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MICROFICHE
-REFERENCE iL
LIBRARY
4 project of Vol&te& in As,ia
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by: Edward Mazria
Published by: .. I '
Rodale Pfess, Inc. "
331East Hinor Street
Emmaus, PA 18049 USA
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Pqper @bpies are $12.95.
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.Availa.ble from: r. .-Qi
x Rodale Press, Inc. ,,'
r,- .,'33 East Minor Stgeet I,,~ --A -' .,
'F mmaus., PA' 180-49- USA
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Reprodu'ced by. permlksion of the, Rbdale Press. , i
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all of the4nforhation nece$saG. tq successfully.d.qign aneffective
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... .I The best book tie Ii&e seen on passive solar. b;il&ngs becau:e-it makes the O
.*- fundamental,.r&isons why su,ch buildings are highly desirable so crystal
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t - clear. And, once you really understand the fundamentals Qf any suI+ct, the
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; BY EDWARD MAZftlA
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i Copyright @ 1979 by Edward Mazrja
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All rights reserved. No part of this publication may
be reproduced or transmitted in any form{ or by any -“’ *I means, electronic or mechadical,.includrng photocopy, recording, or any. information storage and retrieval system without the written permission of the publisher.
S
L , f3ookDesign hy 7 A lcpley * ”
-.\ .. The passive solar energy book. L
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5 . Bjb;liography:. p.
_ Includes index, , I . \ 1. Solar energy~ 2.Solar heating. I. Title.
\ TJSiO.M32 1979b 696 78-21656 ISBN,O-87857-260-0 (Hardcover) I$ BN O-87857-237-6 (Paperback)
4, 8'10 9 1 hardcover
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Printed in the United States of America on recycled paper, containing a high percentage of de-inked fiber.
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IV;_ Using the Patterns _ -_ . !
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The Passive Solar Energy Book l
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Direct Gain Systems
9. SOLAR WlNDg>WS c “, 10. CLERESTORIES AND SKYLIGHTS 11. MA&ONRY HEAT STORAGE ,- ---- \ _32- JNIERLOR. WATER -WALL- .
Thermal Storage Wall Systems
13. S[ZIbk THE WALL ce. i4. WALL DETAILS .,
I Attach%d Greenhouse Systems \
15. SIZING THE GREENHOUSE 16. GREENi-lOuSE CONNECTIONp
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Robf Pond Systems 1 bj K,enneth 1. Haggard and PO//Y Cooper
17. iZING THE ROOF POND I
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18. ROOF POND DETAILS 193
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Greenhouse . ; ,
19. SOUTH-FA~NG GREENHOUSE 20, GREENHOUSE DETAILS
200
.- 208
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:, 21. ,dXMEitilNC SYSTEMS 22. CLOUDY DAY STORAGE 23. MOVABLE lNSU\+TION 24. REFLECTORS ?,
25. SHADING DEVli3ES .,
26. INSULATION ON THE OUTSIDE 27. SUMMER COOLING
---219. ~- --2i5 230
249 * 258 262
V. The Sun Charts--how the sun works, the cylindricdl 267
THE TOOLS ~ sun chart, sun charts, sun time, plqtting the skyline . . .
The Solar Radiafion Calculator--hourly radiatiov . 293 6 totals, daily radiation totals, splar I intensity masks
The Shadingcalculator-p/ottirfg the sha$ng mask 301 ;
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1. Perfocwa+ce Calcblations 2. Percentaie of Solar Radiation Absorb&i
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)I, :y -2. 3. Averqhe Daily Sol/wRad~iak5~ + -3.
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Four years *igo, when .I kegan writing this book, information concerning ” passive solar heating was,virtually nonexistent. During this time many fri ds have worked with me to generate portions of the information in ihe text. Their work andassistance made the scope of this book possible.
-I want to especially thank: ....,. J
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I ,J Steve Baker who”worked”closely withme for t.wo years to genera!e. data
*for the- formulation of the patterns and calculation p.rocedures. His
i;-iii
- %tsight and kno-w.ledge ofthe subject add a dinet$ion to, the book that .- I would otherwise be-absent. I am grateful not only for his contribution to the book, but for his support,and friendship during iti. production.
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,Ii._ Robert Young who spent numerous hours assembling the .Appendix,
..\$~, i I z producing the technjcal drawi.ngs and photograiphing,many of the build-.
>!, 0 1 -ings.presented .in the book. . y.
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Raymond Har@;n.$ho gave generously of his time, at the conception
,. of the-hook, to answer my seemingly endless questions about solar energy
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Acknowledgments
h-Haggard and Polly Cooper (of their patterns onroof ponds. /.
.
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i oh Cettingsfor his beautiful photographs.
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: &&“lStone~ fbrher early and c
. eagement.
_
i&&a H&&n for be$&&qre wh%& t&going G&?isugh.. -- -* b . .
P.F
n&to MA?Rfi for p;oviding a supportive environment.
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.. 4 1 * . Thei.conti.nuing support of, many -friend.q ,&heir confidence in me and patience i inade.it all,possible: Joyce Brown, Bonnie Katz, Aaron Mazria;,Gary Goldberg, David Tawif, Jim Greenan, Larry Keller, Charlene Cerny, KantFowitz, Barbara.Levy, J. Douglass and Sara Balcomb, Nichols, Rosalie Harris, Carol Bickleman, Boyd B&&it&m
Tim Zanes, Peter Calthorpe, Jim Van Duyn, Eric Hoff and Richard ~-~~
CT
in the text .is modeled after “The Pattern Language”
by Christopher Alexander, Center for Environmental Structure,
.
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xi
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. Ii. known for his c$inmercial.d~~ign~,-j-jltmtrations ,. <__ , r I
. . 0 has been art dire&r 6f threemhjor &ertising
~. / 1s~pr,ints~ and paintings are shown i-n galleries *
\ c United. States. Since the illustrations for this bodk L
: technical information clearly and precisely, as Ily appealing, the illustrdtor and author “have gether throughout the four years of the boo,ks \, dqelopmen t.
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building that is strongly related to* site, climate, local buildid) m,aterials ,and the>sun. It implies a,,specMI.relatio~ship to naturalpsocesses that offers the potential for an inexhaustiblesupply of vital energy. This attitude is obviousjy j not entirely new, since much vernacular architecture has always reflected a
.
. strong relationship to daily and seasonal climatic and solar variations:In recent years, however, relying on the misconception of an infinite and inexpensive energy suf~ply, people have choseen t
siderations. P abandon these Ion&standing con-
.f.;
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Architecture in the twentieth century has been characterized by an emphasis on technology to the exclusion of othervalues. In the built environGment this
concern manifestsitself in *the I
materials we build with, such as plastics and synthetics. There is an existing -dependknce on mechanical control of the indoor enviro?ment rather than exploitaeion of climatic and other ,natural processes to satisfy our comfo~rt -prisoners of complicated mechanical
nts. In a ,sense,, we have become since windows.must be inoperable and sealed in order for work. A minor power. or equipmenf failure can ,make these buildings uninkabitable. Today, little.attention is paid to the unique character andvariation of local climate and building materials. One can now see essentially the same type building from coast to
coast. 1 4 4. Today, there is a strong, new interest in passive solar heating and cooling systems becaus,e they simpjify rathe+r than complicate life: Passive systems are simple in concept at-ii. use,-.ha\Re few moving parts and require little or no maintenance. Also, these systems do not generate thermal pollution, since they
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require ho external energy input and produce no physical by;products or waste. ; f
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.~ Si.nce solar,energy is c0nyenientty.distributed.b alIpa$+ of the globe, expensive transportation and, distribution netwolk$ of energy are also eliminate.dd. *
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Shce a buildingor some element of it is the passive system; TheAappllcatipn 5 of passive solar energy must be included in every step of a buildings design.
,.,_. +eWhereas conventional or a-ctive solar-he.atingiystems can!be s6mewhat independent df the conceptual organization of*:; buildi&, it is extremely difficultto add a passiv,e system to a buildjng once. it hasiheen &signed.
:
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0 I To date; a&hitects,cbuilders and owner-buiklers have made l#tl,e use of the ^
information available conce.roing passive systems because “it :is &o technical: cumbersome and time-consu&ring.,in application. To be useful, information
, mus+t lead to the ne&essary degt;afe of accur$y at yach stage of a buildings I: design. The de.gree of accuracy increases” as the-design moves from the -A ,
... pschematicstagd through detailed drawingsancl models and finally to construe
?:.@ : ,+tion documents. lh the eartystages, it vnakes no sense to perform extensive 0 ! heat, loss and gain calculations,.since the building wfll change, amany times
before a design is complete. 1
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?I > _. n -3!,: The- basic purpose of this book is to make technical information acchssi ” e to
I? a.lI people. The text is written in such a way as to facilitate this. TheLarious elements that make up a passively heated building are- expJained separately -. and,ordkred in a sequence that makes them easy to apply to a buildings
_
Q -.. design. The illustrations that accompany the text are intended to convey very. _i p
: .tPchnical information in a.simple and clear format.
