pump,” pp. 1-7, retrieved Aug. 8, 2013. |
Wikipedia, “Watson-Marlow Pumps,” pp. 1-4, retrieved Aug. 14, 2013. |
Number | Date | Country | |
---|---|---|---|
20140017094 A1 | Jan 2014 | US |