Borsodchem MCHZ, Czech Republic 6,000 NM /H HTCR Topsøe Hydrogen Plant A Case Story: 18 Months From Engineering To Operation
Borsodchem MCHZ, Czech Republic 6,000 NM /H HTCR Topsøe Hydrogen Plant A Case Story: 18 Months From Engineering To Operation
Borsodchem MCHZ, Czech Republic 6,000 NM /H HTCR Topsøe Hydrogen Plant A Case Story: 18 Months From Engineering To Operation
1. Introduction.................................................................................................................................... 3
7. Pre-commissioning...................................................................................................................... 12
9. Operating Experience.................................................................................................................. 13
10. Conclusion................................................................................................................................. 15
BorsodChem MCHZ, Czech Republic
6,000 Nm3/h HTCR Topsøe Hydrogen Plant
A Case Story: 18 Months from Engineering to Operation
3
1. Introduction
BorsodChem MCHZ chose the Topsøe HTCR hydrogen process in connection with an
expansion of the production of amines in 2005. This case story describes the process from
engineering to operation of the 6,000 Nm3/h Topsøe low-energy HTCR hydrogen plant at
BorsodChem MCHZ’s facilities in Ostrava in the Czech Republic. BorsodChem MCHZ and
Topsøe’s HTCR technology are introduced, and the engineering phase, fabrication, site
installation, commissioning and operating experience of the hydrogen plant are described.
The company was privatised in 1992 and in 2000 when the Hungarian company
BorsodChem bought a considerable part of the shares the name became BorsodChem
MCHZ. Since the 1990’s significant investments have been made in new production lines to
match the change in product portfolio. BorsodChem MCHZ employs around 600 people at
the plant in Ostrava.
The products of BorsodChem MCHZ are used mainly in the polyurethane, rubber,
pharmaceutical and food industry. Exports, particularly to Central and Western Europe,
account for more than 75% of the total revenue and BorsodChem MCHZ is considered a
major player on the international market for amines.
Hydrogen plays a major role in the synthesis of the various amine products, and in 1996
BorsodChem MCHZ started up the first hydrogen plant based on natural gas as feedstock.
This hydrogen plant is based on conventional hydrogen technology from Haldor Topsøe with
a side-fired tubular reformer.
Additional hydrogen capacity was required in connection with a recent expansion of the
aniline plant. Even though the first hydrogen plant was operating satisfactorily, BorsodChem
MCHZ was interested in the lower operating cost obtainable with a Topsøe HTCR hydrogen
plant. Furthermore, the compact plant design and easy operation of an HTCR plant was
attractive for BorsodChem MCHZ.
In January 2004 a contract for the supply of a 6,000 Nm3/h HTCR plant was signed between
BorsodChem MCHZ and Haldor Topsøe. The contract covered the full hydrogen production
process from natural gas to the pure hydrogen (>99.999%) exit of a PSA unit.
The HTCR process (Figure 2) uses feeds ranging from natural gas, LPG to naphtha which
are processed in the following steps:
● Desulphurisation of feedstock
● Pre-reforming
● Convective reforming in an HTCR reactor
● Shift conversion
● Purification by Pressure Swing Adsorption (PSA)
BorsodChem MCHZ, Czech Republic
6,000 Nm3/h HTCR Topsøe Hydrogen Plant
A Case Story: 18 Months from Engineering to Operation
5
The heart of the HTCR technology is the reformer which consists of a vertical, refractory
lined vessel, containing the tube bundle with several tube assemblies. Below the vertical
section is a horizontal combustion chamber containing a single burner.
Each tube assembly consists of three tubes: Outermost is the flue gas tube where the heat
flux is adjusted by a proprietary flue gas control device. As the flue gas flows upwards
through the flue gas annulus, heat is transferred to the catalyst by convection. The catalyst is
placed in the annuli between the reformer tube and the centre tube. The centre tube through
which reformed gas leaves the reformer is inside the catalyst tube. Hereby the reformed gas
is cooled on its way out, and the heat is passed on to the catalyst.
