IE960722A1 - Method and apparatus for securely adding an additive to¹fluid dispensed from a delivery means - Google Patents

Method and apparatus for securely adding an additive to¹fluid dispensed from a delivery means

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Publication number
IE960722A1
IE960722A1 IE960722A IE960722A IE960722A1 IE 960722 A1 IE960722 A1 IE 960722A1 IE 960722 A IE960722 A IE 960722A IE 960722 A IE960722 A IE 960722A IE 960722 A1 IE960722 A1 IE 960722A1
Authority
IE
Ireland
Prior art keywords
additive
fluid
delivery
base fluid
flow
Prior art date
Application number
IE960722A
Inventor
Brian Francis Mooney
Original Assignee
Cassiano Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Cassiano Ltd filed Critical Cassiano Ltd
Priority to IE960722A priority Critical patent/IE960722A1/en
Priority to DE69725623T priority patent/DE69725623D1/en
Priority to JP9529949A priority patent/JP2000505402A/en
Priority to CA002247095A priority patent/CA2247095A1/en
Priority to US09/125,492 priority patent/US6095371A/en
Priority to EP97905371A priority patent/EP1009713B1/en
Priority to CN97192499A priority patent/CN1211964A/en
Priority to BR9707732-1A priority patent/BR9707732A/en
Priority to AT97905371T priority patent/ATE252057T1/en
Priority to PCT/IE1997/000011 priority patent/WO1997030930A2/en
Priority to AU22275/97A priority patent/AU723888B2/en
Publication of IE960722A1 publication Critical patent/IE960722A1/en
Priority to US09/593,825 priority patent/US6478189B1/en

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Abstract

A delivery vehicle oil tank (1) delivers fluid with and without an additive securely added by an apparatus which is used in association with a flow meter (3), and a controller (13). The tank (1) includes a reservoir of additive and an injector pump (10) for including the additive with the fluid. The controller (13) securely counts or records the occurrence of an event associated with the filling, depletion, replacement or connection of the reservoir (7). The apparatus includes a blender (21) having a diffusion chamber (22) which causes fluid flow to occur at different rates or speeds and the apparatus is operable so that the slugging effect of additive injection is reduced. The injector pump (10) operates in a cycle which includes a delivery stroke which delivers additive in discrete amounts through an outlet (32) into a delivery pipe (6) at a plurality of positions along one or more paths of flow of the delivery pipe (6). <Fig. 1>.

