颜江涛，等：

              金属增材制造检测技术与质量控制研究进展

                   internal  defects  formation  mechanism  of  selective  laser   316L[J]. International  Journal  of  Fatigue，2022，163：
                   melting  based  on  laser-powder-melt  pool  interaction：a   107025．
                   review[J]. Chinese  Journal  of  Mechanical  Engineering：    [26]  GHODS S，SCHUR R，SCHULTZ E，et al．Powder
                   Additive Manufacturing Frontiers，2022，1（3）：100037．  reuse  and  its  contribution  to  porosity  in  additive
                [15]  HUANG  Y  Z，FLEMING  T  G，CLARK  S  J，         manufacturing  of  Ti 6 Al 4 V[J]. Materialia，2021，15：
                   et  al．Keyhole  fluctuation  and  pore  formation   100992．
                   mechanisms  during  laser  powder  bed  fusion  additive     [27]  MONTAZERI  M，RAO  P．Sensor-based  build
                   manufacturing[J]. Nature  Communications，2022，13：  condition monitoring in laser powder bed fusion additive
                   1170．                                             manufacturing  process  using  a  spectral  graph  theoretic
                [16]  LIU Q C，ELAMBASSERIL J，SUN S J，et al．The       approach[J]. Journal  of  Manufacturing  Science  and
                   effect of manufacturing defects on the fatigue behaviour   Engineering，2018，140（9）：091002．
                   of  Ti-6Al-4V  specimens  fabricated  using  selective     [28]  KHANZADEH  M，CHOWDHURY  S，TSCHOPP
                   laser  melting[J]. Advanced  Materials  Research，2014，  M  A，et  al．In-situ  monitoring  of  melt  pool  images
                   891/892：1519-1524．                                for  porosity  prediction  in  directed  energy  deposition
                [17]  HONARVAR  F，VARVANI-FARAHANI  A．               processes[J]. IISE Transactions，2019，51（5）：437-455．
                   A  review  of  ultrasonic  testing  applications  in     [29]  闫文韬，钱亚，林峰. 选区熔化过程多尺度多物理场建
                   additive  manufacturing：defect  evaluation，material   模研究进展[J]. 航空制造技术，2017，60（10）：50-58．
                   characterization，and  process  control[J]. Ultrasonics，    [30]  CHENG B，LYDON J，COOPER K，et al．Melt pool
                   2020，108：106227．                                  sensing  and  size  analysis  in  laser  powder-bed  metal
                [18]  LOPEZ  A，BACELAR  R，PIRES  I，et  al．Non-       additive  manufacturing[J]. Journal  of  Manufacturing
                   destructive  testing  application  of  radiography  and   Processes，2018，32：744-753．
                   ultrasound  for  wire  and  arc  additive  manufacturing     [31]  MA  H，MAO  Z  Z，FENG  W，et  al．Online  in situ
                   [J]. Additive Manufacturing，2018，21：298-306．      monitoring  of  melt  pool  characteristic  based  on  a
                [19]  SEOW C E，ZHANG J，COULES H E，et al．Effect       single  high-speed  camera  in  laser  powder  bed  fusion
                   of  crack-like  defects  on  the  fracture  behaviour  of    process[J]. Applied  Thermal  Engineering，2022，211：
                   wire  +  arc  additively  manufactured  nickel-base  alloy   118515．
                   718[J]. Additive Manufacturing，2020，36：101578．    [32]  LOUGH  C  S，LIU  T，WANG  X，et  al．Local

                [20]  ZHANG J，ZHAO X，YANG B，et al．Nondestructive     prediction of Laser Powder Bed Fusion porosity by short-
                   evaluation of porosity in additive manufacturing by laser   wave infrared imaging thermal feature porosity probability
                   ultrasonic  surface  wave[J]. Measurement，2022，193：  maps[J]. Journal  of  Materials  Processing  Technology，
                   110944．                                           2022，302：117473．
                [21]  YU J，ZHANG D Q，LI H，et al．Detection of internal     [33]  ESTALAKI  S  M，LOUGH  C  S，LANDERS  R  G，
                   holes in additive manufactured Ti-6Al-4V part using laser   et  al．Predicting  defects  in  laser  powder  bed  fusion
                   ultrasonic testing[J]. Applied Sciences，2020，10（1）：365．  using  in situ  thermal  imaging  data  and  machine
                [22]  LV  G  L，YAO  Z  J，CHEN  D，et  al．Fast  and  high-  learning[J]. Additive Manufacturing，2022，58：103008．
                   resolution  laser-ultrasonic  imaging  for  visualizing     [34]  REPOSSINI  G，LAGUZZA  V，GRASSO  M，et  al．
                   subsurface  defects  in  additive  manufacturing   On the use of spatter signature for in situ monitoring of
                   components[J]. Materials & Design，2023，225：111454．  Laser  Powder  Bed  Fusion[J]. Additive  Manufacturing，
                [23]  KIM  F  H，MOYLAN  S  P，GARBOCZI  E  J，et  al．  2017，16：35-48．
                   Investigation of pore structure in cobalt chrome additively     [35]  ZHANG  B，ZIEGERT  J，FARAHI  F，et  al．In situ
                   manufactured  parts  using  X-ray  computed  tomography   surface  topography  of  laser  powder  bed  fusion  using
                   and  three-dimensional  image  analysis[J]. Additive   fringe  projection[J]. Additive  Manufacturing，2016，12：
                   Manufacturing，2017，17：23-38．                      100-107．
                [24]  张祥春，张祥林，刘钊，等. 工业CT技术在激光选区熔                  [36]  LI J C，CAO L C，XU J，et al．In situ porosity intelligent
                   化增材制造中的应用[J]. 无损检测，2019，41（3）：52-57．              classification  of  selective  laser  melting  based  on  coaxial
                [25]  NAFAR  DASTGERDI  J，JABERI  O，REMES  H．        monitoring  and  image  processing[J]. Measurement，
                   Influence  of  internal  and  surface  defects  on  the  fatigue   2022，187：110232．
                   performance  of  additively  manufactured  stainless  steel     [37]  CUNNINGHAM  R，ZHAO  C，PARAB  N，et  al．
                                                                                                          99
                                                                                         2024 年 第 46 卷 第 9 期
                                                                                                  无损检测