Fabrication Tenders

Description: France – School-meal Services – Restauration Collective Pour Les Écoles, Le Centre Aéré Et Le Foyer Restaurant : Fabrication Et Livraison En Liaison Chaude

Details: Amendment 0002 To The Rfp Is Hereby Issued And Attached For Download. The Purpose Of The Amendment Is To Make The Following Changes To The Solicitation: responses To Rfi Questions submission Due Date Time Extension --------------------------------------------------------------------------------------------------------------- amendment 0001 To The Rfp Is Hereby Issued And Attached For Download. The Purpose Of The Amendment Is To Make The Following Changes To The Solicitation: response To Rfi Questions One ------------------------------------------------------------------------------------------------------------------ this Request For Proposals (rfp) Is For Smithsonian Institution's National Museum American History (nmah) To Move Collections Within The American History Building (ahb), Provide New Smithsonian Approved Collections Housing For All Identified Artifacts, Perform Basic Collections Photography, Documentation, Condition Reporting, Rehouse Artifacts, Track All Collection Location Changes, And Move The Collections To The Smithsonian Suitland Collections Center (scc), And Unpack At Either The Museum Support Center (msc) Pod 6 Or A Paul E. Garber Facility (garber) Designated Building. The Contractor Receiving The Award Shall Provide All Supervision, Labor, Materials, Equipment And Transportation Required To Complete The Work As Described In This Rfp And The Contract Documents. the Smithsonian Currently Estimates That The Fixed Price For The Entire Project Will Be More Than $10,000,000. the Period Of Performance For The Contract Is 1095 Calendar Days From The Notice To Proceed. statement Of Work the Successful Offeror Shall Provide All Materials, Equipment, Labor And Supervision Necessary To Complete The Following Work At The Smithsonian Institution, National Museum Of American History (nmah), 1300 Constitution Avenue Nw, Washington Dc, 20560 And Smithsonian Institution's Suitland Collections Center (ssc), 4210 Silver Hill Road, Suitland, Maryland 20746. the Work Includes, But Is Not Limited To, All Work Specified In The Scope Of Work And Consists Of Drawings, Specifications And A Preliminary Object List. the Objective Of The Nmah Psrp Iv Collections Move Project Is To Relocate Nmah Collections From Nmah To Off-site Storage At The Scc And Includes The Following: a. Project Management Services: Supply A Dedicated Project Manager (pm) With Art Handling Services Background To Lead A Multi-disciplinary Team. Work Will Include: creating And Maintaining A Detailed Schedule For All Move Activities; coordinating With The Designated Nmah Move Coordinator And Project Cotr On Schedules, Coordination, Cost, And Hold Weekly Progress Report Meetings; handling The Resolution Of Any Problems That Interfere With The Progress Of The Project; identifying And Investigating Problems And Making Recommendations For Resolution To Cotr; providing Collections And Storage Space Access For Move Team; advising On Collections Housing, Packing, Documentation, And Shipping Methods; providing Technical Interface Between The Museum Artifact Inventory System (cis Xg) And Barcoding Systems (managing The Collections Information), And The Contractor's Housing And Packing Logs And Shipping Manifests (contract Management Tools); coordinating With The Nmah Move Coordinator On Delivery Of Supplies (boxes, Trays, Acid Free Tissue, Etc. Containers/crates Either In Parts Or Constructed At Another Site And Delivered For Packing; Housing Supplies; Tools And Equipment For Housing/packing/photography); And Staging For Them Until Use And Shipment To The Scc; coordinating Disposal Of Old Cabinetry And Containers As They Are Emptied And The Collections Are Housed And Packed, And Shipped To Scc For Storage On Or In New Rack And Cabinets; ensuring Condition Documentation, Photography, Location Tracking, And Object Number Reconciliation Are Built Into The Workflow; overseeing Contractors/objects Transit Between Facilities (e.g. Travel From Nmah To Off-site Storage At The Scc Required); overseeing Contractors To Remove Boxed Collections From Shipping Containers And Store Them On Pallet Racking And In Cabinets At The Scc, And Updating Final Location