Due to the efficient convection heat transfer, savings on feed and fuel of up to 20 %
compared to traditional reformer designs can be observed.
The convection principle allows for the design of compact reformers. The HTCR plant is to a
large extent supplied as a preassembled skid-mounted unit minimising erection time and
erection costs as compared to a traditional plant.
Reformer
Catalyst
Center
The layout was optimised for easy access to all parts of the plant while maintaining the small
footprint made possible by the compact design of the HTCR unit. The plot area of the plant is
approx. 18 *25 meters.
During the spring of 2004 orders were placed for main equipment (tube bundle, burner, PSA
unit, combustion air blower etc.).
A 3-D arrangement of an HTCR hydrogen plant is shown in Figure 5, illustrating the modular
construction.
Topsøe established cooperation with a contractor in the Czech Republic who was awarded
the contract for the detailed engineering, manufacturing and assembly of the skids in
contractor’s workshop and installation of the skids at plant site and pre-commissioning.
BorsodChem MCHZ, Czech Republic
6,000 Nm3/h HTCR Topsøe Hydrogen Plant
A Case Story: 18 Months from Engineering to Operation
8
The pictures in Figure 6 and Figure 7 show the progress during assembly of the skids in the
contractor’s workshop.
In the work shop the skids were fully assembled with vessels, heat exchangers, reactors,
valves instrumentation, piping etc. For transport reasons the skids are subsequently
separated by cutting the interconnecting piping.
BorsodChem MCHZ, Czech Republic
6,000 Nm3/h HTCR Topsøe Hydrogen Plant
A Case Story: 18 Months from Engineering to Operation
9
Also the suppliers of Topsøe’s proprietary equipment were visited frequently in order to
follow the progress and ensure a high quality of manufacturing. Figure 8 shows the tube
bundle during fabrication.
6. Site Installation
Assembly of the skids in the contractor’s workshop was completed in February 2005 and
after cutting, the interconnecting piping the skids were transported to the site as illustrated in
Figure 9.
Figure 10 shows the site during installation of the skids and illustrates the far from ideal
winter conditions under which the installation started.
After installation of the skids, the inter-connecting piping between the skids was installed
together with pre-fabricated piping, connecting the skids with the PSA, combustion air blower
and BFW pumps. The pre-fabricated staircase, ladders and platforms were bolted to the
skids. Also utilities (natural gas, demineralised water, nitrogen, instrument air and power
supply) were connected to the skids.
Outside the skids, the combustion air blower, the PSA adsorber vessels, the PSA off-gas
drum, the PSA valve skid and the stack were installed. Motor Control Center (MCC) and
Control System (DCS) panels were installed, and the power supply to the various motors
was pulled and connected. A number of loose delivered valves and instruments were
mounted and wired to the DCS which was installed and implemented in the control room.
The refractory-lined HTCR shell was mounted on the burner chamber in the skid structure
and the HTCR tube bundle was placed in the shell (Figure 11).
The plant was mechanically completed at the beginning of May 2005 after which pre-
commissioning activities took place.
BorsodChem MCHZ, Czech Republic
6,000 Nm3/h HTCR Topsøe Hydrogen Plant
A Case Story: 18 Months from Engineering to Operation
12
7. Pre-commissioning
During May 2005 pre-commissioning was carried out including the following activities:
The start-up procedure is easy and very straightforward. Heating of the reformer section is
done by once-through nitrogen whereas the desulphurisation section is heated up in natural
gas. Once the required temperatures in the reformer are achieved, nitrogen is replaced by
steam and natural gas and operating conditions are adjusted towards design. When the
capacity reaches 30 %, the Load and Temperature Management (LTM) system incorporated
in the control system will automatically adjust the capacity to the required level. Since all heat
input is supplied by just one burner, the plant responds very fast to changes in hydrogen
requirements.
