RU106307U1 - NATURAL GAS DISTRIBUTION SYSTEM PRESSURE CONTROL STATION (OPTIONS) - Google Patents

Abstract

1. The pressure control station of a natural gas distribution system, comprising a turbine driven by expanding natural gas entering the pressure control station, with a decrease in its pressure, and the turbine output power is used for a useful purpose; and a heat exchanger configured to extract cold from the natural gas exiting the turbine for use in air conditioning or refrigeration. ! 2. The station according to claim 1, characterized in that an electric generator is provided to drive said turbine. ! 3. A pressure control station of a natural gas distribution system, comprising a gas-fired turbine generator powered by a portion of the natural gas supplied to the pressure control station, wherein the turbine generator is used for its useful purpose; a first heat exchanger using exhaust gases from the turbine power generator to preheat the fluid; a turbine driven by the expansion of natural gas with a decrease in its pressure, and the extraction of the output power of the turbine is used for a useful purpose; and a second heat exchanger using said fluid to preheat natural gas to the turbine.

Description

The technical field to which the utility model relates.

This utility model relates to pressure control stations of a natural gas distribution system.

State of the art

Three types of gas pipelines are used in natural gas distribution systems: high pressure gas pipelines (overpressure is approximately 1000 psi), medium pressure gas pipelines (overpressure is approximately 100 psi) and low pressure gas pipelines (overpressure is approximately 5 psi). At the junction of the high pressure gas pipeline to the medium pressure gas pipeline, the overpressure should be reduced from 1000 psi. inch to 100 psi inch. At the junction of the medium-pressure gas pipeline to the low-pressure gas pipeline, the overpressure should be reduced from 100 psi. inch to 5 psi inch. Pressure reduction is carried out through a series of pressure reducing valves installed in the so-called pressure control stations.

As the pressure of natural gas decreases, it expands, and when natural gas expands, its temperature decreases. A sharp drop in temperature leads to the formation of hydrates, which damage the pressure control valves. To prevent the formation of hydrates, natural gas is preheated at pressure control stations until its pressure decreases, so that the outlet temperature is maintained at about 5 ° C. Preheating of natural gas before supplying it to the pressure control station is carried out due to the consumption of part of the gas to produce hot water or the operation of a low pressure steam boiler that supplies heat to the heat exchanger. The heat exchanger is then used to preheat the incoming natural gas.

In such a conventional installation for regulating pressure in a pipeline, energy losses on pressure reducing valves are associated with a pressure drop of 1000 psi. inch to 100 psi inch, quite substantial. Likewise, energy losses occur on pressure reducing valves associated with a pressure drop of 100 psi. inch to 5 psi inch. If this energy could be captured, there could potentially be a net gain in energy, as opposed to the net loss of energy that occurs at pressure control stations.

US Pat. No. 6,167,692 discloses a fuel gas turbo expander system in a gas distribution system of a power plant. The gas distribution system contains a source of high pressure natural gas directed to the primary turbo expander, and this primary turbo expander drives a generator that can be used to perform various tasks (electrical, mechanical, etc.). This document further discloses the possibility of using an intermediate turbo expander to further expand part of the fuel gas from the primary turbo expander, each of the turbo expanders having a heat exchanger located upstream of them, designed to preheat the fuel gas before it expands in the turbo expander.

Utility Model Disclosure

The objective of the utility model is to create a pressure control station for a natural gas distribution system that uses energy, which is currently lost on the rods of pressure regulating valves in connection with a decrease in pressure, and is also spent on preheating natural gas as a result of burning part of the gas.

In a first aspect, the utility model provides a pressure control station for a natural gas distribution system comprising a turbine driven by expanding the natural gas supplied to the pressure control station while lowering its pressure, wherein the output of the turbine is used for its intended purpose; and a heat exchanger configured to take cold from natural gas exiting the turbine for use for air conditioning or cooling.

The above technical result is achieved through the use of a heat exchanger, which is located downstream relative to the turbine (turbo expander), and through which the natural gas leaving the turbine is directed to select cold, which leads to a decrease in pressure.

In a preferred embodiment, an electric generator is provided for driving said turbine.

In a second aspect, the utility model provides a pressure control station for a natural gas distribution system comprising a gas turbine electric generator driven by using a portion of the natural gas supplied to the pressure control station, the output power of said turbine generator being used for useful purposes; a first heat exchanger using exhaust gases from a turbine generator to pre-heat the liquid; a turbine driven by the expansion of natural gas while lowering its pressure, and the selection of the output power of the turbine is used for its intended purpose; and a second heat exchanger using said liquid to preheat the natural gas sent to the turbine.

In this aspect, involving the operation of the turbine on preheated natural gas, the above technical result is also achieved by selecting the output power of the turbine generator to generate energy through its generator part.

Brief Description of the Drawings

These and other features of the utility model will become apparent from the following description with reference to the accompanying drawings, intended for illustrative purposes only and not limiting in any way the scope of the utility model to its specific embodiments. In the drawings:

1, labeled “prior art”, is a schematic diagram of a pressure control station;

figure 2 is a schematic diagram of a pressure control station, made in accordance with the principles of this utility model.

Utility Model Implementation

A preferred embodiment of a pressure control station of a natural gas distribution system will be described with reference to FIGS. 1 and 2.

