Got Questions? We’ve Got Answers! Here are some common questions you might have about ATII. Hope this page can give you a better understanding about what we do.

1. Terminologies

1.1 AM – The additive manufacturing are often abbreviated to AM. The build-up welding is one of additive manufacturing.

1.2 AFAM – Advanced Friction Additive Manufacture is a new AM technique leveraging solid/semi-solid friction stir. It is named and developed by ATII, and advocated by the AFAM alliance. It is innovative as it is consist of sophisticated strengthening mechanism in additive manufacturing process. The scope of the AFAM technology covers innovation AM structure, manufacturing tools, process simulation, process control, date collection, and OEM/ODM design. AFAM has several patents in US and China.

1.3 Solid/Semi-Solid Additive Manufacturing(S/SSAM)
Solid means feeding material state and semi-solid is additive manufacturing working in the semi-solid state. Current Solid/Semi-Solid Additive Manufacturing technologies includes Ultrasonic additive manufacturing (UAM), Friction Stir Additive Manufacture (FSAM), Additive Friction Stir (AFS) and Advanced Friction Additive Manufacture (AFAM).

1.4 Solid/Semi-Solid Friction Additive Manufacture(S/SSFAM)
This means using friction as heat source to achieve S/SSAM.

1.5 Intensive Additive Manufacture(IAM)
While AM is building, some strengthening mechanism factors are embedded in it partly or wholly.

1.6 Advance Friction Integrated Additive Manufacture(AFIAM)
While AFAM is running, material strengthening procedures and mechanisms are carried out in the meantime.

1.7 AFIAM Grain Refine
While AFAM is running, grain refine strengthening mechanism is embedded by squeezing and making friction.

1.8 AFIAM Forging Solid Solution
While AFAM is running, solid solution strengthening mechanism is embedded by using friction and micro-forging.

1.9 AFIAM Hammer Forging
While AFAM is running, deformation strengthening mechanism is embedded by using friction and hammer forging.

1.10 AFIAM Integrated Strengthening Model
It’s a model special in processes controlling of AFAM and it consists of grain refine, deformation and solid state strengthening.

1.11 AFAM composited Strengthening Model
It’s a model special in theory strengthening mechanism of AFAM and it supports of grain refine, deformation and solid solution strengthening now.

2. About ATII and Innovation

Q: 2.1 Could you tell us your core technology and business as a specialized company?
Answer: Of course, AFAM is our core technology and we have been focusing on research and development of Solid/Semi-Solid friction additive manufacturing. Our research covers AFAM tooling structure, friction head, mechanism, process and application etc. We are providing additive manufacturing tooling design and manufacturing, consultation of AFAM, patent Licensing and training. We help to build an innovation bridge between traditional method and advance material research – delicate microstructure controlling under AFAM, 

 

Figure 1. The ATII AFAM applications

Q: 2.2 Could you talk about your patent and your next step?
Answer: We have two patent registrations in US & China already with additional ones in preparation. AFAM is still new and we are exploring the application and partnership opportunities. The concept of AFAM technology is that it could make traditional machine to have additive capability in better (output quality) and cheaper (cost) way. It provides many innovation possibilities in the industrial chain of light alloy – from material manufacturing to industry parts and applications. We would like to share these possibilities with our partners and organizations to form strategic relationship advancing the concept and development of AFAM standard.

Q: 2.3 Friction Additive Manufacture is an International Challenge, why do you could break down and built an AFAM system?
Answer: It has been proved that key person is very important by endless cases especially the innovation of new technology, from Windows to iPhone, regardless of the size of the company. The key person in our team who developed his first CAD/CAM system based on PC thirty years ago, he has been thinking about this question for years – how to merge material in machining process. After long time technology exploration, thinking, experiment and precipitation, he found the right project and met the right person who provided platform to test FSW AM. The collide of AM and FSW led us explore the concept of AFAM, we then did a lot of experiments to finally find success from a theoretical concept to industry application. Before the first success with industry metal part, who would’ve thought that a few specialists in an innovation company would hold the key to unlock such a hard problem — all started by one guy with an AFAM tool and an idea in a shop.

3. AFAM Additive Tools

Q: 3.1 What is AFAM tool? How many types they have?
Answer: AFAM tool is a type of additive process tool tip like milling cutter, which can be fixed on milling or special FSW machine, so part of additive function could be append these machine immediately. There are two type of AFAM tools now, analog (type I) and digital (type II developing…). This is first friction AM tool tip in the world now.

Q: 3.2 Is AFAM tool a standard part? Where can I buy it?
Answer: No, it isn’t. It is a new tool and AFAM standard is implemented on it. It is patented product and could be bought online in near future.