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sdpTiisbook deliberately does not use pr;ofessional architectural and, ehineeringd y
> * graphic symbols to represent various. mateiials and concepts, but, instead, illustrates them with a degree of r;e.aIism. The @hotographs shew, existing .
en
,& ,applications ofboth entire systems as well LISspecific details.,
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.* f T$ allow, for change resulting&&new experiments and observation, the book c
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.- .is structuredin a way-that \permits ;he..&rder to in1prov.e and ad.d information
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earned about passive sys~&r~s.~~Since each element *of. a passive treated separately in the text, the. Eetetrieval of specific Pieces .of.
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,- inform.ation is made easy. .b m * I
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all locations”betwer$n 28:” and 56”
,adapted to the same latitudes in ~ - e
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the Sfuth,ern Hemisphere by simp.ly reversing the sea&s and reversing true
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most of ;he information you willneed ;\* .
. building. Its contents: are ordered~ in S ,applications to system design and I the fundamental c.oncepts of -1” , It provides the foundation for * t
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_I. -... e.. und<6%a~$~+he-in~n given in the following chapters. ~Chapter 3
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~ i j”. presents the various types of passive @ems. i%i&i~g&ec~ral, examples of, -a
each. system are included; .along with. performance data,, to giv.e-~o~rarr----------~.
a Pndication of-their applicability to a wide range of climates, and xlocations. In
: . I . the chapter on design patterns; chapter 4, a method for designing a passiva- . ,
:, solar hearted building is provided: The intenthere is to lead you through, a process that allows you 10 choose-and size a.system suited t9 yourlparticu,lar a 7-b I
-- --: -needs. Once a building and system has been designed, its performqnce can be
* calculated and then adjusted, if. necessary. The graphic tools that follow in? .s
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3: chapter 5 concern the suns position and movement across the skydome,
z- . solar intensity for different orientations, obstructions to solar collection i .
I
j . 4. “Y and. .the design of ,fixed -,ori movable shading devices. And finally, in bthe
,b. ,, ;Appendices;~d$ta-necessary to accurately design and. calcutate a pa&e
a
$,;,“’ system is +zse.nted. geforeyoubegin reading this book, however, keep in j -. ; .
.__ * “mind Ifhat good destgn is the integratiliii~~f-many concerns of. which soiar
-*I energy is b,u,t dhe.
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,j:c , ., The Pass&e Solar Energy Book covers a wide range of passive solar concepts :
a6nd .information. In.order to understand the d&Is of a particular; passive sys
5_-c a: tern, .it is impoHant to first
* the systems. To help you derstand .the fundamental principles behind all
2”
~GZ fundam,Gifa~s, chapters 2 through &are
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a. <,,.r * w-ritten in such a way. that the sentences in_boldtype+summarjze, the text that
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,:.1 . . tjnuous text; To read the book, first read only thh_bold type, consulting the text
Yo clarify and embellish .particu.lar po.infsbfinformation. This will iake you only
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,z ,I. , * and read,the entire text to acquir+ a full understanding of the detai.ls.4
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The thermonudlear fusions at the core of the sun release energy in the form high-frequency electromagnetic rhdiati.on. The theory which Furrently is
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F&o 11-l: The sun. 3
ccebted states tt-rat electromagnetic radiation can be represented as either a combinak, of rapi y alternating electric and magnetic fields (or waves) or r
energy particles calle photons. This definitioh of radiation is difficult to under-stand and visualize, But.~t& theory behind i-t ?Itcrws usto.dexribP and
predict how radiation,will hct. Radiant energy is produced at the solar core at ” temperatures estimated between 18,000,000” to 25,000,OOO” Fahrenheit
UO,OOO,OOO” ,to 14,000,000” Cqlsius). The average temperature at the surface b o
Of the sun is only Io,ooo”F~(~,~~Q”C). D ,
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The energy travelingthrough space is made up of radiation.in different wave: .r . ” lengths. Electromagnetic radiation is classified according to its wavelength- jz.
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the- more energetic the radiation, the shorter its wavelength. Radiation is , y 3.3 emitteti from the surface of the sun in all ~avelengths.+fromlmg,wa~velength --+~ + T-
radio,.waves to very sport X rays,and gamma rays. I --... .
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Although the sun radiates energy in many kavelengths, it radiates proportionally mdre energy in certaio wzilvelengths.
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At an average temperature of 10,OOO°F, the sun radiates most of. its ene& at
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very hrgh ~~eq~~~c~e~,,~sho~,w~v~engths), Visible .l.i.ght ma.kes up 46% of the _, total energy emitted from ?he sun, Visible,light, or the wavelength to whi&h i.j & the human eye is sensitive, extends from 0.35 <to 0.75 microns (the unft used I_ to m-easure wavelength is the micron or micrometer which is equal to a 1 millionth 4)a meter or .~0~04 of an inch). It is m-ade up of allIthe familiar $,, I~colors from the shorter wavebngth violet (&35microns) to blue, green:yellow, orange,&td the longer wavelength red (0.75 m.icrons). Forty-nine percent of the, radiatibnemittedfromthelsun is in the infrared (below red) band.,Infrared - b
r,adiation, which tie experience as heat, is radiation at wavelengths longer than , the red end of the visible spectrum (greater3han 0.75 microns). The remaining portion of the suns radiati.on is emitb ,d in: the ultra-violet band at wavelengths sbrter)than the violet. end of the visi& spectrum,.(smaller than 0.35 microns). All etectromagnetic -radiation I,eavin$ the sun travels through space at a uniform rate, in the form of diverging rays, traveling at the speed of light which is 786,280 miles a second 1(3oo,000 kilometersa second). The earth a small. f body compared to the,, sun, intercepts such -a-small p&t of the svns radiant output that thecsuns ia@ are assumed to be a parallel beam. At a dGtanee of- . 93 million miles from the.sun, the earth intercepts approximately 2 billionths of the suns:radiant output or the eqd$&nt of about35,000, times the total
energy used by all people. in one year. _.
?
I I ,i *
The Solar Constant, -v&ch defines the, amdunt of rpdiatkm or heat energy
@
reachipg theoutside of the earths atmosphere, is 429.2 Btus.per square fqot . . pqr hour (1.94 calories. per square centjmeter per hour);= In otherwords,“if we located a-square foot of material just butside the ,karths atmosphere and perpendicular to. the GZis r~yys, itwou,[d intercept 429.2, Btu”s of energy, each hour. There aie slight variations in the? numerical value of the Solar Constant
--L
bee--the earths orbit around the sun is almost perfectly circular, within this orbit the sun is slightly off center. This difference is important to
,.>
scientists doing, detailed calculations out in /space, Ibut on the earths surface the variation isso*slight it has little.effect onthe solar heating of buildings. .
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The Passive Solar Energy Book JC
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,J the toij; of the atmdsphere (dottedland at the earih,;s surfrice.
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.,. .I. Of all thq solar radiation intercepted .by t&.ear+ (including theatm&&&re),
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-“from an object is,called the albecJo of the object. The GIbedo of th; earth taken as a whole is 35 10 40%. Most ,of this energy isreflected back Cnto space fro; clotids and atmospheric dust, but some reflection bccurs at the surfa~ce of. the earth from surfaces such as water, snow and sand. ._ \.,
._
Part bf the remaining portion of ,sdar radiation, while passing thiough*the . earths atmosph f re, is scattered in all directiooS as it interacts~wit~--ai;.rnole
1 cuks and dust -partijcles. As a result, some of this scattered or “diffused” radiatiQn comes to eaith from all parts of .the skyd.pme. Scattered radiation a primarily in~the blue porfion of the visible spectrum, is re;ponsible for the blu2 c.olor of the clear sky>
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Fig. 11-2:. WIhat happens.to solar radiation intercepted by the
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.. : While #&ds and dust,scatfei and reflect,Ytipproximately,a third of the incoming
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.. energy, the .watet vapor, carbon diqxide and ozone in the atinosphere absorb
. ” an&her IO_to ?IS%. In the upper atamosphere, ozone removes.yi,rtuaIly all the * high7Cequency ultra-violet rad$ation reaching the earths surface. This is
.
. ,/a y
_/ eisential since ultra-violet radiatlori. can. cause skin burn and eye damage and ,
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0 .~ it can bq letbal even in moderate d9ses. yater vapor and carbon dioxi”de in
.th”e lower atmosphere .absorb portions of the radiation, primarily in th$
,_ . ,infrared band. 2 .
