Embodiments of the invention generally relate to methods and systems for reducing pressure of natural gas and, in particular, to methods and systems for injection delivery of compressed natural gas.
It is a well-known practice to compress non-ideal gases, including elemental and other gases for scientific or industrial purposes, for transport and delivery to consumers or other customers. For example, it is a known practice to transport compressed natural gas (CNG) by truck, ship, or similar delivery system to users that periodically require natural gas supply in excess of the supply available through existing pipelines. Further, there are areas in which natural gas service via pipeline is not available at all, due to remoteness, the high cost of laying pipelines, planned or unplanned outages, or other factors. In such cases, tanks of CNG transported by truck, for example, can be an economical way to provide the natural gas service required by such users.
To be economical, such tanks must be filled with large amounts of usable natural gas. Accordingly, full tanks of CNG are under very high pressure, commonly around 3000 pounds per square inch gauge (PSIG). However, in many cases natural gas under considerably lower pressure, e.g. from 20 to 100 PSIG, is required. Consequently, unloading a CNG tank requires a substantial reduction in the gas pressure prior to being received at a customer's intake. Currently, reducing the pressure of the CNG may be problematic due to substantial cooling of the natural gas caused by the Joules-Kelvin effect. Allowing a large volume of CNG to be depressurized results in a large temperature drop that can expose the material that comprises CNG tanks, valves, pipelines (particularly carbon steel pipes), customer equipment or other pieces of a natural gas system to low temperatures possibly exceeding safe operating ranges specified by manufacturers and codes.
Users of CNG supply systems may require volumes of natural gas that range from very low flow to flows in excess of 5,500 standard cubic feet per hour (SCFH). At such rates, the cooling resulting from depressurization may be transmitted a significant distance downstream from the point of regulation. This may increase the chance of failure if the material or equipment at the customer's intake is not rated for the extreme cold temperature of the gas. Such failures could result in a loss of a substantial volume of gas through a relief valve that releases gas to atmosphere when pressure is too high. At worst, a failure could result in irreparable damage or destruction of equipment and/or explosion.
It is understood that there are electric or electronic devices, control valves, and/or pressure controllers that may be able to accept the high-pressure CNG, depressurize it, and pass it to a standard natural gas intake at a relatively high rate of delivery. Such devices are extremely expensive, however, reducing or eliminating the profitability of truck-delivery of CNG. Further, devices capable of operating at the temperatures ranges produced by extreme depressurization of natural gas are not readily available.
Accordingly, there is a need in the industry for a reliable gas delivery system that provides depressurized gas at a steady rate with varying flow conditions.
In some embodiments, the present invention includes a system for reducing a pressure of a gas. The system may include at least one vortex regulator, a heat exchange device and a pressure-reducing regulator. The at least one vortex regulator may include a vortex tube and may have at least one inlet to receive natural gas and at least one outlet for releasing the natural gas at a substantially decreased pressure and temperature. The heat exchange device may be configured to receive the natural gas from the at least one vortex regulator and to increase the temperature of the natural gas. The pressure-reducing regulator may be in fluid communication with the heat exchange device and may be configured for further reducing the pressure of the natural gas.
In additional embodiments, the present invention includes a method of reducing a pressure of natural gas that includes directing a natural gas stream into at least one vortex regulator comprising a vortex tube, reducing a pressure and a temperature of the natural gas stream using the at least one vortex regulator, heating the natural gas stream from the at least one vortex regulator using a heat exchanger in fluid communication with the vortex regulator and directing the natural gas stream from the heat exchanger to a pressure-reducing regulator to further reduce the pressure thereof.
In further embodiments, the present invention includes a method of delivering natural gas. The method may include directing a natural gas stream from at least one storage vessel to at least one vortex regulator comprising a vortex tube, decreasing a pressure of the natural gas stream while simultaneously reducing a temperature of the gas using the at least one vortex regulator and directing the natural gas stream to a heat exchanger having a surface in communication with a fluid having a temperature higher than that of the natural gas stream to heat the gas.
In yet another embodiment, the present invention may include a system for delivering natural gas that includes a mobile support. The system may include at least one storage vessel for containing the natural gas in a compressed form disposed on the mobile support and a vortex regulator including at least one vortex tube and disposed on the mobile support. The vortex regulator may be in fluid communication with the at least one storage vessel and a heat exchanger. The heat exchanger may be configured for exchanging heat between the natural gas and ambient air.
While the specification concludes with claims particularly pointing out and distinctly claiming that which is regarded as embodiments of the present invention, the advantages of this invention may be more readily ascertained from the following description of the invention when read in conjunction with the accompanying drawings in which:
The illustrations presented herein are not meant to be actual views of any particular material, apparatus, system, or method, but are merely idealized representations that are employed to describe embodiments of the present invention. Additionally, elements common between figures may retain the same numerical designation for convenience and clarity.
