In order to contextualize the supply and transportation of LNG from Canadian ports, as well as introduce some of the participants who may be involved, the first part of this article provides a general overview of the LNG value chain, which is typically comprised of the following elements running between the wellhead and the end user: (1) gas production; (2) pipeline transportation; (3) gas processing and liquefaction; (4) LNG shipping and trading; (5) regasification; and (6) distribution to end-users.
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Each element of the value chain is intended to add economic value, and although each of these phases are linked, each is a substantive, capital-intensive operation in its own right. The manner in which the value chain ties together, and the related contractual arrangements, depend on the financial and operational structure of the project and the individual risk profile and capabilities of the various participants. There are myriad ways in which the LNG value chain can be structured among multiple participants. From the perspective of a downstream utility or other energy company requiring a supply of LNG or gas, for example, there are various ways for it to enter the value chain in order to ultimately source such LNG or gas, including those illustrated in the figure below, that will offer varying degrees of control over supply and associated risk.
While a single sponsor could theoretically invest in the development of an entire value chain for secure supply (including the gas production assets, pipeline, liquefaction facility, LNG carriers, regasification facility, and even downstream pipeline and power generation facilities), in practice it is more common for one or more sponsors to invest in only certain portions of the value chain. For instance, there have been a number of examples of multiple participants investing in the upstream portions (with co-ownership of production assets, pipelines, or liquefaction facilities). Full chain participation by multiple sponsors is less common, as proponents will usually have downstream commitments in different locations, requiring the use of different shipping routes, regasification facilities, and downstream pipelines. Generally speaking, the fewer the participants involved and the more integrated the chain, the more control the participants will have over the supply, but the higher their capital investment (and associated exposure) is likely to be.
Other LNG projects may be structured with less integration and each element of the value chain may be an independent and free-standing operation by independent participants, who are driven by the economics of their individual operation rather than the LNG project as a whole. For instance, a gas producer may sell gas to a liquefaction facility operator, who may sell LNG to a buyer (transported by LNG carriers chartered from a third party shipowner), who may regasify the LNG using third party owned facilities to fulfil gas supply commitments in the destination country. For this type of structure, contractual commitments play a particularly crucial role in managing competing interests and allocating risk among the participants.
Irrespective of whether or not the elements are integrated, the LNG value chain ultimately links together through connections between the infrastructure of each successive phase, and contractually at each interface between two or more participants. Each element is codependent on the others. If, for instance, gas pipeline transportation to the liquefaction plant is interrupted, this may impact all other elements of the value chain both upstream and downstream of the pipeline, making alignment between contractual arrangements at each stage of the value chain desirable where possible.
The upstream segment of the natural gas industry typically refers to the operations involved in exploration, development, and production of natural gas. In Canada, a gas producer will generally first obtain rights (either directly or indirectly) under a mineral permit, licence or lease from the Crown, or a freehold lease if the minerals are privately held. The vast majority of gas that is expected to be fed into LNG projects in Canada is expected to be sourced from onshore reserves, but, if the reserves are offshore, their development will be subject to a different legal regime requiring exploration, significant discovery, and production licences.22 In any case, once a deposit has been selected for development, a production well will need to be drilled. The method of developing the well will be dependent on the geology of the reserve. For conventional natural gas, where the formation exists directly below the earth’s surface, vertical wells may be drilled straight down into the rock formations. Where the formation cannot be accessed vertically, the producer may extract the gas using horizontal drilling. This method incorporates a flexible drill pipe that can be directed horizontally at a desired depth. In the case of unconventional gas, primarily shale gas that is trapped in less porous rock, producers may use multi-stage hydraulic fracturing. This relatively new production method has contributed to the changing economics of the natural gas market, particularly in the US, transforming it from an importer to one of the largest exporters of LNG in a short period of time. However, this production method has not been universally popular, which has created an important role for conventionally sourced natural gas, and the LNG derived from it.23
Once natural gas has been extracted, it will typically be transported via one or more pipelines to a liquefaction facility to be processed and liquefied into LNG. If the pipelines are owned by third parties, gas transportation agreements will typically be entered into between the gas pipeline operators and the shippers of the gas (which could be the owner of the gas or the operator of the liquefaction facility if, for instance, it has agreed to receive gas upstream of the plant and arrange some or all of the pipeline transportation). The gas shipper will generally pay the pipeline tariffs, which factor into the economics of the sale and purchase of gas or LNG downstream and the project as a whole. As with gas production, it is critical to the reliability of any downstream commitments to supply LNG or gas that sufficient firm pipeline capacity be secured in order to ensure the reliable transportation of gas to the liquefaction facility.
The processing and liquefaction of natural gas at a liquefaction terminal can be structured in a variety of ways, but most projects will be structured based on one of the following fundamental models.
In this model, the LNG terminal operator purchases and takes title to the natural gas upstream of the facility (typically by way of a natural gas sale and purchase agreement, which, in Canada, will often be based on one of the GasEDI or NAESB standard forms), processes and liquefies the gas, and sells it as LNG downstream of the facility (typically by way of an LNG sale and purchase agreement (SPA)). Any LNG offtaker (which may not be the same person that sold the corresponding volumes of gas to the LNG terminal operator) will contract directly with the operator of the LNG terminal for the purchase of LNG and the cost of the gas and liquefaction process will generally be incorporated into the price of the LNG.
In this model, title to the natural gas (and LNG derived from it) generally remains with the customer using the LNG terminal during the liquefaction process (subject to any quantities the LNG terminal operator is entitled to use as fuel gas). Under a liquefaction tolling services agreement or other form of terminal use agreement between the customer and LNG terminal operator, the customer will be required to deliver its gas (while retaining title to it) upstream of the LNG terminal and, in return for payment of a tolling fee to the LNG terminal operator, the operator will process and liquefy the gas and deliver LNG to the customer downstream of the plant. The customer will then typically either sell its LNG to an offtaker at the outlet of the LNG terminal (as would be the case if the customer was selling the LNG on a Free On Board (FOB) basis) or arrange for the LNG to be transported to another location (as would be the case if the customer was selling the LNG on a Delivered Ex Ship (DES) or Delivered At Place (DAP) basis).24 Either way, the customer would pay a tolling fee to the LNG terminal operator and would generally seek to recover this cost (together with the cost of producing or purchasing the gas and any transportation costs) through the price at which it ultimately sells the LNG or gas downstream of the LNG terminal.
While the above models are the primary structures most often used for LNG terminals, many variants and hybrids may be used depending on commercial, operational, financial, and other factors. For example, where multiple proponents wish to develop an LNG terminal and participate in two or more components of the LNG value chain, it is not uncommon for integrated project structures to be used that essentially incorporate either the merchant or tolling model for the LNG terminal component. In such a case, the LNG terminal may be owned and operated by a project company which either provides each of the participants with a portion (based on its equity participation) of the terminal’s liquefaction capacity on a tolling basis (for example, with each participant supplying its own volumes of gas and marketing its own LNG) or operates essentially on a merchant basis for the benefit of each of the participants (potentially with the project company sourcing gas from a related upstream joint venture and marketing all of the LNG on behalf of the participants).
Where LNG is produced at a marine terminal for export, it will generally be stored and loaded onto LNG carriers so that it can be transported by sea to the relevant regasification terminal. It is this marine transportation component of the LNG value chain with which the next two parts of this article are primarily concerned. LNG carriers are specially designed vessels with insulated cargo tanks that are intended to carry LNG and keep it cool during a voyage. Despite having insulated tanks, quantities of LNG will inevitably convert to gas during a voyage, which is referred to as “boil-off.”
LNG carriers are often fitted with dual-fuel engines in order that their propulsion systems can run off boil-off gas (as an alternative to fuel oil). They may also be fitted with reliquefaction systems so that boil-off gas can be reliquefied and pumped back into the vessel’s cargo tanks.
Due to the nature of the LNG market, each voyage undertaken by an LNG carrier will typically involve two legs: (1) a “laden” voyage from the loading port where the liquefaction terminal is located to the discharge port where the regasification terminal is located; and (2) a “ballast” voyage from the discharge port to the next loading port. Since the tanks of an LNG carrier must be cooled before loading bulk LNG, a quantity of LNG (referred to as “heel”) is often retained on board following discharge, which is used to maintain the cargo tanks in a cooled state during the ballast voyage in order that the vessel’s tanks are ready to load LNG when they reach the loading port. Otherwise, an LNG carrier’s cargo tanks will need to be cooled down (typically by spraying LNG into the tanks) prior to loading LNG once the vessel reaches a loading port. If a vessel’s cargo tanks are “gas-free” (that is, full of air), which may be the case if the vessel is a newbuild or has had its tanks gas-freed in order to allow maintenance to be carried out on the tanks, then, prior to cooling-down, the tanks will also need to be “inerted” (by filling them with inert gas to remove oxygen) and then gassed-up (by filling them with methane to displace the inert gas). Gassing-up and cooling-down services are often provided at LNG terminals for this reason.
