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Route 9 Corridor Study Traffic Improvements 6/1992ROUTE 9 CORRIDOR STUDY TRAFFIC IMPROVEMENTS Prepared by the Pioneer Valley Planning Commission June 1992 Prepared in cooperation with the Massachusetts Highway Department and the U.S. Department of Transportation - Federal Highway Administration and Federal Transit Administration. Staff Credits Prepared by James P. Cope, Principal Planner and Jeffrey Pechulis, Senior Transportation Planner, under the direction of Timothy W. Brennan, Executive Director. Design and typsetting by Shaun Hayes, Principal Planner /Cartographer, cover by van Schouwen Associates. PREAMBLE TO TRAFFIC REPORT This final Traffic Report of the Route 9 Corridor Study is a compendium of combined efforts of the Massachusetts Highway Department, Pioneer Valley Planning Commission, Town of Hadley, Town of Amherst, City of Northampton, University of Massachusetts, Five Colleges, Incorporated and other local and regional committees organized to enhance the capacity and safety of this essential highway corridor and its environs. These efforts have been continuous since the 1987 commencement of the study by the Pioneer Valley Planning Commission and are expected to continue until implementation of both short and long range improvements are successfully completed. The final two - volume Route 9 study identifies existing and future land use, as well as traffic conditions associated with the Route 9 corridor. Recommendations regarding land use policies to minimize adverse traffic impacts and conceptual roadway and intersection improvements are presented to address both current and forecasted Route 9 corridor deficiencies. Actions are proposed to be taken to implement the study recommendations by numerous organizations and institutions, including the three participating municipalities, the University of Massachusetts, Five Colleges, Inc., the Pioneer Valley Planning Commission, the Route 9 Corridor Advisory Committee, the Pioneer Valley Transit Authority and the Massachusetts Highway Department, among others. The recommendations outlined in this report, however, do not constitute an absolute commitment to construct specific roadway improvements on the part of the Massachusetts Highway Department. Moreover, the Route 9 highway improvements presented to the Massachusetts Highway Department herein are intended to assist the Department to, first, understand the needs of the . corridor, and then, to advance the short and long term highway improvements which will result in enhanced Route 9 corridor capacity and safety for the 1990's and beyond. In accordance with sound transportation planning and engineering practices, therefore, it is recognized that the Massachusetts Highway Department must reserve the right to modify and /or further refine specific highway improvement measures so as to achieve the most beneficial, cost effective and workable solutions possible for this Route 9 corridor. i Abstract Overview The Route 9 Corridor Segments Intersections Transit Operations Corridor Transportation Deficiencies Segments Intersections Other Locations Transit Recommended Corridor Improvements Short Term Improvements - Highway Intersection Geometry /Signal Timing Modifications at Route 9 and Damon Road 31 Old Bay Road 36 Movement Restrictions at the Route 9 and West Street Intersection 38 TABLE OF CONTENTS Route 9 and East Street Intersection Signal Installation Movement Restriction at the Bread & Entrance to and from Route 9 Install Continuous Right -Turn Lane, (Segment V) Circus Eastbound i 1 3 5 8 23 24 24 25 26 26 28 31 42 47 47 TABLE OP CONTENTS (Continued) Transit /Transportation System Management Improvements 49 Develop Commuting Alternatives /Discourage Single- Occupant Automobile Usage 53 Employer- Sponsored Carpooling and Vanpooling 53 Institute Alternate Work Hours Program 55 Establish One or More Transportation Management Associations (TMA) in Conjunction with Educational Institutions 55 Long Term Improvements - Highway 57 Segment I 57 Segments II, III & IV 60 Segment V 67 LONG TERM IMPROVEMENTS - TRANSIT 69 OTHER LONG TERM IMPROVEMENTS 71 Appendices A. 1991 Average Daily Traffic Counts B. Signal Warrant Analysis C. Massachusetts Highway Department 1990 Route 9 Curb -cut Survey D. Route 9 Corridor Supplemental Report LIST OF FIGURES Figure 1 Study Area 4 Figure 2 Segments & Intersection Locations 7 Figure 3 Condition Diagram, Bridge St. & Damon Rd 10 Figure 4 Condition Diagram, Route 9 & Bay Rd 11 Figure 5 Condition Diagram, West St & Route 9 15 Figure 6 Condition Diagram, Route 9 & Middle St 16 Figure 7 Condition Diagram, Route 9 & East St 17 Figure 8 Condition Diagram, Route 9 & Mtn. Farms Mall 18 Figure 9 Condition Diagram, Route 9 & North /South Maple 19 Figure 10 Condition Diagram, Routes 9 & 116 20 Figure 11 Condition Diagram, Route 9 & Campus Plaza 21 Figure 12 Condition Diagram, Route 9 & University Dr 22 Figure 13 AM Peak Hour Turning Movement Counts 29 Figure 14 PM Peak Hour Turning Movement Counts 30 Figure 15 Recommended Improvement, Bridge St. & Damon Rd 34 Figure 16 Damon Rd. /I -91 Ramp Existing Condition 35 Figure 17 Old Bay Rd. Reopened As A One -way Street 37 Figure 18 Recommended Restrictions, Route 9 & West St 41 Figure 19 Recommended Signal Phasing, Route 9 & East St 44 Figure 20 Recommended Traffic Signal with Turning Bay, Route 9 & East St 45 Figure 21 Existing & Recommended Traffic Signals on Route 9 Corridor 46 Figure 22 Continuous Right -Turn Lane 48 LIST OF FIGURES (Continued) Figure 23 Existing Bus Stop Locations & Shelter Recommendations 52 Figure 24 Calvin Coolidge Bridge Existing Condition 59 Figure 25 Existing Bridge - Four Lanes 59 Figure 26 Calvin Coolidge Bridge Total - Reconstruction 59 Figure 27 Alternative I: Segments II & IV, Widen From Two To Four Lanes 63 Figure 28 Alternative II: Four -lane Diversion Between the Bridge & West St 64 Figure 29 Alternative III: Two -lane Diversion Between the Bridge and West Street 65 Figure 30 Alternative IV: Four -lane Diversion Between the Bridge and B &M Crosssing 66 Figure 31 Service Roads to Commercial Development 68 LIST OF TABLES Table 1 Damon Road Turning Movement Counts 31 Table 2 Existing Signal Timing. 32 Table 3 Recommended Signal Timing 32 Table 4 West Street Turning Movement Counts 38 Table 5 West Street Signal Warrant Analysis 39 Table 6 East Street Turning Movement Counts 42 Table 7 East Street Signal Warrant Analysis 43 Table 8 Types of Accidents 1984 -1987 47 Table 9 Bus Shelter Inventory 51 Table 10 Parking Permits 70 OVERVIEW Route 9 has been an important travel corridor in the Pioneer Valley since at least the second quarter of the 18th Century when some of the residents of the Town of Hadley moved to the "East Precinct ", which is now the Town of Amherst. Growth and development occurred at a relatively steady and modest pace for the next 200 years. During the 1960s, however, things began to change rapidly as the University of Massachusetts began a decade of rapid growth. Enrollment increased from 6,495 to over 25,000 students. In addition, Hampshire College was founded in the early 1970s, and Amherst College increased its enrollment as it began to admit women students. Other economic activity grew during this same period, such as the establishment of two large shopping malls in Hadley and the regeneration of downtown Northampton as a vital shopping and office center. This growth caused many changes, not the least of which were the institution of an extensive fare -free bus system in the area as well as a dramatic jump in the amount of traffic on Route 9 between Amherst and Northampton. Today, Route 9 connects the Pioneer Valley to Boston and Worcester to the east and Pittsfield and Albany to the west. Its role as a long -haul route, however, has been overtaken in large part by the Massachusetts Turnpike, and its principal role is now as the principal east -west arterial highway in the northern part of the Pioneer Valley region. One of the main reasons for this Corridor Planning Study is the incapacity of Route 9 to handle the volumes of traffic that regularly try to traverse it between Northampton and Amherst. The roadway's ability to accommodate traffic is the lowest at the westerly end of the study area, especially between Damon Road in Northampton and West Street in Hadley, yet the traffic volumes in the corridor are the highest in this section. The system breaks down under the strain, and the result is severe congestion and stop- and -go conditions during many hours of the day. The problem undoubtedly will get worse unless actions are taken both to increase the capacity of the road system and to manage travel demand. Doing one without the other is akin to boxing with one arm tied behind one's back: the effort will at best be frustrating. A companion report on land use measures that are designed to help manage traffic growth along the corridor has also been prepared. Several assumptions have been made which were necessary for this effort to be completed. First, financial resources are limited. No new equivalent of the Interstate Highway Program is in the offing. Second, environmental and other reasons militate against the development of any major new by -pass of Route 9. Third, a multi- faceted approach is considered to be more likely to succeed than is a unilateral approach. Components of the solution will involve multiple modes of transportation, numerous funding sources, new technologies, and travel demand management through land use controls and incentives. This report summarizes the findings of Phase I of the Route 9 Corridor Study, completed in January, 1989, as well as additional work and analysis during Phase II. It includes basic information on land use and transportation, identifies deficiencies, and presents recommended short -term and long- term improvements for the Route 9 Corridor. 