Our Mission is to provide our LAB EHS 4.0 Total Solution to researchers around the world, which will allow them to breathe safely in their laboratory, when being around or working with toxic gas emitting acid base chemicals.

JE CUBE is a Laboratory Environment, Health and Safety (EHS) Solutions provider.

Solution 1: TOGA Clean System – Toxic gas purification, environmental protection and energy saving products with patented TOXIC GAS filter.

Solution 2: IoT EHS Platform – A Platform to prevent accidents before they occur.

Solution 3: Laboratory EHS Total Solution (AIoT) – Data-based, one-stop service for laboratory EHS optimization.

Hazardous material storage, flammable storage, custom manufacturing of TOGA filters, electric vehicle battery test chamber, semiconductor oven and reliabilty test equipment are other areas that we specialize in.  Please CONTACT US for your custom filter or test equipment needs.

Corporate l Private Sector
Government l Public Sector
University l Education Sector
Korean National Research Institutes

Ovens for the Semiconductor Industry

JE CUBE is also experienced in the semiconductor oven and reliability test equipment industry.  Our goal is to provide customized products that help to reduce production cost and increase production reliability.  

For the semiconductor industry the main product is semiconductor ovens.

Our products can be customized to work with inline automation equipment.

Our engineers are capable of integrating current technology equipment with future automation technology. 

 

Pressure Oven

SPO220 Pressure Oven

Pressure oven provides a constant pressure and temperature.

  • It removes voids when hardening epoxy or underfill solution.
  • Is used in film bonding process.

Clean Oven

SCLO250-2C

Clean oven provides clean working conditions during curing.

  • Cures under clean working conditions
  • In accordance with USA : Fad. Standard 209E Class100 or Class10USA : Fad. Standard 209E Class 100 or Class 10  and international: ISO 14644-1 Class 5 or Class 4

Cure Oven

SCUO250-4C

Cure ovens are the most widely used in semiconductor Industry.

  • Cures under normal conditions.

Vacuum Oven

SVO200WNA-2C Vacuum Oven

Vacuum oven is widely used in the moisture removal process.

  • Cures using radiant heat.

Cone Type Vacuum Oven

SCVO180WNA

Cone Type Vacuum Oven provides drying powdery materials.


High Temperature Oven

SHTO450W

High Temperature ovens are used in semiconductor bumping processes.

Automation In-line Oven

SAICLO250VS

Automation in-line oven used in pre and post semiconductor production processes.

WFLO Hotplate Oven

WLFPHPO280WC

Hotplate oven is used for passivation curing of wafers in teh semiconductor bumping process. 

Other Related Equipment for the Semiconductor Indsutry

Atmospheric Plasma

SAP2500

Atmospheric Plasma improves adhesion by cleaning the surface of ttlat products such as semiconductors, displays, films and touch panels.

UV Cure

SUV50100

UV Cure is used for curing and coating printing of products such as semiconductors, displays, films, touch panels.  Also, used for removal of wafer dicing tape.

Lithium-ion Storage

Low Power Lithium Batteries

Less than 100 Wh per battery

 

Those are the small batteries contained in mobile phones or computers, for example. No special safety requirements apply here, as long as all the manufacturer’s instructions and safety locations are followed. For larger quantities stored (volume over 7 m3) the guidelines for medium capacity lithium batteries applies.

Medium Capacity Lithium Batteries

793+LIX2+VIG290+3 E35LI

Approx. 100 Wh per battery and 12 kg gross per battery

Batteries in this category are used in electric bicycles, electric scooters or similar small vehicles. They should be stored in separate fireresistant enclosures (e.g. a fireproof room or safety cabinet). They should not be stored with other products and this area should be constantly monitored. For larger quantities stored (area occupied at 60 m2 ) the guidelines for high power lithium batteries applies.

Medium Capacity Lithium Batteries

Approx. 100 Wh per battery and 12 kg gross per battery

Batteries in this category are used in electric bicycles, electric scooters or similar small vehicles. They should be stored in separate fireresistant enclosures (e.g. a fireproof room or safety cabinet). They should not be stored with other products and this area should be constantly monitored. For larger quantities stored (area occupied at 60 m2 ) the guidelines for high power lithium batteries applies.

High Capacity Lithium Batteries

More than 100 Wh per battery and 12 kg gross per battery

Batteries in this category are mainly used in electric cars and large stand-alone appliances. The recommendations for the storage of medium power batteries should form the basis for consideration. However, safeguards should be put in place on a case-by-case basis after consideration. • If the storage space is large, fire protection must be adapted. • If the use of sprinklers is allowed, it should be as localised as possible and it is recommended that the batteries are separated and stored in a confined environment to prevent a fire outbreak.

