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Product Engineering Reference

Orifice Flanges

A comprehensive engineering reference for EPC contractors, process instrumentation engineers, flow measurement specialists and procurement teams — covering orifice flange design, pressure tap configurations, Jack Screw function, ASME B16.36 dimensional data, orifice plate beta ratio selection, differential pressure flow measurement principles, material grades and full project documentation.

ASME B16.36 / ISO 5167 Class 300–2500 NPS 1"–24" A105 · A182 F304L/F316L WN · SO · Flange / Corner Tap EN 10204 3.1 / 3.2 MTC
Orifice Flanges by RR Hydraulics
300+
SKUs in Stock
1"–24"
NPS Range
Cl.300–2500
Pressure Classes
12+
Material Grades
RF / RTJ
Face Types
48 hr
Express Dispatch
Part 01

Orifice Flange Design, Pressure Tap Configurations
& Jack Screw Function

Orifice flange design and pressure tap configurations
Part 01 — Design, Pressure Tap Configurations & Jack Screw
Orifice Flange Pair · ASME B16.36 · Pressure Taps
Flange Tap · Corner Tap · Jack Screws · Weld Neck · Slip-On
Orifice Flange · Orifice Flange Pair · ASME B16.36 · ISO 5167 · AGA-3 · Pressure Tap · Flange Tap · Corner Tap · D-D/2 Tap · Jack Screw · Weld Neck Orifice · Slip-On Orifice · Beta Ratio · Differential Pressure · 

Definition and Engineering Function

An orifice flange is a special flange type — supplied and installed as a matched pair — specifically designed to house a removable orifice plate (a thin disc with a precisely sized central bore) between the two mating flange faces for differential pressure flow measurement. The orifice plate restricts the flow, creating a pressure drop across the plate. By measuring this differential pressure (ΔP) between two pressure tapping points — one upstream and one downstream of the orifice plate — the volumetric or mass flow rate of the process fluid can be calculated using the ISO 5167 orifice meter equation.

The orifice flange differs from a standard pipe flange by incorporating: (1) radially drilled and tapped pressure tap holes in each flange body, connecting the pipe bore to the flange face where the upstream and downstream pressures are transmitted to the connected differential pressure (DP) transmitter; and (2) Jack Screws — threaded bolts installed radially in the flange body that push against the upstream and downstream flange faces to separate the flanges sufficiently to allow the orifice plate to be slid in and out without breaking the pipe connection.

Engineering Purpose — Jack Screws

Jack Screws are radially threaded bolts installed in both flanges of an orifice flange pair. When turned inward (clockwise), the Jack Screw tips bear against the face of the adjacent flange and push the two flanges apart — creating a gap sufficient to slide the orifice plate in or out without removing the pipe bolts, disconnecting the pressure impulse tubing, or breaking the pipe connection. Jack Screws eliminate the need to remove the pipe flanges entirely to access the orifice plate — the plate can be changed with the line in service (after depressurisation). Typically two Jack Screws per flange (four per pair) at 90° to the pressure taps, sized 1/2" or 3/4" UNC per ASME B16.36.

Request a Formal Quotation — Orifice Flanges, All Sizes & Materials
ASME B16.36 · Class 300–2500 · WN / SO · CS A105 / SS F304L/F316L / Duplex · EN 10204 MTC

Orifice Flange Anatomy — Four Key Features

Pressure Tap Holes
1/2" NPT · radially drilled
Radially drilled and NPT-tapped holes through the flange body connecting the pipe bore to the outside of the flange. The upstream flange has one tap; the downstream flange has one tap. The tap holes must be drilled precisely at the correct axial position (1" from the flange face for flange tap type) and must open flush with the flange face at the bore wall without protruding into the bore.
Jack Screw Holes
1/2" or 3/4" UNC · radial
Radially tapped holes (90° from the pressure taps) in each flange body that accept the Jack Screw bolts. The Jack Screw tips are pointed or cup-tipped to bear accurately on the mating flange face without damaging it. Four Jack Screws per pair (two per flange) is standard. When turning Jack Screws to open the flanges, the pipe bolts must first be loosened but not removed.
Flange Body (WN or SO)
ASME B16.36 · heavier than B16.5
The orifice flange body is thicker than a standard B16.5 flange of the same pressure class to accommodate the pressure tap and Jack Screw drillings without reducing the structural cross-section below the minimum required. The flange body also has additional bolt holes compared to a standard B16.5 flange to allow the bolt spacing to remain compatible with the tap and Jack Screw positions. Always verify B16.36 bolt pattern — it differs from B16.5 in some NPS/class combinations.
Orifice Plate Slot
Flange face gap for plate
The orifice plate is a flat disc slightly smaller in OD than the flange face raised face diameter, with the precisely bored orifice at its centre. It slides into the gap between the two flange faces. Two centering pins (or a handle tab) on the plate ensure it is correctly centred in the pipe bore. The plate must be oriented correctly — upstream bevel facing upstream per ISO 5167 — and the plate handle tab must project out of the flange gap into a visible location for status identification.

