Hitachi 3500
Mica Withington
Designed to operate with our EX2600-6, EX3600-6 and EX5600-6 ultra-large excavators, the
EH3500AC-3 has exceptional hauling capabilities and is built to operate in the toughest environments. The Advanced Hitachi AC Drive System ensures a smooth and quick operation, whether the truck is starting from a standstill, travelling uphill or performing steering manoeuvres.
The pitch control system reduces bouncing and rebounding when the truck travels over uneven ground and comes to a stop. The side skid control system reduces the chance of slipping when the truck is turning in slippery conditions by utilising changes in the wheel motor torque from left to right during cornering.
By reducing tyre slippage on acceleration and tyre lock-up during braking, Hitachi has achieved a high level of control on its dump trucks. The EH3500AC-3 has an impressive travel performance that ensures consistent haul cycle times, contributing to higher productivity.
The spacious cab fits two full-size seats and has a large multilingual LCD display in clear view of the operator. This provides important information and alerts on operations such as travelling speed, engine RPM and hauling performance, and is invaluable for improved safety and easy maintenance.
You can rent a wide range of Hitachi excavators and wheel loaders direct from Hitachi via our dealer network. Hitachi Premium Rental machines can be hired by the month and for periods up to one year. This gives you the high levels of reliability, quality and service you would expect from Hitachi, and greater flexibility to meet the varying demands of your business.
It's backed by award-winning support
Keeping your lab operational is critical. Our technical and field service support staffs respond quickly to your calls, so that you can continue to respond to those who depend on you for results.
Aneuploidy Detection by QF-PCR of STR Markers on the Applied Biosystems 3500xL Genetic Analyzer
BigDye Direct Cycle Sequencing Kit simplifies workflow for characterizing melanoma mutations in research samples
Development of a Workflow to Detect Sequence Variants in the BRCA1 and BRCA2 Genes
Development of an Interlaboratory-Verified Sequencing Workflow for KRAS Variant Identification
DNA Resequencing Analysis of X-linked Variants Using the Applied Biosystems 3500xL Genetic Analyzer
Fungal DNA sequencing from laser capture microdissection samples
High coverage gene expression profiling on the Applied Biosystems 3500xL Genetic Analyzer (1.6 MB)
ISSR Genotyping of Endangered Plants Using an Optimized Workflow
Resequencing Workflow for MLH1 and MSH2 Variant Analysis
SNP Gentyping Using SNaPshot Multiplex Kit and 3500 Series Genetic Analyzer
Uniparental disomy (UPD) analysis of chromosome 15 (3.2 MB)
Computer System Validation (CSV)
An instrument qualification service is only the starting point to your validation. Our Compliance Services professionals partner with you and can help you get into production faster, while controlling CSV costs and getting you audit-ready faster.
The Applied Biosystems 3500 Genetic Analyzer is a high-performance capillary electrophoresis instrument designed for DNA sequencing and fragment analysis applications. With a throughput of up to 96 samples per run, it offers rapid and efficient processing of genetic samples. The system can analyze DNA fragments ranging from 5 to 500 base pairs in length, providing high-resolution data for accurate genotyping, mutation detection, and sequencing projects. Its advanced optical detection system ensures sensitive and reliable detection of fluorescently labeled DNA fragments, enabling precise and reproducible results. The Applied Biosystems 3500 is widely used in research, clinical diagnostics, and forensic laboratories for a variety of genetic analysis applications.
Not only HP sold PA-RISC computers in the golden decade of Unix RISC workstations in the 90s. Several third party vendors organized in the Precision RISC Organisation (PRO) sold rebadged HP 9000 computers in East Asia in the mid-1990s or developed custom PA-RISC platforms.
These computers were shipped with Unix operating systems, geared towards technical and scientific users.Vendors either licensed HP-UX Unix directly or slightly modified it like Hitachi with HI-UX/WE2 and HI-UX/MPP or Samsung with SS-UX (?).Documentation on these computers and software is almost nonexistent, few sources describe them at all, except some press releases.
Hitachi and HP had a long-term alliance since 1989 that included joint PA-RISC development, before HP opened up the PA-RISC alliance with the PRO consortium in the 1990s.Hitachi then built several lines of computers with PA-RISC processors as part of that consortium over the next years: custom workstations (3050RX) and servers (3500) for HI-UX/WE2, and rebadged HP 9000, sold in Japan as Hitachi 9000V with HP-UX, and the SR2 supercomputers with HI-UX/MPP.
