BUDAPEST METRO LINE 4 FEASIBILITY STUDY

Oktober 1996

Infrastructure and implementation

Introduction

From Stage 1, further investigations have been carried out to optimise Tétényi selected alignment. The objective was essentially to optimise the capital costs of the infrastructure and especially of the stations. The refinement and optimisation of the alignment concern both the horizontal and vertical profiles, they affect the two components of the line: stations and alignment sections. In order to refine and optimise the horizontal and vertical profiles, the following principles were taken into account:

• to select the lower cost cut and cover methods to built the stations whenever it is feasible. Schematic Figure C-6 illustrates cut and cover methods.
• to adapt the alignment sections to the station selected locations (and not the reverse).

That implies, when it is feasible:

• for the horizontal alignment, to implement the stations as close as possible to the main street intersections, the better location being just below the street crossing. Figure C-7- shows the direct service provided by such principle.
• for the vertical alignment, to implement the stations as close as possible to the ground level, and thus to minimise the depth of insertion. Figure C-8- illustrates the theoretical depth implementation for both cut and cover and deep tunnelling methods.

In addition to the cost optimisation objective, it should be noticed that these principles accord with providing a better comfort provided to the passengers in terms of better and shorter access to the platforms.

On the other hand, the design of the rolling stock determines directly the station length and participates to the minimisation of the costs. Based on the outer length of a 5 Car train set, the standard platform length is given to 80 m.

This chapter, with the support of Drawings attached Appendix C, describes Tétényi selected alignment implementation (refer to Figure 1, Appendix C), considering the investigations carried out at that feasibility stage. As described within Section B, several alternatives of possible staging are contemplated, as follows:

Sections and Phasing	Length (km) *	Number of stations **
Kelenföld - Keleti main alignment
Only one stage	7.34	10
Two stages :
Kelenföld -Kálvin	5.18	7
Kálvin-Keleti	2.16	3
Kelenföld -Kálvin section
Only one stage	5.18	7
Budaörs-Kelenföld extension
One further stage	1.92	2

* including the turnround tracks, around 0.6 km

** including terminals

Topography

The preliminary study of any transport infrastructure needs basic input information in order to determine the appropriate design and sizing.

A detailed survey of the whole corridor of the selected route including the existing structures and utilities will be essential to establish a basic knowledge for the future construction works, to estimate the environmental impacts and the associated capital costs.

Based on the local knowledge and on some preliminary investigations previously carried out, the difficulties, especially regarding the public utilities network, have been examined in detail in the Technical Annex attached to Stage 1 Report.

Geotechnical characteristics

Most of the construction difficulties, which result in additional costs or delay, mainly come from the initial imprecise knowledge of the ground characteristics. Therefore, it is essential to carry out first, an exhaustive and accurate soil investigation with complementary analysis of existing geological maps and related documents.

The objective is to establish the longitudinal soil profile along the selected route, including the geotechnical and hydrological characteristics of the corridor of interest influencing the construction and the future works.

For the First stage of the study, general investigations have been carried out in the past and they support in particular the preliminary selection of underground construction methods of cut & cover or deep tunnelling.

3 specific homogeneous geotechnical sections (see Figure C.8bis) are identified, as follows:

1. the Buda area : from Kelenföld to Gellért Square
2. the crossing of the river
3. the Pest area .

Based on previous preliminary investigations, it is assumed that no unexpected difficulty should be anticipated while implementing an underground public transport system.

• Buda area

Bedrock of the area consists of Mid-Oligocene clay of Kiscell and its transitions into the Upper-Oligocene sediments. The underlying original part is gray and the top part, close to the surface is yellow to brownish-yellow. An ancient Danube branch running approximately along the Tétényi út eroded the majority of the upper part of the clay in this area.

The Kiscell clay can be considered homogeneous, except in the vicinity of faults. It is favourable as far as tunnel driving is concerned, since it is impermeable, stable for a long period of time and it has relatively high strength. However, in the vicinity of the faults, the percolating ground water considerably reduces its strength.