Which participant in the LNG value chain arranges shipping will depend on the structure of the particular project and, in particular, the terms of any LNG sale and purchase agreement LNG SPA. LNG SPAs commonly incorporate Incoterms in order to address the place of delivery and various other terms.25 The Incoterms that are most commonly used in LNG SPAs include:
Historically, LNG has been traded predominantly under long-term SPAs continuing for the life of a particular LNG liquefaction project, which was often required in order to secure project financing. However, due to a number of factors including the increasing number of proponents such as oil majors and large trading houses funding LNG projects without the use of project finance and a supply-driven market with LNG buyers requiring greater volume and destination flexibility, LNG is increasingly traded on a short-term or spot basis. This has resulted in a degree of standardization of the terms of the Master LNG SPAs that are commonly used in such short-term and spot trading of LNG, with a number of standard forms having been published by traders of LNG such as Trafigura and BP and industry associations such as the Association of International Petroleum Negotiators (AIPN) and the International Group of Liquefied Natural Gas Importers (GIIGNL).
Whether it is the buyer (in the case of a FOB sale) or the seller (in the case of a DAP or DES sale) that is responsible for transporting the LNG from the LNG liquefaction terminal, it will typically do so using an LNG carrier that it owns or has chartered. In some cases, LNG project proponents may wish to invest in LNG carriers and integrate the marine transportation component of the LNG value chain with other parts of the project. This has been seen in some cases, for example, where companies which have traditionally owned and operated ships have wanted to diversify and invest in other parts of the LNG value chain such as liquefaction, regasification, or power generation. However, given that many, if not most, buyers and sellers of LNG are not in the business of owning and operating LNG carriers — which involves significant capital costs, technical capabilities, and commercial and operational risk — it is common for traders of LNG to charter LNG carriers from shipowners whose principal business is the ownership and operation of such vessels.
Chartering refers to the procurement of the services of a ship such as an LNG carrier by way of a charter party, which is essentially a contract for the hire of a ship for a period of time or for one or more particular voyages. Traditionally, LNG carriers have been chartered under long-term time charter parties in order to fulfil obligations under long-term SPAs, often operating between a single loading port and a single discharge port for 20 years or more.26 However, with the increasing volumes of LNG traded on a short-term or spot basis, it is becoming more common for LNG carriers to be chartered under shorter-term time charter parties, voyage charter parties, or contracts of affreightment.27 In any case, there will be a significant cost associated with engaging a LNG carrier to transport LNG from a LNG liquefaction terminal and the buyer or seller (as the case may be) will have a significant interest in avoiding any delay in loading that could result in wasted hire (in the case of a time charter party) or liability to the shipowner for demurrage (in the case of a voyage charter party), along with additional boil-off of any LNG heel on the LNG carrier.
Users of an LNG terminal will therefore need to structure their offtake arrangements and schedule their deliveries of gas and LNG carefully in order to minimize the risk of delay and ensure that they have rights of recourse against their counterparties in the event of any unexcused delay. LNG SPAs will typically provide the buyer in a FOB sale with a right to receive demurrage and compensation for excess boil-off from the seller in the event the seller fails (other than by reason of force majeure or another excusable event) to complete delivery of the LNG within an allowed period of laytime, which is intended to compensate the buyer for the resulting wasted hire or demurrage and additional boil-off. LNG sellers will wish to ensure that such liabilities are covered up the value chain where possible and, if the seller is the customer of the LNG liquefaction facility under a tolling arrangement, it may seek to negotiate a right to receive compensation from the LNG facility operator if it fails without excuse to make a cargo of LNG available for lifting at the scheduled time. As with the rest of the LNG value chain, maximizing the alignment between contractual arrangements at each point is key.
Once the LNG carrier completes its voyage from the LNG liquefaction terminal and arrives at the destination port, the LNG will typically be unloaded and regasified at the receiving terminal in order that the gas can be transported further downstream by pipeline. In the event that the LNG is sold on a DAP or DES basis, it will be delivered by the seller to the buyer as it is unloaded from the seller’s LNG carrier at the unloading port or, in the case of an FOB sale, the LNG would already have been delivered to the buyer at the loading port and would be unloaded from the buyer’s LNG carrier at the unloading port. In either case, the LNG buyer would be responsible for arranging the receipt and regasification of the LNG.
Regasification facilities can take a number of different forms, and, by way of illustration, may be floating (as is the case with a floating storage and regasification unit (FSRU)), situated on a jetty, or located onshore. FSRUs are often converted LNG carriers with regasification equipment installed on their decks, but may also be purpose-built. They are moored offshore and connected to the shore by pipeline, enabling them to receive LNG from LNG carriers, regasify such LNG onboard, and then send the resulting natural gas onshore by pipeline.
Regasification facilities share a number of similarities with liquefaction facilities (essentially performing the opposite function by converting LNG back into natural gas). As with liquefaction facilities, they may be structured based on a merchant model (such that the operator of the facilities, if it does not already own the LNG, would purchase the LNG upstream of the regasification facilities, regasify it, and either use or sell the resulting gas downstream of the facilities) or a tolling model (such that the owner of the LNG would retain title to the LNG and resulting gas during the regasification process and pay the operator of the facilities a tolling fee for the regasification service provided under a terminal use agreement). They may also be part of an integrated project. There have been examples, for instance, of participants having interests in both the regasification facilities, downstream pipeline, and power generation facilities (for example, in gas to power projects).
Once the LNG has been regasified, the gas will usually be transported by pipeline to its point of consumption, which marks the end of the value chain. Within this section of the value chain downstream of the regasification terminal, there may potentially be multiple further contractual arrangements with respect to the storage, pipeline transportation, processing, and sale of the gas under one or more gas sale and purchase agreements. Alternatively, the gas may be fed directly from the regasification terminal to a single user. The downstream arrangements will depend largely on how the gas will ultimately be consumed.
For example, it may be that the gas will be sold to a utility, fed into the natural gas grid, and ultimately sold to consumers for domestic heating and cooking purposes and businesses for industrial purposes. It may be used to feed a gas-to-power project, delivering power to a market with insufficient existing generation capacity, or it may be used as a chemical feedstock in the manufacture of plastics or other chemicals.
The economics of this component of the value chain are fundamental to the project as a whole. Without a ready market for consumption of gas and a demand for LNG to supply that market, the LNG project would not exist.
The above discussion has focussed on the traditional LNG value chain which has emerged based on the relative ease by which LNG (as compared to natural gas in its gaseous state) can be transported by ship to overseas markets, linking producers of gas in one part of the world with consumers of gas in another. However, LNG has a number of other potential applications, with value chains that may look significantly different from the traditional one discussed above.
One such application is LNG bunkering, which refers to the use of LNG as “bunker” fuel for marine transportation. While LNG carriers have long been fitted with dual-fuel engines that can run on LNG in order to utilize the boil-off gas that naturally results from the carriage of LNG as cargo, due to the relatively low price of LNG in recent years and the increasingly stringent emissions standards that apply to ships and marine fuels, owners of other types of vessels are increasingly considering the use of LNG as an alternative to traditional heavy diesel fuel and marine gas oil and building or converting ships to run on LNG.
On 1 January , a new cap imposed by the International Maritime Organization (IMO) on the sulphur content of marine fuels came into effect, limiting the maximum sulphur content in marine fuels to 0.5 percent globally (referred to as low sulphur fuel oil (LSFO)).28 As discussed in the next part of this article, even more stringent sulphur emissions standards apply in Canadian waters falling within the North American Emission Control Area (ECA). According to a study published by the IMO, switching to LNG “reduces the emissions of NOx [nitrogen oxides] by 85% to 90% (using a gas only engine), and SOx [sulphur oxides] and particles by close to 100% compared to today’s conventional fuel oil.”29 With virtually no sulphur or particulates, converting to LNG is a viable way to meet these emissions standards, while also benefiting from the current relatively low cost of LNG and lower risk of pollution as a result of any spill of bunkers (unlike traditional marine fuels, if LNG is released, it warms, evaporates, and dissipates).
Container shipping fleets, passenger ferries, and cruise liners are examples of the various type of vessels that are turning to LNG with Seaspan and a number of other shipowners already reported to be leading the transition in North America.30 Proposals have also been made to develop LNG bunkering facilities in order to supply the growing number of LNGpowered vessels expected to be traversing Canadian waters, including on both the east and west coasts.31
LNG also has a number of domestic onshore applications. For instance, LNG may also be used as fuel for other areas of transportation, including trucks and locomotives, where similar emissions and cost incentives exist. It may also be transported by truck and used as fuel for power generation and domestic purposes in remote areas without a supply of piped natural gas.
In each of these cases, the LNG value chain will differ from the traditional model described above and will not involve marine transportation of the LNG as cargo. These applications, however, represent important potential areas of supply for many of the Canadian LNG projects that have been proposed, and vessels calling at Canadian ports to load LNG bunkers will be subject to many of the same regulations that apply to the bulk export of LNG by ship.