Q: 3.3 Is DIY AFAM possible without any additive process experiences?
Answer: Yes, you could. Firstly you should have some FSW experience and have AFAM tool at least, second you should be an experienced machine operator, and third download our online training A-level guide which you could read and act on it step by step carefully, you could 3D pint out your first friction sample.

4. AFAM Additive Structure

Q: 4.1 AFAM logic structure of diagram is fairly simple, could you tell us its meaning and value?
Answer: OK, AFAM is an AM system, their structure is only part of it. The logical drawing is shown to the public but the real application can be very complex depending on your application. We want to get semi-solid state of alloy in the AM process in better and cheaper way, this is very difficult. After we simplified FSW factor – stir, this goal was achieved. There are side-additive and top-additive modes in AFAM, which are corresponding two milling mode-vertical milling and horizontal in traditional machinery process. Inspect of each mode has its limit but you could produce many type of parts after using accessories similar to the subtraction machinery process. You could gain the research and design capability of solid/semi-solid additive formation immediately, after adding our AFAM tool at your machine following our guidance.
The important value of AFAM is combining advanced material with mature mechanical process! This is the future of mechanical process,and based on additive mechanism researching and engineering application for the S/SSFAM.

Q: 4.2 How many forging methods in AFAM structure and what are their usage?
Answer: There are two types of forging mechanisms in AFAM, micro forging and hammer forging, micro forging is set up for solid solution and hammer forging is set up for deformation strengthening.

Q: 4.3 The feeding system is tricky in the AM process based on FSW concept, how is that being solved in AFAM?
Answer: OK, we have designed three feeding systems in AFAM structure, forcing feeding, decompressing feeding and dynamic balance feeding. Our online training level A (AFAM-open) has training materials for dynamic balance feeding system.

5. AFAM Process

Q: 5.1 How does AFAM fused advanced material and mechanical process? What types of process does it include?
Answer: We have primarily focused on light alloy such as aluminum alloy in AFAM system. It is working in semi-solid state like FSW, and thus avoided defects that come with melting the materials. It is one of few semi-solid producing methods. We could complete additive manufacturing use AFAM equipment on traditional machine such as FSW or milling device, at least one AFAM tool should be attached to your machine. Part samples can be print out with this platform, so you could do additive manufacture test and research immediately by controlling parameters such as main spindle rotating speed, additive speed, press amount and feeding rate etc.

Q: 5.2 How to use AFAM’s composite strengthening model and control its process?
Answer: AFAM’s composite strengthening model is shown through AFAM integrated process model, it is based on friction intensive grain refining, friction intensive micro-forging solid solution and friction intensive hammer forging deformation.

Q: 5.3 Could you tell us what are the parameters in these strengthening mechanisms? How to decide the optimization value?
Answer: There are four type of controlling items: main spindle rotating speed, additive speed, press amount and feeding rate in AFAM’s friction intensive grain refining and micro-forging solid solution. In addition, there is amount of deformation in friction intensive hammer forging deformation. This is very important in the deformation strengthening. You could decide optimal values in your device test with material analysis. The additive quality of your sample or part depends on these values closely.

Q: 5.4 What are the requirements to the material used in AFAM process?
Answer: The AFAM generally is targeted towards the light alloys. There is no requirement for non-heat treatable reinforced alloys. The material state of the heat treatable reinforced alloy is required to be toughened or softened because the AFAM additive process embeds the mechanism of intensive solid solution.

6. AFAM Additive Mechanism

Q: 6.1 What are the similarities and differences between AFAM and FSW?
Answer: Friction Mechanical-heat mechanisms are used by both AFAM and FSW, including three factors: squeezing, friction and stir in FSW. However, only two important factors are needed in AM: squeezing and friction, stir is redundant or additional factor. These points can be found in our pre-researching of AFAM. This is where the difference is, it has been confirmed by our recent experiments.

Q: 6.2 What is the composited strengthening model of AFAM?
Answer: AFAM’s composited strengthening model is based on grain refine, it can be described by mathematical models along three dimensions which is consisted of grain refine strengthening, deformation strengthening and heat treatment strengthening. Integrated additive manufacturing is AFAM’s process controlling model.