The lower and medium series of strata belonging to the Kiscell clay can be encountered between the Bocskai út and Gellért Square. Within these aleurite, occasionally marl, strata are frequently intercalated with sandstone bank and lenses. Their thickness may range from 0.2m to 20m. They are hard with a high CaCO3 content of around 30 to 45%. The strength of the rocks is determined by their finely dispersed CaCO3 content which is generally of 14 to 19%.

• The crossing of the river

In the vicinity of Budafök út and Gellért Square, the geotechnical conditions are less favourable compared to those described above and in addition the proposed metro routes approaching the aquifers of the thermal waters. Due to these reasons, the average temperature of the rocks is about 27-30°C near the Gellért Square, requiring particular attention during both the construction period and the operation phase of the line.

In the Danube bed, proper exploratory borings have been carried out only near the shore, because of the required clearance of the narrow navigational channel. More detailed knowledge about the geological conditions can be obtained only during tunnel driving which would need to be performed using special precautions.

Under Gellért Square and the Danube, the so-called Tard strata are dominating at the zone of the expected tunnel gradient. They are characterised by the marly nature of the rock and its laminated structure. The homogeneity of the sedimentary rock is interrupted by 5-10 cm thick tufa and sandstone bands. The sediment can be classified as lean to medium clay. Under the riverbed close to the Pest side the movements along the structural lines resulted in the occurrence of Upper-Oligocene sediments in the form of loose sandstone and aleurite.

The Tard layers are particularly characterised by a limited amount of CaCO3 from 0.4 to 5.0%.

In addition to the tectonic characteristics, attention should be paid to the thermal water and methane gases occurring at the tectonic zones.

• Pest area

On this section, about 10 m to 15 m thick permeable granular deposits of the Pleistocene age can be encountered. They are underlain by carbonate silty sand (Upper-Oligocene), mainly aleurite ,and various frequently changing strata of the Miocene age.

The rocks of the section between Sóház utca and Pipa utca are heavily fractured due to the present of fault zones. The scattered and occasional appearance of thin loose or slightly cemented sand layers are prone to loosening, and the use of compressed air might be necessary at the tunnel driving;

The area of the Kálvin Square is constructed in rather hard calcareous, sandy clay of high carbonate content and partly in marly, sandy clay whose properties are relatively favourable as far as station construction is concerned.

To the east of Kálvin Square, sandy clay stratum with bentonite content is encountered. The layer is characterised by becoming plastic and sticky if saturated and is therefore difficult to excavate.

Hydrogeologic conditions

The only major hydrogeological factor of the Buda side is the groundwater flowing towards the Danube in the clayey talus material up to Gellért Square. Due to the irregular surface of the Oligocene aquifuge, the seepage of ground water slows down at some places and the ground water solves sulphates out of the Kiscell clay thus becoming very aggressive to concrete. The average value ranges from 250 to 500 mg/l, but it might increase locally, reaching 1,200 to 2,900 mg/l.

Dewatering problems might be caused by the spring waters percolating in the fissures of rocks in the Gellért Square area and under the Danube. The hazard of the water breaking into the tunnel can be reduced by the use of various amounts of compressed air or by grouting in the vicinity of the tunnel.

In the Kálvin Square area, the Pleistocene aquifer is also encountered with a thickness of 5 m to 15 m. The fluctuation of ground water corresponds to the water table of the Danube.

The old strata (Oligocene, Miocene) are frequent, the stability of the soil for the construction period might be protected by grouting.