As used herein, the terms “compressed natural gas” and “CNG” mean and include natural gas, primarily methane, condensed under high pressure which may be stored, for example, in specially designed storage tanks at from about 2,000 PSIG to about 3,600 PSIG.
The term “disposed on,” as used herein, means and includes mounted on, placed on, positioned on, supported by, attached to, or otherwise connected to the mobile support, either directly or indirectly.
The phrase “in fluid communication,” as used herein, means to engaging in, or currently being available for, one-way or two-way movement of a liquid, gas, or both, as circumstances indicate. Fluid communication between two elements may be direct between the two elements (e.g., when the two elements are physically contacting each other in a functional manner) or indirect (i.e., when the two elements are not physically contacting each other but are connected in a functional manner via an intermediary element(s) such as a transferring means).
The phrase “in selective fluid communication,” as used herein, means that one of the two elements is ready for being placed in fluid communication with the other of the two elements, e.g., the one element would be in fluid communication with the other element if the two elements were connected, directly or indirectly, to each other as previously described.
The terms “Joule-Thompson effect(s)” and “Joule-Kelvin effect(s),” as used herein, mean and include the temperature change of a gas or a liquid when forced through a valve, a narrow jet, or a porous plug adiabatically (i.e., without loss or gain of heat to the system). The rate of change of temperature T with respect to pressure P in a Joule-Thomson process (that is, at constant enthalpy H) is the Joule-Thomson (Kelvin) coefficient μJT. This coefficient can be expressed in terms of the gas's volume V, its heat capacity at constant pressure Cp, and its coefficient of thermal expansion a as:
As used herein, the term “pounds force per square inch gauge,” or “PSIG,” means and includes the pressure in pounds force per square inch exceeding atmospheric pressure.
An embodiment of an embodiment of a system 100 for reducing a pressure of natural gas is shown in a simplified schematic view in
The gas may be directed though the gas flow line 106 to a first regulator 112 configured to substantially reduce the pressure of the gas. As a non-limiting example the first regulator 112 may be a Joule-Thomson expansion valve, a diaphragm regulator or a needle valve regulator, such as, those commercially available from Bryan Donkin RMG (Germany), Elster-Instromet A/S (Denmark) and Tescom-Emerson Process Management (Elk River, Minn.). The pressure of the gas may be reduced by the first regulator 112 such that the gas exiting the first regulator 112 has a pressure of from about 1,500 PSIG to about 2,500 PSIG at a location in the gas flow line 106.
The gas may be fed from the first regulator 112 to a vortex regulator 118 by way of a first valve 116a. Alternatively, a Venturi nozzle or any orifice, such as, a valve or a narrow jet, may be used instead of the vortex regulator 118. For example, the vortex regulator 118 may include a vortex tube, examples of which are disclosed in U.S. Pat. No. 2,907,174 to Willem Peter Hendel, U.S. Pat. Nos. 5,911,740 and 5,749,231 to Tunkel et al., and U.S. Pat. No. 6,071,424 to Tuszko et al., each of which is hereby incorporated by reference in its entirety. A vortex tube, often referred to as the Ranque vortex tube, the Hilsch tube and the Ranque-Hilsch tube, is a static mechanical device that takes pressurized compressible fluid and derives a hot fluid and a cold fluid at a lower pressure. The mechanics by which the vortex tube separates a fluid into hot and cold parts through depressurizing are largely unknown, but empirical data validate that it is a measurable, repeatable and sustainable event. In operation, the pressurized compressible fluid is injected through tangential nozzles into a chamber in which the compressible fluid is simultaneously separated into a fluid stream higher in temperature than the inlet stream and a fluid stream that is cooler than the inlet stream. While not wishing to be bound by any particular scientific theory, tangential injection may set the pressurized compressible fluid stream in a vortex motion. This spinning stream of compressible fluid may turn about 90° and pass down the hot tube in the form of a spinning shell or vortex, similar to a tornado. A valve at one end of the tube allows some of the warmed fluid to escape. That portion of the warmed fluid that does not escape is directed back down the tube as a second vortex inside the low-pressure area of the larger vortex. The inner vortex may lose heat to the larger vortex and exhaust through the other end as a cold fluid stream. The gas in the vortex is cooled because part of its total energy converts into kinetic energy.
By way of non-limiting example, the vortex regulator 118 may be configured to substantially reduce the pressure of the gas using a method such as that disclosed in U.S. Pat. No. 5,327,728 to Lev E. Tunkel, which is hereby incorporated by reference in its entirety. Such a vortex regulator may be obtained from Universal Vortex, Inc. (Robbinsville, N.J.). The vortex regulator 118 is able to reduce the pressure of the gas from about 3,000 PSIG to about 150 PSIG for gas flows ranging from about 1,800 SCFH to about 5,500 SCFH without experiencing regulator freeze up. The vortex regulator 118 may produce a hot gas fraction during the pressure reduction process that is diverted onto surfaces of the vortex regulator 118 to prevent the formation of ice and mitigate the potential freeze up condition associated with high pressure reduction. The pressure of the gas may be reduced by the vortex regulator 118 so that the gas exiting therefrom has a pressure of from about 300 PSIG to about 50 PSIG and, more particularly, about 150 PSIG. The first valve 116a may be, for example, a ball valve such as those commercially available from Swagelok Company (Solon, Ohio).