2 Land along the Route 9 Corridor in Amherst, Hadley, and Northampton was, until recently, mostly farm land. Due to geographic factors, including the location of several colleges and the University of Massachusetts in the area, large numbers of working people and students use the corridor for commuting. Traffic on the highway has been on the increase for many years. With rapid commercial development on former agricultural land, coupled with the increase in travel and traffic congestion in the Route 9 Corridor, it became necessary to conduct a corridor study in order to analyze the corridor and make recommendations addressing deficiencies that were found. The Route 9 Study Corridor runs in a generally southwest to northeast direction for a distance of approximately five miles, from Damon Road in Northampton, across the Connecticut River, and through the Town of Hadley to University Drive in Amherst. Figure 1 shows the study area. THE ROUTE 9 CORRIDOR Rapid commercial growth along Route 9 between Northampton and Amherst along with several other factors, such as the development of much new housing at low densities in the area, a larger student population, smaller households, a general increase in car ownership, and increasing car ownership by teenagers, have resulted in frequent congestion and high numbers of accidents in the corridor. An origin/destination survey conducted in the area indicates that a majority of the people begin and end their trips in Amherst, Northampton and Hadley. The highway varies from one lane to two lanes in each direction with a paved width ranging from 22 feet to 48 feet. The average daily traffic ranges from 23,200 vehicles per day in the vicinity of Mill Valley Road intersection on Route 9 to over 33,000 vehicles per day at the Calvin Coolidge Bridge. There are three unsignalized and eight signalized intersections along the corridor that were analyzed in the study. Speed limits vary from 35 to 45 mph. 3 SEGMENTS For analysis purposes, the Route 9 Corridor was originally divided into five segments as shown in Figure 2. However, some changes have been made in the definition of where the segments start and end. These changes were made to provide a better fit with the physical characteristics of the corridor, including the geometry of the highway, the number of lanes within the roadway, and intersections. Segment I This segment starts about 150 feet west of the Damon Road intersection at the I -91 on -ramp and ends to the east of the Calvin Coolidge bridge. At Damon Road, Route 9 is marked for three lanes in each direction. The Coolidge bridge is fifty feet wide including eight feet used for a raised pedestrian sidewalk along north side of the bridge. The bridge is striped for one lane in the westbound direction and two lanes in the eastbound direction. The alignment of this segment is relatively straight. The bridge does not have shoulders, but they are present on the rest of the segment and range in width from three to six feet. The road width varies from 24 feet east of the bridge to 50 feet at the bridge. Segment II The second segment extends from the east end of the bridge to the eastern leg of West Street in Hadley. Its approximate length is one mile. The alignment of this segment is generally straight, but there is a curve just west of the segment and it consists of one lane in the westbound direction and a taper zone where eastbound traffic coming off the bridge is merging from two lanes to one lane. The road width is 44 feet at the western end of the section, and shoulders are narrow, ranging from two to three feet. East of Bay Road the road narrows to about 41 feet. An "S" curve is located at the eastern end of segment II in the vacinity of the West Street intersections. Pavement markings include centerlines and edge lines. Along this segment land uses are mixed residential and commercial, with numerous curb cuts provided. Segment III The third segment extends from the eastern leg of West Street, past Middle Street (Rte. 47), to a point 300 feet 5 beyond the Middle Street and intersection. This segment is characterized by two lanes in each direction, and is undivided with a road width of about 48 feet. Shoulders are virtually non - existent. Pavement markings include a double yellow centerline, lane markings, and edge markings. East of Middle Street the roadway narrows to one lane in each direction. Like the previous segment, the land uses are mixed, but with a higher density. Service and institutional type uses are predominant. Segment IV The fourth segment is the longest and extends 1.8 miles from a point approximately halfway between Middle and East Streets to the signals at Mountain Farms Mall. This section of the roadway has only one horizontal curve in the vicinity of East Street. It then continues easterly in a straight alignment. This segment consists of one travel lane in each direction with narrow shoulders. Pavement markings include centerlines and edge lines. Land uses are extensively mixed along this segment. They include a limited number of commercial uses, though this use is growing, some residential uses, and a large proportion of open space or agricultural land. Curb cuts are spaced relatively far apart. This segment is the least developed of any of the segments. Segment V The fifth segment that was studied extends from the Mountain Farms Mall entrance east to a point about 100 feet past the University Drive and Route 9 intersection in Amherst. It is approximately 1.5 miles in length. This segment is divided, with two lanes in each direction. Pavement markings include lane markings and edge lines. Shoulders are eight to ten feet wide. The roadway alignment is straight and flat. This segment has the most intensive commercial development, with two shopping malls, one of which contains two major department stores (J C Penney and Steigers) and a large discount store (K- Mart). There are also a number of smaller shopping centers and numerous independent commercial and retail establishments. Curb cuts are numerous, although the presence of a center median barrier minimizes cross - movements. 6 INTERSECTIONS The following are the eleven major intersections along the corridor. (See Figures 3 - 12). Three are unsignalized and eight are signalized. Some of the signals at the inter- sections are pre- timed, or semi - actuated. A pre -timed signal operates on the basis of fixed cycle lengths and phases. It is frequently used where there are predictable and stable traffic volumes. Semi - actuated signals provide a continuous green indication on the major street except when vehicles approach the intersection on the minor street. Vehicle detectors are placed on the minor street to trigger a change in phase for the minor street traffic movements. UNSIGNALIZED INTERSECTIONS West Street and Route 9 West Street is one of the oldest streets in Hadley. Its right -of -way is so wide there is a park -like common over 100 feet wide located in the center of it. Two parallel roadways flank the common, one to the east and one to the west. Therefore, the intersection of Route 9 and West Street is actually two intersections separated by approximately 150 feet. Traffic control both north and south of Route 9 is provided by "STOP" signs on both western and eastern segments of West Street. Both of these segments are two -way. Lane width at the western segment of West Street is 24 feet for the north approach and 24 feet for the south approach of the intersection. At the eastern segment of West Street, the north approach is 24 feet wide and the south approach is 28 feet wide. Stop lines are marked on all minor approaches. Route 9 in this area is marked for two lanes in each direction, narrowing to one lane west of the intersection. The road width is 44 feet. East Street and Route 9 This four -way intersection is controlled by "STOP" signs on the East Street approaches. One 15 -foot lane in each direction is provided on East Street. Route 9 is also marked for one lane in each direction. Pavement width on Route 9 west of the intersection is 42 feet and to the east is 39 feet. These approaches are sufficiently wide, however, for through vehicles to maneuver around turning vehicles, provided the latter are far enough over to the left or right. A crosswalk is provided on the north side of the intersection. 8 Mill Valley Road and Route 9 This'intersection is formed by Mill Valley Road joining Route 9 at an acute angle, and it functions almost like a "T" intersection. The minor street, Mill Valley Road, is controlled by a "STOP" sign and it is very narrow. It is marked for two lanes and is without shoulders. Due to the geometry of the intersection, motorists on Mill Valley Road find it difficult to make left turns onto Route 9. Also the traffic volume on Route 9 is far greater than the traffic volumes on this minor street, making it hazardous for motorists making left turns. Route 9 in this area is marked for one lane in each direction. 10 12 12 R3-7 12 12 12 10 BRIDGE ST. (RTE. 9 ) scale j 0 5 10 20 40 feet 22 R6 -1 R6 -1 11 18 Condition Diagram Bridge St. & Damon Rd. Route 9 Corridor Study R1 -1 R5 -1 ,R10 -12 R4 -7 R6 -1 R6 -1 ENTER '1 KEEP RIGHT R4 -7 ' 12 12 12 LEFT LANE MUST TURN LEFT R3 -7 LEFT' TURN YIELD ON GREEN R10 -12 PIONEER VALLEY PLANNING COMMISSION Figure 3 19 19 RESTAURANT SPEED LIMIT 3.0 r BAY ROAD scale r1_I I I 0 5 10 20 40 feet 'RIGHT LANE MUST 'TURN RIGHT r 21' 10 21' only 10' Condition Diagram Route 9 & Bay Road Route 9-Corridor-Study-_____- ____ 4 ; 10 ' 0 m co WEST 9 HOUSE PIONEER VALLEY PLANNING COMMISSION Figure 4 SIGNALIZED INTERSECTIONS Damon Road and Route 9 This intersection, located at the western end of the study area in Northampton, is a four -way facility and it is controlled by a two -phase semi - actuated control. The southern leg of the intersection is an off -ramp from Interstate 91 with a combined left- through lane and an exclusive right turn lane. The right turn movement from the off -ramp from I -91 is controlled by a "STOP" sign. The two lanes (not marked) for through and left turning traffic are controlled by the signal. There is a significant amount of friction between the through traffic heading north on Damon Road and the southbound Damon Road traffic seeking to turn left to go over the bridge, as well as between left - turning traffic from the off -ramp and right- turning Damon Road traffic seeking to switch into the left turn lane to go south on I -91. The Damon Road approach is 22 feet wide. Although it is not marked for two lanes, it can accommodate two lanes. The Route 9 westbound approach has an exclusive right turn lane, which handles the heavy right turning volumes onto Damon Road, and two through lanes. Route 9's eastbound approach has three 12 foot lanes including an exclusive left turn lane with an advance green signal. Pavement markings are provided on all approaches. Bay Road and Route 9 This intersection is a "T" intersection that is controlled by a semi- actuated two -phase traffic signal. Bay Road is divided by a traffic island and it is marked for one 19 foot wide lane in each direction. This section of the road can allow two lanes of traffic, but it is not striped for two. Right turns on red are permitted. On Route 9 two lanes are provided on each approach with the eastbound right turn lane and the westbound left turn lane signed for exclusive use. Both the westbound and eastbound approaches are marked for two lanes and each lane is ten feet wide. Middle Street (Rte. 47) and Route 9 This location is a four -way intersection controlled by a two - phase signal with pedestrian actuation. An advance green phase for eastbound traffic on Route 9 allows left- turning traffic to clear out.of the intersection. Right turns on red are prohibited on all approaches. Middle Street is marked for one lane on the northbound and southbound approaches. The lanes are 20 feet wide with an eight foot wide shoulder west of the southbound approach lane. Route 9 at the intersection has two 12 foot lanes in each direction with a double yellow line and lane markings, and no approach shoulders. 