Design criteria

Horizontal and vertical alignment design criteria

The design criteria for horizontal and vertical alignment that are considered for the design of Metro line 4 are described in Table C-6, as follows:

	Design criteria
Horizontal profile
Minimal radius
Standard track	(250)-300 m
Turnout track	100 m
Maximal applied superelevation
Standard track	E = 140 mm
Maximal lateral acceleration	0.33 m/s²
Standard track and stations	U = 75 mm
Points and crossings	U = 60 mm
Vertical profile
Maximal slope
Main standard track	50‰
Minimal curve radius	2000 m

The equilibrium superelevetion E_q, in a curve with a given radius R, is calculated with the formula :

And so, for the minimal radius of 300 m, based on the 140 mm maximal superelevation and the 0.33 maximal lateral acceleration, the calculated design speed is 70 kph.

On the main line and the depot connections, transition curve alignments shall be provided wherever possible between straight alignments and curve alignments and between the different radii of compound curve alignments.

When transition curve alignments cannot be installed, the maximal allowed speeds shall be estimated.

A minimal of 100 m length slope of 0.3‰ has to be applied before arriving a station, if a slope of 50‰ is applied from the arriving direction.

Track gauge design criteria

The standard track gauge shall be the 1,435 mm. It should be noticed that, according to the appendix of the Hungarian Metro Regulations, on sharp curves (less than 200 m radius), the gauge should be widened, depending on that the track will be used only by Metro rolling stock or also by Railway rolling stock. That should be examined more in detail in the further preliminary and detailed designs.

General layout and longitudinal profile

The 7.34 km main line between Kelenföld and Keleti stations comprises 10 stations, including the terminals. A possible staging at Kálvin Square is contemplated as described in Table C-5. A likely 2 km extension beyond Kelenföld to Budaörs is also analysed and cost estimated.

Construction methods

• Kelenföld-Keleti alignment

The whole alignment is planned to be underground. The length of the line is , not including the tracks connecting the depot.

These can be the shield-bore technology or gunite (shotcrete) concrete technology. On the Pest side the shield-bore technology can be proposed by all means due to the subsoil conditions. At this stage of investigations, tunnels are planned to be only single-track tunnels (refer to the below cross section, Figure C-9)

4 types of standard stations have been identified, at this stage of feasibility. They are described Figures C-10 & 11, as follows:

• Type n°1: very deep station accommodating 2.75m width platforms, built by tunnelling,
• Type n°2: very deep station accommodating 4.20m width platforms, built by tunnelling,
• Type n°3: cut and cover station, implemented around 20 m depth,
• Type n°4: cut and cover station, implemented around 25 m depth.

They are all designed with central platforms and most of them provide only one exit. Further investigations at preliminary and detailed design stages should refine those issues.

As a matter of course, also double-track tunnel and station design with lateral platforms can be taken into consideration. The minimum width of lateral platform stations executed by bentonite slurry trenching techniques is larger than that of stations with central platforms.

On the Pest side construction of double tunnels executed with shield-bore technology is desirable, due to danger of subsidence and restrictions of transfer connections and trains. The construction of Metro line 4 will expectedly done in stages.

A detailed investigation of the design and a decision concerning the working method depend on the staging. In case of a short section on the Pest side the bore-shield technology should be chosen also on the Buda side.

• Budaörs-Kelenföld extension

Budaörs-Gazdagrét section will be partly on an elevated structure, between the Budaörsi Road and before the station of Gazdagrét, partly constructed by the cut and cover method.

To link Kelenföld station from the station of Gazdagrét, the tunnels could be constructed by any of the deep tunnelling technologies, depending on staging decisions.

Longitudinal profile (refer to the Figures 2 to 4 attached Appendix C)

• Kelenföld-Keleti station alignment

The 7.34 km horizontal alignment follows relatively closely the roadway when possible, in particular Bartók Béla street on Buda side. It comprises 10 stations, including the terminals and the average station spacing is 750 m. The maximal spacing to be noted is 1,350 m, between Tétényi and Kosztolányi stations and the minimal is 400 m, between Gellért and Fövam stations.

