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SPOKANE RIVER BRIDGE AT LONG LAKE DAM............. HAER No. WA-95


[[Category:"Fire"]]
[[file:1993-loc-0002-long-lake-bridge-haer-00.png|thumb|right|200px|Original Cover Page]]
[[Category:Fire]]
State Route 231 spanning the Spokane River
[[Category:RHS Class Composite]]
 
Reardan vicinity
 
Lincoln County
 
Washington
 
HAER WASH 22-REAR...
 
 
WRITTEN HISTORICAL AND DESCRIPTIVE DATA
 
PHOTOGRAPHS
 
HISTORIC AMERICAN ENGINEERING RECORD
page0image
NATIONAL PARK SERVICE
<br>
DEPARTMENT OF THE INTERIOR
<br>
P.O. BOX 37127
<br>
WASHINGTON, D.C. 20013-7127
 
HISTORIC AMERICAN ENGINEERING RECORD
----
[[file:1993-loc-0002-long-lake-bridge-haer-01.png|thumb|right|200px|Original Page 1]]
 
{|
|-
| '''Location'''|| Spanning the Spokane River between Lincoln and Stevens
counties on state route 231, beginning at mile point
44.65.
|-
|'''UTM'''||11/436270/5298530<br>11/436305/5298560
|-
|'''Quad'''||Long Lake, Wash.
|-
|'''Date of Construction'''||1949
|-
|'''Engineer''' ||Washington Department of Highways
|-
'''Fabricator''' ||Henry Hagman of Cashmere, Washington.
|-
|'''Owner''' ||Washington Department of Highways.
<br>
Since 1977, the Washington State
Department of Transportation, Olympia,
Washington
|-
|'''Present Use''' ||Vehicular and pedestrian traffic.
|-
| '''Significance'''
|The bridge is a late example of an open-spandrel reinforced-concrete ribbed
deck arch. Considère hinges were used at the skewbacks to relieve stresses in
the arch during the construction of the bridge. The bridge has been nominated
to the National Register of Historic Places.
|-
| '''Historian''' || Wm. Michael Lawrence, August 1993
|}
----
'''History of the Bridge'''
 
[[file:1993-loc-0002-long-lake-bridge-haer-02.png|thumb|right|200px|Original Page 2]]
The Spokane River Bridge at Long Lake Dam replaced a timber
trestle bridge. It is said to be the longest concrete arch span
constructed in the state from 1941 to 1950.<ref>
1 Department of the Interior, National Park Service, "National Register of Historic Places Nomination Form for Spokane River Bridge at Long Lake Dam, Lincoln and Stevens counties, Washington," 1991.
</ref> The setting for
this bridge is a remote one, with the Spokane River running down
a gorge which separates two very different regions. To the
north, in Stevens County, are the Selkirk Mountains, an area
which has made its living by lumbering, by mining zinc, lead, and
copper, and by ranching sheep and cattle.<ref>
2 Fred C. Bohm and Craig E. Holstine, The People’s History of Stevens County (Colville, WA: Stevens County Historical Society, 1983).
</ref> Lincoln County, to
the south, is mostly a sparsely populated, arid plain with few
trees. Irrigation, using water from Little Falls Lake and Long
Lake, after the construction of two dams in 1910 made the fertile
region into a major wheat-producing area.<ref>
3 Donald E. Walter, Lincoln County: A Lasting Legacy (Davenport, WA: Lincoln County Centennial Committee, 1988).
</ref> The highway across
the Spokane River is one of the links between these two different
regions.
 
