Explosive rock fragmentation techniques used in many resource recovery operations have in the past relied heavily upon traditions of field experience for their design. As these resources, notably energy resources, become less accessible, it becomes increasingly important that fragmentation techniques be optimized and that methods be developed to effectively evaluate new or modified explosive deployment schemes. Computational procedures have significant potential in these areas, but practical applications must be preceded by a thorough understanding of the rock fracture phenomenon and the development of physically sound computational models. This paper presents some of the important features of a rock fragmentation model that was developed as part of a program directed at the preparation of subterranean beds for in situ processing of oil shale. The model, which has been implemented in a two-dimensional Lagrangian wavecode, employs a continuum damage concept to quantify the degree of fracturing and takes into account experimental observations that fracture strength and fragment dimensions depend on tensile strain rates. The basic premises of the model are considered in the paper as well as some comparisons between calculated results and observations from blasting experiments

Boade, R. R.

Grady, D. E.

Kipp, M. E.

UNT Digital Library

SAND 8 0 - 0 8 5 7  C DYNAMIC ROCK FRAGMENTATION: O I L  SHALE APPLICATIONS R.  R. B o a d e ,  D.  E .  G r a d y ,  and M.  E .  Kip] Sandia N a t i o n a l  L a b o r a t o r i e s  - A l b u q u e r q u e ,  New Mexico 8 7 1 8 5  DISCLAIMER This report was prepared as an account of work sponsored by an agency of the United States Government. Neither the United States Government nor any agency Thereof, nor any of their employees, makes any warranty, express or implied, or assumes any legal liability or responsibility for the accuracy, completeness, or usefulness of any information, apparatus, product, or process disclosed, or represents that its use would not infringe privately owned rights. Reference herein to any specific commercial product, process, or service by trade name, trademark, manufacturer, or otherwise does not necessarily constitute or imply its endorsement, recommendation, or favoring by the United States Government or any agency thereof. The views and opinions of authors expressed herein do not necessarily state or reflect those of the United States Government or any agency thereof. DISCLAIMER Portions of this document may be illegible in electronic image products. Images are produced from the best available original document. DY:;.;:.:IC ROCK FR~CIEXTATIOK : OIL S W E  APPLICATIONS* R. R. Boade, D. E. Grady, and M. E. Kipp Sandia Kational Laboratories  Albuquerque, Few ?:exico 87185 IKTRODUCTION Explosive rock fragmentat ion techniques used i n  many resource recovery opera- t i o n s  have inTthe past  r e l i e d  heavi ly upon t r a f i t i o n s  of f i e l d  experience f o r  t h e i r  design. As these  resources,  notably energy resources,  become l e s s  acces- s i b l e ,  i t  becomes increas ing ly  important t h a t  fragmentation techniques be optimized and t h a t  methods be developed t o  e f f e c t i v e l y  eva lua te  neu o r  modified explosive deploynent schemes. Coioputational procedures have s i g n i f i c a n t  p o t e n t i a l  i n  these a r e a s ,  but  p r a c t i c a l  a p p l i c a t i o n s  must be preceded by a  thorough understanding of t h e  rock f r a c t u r e  phenomenon and the  developnent of phys ica l ly  sound conputat ional  models. This paper p resen ts  some of the  impsrtant  f e a t u r e s  of a  rock fragmentation model t h a t  was developed a s  p a r t  of a  program d i rec ted  a t  the  preparat ion of sub- t e r ranean  beds f o r  i n  s i t u  processing of o i l  sha le .  h e  model, wh:ch has been implemented i n  a  two-dimensional Lagrangian wavecode, ecploys a  continuum damage concept t o  quant i fy  t h e  degree of f r a c t u r i n g  and takes i n t o  account experimental observa t ions  t h a t  f r a c t u r e  s t r e n g t h  and f ragaen t  dimensions depend on t e n s i l e  s t r a i n  r a t e s .  The bas ic  premises of the  model a r e  considered i n  the  paper a s  w e l l  a s  some conparisons between ca lcu la ted  r e s u l t s  and observat ions from b las t -  i n g  experiments. More d e t a i l e d  descr ip t ions  of the  model a r e  given i n  Refs. 1-3. FRACTURE AED FRACXEhTATION HODEL The na ture  of t h e  fragmentat ion phenomenon i n  rocks,  and i n  o t h e r  m a t e r i a l s  a s  w e l l ,  i s  c l o s e l y  l inked t o  the  loading condit ions.  