How Engineers stay on track

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Engineers hourly rate: $49,7

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Why should you use timesheet software for engineers?

A timesheet software is an essential tool for any engineer who is in charge of timesheets for their team or company. The main function of a timesheet is to keep track of meetings and tasks. You can track different projects and tasks either individually or as a team. Teams are divided into sub-teams (also known as groups) and different people from each sub-team can be assigned to different tasks.

Engineering timesheet software is used by engineers in a variety of ways. Salaries, client support, forecasting and documentation are just some of the uses that engineers have discovered for the product.

Knowing how engineers develop new ideas is crucial to the success of our businesses. Most of the time, we are focused on the problems that need to be solved. Now, with timesheet software, you will be able to simulate the entire process from brainstorming through implementation. This way, you will be able to get feedback faster and make changes before implementing anything new.

Engineering time tracking

Have you ever wondered what engineers actually do? What criteria go into engineering? Do they spend their time building things? Or designing things to fit into some larger design framework? Engineering time tracker will show you how much time each engineer spends on different tasks and what criteria determine which tasks are necessary for completing

Where is engineering time being tracked? Not in the most conventional form — like at a desk. More often, it’s in a visual way — such as via some sort of dashboard. But regardless of where its tracked, knowing where engineers spend their time is an important part of keeping them productive.

I’m going to share with you some of the best and easiest ways to design your engineering project times. This is a project idea that I added to my user story earlier this year where I wanted to take more control over my engineering time. This is by no means a perfect system, but it’s a good place to start making changes and tracks time well enough that I can easily see if it’s being done effectively.

Engineers work a lot and they need that time off. Think about all the daily tasks your engineers have, such as running tests, reviewing blueprints, or building prototype devices. They might have an unlimited vacation or simply not have to worry about that much so they can take off on weekends or relax during the week. But it’s important to work off steam and tired engineers at night and on weekends. You can’t solve a problem until you’re tired! This is why engineers need some type of time tracking software

A lot of people are used to working on their projects during the evening and paying themselves in cash. But making big-ticket purchases requires tracking time not spent working on the project. Just like managing your time on a weekly or monthly basis, tracking the time you spend doing engineering work is a great way to make sure that you’re getting value from your efforts.

Engineered time (ET) is the most common way that engineers count their time. This is the time per week, month, etc., that is spent working on a project. The definition can vary slightly according to employer, but generally means completed work under tight time constraints (often a few hours per day or at most 5 days per week).

Engineering time is critical to the success of any product or service. But what does optimizing engineers work entails? These questions and many more were asked by my manager as I prepared to start my new job. I was excited to work on an engineering project under a mentor who had more than 12 years of experience as an engineer. This is the best chance for me to learn how to run an engineering team, understand architecture and connectivity issues in real time and ultimately help build exceptional products.

Engineering is a team sport where you may be assigned to a particular project with instructions to fix an existing problem within a particular time frame. You are responsible for working on this issue and finishing before the deadline.Ideally, your tasks will be based around the product and process you are assigned to, but if you are doing something extra or related to the project your duties may become more broad.

What is the job of the Engineers

Engineers work across a number of industries, surveying, inspecting and testing anything from mechanical and electronic systems to power stations and even rockets. With the help of specialist equipment, they can measure the size, temperature or weight of an object, as well as determining if there are any flaws present that may need fixing. An engineer has many duties across various engineering disciplines, which include designing, developing, testing, analyzing, and revising designs for machines and equipment. The job description for an engineer can include responsibilities for manufacturing, quality Control, computer-aided design, energy efficiency, transportation, and other fields. Engineers may work for manufacturing companies producing components or products using traditional manufacturing techniques, or they may work for specialized manufacturing or distribution companies that specialize in designing and manufacturing automation systems.