12 Mountain Farms Mall Entrance and Route 9 This intersection serves as an entrance to the Mountain Farms Mall and to the Montgomery Rose Company. Traffic control is provided by semi - actuated signals. Both minor approaches and the exclusive left -turn lanes on Route 9 are actuated. The northern leg of the intersection is 34 feet wide and the southern leg is 51 feet wide. West of the intersection, Route 9 narrows to one lane, and it is 23 feet wide. Route 9 eastbound has three lanes and is 32 feet wide. East of the intersection, Route 9 is marked - for two lanes and is 22 feet wide. There are no shoulders at the intersection. Maple Street and Route 9 Route 9 in each direction is provided with exclusive right and left turn lanes in addition to two through lanes. The road width in each direction is 34 feet. On Route 9 in both directions the right turn lanes are separated from through lanes by a triangular island and are not controlled by signals. Traffic control is provided by a three -phase signal with both left turns and the minor street approaches under actuated control. Maple Street is marked for one lane in direction. The northern leg of the intersection is marked for an 18 foot lane in each direction and the southern leg has a 12, foot lanes each way. At this location, roadway markings are provided in all approaches. Route -116 and Route 9 This intersection is a "T" intersection controlled by a three -phase semi - actuated signal. Route 116 is divided and has an 18 foot approach lane. The exit ramp for traffic heading west from Route 116 is controlled by a "YIELD" sign. Route 9 eastbound has a 10 foot shoulder, two through lanes, and an exclusive left turn lane. Westbound Route 9 has the same geometr though the left turn lane provides for "U "- turns. Presently, this location is under construction due to the development of the Westgate Center located on Route 9 across from the Route 116 approach. The development will improve the intersection to include siganlized service for the northbound Westgate driveway approach. Campus Plaza Road and Route 9 This intersection is controlled by a three - phase, semi - actuated signal. Campus Plaza Road is divided with sufficient width for two lanes in each direction. It is 27 feet wide, though lanes are not clearly marked. Route 9 is divided at this location. An exclusive left turn lane is 13 provided on the eastbound approach of Route 9, and an exclusive right turn lane for the westbound traffic is provided. University Drive and Route 9 This intersection is located on the east end of the study area. It is a four -way intersection controlled by a three - phase semi - actuated signal. The eastbound approach of Route 9 has two through lanes 'and an exclusive left lane. Each lane is 12 feet wide. On the southbound approach, University Drive has three lanes, which include two 12 foot through lanes and a separate exclusive right turn lane. The exclusive right turn lane is controlled by a "YIELD" sign and is 22 feet wide. Confusion is created, however, by the placement of a signal head on a post on the triangular island near the right turn lane. The Route 9 westbound approach has only two lanes, and the pavement width is 28 feet. The northbound approach of the intersection (University Drive South) has two lanes. It is 26 feet wide. University Drive is divided at the intersection by a 12 foot wide island. Crosswalks are marked on both of the minor approaches, as well as the east side of the intersection, crossing Route 9. Pedestrian actuated signals are provided. 14 .SPED LIMIT 35 WEST ST. 0 15 30 feet RETAIL 11' 13 TOWN COMMON 12' 12' scale 60 0 m a 2' 2' Condition Diagram West St. & Route 9 ---- Route 9 Corridor Study-- - L RESTAURANT RETAIL 12' 14' 9 28' PIONEER VALLEY PLANNING COMMISSION Figure 5 i BANK PEDESTRIAN SIGNAL 5 12' 12 12 10' 12' SCHOOL feet 17 0 5 10 20 4 scale o' 0 / 2 d 19' Condition Diagram Route 9 & Middle St. (Rte. 47) Route 9 Corridor Study ALL / APPROACHES RUSSELL ST. ( RTE.. 9) PED XING NO TURN ON RED LIBRARY 10' 12 12' 12 12' i Figure 6 J' TOWN HALL PIONEER VALLEY PLANNING COMMISSION RESIDENTIAL Condition Diagram Route 9 & East St. Route 9 Corridor Study scale 0 5 10 20 feet RESIDENTIAL PIONEER VALLEY PLANNING COMMISSION Figure 7 40 25 26 MTN. FARMS MALL DRIVEWAY �f KEEP RIGHT "BURGER KING" scale 0 5 10 20 feet 40 0 c —I m to 12 12' No U TURN 22' 1,7 KEEP RIGHT 12' 1 Condition Diagram Route 9 & Mtn. Farms Mall Route 9 Corridor Study 23 20' 34 PIONEER VALLEY PLANNING COMMISSION Figure 8 22 �r KEEP RIGHT LEF UNE MUST TURN LEFT,i Condition Diagram North & South Maple Sts. & Rte. 9 Route 9 .- Corridor Study - LEFT - TURN ON ARROW O'NL Y NO TURN ON RED 41 4' ENTER HERE FOR U TURN Figure 9 r PIONEER VALLEY PLANNING COMMISSION U TURN FOR PASSENGER CARS ON LY I� KEEP RIGHT 10 KEEP RIGHT 26' 12 12 2 11 2 1 24 12 KEEP RIGHT 8 LEFT ON GREEN ARROW ONLY Condition Diagram Routes 9 & 116 Route 9 Corridor Study ROUTE 116 12' 12' 10' scale 1 0 10 20 40 80 feet 6 18' 24' PIONEER VALLEY PLANNING COMMISSION Figure 10 CAMPUS PLAZA DR. 7' 27' SCALE 1"20' 12' / 12 / 12' 12' LEFT ON ARROW ONLY 12' KEEP RIGHT i TURN /1/ Condition Diagram Campus Plaza Dr. & Route 9 Route 9 Corridor Study 12' LEFT ON ARROW ONLY 10' 2 LEFT LAIE MUST TURN LCT 1 12' 10' No U TURN 12' 0 0 —I m c0 PIONEER VALLEY PLANNING COMMISSION Figure 11 KEEP RIGHT UNIVERSITY DRIVE SOUTH I► KEEP RIGHT Condition Diagram Route 9 & University Dr. Route 9 Corridor Study NO U TURN scale YIELD PEDESTRIAN SIGNALS 0 5 15 '30 60 feet PIONEER VALLEY PLANNING COMMISSION Figure 12 TRANSIT OPERATIONS The Route 9 Corridor is served by Pioneer Valley Transit Authority (PVTA) Route 703 which runs from Amherst to Northampton. Bus service extends to Williamsburg on some runs. Although there are numerous stops along Route 703, only three stops are indicated on the bus schedule, Amherst College, Smith College, and Haigis Mall. It is one of the most heavily utilized routes in the PVTA system. Bus service during week days starts at 6:30 AM and stops at 2:00 AM with 10 minute headways during the peak periods (7:20 -9:40 AM and 2:20 -5:40 PM) and with 20 minute headways in the off -peak times. Previously, on -time problems had been experienced with Route 703 due to the bus schedule not realistically reflecting the actual run time of peak hour trips. However, revisions of the bus schedule were made, and improvements in schedule adherence have been realized. There are eight bus stops within the study area served by Route 703. In Technical Memorandum I of the Route 9 Corridor. Study, six of the eight bus stops along the corridor were identified as without signage. These stops were recommended for signage, and they have been recently signed by the Pioneer Valley Transit Authority. Route 703 currently operates weekend service, generally with one hour headways, on Saturday and Sunday. Buses fare -free during the school year, which yields a highly efficient operation with minimal time spent at transit stops. Passengers can load at both front and rear doors. Student fees are assessed by the area colleges to provide the equivalent revenue that would otherwise be collected as fares. During the summer months a normal fare system is in operation on this route. 2.3. The following operational and safety deficiencies have been identified along Route 9. SEGMENT DEFICIENCIES CORRIDOR TRANSPORTATION DEFICIENCIES o Damon Road to Eastern End of Bridge (Segment I) and from the Eastern End of the Bridge to West Street (Segment II): Recent analysis of these segments shows that they operate at level of service F during the afternoon peak hour and that the accident rate was approximately equal to the critical rate which is based on a state averages of vehicle exposure and type of area. In addition, travel speeds over these segments were consistently lower relative to the other segments along Route 9. The Calvin Coolidge bridge has one lane in the westbound direction and two lanes in the eastbound direction, which are inadequate to handle the traffic flow. Segment II of Route 9, (from the east end of the bridge to West Street) is marked for one lane in each direction. Traffic flow on this section of the road is heavily congested during the peak periods of the day, and frequently causes traffic to back up and come to a stop throughout this segment. o From Hadley Center (Between Middle Street and East Street) to Mountain Farms Mall Entrance (Segment IV): This segment of Route 9 has one lane in each direction. Analysis of the segment shows that it operates a level of service E during the peak hour. Although congestion at this segment is not as bad as segments I and II, this section of the road is barely able to handle peak hour traffic volumes. o From Mountain Farms Mall Entrance to University Drive (Segment V): This segment of Route 9 has an accident rate greater than that expected for a similar facility. This segment operates at level of service C. The high accident rate is directly attributable to the surrounding land uses and numerous curb cuts. At the time that Technical Memorandum I was published, the portion of the segment between Mountain Farms Mall and University Drive was found to lack proper signal coordination for the progressive flow of traffic. The effects of this were made evident in excessive travel time and delays as well as in the intersection analysis. The traffic signals at this segment have been recently coordinated and synchronized by the Massachusetts Highway Department and traffic flow has improved. 