The SCR denitration catalyst detection test
bench is a device designed and developed to meet the wear strength detection of
SCR denitration catalysts. The main target customers of this device are thermal
power plants, enabling customers to conveniently and accurately detect the wear
resistance performance of catalyst modules, and providing accurate experimental
data for the design, production, and use of catalysts in flue gas
denitrification.
This test bench is designed as a horizontal
structure, and the main structure of the detection device is a horizontally
placed air duct. A vortex air pump is installed at the front end of the air
duct to provide power, and air is blown into the pipeline from the inlet by the
vortex air pump. There are two rectangular sample compartments arranged in
front and back on the pipeline for placing test catalyst samples. There is a
feeding port for abrasive (quartz sand particles) between two sample chambers.
The abrasive is injected into a horizontally placed air duct at a constant rate
through the feeding port and carried downstream by the airflow generated by the
vortex air pump. The airflow with abrasive passes through the pores in the
middle of the catalyst module in the downstream test sample chamber to polish
the catalyst module. The catalyst powder under wear is carried away by the
airflow, so the reduced mass of the test sample can indirectly reflect its wear
resistance. There is a set of abrasive separation system connected at the end
of the pipeline, and the separated abrasive falls into the bottom hopper, while
the airflow is discharged through the exhaust outlet.
The horizontally set air duct is equipped
with vortex flowmeter, pressure transmitter, anemometer and other detection
instruments to monitor and adjust the wind speed inside the pipeline, so as to
maintain a suitable and stable state of wind speed inside the pipeline in the
test bench.
The wear agent feeding mechanism consists
of a wear agent storage hopper, valves, feeding hopper, spiral feeder, etc. The
spiral feeder is driven by a variable frequency motor and can freely adjust the
speed, thereby freely controlling the speed of the wear agent entering the
pipeline.
Before the experiment begins, add an
appropriate amount of screened abrasive to the feeding hopper, compare the same
catalyst samples in the sample chamber and the test sample chamber, turn on the
fan, observe the flow meter, pressure transmitter, and anemometer, adjust the
fan frequency and air volume adjustment mechanism to achieve the required
stable values of air volume and air speed in the pipeline, adjust the abrasive
feeding screw to the appropriate speed and start it, so that the abrasive is
evenly added to the pipeline. The control system starts timing. When the set
time is reached, the control system automatically stops the feeding work of the
screw feeder, and the fan stops after a certain delay. The operator turns on
the pulse dust removal device, cleans all the abrasive adhered in the dust
collector into the abrasive collection box, takes it out and weighs it. Take
out the comparison sample and the test sample from the sample warehouse, and
weigh them separately. The concentration of the abrasive in the gas passing
through the test sample can be calculated based on the weight of the abrasive.
By comparing the weight difference between the test sample and the control
sample, the degree of wear of the catalyst block can be calculated, thereby
determining the wear strength of the catalyst.
The catalyst wear strength detection test
bench consists of a fan (vortex air pump), an air volume adjustment device, a
comparison sample chamber, an automatic feeding mechanism, a test sample
chamber, a wear agent collection device, a filter, and other main parts. The
test samples of this system are connected in series.