Navigation, shipping, and international trade and commerce generally fall under federal jurisdiction in Canada,32 such that the regulations that apply to marine transportation and export of LNG fall primarily within the responsibility of Canada’s federal authorities, including the Canada Energy Regulator (CER), Transport Canada, and Environment and Climate Change Canada.
There are limited exceptions whereby provincial laws may have an impact on marine transportation of LNG (at least indirectly). One notable exception is with respect to the environment due to the power of the provinces (which is shared with the federal government) to regulate with respect to environmental matters.33 Another notable exception is the health and safety of workers. While federal occupational health and safety (OH&S) legislation will generally apply to employees of companies or sectors operating across provincial or international borders, including with respect to ferries, port services, shipping, and shipping services, there remains significant scope for provincial OH&S laws to apply to maritime matters.34
The vast majority of the regulatory burden relating to the transportation of LNG by ship will be borne by the owners and operators (including bareboat or demise charterers) of such vessels. The owners of LNG cargoes and the charterers of any LNG carriers used to transport them will generally be relatively free from any regulatory obligations that apply directly to them in such capacity, but may have contractual obligations to comply with such requirements (e.g. under any LNG SPA or LNG tolling services agreement), and a significant interest in knowing what the relevant rules and regulations are and ensuring compliance by a vessel’s owners and operators.
With respect to the export of LNG, the majority of the regulatory burden will be borne primarily by the holder of the export licence. Due to its importance to an LNG export project, an export licence will typically be obtained by the project proponents and held by the operator of the LNG facilities, which may not be the same person who ultimately exports the LNG. However, the persons actually exporting LNG who will need to rely on such an export licence may nevertheless bear some of the regulatory burden indirectly by way of contractual obligations (for example, contained in a tolling services agreement) to comply with the terms of the licence and provide the licence holder with the information it will need in order to satisfy its reporting obligations to the CER.
Exportation of gas (which, in this context, includes LNG) falls under the federal regulatory authority of the CER, which replaced the National Energy Board (NEB) on 28 August . Regulations made under the National Energy Board Act35 will remain in force under the Canadian Energy Regulator Act36 until they are repealed or others made in their stead.37 The CER Act grants regulatory authority to the CER as the NEB Act did for the NEB with respect to the federal export and import regulatory framework for oil and gas. It is understood that new regulations and updates to existing regulations are being implemented through a phased approach and the CER anticipates updated regulations will be available in the summer of .38 This area of the law is therefore in a state of flux and the discussion below is based on the law as it stands at the time of writing.
Export of gas from Canada is prohibited unless it is in accordance with an export licence or otherwise authorized under the regulations made under Part 7 of the CER Act.39 Export authorizations include export licences and export orders, which are issued by the CER. Export orders authorize export of LNG in prescribed volumes for anywhere from zero to 20 years.40 An export licence is typically used for long-term applications and is subject to conditions imposed by the CER in the licence.41 To date, export authorizations for LNG have generally taken the form of export licences (due to the long-term nature of the LNG projects that have been proposed), and in recent years the regulation of gas export licences has changed to be more accommodating to the developing LNG industry in Canada. As mentioned above, an export licence under section 344 of the CER Act will typically be obtained by the proponents of an LNG export project at an early stage in its development to ensure the feasibility of the proposed terminal.42 The process of obtaining the licence is therefore unlikely to be a significant concern for transporters of LNG, who will typically rely on the terminal’s export licence, but they will have an interest in ensuring that the licence is maintained such that they are permitted to export LNG throughout the relevant term.
Export licence applicants must obtain two approvals before licences are issued.43 First, applicants must satisfy the CER that the proposed volume of gas to be exported “does not exceed the surplus remaining after allowance has been made for the reasonably foreseeable requirements for use in Canada, having regard to trends in the discovery of oil or gas in Canada.”44 This is known as the “Surplus Criterion.”45 Second, the Minister46 and Governor in Council47 must approve the CER’s issuance of the export licence.
Export licences issued by the CER may contain conditions related to any of the following: (1) the duration of the licence; (2) a deadline for commencement of gas (or LNG) exportation in order for the licence to remain in effect; (3) the quantities of gas (or LNG) that may be exported during the term of the licence; (4) maximum volumes of gas (or LNG) that may be exported in a daily, monthly, or annual period; (5) the tolerance levels necessary to accommodate temporary operating conditions; (6) the points of exportation of gas (or LNG) from Canada; and (7) the environmental requirements that must remain in effect in order for the licence to remain in effect.48 Based on the LNG export licences recently issued by the CER and its predecessor, the NEB, the most common condition types imposed are as follows: the duration of the licence, tolerances, annual volume caps, early expiration in the event that exports have not commenced, and the point of export.
The point of export may raise interesting considerations for LNG terminals and LNG offtakers. Illustrative of the issue is the application by WesPac Midstream Vancouver LLC (WPMV) in for an export licence in connection with the WesPac Tilbury Marine Jetty.49 WPMV’s application proposed a point of export that varied from the point conventionally considered by the NEB and CER. Conventionally, the point of export occurs at the “last land-based locations of the gas before it begins its marine journey to depart Canadian waters”50 for exports by sea or at the highway border crossing for land-based exports. However, to allow for the flexibility WPMV needed to export LNG using different modes of transportation, WPMV requested the point of export to be at (1) the outlet of the loading arm of the WesPac LNG Marine Terminal adjacent to the liquefaction plant located at Tilbury Island, or (2) at the hose connector of the pump at the truck rack at the liquefaction terminal where ISO LNG shipping containers or tanker trucks are filled with LNG for export by ship or truck. This modification would allow for multimodal transportation of LNG.
In its reasons for the decision approving WPMV’s export licence application, the NEB stated:
Historically, the Board considered the act of exporting to occur when gas was sent or removed from Canada and not when gas was loaded into a mode of transport. The exception to that approach is an export point designated to be the outlet of a loading arm of a terminal at which LNG is loaded directly into marine vessels for export. The Board has previously stated that the point at which LNG tankers pass into international waters is not a precise location.
In requesting an export point located at the pump of the truck rack where ISO shipping containers are filled with LNG, WPMV requested a level of flexibility that is not demonstrative of the act of exportation from Canada. In authorizing the following export points, the Board is balancing its practice of conditioning precise locations on an export licence with the flexibility needed to export LNG in ISO containers using different modes of transportation.
For marine exports, the Board approves the last land-based locations of the gas before it begins its marine journey to depart Canadian waters. Therefore, the Board approves the following marine export points:
For land based exports, the Board approves the following export point:
The Board accepts WPMV’s evidence that it requires the flexibility to access various markets and the certainty of a long-term export licence to enter into long-term commercial contracts and finance capital investments.51
While the NEB modified WPMV’s requested export points such that they are effectively the last land-based locations of the LNG before export from Canada by sea or land, in authorizing these export points, the NEB balanced its practice of conditioning precise locations with the flexibility needed to export LNG using different modes of transportation, including ISO containers and trucks.
Under WPMV’s export licence, once LNG is loaded onto an LNG carrier, an ISO LNG container reaches the marine cargo terminal in Vancouver to be loaded onto a ship or LNG crosses the highway border with the US in a truck, it will be regarded as having been “exported” for the purposes of the export licence. A canvass of the export licences issued in the last five years reveals that no other licence holder has availed itself of such flexibility.
WPMV’s export licence may also be used to illustrate another issue related to LNG export regulations that may be of concern to LNG offtakers: who holds the export licence. WPMV applied for an export licence on its own behalf and as an agent acting on behalf of affiliates and third parties, which reflects the fact that while WPMV owns the Tilbury Marine Jetty, FortisBC owns the Tilbury liquefaction terminal located adjacent to it and third parties are likely to own the majority of the LNG exported from it.