The minimal applied horizontal radius is 350 m, on Buda side before Kosztolányi. On Pest side, this issue cannot be reached and the stations are located as close as possible to the intersections.

The vertical profile is implemented between 17 m and some 44 m depth, depending on the sections. Because of the Danube constraint and the existing Metro line 2 & 3 to cross, relatively deep tunnel should be installed.

The greatest slope is 30‰, the minimal are 1‰. All the stations are located in straight and minimal slope sections. When a station is located after a slope section (more than 25‰), a limited slope section (less than 15‰) is the inserted on a 150 m length. Transition curves are clothoides and their parameters are based on the above design criteria.

Some alternatives of implementation have been analysed to optimise the vertical alignment, especially on the eastern Pest side section, after crossing Metro line 3 at Kálvin Square. The objective being to restrict the implementation depth of the stations, an alternative of tunnel crossing Metro line 2 above reduces the depth to some 20 m.

On Buda side, a relatively constant depth of 20 m is encountered from the terminal of Kelenföld to Móricz Zsigmond Circus, then the profile dives to be in a position to reach a reasonable 40 m depth below the Danube.

• Budaörs-Kelenföld extension

The 2 additional kilometre alignment follows partly the Budaörsi Road and then connect with Kelenföld station. It comprises 2 (or 3) stations.

Partly elevated from Budaörs terminal, the vertical profile dives to be in a position to connect with the underground Kelenföld station. Further investigations to be carried out at the preliminary and detailed design stages would refine the vertical alignment.

Budaörs terminal station is the only station planned to be elevated. The turnout tracks, benefiting from the specific area topography, will be at-grade. The two other stations are designed according to the types n° 3 and 1 identified in the above paragraph.

Stations and interchanges

This section describes the station implementation and specifies the difficulties or impacts of implementation that could be addressed during the construction period. Tables C-7 & 8 summarise the station characteristics.

For some of the stations, several alternatives have been contemplated, depending on their location and feasible insertion, they have been cost estimated.

Kelenföld-Keleti alignment

• Terminal of Kelenföld Station

Two alternatives have been analysed, as follows:

Terminal station, of Type n°1 (refer to Figure 5, Appendix C): It is a deep station of type n°1, located under the Kelenföld Railway tracks, benefiting from two exits.

The exit of Etele Square is situated in an engineering structure executed partly by bentonite slurry trenching techniques, and the escalators connect with the level of an underground pedestrian passage.

The exit of Õrmezõ reaches the underground pedestrian passage situated under the railway station through a 90 m long corridor. From the underground pedestrian passage, escalators connect with the surface.

Its construction can be performed without specific difficulties. The design of the public transport interchange (urban and suburban buses, Park and Ride) will require expropriation of land.

Terminal station of Type n°4 (refer to Figure 6, Appendix C)

The multilevel station of type n° 4 is located on the eastern side of the railway tracks, at the Etele Square. It could be executed by bentonite slurry trenching techniques. Its upper level is part of the underground pedestrian passage to be established in the framework of an overall urban re-organisation of the area. Its design and construction technology should be harmonised with the regulation plans of the square being in the process of design. Some specific arrangements to connect with Örmesö direction should be provided, taking the opportunity of the existing railway pedestrian passage.

According to the importance of the passenger flow forecasts, extra platforms will be designed to comply with the required level of service.

• Station of Tétényi Road (refer to Figure 7, Appendix C)

The four-level station of type n° 3 has a single exit and is to be executed by bentonite slurry trenching techniques. It is located in the vicinity of the Etele Road, close to the Tétényi Road. The escalators connect with the concourse level structure built on the surface.

Its construction requires just a limited rerouting of public utilities, without planned restriction of the traffic.

• Station of the Kosztolányi Dezsõ Square (refer to Figure 8, Appendix C)

The four-level station of type n° 3 has a single exit and is to be executed by bentonite slurry trenching techniques. It is located on Kosztolányi Dezsõ Square. The escalators connect with a concourse level structure built on the surface.

