Toggle Categories
Get Instant Support
Choose your preferred way to connect with our team
-
Get Free Quote Fill out form for detailed pricing
-
Send Email Detailed inquiry support
-
WhatsApp Quick mobile chat
Response Time
Within 8 hours on working days, 24 hours on holidays
Sample Preparation
KinTek sample preparation equipment includes sample crushing,milling, as while as while sieving equipment, hydraulic press equipment includes manual press, electric press, isostatic press, hot press and press filtering machine.
Thermal Equipment
KinTek supplies a broad range of high-temperature furnaces, including lab, pilot production, and industrial production furnaces, with a temperature range of up to 3000 ℃. One of KinTek's advantages is the ability to create custom-made furnaces tailored to specific functions, such as different heating methods and speeds, extra high and dynamic vacuums, controlled atmospheres and gas circuits, automated mechanical structures, and software and hardware development.
Lab Consumables & Materials
KinTek offers a range of lab consumables and materials, including evaporation materials, targets, metals, electrochemistry parts, as well as powders, pellets, wires, strips, foils, plates, and more.
Bio-Chem Equipment
KinTek bio-chem equipment comprises rotary evaporators, glass and stainless steel reactors, distillation systems, circulating heaters and chillers, as well as vacuum equipment.
Products
Cylindrical Lab Electric Heating Press Mold for Laboratory Applications
Item Number : PMH
Infrared Heating Quantitative Flat Plate Press Mold
Item Number : PMHD
Double Plate Heating Press Mold for Lab
Item Number : PMD
Warm Isostatic Press for Solid State Battery Research
Item Number : PCIH
Isostatic Molding Pressing Molds for Lab
Item Number : PIPM
Electric Split Lab Cold Isostatic Press CIP Machine for Cold Isostatic Pressing
Item Number : PCESI
Square Lab Press Mold for Laboratory Applications
Item Number : PMS
Automatic Lab Cold Isostatic Press CIP Machine Cold Isostatic Pressing
Item Number : PCIA
Cylindrical Press Mold for Lab Applications
Item Number : PMC
Electric Lab Cold Isostatic Press CIP Machine for Cold Isostatic Pressing
Item Number : PCIE
Special Heat Press Mold for Lab Use
Item Number : PCHF
Manual Cold Isostatic Pressing Machine CIP Pellet Press
Item Number : PCIM
Carbide Lab Press Mold for Laboratory Applications
Item Number : PMW
Assemble Square Lab Press Mold for Laboratory Applications
Item Number : PMAS
Assemble Lab Cylindrical Press Mold
Item Number : PMAC
XRF Boric Acid Lab Powder Pellet Pressing Mold for Laboratory Use
Item Number : PMXB
XRF & KBR steel ring lab Powder Pellet Pressing Mold for FTIR
Item Number : PMXS
XRF & KBR plastic ring lab Powder Pellet Pressing Mold for FTIR
Item Number : PMXP
Special Shape Press Mold for Lab
Item Number : PMT
Warm Isostatic Press WIP Workstation 300Mpa for High Pressure Applications
Item Number : PCIW
Automatic Laboratory Hydraulic Press for XRF & KBR Pellet Press
Item Number : PMXA
Lab-Scale Vacuum Induction Melting Furnace
Item Number : KT-VI
Vacuum Hot Press Furnace Machine Heated Vacuum Press
Item Number : KT-VHP
Electric Heated Hydraulic Vacuum Heat Press for Lab
Item Number : PPZ
Vacuum Hot Press Furnace Heated Vacuum Press Machine Tube Furnace
Item Number : KT-VTP
Electric Rotary Kiln Continuous Working Small Rotary Furnace Heating Pyrolysis Plant
Item Number : KT-RFTF
REQUEST A QUOTE
Our professional team will reply to you within one business day. Please feel free to contact us!
Related Articles
The Architecture of Isolation: Why Control Beats Volume in Material Science
Discover why the tube furnace is the engineer's choice for precision. We explore the critical role of atmospheric isolation and thermal uniformity in advanced material synthesis.
