Contents
4.2 HKLR Viaduct (from HKSAR Boundary to Airport Island)
4.3 HKLR Tunnel cum At-grade Road (from Airport Island to HKBCF)
4.6 HKBCF Drainage, Sewerage and Utilities
4.8 Automated People Mover (APM) between HKBCF & Hong Kong International Airport (HKIA)
Figures
Figure 4.1
1st Phase and Full Phase of HKBCF
Figure 4.2
Main Works Elements of HKLR
Figure
4.3
Main Works Elements of HKBCF
Figure
4.4
Typical Arrangements for Pile and Pilecap
Construction
Figure
4.5
Types of Seawall and Reclamation
Figure 4.6
Sequence A of HKBCF Reclamation
Figure 4.7
Sequence B of HKBCF Reclamation
Figure 4.9
Overall Layout of Buildings within the HKBCF
Figure
4.10 Proposed
Automated People Mover (APM)
Figure
4.11 Envisaged
Construction Methods for the APM (Sheet 1 of 2)
Figure
4.12 Envisaged
Construction Methods for the APM (Sheet 2 of 2)
Figure 4.13
Tentative Programme for HKBCF
Figure 4.14
Tentative Programme for HKLR
4 CONSTRUCTION DESCRIPTIONS
4.1.1 As explained in Section 1, the HKLR and the HKBCF are closely inter-related. Hence the construction descriptions of both projects are presented in each’s EIA Report.
4.1.2 The HZMB is targeted to be commissioned by 2015. To meet this target:
(a) Construction of the HKLR will start in 2011, for completion in 2015, with a construction period of 4 years; (At this stage, there is still some flexibility on the exact timing within 2011 for starting the construction of HKLR. However, it is patently desirable to start construction earlier, say in Early 2011, so as to alleviate the acuteness of criticality of construction works.)
(b) Construction of the HKBCF will start in the 3rd quarter of 2010, for first phase completion by End 2015, and second (final) phase completion by End 2016. [The construction of HKBCF will involve reclamation, including lengthy surcharge-periods, followed by land-works including buildings and infrastructures etc. It is anticipated that the overall construction period for HKBCF will be at least 6 years. Even if construction (reclamation work) can start as early as 2010 3rd quarter, overall completion of HKBCF cannot be achieved by 2015. The reclamation and the landworks for HKBCF will therefore need to be completed in phases, such that at least a part ie. the first-phase of HKBCF (the extent of which and the facilities within which are adequate to handle the initial stage of the commissioned HZMB) will be completed by End 2015.]
4.1.3 The attached Figure 4.1 shows the phasing extent of HKBCF, as well as the interim layout for the first phase and the overall layout for the second phase (ie. the final phase).
4.1.4 In terms of construction activities, main Works elements for HKLR and HKBCF will broadly include:
(a) For HKLR:
• Approx. 9.4 km viaduct (ie. elevated bridgework, including substructures/ foundations and superstructures) from HKSAR boundary to Scenic Hill on the Airport Island, which is mostly over waters and which constitutes a major proportion of the Works of HKLR;
• Approx. 1.1 km tunnel
through Scenic Hill and underpassing the
• Reclamation adjacent
to the eastern side of the
(b) For HKBCF:
• Reclamation Works, including mainly dredging, consolidation-measures, seawalls, reclamation-filling; (The consolidation-measures are to accelerate consolidation of those marine sediments that are not dredged. These measures will mainly include laying of geotextile & sandblanket onto the seabed, together with installation of band-drains and surcharging.)
• Land Works on the reclamation for serving the HKBCF, including mainly the Passenger Clearance Building and other buildings for BCF functions, various facilities for processing of coaches/cars/good vehicles, other infrastructures such as roadwork & services/utilities, associated works including landscaping;
• Works on the
4.1.5 Key construction features related to HKLR and HKBCF as outlined above are shown on Figures 4.2 and 4.3. These are described further in the following paragraphs.