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r. Besides the composition of the atmosphere,- the most iTp&tant fa&or in , determining the &ng+,, of solar rac&tion reaching the ea@s surface- is the
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. .l&ngth of atmosphere jhe-radiation must pass through. Durir)g, the day when
” the sun is directly dverhead., radiation travels through the least amount-pf
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tmosphere en route to the earths surface. ,As the sun moves Ftoser to the orizon (sunset), the path of th,e- radiation through the atmo$here lengthens.. he more atmosphere or air mass that ra$ation must pass throughl;/the less its energy content will be due-to the in&eased, absorption,and scattering of the /radi&i.on. At sunset the,radiation content of the solar beam is sufficiently low /to enable us to glance d,irectly at t-he sun. As th.&“;!height above sea level I increases, the amount of atmosphere that solar radiation must pass through /.decreases. Therefdre, the energy coptent of sblar radiation at high altitude
locations will be somewhat higher. . _ *:
i : .
( Because of the eatihs tilt and iotation, the, length!of atmosphere that solar - radiation passes throkgh will vary with the time of day and month of the year. . The path of the earth around the sun is a sl-ight ellipse, barely distinguishable I once a day on an axis that” axis,is tilted23Vz o (exactly ! around the sun. n
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toperpendicular to t (1 HFrqisphere receiveq fewer hour: of, sunshine,
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The angle the bun,% rays rqake witW a surface wili determiye how- much ehergy ttiat surface receives. Since solar radiation comes to earth i,,nessentially parallel
I rays, a surface that is perpend(cular to those rays will intercept the greategt amount of energy.As the suns rays mosF,away from being perpendicular, the energy intercepted by a surface wiU decrease. t
1. y---- Perhqps the best way t.0 imagine this pi; tq think of- the parallel rays - :, -==a%<-.> of the Sun as a handful ,of pencils held with thebr points touching a *a
_-- c~--_Y...-._-_“!abIetop. 7hd dots made by the points represent unifs of energy. When the pencils are held perpendicular toqthe tabletop, thedots are . ”
p
2 . 9 as compactly arrariged. as possible: enefgy density-: per -sqciare inch is
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4 a However, a surface can be facing as muchas 25” away.from perpendicula; to
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the sun and still intercept over 90% of the direct radiation. The angle that the rays of the sun make with a line perpendicular to a surface (also called the angle of incidence) will determine the percentage of direct sunshine
I
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. * intercepted by that surface. Table II-1 lists the percentage .of sunshine inter- ,_
., cepted- by .a surface for different incident dngles.
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r > , , 5 The totql amount d energy interce!pted by a s&-face &mists of not only direct radiation, butalso diffuse and reflected &djation. The total amount of radiant energy intercepted b,y a surface is greater than that from the direct rays alone. Diffuse radiation, 0~ the energy scattered by ttie atmosphere and redirected to the earths surface, can be as-much as 50% of the total when the sun is, at a lo& altitude: and ltj0"/0 on a completely cloudy day, However, on clear days /diffuse radiation comprises. only a small fraction of the total. The intensity of radiation reaching a surface from a reflective material. depends upon the quality of that materials surfa% finish and the angle of inci.$&-rce between the solar beam and the ,reflector. The larger the angle of incidence, the more
the radiation will be ref!ected-. S - : -.
,1. ,;
It js important f” realize that. the collection of solar radiation is deperident on the area of -the col,lecfing surfac.es. The energy content of solar radiation is A fixed. by the output of the ,sun. To collects certainamount of energy from thle sun, an area large/enough, to collect it is necessary.., This applies to all solarheaiing systems from south-facing glass in a.reside%ce to collectors”that focus
__b the sun!s energy,. The area intercepting the suns rays will determine -the
.
:.Y- p . . R * maximum amount of radiant energy that cat-r be collected. ..j
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a* c o a. As solar radiption strikes the surface of a material, three things can happen. .I
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,I =. [l)epending on the gurface,&&re of the matdrial, reflected radiation w-ill either C *
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I 1 be scattered (diffused) or reflected in a ptedictable~~~anne;:iRoughi~~xtured ..
.-_
surfaces will scatter radiatio,n,.while,surfaces such as aGSirrc%$ highly polished i ,aluminu.m wili reflectiight in p.red;ctdble parallel rays. For example: a masonry, . wall, because,ofthe irregularities of.its surface, vyill not reflect $adiafion ina I \ predictable ,manner. It will &attersr diffuse the radiation. in all*direct-ions. In
-. .. . , >! I ”
.- -m-contrast, a very smo,$-r z$dhighI~$olished surface will produte a predictable
>. -,,..
- . -- _~. reflection. (!n this manner, lig&@nd other radiant energy source3 can 64 * 1
controlled.)Yhe at-&e &which the:rays strike a .refle&ng surfacgW$ill *be equal 1 ::* : , tothe angle of tt$. reXJc%d rays, q-5 to ;put it anothec way, the angle ,of
SC :
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.I h&t. v& per&w as color is the resultof~ v&X&-radiattin in certain: wave
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. . .. , SPECULAR ,bREFLECTION
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I ”. . .n- k material that tra&&its most of the visible radiatidn that Strikes it is TRANS
PARENT. The direct passage of sunlight through. a material is best illustrated r *I_:~by.ordinasy window glass. Most of the solar. radiation passes through glass wjth
.i v&r-y little distortion. i2.
During a clear ,win.ter, day, for examtile, a vertical single .< pla)eglass window transmits about 85% of the solar ene&y-strikinh its surface,
.
doutile glass about 75%. Other materialscan be equaily-t.ransmis;ive but will deflect or scatter the radiation that passes. through .it. We refer to, these materials a5 being TRANSLUCENT.. , .
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. . Fig. 11-8: Color per&p&ion.
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Solar rqdiation $bsorbed”by a .s&stdnce ii conver@ itSto iherr$ svqy.cfr heat. Solar r8di;itibn ,absoybed by the moleculesat t,he surface of a material will accelerate their movement. As the vibrational inovempnt of mdkules.
i in a mateliol iryreases, tha heat conteqt of !he rrfbte?Zi.iqi&$y~. %:.i .
i: .
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L .- . As hei1 i+zikdleda to i solid “rkatekat,*ik temperature will r&k Ther~fork,~tem~ .
ljera~re~is4\F$ mekure of&e intensity bf heat, which is defi(;ed In tey oFt,he
. a .
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\..A ,_ First, as solar radiation is absorbed by a/material, the at&orbed
..\....
-...L ~ redistributd itself within the mateiial as ,it is passed or COrupuCTED between P
: ‘“’ I mdlecu,les. Conduct$n: @the process ,in &ich heat ene\gy is transferred
\
:.a , _ betweT molkcu~eswjthin a substance, orbktween two substances in physical
_.__ 1 contact-,, by-dil_ectmolecular interaction. The &qmer molecules bump info and 1 \ I rjass some,of the+-vibrat&naI energy to adjacentrnolecules. The dilection of
heat flow is always frot?warm.to $ool.As themolecules at the surface of a I material are heated by solar radiation, they $ass this energy to cooler adjacent++ . L-molecules dispersing the heat through the rr&$ial- so th&dt. takes on a more
--, -tt- wdh-e rate of h&t flow or the thermal co&c@CtjVjt~ (k).of-a
*
,_X-- , subst$nce is dep@ndent on the capability of its moleculesto sendh,and3receive
. .,., . heat. Forexam$$q,-metal, dill feel colder,to the touch than wood c&the ,.same
. low temperatur$ This is due to the fact that metal/has a higher con?lu&ivi~ i ._ hnd it will absorb heattnd pass it from its surface to its .A than wood. The more heat conducted from the hand,
,. In general, because gases are poor conductors,
“-:.--- ockets are usually poor conductors.,A goo,d example of this is building
,- ,
.$ - * insulation.which cgntains- thousandsqf tiny air poc.ket:s.
:. 8
k--__- . ..
.:7. --L Second, H hate!ial will Yransfer h,pat &&gy from its kfaceto the moiecules 0
--- ._
: of Gmt$!_u_ig-?-.by CONVECTION. f;onvection is -defined.: as 0) the
“: , .
. . L-transfer of heat betweer&urface. and a moving fluid, or (2) the transfer of
. hea,! by: the movement of the molecules from onepo&t-in a fluid to “another.
.-....I.. __
..\a ! . ,.;l-n-canv~ctiop pro&seS, heat again always moves from warm%-c&LA&e - o
: .,, ;... .,
,.I. ;cool*moleculesof a”?luid such.as wate-ror air come into physical contact with a
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yarm surface,,sdme of thevrbrationaf energy at the surface &f the material is. :
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The P$ssive Solar Energy Book .