Key tasks of the Engineers

  • Identify and recommend energy savings strategies to achieve more energy-efficient operation.
  • Conduct energy audits to evaluate energy use and to identify conservation and cost reduction measures.
  • Monitor and analyze energy consumption.
  • Monitor energy related design or construction issues, such as energy engineering, energy management, or sustainable design.
  • Inspect or monitor energy systems, including heating, ventilating, and air conditioning (HVAC) or daylighting systems to determine energy use or potential energy savings.
  • Advise clients or colleagues on topics such as climate control systems, energy modeling, data logging, sustainable design, or energy auditing.
  • Analyze, interpret, or create graphical representations of energy data, using engineering software.
  • Verify energy bills and meter readings.
  • Collect data for energy conservation analyses, using jobsite observation, field inspections, or sub-metering.
  • Manage the development, design, or construction of energy conservation projects to ensure acceptability of budgets and time lines, conformance to federal and state laws, or adherence to approved specifications.
  • Perform energy modeling, measurement, verification, commissioning, or retro-commissioning.
  • Review architectural, mechanical, or electrical plans or specifications to evaluate energy efficiency.
  • Prepare energy-related project reports or related documentation.
  • Review or negotiate energy purchase agreements.
  • Train personnel or clients on topics such as energy management.
  • Direct the implementation of energy management projects.
  • Research renewable or alternative energy systems or technologies, such as solar thermal or photovoltaic energy.
  • Promote awareness or use of alternative or renewable energy sources.
  • Write or install energy management routines for building automation systems.
  • Recommend best fuel for specific sites or circumstances.
  • Design engineering systems for the automation of industrial tasks.
  • Create mechanical design documents for parts, assemblies, or finished products.
  • Maintain technical project files.
  • Implement or test design solutions.
  • Create mechanical models and tolerance analyses to simulate mechatronic design concepts.
  • Conduct studies to determine the feasibility, costs, or performance benefits of new mechatronic equipment.
  • Publish engineering reports documenting design details or qualification test results.
  • Research, select, or apply sensors, communication technologies, or control devices for motion control, position sensing, pressure sensing, or electronic communication.
  • Identify and select materials appropriate for mechatronic system designs.
  • Apply mechatronic or automated solutions to the transfer of materials, components, or finished goods.
  • Design advanced precision equipment for accurate or controlled applications.
  • Upgrade the design of existing devices by adding mechatronic elements.
  • Analyze existing development or manufacturing procedures and suggest improvements.
  • Provide consultation or training on topics such as mechatronics or automated control.
  • Oversee the work of contractors in accordance with project requirements.
  • Create schematics and physical layouts of integrated microelectromechanical systems (MEMS) components or packaged assemblies consistent with process, functional, or package constraints.
  • Investigate characteristics such as cost, performance, or process capability of potential microelectromechanical systems (MEMS) device designs, using simulation or modeling software.
  • Create or maintain formal engineering documents, such as schematics, bills of materials, components or materials specifications, or packaging requirements.
  • Conduct analyses addressing issues such as failure, reliability, or yield improvement.
  • Plan or schedule engineering research or development projects involving microelectromechanical systems (MEMS) technology.
  • Propose product designs involving microelectromechanical systems (MEMS) technology, considering market data or customer requirements.
  • Develop formal documentation for microelectromechanical systems (MEMS) devices, including quality assurance guidance, quality control protocols, process control checklists, data collection, or reporting.
  • Communicate operating characteristics or performance experience to other engineers or designers for training or new product development purposes.
  • Analyze system performance or operational requirements.
  • Develop optical or imaging systems, such as optical imaging products, optical components, image processes, signal process technologies, or optical systems.
  • Develop or test photonic prototypes or models.
  • Design, integrate, or test photonics systems or components.
  • Assist in the transition of photonic prototypes to production.
  • Read current literature, talk with colleagues, continue education, or participate in professional organizations or conferences to keep abreast of developments in the field.
  • Write reports or proposals related to photonics research or development projects.
  • Conduct testing to determine functionality or optimization or to establish limits of photonics systems or components.
  • Determine applications of photonics appropriate to meet product objectives or features.
  • Conduct research on new photonics technologies.
  • Design electro-optical sensing or imaging systems.
  • Document photonics system or component design processes, including objectives, issues, or outcomes.
  • Design photonics products, such as light sources, displays, or photovoltaics, to achieve increased energy efficiency.
  • Train operators, engineers, or other personnel.
  • Analyze, fabricate, or test fiber-optic links.
  • Design gas lasers, solid state lasers, infrared, or other light emitting or light sensitive devices.
  • Create or maintain photonic design histories.
  • Oversee or provide expertise on manufacturing, assembly, or fabrication processes.