Its construction requires rerouting of public utilities. During construction restriction of the traffic will be necessary.

• Station of the Móricz Zsigmond Circus (refer to Figure 9, Appendix C)

The four-level station of type n° 4 has a single exit, and will be constructed on the square by bentonite slurry trenching techniques. Its upper floor is part of a pedestrian underground passage to be constructed when the area will be re-organised.

During the construction period a restriction in public road traffic of minor extent is required and construction of a temporary tram track will be necessary.

The rerouting of public utilities is insignificant.

• Station of the Szent Gellért Square (refer to Figure 10, Appendix C)

Gellért station is a very deep station of type n° 1. It will be executed by the deep tunnelling method, and will be located between the Bartók Béla Road and the Budafoki Road. The station has a single exit. The escalators of the broken-lined exit will be located in an engineering structure to be executed by the bentonite slurry trenching techniques, and will connect with a hall of poured in place reinforced concrete structure under the surface.

Its construction requires rerouting of public utilities to a minor extent, and a restriction of the traffic will be necessary.

• Station of the Fõvám Square (refer to Figure 11, Appendix C)

The very deep station of type n° 1 has a single exit, and will be located partly below the lower quay of the Pest side and partly under the Danube. The exit has a broken lined tracing. The engineering structures of the escalators connecting up with the platform, and of the corridor will be executed with deep tunnelling method. The engineering structure of the escalators arriving into the new underground pedestrian passage will be constructed by the bentonite slurry trenching techniques.

In connection with the station, a complete re-organisation of the area will be needed, implying in particular a rerouting of public utilities to a considerable extent. During the construction period, traffic will be maintained by temporary roads and tram tracks. Construction of the station in depth and remodelling of the surface can be carried out independently from each other with adapt phasing.

• Station of the Kálvin Square (refer to Figure 12, Appendix C)

The construction of this station, in connection with Metro line 3, is constrained on one hand by the Metro line 3 alignment and on the other hand by already previously built connections. It is a deep seven-level station of type n° 2, with a single exit. It will be situated under the square. The escalators will arrive to the surface into a lockable structure. Kálvin Square station is to be envisaged as a temporary terminal, if decision is taken to built the line according to two phases. Special turnround tracks would be provided and extra departure platforms would be designed, implying extra construction costs.

The construction of the station does not require either rerouting of public utilities or restriction in traffic.

• Station of the Rákóczi Square (refer to Figure 13, Appendix C)

The five level station of type n° 3 has a single exit, and will be situated under the square. The escalators will arrive to the surface into a lockable structure. Further investigations should demonstrate that the implementation is feasible closer to the ground.

The construction of the station does not require either rerouting of public utilities or restriction in traffic.

• Station of the Köztársaság Square (refer to Figure 14, Appendix C)

The station lies at the south west-corner of the square, in the vicinity of the Luther Street and the Népszinház Street. The seven-level station is of type n° 3, and is an engineering structure executed by the bentonite slurry trenching techniques, and has a single exit. The escalators arrive to the surface into a lockable structure. Further investigations should demonstrate that the implementation is feasible closer to the ground.

The construction of the station does not require either rerouting of public utilities or restriction in traffic.

• Station of Keleti

Two alternatives have been analysed, depending on the location of the station, as follows:

Terminal station below the Railway station of Keleti (refer to Figure 15, Appendix C)

The line intersects the Metro line 2 below this latter one. The station lies under the building of the Eastern Railway Station. It has two exits. One of the exits is situated in a hall established on the level of the underground passenger passage, and lies in the direction of the Thököly Road. The station has a transfer connection with Metro line 2. Its second exit is similar to the new second exit of Metro line 2, connecting with the existing underground pedestrian passage of the Baross Square.

The station is a deep station of type n° 2, and will be constructed by the deep tunnelling method, together with the engineering structure of transfer connection and partly with the exits. The establishment of the transfer connection engineering structure makes necessary the remodelling of the service and plant spaces located in the station of Metro Line 2.

