Technical Field

The invention relates to methods of metering and supplying liquid to a usage station, such as ink to a printing press, by means of a positive displacement pump, and to systems for carrying out these methods and for supplying liquid on a priority basis to a plurality of usage stations. Background Art The conventional method of metering liquid consumption is to place a so-called paddle wheel or other movable device in the liquid flow. The accuracy of such standard flow-meters is, however, dependent on a number of factors including temperature, pressure, the specific gravity and viscosity of the liquid, and the presence of any air in the liquid. Such flow-meters may also vary in their characteristics as a function of time, hence requiring periodic calibration.

This problem is especially noticeable when pumping ink to a printing press, because the ink is typically closer in viscosity to toothpaste than to water, is thixotropic (i.e. the viscosity varies with conditions), and is pumped in frequent stop and start cycles.

In an endeavour to overcome the difficulties involved in accurately monitoring the supply of such a relatively viscous liquid, a flow-meter has been designed that employs a meshed oval gear structure to replace the paddle wheel. However, this meter has suffered from essentially the same problems as the paddle wheel meters. Moreover, it has been particularly prone to jamming and has experienced premature wear due to the presence of foreign particles in the ink.

Typically, commercial operations maintain a supply of liquid, e.g. ink, in a reservoir and feed a supply of such liquid to one or more usage stations (each station could, for example, be a printing press) by means of a

conventional, positive displacement pump that makes the liquid available under pressure at each station. Such a pump will normally be powered by air, usually received at about 400 kPa or higher, the air being exhausted to atmosphere after each stroke. In the liquid line the pump takes in liquid from the reservoir under gravity feed, i.e. at approximately atmospheric pressure, and delivers a predetermined volume of the liquid with every stroke at a relatively high pressure, e.g. 10,000 kPa. Each pump is set to maintain a constant liquid pressure in its supply line for a given air pressure setting. When a usage station takes an amount of the liquid the line pressure drops. The pump is sensitive to this pressure drop and it automatically starts up to re- establish the desired supply line pressure.

Disclosure of the Invention

The invention consists of a method of metering the volume of a liquid, such as ink, discharged by a positive displacement pump, comprising monitoring each stroke of the pump to select those strokes that are productive and counting such selected strokes.

In its preferred form, the invention replaces mechanical metering in the liquid supply line by a system in which the number of strokes of the pump are counted. Since the pump delivers a set volume of liquid per stroke, such count should identify the total volume of liquid. There is, however, the problem that, if there is air present in the liquid chamber of the pump due to an inadequate supply of liquid to the pump by reason of the inlet valve being closed or the reservoir being empty, the pump cannot deliver liquid to the supply line and will therefore perform a non-productive stroke that does not deliver the volume of liquid that is equivalent to a productive pump stroke when the pump is functioning normally. In these circumstances a stroke count alone would provide erroneous information.

However, when this type of pump experiences an inadequate liquid supply, it tends to race, i.e. the stroke speed increases because of the less effective work that it is accomplishing. A further feature of the present invention is thus to monitor this speed and signal a data control system (computer) accordingly.

In an apparatus aspect, one preferred form of the invention provides a metering system for use in an installation having a reservoir of a liquid and a positive displacement pump for transferring the liquid from the reservoir to a supply line for travel to a usage station, the system comprising a first sensor for generating a first series of signals each indicative of completion of a pumping stroke, a second sensor for sensing the speed of the pump to generate a second series of signals each indicative of the positive supply of liquid to the line by the pump, and a computer for counting the signals of the first series only in the presence of a corresponding signal of the second series. In this way the system can provide an accurate numerical indication of the supplied volume.

The pump can be powered by pressure air and the sensor for generating the first series of signals can be an audio-sensor located in the vicinity of the air exhaust from the pump. This arrangement facilitates the universal applicability of the sensor to different makes of pump. All air powered pumps have in common the feature that at the end of each power stroke the air is exhausted with a distinctive burst of sound that the system can distinguish from ambient sounds.

Alternatively, the invention can provide for sensing completion of a pump stroke, e.g. sensing a pressure surge in the supply line, and also for sensing whether such pump stroke was productive in providing a positive supply of liquid to the supply line, e.g. by sensing attainment by such surge of a predetermined threshold level. The computer will then count only the productive strokes to

provide the numerical indication of the supplied volume. In yet another aspect, the invention consists of a liquid supply system comprising a plurality of liquid reservoirs; a plurality of positive displacement pumps each for transferring a liquid, such as ink, from one of the reservoirs to one of a plurality of usage stations, such as printing presses; and sensing and computing means associated with each pump for metering the volume of liquid discharged by the pump; the computing means dedicating the pumps to supply liquids to a selected one of the usage stations for a reserved time period provided that there is a demand during this period for one or more of such liquids at the selected usage station, and subsequently dedicating the pumps to supply liquids to a second selected one of the usage stations for a further reserved time period provided that there is a demand during this further period for one or more of such liquids at the second selected usage station, and so on sequentially for each usage station individually.