The state highway department prepared a design for a new
reinforced-concrete arch bridge in 1948. The engineers completed
the design before 15 July 1948, when the drawings received the
approval of Ray Dinsmore, the director of highways.<ref>
4 Washington Department of Highways, "Secondary State Highway No. 3-J, Spokane River Bridge at Long Lake" (approved 15 July 1948 by the director of highways), 15 sheets of drawings, copies held by Records Control, Washington State Department of Transportation, Olympia, WA [WSDOT].
</ref> The
department did not call for bids, however, until the following
year. A copy of the announcement appeared in the Pacific Builder
and Engineer, the major contracting and engineering journal in
the northwest, on 9 February 1949.<ref>
5 Office of the Director of Highways, Olympia, Washington, "Notice to Contractors," in "Construction News Bulletin," Pacific Builder and Engineer 55 (19 February 1949): 16.
control, WSDOT.
</ref> Bids for this and several
other projects were opened on the 4 March. Henry Hagman, of
Cashmere, Washington, was the low bidder at $233,698.74. The
other bids were submitted by State Construction Co. of Seattle,
at $244,366.12, and David Nygren of the same city, at
$270,341.80.<ref>
6 "Construction News Bulletin," Pacific Builder and Engineer 55 (12 March 1949): 2.
</ref> Hagman and the state signed the contract on 14
March.<ref>
7 State of Washington and Henry Hagman, Contract (8 March 1949). Copy at Records Control, Washington State Department of Transportation, Olympia; the contractor completed the project in May of 1950 and on 1 June 1950 D. A. Kelley, the resident engineer, reported a final cost estimate of $233,175.09 to the Director of Highways. See Washington Department of Highways, Twenty-third Biennial Report of the Director of Highways, 1948-1950, 24.
</ref>
 
'''Design and Description'''
 
The Spokane River bridge at Long Lake dam is a late example the
open-spandrel reinforced-concrete ribbed deck arch built in the
United States during the early twentieth century. Considère
hinges were used during its construction. Its streamlined
appearance contrasts with earlier, ornamented concrete arch
bridges.
 
The bridge is a 485’ long reinforced-concrete structure,
consisting of a deck supported by an open-spandrel ribbed arch
and seven spans supported by bents. Its deck rests on cross
beams and longitudinal girders supported by the bents and the
spandrel columns. It consists of:
 
* one 40’ reinforced-concrete deck girder span
* one 41’ reinforced-concrete deck girder span
* one 200’ reinforced-concrete ribbed deck arch span
* one 41’ reinforced-concrete deck girder span
* three 40’ reinforced-concrete deck girder spans
* one 30’ reinforced-concrete deck girder span
[[file:1993-loc-0002-long-lake-bridge-haer-03.png|thumb|right|200px|Original Page 3]]
The arch is over the river and the bents are on steep slopes on
either side on the channel.<ref>
8 Washington Department of Highways, "Secondary State Highway No. 3-J, Spokane River Bridge at Long Lake" (approved 15 July 1948 by the director of highways), sheet 1, copies held by Records
</ref>
 
The deck is 31’-4" wide with a 24’ wide roadway and a 4’ wide
sidewalk. It bears on cross beams at 10’ on center framing into
two rows of girders at 9’ to either side of the centerline of the
bridge. The deck is an 8"-thick reinforced-concrete slab. These
members are monolithic. The beams are 12" x 1’-8" (wide x deep),
while the girders are 1’-8" wide and vary in depth from 3’ at the
span to 4’-9-5/8" at the bents, the underside of each girder
being a parabolic curve.<ref>
9 Ibid., sheet 4 and 5.
</ref>
 
The bents are, on the average, 3’ x 2’, with the long dimension
parallel with the spans. Each has a batter of 1:144. They bear
on footings in the embankments.<ref>
10 Ibid., 4.
</ref> The spandrel columns are
similar, but rest on the arch, with the outermost panels at 25’
on center and the middle seven panels at 23’.<ref>
11 Ibid., 1.
</ref>
 
The bents closest to the arch and the outermost spandrel columns
bear on the arch abutments, adjoin each other, and are separated
throughout their heights by a 1" open joint, assuring that the
arch span can expand and contract independently of the
approaches. The second spandrel column on either side of the
crown of the arch is similarly split by a vertical joint,
allowing the deck above to contract and expand.<ref>
12 Ibid., 7. The details are in the "Longitudinal Section Thru Half Arch.
</ref>
 
