Download Free Scanner Hp Ink Tank 310

Eliminate Tank Shifts, Gain Time

Tank shifts take time and compromise the stability of the original scanning setup. Because of its cylindrical shape, 3D SCANNER enables a 65 cm scan range -- allowing full 40 x 40 cm field scans, even at 100 cm SSD and 30 cm depth. Its shape and size remove the need for tank shifts.

Tank Scanner

Acquires data from field Instruments (15 tanks with Modbus or WM550 protocols and 10 with the V1 protocol). The inbuild web server enables the user to visualize the incoming data as well as the calculated values and configure the device.

Download Scanner Hp Ink Tank 310

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Deliver state-of-the-art thickness inspection results with the NAVIC - Tank Scanner. Paired with the actuated probe lift, the NAVIC operates remotely at a distance of up to 30 m (100 ft) while offering steering control and the ability to raise and lower the probe. Powerful, magnetic wheels drive vertically (and inverted) along the ferrous surfaces of tanks and vessels.

The NAVIC 2 - Base Crawler is a modular, motorized, steerable scanner that carries various attachments for scanning and inspection applications. The list of possibilities is seemingly endless with this industry-leading crawler. The NAVIC can perform circumferential and longitudinal inspections on ferrous tanks, pipes, and vessels.

Processing agricultural products at this scale involves storing huge quantities of produce in tanks and silos. Upkeep of these enormous vessels is a serious business. The tanks are a critical financial resource for the company as well as being subject to international safety standards. At PT Wilmar Nabati Indonesia, the project team must regularly inspect all above-ground storage tanks, reporting to management the measurements that indicate the integrity of the structures. Previously, tank inspection was a time-consuming manual process.

Already a Leica Geosystems user in other parts of the business, PT Wilmar chose to implement laser scanning. The company equipped the project team with Leica RTC360 laser scanners to digitally scan the silos and Cyclone 3DR software for data analysis. The RTC360 3D laser scanner has a measuring rate of up to two million points per second and with an advanced High-Dynamic Range (HDR) imaging system, coloured 3D point clouds can be completed in under two minutes.

Manual inspection was time consuming because to meet international standards of tank inspection (API 650/653), you need to accurately collect multiple datapoints, including diameter measurements, roundness, verticality of the tanks and settlement of the contents. This is in addition to measuring the volume of production, which is vital information for the business.

Using RTC360 laser scanners and Cyclone 3DR software for tank inspections has been a success for PT Wilmar Indonesia. Not only has the objective to improve efficiency been met, but the 3D scans have made it easier for the project team to report to management about maintenance and to compile their yearly audits.

Hello.

I just bought this printer and everything is working as it should.

But i noticed the scanner light is always blinking, even when the printer goes into sleep mode (when it turns off all lights but the power and wifi).

At first I thought it was only when the scanner lid was open, but I peeked with the lid closed and I can see it's still blinking. It only stops blinking when, obviously, I turn off the printer completely.

Everything works well, the scanner too. But I find it just odd that it always blinks like this. Is this normal? Surely it will shorten the life of the light?

Thanks in advance

Hello.

Thank you for your reply.

Neither worked.

Did the reset, but the scanner light is still blinking.

The printer firmware didn't update as it was already on the latest version.

Is the scanner light blinking normal? Because I've read other threads where people are saying it's normal and others that it isn't.

Im trying to help my cousin who's about to be given an HP Ink Tank 315. She only has a smartphone, so PC installation is a no go. How can we use the scanner of the printer through the smartphone itself?

Im testing it on my Huawei P30 Lite using an OTG adaptor, and the "HP Smart" app I installed wont detect it. The HP Print Service Plugin however can, and has no issue in printing a test pdf. I have already tested the printer on my pc, and both printer and scanner works well, through the HP Smart pc app from the store.

With oil storage in high demand, oil company owners and tank inspectors are rapidly maximizing tank assets, increasing the need for tank measurement and inspection using the most advanced technologies.

The combination of too much oil production, plummeting prices, and suppressed demand from the COVID-19 pandemic are driving a major effort to keep petroleum storage tanks and terminals in good repair, retrofit or improve old tanks so they are more efficient, and construct new tanks and tank farms.