Q: 6.3 Could you tell us what is AFAM’s heat-generating model?
Answer: Yes, the working condition of H Schmidt’s model[1] is very similar to our AFAM, which was used for reference by us. For AFAM-tool-I-100X20X20-side tip type, set Q2=Q4; For AFAM-tool-I-100X20X20X6-side-top tip type, plus Q4. To see in Fig. 2

Fig2. AFAM heat generation contributions in analytical estimate
[1] H Schmidt, J Hattel1 and J Wert,An analytical model for the heat generation in friction,Modelling Simul. Mater. Sci. Eng. 12 (2004) 143–157

 

7. The visualization of AFAM composite strengthen mechanism

Q: 7.1 Could you tell us whether AFAM’s composite strengthening model can be visualized or not? What are these geometric meanings?
Answer: There are three typical strengthening mechanisms that supported by AFAM: fine grain, deformation and solid solution, since intensive friction solid solution can be applied in solid solution strengthening or precipitation strengthening, so heat treatment strengthen can be made sure in AFAM supported.
These three strengthening mechanisms just map to 3 axes in Cartesian system, so they have clearly geometric meanings – a set of values (three) represent a unique point, and then AFAM composite strengthening model map to feature curved surface also. They can be visualized and internal rules can be descried too by this value’s development tendency. This model’s visualization is very helpful to additive property. It’s could be used for guiding in the process.

 

Fig3. A example of feature curved surface

  1. 8. AFAM Material

Q: 8.1 Could you tell us the type of AFAM material and its state?
Answer: You could use any one or several types of light-alloy depended on your project, refer to 5.4 about their heat treatment state.

Q: 8.2 Could you tell us what’s the application of AFAM? Is it only using for light alloy?
Answer: The answer is similar to FSW, it can be used for many systems of material such as steel/copper/nickel based besides aluminum, but now we focused on light alloy. The main challenge of working with harder material is abrasion of tool tip, extra heating resource is the future of AFAM.
Q: 8.3 What are the AFAM tool made of? How long does it last?
Answer: The AFAM tool is made of premier tungsten steel; in laboratory condition it can last half a year.

9. AFAM Standard

Q: 9.1 Is it possible to produce AFAM standard, and why?
Answer: It is possible. There are differences in working environment, in shape and status of using material. So we will be working in standard additive environment (temperature, humidity and oxygen content etc.) and standard platform (additive process structure, tool and fixer etc.) for the future, the standard developed in standard conditions is more important in guiding the additive manufacturing process.

Q: 9.2 How many AFAM standard classes should be included?
Answer: AFAM’s standard should have three items classes at least:

(1) Firstly, additive environment which included temperature, humidity and oxygen content etc.

(2) Secondly, standard working platform which consisted of additive process structure, tool and fixation etc.

(3) And thirdly, standard material which included alloy material composition, material shape and status of heat treatment etc.

Q: 9.3 Why do you posted it so early about the AFAM standardization which can take a long time?
Answer: It’s needed for the AFAM’s standard perception in R&D of application. A technology that has the potential to standardization in industry will have broader appeal to the industry and be adopted more so even though it is still early, we want to point out the potential and what we want to finally achieve with the technology.

10. AFAM Application

Q:10.1 Could you let us know what how to us AFAM in our project? Since the tendency was showed in getting high property by AFAM which was composited by solid / semi-solid friction additive manufacture processes?
Answer: The AFAM is a new branch of solid /semi-solid additive manufacturing. It can be a powerful additive manufacturing platform. It enables you to set up a high-quality innovative experiment platform cost efficiently.
The application would be divided into three-level, consulting table.1 for details.

AFAM application levels Devices Additive functions Partners AFAM Strengthening mechanisms
AFAM-Open

Entry level application

FSW Machine or Mill

+ AFAM Tool

Solid/semi-solid friction additive manufacture R&D ability

AFAM side additive mode

Cube , cuboid & Samples Printing

FSW / FSAM

Mechanism research

Material research

Process development

Application development

Fine grain
AFAM-Closed

Intermedium level application

FSW Machine or Mill

+ AFAM Tool

+ AFAM Translator & Closed set

+ C axis

+ Fixation & process equipment

All of the above

+ Antioxidation

+ Loop-forming element

+ sphere composited

All of the above

+ higher property

Fine Grain

+ Solid Solution

AFAM-Embedded

Advanced level application

5 Axis FSW Machine or Mill Strengthened

+ Embedded AFAM Set

+ Fixer & process equipment

All of the above

+ Common shape parts

+ AFAM combined strengthening

All of the above

Device vendor

Big AFAM part manufacture

Fine Grain

+ Solid Solution

+ Deformation

In short, whatever your goal is in the light alloy industry and manufacturing chain, e.g. AM theory research, material research, material pre-process, material analysis, FSW/FSAM, device research, process development, application research, or AM parts, AFAM can help you get into additive manufacturing technology with easy and enable you to be more innovative in your own field.
Q: 10.3 It seems AFAM is a promising technology, what’s the limit then?

Answer: There is always limitations in every technology. Although the challenges related to additive material clapping, material utilization ratio and high cost have been solved by AFAM, it is not meant to produce small and delicate parts. AFAM is targeted to produce middle and big parts with requirement for high mechanical properties. The wear of tooling is another limitation of AFAM for now, composited heat resource is next development direction.

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