Company Profile
Shandong Synergy Tech Co., Ltd is a leading manufacturer of chemical materials, adsorbents, desiccants, and catalysts in Petroleum and petrochemical industry. Our company, founded in 2015, is situated in Zibo, Shandong, a renowned city for its classical heavy industries. We operate on a 30 mu area, with a registered capital of 16 million yuan and a dedicated team of 115 employees, including 6 senior engineers and 10 technical engineers.
At our company, we are committed to the development and production of the most advanced, reliable, and cost-effective materials, catalysts and adsorbents. We have successfully established partnerships with renowned international companies such as China National Petroleum Corporation, Sinopec, and Petrochemical Industry Companies from Russia, Germany, Britain, Kuwait, Saudi Arabia, Iran, Syria, Jordan, South Korea, New Zealand, Thailand, Indonesia, the Philippines, and other countries worldwide.
Why choose us?
High quality
Our products are manufactured or executed to very high standards, using the finest materials and manufacturing processes.
Professional team
Our professional team collaborate and communicate effectively with one another, and are committed to delivering high-quality results. They are capable of handling complex challenges and projects that require their specialized expertise and experience.
Long warranty
The long-term warranty is designed to give consumers more confidence that their purchases and services will continue to be valid.
Rich experience
Dedicated to strict quality control and attentive customer service, our experienced staff is always available to discuss your requirements and ensure complete customer satisfaction.
What is CO Removal
Carbon monoxide removal catalyst, also called CO removal catalyst and Hopcalite catalyst, is mixture of Copper Oxide and Manganese Dioxide, Carbon monoxide removal catalyst is used to convert carbon monoxide into carbon dioxide . With advantage of low cost and high efficiency, XINTAN Carbon monoxide removal catalyst is widely applied in fire escape equipment, diving devices , air-purifying respirator, environmental protecting ,mine rescue, exhaust treatment other fields . We have gained favor of domestic and foreign customers. Although primarily used to converting carbon monoxide to carbon dioxide, Hopcalite catalysts is also used to remove ethylene oxide and other VOCs as well as ozone from gas streams.
Carbon monoxide (CO) is a kind of carbon oxide compound. It is usually a colorless, odorless and tasteless gas with strong toxicity. The lowest lethal concentration of human inhalation is 5000ppm (5 minutes).
In the petrochemical industry, semiconductor industry, coal mines, refuge chambers, submarines, and smoking rooms, mixed gases containing carbon monoxide will be produced. For personal safety or process purification needs, the carbon monoxide should be disposed of. At present, the mature methods for treating carbon monoxide include absorption method, incineration method, and catalytic oxidation method.
For high-concentration carbon monoxide, copper-ammonia complex solution can be used for absorption. This method has high equipment construction costs, and the tail gas also contains relatively low-concentration carbon monoxide.
For high-concentration carbon monoxide, the incineration method can also be used for incineration. This method requires the construction of a torch and corresponding supporting systems, and the construction cost is high.
For gases containing carbon monoxide with a low concentration, the commonly used method is the catalytic oxidation method, which oxidizes carbon monoxide to carbon dioxide at a lower temperature. This method does not require the construction of complex devices and the operating cost is relatively low. Catalytic oxidation method to remove carbon monoxide is an economical choice.
CO Removal of Product Features
The catalyst has high strength, and the average crushing strength is greater than 45N/cm;
The specific surface area is high, with a specific surface area as high as 180-240m2/g. A large number of microporous structures are distributed inside the catalyst, which can effectively absorb carbon monoxide and carry out catalytic oxidation;
The catalyst can withstand high temperature, does not contain flammable components and volatile components, there is no risk of burning at high temperature, which is safe to use, and will not cause secondary pollution;
The content of active ingredients is as high as more than 80%, the performance is stable, the life is long, and it is not easy to lose;
The specific gravity of the catalyst is low, and the high specific surface area makes the specific gravity of the catalyst only 0.68g/cm3, and the weight quantity of the catalyst required to process the same air volume will be reduced by 1/3;
The raw materials and production process of the product are completely independent and controllable, and can be supplied stably for long-term.
