Abstract:
Disclosed is a conduit expansion method, including: inserting a liner conduit formed from a polyvinyl chloride material at least partially within a host conduit; circulating fluid within an inner area of the liner conduit; and injecting fluid into the inner area of the liner conduit; wherein the liner conduit at least partially expands within the host conduit.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application is a divisional application of U.S. application Ser. No. 10/865,503, filed Jun. 10, 2004, which takes priority from U.S. Provisional Patent Application Nos. 60/478,508 and 60/478,513, both filed Jun. 13, 2003, all of which are incorporated herein by reference in their entirety. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates generally to systems for expanding conduit, such as polyvinyl chloride piping, and in particular to a fluid processing system for injecting and recycling fluid to and from a conduit expansion system, and to a mobile or transportable arrangement and fluid processing system. 
     2. Description of Related Art 
     Conduit systems are used extensively throughout the world in order to transfer or convey material, such as water and other fluids, from location to location for distribution throughout the system. For example, extensive conduit systems are used to distribute water to both residences and businesses for use and further processes. Typically, such conduit or piping systems are located underground, as aboveground piping would be both unsightly and intrusive. 
     Typical water conduit systems transport material through pipe, e.g., cast iron, ductile iron, reinforced concrete, cement-asbestos, etc., buried underground with the branches extending in various directions in order to reach the end user. Normally, after many years of use, or for some other reason, the present piping fails and begins to leak, thereby reducing line pressure and unnecessarily allowing water to leak into the area surrounding the piping. Such leaks not only affect the system, but also increase the processing costs of the supplier, which, in turn, increases the end user costs. Therefore, these leaks must be quickly repaired and preventative measures taken to ensure that further leakage is prevented. 
     Due to the underground positioning of the conduit system, repairing a leaking pipe is particularly labor intensive and time consuming. Trenches must be dug along the pipeline to locate the leak and effectively repair it prior to putting the pipe back in service. Various lining systems have been developed according to the prior art in an attempt to seal a leaking pipe or a pipe that has fallen into disrepair, whether to repair a present crack or to preventatively ensure against future cracks or breaks. In addition, the use of a much smaller diameter pipe within the larger diameter cracked or broken pipe has been used. However, this merely replaces the problem of a cracked outer pipe with a cracked or otherwise leaking inner pipe. Still further, using such a pipe-in-pipe system drastically reduces the flow through the conduit system and evidences unwanted and varying pressure parameters. 
     To that end, a pipe liner and method of installation have been developed, as disclosed in U.S. Pat. No. 5,794,662 to St. Onge et al., specifically directed to pressurized pipeline applications. The St. Onge patent is directed to a method of relining sewer lines, water lines or gas lines, and uses a segmented liner of reduced size relative to the pipe being relined. However, as opposed to merely leaving the small diameter liner conduit within the large diameter outer conduit, the method of the St. Onge patent uses heat and/or pressure to mold the reduced size pipe to the shape of the pipe being relined. In particular, the inner or liner conduit is a thermoplastic pipe, typically a polyvinyl chloride (PVC) pipe that, when exposed to heat or pressure, expands and molds against the inside of an existing conduit to effect the relining of it. This process allows for both the lining of the entire length of pipe or only a portion of it that is damaged, which is typically referred to as “spot repair.” 
     According to the St. Onge patent, once the length of the liner conduit is inserted into the existing or host conduit, the liner conduit is plugged at either end and exposed to steam under pressure to heat the liner conduit along its length and apply pressure, which urges it to expand and contact the interior walls of the surrounding host conduit. Once the liner conduit has fully expanded to conform to the interior surface of the existing conduit, it is cooled and the plugs are removed. The resulting expanded liner conduit conforms to the walls of the host conduit, thereby preventing any further leakage. Also, the method of the St. Onge patent requires only pits to be dug at either end of the section to be repaired. 