4.2
HKLR Viaduct (from HKSAR Boundary to
4.2.1 Substructures
4.2.1.1 The substructures of the HKLR Viaduct will take the form of reinforced concrete (r.c.) columns & pilecaps founded on r.c. bored-piles. As stated above, the majority of the substructures will need to be constructed in waters.
4.2.1.2 Figure 4.4 shows a typical arrangement for construction of the pilecaps and piles; including water-quality protection measures notably the use of casings etc. to contain any pollutants arisen from these construction works.
4.2.1.3
The aforesaid water
quality protection measures were in fact adopted during construction of the
marine bridge for Shenzhen Western Corridor SWC (now renamed as
4.2.1.4 Pursuant to the above, the number of substructures being constructed concurrently will be assumed to be limited. The water quality modelling will take the assumed leakage rate and the assumed number of concurrent substructures into account. Details in this regard will be described further in Section 9 on Water Quality.
4.2.2 Superstructures
4.2.2.1 It is envisaged that the superstructures of the HKLR Viaduct, for accommodating the dual-3 lane (plus a hardshoulder on each bound) carriageway, will be constructed by one of the following methods:
(a) Precast segmental method, with the bridge deck constructed as precast segments (each a few metres long) which are lifted into position and then stitched & prestressed together –– This method was adopted extensively for numerous bridgework projects in Hong Kong in recent years (e.g. SWC, Deep Bay Link, Route 8);
(b) Precast spans method, with each span (about 100 m or even longer) precast as a mega element and then lifted into position by vessels of mega lifting capacity –– This method was adopted in some of the mega bridgework projects worldwide (e.g. the Dong Hai Da Qiao 東海大橋 project in Mainland China);
(c) In-situ
balanced-cantilever method, with the bridge deck constructed as in-situ
segments by a travelling formwork (each segment was concreted in-situ and then prestressed onto the preceding segment) –– This method was
adopted in some of the projects in
4.2.2.2 The foregoing methods do not differ significantly in terms of environmental impacts. The selection of method is, rather, driven by consideration on engineering constraints and the individual contractors’ available equipment/resources in-hand. For instance, contractors with good ability in arranging vessels of mega lifting capacity may opt for the precast spans method for the section of HKLR from HKSAR boundary to San Shek Wan (SSW) headland, but the restrictive conditions in the Airport Channel do not favour such a method.
4.2.2.3 It should be noted that although the precast segmental method does not require mega lifting equipment as that for the precast spans method, the length of spans that the precast segmental method can sustain is usually limited to about 80 m (due to limitation on the capacity of the launching girder for such a method). To avoid stretching to the limit, it is assumed that the length of spans for precast segmental method should be limited to 75 m. This was also the spans-length adopted for the typical spans of the SWC approach viaduct.
4.2.2.4 For the section of HKLR Viaduct from HKSAR boundary to SSW headland, the water quality modelling will assume a spans-length less than 75 m. (Note: Even if typical spans are 75 m, the overall average span will be less than 75 m, as spans adjacent to expansion joints will be shorter for structural reason.) The Contractor will of course be allowed to adopt the precast spans method with spans well above 75 m, but that will only be more favourable in terms of water quality.
4.2.2.5 The HKLR Viaduct does have a number of spans that must be significantly longer than 75 m mainly for navigation reason. These will be constructed either by the precast spans method (where the Contractor has got mega vessels available and where conditions allow the use of such vessels), or by the in-situ balanced-cantilever method (such as those long spans in the Airport Channel which may be too restrictive for precast spans method anyway).
4.2.2.6 The span-lengths assumed in the water quality modelling will be set as the lower-bound for span-lengths in the detailed design of those portions of the HKLR Viaduct in waters.
4.3
HKLR Tunnel cum At-grade Road (from
4.3.1 Tunnel
4.3.1.1 The tunnel through Scenic Hill will be constructed as a bored-tunnel, as this is the only tunnel-form viable for tunnelling through a hilly terrain.
