The URL can be used to link to this page

Home My WebLink About03253 - Technical Information Report - Geotechnical � 5*' n�..:;; ,i��. -yr� .•y �` ^�'�q.� �,� ;��i`�� ,r��'! j� ��1�'�y,,yr��`� y �D ��" ' "�,� � .i o-k�t�R:�. ��;a,a�"",�,i�`_ rj . .� r/. '�+ .Y: �:.'��'t ;r•��, a��..�� k.rF��'�y�,♦ !li. �� .ki �T��.A�X F e �� d ix,Y``�� Sd�.i'.�i� y ,�f►, {G�:s r'-,y � ;S t �.F''}..,`�.' �'�% {;6 s°'��.,�.�,,.r��, �a�,v .{ a � .,i ,�' �f . 'r�w �' � �',�,yr""i; , ,; ,; l� . .1.�'t°_�'�qC�'.1. 1', ..S;�,W.. g�'r; m;t,: �+ac `;.!..*r {_ 1.�!..!,�'. � r y'.T'"; N ^,!�!�rq„ •i �:r5.. � A ,��'! k^sf:� ��C w�"- -�41%` .,r�.��,i.aw��IJ`.,"Y�'.., �,� �n"�_ ,.'A!r}� �2- '}. : .�"" t� '.`t�,,,,:5 t,�ti`ar,. .�`,�.: :,�!', I e� '.i �, �w•. ��k" ...�r., � *`� e'. s . �� .� x !�s � .� �..&' �n.a h l� , .- , . ,.;, rS �«� " �*'.+.'i�'° ± ':-^�*f.� � i,y+ ,nrr� <i � �, �.� � rr,", � ..s' � i� �t ��', � ,�. � ��„ ��.�� -` Y r �J �' ;u"�:yt .n. ,y ��' r�, ��, t y iW. P a t a a.,r' „� ':.1;34.,��I {'i� :a;: �'�,.� �� M�q S,��.,,��: „t .r, .,��- +e�+`r�'r ,,:{ ,rr., fi �j'� � , 4 k�. �.�.J��' y.,.�� .L,a 1+.,.'f�, t� �3`�: ::°i-..s�. `':s�: '.r.,� �..f� ,....+c' /,''r� � . , ;.,,,. �ay t�; j i ;. . a �'e*_ �. �^f!i��..',�» �'� :�� 5a " k�.-.. �3�� ' � �'��,�.%,• ...� d ,....,,1< •'�,��;.}y' - r�"�:k. ��+�, �i :.�i. �+�w: �y�;f ':� E, y,� �..,y.yr,,.: �"� , �t n {.'�.�..�y4 Y. _ 14 ��1 :.b �x .�-,� �¢r �'µ��t�..iy.,,f, y. �,5`"r. l�� .F �:�',. „�y�.� r��l .�4p� A' ¢,h _�_� N ,'J rN,�. �/� ��" d'r' 'k 3'S' k. f, :`4t°.` �'t c f�' ,��' .,.�F�� .i �..., S�'� i�',. 'u��yc.P: .� ��.�, t y�f. �';�� .. :r� �,r.`' �.- r e y+ww'+ ,�+n."r.':.`9"�:,�. '�k� .� s.� �.4� a� .{',y{�. -�� `.Pgy., Iy �� "ir r � � ;rv' ,rh��-.M.��r.'�� Tt ''�t ,�: ¢,y1 ;� � .��."w� �� 4+�,?, 1 T�i } 1'V�[ (�V' vY8 t�.M'.' i '1..`�� ,�y� .q"� t��`..,`i.' t1'e' r't �,pp��4y i�. t < ` w�".v. �,.`.'. :�;i. �., �, ` ',�_ r.� .... ��.,... ...b.�+ e� r. �'F^ k � f'W+d ''"t t��. ..,,j+`k . rv•..r,. `J. '' � �i�is4: fi �,y,w=4'M�c�M,.. �� ''I � 3,. r ��.3 1 h �i.Y �, d� M y+.,�,; ;"�'� .�i � f�. t � ,..A ��. �q: t" s' r.t d'�'u�. r r�1"i..; '4r.�� .,� °�V,q.�y � ,��r ,.a��'y�"{; p.'rY��'�� w�,ra, �.,�� .�'��«�'li! �r"'��a;;'�.,. .r�. ��'. i;p� ;:. � j , "'�' �k ,� �„� - - ,.f�. � '� �, - .. � � ; R,� b�,.. a� 7 y .��.._ f., ;'P'�$ �.:.�.. B v �" �{��'Sit#�>.� .. •,., � ai � q q.'�r ,� f .f �� SI'I�F� �h�' � �'�� .R t t .,� y :Y�M.� ° <� ��x.� �,X'h�".. d a r '�`� „�4. .i" �%' �Si 1. �L�r�� •, �� ,'�.�� .,��Y� i� _$'6�� ,' :�`�i d�^,�� - i� ,�. ;.i'� �d x. +r a :��p ��X`, �� ,�'?t ^C�..4 ,.p�+y��' ro; � � 3�axS� .:,7§ +7 �,t.,,r,p,. „ _ �. e � �, i�t��. p as�,� ".f�:�_� �^'�� tY. ii. �t .�� +. .;r�. '��` /� �` .�`i' t ,''`�' t r''�q�,9r.�,�Cr'a ,y�5 j.,rv � tl k r � ! �¢ ;`."��;.,'�' r , r; ,�, '�)7 r Y� T �t�fy��a ..yl:.' �� n�yqt ��f � !," .4 . � i]p; ;�''t- � �� ",G'1 �'k �rI'. � ��,� �� ' `4'�. .�,�4�� n'.° r :.^ 1L� �j�;�4 ,��1� ��'- r,:3 �'�', - ."'� ,:a.. +� R . _ �+ h'S., 1� � �� " .�x' E �':Y'�"� .{" ;� �f'.. 'A � '✓�� 1 't a FR��'Y '�n i r�l.'y �. �t��'e � � r�, t,t,� ,�, , ]�Prb. ,r��`�Ey�? .r .�>.`.�1 F,k.��r�..�P�; �;X��"� � }� l �;, ,a- �� w, '�^ � a. t-�*s .Mr �� ,r �.� x � , �� , �M� Y, raa � •r'�� '+ . �� J T `�a ,y�, ��c�. "r,'-j .�. o, ,iiy�i�z, �� ^�"t$i': ll'^j.��.. e1'� c "� ��A. r,t,,,._ ��:;,, �, fw,'T' � '!"_:�: � , y ,. � n. -,n ,.,"�". `tt w {.. � ,. ,. � ,,. „I . , ,- �'� ��r,�f t .�. �. y .... �::r�r, .��{.:�? �..�,£ Z��y....yM�'"�ri,f ��7 q' ��'.. �.�x.; '��JP � `:r ?,i.� :'A°�� : , ; ,.� �- , , , � S; �• }„ t�. i b. _ , �1;�. '� � i . ,�� .f,':� �'S ....� yk-�wd.�.'` �� '' ., .�,�i ��7= �.rtrr,-J,, . �"" � r '`�?;;.i�,, �. '. _.•-. ,Y';.y�',t�'- ,.� ,-,J,r ,. `:.'�J��+�n.�,..�:is x� ti "'� f-'" � �x+w��' ''�. s...:b';" t«M:. �a.. . .,��4 ' . .d?'.«y..�IL�. . � �.;�' ...'n, ''1..:?�r b ..�� .'�fb`- k�f i [ '1��r' .+�� !�� `�(� Y"*� J'S . .� .. •. t� ;� � F �`1� 4,�.,,�7""�*•,y',f�� ''� � .'r ; � �, a� �' �t r'. '"�.;�. k.� � $.. i ��. tg� 1y �{�'7 f� '7 �� ,�v` '4 r t�••� � � t:�- '��'"��:.�� z"r '�' �„�,{�G�7;,�. (� , '. „' r w � � .., ' .�� '. __� �� .;.Yr k �.. 3 �.`: 4 a, q1; a'" r" ��, y w;. �''+��s r;�: S_�� -"�' � a� � 7_ ,S d�. �' ,c3,.',. �,i��•., x; r a �,�. 4 y y, � t ��,p.&� �`�eL;;"`�w .� �� t .� ;� f ��. # i- �"� t�i�� ( �.. ''Kv.� .: : .._� . . y ,; .,�gy ��'.�" � �"��. � F— J� C`.�V �� 't a a r,� n'�"�7��,y�;P% , � �; �.3� .�y.r,' +, r rr.�y'.. 4' .:r b .�+*t'y*"�s,M✓'�"i�'��°. +�� ,� � � r{� �� '� � N � ��.� " _�n M � �t�' t ��w.+ *` � ywtYu� � �� 5 +" W �.. �a��k3` �P'. 5`x't ��' i �k�n ! > .^L �,'� '=f c'�. � �. ��. ry d . ��y� w � � � .,k k� '� �r � � e:',hf�z� `�� Y• rky��'- � � W LL O �n* r � �� '� � �t �, '.��'� �a'� � �'.' vs A �tM" y�+ ��M � ?:{'�r�,?i�+ �„, My� � � r— a,�+�d�. �4�,r r� � t Q ��t � ""�` ��`q �+q . '_t� I.l. � /A � �� ,W � � . f ��`� i r. ¢' � 4 �' 4" � f ..�d'1� � ��S �L:'fi �,Al:"r� F j i, '- f vi w W � ."C Z '.;a� y t " :?'� �;z i7;.�� j't ,� ,.,��°,k, �p �... "z, y�. �,nr�� ..•:, �,s ., ��. �.-��:�w �- r .: i�.m r "�;�^•.4'�; I t� +��x.�� _ V Z � `.r � � ��"t 1; .s '.+s '"'�r.� � .fti"�tR+'�"1" �y, t '"yy, �fi s',� '�.'�;' . � rc�� T'"' T� ` Z Q � _ �V-- # , $� r �,, }�-,. y y s .. °� ti�- '� 'w :.t '2 '�.X 1 �. '�s` �. �� —1 r; .x ni.� � a � f-�� ;,. �� .< k,� t � �. �, � t� �� ;�� ,,; � �� *. �� ,�,. W � o � �� ;� �`� :�'�� " ;�,�1I �: .a; ��,� � `�� ,��< �� ,�a,�E ��s�+'T��. � ,�� ' Npr e � � W W W � � ��kr:. �I ,�yy�, "� �tl y� Y � 1 � K+t'a.�i4 + . .T ;c a M� J '�` �. "'' ��.` .. ,� '.C' � �� . 5 at {�•:'� � m � O = � ..�f�'tl � �"�t�; �. � �� 1 '°s r t i.� +° �.��j.�'�Y -�.. ��,�}� :� k �1�1 � W LL' � N ` �t'Y Y�v� � `��' �i y `' 7� ;;'�a � � �`:�,,, q�yi�' �' �, ��w3'� � n'��. .� V a l-- } a1.- tr.. M h �w� �� Y a;Kr `k,.. `�`��v�y �� M ��pA�i 'T� o�..1 Z Q D � r .:'��r . . . �nL� b 9 t t '4K h;.;kt5��'�G,`�;"°' n:V• ��., �,�,�' , � w i�, � � �� .If R 4 Y Np ,y�. �,� t�,,.:". • �. _ e . � : . ; . r+';.�,` , R �,;, W J N � r— r::, xr� � , '1� � ' a `� �. "; �'��..a,� `° . .'�.y e; ; , , ' _ • 7. . , y1, ' � y 7y� � Q � � �.... � ��'e�� i , '�y,��. �„' .u��yy��n �{ L ' k� , ' � � . � ; ; � x �+ k�M' �y +�t '('J� \ 1 ,fi' � , t�` .. �y('. � '�1 �� '� v1��,, Q � a W Z t ; 'I ',?� � j � p C��' J. 1�f ��°-�,�� S µ-ir l,�� p�"� �� '°.y�� 'o /� � _ �, �+� d � t'. � �k t �<'� �^�'S a�"'h*'.,ra3+i ,:�a �*� c, rl+, �. l�^II��f ��'q V 0 z � O �� d,• � s � �1 �i.: r� «� a _ k�s,°;� '� i u,v -,t t"r«��,,.,d4�� z ��"'��`'di� � - '�t� +�,r�'�., O Q �' �..� �� "�6' � � i� � i � r r ,, :. ; ,:1a"�`�'�" -<��:. �e,�ps r� ;M1 i� r•�.7�' Z � Z C.,. �� l � . �, ' a � h � '� � ��..h� �. �` r" � O W t . 1 � v � }4 I 9S` 1 �� A' �r� 1 4 {� .1�,� � � �r�.if'��, (,� � � Z � �� ,. ..,�'�^1 a�,� y � d� X'^` ° .�. " � '�' j + ��to- a.�� r.��. � ��t Mt < E. / � r x � f P[' �h�i'r_: Lt�L� W � VI� 's�+ 1� ,, ,T 'k'fw� 'b� ;°�.i' �� w � .' k eF F e x e''4.", � y�i � t r }tk�u",��+�� f� O �: �'�°� i � '��- �� +;:' �y�,�r , p+`'"'� ...�� f'kL;� ,� t i'� �a � Z i.A w t :,�iF �'� �*.�� 4� ��.h $ d,"'. O � �. .�� 't� ` rw+� �i t, t # ' ,y A`,��. � � �' rn y1:..` -t�i ��' '."l�i9'`{`.�� ry � � ri� �K r;�{`'ja�, ;" � x �,+, �� r4� ° t�. v � . � z�k`�� 7 '�p � Y �'� t�}�, t ' � �: � � Y�,, r}ro �n� i '�,�� i y � �� i i �; ��r :4� r�K�``� 3��y- '.� 4t 1 t ,��i '� ,� . �� f� .. r �.+"" .J C +p� .��m�N� e+ _i dy,R,Sn �..,,y r ., i� l� � y . � +, �� 4�4 f,-"�T.,�'. �rt+`/ x i�'�' Sn }y�'i F� t�., 'rr, r �` ;i x+� . t T4��` a,.R�. t�a ; '�`+:'� ��`� r ° ' + �r ''�'.y� 1 I'. r t r ti,4 � y i , aa � � q; , �� ;y .)9� ..�y < � �I '�'',. M �,4V�);.�.: �"$�, � A . �1n '1 �:�"�r, �'��"` 4 C •�[U1�. � 'd ,.,i Eff% �rtFa�P`N t �`" r+�. � P�te,^tl�' � ,e r�'S::�s\ �' :ti d �w f kkf t �.i�� { � �f� ��lw w,.:� , � � � v� . � ',� `,.� t�. � . e � .� •�<a � * n� 1,'� ,, k fi:r'�� t� �s*2 ;�' g a � �%'s �,,r ,+��*�.. .�,'" �> M k, � ,.y�. i� ' .�Y��` k�� .Jt a�� s) -, ✓ �° ^.. a t a r,'° � � '�`a'�' � .�:. . . $�.... y.',� . .+ �. .. � "k$d�. i.-. � �'_� zl h�. � �o �( T M '+` � : , �'n� .7 .. na't.. .'+ k s �_� �. �.. ..�, p R'p�7" d�.;+,1 f ,L.d4Y�JY�: '.�i� � 3. S ,y....;��,f� i:' "` ,_k YYk: : F mr � +'y�8 Y P' ! A� �T�t 2 `�� A ,Y ' .Y4� 4 y� ri��csK R 4,iy� ,7t �. i-r �:C . , +� , - r. . . t S .t� ; -�y,�: ttyyi r x :��S�.c� k .i; t ..�s { '',�.�`�?�l. P` � •n r "+�,kY�z .S�,Xt�� y :�r �Y'�A k,:v�.q ",'4 , w�-. ...p. � r ,r � a�;F-��..n� `, , ,�. �, ,ai ,r.�•,�1' �t'" Y' '.,o k�'.A. � Y.,:. F r�``rr� °. Y t. ?r, 4, '� �Y ''�rSA'c 7��i+'�Y'' �y `.w` y,vr' x A4"':Y�. �d �k�:"`�. * , i��' u. Y �',, a.: .�,„ '�-1�,xw,. -.'., "4 dv +a✓ `��i�� i ;� ,�� '�"+ �� •v,rx4�,.� s, ,�,a x�.� � ' y. ��: � �a �+ ��r �'`t ^ +�;� �1 � . ,. ` , ��'�' ,.,.. ,� � ��' ti"' ' � r, :�s.:. w d R'. vr�r��. .t �, ��d �Wy "� r ':t�i ^`�.gv`..r�':`�'�`''�?,�.`�, � ,:Y. lel�.�.. fj � �q�.;.ry. .�{ a` .{' � :�`..h '�Yt-^ �} R�"�W�� .J� r{.l I` _±;R ��". . �,�iyi."k'�~ '� I h�'�.�h'W��; ��'h,�',�,�'L 1 �;""_, �.. , ° .. ,- .. . .�- . �..I .��i .: l�y#�"� :��'PH r �'rc,� ' 4 �-� tt�+,kY�.. '�,,.�. �.t�'�' �•'�St r� ,3•� s ,. � a•� �'-�y''y^ ,{ y �" �� a ��' � S il•, .. �. t � '� ` _ �'.'a�. �>r,iy•��a r. �`+ '�� 'S ,'.