I. Field of the Invention
This invention relates generally to fire fighting equipment, and more particularly to a control system for controlling the addition of a liquid chemical foamant to selected ones of a plurality of water delivery fire hoses such that the concentration of liquid chemical foamant at the discharge end of the fire hoses if maintained at a preset desired value as the water flow rate through the several hoses is made to vary.
II. Discussion of the Prior Art
Fire trucks, fire boats, military equipment and the like used in extinguishing large industrial fires will typically have a plurality of water discharge lines coupled through a manifold to a large capacity mid-ship pump where the discharge lines vary in size from those feeding a water cannon capable of delivering 1,000 gallons-per-minute or more to hand lines used in mopping-up operations that may carry 20 gallons-per-minute or less.
One of the most significant advancement in the filed of fire fighting has come through the use of chemical foamants specifically formulated to augment the fire fighting ability of water. Foam injection systems have been designed to introduce liquid chemical foamant concentrate into a water stream being directed at a fire. A key advantage to using such foams is the dramatic reduction in the time required to extinguish fires. It has been demonstrated that Class A foam is from five to ten more times more effective as a fire suppressant than water alone. Utilizing foam, fires are extinguished faster and with substantially less water damage. The foam proves to be an effective barrier, preventing fire from spreading and protecting adjacent structures. As is set out in the Arvidson et al. U.S. Reissue Pat. 35,362, the teachings of which are hereby incorporated by reference, it is desirable to have a foam injection system that is capable of automatically proportioning the foam additive in an exact concentration required for the specific fire-fighting problem, but without overusing and, therefore, wasting the chemical foamant. That patent describes a system that is readily suited to residential fires, automobile fires and those applications where water flow rates tend to be below 1,000 gallons-per-minute. Moreover, the system shown in the aforereferenced Arvidson Reissue Patent accommodates only a single injection point. In that fire vehicles designed for use in fighting large industrial fires may have several discharge lines of varying capacity, a need exists for a foam injection system that permits foam concentrate from a single storage tank to be injected into a plurality of water discharge lines where the water flow rate through the individual lines may vary drastically. For example, one discharge line may be feeding a water cannon while discharge lines are hand lines used in mopping operations.
A need exists for a foam injection system for use with a fire truck or other fire fighting apparatus where there is a plurality of discharge lines downstream from a main water pump. A desirable feature of such a system is to have some or all of the discharge lines capable of flowing a water/foam mixture, or water only, out the nozzle of the discharge lines. It will frequently happen that the foam/water proportioning in each line be different depending upon the type of fire being fought.
The foam proportioning system must also be capable of displaying a variety of parameters to fire-fighting personnel including, but not necessarily limited to, raw water flow rate, total water used, percent of foam concentrate in each of a plurality of water discharge lines, the total amount of concentrate used in all of the lines, a low concentrate supply warning, line pressure readings.
The foregoing objectives are achieved by providing a foam proportioning apparatus for controlling and monitoring the introduction of a liquid chemical foam concentrate into a plurality of water discharge lines in a fire-fighting system. The foam proportioning apparatus includes a tank in which a supply of a liquid chemical foamant is held. A foam pump couples the outlet of the tank to a plurality of foam concentrate delivery lines that are used to inject foam concentrate into a corresponding plurality of water discharge lines. A large capacity mid-ship pump delivers water through a manifold to that several water discharge line. Each of the water discharge lines having a foam capability includes a water flow meter that produces an electrical signal proportional to the volume rate of flow of water through the water discharge lines. Each of the foam concentrate delivery lines that are coupled individually to the water discharge lines also includes a flow meter that provides an electrical signal proportional to the volume rate of flow of liquid foam concentrate through that delivery line. An electrical control valve is disposed in series with the foam concentrate measuring flow meters in each of the concentrate delivery liens. The system further includes a plurality of microprocessor-based line controller modules that are arranged to receive as inputs, the outputs from an associated water flow meter and foam flow meter. The microprocessor-based controller is programmed to compare the actual proportion or concentration of liquid chemical foamant in the mixture exiting the discharge lines with a predetermined set point value and to develop a control signal, which when applied to the foam concentrate control valve, adjusts the introduction of foam concentrate until the desired set point value is attained. Further, a main controller module is connected to receive information from each of the several line controllers and it is programmed to develop a control signal for adjusting the operation of the foam pump to always insure an adequate supply of foam concentrate to the individual foam concentrate delivery lines.
The foregoing features, objects and advantages of the invention will become apparent to those skilled in the art from the following detailed description of a preferred embodiment, especially when considered in conjunction with the accompanying drawings in which:
With reference to
The foam proportioning system 10 is quite flexible in that it can be configured to control the injection of liquid chemical foamant into only selected ones of the plurality of discharge lines 16, 18, 20. In the depicted embodiment, the system is configured to inject foam concentrate into only discharge lines 16 and 18, leaving discharge line 20 to deliver water only.