Pressure Tap Types — Engineering Descriptions

Flange Tap
ASME B16.36 · ISO 5167-2 · Most common
Pressure taps located exactly 1" (25.4 mm) from the upstream and downstream flange faces, measured along the pipe axis. The flange tap position is independent of NPS and pipe schedule — always 1" from the face in both flanges. This is the most widely specified tap configuration for orifice flanges because the tap position is inherent to the flange design and does not require separate pipe tappings. Covered by ISO 5167-2 with published discharge coefficient tables. Used for NPS 2" and above.
Corner Tap
ISO 5167-2 · NPS 1"–6"
Pressure taps located at the upstream and downstream corners of the orifice plate — at the interface between the flange face and the pipe bore. The corner tap measures the pressure immediately adjacent to the orifice plate, giving a higher differential pressure signal for small-bore meters than flange taps. Used with corner tap orifice carriers (ring-type) or with special corner-tap orifice flanges. Standard for NPS 1" through 6" per ISO 5167-2. Requires very precise face finish and plate seating to avoid leakage around the plate face.
D and D/2 Taps (Radius Taps)
ISO 5167-2 · Radius tap
Upstream tap at 1 pipe diameter (D) upstream of the orifice plate face; downstream tap at 0.5D (D/2) downstream. These taps are made in the pipe wall (not in the orifice flanges themselves) and require separate welded-on pipe nipples. D-D/2 taps give lower permanent pressure loss than flange taps and a slightly higher discharge coefficient accuracy per ISO 5167-2. Used in larger bore, higher accuracy flow measurement applications where the additional installation effort is warranted.
Vena Contracta Taps
ISO 5167-2 · Maximum ΔP
Upstream tap at 1D upstream; downstream tap at the point of vena contracta (minimum pipe cross-section downstream, approximately 0.3D–0.8D downstream depending on beta ratio). Produces the maximum differential pressure signal, maximising meter sensitivity for low-flow conditions. Tap positions depend on the specific beta ratio, making these taps application-specific and less flexible than flange or D-D/2 taps when beta ratio changes. Rarely used in new designs; found in legacy installations.
Weld Neck Orifice Flange
ASME B16.36 · High integrity
Orifice flange in weld neck configuration — the most structurally robust and most widely specified type. The tapered hub provides the same stress distribution advantages as a standard weld neck flange (SIF = 1.0), making weld neck orifice flanges suitable for high-pressure, cyclic and fatigue-sensitive flow measurement applications. Mandatory for Class 600 and above per most EPC piping specifications. Bore must be specified to match the pipe schedule per ASME B36.10M.
Slip-On Orifice Flange
ASME B16.36 · Class 300/600
Orifice flange in slip-on configuration. Lower structural integrity than weld neck but easier to align and install. Two fillet welds required (inside and outside) per ASME B31.3. Limited to Class 150 and 300 in most EPC specifications. Suitable for non-critical low-pressure utility flow measurement. Not recommended for high-pressure, cyclic, hazardous fluid or fatigue-sensitive service. Less common in new plant designs, but widely used in older installations and retrofit flow measurement additions.
Part 02

Flow Measurement Principles, Beta Ratio
& ASME B16.36 Dimensional Data

Orifice flange flow measurement and dimensional data
Part 02 — Flow Measurement, Beta Ratio & ASME B16.36 Dimensions
ISO 5167-2 · AGA-3 · Beta Ratio β · Discharge Coefficient
ASME B16.36 · Class 300–2500 · NPS 1"–24"
ISO 5167-2 · AGA-3 · Beta Ratio β · Orifice Bore · Discharge Coefficient Cd · Differential Pressure ΔP · Reynolds Number · Permanent Pressure Loss · ASME B16.36 · Bore Match · 
Sourcing Orifice Flanges for a Flow Measurement or EPC Project?
ASME B16.36 · All classes · WN / SO · CS / SS / Duplex · EN 10204 MTC · Jack Screws included

