Real-time implementation of generalized predictive algorithm for direct metal deposition (DMD) process control

US 9,044,827 B2
Filed: 05/30/2008
Issued: 06/02/2015
Est. Priority Date: 05/31/2007
Status: Active Grant

First Claim

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1. A method of stabilizing a direct metal deposition (DMD) process of the type wherein a powder is fed into a laser-generated melt pool, comprising the steps of:

monitoring the temperature and the shape of the melt pool during deposition of the melt pool;

applying a recursive least square (RLS) model estimation algorithm to data generated by monitoring the temperature and the shape of the melt pool for identifying process characteristics from the temperature and the shape of the melt pool;

delivering the process characteristics to a generalized predictive controller for predicting the temperature and shape of the melt pool and adjusting the process characteristics with input constraints from predicted temperature and shape of the melt pool to control the direct metal deposition process in real time.

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Abstract

A direct metal deposition (DMD) process is stabilized by monitoring the temperature and the shape of the melt pool during deposition, applying a recursive least square (RLS) model estimation algorithm to adaptively identify process characteristics in accordance with the temperature and the shape of the melt pool, and delivering the process characteristics to a generalized predictive controller with input constraints to control the process. The process may be controlled by adjusting laser power or by adjusting the speed of the movement of the laser. In the preferred embodiment the temperature is monitored using a two-color pyrometer, and the shape of the melt pool is monitored by detecting the edge of the melt pool with a camera and/or photodetector.

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10 Claims

1. A method of stabilizing a direct metal deposition (DMD) process of the type wherein a powder is fed into a laser-generated melt pool, comprising the steps of:
- monitoring the temperature and the shape of the melt pool during deposition of the melt pool;
  
  applying a recursive least square (RLS) model estimation algorithm to data generated by monitoring the temperature and the shape of the melt pool for identifying process characteristics from the temperature and the shape of the melt pool;
  
  delivering the process characteristics to a generalized predictive controller for predicting the temperature and shape of the melt pool and adjusting the process characteristics with input constraints from predicted temperature and shape of the melt pool to control the direct metal deposition process in real time.
- View Dependent Claims (2, 3, 4, 5)
- - 2. The method of claim 1, wherein the process is controlled by adjusting laser power.
  - 3. The method of claim 1, wherein the process is controlled by adjusting the speed of the movement of the laser.
  - 4. The method of claim 1, wherein the temperature is monitored using a two-color pyrometer.
  - 5. The method of claim 1, wherein the shape of the melt pool is monitored by detecting the edge of the melt pool.

6. A system for stabilizing a direct metal deposition (DMD) process of the type wherein a powder is fed into a laser-generated melt pool, comprising:
- a device for monitoring the temperature of the melt pool during deposition;
  
  a device for monitoring the shape of the melt pool during deposition;
  
  a processor applying a recursive least square (RLS) model estimation algorithm to the temperature and shape of the melt pool at the time of deposition of the melt pool for predicting process characteristics of the system from the temperature and the shape of the melt pool thereby generating predicted process characteristics; and
  
  a generalized predictive controller programmed with input constraints for adjusting the direct metal deposition (DMD) process in real time based upon the predicted process characteristics.
- View Dependent Claims (7, 8, 9, 10)
- - 7. The system of claim 6, wherein the process is controlled by adjusting laser power.
  - 8. The system of claim 6, wherein the process is controlled by adjusting the speed of the movement of the laser.
  - 9. The system of claim 6, wherein the temperature is monitored using a two-color pyrometer.
  - 10. The system of claim 6, wherein the shape of the melt pool is monitored by detecting the edge of the melt pool.

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Current Assignee
DM3D Technology, LLC
Original Assignee
DM3D Technology, LLC
Inventors
Song, Lijun, Mazumder, Jyoti
Primary Examiner(s)
Heinrich, Samuel M

Application Number

US12/130,351
Publication Number

US 20080296270A1
Time in Patent Office

2,559 Days
Field of Search

21912163-12166, 219/121.83, 219/121.85, 700/28, 702/135, 374/121, 250/338, 250/341.1, 250/341.6, 250/341.8
US Class Current

1/1
CPC Class Codes

B23K 26/03   Observing, e.g. monitoring,...

B23K 26/032   using optical means

B23K 26/034   Observing the temperature o...

B23K 26/0344   Observing the speed of the ...

B23K 26/123   in an atmosphere of particu...

B23K 26/144   the fluid stream containing...

Real-time implementation of generalized predictive algorithm for direct metal deposition (DMD) process control

First Claim

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10 Claims

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Real-time implementation of generalized predictive algorithm for direct metal deposition (DMD) process control

First Claim

3 Assignments

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Abstract

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10 Claims

Specification

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