� �:d.:: hF "+ .�L a. Y�� " Y�,� ��t .�.;�r-�'"^��f Y�;�:�4' 'a,.. ''�; k�.�,a ;,�{��^. ;�•��{'�.. �' '�i; �"�y . y� �r� � us ;c �"9 i`..i� v$��i.i�v 'a�^y,�d`�, ,.;r KA.3. �y�"', .r . :�' �;! '`�a A .� :,' ' ,` w B�'; , r. �;: Sp�s 4. t ,��`^y t.a 1 p7�,� ,Mt k y� .,� , �,., y� {y;,,� � ,� '�, ,��I•, �. � e;� �. �y��'rF. '�'. tf b•• c'�' d~� D.. jj":� e r� . �w,i �' e i,l`i q;� .� � ��s 5'�". i.�t.1 a' ��' y .� �� p :�w t i. h� ..w�� i ��,�' , :�j� ��'x`v-. `d..., n� ...� d .w:r r ►�w ,,, ��,�r "4�{ r; ,r,r�� „�� A N: $ y;� "k� .,�.�,� �s�uM,, 1 � �.y.3 � i�. "^` ,., �,: , � . � s'Y+;' x.Fla'a " ' i , "'x „�4� '� , �;' f �� .� .'�'� k"� x, y: r� ,�;� „��i;�� }6 :& i. � �,��a .� �+�, �;, � ..,��M �".if ""�I°y�' YSy,�. � s�� .:�.. �� r � 'q y��.,,{�.'� Y +� '�,. .f, '�,�� ` t sµ � w r:�a k �+�'= � °;� Y {�, s�,''4 t Aa�� $�I¢,�,.3.�:. �' '�. °',� G� � iG"..1,+ y�M� r��a _ Z ro1u� `,,.: ..4. .p� �,.'.�'- Yn yz�, r �f `��"t'. r ,. � � 'll. � y . � I �} � y� � h .f � 1+. l�.� A� pl � ry��. � ��uK 14 � .`;, tit tt.' t k a.;,x� s�4. � �„yt • � b'�, „�.q5 �� S°'rt`� 4:�:,�`�; � � x}t I y* r5 ap� r � � '� W rC :�,:, , y. � !s'( \ n t' ,�,;�p ��"�"� lf x s�,� � �S SS � r:', 4J R7�+ S�'° �''�t1� cp� ,� ��,e .�, �"Z�)m a T ,4� ��- r n`y � "`h :`� ��;. p�.n. .(' •,�A•, .�,�� ;� �.y. �s�- �^ � ,�' s �''� t• ,tM'�ti �' ,.+'b�;ti: `� :�.i#+; �"^` ^ ,�"�` g f,4�,. f�;�"`� :"� 1$`� 1ss; ��4'rw . , ".T�.,'"_"��. ;�ti,t�. . �,F;'Y r :,r .. � �' u`jr�'�' s�¢�*,`�,,s, A � ��• i. :t �1 :� . . �ti+�; :G�i � r . �n� � . x �! +�i�� .��"��. ; i�� , . .-� ��:�� ,�'�* ,. �!, 3 « �,� M �. � � ,t'b;�.�.ir;� �i ,..�.� . •� � ,� I",� t"_M1�:�..�1.°�.��1.��L1`.,. .�.�-� �+�.? . �� . -...Y' +.,i.k" ,.,.iia.::.,,j;� ..�n��:k��,.�a�stn � y. ��,. t . ..r 'R �� . ' ' ,anc..� . � �• • GEOTECHNICAL ENGINEERING STUDY PROPOSED AMBER LANE RESIDENTIAL DEVELOPMENT 5409 NORTHEAST FOURTH STREET RENTON, WASHINGTON E-11126 � April 15 2004 PREPARED FOR SEA-PORT DOZING AND DEVELOPMENT, INC. T� -� �� Steven T. Swenson Staff Geologist �`��w��F w I x� �'�f �,r� �•n ,� :? ~o �f �:1 �'� p p � �� 2 �� ,p�,,33t62 p �`�► �s �� F�.YP�FS dZ-03-D S �!�s/�y Kristina M. Weller, P.E. Project Manager Earth Consultants, Inc. 1805 - 136th Place Northeast, Suite 201 Bellevue, Washington 98005 1425) 643-3780 Toll Free 1-888-739-6670 ` ` IMPORTANT INFORMATION �. . ABOUT YOUR ` GEOTECHN�CAL ENGINEERING REPORT More construction probfems are caused by site subsur- technical engineers who then render an opinion about face conditions than any other factor. As troublesome as overall subsurface conditions, their likely reaction to subsurface problems can be, their frequency and extent proposed construction activity, and appropriate founda- have been lessened considerably in recent years, due in tion design. Even under optimal circumstances actual large measure to programs and publications of ASFEj conditions may differ from those inferred to exist, The Association of Engineering Firms Practicing in because no geotechnical engineer, no matter how the Geosciences. qualified,and no subsurface exploration program, no The foliowing suggestions and observations are offered matter how comprehensive, can reveal what is hidden by to help you reduce the geotechnical-related delays, earth, rock and time. The actual interface between mate- i cost-overruns and other costly headaches that can rials may be far more gradual or abrupt than a report occur during a construction project. indicates.Actual conditions in areas not sampled may ,I differ from predictions. Nothing can be done to nrevent tfie , unanticinated, but stens can 6e taken to he(n minimize their ! A GEOTECHNICAL ENGINEERING impact. For this reason, most experienced owners retain their REPORT IS BASED ON A UNIQUE SET 9Qotechnicaf consultants through the construction stage, to iden- tify variances,conduct additional tests whic�i may be OF PROJECT SPECIFIC FACTORS needed,and to recommend solutions to problems encountered on site. A geotechnical engineering report is based on a subsur- face exploration plan designed to incorporate a unique SUBSURFACE CONDITIONS set of project-specific factors.These typically include: the general nature of the structure involved, its size and CAN CHANGE configuration; the location of the structure on the site and its orientation; physical concomitants such as Subsurface conditions may be modified by constantly- access roads, parking lots, and underground utilities, changing natural forces. Because a geotechnical engi- and the level of additional risk which the dient assumed neering report is based on conditions which existed at by virtue of limitations imposed upon the exploratory, the time of subsurface exploration, construction decisions program. To help avoid costly problems, consult the >E��uld not be based on a geotechnical engineering re�ort whose geotechnical engineer to determine how any factors adequacy mau��ave heen affected by time. Speak with the geo- which change subsequent to the date of the report may technical consultant to learn if additional tests are affect its recommendations. advisable before construction starts. Unless your consulting geotechnical engineer indicates Construction operations at or adjacent to the site and otherwise, your geotechnica!engineering report shoutd not natural events such as floods,earthquakes or ground- be used: water fluctuations may also affect subsurface conditions •When the nature of the proposed structure is and, thus, the continuing adequacy of a geotechnical changed, for example, if an office building will be report. The geotechnical engineer should be kept erected instead of a parking garage, or if a refriger- apprised of any such events,and should be consulted to ated warehouse will be built instead of an unre- determine if additional tests are necessary. frigerated one; •when the size or configuration of the proposed GEOTECHNICAL SERVICES ARE structure is altered; PERFORMED FOR SPECIFIC PURPOSES •when the location or orientation of the proposed AND PERSONS structure is modified; .when there is a change of ownership, or Geotechnical engineers' reports are prepared to meet •for application to an adjacent site. the specific needs of specific individuals. A report pre- Geotechnical engineers cannot accept responsibi�ity for problerns }�arecf for a cansuiti�g civil engineer may not be ade- which may deve(op if they are not consulted after factors consid- quate for a construction contractor, or even some other ered in their report's develonment have changed. consulting civil engineec Unless indicated otherwise. this report was prepared expressly for the client involved and expressly for purposes indicated by the client. Use MOST GEOTECHNICAL "FINDINGS" by any other persons for any purpose, or by the client ARE PROFESSIONAL ESTIMATES for a different purpose, may result in problems. No indi- vidual other than the client should appl y this report for its Site exploration identifies actual subsurface conditions intended purnose without�irst conferring with the geotechnical only at those points where samples are taken,when engineer. No persnn shou(d apply this report for any nurnose they are taken. Data derived through sampling and sub- other t�ian that originally contemplated without jirst conJerring sequent laboratory testing are extrapolated by geo- with the geotechnicaf engineec � • . .r A GEOTECHNICAL ENGINEER(NG der the mistaken impression that simply disclaiming re- . � REPORT IS SUBJECT TO sponsibility for the accuracy oE subsurface information MISINTERPRETATION always insulates them from attendant liability. Providing the best available information to contractors helps pre- Costly problems can occur when other design profes- vent costly construction problems and the adversarial sionals develop their plans based on misinterpretations attitudes which aggravate them to disproportionate of a geotechnical engineering report. 'Ib help avoid scale. these problems, the geotechnical engineer should be READ RESPONSIBILITY retained to work with other appropriate design profes- sionals to explain relevant geotechnical findings and to CLAUSES CLOSELY review the adequacy of their plans and specifications relative to geotechnical issues. Because geotechnical engineering is based extensively on judgment and opinion, it is far less exact than other design disciplines. This situation has resulted in wholly unwarranted daims being lodged against geotechnical BORING LOGS SHOULD NOT BE consultants. 