The NEB granted this request and, in its reasons for the decision, confirmed that WPMV is not required to be the owner of the natural gas (or LNG), and can act as an agent on behalf of the owner of the LNG. The NEB determined it did not need to identify this as a term in the export licence, but that WPMV would be responsible for complying with reporting requirements:
Section 116 of the NEB Act prevents any person, except as otherwise authorized by the regulations, from exporting gas except under and in accordance with a licence issued by the Board. In the Board’s view, this section of the NEB Act does not require the holder of the export licence to also be the owner of the natural gas; therefore, the Board does not find it necessary to include a term on the Licence permitting WPMV to act as agent on behalf of the owners of the natural gas. The Board notes that WPMV, acting in its capacity as an agent, would be exporting natural gas under its Licence which requires it to report those exports in accordance with the National Energy Board Export and Import Reporting Regulations.52
It is, therefore, possible under the legislative framework for an export licence to be held by a different person to the person exporting LNG, but from the perspective of the person exporting LNG, it will be important that contractual arrangements are in place to ensure that the export licence holder maintains the licence during the relevant term. From the export licence holder’s perspective, contractual arrangements will also be required to ensure that users of the licence comply with its terms and that it receives the information it needs from such users in order to meet its reporting obligations. Such reporting obligations include the requirement to provide monthly activity reports to the CER, including details with respect to, among other things, the volumes of gas exported, the price, the province of origin of the gas, the name of the export customer, and the geographical region within a country of destination to which gas was exported.53
The export licence is one requirement for the export of LNG, but there is an additional requirement to file all gas (or LNG) export sales contracts pursuant to which the LNG is exported with the CER for its approval.54 Any amendment to such contracts would require further approval by the CER.55 Submission to the CER of copies of export sales contracts may also be required as part of the export licence application process.56
Historically, the requirement to submit export sales contracts was part of the NEB’s comprehensive “Market Based Procedure,” which was designed to evaluate whether the proposed export would meet the Surplus Criterion and be in the public interest.57 The requirement to file export sales contracts grew out of the mandate to examine public interest considerations. In Re KM LNG Operating General Partnership, the NEB described the threepart public hearing component of the Market Based Procedure.58 The first part, the complaints procedure, was “based on the principle that gas should not be authorized for export if Canadians have not had an opportunity to buy gas for their needs on terms and conditions similar to those contained in the export application.”59 The second part, the export impact assessment, examined the Surplus Criterion. The third part, other public interest considerations, considered any other relevant factors, including:
Consideration of these factors clearly required the ability to review the terms of gas export sales contracts. However, in , the Jobs, Growth and Long-term Prosperity Act61 amended the NEB Act and removed the requirement in section 118 (now section 345 of the CER Act) that, “in addition to the surplus criterion, the [NEB has] regard to ‘all considerations that appear to it to be relevant’ when assessing an application for a gas export licence.”62 Since the amendments, the regulator’s mandate63 on export licence applications has been limited solely to the Surplus Criterion, and the public interest aspect is not examined by the regulator.64 Instead of the strict form and substance requirements of the Market Based Procedure, the CER now only requires the information detailed in Guide Q of the Filing Manual for its assessment of the Surplus Criterion.65 Guide Q does not prescribe a specific format or specific content, and its information requirements may be met in a variety of ways. As such, not all of the requirements of section 12 of the NEB Oil and Gas Regulations, such as export sales contracts, are relevant to its assessment of export licence applications.66
As a result, export licence applicants have been requesting relief from some of the information requirements set out in section 12 of the NEB Oil and Gas Regulations.67 In Re Chevron Canada Ltd, the CER noted that such relief has been granted in numerous LNG export applications.68 In that decision, Chevron requested and was granted relief from filing supply contracts on the basis that such contracts did not exist.69 Of greater significance, the CER held that, because not all of the filing requirements are relevant to the CER’s assessment of the application, Chevron was exempted from, among other things, the requirement to file gas export sales contracts.70 In Re LNG Canada, the NEB also advised that because the focus of the regulator is limited to the Surplus Criterion on gas export applications, the regulator does not require all of the information that must be filed pursuant to the NEB Oil and Gas Regulations. Therefore, the regulator may exempt applicants from the information requirements.71
The CER stated in Re Chevron that it is in the process of updating the regulations to align with the changes to the new CER Act.72 Given that no changes have been made to the Surplus Criterion since the amendments to the NEB Act in , and the NEB Oil and Gas Regulations were not updated to align with such amendments,73 it is hoped that the CER’s update to the regulations will reflect the narrowing of the scope of consideration resulting from the shift from the Market Based Procedure to the requirements of Guide Q of the Filing Manual. A letter from the NEB dated 29 June suggests this may be the intention as the NEB proposed a number of regulatory amendments which would have removed the requirement to file gas export sales contracts as part of the licence application.74
With respect to the requirement for licence holders to file all gas export sales contracts and amendments thereto with the CER for its approval, the position may be similar. By removing the public interest mandate of the regulator when considering gas export licence applications, the rationale for requiring licence holders to subsequently file export sales contracts for approval may correspondingly have ceased to exist. However, a secondary rationale for this requirement may be that the filing of export sales contracts is part of the regulator’s ongoing monitoring of Canada’s natural gas supply and demand, including LNG developments.75 The regulator monitors the market so that it can identify where markets may not be functioning properly or where the evolution of supply and demand casts doubt on the ability of Canadians to meet future energy requirements, which could be relevant to consideration of the Surplus Criterion in future export licence applications.76 However, given the abundance of data in the current energy market, it is questionable whether the regulator needs to require the filing and approval of gas export sales contracts in order to perform this function. Further, in recent years, the regulator has repeatedly recognized in the context of the Surplus Criterion that Canadian gas requirements are satisfied because the North American market is integrated, the North American gas resource base is large, the North American gas marketplace is robust and sophisticated, and the North American gas market functions efficiently and there is no evidence to suggest that it will not continue to do so in the future.77
The requirement for CER approval of any LNG SPAs and amendments thereto may be problematic for LNG terminal operators and LNG offtakers, both in terms of the requirement to submit potentially commercially sensitive information to the CER and given the risk that such approval will not be granted, potentially making an LNG project no longer viable. It is noted that Prince Rupert LNG Inc. sought exemption from the NEB from certain monthly reporting requirements on the basis that “the effect of exporting from a unique export point is that … Prince Rupert LNG would be unable to maintain the confidentiality of the details of export sales contracts … which are commercially sensitive documents.”78 While the NEB declined to grant such exemption, the NEB noted that “the information supplied by an export licence holder to the Board is not necessarily the information that is published by the Board. The Board will continue to support market transparency while exercising discretion with respect to the information it chooses to release to the public.”79
The NEB previously exempted KM LNG Operating General Partnership from the requirement to file copies of export sales contracts. According to KM LNG, it was unable to file LNG SPAs because LNG buyers would find the public disclosure of SPAs unacceptable to the point that the requirement to file SPAs “could thwart any opportunity of successfully [negotiating] agreements.”80 The NEB agreed, stating that the NEB was “cognizant that adhering to the filing requirements may introduce an unwarranted level of risk for the Applicant.”81
The CER Act provides an alternative mechanism for protecting commercially sensitive information. Under section 60, the CER may designate information as confidential if it is satisfied that:
Accordingly, to the extent the holders of any export licences are required to file and seek CER approval of any export sales contracts or amendments thereto (which it appears may not be a strict requirement of the CER in certain cases), a mechanism exists to ensure that the terms of any such contracts will remain confidential.
Another area on which guidance is required from the CER is how LNG bunkering will be dealt with under the export regulatory framework. At the time of writing, the CER has not provided any direction on this issue, but there is evidence that suggests that the NEB and CER are at least aware of it. Turning again to the initial WesPac Tilbury Marine Jetty export licence application, WPMV indicated in its application that the terminal “will also provide a means of loading LNG onto barges for marine bunkering (ship fueling) activities, which may also involve the export of LNG.”83 In response, the NEB issued an Information Request asking whether or not such volumes of LNG used for LNG bunkering were included in the export volumes specified in WPMV’s application.84 WPMV confirmed in its response that such LNG bunkering volumes were included in the export volumes and, as a result, the NEB did not need to directly consider whether or not these volumes ought to be included in export volumes, leaving open the question of whether an export licence would in fact be required for the supply of LNG as bunkering fuel.85
While oil has been supplied as bunker fuel from Canadian ports for a long time, the same question does not arise because the NEB Oil and Gas Regulations provide that the exportation of any oil carried by ships in their own tanks for their consumption are exempt from the operation of Part VI of the NEB Act (now Part 7 of the CER Act).86 There is currently no similar exemption in respect of LNG supplied as bunker fuel and, arguably, the position should be no different. However, as matters stand, there is an apparent legislative gap with respect to LNG bunkering, such that an export licence may be required in order to supply LNG bunkers, at least to the extent it is supplied to vessels trading internationally.
The regulation of LNG bunkering is a complex area on which legislative amendments and guidance from the relevant authorities will clearly be required in a timely fashion as the Canadian LNG bunkering industry continues to develop. It was noted by the Vancouver Fraser Port Authority in its response to an Information Request by the NEB in relation to the TransMountain Pipeline Expansion Project that the regulatory framework for LNG bunkering is unclear in Canadian legislation and policy.87 It was suggested that regulation of vessel design and bunkering operations likely resided most effectively with Transport Canada pursuant to the Canada Shipping Act, .88
The Marine Transportation Security Act89 governs safety and security relating to ships, crews, cargo handling, vessel supply, vessel access, ports, and terminals, and the Marine Transportation Security Regulations90 (which closely follow the IMO’s International Ship and Port Facility Security (ISPS) Code framework) require ships to have an approved security plan and various certificates on board.
LNG carriers require a number of operational certificates to operate in Canadian waters, which may be reviewed upon inspection of the vessel under various inspection regimes (Port State Control, Canada Shipping Act,91 Canada Labour Code,92 Vessel Certificates Regulations,93 Vessel Clearance Regulations,94 etc.) based on the standards that apply under the international maritime conventions to which Canada has acceded, including:
The certificates that LNG carriers will be required to carry to operate in Canadian waters will typically include:
Transport Canada may issue Wreck Removal Convention and Bunkers Convention Certificates (if a vessel does not have such certificates issued by its flag state) based on evidence of the compulsory insurance coverage required under such conventions (typically evidenced by the corresponding “Blue Cards” issued by the vessel’s Protection & Indemnity (P&I) Club).
