Last Updated: Aggregation Period:Sep 17, 2025~Oct 14, 2025
This ranking is based on the number of page views on our site.
Last Updated: Aggregation Period:Sep 17, 2025~Oct 14, 2025
This ranking is based on the number of page views on our site.
Last Updated: Aggregation Period:Sep 17, 2025~Oct 14, 2025
This ranking is based on the number of page views on our site.
1~15 item / All 68 items
Lithium-ion electrolyte injection experiment device for small batteries
We design and manufacture various production equipment and experimental devices for lithium-ion (Li-ion) and nickel-metal hydride (Ni-MH) batteries. We accommodate cylindrical, rectangular, and laminated types. Depending on the process, we have demo and experimental machines available, so please feel free to contact us.
For over 30 years, Quanser has specialized in the development of systems and solutions for cutting-edge education and research in control.
Quanser's experimental teaching materials are ready to use as soon as they are taken out of the box. The systems feature an open architecture and modular design, allowing for a wide range of mechatronic experimental configurations due to the commonality of the base unit and peripheral devices across each system. Additionally, by adding or removing various modules, you can expand the functionality of the invested laboratory equipment. Even more importantly, it enables students to create a diverse range of challenges that they should explore. Furthermore, Quanser's comprehensive lineup of mechatronics and control experiments is robust enough to meet the demands of enthusiastic and motivated students.
We have achieved a compact roll-to-roll device in a size of 1.3m × 0.8m, which was previously only possible with large-scale equipment! It enables a wide variety of processing.
We would like to introduce our "Tabletop Roll-to-Roll Experimental Machine." With a compact design, it can be installed on laboratory workbenches or in draft chambers, and we can offer it at a low price due to a minimal equipment configuration. Thanks to the roll-to-roll processing technology we have developed over the years, the processing unit can accommodate a wide variety of treatments. Additionally, by swapping out the processing units, it can support various types of processing. We have a proven track record in the battery and 5G industries. 【Features】 - Compact design allows installation on laboratory workbenches or in draft chambers - Low-cost proposals possible due to minimal equipment configuration - A wide variety of treatments can be performed by exchanging processing units *For more details, please refer to the PDF document or feel free to contact us.
Spiral Pump Experimental Device
This is a device for extensively experimenting with the operational characteristics of a centrifugal pump. It operates a pump with an internal observation capability using a variable speed motor, drawing water from a tank and circulating it back to the tank through a strainer, valve, and venturi tube. The impeller section is designed with a transparent cover for observation. The pump's rotational speed (rev/min), torque (N.m), output (W), differential pressure in the venturi tube (△P), and inlet and outlet pressures of the pump are digitally displayed, allowing for a wide range of experiments by changing operating conditions through valve adjustments. Additionally, by utilizing the optional data automatic collection system VDAS (sold separately), various data can be collected and analyzed in real-time on a PC (sold separately).
Series and parallel vortex pump experimental apparatus
This is a device used to experiment and research the operating characteristics of one or two spiral pumps (connected in series or parallel) over a wide range. Two variable-speed motors operate each pump, which can be observed internally, drawing water from a tank and circulating it back to the tank through a strainer, valve, and venturi tube. The impeller section is designed with a transparent cover for observation. The pump's rotational speed (rev/min), torque (N.m), output (W), pressure differential in the venturi tube (△P), and inlet/outlet pressure of the pump are digitally displayed, allowing for a wide range of experiments by changing operating conditions through valve adjustments. Additionally, by utilizing the optional data automatic collection system VDAS (sold separately), various data can be collected and analyzed in real-time on a PC (sold separately).
Pipe friction loss experimental apparatus
The friction loss of a horizontal small-diameter pipe (φ3xL524mm) will be measured, and the determination of the critical flow transition point and critical Reynolds number will be conducted through the ranges of laminar and turbulent flow. In the low flow experiments, an elevated tank and manometer will be used, while in the high flow experiments, the water supply pipe will be directly connected to the apparatus, and the differential pressure will be measured using a digital differential pressure gauge. The flow rate will be controlled by a needle valve at the downstream end of the test pipe, and water will be supplied using an H1F hydraulic bench (sold separately), although existing water supplies can also be used.
Helshow experimental device
This is an experimental apparatus for visualizing flows similar to potential flow, which creates flow patterns using colored water to observe the flow around various shapes. Additionally, the four valves can control two water supply holes and two drainage holes located near the center to create streamlines. *It is recommended to supply water to the apparatus from a stable source such as an elevated tank.
Piping energy loss experimental device
A compact tabletop experimental device that compares the energy losses of three types of bent pipes, sudden expansion, and contraction pipes, consisting of a multi-tube manometer and a flow control valve. The experiment requires an H1F hydraulic bench (sold separately) for water supply and flow measurement.
