List of Physics and chemistry equipment products
- classification:Physics and chemistry equipment
841~855 item / All 15637 items
Reduce the workload from handling heavy objects! Here are five case studies that solved customer challenges! We are also accepting free consultations and tests tailored to your work!
- Other conveying machines
Strong cold wind from room temperature to -13°C! Depending on the usage environment, you can choose between the combo type or the separate type!
- Cooling system
April 10, 2024 (Wednesday) to April 12, 2024 (Friday) Notice of Participation in Nagoya Manufacturing World 2024
Sanwa Shiki Ventilator Co., Ltd. will be exhibiting at the 2024 Monozukuri World (Nagoya) held at Port Messe Nagoya. We will also be showcasing our large cooling fans and cool/warm ambient products. Date: April 10, 2024 - April 12, 2024 Opening: 10:00 AM Location: Nagoya Port Messe (Exhibition Hall 1) *Our booth: 19-1 We would be grateful if you could visit us if you have the time.
The strength is determined by the variance. Visualize quality variations through testing before mass production.
- Emulsifier/Disperser
- Vacuum degassing machine
- Dispersion/emulsification equipment/homogenizer
What are the reasons for changes in results from the lab to mass production? Causes and countermeasures for the deterioration of distributed quality during scale-up.
Despite obtaining good dispersion results in the lab, the challenge of unstable quality upon mass production occurs in many settings. The main cause of this is that the dispersion conditions are not replicated due to differences in scale. In lab equipment, the smaller size leads to higher energy density, making shear and flow more uniform, while in mass production equipment, the larger scale often results in insufficient dispersion energy at the same rotational speed and processing time. Additionally, differences in equipment structure and flow patterns can cause variations in the shear history and residence time experienced by particles, leading to differences in the dispersion state. Furthermore, simple scale-up does not ensure that critical parameters such as flow rate, residence time, and shear intensity match, making it difficult to reproduce the same results as in the lab. To address these challenges, it is essential to focus on process design based on dispersion energy density and flow conditions rather than merely increasing equipment size. By designing the system so that particles pass through the processing area under consistent conditions, it is possible to achieve reproducible dispersion quality even when the scale changes, as seen in inline continuous processing.
Resolve issues of not dissolving and clumping in advance. Test the dispersibility of the protein.
- Emulsifier/Disperser
- Vacuum degassing machine
- Dispersion/emulsification equipment/homogenizer
What are the reasons for changes in results from the lab to mass production? Causes and countermeasures for the deterioration of distributed quality during scale-up.
Despite obtaining good dispersion results in the lab, the challenge of unstable quality upon mass production occurs in many settings. The main cause of this is that the dispersion conditions are not replicated due to differences in scale. In lab equipment, the smaller size leads to higher energy density, making shear and flow more uniform, while in mass production equipment, the larger scale often results in insufficient dispersion energy at the same rotational speed and processing time. Additionally, differences in equipment structure and flow patterns can cause variations in the shear history and residence time experienced by particles, leading to differences in the dispersion state. Furthermore, simple scale-up does not ensure that critical parameters such as flow rate, residence time, and shear intensity match, making it difficult to reproduce the same results as in the lab. To address these challenges, it is essential to focus on process design based on dispersion energy density and flow conditions rather than merely increasing equipment size. By designing the system so that particles pass through the processing area under consistent conditions, it is possible to achieve reproducible dispersion quality even when the scale changes, as seen in inline continuous processing.
From October 29 (Tuesday) to 31 (Thursday), 2024! We will be exhibiting small ultrasonic dispersion devices and ultrasonic generators!
- Emulsifier/Disperser
- Powder Supply Device
- Dispersion/emulsification equipment/homogenizer
What is decentralized process design? Key points for stabilizing quality.
In dispersion engineering, stable quality cannot be achieved solely based on the performance of the equipment. What is important is the overall design of the process, taking into account material properties and process conditions. This is referred to as dispersion process design. Dispersion quality is determined not only by the strength of shear but also by multiple factors such as flow state, residence time, and method of input. If these conditions are not properly designed, localized agglomeration or variation can occur, making it difficult to maintain stable quality. For example, poor wetting during powder input or the occurrence of stagnant areas due to flow bias can lead to clumping or dispersion issues. Additionally, even if the shear energy is sufficient, if it does not act uniformly on all particles, differences in dispersion state will arise. Therefore, in dispersion processes, it is crucial to design "flow," "shear," and "processing time" as an integrated system. This allows for all particles to receive the same dispersion history, achieving uniform and highly reproducible dispersion quality. In particular, inline continuous processing has the advantage of maintaining consistent conditions within the flow, making it easier to ensure reproducibility in process design. Dispersion process design is a key concept for stabilizing quality and successfully scaling up.
Adjustable Bolt Mounted 5-Wheel Swivel Caster Transport Cart 150kg (58-78mm)
- Stainless steel container
Not just environmentally friendly, but also achieving domestic integrated production and low prices.
- Stainless steel container
About 85% is consumed by the power of the compressor! Replacing the refrigerant often involves sacrifices in comfort and air conditioning effectiveness.
- Mixer/agitator
Reduction of electricity and partial improvement of the environment! Improved thermal conductivity through fine particle dispersion.
- Mixer/agitator
Based on the hearing content, we will create an annual reduction simulation!
- Mixer/agitator
Introducing the process of work from removing the refrigerant to applying the moisture treatment!
- Mixer/agitator
Easy installation possible! It can reduce power consumption by 10-30% and is expected to decrease CO2 emissions as well.
- Other air conditioning equipment
- Refrigerators and freezers
Air conditioning, refrigeration, and freezing account for about 40% of electricity consumption! How will you achieve energy savings in these areas?
- Mixer/agitator
Powerfully agitating the refrigerant! We aim to reduce power consumption by 10 to 30%.
- Mixer/agitator
Major companies are also rapidly adopting it! Introducing the reduction rates for air conditioning units, refrigerators, and freezers!
- Mixer/agitator
Information on whether reductions will be made from the day of implementation and compatibility with pipe sizes is also included!
- Mixer/agitator
No running costs or maintenance required! This product has been selected as eligible for subsidies.
- Other air conditioning equipment
- Refrigerators and freezers