Under the Canada Shipping Act, Vessel Certificates Regulations and Vessel Clearance Regulations, LNG carriers will need to have been constructed in accordance with the applicable edition of the International Code for Construction and Equipment of Ships Carrying Liquefied Gases in Bulk (IGC Code).107 If an LNG carrier meets such requirements, Transport Canada (or a Classification Society on its behalf) will issue a Certificate of Fitness for the Carriage of Liquefied Gases in Bulk which will be valid for 5 years.
Other types of vessels loading LNG as fuel in Canadian waters will need to comply with other requirements depending on the type of vessel and with the International Code of Safety for Ships Using Gases or Other Low-flashpoint Fuels (IGF Code),108 which provides an international standard for ships, other than vessels covered by the IGC Code (which addresses the use of cargo as fuel on LNG carriers), which operate using gas (or other lowflashpoint liquids) as fuel.
Port State Control refers to the program administered by Transport Canada’s Marine Safety Division whereby foreign vessels entering Canadian waters are boarded and inspected by Marine Safety inspectors to ensure they comply with the applicable international and Canadian requirements, including the international conventions referred to above.
Before a vessel enters Canadian waters, Port State Control officers check its safety and inspection record using international databases and it is Transport Canada’s policy to inspect every foreign tanker vessel (including LNG carriers) calling at a Canadian port on its first visit to Canada and at least once a year thereafter.
Canada has grouped together with other countries which share common waters with Canada and has entered into the Paris Memorandum of Understanding on Port State Control (referred to as the Paris MOU),109 which covers the waters of the European coastal States and the North Atlantic basin from North America to Europe, and the Memorandum of Understanding on Port State Control in the Asia-Pacific Region (referred to as the Tokyo MOU),110 which covers the Asia-Pacific region. These agreements are intended to establish harmonized systems of Port State Control, facilitate the sharing of relevant information, and eliminate substandard shipping in the relevant regions.
The IMO emissions regulations under MARPOL relating to the sulphur oxides and nitrogen oxides content of fuels have been adopted under the Canada Shipping Act.111 LNG carriers and other vessels calling at Canadian terminals will be required to comply with these provisions and carry on board an Air Pollution Prevention Certificate.112 As of 1 January , the IMO has imposed a 0.5 percent cap on the sulphur content of marine fuels. However, Canada’s east and west coasts fall within the North American ECA, in which stricter emissions standards apply.113 The North American ECA comprises a 200nm zone around the east and west coastlines of North America and around the Hawaiian Islands within which a sulphur cap of 0.1 percent applies.114 More stringent requirements also apply within the ECA with respect to nitrogen oxides emissions.115
The sulphur content requirements that apply within the North American ECA and elsewhere effectively require ship operators to use low sulphur fuels or install exhaust gas cleaning systems (referred to as “scrubbers”) or other abatement systems achieving the same emissions reductions. As mentioned above, this is one reason (among others such as reduction of pollution risk, reduction of carbon dioxide emissions, and cost-effectiveness) why many ship-owners (not only owners of LNG carriers) are increasingly transitioning to the use of LNG as fuel and why a number of LNG bunkering hubs have been proposed on Canada’s east and west coasts.
The Ballast Water Control and Management Regulations117 require that all vessels prepare and carry a ballast water management plan and set out requirements with respect to the exchange and treatment of ballast water in Canadian waters. Canada acceded to the International Convention for the Control and Management of Ships’ Ballast Water and Sediments, in , which imposes additional requirements. These requirements have not yet been incorporated into domestic law and, in the meantime, the Ballast Water Regulations continue to apply.119 It is possible that LNG terminal operators will contractually require LNG carriers to comply with the requirements of the Ballast Water Convention in any event.
Canada generally applies the International Maritime Dangerous Goods Code (IMDG Code)120 which is incorporated into Canadian law and regulated through two different Acts and related safety regulations:
Such regulations apply to the transportation of LNG within Canadian waters and impose a number of requirements on persons undertaking such activities, including with respect to safety and security standards, emergency response plans, and financial responsibility.
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A range of rules and regulations apply to navigation and pilotage in Canadian waters,125 including with respect to:
It is noted that Bill C-48, An Act respecting the regulation of vessels that transport crude oil or persistent oil to or from ports or marine installations located along British Columbia’s north coast,130 received royal assent on 21 June , but is unlikely to significantly affect the operation of LNG carriers. The Oil Tanker Moratorium Act prohibits oil tankers carrying more than 12,500 tonnes of crude oil or persistent oil products as cargo from stopping, loading, or unloading in the moratorium area of British Columbia’s north coast. However, it does not apply to vessels carrying LNG as cargo and, except for oil tankers that are otherwise subject to the moratorium, does not prevent other vessels loading LNG as bunker fuel.131
All Canadian exports, including in-transit movements, must be reported to the Canada Border Services Agency (CBSA) by submitting the appropriate export documentation to a designated export office within legislated time frames. At least two copies of the crew list must be filed with the CBSA upon the vessel’s arrival so that it may be endorsed by it. The crew list must be kept up to date during the vessel’s stay. Until the crew list is endorsed by a CBSA officer, none of the crew may disembark into Canada.
The port operations regime that applies at any LNG terminal will vary depending on the particular port and whether it is a public port and falls within the responsibility of a port authority. Kitimat, British Columbia, for example, which is the site of a number of planned LNG terminals, is currently a private port with no established federal port authority governing its operations, no existing traffic separation schemes, and no harbour dues. However, the Government of Canada has advised that it will designate Kitimat as a public port in the future.132
Public ports in Canada are operated under the Canada Marine Act,133 the Public Ports and Public Port Facilities Regulations,134 and the Practices and Procedures for Public Ports,135 which govern activities such as:
Each public port also has its own bylaws and tariffs and their use may be subject to berthage fees, harbour dues, storage charges, utility and other service charges, and wharfage and transfer charges.
Under the Canada Shipping Act,136 vessels loading LNG must have an arrangement (such as a contract) with a qualified spill response organization, such as the Western Canada Marine Response Corporation on Canada’s west coast or the Eastern Canada Response Corporation Ltd. on Canada’s east coast.
In the context of LNG carriers, the risk of pollution due to spillage is relatively limited due to the fact that LNG when spilt will generally vaporize and dissipate. Nevertheless, to the extent LNG, bunker fuel, or any other substances released from an LNG carrier cause pollution, this may give rise to both civil and criminal liability. While a detailed discussion of these topics falls outside the scope of this article, brief overviews are set out in the following paragraphs.
Civil liabilities will be governed by the Marine Liability Act,137 which implements the Bunkers Convention,138 which will apply in respect of any pollution caused by bunker oil (to the extent carried by any LNG carrier). Once it comes into force, the International Convention on Liability and Compensation for Damage in Connection with the Carriage of Hazardous and Noxious Substances by Sea, will apply in respect of any pollution caused by hazardous and noxious substances (which include LNG) released by vessels. In the meantime, civil liability of shipowners for releases of LNG will be governed by Part 6, Division 2 of the Marine Liability Act, subject to the limits set out in Part 3 thereof (please see below).140 These civil liability regimes generally impose strict liability on shipowners (subject to certain defences) for pollution caused by substances discharged or originating from their ships, based on the “polluter pays” principle.
Criminal liability for pollution from ships can arise based on pollution-related offences under a variety of statutes, including the Canada Shipping Act,141 Canadian Environmental Protection Act, ,142 Fisheries Act,143 and Migratory Birds Convention Act, .144 Conviction of these offences can, in some cases, result in fines of up to CDN$12 million for corporations and, for individuals, fines of up to CDN$1 million and imprisonment for up to 3 years.
One area of the legal landscape with which shipowners may wish to be familiar before visiting any jurisdiction, including Canada, is the applicable regime for bringing claims against vessels and arresting them as security for such claims. This will be the case particularly if the shipowner is aware of any debts or alleged claims against the relevant vessel or against any other vessels that it may own.
The threat of arrest may also be a concern for cargo owners who could be exposed to the risk of having a cargo of LNG detained in the event of the arrest of the ship on which it is carried. While the arrest of a ship will not generally extend to the property of third parties onboard such as cargo, having to arrange for a cargo of LNG to be discharged or transshipped and stored or carried to the destination port on another vessel may involve a significant amount of time and cost. This includes the cost of the cargo volume reducing during any period of delay due to boil-off, which may not be recoverable if the shipowner is insolvent. Cargo owners, therefore, have a significant interest in knowing the risks associated with any particular shipowner (for example, based on due diligence in respect of its financial position and the existence of any creditors) and the legal regimes of any particular jurisdictions visited by any ships carrying their cargoes.