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* ,~ if th? fluid .is pumped~,or blown across-a surface, the rate of topve&e heat . tra&er will increase. AS a cool fluid comes in coittict with a warm surface,
- . t.~~f~~~.-i~~~~~S~nce~ the rate of h __ ..- ------
\ eat flow fron43e surface EZFiFfid. t increkes as bhe temperaturb difference between t@~ sub&nces increases, the 4
faste<.:the! wcmed fluid moletiules are removed frc$i tt$.surface tnd replaced
.I -.- l by cooler molecules, .qke ofaster twill be the rate qf heat traiisfkr.-For example, *
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. 1i when ai:i.is bagwn against the surface of ahot spoonful of liquid, it cools faster. r
: . The air molecules that have been warmed at the suriace of the liquid are blown away,j&d replaced by cooler ai”rimolecuIes which are,capa,ble of absorbing . +
2 more heat. This protess is.called FORCED CbNVECTlON. L:
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I, i/ 1 Fig. 11-12: Cooling by faced convection. ! .*
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. 4% And third, all materials RADIATE en ( stantly radiating therm;1 energy j-n.. II ,dlrec%ns bkcause of the continual
1
rgy all the tim:. All. m?terials are con
vibrational mavement of~mole$& (r+easured as temperature) at their surface.
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ig contrast to solar radiation, which corisists of shortwave radiation emitted
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at.very high temperatures, thermal radiation experienced as ,heat donsists of longwave infrared radiation emitted at a much lower temperature. ,; ! ” D ,I:
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L 9:
As the fice dies dowrrayd the flame an,d coals becorrie more@red and I give off less light an htly-less heat . . . after, awhile .the flame disappears, the coals ome dull red in a,ppearance, then a darker I red, and finally they no more? Light is no longer emitted from
the war,m coals, but h,eat contiriues to b& g.jven a&. Th6 warmth ,
I --- 1of the. coals-;is felt for- hours as radiated heat or infrared radiation, Ijut jris not seen as light. $6
-__- . .._ _ , : I
. * John Mather*
I, *
-= 4 :
energy a material radiates debends on the temperature .L1
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,- !I P The output of thermal radiation from a surface not only varies Gth surface tekperature,.bAt also with the quality or EMkSlVTTY of the surface. In general,
z
.+ *John R.Pjather, Climatology: Funda6JentaisandzA&lications. i .
23
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most materials are good emitters of “thermal radiation”, that is, they radiate. _
. thermal energy easil). -ihe emitGnce.(E) pf a material is afiindicator of that . materials abilit~,~~ give off thermal.radiation. Mos,t building ,ma@rials,. fgr - ,I
example, haye ermissivities of 0.9 which means that they radiate? 90% of thei thkrmal. energy theoretically possible at a givbn temperatclie: Normally, highly ,.: ;,polished-surfaces, slach as shiny,metals, arepoor emitters of t ,mal;,r8diation.
T
*b- This me&s they radiate very Iittl,e,heat at a given te&perature: \ I ,,o
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- NoI all materials,-howekr~~ -bbsOr& tbermai radiition; “some w~ill jreflect it .. reflect thermal, radiation will the surjace rather th n on jts i_s a good indic,$ion of the ability uo P
ref ect solar :! the ability to reflect the-rmal radiat!o,n. Mdst
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01 color, act as a “black bc@y,” * 4bsorbihg p B
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1; general, &&higl$ p&shed oi shiny Sirfaces, such as, altimqpuk foil, * reflect large amoknts of .ahe thermal iadiatiqn t-hey intercept. The/ designers
of .air@~n& tak6 advantage bf this principle bj/ provid,ihg the unqersides of : airplarjes with, a polished metal finish: so tha,t ihermal -energy or heat radiated
_. ..!
1 _ Jrsrn ti hot.asph$t rqnway will be,refl@ted, this keeping the interjors of th: pldnestCcoqler w,hen phrked at a terminal. - ,, 3
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., _0,,..4. .IThe amount bf thermal radiatibn/A shriace intercepts depends on th% angle the
radi&ion mak& with that surfi&. This. is- the-same $priiicib e that. applies to
1
0 ; ..I . polar r,adiation. Two surfaces that lare+ar&lel ts and facing each other will .
_~
i .-- ... --:c--..-----exchZije. a maximum Gnouht of theC?iKGdradiation, while suriaces facing each
, .. t:
\ 5, er.at an angle wil-I exchangc”lesG If both. bddies have the Sameatjsorptivity,
” e result of this ener& excharige is anet radiant heat trahsfer frpni the warm
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.5 * Glass, which allows virtually all the visibl pakthrough, will absorb most of the I ¶ rddiation it. intercepts. This collecting &lar Gnergy,~.,.Qnce
- -_-
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absorbed by matejials in a space, thermal energy reradiated by these mat.erials will noI pass back ourt through the glass.
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!
This process of trapping heat is commonly known as the “greenhouse effect.” A good example of the reslllt of this etiect IS the heat that bbilds ilp in an ;lutomobile that has been sitting in the sun for a few hours. Other materials, s,uch as some plastic glazing materials that adniit a high percentage of solar radiation, will allow as much as 4O%*oi the thermal rhcliation they intercept
to pass through. In this-aspect, these maderials are slj,$?tly tess desirable for
.
:- ./ - usp in solar heatin,g. 3
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Fig. 11-13: Greenhouse effect..
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-.” .; Heat Storage * ” - n
,
All solar-heating systems .hre based on storing solar energy within. a tiiaterial for a period of tinie. This is accomp1ishe.d by hea4ng a material which will store the tieat until it is need?d. Coojing systems; on the other hand, do exactly the opposite. A substance ,is coole.d, or heat is taken out, and kept
*This does nbt imply that radiation loss.esfro& 2 space are eliminated. Although glassdoes iot
tr_aq,Smtithermal: radiation, it absorbs this energy and then reradiates and conducts it to the
/ 7 [ outside, but at the tower temperature of the glasssurfa&. /
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_,&- * thatwayso it caiabsorb he& at adater titie, Heating and cooling a space is
+entially..based OF the same cancept. Very simply, the i$ea is to keqp a 1 q 1. ” ( “te?%perature difference between the substance and the surrounding tempera
tu re. 0. ..
. . 9
a. * Eqr this reason, when solar heating a building, it is impoja
building of a substance that can store enough sol& energy (2
to con+?!. the heat) ic the day-<; d p
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?, 1time t+ ke.ep& building &arm during a Cold winter night. The capaci,ty of a
.-
.,/ matCat to 9tare thkrmal energy is &lled=its specific heat, which is defined as L
c
l A
i the amwn[ Of heaf (measured in BtuS) &-te pound of a substance can hold 1 1 when its temperature is%raised one degree Fahrenheit. In the construction
j.’”. &trades, however, the-quantity of a su,bstanceis trequently given in cubic feet .
: &-*, a i. rather than potiiids. The&fore, the volemetric heat:capa@ty of orie Cubic foot
, \
of,a substan& is simply its -specific heat multiplied by its density (numberof
/, peunds per cubicfoot). *
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:., -; *i \ Table lb-2 lists boih the specific heat and heat capacities of various substances.
0 :.
.-, .: ,. I\ldtice” thy! alth.ough brickand conctete have~+oughly half the Specific heat of
expanded ,polyurethane, their
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,., they can store substtintially
sity is much greater, so per unit .volumg
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Density Hbat Capacity . D t _, (lb&u ft) (Btuku ft-“F)
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,,.2 . storage medium a $&stance must ,&o have a relatively t
storage medium a high .conduc&j~.
(._ Y“ 1 ., : ..” WWooGGdd aanndd.. bbrriicckk..hhaavv$$&&oo;;tt tthhee ssaammee hheeaatt ssttoorraaggee ccaappaacciittyy;; however, wood”is
/“. t uussuuaa!!ll,,yy nnoott uusseedd ff&&rr hheeaatt ssttoorraaggee.. TThhee rreeaassoorrrriiss ssiimmppllyy tthhaatt wwoooodd ddooeess nnoott . f .a ccoonndduucctt hheeaatt ,,aa$$ wweellll aass bbrriicckk aanndd.. iiss,, tthheerreeffoorree,, ?ot capdhle of .transferring
ssqqffaacckk ttoo iittssiiGGtteerrii,,oorr ffoorr ssttoorraaggee.. ”” / .
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._ 271 -;
Passive SdzW Systems. i
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Approadjes to Solar hating _
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I; There ark basically two distinct approaches to the solar heating of buildings: %
LI active and passive. a
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.. In &neral,.active systems employ hardware and mechanical equipment to
-- n “collect atid transport heat. Flat plate or focusing cdliectors (usually mountedion
1 the roof of a buil,ding) and a separate heat storage unit (rock bin, w.aier,.tank or , _:(* combination of the two) are often the major.elements ofpthe system. Water OT .“
.1 air, pumped through the coHector, absorbs heat and transports it to the storage
unit. This heat is then supblied from the storage unit to the spaces in a bujlding ,
by a completely mechanical distribution system. 1, F
,
Passive systems, on theother hand, collect and transport heat by nonmechan,
. * i&l means. The most,common definition of a passive solar-heating and coolisng
. system is that.it is a system in which the thermal energy flows in the system are 7 by natural means, such as radiation, conduction and natural convection.. In 17
. essence, the building structure orsome element of it is the system. There are . no separate collectors, storage units or mechanical elements. The most striking difference between the systems is that the passive system operates on the r energy av%ilable in its immediate environment and the active system imports -e--- - -: energy, such as electricity, to pow-t&-&s and pumps which make the .
