The article deals with a study to optimize the design process of high-rise bioclimatic buildings when using renewable energy in them. The main attention is paid to the process of determining bioclimatic means that do not have universal solutions, implementation algorithms and optimization tools in connection with their richly parametric nature. Realization of the advantages of bioclimatic approaches when integrating renewable energy into high-rise buildings is possible only when a structure is formed that can ensure the interaction of variable natural and climatic factors and modern engineering and design tools. The study offers a diagram of the process of forming such a structure. The interaction of solar renewable energy technologies with the climatic parameters of the building site and the space-planning solutions of buildings is analyzed. The structuring of the analysis of climatic conditions at the macro, meso and micro levels is proposed, which provides a logical sequence for choosing the optimal restorative energy resource and engineering and technical means when integrating into a high-rise building. The approbation of certain system provisions was implemented by optimizing the design solution for the integration of renewable solar energy into a high-rise building in Kyiv, Ukraine.

Topics
Energy technology, Renewable energy, Solar energy, Engineers
1.
S.
Yardimli
,
D.
Ozer
 and
A.
Shahriary
,
Sustainable street architecture and its effects on human comfort conditions: Yazd, Iran
,
A|Z ITU Journal of the Faculty of Architecture
17
(
2
),
113
122
(
2020
).
Google Scholar
Crossref
Search ADS
 
2.
Z.
Galantini
 and
A.
Tezer
,
Review: In the complex epoch is sustainability “out” resilience “in
”,
A|Z ITU J. of the Faculty of Architecture
15
(
3
),
41
59
(
2018
).
Google Scholar
Crossref
Search ADS
 
3.
K.
Yeang
,
The Green Skyscraper: The Basis for Designing Sustainable Intensive Buildings
, (
Munich
:
Prestel Verlag
1999
),
304
.
Google Scholar
 
4.
P.
Gruber
, Biomimetics in Architecture.
Architecture of Life and Buildings
, (
New York
:
Springer Wien
2011
),
275
.
Google Scholar
 
5.
O.
Krivenko
,
V.
Mileikovskyi
. and
T.
Tkachenko
,
The principles of energy efficient microclimate provision in the skyscraper “Biotecton” of 1 km height
,
European J. of Formal Sciences and Engineering
1
(
3
),
8
17
(
2018
).
Google Scholar
 
6.
V.
Andreychuk
 and
Y.
Filyuk
,
Analysis of the energy potential of solar light of the western region of Ukraine with the account of climatic conditions
,
EUREKA: Physics and Engineering
4
,
25
32
(
2017
).
Google Scholar
Crossref
Search ADS
 
7.
J.
Zhang
,
A.
Florita
,
B.-M.
Hodge
,
S.
Lu
,
H. F.
Hamann
,
V.
Banunarayanan
 and
A.
Brockway
,
A suite of metrics for assessing the performance of solar power forecasting
,
Solar Energy
111
,
157
175
(
2015
).
Google Scholar
Crossref
Search ADS
 
8.
S.
Chan
,
J.
Hannum
,
W.
Logan
 and
M.
Vaish
,
The Skyscrper of the Future: Integrating a Flexible Program with Energy Innovation
, Paper presented at the meeting of Organization Conference (
CTBUH
,
2015
,
New York
), pp.
456
462
.
Google Scholar
 
9.
P.
Semikin
, Printsipy Formirovaniya Arkhitektury Vysotnykh Zdaniy s Vozobnovlyayemymi Istochnikami Energii (Unpublished doctoral dissertation), Central Research and Design Institute of Residential and Public Buildings, Moscow,
2014
.
10.
Y.
Hong
,
W.
Deng
,
C.
Ezeh
 and
Z.
Peng
,
Attaining sustainable high-rise office buildings in warm-summer-cold-winter climates: a case study on Frankfurt
,
International J. of Low-Carbon Technologies
14
(
4
),
533
542
(
2019
).
Google Scholar
Crossref
Search ADS
 
12.
Global Solar Atlas, URL
: https://globalsolaratlas.info/map?c=11.523088,8.525391,3 (date retrieved 22.06.2021).
13.
Prolog Semicor Ltd, URL
: http://semicor.com.ua/wp-content/uploads/2017/11/Datasheet300-315.pdf (date retrieved 22.06.2021).
14.
K.
Afsari
 and
S.
Sarat
,
Rising Trends in Tall Building Design: Environmental Sustainability through Renewable Energy Technologies
,
British Journal of Civil and Architecture Engineering (BJCAE)
01
,
47
54
(
2019
).
Google Scholar
 
15.
P.
Oldfield
,
D.
Trabucco
 and
A.
Wood
,
Five energy generations of tall buildings: an historical analysis of energy consumption in high-rise buildings
,
The J. of Architecture
14
(
5
),
591
613
(
2009
).
Google Scholar
Crossref
Search ADS
 
16.
S.
Haupt
,
B.
Kosovic
,
T.
Jensen
,
J.
Lee
,
J.
Munoz
,
P.
Lazo
 and
L.
Hinkleman
, The Sun4Cast® Solar Power Forecasting System: The Result of the Public-Private-Academic Partnership to Advance Solar Power Forecasting (No. NCAR/TN-526+STR,
2016
).
17.
O.
Krivenko
,
P.
Kulikov
,
A.
Zaprivoda
 and
V.
Zaprivoda
,
Calculation of the instant model of solar radiation distribution on curved surfaces in high-rise buildings
,
EUREKA: Physics and Engineering
6
,
14
23
(
2020
).
Google Scholar
 
18.
T.
Alves
,
L.
Machado
,
R. Gonçalves
de Souza
 and
P.
de Wilde
,
Assessing the energy saving potential of an existing high-rise office building stock
,
Energy and Buildings
173
,
547
561
(
2018
).
Google Scholar
Crossref
Search ADS
 
This content is only available via PDF.
©2023 Authors. Published by AIP Publishing.
2023
Author(s)
You do not currently have access to this content.