The reinforced-concrete arch rises 44’ from the skewbacks to the
crown at the centerline of the rib.<ref>
13 Ibid.
</ref> The skewback centerlines
are 5’-6" from the open joint between the arch and the rest of
the bridge.<ref>
14 Ibid., sheet 1.
</ref> This arch is a parabola with a radius, measured at
the intrados, varying from 126--11" at the crown to 145’-7-5/8"
at the abutments. The arch also rib varies in its dimensions,
from 3’ x 4’ (high x wide) at the crown, to 4’ x 5’-8" (high x
wide) at the abutments.<ref>
15 Ibid., sheet 7.
</ref> The arch and its abutments bear on
footings which are at an angle to the horizontal in order to
counteract the outward thrust of the arch.
 
The arc in its completed form is fixed, having no hinges at the
skewbacks or crown to permit movement. During its construction,
however, it was provided with temporary hinges near its
skewbacks. These hinges are a late example of their use in the
United States. Two decades before, for example, Conde B.
McCullough, the Oregon State Bridge Engineer from 1919 to 1936,
used the type of hinge perfected by the French engineer Armand
 
[[file:1993-loc-0002-long-lake-bridge-haer-04.png|thumb|right|200px|Original Page 4]]
Considére in the crowns of reinforced-concrete tied arches along
the Oregon Coast Highway (U.S. 101) in the early 1930s.<ref>
16 Robert William Hadlow, "Conde B. McCullough, 1887-1946:
Master Builder of the Pacific Northwest" (Ph.D. diss., Washington
State University, 1993), 160-63.
</ref>
 
Throughout most of the rib, the bars are located near the
extrados and intrados. During construction of the lowermost
parts of each ribs, these bars were terminated on either side of
the hinge, with a gap between them. Specially bent bars were
Placed with their ends inserted in this regular reinforcement.
The middles of the bent bars converge at the center of the arch
rib and are surrounded by circular hoops. When the concrete was
poured at this hinge, notches were left in the rib, above and
below the point where the bars converge. After all other parts
of the bridge were poured, the workmen would return, eliminate
the gap between the regular bars by splicing additional bars to
their ends. This was accomplished by means of welding plates.
The workmen then filled the notches with concrete.<ref>
17 Ibid., "Detail of Considère Hinge" and "Welding Details for
Rib Steel at Hinge." For an axonometric illustration of the
Considère hinge, see "Alsea Bay Bridge, HAER No. OR-14," sheet 2 of
2, Todd A. Croteau, et al., delineators, in the Historic American
Engineering Record, Prints and Photographs Division, Library of
Congress.
</ref> At the
narrowest part of the hinge the steel to concrete ratio is
higher, making the hinge flexible. During construction of the
bridge, such hinges reduced stresses in the ribs due to shrinkage
of the concrete during setting and hardening, to elastic
compression in the arch due to superimposed loading, and to
settlement of the abutments under the thrust of the arch.<ref>
18 W. L. Scott and C. W. Spicer, Reinforced Concrete Bridges
(London: Crosby Lockwood & Son, 1925), 156-57.
</ref>
 
Overall, the bridge is rather attenuated in appearance, with its
slender bents and spandrel columns. The elliptical arches formed
by the underside of the girders echoes the form of the arch and
creates a pleasing rhythm. The bridge has no ornament except for
moldings at the top of its railings. Its streamlined appearance
contrasts with bridges adorned with architectural ornamentation
such as the Baker River Bridge in Concrete, Washington (HAER No.
WA-105), a much earlier example of the open-spandrel reinforced-
concrete ribbed arch, built in 1916.<ref>
19 See Department of the Interior, National Park Service,
Historic American Engineering Record, "Baker River Bridge, HAER No.
WA-105," by Wm. Michael Lawrence, 1993.
</ref> The two bridges represent
the early and late years of this type of construction.
 