4.3.1.2 This section of tunnel will be partly through rock. On most occasions, bored-tunnelling through rock will use blasting so as to expedite excavation. However, in view of the proximity of the Ngong Ping 360 Cable-Car facility nearby, blasting will be prohibited, which means tunnelling through Scenic Hill will be limited to mechanical excavation. Though this will be more time-consuming, the length involved is only 0.5 km, hence adopting a more time-consuming method for tunnel excavation will not affect HKLR’s programme critically.
4.3.1.3 The HKLR tunnel will continue beyond Scenic Hill onto the reclamation in Section 4.3.2 below. It will be constructed by a combination of the following methods:
(a) Cut-and-Cover method, involving trench-excavation (i.e. open-cut) followed by in-situ construction of the tunnel structure in the trench, and then backfilling around the tunnel structure;
(b) Trenchless method (for the portion where open-cut is impossible, notably the portion of HKLR tunnel underpassing the Airport Railway), involving bored-tunnelling with special stabilisation measures such as pipe-piling and jet-grouting to support the tunnel-bore during construction.
4.3.1.4
In view of the
proximity of the
4.3.2 Reclamation & At-Grade Road
4.3.2.1 As HKLR tunnel will be at a deep level at the chainages underpassing the Airport Railway, it will need to be embodied by a piece of reclamation at its eastern-most portion (which will be in the waters adjacent to the south-eastern side of Airport Island, hence the need for reclamation to protect the tunnel from vessels collision). The eastern end of the tunnel will daylight as a portal in the reclamation, as shown on Figure 4.2. It is anticipated that the section of tunnel in the reclamation, including the portal, will be constructed by the Cut-and-Cover method.
4.3.2.2 The reclamation will involve the following key features:
(a) Seawall along the periphery of the reclamation, which will involve dredging for removal of marine-deposit along the base of the seawall, followed by rockfilling and then rock-armouring;
(b)
Reclamation filling between the seawall and the existing
(c) In view
of the limited capacity of contaminated mud pit in
4.3.2.3 As the HKBCF will also involve the same type of seawall as above as well as non-dredge reclamation, reference should be made to Section 4.4 below for further descriptions on the foregoing key features.
4.3.2.4
After daylighting from the tunnel-portal in the reclamation area,
the HKLR will continue mainly as an at-grade road on the eastern side of the
4.4.1 Main Types of Seawall/Reclamation
4.4.1.1 In general, the types of seawall/reclamation considered for HKBCF are mainly as that shown on Figure 4.5.
4.4.1.2 As the HKBCF reclamation area is accessible abundantly by land transport, there is no substantial need for berthing of vessels. Accordingly, the seawall along HKBCF’s periphery will substantially be sloping seawall with rock-armour surface, as this type of seawall is generally more cost-effective and performs well in wave-absorption, whereas the vertical type of seawall is usually adopted only if there is a need for berthing of vessels. (At detailed design stage, the need for berthing may arise, but it is not anticipated that the extent involved will be significant, i.e. at most this will lead to some local short sections of vertical seawalls.)
4.4.1.3
As the seawall serves
to retain the reclamation fill behind it, the base of a seawall requires a much
higher engineering capacity than that of the reclamation fill, in order to sustain
pressure on the seawall from the material behind. Accordingly, the
majority of seawalls worldwide adopt full-dredging for total removal of marine
deposit along the base, with the trench thus dredged filled with firm materials
(e.g. sandfill or rockfill) serving as seawall
foundation. This is also the common practice for the design of seawalls
in
4.4.1.4 In the preliminary design of the seawalls for HKBCF, consideration was given to deviate from the above to adopt non-dredge types of foundation. However, as will be explained below, the applicability of these methods is limited. Hence, it is assumed in both the preliminary design and the EIA for HKBCF that the seawalls will adopt fully-dredged foundations.