In some embodiments, where a volumetric flow demand of the gas may be sufficiently high, the gas may be diverted to the bypass line 108, which circumvents the first regulator 112. The gas may be fed through the bypass line 108 and back to the gas flow line 106 by a second valve 116b. After re-entering the gas flow line 106, the gas may be fed into the vortex regulator 118 at a pressure of from about 2,000 PSIG to about 4,000 PSIG and, more particularly, about 3,000 PSIG.
A temperature of the gas is substantially reduced during pressure reduction by the vortex regulator 118 and the first regulator 112. After exiting the vortex regulator 118, the temperature of the gas may be from about −78.9° C. (about −110° F.) to about −56.7° C. (about −70° F.) and, more particularly, about −67.8° C. (about −90° F.). The reduction in pressure is advantageous to the system due to the significant temperature drop that occurs due to Joule-Kelvin effect. The temperature reduction associated with the pressure reduction in the gas is achieved by throttling the gas at a constant enthalpy from through the vortex regulator 118 and the first regulator 112. The temperature gradient between the gas exiting the vortex regulator 118 and ambient air heater 120 enables for significant heat input into the system 100 via ambient heater 120. The ambient heater 120 may be a heat exchanger having a forced convection surface area, or any other device configured for exchanging heat between gas and ambient air. The ambient heater 120 may be in fluid communication with the vortex regulator 118 and a surface of the ambient heater 120 may be in communication with the ambient air for transfer of heat from the ambient air to the gas. The system 100 may further include a fan (not shown) or other device for circulating the ambient air over the surface of the ambient heater 120. Energy transferred from the surrounding environment (i.e., ambient air) into the system 100 at a high rate through a convection process via the ambient heaters 120 and 124 may be determined using the following equation:
Q=H(ΔT)
The variable H is the convection coefficient and is dependent on the gas and geometry of the device it is flowing through. The reduced temperature of the gas resulting from the pressure reduction by the vortex regulator 118 and the first regulator 112 creates a large temperature gradient (ΔT) between the gas and the ambient air. The energy transfer direction (Q) should increase based on the available energy in the ambient environment. Typically the sign of the temperature gradient (ΔT) predicts the direction of energy transfer. Therefore, if the temperature of the gas is less than that of the surroundings, energy is transferred into the system.
By achieving a large temperature gradient from rapid two stage pressure reduction with the primary pressure reduction occurring in the vortex regulator 118, gas heating may be achieved efficiently. The large temperature gradient achieved through pressure reduction by the vortex regulator 118 enables a substantial portion of the heating process to take place in the ambient heater 120.
The ambient heater 120 may be modeled by using a closed loop energy balance that encompass the working fluids (i.e., natural gas) and ambient air. The fundamental equation that describes the required heat input for the heat transfer process associated with the ambient heater 120 is as follows:
Q=UAΔTm,
wherein Q is an overall heat transfer, U is the heat transfer coefficient for the ambient heater, ΔTm is a log mean temperature difference between the gas and the ambient air and A is an overall heat transfer area of the ambient heater 120. By way of non-limiting example, the ambient heater 120 may have a heat transfer coefficient (U) of from about 0.75 to about 1.2 and, more particularly, about 0.965 and a heat transfer area (A) of from about 50 ft3 to about 400 ft3 and, more particularly, about 214.63 ft3.
For example, if the temperature of the ambient air is about 10° C. (50° F.) and the temperature of the gas is about −67.8° C. (−90° F.), the gas may be heated to ambient temperature (i.e., about 10° C.) using about 11,986 BTUs. In some embodiments, an external heat source may be supplied to the ambient heater 120 to increase the efficiency of heating.
The gas exiting the ambient heater 120 may have a temperature of from about 0° C. to about 20° C. (about 68° F.) and, more particularly, about 10° C. (about 50° F.). The gas may be directed from the ambient heater 120 to a second regulator 122 configured to substantially reduce the pressure of the gas. Additionally, the gas, or a portion thereof, may be directed from the inlet 104 to the static pressure line 110. The static pressure line 110 may maintain a constant pressure, the purpose of which is to control the outlet pressure of the second regulator 122. Gas may be directed through the static pressure line 110 by a valve 123.