Data; b.packing And Storage Arrangements For Museum Collections. Preparing Collections For A Move From One Location To Another Following All Safety And Preservation Requirements. Work Will Include: establishing, And Moving Artifacts Within Nmah To Processing Area(s) For Organizing, Documenting, Photographing, Condition Reporting, And Housing Artifacts For Storage In New Cabinets At The Scc – Using Housing Methods That Demonstrate Economies Of Scale For Like Collections, And With Housing Dimensions Fit To Cabinet/racking Configurations At The Scc – Then Packing The Housed Artifacts For Shipment; after Artifact Processing Is Complete And The Artifacts Are Containerized For Relocation, Moving Them To Staging While Awaiting Relocation To Pod 6 At The Scc, And Then Staging, Unpacking, Tracking, And Storing The Artifacts On Stationary Racking Systems, And On Manually Operated Mobile Pallet Rack Systems, And On Manually Operated Mobile Cabinetry Systems Located On (3) Separate Floors Accessible By Elevator. The Mobile Pallet Rack System Sections Are 11' H X 12'w X 4' D, With 3-4 Racks To A Carriage. These Racks Must Be Balanced As Loaded. tracking Collections In Storage, Staging, And Transit Using Barcode System That Is Separate But Interfaced With Contractor's Manifest System, Including Final Storage Updates; coordinating Shipping And Access With Move Coordinator And Other Tenants Moving Into Pod 6 Concurrently; c. Physical Transit Of Art And Museum Objects From Nmah To Scc. Work Includes: providing The Secure And Climate-controlled Air-ride Vehicles With Working Lift-gate, Constant Surveillance, And The Drivers And Any Necessary Permits Or Additional Escort Vehicles; loading And Off-loading Collections Objects From Vehicles; Moving Crates And Objects To Or From The Gallery Or Venue (floor And Shelf As Identified By Nmah Staff); documenting And Alerting The Museum To Collections Found In Poor Condition And Requiring Special Stabilization Or Conservation Treatment Prior To Housing, Packing, And Shipment; designing And Fabricating Crate Interior Fittings And Outer Shells; providing Specialized Equipment, Tools, And Supplies Needed To Move The Works; condition Reporting And Data Entry Of Documentation Into Nmah’s Collection Management System (mimsy Xg). types Of Transportation Vehicles Include: Vans, Box Trucks Or Other Vehicles Meeting The Nmah Loading Dock Size Limitations (13’3” High, 42’ Long). General Standards For Museum Collections Transportation Vehicles Are: 1. The Truck Shall Be Equipped With Air Ride Suspension, A Working Lift Gate, Pallet Jacks, Dual Drivers, Constant Surveillance Service, And Climate Control. 2. Climate Must Be Maintained At 70 Degrees, +/- 2 Degrees Over The Duration Of The Trip. 3. Smithsonian May Monitor Truck Temperature, Humidity Gps Location And Shock Readings. 4. Crates And Packages Shall Be Secured To Prevent Shifting Or Movement During Transport And Shall Not Be Stacked. 5. Pickup And Delivery Should Occur During Normal Business Hours And A Schedule Of The Transit Is To Be Submitted With The Estimate. 6. Stoppage Time Is Not Allowed. d. Rigging. Provide All Engineering And Equipment Expertise To Install Or Deinstall Large Or Suspended Artifacts Ranging From Fine Art Works To Vehicles. Specific Objects Known To Require Rigging Are Identified In The Scope Of Work. Work Includes: producing Engineering And Architecture Drawings; developing A Safety Plan; arranging Suitable Equipment Including Trucks, Gantry, Pallet Jacks, Personnel Lifts, Forklifts, And Other Handling Equipment, Hardware, And Tools; fabricating Supports And Mounts In Suitable Size And Shape, In Compliance With Applicable Safety Regulations And Standards, And Providing Experienced And Licensed Or Certified Equipment Operators. subcontracting Goals the Subcontracting Goals For This Project Are: 40% With Small Business Concerns. At Least 7% Of Total Planned Subcontracting Dollars Shall Be Placed With Small Disadvantaged Businesses (sdb), Including Historically Black Colleges And Universities Or Minority Institutions; 7% With Women-owned Small Businesses (wosb); 4% Shall Be Placed With Hub-zone Small Businesses (hubsb), 4% With Veteran-owned Small Businesses (vosb); And 4% With Service-disabled Veteran-owned Small Businesses (sdv). the Proposal Due Date Is Wednesday, March 19, 2025, At 3:00 Pm Eastern Standard Time.

