Robert-Bourassa generating station

---

title: "Robert-Bourassa generating station" type: doc version: 1 created: 2026-02-28 author: "Wikipedia contributors" status: active scope: public tags: ["james-bay-project", "dams-completed-in-1981", "dams-in-quebec", "dams-on-the-la-grande-river", "publicly-owned-dams-in-canada"] description: "Hydroelectric power station in Québec, Canada" topic_path: "geography/canada" source: "https://en.wikipedia.org/wiki/Robert-Bourassa_generating_station" license: "CC BY-SA 4.0" wikipedia_page_id: 0 wikipedia_revision_id: 0

::summary Hydroelectric power station in Québec, Canada ::

::data[format=table title="Infobox dam"]

Field	Value
name	Robert-Bourassa generating station
image	Centrale RB Intérieur.jpg
image_size	260px
name_official	Centrale Robert-Bourassa
dam_crosses	La Grande River
location	Baie-James, Quebec, Canada
dam_type	Embankment dam
dam_length	2835 m
dam_height	162 m
plant_hydraulic_head	137.2 m
dam_width_crest	9 m
spillway_capacity	17600 m3/s
construction_began	1974
opening	1981
cost	C$3.8 billion (1987)
owner	Hydro-Québec
res_name	Robert-Bourassa Reservoir
res_capacity_total	61.7 km3
res_surface	2835 km2
plant_turbines	16 × 351 MW
Francis turbines
plant_capacity	5,616 MW
plant_annual_gen	31000 GWh
plant_capacity_factor	63%
coordinates
extra	Sources:

• *Hydro-Québec, The La Grande Complex visitor booklet, 2004, | ::

| name = Robert-Bourassa generating station | image = Centrale RB Intérieur.jpg | image_size = 260px | name_official = Centrale Robert-Bourassa | dam_crosses = La Grande River | location = Baie-James, Quebec, Canada | dam_type = Embankment dam | dam_length = 2835 m | dam_height = 162 m | plant_hydraulic_head = 137.2 m | dam_width_base = | dam_width_crest = 9 m | spillway_type = | spillway_capacity = 17600 m3/s | construction_began = 1974 | opening = 1981 | cost = C$3.8 billion (1987) | owner = Hydro-Québec | res_name = Robert-Bourassa Reservoir | res_capacity_total = 61.7 km3 | res_catchment = | res_surface = 2835 km2 | res_max_depth = | plant_operator = | plant_turbines = 16 × 351 MW Francis turbines | plant_capacity = 5,616 MW | plant_annual_gen = 31000 GWh | plant_capacity_factor= 63% | plant_commission = | plant_decommission = | location_map = | location_map_caption = | coordinates = | website = | extra = Sources:

• *Hydro-Québec, The La Grande Complex visitor booklet, 2004,

The Robert-Bourassa generating station, formerly known as La Grande-2 (LG-2), is a hydroelectric power station on the La Grande River that is part of Hydro-Québec's James Bay Project in Canada. The station can generate 5,616 MW and its 16 units were gradually commissioned between 1979 and 1981. Annual generation is in the vicinity of 26500 GWh.

Together with the adjacent 2,106 MW La Grande-2-A generating station (LG-2-A), commissioned in 1991–1992, it uses the reservoir and dam system of the Robert-Bourassa Reservoir to generate electricity. The two plants taken together account for more than 20% of Hydro-Québec's total installed capacity of 36,810 MW in 2009. It is Canada's largest hydroelectric power station, ranks in 15th place on the list of largest hydroelectric power stations and is the world's largest underground power station.

Initially known as La Grande-2, it was renamed after Robert Bourassa who, as Premier of Quebec (1970–1976 and 1985–1994), gave the James Bay Project a vital political impetus.

Context

Main article: James Bay Project

The Robert-Bourassa generating station is the main facility of the James Bay hydroelectric project, a large hydroelectric complex built on the La Grande River, a large river in Quebec's sparsely populated northern Quebec. It was also the first to be built, between 1974 and 1981. It was inaugurated by Premier René Lévesque of Quebec, on October 27, 1979.

Design work on the generating station, dam and reservoir began in October 1970 when Montreal-based engineering firm Rousseau Sauvé Warren (RSW) was commissioned by Hydro-Québec to prepare a feasibility study for a hydroelectric complex on the La Grande River. Another engineering firm, Asselin, Benoît, Boucher, Ducharme & Lapointe (ABBDL) was tasked with a feasibility study on the more southerly NBR (Nottaway, Broadback, Rupert) rivers. At RSW the development of the La Grande River was championed by François Rousseau, one of firm's associates and a former Hydro-Québec senior engineer.