Description

METHOD AND APPARATUS FOR SECURELY ADDING AN ADDITIVE TO FLUID DISPENSED FROM A DELIVERY MEANS The present invention relates to a method and apparatus for securely 5 adding an additive to fluid dispensed from a delivery means which is required to deliver fluid with and without an additive. The invention relates particularly, although not exclusively, to a delivery means which is a delivery vehicle and to a method for securely adding marker chemical to middle distillate oils.
Many countries impose different rates of taxation on particular grades of middle distillate oils. For example, diesel grade oil may be taxed at a relatively high rate when used for powering on-road vehicles, but be untaxed or taxed at a lower rate when used for heating purposes, or for powering off-road vehicles. Where such variations exist, it is necessary for the taxation authority to ensure that the untaxed or lower taxed oil cannot be used in circumstances where the higher tax rate should apply. Various methods have been used to meet this need. One method requires the users of higher taxed oil to keep records of distances travelled by means of a special meter and account for tax on this basis from time to time. Another more common method involves collecting the tax on the higher taxed oil at source and chemically marking the untaxed or lower taxed oil in order that any prohibited use can be readily detected.
Chemical marking usually takes place at the refinery or bulk storage depot. It typically comprises two main components, a coloured dye marking chemical which provides readily recognised marking on visual inspection and an invisible second marking chemical which is much more difficult to remove than the dye chemical.
The use of chemical marker, or marker, has several advantages over the metering method. Firstly, it is more easily controlled. Secondly, it eliminates the need for special meters. Thirdly, it eliminates the need to record and account for distances travelled. Fourthly, it taxes fuel consumption rather than distance travelled anri..lharftforo onmiiranas fnol open to rueuc jnspection UNDER SECTION 28 AND RULE 23 JNL No...../£/.?....... ivuAovuei - 2 efficiency.
However, it has the relative disadvantage that the same delivery vehicle will not normally be able to deliver both marked and unmarked oil where the oil is stored in a common tank on the vehicle. This arises because the systems available for the addition of marker are unlikely to be sufficiently secure to be accepted by the taxation authorities. For example, with systems which are currently available, a dishonest operator could deliver unmarked oil but record it as marked and thereby avoid payment of the higher tax by either disabling the marker system or by replacing the marker with a different fluid. Throughout this specification, the term secure refers to an acceptable level of prevention of tampering or unauthorised interference.
The requirement to use different delivery vehicles for marked and unmarked oil may increase costs in several ways. Firstly, it may necessitate the need for larger numbers of delivery vehicles. Secondly, it may necessitate additional distances travelled in situations where one destination or route could be delivered by one vehicle if it could deliver both types.
An object of the invention is to overcome these disadvantages by providing a secure system which can add marker at the point of delivery and thus allow one vehicle deliver both marked and unmarked types.
It is noted that the disadvantages associated with current systems would not be adequately overcome by using a delivery vehicle with two or more tank compartments, separately containing marked oil and unmarked oil, for the following reasons. Firstly it would be troublesome to attempt to match the relative quantities for marked and unmarked oil on the vehicle with the relative quantities required for its delivery schedule. The relative quantities may not even be known in advance. Also, quantities can only be carried in discrete tank sized amounts. Secondly, changing tank use from marked to unmarked use would necessitate frequent cleaning of the tanks, which would be time consuming and costly, and would carry - 3 the risk of residual marker contaminating the unmarked oil. Thirdly, as the risk of cross contamination would prevent sharing of delivery equipment for marked and unmarked oils, carrying the additional type of oil would further increase costs because it would necessitate equipping the vehicle with an additional pump and flowmeter.
The possibility of cross contamination from shared delivery equipment is also important in the general case of a delivery vehicle with a larger number of separate compartments holding the same basic fluid but with different additives. Such vehicles frequently measure quantities delivered by means of simple dipsticks because a common flowmeter cannot be used due to the possibility of cross contamination and it would be too expensive to provide flowmeters on every compartment. Measurement by dipstick is costly in labour and can be difficult in poor weather conditions. A further object of the invention is to overcome this disadvantage by providing a secure system which can add additive at the point of delivery and thus allow a range of fluid and additive mixtures to be delivered by common equipment, including a flowmeter, without risk of cross contamination.
Additive injection is used to inject fluid additives into base fluids in measured proportions. Reciprocating injection pumps, or injectors, are commonly used as dosing pumps in apparatus used for additive injection.
The injector typically comprises a piston and cylinder arrangement which is provided with an inlet check valve and outlet check valve and a means for reciprocating the piston in the cylinder. When the piston is drawn back in the cylinder, the negative pressure differential created in the cylinder causes the inlet check valve to open and the outlet valve to close or remain closed and additive is drawn in to the cylinder through the inlet pipe. When the piston returns in the cylinder, the positive pressure differential created causes the inlet valve to close or remain closed and the outlet valve to open and additive is expelled from the cylinder into the outlet pipe. This process is repeated at each cycle of the injector.
The reciprocating means can be provided in several different ways, a very common means being by the use of a pneumatic piston and cylinder actuator which has its piston coaxial with and linked to the piston of the injector. The pneumatic actuator piston may be reciprocated by conventional pneumatic control means which in turn reciprocates the injector piston. Other examples of reciprocating means includes spring returned pneumatic actuators and mechanical eccentric cams driven by rotating means.
Where a pneumatic actuator is used, the operation of the injector actuator and pump will usually be triggered by a pulse or signal from a device such as a flow meter measuring the flow of base fluid and which will cause the injector to carry out one reciprocating cycle comprising a suction and delivery stroke. If the pulse or signal from the flow meter is arranged such that it occurs each time a set proportion of base fluid passes the flow meter, then the flow of additive pumped by the injector will be proportional to the flow of base fluid. The reciprocating cycle is conventionally seen to have a characteristic length of time for each injector which will determine the maximum rate at which the injector can be run.
Usually some means is provided whereby the volume displaced at each stroke of the injector piston can be varied by varying the length of the piston stroke. Where a pneumatic actuator is used, this variation is frequently provided by a threaded adjustment member which acts as a stop which limits the length of the piston stroke in one direction. This variation allows the pump to be calibrated subsequent to manufacture.
The accuracy of injectors of the type described above, across the range of working pressures, can vary up to about +5%. Where greater accuracy is required, other means are frequently used, such as proportional metering valve arrangements with direct flow meter control which can readily give absolute accuracies across the range of working pressures within ±0.5%. The metering valve arrangement has the disadvantage that - 5 it is usually more complicated and expensive than an injector.
Injectors can also have the disadvantage that they do not mix additive evenly into the base fluid but inject discrete amounts of additive into a continuous stream of base fluid. This intermittent mixing method, sometimes referred to as slugging, gives rise to two potential problems. Firstly, the injected stream comprising additive and base fluid does not initially form an even mixture. Secondly, where small batch quantities are taken from the uneven mixture, the overall resulting proportions may be significantly incorrect and cannot be rectified by subsequent mixing of the batch quantities.
It is also an object of the present invention to provide apparatus which reduces the slugging problems which can arise from the uneven mixture of additive and base fluid caused by the injection method. It is a further object of the present invention to provide apparatus which can provide much improved accuracy in relation to the proportion of additive injected into the base fluid.
The present invention provides an apparatus for the secure addition of an additive to fluid dispensed from a delivery means which is required to deliver fluid with and without the additive and which is used in association with a flow meter, and a recording means, and which includes a reservoir of additive and a means for including the additive with the fluid, characterised in that the apparatus includes means for securely counting or recording the occurrence of an event associated with the filling, depletion, replacement or connection of the reservoir, whereby an audit or check may be made to compare the actual proportion of additive added to the fluid against set standards.
Advantageously, the apparatus includes a sensor which detects when the reservoir is empty or is depleted to a set level or which detects when additive becomes absent or is depleted to a set level in the additive system, whereby an event associated with the emptying or depletion of the reservoir results directly or indirectly from the operation of the - 6 sensor.
Advantageously, the reservoir comprises an upper and a lower section joined by a narrow constriction fitted with a sensor which detects when the reservoir is depleted to a level within the constriction.
Advantageously, an event associated with the filling, depletion, replacement or connection of the reservoir is recorded by the recording means in chronological order among the chronological list of deliveries.
Advantageously, the recording means is operable to calculate a value or an average value for the relative proportion of additive included in the fluid with which it has been mixed between events associated with the filling, depletion, replacement or connection of the reservoir.
Advantageously, an event associated with the filling, depletion, replacement or connection of the reservoir is the opening or closing of a door or opening or valve associated with the inlet to the reservoir.
Advantageously, the door or opening or valve is lockable and which includes a sensor which detects when the door or opening is opened or unlocked.
Advantageously, an event associated with the opening or unlocking of the door or opening is recorded by the recording means in chronological order among the chronological list of deliveries.
Advantageously, the recording means is operable to check that each event associated with the filling, depletion, replacement or connection of the reservoir is matched by exactly one subsequent event associated with the opening or unlocking of the door or opening.
Advantageously, the apparatus includes a cabinet which encloses part of the apparatus and which comprises a door which is lockable and includes a sensor which detects when the door is opened or unlocked and where the - 7 event associated with opening or unlocking of the door is recorded by the recording means in chronological order among the chronological list of deliveries.