     While the St. Onge patent represents an advance in the art of relining or repairing underground conduit systems, there is room in the art for additional improvements and advancements. Further, the injection or insertion of material or objects into a conduit, for use in repairing or replacing damaged pipe, is known in the art. For example, see U.S. Pat. No. 6,228,312 to Boyce; U.S. Pat. No. 5,503,190 to Kamiyama et al.; U.S. Pat. No. 5,490,964 to Kamiyama et al.; U.S. Pat. No. 5,225,121 to Yokoshima; U.S. Pat. No. 6,050,300 to Schwert et al.; U.S. Pat. No. 4,361,451 to Renaud; U.S. Pat. No. 6,539,979 to Driver; U.S. Pat. No. 5,399,301 to Menendez et al.; U.S. Pat. No. 5,816,293 to Kiest, Jr.; U.S. Pat. No. 5,346,658 to Gargiulo; and U.S. Pat. No. 6,093,363 to Polivka. However, the use of heat and/or pressure includes various problems that require a solution. Typically, steam and compressed air are injected in the liner conduit, and this has been successfully accomplished in small sizes in a safe manner. However, as the scale of the process increases, it becomes obvious that the energy from compressible gases in an extended large diameter pipe could be extremely dangerous. In addition, this steam/air injection has little reaction time to respond to process upsets. Still further, the prior art systems do not teach the use of fluid processing system that is integral with and operational in connection with a conduit expansion process. 
     There also remains a need for mobilizing or otherwise providing an ability to transport equipment utilized in the conduit expansion process in a mobile manner. Various prior art systems have been provided that mobilize various portions of a fluid system, for example U.S. Pat. No. 6,416,692 to Iwasaki-Higbee; U.S. Pat. No. 5,924,455 to Jo et al.; U.S. Pat. No. 5,816,293 to Kiest, Jr.; U.S. Pat. No. 5,501,248 to Kiest, Jr.; U.S. Pat. No. 6,050,300 to Schwert et al.; U.S. Pat. No. 6,539,979 to Driver; and U.S. Pat. No. 5,601,763 to Hunter et al. However, these systems do not allow for a transportable and integrated fluid expansion system. Thus, a need remains for a conduit expansion system that can be assembled on a mobile platform to allow conduit expansion to be routinely done at project locations. 
     SUMMARY OF THE INVENTION 
     It is, therefore, an object of the present invention to provide a fluid system for conduit expansion that overcomes the deficiencies of the prior art. It is another object of the present invention to provide a fluid system for conduit expansion that includes a controlled and safe injection of fluid material from a fluid processing system to a conduit expansion system. It is a still further object of the present invention to provide a fluid system for conduit expansion that has inherent stability greater than the prior art. It is yet another object of the present invention to provide a fluid system for conduit expansion that provides uniform expansion of the liner conduit along the length of the expanded liner conduit. It is another object of the present invention to provide a mobile conduit expansion system that overcomes the deficiencies of the prior art. It is a further object of the present invention to provide a system and arrangement for conduit expansion that uses, for example, hot water, that is mobile and easily transportable to a repair site. It is a still further object of the present invention to provide a system and arrangement for conduit expansion that is mobile and allows for a consistent and repeatable conduit expansion process. 
     In one preferred and non-limiting embodiment, the present invention is directed to a fluid system for conduit expansion for expanding a liner conduit within a host conduit, specifically where the liner conduit is expanded within the host conduit and pressed against an inside wall of the host conduit. The fluid system is a fluid processing system having a fluid injection source for injecting a fluid, such as water, into the conduit expansion system, typically the inside of the liner conduit. In addition, the system includes a fluid recycle return from the conduit expansion system for reprocessing in the fluid processing system. A fluid source provides water to the fluid processing system for further processing and subsequent injection into the conduit expansion system. 
     In another preferred and non-limiting embodiment, the present invention is directed to a mobile fluid system for use in connection with a conduit expansion system for expanding a liner or conduit within a host conduit. The mobile system includes a mobile unit having a platform upon which to include equipment and is capable of transporting equipment for a conduit expansion process to a location or job site. The platform is preferably a chassis-type structure being of a rigid material capable of withstanding excessive weight and force. Additionally, the platform may include hooks located at the front and rear bumper by which to be transported. 
     The platform includes a fluid system having a control system. The fluid system may include a fluid tank, a fluid heater, a plurality of pumps, an air blower and the like. The control system may include a PLC and a computer, which is used to communicate and monitor variables, such as temperature and pressure during the conduit expansion process. Additionally, the platform may include other equipment such as a generator, pumps, blowers, compressors, and the like, as well as storage areas for tools and hardware. Preferably, the major components of the conduit expansion system are enclosed in compartmentalized bodies or structures. Such structures will be commonly recognized in appearance and functional standards as known in the truck body industry. 