4.4.1.5 As regards the reclamation behind the seawall, the scope for application of non-dredged method (i.e. with measures to accelerate consolidation of those marine sediment layers that are not dredged), in lieu of full dredging, is much more realistic than in the case of the seawalls. Typically the consolidation measures involve the laying of geotextile & sandblanket onto the seabed surface, together with the installation of band-drains and surcharging.
4.4.1.6 The key issue to be addressed in deciding whether HKBCF should adopt non-dredge reclamation (with consolidation measures) or fully-dredged reclamation should be adopted will depend on whether its construction programme can accommodate the time-consuming surcharge period entailed by non-dredged reclamation. Another key issue is to consider the environmental advantages of non-dredge reclamation as it obviates dredging and reduces reclamation filling. Consideration in this regard will be presented in Section 4.4.3 below.
4.4.1.7
In view of the limited
capacity of contaminated mud pit in
4.4.2 Non-dredge types of Seawall Foundations considered
4.4.2.1 The following non-dredge types of seawall foundations have been considered for HKBCF:
· Stone-Columns;
· Deep Cement Mixing (DCM);
· Sand Compaction Piles (SCP).
4.4.2.2 The viability/applicability of these methods to the seawalls of HKBCF are outlined below:
Method |
Viability/Applicability or Limitations
|
Stone Columns |
(a) Should this method be adopted, the depth of undredged marine-deposist left below the seawall would have been 14m to 26m. This means very long stone-columns will be required to strengthen the marine deposit. Such a long length will aggravate the stone-columns’ tendency to buckling, hence reducing their engineering capacity.
(b) Stone-Columns’ track-record for strengthening thick marine deposit below seawalls is much less than that of DCM and SCP, and is of course far less than that of the fully-dredged method.
(c) In terms of cost-effectiveness, stone-columns are unfavourable too, of the order of 2 times more costly than the SCP method.
In view of the above, the stone-columns method is considered to be not viable.
|
DCM |
(a) The application of DCM will involve various concerns, including the temperature-rise of cement-hydration, the durability of cement in the seabed, and the risk of eruption from the seabed during injection of the cementitious material. The latest factor is of particular concern, as the erupted materials will contain cement and associated chemicals, causing serious impact on water-quality and marine-ecology.
(b) A full-scale trial will need to be carried out to establish the viability of DCM. This cannot be accommodated in the construction programme of HKBCF.
(c) In terms of cost-effective, DCM is unfavourable too, of the order of 2 to 3 times more costly than the SCP method.
In view of the above, the DCM method is considered to be not viable. (It should also be noted that in the current Busan New Port project, one of the largest marine works projects in the world, DCM was adopted in the early years of the project for seawall foundations, but in recent years SCP has become the predominantly adopted method in that project.)
|
SCP |
(a) In a site visit to the
(b) The SCP method is a relatively new
technique; for instance, in the early years of the
(c) In terms of technical details, there are two more limitations on the application of SCP:
· The seabed will upheave when applied with SCP; in the case of HKBCF, the application of SCP in areas where existing seabed is shallower than -6 mPD will not be OK as the upheaved seabed will affect accessibility of vessels.
· The SCP plant will need a headroom up to +42 mPD. Allowing for safety margin, the above means that SCP is applicable only for those areas where the Airport Height Restriction (AHR) contour is +45 mPD or above.
|
4.4.2.3 In view of the above, it is considered that Stone-Columns and DCM are not viable, whereas SCP may be worth considering for those portions of the HKBCF seawalls where seabed is deeper than -6 mPD and AHR is +45 mPD or above, PROVIDED THAT the following issues can be overcome:
(a) That the Contractor can provide further data to obviate the need for a trial, such as the arrangement of water quality monitoring under a relevant overseas project;
(b) That the actual mobilisation time of the SCP plant will enable the method to be applicable to a significant proportion of HKBCF’s seawalls.