In o i l  s h a l e ,  f o r  example, f r a c t u r e  s t r e n g t h  and f ragzen t  dimensions depend on s t r a i n  r a t e  ( s e e  Figure 1 ) .  This dependence i s  due t o  t h e  ex i s tence  of a  d i s t r i b u t i o n  of flaws within the  m a t e r i a l  whieh have d i f f e r e n t  c h a r a c t e r i s t i c  dimensions and hence a l s o  a r e  a c t i -  vated a t  var ious app l ied  t e n s i l e  s t r e s s  l e v e l s .  A t  low s t r a i n  r a t e s  only a  few of t h e  l a r g e r  flaws a r e  a c t i v a t e d  during t h e  e a r l y  por t ion  of load a p p l i c a t i o n ;  these  grow a s  the  load i s  continued and eventual ly coa lesce ,  causing m a t e r i a l  f a i l u r e  and t h e  t e r - i n a t i o n  of t h e  flaw a c t i v a t i o n  process. Because only a  few f laws have been a c t i v a t e d ,  t h e  f ragnents  a r e  comparatively la rge .  A t  h igher  s t r a i n  r a t e s ,  f law o r  crack coalescence may not  occur during t h e  period of load a p p l i c a t i o n  unless  a  g r e a t e r  number of ffavs a r e  a c t i v a t e d ;  f o r  t h i s  t o  be r e a l i z e d ,  t h e  appl ied t e n s i l e  s t r e s s  l e v e l  must be g r e a t e r .  The f r a c t u r e  s t r e s s  a t  high b t r a i n  r a t c c  thus i s  Erea te r  than a t  low s t r a i n  r a t e s .  Fragnents a l s o  a r e  smaller  a t  high s t r a i n  r a t e s  because a  g r e a t e r  number of flaws a r e  a c t i v a t e d .  lhe s r r a i n - r a t e  dependence of tho fragmentat.f.on phenomenon i s  l m p o r  t a n t  i n  explosive a p p l i c a t i o n s  because s t r a i n  r a t e s  over t h e  e n t i r e  range depicted i n  Figure 1 a r e  possible .  Near a  t y p i c a l  c y l i n d r i c a l  borehole  his work supported by t h e  U. S. Department of Energy 10' lo1 lo2 ]03 S T R A I K  R A T E  ( , - I )  10-1 - E - w c" 10-2- "3 C Z Wr g10-3- = Y A napkinson B a r  lo0 lo1 lo2 10- - I I I [ A  - \ OIL S H A L E  _ ( 8 3  r ; . l i k q )  - *% A G a s  Gun . Cylinder \ Block *\- F1GUP.E 1. 1LLL'STTUTIO~;S OF DEPLSDEIiCE OF FIUu~hTATIOK PROCESS IN OIL SHXLE OK STRAIK RATE. charge ,  s t r a i n  r a t e s  a r e  i n  thf  100 - 1030 6-I range; a t  l a r g e r  r a d i i ,  however, they may drop t o  the  1 - 1 0  6- range. I f  f r e e  faces  a r e  p resen t ,  s t r a i n  r a t e s  i n  t h e  1000 - 10,000 s-I range nay occur when tensions develop a f t e r  t h e  re f lec -  t i o n  of a  compressive s t r e s s  wave. In  developing t h e  fragmentation model discussed here ,  the  above descr ip t ion  of t h e  m a t e r i a l  f a i l u r e  process  was assuaed. Tine cur ren t  s t a t e  of f r a c t u r e  i n  t h e  nodel i s  represented by a  damage parane te r ,  B, which i s  defined a s  t h e  volume f r a c t i o n  of m a t e r i a l  t h a t  has l o s t  i t s  load carrying a b i l i t y .  Mater ial  s t r e n g t h  i s  degraded i s o t r o p i c a l l y  by decreasing the  bulk (K).and shear ( G )  nodul i  by a  f a c t o r  1-D. In  the  l i n e a r  e l a s t i c  r e l a t i o n s ,  t e n s i l e  s t r e s s ,  uij, i s  r e l a t e d  t o  s t r a i n ,  el,, by where = E l l  + €22 + c33. The value of the  parameter D a t  time t i s  given by where 6 i s  the  r a t e  a t  ufiich flaws a r e  ac t iva ted  and v i s  t h e  volume of m a t e r i a l  inf luenced by a  flaw, o r  crack. The number of flaws a c t i v e  a t  a  given s t r a i n  i s  descr ibed by a  W i e b ~ l l  d i s t r i b u t i o n ,  n ( € )  = kcm. =+ere k  and m a r e  cons tan ts ;  k i s  de te rs ined  from 6 by S a h ( l  - D) - km(1 - D ) C ~ - ' ~ ,  where the  1 - D f a c t o r  1s included t o  account f o r  flaws t h a t  a r e  shadowed by o ther  f l avs .  Assuming t h a t  a  crack grows a t  a  constant  t a r e ,  C , utd tlidt t h 5  volume i n f l u e n c ~ d  hy a  crack i s  a  sphere of r a d i u s  C t ,  v  i s  by &rr(Cgt) /3 .  S u b s t l t u i i o n  i n t o  Eq. 2 f o r  N and v  y i e l d s  g 4 t D( t )  - 7rkmc:l r .