Description: Scrap U/s Ms, Gi, Ci Pipes, Signal Post And Fabricated Material Of Pipes Various Sort-various Sizes With Integral Nf, Rubber Attachment Of Minor Nature. Location : Behind A Ward , Near Bin No. 408

Design and Manufacture of Furniture for the Activity Room of the National Design Gallery

Collective Catering for Schools, Recreation Centers and Restaurant Centers: Production and Delivery in Hot Connection

Printing Services, Graphic Design, Supply of Promotional Items, Manufacturing of Communication Media and Videos for Toulouse-III Paul Sabatier University

Details: Invitation to Tender for “Design, Manufacture / fabrication, assembly, testing, shop inspection, painting and supply & delivery of High Pressure Hydro Jet Coke Oven Door Cleaners in a Fixed Station including all commissioning spares, Supervision of Erection, testing, trial run, commissioning and demonstration of Performance Guarantee Parameters in presence of OEM of the system and Two year’s operational & maintenance spares (optional) (Pkg. No. SS-410),” required for rebuilding of Coke Oven Battery no. 6 at SAIL, Bokaro Steel Limited, Bokaro, Jharkhand..

Details: Efficient Additive Manufacturing For Advanced U-x Nuclear Fuel Alloys revolutionizing Nuclear Fuel Production With A Streamlined, Cost-effective Additive Manufacturing Process For U-x Alloys. the Challenge fabricating U-x Compounds Like U3si2 And U-mo Alloys For Nuclear Applications Is Plagued By Inefficiencies And High Costs. Traditional Methods Require Multiple Processing Steps, Such As Powder Fabrication, Pressing, And Sintering, All Of Which Introduce Production Delays And Increased Safety Concerns. Moreover, The Reliance On Uranium Metal And Conventional Techniques Creates Additional Hazards And Regulatory Challenges, Impeding Commercial Scalability And Adoption. how It Works this Patented Technology Employs A Laser Engineered Net Shaping (lens) Additive Manufacturing Process To Directly Fabricate U-x Alloys And Compounds: precision Deposition: The Lens System Uses A Localized Melt Pool To Blend Multiple Powder Sources, Ensuring Uniform Chemical Composition And Properties. versatility: The Method Accommodates Gas/solid And Solid/solid Reactions, Enabling The Production Of Various Fuel Types, Including Monolithic And Dispersive Metallic Fuels. minimized Variability: Controlled Deposition Minimizes Absorptance Fluctuations, Ensuring Consistency In Material Properties. simplified Workflow: This Eliminates Intermediate Steps Such As Powder Preparation And Pressing, Directly Converting Uranium Precursors Like Uf4 Into Finished Fuel Forms. key Advantages reduced Complexity: Eliminates Multiple Traditional Steps, Streamlining The Manufacturing Process. lower Costs: Avoids The Need For Uranium Metal, Reducing Material Costs And Associated Security Requirements. enhanced Safety: Minimizes Hazards By Replacing Traditional Powder Metallurgy With Additive Techniques. improved Thermal Conductivity: Facilitates The Production Of Accident-tolerant Fuels Like U3si2, With Superior Thermal Performance Compared To Uo2. customizable Fuel Designs: Enables Precise Control Over Alloy Composition, Supporting Tailored Solutions For Diverse Reactor Needs. market Applications commercial Nuclear Reactors: Fabrication Of U3si2 As A Next-generation Accident-tolerant Fuel For Light Water Reactors. research Reactors: Production Of Low-enriched Uranium Fuels, Such As U-mo Monolithic And Al-matrix Dispersive Fuels, Essential For Scientific Research And Isotope Production. defense And Space Applications: Advanced Nuclear Fuels For Specialized Reactors In Defense And Space Exploration. inl’s Technology Deployment Department Focuses Solely On Licensing Intellectual Property And Collaborating With Industry Partners Who Can Commercialize Our Innovations. we Do Not Engage In Purchasing, Procurement, Or Hiring External Services For Technology Development. Our Objective Is To Connect With Companies Interested In Licensing And Bringing Our Technologies To Market.

Details: Titanium-tantalum Alloy Manufacturing For Biomedical And Engineering Applications an Innovative Electrochemical Process Delivering Cost-effective, Sustainable Solutions For Alloy Coatings And Bulk Manufacturing Directly From Metal Oxides. the Challenge traditional Methods For Manufacturing Titanium-tantalum Alloys Rely On Energy-intensive Melting Or Complex Powder Metallurgy (pm) Processes. These Approaches Are Time-consuming, Expensive, And Generate Significant Material Waste, Particularly From Degraded Components Exposed To Corrosive Environments During Production. As Demand For Advanced Biomedical Materials And High-performance Alloys Grows, The Industry Faces Pressure To Innovate Cost-effective And Sustainable Manufacturing Technologies. how It Works this Groundbreaking Process Utilizes The “contact Electrode” Concept To Synthesize Titanium-tantalum Alloys Directly From Tantalum Oxide: direct Electrochemical Reduction: Tantalum Oxide Is Electrochemically Reduced In Molten Calcium Chloride, Releasing Oxygen Ions To The Electrolyte. in Situ Alloy Formation: The Reduced Tantalum Reacts Chemically With A Titanium Current Collector To Form The Alloy During The Reduction Process. versatility: The Method Is Applicable To Both Alloy Coatings And Bulk Alloys, Supporting A Wide Range Of Manufacturing Needs. low-waste Approach: Unlike Traditional Methods, The Current Collector Is Intentionally Incorporated Into The Final Alloy, Eliminating Waste And Maximizing Material Use. key Advantages cost Efficiency: Simplifies Manufacturing By Eliminating Intermediate Processing Steps, Reducing Time And Energy Consumption. material Versatility: Enables Synthesis Of Advanced Engineering Alloys Directly From Oxide Precursors. sustainability: Converts Degraded Current Collectors Into Valuable Alloy Materials, Reducing Industrial Waste. scalability: Offers Potential Integration With Additive Manufacturing (am) Techniques For Near-net-shape Production. biomedical Potential: Titanium-tantalum Alloys Are Ideal For Applications Such As Implants, Thanks To Their Biocompatibility And Corrosion Resistance. market Applications biomedical Devices: Manufacturing Biocompatible Titanium-tantalum Alloys For Implants And Prosthetics. metal And Structural Materials: Producing High-performance Alloys For Aerospace, Automotive, And Defense Applications. corrosion-resistant Coatings: Creating Durable Alloy Coatings For Industrial Equipment. additive Manufacturing Integration: Fabricating Near-net-shape Alloy Components For Advanced Engineering Applications. inl’s Technology Deployment Department Focuses Solely On Licensing Intellectual Property And Collaborating With Industry Partners Who Can Commercialize Our Innovations. we Do Not Engage In Purchasing, Procurement, Or Hiring External Services For Technology Development. Our Objective Is To Connect With Companies Interested In Licensing And Bringing Our Technologies To Market.