Product parameters
|
Parameter |
Result |
|
Diameter(mm) |
1.1±0.1mm or 3mm |
|
MnO₂/CuO Ratio |
3:2 or 2:1 |
|
Length |
5-10mm |
|
Bulk density |
0.78-1.0 g/ml |
|
Ball-milling Strength |
60%min |
1% CO mixture gas is made into 1.6 Pa saturated solution through partial pressure of water vapor , passing through catalyst layer with diameter of 26mm and thickness of 27mm at a flow rate of 2300ml/min in environment of 50±0.2℃ , CO concentration in the gas outlet was not higher than 0.04%.
Packing: 35 kg into Iron bucket with plastic bags
Storage and Transportation: Carbon monoxide removal catalyst is sensitive to moisture. Keep it in dry envoironment.
Why focus on carbon dioxide for climate stabilization
If emissions of multiple greenhouse gases (carbon dioxide, methane, nitrous oxide, and hydrofluorocarbons) are causing the climate crisis, why does this primer focus only on removing CO2 from the atmosphere? The answer lies in the properties of greenhouse gases once they reach the atmosphere as well as their relative atmospheric concentration.
Under a common measure of cumulative long-term warming impacts, carbon dioxide is the most important greenhouse gas emitted by human activity (Edenhofer et al., 2014). This measure takes into account the total emission rate of the gas, as well as its atmospheric lifetime and ability to absorb incoming solar radiation (Myhre et al., 2013). Carbon dioxide is a very long-lived gas, with carbon cycle impacts that can last centuries to millennia (Archer et al., 2009). By contrast, other important greenhouse gases, commonly referred to as short-lived climate pollutants (SLCPs), have much shorter atmospheric lifetimes closer to 10 to 100 years. While the atmospheric concentration of CO2 may already seem low at around 410 parts per million (ppm), its concentration is significantly larger than the next-most-abundant greenhouse gas, methane, which is around 2 ppm (Saunois et al., 2020). The relative abundance of CO2, its long atmospheric lifetime, and its chemical reactivity make CO2 an appealing candidate for removal. Furthermore, the global carbon cycle flux of CO2 (its rate of movement between reservoirs) is substantially larger than that of any other gas, which allows for more biological, geological, and chemical CDR interventions to be explored.
An estimate of the scale of hard-to-avoid emissions
The following is a by-sector analysis based on multiple studies to estimate a range of values for global hard-to-avoid emissions. For each type of emission, the higher end of the range is based on the lowest emissions values of a set of socioeconomic model trajectories; the lower end is based on a direct sector-specific feasibility assessment. The exception is the lower end of agriculture and waste N2O emissions, which is based on a limiting model trajectory. This is because agricultural output is predominantly a social justice, not physical, constraint, relying on society-wide assumptions that cannot be calculated purely on a feasibility basis. Whenever more detail was available, we rounded results from analyses we used to the nearest 0.1 GtCO2eq. A measure of “CO2eq hard-to-avoid emissions” is used to compare across the different greenhouse gas emission sources and normalize to an equivalent warming from CO2. A large part of our analysis is based on the IPCC’s Low Energy Demand (LED) scenario (Grübler et al., 2018), which we evaluate because it estimates an upper bound for hard-to-avoid emissions by minimizing CDR use while limiting warming to 1.5º C. To meet these conditions, this model makes a case for the feasibility of decarbonizing the electricity and industrial sectors. Despite a massive 40% reduction of energy consumption compared to today, LED suggests significant hard-to-avoid emissions will remain, mainly in the agriculture and transportation sectors. The IEA 2020 Energy Technology Perspectives report is used to further justify decarbonization feasibility assessments.
Agriculture and waste nitrous oxide: The partial evaporation of fertilizer applied to soils and manure left on pasture, necessary for maintaining food security, are the largest contributors to global anthropogenic nitrous oxide (N2O) emissions (Tian et al., 2020). While fossil fuel and industrial sources of N2O could be decreased, given necessary waste processing practices and the massive area of global farmland and pasture, it is not feasible to prevent these emissions from reaching the atmosphere (e.g., through domes or other technological improvements). The lifetime of N2O is greater than a century, so its global warming potential at 100 years is used to normalize to CO2eq.