Reynolds number and transition flow experimental apparatus
We will demonstrate the transition from laminar flow to turbulent flow and compare the critical Reynolds number in transitional flow with theoretical values. The setup consists of a glass head tank and glass tubes, an ink tank, and an injector, allowing us to observe the behavior of the flow using dye while adjusting the flow rate with a drainage valve located at the bottom of the apparatus. We will experiment to see what happens when the flow changes from laminar to turbulent. Additionally, experiments can be conducted using an optional heater module (sold separately) to vary the water temperature and viscosity.
Water Hammer (Hydraulic Shock) Experimental Device
This is an experimental device for understanding the significance of water hammer and cavitation that occur in pumps and hydraulic turbine systems. It consists of a 61-meter long coiled copper pipe, a solenoid valve, pressure sensors and Bourdon tube pressure gauges, a floating flow meter, a flow control valve, and a bypass valve. Water is supplied to a copper pipe with an inner diameter of 12.7 mm, and the flow rate inside the pipe is adjusted using the flow meter and bypass valve. The control box has a solenoid valve operation switch and a BNC terminal for pressure measurement, which can be connected to an oscilloscope (sold separately) to observe the behavior.
Series and parallel pump experimental apparatus (constant speed)
We will experiment with the operation characteristics of two centrifugal pumps in series and parallel operation, or the performance of a single pump. The equipment consists of electric motors (constant speed) that drive each pump individually, a transparent acrylic water storage tank and valves, and a floating flow meter, with pressure gauges placed at the pump inlet and outlet. The impeller part of each pump is designed with a transparent cover for observation, and cavitation demonstrations can also be conducted. *There is also a PC data collection system type available with an experimental setup similar to H52. H53V Series and Parallel Pump Experimental Equipment (Variable Speed) H53V allows for variable speed control of the pump motor, displaying rotational speed (rpm), torque (N.m), power (W), pressure (bar), flow rate (L/s), and temperature digitally. Additionally, the accompanying software enables real-time data collection and analysis on a PC (sold separately).
Cavitation experiment apparatus
This is a device for efficiently experimenting with the causes and phenomena of cavitation generated by pumps and turbines. The device consists of a water tank, an electric pump, a flow control valve, a flow meter, a pressure gauge upstream of the Venturi tube and a pressure gauge at the throat, and a Venturi tube (with a transparent window). It allows for easy observation of the occurrence of cavitation while adjusting the flow rate, helping to understand how cavitation begins based on the theory calculated from the temperature, density, and pressure of the water and experimental results.
Aerodynamics experimental apparatus
This is a small wind tunnel experimental device with a test section of 100x50mm. It has a very compact design, allowing for easy movement and storage when not in use. It can be used in a wide range of experiments in combination with auxiliary equipment for demonstrations in lectures, practical training in laboratories, and student research projects. The air discharged from the blower flows into the test section through the rear duct, upper chamber, honeycomb, and converging section. The wind speed is derived using Bernoulli's theorem from the pressure in the test section and the chamber. This device has eight types of experimental setups available for separate purchase, ranging from AF11 to AF18, which can be easily attached to AF10. Each experimental setup can be purchased individually, and you are encouraged to consider configurations that meet your needs.
Series and parallel pump experimental apparatus (variable speed)
This is a compact tabletop experimental device for testing the operation characteristics of two centrifugal pumps in series and parallel operation, or a single pump. The device consists of electric motors (variable speed) that drive each pump individually, a transparent acrylic water storage tank and valves (for each pump inlet and outlet), pressure sensors (for each pump inlet and outlet), and a flow sensor (for the drainage outlet). The impeller part of each pump is designed with a transparent cover for observation, allowing for demonstrations of cavitation. The included control box allows for variable adjustment of motor speed and digitally displays rotation speed (rpm), torque (N.m), output (W), pressure (bar), flow rate (L/s), and temperature. Additionally, the included data acquisition software VDAS can collect and analyze various data in real-time on a PC (sold separately). *There is also an analog type of experimental device similar to the H53V. H52 Series and Parallel Pump Experimental Device (Constant Speed) The H52 has a constant speed pump motor and is composed of an analog pressure gauge and a float-type flow meter.
Seiki experimental device
It is a small water channel made of reinforced plastic, which allows for the installation of different weirs to control the flow and measure and analyze the flow rate. The device is installed on a hydraulic bench H1F (sold separately) to supply water. It comes with a rectangular weir, two types of V-shaped weirs, and a height gauge. For the experiment, a hydraulic bench H1F (sold separately) for water supply and flow measurement is required.