The execution of the station requires a rerouting of public utilities to a minor extent. Because of the second exit to be constructed toward the Baross Square, a restriction in traffic is necessary in front of the Eastern Railway Station.

Terminal station close to Metro line 2 station (refer to Figure 16, Appendix C)

The line intersects the Metro line 2 over the latter one. The station is located on the Baross Square, below the direction of the Thököly Street. Its exit connects with a new underground pedestrian passage. It has a transfer connection with Metro line 2. Because of the design of the transfer connection, the existing exit engineering structure of Metro line 2 should be demolished, implying a specific phasing for the works. The second exit of Metro line 2 should be constructed before starting construction of the station. Establishment of the second exit makes the remodelling of service and plant places situated in the station of Metro line 2 necessary.

The station is an engineering structure of type n° 4, executed by the bentonite slurry trenching techniques. Engineering structures of the transfer connections can be constructed with the deep tunnelling method applying special treatment (freezing, soil solidifying, etc.). The same relates to the connecting up line sections too.

The establishment of the station requires the demolishing of the existing underground pedestrian passage system and construction of a new underground pedestrian passage. It induces the overall remodelling of area, together with the existing public utilities. During the construction period a major restriction in traffic will be necessary.

In both cases, an eastern extension of the alignment is feasible.

Budaörs-Kelenföld extension

• Terminal of Budaörsi Road (refer to Figure 17, Appendix C)

The terminal will be located after the underground passage on the bridge, along the Budaörsi Road.

For the Terminal of Budaörsi Road the bridge structure will be a poured in place reinforced concrete slab supported by columns, and for a Vehicle Depot at the Etele Square the bridge structure will be a steel box girder supported by reinforced concrete columns. The terminal will possess extreme platforms. From the platforms stairs will lead down to the ground level. The execution of the project requires expropriation of land (and depends on purchasing opportunities of the area).

• Station of Gazdagrét (refer to Figure 18, Appendix C)

The station will be located between the Gazdagréti Road and the Naprózsa Street, between the Budaörsi Road and motorway No M1-M7, with a pedestrian underground passage above it.

The double-level station of type n° 3 can be executed in bentonite slurry trenching techniques design. To the upper level an underground pedestrian passage will be connected up below the Budaörsi Road.

The execution of the project requires expropriation of land.

Construction of the underground pedestrian passage can be carried out under restriction in traffic. Rerouting of the public utilities is necessary.

• Station of Õrmezõ (refer to Figure 19, Appendix C)

This is a deep station of type n° 1 situated between the motorway M1/M7 and the Kelenföld Railway Station, with two exits. The escalators located in incline shaft and executed partly by bentonite slurry trenching techniques arrive into a closed on-surface structure. It could be possibly envisaged as a temporary terminal instead of Kelenföld terminal to provide better service for the western areas.

Its realisation requires expropriation of land.

Its construction can be performed with insignificant rerouting of public utilities without restriction in traffic.

