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C h r i s D e r r i n g e rMBA Operations Management, BFA Interior Design
P o r t f o l i o
Contents1 - 2 Resume
3 - 4 Guest room Designs
5 - 10 Concept Design
11 - 14 2D Drawings
15 - 17 3D Drawings
Profile
Recent MBA graduate with over 10 years of experience in customer service and supplier relations. My designs are inspired from visual ele-ments found in nature and architectural details. Within the designs I create spaces are infused with modern and traditional design elements.
Education
Master of Business Administration in Operations Management, 2012American InterContinental University, Atlanta, GAGPA: 3.88Delta Mu Delta, International Honor Society in Business Adminis-tration
Bachelors of Fine Arts, Interior Design, 2010American InterContinental University, London, United KingdomLondon South Bank University, London, United KingdomUpper Second Degree with Honors
Skills:
• Proficient in Microsoft software packages • Proficient in 2D & 3D AutoCAD and SketchUP programs• Fluent in Adobe Creative Suite; Photoshop/InDesign/ Illustrator• Ability to effectively liaise between clients, suppliers, and management meeting budgets and deadlines.
Resume
Sales Associate The White Company, London, UK, 2008 – 2010
• Provided personalized customer service to clientele to include custom ordering.• Oversaw inventory control to include merchandise ordering and storage management.• Developed sales strategies taking into consideration for product and inventory availability, pricing, and store promotions.• Assembled and merchandised internal displays using visual guidelines of color, pattern, texture, and balance.
Executive Administrative Assistant United States Navy, Norfolk, VA, Sigonella, Italy, and Kuwait, 2003 – 2007
• Established, managed, and coordinated daily administrative operations for over 300 personnel including Executive Staff.• Liaison between Executive Staff and 10 Department Managers on three continents.• Prepared, analyzed, and tracked current and future travel expenditures and allocations while managing a travel budget of $1.5 million. • Managed the proper handling and processing of over 10,000 pieces of official mail, resulting in a top ranked mail program.• Deployed to Kuwait as Lead Administrative Assistant in conjunction with the U.S. 3rd Army, performed administrative duties for 190 deployed naval personnel.• Awarded Navy and Marine Corps Achievement Medal and Army Achievement Medal for improving processes and providing assistance out-side the normal scope of responsibilities.
1
Restaurant General Manager KFC Yum Brands Inc., Kansas City, 1998 – 2003
• Advanced professionally to General Manager within two years of working with the company.• Reduced Inventory by monitoring a staff of 20, facilitated in-house train-ing and incentive plans, and introduced improved inventory controls. • Tracked sales levels to determine product volume adjustments, replenish-ments, and allocations.• Conducted P&L accountability; manage sales analysis, forecasting, and reporting activities.• Consistently received outstanding marks on monthly and quarterly in-spections and was considered a leader throughout the market for profitabil-ity, quality and customer service.• Gave hands-on instruction on new product roll-outs, conducted and su-pervised career development programs, lead monthly orientation classes.• Assisted in the training, planning, and execution of three store openings.
PROFESSIONAL ASSOCIATIONS
Association for Operations Management, APICSCouncil of Supply Chain Management Professionals, CSCMPDelta Mu Delta International Honor Society in Business Administration Customer Satisfaction Measurement Benchmarking Association, CSMASociety of British Interior Design, SBID
Acheivements
CSMP 2012 Scholarship Recipient Delta Mu Delta, International Honor Society in Business Administration Navy and Marine Corps Achievement Medal Army Achievement Medal
Christopher Derringer
105 Sheffield PL, Cartersville, GA 30121 Telephone: (678) 956-0088 E-mail: [email protected] LinkedIn: : http://www.linkedin.com/in/christopherderringer
2
Guest rooms Cartersville, GA
3
4
Nursery SchoolLondon, England
BRIEF: Renovate the first two floors and garden of an exist-ing Nursery School reinforcing Montessori’s teaching philosophy. The new scheme incorporates several learning environments focusing on movement and congregation, learning from peers, and education from nature and its surroundings.
5
Ground floor incorporates several learning environments while enforcing Montessori’s principles of movement and congregation and learning from peers. Social integration is encouraged through the open concept design. .
KEY:
[1.] Female W/C[2.] Male W/C[3.] Disabled W/C [4.] First Aid[5.] Storage[6.] Office Space[7.] Reception
6
CLASSROOM
3
2
1
LIBRARY 4
LIFT
5
FIREEXIT
6
6
ENTRANCE
7
CLASSROOM
LIGHT WELL
INFLATABLE STRUCTURE
A
SECTION A
Flexible Seating
Cork Flooring
Soft Play Area Inflatable Structure
Soft Mobile Seating
Wall Structure
LIFT
FIREEXIT
Image 51 1st Floor Plan
0 50
Scale: cm
150100
FIRST FLOOR: Creates a open concept learning environment explores Montessori’s principle learning from peers and movement and congregation. Providing a space where children can interact and learn with each other.