A final decision to build the hydroelectric complex on the La Grande hydrographic system was made in 1972, after engineers determined the NBR project would be less cost effective because of the silty nature of the soils in the NBR area. The La Grande option had the added advantages of a lesser impact on First Nations hunting and fishing, on the boreal forest and would require less flooding.

Construction

The main dam is located 117.5 km from the mouth of the river, in the transition zone between the plateau and the coastal plain, and has a maximum height of 162 m. Twenty-nine dykes of various sizes close the reservoir. They are organized in three group: dykes D1-D4 are located north of the spillway, nicknamed the Staircase of the Giants, D5-D14 are located on the left shore of the river while a third group, nicknamed the Duncan dykes (D17-D27), are located 30 km south. The dam and dykes hold a reservoir covering an area of 2835 km2 with a useful capacity of 19.365 billion m3.

The generating station itself is located 137.2 m underground, 6 km downstream from the main dam. It hosts 16 Francis turbines, set up in two groups of eight each.

In 1974, in what was one of the most extreme cases of workplace sabotage up to that time, workers at the La Grande-2 site used bulldozers to topple electric generators, damage fuel tanks, and set buildings on fire. The project was delayed a year, and the direct cost of the damage estimated at CAD$2 million. The causes were not clear, however three factors have been cited: inter-union rivalry, poor working conditions, and the perceived arrogance of American executives at the contractor, Bechtel Corporation.

Road

Main article: James Bay Road

::figure[src="https://upload.wikimedia.org/wikipedia/commons/0/0b/Bridge_at_Eastmain_river.jpg" caption="p=54}}"] ::

The first step towards the construction of the La Grande-2 generating station took place in June 1971, in Matagami, a small mining town located 630 km south of La Grande River. Engineering firm Desjardins, Sauriol and Associates were tasked with the construction of a basic road to the future site and the Cree settlement at Fort George. The deadline was tight: 450 mi in 450 days.

The first challenge involved deploying teams of land surveyors and lumberjacks by seaplanes and helicopters to clear a path for a permanent road. Parallel to the path, a few kilometres away, an ice road was built to move heavy machinery north. The first milestone was reached on February 11, 1972, with the opening of the 555 m ice bridge crossing the Rupert River.

The temporary road reached the La Grande River in December 1972, allowing the minimum necessary level of access needed to begin work – namely to construct housing for the thousands of people who would work on the dam for the next decade. A permanent road surfaced with gravel was completed on October 20, 1974, at a cost of $348 million, and was paved over the next two years.

Temporary diversion

The first stage of construction was the temporary diversion of the La Grande River; the tunnels had to be big enough to protect the construction site from floods, but not so large as to unnecessarily increase cost. Two diversion tunnels were drilled into the left bank of the river and were opened on April 27, 1975. For the next three and a half years the flow of the river would be diverted through the tunnels. Each tunnel was 14.8 m wide and 18 m high; the north tunnel was 730 m long and the south, 830 m. The tunnels were designed to carry the 65-year flood flow of the La Grande River, calculated at 7500 m3/s.

Since the original construction schedule called for completion on February 15, 1980, the south diversion tunnel was scheduled to be closed in November 1978, during low river flows in the winter. However, the deadline was revised forward by 60 days, and the tunnel had to be reinforced to withstand harsh autumn conditions.

After the dam was completed, the tunnels are still used as flood control outlet works and have a design flow of 3100 m3/s.

Dam and dykes

::figure[src="https://upload.wikimedia.org/wikipedia/commons/c/c0/Staircase_of_the_giants.jpg" caption="Spillway (left) and main dam"] ::

The Robert-Bourassa dam is located 117.5 km from the mouth of the La Grande River, in the transition zone between the Laurentian Plateau (the elevated Canadian Shield) and the coastal plain. It has a maximum height of 162 m and is 2836 m long at the crest. The core of the earthfill dam is made of glacial moraine which is impervious, and available in large quantities within a 10 km radius of the dam site, due to extensive glaciation of the area during the last ice age. The core is slightly inclined upstream, to increase resistance against the immense pressure of water in the reservoir. The layers above consist of fill zones of varying coarseness, and is surfaced with riprap to reduce erosion.

The original plan envisioned the construction of a concrete-face rock-fill dam, but this was rejected in favor of a more conventional embankment design, partly because of the lower cost, and also because the concrete face would have to be inspected from time to time requiring drainage of the reservoir. Because of the huge size of the reservoir, this would be essentially impossible.

