The present invention relates to systems for transporting high solid sludge (which includes slurries and mixtures of organic or inorganic solids, liquids, and gases such as air). In particular, the present invention relates to sludge flow measuring systems used in conjunction with a positive displacement pump to measure and monitor flow of sludge by determining a fill percentage during each pumping stroke.
Sludge flow monitoring systems were introduced in the early 1990's, and have been the subject of a number of patents, including U.S. Pat. No. 5,106,272 (reissued as Reissue 35,473), entitled “Sludge Flow Measuring System”; U.S. Pat. No. 5,257,912, entitled “Sludge Flow Measuring System”; U.S. Pat. No. 5,336,055, entitled “Closed Loop Sludge Flow Control System”; U.S. Pat. No. 5,330,327, entitled “Transfer Tube Material Flow Management”; and U.S. Pat. No. 5,346,368, entitled “Sludge Flow Measuring System”.
Sludge flow measuring systems have defined a standard for measurement of the volume of material delivered by a sludge pump through a pipeline. Some applications, however, require even greater accuracy than has been available in the past from sludge flow monitoring systems. High accuracy would be of great importance to the user in those cases where compensation is based upon the actual volume of material that has been pumped.
A sludge flow monitoring system and method makes use of hydraulic system sensors to define the beginning and end of each pump cycle, while using a signal from a poppet valve sensor to identify when pumping of material from a cylinder begins. The use of hydraulic system sensors, rather than solely the state of the poppet valves, provides greater accuracy to the beginning and end of each pump cycle.
The sludge flow measurement is achieved by use summations of periodic piston speed command values. Fill efficiency (or percentage) is determined based upon a first summation of periodic piston command speed values from the start of a pumping stroke to the end of the pumping stroke, and a second summation of periodic piston speed command values from the opening of the outlet poppet valve signifying flow of material from the cylinder to the end of the pumping stroke.
Inlet poppet valves 26 and 28 are controlled by hydraulic inlet valve cylinders 34 and 36, respectively. Outlet poppet valves 30 and 32 are controlled by hydraulic outlet valve cylinders 38 and 40.
In the particular position shown in
Material pistons 22 and 24 are coupled to hydraulic drive pistons 44 and 46, respectively, which move in hydraulic cylinders 48 and 50. Hydraulic fluid is pumped from hydraulic pump 52 through high pressure lines 54 to control valve assembly 56. Assembly 56 includes throttle and check valves which control the sequencing of high and low pressure hydraulic fluid to hydraulic cylinders 48 and 50 and to poppet valve cylinders 34, 36, 38 and 40. Low pressure hydraulic fluid returns to hydraulic reservoir 58 through low pressure line 60 from valve assembly 56. As shown in
Forward and rear switching valves 62 and 64 sense the presence of piston 46 at the forward and rear ends of travel and are interconnected to control valve assembly 56. Each time piston 46 reaches the forward or rear end of its travel in cylinder 50, a valve sequence is initiated which results in cycling of all four poppet valves 26, 28, 30, 32 and a reversal of the high pressure and low pressure connections to cylinders 48 and 50.
The sequence of operations of pump 10 is generally as follows: As the drive pistons 44 and 46 and their connected material pistons 22 and 24 come to the end of their stroke, one of the material cylinders (in
At this point, pistons 22 and 24 are at the ends of their stroke, and their direction movement is about to reverse. All four poppet valves 26, 28, 30 and 32 are closed. Hydraulic pressure begins to increase in cylinder 48, which drives piston 44 forward. In turn, piston 22 moves forward toward poppet valve housing 42. Piston 22, therefore, is now in a pumping or discharging stroke. At the same time, hydraulic fluid located forward of piston 44 is being transferred from cylinder 48 through interconnection 66 to the forward end of cylinder 50. This applies hydraulic pressure to piston 46 to move it in a rearward direction. As a result, material piston 24 begins moving away from poppet valve housing 42 and it is in a loading or filling stroke. When the pressure in valve housing 42 below poppet valve 28 essentially equals the pressure on the inlet side, poppet valve 28 opens, which allows sludge to flow through inlet 14 and into cylinder 20 during the filling stroke.
As piston 22 begins to move forward, it first compresses the sludge within cylinder 22. At the moment when the compressed sludge equals the pressure of the compressed sludge in the delivery line and at outlet 16, poppet valve 30 opens. Since the poppet valve for the discharging cylinder opens only when the cylinder content pressure essentially equals the pressure in the pipeline, no material can flow back.