	Type n°	Station length, outer (m)	Platform length ( m )	Platform chainage (1) (km)	Depth (2) (m)	Station function	Number of escalators	Number of exits and insertion	Lift installation	Construction method	Turnout tracks
Kelenföld-Keleti alignment
Kelenföld I. (Etele Square)	4	83	80	2,190	-18	id	4	1, pedestrian subway	possible	cut and cover (slurry trenching )	+
Kelenföld II. (under MÁV)	1	85	80	2,080	-13	Interchange & Car Park	2x4 + 4	2	possible	mining
Tétényi út	3	83	80	3,020	-21	Standard	3	1, at grade	possible	cut and cover (slurry trenching )
Kosztolányi	3	83	80	4,400	-20	Standard +local feeding	3	1, at grade	possible	cut and cover (slurry trenching )
Móricz Zs.	4	83	80	5,010	-25	Interchange	4	1, pedestrian subway	possible	cut and cover (slurry trenching )
Gellért	1	85	80	5,790	-34	Standard & interchange	3+3+3	1	possible	mining
Fõvám	1	85	80	6,200	-36	Standard & interchange	3+3	1	possible	mining
Kálvin	2	85	80	6,690	-42	Metro interchange	14+3	2, pedestrian subway	possible	mining	+
Rákóczi	3	83	80	7,620	-34	Standard	3	1, at grade	possible	cut and cover (slurry trenching )
Köztársaság	3	83	80	8,190	-36	Standard	3	1, at grade	possible	cut and cover (slurry trenching )
Keleti. I.	2	85	80	8,890	-43	Interchange	7+3+3	2, pedestrian subway	possible	mining	+
Keleti II.	4	83	80		-16	Interchange	9+4+3	2	possible	cut and cover (slurry trenching )	+

(1) Middle of the platform

(2) '+' means elevated structure,' - ' means underground

Type n°

Station length, outer (m)

Platform length ( m )

Platform chainage (1) (km)

Depth (2) (m)

Station function

Number of escalators

Number of exits and insertion

Lift installation

Construction method

Turnout tracks

Budaörs-Kelenföld extension

Budaörs

Elevated

82

80

0.160

+8

Terminal, Interchange & Car Park

4

1 (2), at grade

possible

on viaduct

+

Gazdagrét

3

83

80

1.010

-10

Standard

0 (or 3)

1, pedestrian subway

possible

cut and cover (slurry trenching )

Õrmezõ

1

85

80

1.770

-26

Standard + local feeding

3+3

2, at grade

possible

mining

(1) Middle of the platform

(2) '+' means elevated structure,' - ' means underground

The line from the Budaörsi u. terminal will be constructed partly on viaduct, partly at grade and partly cut and cover. From the Gazdagrét Station deep tunnelling will be applied.

Vehicle Workshop and Garages

Two locations are still envisaged, depending on staging decisions. If the first stage concerns the main Kelenföld-Keleti alignment, obviously, the proposed Etele Square depot is essential to operate the line. If the decision concerning the staging includes the extension beyond Kelenföld, the second location should seem the most appropriate.

• Vehicle depot of Etele Square (refer to Figure 20, Appendix C)

The vehicle depot can be located on the area of MÁV (Hungarian State Railways) bordered by the Kelenföld Railway Station - Etele Square - Thán Károly Street - Andor Street. Its area runs up to 7 ha and is appropriate to accommodate the workshop and the garages for Metro line 4 rolling stock. In addition, if needed for further maintenance purposes, connections with MÁV installations could be provided.

The vehicle depot can be constructed at the same level as the Thán Károly Street, in a cut toward the Railway Station. On the side toward the railway station, earth retaining walls and the tunnel of the trial track provide level differences. Connection with the main metro line can be established by connecting up tunnels branching off before the second station, Tétényi Road.

On its area, the necessary track network, plant and storage buildings, and the dispatcher centre will be located. The trial track can be constructed in the necessary length as a single tracked tunnel made as a poured in place reinforced concrete structure.

It should be noted that this depot is suitable for servicing the line at any staging. A precondition of the establishment is of course the purchase of the land.

• Vehicle depot at Budaörs ( refer to Figure 21, Appendix C)

The vehicle depot is located between the Budaörsi Road and the motorway M1/M7 after the underground passage of Kõérberki, taking into consideration the situation of the relieving road of South-Buda. Its potential area is 8.5 ha. No MÁV connections could be easily provided.

The vehicle depot will be constructed partly on the ground surface partly on a poured in place reinforced concrete slab supported by columns.

On its area the necessary track network, plant buildings, trial track and a dispatcher centre will be located. Its establishment will be actual, if the first executed metro line section reaches Budaörs. A condition of its establishment is the purchase of the area.