'Ib help prevent this problem,geotechnical engineers have developed model clauses for use in writ- SEPARATED FROM THE ten transmittals.These are not exculpatory dauses ENGINEERING REPORT designed to foist geotechnical engineers' liabilities onto someone else. Rather, they are definitive cla�ses which Final boring logs are developed by geotechnical engi- identify where geotechnical engineers responsibilities neers based upon their interpretation of field logs begin and end. Their use helps alt parties involved rec- (assembled by site personnel)and laboratory evaluation ognize their individual responsibilities and take appro- of field samples. Only final boring logs customarily are priate action. Some of these definitive dauses are likely included in geotechnical engineering reports. These logs to appear in your geotechnical engineering report, and should not under any circumstances be redrawn for indusion in you are encouraged to read them closely.Your geo- architectural or other design dra�a�ings, because drafters technical engineer will be pleased to give full and frank may commit errors or omissions in the transfer process. answers to your questions. Although photographic reproduction eliminates this problem, it does nothing to minimize the possibility of OTHER STEPS YOU CAN TAKE TO contractors misinterpreting the logs durin�bid prepara- tion. When this occurs,delays,disputes and unantici- REDUCE RISK pated costs are the all-too-frequent result. Your consulting geotechnical engineer will be pleased to To minimize the likelihood of boring log misinterpreta- discuss other techniques which can be employed to mit- tion, give contractors ready access to the complete geotechnical igate risk. In addition, ASFE has developed a variety of � engineering renort prepared or authorized for their use. materials which may be beneficial. Contact ASFE for a , Those who do not provide such access may proceed un- complimentary copy of its publications directory. II Published by ' THE ASSOCIATION OF ENGINEERING FIRMS PRACTICING IN THE GEOSCIENCES 8811 Coles�ille Road/Suite G 106i Silver Spring, Maryland 20910/(301) 565-2733 0788/3�d . . � ��rrr� Co��lsultants, Inc. . �,�:. _ , ..,. c�xttcxluik�ilt:ii�;i�uxr�,(;��k�};i5t5&I��ir�Huixytt��lticiciuis�ti hStcl�)�IS�If'(� 1975 C[)I lSl f l I('IKII l 7(.SI111};&ICI 1()!��'i113()III.S'�xY'l l(Nl S(YV'NYLS April 9, 2004 E-11126 Sea-Port Dozing and Development, Inc. P.O. Box 3015 Renton, Washington 98056 Attention: Mr. Robin Bales ; Dear Mr. Bales: Earth Consultants, Inc. (ECI) is pleased to submit our report titled "Geotechnical Engineering Study, Proposed Amber Lane Residential Development, 5409 Northeast Fourth Street, Renton, Washington". This report presents the results of our field exploration, selective laboratory tests, and engineering analyses. The purpose and scope of our study were outlined in our April 5, 2004 proposal. In general, our study indicates the site is underlain by native medium dense to dense silty sand with varying amounts of gravel. Based on the results of our study, it is our opinion the site can be developed generally as planned. The proposed single-family residences should be supported on conventional spread and continuous footing foundation systems bearing on competent native soil or on newly placed structural fill used to modify site grades, We appreciate this opportunity to be of service to you. If you have any questions, or if we can be of further assistance, please call. Respectfully submitted, EARTH CONSULTANTS, INC. Scott D. Dinkelman, LEG Associate Principal STS/SDD/KMW/csm 1805 136th Place N.E., Suite 201, Bellevue,WA 98005 : Bellevue f425)643-3780 FAX(4251 746-0860 Toll Free (888) 739-66'0 � . ' TABLE OF CONTENTS E-11126 PAGE INTRODUCTION................................................................................................ 1 General ....................................................................................................... 1 Scopeof Services ........................................................................................ 1 Project Description ...................................................................................... 2 SITECONDITIONS ........................................................................................... 3 Surface ....................................................................................................... 3 Subsurface .........................................................................................�....... 3 Groundwater........................................................................................�........ 4 LaboratoryTesting ....................................................................................... 5 DISCUSSION AND RECOMMENDATIONS ........................................................... 5 General ....................................................................................................... 5 Site Preparation and General Earthwork........................................................... 6 Foundations................................................................................................. 7 Slab-on-Grade Floors..................................................................................... 8 RetainingWalls ........................................................................................... 8 ' Seismic Design Considerations....................................................................... 9 GroundRupture ....................................................................................... 9 Liquefaction ............................................................................................ 10 Ground Motion Response.......................................................................... 10 ' Excavations and Slopes................................................................................. 10 SiteDrainage ............................................................................................... 1 1 Utility Support and Backfill ............................................................................ 12 Pavement Areas ........................................................................................... 13 LIMITATIONS ................................................................................................... 13 AdditionalServices....................................................................................... 14 Earth Consultants, Inc. • �. • TABLE OF CONTENTS, Continued E-11126 ILLUSTRATIONS Plate 1 Vicinity Map Plate 2 Test Pit Location Plan Plate 3 Retaining Wall Drainage and Backfill Plate 4 Typical Footing Subdrain Detail Appendices , Appendix A Field Exploration Plate A 1 Legend Plates A2 through A5 Test Pit Logs Appendix B Laboratory Test Results Plate B1 Grain Size Analyses Earth Consultants, Inc. �• . GEOTECHNICAL ENGINEERING STUDY PROPOSED AMBER LANE RESIDENTIAL DEVELOPMENT 5409 NORTHEAST FOURTH STREET RENTON, WASHINGTON E-11126 INTRODUCTION General This report presents the results of the geotechnical engineering study completed by Earth Consultants, Inc. IECI) for the Proposed Amber Lane Residential Deveiopment, 5409 Northeast Fourth Street, Renton, Washington. The general location of tiie site is shown on the Vicinity Map, Plate 1 . The purpose of this study was to explore the subsurface conditions at the site and, based on the conditions encountered, to develop geotechnical recommendations for the proposed single-family residence development. Scope of Services We performed this study in general accordance with the scope of services outlined in our April 5, 2004 proposal. On this basis, our study addresses: • Subsurface soil and groundwater conditions; • Site preparation, grading, and earthwork procedures, including details of fill placement and compaction; � The suitabi�ity of using on-site materials for use as structural fill, and providing recommendations for imported fill materials; • Foundation design recommendations, including bearing capacity and lateral pressures for walls and structures; • Utility trench excavation and backfill recommendations; • Seismic design criteria, including an evaluation of potential liquefaction hazard; � Short-term and long-term groundwater management and erosion control measures; Earth Consultants, Inc. . '. . GEOTECHNICAL ENGINEERING STUDY Sea-Port Dozing and Development, Inc. E-1 1126 April 15, 2004 Page 2 • Potential total and differential settlement magnitudes; and ', • Temporary slope recommendations. , Project Description ' We understand it is planned to develop the approximatety 1 .3-acre, irregularly shaped, i property with a single-family residence development. Based on preliminary project information provided by the client, the proposed development will include �,p to five single-family residence lots, a stormwater detention tract, a wetland tract; and an arterial roadway extending to Lyons Avenue Northeast. At the time our study was performed, the site and our exploratory locations were approximately as shown on the Test Pit Location Plan, Plate 2. � Based on our experience with similar projects, we anticipate the single-family residences will be two stories in height and will be of relatively lightly loaded wood- frame construction with a combination of slab-on-grade and wood joist floors. Wall loads will likely be on the order of 2 to 3 kips per lineal foot, with column loads of 20 to 30 kips, and slab-on-grade floor loads of 150 pounds per square fo�t (psf). We estimate cuts and fills of five feet or less will be required to reach construction subgrade elevations within the site. The conclusions and recommendations