Differential Pressure Flow Measurement Principle

The orifice meter operates on the Bernoulli principle: as fluid accelerates through the restriction created by the orifice plate bore, the velocity increases and the static pressure decreases. The differential pressure (ΔP) between the upstream and downstream pressure taps is a function of the flow rate. The flow rate Q is calculated from the ISO 5167 orifice meter equation:

ISO 5167-2 — Orifice Meter Flow Rate Equation Q_m = C_d / √(1-β⁴) × (π/4) × d² × √(2ΔP × ρ) // Mass flow rate [kg/s]; d = orifice bore [m], ρ = fluid density [kg/m³]
β = d / D // Beta ratio; d = orifice bore [m], D = pipe bore [m]; typical range 0.30–0.75
C_d 0.603 – 0.624 // Discharge coefficient for flange taps per ISO 5167-2 (function of β and Re_D)

// BETA RATIO SELECTION GUIDE:
// β = 0.30–0.45: High ΔP, low flow range, high permanent pressure loss; small bore meter
// β = 0.45–0.65: Balanced ΔP and accuracy; most common range for process flow measurement
// β = 0.65–0.75: Lower ΔP, wider flow range, lower permanent pressure loss; large bore meter

Beta Ratio (β) Selection and Permanent Pressure Loss

The beta ratio (β = orifice bore / pipe bore) is the primary design parameter for an orifice meter. A lower beta ratio produces a higher differential pressure (better meter sensitivity and turndown) but also a higher permanent pressure loss in the system — energy that is permanently lost to the process as heat due to the turbulence downstream of the orifice plate. A higher beta ratio reduces permanent pressure loss but also reduces the differential pressure signal and meter sensitivity.

The permanent pressure loss as a fraction of the differential pressure is approximately: ΔP_perm / ΔP_total ≈ (1 − β²). For β = 0.5: ΔP_perm ≈ 75% of ΔP_total — a significant energy penalty in high-flow, high-pressure systems. For β = 0.7: ΔP_perm ≈ 51%. The trade-off between meter sensitivity, turndown ratio, accuracy and permanent pressure loss must be evaluated for each application by the flow measurement engineer.

Table 1 — ASME B16.36 Orifice Flange Dimensions: Class 300 Weld Neck (Selected NPS)
NPSFlange OD (mm)Bolt Circle (mm)No. BoltsBolt SizeFlange Thick. (mm)Tap Hole SizeJack Screw Size
2"165.1127.08M1628.61/2" NPT1/2" UNC
3"209.6168.38M2031.81/2" NPT1/2" UNC
4"254.0200.08M2035.11/2" NPT1/2" UNC
6"317.5269.912M2038.13/4" NPT3/4" UNC
8"381.0330.212M2444.53/4" NPT3/4" UNC
10"444.5387.316M2450.83/4" NPT3/4" UNC
12"520.7450.816M2757.23/4" NPT3/4" UNC

ASME B16.36-2015. Weld neck orifice flange dimensions for Class 300. Flange OD and bolt circle are the same as ASME B16.5 Class 300 standard flanges — orifice flanges are bolt-compatible with standard flanges of the same NPS and class. Orifice flanges are typically thicker than standard B16.5 flanges to accommodate the tap and Jack Screw drillings. Orifice flanges are always supplied as matched pairs (one upstream + one downstream); tap hole position and Jack Screw holes are drilled and tapped at the manufacturer before dispatch. Bore specified to match pipe schedule per ASME B36.10M.

Table 2 — Straight Pipe Run Requirements: Upstream and Downstream of Orifice Plate (ISO 5167-2)
Upstream FittingBeta = 0.30 (D upstream)Beta = 0.50 (D upstream)Beta = 0.70 (D upstream)Downstream (all β)
Single 90° elbow10D14D22D5D minimum
Two 90° elbows (same plane)16D22D42D5D minimum
Two 90° elbows (different planes)34D44D70D5D minimum
Reducer (2D to D, >0.5D taper)5D8D12D5D minimum
Expander (0.5D to D, full bore valve)16D22D44D5D minimum
Globe valve (fully open)18D24D46D5D minimum
Gate valve (fully open)5D8D12D5D minimum

ISO 5167-2:2022. D = pipe inside diameter. Straight pipe run requirements are the minimum unobstructed straight pipe lengths (no fittings, no valves, no changes in direction) required upstream and downstream of the orifice plate to achieve the uncertainty values stated in the ISO 5167-2 discharge coefficient tables. Insufficient straight run is the most common cause of orifice meter measurement error in installed systems. Always verify available straight run during piping layout — insufficient run requires a flow conditioner upstream.

