Abstract: Disclosed aspects relate to a flow meter comprising a flow target arranged to be disposed in a fluid flow path in a conduit; a beam coupled to the flow target and arranged to extend outside of the conduit; a sensor having a moveable sensor part coupled to the beam at a position which in use is outside of the conduit, and a static sensor part, wherein displacement of the moveable sensor part with respect to the static sensor part generates a signal. In use, fluid flow acting on the flow target causes displacement of the moveable sensor part, thereby generating a signal which is representative of the fluid flow rate.

Abstract: There is disclosed a valve comprising a valve body having an upper sealing surface and a maintainable seat detachably attached to the valve body and having a lower sealing surface. A gasket is disposed between the upper and lower sealing surfaces so as to provide a seal between the valve body and the maintainable seat. At least one of the sealing surfaces is profiled. This results in the gasket being highly-compressed so as to form an effective seal.

Abstract: The invention relates to a monitoring apparatus (312) for a steam plant, the apparatus comprising: a vibro-acoustic sensor (311) associated with a component of the steam plant, the sensor (311) being configured to provide an output indicative of the operating condition of the component; and a condition monitoring unit (313) coupled to the sensor (311); wherein the condition monitoring unit (313) is configured to analyse the output of the sensor (311) in order to identify characteristics attributed to live steam and characteristics attributed to condensate and to estimate steam leakage and condensate load for the component based on the identified characteristics. The invention also relates to a corresponding method of monitoring a steam plant.

Abstract: The invention relates to a monitoring apparatus for a steam plant, the apparatus comprising: a sensor unit (110) associated with a component of the steam plant, the sensor unit (110) being configured to provide an output indicative of the operating condition of the component; wherein the sensor unit (110) has a plurality of operating modes, each operating mode having a different resource usage; the apparatus further comprising: a selector (130) for selecting one of the plurality of operating modes; wherein the operating mode is chosen based on a current operating condition of the steam plant. The invention also relates to a method of operating such an apparatus.

Abstract: The invention relates to a monitoring apparatus for a steam plant, the apparatus comprising: a receiver (14) for receiving data from a sensor unit (10) associated with a component of the steam plant, the sensor unit (10) being configured to provide an output indicative of the operating condition of the component over a given period; a storage unit (16) which stores the data received by the receiver (14); and a trend analysis unit (18), the trend analysis unit (18) being configured to retrieve the data from the storage unit (16) and to process and analyse the data to thereby identify a trend in the operating condition of the component. The present invention also relates to a corresponding method of monitoring a steam plant.

Abstract: A vent head for a steam system is provided. In one embodiment, the vent head may comprise a body defining a vent head chamber and having a vent head outlet. The vent head comprises a steam inlet conduit having a steam outlet that opens into the vent head chamber and a baffle disposed within the vent head chamber and above the steam outlet. The baffle may have an impingement region and a convex portion which is disposed between the impingement region and the edge of the baffle. In use, the steam outlet discharges steam into the vent head chamber which impinges on the impingement region of the baffle, thereby separating entrained liquid water from the steam.

Abstract: A vent head for a steam system is provided. In one embodiment, the head comprises a body defining a vent head chamber and having a vent head outlet. The vent head comprises a steam inlet conduit having a steam outlet that opens into the vent head chamber and a baffle disposed within the vent head chamber above the steam outlet. A drainage passageway is provided for fluid communication between the vent head chamber and the steam inlet conduit. In use, the steam outlet may discharge steam into the vent head chamber which impinges on the baffle, thereby separating entrained liquid water from the steam. The separated water is collected in the vent head chamber returned to the steam inlet conduit via the drainage passageway.

Abstract: Systems and methods are provided that relate to determining the phase compositions of a multiphase fluid flow in a fluid line, including determining a flow velocity parameter which is related to the flow velocity of the fluid flow in the fluid line using a flow sensor and obtaining a vibration signal from the fluid flow using a vibration sensor comprising a target disposed in the fluid flow which vibrates in response to fluid flow in the fluid line. The signal may be analysed to determine an energy parameter which is related to the energy of the vibration signal within a frequency band, and a phase composition parameter, such as a dryness parameter, relating to the phase compositions of the fluid flow is determined using the flow velocity parameter and the energy parameter. An apparatus for determining the phase compositions of a multiphase fluid flow in a fluid line is disclosed.

Abstract: A vent head for a steam system is provided. In one embodiment, the head comprises a body defining a vent head chamber and having a vent head outlet. The vent head comprises a steam inlet conduit having a steam outlet that opens into the vent head chamber and a baffle disposed within the vent head chamber above the steam outlet. A drainage passageway is provided for fluid communication between the vent head chamber and the steam inlet conduit. In use, the steam outlet may discharge steam into the vent head chamber which impinges on the baffle, thereby separating entrained liquid water from the steam. The separated water is collected in the vent head chamber returned to the steam inlet conduit via the drainage passageway.

Abstract: A vent head for a steam system is provided. In one embodiment, the vent head may comprise a body defining a vent head chamber and having a vent head outlet. The vent head comprises a steam inlet conduit having a steam outlet that opens into the vent head chamber and a baffle disposed within the vent head chamber and above the steam outlet. The baffle may have an impingement region and a convex portion which is disposed between the impingement region and the edge of the baffle. In use, the steam outlet discharges steam into the vent head chamber which impinges on the impingement region of the baffle, thereby separating entrained liquid water from the steam.