Advantageously, the apparatus includes an anti flush section which is located on the additive line and may be integral with the additive tank, where the anti flush section comprises retarding means such as perforated baffles and anti draining means such as an outlet pipe which has its entry in the upper region of the section.
Advantageously, the fluid is oil, the additive is marker chemical and/or the delivery means is a delivery vehicle.
The present invention also provides a method of securely adding an 15 additive to fluid dispensed from a delivery means which is required to deliver fluid with and without the additive and which is used in associated with a flow meter, and a recording means, and which includes a reservoir for an additive and a means for including the additive with the fluid, the method being characterised by securely counting or recording the occurrence of an event associated with the filling, depletion, replacement or connection of the reservoir, whereby an audit or check may be made to compare the actual proportion of additive added to the fluid against set standards.
The invention further provides an apparatus for use where additive is injected in discrete amounts through an additive outlet means into a base fluid delivery means characterised in that the apparatus includes a blending means having one or more receptacles, diffusion chambers or channels which have resistances to fluid flow which causes fluid flow to occur at rates or speeds different to each other or to the base fluid delivery means and where the receptacles, diffusion chambers or channels have base fluid inlets for receiving a portion of the fluid flowing through the delivery means and blender outlets, the apparatus being operable so that the slugging effect of additive injection is reduced; ® 960722 - 8 Advantageously, the apparatus comprises a diffusion chamber in which fluid flow occurs at a rate or speed different to the base fluid delivery means and which has a base fluid inlet for receiving a portion of the fluid flowing through the delivery means, an inlet for receiving additive and a blender outlet for releasing from the diffusion chamber a mixture of base fluid and additive resulting from the combined flow or fluid flow mixing of the base fluid and additive within the diffusion chamber.
Advantageously, the diffusion chamber is connected to the delivery means, which may comprise a delivery pipe, by a base fluid inlet means, which may comprise a pipe, and a blender outlet means, which also may comprise a pipe, and where the base fluid inlet means or the blender outlet means or the diffusion means is restricted to regulate the flow of fluid passing through the diffusion chamber.
Alternatively, the diffusion chamber is located in the stream of base fluid in the delivery means, which may comprise a delivery pipe where a part of the diffusion chamber, such as the base fluid inlet or the blender outlet, is restricted to regulate the flow of fluid passing through the diffusion chamber.
Advantageously, additive is injected into the base fluid at a plurality of positions along one or more paths of flow of the base fluid.
Advantageously, the apparatus further comprises a manifold located in the diffusion chamber where the manifold is connected to the additive inlet and comprises a plurality of openings communicating with the diffusion chamber.
Advantageously, mixing of additive and base fluid is increased in the blending means by geometric means which creates turbulence within the blending means by utilising the flow energy of the additive when injected into the base fluid or by utilising the flow energy of the base fluid and additive by means of baffles or irregularities in the blending means. - 9 Advantageously, the injection means operates in a cycle which includes a delivery stroke and where the delivery stroke is arranged to occur at a relatively slow speed.
Advantageously, the apparatus comprises a diffusion chamber which communicates with a delivery means, such as a delivery pipe, where additive is injected into the base fluid from a plurality of openings along a manifold located in the diffusion chamber and connected to the additive inlet so that additive injected into the diffusion chamber mixes with base fluid along the manifold to form an elongated body of mixed or partly mixed fluid, and the base fluid inlet means or the blender outlet means or part or parts of the diffusion chamber are restricted to regulate the flow and relative speed of fluid passing through the diffusion chamber so that there is overlap between successive elongated bodies of fluid passing through the diffusion chamber so that a substantially continuous stream of mixed fluid enters the delivery pipe from the blender outlet of the diffusion chamber.
Advantageously, the manifold has openings on its upper surface so that additive is retained in the manifold.
Advantageously, the blending means or diffusion chamber is positioned below the delivery means so that the mixture of base fluid and additive is retained in the blending means or diffusion chamber.
Advantageously, the blending means or diffusion chamber is positioned at an inclined angle so that air entrapment is avoided in the blending means or diffusion chamber.
Advantageously, the blending means inlet and outlet pipes are raised in the delivery means so that the ingress of sludge or debris is avoided.
Advantageously, the blending means inlet is arranged with a much lower resistance than the blender outlet so that the greater part of any flow surges which take place during injection will occur through the blending - 10 inlet means.
Advantageously, scouring of the manifold is reduced or eliminated by having the manifold openings of small cross sectional area and of length which is relatively long in proportion to their width.
Advantageously, the manifold openings are of small cross sectional area and of length which is relatively long in proportion to their width so that the speed of injection is reduced and so that substantially even flow occurs through each of the manifold openings during injection.
Advantageously, two or more blending means are used in combination, with the base fluid of one blending means being the additive of another blending means.
The present invention also provides an apparatus for use where additive is injected in discrete amounts through an additive outlet means into a base fluid delivery means, including an injection means which operates in a cycle which includes a delivery stroke and which delivers additive in discrete amounts through an additive outlet means into a base fluid delivery means characterised in that additive is injected into the base fluid at a plurality of positions along one or more paths of flow of the base fluid and the delivery stroke of the injection means is arranged to occur at a relatively slow speed so that the slugging effect of the injection means is reduced.
The invention further provides an apparatus for use where additive is injected in discrete amounts through an additive outlet means into a base fluid delivery means including a means for constructing a record of additive usage for use where additive is injected in discrete amounts through an additive outlet means into a base fluid delivery means and where injection is carried out on consecutive batch quantities, characterised in that the injection system operates on the basis of a continuous running total such that each new batch quantity picks up from where the previous batch quantity left off to preserve the overall proportions of additive to base fluid so that the error associated with slugging is eliminated when constructing a record of additive usage.
The invention also further provides an apparatus for use where additive is injected in discrete amounts through an additive outlet means into a base fluid delivery means comprising a body including an inlet and an outlet each having a check valve, the inlet being connectable to an additive supply reservoir and the outlet being connectable to a base fluid delivery means, a cylinder located within the body and a piston operable to reciprocate with forward and reverse strokes within the cylinder to pump additive from the inlet to the outlet, characterised in that the injector cycle of operation is arranged to provide a preset delay period prior to each forward and reverse stroke sufficient to allow the check valves to come fully to rest and where the injector size is arranged such that the required stroke rate allows the necessary delay periods.
Advantageously, injector is arranged with a relatively high stroke to diameter ratio so that the seal surface area is reduced in proportion to the cylinder capacity and the stroke length is increased in proportion to the cylinder volume.
Advantageously, the injector includes an actuator for reciprocating the piston and the injector and actuator are arranged such that the force developed by the actuator is much greater than the force required by the injector over the complete range of working pressures in the base fluid delivery means so that the effects of variations in working conditions on injector performances are reduced.
Advantageously, the injector stroke capacity is arranged to be of a size which is sufficiently small such that unacceptable slugging does not take place but is sufficiently large such that the injector stroke provides adequate preset delay periods prior to each forward and reverse stroke sufficient to allow the check valves come fully to rest. - 12 Advantageously, the injector is reciprocated by a pneumatic actuator and the actuator is provided with restrictor arrangements which control the speed of the actuator.
The invention also provides an apparatus for the secure addition of an additive to fluid dispensed from a delivery vehicle, which is required to deliver fluid with and without the additive and which is used in conjunction with an electronic flow counter comprising one or more memory devices and a means for the addition of an additive to fluid dispensed from a delivery vehicle, characterised in that the apparatus is provided with security means for denying or monitoring physical access to reprogramme or hack into the electronic flow counter, said security means being capable of physically isolating one or more of the memory devices.
Advantageously, said security means is a mechanical or electronic locking means and an enclosure means.
Advantageously, said security means is a sealing means and an enclosure means.
Advantageously, said security means includes a detection means for sensing when a circuit is broken on the occurrence of physical access or removal of part of the flow counter or for sensing activation of a sensor on the occurrence of physical access or removal of the flow counter.
Advantageously, one or more of the memory devices comprising the flow counter are replaced by memory devices which cannot be reprogrammed.
Advantageously, all or part of the security means is duplicated on an on-truck-computer and flow counter.
The invention will now be described more particularly with reference to the accompanying drawings which show, by way of example only, an embodiment of the invention which is suitable as an apparatus for securely adding marker chemical to middle distillate oils dispensed from \£ 960722 a delivery vehicle which is required to deliver oil with and without the marker.
Figure 1 shows, in diagrammatic form, the delivery and control apparatus on a delivery vehicle, with electronic, electric or pneumatic control lines shown as dashed lines; Figure 2 shows, again in diagrammatic form, a view of part of the delivery and control apparatus shown in Figure 1 in more detail and on a larger scale; and Figure 3 shows a diagrammatic and simplified view of an injector with a pneumatic actuator provided with directional and speed control valves.
The injector and pneumatic actuators are shown in section.