Part 03

Material Grades, NACE Compliance
& Bore and Face Finish Requirements

Orifice flange material grades
Part 03 — Materials, NACE Compliance & Critical Finishes
A105 · A182 F304L/F316L · Duplex F51 · F11/F22/F91
NACE MR0175 · Bore Finish · Tap Hole Cleanliness
A105 · A350 LF2 · A182 F304L · F316L · F321 · F51 Duplex · F53 Super Duplex · F11 · F22 · F91 · Inconel 625 · NACE MR0175 · Bore Ra 3.2 µm · Tap Hole Clean · 
Table 3 — Material Grades for Orifice Flanges
MaterialASTM GradeYield (MPa)Temp Range (°C)CorrosionApplication
Carbon SteelA105 N≥250−29 to +538LowStandard process piping, gas measurement, utilities
LTCSA350 LF2 Cl.1≥260−46 to +343LowCold service, LNG vapour, ethylene plant
1.25Cr-0.5MoA182 F11 Cl.2≥310−29 to +593ModerateHigh-temp refinery flow measurement, H₂ service
2.25Cr-1MoA182 F22 Cl.3≥310−29 to +621ModerateHydrocracker, reformer, high-temp/pressure refinery
9Cr-1Mo-VA182 F91≥585−29 to +649ModerateUltra-supercritical power steam flow measurement
SS 304/304LA182 F304/F304L≥205−196 to +816HighChemical, pharmaceutical, food, cryogenic measurement
SS 316/316LA182 F316/F316L≥205−196 to +816Very HighOffshore, chloride, chemical, pharma measurement
Duplex 2205A182 F51≥450−50 to +315Very HighOffshore sour gas flow measurement, seawater
Super DuplexA182 F53/F55≥550−50 to +300ExtremeSubsea, severe sour, HPHT flow measurement
Inconel 625A182 F625≥414−196 to +980ExtremeHigh-temp corrosive, acid service measurement

Critical Bore and Tap Hole Finish Requirements

Unlike standard pipe flanges, orifice flanges have two additional critical finish requirements that directly affect the accuracy of the flow measurement: (1) Pipe bore surface finish — the internal bore of the pipe in the straight run region approaching the orifice plate must have a surface roughness of Ra ≤ 3.2 µm (125 micro-inch) for a length of at least 2D upstream of the orifice flange, per ISO 5167-2. A rougher bore surface causes additional turbulence that shifts the discharge coefficient outside the published ISO 5167 calibrated range, introducing measurement error. The orifice flange bore itself must also be machined to Ra ≤ 3.2 µm; (2) Pressure tap hole cleanliness and finish — the pressure tap holes must be free of burrs, chips, weld spatter and rust on the inside bore and at the opening into the pipe bore. Any protrusion of the tap hole edge into the pipe bore, or any roughness at the opening, creates a local flow disturbance that shifts the measured pressure at that tap and introduces a systematic measurement error. The tap hole opening at the bore must be sharp-edged and flush with the bore surface — neither recessed nor protruding.

Critical Requirement — Tap Hole Opening at the Pipe Bore

The pressure tap hole opening at the pipe bore wall is the most critical machining feature on an orifice flange. The opening must be: (a) sharp-edged — no burr, chamfer, radius or bevel at the bore opening; (b) flush with the bore wall — the tap hole must not protrude into the bore (a protrusion of even 0.1 mm introduces a stagnation zone that reads a different pressure than the true static pressure); (c) perpendicular to the bore wall — the drilling axis must be exactly radial; an angled tap introduces a velocity component into the pressure reading; (d) correct diameter at the opening — ISO 5167-2 limits the tap hole diameter to a maximum of D/8 (one-eighth of the pipe bore diameter) at the bore wall opening. Each of these requirements must be verified by inspection with a dial gauge and optical examination before the orifice flange is dispatched. A non-conforming tap hole cannot be corrected in the field — the flange must be remachined or replaced.