In Canada, arresting a ship is a relatively simple matter, but so is getting a ship released from arrest. Most claimants will accept a Letter of Undertaking from a member of the International Group of P&I Clubs as security in lieu of bail (although a Canadian court has no jurisdiction to oblige a claimant to accept a Letter of Undertaking). Canada recognizes the status of maritime claims based on the law where the claim occurred. Therefore, even if the claim is one that under Canadian law is not a true maritime lien, the ship can be arrested and held liable if the claim is a maritime lien under the law where the liability was incurred. This is particularly vexatious for shipowners who suffer the misfortune of a charterer who runs up many maritime lien debts before becoming insolvent. It may also increase the risk of arrest from the perspective of cargo owners. Canada also allows for sistership arrest but only if the ships share identical beneficial ownership.
Canada has adopted the Convention on Limitation of Liability for Maritime Claims, ,145 as amended by the Protocol of to amend the Convention on Limitation of Liability for Maritime Claims,146 which are incorporated into Canadian law by way of Part 3 of the Marine Liability Act.147 This entitles shipowners (and charterers) to limit their liability for loss of life, personal injury, and property claims (including in respect of cargo) to legislated limits depending on the gross tonnage of the ship. Such limits may, however, be broken if “it is proved that the loss resulted from [the shipowner’s] personal act or omission, committed with the intent to cause such loss, or recklessly and with knowledge that such loss would probably result.”148 The right to limit liability may also be waived by contract.149 It is not uncommon for such rights of limitation to be waived under the terms of the conditions of use or port liability agreements typically imposed by LNG terminal operators upon the ships using their facilities and replaced with other contractual limits of liability in respect of any claims falling within the scope thereof. It is important to ensure that such terms are acceptable to the shipowner’s P&I Club before waiving such rights.
The above discussion focusses on the requirements that may apply directly to the owners and operators of ships loading LNG at Canadian ports as a matter of Canadian law. Vessels trading internationally will also be subject to a wide range of international laws and national laws of the vessel’s flag state and of other jurisdictions in whose waters the vessel operates. A vessel’s flag state may also impose other requirements in order to register the vessel, such as that the vessel maintains class with a recognized classification society,150 which will also be a requirement of the vessel’s insurers, a requirement of entry into many ports and waterways, and likely a contractual requirement under any charter party. These requirements are not specific to Canada or to the LNG sector and detailed discussion of them falls outside the scope of this article.
However, other requirements may also be imposed on vessels loading LNG at Canadian ports under the various contractual arrangements which will customarily be entered into when undertaking such operations. Such contractual arrangements form an important part of the maritime component of the LNG value chain alongside, and often interacting with, the regulatory requirements discussed in the previous part of this article. As discussed in Part II of this article, alignment between these contractual arrangements and those in other parts of the value chain is key to the effective allocation of risks and liabilities across the value chain as a whole.
Contractual requirements may be imposed by the LNG terminal operator on the owner or operator of any vessels calling at the terminal. Such requirements may be imposed directly by way of conditions of use or other contractual instruments entered into between the LNG terminal operator and the shipowner or operator.151 Such conditions of use are generally employed in order to allocate risk and responsibility as between the LNG terminal operator and owner of any vessel calling at the terminal (who may not otherwise have a contractual relationship with one another unless, for instance, the owner of the vessel is also a liquefaction tolling customer of the terminal or is purchasing LNG from the terminal operator) in respect of any loss or damage that may result from any incidents occurring at the terminal. They may also place various obligations on the vessel owner, such as with respect to compliance with applicable laws (including those discussed in Part III above) and any directions of the terminal operator and maintenance of insurance, and, importantly, will typically specify the law by which their relationship is to be governed and the forum in which any disputes between them are to be resolved.
Requirements of the terminal operator may also be imposed indirectly on a shipowner. For instance, if the vessel is the subject of a charter party, the charter party may indirectly impose on the shipowner certain obligations that the charterer may have under any agreement with the terminal operator, such as a liquefaction tolling agreement, or under an LNG SPA (which may be entered into by the charterer with the terminal operator or a tolling customer who is selling LNG on an FOB basis at the terminal). The charter party may cover some of the same obligations as are imposed directly on the shipowner by conditions of use, such as obligations to comply with applicable laws and to maintain insurance, but may also cover a broad range of additional obligations imposed by the terminal operator with respect to vessels calling at the terminal. Liquefaction tolling agreements, LNG SPAs and LNG carrier charter parties will all commonly include provisions addressing certain matters associated with vessels calling at the liquefaction terminal to load LNG, such as:
Such obligations will ideally be flowed through from the terminal operator to the shipowner through back-to-back arrangements under any liquefaction tolling agreement, LNG SPA, or charter party. Any parties in the middle of the chain (such as a liquefaction tolling customer who is chartering the vessel and selling LNG on a DAP basis or who is selling LNG to a buyer who is chartering the vessel and buying LNG on an FOB basis) will have a particular interest in ensuring that such back-to-back arrangements are sufficiently aligned in order to avoid being left with stranded liabilities which cannot be passed down the contractual chain to the shipowner.
Many of the above obligations will be imposed by the terminal operator for operational and safety reasons and in line with standard market practices. However, some obligations may be more specific to the particular terminal. Terminal-specific requirements may, for instance, be imposed by a terminal operator through the terminal rules with which shipowners are required to comply. Such terminal rules may cover a range of requirements, such as navigation, use of pilots and escort tugs, docking procedures, use of boil-off gas, and operator in order to comply with any conditions attached to its Facility Permit or Environmental Assessment Certificate, any commitments that have been made to third parties including Indigenous groups, and any other terminal policies that have been adopted.
Facility Permits can potentially impose requirements on the facility operators which will result in contractual obligations being imposed directly or indirectly on shipowners. For example, LNG Canada has been issued a Facility Permit which requires, among other things, an Ambient Noise Model and Marine Control Zone Plan to be provided to the BC Oil and Gas Commission (BC OGC).166 The Liquefied Natural Gas Facility Regulation also requires LNG facilities to have various plans approved by the BC OGC, including an Emergency Response Plan and a Security Plan, and LNG carriers using such facilities may be required by the terminal operator to comply with these (and potentially other) plans when doing so.167
The environmental assessment process may also result in conditions imposed on terminal operators that lead to requirements placed on vessels calling at the terminal. Although only recently codified into legislation, over the past several years, the Canadian federal government has mandated that environmental assessment processes consider the cumulative effects of resource development. On 28 August , the federal government revamped the environmental assessment legislation and the IAA came into force.168 The IAA expands the criteria that must be considered during the environmental assessment process to include “any cumulative effects that are likely to result from the designated project in combination with other physical activities that have been or will be carried out.”169 The scope of the review requires consideration of Indigenous rights and may require the consent of affected Indigenous groups pursuant to constitutional rights recognized and affirmed by section 35 of the Constitution Act, .170
The environmental impacts that project proponents must consider also include the impacts of marine shipping activities downstream of their facilities. As the scope of review has been under development in recent years, it is difficult to predict exactly how this will affect vessels calling at LNG facilities in each case and the effects may be different for different LNG facilities.
For example, LNG Canada was granted an Environmental Assessment Certificate on 17 June , which includes 24 conditions requiring, among other things, the development and approval of various plans relating to LNG Canada’s various commitments to regulators and other interested parties, including Indigenous groups.171 These plans include, for example, an air quality management plan, a noise management plan, a greenhouse gas (GHG) emissions plan and a wake verification plan,172 which may potentially result in requirements imposed on LNG carriers when using the LNG facility.
In contrast, the environmental assessment requested by WPMV with respect to the WesPac Tilbury Marine Jetty has required consideration of possible mitigation efforts with respect to marine accidents and malfunctions, various navigational risks associated with incremental increases in shipping traffic, the impact of vessel traffic on other commercial and non-commercial activities (including activities of Indigenous populations adjacent to the terminal), killer whales and baleen whales, fish and fish habitat, and water quality.173 WPMV’s environmental assessment process has been delayed after the federal government mandated a new scope to the cumulative effects analysis, expanding the geographical area of impact to include the passage from the mouth of the Fraser River to the outer boundary of Canada’s territorial waters. At the time of writing, an Environmental Assessment Certificate has not yet been granted and the conditions for the WesPac Tilbury Marine Jetty which may result in requirements imposed on LNG offtakers are not yet known. However, given the relatively expansive scope of evaluation, it is possible there will be more conditions and perhaps conditions of greater impact on LNG offtakers, including both LNG carriers and LNG bunkering customers. The Kitimat LNG Project has experienced similar delays with respect to the federal government’s expansion of the scope of review, although the project is at a relatively early stage of the process.
Terminal rules imposed by terminal operators may also include requirements based on the recommendations of any TERMPOL (Technical Review Process of Marine Terminal Systems and Transhipment Sites) review undertaken at the request of the LNG project proponents. A TERMPOL is a voluntary and non-binding review by the federal government that is intended to identify any risks associated with navigation and marine operations and provide recommendations to enhance marine safety beyond regulatory requirements. It may also include recommendations on or arising from engagement with Indigenous groups.