Details: High-temperature Compact Heat Exchangers For Harsh Environments refractory Metal Designs With Embedded Sensors For Enhanced Performance And Reliability the Challenge high-temperature Compact Heat Exchangers (chxs) Are Vital For Industries Like Power Generation, Chemical Processing, And Metallurgy. However, Existing Solutions Made From Nickel-based Alloys Face Critical Limitations: temperature Constraints: Mechanical Strength Deteriorates Above 750°c. corrosion Issues: May Exhibit Poor Resistance To Harsh Environments, Such As Molten Salts. design Limitations: 2d Channel Configurations Restrict Heat Transfer Efficiency. energy-intensive Manufacturing: Current Techniques, Like Diffusion Bonding And Brazing, Are Challenging, Resource-heavy, And Inefficient. these Barriers Prevent Chxs From Reaching The Temperatures Needed For Peak Efficiency And Long-term Durability In Extreme Conditions. how It Works this Novel Technology Introduces High-performance Chxs Using Mo- And W-based Refractory Alloys Combined With Advanced Manufacturing Techniques: refractory Alloy Design: Mo- And W-based Alloys Are Optimized For Superior Corrosion Resistance (200%+ Improvement Over Conventional Materials) And Mechanical Strength At Temperatures Up To 1500°c. 3d Channel Fabrication: Customizable 3d Flow Channels Are Created Using Traditional Additive Manufacturing And Digital Light Projection (dlp) Printing, Significantly Improving Heat Transfer Efficiency. efficient Sintering Process: Electric Field Assisted Sintering (efas) Compacts Refractory Alloys Into Robust Structures, Achieving A 70–90% Reduction In Energy Consumption During Manufacturing. embedded Sensors: Aerosol Jet Printing (ajp) Integrates Multimodal Sensors For Real-time Structural Health Monitoring (shm), Enabling Advanced Safety And Reliability Monitoring. this Integrated Approach Allows For The Fabrication Of Durable, High-performance Chxs Designed For Extreme Environments. key Advantages enhanced Durability: Operates At Temperatures 2x Higher Than Nickel Alloys With Superior Corrosion Resistance. energy Efficiency: Reduces Manufacturing Energy Use By Up To 90% Compared To Diffusion Bonding. customizable Designs: Enables Freeform 3d Channels For Improved Heat Transfer And Flow Performance. embedded Monitoring: Integrated Sensors Provide Real-time Data On Temperature And Strain For Proactive Maintenance. cost Savings: Lowers Production Costs By Over 30%, With Scalable Methods Suitable For Industrial Deployment. market Applications power Generation: Enhances Efficiency In Advanced Nuclear And Concentrated Solar Power Systems. chemical Processing: Enables Reliable Operations In Corrosive And High-temperature Environments. metallurgy: Improves Heat Recovery Systems In Smelting And Refining Processes. industrial Safety: Provides Continuous Monitoring Of Critical Systems Via Integrated Sensors. inl’s Technology Deployment Department Focuses Solely On Licensing Intellectual Property And Collaborating With Industry Partners Who Can Commercialize Our Innovations. we Do Not Engage In Purchasing, Procurement, Or Hiring External Services For Technology Development. Our Objective Is To Connect With Companies Interested In Licensing And Bringing Our Technologies To Market.