Part 04

Installation Requirements, Applications
& Quality Control and Documentation

Orifice flange installation and applications
Part 04 — Installation, Applications & QC Documentation
Straight Run · Orifice Plate Orientation · DP Transmitter
Gas · Oil · Steam · Chemical · Refinery · Power Plant
Straight Pipe Run · Flow Conditioner · Orifice Plate Orientation · Upstream Tag · DP Transmitter · Impulse Tubing · Gas Metering · Liquid Metering · Steam Flow · Refinery · Power Plant · Offshore · 

Installation Requirements

Straight Pipe Run Verification

Before finalising the orifice flange location in the piping layout, the upstream and downstream straight pipe run requirements per ISO 5167-2 (Table 2 above) must be confirmed as achievable in the actual piping arrangement. The straight run is the most commonly violated requirement in orifice meter installations — often because the meter location is chosen for convenience without checking the distances to the nearest upstream and downstream fittings. Insufficient straight run is the primary cause of orifice meter measurement uncertainty exceeding the ISO 5167 stated limits. Where adequate straight run cannot be achieved, a flow conditioner (e.g. Gallagher-type, CPA-type or tube bundle) installed upstream can reduce the required straight run length — but the specific conditioner type and its qualifying run must be verified per the conditioner manufacturer's data and the applicable flow measurement standard.

Orifice Plate Installation and Orientation

The orifice plate must be installed with the bevelled (upstream) face of the orifice plate facing upstream — the flat face must face downstream. The ISO 5167-2 discharge coefficient tables are calibrated for this specific orientation. Installing the plate reversed (flat face upstream) produces a significantly different discharge coefficient — typically 2–5% different — introducing a systematic measurement error. The orifice plate tab or handle must project outward from the flange gap and must be marked with the flow direction arrow and the plate serial number, beta ratio and bore diameter for identification without removing the plate.

Pressure Impulse Tubing and Transmitter Connection

The upstream and downstream pressure taps are connected to a differential pressure (DP) transmitter by impulse tubing. For liquid service, the impulse tubing must be routed downward from the orifice flange taps to the DP transmitter to prevent gas pockets forming in the impulse lines — gas pockets cause the measured pressure to be different from the true process pressure at the tap. For gas service, the impulse tubing must be routed upward to prevent liquid accumulation in the lines. For steam service, condensate pots (steam legs) must be installed in the impulse lines to equalise the liquid column on both sides of the DP transmitter. Incorrect impulse line routing is the second most common cause of orifice meter measurement error in installed systems.

Applications by Industry

Natural Gas and Pipeline Measurement

Orifice flanges per ASME B16.36 and AGA Report No. 3 (equivalent to ISO 5167-2 for natural gas) are the most widely used primary flow measurement device in natural gas transmission pipelines, gas distribution systems, custody transfer metering stations and gas processing plants. Carbon steel A105 weld neck orifice flanges in Class 300 through Class 1500 are standard for high-pressure gas transmission. Flange tap configuration is standard for all AGA-3 / ISO 5167 custody transfer applications requiring the published uncertainty values.

Refinery and Petrochemical Process Flow

Orifice flanges are the standard flow measurement device for process flow measurement throughout refineries and petrochemical plants — measuring crude oil feed, product streams, hydrogen flow, steam flow, cooling water, fuel gas, chemical injection rates and utility flows. A105 for standard carbon steel service; A182 F11/F22 for high-temperature hydrogen service; A182 F304L/F316L for corrosive chemical service; duplex 2205 (F51) for sour service with chloride. All refinery orifice flanges require EN 10204 3.1 MTC minimum; NACE sour service flanges require 3.2 with TPI.

Steam Flow Measurement in Power Plants

Weld neck orifice flanges in A182 F22 (2.25Cr-1Mo) and A182 F91 (9Cr-1Mo-V) are used for main steam, hot reheat and extraction steam flow measurement in power generation plants. High-temperature steam orifice flanges require PWHT after butt welding to the pipe and post-PWHT hardness verification. The bore finish requirement (Ra ≤ 3.2 µm) is particularly important in steam service where condensate on a rough bore surface can cause local flow asymmetry and measurement error during warm-up transients.

Offshore and Marine Flow Measurement

Duplex 2205 (A182 F51) and SS 316L (A182 F316L) orifice flanges are standard for flow measurement on offshore platforms — production wellhead flow measurement, separator test separators, gas lift metering, produced water metering and utility cooling water measurement. All offshore orifice flanges require EN 10204 3.2 MTC with TPI, PMI, NACE hardness mapping, Charpy impact testing (LTCS grades), ferrite content measurement (duplex) and bore finish verification reports as standard documentation.