2 system work:
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F There are twb basjc elements in every passive solar-heating system,: south
“.; facing glass (or transparent plastic) for solar collection, and. therma! mass for
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Passive Solar Systems ?
heat ab&rptioq, storage and Odistributi?d. Popular belief has it that iiassive
i, .
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building. must iriC6Lporate large quanlX& ?if?hYG? two elem”Gif~~.~-6r~~studies
-1 ;how, hotiever, that while there must be some thermal mass and glazing in
n . ,?.-.,
_
:
each space,when prope”ily designed they are not necessirily excessive. This will become evident Gh&Y you read the sizcing procedures given in chapter, 4,
.(pes,ign Patterns.” _ a
I.
To establish a framework for understanding passive systems, three concepts will be “defined: DIRECT CA\N, INDIRECT GAIN and ISOLATED GAIN. Each explaini th& relationship between the su?, heat storage and living space. Within each of these categoric? we are able to identify various systems, ._ .
birect. Gain _ _ : ,
The firsi and simplest approach to passive solar heatirig is th@ conc”ept bf Direct Gain. Simply defin.ed, the actual living space isdifectty Heated by sunlight. When the space is used as a solar collector, it must also cqntain a method for absorbing and..storing enough daytime, heat for cold *winter nights. In other words, with the direct gain approach *the space be&mes a live-bn solar dollector, heat storage and distribution system all in one. One important note, Direct Gain Systems arealways working. This means they collect and use every bit of energy that passes through the glazing-direct or diffuse.
@sj
Because of this, th& notonly wart well in sunpy climates, but also in Floudy climates with great ,amourjts of d&use solar &nergy, ti,here active .systems can
hardly pqrform as effectively. ._-._ - -: -
In this approach, there is an expanse of south-facing glass and enough. thermal mass, strategically located in a space, for beat absorption and storage. Southfacing glass (the,coIIec,,tor) is exposed to the m&in& amount of solar energy i! winter, and minimum amount in summer. For this reason; it is the Pdeal location for admitting direct sunlight into-a ,pace: Since a portion of this solar heat gain (sunlight) must be stored in the s$ace for, use at night (and pos$bly during periods of cloudy weather), .tRe floor and/or wal.ls must be.
cpnstructed of materials capable @fstoring heat. 1
-.
t ~
7.
Today; the tw6 most.common materials used for heat storageTare masonry and water. Masonry theimal storige materials cnclude concrete, currdrete block, brick, stone .,and adobe, either individually or in various combinations. Typicallyg~at least one-half to two-thirds of:the-total surface area in a space is construFt@d of thick-masonry. This imb!je$, that the interior be IargeLy cdn
3.
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df e,xposed mass the other hand, ~A,,
door-and sp$ce tempe,t+t;res begin to .drop, this-heat is returned to the space. . u ” _
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i&rs%tl~~ one wall of a space. Thelwater wall- is located in < . the Space in such a way that direct sunlight strjkes jtfor most of the day. ~ M&terial$.commo$y used to construct- thg. wall are plastic,.or metal containers. R During the daytim:e, the mass is charged with heat so that at night when out- .
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\,..” ~l~nho~ summer climateswithcool nighttime t&nperatures,*the mass can also
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.. , f . act to keep a building @cool :during the day. First, because of its time-lag&a
?l* properties, massive walls keep heat from reaching..the interior of the building 0
.
_ , -.- until the evening when outdooretemeeratures are cooler. Second; outdoor air
, .I
7 circulated, through tlie buildingTat night cools the interior mass so it absorbs
c heat and provides cool i.n,terior-surfaces du$ing the da.y.
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one-of the earlikst and largest contemporary examples of a Direct Gain System n is thI! St. Qorg.e.sXounty Secondary School in Wallasey, England, near Liver.*Ap~ol. The building, d.esigned by-architect Emslie 2 Morgan, was completed in
I .
;P.,, 1962. .Public reaction to the building at that time was that the architect flad
somehow harnessed. a new physical principle. It was not until the late 1960s that extensive research and testing of the building was begun. @
\ .- p ,.
<\
. 1, 0 1 - .
x“Xj The -build$tg, constructed of masonry, hasEla transparent qouth wall for 4 = m@mum solar.gain in winter. Concrete, 7 to 10 inches in thickness, forms the /I = roof and floors, with the,north walj and interior partitions u-?ade of %in.ch
br;jck. Th;s masonryis the principal means of heat storage in the building.,..lt is ,I ,
“, exposed to the0 interior and insulapd frqm theV+terior with 5 inches of
/
1, , expanded polystyrene:.QBy contrast, the eni~rk south wal! of the building is
,_ esserrtially transpayent. Tti sheets of gfass, the outside layer Clear ,ahd the insid,:e translucent, make. up the roughly 230-by-27-foot wall. The translucent _layerrefracts~d(rect sunlight diffusing it over the surface area of interior mass, somewbat..uniformly. ,r c> - 0
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. The ~masok$ krior stoie$. heit and acts to p&venk large fluctuations j,of
itidoor temperatures over the day. Becorded classroom flu)ctuations are on
I* the average Gnly 7“F throughout the year (cl&r-day ftuctuations are ;omewt+at
;\;, higtier). Thticlearly illdstrates the effect masonry has in keeping indoor tem
peratures rel$tively stable. 0 b
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,~ 81
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:1..:.....l;i,~. .: : The south wall &nits enou& S
.buildings heating needs during rgytosupply, roughly 5O?b hf he .i-- :
. \ ?.e ., * climate. Wallasey is located on, the wes
r; kd all this i? a less-than-ideal . f England at 53”NL. Its outdoor o - r& temperatures are moderated by the f Stream, but the current also *
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:= . , .brings,with it much fog and cloudy weather. te; at best thought to be .
,
.. “/
” ,I margina~l&suited;for solar energy application,
.Bk\ -the sun with the remaining 50% supplled by lig
utlding is heated5d% by
students. The conven- i b.. .
(\
.. \ tional heatjng system, originally installed, was Fever and su bsequentjy @ ,
removed. . B .c
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Table *!ll-1 principal Heai Sources a t* 1
Percentage of Heating Supplied c_I
B----- _I_____,.._-~~j--v.- LE.--,-i ,-___ cGiIijjh esttmateT-- _~_._ -. -_
e
4$. . Sburce (196&69)
m .,
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.! Soiir energy - 1 50 - , Incandescent lights , 34
cl l.JOOi~n classroom I 2,400 in art .rooin
+ S&dents: 15 tq35”students ” 16 r< . 0 ! per c!ass L
SOURCE: ]osebh E. Perry, Jr., <The Wallasey Schbol,” Passive Solar Heating a.nd Coo[ing Con
*, ference and Workshop Proqedings (Springfield, Va.: National Technical Inf rrnation
c:
. Service, 1976). o s6I . \!r u
* I) “is mq
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fJ” bflck wall faded with pfartor,
- 5” tnrulation
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,i-..Q Fig. 111-2: Sunlight iidiff+ed over a large.i&ace area of mason&. 0 .
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-passive Solar S&ems ._
Photo III-I: South and north face of St. Georges County Secondary School. .
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. restaurant, located in. Albuqyerque, New Mexico. The restaurant employs al
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and flnishecl \Gith pipster, and <I 5latcl floor th;lt I\ \(I1 111<I nlortdr I)(~(1 o\(r ,I 6-inch concrete. slab. E>scntl,lllX,, thls Dlrryt (I,lln SL~ivn1 IU~C rIon\ in th(> ~rll( way as the ~allssey School ~&fit1 ,\~~.~~~n~~ll~;in~ rvqtCjurClnt ,”
Figure III-4 illustrates that even during periods of 0 F weather t,he buildipg
maintained temperatures which were 56 F above outdoor tcmpeA$ures. It I\
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Many applications of interior water walls employ a combination of materials. For example, the Karen,Terry house in Santa Fe, New Mexicq, is a Direct Gain System with both inter:& masonry and wat.er walls. The house, eloggated dong the north-south axis, follows the contour of the south-sloping terrain. Tl-ie interior, separated into three IevCls by ietalnlng ~~11s containing ivatrr, IS constructed mainly of brick, adoh: and concrctc block. Th consist of Twenty-eight 55-gallon drums filled with water and p
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additive, and covered with mud plaster. Sunlight enters the space through ,t south-facing clerestories tilted at a 45 @ angle from horizontal. These Aerestories are plated in such a way that sunlight, at mldday rn lvlnter, strikes the water walls for maximum heat absorption .