The second regulator 122 may be a Joule-Thomson expansion valve, a diaphragm regulator or a needle valve regulator such as, for example, a 26-1200 SERIES high flow regulator which is commercially available from Tescom-Emerson Process Management. The second regulator 122 may control the pressure of the gas to enable for a large flow differential while substantially reducing or eliminating pressure spikes suing incremental flow changes. As a non-limiting example, the second regulator 122 may reduce the pressure of the gas to from about 20 PSIG to about 100 PSIG and, more particularly, about 45 PSIG.
The gas may then be directed to another ambient heater 124 configured to increase the temperature of the gas within about 28.9° C. (about 20° F.) of an ambient temperature, such as, from about 28.9° C. (about 20° F.) to about 10° C. (about 50° F.). The gas exiting the system 100 may be conveyed to a gas main to be directed to residential, commercial and industrial applications.
In some embodiments, the system 100 may be disposed on a mobile support, such as, a vehicle or a trailer. The ambient heaters 120 and 124 may also be disposed on the mobile support or, alternatively, may be separate from the mobile support. The system 100 may further include a heat source that provides heat to the ambient heaters 120 and 124. For example, the heat source may be suitable an internal combustion engine 125 used to provide power for transporting the system 100 on the mobile support. As a non-limiting example, heat source may besuch as used on a flameless nitrogen skid unit such as those described in U.S. Pat. No. 5,551,242 to Loesch et al., the entirety of which is hereby incorporated by reference in its entirety.
In other embodiments, the system 100 may be used to provide an uninterrupted natural gas source to end-users. For example, such a system 100 may be used to provide natural gas to power generation facilities, residences, local distribution companies, service centers, manufacturing plants, hospitals, and the like. The system 100 may be installed in a location in which a natural gas source is desired and compressed natural gas may be stored in containers, such as storage tanks.
The system 100 may further include monitoring equipment 127, such as, sensors, computers and the like for monitoring the pressure, temperature, flow rate and the like, of the natural gas at various points in the system 100. Such monitoring equipment 127 is well known in the art and is, thus, not described in detail herein.
The system 100 enables the pressure of natural gas to be reduced from about 3,000 PSIG to about 45 PSIG while substantially reducing or eliminating freeze up conditions that may result in loss of control or interruption of gas flow. For example, the temperature of the gas exiting the system 100 may be greater than or equal to about −28.9° C. (about −20° F.). The system 100 may be used to reduce the pressure of natural gas at flows less than or equal to about 5500 SCFH.
Another embodiment of an embodiment of a system 200 for reducing a pressure of natural gas is shown in a simplified schematic view in
The system 200 may include a first pressure relief valve 210a along the gas flow line 206 that may be used to release excess pressure from the system 200. The pressure relief valve 210a may be, for example, a pilot-operated or spring-operated pressure relief valve. Examples of pressure relief valves include Anderson Greenwood valves, which are available from Tyco Flow Control (Princeton, N.J.). A portion of the gas may be directed through the gas flow line 206 through a first valve 212a to a high flow vortex regulator 218. The first valve 212a may be, for example, a ball valve. The gas flow line 206 may, optionally, include a first temperature gauge 214a and a first pressure gauge 216a that may be used to determine at least one setting of the high flow vortex regulator 218. The high flow vortex regulator 218 may include a vortex tube and may be configured to substantially reduce the pressure and temperature of the gas. By way of non-limiting example, the high flow vortex regulator 218 may reduce the pressure and temperature of the gas so that the gas exiting therefrom has a pressure of from about 300 PSIG to about 50 PSIG and, more particularly, about 150 PSIG and a temperature of from about −78.9° C. (about −110° F.) to about −56.7° C. (about −70° F.) and, more particularly, about −67.8° C. (about −90° F.).
In some embodiments, where a volumetric flow demand of the gas may be sufficiently low, at least a portion of the gas may be diverted to the bypass line 208, which circumvents the high flow vortex regulator 218. The gas may be fed through the bypass line 208 to a low flow vortex regulator 220 by a second valve 212b. The reduced pressure gas may be fed from the low flow vortex regulator 220 to the gas flow line 206 at a pressure of from about 300 PSIG to about 50 PSIG and, more particularly, of about 150 PSIG and a temperature of about −78.9° C. (about −110° F.) to about −56.7° C. (about −70° F.) and, more particularly, about −67.8° C. (about −90° F.).
The gas flow line 206 may include a second temperature gauge 214b, a second pressure gauge 216b, a second pressure relief valve 210b and a third pressure relief valve 210c. The gas may be directed to an outlet 222 via a system 200 at a substantially reduced pressure, such as, a pressure of from about 5 PSIG to about 200 PSIG.