The following is an index of the reference numerals used in the figures:1 Oil tank Oil pump Oil flow meter Two-way valve Unmarked oil delivery pipe Marked oil delivery pipe Marker tank Marker level sensor Marker low flow sensor Injector or injector pump Cabinet Pulser unit Electronic control and recording means or controller Cab warning indicator Marker refill sensor Cabinet access sensor Marker tank, lower section Anti flush section Anti flush retarding means Anti flush outlet pipe Blender or blending means Blender diffusion chamber Blender oil inlet Blender marker inlet Blender outlet Blender manifold Blender manifold openings Injector body Cylinder Piston Cylinder cavity Injector outlet Outlet check valve Injector inlet Inlet check valve Actuator Actuator body Actuator cylinder Actuator piston Link rod Actuator cylinder cavity Actuator port Directional control valve Restrictor check valve arrangement Adjustment member Adjustment member lock nut Referring now to Figures 1 and 2, there is shown a delivery vehicle oil tank 1 of unmarked oil which may comprise one or a plurality of interlinked compartments. Oil is pumped from the tank 1, by an oil pump 2 through an oil flow meter 3 to a two-way valve 4 connected to one of two delivery pipes, an unmarked oil delivery pipe 5 and a marked oil delivery pipe 6. - 15 The marked oil delivery pipe 6 is connected to a marker system which securely and automatically adds marker in the desired proportion to oil. The marker system comprises a marker reservoir or tank 7 with an upper section and a lower section, the sections being connected by a short pipe section in which a marker level sensor 8 is mounted. The marker tank comprises a further anti-flush section 18 below the lower section of the tank. Marker flows by gravity feed along a marker pipe to an injector unit 10 which pumps marker in the desired proportion into the marked oil delivery pipe 6. The injector unit 10 comprises a fixed stroke piston pump which delivers a set volume of marker when signalled by an electric or pneumatic pulse.
The anti flush section 18 is fitted with retarding means 19, which control and retard flow within the section 18, and with anti draining means, such as an outlet pipe 20 which has its entry in the upper region of the section 18. The retarding means 19 may comprise, for example one or more partly perforated receptacles or a number of perforated baffles.
The marker pipe is provided with a marker low flow sensor 9.
The marker tank 7. and all the components on the marker system down to the marked oil delivery pipe 6, including the adjacent section of marked oil delivery pipe 6 are contained within a secure cabinet 11. The cabinet comprises a door with a lock and with a cabinet access sensor 16 which signals if the door is opened. The cabinet access sensor 16 is securely mounted within the cabinet 11 .
A pulser unit 12 is attached to the flow meter 3 and generates pulses in proportion to the flow of oil through the flow meter 3.
The apparatus is also provided with an electronic control and recording device 13, henceforth referred to as the controller 13, which is connected by electronic, electric or pneumatic signal lines to the marker level sensor 8, the marker low flow sensor 9, marker refill sensor 15 the - 16 cabinet access sensor 16, the two-way valve 5, the injector unit 10, the pulser unit 12 and the cab warning indicator 14. The controller 13 is also connected to the warning indicators 14, such as lamps, in the vehicle cab and on the cabinet 11.
The apparatus is additionally provided with a printer which produces a customer coupon which states the quantity of oil delivered and identifies whether it is marked or unmarked oil. In one variation, the printer is an electronically controlled type connected to the controller 13. In another variation, it is a mechanical type connected directly to the oil flow meter 3.
Flow meters with printers and injector units with associated pulser units for adding additives to fluids at the point of delivery are all well known and widely used on delivery vehicles. Electronic control and recording devices of various types are also well known and widely used on delivery vehicles.
The marker level sensor 10, marker refill sensor 15, and cabinet access sensor 16 may comprise electronic proximity sensors, the marker low flow sensor 9 may comprise a switch with a magnetic float in a tapered tube. The marker refill proximity sensor may directly detect the presence of marker in the restriction or may detect the movement of a float in the restriction. The two-way valve 5 may comprise a manually operated ball valve with electronic proximity sensors signalling the position of the operating lever. Alternatively, the two-way valve 5 may comprise a solenoid operated valve controlled by signals from the controller 13.
The operation of the particular embodiment of the invention will now be described.
Many of the elements involved in delivering marked and unmarked oil are similar to those used in various combinations in the known art for the delivery of fluids with or without an additive where the system does not require a high level of security. In these known elements, the two-way valve 4 directs the pumped fluid, oil, into one of two separate delivery pipes 5,6 as appropriate. Additive, marker, fed from a storage tank 7 on the vehicle, is injected into the relevant delivery pipe 6 in proportion to the quantity of oil delivered through the pipe 6 by means of the injector unit 10 controlled by the controller 13 and pulser unit 12 associated with the flow meter 3. A coupon is printed and an electronic record of the delivery made by the controller 13 by means of signals from the pulser unit 12 and the two-way valve 4.
The particular embodiment of the invention includes the following additional elements which are not known in the relevant prior art.
The marker tank is divided into two sections 7, 17 joined by a narrow constriction fitted with a marker level sensor 8. The volume of the upper section 7 corresponds to the standard refill volume and may, for example correspond to one or more discrete refill containers of marker. The base of the upper section 7 is sloped towards the entry to the constriction in order to ensure that no residual marker remains in the upper section when the level in the tank falls to the level of the marker level sensor 8. The volume of the lower section 17 corresponds to the quantity of marker considered necessary to act as a reserve to provide marked oil in the interim period between the driver being altered by a signal associated with the operation of the marker level sensor 8 and the tank being refilled with marker. The volume of the lower section 17 may be made relatively large if the possibility or desirability of long interval periods is envisaged. However, the lower section 17 should not be larger than the upper section 7, because a single standard refill might otherwise not reach the level of the marker level sensor 8.
Positioning the marker level sensor 8 in the constriction between the two tank sections 7, 17 increases its accuracy in two ways. Firstly, it measures the level where the cross sectional area is small and a small difference in volume causes a relatively large difference in level. Secondly, its operation is no longer measurably affected by variable inclination of the delivery vehicle and its equipment. - 18 960^2^ When the marker in the tank 7 falls to the level of the marker level sensor 8, the sensor 8 signals the controller 13 and the event is electronically recorded and a warning indicator 14, such as a lamp in the vehicle cab, remains activated until the marker tank 7 is refilled. The driver will arrange for the marker tank 7 to be refilled during a subsequent visit to the depot where replacement marker is stored.
The tank 7 is always refilled with a defined and accurately controlled quantity of marker. Consistent and tamper resistant refill quantities are assured in several ways. Firstly, the refill quantity is taken from one of a set number of accurately filled containers of marker or is taken from a bulk tank of marker at the depot using a device which will accurately dispense the required quantity. Secondly, access to refill the marker tank is controlled by a locking means. For example, the marker tank may be refilled through a refilling inlet, such as a dry coupling, which is located within a compartment with a lockable door. Thirdly, access to refill the tank is monitored and recorded by means such as a sensor recording the opening of the access door to the marker tank refilling inlet. The sensor signals the controller and the event is electronically recorded.
The controller automatically prepares electronic summarised records of all deliveries in chronological sequence, distinguishing between marked and unmarked deliveries, and simultaneously accurately records real usage of marker related to marked deliveries. The operation of the marker refill lock and cabinet access lock sensors are also chronologically recorded and all events are logged against time and date using the controller internal clock and calender. Any irregularities are automatically analysed and signalled. The resulting records can be used for legal purposes, spot checks, audits, general statistics or historical checking of suspected blocks of deliveries. Usually the records will not be disclosed to the vehicle operator or driver but will be monitored and stored at a centralised base. - 19 IE 960722 The recorded information allows immediate and subsequent audits or checks to be made to compare the actual proportion of marker added to the oil against the set standard because the known refill quantity is the amount used between operations of the marker level sensor. The controller 13 automatically checks the proportion and indicates if it is not within acceptable tolerances.
The operation of the marker refill sensor 15 provides an additional important security measure including a check that each marker level sensor 8 operation is matched by exactly one subsequent marker refill sensor 15 operation. The controller 13 again automatically checks that this condition has been satisfied and indicates if it has not.
The marker low flow sensor 9 is used to ensure that oil is not accidentally or deliberately dispensed through the marked oil delivery pipe 6 without the addition of marker.
If any of the sensors detects an abnormal condition, the event is recorded by the controller and dispensing is automatically stopped by closing a valve on the oil line. The controller will also activate any systems which are available to alert the central base.
The anti flush section 18 is used as a further safeguard to prevent intermittent replacement of marker by a spurious fluid such as unmarked oil or oil which contains a transient or easily removed dye, or by marker without the invisible second marking chemical. For example, gaining unauthorised access to the cabinet 11 and overriding or disabling the signals from the relevant sensors could allow replacement of the marker by an equal quantity of spurious fluid and visa versa. This deception would not be detected by the marker low flow sensor 9 or by the apparent proportion of marker to marked oil which would be recorded by the controller 13.
The anti flush section 18 contains a significant quantity of marker and is constructed in a way such that it is very difficult to quickly remove all or a significant portion of its contents. The outlet pipe 20 prevents the contents of the section 18 being drained or being blown out under pressure. The retarding means 19 prevent the main body of marker being quickly flushed out by flushing spurious fluid through the device as the flushing fluid will largely short circuit from the inlet to the outlet of the section 18 and little or none will reach the inner sections of the section 18. The section 18 is arranged such that air can freely vent upwards when the marker tank is filled. Any cover members comprising the anti flush section are arranged with a sloping surface to prevent air entrapment.
The particular embodiment includes retarding means 19 which comprise one or more partly perforated and lidded receptacles which are fixed a small distance from the floor and sides of the tank. The perforations allow restricted communication of the contents of the immersed receptacles with the tank and are positioned in the upper region of the receptacles such that the receptacles will retain all or a substantial amount of marker in the event of the tank being drained. The receptacles are fixed away from the floor and sides of the tank to guard against holes being made in the tank, or being made and subsequently concealed, with the purpose of illicitly draining or flushing the contents from the tank.
The apparatus is made subject to periodic spot checks to ensure that it has not been tampered with and that the correct type of marker is being used. Where possible, the apparatus is arranged or constructed in a manner which will show up any alterations or unauthorised interference.