in this study are based on our understanding of the proposed development, which is in turn based on the project information provided us. If the above project description is incorrect or the project information changes, we should be consulted to review the recommendations contained in this study and make modifications, if needed. Earth Consultants, Inc. . GEOTECHNICAL ENGINEERING STUDY Sea-Port Dozing and Development, inc. E-11126 April 15, 2004 Page 3 SITE CONDITIONS Surface The subject site consists of an approximately 1 .3-acre, irregulariy shaped, property that includes an existing residential lot located at 5409 Northeast Fourth Street, Renton, Washington. The approximately 1 .i-acre, roughly rectangular, portion of the site to be II developed lies immediately south of the existing residential lot. The area to be � developed extends roughly seventy-five (75) feet west, two hundred twenty-ftve (225) feet east, and one hundred sixty-three (163) feet south of the southwest property , corner of the existing residential lot (See Plate 1 , Vicinity Map?. The site is bordered to the north by Northeast Fourth Street, to the south by an existing residential development, to the east by single-family residences and Lyons Avenue Northeast, and to the west Chuck's Donut Shop and an existing single-family residence. The site contains an existing single-family residence located in the northern portion of the property and a north-south running drainage located in the western portion of the property. We understand that the existing residence is to remain. The site topography is relatively level with a maximum elevation change on the order of four feet. The site is primarily vegetated with short grass and scattered growths of blackberries. The site is also vegetated with sparse, medium to large diameter pouglas fir, maple, cedar, and cottonwood trees. Subsurface Subsurface conditions at the site were evaluated by excavating four test pits at the approximate locations shown on Plate 2, Test Pit Location Plan. The test pits were excavated to a maximum depth of eleven and one-half (11 .5) feet below existing grade. Please refer to the Test Pit Logs, Plates A2 through A5, for a more detailed description of the conditions encountered at each location explored. A description of the field exploration methods is included in Appendix A. The following is a generalized description of the subsurface conditions encountered. Earth Consultants, Inc. . GEOTECHNICAL ENGINEERING STUDY Sea-Port Dozing and Development, Inc. E-11126 April 15, 2004 Page 4 At our test pit locations, we encountered a surficial layer of topsoii and grass. The topsoil and vegetation layer was typically three to six inches thick but ranged up to one and one-half feet thick as encountered in Test Pit TP-4. The topsoil and vegetation layer was characterized by its dark brown color, loose consistency, and the presence of abundant roots and organic debris. The topsoil and vegetation layer is not considered suitable for support of the proposed foundations. In addition, it is not suitable for use as structural fill, nor should it be mixed with material to be used as structural fill. Underlying the topsoil and grass, we encountered medium dense native soil cor�wprised of silty sand with varying amounts of gravel (Unified Soil Classification SM). � The soil became dense at two to four feet below existing grade and remained dense to the maximum depth explored in Test Pits TP-1 through TP-3. In Test Pit TP-4, the dense silty sand (SM) became medium dense at approximately six feet below existing grade. Medium dense poorty graded sand with silt (SP-SM1 was encountered from approximately ten and one-half (10.5) feet below grade to the maximum exploration depth of eleven and one-half (1 1 .5? feet. Groundwater We encountered moderate to heavy groundwater seepage at our test pit locations at depths ranging from one and one-half �1 .5) to ten and one-half (10.5) feet below existing grade. The observed seepage is likely indicative of seasonal perched groundwater collecting along the contact between the overlying medium dense soils and underlying dense soils encountered at our test pit locations. If earthwork is conducted during the wet season, it is likely moderate to heavy groundwater seepage will be encountered. If seepage is encountered, the contractor should be prepared to address seepage in excavations. Based on observed conditions at the site, groundwater levels at the site will likely fluctuate, depending on the season, amount of rainfall, surface water runoff, and other factors. Generally, the water level is higher and seepage rates are greater in the wetter winter months (typically October through May). Earth Consultants, Inc. GEOTECHNICAL ENGINEERING STUDY Sea-Port Dozing and Development, Inc. E-11126 April 15, 2004 Page 5 Laboratory Testing Laboratory tests were conducted on representative soil samples to verify or modify the field soil classifications and to evaluate the general physical properties and engineering characteristics of the soil encountered. Visual field classifications were supplemented by grain size analyses on representative soil samples. Moisture content tests were performed on all samples. The results of laboratory tests performed on specific samples are provided either at the appropriate sample depth on the individual test pit logs or on a separate data sheet contained in Appendix B. It is important to a�ote that these test results may not accurately represent the overall in-situ soil conditions. Our geotechnical recommendations are based on our interpretation of these test results. ECI cannot be responsible for the interpretation of these data by others. In accordance with our Standard Fee Schedule and General Conditions, the soil samples for this project will be discarded after a period of fifteen (15) days following completion of this report unless we are otherwise directed in writing. DISCUSSION AND RECOMMENDATIONS General Based on the results of our study, in our opinion, the proposed single-family residences should be supported on conventional spread and continuous footing foundation systems bearing on competent native soil or on newly placed structural fill used to modify site grades. Slab-on-grade floors should be similarly supported. If loose native soil is encountered at construction subgrade elevations, it should be compacted in- place to the requirements of structural fill to a depth of at least twelve 112) inches below the proposed subgrade elevation. This report has been prepared for specific application to this project only and in a manner consistent with that level of care and skill ordinarily exercised by other members of the profession currently practicing under similar conditions in this area for the exclusive use of Sea-Port Dozing and Development, Inc. and their representatives. No warranty, expressed or implied, is made. This report, in its entirety, should be included in the project contract documents for the information of the contractor. Earth Consultants, Inc. . . . GEOTECHNICAL ENGINEERING STUDY Sea-Port Dozing and Development, Inc. E-1 1126 April 15, 2004 Page 6 Site Preparation and General Earthwork ' Building, pavement, and areas to receive structural fill should be stripped and cleared of ' surface vegetation, organic matter, and other deleterious material. Based on the thickness of the topsoil and vegetative layer encountered at our test pit Iocations we estimate a stripping depth of approximately three to six inches for the majority of the site with localized areas extending to twelve (12) inches below existing grade. Stripped materials should not be mixed with materials to be used as structuraL fill. The stripped materials may be wasted on-site in landscaping or yard areas. Following the stripping operation, an ECI representative should observe the ground surface where structural fill, foundations, or slabs are to be placed. Soil in loose or soft areas, if recompacted and still yielding, should be overexcavated and replaced with structural fill. The optional use of a geotextile fabric placed directly on the overexcavated surface may help to bridge unstable areas. ECI can provide recommendations for geotextiles, if necessary. Structural fill is defined as compacted fill placed under buildings, roadways, floor slabs, pavements, or other load-bearing areas. Structural fill under floor slabs, footings and pavements should be placed in horizontal lifts not exceeding twelve (12) inches in loose thickness and compacted to a minimum of 90 percent of its laboratory maximum dry density determined in accordance with ASTM Test Designation D-1557-91 (Modified Proctor). The fill materials should be placed at their optimum moisture content. The top twelve (12) inches of fill under floor slabs and pavements should be compacted to 95 percent of maximum dry density. Based on the results of our laboratory tests, the on-site soils, at the time of our exploration, appear to be at or above their optimum moisture content and may require moisture conditioning to