'''Repair and Maintenance'''
 
The bridge is in good condition with some minor cracking,
efflorescence, and spalling. The deck has been worn down to the
aggregate, exposing a few reinforcing bars.<ref>
20 "Spokane River Bridge at Long Lake Dam, No. 231/101," Bridge
Preservation Section, WSDOT.
</ref>
 
'''Data limitations'''
 
The most helpful sources for this report were the working
drawings, the contract, and the final estimate, which survive at
the Washington State Department of Transportation archives, and
two entries in the ''Pacific Builder and Engineer.'' The drawings
made it possible to describe and analyze the structure. All of
these documents made it possible to establish its dates.
 
[[file:1993-loc-0002-long-lake-bridge-haer-05.png|thumb|right|200px|Original Page 5]]
A search of engineering and contractors’ journals failed to
discover any articles regarding this bridge. The clipping files
at the Washington State Library in Olympia, the Washington State
Historical Society at Tacoma, the Museum of History and Industry
in Seattle, and the Special Collections Room at the University of
Washington in Seattle, and the Seattle Public Library contained
newspaper articles regarding many other bridges, but not this
one.
 
'''Project Information'''
 
This project is part of the Historic American Engineering Record
(HAER), National Park Service. It is a long-range program to
document historically significant engineering and industrial
works in the United States. The Washington State Historic
Bridges Recording Project was co-sponsored in 1993 by HAER, the
Washington State Department of Transportation (WSDOT), and the
Washington State Office of Archeology & Historic Preservation.
Fieldwork, measured drawings, historical reports, and photographs
were prepared under the general direction of Robert J. Kapsch,
Ph.D., Chief, HABS/HAER; Eric N. DeLony, Chief and Principal
Architect, HAER; and Dean Herrin, Ph.D., HAER Staff Historian.
 
The recording team consisted of Karl W. Stumpf, Supervisory
Architect (University of Illinois at Urbana-Champaign); Robert W.
Hadlow, Ph.D., Supervisory Historian (Washington State
University); Vivian Chi (University of Maryland); Erin M. Doherty
(Miami University), Catherine I. Kudlik (The Catholic University
of America), and Wolfgang G. Mayr (U.S./International Council on
Monuments and Sites/Technical University of Vienna),
Architectural Technicians; Jonathan Clarke (ICOMOS/Ironbridge
Institute, England) and Wm. Michael Lawrence (University of
Illinois at Urbana-Champaign), Historians; and Jet Lowe
(Washington, D.C.), HAER Photographer.
 
[[file:1993-loc-0002-long-lake-bridge-haer-06.png|thumb|right|200px|Original Page 6]]
BIBLIOGRAPHY
 
Bohm, Fred C. and Craig E. Holstine. The People’s History of
Stevens County. Colville, WA: Stevens County Historical
Society, 1983.
 
“Construction News Bulletin," Pacific Builder and Engineer 55 (19
February 1949): 16.
 
"Construction News Bulletin," Pacific Builder and Engineer 55 (12
March 1949): 2.
 
Hadlow, Robert William. "Conde B. McCullough, 1887-1946: Master
Builder of the Pacific Northwest." Ph.D. diss., Washington
State University, 1993).
 
Scott, W.L. and C. W. Spicer. Reinforced Concrete Bridges.
London: Crosby Lockwood & Son, 1925.
 
U.S. Department of the Interior. National Park Service.
Historic American Engineering Record. "Alsea Bay Bridge,
HAER No. OR-14," drawings, Todd A. Croteau, et al.,
delineators, 1990, held by Prints and Photographs Division,
Library of Congress.
 
U.S. Department of the Interior. National Park Service.
Historic American Engineering Record. "Baker River Bridge,
HAER No. WA-105," by Wm. Michael Lawrence, 1993.
 
U.S. Department of the Interior. National Park Service.
"National Register of Historic Places Nomination Form for
the Spokane River Bridge at Long Lake Dam, Lincoln and
Stevens counties, Washington," 1991.
 
Walter, Donald E. (ed.) Lincoln County: A Lasting Legacy.
Davenport, Washington: Lincoln County Centennial Committee,
1988.
 