Another embodiment of a system 300 for reducing pressure of a gas, such as natural gas, is shown in a simplified schematic view in
Upon entering the gas inlet 302, a portion of the gas may be directed to the pressure controller 316 or the static pressure line 306. For example, the gas may be directed to at least one of the pressure controller 316 and the static pressure line 306 by a t-shaped connector 330a, such as, an SS-1610-1-16 connector that is available from Swagelok Company. The pressure of the gas entering the pressure controller 316 may be determined using the first pressure gauge 312, or other pressure measuring device. As a non-limiting example, the first pressure gauge 312 may be a PGI-115P industrial pressure gauge available from Swagelok Company. For example, the first pressure gauge 312 may be connected to the gas inlet 302 by way of a t-shaped connector 330b, similar to that previously described, and reducing bushing 333a. The reducing bushing 333a may be, for example, an SS-4-RB-2 stainless steel pipe fitting-reducing bushing or an SS-8-RB-4 stainless steel pipe fitting-reducing bushing, each of which is available from Swagelok Company. The t-shaped connectors 330a and 330b may be connected to one another by way of a fitting 332a such as, for example, an SS-8-CN stainless steel pipe fitting, close nipple, available from Swagelok Company.
The first pressure relief valve 314 may be connected to the first pressure gauge 312 by a fitting 332b and a t-shaped connector 330c similar to those previously described. The first pressure relief valve 314 may be a direct spring operated pressure relief valve such as an Anderson Greenwood Type 81 pressure relief valve which is available from Tyco Flow Control. The first pressure relief valve 314 may be in fluid communication with the high flow bypass line 308 via t-shaped connector 330d and valve 334a. For example, the valve 334a may be a ball valve such as a three-piece high-pressure alternative fuel service valve, which is available from Swagelok Company. The first pressure relief valve 314 may be in fluid communication with the pressure controller 316 via the t-shaped connector 330d and tube connectors 336a and 336b. The tube connectors 336a and 336b may be stainless steel connectors such as, for example, an SS-810, SS-1610 and SS-400 tube fitting connectors available from Swagelok Company. The pressure controller 316 may be used, for example, to control the flow of the gas into the high flow vortex regulator 304. The pressure controller 316 may be a high flow, pressure-reducing regulator or Joule-Thomson expansion valve and may have an inlet pressure of from about 3,570 PSIG to about 6,000 PSIG, an outlet pressure of from about 10 PSIG to about 2,500 PSIG and a flow capacity (Cv) of from about 0.8 to about 2. By way of non-limiting example, the pressure controller 316 may be a 44-1300 Series high flow/high pressure-reducing regulator, which is available from Tescom-Emerson Process Management. The pressure controller 316 may, optionally, be connected to or in fluid communication with a check valve 338 such as, for example, a SS-58S8-SC11 lift check valve that is available from Swagelok Company. The pressure controller 316 may prevent the gas pressure on the outlet of the check valve 338 from exceeding about 2,500 PSIG. A tube connector 336c, such as that previously described, may connect the pressure controller 316 and the check valve 338. The inlet 302 may be in connected to or in fluid communication with the high flow bypass line 308 and in selective fluid communication with a low flow bypass line 342 via a cross-shaped connector 340, such as, an SS-8-VCR-CS 316 SS face seal fitting, which is available from Swagelok Company.
A valve 334b may, respectively, be disposed between the cross-shaped connector 340 and the high flow vortex regulator 304, and may be used to control fluid communication therebetween. The valve 334b may be connected to the high flow vortex regulator 304 by tube connectors 336d and 336e, such as those previously described. The high flow vortex regulator 304 may be obtained from Universal Vortex and may have a maximum flow volume of about 29 thousand cubic feet per hour (about 821.188 cubic meters per hour). Optionally, a reducing bushing 333b may be disposed between the valve 334b and the high flow vortex regulator 304.
Another valve 334c may be disposed between the low flow bypass line 342 and the cross-shaped connector 340, and may be used to control fluid communication therebetween. As a non-limiting example, the valve 334c may be connected to the low flow bypass line 342 by a tube connector 336f, similar to those previously described, and may connected to the cross-shaped valve 340 by a fitting 332d, similar to those previously described. The low flow vortex regulator 318 may have a maximum flow rate of about 9 thousand cubic feet per hour (about 254.851.6 cubic meters per hour).
The low flow vortex regulator 318 and the high flow vortex regulator 304 may each be in fluid communication with the first ambient heater (not shown) via an ambient heater inlet 344. The ambient heater inlet 344 may include a fitting, such as, an SS-8-SE street elbow fitting which is available from Swagelok Company, which may be connected to the low flow bypass line 342 and the high flow vortex regulator 304 by a t-shaped connector 330e, similar as those previously described.