24 INTERSECTIONS - DEFICIENCIES - Intersection of I -91 On -Ramp with Route 9: Westbound traffic wanting to turn left onto I -91 South often exceeds the capacity of the storage lane during peak hours. In addition, traffic that has turned right from Damon Road has but a short distance to weave over to the left on Route 9 westbound and get into position for this left turn movement. - Intersection of Damon Road and Route 9: For both the morning and afternoon peaks, this location was found to operate at level of service E or F. For vehicles that are travelling southbound on Damon Road and turning left onto Route 9, delays are being experienced due to the high volumes of traffic making left turns as well as opposing traffic coming from the I -91 off -ramp, and, as a result, the intersection operates poorly. In addition, analysis of accident data showed that while the accident rate was not higher than expected, there was a high proportion of rear -end collisions on the eastbound Route 9 approach. - Intersection of Bay Road and Route 9: This location was found to operate at level of service F during the morning peak period. This is a result of heavy through traffic plus right turning traffic both being forced to travel in a single lane until a right -turn lane appears shortly before the intersection. - Intersection of West Street and Route 9: The western segment of this intersection was found to operate at a level of service F during the late afternoon. This is a result of the "bottle neck" situation to the west. This results in an excessive delay for traffic on both the major and minor streets. Intersection of East Street and Route 9: This location operates at level of service E during the morning peak and at a level of service F during late afternoon. However, this condition is experienced only by the minor street (East Street) traffic volumes wanting to go through or turn onto Route 9. This is due to the lack of gaps in the traffic flow and can be remedied by a traffic signal. Bread & Circus Entrance: This location has a raised island designed for only right- turn -in and right -turn- out vehicle movements. Route 9 at this location provides for one lane in each direction. The location was found to be hazardous to motorists because of a lack of signage. Vehicles carry out illegal left- turn -in and left- turn -out movements at this location. 25 - Intersection of Maple Street and Route 9: This location operates at level of service D during the afternoon peak period. This is a borderline condition for an road such as the Route 9 corridor and its operation will likely degenerate into traffic congestion as additional corridor development takes place with its resulting traffic growth. Intersection of Route 116 and Route 9: As with the Maple Street intersection, this location operates at a level of service D during the afternoon peak period. The underway improvements to this intersection associated with the Westgate Center development is expected to maintain the present service levels as additional growth and development occur. Intersection of University Drive and Route 9: This location was found to operate at a level of service E during the afternoon peak period. This was in part due to the lack of proper coordination of signals. However, the traffic signals at all of the intersections from University Drive to Mountain Farms Mall have recently been coordinated and these intersections now operate at a level of service C. OTHER LOCATIONS A number of less serious problems were observed to exist at other locations along the Route 9 study corridor during the extensive field data collection work. Many of these would require only minor changes to correct, such as pavement markings, signage, or signal retiming /coordination. TRANSIT - DEFICIENCIES - Weekend Transit Capacity: The majority of Saturday ridership on Route 703, which runs along the entire length of the Route 9 study corridor, tends to be during the afternoon hours, from 1:00 PM - 5:00 PM, and most trips during this period operate over capacity. The reason for this is too few buses (or too small buses) being made available to carry the riders. The operator of this route has resorted to using "trippers ", which are extra buses, to accommodate the heavy demand. Sunday service for Route 703 experiences an occasional overload during the mid - afternoon period. This overload is not as severe as the frequent overloading seen on Saturdays. - Weekend Schedule Adherence: Staff observations have noted that on -time performance is not satisfactory for 26 Saturday operations on Route 703. Upon entering the study area at Damon Road, the bus is frequently full and falling behind schedule. While loading and unloading at the malls, a stop which draws many passengers, on -time performance continues to deteriorate. Another reason for passenger build -up is attributed to late buses. There is only one bus per hour on Saturday, and no relief is seen for those gathering for an already late bus. As a result of this, extra time is spent loading and unloading and on -time performance continually suffers. The ill effects are eventually halted when a shift change occurs, and a new bus begins a run on time and the late bus returns to the garage. - Bus shelters: Currently there is only one bus stop locations on the Route 9 Corridor that have shelters. This bus shelter is located in front of the Hampshire Mall. 27 RECOMMENDED CORRIDOR IMPROVEMENTS The Phase I Study of the Route 9 corridor recommended several improvements along the entire corridor that would reduce the existing traffic congestion and improve capacity and safety. This report contributes additional proposals for improving traffic conditions. Analyses of these improvements were made based on the data in Figures 13 and 14. The improvements have been divided into the following: - Short term improvements: Traffic improvements or solutions that can be implemented within a short period (less than five years). - Long term improvements: Traffic improvement measures that can implemented in five years or more. 28 UNmIE RSIT R. 6 77 N. M ST. 4 • 126 66 103 �y 133 87 58 38 �y + n 58 34 34 PI) N O N u'1N EAST STREET I I L u 9 — 9S —1 0 MIDDLE ST. II 6Z 94 16 — — 309 O� • ■ lT T f 4., 4, M -0 OFF oo. H O N 0 W J 0 0 U az LLJ LLJ T z Q J 5 C a_ i f C_1 n=r0 O t=i CD ts`,- 1 9£Z—A 1T 9 ___,,, o= - u Y +0 La zz oz -+ 9 -v 6 p'L CD N a J W L 9l-4 6Z � m Z6 - 0£ Er- Li 1T1 133US 3100PN ON 0 i1L oz te- lZ lTr u m + umm 133aLS 1SV3 SHORT TERM HIGHWAY IMPROVEMENTS TRANSPORTATION SYSTEM MANAGEMENT INTERSECTION GEOMETRY /SIGNAL TIMING MODIFICATIONS AT ROUTE 9 AND DAMON ROAD The existing traffic signal at Damon Road is a three phase semi - actuated signal with a cycle length of 75 seconds. The analysis of the existing traffic signal operation and the intersection geometry was taken into account to determine the current operational level of service. The analysis shows that the intersection is operating at a level of service F. Table 1 shows the existing signal timing. By modifying the signal timing, widening and restriping Damon Road in the southbound direction for exclusive left /right turn lanes, the performance of the intersection would improve. Approach Table 1 Route 9 (Bridge Street) and Damon Road Intersection Turning Movement Counts, PM Peak Hour Route 9 W/B - 962 Route 9 E/B 72 658 Damon Road 417 Approach Left Through Right Total Total entering volumes 31 481 209 1,443 730 629 2,799 Movement Movement Table 2 Existing Signal Timing Route 9 and Damon Road Semi - Actuated Rte. 9 left turn only Rte. 9 through & left Damon Rd. & Ramp, all movements Green Time (sec.) 7 35 20 Cycle length: 74 sec. Table 3 Green Time (sec.) Cycle length: 95 sec. 32 Yellow + Red Clearance (sec.) 4 4 4 The analysis was carried out by using the existing turning movement count (see Table 2), which was entered into the Highway Capacity Software for signalized intersections. The signal should be pre -timed with a total cycle length of 95 seconds with three phases. The best level of service that can be achieved is C. The estimated delay at the intersection is 23.7 seconds. Table 3 documents the timing and movements during each phase. Recommended Signal Timing - Pretimed, Route 9 and Damon Road Rte. 9 all movements 35 7 Damon Rd. lefts 28 6 Damon Rd. /Ramp through 15 4 & right Yellow + red clearance (sec.) By restriping Damon Road southbound lanes to two 11 -foot lanes (see Figure 15) for exclusive right and left turn movements, and also adjusting the signal timing, the following conditions can be achieved: - By providing an auxiliary lane for right turns, left turning traffic would not impede traffic making right turns. As a result, there would be a progressive movement of traffic. - Also, the addition of a right turn lane would provide added safety and reduction of accidents. It should be noted that occasionally the left turn volume of the westbound traffic heading towards I -91 south exceeds the left turn storage lane capacity, thereby backing traffic up to the Damon Road /I -91 off ramp on Route 9. This causes disruption of traffic movements when the traffic signal on Route 9 and Damon Road changes to green for vehicles on Damon Road /Off Ramp (See Figure 16). There are two alternative solutions to correct this problem: The first alternative would be to provide a traffic signal system at the on -ramp intersection that would be green constantly for the vehicles heading west on Route 9. During off -peak times eastbound vehicles would also have a constant green, and vehicles wanting to carry out a left turn movement heading towards I -91 south could do so within a safe gap. A detector would be installed in the left turn storage lane `so that when vehicle volume exceeds storage capacity during peak times, the signal would be activated. Traffic heading eastbound would then receive a red phase and those making left turns would receive a green phase. This would clear the traffic congestion in this area. The second alternative would be adopted only if this situation continues and tends to get worse. This solution will involve the coordination of the existing and proposed signals so that vehicles could move progressively when the signals change phases on at Route 9 and Damon Road /Off Ramp. Traffic would thus be cleared from both intersections. 