     The present invention, both as to its construction and its method of operation, together with the additional objects and advantages thereof, will best be understood from the following description of exemplary embodiments when read in connection with the accompanying drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a schematic view of a fluid system for conduit expansion according to the present invention; 
         FIG. 2  is a schematic view and flow diagram of a preferred embodiment of a fluid system for conduit expansion according to the present invention; 
         FIG. 3  is a schematic view and flow diagram of a further preferred embodiment of a fluid system for conduit expansion according to the present invention; 
         FIG. 4  is a top schematic view of a mobile fluid system for conduit expansion according to the present invention; and 
         FIG. 5  is a side schematic view of a further preferred embodiment of a mobile fluid system for conduit expansion according to the present invention. 
     
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     For purposes of the description hereinafter, the terms “upper”, “lower”, “right”, “left”, “vertical”, “horizontal”, “top”, “bottom” “lateral” and “longitudinal” and derivatives thereof shall relate to the invention as it is oriented in the drawing figures. However, it is to be understood that the invention may assume various alternative variations and step sequences, except where expressly specified to the contrary. It is also to be understood that the specific devices and processes illustrated in the attached drawings, and described in the following specification, are simply exemplary embodiments of the invention. Hence, specific dimensions and other physical characteristics related to the embodiments disclosed herein are not to be considered as limiting. 
     Other than in the operating examples or where otherwise indicated, all numbers or expressions referring to quantities of ingredients, reaction conditions, etc., used in the specification and claims are to be understood as modified in all instances by the term “about.” Various numerical ranges are disclosed in this patent application. Because these ranges are continuous, they include every value between the minimum and maximum values. Unless expressly indicated otherwise, the various numerical ranges specified in this application are approximations. 
     The present invention is a fluid system  10  for use in connection with a conduit expansion process and is illustrated in various embodiments in  FIGS. 1-5 . Specifically, with reference to  FIG. 1 , the fluid system  10  is typically used in connection with a liner conduit  100  that is positioned within a host conduit  102  in a conduit expansion system  12 . In a preferred embodiment, this liner conduit  100  is manufactured from a thermoplastic material, such as polyvinyl chloride. However, it is envisioned that any material having the appropriate expansion characteristics can be used, and this fluid system  10  works equally effectively with any expandable liner conduit  100  in a conduit expansion system  12 . 
     Referring to  FIG. 1 , the fluid system  10  includes a fluid processing system  14  for processing a fluid emanating from a fluid source  16 . The processed fluid is injected into the conduit expansion system  12  (and typically the liner conduit  100 ) via a fluid injection source  18 , and after the fluid has been used beneficially in the conduit expansion system  12 , it is returned to the fluid processing system  14  via a fluid recycle return  20 . Next, the fluid processing system  14  reprocesses the fluid for reuse in the conduit expansion system  12 . 
     It should be noted that the above-discussed systems, and the specific arrangement of the components and subcomponents of these systems, as discussed in detail hereinafter, represent only exemplary embodiments. It is envisioned that the fluid may be both injected through and recycled from fluid injection source  18 , while alternatively, the fluid may be injected through the fluid injection source  18  and removed through the fluid recycle return  20 . It is only necessary that the fluid is somehow inserted or injected appropriately into the conduit expansion system  12  and, if required, removed therefrom. 
     In one preferred and non-limiting embodiment, as shown in  FIG. 2 , fluid, typically water, is injected into the conduit expansion system  12  via the fluid injection source  18 , as driven by a circulation pump  22 . After use in the conduit expansion system  12 , the used or spent fluid is returned to the fluid processing system  14  via the fluid recycle return  20 . As used and discussed hereinafter, an enormous benefit is recognized by the present invention by using elevated temperature water, since hot water is relatively incompressible and will not fluctuate in temperature or pressure as rapidly as steam and/or air. In addition, since heated water does not have as high of a BTU content as, for example, steam, circulation and BTU replacement issues do not arise as in prior art systems. Therefore, as set forth in detail hereinafter, the fluid will be referred to as water or hot water. The fluid processing system  14  may be either a low or high pressure system. 
     In a preferred and non-limiting embodiment, the hot water is of sufficient temperature to effect the expansion of the liner conduit within the host conduit. Typically, hot water, having a temperature of at least 125° F., in some cases at least 150° F., in other cases at least 175° F., and in some situations at least 200° F. is used. The water is circulated in the liner conduit  100  until all of the walls of the conduit  100  approach the temperature of the water. 