The operation continues, with piston 22 moving forward and piston 24 moving rearward until the pistons reach the end of their respective strokes. At that point, switching valve 64 causes valve assembly 56 to close all four poppet valves and reverse the connection of the high and low pressure fluid to cylinders 48 and 50.
The operation continues with one material piston 22, 24 operating in a filling stroke while the other is operating in a pumping or discharge stroke.
This method takes some of the delay from the poppet shifting (of poppet valves 30 and 32) out of the fill efficiency calculation that was previously included, and represented an error in the calculation. Times t0, tp, and to will be discussed further, and are shown in conjunction with
Sludge is supplied to hopper 120, in which a pivoting transfer tube 122 is positioned. Transfer tube 122 connects outlet 124 with one of the two material cylinders (in
At the end of a stroke, hydraulic actuators 126 which are connected to pivot arm 128 cause transfer tube 122 to swing so that outlet 124 is now connected to cylinder 104. The direction of movement of pistons 106 and 108 reverses, with piston 108 moving forward in a discharge stroke while piston 106 moves backward in a filling or loading stroke.
Hydraulic fluid to operate the cylinders and the controls of pump 100 is supplied by a hydraulic pump and reservoir assembly (not shown in
A primary difference between pump 100 shown in
Like the system of
Clock 154 provides a time base for computer 152. Although shown separately in
Output device 156 takes the form, for example, of a liquid crystal display, a printer, or communication devices which transmit the output of computer 152 to another computer based system (which may, for example, be monitoring the overall operation of the entire facility where sludge pump 10 is being used).
Sensors 158 and 162 monitor the operation of pump 10 and provide signals to computer 152. Signals PP1 and PP2 (or PP0) from sensors 158, signals S2, S3 from sensors 162, together with periodic piston speed command signals S(tk) (shown in
In one preferred embodiment of the present invention, the determination of volume pumped during a pumping cycle is achieved by accurately calculating fill percentage of sludge pump cylinder using hydraulic control valve switching, poppet valve switching, and the time-history of analog piston speed command signals during each pumping stroke.
Pump 10 (or 100) has an outlet valve 30, 32 (or 130) between the cylinders and the outlet which opens only when pressure within the cylinder overcomes pressure at the outlet. The opening of the outlet valve is sensed by the computer via poppet valve sensors PP1, PP2 (or PP0), and a quantity that is proportional to the distance traveled by the piston from its position when the outlet valve is opened to its position at the end of the stroke is determined by periodically recording the piston speed analog command signal at small fixed time intervals and summing the recorded command signal values. The value of this summation is compared to the value of a similarly obtained piston analog speed command summation recorded during the entire stroke. The ratio of these summations gives an accurate calculation of the filling efficiency of the stroke. This calculation is obtained without the use of a piston position sensor, hydraulic flow sensor, piston speed sensor, or the recording and use of the time of any sensed event. A significant advantage to this calculation method over other methods of determining filling efficiency is that the estimation is valid regardless of whether the piston speed changes mid-stroke provided that the speed command sample period is short enough to provide adequate resolution between measurements.
A hydraulic control valve proximity switch (PS2) provides indication to the computer of the start of a pumping stroke at time t0. Another hydraulic control valve proximity switch (PS3) indicates to the computer the end of the pumping stroke at time te. Poppet valve switches (PP1, PP2 or PP0) indicate the opening of the poppet outlet valves at time tp. At the beginning of the stroke, the computer begins periodically totalizing the piston speed command signals S(tk) it sends to the hydraulic swashplates, beginning with S(t0), adding to the summation the commanded speed value at each consecutive periodic time value tk. This summation (E1) finishes totalizing at the end of the stroke at time te. The computer begins totalizing a second periodic summation of speed commands (E2) when it senses the poppet outlet valve has opened at time tp, starting with S(tp), adding to this summation the commanded speed value at each consecutive periodic time value tk. This summation also finishes totalizing at the end of the stroke at time te. Assuming that the speed command signal is proportional to the actual speed of the piston, E1 is proportional to the entire stroke distance, and E2 is proportional to the distance traveled by the piston when the cylinder contents were fully compacted into the cylinder. This calculation method does not calculate or measure piston speed. Rather, it calculates a quantity that is proportional to piston speed. Similarly, piston position and distance are never calculated or measured, nor is any time value of any sensed event involved in the calculation. The time values mentioned above and in the diagram below (t0, tk, tp, te) are only illustrative of the process sequence and are not included in the efficiency calculation below.
