Olympus FV1000 manual Dimensions, Weight and Power Consumption

Page 27

Expandability

Dimensions, Weight and Power Consumption

 

 

Dimensions (mm)

Weight (kg)

Power consumption

 

 

 

 

 

 

 

Microscope with scan unit

BX61/BX61WI

320

(W) x 580 (D) x 565 (H)

41

 

 

IX81

350

(W) x 750 (D) x 640 (H)

51

 

 

 

 

 

 

 

 

 

 

 

Fluorescence illumination unit

Lamp

180

(W) x 320 (D) x 235 (H)

6.7

 

 

 

Power supply

90 (W) x 270 (D) x 180 (H)

3.0

AC 100-240 V 50/60 Hz 1.6 A

 

 

 

 

 

 

 

Transmitted light detection unit

 

170

(W) x 330 (D) x 130 (H)

5.9

 

 

 

 

 

 

 

 

Microscope control unit

 

125

(W) x 332 (D) x 216 (H)

5.2

AC 100-120/220-240

V 50/60 Hz 3.5 A/1.5 A

 

 

 

 

 

 

 

FV Power supply unit

 

180

(W) x 328 (D) x 424 (H)

7.5

AC 100-120/220-240

V 50/60 Hz 4.0 A/2.0 A

 

 

 

 

 

 

FV control unit (PC)

 

180

(W) x 420 (D) x 360 (H)

10.5

AC 100/240 V 50/60 Hz 497.5 W

 

 

 

 

 

 

 

19 inch, dual (value per monitor)

363

(W) x 216 (D) x 389.5–489.5 (H)

5.9

AC100-120/200-240 V 50/60 Hz 0.65 A/0.4 A

Display

 

 

 

 

 

 

 

29.8 inch

689

(W) x 254.7 (D) x 511.5–629.5(H)

15.7

AC100-120/200-240

V 50/60Hz 1.8 A/0.8 A

 

 

 

 

 

 

 

 

Power supply unit for laser combiner

 

210

(W) x 300(D) x 100 (H)

4.0

AC 100-120/200-240

V 50/60 Hz 2.0 A/1.0 A

 

 

 

 

 

 

 

Laser combiner (with Ar laser heads)

 

514

(W) x 504 (D) x 236 (H)

45

 

 

 

 

 

 

 

 

 

Laser combiner (without Ar laser heads)

 

514

(W) x 364

(D) x 236 (H)

40

 

 

 

 

 

 

 

 

LD559 laser power supply

 

200

(W) x 330

(D) x 52 (H)

1.2

AC 100-240 V 50/60 Hz 30 W

 

 

 

 

 

 

 

Multi Ar laser power supply

 

162

(W) x 287

(D) x 91 (H)

4.4

AC 100-240 V 50/60 Hz 20 A

 

 

 

 

 

 

 

HeNe(G) laser power supply

 

130

(W) x 224

(D) x 62 (H)

1.8

AC 100-120 V 50/60 Hz 0.45 A

 

 

 

 

 

 

 

 

Recommended FV1000 system setup

 

(IX81, BX61, BX61WI)

(unit: mm)

 

1310

680

1200

 

1880

Depth: 990

*1 This product corresponds to regulated goods as stipulated in the "Foreign Exchange and Foreign Trade Control Law". An export license from the Japanese government is required when exporting or leaving Japan with this product.

*2 The performance and safety of this device is not guaranteed if it is disassembled or modified.

*3 This device is designed for use in industrial environments for the EMC performance. (IEC61326-1 Class A device) Using it in a residential environment may affect other equipment in the environment.

Images are courtesy of the following institutions:

"Brainbow" mouse brain stem

Mouse brain section

Osteoclast induced from rat monocyte in rat kidney

Courtesy of the laboratories of Jeff W. Lichtman and Joshua R.

Courtesy of Mr. Masayuki Sekiguchi (Section Chief)

Courtesy of Dr. Keiko Suzuki,

Sanes Harvard University MCB Department and the Center for

Department of Degenerative Neurological Diseases,

Department of Pharmacology, Showa University School of

Brain Science

National Institute of Neuroscience, National Center of

Dentistry

 

Neurology and Psychiatry

 