     After the water is returned to the fluid processing system  14  via the fluid recycle return  20 , it is transferred into a fluid heater  24 . The fluid heater  24  re-elevates or heats up the water, and the circulation pump  22  replaces the water in the conduit expansion system  12  via the fluid injection source  18 . Prior to return of water through the fluid heater  24 , a drain  26  may be used to remove excess water. In addition, a bleed line  28  may be used to bleed off water and/or reduce pressure in the fluid processing system  14 . 
     Hot water may also be added near the exit of the fluid heater  24 . Specifically, water may be drawn from a fluid vessel  30  and moved into the system  10  via an expansion pump  32 . A bypass line  34  may also draw from the fluid vessel  30 , however the bypass line  34 , specifically the water in the bypass line  34 , is not processed through the expansion pump  32 . 
     Water is transferred into the fluid vessel  30  via the fluid source  16 , and this fluid source  16  can be any number of water sources, for example a fire hydrant or the like. In addition, the fluid vessel  30  includes an overflow line  36  for use in conditions where the water in the fluid vessel  30  is excessive in volume. 
     As shown in  FIG. 2 , any one or more of the components or subcomponents of the fluid processing system  14  may be controlled and/or monitored by a control mechanism  38 . While in the fluid processing system  14  illustrated in  FIG. 2 , the control mechanism  38  is shown to be in communication with the fluid heater  24 . It is envisioned that the control mechanism  38  can be in communication with any of the components or subcomponents, whether individually or collectively, in the fluid processing system  14 , the fluid source  16  and/or the conduit expansion system  12 . This control mechanism  38  provides computerized control of the measurement and control devices, such as valves, check valves, meters, gauges and the like. In addition, the control mechanism  38  collects information for use in research and developing an improved and more efficient fluid system  10 . 
     In one preferred and non-limiting embodiment, the fluid heater  24  is a single pass heating device with an output of about 60 gallons per minute. In the first pass, the fluid heater  24  can elevate the temperature of the water to 180° F., and, thereafter, use a diesel-operated heating system to further elevate the temperature from about 200° F. to about 210° F. The fluid heater  24  is used to control the temperature of the water in the range of 150° F. to 210° F. By using modified connections on the fluid heater  24 , the elevated or heated water can be quickly heated and returned to the conduit expansion system  12  for further use. 
     From the inlet from the conduit expansion system  12  (fluid recycle return  20 ), the hot water moves through a basket strainer  54  and into the circulation pump  22 . The circulation pump  22  transfers the water through a check valve  46  and into the system for further processing, for example back to the first heater unit  42 . In addition, the outlet of the circulation pump  22  includes an air release  56 , as well as a measurement device  58 . In this embodiment, the measurement device  58  measures pressure. In addition, this outlet line of the circulation pump  22  includes a flow meter  60  for measuring and monitoring flow into the fluid injection source  18 . 
     Another preferred and non-limiting embodiment is illustrated in  FIG. 3 . Beginning with the fluid recycle return  20  (or inlet from conduit expansion system  12 ), the water flows through valve  40  and into the fluid heater  24 . Since the system  10  can optionally have more than one fluid heater  24 , the water at this point will flow into the first heater unit  42 . The water may optionally be transferred through valve  44  and into the fluid vessel  30 . After heating by the first heater unit  42 , the hot water is moved through a check valve  46  and further through valve  48 . At this point, the water may move through a pressure relief valve  50  and back into the fluid vessel  30 , or through the added pressure relief dump valve  52 , and, again, to the fluid vessel  30 . 
     Returning to the fluid injection source  18 , the water may move through valve  62 , which acts as the main loop control valve, and, thereafter, interacts with multiple measurement devices  58 , one measurement device  58  measuring temperature and the other measurement device  58  measuring pressure. In addition, the water moves through a flow meter  60  after encountering valve  62 . Finally, the hot water is transferred to the outlet to the conduit expansion system  12  (fluid injection source  18 ). 
     With respect to the fluid vessel  30 , the water in the fluid vessel  30  is transferred through the expansion pump  32  and may be returned back to the fluid vessel  30  via valve  64 . Alternatively, the water may move by measurement device  58 , through check valve  46 , further through flow meter  60  and through valve  66 , where it is injected into the outlet of the first heater unit  42 . The water then flows along the previously-discussed path of check valve  46  and valve  48 . Optionally, the discharge of the expansion pump  32  can also flow to or connect to the discharge of the circulation pump  22 . 