The accuracy of this method is improved over time-based filling efficiency calculation methods which use poppet valve cylinder closing event as the start of the timed stroke event (t0). This is because this method uses the sensing of hydraulic control valve actuation, which correlates directly with piston presence at its end-of-travel, as indication of the start of a piston stroke. Time based systems using the poppet closing event to start the timer include poppet valve changeover time as part of the calculation, adding time to the clock that is not actually time spent stroking the pumping cylinder. This can artificially skew the time-based efficiency calculation.
An alternative embodiment also calculates fill efficiency by recording speed command signals periodically from the start of the stroke to the end of the stroke and also periodically recording speed command signals from the opening of the poppet valve to the end of the stroke. For each of the two sets of recordings, an average speed command recording value is calculated. A1 is the average of the speed command values taken during the entire stroke, and A2 is the average of the speed command values taken after the poppet valve opened. A quantity that is proportional to the pump piston distance traveled from the piston position when the poppet valve opened to the piston position at the end of stroke, and a quantity that is proportional to the pump piston distance traveled from the beginning of the stroke to the end of the stroke can be determined by multiplying each average speed command quantity (A1 and A2) by the time duration over which the associated recordings were taken (ta and tb). The ratio of these quantities is equal to the filling efficiency of the piston stroke.
The time durations can be found in several ways. An independent timer can be used to time the duration of the whole stroke, starting timing at the stroke beginning event and ending timing at the stroke end event (this duration is ta). Similarly, an independent timer can be used to measure the duration of the stroke portion that occurred from the poppet valve opening event to the end of stroke event (this duration is tb). Alternately, ta and tb can be calculated by multiplying the time period between consecutive speed command recordings by the number of speed command recordings taken during the duration of each associated piston travel event.
Where:
A1=Average Value of Speed Commands Taken During Entire Stroke
A2=Average Value of Speed Commands Taken During Filled Cylinder Portion of Stroke
D1=Whole Stroke Distance
D2=Filled Cylinder Distance
ta=Time Duration of Entire Stroke
tb=Time Duration of Filled Cylinder Portion of Stroke After Poppet Sensor has Opened
λ=Proportionality Constant
One benefit of the present invention is that it does not require an assumption that pump speed be constant from pump stroke to pump stroke, or even during a single pump stroke. Horsepower limitations can, in some cases, require that pump speed be varied during a single pump stroke. This has, in the past, been a source of inaccuracy in sludge flow measurement.
Another source of inaccuracy in the past was the use of poppet valves to define the beginning and end of a piston stroke, as well as defining when material began to flow out of the cylinder. Typically, the end of one pump stroke and the beginning of the next pump stroke was considered to be the same event because signals derived from the poppet valve could not distinguish between when the end of one piston stroke ended and the next piston stroke began. The time delay between those two events was not factored into the calculation, and therefore, the time duration of the piston stroke from beginning to end was actually shorter than the time derived from opening and closing of poppet valves.
Other embodiments make use of sensing to and te with hydraulic sensors (PS2, PS3) and start of material flow with poppet valve sensors (PP1, PP2, or PP0), but use a parameter other than periodic piston speed commands. Examples of other embodiments include:
In these alternative embodiments, accuracy is improved as the time the poppets take to shift is eliminated from the calculation. This time was included in the original invention and constituted a varying amount of error based on the pumping speed.
Additionally, three poppets change position at te, but the discharge poppet will be held closed until time tp, at which time this poppet takes oil from the pumping speed. This oil is a fixed volume so a constant can be introduced into these calculations to further eliminate this error from the calculation. This would not apply to alternatives (2), (3), and (5).
While the invention has been described with reference to an exemplary embodiment(s), it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment(s) disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.
Number | Name | Date | Kind |
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5106272 | Oakley | Apr 1992 | A |
5257912 | Oakley | Nov 1993 | A |
5330327 | Anderson | Jul 1994 | A |
5332366 | Anderson | Jul 1994 | A |
5336055 | Anderson | Aug 1994 | A |
5346368 | Oakley et al. | Sep 1994 | A |
RE35473 | Oakley et al. | Mar 1997 | E |
5839883 | Schmidt | Nov 1998 | A |
6929454 | Munzenmaier | Aug 2005 | B2 |
7611331 | Hoefling | Nov 2009 | B2 |
7611332 | Hofmann | Nov 2009 | B2 |
8899819 | Alden | Dec 2014 | B2 |
Number | Date | Country | |
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20160069343 A1 | Mar 2016 | US |