Abstract: Aspects relate to an energy recovery unit comprising a vessel having a condensate inlet and a condensate outlet and a fluid feed line defining a fluid path. First and second heat exchangers are located within the vessel and are arranged to transfer heat from flash vapor and condensate respectively, to fluid in the fluid feed line. The energy recovery unit can be used to recover waste energy from condensate and flash steam and use it to pre-heat process water, such as boiler feed water.

Abstract: A flow meter for monitoring fluid flow through a pipeline, the flow meter comprising a conduit having a fluid inlet and a fluid outlet for communication with respective sections of the pipeline; a target element positioned inside the conduit between the fluid inlet and the fluid outlet, the target element being mounted for resilient axial displacement under a pressure differential between the inlet and the outlet; an arm secured at an anchor point on one side of the conduit and extending radially across the conduit, the target element being coupled to the arm for applying a load to the arm, upon said axial displacement of the target element, so as to deflect the arm relative to the anchor point; a sensor arrangement for measuring deflection of the arm at a point on the opposite side of the applied load to the anchor point; and a processor configured for providing a signal representative of the steam flow through the conduit in response to said measured deflection.

Abstract: A condensate recovery system may comprises a plurality of drain lines for draining condensate from an associated steam plant. Each drain line may incorporates a steam trap and feeds into a common condensate return line running between the drain lines and a condensate receiver tank. The system further may comprises an acoustic sensor positioned along the common condensate return line, upstream of the receiver tank, for providing an acoustic output indicative of the collective steam loss through steam traps upstream of the sensor.

Abstract: A method of detecting the presence of a slug of condensate in a conduit carrying a saturated steam comprising using a flow meter to provide an output signal representing mass flow rate of the saturated steam through the conduit; determining the rate of change of the output signal; and generating an alert in response to a predetermined profile of the output signal, when the profile includes a rate of change of the output signal falling outside a predetermined range.

Abstract: There is provided a valve element for a condensate trap comprising an expansion chamber in the form of a metallic bellows having a variable axial length and having first and second ends sealed with first and second end caps respectively. A valve closure member is provided on the second end cap and is arranged to cooperate with a valve seat. A first guide member is coupled to the first end cap and axially extends into the bellows and a second guide member is coupled to the second end cap, axially extends into the bellows and cooperates with the first guide member. This allows relative axial movement between the first and second end caps but restricts relative radial movement between the first and second end caps. This helps to ensure that the valve closure member properly seats on the valve seal.

Abstract: A condensate trap comprises a trap element 12 disposed in a trap chamber 6, and a sensor chamber 16 containing a sensor element 24 for monitoring the performance of the trap element 12. The sensor chamber 16 communicates with the trap chamber 6 through a first passageway 26 and one or more second passageways 28. The first passageway 26 opens into the sensor chamber 16 at an upper region of the sensor chamber, while the second passageway 28 opens at a lower region, so that the sensor element 24 is situated at a level above the lowermost part of the port at which the second passageway 28 opens into the sensor chamber 16. If the trap element 12 does not close the outlet 10 properly, condensate accumulating in the sensor chamber 16 will be forced into the trap chamber 6 through the second passageway 28, and the level will fall to expose the sensor element 24 which will react to provide an alarm signal.

Abstract: A condensate trap assembly includes a monitoring device 4 which is closely coupled to, or integral with, a condensate trap 2. The monitoring device 4 includes a flow restriction 56 and a condensate receiving chamber 48 which accommodates a sensor 66. The chamber 48 communicates with an inlet passage 52 on the upstream side of the flow restriction 56 and, via a bore 50, with an outlet passage 54 on the downstream side of the flow restriction 56. The sensor 66 provides an indication of the condition of the condensate trap 2, in accordance with whether the sensor tip 68 is submerged in condensate and in accordance with the temperature of the condensate.

Abstract: A pressure powered pump has valve members 18, 20 operated by a float acting through an overcenter mechanism 24. The overcenter mechanism has a valve actuating lever 36, on which are provided actuating pins 46, 48 for engagement with the respective valve members 18, 20. When the valves are closed, there is a substantial clearance a between the actuating pins 46, 48 and the respective valve member or its stem 50. This causes the actuating pin 46, 48 to apply an impact to the-valve member 18, 20, so assisting its opening movement. Stops 58, 60 are provided to arrest the valve actuating member 36 at its stable end position, so avoiding high impacts being applied to the valve members 18, 20 when they close.

Abstract: A thermodynamic condensate trap comprises a body 2 and a cap 18 which define a chamber 24. Inlet and outlet passage 8, 10 emerge into the trap chamber 24 at a seating face 12. A valve element in the form of a disc 26 is movable within the chamber 24 to open and close a flow path through the chamber 24 between the inlet passage 8 and the outlet passage 10. The cap 18 has thermal insulating means, for example in the form of air spaces 30, 32 to reduce heat transfer between the trap chamber 24 and the ambient surroundings. This reduces the cycle time of the trap, and consequently, extends the useful life of its components.

Abstract: A flow meter comprises a divergent nozzle region 6 and a plug 10 which is axially displaceable within the nozzle region 6 under the influence of a flowing fluid. The plug 10 is guided, during displacement, by vanes 38 extending inwardly from the wall of the nozzle region 6. The plug 10 is displaceable against the action of a spring 20 which abuts a support ring 22. The force applied by the spring 20 to the support ring 22 is transmitted to a strain element 26. Processing circuitry 36 receives inputs from strain gauges 32 and provides an output representing the flow rate of fluid through the flow meter.