Options for Expanding Your Productivity

Split /Splitless Injector

SPL‒2030

‒ The injection port can be opened or closed without tools, making insert replacement easy. It ensures an airtight seal even at high temperatures and pressures.

‒ Standard configuration supports high‒speed GC with narrow bore ‒ capillary columns.

‒ The carrier gas saver function reduces split gas consumption.

‒ Permits high‒pressure injection mode.

On‒Column Injection Unit

OCI‒2030

‒ Samples can be injected using cold on‒column injection (OCI).

‒ By using an optional easy OCI insert, cold on‒column injection allows a narrow‒bore capillary column to be connected directly to the injector without a 0.53 mm I.D. pre‒column. (Press‒Tight connector not necessary).

‒ It also supports analysis of high‒boiling compounds (straight‒chain hydrocarbons with 100 or more carbons)

‒ Two units of OCI can be mounted at the same time.

Direct Injection Unit

WBI‒2030

‒ The injection port can be opened or closed without tools, making insert replacement easy. It ensures an airtight seal even at high temperatures and pressures.

‒ Equipped with a septum purge flow channel to inhibit solvent tailing.

‒ Shares and simplifies the glass inserts for splitless analysis (patented).

Note: Contact your Shimadzu representative separately regarding connecting a packed column

Programmed Temperature

Vaporization Injector

PTV‒2030

‒ Samples can be injected using the PTV method.

‒ Uses an inert heat‒resistant quartz insert.

‒ Two units of PTV can be mounted at the same time.

Flame Ionization
Detector

FID‒2030

All organic
compounds

‒ An optimized nozzle and collector structure provides better response than previous models.

Flame Photometric
Detector

FPD‒2030

Organic
phosphorus
compounds

Sulfur compounds

‒ A novel optical system with a more advanced dual‒focus system results in the world's highest sensitivity*.

‒ The nozzle structure prevents adsorption and decomposition of sample components and an improved nozzle shape heightens flame stability.

‒ A dedicated cooling fan achieves a more compact design that also enables high‒temperature (450 °C) operation.

‒ Reverse threads are used on hydrogen connector joints to prevent incorrect pipe connections.

‒ When using LabSolutions, the recommended detector flowrates can be set automatically for optimal sensitivity, by simply selecting the filter type (for phosphorus, sulfur, or tin).

Thermal
Conductivity
Detector

TCD‒2030
（for capillary columns）

Inorganic gases

High‒concentration
organic compounds

‒ A microvolume cell supports even sharp peaks.

‒ An improved structure results in a shorter stabilization time than previous models. It enable more reliable analysis that is less easily affected by column oven temperature.

Flame Thermionic
Detector

FTD(NPD)‒2030

Organic nitrogen
compounds

Organic
phosphorus
compounds

‒ An improved collector reduces the negative peaks from impurity components.

‒ Collectors can be replaced without tools.

‒ Using an alkali source regeneration kit (optional) can reduce running costs.

‒ Reverse threads are used on hydrogen connector joints to prevent incorrect pipe connections.

Electron Capture
Detector

ECD‒2010 Exceed

Electrophilic compounds

‒ Redesigned internal structure provides increased durability, higher sensitivity, and wider dynamic range, achieving the world's highest* ECD performance.

‒ An optimized ECD cell structure achieves the world's highest sensitivity.

Barrier Discharge

Ionization Detector

BID‒2030

Low‒concentration
inorganic gases
Organic
compounds

‒ A wide variety of compounds other than He and Ne can be detected with high sensitivity.

‒ Provides over 100 times higher sensitivity than TCD and over 1.5 times higher than FID.

‒ A barrier discharge plasma source that does not contact the electrode prevents high electrode temperatures. Consequently, electrodes almost never deteriorate, which ensures long‒term analytical stability.