Washington State and Henry Hagman. Bid proposal (2 March 1949)
and Contract (8 March 1949) for Spokane River Bridge at Long
Lake Dam [No. 231/101]. Copy held by Records Control,
Washington State Department of Transportation, Olympia, WA
(WSDOT).
 
Washington. Department of Highways. "Secondary State Highway No.
3-J, Spokane River Bridge at Long Lake" (approved 15 July
1948). 15 sheets of drawings, held by Records Contr1993-loc-0002-long-lake-bridge-haer-00.pngol,
WSDOT.
 
[[file:1993-loc-0002-long-lake-bridge-haer-07.png|thumb|right|200px|Original Page 7]]
Washington. Department of Highways. Twenty-third Biennial Report
of the Director of Highways, 1948-1950.
 
Washington.  State Department of Transportation. Bridge
Preservation Section.  Bridge Files.
 
ENDNOTES
 
[[file:1993-loc-0002-long-lake-bridge-haer-08.png|thumb|right|200px|Original Page 8]]
[[file:1993-loc-0002-long-lake-bridge-haer-09.png|thumb|right|200px|Original Page 9]]
[[category:Long Lake Bridge]]

Latest revision as of 17:05, 31 August 2023

SPOKANE RIVER BRIDGE AT LONG LAKE DAM............. HAER No. WA-95

State Route 231 spanning the Spokane River

Reardan vicinity

Lincoln County

Washington

HAER WASH 22-REAR...


WRITTEN HISTORICAL AND DESCRIPTIVE DATA

PHOTOGRAPHS

HISTORIC AMERICAN ENGINEERING RECORD page0image NATIONAL PARK SERVICE
DEPARTMENT OF THE INTERIOR
P.O. BOX 37127
WASHINGTON, D.C. 20013-7127

HISTORIC AMERICAN ENGINEERING RECORD


Fabricator ||Henry Hagman of Cashmere, Washington.
Location Spanning the Spokane River between Lincoln and Stevens

counties on state route 231, beginning at mile point 44.65.

UTM 11/436270/5298530
11/436305/5298560
Quad Long Lake, Wash.
Date of Construction 1949
Engineer Washington Department of Highways
Owner Washington Department of Highways.


Since 1977, the Washington State Department of Transportation, Olympia, Washington

Present Use Vehicular and pedestrian traffic.
Significance The bridge is a late example of an open-spandrel reinforced-concrete ribbed

deck arch. Considère hinges were used at the skewbacks to relieve stresses in the arch during the construction of the bridge. The bridge has been nominated to the National Register of Historic Places.

Historian Wm. Michael Lawrence, August 1993

History of the Bridge

The Spokane River Bridge at Long Lake Dam replaced a timber trestle bridge. It is said to be the longest concrete arch span constructed in the state from 1941 to 1950.[1] The setting for this bridge is a remote one, with the Spokane River running down a gorge which separates two very different regions. To the north, in Stevens County, are the Selkirk Mountains, an area which has made its living by lumbering, by mining zinc, lead, and copper, and by ranching sheep and cattle.[2] Lincoln County, to the south, is mostly a sparsely populated, arid plain with few trees. Irrigation, using water from Little Falls Lake and Long Lake, after the construction of two dams in 1910 made the fertile region into a major wheat-producing area.[3] The highway across the Spokane River is one of the links between these two different regions.

The state highway department prepared a design for a new reinforced-concrete arch bridge in 1948. The engineers completed the design before 15 July 1948, when the drawings received the approval of Ray Dinsmore, the director of highways.[4] The department did not call for bids, however, until the following year. A copy of the announcement appeared in the Pacific Builder and Engineer, the major contracting and engineering journal in the northwest, on 9 February 1949.[5] Bids for this and several other projects were opened on the 4 March. Henry Hagman, of Cashmere, Washington, was the low bidder at $233,698.74. The other bids were submitted by State Construction Co. of Seattle, at $244,366.12, and David Nygren of the same city, at $270,341.80.[6] Hagman and the state signed the contract on 14 March.[7]

Design and Description

The Spokane River bridge at Long Lake dam is a late example the open-spandrel reinforced-concrete ribbed deck arch built in the United States during the early twentieth century. Considère hinges were used during its construction. Its streamlined appearance contrasts with earlier, ornamented concrete arch bridges.