  • Determine commercial, industrial, scientific, or other uses for electro-optical applications or devices.
  • Review or approve designs, calculations, or cost estimates.
  • Process or interpret signals or sensor data.
  • Debug robotics programs.
  • Build, configure, or test robots or robotic applications.
  • Create back-ups of robot programs or parameters.
  • Provide technical support for robotic systems.
  • Design end-of-arm tooling.
  • Design robotic systems, such as automatic vehicle control, autonomous vehicles, advanced displays, advanced sensing, robotic platforms, computer vision, or telematics systems.
  • Supervise technologists, technicians, or other engineers.
  • Design software to control robotic systems for applications, such as military defense or manufacturing.
  • Conduct research on robotic technology to create new robotic systems or system capabilities.
  • Investigate mechanical failures or unexpected maintenance problems.
  • Integrate robotics with peripherals, such as welders, controllers, or other equipment.
  • Evaluate robotic systems or prototypes.
  • Install, calibrate, operate, or maintain robots.
  • Conduct research into the feasibility, design, operation, or performance of robotic mechanisms, components, or systems, such as planetary rovers, multiple mobile robots, reconfigurable robots, or man-machine interactions.
  • Document robotic application development, maintenance, or changes.
  • Design automated robotic systems to increase production volume or precision in high-throughput operations, such as automated ribonucleic acid (RNA) analysis or sorting, moving, or stacking production materials.
  • Write algorithms or programming code for ad hoc robotic applications.
  • Make system device lists or event timing charts.
  • Write proposals to secure external funding or to partner with other companies.
  • Synthesize, process, or characterize nanomaterials, using advanced tools or techniques.
  • Supervise technologists or technicians engaged in nanotechnology research or production.
  • Prepare reports, deliver presentations, or participate in program review activities to communicate engineering results or recommendations.
  • Provide scientific or technical guidance or expertise to scientists, engineers, technologists, technicians, or others, using knowledge of chemical, analytical, or biological processes as applied to micro and nanoscale systems.
  • Conduct research related to a range of nanotechnology topics, such as packaging, heat transfer, fluorescence detection, nanoparticle dispersion, hybrid systems, liquid systems, nanocomposites, nanofabrication, optoelectronics, or nanolithography.
  • Identify new applications for existing nanotechnologies.
  • Design or conduct tests of new nanotechnology products, processes, or systems.
  • Develop processes or identify equipment needed for pilot or commercial nanoscale scale production.
  • Generate high-resolution images or measure force-distance curves, using techniques such as atomic force microscopy.
  • Design nano-enabled products with reduced toxicity, increased durability, or improved energy efficiency.
  • Provide technical guidance or support to customers on topics such as nanosystem start-up, maintenance, or use.
  • Prepare nanotechnology-related invention disclosures or patent applications.
  • Engineer production processes for specific nanotechnology applications, such as electroplating, nanofabrication, or epoxy.
  • Design or engineer nanomaterials, nanodevices, nano-enabled products, or nanosystems, using three-dimensional computer-aided design (CAD) software.
  • Develop catalysis or other green chemistry methods to synthesize nanomaterials, such as nanotubes, nanocrystals, nanorods, or nanowires.
  • Apply nanotechnology to improve the performance or reduce the environmental impact of energy products, such as fuel cells or solar cells.
  • Create designs or prototypes for nanosystem applications, such as biomedical delivery systems or atomic force microscopes.
  • Design nanosystems with components such as nanocatalysts or nanofiltration devices to clean specific pollutants from hazardous waste sites.
  • Create or maintain wind farm layouts, schematics, or other visual documentation for wind farms.
  • Recommend process or infrastructure changes to improve wind turbine performance, reduce operational costs, or comply with regulations.
  • Create models to optimize the layout of wind farm access roads, crane pads, crane paths, collection systems, substations, switchyards, or transmission lines.
  • Create plans for solar energy system development, monitoring, and evaluation activities.
  • Conduct engineering site audits to collect structural, electrical, and related site information for use in the design of residential or commercial solar power systems.
  • Design or coordinate design of photovoltaic (PV) or solar thermal systems, including system components, for residential and commercial buildings.
  • Create electrical single-line diagrams, panel schedules, or connection diagrams for solar electric systems, using computer-aided design (CAD) software.
  • Review specifications and recommend engineering or manufacturing changes to achieve solar design objectives.
  • Develop design specifications and functional requirements for residential, commercial, or industrial solar energy systems or components.
  • Provide technical direction or support to installation teams during installation, start-up, testing, system commissioning, or performance monitoring.
  • Perform computer simulation of solar photovoltaic (PV) generation system performance or energy production to optimize efficiency.
  • Develop standard operation procedures and quality or safety standards for solar installation work.
  • Create checklists for review or inspection of completed solar installation projects.
  • Test or evaluate photovoltaic (PV) cells or modules.
  • Perform thermal, stress, or cost reduction analyses for solar systems.
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What other tasks a Engineers may have