KEY:
[1.] Female W/C[2.] Male W/C[3.] Disabled W/C [4.] Reading Area[5.] Food Prep Area[6.] Office Space[7.] StorageSection B
Bamboo Garden
Flexible seating
Transparent WallsCurtain Divider
Wall Structure
Reading Area
OPEN CONCEPT CLASSROOM
1
2
34
5
6 7
7
B
7
8
Staircase linking the common areas
Second floor play area incorporating movement trough the staircase design Classroom design
BUILDING
GARDENS: Creates a learning environment that explores Montessori’s principle learning from nature and its surroundings while providing a space where children can interact and learn with each other.
Greenhouse
Underground Play Tunnel
Outdoor Play Area Existing Playground
Hedge Maze
Orchard
A
Elevation A
9
GARDENS: Creates a learning environment that explores Montessori’s principle learning from nature and its surroundings while providing a space where children can interact and learn with each other.
10
ECO Titanic
Title
Date: October 2010Drawn By: Christopher Derringer
Size36 x 66
Number Revision
Sheet 1 of 1A
UK Building Regulations and Codes
N-387
A1 (1) The building shall be constructed so that the combined dead, imposed and wind loads are sustained and transmitted by it to the ground:
(a) safely; and(b) without causing such deflections or deformation of any part of the building, or such movement of the ground, as will impair the stability of any part of another building.
(2) In assessing weather a building complies with sub paragraph (1) regard shall be had to the imposed wind loads to which it is likely to be subject in the ordinary course of its use for the purpose for which it is intended.
A2 The building shall be constructed so that ground movement caused by:
(a) swelling, shrinkage or freezing of the subsoil; or(b) land-slip or subsidence ( other than subsidence arising from shrinkage, in so far as the risk can be reasonably foreseen en), will not impair stability of any part of the building.
A3 The building shall be constructed so that in an event of an accident the building will not suffer to an extent disproportionate to the cause.
B1 The building shall be designed and constructed so that there are appropriate provisions for early warning of fire, and appropriate means of escape outside the building capable of being safely and effectively used at all material times.
B2 (1) To inhibit the spread of fire within the building, the internal lining shall:
(a) Adequately resist the spread of flame over their surfaces; and(b) have, if ignited, a rate of heat or a rate of fire growth, which is reasonable in the circum-stances.
(2) In this paragraph “internal linings” mean the materials or products used in lining any parti-tion, wall, ceiling or other internal structure
B3 (1) The building shall be designed and constructed so that, in the event of fire, it’s stability will be maintained for a reasonable period.
(2) A wall common to two or more buildings shall be designed and constructed so that it ad-equately resists the spread of fire between those buildings. For the purpose of this sub-paragraph a house in a terrace and a semi-detached house are each to be treated as a separate building. (3) Where reasonably necessary to inhabit the spread of fire within the building, measures shall be taken, to an extent appropriate to the size and intended use of the building, comprising either or both of the following: (a) sub-division of the building with fire-resisting construction;(b) installation of suitable automatic fire suppression systems.
(4) The building shall be designed and constructed so that the unseen spread of fire and smoke within concealed spaces in its structure and fabric is inhibited.
B4 (1) The external walls of the building shall adequately resist the spread of fire over the walls and from one building to another, having regarded to the height, use and position of the building.
(2) The roof of the building shall adequately resist the spread of fire over the roof and from one building to another, having regard to the use and position of the building.
B5 (1) The building shall be designed and constructed so as to provide reasonable facilities to assist firefighters in the protection of life.
(2) Reasonable provisions shall be made within the site of the building to enable fire appliances to gain access to the building.
C1 (1) The ground to be covered by the building shall be reasonably free from any material that might damage the building or affect stability, including vegetable matter, topsail and pre-existing foun-dations. (2) Reasonable precautions shall be taken to avoid danger to health and safety caused by con-tainments on or in the ground covered, or to be covered be the building and any land associated with the building.
(3) Adequate subsoil drainage hall be provided if it’s needed to provide: (a) the passage of ground moister to the interior of the building;(b) damage to the building including damage through the transport of water-borne contaminants to the foundation of the building.
(4) For the purpose of this requirement, “containment” means any substance which may become harmful to persons or building includes substance are corrosive, explosive, flammable, radioactive or taxic.
C2 The floors, walls and roof of the building shall adequately protect the building and people who use the building from harmful effects caused by:
(a) ground moister;(b) precipitation and wind-driven spray;(c) interstitial and surface condensation ; and(d) spilling of water from or associated with sanitary fittings or fixed appliances.
D1 If the insulation material is inserted in a cavity wall reasonable precautions shall be taken to pre-vent the subsequent permeation of any toxic fumes from the material into any part of the building occupied by people.
K1 Stairs, Ladders and ramps shall be designed, constructed and installed as to be safe for people moving between different levels in or about the building.
K2 (a) Any stairs, ramps, and balconies and any roof to which people have access, and (b) any light well, basement area or similar sunken area connected to a building, shall provide with barriers where it is necessary to protect people in or about the building from falling.