-' i ( 1  - D ) ( t  - 7)' d r  . ( 3 )  The quest ion of fragmentation i s g d d r e s s e d  by f i r s t  assuming t h a t  t h e  s u r f a c e  a rea  of a  c rack  a t  time t i s  L*Cgt)- and that  t h e  t o t a l  sur face  a r e a  i s  Defining an average volume a t  time t ,  G ( t ) ,  and an average a r e a ,  B ( t ) ,  a long with an average rad ius  F ( t ) ,  Eqs. 2 and 4 can be r e w r i t t e n  a s  and E l l a i n a t i n g  F from Eqs. 5 and 6 y i e l d s  N(t) i s  t h e  d e n s i t y  of ac t iva ted  cracks so  i t s  rec iproca l  i s  the  average volume per crack and L ( t )  can be considered t o  be t h e  average d i s tance  between cracks,  o r  the  approximate fragment dimension. The cons tan ts  i n  t h e  model were evaluated usi?lg data  i n  Figure 1 and Eqs. d  4 o r  the  s p e c i a l  case of constant  s t r a i n  r a t e .  The r e s u l t s  a r e  k  - ~ ~ 7 ~ ~ 0 " )  m-' , m - 8, and C - 1300 m / s .  It i s  s i g n i f i c a n t  t o  note  here t h a t  g  cons tan ts  i n  t h e  model have been based on labora tory  da ta ,  not  f i e l d  data .  The t e n s i l e  f r a c t u r e  and fragmentation model described i n  t h e  foregoing has been incorporated i n t o  a  two-dimensional Lagrangian wave propagation code c a l l e d  TOODY. For numerically s imulat ing the  experiments t h a t  w i l l  be discussed i n  t h e  next s e c t i o n ,  t h e  o i l  sha le  was t r e a t e d  a s  an i s o  ropic  e l a s t i c - p e r f e c t l y  p l a s t i c  m a t e r i a l  with an i n i t i a l  dens i ty  of 2.27 Wg/mJ, a  bulk sound speed of 3000 m/s, a  Poisson r a t i o  of 0.4, and a  y i e l d  s t r e n g t h  of 200 MPa. l'he damage and f r a c t u r e  sur face  equat ions were reduced t o  approximate ordinary d i f f e r e n t i a l  r a t e  equat ions f o r  i n t e g r a r i o n  i n  the  wavecode. The explosive energy source was t r e a t e d  a s  an i s e n t r o p i c  re lease  of energy i n  a  gas from t h e  Chapnan-Jouguet point  of t h e  explosive. The use of uavecodes t o  s k . ~ l a t e  xplosive b l a s t s  i n  rock media provides i n s i g h t  i n t o  t h e  nature of the  early-time s t r e s s  wave propagation and the  at ten-  dant  f ragmentat ion;  subsequent motion of t h e  fragments i s  not simulated. Several s t u d i e s  e  ploying the  model discussed i n  t h e  previous s e c t i o n  have been per- formed,'-' some t o  eva lua te  t h e  model and some t o  ob ta in  information about t h e  e f f e c t s  of varying charge shape, charge b u r i a l  depth,  and detonat ion i n i t i a t i o n  scheme. Two r e p r e s e n t a t i v e  examples a r e  considered here;  both a r e  s i o u l a t i o n s  of experimental explosive b l a s t s  i n  o i l  s h a l e ,  one involving a  s a a l l  charge i n  a  meter-sized block and che orher  a c y l i n d r i c a l  charge rn  a borehole d r i l l e d  l n r o  t h e  f l o o r  of a mine. Block Experiment - The block experiment, &lch i s  i l l u s t r a t e d  o n . t h e * l e f t  s i d e  of r i g u r e  2. involved an 80 gkcharge of C-4 ~ x p l o s i v e  i n  an instr,umented block of o i l  shale. The charge was about  0.4 m from t h e  neares t  surface which was supported on a s l a b  of l o r - d e n s i t y  foam. The foaa e e m e d  t o  con ta in  fragments t h a t  maj- .dve been e jec ted  'but had an impedance t h a t  was n e g l i g i b l e  compared t o  t h a t  of t h e  rock so t h a t  f o r  s t r e s s  wave 1nterac. t ions t h i s  rock sur face  was f ree .  M 18 sham in Figure 2, tbe block. W K S  surrounded at  a l l  o t h e r  s u r f a c e s  by a n  impedanccrmatchin~ grout  t o  minimize e f f e c t s  caused by i n t e r n a l  wave r e f l e c t i o n s .  Af te r  t h e  shot  t h e  block was slabbed f o r  d i r e c t  examination. Fragment dimen- s i o n s  (shown on t h e  r i g h t  of Figure 2 )  were determined a s  a func t ion  of d i s t a n c e  from t h e  charge, both i n  the  d i r e c t i o n  tovard t h e  f r e e  f a c e  ( s o l i d  d a t a  bars )  and i n  a n  orthogonal d i r e c t i o n  (dashed data  bars) .  As i s  ev iden t ,  t h e  fragments tend t o  be small  near the  charge and t o  become l a r g e r  a t  g r e a t e r  d i s t a n c e s ,  which would be expected singe the strain rate decreases. An erceprion to this is the solid data bar representing fragment dimensions near the free face; fragments are small here because strain rates are high for tensile waves produced by reflection of com- preseive waver. Results of the numerical simulation are also shown in Figure 2. Trends evident in the measurements are alro evident in the csaputations. The agreement between the measurements and calculations is-in general within a factor of,two, uhCch is considered reasonable in view of the relatively large spread inherent to the measured dimensions. Mine Experiment - The mine experiment was performed in the floor of the Colony Oil Shale Xine in Western color ad^ by persannel from the t o e  Alamos National Scientific ~aboratories.