Laboratory Equipment

Why Choose Us

Kelinan has inherited the original team and products of Wuxi Yabo Textile Equipment Co., Ltd., with more than 20 years of production experience, and has been committed to the dyeing machine industry, making a perfect combination from laboratory equipment to large-scale equipment in the production workshop.

Wide Product Range
Overflow dyeing machine, laboratory dyeing machine, drying and setting machine, physical testing equipment.

Large Scale
Our factory is divided into two parts: the laboratory equipment production factory is in Wuxi City, Jiangsu Province, covering an area of 1,800 square meters and with more than 30 people in the workshop. The large-scale dyeing machine production factory is located in Zibo City, Shandong Province, covering an area of 15,000 square meters and with more than 70 people in the workshop.

Wide Range of Applications
Our products are widely used in textile factories, dyeing and finishing factories, dye factories, auxiliary factories, fabric trading companies, research institutes, etc.

Advanced Equipment
We have professional production equipment such as laser machine, bending machine, automatic welding machine, rolling machine, automatic polishing machine, fully automatic pipe bending machine, laser pipe cutting machine.

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What is Laboratory Equipment

Textile Testing Machine is used to test textile fiber, yarn and textile products properties including abrasion, pilling, air permeability, WVP, colorfastness, tensile strength, burst strength, twist and etc. If you want to know the specifications and prices of Laboratory Equipment, please contact us!

Advantages of Laboratory Equipment

Reduced Maintenance Issues
While purchasing a new piece of laboratory equipment may require a significant up-front cost, doing so could ultimately save you money over time. If your old equipment experiences frequent issues and breakdowns, the cost to constantly repair it will likely rack up a considerable bill.
Plus, frequent breakdowns result in lost productivity, which increases the potential for financial loss. By purchasing new, properly working equipment, you may end up saving more money than sticking with your old, faulty lab appliances.

Increased Safety
Another key benefit of upgrading your lab equipment is the increased safety that more advanced equipment can provide. Outdated equipment is often not equipped with the latest, most advanced safety features that have developed over time. To create the safest laboratory environment possible, it is often advantageous to invest in newer, more updated equipment.

Enhanced Integration
Upgrading laboratory equipment can also improve integration. As software and laboratory systems rapidly advance, the process of upgrading newer software on older equipment can prove exceedingly difficult and, in some cases, impossible. Such integration challenges can prevent laboratories from upgrading their software packages and may limit their operational choices. By upgrading your lab equipment, you can achieve the many benefits of a fully integrated system—such as improved productivity and greater ease of gathering and storing information.

Improved Accuracy
In the industry of science, optimal accuracy is essential. Even minute inconsistencies can pose a significant problem. Utilizing older, outdated equipment, however, often reduces the accuracy of experiments and tests. To ensure that the lab results from your facility are as accurate as possible, it is important to periodically upgrade your equipment.

Optimized Efficiency
Increased efficiency is another benefit that your lab can obtain by upgrading the equipment. Each year, laboratory equipment undergoes advancements that allow it to operate more quickly and efficiently. In an industry that often operates under strict deadlines and time constraints, the increased efficiency that newer laboratory equipment can provide is invaluable.

Types of Laboratory Equipment

Mixers, Shakers, and Stirrers
These apparatus are useful when mixing various chemical liquids and solids for different lab applications. Laboratory mixing apparatus come in different ranges: rotators and vortexes, 3D gyratory rockers, microplate shakers, linear shakers, orbital shakers, and magnetic stirrers. If you want to increase the capacity of any shaker, attach a clamp or any other suitable platform.

Centrifuge
A centrifuge is an equipment used to separate gases, fluids, and liquids with different densities. Centrifuges are mostly used in research laboratories to purify nucleic acids, proteins, viruses, organelles, and cells. In a hospital laboratory, a centrifuge is useful in separating various blood components such as plasma and serum.

Spectrophotometer
A spectrophotometer is equipment that helps determine the light intensity by measuring the number of photons absorbed as they pass through a specific solution. The equipment is also useful in determining the concentration of chemical substances by analyzing the amount of light intensity. Spectrophotometers are classified according to the wavelength range of their light sources.

Thermostatic Bath
A thermostatic bath is useful in inactivating and incubating cell cultures, thawing frozen samples, processing chemical reactions, and warming bacterial media. It is an important piece of equipment in medical research, a special and standard lab that deals with industrial and scientific experiments. Modern thermostatic baths are equipped with microprocessors with a controller that allows temperature co

Ultrasonic Cleaner
An ultrasonic cleaner perfectly cleans laboratory equipment using high-frequency waves that pass through a cleaning liquid. The immersed part of lab equipment is cleaned by the agitated liquid solution, mainly a solvent or water. The ultrasonic cleaner works by causing cavitation to the solution. Cavitation is when sonic energy dislodges the contaminants from the equipment surfaces by attracting them to the solutions bubbles.