33 12 12 R3 -7 12 j 12 - 12 10 BRIDGE ST. (RTE. 9 ) 5/ R6 -1 scale 0 5 10 20 40 feet 11 ♦1 18 DO NOT ENTER R5 -1 R6 -1 12 Recommended Improvement Bridge St. & Damon Rd. Route 9 Corridor Study KEEP RIGHT R4 -7 LEFT LANE MUST TURN LEFT R3 -7. LEFT TURN YIELD ON GREEN • R10 -12 12 12 PIONEER VALLEY PLANNING COMMISSION Figure 15 L O E 0 Cr) cd cd 1 O N T cc 1 fV T 1 N 1 0 OPEN OLD BAY ROAD ONE -WAY FOR EASTBOUND TRAFFIC TO PROVIDE DIRECT ACCESS TO BAY ROAD Old Bay Road, currently a dead -end street, is 22 feet wide and approximately one quarter of a mile in length consisting of two lanes. (See Figure 17). By reopening Old Bay Road and designating it as a one -way street eastbound, direct access to Bay Road would be provided. Traffic diverted to Old Bay Road would eliminate or reduce right turns at the Bay Road /Route 9 intersection. This concept was evaluated by using the Highway Capacity analysis software which indicated that the portion of Route 9 between the Bay Road Route 9 intersection and the eastern section of the Coolidge bridge would improve from the level of service F to E. Reopening and designating Old Bay Road one -way eastbound would reduce approximately 2,000 vehicles daily at the Bay Road intersection. The reopening of Old Bay Road would require resurfacing, with a one half inch binder course and a one half inch over -lay of finish black top. The resurfacing would require an addition of a 3 foot shoulder on each side of the road. In addition, a "speed- change lane" would be required on Route 9 west of the Old Bay Road /Route 9 intersection. According to the Massachusetts Highway Department, the speed- change lane would be 12 feet wide and 300 feet long. The speed limit on this section of Route 9 is 35 M.P.H. This lane would function as a deceleration lane for traffic turning onto Old Bay Road, and would help to reduce traffic congestion in this critical area of Route 9. It is estimated that the cost of this project would be about $75,000. Some additional costs due to land acquisition, excavation, and removal of utility poles could increase the estimate somewhat. 36 one way sign Reopen N Rte. 9 Old Bay Road (one way traffic eastbound) existing traffic signal 2 Lanes Cleft only and through) Old Bay Road: Reopened as a one way street (eastbound) Bay Rd. Prepared by: Pioneer Valley Planning Commission, 1989 - Figure 17 TRAFFIC MOVEMENT RESTRICTIONS AT WEST STREET INTERSECTIONS WITH ROUTE 9 West Street West Street is actually two intersections separated by approximately 150 feet. The geometry of the intersection is dictated by the presence of a Town Common which divides the street (western and eastern segments). Both segments are two - way. However, the western segment of West Street's inter- section with Route 9 was chosen for analysis due to the fact that it is the busier of the two segments. Western Segment The intersection of West Street and Route 9 experiences peak travel conditions during the PM commuter period. Table 4 shows the existing late afternoon peak hour traffic volumes. The vehicle volumes along the West Street approaches are comprised of right turn movements exclusively. The Route 9 vehicle volumes are significantly high for the through movements with a minimal number of vehicles turning onto West Street. Approach Table 4 Route 9 and West Street Intersection (Turning Movement Counts, PM Peak Hour) Approach Left Through Right Total Route 9 Westbound 32 1,087 13 1,132 Route 9 Eastbound 48 877 7 932 West St. Northbound 0 0 0 0 West St. Southbound 0 1 133 134 Total Entering Volumes = 2,198 38 Intersection data for the western segment of West Street was applied to the signal warrant criteria outlined in the Manual on Uniform Traffic Control Devices (MUTCD) developed by the U.S. Department of Transportation and the Federal Highway Administration. The western segment of West Street /Route 9 intersection satisfied five of the eleven traffic signal warrants set by MUTCD. The five signal warrants satisfied are on the basis of accident experience, network system improvement, peak hour vehicle volumes and peak hour delay. The warrant analysis is summarized in Table 5. See appendix for details of this warrant. Table 5 Traffic Signal Warrant Analysis Summary Route 9 and West Street Signal Warrant Satisfied 1. Minimum Vehicular Volume No 2. Interruption of Continuous Traffic No 3. Minimum Pedestrian Volume No 4. School Crossing Not Applicable 5. Progressive Movement No 6. Accident Experience Yes 7. Systems Warrant Yes 8. Combination of Warrants No 9. Four Hour Volumes Yes 10. Peak Hour Delay Yes 11. Peak Hour Volume Yes Number Satisfied 5 Number Not Satisfied 5 Number Not Applicable 1 Total 11 The satisfaction of a signal warrant is not in itself justification for a signal. Indication of improvement to the overall safety and operation of the intersection is a necessity. Review of the turning movement information in Table 4 identifies that all West Street traffic is making a right turn onto Route 9 westbound. Installation of a traffic signal will delay the Route 9 through traffic while accommodating the less critical movement on West Street. Installation of signals at this location is not recommended at this time, however, this location should be monitored regularly to identify changes in the intersection safety and operation. 39 Eastern Segment of West Street The eastern segment of the West Street intersection with Route 9 experiences minimal vehicle traffic. In order to reduce several conflicting turning movements, it is recommended that turning movement restrictions be imposed at the intersection of the eastern segment of West Street and Route 9. Figure 18 shows allowed traffic movements in a scheme that would prevent movements which would interfere with the functioning of the intersection. No left turns would be allowed from the easterly segment at this intersection, and left turn restrictions would also apply to traffic on Route 9 at this location, with the exception of emergency vehicles. Only through and right turn movements would be allowed on all approaches. Service to Route 9 for all vehicles presently traveling on the northern leg of West Street will be maintained via an existing 22 -foot wide cross -road in the common that connects the western and eastern segments of West Street north of Route 9. Vehicles could use the cross -road to make left turns onto Route 9 via the western segment of West Street. The southern leg of West Street does not have a cross -road, thereby, restricting travel to Route 9 westbound from the eastern segment. In order to maintain service, a proposed cross road would have to be provided. These changes to Route 9 and two West Street intersections are examples of ways in which travel conditions can be improved. Rather than attempting to develop definitive traffic control proposals at this time, it is recommended that further engineering studies be conducted in collaboration with the Town of Hadley which consider defined circulation changes, geometric changes and other control options. This process will best suit the needs of the local residents and the operations of the corridor. 40 4 West St. (western segment) Rte. 9 Y existing cross road Y i 700' o • "4:t IMO West St. (eastern segment) proposed cross road (approximately 700 feet from Rte. 9 intersection) No left turns to be allowed at the intersection of Rte. 9 and the eastern segment of West St. Pioneer Valley Planning Commission,, 1992 Recommended Turning Restrictions - M. GO - -- 0 stop sign proposed road Figure 18 TRAFFIC SIGNAL INSTALLATION AT THE INTERSECTION OF EAST STREET WITH ROUTE 9 The intersection of East Street and Route 9 is unsignalized. Traffic is controlled by stop signs at the East Street approaches. Table 6 shows afternoon peak hour turning movement counts which were taken in March 1987. The turning movement count was entered into the Highway Capacity Software (HCS) in order to analyze the intersection performance and level of service. It is based on the Highway Capacity Manual, cited earlier. The unsignalized intersection operates at a level of service E during peak hour conditions. Approach Table 6 Route 9 and East Street Intersection Turning Movement Counts, PM Peak Hour Approach Left Through Right Total Route 9 Westbound 33 889 48 970 Route 9 Eastbound 73 751 18 842 East St. Northbound 5 16 29 50 East St. Southbound 21 20 114 155 Total entering volumes = 2,017 Intersection data for the East Street and Route 9 intersection was applied to the signal warrant criteria outlined in the MUTCD. Six of the eleven signal warrants were satisfied based on this data. The six signal warrants satisfied are associated with continuous traffic flow, accident experience, .network system improvement, peak hour vehicle volumes and peak hour delay. The warrant analysis is summarized in Table 7. See appendix for details of this warrant. 42 Table 7 Traffic Signal Warrant Analysis Summary Route 9 and East Street Signal Warrant Satisfied 1. Minimum Vehicular Volume No 2. Interruption of Continuous Traffic Yes 3. Minimum Pedestrian Volume No 4. School Crossing Not Applicable 5. Progressive Movement No 6. Accident Experience Yes 7. Systems Warrant Yes 8. Combination of Warrants No 9. Four Hour Volumes Yes 10. Peak Hour Delay Yes 11. Peak Hour Volume Yes Number Satisfied 6 Number Not Satisfied 4 Number Not Applicable 1 Total 11 By installing a traffic signal at Route 9 and East Street the following can be achieved: - Fewer serious accidents would occur at the intersection. - The signal would provide better traffic movement on the minor street (East Street) in both directions. East Street traffic would not have to wait for a safe gap in the opposing traffic stream to make movements. - The Route 9 vehicles accessing the Hadley Post Office would be provided breaks in the constant Route 9 traffic flow. Turning delays for these movements will be reduced. Figure 20 shows Route 9 and East Street intersection with a turning bay. The HCS program was applied to the East Street intersection to analyze conditions under signal control. The result of the analysis indicates that the intersection would operate at a Level of Service "B" with an estimated delay of 7.4 seconds. Figure 19 presents the proposed signal phasing analyzed for this location. 43 Figure 19 Route 9 and East Street Intersection Signal Phasing Diagram Green time Y & R time 50 sec. 6 sec. Cycle Length Cost of Traffic Signal Installation 44 Green time Y & R time 80 sec. 20 sec. 4 sec. Sources at the Massachusetts Department of Public Works indicate that the cost of construction and installation of the traffic signals at the intersection of East Street and Route 9 is estimated to be about $60,000. Assuming that contracts and permits had been issued, it would take about six months to complete the required work. Engineering and design tasks will require additional funds and time prior to the construction and installation phases. 