~ It consisted of a 5.2 kg charge of ILYFO, 0.75 m high, at the bottom of a 0.1 m diameter, 2.0 m deep borehole drilled into the floor of , the mine. The charge was bottom detonated. The blast did not result in significant ejection of frapented material above the charge. Fragments were formed, however, but were not displaced significantly f r w  their original locatiolrs. After the ehot the loose fragments were excavated from the rock mass and profilea of the resulting crater were measured at ninery- degree intervals around the axis of the borehole. The four profiles are shown in Figure 3. There is some variation between these profiles as would be expected Crater  FIGURE 3. MEASURED CRATER PROFILES (DASKED) AND CALCULATED DAMAGE (LEFT) MQ FRAG?IE~ SIZE COYTOURS (RIGHT) FOR EXPERIMENT IN MINE. because the fragmentation process must be controlled to sane extent by the joint structure of the rock medium. One calculated damage contour ie also shown in Figure 3, for D - 0.2. This contour has essentially two parts. The lover portion is due largely to the deve- lopnent of a tensile stress wave wfiich trails the con?ressive wave induced in the rock by the detonation. The upper portion, which includes the lobe extending to the right near the floor, is due to the deve1opz.o-nt of tension as the compressive wave reflects from the free face. The calculated curve is considered to be a good representation of the neasured crater profiles. There are discrepancies, however, some of which can be understood by considoring fragzent dimensions. The average fragnent dimensions calculated for this explosive geometry are shown on the right side of Figure 3, along with the four crater profiles. The smallest fragments again appear near the charge and near the free face because of the high strains rates realized in these regions. Fragment dfmensions again increase at the larger ranges. In the radial direction from the charge, the rate of increase o.f fragnent dimensions is rather large, which would tend to make excavation f r m  such tight quarters sone:hat difficult. In addition, fragments in this region yay be lodged rather firmly by residual stress fields induced by the detonation. In regions above the charge and near the crater profiles, crl- culated fragment dimensions are comparable to spatial variations between the pro- files. It is easy to hypothesize that in regions where fra~ents are calculated to be large, cracks may indeed form and may even surround a fragment, but may not be detected because of snall displacemente. It is reasonable t a  expect the uncar tainty in a calculated, or measured, crater profile to be at least as large as the local fragment dimension. CONCLUSIONS Essential physical processes vhich affect dynamic fracture and fragmentation of rock have been incorporated into the model described in this paper. The overall agreement between calculated and experimental results is encouraging, p a r  titularly in view of the fact the the model constants vere deduced from small- scale laboratory experiments and yet appear to be appropriate for larger scale field applications. REFERENCES 1. Grady, D. 6. and Kipp, M. E., "Continuuz Modelling of Explosive Fracture in Oil Shale", x. J. Rock *:ha &. s. and Geonech. Abstr. Vol. 17, pp. 147-157 (1980). 2. Crady, DO E. and Kipp, M. E-, "Explosive Fracture Studies in Oil Shale", to be published in &. &t. Ea. 2. (Oct. 1980). 3. Mpp, M. E. and Grady, D. E., Nu~erical Studies of Rock Fragmentation, SANm 79-1582, Sandia Eiational Laboratories, Albuquerque, hW (1980). 4. Schmid* S., Ed., Explosively Produced Fracture in MI Shale, LA-8104-PR, Lor Alarmas ljational Scieotific Laboratory, los AZanos, h?.l (1980). 5. Schmidt. R. A,, Boade, R. t, and Bass, R. R., "A New Perspective on Well f;hoocing - the Behavior of Coateinpd Explasionr -and Oef lagxat$~n". froc. 54th Soc. Pet. &. Fall Tech. Conf., Las Vegas, EFV (1979). -7  

Dynamic rock fragmentation: oil shale applications

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Dynamic rock fragmentation: oil shale applications

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