The bridge is a 485’ long reinforced-concrete structure, consisting of a deck supported by an open-spandrel ribbed arch and seven spans supported by bents. Its deck rests on cross beams and longitudinal girders supported by the bents and the spandrel columns. It consists of:

  • one 40’ reinforced-concrete deck girder span
  • one 41’ reinforced-concrete deck girder span
  • one 200’ reinforced-concrete ribbed deck arch span
  • one 41’ reinforced-concrete deck girder span
  • three 40’ reinforced-concrete deck girder spans
  • one 30’ reinforced-concrete deck girder span

The arch is over the river and the bents are on steep slopes on either side on the channel.[8]

The deck is 31’-4" wide with a 24’ wide roadway and a 4’ wide sidewalk. It bears on cross beams at 10’ on center framing into two rows of girders at 9’ to either side of the centerline of the bridge. The deck is an 8"-thick reinforced-concrete slab. These members are monolithic. The beams are 12" x 1’-8" (wide x deep), while the girders are 1’-8" wide and vary in depth from 3’ at the span to 4’-9-5/8" at the bents, the underside of each girder being a parabolic curve.[9]

The bents are, on the average, 3’ x 2’, with the long dimension parallel with the spans. Each has a batter of 1:144. They bear on footings in the embankments.[10] The spandrel columns are similar, but rest on the arch, with the outermost panels at 25’ on center and the middle seven panels at 23’.[11]

The bents closest to the arch and the outermost spandrel columns bear on the arch abutments, adjoin each other, and are separated throughout their heights by a 1" open joint, assuring that the arch span can expand and contract independently of the approaches. The second spandrel column on either side of the crown of the arch is similarly split by a vertical joint, allowing the deck above to contract and expand.[12]

The reinforced-concrete arch rises 44’ from the skewbacks to the crown at the centerline of the rib.[13] The skewback centerlines are 5’-6" from the open joint between the arch and the rest of the bridge.[14] This arch is a parabola with a radius, measured at the intrados, varying from 126--11" at the crown to 145’-7-5/8" at the abutments. The arch also rib varies in its dimensions, from 3’ x 4’ (high x wide) at the crown, to 4’ x 5’-8" (high x wide) at the abutments.[15] The arch and its abutments bear on footings which are at an angle to the horizontal in order to counteract the outward thrust of the arch.

The arc in its completed form is fixed, having no hinges at the skewbacks or crown to permit movement. During its construction, however, it was provided with temporary hinges near its skewbacks. These hinges are a late example of their use in the United States. Two decades before, for example, Conde B. McCullough, the Oregon State Bridge Engineer from 1919 to 1936, used the type of hinge perfected by the French engineer Armand

Considére in the crowns of reinforced-concrete tied arches along the Oregon Coast Highway (U.S. 101) in the early 1930s.[16]

Throughout most of the rib, the bars are located near the extrados and intrados. During construction of the lowermost parts of each ribs, these bars were terminated on either side of the hinge, with a gap between them. Specially bent bars were Placed with their ends inserted in this regular reinforcement. The middles of the bent bars converge at the center of the arch rib and are surrounded by circular hoops. When the concrete was poured at this hinge, notches were left in the rib, above and below the point where the bars converge. After all other parts of the bridge were poured, the workmen would return, eliminate the gap between the regular bars by splicing additional bars to their ends. This was accomplished by means of welding plates. The workmen then filled the notches with concrete.[17] At the narrowest part of the hinge the steel to concrete ratio is higher, making the hinge flexible. During construction of the bridge, such hinges reduced stresses in the ribs due to shrinkage of the concrete during setting and hardening, to elastic compression in the arch due to superimposed loading, and to settlement of the abutments under the thrust of the arch.[18]