Hippocampal neurons

Rudimentary limbs of larva in latter part of 3rd instar

Fucci–Sliced mouse brain, expressing S/G2/M phases

Courtesy of Dr. Shigeo Okabe

Courtesy of Dr. Tetsuya Kojima

Courtesy of Dr. Hiroshi Kurokawa, Ms. Asako Sakaue-Sawano

Department of Cellular Neurobiology, Graduate School of

Laboratory of Innovational Biology, Department of Integrated

and Dr. Atsushi Miyawaki

Medicine, The University of Tokyo

Biosciences, Graduate School of Frontier Sciences, University

RIKEN Brain Science Institute Laboratory for Cell Function

 

of Tokyo

Dynamics

Cultured nerve cells derived from the mouse hippocampus

Zebrafish

Immunolabeling of a transgenic mouse retina showing the

Courtesy of Dr. Koji Ikegami, Dr. Mitsutoshi Setou

Courtesy of Dr. Toru Murakami,

major retinal cells types

Molecular Geriatric Medicine, Mitsubishi Kagaku Institute of Life

Department of Neuromuscular & Developmental Anatomy,

Courtesy of Dr. Rachel Wong, Mr. Josh Morgan

Sciences

Gunma University Graduate School of Medicine

Dept. Biological Structure, University of Washington, Seattle.

Cerebellum Purkinje cell

Medaka embryogenesis (somite stage)

Wild-type embryo in stage 17 of drosophila

Courtesy of Dr. Tetsuro Kashiwabara, Assistant Professor; and

Courtesy of Minoru Tanaka, Hiromi Kurokawa

Courtesy of Dr. Tetsuya Kojima

Dr. Akira Mizoguchi, Professor;

National Institute for Basic Biology Laboratory of Molecular

Laboratory of Innovational Biology, Department of Integrated

Neuroregenerative medicine course, Mie University School of

Genetics for Reproduction

Biosciences

Medicine

 

Graduate School of Frontier Sciences, University of Tokyo

Drosophila, Stage 14

Pilidium larva of Micrura alaskensis

Alpha Blend method (Cultured nerve cells derived from the

Courtesy of Dr. Tetsuya Kojima

Courtesy of Dr. Svetlana Maslakova of the University of

mouse hippocampus)

Laboratory of Innovational Biology, Department of Integrated

Washington and Dr. Mikhail V Matz of the Whitney Laboratory

Courtesy of Dr. Koji Ikegami, Dr. Mitsutoshi Setou

Biosciences Graduate School of Frontier Sciences, University

for Marine Bioscience, University of Florida.

Molecular Geriatric Medicine, Mitsubishi Kagaku Institute of Life

of Tokyo

 

Sciences

26

Image 27
Contents FV1000 Olympus is Open FLUOVIEW--FromIng up New Worlds Imaging to AnalysisAdvanced Fluoview Systems Enhance the Power of Your Research Page Excellent Precision, Sensitivity and Stability Laser combiner/FiberScanners/Detection Icity Optical SystemSamples and Specimens Filter Based Detection Spectral Based DetectionMulti-Purpose Laser Combiner SIM Simultaneous Scanner UnitSimultaneous Laser Light Stimulation and Imaging Wide Choice of Bleaching ModesFlatness Comparison Image at 1x Zoom Improved Flatness and Resolution at 405 nmNEW Low Chromatic Aberration Objective Best Reliability for Colocalization AnalysisFV1000MPE Multiphoton Excitation System User-Friendly Software to Support Your Research Multi-Area Time-Lapse Software Re-Use FunctionHelp Guide Multi Stimulation SoftwareFret Light Stimulation Multi-Dimensional Time-Lapse3D/4D Volume Rendering MeasurementFrap Analysis Diffusion Measurement PackageRICS-Raster Imaging Correlation Spectroscopy Point FCS-Point scan Fluorescence Correlation SpectroscopySpatial Correlation Algorithm Rics Application and PrinciplesRics Principle Rics Analysis MethodFRAP-Fluorescence Recovery after Photobleaching Laser Light StimulationFLIP-Fluorescence Loss in Photobleaching Photoconversion UncagingMulti-Point Laser Light Stimulation Maintain Cell Activity Over a Long Period Multi-Dimensional Time-LapseSignificantly Improved Long Time-Lapse Throughput Focal Drift Compensation for Long Time-Lapse Imaging3D Mosaic Imaging Mosaic Imaging for 3D XYZ ConstructionAutomated from 3D Image Acquisition to Mosaic Imaging Analysis Expandability to Support Diverse Application458 473 488 515 MCherry405 Ulti NHeNe ReeIllumination Units Optional Upgrade Equipments for FV1000Scanning Units Laser SystemsFV1000 System Diagram CO2 IncubatorHigh-Precision Motorized Stage/ Prior H117 Objectives for BX2 Main SpecificationsUsing U-UCD8A-2, IX2-LWUCDA2 and U-DICTS Using WI-UCD, WI-DICTHRA2Dimensions, Weight and Power Consumption Recommended FV1000 system setup IX81, BX61, BX61WIImages are courtesy of the following institutions Olympus Corpoaration is ISO9001/ISO14001 certified Fluoview website