Incubators and Ovens

Incubators and ovens are mostly used in microbiology, biology, and clinical labs. Lab incubators are used to incubate media, samples, and reagents. A lab incubator provides a steady temperature when warming the samples or reagents. Other applications of incubators include biotech, pharmaceutical, clinical, bacteriology, and food and beverage testing.

Ovens are mostly used in laboratories for drying samples and glassware, annealing, product age acceleration, sterilization, evaporation, and polymerization.

Rotary Evaporator
Also known as rotavap, a rotary evaporator is an equipment that helps separate solvents from a given sample through evaporation. The process is usually done under low or reduced pressure. Lowering the pressure in the flask allows the solvent to boil at a low temperature. The solvent is mostly put in a round bottom flask to provide a larger surface area for faster evaporation. The most common solvents to be separated from a sample are hexane and ethyl acetate.

Polarimeter
A polarimeter is an equipment that measures the angle of rotation after an optically active material polarizes a light. Some chemicals are optically active and will polarize right, causing it to rotate either clockwise or anticlockwise. The intensity of such a light rotation is called the angle of rotation. The direction of rotation of the polarized light provides the properties of such substance and its concentration in a given sample.

Microtome
A microtome is cutting equipment used to produce very thin slices of samples under experiment. Microtomes are mostly used in microcopy, where samples are studied through electron radiation or observed through light. Most microtomes have diamond, glass, or steel blades. The blades vary according to the specimen to be used and the thickness of the slices required.

How to Choose Laboratory Equipment

Infrared High Temperature Sample Dyeing Machine

Equipment Quality and Brand
Before you buy laboratory equipment, whether it is for a chemistry or medical lab, it is important to collect details about the brands or models of multiple lab devices available within the market. Leading manufacturers will offer premium and quality models of equipment for specific applications. It is important to pick the right model to meet your laboratory's specific needs. Consider the product's features, performance stability, and accurate results too. Buying branded lab instruments would provide the advantage of higher operational durability and efficiency.

Specifications and Features for the Laboratory Equipment
Before buying a particular device for your lab, it is vital to conduct a detailed evaluation of your product's technical specifications and features. Compare the features of two different models or brands (of pipettes, for example) and pick the one that can best serve your requirements. Many leading brands offer benchtop models for chemistry analyzers, centrifuges, and other instruments that function well and take up little space. Try to buy lab equipment that is safe and user-friendly.

Laboratory Equipment User Friendliness
Speaking of user-friendliness, the lab equipment that you buy should be user-friendly. It is vital to check whether the specific product features support the different procedures you will perform in your lab. This equipment should be very easy to operate and should ensure user safety. Laboratories with staff constraints can go for advanced automated lab equipment that saves time required to perform lab tests and require less user intervention.

Purchase Plan
Start with a purchase plan by making an inventory of equipment required. A purchase plan will give a clear view into what's required, mandatory, and optional. You may also want to cross check the plan inventory to see if some of the equipment are already available.

Research on Options Available
Identify the top 3 vendors of the equipment and visit their website or online store to check for options available. Sometimes, a better option than what you considered might be available in the market. Check on the product features & specifications, the ease of use considering researchers comfort, and importantly the power requirement & consumption. Also check the available lab space, against the equipment requirements.

Choose Reputable Brands
Safety is of paramount importance in your laboratory. Shortlist the equipment suppliers with reputable brands and a proven history of quality products.

Warranty & After-Sales Support
In addition to equipment safety and quality, also research on after sales support and warranty. Timely support and guarantee of resolution are critical to smooth functioning of the laboratory.

Check Production Capacity
Delayed equipment may adversely impact your laboratory project planning and timelines. Reputed manufacturers have well-oiled supply chain mechanism with adequate production capacity to meet the demands.

Environmental Friendliness
Given the focus on sustainability in laboratories, the choice of “green equipment” may be limited. However, it pays off in the long-term and in many jurisdictions mandated by law to reduce the carbon footprint.

Explore Packaged Solutions
If your project is of a larger scope, then you may consider packages solutions like turnkey. Due to bulk orders and lower overheads, manufacturers may offer better pricing structures in a packaged deal.

