Petroleum och motsvarande tekniker

This standard covers architectural doors applied to topside and living quarter areas for fixed or floating offshore oil and gas projects.

This document is applicable to all wells that are operated by the petroleum and natural gas industry. This document is applicable to any well, or group of wells, regardless of their age, location (including onshore, subsea and offshore wells), function, status or type (e.g. naturally flowing, artificial lift, injection wells). This document is intended to assist the petroleum and natural gas industry to effectively manage well integrity during the well life cycle by providing: — minimum requirements to ensure management of well integrity; and — recommendations and techniques that well operators can apply in a scalable manner based on a well’s specific risk characteristics. Assuring well integrity comprises two main building blocks: the first is to ensure well integrity during well design and construction, and the second is to manage well integrity throughout the remaining well life thereafter. This document addresses each stage of the well life cycle, as defined by the six phases in a) to f), and describes the deliverables between each phase within a Well Integrity Management system. a) The “Basis of Design Phase” identifies the probable safety and environmental exposure to surface and subsurface hazards and risks that can be encountered during the well life cycle. Once identified, these hazards and risks are assessed such that control methods of design and operation can be developed in subsequent phases of the well life cycle. b) The “Design Phase” identifies the controls that are to be incorporated into the well design, such that appropriate barriers can be established to manage the identified safety and environmental hazards. The design addresses the expected, or forecasted, changes during the well life cycle and ensures that the required barriers in the well’s design are based on risk exposure to people and the environment. c) The “Construction Phase” defines the required or recommended elements to be constructed (including rework/repair) and verification tasks to be performed in order to achieve the intended design. It addresses any variations from the design which require a revalidation against the identified hazards and risks. The construction phase typically ends once the well is handed over to the production operations function. d) The “Operational Phase” defines the requirements or recommendations and methods for managing well integrity during operation. This is when typically wells are under the control of operations / production function. e) The “Intervention Phase” (including work-over) defines the minimum requirements or recommendations for assessing well barriers prior to, and after, any well intervention that involves breaking the established well barrier containment system. f) The “Abandonment Phase” defines the requirements or recommendations for permanently abandoning a well. The six phases of the well life cycle (including handover), as defined in this Scope, and their interrelationships, are illustrated in Figure 2 in the Introduction. v This document is not applicable to well control. Well control refers to activities implemented to prevent or mitigate unintentional release of formation fluids from the well to its surroundings during drilling, completion, intervention and well abandonment operations, and involves dynamic elements, i.e. BOPs, mud pumps, mud systems, etc. This document is not applicable to wellbore integrity, sometimes referred to as “borehole stability”. Wellbore integrity is the capacity of the drilled open hole to maintain its shape and remain intact after having been drilled.

This document specifies the requirements for qualification, application, testing and handling of materials for plant application of single layer fusion-bonded epoxy (FBE) coatings applied externally for the corrosion protection of bare steel pipe for use in pipeline transportation systems for the petroleum and natural gas industries as defined in ISO 13623. NOTE Pipes coated in accordance with this document are considered suitable for additional protection by means of cathodic protection.

I detta dokument anges krav på provtagning, tekniska krav, miljökrav, provningsmetoder och beteckning för hydraulvätskor av klass M (utan krav på köldegenskaper) och klass V (med krav på köldegenskaper).

Detta dokument är tillämpbart för den färdiga, oanvända hydraulvätskan, inklusive tillsatsmedel.

Detta dokument omfattar inte svårbrännbara hydraulvätskor.

This document specifies a method for evaluating the change of consistency, as measured by cone penetration, of lubricating grease when worked in the roll stability test apparatus. The method only applies to greases with cone penetration in the range 175 1/10 mm to 385 1/10 mm as measured using ISO 2137.

This document specifies a method for evaluating the change of consistency, as measured by cone penetration, of lubricating grease when worked in the roll stability test apparatus, in presence of water. The method only applies to greases with cone penetration in the range 175 1/10 mm to 385 1/10 mm as measured using ISO 2137.

This document covers the design, construction, operation, inspection and maintenance of stations for fuelling compressed natural gas (CNG) to vehicles, including equipment, safety and control devices. This document also applies to portions of a fuelling station where natural gas is in a gaseous state and dispensing CNG derived from liquefied natural gas (LCNG) according to ISO 16924. This document applies to fuelling stations supplied with natural gas as defined in local applicable gas composition regulations or ISO 13686. It also applies to other gases meeting these requirements including biomethane, upgraded coal-bed methane (CBM) and gas supplies coming from LNG vaporization (on-site or off-site). This document includes all equipment for downstream gas supply connection (i.e. point of separation between the CNG fuelling station piping and the pipeline network). Fuelling station nozzles are not defined in this document. This document covers fuelling stations with the following characteristics: — slow fill; — fast fill; — private access; — public access (self-service or assisted); — fuelling stations with fixed storage; — fuelling stations with mobile storage (daughter station); — multi-fuel stations. This document is not applicable to domestic CNG fuelling devices without buffer storage. NOTE This document is based on the condition that the gas entering the fuelling station is odorized. For unodorized gas fuelling stations, additional safety requirements are included in Clause 10.

This document specifies the design, construction, operation, maintenance and inspection of stations for fuelling liquefied natural gas (LNG) to vehicles, including equipment, safety and control devices.This document also specifies the design, construction, operation, maintenance, and inspection of fuelling stations for using LNG as an onsite source for fuelling CNG to vehicles (LCNG fuelling stations), including safety and control devices of the station and specific LCNG fuelling station equipment. NOTE Specific CNG equipment is dealt with in ISO 16923. This document is applicable to fuelling stations receiving LNG and other liquefied methane-rich gases that comply with local applicable gas composition regulation or with the gas quality requirements of ISO 13686. This document includes all equipment from the LNG storage tank filling connection up to the fuelling nozzle on the vehicle. The LNG storage tank filling connection itself and the vehicle fuelling nozzle are not covered in this document. This document includes fuelling stations having the following characteristics: — private access; — public access (self-service or assisted); — metered dispensing and non metered dispensing; — fuelling stations with fixed LNG storage; — fuelling stations with mobile LNG storage; — movable fuelling stations; — mobile fuelling stations; — multi-fuel stations.

This document specifies the requirements for qualification, application, testing and handling of materials required for the application of reinforced concrete coating externally to either bare pipe or pre-coated pipe for use in pipeline transportation systems for the petroleum and natural gas industries as defined in ISO 13623. The external application of concrete is primarily used for the negative buoyancy of pipes used in buried or submerged pipeline systems and/or for the mechanical protection of the pipe and its pre-coating. This document is applicable to concrete thicknesses of 25 mm or greater.