The ambient gas heater may be in fluid communication with the pressure regulator 322 via an ambient gas flow outlet 346. The ambient gas flow outlet 346 may include a fittings such as those previously described with respect to the ambient heater inlet 334. The pressure regulator 322 may be, for example, a regulator having an inlet pressure of from about 6,000 PSIG to about 10,000 PSIG, an outlet pressure of from about 55 PSIG to about 6,000 PSIG and a flow capacity (Cv) of from about 3.3 to about 12. As a non-limiting example, the pressure regulator 322 may be a diaphragm sensed pressure-reducing regulator such as a 26-1200 Series high flow regulator, which is commercially available from Tescom-Emerson Process Management. The second pressure valve 320, or other pressure measuring apparatus, and a reducing bushing 333c may, optionally, be disposed between the ambient gas outlet 346 and the pressure regulator 322. The pressure regulator 322 or the reducing bushing 333c, if present, may be connected to the t-shaped connector 330e by a fitting 332e.
The pressure regulator 322 may be in fluid communication with a second ambient heater (not shown) and a heater bypass line 348 via a second heater inlet 350 and a second heater outlet 352. The second ambient heater may, optionally, be connected to a third pressure gauge 324 or other similar pressure measuring device, through a t-shaped connector 330f and a reducing bushing 333d, similar to those previously described.
The heater bypass line 348 may be in fluid communication with the pressure regulator 322 via a t-shaped connector 330g, similar to those previously described. The heater bypass line 348 may be connected to the pressure regulator 322 at one end and to the t-shaped connector 330g at an opposite end by tube connectors 332f and 332g. Optionally, a reducing bushing 333e may be disposed Fittings 332e and 332g may be used to interconnect the t-shaped connectors 330f and 330g and a fitting 332h connected to the second pressure relief valve 326. By way of non-limiting example, the second pressure relief valve 326 may be a direct spring operated valve, such as, an Anderson Greenwood Type 81 pressure relief valve which is available from Tyco Flow Control.
The static pressure line 306 may include the injection regulator 328 having an inlet pressure of from about 6,000 PSIG to about 10,000 PSIG, an outlet pressure of from about 5 PSIG to about 6,000 PSIG and a flow capacity (Cv) of from about 0.02 to about 0.12. The static pressure line 306 and the injection regulator 328 may be used to maintain a static pressure on the high flow regulator 322. For example, the injection regulator 328 may be a 44-1100 Series high pressure-reducing regulator, which is available from Tescom-Emerson Process Management. As a non-limiting example, the static pressure line 306 may be connected to the gas inlet 302 by a tube connector 336h and may be connected to the pressure regulator 322 by tube connectors 336i and 336j, such as those previously described.
A system 301 for reducing the pressure of a gas similar to that shown in
Referring to
Optionally, the gas, or a portion thereof, may be directed to the low flow bypass line 342, and may be passed though the low flow vortex pressure reducer 318, which substantially reduces the pressure of the gas. As a non-limiting example, the gas exiting the low flow vortex pressure reducer 318 may have a pressure of from about 150 PSIG to about 2,000 PSIG. The gas may be directed to the high flow vortex regulator 304 wherein the pressure of the gas is substantially reduced. For example, the gas entering the high flow vortex regulator 304 may exhibit a pressure of from about 500 PSIG to about 2,500 PSIG and may exit having a pressure of from about 50 PSIG to about 2,000 PSIG and, more particularly, about 145 PSIG. A temperature of the gas may also be substantially decreased during pressure reduction by the high flow vortex regulator 304 For example, the gas exiting the high flow vortex regulator 304 may have a temperature of from about −78.9° C. (about 110° F.) to about −56.7° C. (about −70° F.) and, more particularly, about −67.8° C. (about −90° F.).
The gas may be directed through the ambient heater inlet 344 to the first ambient heater which may substantially increase the temperature of the gas. For example, the gas exiting the ambient heater may have a temperature of from about 0° C. to about 20° C. and, more particularly, about 10° C. The gas may then be directed through the ambient gas flow outlet 346 to the high flow regulator 322 wherein the pressure of the gas may be reduced to from about 15 PSIG to about 75 PSIG and, more particularly, about 45 PSIG. Optionally, the pressure of the gas may be determined before entering the pressure regulator 322 using the second pressure gauge 320.
The gas exiting the pressure regulator 322 may, optionally, be directed to the second ambient heater by the second heater inlet 350, as shown in
Another embodiment of a system 400 for reducing pressure of a gas, such as natural gas, is shown in a simplified schematic view in
The t-shaped connector 416b may be connected to another t-shaped connector 416c by a fitting 420e. The t-shaped connector 416b may be connected to a valve 422a leading to a bypass line 424 and to another t-shaped connector 416c connected to a first pressure release valve 412a. The valve 422a may be, for example, an SS-AFSF8 ball valve or an SS-AFSS8 ball valve, which are available from Swagelok Company, or any other device suitable for controlling gas flow. The bypass line 424 may include the low flow vortex regulator 404 coupled thereto by fittings 420f and 420g similar to those previously described. The bypass line 424 may be in fluid communication the high flow vortex regulator 406 via a t-shaped connector 416d. The bypass line 424 and the first pressure relief valve 412a may be in selective fluid communication with the high flow vortex regulator 406 via valves 422b and 422c a t-shaped valve 416d. The high flow vortex regulator 406 and the low flow vortex regulator 404 may each be in fluid communication with a series of pressure-reducing regulators 408a, 408b, 408c, 408d and 408e. The low flow vortex regulator 404 may have a maximum flow rate of about 9 million cubic feet per hour (about 254,851.6 cubic meters per hour). The high flow vortex regulator 406 may have a maximum flow volume of about 25 million cubic feet per hour (about 707921.175 cubic meters per hour).