For those discharge lines that are configured to deliver a water/foam mixture to a fire (lines 16 and 18), there is included in the water discharge line 16 a check valve, as at 28, and a water flow meter 30. A flow meter 32 is in discharge line 18. The water flow meters may be either of the common paddlewheel-type or they may be commercially available magnetic-type flow meters. Smaller lines may use a more economical paddle-wheel design while larger (typically 4 in. and higher) lines will preferably use the magnetic type of flow meter. The magnetic style flow meters exhibit a wider flow range and are less affected by turbulence and can be used where straight inlet runs are limited in length.
Liquid foam chemical concentrate is contained within a refillable storage tank 34 carried by the fire-fighting vehicle. The tank has an outlet 36 coupled to an inlet port 38 of a foam supply pump 40. The foam supply pump 40 may be a positive displacement pump preferably like that described in co-pending U.S. patent application Ser. No. 10/140,254, filed May 6, 2002, and entitled “Variable Displacement, Positive Displacement Pump”, the contents of which are hereby incorporated by reference. That pump has a control shaft that can be manually turned or turned by a motor to thereby change the angle of a swash plate to thereby change the displacement of the pump's plungers. The crank shaft of the pump 40 is adapted to be coupled to the power take-off of the engine for the fire-fighting vehicle causing the pump's plungers to deliver the liquid chemical foam concentrate under pressure through the line 42 to foam concentrate delivery lines 44 and 46. There is one such delivery line for each water line that is to have a foam capability.
Foam concentrate delivery line 44 is associated with water discharge line 16 while foam concentrate delivery line 46 is associated with water discharge line 18. In the exemplary embodiment of
Also included in the foam concentrate delivery lines 44 and 46 are injection check valves as at a 56 and 58 which serve to keep water and foam concentrate from mixing on their own.
Associated with each of the foam concentrate delivery lines is a line controller module as at 60 and 62. Line controller module 60 receives input electrical signals from the water flow meter 30, via conductor 64, and electrical input signals from the foam flow meter 48 by way of conductor 66. In the drawing of
As will be explained in greater detail below, each of the line controllers includes a microprocessor that monitors the water flow meter and the foam flow meter and provides a drive signal to an associated control valve. Thus, line controller 60 provides a control signal over conductor 68 to the foam control valve 52 to adjust its orifice size. In a similar fashion, line controller 62 receives input signals from the water flow meter 32, via conductor 70, as well as electrical signals from the foam concentrate flow meter 50, via conductor 72. The line controller 62 then provides an appropriate DC signal over line 74 to the foam control valve 54.
The microprocessors in the line controllers 60 and 62 provide data to a main controller 76, via buses 78 and 80, to set the amount of total foam concentrate that needs to be delivered to the individual lines to satisfy their rate of discharge. To vary the flow rate of foam concentrate through the line 42, the main controller 76 provides an appropriate electrical signal over conductor 82 to a DC motor 84 that is connected in driving relation to the swash plate control shaft of the positive displacement variable displacement foam pump 40. In this fashion, the main controller is capable of adjusting the displacement of the pump 40 to deliver the total required foam to the system.
While the positive displacement variable displacement foam pump described in the aforereferenced Maki et al. patent application is well suited to the foam proportioning system of the present invention, those skilled in the art will appreciate that a hydraulic gear pump and hydraulic motor of appropriate capacity may also be employed and, in this event, the control signal on line 82 would be such as to vary the speed of the hydraulic motor to produce the required total foam flow for the system.
Having described the overall layout of the foam proportioning system configured in accordance with the present invention, a more specific explanation of the constructional and operational features of the proportioning system 10 will now be described.
As is typical with fire-fighting apparatus, there are a plurality of discharge lines 16, 18 and 20 downstream of a main water pump 12. The system may be required to have some, or all, of these discharge lines capable of flowing a water/foam mixture, or water only, out the discharge nozzles 22, 24 and 26. In addition, each foam/water mixture line typically requires a different foam-to-water proportion, depending on the nature of the fire being fought. Thus, each discharge line must be planned and constructed during the construction of the fire-fighting assembly, be it a pumper vehicle, a fireboat, or other apparatus. The actual number of total lines and foam capable lines in a given system will vary as the system is designed. The proportioning ratios are determined in the line controllers 60 and 62 for each foam capable line. In the system of
As indicated, for each foam capable water discharge line, there must be one associated foam concentrate delivery line.