Budget & Flexibility
Finally, based on all the research, estimate a budget for the equipment purchase. If the price sheet is not available on the vendor's website, check with them or speak to your supply chain team, who may have it already. Build adequate flexibility into the budget to account for variants and unplanned additions.

How to Maintain Laboratory Equipment

Read the Manual
Before using any piece of lab equipment, you should read the manual. Though these manuals may not be immediately accessible in the lab—an old centrifuge is unlikely to be kept with its manual intact—it's worth looking online or calling the manufacturer to obtain one. Compiling a list of these manuals is important for both troubleshooting when something goes wrong as well as training individuals to use the machine. One need not pour over the manual either; briefly reading the manual is a good way to assess how to use it properly and to potentially discover options you didn't know were available.

Get Trained on it
Training is the best way to learn how to use instrumentation properly. Remember, the easiest way to damage equipment is by using it improperly (everyone knows of someone who didn't quite balance their tubes in the ultracentrifuge), and the most reliable way to avoid that is by training with experienced personnel. Don't take training for granted either; if you've allocated time for it, aim to do a little experimental planning and troubleshooting, especially for machines like flow cytometers and mass spectrometers, which require many steps and adjustments to process samples.

Get Others Trained on it
A frequent source of damaged equipment is scientists from outside your lab performing an experiment without the proper training. In academic labs, where equipment is often shared without physical borders, this kind of thing can happen regularly to centrifuges, balances, microscopes, and other high-end imaging and detection systems. It's therefore a worthy investment to train not only your own lab's personnel but to actively identify and train others who may want to use the instrumentation. This can help avoid disagreements and infighting later through preventing the unauthorized and improper use of the instrument by personnel working outside your lab.

Clean it After Use
Though a common-sense tactic to keeping your things in pristine condition, cleaning up after oneself is sometimes overlooked in the lab. For equipment, cleaning is essential, as it prevents the build-up of potentially hazardous powders and liquids from clogging your instrumentation. Moreover, merely performing a routine lab cleanup can limit the accumulation of dust, which can cause problems if left coalescing in and around your equipment over long periods.

Inspect it Frequently
Problems with equipment aren't always immediately apparent. It's crucial to physically inspect your instruments throughout the year and to run performance tests, if applicable. This is especially necessary for equipment that isn't used very often, as you'll be able to resolve potential issues before the instrument is needed for testing down the road. While potentially expensive, maintenance contracts for critical equipment is usually a wise investment.

Calibrate
Calibrate your instruments and performing regular preventative maintenance keeps them working as accurately and precisely as possible. For instruments like pipettes, it's worth getting them professionally calibrated once every 3 to 6 months. However, as stated above, it's necessary to continually monitor their accuracy by testing them using pure water, a balance, and a weigh dish (the amount of water pipetted should yield the correct weight on the balance). A great way to track routine maintenance and calibration is to use specially designed labels that are affixed onto equipment and record maintenance information. These labels will also protect hand-written information from accidental spills and prevent unauthorized modification.

Refurbish
Refurbishing your equipment (i.e. taking it apart component by component to clean and repair) has its advantages when it comes to maintenance. It gives you the opportunity to verify the current quality of your components and to determine if any of them need to be replaced or repaired. It's also much more effective to clean an instrument when it's taken apart. Just be sure you know how to put it back together.

Log usage of the Equipment
It's important to keep track of who's using the equipment and what they're doing with it, as identifying the source of any problem requires a firsthand account of how it occurred and when. It will also allow you to assess when the machine needs its regular calibration/maintenance.

Our Factory

Our factory is divided into two parts: the laboratory equipment production factory is in Wuxi City, Jiangsu Province, covering an area of 1,800 square meters and with more than 30 people in the workshop. The large-scale dyeing machine production factory is located in Zibo City, Shandong Province, covering an area of 15,000 square meters and with more than 70 people in the workshop. From sheet metal processing to assembly, the quality of the entire assembly line is controlled by ourselves.

Frequently Asked Questions

Q: What is a laboratory testing machine?

A: A laboratory testing machine is an instrument or equipment used to conduct tests and experiments to assess the properties, performance, and durability of materials, components, or products. These machines apply controlled forces, pressures, or conditions to test materials under simulated real-world scenarios, ensuring they meet required specifications and standards.

Q: What are the types of laboratory testing machines?

A: There are various types of laboratory testing machines, each designed for specific applications. Common types include tensile testing machines (for measuring the strength and elasticity of materials), compression testers (to test the material's resistance to crushing or deformation), hardness testers (for determining material hardness), impact testing machines (for measuring toughness under sudden forces), fatigue testers (for cyclic stress testing), and universal testing machines (which can perform multiple tests such as tensile, compression, and flexure).