be suitable for use as structural fill. Laboratory testing indicates the site soils have between 18 and 33 percent fines passing the No. 200 sieve. Soil with fines in excess of 5 percent will degrade if exposed to excessive moisture, and compaction and grading will be difficult if the soil moisture increases significantly above its optimum level, Earth Consultants, Inc. . GEOTECHNICAL ENGINEERING STUDY Sea-Port Dozing and Development, Inc. E-1 1126 April 15, 2004 Page 7 During dry weather, any non-organic compactable granular soil with a maximum grain size of four inches can be used. Fill for use during wet weather should consist of a well graded granular material having a maximum grain size of four inches and no more than 5 percent fines passing the No. 200 sieve based on the minus 3/4-inch fraction. A contingency in the earthwork budget should be included for this possibility. Foundations Based on the results of our study and provided our recommendations are fol�owed, in our opinion, the proposed single-family residences should be supported on conventional spread and continuous footing foundation systems bearing on competent native soil or on newly placed structural fill used to modify site grades. Exterior foundation elements should be placed at a minimum depth of eighteen (18) inches below final exterior grade. Interior spread foundations should be placed at a minimum depth of twelve (12► inches below the top of slab, except in unheated areas, where interior foundation elements should be founded at a minimum depth of eighteen (18? inches. With foundation support obtained as described, for design, an allowable soil bearing capacity of two thousand five hundred (2,500) psf should be used for competent native soil, native soil compacted in place to the requirements of structural fill, or for newly placed structural fill used to modify site grades. Continuous and individual spread footings should have minimum widths of sixteen (16) and eighteen (18) inches, respectively. Loading of this magnitude would be provided with a theoretical factor-of- safety in excess of 3.0 against shear failure. For short-term dynamic loading conditions, a one-third increase in the above allowable bearing capacities can be used. With structural loading as expected, and provided the above design criteria are �� followed, total settlement in the range of one inch is anticipated with differential I, settlement of about one-half inch. Most of the anticipated settlements should occur ' during construction as dead loads are applied. �� Earth Consultants, Inc. , GEOTECHNICAL ENGINEERING STUDY Sea-Port Dozing and Development, Inc. E-11 126 April 15, 2004 Page 8 Horizontal loads can be resisted by friction between the base of the foundation and the supporting soil and by passive soil pressure acting on the face of the buried portion of the foundation. For the latter, the foundation must be poured "neat" against the competent native soils or backfilled with structural fill. For frictional capacity, a coefficient of 0.35 should be used. For passive earth pressure, the available resistance should be computed using an equivalent fluid pressure of three hundred fifty (350) pounds per cubic foot (pcf). The lateral resistance value is an allowable value, a factor- of-safety of 1 .5 has been included. As movement of the foundation element is required to mobilize full passive resistance, the passive resistance should be �weglected if such movement is not acceptable. � Footing excavations should be observed by a representative of ECI, prior to placing forms or rebar, to verify that conditions are as anticipated in this report. Slab-on-Grade Floors Slab-on-grade floors should be supported on competent native soil or on structural fill used to modify site grades. Loose or disturbed subgrade soil must either be recompacted or replaced with structural fill. Slabs should be provided with a minimum of four inches of free-draining sand or gravel. A vapor barrier such as a 6-mil plastic membrane should be placed beneath the slab. Two inches of damp sand may be placed over the membrane for protection during construction and to aid in curing of the concrete. Retaining Walls If retaining walls are planned for this project, they should be designed to resist the lateral earth pressures from the retained soils and applicable surcharge loading. Walls that are designed to yield can be designed to resist the lateral earth pressures imposed by an equivalent fluid with a unit weight of thirty-five (35) pcf. If walls are to be restrained at the top from free movement, the equivalent fluid weight should be increased to fifty (50) pcf. These values are based on horizontal backfill conditions. Surcharges due to backfill slopes, hydrostatic pressures, traffic, structural loads or other surcharge loads are assumed to not act on the wall. If such surcharges are to apply, they should be added to the above design lateral pressure. The passive pressure, allowable bearing capacity, and friction coefficient previously provided in the Foundations section are applicable to the retaining wall design. Earth Consultants, Inc. , • .� GEOTECHNICAL ENGINEERING STUDY Sea-Port Dozing and Development, Inc. E-11126 April 15, 2004 Page 9 To reduce the potential for hydrostatic pressures to build up behind the walls, retaining walls should be backfilled with a free-draining material extending at least eighteen (18) inches behind the wall. The remainder of the backfill should consist of structural fill. The free d�aining backfill should consist of sand and gravel with a fines content of less than 5 percent, based on the minus 3/4-inch fraction. A rigid, schedule 40, perforated PVC or SDR 35 drain pipe should be placed at the base of the wall and should be surrounded by a minimum of one cubic foot per lineal foot with one inch drain rock. The pipe should be placed with the perforations in the down position. The remainder of the backfill should consist of structural fill. A typical retaining wall backfil� detail is provided on Plate 3. Seismic Design Considerations The Puget Lowland is classified as a Seismic Zone 3 in the 1997 Uniform Building Code (UBC1. Earthquakes occur in the Puget Lowland with regularity, however, the majority of these events are of such low magnitude they are not felt without instruments. Large earthquakes do occur, as indicated by the 1949, 7.2 magnitude earthquake in the Olympia area and the 1965, 6.5 magnitude earthquake in the Midway area and the 2001 , 6.8 magnitude Nisqually earthquake. There are three potential geologic hazards associated with a strong motion seismic event at this site: ground rupture, liquefaction, and ground motion response. Ground Rupture The strongest earthquakes in the Puget Lowland are widespread, subcrustal events, ranging in depth from thirty (30) to fifty-five (55) miles. Surface faulting from these deep events has not been documented to date. Therefore, it is our opinion, that the risk of ground rupture at this site during a strong motion seismic event is negligible. Earth Consultants, Inc. • I GEOTECHNICAL ENGINEERING STUDY Sea-Port Dozing and Development, inc. E-11126 ' April 15, 2004 Page 10 Liquefaction Liquefaction is a phenomenon in which soils lose all shear strength for short periods of time during an earthquake. Groundshaking of sufficient duration results in the loss of grain-to-grain contact and rapid increase in pore water pressure, causing the soil to behave as a fluid. To have a potential for liquefaction, a soil must be cohesionless with a grain size distribution of a specified range (generally sand and silt); it must be loose; it must be below the groundwater table; and it must be subject to sufficient magnitude and duration of groundshaking. The effects of liquefaction may� be large total and/or differential settlement for structures founded in the liquefying soils. In our opinion, the potential for widespread liquefaction-induced settlement at this site is negligible. The absence of a shallow groundwater table and the generally medium dense to dense condition of the soils is the primary basis for this conclusion. Ground Motion Response The 1997 UBC Earthquake regulations contain a static force procedure and a dynamic force procedure for design-base shear calculations. Based on the encountered soil conditions, it is our opinion soil profile type Sc, Very Dense Soil or Soft Rock as defined in Table 16-J should be used to characterize the site soils. Excavations and Slopes The following information is provided solely as a service to our client. Under no circumstances should this information be interpreted to mean that ECI is assuming responsibility for construction site safety or the contractor's activities; such responsibility is not being implied and should not be inferred. The inclination of temporary slopes is dependent on several variables, including the height of the cut, the soil type and density, the presence of groundwater seepage, construction ' timing, weather conditions, and surcharge loads from adjacent structures, roads, and