Other variations of marker reservoir 7 and means to detect the rate at which marker is replaced may be used in effecting the apparatus of the invention. For example, the reservoir 7 may comprise one or more containers of marker linked to the apparatus. The audit or check to compare the actual proportion of additive added to the fluid against set standards may also be made by securely counting or recording the occurrence of various events associated with the filling, depletion, replacement or connection of container or tank reservoirs 7. - 21 Various types of electronic control and recording means, are used on tanker vehicles which deliver oil or other fluid products. They frequently comprise a computer in the vehicle cab used in conjunction with an electronic flow control device, hereafter referred to as a flow counter, pulsed from a flow measurement device on the oil delivery line. Vehicle computers are usually termed OTCs, or on-truck-computers. The flow counter comprises a small programmable logic unit and typically includes a memory device such as an erasable programmable read-only memory or EPROM device. The OTC usually compiles the electronic record of the deliveries and other relevant information and this record is retrieved by various means for subsequent checking and storage.
A problem which arises from the use of an OTC where additive must be securely added on a delivery vehicle is that it is very difficult to prevent the possibility of dishonest operators reprogramming or hacking into the software system to manipulate the record or calculation of additive concentration. OTC systems are very similar to ordinary personal computer systems and a wide cross section of people are familiar with their operation and manipulation. It is an object of the present invention to overcome or reduce this problem.
The present invention provides various means which prevent reprogramming or hacking into the flow counter software. These means include apparatus which physically denies access required for reprogramming or hacking into the flow counter by the use of a mechanical or electronic locking means or by means of a sealing means, used in conjunction with an enclosure means which isolates one or more memory devices comprising the flow counter and to which access must be gained in order to modify or disable the security system. The enclosure means may comprise a secure casing with a lockable or sealable opening. The locking means may, for example, comprise a key operated locking device. The sealing means may, for example, comprise a wire and lead tag.
The present invention also includes detection means which monitor ® 960722 - 22 physical access to or removal of one or more memory devices comprising the flow counter which permits reprogramming or hacking to be carried out. The security system is activated if illicit access or removal is detected. The detection means may, for example, comprise a normally live circuit within the memory devices or some part of the flow counter which is arranged such that it is broken if the relevant physical access to or removal to permit reprogramming or hacking takes place. The detection means may also, for example, comprise an electronic or electric sensor which is activated if the relevant physical access to or removal to permit reprogramming or hacking takes place.
Isolation of the flow counter memory devices can be achieved in ways that are not possible with a computer such as an OTC. Unlike a computer or OTC, the memory devices or flow counter normally cannot be reprogrammed or hacked into using the operational external input or output wires or terminals. Also, the memory devices are very much smaller than an OTC and have no operator interfaces such as screens or keyboards, which accordingly allows them to be readily enclosed in a secure casing.
The present invention also provides for one or more of the memory devices comprising the flow counter to be replaced by memory devices which cannot be reprogrammed. An OTP or one-time-programmable device is an example of such a memory device.
The present invention additionally provides for part of the security system to be duplicated on the OTC and on the electronic flow counter.
If either system detects illicit manipulation, it will independently activate a security system, such as shutting down the truck delivery system, marking an electronic record or alerting the central base.
Usually the electronic flow counter will have more limited programmable capacity than the OTC and will therefore operate a simpler security system than the OTC. However, the invention may also be used on trucks without OTCs.
Returning to Figures 1 and 2, the apparatus is also provided with a blending means or blender 21 connected to the delivery pipe 6. The blender 21 includes a manifold 26 and a receptacle or diffusion chamber 22. The diffusion chamber 22 may comprise an elongate tube. The injector outlet pipe 32 communicates with the manifold 26 through a short length of pipe which is connected through a marker inlet 24 to the manifold gallery which in turn communicates with the diffusion chamber through a row of holes or openings 27 along the upper surface of the manifold 26. The diffusion chamber communicates with the delivery pipe 6 through a blender base fluid or marker inlet 23 at one end and a blender outlet 25 at the other end. The blender 21 is positioned below the delivery pipe 6 and at an inclined angle to prevent air entrapment and to prevent leakage of the mixture of oil and marker from the diffusion chamber 22 into the delivery pipe 6 between deliveries. The manifold 26 is also arranged with the manifold openings 27 on its upper surface so that additive is retained in the manifold between deliveries. The blender inlet 23 and outlet 25 pipes are raised in the delivery pipe 6 to prevent ingress of sludge or debris and are provided with oblique openings facing respectively upstream and downstream in the delivery pipe 6. The relative flow of oil through the diffusion chamber 22 is regulated by a restriction in the outlet 25 pipe which is not shown in the figures.
The inlet 23 pipe is deliberately arranged with very little resistance in order that the greater part of the flow surge which occurs when injection takes place, flows backwards through the inlet 23, thus preventing a slug of oil-marker mixture being displaced into the delivery pipe 6. The backward flow through the inlet 23 into the delivery pipe comprises oil without marker. As oil flows in the delivery pipe 6, a pressure differential is created between the two openings 23, 25 of the diffusion chamber 22 which causes flow within it, but at a lower speed. The speed may be set by suitable arrangement of the restriction.
Additive injected into the diffusion chamber 22 mixes with base fluid along the manifold 26 to form an elongated body of mixed or partly mixed fluid, and the outlet 25 in the diffusion chamber 22 is restricted to 960722regulate the flow and relative speed of fluid passing through the diffusion chamber 22 to ensure that there is overlap between successive elongated bodies passing through the diffusion chamber 22. This ensures that a substantially continuous stream of mixed fluid enters the delivery pipe 6 from the release outlet 25 of the diffusion chamber 22.
It is important to ensure that additive is not removed from the manifold 26 when injection is not taking place either by the passage of oil over the openings 27 or by pressure differentials set up within the diffusion chamber 22 which could cause oil to enter some of the openings 27 in the manifold 26 and displace additive through openings 27 where the fluid is at a lower pressure. Such removal of additive shall henceforth be referred to as scouring. Scouring will give rise to inaccuracies in the proportion of oil and additive in that the scoured additive will increase the concentration when scoured but will reduce the concentration at the following injection as the manifold 26 will require to be replenished. When scouring occurs, its effects will be variable due to variations in the flow of oil in the delivery pipe 6 and to factors such as temperature influenced viscosity effects.
The possibility of scouring is reduced or prevented by various means. These include avoiding irregularities or resistances in the diffusion chamber 22 which might give rise to pressure differentials along the manifold 26. In particular, where a diffusion chamber 22 of the type described in the preferred embodiment is used with a single manifold 26, the flow restrictors should be either upstream or downstream of the manifold. Scouring is also reduced or eliminated by arranging the manifold openings 27 to be of small cross sectional area and to be of length which is relatively long in proportion to their width. For example, a manifold 26 of around 150 mm to 200 mm in length may be provided with about 6 holes of diameter 1 mm and depth 10 mm. It is important to ensure that the injector pump 10 develops sufficient pressure in the additive to allow it to pass through the holes within the allowable time cycle and that the additive is not of a type which will clog small passageways. Alternatively, scouring can be reduced or minimized by providing small check valves in the manifold 26. For example, if the manifold 26 gallery is fed from the centre, a check valve may be placed in each section of the gallery to prevent backwards flow and thereby prevent internal circulation between its two sections. Alternatively, the manifold 26 may comprise manifold openings 27 where each is provided with a separate check valve.
The effect of any scouring which might accidently occur is minimised by reducing the quantity of additive contained in the manifold. This is achieved by ensuring that the connecting passages and galleries to the manifold 27 openings are not made larger than is required for the operation of the injector pump 10 within the allowable time cycle or is necessitated by the manufacturing process.
When regulating the rate of flow in the diffusion chamber 22 to set the degree of overlapping of the elongated bodies, a compromise must be reached. On the one hand, reducing the flow will give a greater degree of overlapping and consequently a more homogeneous mixing in the diffusion chamber 22. On the other hand, reducing the flow and increasing the degree of overlapping will increase the average concentration of marker in the oil in the diffusion chamber 22. This will have the potential drawback of increasing any problems of fluid expelled from the diffusion chamber 22 by the injection stroke or problems of leakage between the diffusion chamber 22 and the delivery pipe 6 between deliveries. In practice a rate of flow which causes one to three overlaps of the elongated bodies has been found satisfactory.
The use of manifold openings or outlet holes 27 of small diameter and relatively long length has advantages in addition to preventing or minimising scouring or leakage of marker into the diffusion tube 22 when the system is out of operation. The small holes lengthen the time period of injection and thereby assist the formation of the elongated bodies and reduce the effect of fluid being expelled from the diffusion chamber 22 during injection. The small holes also help to ensure even flow through each of the manifold openings or holes 27 during injection. Κβ6 0 7 c The blending means 21 reduces or eliminates the problems and inaccuracies which arise from slugging where shots of additive are injected into the continuous stream of oil. If not otherwise dealt with, the oil and additive mixture delivered into the delivery line would comprise alternating quantities of marked and unmarked oil. Although these alternating quantities would usually mix together in the storage tank into which they are delivered, if a small quantity of oil and additive mixture is delivered or if a small sample is taken for examination, the proportion of additive in the mixture would most likely be incorrect. Slugging also gives rise to a potential security problem in that it is possible to separate the marked and unmarked quantities of oil passing down the delivery line by connecting a length of transparent hose to the end of the line and manually switching the hose end between two tanks as the oil alternates between marked and unmarked. Switching could also be achieved without the use of a transparent hose by initial observation of the outflowing oil and then using the noise of the injector pump 10 when the appropriate sequence pattern becomes clear. In either of these cases it is possible for the operator to reduce the flow from the hose end and thereby increase the interval time between injection pulses. Switching could also be achieved automatically using a photocell controlling a change-over valve, in which case the deception could be achieved by the recipient without the delivery operator being aware that it was taking place.