     The fluid vessel  30  may be equipped with a sight glass  68  or other level sensing or monitoring device for viewing or sensing the level of water in the fluid vessel  30 , and is used in conjunction with the overflow line  36  for managing the volume of water in the fluid vessel  30 . In addition, the water enters the fluid vessel  30  from the fluid source  16 . Specifically, the water moves through check valve  46 , through valve  70  and further through check valve  46  and into the fluid vessel  30 . 
     When using a second heater unit (not shown), water moves from the outlet of this second heater unit to the inlet from the second heater unit and through valve  72 , where it proceeds along the same path from the circulation pump  22  as discussed in connection with the previously-discussed first heater unit  42  outlet. Similarly, water can be returned to the second heater unit through valve  74  and into the inlet of the second heater unit. 
     In this manner, the present invention provides a fluid system  10 , including one or more fluid heaters  24 , for use in connection with a conduit expansion system  12 . This system provides controlled movement of water through the fluid processing system  14  and into the conduit expansion system  12 . This water is monitored at various points throughout the system for pressure, temperature, flow, etc. in order to allow for efficient control as well as further system  10  monitoring. In addition, the fluid heater  24  provides this beneficial hot water to the conduit expansion system  12  in a controlled and inherently safer manner. In addition, the use of hot water provides a more stable system and a more uniform heat distribution in the liner conduit of the conduit expansion system  12 . Therefore, the fluid system  10  drastically increases the safety, stability and uniformity of the material used in the conduit expansion system  12 . 
     Example 
     The fluid processing system  14  is capable of providing a variable flow rate of up to 350 gallons per minute up to a pressure of 150 to 200 psi. In addition, the expansion pump  32  also provides a variable flow rate through the piping system up to 70 gallons per minute at a pressure of up to about 210 psi. The fluid heater  24  is a 3.4 MBtu/hour enclosed-flame diesel-powered water heater. 
     The fluid vessel  30  may have varying capacities, for example, 250 gallons. This fluid vessel  30  allows for inlets from the surge of the hot water fill through valve  44 , inlets from the various pressure relief valves  50  and  52 , as well as bypass inlet through valve  64 . In addition, the fluid vessel  30  uses a sight glass  68 , in conjunction with the overflow line  36  for controlling the water in the fluid vessel  30 . 
     The circulation pump  22  and expansion pump  32  should meet the required specifications of the system, for example, the circulation pump  22  may be a 25-30 HP motor with a maximum flow of 350 gallons per minute, while the expansion pump  32  may be a 5-10 HP motor with a maximum flow of 70 gallons per minute. Check valves  46  are used in connection with the other valves of the system to prevent movement of water in the undesired direction. For example, valve  70  can be a backflow preventer for ensuring that water does not move back into the fluid source  16 . All of the check valves  46 , valves and measurement devices  58  operate in a manner as known in the art. 
     The fluid heater  24  should be capable of continuous operation and located downstream of the circulation pump  22 , such that water supplied to the expansion loop is on the last pass through the fluid heater  24 . In addition, the water from the expansion pump  32  should be injected into the fluid heater  24  inlet. The fluid heater  24  should be equipped with a suitable temperature control for maintaining the water temperature under operating conditions after the initial and desired temperature is reached. Still further, the fluid heater  24  should be equipped with any appropriate safety devices for preventing the occurrence of unsafe or potentially damaging conditions. For example, the fluid heater  24  may be supplied with a flame detection circuit, water flow monitors, air flow monitors, spark arresters and temperature switches as needed. 
     The control mechanism  38  may be in the form of a personal computer, a laptop, a PDA, a printed circuit board, a computerized mechanism, or other means for automatic control of the various components and subcomponents of the fluid processing system  14 . For example, the measurement devices  58  may transmit information remotely to the control mechanism  38  and receive control signals from the control mechanism  38  in a wireless or hardwired format. Various diagnostics can be monitored while the fluid processing system  14  is in operation. Further, the control mechanism  38  for the fluid processing system  14  may also be used in connection with the conduit expansion system  12  and the fluid source  16 . 