In order to hold the reservoir at its operating height of 175.3 m, 29 dikes surround the reservoir basin at various locations. Dikes D-1 to D-4 are located immediately to the north; D-5 to D-14 (the "Forebay dikes") to the south; and D-17 to D-27 (the "Duncan dikes") about 30 mi further south. They range in size from D-26B, 82 m long, to D-20, 6052 m long.

::data[format=table title="Dams and dikes of the Robert-Bourassa development"] | Type | Crest length | Max. height | Min. top width | Excavation volume | Fill volume | m | ft | m | ft | m | ft | m3 | ft3 | m3 | ft3 | |---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---| | North dikes (D1-D4) | 5278 m | 50 m | 8 m | 1361000 m3 | 26274000 m3 | | | | | | | | | | | | Main dam | 2836 m | 162 m | 9 m | 1361000 m3 | 26274000 m3 | | | | | | | | | | | | Forebay dikes (D5-D14) | 9018 m | 66 m | 7.6 m | 2176000 m3 | 11482000 m3 | | | | | | | | | | | | Duncan dikes (D14-D27) | 13675 m | 52 m | 7.6 m | 1884000 m3 | 12070000 m3 | | | | | | | | | | | | Total | 27972 m | | | 5421000 m3 | 49826000 m3 | | | | | | | | | | | ::

Reservoir

::figure[src="https://upload.wikimedia.org/wikipedia/commons/2/2f/Robert-Bourassa_Reservoir.jpg" caption="The Robert Bourassa Reservoir as seen from space"] ::

Covering an area of 2835 km2 – greater in size than Luxembourg – the vast Robert-Bourassa Reservoir is fed by an upstream catchment of 32480 km2, plus water diversions from the James Bay Project, the Caniapiscau Reservoir and the EOL (Eastmain-Opinaca-La Grande) diversion project. About 19.365 km3 is active or usable storage for power generation, out of a total volume of 61.4 km3. Because of its great size, it is inhabited by a diverse array of aquatic flora and fauna.

On November 27, 1978, the diversion tunnels were closed and water began to back up behind the dam. The enormous reservoir took over a year to completely fill. The water initially rose very fast: 43 m during the first week, with 15 m on the first day alone. The reservoir reached its minimum operational level of 167.6 m on September 2, 1979, and reached its normal maximum level of 175.3 m in December 1979.

Desaulniers pumping station

The construction of the Duncan dikes partially blocked the flow of the Desaulniers River, which is located to the southeast of the Robert-Bourassa Reservoir. The river flowed into Desaulniers Lake at an elevation of 143.3 m, 32 m below the level of the Robert-Bourassa Reservoir. To prevent the flooding of an additional 30 km2 and preserve the lake in its natural state, a pump station was installed which removes water from the Desaulniers Lake to the Robert-Bourassa Reservoir. The pump station was designed to remove an annual average of 2.8 m3/s, from a drainage area of 160 km2.

The pumping station was commissioned in June 1977. It has four pumps with a capacity of 1.7 m3/s each, with a maximum lift of 54.3 m. Each pump is powered by a 1,120 KW (1,500 hp) motor. The pumping station also served to divert water away from the Desaulniers river bed, during the construction of dike D-20.

Spillway

::figure[src="https://upload.wikimedia.org/wikipedia/commons/b/b2/Évacuateur_de_crues_(spillway)3.JPG" caption="Spillway close up view"] ::

The spillway, nicknamed Staircase of the Giants, is near the north end of the main dam and is part of dike D-4. It consists of a concrete control structure and a man-made waterfall discharging into a stilling basin below the dam. The spillway has eight 12.2 m wide gates, separated by 4.3 m thick columns. The gates are opened and closed by cable winches, in order to control spills. The eight gates are all opened at the same time once every 15 years.

Having passed through the gates, the kinetic energy of the water is dissipated in a 135 x basin at the foot of the control structure. It then flows down a 1500 m long rock channel with a vertical drop of 110 m on its way back into the La Grande river. The channel has 10 steps ranging from 9.1 to in height and 127 to in length. The flow rate increases from 11 m/s at the top of the spillway to 22 m/s at the bottom.

Generating station

The Robert-Bourassa hydroelectric station, formerly named La Grande-2 or LG2, is located underground about 6 km downstream of the main dam. With an installed capacity of 5,616 megawatts, it is the largest power station owned by Hydro-Québec, and the largest underground power station in the world. On October 27, 1979, 3,000 people gathered for the dedication of the power plant by Quebec Premier René Lévesque.

The underground complex, including a service tunnel, the generation room and a surge chamber, required the excavation of 2350000 m3 of material. The plant was constructed by Rousseau Sauvé Warren (RSW) of Montreal. Unlike other facilities in the James Bay Project, the LG2 was constructed to imperial rather than metric specifications, even though Canada had converted to the metric system in the 1970s.