In most cases the effectiveness of the blending means 21 is increased by any mixing which takes place between additive and base fluid within the blending means 21 or the diffusion chamber 22 for reasons which include the following. Firstly, mixed fluid within the blending means 21 or diffusion chamber 22 will promote more even dispersion in the delivery means 6 as it gradually flows into it. Secondly, any quantity of fluid which might be displaced into the delivery means 6, when additive is injected into the diffusion chamber 22, should ideally comprise a well mixed and diluted combination of additive and base fluid to minimise slugging effects. The blending means 21 may be geometrically arranged such that injection of additive creates turbulence within the blending means 21 to increase mixing within it. The blending means 21 may also be provided with baffles or irregularities to increase mixing as the additive and base fluid pass through it.
The blending means 21 may be arranged in various other ways and the suitability of different variations may depend on the flow of base fluid, the proportion of additive injected, the rate of injection and the viscosities and miscibilities of the two fluids. In some cases the manifold 26 may be omitted from the diffusion chamber and injection take place from an outlet with mixing occurring within the chamber 22 by other means including turbulence.
The blending means 21 may also comprise arrangements which do not include a manifold 26 but where injection occurs at different outlets or openings in the blending means or in the delivery means 6.
The blending means 21 may additionally comprise the deliberate slowing down of the injection stroke. This can be achieved by several means including arranging the injection opening or manifold openings 27 to be of small cross section, or by restricting the exhaust of the actuator where the injector 10 is driven by an air actuator 36.
The blending means 21 may also comprise one or more injection points or an injection manifold 26 located in a section of a delivery means 6, where flow speed is reduced by increasing the relative cross sectional area.
The blending means 21 may also be located in the delivery means 6 downstream of the injection position. In this instance the flow in the delivery means 6 is divided into separate receptacles or channels with different resistances to flow, such that individual quantities of the separate flows are staggered or spaced apart as they come together again in the delivery means 6. Thus, a slug of additive moving in the stream of base fluid will be broken into several smaller spaced apart slugs of additive. The overall cross sectional area of flow may be increased to compensate for the lower flow rates in the restricted channels. The cross section of individual channels or groups of channels may be increased in proportion to the resistance to flow to allow even sizing and separation of the smaller slugs.
The present invention additionally overcomes or reduces the potential problems associated with slugging in another way. For control and recording purposes, the injection system is arranged to operate on the basis of a continuous running total such that each delivery picks up where the previous delivery left off to preserve the overall proportions of additive to oil. This will eliminate the error associated with individual shots being used with a continuous oil flow when constructing a record of additive usage for security purposes. In some instances this system may be refined to avoid an injection shot being interrupted by the termination of the delivery. This can be achieved where the system is under electronic or computer control and the delivery quantity is preset. The injection shots are reorganised such that none are interrupted by the termination of delivery, but the ongoing proportion rebalanced to preserve the correct proportions.
The blending means 21 may be used with a wide variety of fluids including gases where suitably arranged. Where it is required to blend two or more fluids where an additive is injected in very low concentration, it may be advantageous to use a combination of two or more blending means 21 with the base fluid of one being the injected additive of another.
Referring now to Figure 3, the injector 10 comprises an injector body 28, a cylinder 29 and a piston 30. The piston 30 and cylinder 29 arrangement is provided with seals which are not shown in the figure, but which may be fixed in the injector body 28 and make sealing contact with the piston 30 or link rod 40. The piston 30 is operable to reciprocate in the cylinder 29 thereby increasing and decreasing the volume in the cylinder cavity 31. The injector 10 is provided with an inlet 34 which communicates with the cylinder cavity 31 and is connected to an inlet pipe feeding from the marker tank. The inlet 34 is provided with a check valve 35 which allows additive to enter the injector 10 but prevents flow in the opposite direction. The injector 10 is also provided with an outlet 32 which communicates with the cylinder cavity 31 and which is connected to the blender marker inlet 24 and marked oil delivery pipe 6. The outlet 32 is provided with a check valve 33 which allows additive to leave the cylinder cavity 31 but prevents flow in the opposite direction. Reciprocating of the piston 30 will accordingly draw additive in through the inlet 34 and pump it out through the outlet 32. The check valves 33, 35 may of the known type where ball members seal against seatings and are held against the seatings by the assistance of gravity and springs.
The injector 10 is provided with a pneumatic actuator 36 which reciprocates the injector piston 30. The actuator 36 comprises an actuator body 37, an actuator cylinder 38, an actuator piston 39 and a link rod 40. The actuator piston 39 and actuator cylinder 38 arrangement is provided with seals which are not shown in the figure. The injector body 28 and actuator body 37 may be made in one piece. The injector piston 30 is axially connected to the actuator piston 39 by the connecting link rod 40 which may conveniently be arranged to allow some lateral movement. Each side of the actuator cavity 41 is connected to an actuator port 42 which communicates with a solenoid operated directional control valve 43 via restrictor arrangements 44 which control the speed of the actuator, such as restrictor and check valve arrangements 44. The restrictor and check valve arrangements 44 allow air to freely enter the cylinder cavity 41 through the check valve but restricts its exit by forcing the air to pass through the restrictor valve. The solenoid valve 43 is thus operable to control the reciprocation of the injector piston 30 and the restrictor and check valve arrangements 44 are operable to control the speed of the movement of the injector piston 30.
The actuator 36 is provided with a threaded stroke adjustment member 45 which enters the actuator through a threaded hole and limits the stroke of the actuator piston 39 in one direction. The position of the adjustment member 45 can be varied by screwing it in or out of the •607?? actuator 36 and can be locked in position with a lock nut 46.
The accuracy of the injector can be affected by variations in operating conditions. These variations include pressure variation in the oil delivery system. Some of this variation arises from the elevation at which the delivery is being made in relation to the level of oil in the vehicle and some is due to the position of the operator controlled valve at the delivery hose gun, which may be open or partly closed during delivery. Other variations include the temperature related viscosities of the oil and additive, which can affect back pressures and valve operation, and temperature effects on the resilience of valve or piston seals and on friction effects in the valves or actuator.
When an injector is operating in a conventional manner the injector check valves can remain in a dynamic situation during part of the cycle when, ideally, they should be firmly closed. Check valve dynamics are generally not well understood when the valves are operating rapidly and the inaccuracies arising from this phenomenon are conventionally dealt with by the process of calibration which compensates for losses across the valves. The present invention provides that the injector cycle of operation is arranged to provide a deliberate preset delay prior to both the suction and delivery strokes to allow the valves to completely settle and arranging the injector size to be such that there is sufficient pumping capacity to allow these delays.
Variable flexing of piston seals may give rise to variations in the volume of additive pumped on each stroke of the injector. This potential source of inaccuracy can be reduced by arranging the injector pump with a relatively high stroke to diameter ratio which reduces the seal surface area in relation to the cylinder capacity. Increasing this ratio also increases the relative accuracy of using end stops on the stroke to control the volume as it minimises the volume in relation to the stroke length.
The injector pump and actuator are also arranged such that the force developed by the actuator is much greater than the force required by the injector pump over the complete range of pressures possible in the base fluid delivery means. This will minimise the effects of variations in delivery line pressure on pump performance. It will also minimise the effects of friction variations in the injector or actuator.
The injector stroke capacity is arranged relatively small, but not so small that the stroke rate is too high to allow sufficient time for the valves to fully close as discussed earlier.
The actuator may be provided with restrictor and check valve arrangements which control the speed of the actuator in each direction. This prevents mechanical impact and shock on the end stops and other parts, which reduces piston bounce and noise. It also reduces wear on the end stops and helps to maintain consistency of stroke length over the life of the injector. It additionally reduces hydraulic shock and instability in the fluid systems which assists valve stability and helps prolong the life of seals and components. High piston velocity can create undesirable high kinetic energy in the fluid, both within and outside the injector, the dissipation of which can unsettle the operation of the check valves and other moving parts when the piston reaches the end of its stroke.
An example of an application of the invention is given below where the oil pump flow rate is 10 litres per second, the oil line operating pressures vary from 0 bar to 9 bar, the additive concentration is 100 parts per million and the regulated air supply to the actuator is 4 bar. An injector piston diameter of 6 mm is used with a stroke length of 50 mm, giving a stroke volume of 1.41 ml. The average resulting time of the injector is about 1.41 seconds per cycle. This time period is divided between the valve settling before delivery, the delivery stroke, the valve settling after delivery and the suction stroke. A longer period is allowed for the suction stroke than for the delivery stroke. The overall time period is sufficient to satisfy the requirements for effective valve closure and the piston diameter to stroke ratio is adequately high to minimise the effects of seal flexing and accentuate the effectiveness of the end stop accuracy. An actuator piston diameter of 25 mm is used with a stroke of 50 mm matching the stroke of the injector piston. This can be shown to cause the force capability of the actuator to be about seven times greater than the maximum resistance resulting from the oil line pressure acting on the injector which is adequate to minimise the effects of variations in oil line pressure. In a properly designed system, this arrangement can readily provide accuracies within +0.5%.
It will of course be understood that the invention is not limited to the specific details described herein, which are given by way of example only, and that various modifications and alterations are possible within the scope of the invention as defined in the appended claims.