     The present invention is also directed to a mobile fluid system  80  for use in connection with the conduit expansion system  12 , and this mobile fluid system  80  is positioned on or within a mobile unit  82  for use in connection with the conduit expansion process and is illustrated in various embodiments in  FIGS. 4 and 5 . The mobile unit  82  may be referred to as a mobile pipe expansion vehicle, mobile conduit expansion unit or the like. The mobile unit  82  is designed to provide the capabilities required for expansion of replacement structural water lines in systems such as stand-alone structural systems used to rehabilitate pressure lines, such as water lines, force mains and other industrial lines. As discussed above, one such example of a process is a conduit expansion process and system  12 , which is typically used in connection with the liner conduit  100  positioned within the host conduit  102  in the conduit expansion system  12 . 
     The mobile conduit expansion system  80  includes a mobile unit  82 , such as a truck, a vehicle, a trailer, and a skid, having a platform  84  upon which to secure equipment, and which is capable of transporting equipment for a conduit expansion process to a job site. The platform  84  may include steps or a ramp, to facilitate entry, exit and access to the equipment. As illustrated in  FIGS. 4 and 5 , the equipment on the platform  84  preferably includes the fluid system  10  discussed above, including at least a fluid heater  24 , a fluid vessel (not shown) and a control system  38 , as well as a generator  86  and storage area  88 . While the present invention is referred to in terms of a fluid system  10  and control system  38 , it is by no means limited to only a fluid system  10  and control system  38 . The equipment on the platform  84  may relate to pressure systems, heat systems, and the like, and will include equipment as known by one skilled in the art, such as the generator  86 , as well as pumps and valves utilized in the system and process. 
     The platform  84  is preferably a chassis-type structure being of rigid material capable of withstanding excessive weight and force. The chassis is preferably rated to sustain loads imposed by the vehicle at highway speeds. The chassis may also include hooks  90  located at the front and rear bumper by which to be transported. Additional equipment that may be located on the chassis, including those described hereinafter, may include the following: heater/defroster, lights, electric wipers and washer, rearview mirrors, vinyl seat trim, etc. Optionally, an engine hour meter may be located in the cab to record truck engine operating hours. 
     Items may be located in various areas on the platform  84 . For example, while a pump may be placed on the platform  84 , it may also be located underneath the platform  84 . Another example includes placing a hose reel for an air compressor or even a hose storage rack on the bottom or back of the platform  84 . Thus, the equipment may be arranged in such a manner so as to allow efficient use of space on the platform  84 , allow for placement of equipment in a desired process arrangement, etc. 
     The mobile fluid system  80  positioned on the mobile unit  82  operates substantially as described above in connection with the fluid system  10 . Accordingly, the mobile fluid system includes the fluid processing system  14  for processing a fluid emanating from a fluid source  16 . The fluid processing system  14  operates as described above. 
     The mobile fluid system  80  also has adequate access to components for servicing or removal of the equipment positioned on the mobile unit  82  and/or platform  84 . Isolation shutoff valves may be installed at locations where large spillage may occur if a line were to break or a valve where needed for safe operation of the mobile unit  82 . A back flow preventer may also be installed on the inlet of the fill line to prevent water from back flowing, which is particularly undesirable in the mobile fluid system  80 . The water system also includes a dump valve to remove water from the loop during initial heat-up with an outlet connected to the water tank. The system may also include a deaerator at the inlet to the heater. 
     As with the fluid system  10  described above, the mobile fluid system  80 , and any one or more of the components or subcomponents of the mobile fluid system  80  may be controlled and/or monitored by the control system  38 , also positioned on or within the mobile vehicle  82 . The control system  38  may include a room having a PLC and a computer used to communicate and monitor temperature and pressure of the conduit expansion system  12 . While in the fluid processing system  14 , the control mechanism  38  is shown to be in communication with the fluid heater  24 , it is envisioned that the control mechanism  38  can be in communication with any of the components or subcomponents, whether individually or collectively, in the fluid processing system  14 , the fluid source  16  and/or the conduit expansion system  12 . 
     Additional process controls in the control system  38  may include remote-mounted temperature and pressure sensors using wireless data transmission. Additionally, the control room may include on/off controls within the control room for the heater. Other heater control box displays (LED) may include heater performance features, such as hours of operation, fuel pressure, de-icing water temperature, diagnostic features located at the heater. 
     Overall, the components of the mobile fluid system  80  are preferably enclosed in a compartmentalized type structure, with the platform  84  body having an external appearance of one continuous enclosure. The heater exhausts preferably exit toward the top side of the mobile unit  82  to minimize damage to equipment parked to either side. Shrouding may be utilized to cover in efforts to help minimize noise. Additionally, the platform  84  may include storage areas for tools, hardware and pipe storage compartments. Access doors may be included to aid in maintenance as well as lockable latches. Louvers may also be provided for adequate ventilation. 