For example, TERMPOL reviews have been undertaken for the LNG Canada and Kitimat LNG projects.174 The resulting reports were prepared and reviewed by Transport Canada, Environment and Climate Change Canada, Canadian Coast Guard, Pacific Pilotage Authority, Canadian Hydrographic Service, and other government authorities. They include various recommendations and findings, some of which may potentially be followed by the relevant terminal operators and imposed on any ships calling at them (e.g. through any terminal rules with which they are required to comply), including in relation to:
The above discussion of terminal operator requirements includes discussion of some of the obligations under charter parties that may flow through the charterer from the terminal operator to the shipowner. However, other obligations will be imposed by the charterer that do not necessarily relate to any obligations it may have towards the terminal operator. These obligations will cover a broad range of matters, but most of the matters that will be specific to Canadian LNG terminals, including the requirements of terminal operators and the regulatory requirements discussed in Part III of this article, have already been discussed above, and a broader discussion of charter party terms falls outside the scope of this article.
As with any commercial vessel, operators of LNG carriers and LNG-fueled vessels will also enter into a wide range of contracts with third parties in connection with the operation of such ships, including with classification societies, insurers, ship managers, crew managers, marine service providers, bunker suppliers, tug and escort vessel service providers, pilots, and so on. While these will also impose a range of requirements on shipowners, since such requirements do not relate specifically to transportation of LNG from Canadian LNG terminals, detailed discussion of them falls outside the scope of this article.
The growth of the floating storage and regasification unit (FSRU) market has been exponential over the past decade. The birth of the industry can be traced back to mid-, when El Paso contracted with Belgian ship-owner Exmar to fit regasification units onboard three existing new-build LNG ships and one new contracted LNG ship at Korea's Daewoo Shipbuilding & Marine Engineering (DSME). The market has grown significantly ever since, with 18 FSRU projects now operational across the world. Surprisingly, such growth has been achieved against the backdrop of a slowdown in emerging markets driven by weak commodity prices. This article looks at the key drivers behind the growth in the FSRU market and how we expect the market to evolve in the future.
Cost Differential with Land Based Terminals
Developers have a multitude of options to consider when structuring regasification projects. An important initial decision is whether to opt for an onshore regasification terminal or procure a floating regasification vessel. If the latter, some consideration should also be given to the type of vessel: FSRU, floating storage unit (FSU) with onshore regasification or floating power plant unit (FPPU). In terms of FSRU procurement, developers need to decide whether to lease or purchase and whether to elect for a new-build vessel or convert an existing LNG carrier (new-build vessels often being preferred due to the cost savings associated with superior boil-off efficiency). The cost differential between FSRUs and onshore regasification terminals is significant: a new-build 170,000 cubic meter FSRU typically would cost in excess of US$250 million to purchase, whereas the cost of developing a land-based terminal of comparable size is likely to be in the region of US$1 billion [1]. However, developers typically opt to lease FSRUs rather than purchase, which can be explained by a number of factors. First, the conventional FSRU owners (BW, Excelerate Golar, Hoegh and Mitsui O.S.K Lines (MOL)) have long-standing relationships with the dominant ship manufacturing yards and usually secure options for multiple FSRUs on the basis of discounted individual units costs. Such discounts are unlikely to be available to developers wishing to procure individual units directly from the yards. Second, the lack of operational experience is a deterrent for developers wishing to purchase FSRUs directly – there are only 18 operational FSRU projects in the world [2] and very few companies that have operational experience of FSRUs. Typically developers would opt to lease FSRUs on the basis of a day rate, which can vary between US$130,000 and US$155,00 per day [3]. However, it is hard to determine a “market rate” for FSRUs given the number of different variables that need to be taken into account including: capacity of the vessel; new-build vs converted LNG carrier; length of the charter; terms and conditions of charter; credit support provided by charterer; and jurisdiction specific risks such as the prevailing legal and taxation regimes in the country where the FSRU is deployed.
Growth of FSRUs largely driven by the move to cleaner fuels
While there has always been a significant cost differential between FSRUs and onshore regasification terminals, the evolution of a preference towards FSRUs is rooted in several other factors including the need to reutilize excess shipping capacity and the necessity to cater for seasonal gas demand. In certain jurisdictions such as China and Indonesia, the move towards FSRUs was in large part driven by the need to diversify the energy mix and switch away from crude and coal to cleaner fuels such as gas – for Indonesia, FSRUs offered the lowest cost and fastest option to effect the switch to gas when compared with other gas procurement options such as onshore regasification or pipeline supply.
Speed of deployment influenced by regulatory backdrop of relevant jurisdiction
It has been stated that FSRUs are up and running as much as six times faster than onshore regasification terminals [4]. While it is accurate to say that generally FSRUs are faster to deploy than onshore regasification terminals, some of the obstacles and hurdles surrounding the deployment of FSRUs should be considered in detail before making any presumptions. Despite the fact that FSRUs are moored offshore there is often a complex permitting regime that needs to be navigated prior to deploying a FSRU. This may require a number of different licenses and permits relating to (among others) environmental impact and management, marine operation, gas processing and trading, employment/social security of shipboard personnel and often a general business or commercial license. Additionally, from a tax perspective the FSRU owner will typically have to apply for an import tax exemption (in respect of the tax treatment of the vessel), in some cases an exemption from local employment laws in connection with shipboard personnel and a Value Added Tax (VAT) exemption in relation to the importation of goods and equipment in connection with the vessel. Such regulatory requirements vary significantly from project to project and can cause significant delays to the deployment of the FSRU in the relevant jurisdiction. That said, there are recent examples where FSRUs have been deployed swiftly to address acute power shortages. BW recently concluded a five year FSRU charter with Egyptian Natural Gas Holding Company (EGAS) which operated on the basis of a five month timeframe from project inception to first gas – which represents a record short time for implementation [5]. Egypt is battling with significant power shortages and has had to significantly increase the level of imported LNG in order to meet domestic demand and has already deployed two FSRUs (Hoegh’s Gallant is moored next to BW Singapore in Ain Sokhna) with plans for the procurement of a third FSRU next year [6].
Flexibility is the foundation of the FSRU market
The contracting structures for FSRUs have changed since Golar finalized the time charter for the world’s first two FSRUs to Petrobas back in . The market in was characterized by long-term charters with a minimum of 10 to 15 years. The contracting structures adopted in the early years were more conventional and rigid. This was likely driven by the lending banks, which, at the time, were cognizant of the development/technology risks associated with this fledgling industry. Fast forward almost a decade and the market fundamentals have evolved. Flexibility for the charterer is a fundamental theme. We have seen the emergence of some seasonal FSRU charters such as Golar’s charter with Kuwait National Petroleum Company (KNPC) where the vessel is deployed as a FSRU for nine months of the year and is free to pursue spot carrier and other short term business opportunities for the remaining three months of the year [7]. The charter length for FSRUs now varies considerably. Shorter term charters, particularly in Middle Eastern countries such as Egypt and Kuwait, are being used as a bridging solution for the development of land-based terminals (Kuwait) or as a mid-term solution until offshore gas discoveries are commercialized (Egypt). We have also seen conventional infrastructure concepts adopted in FSRU projects – in Bangladesh, Petrobangla has signed an agreement with Excelerate which operates on a build-own-operate-transfer basis, where the FSRU is transferred to Petrobangla at the end of the 15 year term [8]. In some instances, FSRU owners are willing to make investments further downstream – Golar LNG has recently announced that it is in talks with Brazilian power partners to provide a FSRU to fuel a 1.5GW combined cycle power station in Sergipe (Northern Brazil). Golar is reportedly participating in up to 25% of the power project, which envisages Golar making an equity investment in the project [9]. Often developers have requested that the FSRU owner is responsible for operating and maintaining offshore infrastructure such as the jetty and potentially any interconnecting facilities – this envisages the FSRU owner taking on an entirely different risk profile than a conventional FSRU charter, this will typically be priced into the rate of hire. The ways in which FSRUs are financed have also changed significantly – a number of banks have entered the market and have found flexible, creative ways of tackling fundamental financing issues such as development risk and sovereign credit. FSRU owners have adopted new financing structures such as master limited partnerships (MLPs) to optimize returns – predominantly used to maximize cash flow and distribution growth from “dropping down” multiple shipping and FSRU charters into a limited partnership fund structure.