Quality Control — Orifice Flange Specific Requirements

QC for orifice flanges covers all standard weld neck flange requirements (dimensional inspection, bore match, face finish, NDE) plus the following orifice-specific checks: (1) Tap hole position — the centreline of each tap hole must be at exactly 25.4 mm (1") from the upstream and downstream flange faces for flange tap type, measured along the pipe axis; (2) Tap hole opening diameter — must be ≤ D/8 per ISO 5167-2; (3) Tap hole opening condition — sharp-edged, flush, no burr, no chamfer, verified visually and by dial gauge; (4) Bore surface finish — Ra ≤ 3.2 µm measured with a profilometer in the tap hole region; (5) Jack Screw thread engagement — Jack Screws installed and function-tested (full in/out travel verified before dispatch); (6) Matching of paired flanges — upstream and downstream flanges must be tagged as a matched pair with serial numbers cross-referenced in the inspection report.

Export Packaging

  • Orifice flange pairs packed together as matched sets — upstream and downstream flanges must not be separated during transit; matched set tag on both flanges cross-referencing each other
  • Pressure tap holes plugged with clean plastic thread protector plugs (not metal — metal plugs can produce swarf inside the tap hole during removal); Jack Screw holes also plugged
  • Flange faces protected with foam or cardboard face pads; bore sealed with plastic bore caps
  • Jack Screws installed finger-tight in the flange holes for transport; additional spare Jack Screws supplied with the matched pair in a tagged poly bag
  • MTC (EN 10204 3.1/3.2), dimensional inspection report including tap hole position and opening diameter, bore finish report (Ra), tap hole opening condition report, Jack Screw function test certificate, PMI (alloy grades), NDE reports, NACE hardness (sour service), Charpy impact (LTCS), ferrite content (duplex) — all in waterproof sealed envelope with each matched pair
EPC & Flow Measurement Project Documentation Package — Orifice Flanges (12 Documents)
#DocumentStandard / ReferenceMinimum Requirement
01Material Test Certificate (MTC)EN 10204 3.1 / 3.23.2 (TPI co-signed) for offshore / NACE / alloy / safety-critical
02Dimensional Inspection ReportASME B16.36OD, bolt circle, flange thickness, bore ID (per pipe schedule) — all mandatory
03Tap Hole Position Report ASME B16.36 / ISO 5167-2Tap centre at 25.4 mm (1") from face ±0.5 mm confirmed for flange tap type
04Tap Hole Opening Condition ReportISO 5167-2 Clause 5.1.4Sharp-edged, flush, no burr; dia. ≤ D/8; dial gauge and visual verification
05Bore Surface Finish ReportISO 5167-2 / B46.1Ra ≤ 3.2 µm at tap hole region — profilometer measurement mandatory
06Jack Screw Function Test CertificateASME B16.36Full travel in/out verified; tip condition; thread engagement confirmed
07Face Finish ReportASME B16.5 / B46.1125–250 AARH for RF gasket face; RTJ groove dimensions confirmed
08PMI Report (XRF / OES)Project specification100% SS, duplex, Inconel and all alloy grade orifice flanges
09Hardness Test ReportASTM E10 / NACE MR0175NACE sour service: ≤22 HRC cross-section; duplex: ≤310 HB
10Charpy Impact Test ReportASTM A370 / EN ISO 148Mandatory for A350 LF2/LF3 LTCS; ≥27 J at MDMT
11ISO 9001 Manufacturer CertificateISO 9001:2015Current; scope must include pressure flange forging and precision bore machining
12ISPM-15 Phytosanitary CertificateIPPC / FAOAll wood packing for international export
Manufacturer Capability — RR Hydraulics

RR Hydraulics manufactures and exports orifice flanges as matched pairs in weld neck and slip-on configurations per ASME B16.36, in all pressure classes (300–2500), in A105, A350 LF2, A182 F11/F22/F91, A182 F304L/F316L, A182 F51/F53 and Inconel 625. Flange tap (1/2" and 3/4" NPT) and corner tap configurations; Jack Screws (1/2" and 3/4" UNC) included with each pair. Bore matched to pipe schedule per B36.10M; bore finish Ra ≤ 3.2 µm verified by profilometer. Tap hole position and opening condition inspection reports included. EN 10204 3.1/3.2 MTC, PMI, NACE hardness, Charpy impact, ferrite content (duplex), TPI witness by BV/DNV/Lloyds/SGS/TÜV. 48-hour express dispatch on standard in-stock sizes.

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