As the foregoing aspects do involve uncertainty that cannot be eradicated at this stage, the EIA for HKBCF will assume full-dredging for all the seawalls. This will be on the conservative side, as SCP (if adopted for any portion of the seawalls) should only constitute an improvement as it serves to reduce the amount of dredging, hence reducing the amount of seawall-filling too.
4.4.3 Dredge/Non-Dredge for Reclamation and Overall Construction Sequence of Reclamation Works
4.4.3.1 In the preliminary design and the planning for the HKBCF Reclamation Works, the following aspects are considered together as they are interrelated/interdependent with each other:
(a) Whether the reclamation behind the seawall should adopt the non-dredge option (with consolidation measures as noted in Section 4.4.1 above) or the fully-dredged option;
(b) The overall construction sequence of the reclamation works (including seawalls, dredging if any, consolidation measures, reclamation filling), for ensuring that relevant parts of HKBCF’s reclamation areas will be available early enough for the Land Works, which are targeted to be completed in two phases by 2015/2016.
4.4.3.2 Whereas for reasons explained above full-dredging is assumed for all the seawalls of HKBCF, the reclamation behind the seawalls will adopt the non-dredge option (with consolidation measures) as far as applicable, i.e. full-dredging will be adopted only if it is essentially needed. This serves to reduce the amount of dredging hence reducing the amount of reclamation filling.
4.4.3.3 Another important principle is to plan the sequence of reclamation works in such a way that seawalls construction will precede reclamation filling, so that the former will afford a degree of containment on the latter. This will serve to reduce water quality impact during reclamation filling.
4.4.3.4 Taking account of the relevant factors involved, two options are formulated as regards the construction sequence of the Reclamation Works for HKBCF, as shown on Figures 4.6 and 4.7. These are referred to as Sequence A and Sequence B; a comparison of the key aspects of these two Sequences is tabulated below:
4.4.3.5 In view of the above, Sequence B should be adopted as it is environmentally more advantageous and as it can still meet the vital programming target. Nevertheless, for such a complicated project as HKBCF, there is a possibility that the need to change to Sequence A may occur; for instance, in case of unforeseen delay in the earlier tasks, the change from Sequence B to Sequence A will enable the project to gain back time to compensate for earlier delay. For this reason, though the planning of HKBCF should be based on Sequence B, the assessment of water quality impacts will be based on Sequence A for conservatism.
4.5 HKBCF Roadworks
4.5.1 The majority of roadworks for HKBCF will be in the form of at-grade roads in the reclamation area. It is anticipated that these will mainly be in the form of bituminous surfacing layers laid on subbase materials.
4.5.2 The HKBCF will also involve various elevated bridge structures for the following:
(a) HKLR’s connection to the HKBCF, in order to overpass the road connecting TMCLKL to the Airport;
(b) Various ramps connecting
HKBCF to the TMCLKL (for connecting to both its main tunnel across
(c) HKBCF’s
roadlink to the Airport, which will be constructed
partly within the HKLR reclamation in Section 4.3.2 and partly on the
existing
4.5.3
These elevated
bridgework will take the form of prestressed concrete
box-girders for the bridge deck, founded on reinforced concrete substructures
(columns, pilecaps and bored-piles). As they
are constructed on land either on HKLR/HKBCF reclamation or on the existing
4.5.4
A special point to note is that one of the legs
in the HKBCF-Airport roadlink will take the form of a
tunnel, extending from the HKLR reclamation area onto the existing
4.5.5 An overall layout of the HKBCF-related roadworks, as described in Sections 4.5.1 to 4.5.4 above, is shown on Figure 4.8.
4.6.1 During the construction stage, peripheral temporary surface channels will be constructed to collect surface runoff in the reclamation area for desilting before discharging into the adjacent waters.
4.6.2 The temporary drainage system during the construction phase will be formulated by the Contractor to match his method of works and construction programme. The temporary drainage will comply with EPD’s Practice Note ProPecc PN 1/94.