Brief Description of Drawings

Preferred embodiments of the invention are illustrated diagrammatically and by way of example in the accompanying drawings, in which

Figure 1 is a block diagram of a first embodiment; and

Figure 2 is a block diagram of a second embodiment.

Best Mode for Carrying Out the Invention

Figure 1 illustrates an air powered, positive displacement pump 10 having a liquid intake 11 supplied by gravity feed from a reservoir 12, and a high pressure, liquid supply line 13 feeding to a usage station 14, such as a printing press. The pump 10 is driven by air under pressure, supplied from a source (not shown) through an air input 15, the used air being exhausted through an exhaust port 16, a pipe 17 and a muffler 18.

A sensor 19 in the form of a microphone is mounted in the pipe 17 to detect the sound of the exhaust air without significantly obstructing its flow. The sensor's output is passed through an amplifier 20 to a filter 21. The amplifier 20 not only amplifies the signal from the microphone but also converts it from a bipolar signal, e.g. +15 to -15 volts, to a unipolar signal, e.g. 0 to 15 volts. The filter 21 is designed to pass only those signals that properly correspond to the burst of sound generated by the exhaust air, such sound representing the trailing edge of a pump stroke. A threshold detector 22 measures the time duration of the signal from the filter 21 to ensure that the sound picked up by the microphone is long enough to correspond to that of the air exhaust. Thus the filter 21 and threshold detector 22 together recognize the particular sound characteristics or "signature" of the air exhaust. In this way interference by ambient sounds is substantially eliminated. The signals passing through the amplifier 20 and filter 21 and into the threshold detector 22 are analog, while the output from the threshold detector 22 is a digital pulse which powers a red LED 23 so that this LED is lit by each pulse and is not lit between pulses. The same digital pulse also sets a latch 28 to turn on a green LED 29. While this method of detection of the pump stroke based on the sound of the air exhaust is the preferred method of detection, the invention includes other methods, such as one that detects air pressure fluctuations in the pipe 17 or liquid pressure fluctuations in the supply line 13, or detection that involves a mechanical connection to the pump, the important consideration being avoidance of any interference in the liquid supply line 13.

The next requirement of the circuit is to distinguish "productive" pump strokes from "non-productive" pump strokes. A productive pump stroke is one in which the pump forces a full charge of liquid into the supply line 13, whereas a non-productive pump stroke is one that

occurs whenever the pump has an inadequate supply of liquid and is trying to pump air. In this latter circumstance the pump will tend to race. A productive pump stroke will last from 0.5 to 1.5 seconds, depending on the pump, whereas the duration of a racing stroke will be 4 or 5 times shorter. "Racing" describes a series of pump strokes in which less than a desired amount of liquid is transmitted with each stroke, i.e. an operational abnormality of the pump. For detecting this racing condition, there is a counter 24 that receives clock pulses from a clock 25. The digital pulse from the detector 22 resets the counter to start it. The output of the counter 24 is fed to a comparator 26, where it is compared to a preset number supplied from a time set device 27. When the numbers received in the comparator 26 from both the counter 24 and the time set 27 become equal, the comparator emits an output pulse to the latch 28 which serves both to shut off the green LED 29 that was illuminated by the digital pulse from the detector 22 and to again reset the counter 24 to await a fresh signal from the detector 22. The green flashes thus represent a second series of signals, these being indicative of the positive supply of liquid by the pump at each stroke.

Since the green LED 29 is only turned off by a pulse generated at the comparator 26, i.e. a pulse that identifies a "liquid" or productive pump stroke, the flashing at the red LED 23 is a visual signal of all pump strokes while each "shutting off" of the green LED 29 is a visual signal of a productive pump stroke. In other words, a flash of the red LED 23 occurs every time the sensor 19 detects completion of a pump stroke and a flash off of the green LED 29 occurs whenever each red flash is sufficiently spaced from the previous red flash, but not if two red flashes are too close together. This procedure distinguishes productive pump strokes from non-productive ones.

A computer 30 counts the number of pulses from the

threshold detector 22, i.e. the total number of pump strokes whether productive or not. It also receives the pulse sent to the latch 28 from the comparator 26, which pulse signals the existence of a productive pump stroke. The computer 30 thus distinguishes the existence of a racing pump from one that is operating normally and effectively counts and displays the productive strokes by counting all the strokes and discounting the unproductive ones. As an alternative, the racing of the pump can be detected mechanically or in any other way, the information that the pump is racing being fed to the computer 30.