Visal and Audible Alarm Box
Smoke Detector
Automatic Fire Extinguisher
Visual Alarm
Cable Passage with Inserts
Surge Protector-US
Surge Protector-SU
Ventilation Box
Perforated Shelf
Duct Connecting Kit

To ensure the safety of people and goods, we have created a safety storage solution for Lithium-ion batteries. Indeed, lithium-ion batteries have the particularity to present many risks of which the most known and the most frequent is the thermal runaway which can be due to a rise of temperature of the environment, a shock, or a problem of assembly of the battery.

The consequence is that the battery can ignite dangerously and cause a fire.

Based on our experience and our know-how on the EN14470-1 105 minutes European standard fire-proof cabinets, we offer several models of different sizes that can meet the most varied storage needs. These cabinets can be equipped as needed, with perforated shelves (with high load capacity – 100kg per level) and Containment sumps in the lower part of the cabinet to prevent possible electrolyte leakage damages from the battery. There is also the possibility to recharge batteries stored via the rack power strips. The exceptional fire resistance of our cabinets (105 minutes under the European test) guarantees maximum safety. However, it is possible to further secure the storage by adding optional solutions such as :

• The internal safety extinguisher in the special lithium-ion battery cabinet (ref. EX100LI or EX200LI)

• Or the safety set including the extinguisher, an audible and visual alarm, the smoke detector, the control box and a cable passthrough in the upper part of the cabinet PINTOLI ref. (VIG190 or VIG290). There are four types of usage, depending on your needs :

• Simple battery storage : Cabinet equipped with perforated shelves and a Containment sump.

• Storage and charging of batteries: Cabinet equipped with perforated shelves, a Containment sump and electrical outlet racks + PEXTBALI50 (max. 4 x 8 mm cable entry).

• Simple battery storage + advanced protection system : Cabinet equipped with perforated shelves with a Containment sump and optional advanced protection system (either a fire extinguisher or a security set including visual and sound alarm, control box, automatic smoke detector, fire extinguisher and cable pass through).

• Storage and charging of batteries + advanced protection system: Cabinet equipped with perforated shelves, a Containment
sump and electrical outlet racks + optional advanced protection system (either a fire extinguisher or a security set including visual and sound alarm, control box, automatic smoke detector, fire extinguisher and cable pass-through). Any polluting liquid must be stored in tanks having a retention capacity of at least 50% of the volume of that liquid, as well as the retention capacity for flammable or combustible liquids contained in movable containers less than or equal to 250 L must be at least 800 L.

The containment sump must be of controlled tightness and must resist the physiochemical properties of the material it contains.Their storage is governed by chemical incompatibilities and the established safety rules put in place. In the event of a fire, the cabinets must not be moved except by the fire brigade.

What is a lithium-ion battery?

In accordance with EN14470-1

A Li-ion battery or Li-ion accumulator consists of two electrodes (cathode and anode) and an electrolyte that ensures the ion exchange of the system.

WHAT ARE THE DANGERS ASSOCIATED WITH THESE BATTERIES?

Of the 50 potential accidental scenarios identified by INERIS (Institut National de l’Environnement Industriel et des Risques) during the various stages of the battery life cycle, 12 were considered critical. They concern in particular the storage, recharging and use stages. The most problematic outcome of these risks concerns battery fire (or metal fire). This is a significant risk because the fire caused by lithium-ion batteries cannot be extinguished in a conventional way, as the battery itself generates the oxygen molecules and heat needed for combustion. It can only be extinguished with the help of special powders, all in a confined environment (with the risk of the powder losing its effectiveness).

By thermal runaway due to overcharging or exposure to excessive temperatures

A battery usually delivers the chemically stored energy on discharge as electrical energy. However, not all of the energy may be delivered as electrical energy, but may cause overheating that can be as much as 7 to 11 times the electrically stored energy. Given the structure of the battery, the reaction itself becomes stronger and causes critical overheating. The materials of the battery also release bound oxygen, which further fuels the fire.

By full discharge

The full discharge associated with not using the battery for too long periods can damage the battery. If the battery is then exposed to temperatures that are too cold, this can cause a change in the physical and chemical properties of the electrolyte liquid and lead to the formation of flammable gas. The absence of the liquid breaks down the protection of the battery, leading to a short circuit or fire.

By mechanical damage

Shocks or misuse can damage the internal structure of the battery and lead to deterioration of the battery separator, leading to a short circuit or fire