equipment. Because of the many variables involved, the inclination of temporary excavation slopes should be further evaluated during construction, as the actual soil and ' groundwater conditions become more apparent. Earth Consultants, Inc. , ' GEOTECHNICAL ENGINEERING STUDY Sea-Port Dozing and Development, Inc. E-11 126 April 15, 2004 Page 1 1 In no case should excavation slopes be greater than the limits specified in local, state (WISHA), and Federal (OSHA) safety regulations. Based on the information obtained from our subsurface exploration, the medium dense soils encountered in the upper two to four feet at our test pit locations would be classified as Type B by OSHA/WISHA. Temporary cuts greater than four feet in height in Type B soils should be sloped at an inclination of 1 H:1 V (Horizontal:Vertical). The underlying dense soils would be classified as Type A by OSHA/WISHA. Temporary cuts greater than four feet in height in Type A soils should be sloped at an inclination of 0.75H:1 V. If seepage is encountered in site excavations, the soil should be considered a Type C soil by OSHA/WISHA. Temporary cuts graater than four feet in height in Type C soils should be sloped at an inclination of 1 .5H:1 V. � If slopes of this inclination, or flatter, cannot be constructed, temporary shoring may be necessary. ECI should observe temporary excavations during construction to verify the OSHA Soil Type. Shoring will help protect against slope or excavation collapse, and will provide protection for workers in the excavation. If temporary shoring is required, we will be available to provide shoring design criteria. Permanent cut and fill slopes should be inclined no steeper than 2H:1 V. Cut slopes should be observed by ECI during excavation to verify that conditions are as anticipated. Supplementary recommendations can then be developed, if needed, to improve stability, including flattening of slopes or installation of surface or subsurface drains. Permanently exposed slopes should be seeded with an appropriate species of vegetation to reduce erosion and improve stability of the surficial layer of soil. Site Drainage Moderate to heavy groundwater seepage was encountered at our test pit locations excavated as part of this study at depths ranging from one and one-half (1 .5) to ten and one-half (10.5► feet below existing grade. The observed seepage is likely indicative of seasonal perched groundwater collecting along the contact with the underlying dense soils encountered at our test pit locations. Earth Consultants, Inc. • GEOTECHNICAL ENGINEERING STUDY Sea-Port Dozing and Development, Inc. E-11126 April 15, 2004 Page 12 Based on the conditions observed during our subsurface exploration, perched groundwater seepage will likely be encountered in excavations if the grading is conducted during the wet season. If grading is conducted during the dry season, the potential and magnitude of seepage should decrease. If seepage is encountered in foundation or utility excavations during construction, the bottom of the excavation should be sloped to one or more shallow sump pits. The collected water can then be pumped from these pits to a positive and permanent discharge, such as a nearby storm drain. Depending on the magnitude of such seepage, it may also be necessary to interconnect the sump pits by a system of connector trenches. , During construction, the site must be graded such that surface water is directed off the site. Water must not be allowed to stand in areas where buildings, slabs, or pavements are to be constructed. Loose surfaces should be sealed by compacting the surface to reduce the potential for moisture infiltration into the soils. Final site grades must allow for drainage away from the residence foundations. The ground should be sloped at a gradient of 3 percent for a distance of at least ten feet away from the building, except in paved areas, which can be sloped at a gradient of 2 percent. Footing drains should be installed around the residence perimeters, at or just below the invert of the footing, with a gradient sufficient to initiate flow. A typical detail is provided on Plate 4. Under no circumstances should roof downspout drain lines be connected to the footing drain system. Roof downspouts must be separately tightlined to an approved discharge. Cleanouts should be installed at strategic locations to allow for periodic maintenance of the footing drain and downspout tightline systems. Utility Support and Backfill Utility trench backfill is a key concern in reducing the potential for settlement along utility alignments, particularly in pavement areas. It is important that each section of utility line is adequately supported in the bedding material. The material should be hand tamped to provide support around the pipe haunches. Fill should be carefully placed and hand tamped to about 12 inches above the crown of the pipe before heavy compaction equipment is brought into use. The remainder of the trench backfill should be placed in lifts having a loose thickness of less than twelve (12) inches and compacted to the appropriate structural fill requirements. Earth Consultants, Inc. • GEOTECHNICAL ENGINEERING STUDY Sea-Port Dozing and Development, �nc. E-11126 April 15, 2004 Page 13 Pavement Areas The adequacy of site pavements is related in part to the condition of the underlying subgrade. To provide a properly prepared subgrade for pavements, the subgrade should I be treated and prepared as described in the Site Preparation and General Earthwork I section of this report. This means at least the top twelve (12) inches of the subgrade '� should be compacted to 95 percent of the maximum dry density (per ASTM D-1557-91 ). ', It is possible that some localized areas of soft, wet or unstable subgrade may still exist , after this process. Therefore, a greater thickness of structural fill or crushed roc�c may be needed to stabilize these localized areas. ' ' The following pavement sections are applicable to parking and drive areas that will be subjected to primarily passenger vehicles and occasional truck traffic: • Two inches of asphalt concrete (AC} over four inches of crushed rock base (CRB) material, or • Two inches of AC over three inches of asphalt treated base (ATB) material. We can provide pavement recommendations for areas that will receive heavy traffic, if needed. Pavement materials should conform to WSDOT specifications. The use of a Class B asphalt mix is suggested. LIMITATtONS Our recommendations and conclusions are based on the site materials observed, selective laboratory testing and engineering analyses, the design information provided us, and our experience and engineering judgment. The conclusions and recommendations are professional opinions derived in a manner consistent with that level of care and skill ordinarily exercised by other members of the profession currently practicing under similar conditions in this area. No warranty is expressed or implied. Earth Consultants, Inc. • • �I •• I�i GEOTECHNICAL ENGINEERING STUDY Sea-Port Dozing and Development, Inc. E-11126 April 15, 2004 Page 14 The recommendations submitted in this report are based upon the data obtained from the test pits, laboratory test data, and our visual observations. Soil and groundwater conditions between test pits may vary from those encountered. The nature and extent of variations between our exploratory locations may not become evident until construction. If variations do appear, ECI should be requested to re-evaluate the recommendations of this report and to modify or verify them in writing prior to proceeding with the construction. Additional Services , As the geotechnical engineer of record, ECI should be retained to perform a general review of the final design and specifications to verify that the earthwork and foundation recommendations have been properly interpreted and implemented in the design and in the construction specifications. ECI should also be retained to provide geotechnical services during construction. This is to observe compliance with the design concepts, specifications or recommendations and to allow design changes in the event subsurface conditions differ from those anticipated prior to the start of construction. We do not accept responsibility for the performance of the foundation or earthwork unless we are retained to review the construction drawings and specifications, and to provide construction observation and testing services. Earth Consultants, Inc. . :i __ � _ t * �"' `'- ,� x � , �,'�� • : �f ,� ; `� � �l -.r _. '�' �`� . .� 1 � � --� .- , �� I `� ,. t C . i If _ 1 �v� _."_' � �' .. _ r�iL �' • ' �.�l t.�- � l , � I � ��.a..�.. ,.#,�-�� __�_. �..v„�:;,-- �.. � _jL, � � �� _�►;_ �- ` L� . I � I ".j r�� .s�'� � ;r r_ �,_ . - . E � _ _ . d��, i : ' n'-�F � � � E � � � -. - - � . -� _ � c j� _.• '} .i.- .�_. •I � � . ) . .. - •1' '1 . _ �. 1 ... . . ,`_' l 1�� :� , ._ � �i� _ � . .' -: � � � -- _ - �i' - � ; - ` : I : , i � -_ _. _ ,_ �_� __ _ i Pj � `'�'/'^'� ( SJ � �•�� ,. � ' _ I ' '��S�._� F �e./ � , .