2 1 i.‘ f I xi v I Figure 19 Route 9 and East Street Intersection Signal Phasing Diagram Green time Y & R time 50 sec. 6 sec. Cycle Length Cost of Traffic Signal Installation 44 Green time Y & R time 80 sec. 20 sec. 4 sec. Sources at the Massachusetts Department of Public Works indicate that the cost of construction and installation of the traffic signals at the intersection of East Street and Route 9 is estimated to be about $60,000. Assuming that contracts and permits had been issued, it would take about six months to complete the required work. Engineering and design tasks will require additional funds and time prior to the construction and installation phases. GAS STATION RESIDENTIAL Recommended Traffic Signal w/ Turning Bays Route 9 & East St. Route 9 Corridor—Study POST OFFICE scale r 0510 20 feet RESIDENTIAL PIONEER VALLEY PLANNING COMMISSION Figure 20 MOVEMENT RESTRICTIONS AT THE BREAD & CIRCUS ENTRANCE TO AND FROM ROUTE 9 The intersection of the Bread & Circus entrance with Route 9 is restricted to only right -in and right -out vehicle movements. This intersection is not properly signed and motorists tend not to observe or obey the traffic movement restriction at this location. To correct this problem, and to prevent motorists from carrying out illegal movements, adequate and visible signage should be provided the Bread & Circus Entrance. In addition to the installation of signs, local police enforcement of left -turn movement restrictions is strongly recommended. INSTALL CONTINUOUS RIGHT -TURN LANE, EASTBOUND (SEGMENT V) A review of accident data covering the period 1984 to 1987 showed that a relatively high number of rear -end type collisions occurred along the eastbound portion of Route 9 between Maple Street and University Drive (Segment V). Table 8 summarizes the types of accidents which occurred in this Route 9 segment. These accidents were found to have taken place near driveways to several commercial businesses. These accidents occur because of a large differential in speed between vehicles slowing to make right turns and through traffic behind them. Table 8 Types of Accidents 1984 -1987 Type Number Rear -End 24 Sideswipe 4 Cross - Movement 3 Fixed Object 2 Head -On 1 Total 34 One way to reduce the frequency of this type of accident is to establish a continuous right -turn lane where there is a high frequency of driveways joining the highway, such as at the vicinity of McDonald's and the Ski shop or along the stretch between Soda and Pet Food City and Dominoes Pizza. Such a lane would allow right- turning traffic to decelerate without risking being hit by vehicles behind them. It would also allow vehicles entering the highway to accelerate before joining the stream of traffic. (See Figure 22). 47 TRANSIT /TRANSPORTATION SYSTEM MANAGEMENT IMPROVEMENTS IMPROVE TRANSIT PASSENGER AMENITIES Bus Shelters Bus shelters at bus stops are very important, particularly during inclement weather. Currently, out of the eight bus stops in the corridor, only the bus stop location at the Hampshire Mall is provided with a bus shelter. Bus shelters should be provided at the rest of the stops. However, due to the possibility that funds might not be available, the following six bus stop locations are considered most important for bus shelter installation due to their strategic locations: (See Figure 23) - Mountain Farms Mall - Hadley Village Barn - Mobil Car Wash - Former Carbur's location - Hadley Town Hall - Crown Point Apartments There are other factors involved in the installation of bus shelters. The Pioneer Valley Transit Authority indicates that the following have to be considered before a bus shelter can be installed: The presence of activities near the bus stop, such as retail shops or other generators of activity, and whether the bus stop is used by many riders. - Whether a bus stop is in close proximity to housing for the elderly or apartment complexes. - Safety concerns, such as whether waiting passengers are going to be protected from fast - moving traffic. - Whether shelters are to be located on private property, which may require more negotiation than public locations In addition, Route 9 is a state highway. Therefore, the Massachusetts Highway Department requires a permit before a bus shelter can be installed. The Pioneer Valley Transit Authority indicates that they consider requests from citizens for bus stop shelter installations. 49 Bus Shelter Size The bus shelter size at the Hampshire Mall is twelve feet by four feet with a height of eight feet. It is 40 feet from the entrance to the J C Penney Department Store. The number of passengers waiting at the shelter at Hampshire Mall often exceeds the bus shelter capacity during peak hours, particularly on major shopping days such as Saturdays and during the Christmas holiday season. Consequently, bus passengers resort to using the J C Penney entrance as an additional waiting area, and crowding at the entry sometimes occurs. The bus stop shelter at the Hampshire Mall should be expanded to accommodate more passengers waiting to board the bus. The Pioneer Valley Transit Authority should explore entering into an agreement with the Mall owner to expand the bus shelter. If possible, the shelter should be built as an extension of the J C Penney building with a heated waiting area. During the early part of weekdays, westbound buses stop near the Kentucky Fried Chicken establishment near Mountain Farms Mall instead of the Hampshire Mall. (This is done mainly to save time and keep the buses on schedule.) A substantial shelter should be erected at this location as well. 50 Table 9 Route 9 Corridor Bus Shelter Inventory Bus Stop Bus Stop Direction Sign Shelter Hadley Village Barn EB /WB Yes No Mobil Car Wash EB /WB Yes No Carbur's EB /WB Yes No Town Hall EB /WB Yes No Hadley P.O. EB /WB Yes Antique Shop EB /WB Yes No Hampshire Mall EB /WB Yes Yes Mountain Farms Mall EB /WB No No Crown Point Apartments EB /WB Yes * EB /WB - Denotes Eastbound and Westbound directions 51 c N W 53 The following are possible ways to increase efficiency and reduce vehicle trips: DEVELOP COMMUTING ALTERNATIVES /DISCOURAGE SINGLE- OCCUPANT AUTOMOBILE USAGE Analysis of the origin and destination survey conducted by the Pioneer Valley Planning Commission in June, 1987 indicates that most people travelling work on Route 9 commute between Northampton and Amherst. The results of the survey show that, out of 2,026 people surveyed, 74% ride alone in their vehicles, 19% ride with another person, 3% ride with two other persons, and 2% ride with three other persons. Also, the origin- destination survey showed that Northampton, Hadley and Amherst were the top ranked communities in terms of where the majority of commuters began and ended their trips. The primary reason for this is the large student and staff populations in the area that are destined for the University and the other colleges in Amherst, Northampton, and South Hadley. EMPLOYER- SPONSORED CARPOOLING AND VANPOOLING A carpooling program involves matching people according to their origins and destination and time of travel. Participants either take turns driving or contribute funds to the driver. Vanpool programs are usually organized by companies or institutions. The van is typically provided by the employer and given or leased to a driver. The program is coordinated by the company. The company assigns the driving of the van to a principal driver who also manages his or her vanpool. As an incentive, the driver is allowed to keep the van for personal use on weekends. If a ridesharing program is effectively promoted and coordinated with area businesses, colleges and towns, it could result in some reduction in daily traffic on the Route 9 Corridor. In order to coordinate effectively a carpool/ vanpool program, the following steps should be taken: Encourage people to switch to ridesharing modes. Computer matching techniques and a classified "ad" style publication similar to Connecticut's "Commuter Register" should be tested in the area. Increase parking fees. If the area colleges increase parking fees, users would be influenced to find an alternative means of transportation. - Establish ridesharing staging lots. These staging lots would serve as parking, loading and unloading areas for commuters. Express Bus Service Further exploration of the feasibility of commuter express bus service operations from outlying communities such as Easthampton and Williamsburg to the University and Amherst College is recommended. By establishing an express bus service within the Route 9 Corridor in conjunction with park and ride lots, the traffic congestion along this corridor could be reduced. Express bus services are geared to eliminate local stops and reduce travel time. By this action, bus services could become more competitive with the automobile. Consequently, they could attract more riders. Park and Ride Lots The primary purpose of establishing a park and ride lot is that it serves as a meeting place for commuters in a residential area who wish to take a bus or other transit vehicle to commute to a high density area, like an area of employment concentration. It can also serve those who carpool or vanpool. They are usually located outside the central business areas in lower density areas. Implementation of a park and ride lot program can be achieved within a short time by utilizing existing parking facilities that are under- utilized during the work week, such as those associated with churches. Park and ride lots would also support ridesharing by carpool and vanpool users. A park and ride lot should be sited in a good location that is easily accessible, and also it should be large enough in size to provide enough parking to meet the expected demand. The effectiveness of establishing a park and ride lot in reducing traffic congestion depends on the following conditions: - The distance from the lots to travel destination (which should be a minimum of about 15 miles). The longer the distance the more likely the program would prove to be effective. - Trips should be exclusively trips to work (or class), and trips should be scheduled at least every 15 minutes over a two -hour period inbound in the morning and a two -hour period outbound in the afternoon. 