The initial start-up was very smooth, and the reformer refractory was slowly dried out
following the prescribed temperature curve.
When the load was increased towards 100 %, it was seen that the burner flame was not
stable at high rates. A design error in the burner nozzle made by the burner supplier was
detected. Until a re-designed burner nozzle was fabricated and installed at the beginning of
August 2005 the plant operated at 80 % capacity. After the replacement of the burner nozzle,
the burner has been operating exactly according to specifications in the whole capacity
range.
A 72-hour test run was carried out in September 2005. Production and consumption figures
achieved during the test run are given in Table 1.
BorsodChem MCHZ, Czech Republic
6,000 Nm3/h HTCR Topsøe Hydrogen Plant
A Case Story: 18 Months from Engineering to Operation
13
The data from the test run met or outperformed the flow sheet figures and confirmed the high
energy efficiency of the HTCR plant. Due to initial problems with the PSA switching valves,
the HTCR plant was only formally accepted by BorsodChem MCHZ following a new test run
in December 2005 after rectification of the PSA valves.
9. Operating Experience
BorsodChem’s HTCR hydrogen plant has now (October 2007) been in operation for 28
months.
The HTCR plant has operated practically continuously at 100 % capacity except for a few
scheduled shutdowns and a handful of unscheduled shutdowns caused by factors not related
to the HTCR plant. One of the shutdowns related to the before mentioned rectification of the
PSA valves.
It should be noted that BorsodChem MCHZ has maintained the existing number of operators
as each shift of two operators now operate both the existing hydrogen plant and the new
HTCR hydrogen plant. The feedback from BorsodChem MCHZ’s personnel has been very
positive with respect to operation of the HTCR plant: The HTCR plant is very easy to operate
and requires a minimum of attendance.
Start-up and shutdown of the HTCR plant is much easier than in the existing plant according
to the operators: A hot restart of the plant can be done in 2-3 hours; a procedure which
typically takes 15-20 hours in the existing plant. The Load and Temperature Management
system (LTM) is working very well and capacity can be increased fully automatically from 30-
100 % in approx. 1 hour.
Approximately 6 months after start-up a very slow but constant deactivation of the reformer
catalyst was noticed. By analysing gas samples it was detected that the natural gas used as
feedstock contains organic sulphur which was not known at the time the plant was designed.
In September 2006 a Co/Mo hydrodesulphurisation catalyst was installed, and a hydrogen
recycle stream was established in order to eliminate the continuous sulphur poisoning. At the
same time the reformer catalyst was replaced to re-establish full activity in the reformer.
The energy efficiency for the HTCR plant is even better with the new operating data com-
pared to the test run which can be ascribed to tuning in of the plant.
BorsodChem MCHZ, Czech Republic
6,000 Nm3/h HTCR Topsøe Hydrogen Plant
A Case Story: 18 Months from Engineering to Operation
15
10. Conclusion
Haldor Topsøe A/S has supplied a 6,000 Nm3/h HTCR hydrogen plant to BorsodChem
MCHZ in the Czech Republic. The HTCR plant was engineered, constructed and
commissioned in less than 18 months with start-up in June 2005. A test run was completed
in 2005 with production and consumption figures meeting or exceeding the design figures.
Since test run the plant has operated almost continuously at 100 % capacity and the very
high energy efficiency has been confirmed with an energy consumption of natural gas around
3.5 Gcal/1,000 Nm3 hydrogen.
The HTCR concept with only one burner providing the heat input for the plant has
demonstrated its ease of operation with very fast start-up and shutdown procedure and
adaptation to changes in hydrogen requirements. The Load and Temperature Management
system (LTM) provides a fully automatic operation of the plant between 30 and 100 % load
minimising operator involvement during operation. BorsodChem MCHZ’s operators and plant
personnel who also have operating experience from an existing conventional hydrogen plant
have confirmed the superiority of the HTCR technology and expressed their full satisfaction
with their HTCR hydrogen plant.