  • Consult with construction or renovation clients or other engineers on topics such as Leadership in Energy and Environmental Design (LEED) or Green Buildings.
  • Design, develop, or implement control circuits or algorithms for electromechanical or pneumatic devices or systems.
  • Design advanced electronic control systems for mechanical systems.
  • Develop electronic, mechanical, or computerized processes to perform tasks in dangerous situations, such as underwater exploration or extraterrestrial mining.
  • Design mechatronics components for computer-controlled products, such as cameras, video recorders, automobiles, or airplanes.
  • Create embedded software design programs.
  • Evaluate materials, fabrication methods, joining methods, surface treatments, or packaging to ensure acceptable processing, performance, cost, sustainability, or availability.
  • Refine final microelectromechanical systems (MEMS) design to optimize design for target dimensions, physical tolerances, or processing constraints.
  • Conduct harsh environmental testing, accelerated aging, device characterization, or field trials to validate devices, using inspection tools, testing protocols, peripheral instrumentation, or modeling and simulation software.
  • Develop or file intellectual property and patent disclosure or application documents related to microelectromechanical systems (MEMS) devices, products, or systems.
  • Conduct or oversee the conduct of prototype development or microfabrication activities to ensure compliance to specifications and promote effective production processes.
  • Conduct experimental or virtual studies to investigate characteristics and processing principles of potential microelectromechanical systems (MEMS) technology.
  • Devise microelectromechanical systems (MEMS) production methods, such as integrated circuit fabrication, lithographic electroform modeling, or micromachining.
  • Develop or validate specialized materials characterization procedures, such as thermal withstand, fatigue, notch sensitivity, abrasion, or hardness tests.
  • Validate fabrication processes for microelectromechanical systems (MEMS), using statistical process control implementation, virtual process simulations, data mining, or life testing.
  • Demonstrate miniaturized systems that contain components, such as microsensors, microactuators, or integrated electronic circuits, fabricated on silicon or silicon carbide wafers.
  • Manage new product introduction projects to ensure effective deployment of microelectromechanical systems (MEMS) devices or applications.
  • Conduct acceptance tests, vendor-qualification protocols, surveys, audits, corrective-action reviews, or performance monitoring of incoming materials or components to ensure conformance to specifications.
  • Develop or implement microelectromechanical systems (MEMS) processing tools, fixtures, gages, dies, molds, or trays.
  • Develop customer documentation, such as performance specifications, training manuals, or operating instructions.
  • Identify, procure, or develop test equipment, instrumentation, or facilities for characterization of microelectromechanical systems (MEMS) applications.
  • Develop or validate product-specific test protocols, acceptance thresholds, or inspection tools for quality control testing or performance measurement.
  • Oversee operation of microelectromechanical systems (MEMS) fabrication or assembly equipment, such as handling, singulation, assembly, wire-bonding, soldering, or package sealing.
  • Design solar energy photonics or other materials or devices to generate energy.
  • Design or redesign optical fibers to minimize energy loss.
  • Develop photonics sensing or manufacturing technologies to improve the efficiency of manufacturing or related processes.
  • Develop laser-processed designs, such as laser-cut medical devices.
  • Design or develop new crystals for photonics applications.
  • Design laser machining equipment for purposes such as high-speed ablation.
  • Select, purchase, set up, operate, or troubleshoot state-of-the-art laser cutting equipment.