� � F � . . . � I � . F ' e , , � � ; ' : � " � , : . � _ _.__.. _ ._ . ,,, >--:• :. �,_ : ' : - _. `" - ... s I .� � ` �, �.. Y� " : � . }t i �1;� j:4 t�': ... . . _._ _ .. � . i�." . �� . -- � \ ' \'� ` . - . - . - -� ;i'•: _ ! `-'a', . . . , �,-.e � ��'? tii� . .,_ �_. . _ _ �ti `.x ,� .. _ ., . ._,. .. . `"�\ . t _ _T��...i , . _ :t:' J- .. � •� ... . . � . . - _ _ �e4;.A• • _ .. . - •_ • . �\`�-' ' _. � .. •,��:.1 . _ . •. v _ . j1..J�:. ':�[_ l�tr . . ... . , .��- .).•. � _ _'_�... ....___ . � - .. . . .. . .. .. �� f� y!��_�5-d'��, \'\-" .. . ... t .E�i 'i� _ •.. .. . . . � I v� '�\ .. . .• _ > .. �\�� . i ... . ' • _ . .. � `a , _ i . ' - ,'`t.. � � �` ::} ' .__- _ �._ . . 4�t:' +`� - . I � : .'f _ _ ' "+ :�1 .. -:. • .. ..: . . . �.. . - . .. � �� , �....._� �.':.. :� .; -`:: � �:. .. ... � - e ��•�l,~�� _ 4 -�� " � .;�' _ _ - ._ � L " � _ 1 - _ _ _ a;�. _ I - . '; ':r. ry 5 .. _ - �. � % � _ � ` � I - C � ' — ... .. ,. �� .. ' .. . - ��\r� _ ` ' ` .. � � . � _ ,, .. `'., ra f .� :..' - _ ,;.. ' _ �. .. 4 . .: . .. . . .. .� � _ __ .. ,. � 1 . . . . '�• . � , -. ..i .,_ • . •= ,. -- . z ;:-`• � ��°��._ . I � .... _ . } , . . . - � .. _" '. . • .f�':-1�. ' . <.. . .-�� .. ... .. —'' _ i - .. . .. . " ' _ : � ._ ' . ' _ .... . 1 . � f:� . -. .. .. _ .. . � . . ".. ' ..-i _ . - ,- . • - - �'/-:" r�.�: � Earth Consultants, tnc. �Geotechnical En�neering.Geology.Em�ronrr�enfal Sciences Reference: � Construction Testing&ICBO/WABO lnspecrion Services King County °��;".� Map 656 By Thomas Brothers Maps Vicinity Map I Dated 2004 Amber Lane Renton, Washington NOTE: This plate may contain areas of color. ECI cannot be responsible for any subsequent ��'^rn• GLS Date April 2004 Proj. No. 11126 � misirrterpretation of the information resulting � from black&white reproductions of this plate. Checked STS Date 4R/04 Plate ` 1 '. N.E. 4th STREET � Existing House r___i � i 5409 i i i �----� � 4 TP-41 —�— I �TP-2 —■_ f , TP�I � �r TP-1 I —•— - - - I �3;��`�� — .1G a � a. _ '�� i,, �l i ,I_. 1��/ a 3- LEGEND � ��. TP-1—�—Approximate Location of �� I ECI Test Pit, Proj. No. v E E-11 i2fi, April 2004 Not - To - Scale Subject Site �'`� � �� Earth Consultants, Inc. i Geotectvrical En�neerhng Geology.Envirorunernal Sdc�nces •.� �� Wetland Area ��, , .�� Const[�tlonTesringh ICBO!WABOIrLspectionServices ��=� ''� (Detineated By Others) �-�--'' Test Pit Location Plan Lot Number Amber Lane Renton, Washington ; NO'TE: This plate may contain areas of cobr. ECt cannot be responsible for any subsequerrt ��►• GLS Date Aprii 2004 Proj. No. 11126 misiMerpretation of the information resulting from bladc 8�white reproductions of this plate. Checked STS Date 4J7/04 Plate . 2 I ` ,� -- - - -- -- - -- ---- � I i Free Draining 1 S inches min. i Backfi II --�. °u�� - - :•:; I •��=.:� 111=111=111= Min 2"Dia. flo o° o� 12 inches :�=:�:��:'.;: ::�':`;"':�:::�:::' IIIIII III ;r•;:- :s. . '.c:--�.:..:~�'•••:�� Weep Hole o 0 0°� .�� ,::•,; :•:•;;• ?:;: 00 00 -�.o.. •. .D o• o00 �o�'�-o- ;:;-,-: 0 ��. � o °�co� �o o c� o " . p�� o a o '� •�."'O �oo � ° C�' t0�0� � � oo Oo�00 '�1."J.p'' � ; `b � � o o a oo�� •0.0 . .Q . Min. 6" :o�oo oo� 1"Drain �oo�Op ° ooO o°eo 0 0, +•;:o=;� p 1� 0 ��o�� o� R�il� 00 �oO O ��O�oo �.�p;� :�i ' ��I��I�� o 0 0 0 0 0 � o o •� •' �--��vated Sbpe o�o � o � �o°oa o o • 00o cbo 000 ° o a�' •�{. �o 00 O o,-,l1 Qoo •• . a a O Q Q �v-Ope o �.O.��a � �o �� 0'�a �r � . ��,�� O O� � O o�0 o Oa D O,��.•• WEEP HOLE DETAIL °� ° � �°` � °� .�= � a a o0 0 aoa 000aoopq,o�o ' 0o a o a o 0 0�0 0 0 '. Perforated Pipe 111=111=111 a° °o 0 0 o a o° o .°:': Wrapped with 1 foot min.I 'o"_�� • ° Fiter Fabric ,� - ii foot min.Compacted Subgrade i �--- � 1 ' I � STANDARD NOTES 1 FrFNQ ' 1) Free Draining bacl�ill should consist ot .:: '.�: Surface Seal; Natnre Soil or other Low granular soil having no more than 5 �::;'��'�=:; peRneability Material per+�ent passing the#200 sieve and no particles greater than 4 inches in o°o 0 0o Free Draining Backfill dameter.The percentage of patticles passing the#4 sieve should be between o.:- 25 and 75 peroent �a`;:-:o- Stn�ctural Fiil compacted to 90 pe�errt d-- ' - ' relative compaction 2) Structural backfill should be free of o 0 0,a organics,clayey soils,debris and other o000�ea 1 inch Drain Rock deleterious materials. It should be placed at or near the optimum moisture corrtent. SCHEMATIC ONLY- NOT TO SCALE 3) Where weep holes are utilized,surround NOT A CONSTRUCTION DRAWING each weep hole with 3 cubic feet of 1 inch � drain rock. Maximum horizorrtal spacing � of weep holes should be 6 feet. �� Eartrl COI(1SUItaI1tS, Inc. -.Geaechnical Engineers.Geobgists 6 Environrtiercal Scientiscs 4) Drain pipe;perforated or slotted rigid ,I Construction Testing 6 ICBO J WABO Itispection Services � PVC pipe laid with perforations or slots facing down;tight jointed;with a positive RETAINING WALL DRAINAGE AND BACKFILL gra�errt. Do not use fle�dble corrugated Amber Lane plastic pipe. Drain line should be bedded Renton, Washington on and surround with free draining 1 inch drain rock.The drain rodc may be er�capsulated with a geotechnical drainage Drwn. GLS Date April 2004 ProJ. Na. 1112fi fabric at the engineers discreLion. Checked STS Date 4/8/04 Plate 3 - i . , -- _ --- ---� . i ,I ; i i �r I - Slo e To Drain . .•� �----___ P _ -::.::i:;:'• - - •...:a, :,: 'ti.� �': I 6 inch min. �%r �"t� •�f~. �:�.f- � I .:c ;.ti.. ~.; ;:_'• ;.::`:_: ..:� :::- �.�:�. � .:��1��:•• •��:•.•�•�•.::��yi.•i� • ':•:�:i..::'• I •..;:•.: •.... '�' ' � �r:•• .� �•::.:�:''��'r'=�:• i •o=o'�'�'ep�o•O"v��o�o��'Lv�uoOlS� oo"O o��p°a I i 0 � o O p O�00 Op O a��p Qo�D Op O o��Qa I I 04� aoo ° a� o�y° o00 ° 00 ooc� oo� � i81flCf1 I o e �po o �� o o ao o �0 o a �o '. �o o� c o� �a o�000 o� �� 4�oo min. �� UQ �°O�o° D �OoUO �v O o� O �flo�p �a O a UO � a � o p o0 � o � o p o�� o I' o po�a00 � o Oo0o00 a o—po0 0 0 0 0O 0 o e a � � a o 0 0 ! I � p o oa�. °O � � p a o �O � � p o o '��. O°� w0 O� �� a po0 �OD�p�o o ° �oo � I � 4 inch min. °o°a�o a�o°u ��o�o 00 0 o a o 0 ona � � O ° o O o D � D � o O o p ° � ° a �. ; Diameter o°°°o o � a` °o°°°o o � ° ° � ; Perforated Pipe o o��o 0 0� �oo°��o o ; � � oaa a o 0 ooa o Wrapped in Drainage �° � °o°°o °�o �� a °o i Fab17C a �o° � � °�oo o00 0� � ' �o 0 0��o ° �— IQO O�O O � ° o o � � _ n � � i 2 inch min. 2 inch min./4 inch mau_ 12 inch min. iF��Nn ::r':��' Surface seal;native soil or other SCHEMATIC ONLY- NOT TO SCALE '� �� NOT A CONSTRUCTION DRAWING bw permeability material. 0 a°° °�° 1�Drain Rock � ��o i ' i Drain pipe; perforated or slotted rigid �`"'�: I� I � � O PVC pipe laid with perforations or � �, Earth Consultants, Inc. � i slots facing down; tight jointed;with a a Geolechnical Engineers,Geobgsts�EnvironmeMal Scient�sts � positive gradient Do not use fle�able Construction Testing 6 1CB0/wnBO lnspecrion 5ervices � ,s ,p' corrugated plastic pipe. Do not tie building downspout drains into footing �P�CAL FOOTING SUBDRAIN DETAIL lines. Wrap with Mirafi 140 Ftter Fabric Amber Lane or equivalent. Renton, Washington Drwn. GLS Date April 2004 Proj. No. 11126 Checked STS Date 4/8/04 Plsbe 4 . �' . APPENDIX A FIELD EXPLORATION E-11126 Our subsurface exploration was performed on April 6, 2004. The subsurface conditions at the site were explored by excavating four test pits to a maxim�m depth of eleven and one-half (11 .5) feet below existing grade. Test pits were excavated with a John Deere 310 SE rubber-tired backhoe, provided by the client. Approximate test pit locations and elevations were estimated based on pacing from existing features depicted on a preliminary site plan provided by Core Design,,lnc. The locations and elevations of the test pits should be considered accurate only to the degree implied by the method used. These approximate locations are shown on the Test Pit Location Plan, Plate 2. The field exploration was continuously monitored by a geologist from our firm who classified the soils encountered, maintained a log of each test pit, obtained representative samples, measured groundwater levels, and observed pertinent site features. The samples were visually classified in accordance with the Unified Soil , Classification System (USCSI, which is presented on Plate A1 , Legend. Representative soil samples were collected and returned to our laboratory for further examination and testing. Logs of the test pits are presented on Plates A2 through A5. The final logs represent our interpretations of the field logs and the results of our laboratory examination and testing. The stratification lines on the logs represent the approximate boundaries between soil types. In actuality, the transitions may be more gradual. I Earth Consultants, Inc. I ' MAJOR DIVISIONS GRAPH LETTER TYPICAL DESCRIPTION ISYMBOL SYMBOL Gravel e e o (aN/ Weil-Graded Gravels,Gravel-Sand And Clean Gravels a a b gw Mixtures, Little Or No Fines Gravelly (little or no fines) r r Coarse Soils . � , GP Poorly-Graded Gfavels,Gravel- Grained � � � gp Sand Mixtures,Little Or No Fines Soils More Than GM Silty Gravels,Gravel-Sand- 50°r� Coarse Gravels With gm Silt Mixtures Fraction Fines(appreciable Retained On amount of fines) CiC Clayey Gravels,Gravel-Sand- No.4 Sieve gC Clay Mixtures Sand � o ' SW Well-Graded Sands. Gravelly And Clean Sand � o�o��' o o SW Sands, Little Or No Fines Sandy (little or no fines) y, � ;: More Than Soils 6 }:A o ' sP Poorly-Graded Sands, Gravelly 50°o Material ,,4.; A*.,,.