B513 Planning Meeting, 7th November 2002
Present:
Nigel Baddams, Tony Cass, Anne
Funken, Jukka Lindroos, Jose Miranda, Bruno Pichler
1.
Previous Minutes
- Approved with minor corrections.
- Matters arising:
- 2.2 2a: We still need to understand the
cost for boring tubes to the technical gallery.
- 2.2 2b: Anne has an appointment with Guy
Salomon/TIS to discuss the safety requirements for routing 18kV cables..
2.
Substation Planning
2.1.
Compensation System
- Anne remains concerned about coping with
the impact of 3rd harmonics. Ensuring adequately sized neutral
conductors is the main issue but purchasing higher capacity equipment (with
high cross sections for all conductors) is expensive and it is not
possible to modify all of the necessary equipment. Some form of
compensation equipment to reduce the level of neutral currents will
therefore be needed. Two sorts of equipment are available:
- Active filters.
These can only be placed in the machine rooms as there are no models
large enough to handle the aggregate loads at the substation level.
- Passive filters
can be located either in the machine rooms or in the substation.
- There is a strong preference for compensation equipment to be
installed in the machine rooms as this allows smaller cables to be used
between the substation and the machine room. Space has been allocated for
filters in the substation, however, so there is no need to delay design of
the bunker whilst the filter arrangements are finalised.
- Choice of which type of compensation (active or passive) to use
will depend on space and price considerations. Passive filters are
cheaper, but standard passive filter unit cannot be maintained live. If continuity
of service during maintenance or after failure is required then the unit
cost increases from €20K to €60K! Filters that reduce the level of neutral
currents by 50% (rather than by 90%) are being considered.
- In principle, we can simply allocate space for filters in the
machine room PDUs now and install filters later only if they are needed.
However, installation of the filters would require a service interruption.
2.2.
Construction Plans
- Nigel showed the latest plans for the
bunker. Taking into account the 5.8m width of the 18kV room, the overall
length is now 27.2m. There is no ”double wall” at the Jura end; extending
the reinforcement bars beyond the end of the bunker is adequate to allow
for any future extension.
- Jose commented that the increased length
of the bunker meant an increased cost and could prevent us from using the
existing market survey. Our options in this area need to be studied
carefully as there is not much time if the new substation is to be in
service at the end of February 2004.
- A review of the various installation
delays suggested that the tender for the bunker should require
construction to start on May 1st, with completion expected to
be at the end of September. This would allow installation of the
electrical equipment from October.
- There was again much discussion about how to route cables into
and out of the bunker. Nigel and Jose were concerned about the structural
implications of a caniveau along the length of the S-206 and, more
generally, bringing cables in under the foundations of B513. Despite the
limited clearance, the only option is to route cables at ceiling level.
- As the cables from the transformers will now be routed
vertically into the 18kV room there is no need for a caniveau between the
ducts along the wall of B513. It was therefore agreed to draw up plans
such that cables could be routed at all possible places along the common
wall (excluding only ducts and joists). This allows the building design to
be finalised now, avoiding the need to wait for precise planning of cable
routes.
- It was agreed that Nigel would prepare the final designs for
November 15th and that Jose would look into ways in which
various contracts can be used and how to arrange the design study.
Although a Site Committee review is required before placing the
construction order, we already have approval for the design study phase
3.
Air conditioning
- Jukka presented a cost breakdown of the
work required to support a 2.5MW load (900KCHF) and to upgrade to support
a 4MW load (a further 1,200KCHF). He confirmed that work for the 2.5MW
solution could be carried out in 2005-7 and that the upgrade for 4MW could
take place later without any interruption to services (although some work
might have to be scheduled in winter).
|
Costs
to support 2.5MW equipment load
|
KCHF
|
|
New 2MW chiller
|
350
|
|
2 pumps; 500m3/hr
capacity, with variable speed control
|
100
|
|
Additional cooling coils in
the stations
|
100
|
|
Chilled water piping
|
200
|
|
Duct modifications
|
50
|
|
Miscellaneous &
contingency
|
100
|
|
Total
|
900
|
|
Additional
costs to support 4MW equipment load
|
|
|
Replace 2 chillers with 2MW
models
|
700
|
|
2 additional 1.5MW cooling
towers, with associated pumps
|
180
|
|
Condenser piping
|
100
|
|
Duct modifications
|
100
|
|
Miscellaneous &
contingency
|
100
|
|
Total
|
1180
|
|
Maintenance
required during LHC operation
|
|
|
Replace old 1.2MW chiller
|
250
|
- The 4MW solution requires the
replacement of the existing chillers with higher capacity units. If we do
not upgrade, these chillers will, for maintenance reasons, need to be
replaced with equivalent capacity at some point during LHC operation.
However, as for the upgrade, any replacement could be done without any
interruption to services—in fact, Jukka confirmed that all maintenance
work could be undertaken without interrupting services, at least during
winter.
- More time is needed to study the power
needs for 4MW solution, but Jukka agreed to provide this information to Anne
by November 15th.
4.
AOB
- Next meeting, 4pm, Tuesday
19th November.