Instead of the sound sensor 19 each pump stroke can be noted by a microswitch that senses every stroke or by a capacitive proximity sensor that detects the same.

As a further alternative, the pulse generated by the sensor 19 can be produced by a pressure transducer in the liquid line 13, which, in turn, causes a digital pulse to be generated at the threshold detector 22, either with every pump stroke or only with pump strokes whose pressure surge is sufficiently large to represent a productive pump stroke. In this embodiment of the invention, the actual line pressure and the pressure differential caused by each productive pump stroke is known, so that a consumption count can be computed from a preset program of pressure differentials versus volumes of liquids for the pump at various pressure levels. This use of the first and second series of pulses as in the embodiment described above pro¬ vides a way of accounting for the different quantity of liquids transmitted by productive pump strokes where greater accuracy is required and/or where the intrusion of a sensor into the liquid flow is not detrimental. With this alternative the threshold detector 22 can be set to generate a digital pulse only when the liquid pressure surge is sufficiently large to represent a productive stroke, the second series of pulses from the comparator 26 still identifying when a given pump is racing continuously.

Industrial Applicability

The computer 30 can also receive a signal from the usage station 14 indicative of the productive use of the liquid. For example, when the usage station is a printing press, this indication will be the number of impressions printed. The computer can then calculate the rate of consumption of ink per 1000 impressions. This is a statistic that is often important for quality control. It can be displayed to the operator on a continuous basis for optimizing the efficiency of the system.

The invention is applicable to other industries. For example, in an automated piece dip painting operation, data on the number of articles dunked is fed to the computer to be compared with the volume of paint being supplied per unit time by the pump to the dipping equipment.

In practice, whether the usage station is a printing press or any other industrial operation, there will often be a plurality of such stations each supplied by its own pump(s) . The computer can keep track of the consumption of liquid at each station and make any necessary comparisons.

Frequently, a given usage station may receive more than one liquid, such as shown in reservoirs 12a, 12b, 12c and 12x in Figure 2. For example, a printing press often requires four different types of ink (different colours, heatset or non-heatset) . ^• Many user stations can be supplied with several liquids from a single bank of pumps 10a, 10b, 10c and 10x, and a priority system can be set up by the computer 30, which sequentially and ^r concurrently makes available all these liquids from each bank of pumps to each usage station 14a, 14b, 14c and 14x. Each pump lOa-lOx has an associated metering means 33a-33x. The elements 19-29 are shown collectively as metering means 33 in Figure 2. Each metering means sends the digital pulses from detector 22 and the latch 28 on lines 34a-34x to the computer 30.

In this expanded embodiment of the invention, the priority system of the computer 30 assigns a "settle time" which is a period of time (5 to 20 seconds, usually) required to return the pressure in the liquid line 13a, 5 13b, 13c or 13x to its preset maximum level so that the consumption recorded at a given station starts and finishes at a constant pressure condition. Each usage station 14a, 14b, 14c and 14x is assigned a "fill time" (typically one minute) according to its normal needs.

10 Also, each usage station 14a, 14b, 14σ and 14x is assigned a common "skip time" (typically 30 seconds) so that, if there is no demand at a given usage station that is supplied automatically within the first 30 seconds (skip time) of its "fill time", the priority system skips to the

15 next usage station which is also supplied automatically. This method of dedicating many pumps to only one automatically supplied usage station at, and for, a reserved time period is accomplished by the priority system which commands that all other automatically

20 supplied usage stations are rendered incapable of receiving any liquids during this reserved time period. Typically, an automatic supply control device at a usage station senses the liquid present by the use of a weight scale, a capacitance proximity sensor, an ultrasonic

25 sensor, a microswitch or the like, and, when the liquid supply is found to be inadequate, it sends through the computer 30 an electrical command on a line 35a-35c to operate an electrical relay 32a-32c which operates a motor/valve assembly 31a-31c in a liquid supply line 13a

30 to 13c as the case may be. In applications where one or more usage stations, such as station 14x, are supplied manually, such stations are placed on "standby" by the sequencing software of computer 30, in which condition each may request a supply of any or all of liquids 12a,

35 12b, 12c and 12x by a simple push button switch 32x. When the switch 32x is activated at a usage station, this alerts the computer 30 on line 35x to request supply of

one or more of the liquids which, in turn, places that usage station next in line to receive its supply to the exclusion of all other usage stations for a preset "fill time". Lines 36a-36x keep the computer 30 informed of the production at the respective usage stations, i.e. consumption of the various liquids.

This method of sequentially supplying multiple usage stations, be they automatic or manual usage stations, or both, is valuable in practice for effective liquid monitoring.