Overall, the bridge is rather attenuated in appearance, with its slender bents and spandrel columns. The elliptical arches formed by the underside of the girders echoes the form of the arch and creates a pleasing rhythm. The bridge has no ornament except for moldings at the top of its railings. Its streamlined appearance contrasts with bridges adorned with architectural ornamentation such as the Baker River Bridge in Concrete, Washington (HAER No. WA-105), a much earlier example of the open-spandrel reinforced- concrete ribbed arch, built in 1916.[19] The two bridges represent the early and late years of this type of construction.

Repair and Maintenance

The bridge is in good condition with some minor cracking, efflorescence, and spalling. The deck has been worn down to the aggregate, exposing a few reinforcing bars.[20]

Data limitations

The most helpful sources for this report were the working drawings, the contract, and the final estimate, which survive at the Washington State Department of Transportation archives, and two entries in the Pacific Builder and Engineer. The drawings made it possible to describe and analyze the structure. All of these documents made it possible to establish its dates.

A search of engineering and contractors’ journals failed to discover any articles regarding this bridge. The clipping files at the Washington State Library in Olympia, the Washington State Historical Society at Tacoma, the Museum of History and Industry in Seattle, and the Special Collections Room at the University of Washington in Seattle, and the Seattle Public Library contained newspaper articles regarding many other bridges, but not this one.

Project Information

This project is part of the Historic American Engineering Record (HAER), National Park Service. It is a long-range program to document historically significant engineering and industrial works in the United States. The Washington State Historic Bridges Recording Project was co-sponsored in 1993 by HAER, the Washington State Department of Transportation (WSDOT), and the Washington State Office of Archeology & Historic Preservation. Fieldwork, measured drawings, historical reports, and photographs were prepared under the general direction of Robert J. Kapsch, Ph.D., Chief, HABS/HAER; Eric N. DeLony, Chief and Principal Architect, HAER; and Dean Herrin, Ph.D., HAER Staff Historian.

The recording team consisted of Karl W. Stumpf, Supervisory Architect (University of Illinois at Urbana-Champaign); Robert W. Hadlow, Ph.D., Supervisory Historian (Washington State University); Vivian Chi (University of Maryland); Erin M. Doherty (Miami University), Catherine I. Kudlik (The Catholic University of America), and Wolfgang G. Mayr (U.S./International Council on Monuments and Sites/Technical University of Vienna), Architectural Technicians; Jonathan Clarke (ICOMOS/Ironbridge Institute, England) and Wm. Michael Lawrence (University of Illinois at Urbana-Champaign), Historians; and Jet Lowe (Washington, D.C.), HAER Photographer.

BIBLIOGRAPHY

Bohm, Fred C. and Craig E. Holstine. The People’s History of Stevens County. Colville, WA: Stevens County Historical Society, 1983.

“Construction News Bulletin," Pacific Builder and Engineer 55 (19 February 1949): 16.

"Construction News Bulletin," Pacific Builder and Engineer 55 (12 March 1949): 2.

Hadlow, Robert William. "Conde B. McCullough, 1887-1946: Master Builder of the Pacific Northwest." Ph.D. diss., Washington State University, 1993).

Scott, W.L. and C. W. Spicer. Reinforced Concrete Bridges. London: Crosby Lockwood & Son, 1925.

U.S. Department of the Interior. National Park Service. Historic American Engineering Record. "Alsea Bay Bridge, HAER No. OR-14," drawings, Todd A. Croteau, et al., delineators, 1990, held by Prints and Photographs Division, Library of Congress.

U.S. Department of the Interior. National Park Service. Historic American Engineering Record. "Baker River Bridge, HAER No. WA-105," by Wm. Michael Lawrence, 1993.

U.S. Department of the Interior. National Park Service. "National Register of Historic Places Nomination Form for the Spokane River Bridge at Long Lake Dam, Lincoln and Stevens counties, Washington," 1991.