First, a prior art system will be described. 1, the high pressure pipe system is shown at number 12, and the low pressure pipe system is shown at number 14. Between the high pressure pipe system 12 and the low pressure pipe system 14, there is a pressure control station, indicated generally by 16. The high pressure natural gas flowing from the high pressure pipe system 12 passes through a first linear shutoff valve 18, a coarse control valve assembly, generally designated 20, a valve assembly 22 orku precise regulation, before entering the second linear stop valve 24. The boiler 26 with a related heat exchanger 28 is disposed in a bypass loop 30. There are three valves 32 that control the supply of natural gas to the heat exchanger 28 and its exit from the heat exchanger. In the heat exchanger 28, preheating of natural gas occurs. The preheated natural gas is then sent through a series of pressure reducing valves 34. A third linear stop valve 36 isolates the pressure control station 16 from the low pressure pipe system 14. The fuel gas supply line 38 diverts a portion of the reduced pressure natural gas for use in the fuel boiler 26. The principle of operation is to pre-heat the natural gas in the heat exchanger to prevent hydrates from forming when the natural gas passes through a series of pressure reducing valves 34. The energy released when the natural pressure is reduced gas is lost on the pressure reducing valves 34. In addition, energy costs are required in the form of gas consumption by the boiler 26. Thus, then net energy loss.

Figure 2 presents the configuration according to the proposed utility model in relation to the known from the prior art pressure control station. Preservation of the existing infrastructure for maintaining backup systems for the purpose of ensuring security is envisaged.

According to the principles of the proposed utility model, natural gas is diverted by bypassing the heat exchanger 28 and a number of pressure reducing valves 34. A key aspect is the direction of the natural gas entering the pressure control station through line 50 to the turbine 52, driven by the expansion of natural gas with decreasing his pressure. The output of the turbine 52 is then selected for its intended use. Preferably, the turbine is used to drive the electric generator 54. The turbine 52 may operate either on preheated natural gas or on unheated gas, as will be further explained.

Turbine 52 is preferably a turbine known as a “turbo expander." It is a radial centripetal turbine equipped with rotary inlet blades for regulating the flow, which are used to take energy from the gas stream. The use of a turbo expander (turbine 52) for generating energy at pressure control stations 16 in a natural gas distribution system is proposed. The expansion of gas at the input vanes and the impeller of the turbine creates a torque, and the power on the shaft can be used to rotate the electric generator 54.

When this is allowed by the characteristics of the natural gas operating stream, turbine 52 can be used without pre-heating the gas. Natural gas is sent to turbine 52 with the intention of creating lower temperatures. A heat exchanger 56 is provided to select the cold used either for cooling or for air conditioning. A fluid used to condition the air in adjacent rooms or to cool nearby refrigerated warehouses can be circulated through the heat exchanger 56. The degree of cooling achieved by expansion of the gas is usually much higher than that achieved by expansion of the Joule-Thomson on the valve.

If pre-heating of natural gas is required, the boiler 26 is replaced by a turbine electric gas generator 58, sometimes referred to as a “micro-turbine." Part of the high-pressure natural gas is diverted via line 60 and passed through a gas processing system 62 that prepares natural gas for use as a turbine generator 58 gas. The exhaust gas from the turbine generator flows through line 64 and passes through a first heat exchanger 66. A hot water circuit is provided including a circulation line 68, an expansion tank 70, a pump 74 and valves 76. The expansion tank 70, if necessary, provides water for qi circulation line 68. Pump 74 is used to circulate hot water through circulation line 68. Water circulates through line 68, which passes through heat exchanger 66, so that heat is transferred from the hot exhaust gases coming from the turbine generator 58 to the heated water. The exhaust gases are then released into the atmosphere. Secondary heat exchange occurs in a second heat exchanger 78 between hot water and natural gas. The natural gas preheated in the second heat exchanger 78 is then sent via line 50 to the turbine 52. The output power of the turbine generator 58 is also taken to generate energy through the generator part 54. The objective of the proposed utility model is the selection and use of energy, which is currently wasted . Depending on the circumstances, it may be advantageous to install a water separator in front of the second heat exchanger 78 in order to dry the natural gas. Suitable are water separators using absorbent media known in the art. Usually two water separators are used. While one water separator is in operation, the absorbent medium of the other water separator is regenerated. Of course, if the task is to provide low temperatures for air conditioning or cooling, the hot water circuit is not used.

In the context of this document, the word “contains” should not be used in a restrictive sense, that is, that objects following this word are included, and objects not specifically mentioned are not included. A reference to an element using the indefinite article “a” does not exclude the possibility of more than one such element, unless it is clear from the context that there should be one single element.

It is obvious to the skilled person that the described preferred embodiment can be modified without going beyond the scope and essence of the utility model defined in the formula.

Claims (3)

1. A pressure control station for a natural gas distribution system comprising a turbine driven by expanding the natural gas supplied to the pressure control station while lowering its pressure, wherein the output of the turbine is used for its intended purpose; and a heat exchanger configured to extract cold from natural gas exiting the turbine for use for air conditioning or cooling. 2. The station according to claim 1, characterized in that an electric generator is provided for driving said turbine. 3. A pressure control station for a natural gas distribution system containing a gas turbine electric generator driven by using a portion of the natural gas supplied to the pressure control station, wherein the output power of said turbine generator is selected for its intended purpose; a first heat exchanger using exhaust gases from a turbine generator to pre-heat the liquid; a turbine driven by the expansion of natural gas while lowering its pressure, and the selection of the output power of the turbine is used for its intended purpose; and a second heat exchanger using said liquid to preheat the natural gas sent to the turbine.