4.6.3 Appropriate mitigation measures to prevent impacts to water quality are discussed in the section on Water Quality Impact Assessment.
4.6.4 Drainage, sewerage and utilities will be installed only after the removal of surcharge for control of settlement. Open cutting of trenches with sufficient width and depth would be used for these culverts / drains and utilities. The trenches will then be backfilled after the culverts / drains and utilities are installed.
4.7 Buildings within HKBCF
4.7.1 The building works to be constructed within the HKBCF reclamation area will include:
(a) The
(b) Other buildings for accommodating BCF-related facilities and offices for the various Government Departments and personnel involved in the operation/management/maintenance of the HKBCF.
4.7.2 An overall layout of these buildings is shown on Figure 4.9.
4.7.3 For the PCB, its size will be approximately 160m x 200m on plan; the building will have 4 storeys: G/F for processing inbound HZMB passengers arrived by coaches, 1/F for processing outbound HZMB passengers arrived by coaches, 2/F for operational departments’ offices, 3/F for other supporting facilities such as staff canteen, plant rooms and other M&E facilities etc.
4.7.4 It is anticipated that the substructure of the PCB will comprise piles with pilecaps, whereas its superstructure will be selected from the following options:
· Conventional in-situ reinforced concrete construction;
· Precast concrete construction;
· Steelwork construction much of which will be in the form of prefabricated steelwork elements.
4.7.5
The building works on
HKBCF reclamation are over 2km from the sensitive receivers (SRs) at Tung Chung. Even for the relatively near SRs on the
4.7.6 The other buildings, being smaller in terms of construction work content, are likely to adopt the more conventional reinforced concrete structural form. However, as stated above, even if a different form is eventually adopted, it should not have significant effect as regards environmental impacts.
4.8
Automated People Mover (APM) between
4.8.1
A number of alignment
options have been considered for the APM between HKBCF and the Airport.
Various meetings were held between AAHK, HyD/HZMBHKPMO, FSD, CAD and Arup, the
preferred APM alignment is basically an extension of the existing T1-T2 APM
line to connect to the HKBCF in tunnel form, passing underneath
4.8.2 For this APM alignment between HKBCF and the Airport, it is envisaged that the APM tunnel can mainly be divided into four sections with respect to construction methods. An indication of the extent of these sections is shown in Figure 4.11 and Figure 4.12.
4.8.3 For the section from the extended HKIA APM line at T2 to the south of AsiaWorld-Expo (AWE), the tunnel section is envisaged to be constructed by cut and cover method in rock in view of the shallow rockhead. Depending on the geological condition of the site, the cut and cover tunnel section will involve rock mining at certain sections where rockhead level is higher than the proposed APM tunnel level, and that will involve temporary lateral support works for tunnel excavation at sections where rockhead level is deep.
4.8.4
From the south of AWE
to existing FSD Rescue Berth, the APM tunnel will be constructed by tunnel
mining method (in rock) underneath the existing
4.8.5 For the section from existing FSD Rescue Berth to HKBCF’s western seawall, it is envisaged that the APM tunnel will be constructed by immersed tube method. The immersed tube tunnel units will be constructed at offsite casting facilities, and then towed to the tunnel site for installation.
4.8.6 For the section after passing HKBCF’s seawall and within HKBCF’s main reclamation area, it is envisaged that the APM will take the form of a cut-and-cover tunnel.
4.9 Tentative Programme
4.9.1 The tentative construction programme of HKBCF and HKLRF are shown in Figure 4.13 and Figure 4.14 respectively.
4.10.1 The construction plant anticipated to be required for various stages of the construction of HKLR and HKBCF are given in Section 6.
4.10.2 The Contractors, when developing their own construction programme and methodology, shall take into account the design, work areas, scheme boundary, mitigation measures etc described in this EIA Report. The need and extent of the mitigation measures shall be updated by the Contractors, subject to approval from the relevant authorities.