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In the winier of Ib75-76, the auxiliary heating supply for this hwse consisted, of one-half &ord o(,wood, burned ih a small adobe iireplace. Wi-tt/lout applying insulating “shutters $ver thP dazing ,at night, the house t$aintai~ed tempera
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Thr.ou&h openings or vet?tS loc;tted;at the top of the tvall, warm $ir rising in tlT&.%? aii.$pac&&nters the room while sim&aneo;sIy drawing cool room air through
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.Re,sulis from stbdies shoi that apptoximately 70% of this buildings yearly heating, needs are supblied by solar energy. .Rcscarch“un(lcr.taken since 1974 indicates [hat ,Ibs~t 36% of the energy ir;lciiclcnt on the glass I\ *piiccliw in heating the building int winter. In this spn&, thci systtlfiis ctiiiclc~nq I\ co&~parable to a good active solar heating sys\cm.
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DEC. 27 DEC. 28 DE& 99 I
INDOOR AND OUTDOOR TEMPERATURES- I
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i avkdage about63”F, atid upstArs.72” and 62”F, with an-estimated average of - * ** ”
; _ 6;I”q. The up.stairs experienced”*slightly higher temperatures die to the A- migqatidh of warmed air through the open stairwell cotinecting the levels; :.L
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* ;ColYrales,“$Je\?i Mexiio;-T)eXhouse *s a series of ten so.nnected. doies which. i 1 enclose 2,000 jquare feet,.,&, floor area. The domes actually employ a com- . j
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Some of the south-facing walls are vertical and contain water-filled 5%gallon , metal drums, stacked horizontally in a metal support frame.--The. walls
440 square feet in area, are single-glazed and fitted with eiteri alf S These panels: a,re hinged t.o the wall at th$ bottom SO .“that b their “open &&ition, they fu?($pn.a!, reflectors, incre.asing i through tde sguth wall. Atgnight, hoisted into a-vertical wall, they insulate l&e wall*~o keep the heat cdlec&d by.
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space. control ove;the heat output of&e systemhas been :
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temperature.will,drop only I$to 3°F each day. Auxiliary heating, provided by I - three wood-burning stoves, consumes “a total &of approximately one cord of -
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An attachGd.greenhotise is esskntially a combination @f Direct and Indirect + -Cain Systems. In this cas&a gre,enhouse (or sun-rpom) is*constructed. onto the j
south side of a building \Nith a mass wall separafing the greenhouse from the building. Since it is directly heated by sunlight, the greenhouse functions as as y
Direct CainSystem. However; the s,oace adjacent to the greenhouse receives
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L* $@$ally; sunlight is,absorbed by the back wall in the gr&nhouse, convertvd
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sense, the attach@ greenhouse is simply .kn expanded Thermal Storage4 Wall b “-L;F:
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There are many possible, variations that allow-for design flexibility in attached s greenhouse application. For example, active systems such as fans can be used
fo in~ure+t?t a greater percentage $ heat is extracted from the greenhouse to c, heat adjofning spaces&(see fig. IV-16$1X; In this case, warm air ducted from the,
greenhouse is stored in a rock bed usually located under the floor of the spaces being heated. Heat is then delivered to the space passively by radiation and cohvection~froz,m the,floors surface.
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In a Roof Pond System, thethermal masj: is locaied on the r&of of the building. In this case water ponds, enslpsed i; thin plastic bags, are supported by a roof (usually a metal deck) that,also serves as the ceiling of the room below. The system is equally suited to both heating tn winter and cooling in summer.
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In w&&r, the po~~qls are exposedto &nlight during the day and then-covered with insulating”paiiels at night.:-!$eqt collected by the ponds ismostly radiited t I from-the ceiling directly tojheppace below. The con;ection of heat from thP _ .ceili.ng to iir i&he sp%ce plaisa relatively mi& role. ”
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-. 0 Ir&umme~t~e pa?el;posiiions are reversed, icovering the ponds d.uiing the da) !G protect them from the sun and heat ind removing thev at night to allow Ahe ponds. to bee-cooled by n;lturdl~ con+vection and by radiation to the ~901. night sky. After being cooled at night, the ponds ar% then read9 to absorb heat
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A third app!oach to passive solar heating is the c&cept of Isolated Gain. 1 ~ In principle, solar c4lection and thermal storage are isolated from the living . spaces. This relationship a,llows the system to ftiction independefitly of the . , !“y
building, with h&at drawn from,the system, only when needed. b<J*.:/,. ,
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The most common a&$cation of ihis cb$cept is >the natural cpnveciive loop,., ,.>T L 0 Th,e major cbmponeIi!s o? this system include a flat plaie colkctor and &eat
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i stor&$ tank. Ttio ty&es of h6at iransder and storage mediums are used: w!at&,r 3 .and air with rock storag-e.& the water or Air in a collector is heated by Isun
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tight, it rises and enters tile ;op of the storage tank, while simultanedusly. ”
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1 water heater. Alth6ugh there a* many variatsns of this system.“.moit/ are ! ,
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The earliest example using.arp Air loop Rock Storage System is the P
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used to d&ign and size these systems are similar to thos@..used formve P-&stet&-Ihe cerwetie-loop .will not be discussed further since it is outside
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. SMH~y claims havd be& mz&de for ihe $dvantages of pa$sive solar heating
-systems. These claims cprr be separated. into three categories: f
econbmic, “.
“..._ architectiiral,and covfart/health. It is Prnportant to realize that the extent to e
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which an.y of these claims is Galized depends on the-extent*0 which the actual * .dksign is successful in ach-ieving i,ts_goals.
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a * . Of great integst to&&e iAvolv4ir-i pasGves)istems is th4. possibility that the ( .
.system not only affords large savings .of energy fdr heating, blrt that it also can .
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_7-- ,- e-2, -tiog sf a b~ilc&jj. Sihce- the pirice of m aterials.varies greatly from &ace to
pIa& i:t is not possible to generhTize about\ this claiin. In iome situatibns, such .
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, the.ektra cost may be considerable. The s/ghifiicant econotiic advantages of-i, ,-I A
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Phdto 111-11: Busshelte;--simplicity of design operation and f 4 maintenance; north and south v ihv s.
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ll..- 0--m--environment i~9,wliich .&e ,bodv lose beat at a:kte equal to its production
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t* ne h&l (w fhi\;er bn the other. The a&rage
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~.&W&..ftinctiong. .Th& energy needed tocarry ot+#hese functidns is I 7x- . ag$pximately 80 Btus per hour: Sncethe h&&n body is-$sse?tially a heat
_. engit$e with a thermal efficiepcy of about 20%, it Vmust dissipate 460 ~~ttis~~@r~ ., ..m --.-:- hou: of-waste heat to%s sur.roundings. I .~
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- 1 and ra@i6tion. For sta$&rd conditions, an adult at rest with light clothing in ,, . 74”J %ir teyperature and 50% relative humidity .has Anrevaporation of 1
7 perspiration froin the skin of approximately 25% of the tpt;?l body heat ,loss or, 100 Btu/hr. The loss of heat by convkction to the surrounding air constitutes bI. . anot-her 25% oral00 Btu/hi, The remaining 50% or 200 Btu/hr is by radiation
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:: . &-eater effect or;l. body heat loss than a one degree change in air temperature.
.I. ,;..I s Ot, for thk .sa&7e f4.eling of cowfort (?O”F), for each I “F increas.e in mrt the e.
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i a> space iir temperature can ge Table Ill-2 giv”e_st& yaltes of mrt (
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‘” Notice t.hat a mrt of 15°F
to produce a feeling of 70°F. 8~~m
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This makes it difficu-lt to state con~lus~vety, In terms of hard facts, rhat t~ertaln interior conditions are more comfortJb.Ie than others.
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Within their omfort range, most people kill dccept the statemint that the lower the ai P temperature in a space, the greater the sensation of comfort and health. Many people feet coo-ter a~i is ntore invlgo:atIfig, iresher and less- stuiiy, and tha.t [heir ability to work (and think incrcClsc$ 1r1 a spaccl whercx they Ire warm but,t”neair temperature is tower than 71)“F!
- rl As has been previously noted, the iriside air temperature for comfort in a passively heated space is usually somewhat lower, and frequently substantially lower, than in a space heated by, conventional (convective) means. B. Another relatively intangible advantage of passive solar heating is the main: taining of a warmer floor. In cold ctimCItcs, convcclior~-l\/J:,o healing systems e, can lead lo unusually large itoor-to-ceiling temt)cralure p,r;l$icnls, with IOLV : floor temperature5 causirig thermal disConi(ort. In d pa5I;ivcty tbc~L\tNl <pqcc, however, the. surface tgmperalurc of the> floor I; usunIty found 10 be higher . _ _ ...._._than....a ,similar floor in a space with a convccrive hcaLlng sys~cru,.regardlrigs .<“-/
of whether the systen,\ is ;1 direct gain, thcr.niJt storage ~vatt or ~.ooi pond.