Claims (45)

CLAIMS :
1. An apparatus for the secure addition of an additive to fluid dispensed from a delivery means which is required to deliver fluid with and without the additive and which is used in association with a flow meter, and a recording means, and which includes a reservoir of additive and a means for including the additive with the fluid, characterised in that the apparatus includes means for securely counting or recording the occurrence of an event associated with the filling, depletion, replacement or connection of the reservoir, whereby an audit or check may be made to compare the actual proportion of additive added to the fluid against set standards.
2. An apparatus according to Claim 1, including a sensor which detects when the reservoir is empty or is depleted to a set level or which detects when additive becomes absent or is depleted to a set level in the additive system, whereby an event associated with the emptying or depletion of the reservoir results directly or indirectly from the operation of the sensor.
3. An apparatus according to Claim 1 or Claim 2, in which the reservoir comprises an upper and a lower section joined by a narrow constriction fitted with a sensor which detects when the reservoir is depleted to a level within the constriction.
4. An apparatus according to any one of the preceding claims, in which an event associated with the filling, depletion, replacement or connection of the reservoir is recorded by the recording means in chronological order among the chronological list of deliveries.
5. An apparatus according to any one of the preceding claims, in which the recording means is operable to calculate a value or an average value for the relative proportion of additive included in the fluid with which it has been mixed between events associated with the filling, depletion, replacement or connection of the reservoir. 96072234
6. An apparatus according to any preceding claim, where an event associated with the filling, depletion, replacement or connection of the reservoir is the opening or closing of a door or opening or valve associated with the inlet to the reservoir.
7. An apparatus opening or valve when the door or according to any preceding claim, where the door or is lockable and which includes a sensor which detects opening is opened or unlocked.
8. An apparatus according to any preceding claim, in which an event associated with the opening or unlocking of the door or opening is recorded by the recording means in chronological order among the chronological list of deliveries.
9. An apparatus according to any preceding claim, in which the recording means is operable to check that each event associated with the filling, depletion, replacement or connection of the reservoir is matched by exactly one subsequent event associated with the opening or unlocking of the door or opening.
10. An apparatus according to any preceding claim, which includes a cabinet which encloses part of the apparatus and which comprises a door which is lockable and includes a sensor which detects when the door is opened or unlocked and where the event associated with opening or unlocking of the door is recorded by the recording means in chronological order among the chronological list of deliveries.
11. An apparatus according to any preceding claim, including an anti flush section which is located on the additive line and may be integral with the additive tank, where the anti flush section comprises retarding means such as perforated baffles and anti draining means such as an outlet pipe which has its entry in the upper region of the section.
12. An apparatus according to any preceding claim, where the fluid is 360722 oil, the additive is marker chemical and/or the delivery means is a delivery vehicle.
13. A method of securely adding an additive to fluid dispensed from a delivery means which is required to deliver fluid with and without the additive and which is used in associated with a flow meter, and a recording means, and which includes a reservoir for an additive and a means for including the additive with the fluid, the method being characterised by securely counting or recording the occurrence of an event associated with the filling, depletion, replacement or connection of the reservoir, whereby an audit or check may be made to compare the actual proportion of additive added to the fluid against set standards.
14. An apparatus for use where additive is injected in discrete amounts through an additive outlet means into a base fluid delivery means characterised in that the apparatus includes a blending means having one or more receptacles, diffusion chambers or channels which have resistances to fluid flow which causes fluid flow to occur at rates or speeds different to each other or to the base fluid delivery means and where the receptacles, diffusion chambers or channels have base fluid inlets for receiving a portion of the fluid flowing through the delivery means and blender outlets, the apparatus being operable so that the slugging effect of additive injection is reduced;
15. An apparatus according to Claim 14, comprising a diffusion chamber in which fluid flow occurs at a rate or speed different to the base fluid delivery means and which has a base fluid inlet for receiving a portion of the fluid flowing through the delivery means, an inlet for receiving additive and a blender outlet for releasing from the diffusion chamber a mixture of base fluid and additive resulting from the combined flow or fluid flow mixing of the base fluid and additive within the diffusion chamber.
16. An apparatus according to Claim 14 or 15, where the diffusion chamber is connected to the delivery means, which may comprise a delivery 9607224 pipe, by a base fluid inlet means, which may comprise a pipe, and a blender outlet means, which also may comprise a pipe, and where the base fluid inlet means or the blender outlet means or the diffusion means is restricted to regulate the flow of fluid passing through the diffusion chamber.
17. An apparatus according to Claim 14 or 15, in which the diffusion chamber is located in the stream of base fluid in the delivery means, which may comprise a delivery pipe where a part of the diffusion chamber, such as the base fluid inlet or the blender outlet, is restricted to regulate the flow of fluid passing through the diffusion chamber.
18. An apparatus according to any one of Claims 14 to 17, wherein additive is injected into the base fluid at a plurality of positions along one or more paths of flow of the base fluid.
19. An apparatus according to any one of Claims 14 to 18, wherein the apparatus further comprises a manifold located in the diffusion chamber where the manifold is connected to the additive inlet and comprises a plurality of openings communicating with the diffusion chamber.
20. An apparatus according to any one of Claims 14 to 19, wherein mixing of additive and base fluid is increased in the blending means by geometric means which creates turbulence within the blending means by utilising the flow energy of the additive when injected into the base fluid or by utilising the flow energy of the base fluid and additive by means of baffles or irregularities in the blending means.
21. An apparatus according to any one of Claims 14 to 20, wherein the injection means operates in a cycle which includes a delivery stroke and where the delivery stroke is arranged to occur at a relatively slow speed.
22. An apparatus according to any one of Claims 14 to 21, comprising a diffusion chamber which communicates with a delivery means, such as a •60722 delivery pipe, where additive is injected into the base fluid from a plurality of openings along a manifold located in the diffusion chamber and connected to the additive inlet so that additive injected into the diffusion chamber mixes with base fluid along the manifold to form an elongated body of mixed or partly mixed fluid, and the base fluid inlet means or the blender outlet means or part or parts of the diffusion chamber are restricted to regulate the flow and relative speed of fluid passing through the diffusion chamber so that there is overlap between successive elongated bodies of fluid passing through the diffusion chamber so that a substantially continuous stream of mixed fluid enters the delivery pipe from the blender outlet of the diffusion chamber.
23. An apparatus according to any one of Claims 14 to 22, wherein the manifold has openings on its upper surface so that additive is retained in the manifold.
24. An apparatus according according to any one of Claims 14 to 23, wherein the blending means or diffusion chamber is positioned below the delivery means so that the mixture of base fluid and additive is retained in the blending means or diffusion chamber.
25. An apparatus according to any one of Claims 14 to 24, wherein the blending means or diffusion chamber is positioned at an inclined angle so that air entrapment is avoided in the blending means or diffusion chamber.
26. An apparatus according to any one of Claims 14 to 25, wherein the blending means inlet and outlet pipes are raised in the delivery means so that the ingress of sludge or debris is avoided.
27. An apparatus according to any one of Claims 14 to 26, wherein the blending means inlet is arranged with a much lower resistance than the blender outlet so that the greater part of any flow surges which take place during injection will occur through the blending inlet means.
28. An apparatus according to any one of Claims 14 to 27, wherein scouring of the manifold is reduced or eliminated by having the manifold openings of small cross sectional area and of length which is relatively long in proportion to their width.
29. An apparatus according to any one of Claims 14 to 28, wherein the manifold openings are of small cross sectional area and of length which is relatively long in proportion to their width so that the speed of injection is reduced and so that substantially even flow occurs through each of the manifold openings during injection.
30. An apparatus according to any one of Claims 14 to 29, wherein two or more blending means are used in combination, with the base fluid of one blending means being the additive of another blending means.
31. An apparatus for use where additive is injected in discrete amounts through an additive outlet means into a base fluid delivery means, including an injection means which operates in a cycle which includes a delivery stroke and which delivers additive in discrete amounts through an additive outlet means into a base fluid delivery means characterised in that additive is injected into the base fluid at a plurality of positions along one or more paths of flow of the base fluid and the delivery stroke of the injection means is arranged to occur at a relatively slow speed so that the slugging effect of the injection means is reduced.
32. An apparatus for use where additive is injected in discrete amounts through an additive outlet means into a base fluid delivery means including a means for constructing a record of additive usage for use where additive is injected in discrete amounts through an additive outlet means into a base fluid delivery means and where injection is carried out on consecutive batch quantities, characterised in that the injection system operates on the basis of a continuous running total such that each new batch quantity picks up from where the previous batch quantity left off to preserve the overall proportions of additive to base fluid so that - 39 the error associated with slugging is eliminated when constructing a record of additive usage.
33. An apparatus for use where additive is injected in discrete amounts through an additive outlet means into a base fluid delivery means comprising a body including an inlet and an outlet each having a check valve, the inlet being connectable to an additive supply reservoir and the outlet being connectable to a base fluid delivery means, a cylinder located within the body and a piston operable to reciprocate with forward and reverse strokes within the cylinder to pump additive from the inlet to the outlet, characterised in that the injector cycle of operation is arranged to provide a preset delay period prior to each forward and reverse stroke sufficient to allow the check valves to come fully to rest and where the injector size is arranged such that the required stroke rate allows the necessary delay periods.
34. An apparatus according to Claim 33, wherein the injector is arranged with a relatively high stroke to diameter ratio so that the seal surface area is reduced in proportion to the cylinder capacity and the stroke length is increased in proportion to the cylinder volume.
35. An apparatus according to Claim 33 or 34, wherein the injector includes an actuator for reciprocating the piston and the injector and actuator are arranged such that the force developed by the actuator is much greater than the force required by the injector over the complete range of working pressures in the base fluid delivery means so that the effects of variations in working conditions on injector performances are reduced.
36. An apparatus according to any one of Claims 33 to 35, wherein the injector stroke capacity is arranged to be of a size which is sufficiently small such that unacceptable slugging does not take place but is sufficiently large such that the injector stroke provides adequate preset delay periods prior to each forward and reverse stroke sufficient to allow the check valves come fully to rest. »60722
37. An apparatus according to any one of Claims 33 to 36, wherein the injector is reciprocated by a pneumatic actuator and the actuator is provided with restrictor arrangements which control the speed of the actuator.
38. An apparatus for the secure addition of an additive to fluid dispensed from a delivery vehicle, which is required to deliver fluid with and without the additive and which is used in conjunction with an electronic flow counter comprising one or more memory devices and a means for the addition of an additive to fluid dispensed from a delivery vehicle, characterised in that the apparatus is provided with security means for denying or monitoring physical access to reprogramme or hack into the electronic flow counter, said security means being capable of physically isolating one or more of the memory devices.
39. An apparatus according to Claim 38, wherein said security means is a mechanical or electronic locking means and an enclosure means.
40. An apparatus according to Claim 38 or Claim 39, wherein said security means is a sealing means and an enclosure means.
41. An apparatus according to any one of Claims 38 to 40, wherein said security means includes a detection means for sensing when a circuit is broken on the occurrence of physical access or removal of part of the flow counter or for sensing activation of a sensor on the occurrence of physical access or removal of the flow counter.
42. An apparatus according to any one of Claims 38 to 41, wherein one or more of the memory devices comprising the flow counter are replaced by memory devices which cannot be reprogrammed.
43. An apparatus according to any one of Claims 38 to 42, wherein all or part of the security means is duplicated on an on-truck-computer and flow counter.
44. An apparatus for use where additive is injected in discrete amounts through an additive outlet means into a base fluid delivery means, substantially as herein described with reference to and as shown in the accompanying drawings.
45. A method of securely adding an additive to fluid dispensed from a delivery means, substantially as herein described with reference to the accompanying drawings.
IE960722A 1996-02-21 1996-10-14 Method and apparatus for securely adding an additive to¹fluid dispensed from a delivery means IE960722A1 (en)