Why won’t constant methane emissions need continuous CDR offsetting? Substantial emissions of methane (on the order of tens of MtCH4/yr), including from livestock production, rice cultivation, and landfills, will also likely remain throughout this century (Saunois et al., 2020). Over a long timescale (longer than methane’s ~12-year lifetime), constant methane emissions are balanced by atmospheric methane degradation and do not accumulate in the atmosphere or contribute to increasing warming (Cain, 2018). For this reason, while these constant methane emissions can be considered hard to avoid, they do not factor into our estimate of the hard-to-avoid CO2eq emissions that require ongoing CDR (Allen et al., 2018). Note, however, that offsetting this constant level of methane emissions through a one-time “pulse” of CDR would reduce global temperature.
Carbon dioxide removal and the carbon cycle
To understand the relevance of CDR to climate change, it is necessary to put CDR in the context of the global carbon cycle (Keller et al., 2018). The carbon cycle concerns the amount and flux of carbon – in various chemical states – between the ocean, terrestrial biosphere (or “land”), atmosphere, and geologic formations in the Earth (Figure 1.2a; Friedlingstein et al., 2019). Large-scale CDR deployment will directly affect levels of atmospheric carbon, but also create feedback loops that alter fluxes among other carbon reservoirs. For this reason, removing 1 GtCO2 from the atmosphere will ultimately reduce atmospheric CO2 concentrations by less than 1 Gt. To understand how CDR perturbs the carbon cycle, we need to characterize its effects on fluxes between reservoirs as well as how carbon is stored in reservoirs. Moreover, even if net-zero emissions are achieved by the end of this century through the use of CDR to offset hard-to-avoid emissions, the particular emission and CDR pathways may leave long-lasting harmful imprints on parts of the global climate system, such as ocean acidity or ecosystem health (Mathesius et al., 2015).
How Does CO Scrubbing Work
Carbon monoxide is scrubbed from the air using a catalytic process. The reaction is exothermic, which means heat generates as a by-product.
The MARCISORB CO Cartridge is a highly active transition metal oxide catalyst formulated for the oxidisation of contaminants such as CO. Air is passed through the MARCISORB CO Cartridge, converting carbon monoxide into CO2 and H2O. The carbon dioxide produced is then removed by MARCISORB CO2.
Portable refuge chambers only require one CO cartridge. The cartridges are also effective at removing other gases, such as ethylene oxide, hydrogen, and ethane.
Where does carbon monoxide come from
Carbon monoxide is a byproduct of burning or the process of combustion. It’s made from:
●Car and truck engines.
●Small gasoline engines.
●Fuel-burning space heaters (not electric).
●Gas stoves or ranges.
●Grills.
●Lanterns.
●Heating systems, including home furnaces.
●Burning charcoal, kerosene, propane or wood.
What’s the difference between carbon monoxide and carbon dioxide
Carbon monoxide (CO) is a compound made of one carbon atom bonded to one oxygen atom. Carbon monoxide doesn’t naturally form in Earth’s atmosphere. It forms when certain components burn (combustion). Oxygen is a key component of combustion, in addition to fuels like oil and natural gas. When the oxygen level is low in an area where something’s burning, carbon monoxide forms as a byproduct of the chemical reaction.
Carbon dioxide (CO2) is a compound made of one carbon atom bonded to two oxygen atoms. Carbon dioxide forms naturally in our environment. When you breathe in oxygen, your body releases carbon dioxide.
Top Tips for Carbon Monoxide Safety
Install carbon monoxide (CO) alarms. Make sure there is one on every level of your home, especially around sleeping areas.
●Test CO alarms every month. Replace them according to the manufacturer’s instructions.
●Avoid using gas appliances inside your home. Use generators and grills outside of your home, away from windows and doors. Warm up vehicles outside of your garage.
●In a CO emergency, leave your home immediately. If the CO alarm sounds, quickly leave your home. Move to a safe location outside where you can breathe in fresh air before you call for help.
Our Factory
Shandong Synergy Tech Co., Ltd is a leading manufacturer of chemical materials, adsorbents, desiccants, and catalysts in Petroleum and petrochemical industry. Our company, founded in 2015, is situated in Zibo, Shandong, a renowned city for its classical heavy industries. We operate on a 30 mu area, with a registered capital of 16 million yuan and a dedicated team of 115 employees, including 6 senior engineers and 10 technical engineers.
FAQ
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