List of Scientific and Physics Equipment products
- classification:Scientific and Physics Equipment
9601~9615 item / All 35966 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 best finish in the history of insect traps.
- Stainless steel container
The M761WS-512UMBS is an integrated device that combines a tipping bucket rain gauge, temperature sensor, humidity sensor, and barometric pressure sensor.
- Stainless steel container
Can be used without cooling devices or reflectors! Compatible with MINI series G14-25 and G7-50.
- Other heaters
[Data Published] Heating efficiency changes significantly with medium-wave infrared - A technical explanation of the essential differences between near-infrared and far-infrared.
Leister offers not only plastic welding machines and hot air generators but also "mid-infrared heaters" as part of its product lineup. When selecting infrared heaters based solely on "output," it can lead to unexpected power loss and quality issues. The key factor is the compatibility of materials and wavelengths. Many industrial materials such as resins, paper, wood, and water have been confirmed to have high absorption efficiency in the mid-wave infrared range. On the other hand, near-infrared has a fast response time but is peakier, while far-infrared has a broad range but a slow response time, making it prone to energy loss due to continuous power supply. In actual comparative tests, it has been reported that the power consumption can differ by about twice to achieve the same heating results. This affects not only electricity costs but also heating time, equipment capacity, and finished quality. This document organizes the differences between near-infrared, mid-wave, and far-infrared, and technically explains why the 2.6μm mid-wave infrared heater is a rational choice for many industrial applications. If you want to reconsider your heater selection, please refer to the technical materials and the product pages for infrared heaters.
A compact all-in-one weather sensor for measuring temperature, relative humidity, and atmospheric pressure.
- Stainless steel container
A compact all-in-one weather sensor for measuring wind direction and wind speed.
- Stainless steel container
Rust removal, dirt removal, surface modification... Easy and speedy with lasers!
- Other cleaning machines
Quickly remove rust and dirt! Achieve efficiency in metal processing with laser technology!
- Other cleaning machines
Instantly remove rust and dirt with lasers! Streamlining surface treatment of aerospace components.
- Other cleaning machines
Modular and flexible infrared heater! Fast response time for accurate temperature.
- Other heaters
[Data Published] Heating efficiency changes significantly with medium-wave infrared - A technical explanation of the essential differences between near-infrared and far-infrared.
Leister offers not only plastic welding machines and hot air generators but also "mid-infrared heaters" as part of its product lineup. When selecting infrared heaters based solely on "output," it can lead to unexpected power loss and quality issues. The key factor is the compatibility of materials and wavelengths. Many industrial materials such as resins, paper, wood, and water have been confirmed to have high absorption efficiency in the mid-wave infrared range. On the other hand, near-infrared has a fast response time but is peakier, while far-infrared has a broad range but a slow response time, making it prone to energy loss due to continuous power supply. In actual comparative tests, it has been reported that the power consumption can differ by about twice to achieve the same heating results. This affects not only electricity costs but also heating time, equipment capacity, and finished quality. This document organizes the differences between near-infrared, mid-wave, and far-infrared, and technically explains why the 2.6μm mid-wave infrared heater is a rational choice for many industrial applications. If you want to reconsider your heater selection, please refer to the technical materials and the product pages for infrared heaters.
We will introduce examples of adoption by manufacturing companies, starting with "emulsification of flavor oils"!
- Emulsifier/Disperser
Introducing examples of adoption, starting with "dissolution of film-coated tablet raw materials in water"!
- Emulsifier/Disperser
We will introduce examples of adoption by food processing companies, starting with "a mixture of soy milk and nigari"!
- Emulsifier/Disperser
Ultra-compact cubic infrared radiation! Requires almost no maintenance and boasts reliable performance.
- Other heaters
[Data Published] Heating efficiency changes significantly with medium-wave infrared - A technical explanation of the essential differences between near-infrared and far-infrared.
Leister offers not only plastic welding machines and hot air generators but also "mid-infrared heaters" as part of its product lineup. When selecting infrared heaters based solely on "output," it can lead to unexpected power loss and quality issues. The key factor is the compatibility of materials and wavelengths. Many industrial materials such as resins, paper, wood, and water have been confirmed to have high absorption efficiency in the mid-wave infrared range. On the other hand, near-infrared has a fast response time but is peakier, while far-infrared has a broad range but a slow response time, making it prone to energy loss due to continuous power supply. In actual comparative tests, it has been reported that the power consumption can differ by about twice to achieve the same heating results. This affects not only electricity costs but also heating time, equipment capacity, and finished quality. This document organizes the differences between near-infrared, mid-wave, and far-infrared, and technically explains why the 2.6μm mid-wave infrared heater is a rational choice for many industrial applications. If you want to reconsider your heater selection, please refer to the technical materials and the product pages for infrared heaters.
Enhancing flexibility with a compact module! Excellent low maintenance and robustness.
- Other heaters
[Data Published] Heating efficiency changes significantly with medium-wave infrared - A technical explanation of the essential differences between near-infrared and far-infrared.
Leister offers not only plastic welding machines and hot air generators but also "mid-infrared heaters" as part of its product lineup. When selecting infrared heaters based solely on "output," it can lead to unexpected power loss and quality issues. The key factor is the compatibility of materials and wavelengths. Many industrial materials such as resins, paper, wood, and water have been confirmed to have high absorption efficiency in the mid-wave infrared range. On the other hand, near-infrared has a fast response time but is peakier, while far-infrared has a broad range but a slow response time, making it prone to energy loss due to continuous power supply. In actual comparative tests, it has been reported that the power consumption can differ by about twice to achieve the same heating results. This affects not only electricity costs but also heating time, equipment capacity, and finished quality. This document organizes the differences between near-infrared, mid-wave, and far-infrared, and technically explains why the 2.6μm mid-wave infrared heater is a rational choice for many industrial applications. If you want to reconsider your heater selection, please refer to the technical materials and the product pages for infrared heaters.