Q: What is a universal testing machine (UTM)?

A: A universal testing machine (UTM) is a versatile device used to test the mechanical properties of materials, including tensile strength, compressive strength, and bending resistance. The UTM can be programmed to perform a variety of tests on materials such as metals, plastics, composites, textiles, and more. It typically includes load cells, crossheads, and grips to apply different forces and measure the material's response.

Q: How does a tensile testing machine work?

A: A tensile testing machine applies a controlled pulling force to a material sample until it breaks. The machine measures the force applied and the elongation of the sample, providing data on tensile strength, elongation at break, yield strength, and Young's modulus. This test is commonly used to determine how materials behave under tension, which is critical for applications in engineering, manufacturing, and quality control.

Q: What software is used to control laboratory dosing systems?

A: Most modern laboratory dosing systems are controlled by specialized software that allows the user to set dosing parameters, such as volume, flow rate, timing, and sequence of operations. The software provides real-time monitoring and data logging to ensure precision and consistency. It may also offer automated calibration, error detection, and batch management features. The software interfaces can often be integrated with laboratory information management systems (LIMS) for seamless data tracking and analysis.

Q: Can laboratory dosing systems be integrated with other laboratory equipment?

A: Yes, laboratory dosing systems can often be integrated with other equipment, such as reactors, mixers, balances, or chromatography systems. This allows for automated, seamless processes in workflows such as chemical synthesis, formulation, or sample preparation. Integration enhances efficiency, reduces manual handling, and improves the precision of complex, multi-step processes by synchronizing the dosing system with other instruments in the lab.

Q: What are the safety features of a laboratory dosing system?

A: Safety features of laboratory dosing systems typically include emergency stop buttons, overpressure valves, leak detection systems, and inert gas purging for hazardous materials. Many systems also have protective enclosures or fume extraction systems to ensure safe handling of volatile or toxic substances. Automated systems often include safety interlocks that prevent operation if unsafe conditions are detected, such as improper pressure levels or incorrect flow rates.

Q: What is continuous vs. batch dosing in laboratory systems?

A: In continuous dosing, the system dispenses a constant flow of material over a set period, which is commonly used in processes that require ongoing chemical reactions or long-term sample preparation. Batch dosing, on the other hand, involves dispensing a specific amount of material in discrete quantities or batches, which is typical for preparing separate samples or precise formulations. Both methods can be automated, but the choice depends on the nature of the experiment or process.

Q: Can a dosing system handle multiple components at once?

A: Yes, multi-component dosing systems are designed to handle multiple substances simultaneously. These systems often feature separate pumps or dispensing units for each material, allowing precise control over the amount and ratio of each component being dosed. This is especially useful in chemical reactions or pharmaceutical formulations where multiple reagents must be added at specific intervals and in exact proportions.

Q: How do you troubleshoot common issues in a laboratory dosing system?

A: Common issues in laboratory dosing systems include blockages, leaks, inaccurate dosing, or software errors. To troubleshoot, check for blockages in tubing or nozzles and clean the system as needed. Ensure that all connections are secure and that the system is properly calibrated. For software issues, restarting the system or re-entering dosing parameters can resolve problems. If the problem persists, referring to the user manual or contacting technical support may be necessary.

Q: Are there specific standards or certifications for laboratory sample dyeing machines?

A: Yes, laboratory sample dyeing machines may need to comply with various industry standards and certifications, such as ISO standards related to quality management and environmental impact, as well as ASTM standards for textile testing and dyeing processes, and adherence to these certifications ensures that the machines meet established safety and performance benchmarks.

Q: Can laboratory sample dyeing machines handle custom dye formulations?

A: Many laboratory sample dyeing machines are designed to accommodate custom dye formulations, which allows users to experiment with unique color blends and dye types, making this capability particularly beneficial for research and development processes aimed at creating proprietary colors or effects.

Q: What kind of training is required to operate a laboratory sample dyeing machine?

A: Training for operating a laboratory sample dyeing machine typically includes understanding machine controls to become familiar with the digital interfaces and settings, learning safety protocols to ensure proper use of PPE and awareness of hazards, gaining knowledge of dyeing techniques including the preparation of dye solutions and fabric handling, and many manufacturers provide training sessions or user manuals to assist operators in mastering the equipment.

We're professional laboratory equipment manufacturers and suppliers in China, specialized in providing high quality customized service. We warmly welcome you to wholesale high-grade laboratory equipment made in China here from our factory.

Room Temperature Dyeing Machine, Mini Tenter, Sand Sample Dyeing Machine