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By contrast, the, maior problem associated~ with passive systems is one of * 1 control. Since each system has a large heat storage capacity Lvhich is an integral
part of the buildings structure., its ability to respond quickly to changes is greatly impeded. Also, storing heat -requi.res a change in the temperature of a 0 matGriat, and sinke >torage n-iateriats are an Integral part 0i the living space, the space wilt atsd fluctuate in Lcmperature. ExcessivP gpacc Icmperaturc flvcluations can lead 1~; unsatisiaclory comiort concti\lons II,J~C! system js not
L properly dIesigned. . I
Fortunately, however, there? are relatively simple solutions to these problems.
s For residential applications, temperature control i;cludes operable .wihdows, shading devices and a back-up heating system. In large-&ale applications, fhe
, .solution to control lies in cmhoosing a back-up system that can respond effectively tb the users comfort requirements. There&ill always be, fluctuations of
i I indoor temperature but these ,,can be minimized by pro-petty >izing and
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All adts of.building,,tio matter how large or small, are based on ruks ,of themb. -Architects, contractors, mechanical engineers wld.-owner-builders design and .build ,buildings based on the rules of thumb they have dev&opGd through
years of their own or-other peoples experiences. For example, a rulerof thumb a to determine 6e depth of 2-in& root joists .is given as half the span of the ioists(feet) in inches; in other wor&. to span a 20-foot space one ,would need roughly 2-by-lO-?nch joists. Calculations are used to verify and modify these rules of thumb after the building has been designed.
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We call these rules of thumb “pattelns,“’ Each pattern tells us how to perform and combine specific.acts of building. We perceive these patterns in our mind. * They are the accumulation of our experiehces about the design and constructionof buildings. The qua!:ity of a building, whether it w.ocks well or not, will depend largely upon the+atterns we use to create it. ~,
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To be useful in a design process, rules of thumb must be specific, yet not overly. restrictive. For examplhif you are required to know the heat loss of .a . ” space hefore applying a rule\of thumb. to size south-facing glass areas, then ,the * - 0 rule of thtimlj is too specifiP9nd of little use since a building ,has not yet been * defined. If, on &e.other hand, therule of thumb recommends an approximate size of glass needed for each square foot of building floor a\r%a,then the glass -/ o . *~I I -----carr-be-~ncorp~~?ted.,~nto the-buildingls de&n. After cornpletIng a preli-binary
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. : This ch&ur co$ains twenty-seven patterns for the application of passive solar 4 .. energy systems to building, desjgn. ,The patterns are ordered in a rough, r *
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. sequence, from large-scale concerns -BUILDING LOCATION(l), BUILD.I~G :.
*. b . SHAPE AN~~~T)RIENTATlO~N(2)-to smaller ones-MOVABLE INSULATION . (23), REFLECTORS (24):fro.m applications with the most influence on a build- -\
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m --ings design to”on.es which de&with specific details of the heating system. .
e-- -- When-us.ed in this sequence, the patterns form?a step-,by-step process for the ._I -~-design of a passive solar heated bui1din.g. Each pa@etn contains a rule of
.,>* r thumb,, based :on-all the available information at this. time-for that particular
--d&t ofthe b,u.ih%ngs des,ign. ._ ” .,
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* . Each pattern is connected -to other pattems which relate. to it. Every.“pattern
“. , -is~.i.ndependent,iyet it needs other patterns to help make it more complete. I Larg&scale p$&erns set the context for th”e ones that follow, and each succeedI i.ng pattern lielps;refine the one that came before it. For example, a .window
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at nigh$is used wit,h the pattern, SOLAR WINDOWS(9)I 0
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,*Each pat)tern has the same format. First, most
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\. Yr for it. Then there is a statement of the problem. -After the problem statement is t.he recommendation+he solution to the problem+-w~hIch gives a specific !
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.-._.. . ( most recommendations is. a diagram describing the rule of thumb. Then, the
~ 1&.. p$te.rn Js >cross-referenced, to .the smaller. patterns that relate to it and help “’
aI, m$kd it more. cornpIe& And”finally; there. is theb information, which contain% p all the avail;abfe .data about the pattern and evidence for its validity.
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+ Together tbe p$tf(erns for& a coherent .pieture k?f .a step-by=step process for . is written in such
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read the information in each tpattern when a more
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Related Larger Scale Patterns--- patterns &hich ,help set the context for this pattern
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Piobleni Statement--dm$i bes I e of the problem
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The Recdmmendatiow--3. rule $f thumb that gives the physical relatidnships necessary ih solve the Ffroblem .
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-. Illustration-a visual repres,:ntation of the rule of thumb
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Rekafed Snfaller Scale PAtterns--patterns which embellish this-pattern, help implement it <and fill..in the dethijs i .
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. The Info~rnakiony~rovides all the available ipforqation about the- pattern, evidence for its validity and the range of diffkrl ent. ways the pattern can be applied to a building - .
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9. Solar Windows
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Fig. IV-I: Structure of a pattern.
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: .. ap,ply to Bach project. For example, the
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i (7), giv/ei cri<eriB. JO help you .ielect the most : D ur project. After maki.ng th.is choice, patterns
5 s Bre not relevant. Also, a pattern may n& r this casg, it is ..important: to und.erstaTd tb _.
?I. spirit of.thG.pattern and modify i\ so that it:makes sense for you. :
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And thi&l are the patterns” with &ec,ifi~ instructions to make the building more
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B 1 I. 23. MOVABLE lN$.ULATION 5;
y* 14. REFLECTORS I 9, .
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a”, . 26. INSULATlbN ON THE OLTSIDE..
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./ Remember that these patietis are e&lving and ,will change over time. Each 6attern represents a current recommendation of how to solve a particular
a.
> defined, new patterns will be
may evolve over time as ~
,
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This n)e@, that the patterns should not be taken too literally. Since>resear&, _ y -- ----
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into passive<systems is relatively new need Itof qu,estion and refine b,; the patterns oyer a period of time. There may be some instances where *YOU
ha,ve,.informat,ion $hich is ,more Baccurate or- relevant to YQIJ. particular situ-. ,0
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ation. You can.see:,then that the patterns are meant to 6”e flexibJe. They are
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that if you want to add new inforkktion to a pattern,
can do so $tho.ut losing the essence of it. : 3
must realize $at the Cxtent to which ant or ail of the
practice de,+n+ in. large ~measure pn the extent to
hich- tile d+grter succeeds. in ulderst&ding an$ applying the patterns. *
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The apo,unt of:arc taken.In placrng Clt)urltllng on J SI~C\vi;h respccl 10 open space and sun is perhaps the 5inglv na0s.t Important (ICilSIon you \v~ll n7;1kta
almtlt ,Jhc building. D
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/ Buildings blockedv froE exposure to the+ low winter sun bettveen the hours of
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:9:00 a.m. and 3:OO p.m: cannot make direct use of the sun3 energy for heating. - During Lhc wipler months, appirosrnist~~l~ ~10°~, oi :hc suns cnclrgy output occurs hctwrcn tliv Ilnurs oi 9.00 G.ni. 31~~13:W 1, m. <trn Iinic (WC chap 5 Ior dn ~~splC~nal~on0i sun Iini~~, for w,~n~~~l~~, ttl Ncb\v York CI~Y t-10 NL) on ~sclunrc I:ooL oi 5oulh-~dc1ng t;llr-i,lc(.l 011;I clcdr cldy 1111h~11m~nll7 0i UN (~rilh[lr, l,GlO UIut; out of d dally iol;ll 0i 7,724 Ktu”; 10~ 03% 0i Ihcl 101dl) ,II-( Iril(>r-i ceptccl bet~vvcen the hour-s 0i 3:OO a.m. anal 3:OO pm, Lir~l\vt~~!n Ih(: h0ur5 0i 9::30 c1.m. ;Intl 2:30 p.m. 1,272 13tlls (or ;-I”$~ 0i thy t0tdli JI-;I It2tcrccptd Any surrounding eletmvnts, such 25 I-,LIIIcII~I~~ 01 lall tiec~, that block 1hv sun
during 1hese limes Lvill severely limit they use oi solar en.ergy ds a heating l
source. ,, i /
Thie Recommenchtion
To.take ad.vantage of the sun in tlimates where heating is needed during Ihe winter, find the areas on the site that receive the most sun during the hours of makitium solar radiation&):00 a.m. to x:00 p.m. (sun time). Placing .the building in the northern po&tion of Jhis sunny area will (1) insure that-the, outdoor areas and gqrdens placed to the south. wil,l have adequate wir$!er sun and (2) help minimize the:possibility of shading the building in* ,the future by off-site developments.., d fr il
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T” --,-. Whkn.deciding OYJthe exact location for the *building within a sunny area give the building a rough shape--BUILDING SI--!APE AND ORIENTAfl(SN(2j~
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and place the etitrance of the building so that .it,receives the greatest protec-
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To take advantage of-the winte,r sun,.first the sunny places on t{leGsite n&d to ” / ,, be Located. To do this, explore.the site and determine which.places have an *. “. I open vie.vv to the sou;th ith
sw,n chart (chap., 5) is
minimum blockage of-the low winter sun. The useful in visualizing site ob,,structions that,block . j \ d”irect tin from reachi
. * sun chart for your latitude.
y ,point on -th<site. Remkmber -to use the correct ,,
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4 If the skyline to the south is low with no obstructions such as tall trees buildings or abruptly rising h-ills, then the following p?ocedure>is unnecessat$ as all
points on the site-will receive sun during the winter. If there are obstructions .
then the skyline should be accurately plotted on the ;un chart to determinethe
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F ent points on the site only a few fegt,awa$rom each other. In this-situation a
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r. simple :threeYdimensional mod#of the and its surroundings shoyId be
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IL determine the best building locations with exposure to the winter sun.
