20 Analytical Instrumentation


Titan Enterprises Analyses Solutions for Low Flow Liquid Measurement


The measurement of low fl ow is becoming widely used in many industries. However, the smaller the fl ow, the trickier it is to control and measure, and fi nding a suitable fl ow measuring technology at reasonable cost can prove challenging for both users and fl ow sensor manufacturers.


There is no set defi nition for ‘low fl ow’ in terms of measurement limits for fl uidics handling. However, low- fl ow applications encounter amplifi ed fl ow stability and performance issues not seen in larger fl ows. The minimal liquid volume being measured in low fl ows renders them highly sensitive, such that even the slightest disruptions in


process or ambient conditions can exert a substantial impact on fl ow stability.


Within the markets Titan Enterprises operates in, we consider low fl ow rates as those below 50 ml/min, with many customers seeking fl ow rates of between 2 and 20 ml/min.


Neil Hannay, Titan’s Senior R&D Engineer observes: “We are certainly seeing an increase in demand for low fl ow measurement technologies driven by various industries moving towards transporting heavily concentrated liquids, which are then diluted at the point of use. This translates into huge savings on transport and storage costs and also has a positive environmental impact.”


Whether cleaning fl uid additives, syrups and fl avourings for beer or soda, chemical additives for oil and fuel, paint pigments or administering drugs, low fl ow fl owmeters are required to dose these concentrated fl uids at the end process, dispensing the precise amount of liquid to the correct dilution.


As mentioned, measuring low fl ow is a challenging application to satisfy. The amount of energy available in low liquid fl ow is unlikely to be suffi cient to drive most mechanical fl owmeters to give linear results. By comparison, electronic fl ow meters can be limited by sensitivity, zero drift and slow response times. Here we analyse 5 types of fl ow meter - Ultrasonic, Turbine, Oval Gear, Thermal and Coriolis - and their suitability for low fl ow measurement:


As fl owmeters can be the most limiting component of a low fl ow fl uidic system, it is essential to choose the most suitable high-precision fl ow sensor for your application.


“We know there is a strong market for low fl ow meters and we are currently working with two international OEMs to develop a solution for measuring ultra-low fl ows using our oval gear technology and miniaturised gears,” says Neil.


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email: TALKING POINT Is biomass a sustainable energy source?


Biomass has long been regarded as a renewable and sustainable source of energy. Historically, it provided an eco- friendly alternative to fossil fuels, using organic materials like wood, crop residues, and animal manure. The key idea was that the CO2 offset by the CO2


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maintaining a carbon-neutral balance. However, modern developments and increased scale have raised signifi cant concerns about the sustainability of biomass energy.


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The modern large-scale utilisation of biomass energy introduces several challenges. A major issue is carbon emissions. While theoretically carbon-neutral, the entire lifecycle of biomass energy production—from cultivation to processing and transportation—can result in substantial greenhouse gas emissions. This undermines the carbon- neutrality claim and necessitates comprehensive lifecycle assessments to evaluate the true environmental impact.


Deforestation poses another signifi cant challenge. The growing demand for biomass, particularly wood, has led to unsustainable forestry practices. Large-scale deforestation contributes to biodiversity loss, soil degradation, and reduces forests’ carbon sequestration capacity, exacerbating climate change. Additionally, converting natural forests to monoculture plantations for biomass production can have detrimental ecological impacts, including reduced habitat complexity and soil fertility.


Land use and food security concerns are paramount. Allocating agricultural land for biomass crops can directly compete with food production, leading to higher food prices and potential shortages. This competition is particularly problematic in regions already facing food insecurity. Intensive agricultural practices required for biomass crops can also lead to soil erosion, water depletion, and increased use of fertilisers and pesticides, further degrading the environment.


released during biomass combustion was absorbed during the biomass growth phase,


Energy effi ciency is another concern. Biomass energy conversion processes, such as combustion, gasifi cation, and pyrolysis, often have lower effi ciency compared to other renewable energy sources like solar and wind. The energy yield from biomass can be comparatively low, making it a less attractive option in terms of energy output per unit of input.


To restore biomass as a sustainable energy source, several strategies must be implemented. Sustainable sourcing of biomass is crucial. This involves adopting responsible forestry practices, such as selective logging and reforestation, and utilising agricultural residues and non-food crops for biomass production. By ensuring that biomass is sourced sustainably, the negative impacts on forests and agricultural lands can be mitigated.


Advancements in biomass conversion technologies are essential for improving energy effi ciency and reducing emissions. Innovations in pyrolysis, gasifi cation, and anaerobic digestion can enhance the effi ciency of biomass energy systems and minimize their environmental footprint. For instance, pyrolysis can convert biomass into biochar, a stable form of carbon that can be used to improve soil health and sequester carbon.


Integrated energy systems can optimise the use of biomass in conjunction with other renewable energy sources. Combining biomass with solar or wind energy can provide a more stable and effi cient energy supply, reducing reliance on any single source and enhancing overall sustainability. Such integrated approaches can maximise resource utilisation and minimise environmental impacts.


Policy and regulatory frameworks play a crucial role in ensuring the sustainability of biomass energy. Governments and international bodies need to implement stringent policies that promote sustainable biomass production and usage. This includes setting clear emission standards, encouraging sustainable land use practices, and providing incentives for


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research and development in advanced biomass technologies. Additionally, international cooperation and knowledge-sharing can help disseminate best practices and drive global efforts towards sustainable biomass energy.


A detailed exploration from Low-Tech Magazine provides valuable insights into making biomass energy sustainable again. It emphasises the importance of using biomass waste instead of dedicated crops, reducing the pressure on arable land. It also highlights the benefi ts of decentralised biomass energy systems, which can reduce transportation emissions and improve effi ciency by using local resources. Furthermore, it advocates for the adoption of low-tech, low-cost solutions that are accessible and practical for various regions, particularly in developing countries.


While biomass has the potential to be a sustainable energy source, its current practices require signifi cant improvements to meet environmental and social sustainability standards. Addressing the challenges related to carbon emissions, deforestation, land use, and energy effi ciency is essential for revitalising biomass as a key component of the renewable energy mix. Sustainable sourcing, technological advancements, integrated energy systems, and robust policies are crucial for achieving this goal. By innovating and adopting practices that ensure the sustainable use of biomass, we can harness its potential to contribute to a greener and more sustainable future.


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