  • Design or program robotics systems for environmental clean-up applications to minimize human exposure to toxic or hazardous materials or to improve the quality or speed of clean-up operations.
  • Plan mobile robot paths and teach path plans to robots.
  • Design robotics applications for manufacturers of green products, such as wind turbines or solar panels, to increase production time, eliminate waste, or reduce costs.
  • Automate assays on laboratory robotics.
  • Coordinate or supervise the work of suppliers or vendors in the designing, building, or testing of nanosystem devices, such as lenses or probes.
  • Design nano-based manufacturing processes to minimize water, chemical, or energy use, as well as to reduce waste production.
  • Design nanoparticle catalysts to detect or remove chemical or other pollutants from water, soil, or air.
  • Reengineer nanomaterials to improve biodegradability.
  • Integrate nanotechnology with antimicrobial properties into products, such as household or medical appliances, to reduce the development of bacteria or other microbes.
  • Develop green building nanocoatings, such as self-cleaning, anti-stain, depolluting, anti-fogging, anti-icing, antimicrobial, moisture-resistant, or ultraviolet protectant coatings.
  • Provide engineering technical support to designers of prototype wind turbines.
  • Investigate experimental wind turbines or wind turbine technologies for properties such as aerodynamics, production, noise, and load.
  • Develop active control algorithms, electronics, software, electromechanical, or electrohydraulic systems for wind turbines.
  • Develop specifications for wind technology components, such as gearboxes, blades, generators, frequency converters, or pad transformers.
  • Test wind turbine components, using mechanical or electronic testing equipment.
  • Oversee the work activities of wind farm consultants or subcontractors.
  • Test wind turbine equipment to determine effects of stress or fatigue.
  • Monitor wind farm construction to ensure compliance with regulatory standards or environmental requirements.
  • Direct balance of plant (BOP) construction, generator installation, testing, commissioning, or supervisory control and data acquisition (SCADA) to ensure compliance with specifications.
  • Analyze operation of wind farms or wind farm components to determine reliability, performance, and compliance with specifications.
  • Perform root cause analysis on wind turbine tower component failures.
  • Design underground or overhead wind farm collector systems.
  • Write reports to document wind farm collector system test results.
  • Design or develop vacuum tube collector systems for solar applications.
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Top reasons to use time tracking for Engineers

Organize your paperwork and comply with legal requirements

Use Monitask for complete control over your employees' working hours and get information about the hours worked in the form of convenient reports.
Demonstrating the total number of hours spent each year helps support your business and increases transparency with your customers.

Receive more grants and investments

Proper time calculations will ensure that you have supporting documents and data to show when you apply for investments or search for new strategic partners.

Save on payroll and identify bottlenecks

Review daily timesheets and productivity scores to identify bottlenecks and ways to improve your operations quickly.
Implementing the correct time-tracking solution always results in reduced payroll costs for part-time and full-time employees, and companies can get more things done for each dollar they invest in their recruitment efforts.

Improve staffing and scheduling

Scheduling takes the guesswork out of the project's management.
By reviewing scheduling reports, managers can quickly identify efforts and estimated the workforce needed to complete the projects on time.

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