Customization: | Available |
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Material: | Stainless Steel |
Type: | Central Bench |
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chemistry lab furniture with adjustable feet
Worktop Compare | Stainless Steel | Edge Grain marble | High Pressure Laminate | Epoxy Resin | Phenolic Resin |
chemical resistance | good | fair | fair | excellent | excellent |
abrasion resistance | good | fair | good | good | good |
heat resistance | good | fair | fair | excellent | good |
impact resistance | excellent | good | good | good | good |
areas of use | select | select | select | all | all |
cost | high | medium | low | medium | medium |
moisture resistance | excellent | fair | fair | excellent | excellent |
bacterlal resistance | excellent | poor | fair | excellent |
excellent
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How to design the dental lab furniture?
Then there are bulk sample storage areas. These can reside in less desirable-or less expensive-spaces, but it remains important to plan ways that samples can travel efficiently through the building-from receiving to storage to lab and back to storage.Laboratory space comes in two basic kinds or zones. First, there is research space
where researchers feel comfortable and productive. These are the best spaces in the building, perhaps with lots of glass to provide views and plenty of natural light, plus HVAC systems designed to meet human and scientific needs.These decisions must be made early, during the planning phase. As with many planning decisions, the culture of the institution will provide a major influence on the adjacencies of the three different kinds of space. Two key considerations here are the particular science to be practiced in.Colleges and universities can select from a number of different trends in laboratory design today. At a conceptual level these trends typically involve determining how bench and lab space relate to lab support space, and how support space relates to office space.
Product Description
Frame | steel structure or C-frame structure |
Table top | made of 12.7mm thick corrosion-resistant black C-SPC, one door one drawer |
Cabinet | use high quality cold-rolled steel sheet, the surface is parkerised by acid and electro-sprayed by epoxy resin powder, color can be chosen according to colordisc |
Slideway | three section slide rail, no noise |
Adjustable foot |
can adjust height of the bench |
Hinge | open type high quality hinge |
Handle | stainless steel bright type handle |
Sink | PP sink, acid-resistance, alkali-resistance and corrosion-resistance, flexible |
Cock | three outles cocks use high quality copper, the surface is coated by epoxy resin powder, ceramic cartridge, use special for lab research |
Reagent Shelves | steel-glass structure , or others |
Size | 3000/3600*1500/750*850/900mm or customized |
Pegboard | C-SPC board ,PPstick ,400*500mm |
Handle | stainless steel bright type handle |
Sink | PP sink, acid-resistance, alkali-resistance and corrosion-resistance, flexible |
Cock | three outles cocks use high quality copper, the surface is coated by epoxy resin powder, ceramic cartridge, use special for lab research |
Why we need the laboratory?
The scientists, students, maintenance people, and administrators that use and manage college and university science laboratories are integral to not only planning what is needed and wanted, but also why. Providing the architects with sufficient information requires meaningful planning discussions with a full spectrum of institutional people. Often, the lab manager will rank as a key decision maker, but input from principal investigators, operational and maintenance teams, and the administrators responsible for allocating resources is indispensable.
Their combined input can ensure that a facility is both optimized for controlling laboratory processes and set up for effective operational control of building systems. Here's how.
Lab design enables (or disables) processes such as DNA sequencing. Designers must understand the way the different spaces interact with each other as they are passed through along the research material pathway. Designers must also understand the mechanical and electrical requirements of each of the spaces as well as the design principles related to the efficient operation of each.
Optimizing processes foundational step. Optimizing processes is at the heart of lab planning. For example, sequencing DNA in a lab requires a definitive workflow that extends from sample extraction through the prep room, into the sequencing room, and then into a local or remote bulk storage system. The precise protocols followed at each of these steps ensure the purity of the sample and the integrity of the data obtained from the process.
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