The power station can be accessed either by an elevator or a tunnel. The plant has 16 Francis turbines, divided into two sets of eight each, and separated by a mounting area, workshops, control room, elevator shaft and ventilation system.

The turbines were built by two partners of James Bay Energy (SEBJ). Units 1, 3, 5, 7, 10, 12, 14 and 16 were built by Marine Industries Limited (MIL), while units 2, 4, 6, 8, 9, 11, 13 and 15 were built by Canadian General Electric (alternators) and Dominion Engineering Works (turbines). The two groups have somewhat different characteristics. The turbines manufactured by MIL are lighter, 96 tonnes compared to 111, and have fifteen blades, compared to 11 for the other group.

Each turbine is rated at 339 MW at a 137 m head and a speed of 133.33 rpm. The generators are rated at 370 megavolt amperes (MVA), which is increased to 390 MVA in the winter.

::data[format=table title="Power station specifications"] | Facility | Soil excavation | Rock excavation | Concrete | Steel | m3 | ft3 | m3 | ft3 | m3 | ft3 | kg | lb | Intake channel | Water crane | Penstocks | Service tunnel and well | Adit | Transformer station | Generator room and ventilation | Surge chamber | Drainage galleries | Tailrace | |---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---| | 78000 m3 | 552000 m3 | | | | | | | | | | | | | | | | | | | | | | | | 183000 m3 | 81500 m3 | 4200000 kg | | | | | | | | | | | | | | | | | | | | | | 190000 m3 | 55000 m3 | 960000 kg | | | | | | | | | | | | | | | | | | | | | | 101000 m3 | 3500 m3 | 25000 kg | | | | | | | | | | | | | | | | | | | | | 21000 m3 | 175000 m3 | 2500 m3 | 3000 kg | | | | | | | | | | | | | | | | | | | | | 417000 m3 | 530000 m3 | 19000 m3 | 711000 kg | | | | | | | | | | | | | | | | | | | | | | 454000 m3 | 127000 m3 | 5951000 kg | | | | | | | | | | | | | | | | | | | | | | 371000 m3 | 12000 m3 | 550000 kg | | | | | | | | | | | | | | | | | | | | | 608000 m3 | 1370000 m3 | 500 m3 | | | | | | | | | | | | | | | | | | | | | | 114000 m3 | 179000 m3 | | | | | | | | | | | | | | | | | | | | | | | Total | 1,238,000 | 43,720,000 | 4,105,000 | 144,967,000 | 301,000 | 10,630,000 | 12,400,000 | 27,337,000 | | | | | | | | | | | | | | | ::

La Grande-2-A

Main article: La Grande-2-A generating station}} This part of the James Bay Project can generate 2,106 MW and was commissioned in 1991–1992.{{Cite web

Photos

Image:Bourassa power plant.jpg|Main entrance of the underground generating station Image:Réservoir R-B.jpg|The Robert-Bourassa Reservoir, near the generating station Image:Transformateur CentraleR-B.jpg|Electric transformers at the plant's switchyard

References

Works cited

• (also available in English, under the title Hydro-Québec After 100 Years of Electricity)
• .
• .
• .
• .

References

1. Hydro-Québec Production. (2010). "Hydroelectric Generating Stations (as of December 31, 2009)". Hydro-Québec.
2. Pierre Parent of Hydro-Quebec. (2004). "Implementing Detailed Efficiency Data for Optimal Use in Hydroelectric Generating Plants".
3. "Centrales - Hydro-Québec Production".
4. {{harvnb. Bolduc. 2000
5. {{harvnb. Bolduc. Hogue. Larouche. 1989
6. {{harvnb. Turgeon. 1992
7. {{harvnb. Société d'énergie de la Baie James. 1987
8. Rinehart, J.W. ''The Tyranny of Work'', Canadian Social Problems Series. Academic Press Canada (1975), pp. 78-79. {{ISBN. 0-7747-3029-3. See also Auf Der Maur, in Further Reading.
9. {{harvnb. Société d'énergie de la Baie James. 1987
10. {{harvnb. Lacasse. 1983
11. {{harvnb. Société d'énergie de la Baie James. 1987
12. {{harvnb. Lacasse. 1983
13. "Opening of the spillway gates at Robert-Bourassa generating station".
14. "La Grande 2-A Generating Station".

::callout[type=info title="Wikipedia Source"] This article was imported from Wikipedia and is available under the Creative Commons Attribution-ShareAlike 4.0 License. Content has been adapted to SurfDoc format. Original contributors can be found on the article history page. ::