54 Benefits and Costs of Ridesharing The following are benefits involved in a rideshare program: - There are savings involved by riding together since the Cost is shared by individuals sharing the ride. - The cost to individual riders in a carpool or vanpool program varies. On the average, it costs a rider about $15 to $25 per month to commute to and from work for a typical round trip of 25 miles, compared to $50 per month if driving alone. - Because people are teaming up and riding together, there are fewer vehicles and less congestion and pollution in the area. Also, the roadways would last longer, and travel times for everyone using the corridor would be reduced. INSTITUTE ALTERNATE WORK HOURS PROGRAM Employers with more than fifteen employees in their workforce should consider establishing variable work hours for their The program would allow employees to come to work within a; specified span of time and leave after having put in the required number of hours. Due to employees arriving and leaving their work place at different times, the program would ease congestion during the morning and afternoon peak hours of traffic. The results of employers implementing variable work hours could improve employee morale, reduce sick leave and increase productivity. ESTABLISH ONE OR MORE TRANSPORTATION MANAGEMENT ASSOCIATIONS (TMA) IN CONJUNCTION WITH EDUCATIONAL INSTITUTIONS In order to respond effectively to Route 9's traffic congestion, the Towns of Hadley and Amherst, the City of Northampton, the University of Massachusetts, and the colleges in the area should consider forming a Transportation Management Association (TMA). Members of a TMA typically come from various backgrounds, neighboring communities, and employers in the area and can effectively address, make recommendations on, and respond to commonly -felt transportation problems. TMAs are usually private non - profit groups formed to facilitate private sector involvement in addressing transportation issues in communities such as those in the study area. 55 TMAs typically play the following key roles in communities: - Policy Leadership and Advocacy. TMAs serve as the private sector's voice on highway and transit planning, priorities and funding. - Mitigation of Transportation Impacts. Through education and technical assistance, TMAs facilitate transportation demand management programs of member organizations. - Planning. TMAs work with public officials on transportation planning, implementation and evaluation. The Towns of Hadley and Amherst, the University and colleges, along with major businesses in the area should, through the efforts of PVPC, draw up a cooperative memorandum of agreement to form a TMA. Traffic Management Plan An immediate action which is cost effective that would have a major long -term impact in the relief of traffic congestion on Route 9 is the application of a traffic management plan by the TMA. Such plans generally include the following: Ridesharing coordination program - Vanpool commuting program - Transportation coordinator at major employers - Ridesharing staging 'lots/ Priority for high occupancy vehicle parking - Alternate work hours program Transportation impact fees - Timing coordination of major functions. - Policy recommendations regarding automobile ownership and use by students. 56 LONG TERM IMPROVEMENTS - HIGHWAY Out of a large universe of potential solutions to the Route 9 traffic problem, only a few are discussed here. These were chosen because they represent fundamentally different approaches. They attempt to reduce the adverse effects of the present situation where traffic volumes greatly exceed the capacity of the road system, as well as take into account the projections of additional traffic to be generated from new development along the corridor and in areas tributary to it. Demand reduction efforts will supplement the proposals made in this section. They are covered in the Land Use volume of the study. As noted previously, the entire length of Route 9 that is studied in this report is not uniform in its configuration or in the extent of its deficiencies. The corridor has segments that have two lanes, three lanes, and four lanes. Shoulders are broad and paved in some sections, whereas other areas have no shoulders at all. The focus of the long -range recommendations made here is on those segments of the corridor that are deficient now or are expected to become so within the next ten years. Segment I The Calvin Coolidge Bridge acts as a serious bottleneck to traffic at the present time because it provides only one lane for westbound vehicular traffic. There are three basic choices to resolving this problem: 1. Create four lanes on the existing bridge. According to plans of the original construction of the bridge, there is a width of about 50 feet between the stone monuments at each end of the bridge. This would allow four 12 -foot lanes, plus a few inches between the fog lines and the curb on each side. There is'no easy way to provide sidewalks short of cantilevering off one or both sides, and these would have to wrap around the monuments in some fashion. Bicyclists will need to be directed to the former B & M Railroad bridge that is part of the Five College Bikeway, now under construction. This concept should, therefore, be considered in concert with the Bikeway in that it would be dependent on it to provide safe movement for the significant numbers of cyclists, and to a lesser extent pedestrians, who would use it. The alignment of lanes at the western end of the bridge could be somewhat difficult in that the alignment of the bridge itself doesn't "aim" directly at the I -91 57 underpass. With four lanes, those that are westbound could not start to curve until the end of the stone wall guardrails. (In contrast, the single existing westbound lane begins its curve before the end of the bridge.) The result would be a rather abrupt curve to the left as.motorists are coming off the bridge, and safety problems might ensue. If these issues can be . successfully addressed in the engineering feasibility study now underway, this option may prove to be very cost - effective and it would preserve a local landmark in its familiar form. (See Figure 24) 2. Add width to the existing bridge. A more ambitious concept would be to add width, perhaps equivalent to two lanes (24 feet), to the north or south side of the Calvin Coolidge Bridge. Adding lanes in this manner would require new support structures extending to the same bearing material as for the existing bridge, as if an entirely new structure were being constructed. The advantage would be a savings in material in that the new structure would be only 24 feet wide, rather than over 70 feet. Placing the addition on the north side would be preferable from a historic preservation standpoint, as no view of that side is generally seen. Its feasibility from the standpoint of alignment, however, will need to be determined. (See Figure 25) 3. Replace the bridge. A new four -lane structure could be fully designed to accommodate vehicular, and pedestrian traffic. Four 12 -foot travel lanes, two 8 -foot shoulders, and two 5 -foot sidewalks would result in a paved width of 74 feet. Perhaps it would be wise to anticipate future expansion of the structure to accommodate two more lanes, but this will be a function of the economics of the project. Other issues may arise, such as the relationship of Route 9 and Interstate 91, and whether a northbound on -ramp should be included in the design solution. The alternative of building a new bridge will certainly be expensive, but it would have a long lifespan, and the annual amortization costs may be acceptable. (See Figure 26.) 58 Figure 24 Calvin Coolidge Bridge Segment 1 Existing Condition Figure 25 Existing Bridge - Four Lanes Figure 26 Total Reconstruction 48' 5" — 74' 48' — 8' sidewalk 16' 5" lane 12' lane 12' lane 12' lane 12' lane 12' lane 12' lane 5' sidewalk 8' shoulder/bike lane 12' lane 12' lane 12' lane 12' lane 8' shoulder/bike lane 5' sidewalk Segments II, III and IV The bottleneck created on the bridge becomes worse in Segment II. This section of Route 9 is located between the bridge and West Street in Hadley and it operates at a level of service F. Only two lanes, with minimal shoulders, are provided, and traffic is often backed up in both directions for several hours per day. Of all areas studied in this project, traffic volumes were found to be highest in this segment. Additional lane capacity is clearly needed. Analysis of the proposal to add two more lanes, one in each direction, indicates that traffic flow would be greatly improved with less delay, and that the level of service would change from F to D. Segment III, from West Street to the American Legion Hall, seems generally capable of handling the amount of traffic that passes through it, although the center of the Town of Hadley has become dominated by vehicles. This produces visual impacts as well as difficulties for school- children and other pedestrians who wish to cross the road. The lack of shoulders is a deficiency in this segment. Four ways were examined in seeking the least adverse means for accomplishing improvements to these situations, particularly between the bridge and West Street (Segment II): 1. Widen the existing roadway. The recommended improvement to Segment II is to add two lanes to the existing roadway. The width of the right -of -way between Aqua Vitae Road and West Street is only 50 feet, whereas a minimum of 74 feet is recommended. Thus, in order to widen the road to four lanes, and provide for shoulders lanes and sidewalks on both sides, additional land will be required. Taking 12 feet from each side would result in the loss of most, if not all, of the front yards of the parcels located along the north side of the road. The impacts on the use of many of these properties might be sufficiently severe to require the acquisition of them in their entirety. Another alternative, which would result in far fewer takings, would be to acquire, to the extent possible, the additional needed land from properties located along the south side of Route 9. A substantial portion of this land is undeveloped, and only a few buildings are located close to the road. Some problems, such as the multitude of driveways that enter onto Route 9, particularly on the north side but increasingly on the south, will not be solved by simply widening this stretch, nor will the hazardous "S" curve near West Street be made much safer. Nevertheless, it is likely that the level of service would show significant improvement. 