Optionally, a second pressure gauge 415b may be disposed between the high flow vortex regulator 406 and at least one of the pressure-reducing regulators 408a, 408b, 408c, 408d and 408e. As a non-limiting example, each of the pressure-reducing regulators 408a, 408b, 408c, 408d and 408e has a maximum inlet pressure of 3,600 PSIG, a pressure control range of from about 0 PSIG to about 250 PSIG, a flow coefficient of about 1.0 Cv and a maximum operating temperature of about 200° C. Each of the pressure-reducing regulators 408a, 408b, 408c, 408d and 408e may be, for example, a high-flow, high-sensitivity, diaphragm-sensing pressure regulator, such as, a KHF Series pressure-reducing regulator available from Swagelok Company. The pressure-reducing regulators 408a, 408b, 408c, 408d and 408e may be connected via t-shaped connectors 416e, 416f, 416g, 416h and 416i and fittings 420h, 420i, 420j and 420k. Each of the pressure-reducing regulators 408a, 408b, 408c, 408d and 408e may be connected to one of valves 422d, 422e, 422f, 422g, and 422h. Each of the valves 422d, 422e, 422f, 422g, and 422h may be connected to connector, such as elbow connector 428a and t-shaped connectors 416j, 416k, 416l and 416m and via fittings 420l, 420m, 420n, 420o and 420p and tubing 426a, 426b, 426c, 426d and 426e. The t-shaped connectors 416j, 416k, 416l and 416m and via fittings 420l, 420m, 420n, 420o and 420p may be similar to those previously described. The elbow connector 428a may be, for example, a SS-16-E fitting available from Swagelok Company. The elbow connector 428a and each of the t-shaped connectors 416j, 416k, 416l and 416m and may be connected to another via fittings 420q, 420r, 420s and 420t.
A third pressure gauge 415c may, optionally, be disposed between the second pressure relief valve 412b and the series of pressure-reducing regulators 408a, 408b, 408c, 408d and 408e. For example, the third pressure gauge 415c may be connected to t-shaped connector 416o by fitting 420u, elbow connector 428b and a reducing bushing 418c. A t-shaped valve 416p and a reducing bushing 418d may connect the second pressure relief valve 412b. The second pressure relief valve 412b may be, for example, an Anderson Greenwood Series 800 pilot operated pressure relief valve, which is available from Tyco Flow Control. A second temperature gauge 421b may, optionally, be disposed between the second pressure relief valve 412b and the pressure-reducing regulator 410. As a non-limiting example, the second temperature gauge 421b and the pressure-reducing regulator 410 may each be connected to a t-shaped connector 416q. A reducing bushing 418e and a fitting 420w may be used to connect the second temperature gauge 421b to the t-shaped connector 416q. By way of example and not limitation, the pressure-reducing regulator 410 may have a maximum inlet pressure of about 2,000 PSIG, an outlet pressure of about 5 to about 500 PSIG and an operating temperature range of from about 29° C. to about 82° C. The pressure-reducing regulator may be, for example, a 627 Series pressure-reducing regulator available from Tescom-Emerson Process Management.
Optionally, the third pressure relief valve 412c, a fourth pressure gauge 415d, a plug valve 430 and a fifth pressure gauge 415e may be included in the system 400. By way of non-limiting example, the third pressure relief valve 412c may be connected to the system 400 by way of a t-shaped connector 416r, an elbow connector 428c, fitting 420x and reducing bushing 418f. The fourth pressure gauge 415d may be in fluid communication with the pressure-reducing regulator 410 and the second pressure release valve 412b by way of a t-shaped connector 416r. For example, elbow connectors 428d, 428e, and 428f, fittings 420y and 420z, t-shaped connector 416s and reducing bushing 418g may connect the fourth pressure gauge 415d to the t-shaped connector 416r. The plug valve 430 may be connected to the t-shaped connector 416s by a fitting 420aa. The plug valve 430 may be, for example, a Class-300 XENITH® plug valve, which is available from Xomox Corporation (Cincinnati, Ohio). The fifth pressure gauge 415e may be connected to the plug valve 430 by a fitting 420ab, a t-shaped connector 416t and a reducing bushing 418h.