Under this market pressure, oil producers, tank owner/operators and tank inspectors are looking for faster, more efficient inspection and construction methods, including 3D laser scanning, which enables quick, safe and accurate creation of point clouds of tank structures to reveal any problems.

Meanwhile, tank inspectors are learning how 3D laser scanning workflows can provide more complete and actionable information for their customers, which is more critical than ever as storage capacity is pushed to the limit.

In this post/article, we answer: How can owners/operators and tank inspectors move into a different type of tank measurement and inspection practice that is safer, more thorough and saves time?

Although they may look like simple structures, storage tanks are more complicated than they appear. Large petroleum storage tanks can be more than 500 feet (120 meters) in diameter and contain more than 1.5 million barrels. They also change over time, with large fluid volumes putting enormous stress and strain on tank walls and floors, leading to deformation. In addition, weather, subsidence and corrosion can lead to tank failures and the release of hazardous or toxic materials into the environment.

API 653 standards call for measured data on the verticality of tank shells, the roundness of tank shells, flatness of the tank bottom and any subsidence. Today, measurements that used to be gathered by surveying instruments known as total stations are increasingly made with laser scanning technology.

Laser scanners are roughly the same size as total stations and use a similar tripod and workflow in the field. To conduct a scan, the operator places the scanner at a few locations around a tank. In a few minutes, the scanner captures a point cloud consisting of closely spaced 3D points on the tank and structures. Depending on the size of the tank, the operator performs multiple scans to capture the entire site. In most situations, crews using high-speed scanners can complete the work in less than one hour.

Early lidar data-processing software was focused on managing point clouds and offered only limited functionality for analysis or modelling. With advances in software technology, the additional data from laser scanning offers a more detailed look at a tank, and the analysis process itself is far less cumbersome.

Today, software is used to take data from an inspection and automatically merge multiple point clouds into a single cohesive dataset. With the software enabling basic clean-up and organization, and the resulting point cloud provides a comprehensive and precise picture of the tank.

Once the scanning data is imported and processed, the software can be used to examine the entire tank, leading to recommendations and approaches for any required maintenance and repairs. On out-of-service tanks, where the interior is scanned, inspectors can get detailed maps of the tank bottom, using color-coding to indicate bends or depressions. Similarly, software can compare the tank shell to true vertical reference and automatically identify bulges or deformations that exceed a specified amount. This is where the benefits of laser scanning are really seen as the data shows the entirety of the tank surfaces, not just a sampling of areas that are documented with traditional methods.

The software also helps manage the area around a tank. With only a marginal increase in time on site, field operators can extend the scans to capture the surrounding ground and features. Customized analysis routines in the software enable technicians to efficiently isolate the structure or earthen berms that make up a secondary confinement. From there, the software can identify low areas or spill points in the containment berms, and then compute the capacity of the containment. This value is compared to the measured capacity of the tank to determine the efficacy of the secondary containment. The analysis can even account for an expected rainfall and adjust the containment capacity as needed.

Throughout the processing, analysis and reporting phases, the software provides a 3D visualization of a tank. Users can easily create virtual views from anywhere in the project, including viewpoints from inside or above the tank. Viewing software, provided at no charge, enables clients to view the project and make basic measurements while preserving the integrity of the original data.

The Focused Ultrasound Foundation has developed a low-cost, validated, open-source hydrophone scanner for the spatial characterization of ultrasound transducers. Assembly instructions and a MATLAB control graphical user interface are provided such that the device can be easily replicated for less than $1000 in roughly 40 person-hours. The low-cost scanning tank's performance was compared with data collected with a commercial automated scanning tank. Pressure measurements of a focused transducer and a planar transducer had less than a 10% difference between the two scanning systems. Two-dimensional automated scans (20 20 mm at 0.25-mm resolution) took the low-cost scanning tank 45 min compared with the commercial system's 30 min. A reproducibility study found that the low-cost scanner made consistent peak negative pressure measurements as reflected by the low coefficient of variation for both focused (1.88%) and planar (0.98%) transducers. The low-cost scanner described here is a viable alternative for ultrasound laboratories needing efficient, accurate characterization of ultrasound transducers. 2351a5e196