     In this manner, the present invention also provides a mobile fluid system  80 , including the fluid processing system  14  and a control system  38  for use in connection with a conduit expansion system  12 . This system  80  provides for the controlled movement of fluid, preferably water, through the fluid processing system  14  and into the conduit expansion system  12 . The mobile fluid system  80  drastically increases the ease with which to transport equipment used for, as well as perform, the conduit expansion process. It also increases safety, stability and uniformity of the process. 
     Example 
     The mobile fluid system  80  includes a Ford F-650 truck chassis as the mobile unit  82 , which includes a platform  84 , and has a 7.2 L diesel engine, automatic. Power steering and hydraulic braking systems are provided. Axle ratings of the chassis may be about 8,500 lbs on the front axle, about 17,500 lbs on the rear axle and about 26,000 lbs total. The chassis batteries include two 550 CCA each for a total of 1100 CCA Group 31. The wheelbase may be 194″ with a CA of 120″. The fuel tank of the chassis may have a capacity of about 50 gallons. 
     The fluid processing system  14  is capable of providing a variable flow rate of up to 350 gallons per minute up to a pressure of 150 psi. In addition, the expansion pump also provides a variable flow rate through the piping system up to 70 gallons per minute at a minimum pressure of 210 psi. The fluid heater  24  is a 3.4 MBtu/hour enclosed-flame diesel-powered water heater. 
     The fluid vessel may have varying capacities, for example, 250 gallons. This fluid vessel allows for inlets from the surge of the hot water fill through a valve, inlets from the various pressure relief valves, as well as a bypass inlet through a valve. In addition, the fluid vessel uses a sight glass, in conjunction with the overflow line for controlling the water in the fluid vessel. 
     The circulation pump and expansion pump should meet the required specifications of the system, for example, the circulation pump may be a 25 HP motor with a maximum flow of 350 gallons per minute, while the expansion pump may be a 5 HP motor with a maximum flow of 70 gallons per minute. Check valves are used in connection with the other valves of the system to prevent movement of water in the undesired direction. For example, valves can be a backflow preventer for ensuring that water does not move back into the fluid source  16 . All of the check valves, valves and measurement devices operate in a manner as known in the art. 
     The fluid heater  24  should be capable of continuous operation and located downstream of the circulation pump  22 , such that water supplied to the expansion loop is on the last pass through the fluid heater  24 . In addition, the water from the expansion pump should be injected into the fluid heater  24  inlet. The fluid heater  24  should be equipped with a suitable temperature control for maintaining the water temperature under operating conditions after the initial and desired temperature is reached. Still further, the fluid heater  24  should be equipped with any appropriate safety devices for preventing the occurrence of unsafe or potentially damaging conditions. 
     The control system  38  may be in the form of a personal computer, a laptop, a PDA, a printed circuit board, a computerized mechanism, or other means for automatic control of the various components and subcomponents of the fluid processing system  14 . For example, the measurement devices may transmit information remotely to the control system  38  and receive control signals from the control system  38  in a wireless format. Various diagnostics can be monitored while the fluid processing system  14  is in operation. Further, the control system  38  for the fluid processing system  14  may also be used in connection with the conduit expansion system. 
     The present invention provides a fluid system  10  that overcomes the deficiencies of the prior art by using hot water as an injection material into a conduit expansion system  12 , as opposed to steam and/or compressed air. Therefore, the fluid system  10  of the present invention is safer, more stable and provides greater uniformity than similar systems and materials in the prior art. Further, all of the components and subcomponents of the fluid system  10  can be monitored and controlled to further enhance the beneficial characteristics of the present invention. In addition, the present invention provides a mobile fluid system  80  that overcomes the deficiencies of the prior art by being a mobile unit  82  that can be moved or transported easily to a job location. Therefore, the mobile fluid system  80  of the present invention is safer, more stable, provides greater uniformity than similar systems and materials in the prior art, as well as easily transportable. Further, all of the components and subcomponents of the fluid system  10  can be monitored and controlled from the mobile unit  82  to further enhance the beneficial characteristics of the present invention. 
     This invention has been described with reference to the preferred embodiments. Obvious modifications and alterations will occur to others upon reading and understanding the preceding detailed description. It is intended that the invention be construed as including all such modifications and alterations.