The outlet 414 may comprise a reducing bushing 418i, such as that shown in
Natural gas having a pressure of about 3,000 PSIG and a temperature of about 15.6° C. (about 60° F.) may be injected in to the system 400 through the inlet 402. The natural gas injected into the system 400 may be obtained, for example, from a storage container (not shown).
The natural gas, or portions thereof, may be passed to the low flow bypass line 424 or to the high flow vortex regulator 406, each of which is in selective fluid communication with the inlet 402. If the pressure of the natural gas in the system 400 exceeds about 3,500 PSIG, sufficient pressure may be released by the first pressure relief valve 412a such that the pressure of the gas entering the high flow vortex regulator 406 is less than or equal to about 3,000 PSIG. In the low flow bypass line 424, the natural gas may be directed through the low flow vortex regulator 404 by valve 422a. The natural gas exiting the low flow vortex regulator 404 may have a substantially decreased pressure and temperature. For example, the temperature of the gas exiting the low flow vortex regulator 404 may be about −51.1° C. (−60° F.) while the pressure may be from about 150 PSIG to about 2,000 PSIG.
The natural gas exiting the low flow vortex regulator 404 may be directed to the high flow vortex regulator 406. The gas exiting the high flow vortex regulator 406 may have a substantially decreased pressure and temperature. For example, the temperature of the gas exiting the low flow vortex regulator 404 may be about −51.1° C. (−60° F.).
The natural gas may be directed from the low flow vortex regulator 404 and the high flow vortex regulator 406 to the series of pressure-reducing regulators 408a, 408b, 408c, 408d, and 408e. Each of the pressure-reducing regulators of the series of pressure-reducing regulators 408a, 408b, 408c, 408d, and 408e may be in selective fluid communication with the second pressure relief valve 412b and the pressure-reducing regulator 410 by way of the valves 422a, 422b, 422c, 422d, and 422e. The natural gas exiting the series of pressure-reducing regulators 408a, 408b, 408c, 408d, and 408e may exhibit a pressure of about 225 PSIG.
The second pressure relief valve 412b may be used to reduce the pressure of the natural gas within the system 400. For example, if the pressure of the natural gas exiting the series of pressure-reducing regulators 408a, 408b, 408c, 408d, and 408e is greater than about 300 PSIG, a portion of the natural gas may be release through the second pressure relief valve 412b.
The natural gas may then be directed to the pressure-reducing regulator 410 wherein the pressure of the gas is reduced from about 225 PSIG to about 60 PSIG. The third pressure relief valve 412c may be used to release a portion of the natural gas, for example, if the pressure exceeds about 75 PSIG. The natural gas may exit the system 400 at a substantially reduced pressure and temperature.
The hose reels 504, or other suitable device, may be used to store hose for connecting an outlet of the system 500 to the gas distribution line. The storage assembly 508 may be configured to hold storage containers for storing the compressed natural gas. For example, the storage containers may be steel cylinders or bottles 516 in selective fluid communication with the pressure reduction system by way of connective tubing 518. The control cabinet 512 may include controls for operating the pressure reduction system. The system 500 may further include monitoring equipment 520, such as, sensors, computers and the like for monitoring the pressure, temperature, flow rate and the like, of the natural gas at different points of the pressure-reducing system. Such monitoring equipment 520 is well known in the art and is, thus, not described in detail herein.
Specific embodiments have been shown by way of example in the drawings and have been described in detail herein. The invention, however, may be susceptible to various modifications and alternative forms. It should be understood that the invention is not intended to be limited to the particular forms disclosed. Rather, the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the following appended claims.
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Universal Vortex, Inc., Self Heating Pressure Regulator, www.universal-vortex.com/SelfHeatingPressureRegulator/tabid/94/Default.aspx http://wayback.archive.org/web/20060601000000*/http://univeersal-vortex.com/SelfHeatingPressureRegulator/tabid/94/Default.aspx. |
Universal Vortex, Inc., Sample Gas Heater, www.universal-vortex.com/SampleGasHeater/tabid/96/Default.aspx http://wayback.archive.org/web/20060815000000*/http://www.universal-vortex.com/SampleGasHeater/tabid/96/Default.aspx. |
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Universal Vortex, Inc., Self-Heating Pressure Regulator. Retrieved Dec. 4, 2012. www.universal-vortex.com/SelfHeatingPressureRegulator/tabid/94/Default.aspx <http://web.archive.org/web/20070209144309/http://www.universal-vortex.com/SelfHeatingPressureRegulator/tabid/94/Default.aspx>. |
Universal Vortex, Inc., Self-Heating Pressure Regulator. Retrieved Dec. 4, 2012. www.universal-vortex.com/SelfHeatingPressureRegulator/tabid/94/Default.aspx <http://web.archive.org/web/20080807130940/http://www.universal-vortex.com/SelfHeatingPressureRegulator/tabid/94/Default.aspx>. |
Number | Date | Country | |
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20110056570 A1 | Mar 2011 | US |