Considering the make-up of the foam concentrate delivery lines, the injection check valves 56 and 58 employed preferably, but not necessarily, may have a minimum cracking pressure of 6 psi and a 400 psi minimum working pressure. The injection check valves are also made from materials that are capable with the foam being pumped. The inlet of the check valves 56 and 58 connect to the outlet from the foam control valves 52 and 54 and the outlet of the check valves 56 and 58 are connected to the associated water discharge lines which thereby receive the proportioned foam flow. The foam control valves preferably each comprise a two-way ball valve having a minimum working pressure of about 400 psi. The valve includes an electrical device to variably open, meter and close the valve orifice. As mentioned, the associated line controller 60 or 62 provides the control signals for the valve.
The foam flow meters 48 and 50 may also have a minimum pressure rating of 400 psi working pressure and is designed to produce a digital pulse signal proportional to the foam flow and this signal is delivered to its associated line controller 60 or 62. Power supplied to the flow meter can be either 12 volt or 24 volt automotive DC, depending upon the battery powering the fire-fighting vehicle in which the foam proportioning system 10 is incorporated.
The line controllers are the principal control mechanism for the operation and processing of information to inject the proper amount of foam into the appropriate water discharge line to achieve a preset (preprogrammed) foam/water concentration. The line controllers receive the flow meter signals from both the water flow meters and the foam flow meters to determine two parameters. One parameter is the displacement or volume of foam required to be delivered from the foam delivery system. The other parameter is to determine the correct positioning of the foam control valves to allow the correct amount of foam to be injected into their respective discharge lines. The objective is to find a balance between the foam delivery system including the pump 40 and the positioning of the foam control valves in the respective foam concentrate delivery lines.
As best seen in
Referring still to
The main controller 76 comprises the hub of the system 10, receiving flow information from all of the line controllers to determine the amount of foam flow to generate. The main controller 76 accordingly adjusts the displacement of the foam pump 40 (
Turning next to
The line control microprocessor 112 is also arranged to communicate with a downstream line controller as well as with the main controller and, in this regard, there is provided a “Bus In” connector 118 and a “Bus Out” connector 120 that connect through a two-wire differential serial bus interface 122 under control of a bus control module 124. It has been found expedient to use the Controller Area Network (CAN Bus) architecture as outlined in ISO 11898. Such a CAN Bus operates in noisy electrical environments with a high level of data integrity and its open architecture and user-definable transmission medium make it extremely flexible.
The modules 100-104 and 76 in
Turning next to
Also providing an input to the pump control microprocessor 126 is a float sensor 130 that is disposed in the chemical supply tank 34 to provide an indication that an adequate quantity of liquid chemical foamant is present in the tank so that operation can continue. The power take off (PTO) of the fire vehicle also provides a signal to indicate that it is running. It is referred to as the “Pump Engaged Input” 132 in
The current monitor 117 comprises a very low value resistor on a ground end of a bridge circuit in the motor driver 138 whose voltage drop is proportional to the current being drawn by the swash plate motor 84. A RC filter is connected to the top of the resistor and connects to an input of a voltage amplifier. The output of the amplifier is inputted to the pump control microprocessor 126 and a current overload detector.
The monitor circuit 117 serves two purposes. First, it provides the microcontroller 126 with an analog value representative of the actual average motor current drawn by the swash plate motor 84. The pump control microprocessor 116 is constantly monitoring the current level several times a second. When the swash plate motor 84 drives the swash plate to an end position, the current will rise and the motor stepping pulses go to zero. By running the motor to both end points for the swash plate, the pump control microprocessor can determine the value of pump 40 output based on speed sensor 128 pulses (e.g. X pulses=1 gallon). The microprocessor-based pump controller 126 can then, during operation, move the swash plate to a predicted value based on sensor pulse counts. This allows for more rapid movement to get close to a desired operating set point before correction based upon actual flow meter readings take over.
The second function of the monitor circuit 117 is to protect the electronics from severe overload conditions. It does this by disabling the motor driver 138 whenever the current being drawn exceeds a predetermined value, say, 30 amps, for longer than a predetermined monitor filter time, say about 50 ms. The overload also sets an “overload detected” latch that indicates to the pump control microprocessor 126 that an overload has occurred and that a diagnostic routine should be run to determine the cause of the overload.
In that the bus structure for the main controller module is identical to that used with the line controller and which has been explained above, no further discussion thereof is deemed necessary.
This invention has been described herein in considerable detail in order to comply with the patent statutes and to provide those skilled in the art with the information needed to apply the novel principles and to construct and use such specialized components as are required. However, it is to be understood that the invention can be carried out by specifically different equipment and devices, and that various modifications, both as to the equipment and operating procedures, can be accomplished without departing from the scope of the invention itself.