Walter, Donald E. (ed.) Lincoln County: A Lasting Legacy. Davenport, Washington: Lincoln County Centennial Committee, 1988.

Washington State and Henry Hagman. Bid proposal (2 March 1949) and Contract (8 March 1949) for Spokane River Bridge at Long Lake Dam [No. 231/101]. Copy held by Records Control, Washington State Department of Transportation, Olympia, WA (WSDOT).

Washington. Department of Highways. "Secondary State Highway No. 3-J, Spokane River Bridge at Long Lake" (approved 15 July 1948). 15 sheets of drawings, held by Records Contr1993-loc-0002-long-lake-bridge-haer-00.pngol, WSDOT.

Washington. Department of Highways. Twenty-third Biennial Report of the Director of Highways, 1948-1950.

Washington. State Department of Transportation. Bridge Preservation Section. Bridge Files.

ENDNOTES

  1. 1 Department of the Interior, National Park Service, "National Register of Historic Places Nomination Form for Spokane River Bridge at Long Lake Dam, Lincoln and Stevens counties, Washington," 1991.
  2. 2 Fred C. Bohm and Craig E. Holstine, The People’s History of Stevens County (Colville, WA: Stevens County Historical Society, 1983).
  3. 3 Donald E. Walter, Lincoln County: A Lasting Legacy (Davenport, WA: Lincoln County Centennial Committee, 1988).
  4. 4 Washington Department of Highways, "Secondary State Highway No. 3-J, Spokane River Bridge at Long Lake" (approved 15 July 1948 by the director of highways), 15 sheets of drawings, copies held by Records Control, Washington State Department of Transportation, Olympia, WA [WSDOT].
  5. 5 Office of the Director of Highways, Olympia, Washington, "Notice to Contractors," in "Construction News Bulletin," Pacific Builder and Engineer 55 (19 February 1949): 16. control, WSDOT.
  6. 6 "Construction News Bulletin," Pacific Builder and Engineer 55 (12 March 1949): 2.
  7. 7 State of Washington and Henry Hagman, Contract (8 March 1949). Copy at Records Control, Washington State Department of Transportation, Olympia; the contractor completed the project in May of 1950 and on 1 June 1950 D. A. Kelley, the resident engineer, reported a final cost estimate of $233,175.09 to the Director of Highways. See Washington Department of Highways, Twenty-third Biennial Report of the Director of Highways, 1948-1950, 24.
  8. 8 Washington Department of Highways, "Secondary State Highway No. 3-J, Spokane River Bridge at Long Lake" (approved 15 July 1948 by the director of highways), sheet 1, copies held by Records
  9. 9 Ibid., sheet 4 and 5.
  10. 10 Ibid., 4.
  11. 11 Ibid., 1.
  12. 12 Ibid., 7. The details are in the "Longitudinal Section Thru Half Arch.
  13. 13 Ibid.
  14. 14 Ibid., sheet 1.
  15. 15 Ibid., sheet 7.
  16. 16 Robert William Hadlow, "Conde B. McCullough, 1887-1946: Master Builder of the Pacific Northwest" (Ph.D. diss., Washington State University, 1993), 160-63.
  17. 17 Ibid., "Detail of Considère Hinge" and "Welding Details for Rib Steel at Hinge." For an axonometric illustration of the Considère hinge, see "Alsea Bay Bridge, HAER No. OR-14," sheet 2 of 2, Todd A. Croteau, et al., delineators, in the Historic American Engineering Record, Prints and Photographs Division, Library of Congress.
  18. 18 W. L. Scott and C. W. Spicer, Reinforced Concrete Bridges (London: Crosby Lockwood & Son, 1925), 156-57.
  19. 19 See Department of the Interior, National Park Service, Historic American Engineering Record, "Baker River Bridge, HAER No. WA-105," by Wm. Michael Lawrence, 1993.
  20. 20 "Spokane River Bridge at Long Lake Dam, No. 231/101," Bridge Preservation Section, WSDOT.