�!;;:` Sp Sands, Little Or No Fines Larger Than More Than No.200 Sieve 50°6 Coarse SM Silty Sands, Sand- Silt Mixtures Size Sands With S�l'1 Fraction Fines ;appreciable S eveng No.4 amouM of fines; � i//;,J SC SC Clayey Sands, Sand-Clay Mixtures II II ML Inorganic Silts&Very Fine Sands,Rock Flo�r,Sitty- m�' Clayey Fine Sands;Clayey Silts w/Slight�lasticity Fine Silts Liquid Limit CL Inorganic Clays Of Low To Medium Plasticity, Grained �d Less Than 50 � C� Gravelly Clays, Sandy Clays, SiltY Clays, Lean Soils Clays � I � I � I QL Organic Silts And Organic � I � I � I O� Silty Clays Of Low Plasticity ' MH Inorganic Silts, hlicaceous Or Dfaiom2ceous FirE More Than mh Sand Or Silty Soils 50°6 Mater�al Silts Smaller Than q�d Liqcid Limit , CH Inorganic Ciays Of High No.200 Sieve Clays Greater Than 50 C�'1 Plasticity, Fat Clays. Size // // ��j QH Organic Clays Of Medium To Fligh Ofl Plasticity, Organic Silts `�� "� �"� pT Peat, Humus, Swamp Soils Highly Organic SoiVs �, ��, ��, ��r pt With High Organic Contents , Topsoll �y'�'y�'� Humus And Duff Layer II Fill Hiyhly Variable Constituents II The discussion in the text oi this report is necessary for a proper understanding of the nature of the material presented in the attached logs. DUAL SYMBOLS ere used to indicate bwderline soil clessification. C TORVANE READING,tsf T 2"O.D. SPLiT SPOON SAMPLER qu PENETROMETER READING,tsi � W MOISTURE, %dry'weight � 24"I.D. RING OR SHELBY TUBE SAMPLER P SAMPLER PUSHED * SAMPLE NOT RECOVERED i WATER OBSERVATION WELL pcf DRY DENSITY,Ibs. per cubic ft. LL LIQUID LIMIT, % � DEPTH OF ENCOUNTERED GROUNDWATER PI PLASTIC INDEX DURING EXCAVATION I SUBSEQUENT GROUNDWATER LEVEL W/DATE Fc�11�I1 COI"lSUltal�tS II1C. LEGEND (��uieil�niatl lhig'n��r�:rs.Ga3lugLtls 51fivlrunincnial5c;uil�sis Proj. No, iii26 Date APrii zoo4 Plate Al • • Test Pit Log � Projea Name: snea or ', Amber Lane 1 1 Job No. Loc,�ed by: Date: Test Pit No.: 11126 STS 4/6/04 TP-1 E�avation Contactor: Ground Surfaoe Elev�ion: Client Provided 435' Naes: Genera� w " 8 L m u, B suAace conditions: Depth of Topsoil 8�Sod 6": short grass Notes �/, " T °' " m � �. ( ) c� cn � �n � �n SM Brown silty SAND, medium dense, moist � -trace grav�el and charcoal fragments 2 SM Light brown silty SAND with gravel, dense, moist 3 -iron obde staining i 10.1 4 � -18.6%fines 5 -trace cobbles s � e -increase in moisture content 13.3 9 10 Test pit terminated at 10.0 feet below e�asting grade. Groundwater seepage encountered at 8.5 feet during e�acavabon. NOTES: Test pits were e�acavated using a John Deere 310 SE rubber tired backhoe provided by the client. Test pit elevations estimated based on topographic data shown on the Site Plan provided by the Client. e : 0 � U W � Q CJ � Test Pit Log �(7 Earth Consultants Inc. Amber�ane O Ccx�cYmh:al Fnghx�n�,Gc-[W�g�sA k FiMmnn�r�ra;ticlrntt+"+ � Renton,Washington a � F Proj.r�o. 11126 Dwn. GLS Date Ap�il 2004 Chedced STS oate 4/7/04 Plate A2 Subsurface condRions depicted represent our observations at the time and location af this e�loratory hole,modified by engir�ing tests,analysis and �txigrrrent. They are nd r�ecessariy represeMative aF dher times and locatans.We cannd acoept responsibility for the use or interpretation by others of ..F,,.,.,�.�..,..,.�a..��,,.,.ti��w, - ' � Test Pit Log ' Projed Name: Shee1 of � Amber Lane 1 1 Job No. Loc�ged by: Darte: Test Pit No.: 11126 STS 4/6/04 TP-2 Ezcava2ion Ca�tador. Ground Surface Elevation: Client Provided 436' Na�: o $ L a � � surface canditions: Depth of Topsoil 8�Sod 6": short grass General W Notes (��) 1O E. p " � � i. � � � � SM Brown silty SAND, medium dense, moist to w�et � -contains gravel 2 3 SM Light brown silty SAND with gravel, dense, moist � 4 � 5 -iron o�dde staining �o� -contains cobbles s � -moderate caving of test pit walls due to seepage 8 -increase in moisture s ��.� �o �� Test pit terminated at 11.0 feet below ebsting grade. Groundwater seepage encountered at 2.5, 4.0 and 7.0 feet during e�avation. 0 � < 0 � U w � a � � Test Pit Log � F�lrtrl COY1SUItaY1tS II1C. Amber�ane � O c�xwrtic�kalFiigtnrcxn,c�tsn�t�vlrtnnx-nra��ernrt+s Renton, Washington � a � w Proj.No. 11 126 Dwn. GLS Date Ap�il 2004 Chedced STS Date 4/7/04 Plate A3 Subsurface condRions depided represent our observations at the time and location of this e�loratory hole,modified by engineering tests,analysis and judgment. They are nd r�eoessariy representative of dher times and locations.We cannot accept responsib�lity for the use or interpretatron by others of �fnrmefir�n rvmnnfo'1 nn{hi�IM � , Test Pit Log ' Project Narrie: Sheet af �� Amber Lane 1 1 Job No. Logged by: Date: Test PR No.: 11126 STS 4/6/04 TP-3 Ewcavatian Contador: Graund Surfaoe Elevation: Client Provided 434' Mates: � — m surfaoe condicions: Depth of Topsoil 8�Sod 3": short grass General W t $ = a `n g Notes (%) 1O i. p � m � i. (7 m u� cn SM Brown silty SAND with gravel, medium dense, moist � -contains grav�el and organics �e 2 -increase in moisture,28.6%fines 3 -moderate caving of test pit walls due to seepage 4 -becomes light brown, iron obde staining ': 5 -becomes dense s � Test pit terminated at 7.0 feet below e�usting grade. Groundwater seepage encountered at 2.5 feet during e�a;avation. � a 0 � U W � a � � Test Pit l.og (7 Earth Consultants Inc. Amber Lane p C<»le�.cimk`al Fnghwryti,GKikxQtilA h F�MrC�nir.nf,�l ticlnifltit� Renton, Washington H a � W Proj.t�o. 11126 Dwn. GLS Date April 2004 Chedced STS Date 4/7/04 Plate A4 Subsurface conddions depicted represent our observations at the time and location ofi this e�loratory hole,modified by engineering tests,analysis and judgment. They are not necessarily representative of dher times and locations.We cannot accept responsibility for the use or interpretation by others of „�,,.,,,�«�.,,,.v�e..r�,,.,�tiM i,�, ` � Test Pit Log , Project Narrte: Shee� of ' Amber Lane 1 1 Job No_ Logged by: Date: Test Pit No.: 11126 STS 4/6/04 TP� E�,avation Contador: Ground Surfaoe Elevation: Client Provided 434' Wates: , � — m Sur�ace conda�ons: Depth of Topsoil 8�Sod 18": short grass �I L L a � Notes' (� 10 $ p " � � $ II � � � N , ,y TPSL TOPSOIL and organics � � y 2 SM Brown silty SAND with grav�el, medium dense, moist to wet 3 -becomes light brown and dense 4 -contains cobbles, iron obde staining � 5 s -increase in moisture, becomes medium dense 11.3 � -moderate to heavy caving of test pit walls due to seepage 8 -increase in sand content,decrease in gravel content s �o -33.4%fines " 17.5 SP-SM Brown poorly graded SAND with silt, medium dense, wet, heavy o : �� seepage at 10.5' Test pit terminated at 11.5 feet below e�asting grade. Groundwater seepage encountered at 1.5 and 10.5 feet dunng e�acavation. 0 � � 0 � U w � a N Test Pit Log Earth Consultants Inc. Amber Lane � cr.ai�imkalFiighx�xs.cm�0.v�1�fYMmnnienra��itt� Renton, Washington H a � W Proj.No. 11126 Dwn. GLS Date April 2004 Checiced STS Date 4/7/04 Plate A5 Subsurface condRions depided represent our observations at the time and location of this e�loratory hole,modified by engineering tests,analysis and judgment_ They are nok necessarily repre,sentative o�f ather times and locations.We cannot accept responsibil"ity for the use or interpretation by others of n4.,rrr.aFiiv,nrncnnlcrl nn fhic liv. r ` ,Y` I i APPENDIX B LABORATORY TEST RESULTS E-11126 Earth Consuitants, Ina ( _ f � . Particle Size Distribution Report ., � � � � C Sc Y � Q 5� g �j ii m n �v � c e� � �! ii if i� i �i s �� 'I, ' i, �i I � i i i i I i I � il I i �I i ;, i � ' i � � ' � � I 70 � 1' � ;� Z � ' I; i + � � � I i � F- � Z � U �� ' i � , ' a � ' ' i s 30 - I i � ! � 20 �' �; : I �; , � !� �� 10 I I i ;i f i ;I 0 � ' � 200 100 10 1 0.1 0.01 0.001 GRAIN SIZE- mm 96 C08BLES %GRAVEI. %SAND 96 SILT 96 CLAY USCS AASHTO PL LL � � 26.3 55.1 18.6 SM 0 19.1 52.3 28.6 SM � 3.8 62.8 33.4 SM SIEVE PERCENT FINER SIEVE PERCENT FINER SOIL DESCRIPTION inches C ❑ G number � r , O TP-1:4'-SM 1 5 100.0 100.0 100.0 S#4 73.7 80.9 96.2 Light brown silty Sand with gravel, 10.1% 3/4 100.0 10�.0 100.0 #8 67.7 72.1 90.1 moisture 3/8 82.8 89.2 99.7 #16 62.7 G6.1 gs,� �TP'3:z�-sM �30 522 61.0 �g.j Brown silty Sand wtith gravel(contains #50 41.7 S 1.5 62.9 organics),26.8%masture #l00 28.4 38.5 43.4 �TP�= 10'-Shs f1200 18.6 28.6 33.4 Light brown silty Sand, 17.5%moisture GRAIN SIZE REMARKS: �gp 0.966 0.545 0.271 o STs �30 0.164 0.0836 , p�� ❑STS COEFFICIENTS i C� � STS GU o Source: Sample No.:TP-1 Elev./Depth:4' ❑Source: Sample No.:TP-3 Elev./Depth: 2' � Source: Sample No.:TP-4 Elev./Depth: 10' EARTH Client: i Project: Amber Iane,Renton ' CONSULTANTS, INC. pro' No.: E-11126 Plate B1 , • _+ DISTRIBUTION E-11126 4 Copies Sea-Port Dozing and Development, Inc. P.O. Box 3015 Renton, Washington 98056 Attention: Mr. Robin Bales � Earth Consultants, Inc.