Careful prior assessment of gas demand is key to optimizing sustained utilization
The ability to accurately calculate future gas and electricity demand, taking into account any geographical discrepancies and changes in market fundamentals, is critical to the success of any FSRU project. Hoegh’s Lampung FSRU illustrates some of the risks associated with the development of gas infrastructure projects. The Lampung terminal is estimated to have cost approximately US$400 million and has the capacity to process 2 MTPA, which could satisfy 14% of Indonesia’s total power demand (based on last year’s figures) [10]. However, the FSRU has now sat idle for approximately six months (it was only commissioned last summer) [11]. The market fundamentals in the locality have changed since the project’s inception: gas demand has plummeted as the economic situation deteriorated and the decrease in oil price has created fuel-on-fuel competition, with gas from LNG becoming less competitive than oil in some parts of West Java. It is not always possible to account for such changes in the market fundamentals, but this example illustrates the importance of ensuring flexible contractual structures that allow for redeployment of the FSRU at alternative locations, variations to the length of the charter and potentially even the ability to sub-charter for use as an LNG carrier in low utilization periods.
Project delays part and parcel of the FSRU industry
Project delays and re-configurations of regasification projects are common in the FSRU industry. In Uruguay, the government recently cancelled its contract with GNLS S.A. (a 50/50 joint venture between Engie and Marubeni Corporation) for the development of a regasification project in the port of Montevideo, in which envisaged GNLS S.A. chartering a FSRU from MOL for 20 years. The government has since announced plans to continue the project by using MOL’s FSRU and directly charter from MOL – it is the first project where MOL will solely build, own and operate the facility. The FSRU proposed for the project will be the world’s largest – with a storage capacity of 263,000 cubic meters – and is expected to commence service in mid- [12].
Re-deployment a fundamental risk mitigation strategy for FSRU projects
In , Engie (then GDF Suez) and MOL agreed to charter two FSRUs from Hoegh LNG (co-owned by MOL) on 20-year time charters to support its Neptune LNG Deepwater Port project in Massachusetts, US. However, as the price of gas plummeted in the US, GDF Suez decided to suspend the operations when the economics of importing gas became uncertain. . The vessels originally planned for use at the Neptune LNG Deepwater Port have since been repurposed. The GDF Suez Cape Ann is currently operating as China’s first FSRU in Tianjin, China, having been sub-chartered in to China National Offshore Oil Corp (CNOOC) for 5 years. The GDF Suez Neptune is currently utilised as an LNG carrier, having delivered LNG cargoes to the Everett import terminal earlier this year from Trinidad and Tobago [13].
Small scale opportunities for FSRUs in South East Asia
The geographical profile of certain South East Asian countries such as Indonesia and the Philippines highlights the future growth opportunities for small scale FSRUs. In Indonesia, the population is scattered across thousands of islands with varying levels of gas demand. The Eastern part of Indonesia, has certain areas with marginal gas demand in the range of 3 to 30 mmscf [14]. The procurement of a conventional FSRU (120,000 to 170,000 cubic meters) would be wholly unsuitable and uneconomical – in certain areas the water depth is too shallow for a conventional FSRU to operate. A number of domestic companies have now identified that small scale LNG transportation and receiving terminals are the most suitable and efficient way for gas distribution in certain parts of Indonesia. There are currently plans for a range of smaller scale FSRUs ranging from as little as 3,000 cubic meters to cater for certain isolated regions of Indonesia. Small scale LNG projects create a number of unique legal issues to consider such as the delivery mechanism, nomination procedure and take-or-pay mechanisms behind new forms of gas transportation such as LNG truck and container deliveries. It is important to synchronise the terms of the primary LNG supply and FSRU charter agreements with the various downstream supply and end-user distribution agreements to ensure that risks are allocated appropriately. However, further analysis of the economies of scale in the small scale FSRU market is required to understand whether such developments will be economically viable in the future. The fundamentals show that smaller scale FSRUs on a per unit basis are more expensive than conventional FSRUs [15]. As noted earlier, the capital expenditure required for a 170,000 cubic meter vessel is in the region of US$250 million (although the cost would be closer to US$100 million for a second-hand converted LNG carrier). It is estimated that the cost for a 20,000 to 50,000 cubic meter FSRU would be in the region of US$50 to US$70 million (which would have to be a new build vessel as no FSRUs of this size have been constructed to date) [16].
Small-scale FSRU
Conventional FSRU
Capacity
7,500 to 20, cbm
170,000 cbm
Cost
US$50 to 70 million
US$250-300 million new-build (existing conversion approximately US$100-120 million)
Max Send-out
170 MMSCF
800 MMSCF
Source: Based on information from General Electric Company, Galway Group, IGU World Report
Conclusion
Over the past decade, the FSRU market has changed considerably. This change has manifested itself in the now increasingly flexible charter party agreements and in some instances, a number of risks are now being shifted on to the FSRU owners – we are now seeing seasonal charters and some shorter length charters. On the financing side we have seen a variety of new financing options available for FSRU projects as lending banks’ skepticism over the technology and development risk of FSRU projects seems to have abated. In South East Asia, geographical and regional fluctuations in gas demand present significant opportunities for the small scale FSRU market – although the economics of such projects need to be carefully considered. There are a number of challenges on the horizon for the FSRU industry as it grapples with a change in some of the fundamentals that have underpinned the industry for the past decade – cheaper oil presents fuel-on-fuel competition and the growth in the number of FSRU owners potentially presents a threat to profit margins. However, looking ahead to the next decade demand is continuing to increase – there are a further 30 FSRU projects currently being considered – and therefore any argument that suggests the industry will experience a slowdown should be carefully scrutinized.
Operational FSRU Projects as of November *
*sourced from publicly-available information
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[1] Capt Doug Brown Gas/LNG Outlook: Does LNG Work for Central America?, Poten Partners, June . See http://www.platts.com/im.platts.content/productsservices/conferenceandevents/
/pc307/presentations/douglas_brown.pdf
[2] LNG Shipping Market Update, Fearnley LNG, October .
[3] LNG Shipping Market Update, Fearnley LNG, October .
[4] Anna Shiryaevskaya, The Hottest Commodity Asset Right Now Is a 35,000-Ton Steel Ship, Bloomberg, 16 September – referencing views of Hoegh LNG Holding Ltd. and Excelerate Energy LLC. See http://www.bloomberg.com/news/articles/-09-15/the-hottest-commodity-asset-right-now-is-a-35-000-ton-steel-ship
[5] BW to Provide FSRU to EGAS for Deployment to Ain Sokhna, Egypt, Rigzone, 4 August , quoting Carsten Mortensen, BW Group CEO. See http://www.rigzone.com/news/
oil_gas/a//BW_to_Provide_FSRU_to_EGAS_for_Deployment_to_Ain_Sokhna_Egypt#sthash.1rHPdL40.dpuf
[6] Ehab Farouk and Eric Knecht, Egypt plans to rent third regasification unit by early , Reuters, 24 October . See http://www.reuters.com/article//10/24/egypt-lng-terminal-idUSL3N12O09C#iTLTFGvSDpmGeeJ1.97
[7] Rob Almeida, Kuwait Petroleum Signs Charter Contract for Golar LNG’s Newbuild FSRU, ‘gCaptain’, 5 August . See http://gcaptain.com/golar-lng-fsru-igloo-kuwait/
[8] Aminur Rahman Rasel, Deal signed with Singapore-based firm for Moheshkhali LNG terminal, Dhaka Tribune, 26 February , See http://www.dhakatribune.com/bangladesh//feb/26/deal-signed-singapore-based-firm-moheshkhali-lng-terminal
[9] Golar in talks to provide FSRU to Brazil power project, LNG World News, 27 August . See http://www.lngworldnews.com/golar-lng-in-talks-to-provide-fsru-to-brazil-power-project/
[10] Fergus Jensen and Wilda Asmarini, As Indonesia gas demand falters, floating LNG plant lies idle, Reuters, 1 July . See http://www.reuters.com/article//07/01/indonesia-lng-demand-idUSL3N0ZA30Q
[11] Fergus Jensen and Wilda Asmarini, As Indonesia gas demand falters, floating LNG plant lies idle, Reuters, 1 July . See http://www.reuters.com/article//07/01/indonesia-lng-demand-idUSL3N0ZA30Q
[12] MOL continues to agree FSRU Project in Uruguay, LNG World News, 5 October . See http://www.lngworldnews.com/mol-agrees-to-continue-fsru-project-in-uruguay/
[13] GDF Suez Cape Ann to serve as FSRU in China, LNG World News, 2 May . See http://www.lngworldnews.com/gdf-suez-cape-ann-to-serve-as-first-fsru-in-china/
[14] Moh. Taufik Afianto, Small Scale LNG, the Best Suited for Indonesia’s Archipelagos, PT Pertamina (Persero), Presentation Paper: 7th International Conference & Exhibition on Liquefied Natural Gas (LNG 17), Houston, 16 – 19 April See http://www.gastechnology.org/
Training/Documents/LNG17-proceedings/10-5-Taufik_Afianto.pdf
[15] Gauthier Van Marcke and Alina Dumitrasc, Opportunities and Challenges of using LNG as fuel in small to medium-size Power Generation”, Galway Group, Presentation Paper: 7th International Conference & Exhibition on Liquefied Natural Gas (LNG 17), Houston, 16 – 19 April . See http://www.gastechnology.org/Training/Documents/LNG17-proceedings/10-3-Gauthier_van_Marcke.pdf
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