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problem dramatically. Along Webster Street-an east-west street-38 .
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t. - of 20 persons interviewed saiOd Lhey used only th: sunny parts of ..._.
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--I . their ya@.s. Half ,of tljese people living on the north side of the
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D Of coupe, its significahce varies as jatitude and&climate change. In B I”.~..: I Eugene, ,Oregon, for example, with a rather rainy climate, at about
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! 44”,datitude, th,e pattern is even more essential: the south faces of
3 the buildings are the most valuable outdoor-spaces on synny days. i a ~
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It is evibkntthat. the south faces of buildingsare not only imljortant for the \ * * ~
collecti,on of sqlg radiation, but-are, a”lso the most &luablS outdoor spqaces ”
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-With an idea for the location of the building okthe &--BUILDING LbCAc, .?lON(l), it is necessary to define khe.rough shape”of the building, with con
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Buildings, shiped.yithout, regaid for the suns irt$a& requjre large amount+, of is energy $o:heat and-cool; Approximately 20% of th,
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energy, consumed in the. . United .States is used for thd space heatjng and coo Sng of .buildings. of worldwide dwind.ling energy resources, maq buildings today. * . shaped without regard for the suns impact on, and %potentia! contribution to\
space heating and cooling. 7: 7 -1..1.1
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5 The &$imum sliipe of. a ,building is one whichloses anminimum amount of
:X&i heat jnthe winter and gains a,minimum ahount of heat;in tk.summer.. Victdr,~~,,.“~“~“’ ,, I,*““’
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\.,_ e(s. : Glgyay, in his book Design ,wwitti C/in-rite, has investigated the ;ffect of thermal
-. I- ,,: :. impact; (sun and air temperature) on building shaphs for different climates in . ~
\ ,,the United ,States. ;From these investfgations he drew,,; the following con- 1
J . , elusions: :: 4
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, . !I~~fhe squ;ii e house is not,the opt/mum form in any location. .
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summer with less efficiency * \han the square one. c
I G ” 3. The optimrrm shape t&s In even/ CXF tatt:rlimates 4-f in a f&m ;; elongated somewherq along the east-west direction.
By looking at the rtidiation impacts on the sid,es of a bui,lding, at different . latitudes, both in wibter and summer, Olgi/ay:s conclusions become rradily apparegt. .- . ” A ,,building elongated along the e&t-west axisexposes the longer south side of the building to r&ximum heat gain during the winter months, while exposing th@ sh,d rter east And vwest si$s to .maximum *heat gain in the summer, when the sdn is not wanted. tn. all northern latitudes (32” to 56”), the squth side
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of theibuilding receives nearly 3 times a5 much solar r;adiatlon in the_ winter *
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.I Phofo IV-26 Housing units at&&d along the east-\&t axis. Y ~.
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2. uilding Shape and Orientatioy
roof and east and w&t sides ot the bulId;ng 130th In jurnmer and IvIn\cr th,cJ
. north side of the building reqelv.cJs, vc;r\j IIEtti~ ~acl~altc~r~. BCJSI~(T t)cJing, an -efficient shqw, the largtl southern CXTI~F,U~Pi5,1tltlal tor th(~.coIIc,(.-1”1(,nr)i sol,11 L r;ldlntion. Major collectlng C~r~~Cfa~~lfi~nq 01 ihi. t~i~il~lin~ c)r~~ntc~l to lhtk
.+jJ south iv111 Intercept the nla\lmum anlount ot so/,jr ra(jl,lt[on C~~;l~l;~l-~t(~lu~ring”
ttie wntcr months.
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At all latitudes, althougtl bulId1ngs t~l~ngat~~ ,~long the ~astx\lest <IY.ILdr$ thcx / most efficient, the amount oi clongatlon dcpc>ndc upon thtl cj~rn,itt> ic,rrle i icneral principles ;a,; be <tated tor dltterclnt c \iin,~te~, In c0~11~ik\Ifin(~a/3oIiL / 0 and hotwiry (Phoc~ntx) r.lImat~t~s 1 compact builti~ng I~,rnl, c>upc,s~ng,I ni1n~r9uni
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of sujce area to a harsh environment is desirable. In temperate (New York /City) climates there is more freedom ofbuilding shape withbtit sev $excessive heat gain or loss). In hot-humid climates (Miami;), buildi be freely elorigated i,n.theeist-west direction. In”,this climate because of ibtense sumser solar radiatioq on the east and n/est;si?{es; bulldings shaped along .,, the north-sou!h axis pay a severe penalty in eJnergy consumptron (for cooling). - , In all climates, atLachedunits&Bch as roiv houses) with Cast and \Gest common walls qre most efficient since only the end units are ei$osed on the east or west face. :.
-4 I F
Y j\\ Assuming that a bvilding elongated ayong th,e easf-Lyest axls Is:c.ompatibie lvith oiher site and design considerations, lo give the bullding a rough form tve need I “,to determine the width of th.c> building. When the .prlmdry jou;ce ot $tinlight
entering a~sr”,ace is through south-facing \&indows, ll1cn ihra Ck![,l~l, oi spaces along the souIh wall 0i thq building should no1 ~scc/ed El/i times the: height a of the windows frorn the floor. ThiS assures that sunlight will pcknctrate the en tire spacer. a
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Also, this rule of thinib prqvides fog. the adequatc daylIghting of interior sppces. According to.siu,dies done by the Illuminating Engineering- Society, the epth
4
of a space for idequate natiral i.llumination should be limited to he range of 2 to 2% times the windo.w height (from t,he floor to the top of the fi i indow). For an average window height of 7 feet, this means a ma%imu& -pace depth of 13 to 18:feet. For Thr+rmal Storagk wail and Attached seen- 0 hous&Systems, room depth is limitid t& 15 to 20 feet. This is rJ
d -ma,xi
tie urn distance for effective heating irom n radiant wall.
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If fhe major spaces of the bhildingare, placed along thesyuth wall (fo;suX _ ! \. *
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light requirements) and the buffer spaces placid along the north wall, then th,$ ~ maximunl dept;h df the building will be roughly 25 to-30 feet. Spa&es which 1, need to be deeper orI do not want large south-facing. lvindows with direct sue
,y shining directly through the space can let the sun in ihrotigh south-faci$ clerestory window!! or skylights. :Admitting<.the hajor;portion of sunlight into .a space through- the roof h.as the a.dvantage of allawir?g flexibility ic distributing $ght ahd heat,to different parts of a space-CLERESTORIES AND SKYLIGHTS c (10). This allows for the maximum flexibility in locating thermal mass within a
. s+te--MASQNRY HEAT*STORAG~~l1), INTERIOR WATFR WAL,L(l2). ifK
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BUtLDING LOCAT-EON(l)--the adjoining outdoor spaces to the north- need .
. sunlight to yak6 them alive. When giving the bu-ilding a iough shape, <JS 0 ,sUltDlNG SWAPE AND ORIENTATION(2)-it is ,nccess$ry to consider the
4 buildings iinpact on the outdoor spaces to4he nbrth. $ 9
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._..__A I- -<March .X11(6 -months) the north wall of a btiiI,d!r?e and its”adjoinilg outdoor :/ spaces are in contihual shzcfe. During-;thes8 m&t$ the sun is low in the
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_--. -~_- .-: -th&e for-long-p&iods-oftime,making area unusabk. W&&e, p-revailing-: ,/ winter wihds.from the north an,d/qr west,in the United-States, the north iid6
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Locate spaces in the building that have small- lighting and heating requirc_ments to the north. These spaces act as a buffer between the living spaces andf the cold north face of fhe building-LOCATION OF. lNDOOR.SPACES(4). I ..
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0 L ,,_,i:,,There are ways, though, to mal;e these places alive and useful. For example, u sjting albuilding into a south-facing slope or berming earth .against the north wall &.duces or, eli.minates the shadow cast by the building. Besides providing sunlightto the north side, covering a north wall withTe.arth reduces heat loss ,
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walkway. To p,rotect these outdoor area% In winter, plant a dense row of evergreen trees and shrubs or tocaMp solid chstruction (kyat1lLt.o blc& the-~-_ - --_
prevailing winter winds.
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