API TR 2578:2017 pdf free download.Flow Conditioner Installation and Effects on Turbine Meters
API MPMS Chapter 5.3 and parts of API MPMS Chapter 6 cover the installation requirements and performance characteristics of turbine meters in liquid hydrocarbon service. This research work provides data that should be considered for future incorporation into these standards.
Phase I of this flow conditioning task force was performed on water prior to 2009. As part of Phase I, an addendum was included in API MPMS Chapter 5, Section 5.3.5.3 and Appendix A.1, that recommended the need for flow conditioning rather than straight pipe of any length. Phase II was intended to prove or disprove whether the results on water would translate to light hydrocarbons, higher viscosities, larger line and strainer sizes, and different Reynolds numbers.
Phase II of the flow conditioning project tested several sizes and types of turbine meters, strainers, and piping arrangements with various types and arrangements of commercially available flow conditioners. This was carried out on a range of petroleum liquids to try to determine which flow conditioner arrangements provide adequate turbine meter accuracy for liquid hydrocarbon applications.
Previous work by the Ad Hoc Flow Conditioning Task Force determined that meter performance, as reflected by meter factor deviation, repeatability, and reproducibility, was sensitive to flow profile effects caused by obstructions in strainer baskets, as well as strainer basket movement.
Phase II testing continued with obstructions similar to those in Phase I (water testing), but “finger left” (D) and “finger right” (E) obstructions were eliminated part way through Phase II testing, as they were found to cause minimal change to meter factor deviation.
On either configuration (above), there were five different strainer obstructions:
a) half-moon left
b) half-moon right
c) full moon
d) “finger left”
e) “finger right”
Figure 2 shows the devices utilized to replicate installation effects or varying strainer blockages. Obstructions A and B were constructed having approximately half the strainer discharge bore. Obstruction C was constructed having close to the entire strainer discharge bore. The dimensions of obstructions D and E are approximately 1” x 4” regardless of strainer discharge bore. Strainers used in testing had nozzle diameters of 4”, 6”, and 8”.
Each separate test consisted of runs 1–7 (as listed below). Each of these seven runs consisted of six meter provings of five runs each. Each test was conducted at 53 % and 80 % of the maximum BPH rate of each size meter. The strainer, flow conditioning section, and meter remained constant while five different obstructions were sequentially installed in the strainer basket:
1. no obstruction
2. obstruction A (A-type in Figure 3 shows position)
3. obstruction B (B-type in Figures 3 and 4 shows position)
4. obstruction C (C-type in Figure 3 shows position)
5. obstruction D
6. obstruction E
7. no obstruction
2 Discussion of Results Phase II testing was conducted with two liquids similar to light hydrocarbons. One liquid was 2 to 2.5 cSt and the other 13.5 to 15 cSt. Phase II testing replicated the results of Phase I testing on water.
2.1 Strainers
If the basket changed position in the strainer body during operation (Figure 5), this affected the meter readings. We overcame the issue by bolting the basket to the basket ring in the body.
2.1.1 Strainer effects on flow profile and meter performance (performances and effects) are caused by:
a) nozzle-to-body ratio, size (nozzle/body), exit nozzle velocity;
b) basket movement during operation and consistent relocation on reinstallation after inspection;
c) basket location in the strainer body (annular width between basket and body wall) with respect to outlet nozzle;
d) debris on the basket wall; or
e) exit nozzle fluid velocity.
2.1.2 The data from our testing shows that the larger the strainer inlet/outlet and body, the lower the variation in meter factor (MF) on proving runs.
a) For the same nozzle size and configuration, a larger body/basket yielded slightly less variance in MF on the test runs.
b) For the same body size, a larger outlet nozzle size gave noticeably less variance in MF on the test runs.
c) The MF stability improves noticeably at strainer outlet nozzle velocities ≤ 15 fps, and is greatly improved ≤ 10 fps.
d) Only conical or concentric reducers were used at the strainer nozzle outlet.
e) The strainer basket being secured/fixed inside the body reduces the varying perturbations that the basket adds to the flow profile.API TR 2578 pdf download.API TR 2578:2017 pdf free download