60 A major risk, however, is that vehicle trips will continue to grow as vacant and underdeveloped land parcels along the route are developed. There would consequently be an increase in the number of curb cuts, which would cause decay in the increased capacity created by the added lanes. General growth of the area will also contribute additional traffic, thereby further congesting the improved facility. No special bikeway provisions are proposed under this alternative; construction of the Five - College Bikeway is expected to accommodate all bike traffic. (See Figure 27). 2. Develop a four -lane diversion between the Calvin Coolidge Bridge and West Street. This concept would involve the use of the old Boston & Maine Railroad right -of -way for a new four -lane highway designated as a divided boulevard with a median strip between signalized intersections. It is proposed that access .. to this stretch of road be restricted to prevent drive -ways from entering directly onto it. The pavement of the existing Route 9 would remain substantially as it presently is, except that its "ends" (near the east end of the bridge and near West. Street) would no longer connect directly to Route 9 east and west. Instead, access to this section would be via Bay Road (extended north to intersect with the new road) and via West Street. Two houses and one business would need to be moved to new sites, and three to four acres of land would need to be acquired if this proposal were adopted. Provisions for accommodating the Five College Bikeway are included, and a grass strip would separate the roadway from the bikeway. (See Figure 28.) 3. Develop a two -lane diversion for westbound traffic along the old B & M right -of -way, and set up the existing section of Route 9 between the bridge and West Street to carry eastbound traffic. This proposal would use the same section of the old railroad right -of -way as the one described above, but only two lanes would be constructed. At the West Street Common, westbound traffic would continue straight ahead, rather than having to make the "S" curve around Carmelina's Restaurant. It then would gradually curve to the left to pass over the old B & M rail route. These lanes would rejoin their eastbound counterparts just east of the bridge where the former B & M right -of -way abuts the state highway. The eastbound lanes would use the existing pavement of Route 9, which would receive some 61 improvements, such as a shoulder along the south side, sidewalks, and curbs. The "S" curve at West Street would continue to be somewhat of a problem for eastbound traffic, as would the numerous existing driveway entrances. In addition, motorists would need to be "trained" to use the new configuration in order to minimize wrong -way traffic, particularly as it exits from properties abutting the roadway. Perhaps driveway entrances could be designed to be separated from exits, as was done at the Bread & Circus driveway, to minimize drivers' errors. Two houses and a business would have to be moved, as in the four -lane concept described above, but less land would need to be acquired, probably on the order of two acres. Similar provisions for the Five College Bikeway would be made under this proposal as for Alternative 2, above. (See Figure 29). 4. Construct a four -lane divided roadway between the bridge and old crossing of the B & M tracks over Route 9. This alternative would divert through traffic onto the old railroad right -of -way, causing a drastic reduction in traffic in the center of Hadley. The Five College Bikeway could still be accommodated, paralleling the new road but separated from it by a landscaped buffer. Access onto the new road should be limited to a few points, including Spruce Hill Road, East Street, Middle Street, and a northerly extension of Bay Road. No driveway access directly onto the new road should be permitted. Existing Route 9 could be realigned to connect with Mill Valley Road. (See Figure 30.) The first alternative, described above, is recommended. Simply put, it will solve the traffic problem in this segment. It should be borne in mind that no "solution" will be free of any adverse effect. 62 - 21 m e m 43 0 The difficulty with the segment of Route 9, which lies to the east of Segment II and extends to the main entrance of Mountain Farms Mall, is simply that the traffic volumes exceed the capacity of the road. It operates at a level of service E. A straightforward solution would be to widen the roadway to four lanes. Land is generally undeveloped along this stretch, and the few buildings that do exist are, for the most part, set well back. A major concern, however, would be control of future access onto the improved roadway and the generation of new trips. Otherwise, the present problem of traffic congestion will recur a few years hence. Analysis shows that by adding extra lanes in both directions, traffic flow would improve and the level of service would rise from E to C in this segment. It is recommended that Route 9 in this segment be widened to four lanes, divided if possible with a median. Paved shoulders should be provided along both sides, but sidewalks would seem to be unnecessary east of Mill Valley Road. Segment V One type of long -term improvement is recommended for the portion of Route 9 between the Mountain Farms Mall entrance and University Drive. This is the establishment of service roads to extend either in front of or behind areas of future commercial development that otherwise will have no alternative but to obtain access directly off of Route 9. (See Figure 31.) No further recommendations are made for this segment because major improvements made a few years ago appear to be adequate for the foreseeable future, assuming effective actions are taken to control future development. 67 1n„ ' k \r'''' S \,\„ \ .t��} lw \\f%‘,,,t ? 1 \ 1R��1ts;;,1�\1kk: 1\ u1 LONG TERM IMPROVEMENTS - TRANSIT With respect to the potential of mass transit to ameliorate the degree of traffic congestion on Route 9, trends in the use of public transportation in the Pioneer Valley are not encouraging. Transit ridership has been declining while auto ownership has risen over the past several years, and auto ownership among young drivers in particular has gone up dramatically. This fact is reflected in the number of parking permits that have been issued over the past several years at the University of Massachusetts. (See Table 10.) Nevertheless, transit can play an important role in affecting congestion as well as increasing the mobility of the region's population. The following long -term measures to increase the use of public transit in the Route 9 Corridor should be seriously considered: 1. Support of the recommendations of Transit 1990s, a project sponsored jointly by the Pioneer Valley Transit Authority and the Pioneer Valley Planning Commission. These recommendations cover a basic restructuring of public transit in the region, the provision of transportation services to elderly and disabled residents, new transit technologies, and involvement of the private sector in supporting transit services. 2. Support for continued funding of transit services by all levels of government as well as private sources. The resources that have been available to provide high quality transit service in the region for the past 15 years are now threatened, and the future of the service in increasingly in doubt. At the federal level, the Gramm- Rudman - Hollings law requires that the federal budget meet ever -more stringent targets in an effort to reduce and eventually eliminate the federal budget deficit. This is impacting resources for public transit by forcing the Federal Transit Administration to cut back on allocations of capital and operating funds for local transit agencies. In addition, the President is seeking to eliminate all operating subsidies, which currently provide 22.5% of the PVTA's operating budget, about $3,284,788 million annually. At the state level, there is much concern about the Commonwealth's ability to pay its traditional share (about 28.7 %) of the transit budget. Finally, local communities are feeling the effects of "Proposition 2 1/2" and are having to cut back their commitments to public transportation. New approaches to supplement traditional funding sources may be necessary. 69 3. Investigation of the feasibility of rail transit to parallel Route 9. New rail transit technology may make the reinstitution of rail passenger service possible between Amherst and Northampton, and perhaps extending beyond to Springfield, Hartford, and points south. 4. Support for a campaign to promote the use of transit as a means for improving air quality and reducing impacts on the environment. Transit generally produces far less pollution per passenger mile than any other mode of transportation except walking, bicycling, and hang gliding. Table 10 Parking Permits Issued by the University of Massachusetts at Amherst Year Date A Permits Issued 79 -80 February 10,009 80 -81 April 9,501 81 -82 April 9,939 82 -83 April 10,114 83 -84 April 10,659 84 -85 April 11,665 85 -86 April 13,251 86 -87 April 15,419 87 -88 April 16,366 88 -89 April 16,173 70 OTHER LONG TERM IMPROVEMENTS In addition to the improvements described in the preceding sections, there are some further actions that could aid in reducing the congestion and inconvenience that are characteristic of the Route 9 Corridor. Many of these are presented in the Land Use element of the corridor study, which is a companion volume to this report. However, some additional potential transportation actions can be taken to improve capacity, decrease congestion, and increase safety in the Route 9 Corridor, including: 1. Complete the Five College Bikeway with extensions at each end to assure safe integration of bicycle traffic onto local streets. 2. Establish a communications center to monitor the use of Route 9. Transit vehicles are already equipped with radios, and bus drivers, along with drivers of other vehicles with citizens band, short wave, and cellular phone equipment, could act as "eyes and ears" of the system. They would be encouraged to report in to the center any incidents, such as traffic accidents, emergencies, or traffic tie -ups, in order that the general public could be informed about traffic conditions by tuning to a special radio channel. 71