The Silent Interface: Mastery Over Electrode Decay
Electrode failure is rarely sudden; it is the compound interest of neglect. Learn the disciplined maintenance protocols that preserve accuracy and longevity.
The Architecture of Heat: Inside the Precision of Laboratory Tube Furnaces
Explore the engineering behind tube furnaces, from the feedback loops of thermocouples to thermal uniformity, and why precision is an active process.
The Hidden Enemy in Your Furnace: Why Your Heat-Treated Parts Have Scale and Discoloration—And How to Fix It for Good
Frustrated with oxidized, inconsistent results from your furnace? Discover why air, not heat, is the real culprit and how to solve it permanently.
The Architecture of Nothingness: Mastering Heat in a Vacuum
Heat transforms materials, but air corrupts them. Discover how vacuum furnaces utilize low-pressure environments to ensure purity in brazing and sintering.
The Architecture of Control: Why Thermal Stability Defines Electrochemical Precision
Master electrochemical accuracy by understanding the interplay between three-electrode systems and thermal regulation. Eliminate variables to ensure reproducibility.
The Architecture of Heat: Aligning Engineering Precision with Laboratory Reality
Choosing a tube furnace is not about finding the "best" model, but matching specifications—temperature, zones, and atmosphere—to your scientific reality.
Why Your High-Temperature Processes Fail: The Hidden Enemy in Your Vacuum Furnace
Frustrated by inconsistent vacuum furnace results? Discover the real cause of failures and how to fix it by ensuring true vacuum integrity.
The Art of Nothingness: Vacuum, Inert Gas, and the Pursuit of Purity
Vacuum vs. inert gas furnaces: Understand the trade-offs between absolute purity and cost-effective protection in laboratory heat treatment.
Why Your High-Temperature Furnace Fails—And How to Choose the Right One
Is your high-temp furnace causing delays and costly repairs? Learn why focusing on workflow, not just temperature, is the key to choosing the right one.
The Inverted Cup: When Physics Hides a Lethal Trap in Vacuum Furnaces
Hot argon behaves counter-intuitively in bottom-loading furnaces. Discover the physics of the "inverted cup" effect and how to prevent silent asphyxiation.
The Geometry of Control: Why the Tube Furnace is Science’s Precision Tool
Tube furnaces offer unmatched thermal uniformity and atmospheric control. Discover the engineering logic behind these precision instruments.
Why Your Lab Press Fails: It's Not the Tonnage, It's the Steel
Discover the hidden reason your hydraulic press gives inconsistent results. Learn why the choice of steel is more critical than tonnage for safety and accuracy.
Your Induction Furnace Is Failing You. The Reason Isn't What You Think.
Struggling with inconsistent melts or high costs? The problem may be a fundamental mismatch in your induction furnace type. Learn to fix it.
The Architecture of Control: Why Thermal Stability Defines Electrolysis Success
Discover how double-layer water-bath electrolytic cells eliminate thermal variables, ensuring accuracy and reproducibility in electrochemical research.
Why Your Lab Pellets Crack: The Hidden Physics of a Perfect Press
Stop blaming your powder. Discover the real reason your lab pellets fail and how a precision hydraulic press solves inconsistent sample prep for good.
The Invisible Geography of Heat: Why "Max Temperature" is a Trap
In thermal processing, maximum temperature is often a vanity metric. Discover why the "Uniform Heated Zone" is the true architect of repeatability.
Why Your Lab's Hydraulic Press Keeps Failing (It’s Not What You Think)
Discover the three 'silent killers' of lab hydraulic presses, like off-center loading and fluid contamination, and how to prevent costly failures.
Why Your Induction Furnace Fails with Aluminum—And How to Fix It for Good
Struggling to melt aluminum? Discover the hidden physics behind inconsistent results and learn how the right high-frequency induction furnace solves it.
The Breakthrough in a Box: How Vacuum Tube Furnaces Eliminate Contamination in Materials Research
Frustrated by oxidation ruining your high-temperature experiments? Discover how the vacuum tube furnace creates a perfect, contamination-free environment, enabling breakthroughs.