Priority Applications (12)

Application Number Priority Date Filing Date Title
IE960722A IE960722A1 (en) 1996-02-21 1996-10-14 Method and apparatus for securely adding an additive to¹fluid dispensed from a delivery means
EP97905371A EP1009713B1 (en) 1996-02-21 1997-02-21 Apparatus for adding fluid additives to fluids
JP9529949A JP2000505402A (en) 1996-02-21 1997-02-21 Method and apparatus for adding a fluid additive to a fluid
CA002247095A CA2247095A1 (en) 1996-02-21 1997-02-21 Method and apparatus for adding fluid additives to fluids
US09/125,492 US6095371A (en) 1996-02-21 1997-02-21 Method and apparatus for adding fluid additives to fluids
DE69725623T DE69725623D1 (en) 1996-02-21 1997-02-21 DEVICE FOR ADDING LIQUID ADDITIVES TO LIQUIDS
CN97192499A CN1211964A (en) 1996-02-21 1997-02-21 Method and apparatus for adding fluid additives to fluids
BR9707732-1A BR9707732A (en) 1996-02-21 1997-02-21 '' method and apparatus for adding fluid additives to fluids ''
AT97905371T ATE252057T1 (en) 1996-02-21 1997-02-21 DEVICE FOR ADDING LIQUID ADDITIVES TO LIQUIDS
PCT/IE1997/000011 WO1997030930A2 (en) 1996-02-21 1997-02-21 Method and apparatus for adding fluid additives to fluids
AU22275/97A AU723888B2 (en) 1996-02-21 1997-02-21 Method and apparatus for adding fluid additives to fluids
US09/593,825 US6478189B1 (en) 1996-02-21 2000-06-13 Apparatus for adding fluid additives to fluids

Applications Claiming Priority (5)

Application Number Priority Date Filing Date Title
IE960151 1996-02-21
IE960306 1996-04-22
IE960369 1996-05-27
IE960462 1996-06-21
IE960722A IE960722A1 (en) 1996-02-21 1996-10-14 Method and apparatus for securely adding an additive to¹fluid dispensed from a delivery means

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IE960722A1 true IE960722A1 (en) 1997-08-27

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IE960722A IE960722A1 (en) 1996-02-21 1996-10-14 Method and apparatus for securely adding an additive to¹fluid dispensed from a delivery means
IES960721 IES77330B2 (en) 1996-02-21 1996-10-14 Method and apparatus for securely adding an additive to fluid dispensed from a delivery means

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IES960721A2 (en) 1997-08-27
IES77330B2 (en) 1997-12-03

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