Hitachi designed a range of custom PA-RISC workstations for the Japanese market in the 90s.These very rare systems were apparently marketed as Hitachi Creative Station 3050RX Group and ran HI-UX/WE2, the Hitachi HP-UX variant.
Hitachi developed and produced a line of 32-bit supercomputers based on its own PA-RISC chips utilizing a hyper (3-D) crossbar design.Both ran Hitachi HI-UX/MPP, an Unix with Mach 3.0 microkernel extensions.
NEC Electronics of Japan was also a Precision RISC Organization (PRO) member and actively sold PA-RISC computers marketed as TX7 in the mid-1990s mostly in Japan.TX7 and NX7000 were often rebadged HP 9000 computers sold by NEC as OEM, with the custom P590 designed by NEC to fill the gap between D and K-Class.NEC PA-RISC computers ran licensed HP-UX Unix.
Similar to Mitsubishi in the early 1990s, Oki Electric Industry sold various PA-RISCworkstations and servers from HP rebranded as OEM systems.These were integrated into the OKITAC brand of OKI and shipped from 1992 onward mostly in Japan, running stock HP-UX.
OKI also developed a custom PA-RISC processor in the 1990s as member of the Precision RISC Organization (PRO) consortium.This OP32 processor was not used in its own workstations, but geared towards embedded devices.
Samsung Electronics produced and sold HP 9000 workstations under licence from 1993 on as part of the Precision RISC Organization, PRO.Custom workstations systems were designed by the Samsung Workstation Division in San Jose, USA, running SS-UX operating system with added I/O-features to HP-UX Unix, which Samsung also licensed from HP.
Samsung intended to sell the SWS715 through indirect channels to non-HP partners, targeting imaging and scientific visualisation, probably limited to the Korean market.Press releases mention Samsung planning to develop its own PA-RISC processor, with integrated memory technology, and separately port or ship Microsoft Windows NT to its PA-RISC computers.
OpenPA is an independent resource on PA-RISC computers, technology and operating systems, edited since 1999 by Paul Weissmann.He also publishes OpenKRITIS on critical infrastructures.OpenPA is a registered serial publication, ISSN 1866-2757.
The Hitachi LPWU3500 is a high-performance WUXGA projector designed to deliver superior image quality and versatility for professional presentations, large venues, and educational environments. With its impressive brightness, WUXGA resolution, and advanced features, the LPWU3500 ensures impactful visuals, making it a reliable choice for a wide range of applications.
In summary, the Hitachi LPWU3500 3500 ANSI Lumens WUXGA Projector is a powerful and versatile solution for demanding professional and educational environments. With its high brightness, WUXGA resolution, and advanced features, the LPWU3500 offers reliable performance and flexibility for a variety of presentation needs.
This laboratory is designed to introduce the Hitachi S-3500N Scanning Electron Microscope. You will investigate methods for sample preparation and look at the effects of condenser lens strength. In this initial laboratory, the methods for basic operation and alignment of the instrument will be covered. The purpose of this lab is to familiarize you with the standard operation of the SEM and general facility practices.
As you know from the class, SEM merely provides the means to generate and analyze myriad signals generated from electron-specimen interactions. Of all these signals, the most prolific imaging signal is from secondary electrons (SEs). Much of the imaging in this and many other labs will be done by imaging the SE signal in SEM.
Objective:
By the end of this laboratory session, you should be able to:
1. Prepare and mount both conductive and insulating samples for examination.
2. Start and align the Hitachi S-3500N SEM and explain the effects of the alignment upon the imaging conditions.
3. Increase the resolution of the SEM image through the use of the condenser lenses and explain the optics behind this increase.
Specimen Preparation:
Since SEM imaging involves bombarding a material with an electron beam, the surface of the sample will accumulate charge if the electrons are not allowed to escape from the surface via a conductive path. If there is no such path, the image formed by the SEM will be very poor. Charging can also lead to excessive heating of the sample, causing material degradation. Insulating and semiconducting materials, i.e. ceramics, polymers, and organics, should be coated with a conductive material to prevent surface charging. Usually, specimens are coated with either a metal or carbon.