L1 Reasonable provisions shall be made for the conservation of fuel and power in building by:
(a) limiting heat gains and losses: i. through thermal elements and other parts of the building fabric; and ii. from pipes, ducts and vessels used for space heating, space cooling and hot water ser-vices.
(b) providing and commissioning energy fixed building services with effective controls; andproviding to the owner sufficient information about the building, the fixed building services and their maintenance requirements so that the building can be operated in such a manner as to use no more fuel and power than is reasonable in the circumstances.
N1 Glazing, with which people are likely to come into contact whilst moving in or about the building shall:
(a) if broken on impact, break in a way which is unlikely to cause injury; or(b) resist impact without breaking; or(c) be shielded or protected from impact.
N4 Provisions shall be made for any windows, skylights, or any transparent or translucent walls, ceil-ings or roofs to be safely accessible for cleaning.
Target carbon dioxide Emission Rate (TER)
The Target CO2 Emissions Rate (TER) is the minimum energy performance required specified in Regulation 17B. It is the mass of CO2 emitted per year per square meter of total useful floor area of the building (kg/m2/year). The TER must be calculated using one of the calculation tools included in the methodology for calculating the energy performance of buildings ap-proved by the Secretary of State pursuant to regulation 17A. Those tools include: (a) The Simplified Building Energy Model (SEBEM) for those buildings whose design features are capable of being adequately modeled by SBEM or (b) Other ap-proved software tools. These procedures for approving such software are set out in Annex 1 of ODPM Circular 03/2006.
U Value Calculation : (W/m2k)
8 mm recycled Oak flooring, oiled and waxed with biological products10 x 30 mm Battens30 mm ventilation cavity30 mm screed with under floor heating system polyethylene separation membrane200 mm reinforced concrete200 mm wood framed drop ceiling 120 mm thermal and sound impact insulation10 mm gypsum board finished with biological paintLow energy affiant lighting
20 mm cladding, clay constructed panels100 mm battens
100 mm thermal insulation polyethylene separation membrane
300 mm reinforced concrete 10 mm gypsum board, finished with
biological paint
20 mm slate pavers, adhesive fixed30 mm screed with under floor heating systempolyethylene separation membrane100 mm thermal and sound impact insu-lation 20 mm cladding, clay constructed panels with 100 mm battens
20 mm gipson board finished with biological paint200 mm reinforced concrete20 mm gipson board finished with biological paint
8 mm recycled oak flooring, oiled and waxed with biological products10 x 30 mm battens30 mm ventilation cavity30 mm screed with under floor heating systempolyethylene separation membrane200 mm reinforced concrete200 mm wood framed drop ceiling120 mm thermal and sound impact insulation10 mm gypsum board finished with biological paintlow energy efficient lighting
20 mm slate pavers, adhesive fixed30 mm Screed with under floor hating systempolyethylene separation membrane 130 mm thermal and sound impact insulation 300 mm reinforced concrete floor slab
solar vortex panels 20 mm steel sheeting100 mm thermal insulationRoof membrane with double polyethylene reinforcement 110 mm screed300 mm reinforced concrete180 mm wood framed drop ceiling80 mm thermal and sound impact insulation
2 layers 20 x100 Double glazed switch able windows (“smart” win-
dows), with 400 mm gap sealed with silicone adhesive supported joined
together with 04 mm stainless steel tension cable system
20 mm slate pavers, adhesive fixed30 mm Screed polyethylene separation membrane 200 mm concrete floor slab
2000 mm x 20 mm Glass landing supported by steel trusts welded to 200 mm round steel tubing
20 mm slate pavers, adhesive fixed30 mm Screed polyethylene separation membrane 180 mm reinforced concrete floor slab
20 mm thick glass platform supported by 40 x 3000 glass supporting beams with 40 mm x 260 glass steps
20 mm thick glass platform supported by 40 x 3000 glass supporting beams with 40 mm x 260 glass steps
N4
A1-3
B5 Fire Alarm System
K1
K2
N1
L1
L1
Low growing vegetation improves air quality,offers aesthetic qualities, and provides natural habitat for wildlife.
100 mm Lightweight growing medium formulated to absorb 40% of its volume in rainwater.
Filter fabric helps prevent fine grained soil from clogging the drainage layer.
60 mm Dainage layer carring rainwater away from the serface of the roof deck to a rainwater harvesting system.
Sheet barrier protects the waterproof membrane mechanical abrasion and root attachment or penetration.
Waterproof membrane the waterproofing of the roof.
100 mm thermal insulation provining the required resistance to heat flow through the roof assem-bly.300 mm Reinforced concrete roof slab.
Angled welded bars support pannel to pockets milled into edges of facade pannels.
Clip angled with slotted hole for ex-pansion bolt, welded or bolted to angle cast into edge of slab.
Pannels mounted on a steel subframe are designed to transmit gravity and lateral loads from the facade slabs to the structural frame of the building. The subframe consists of steel struts that support stainless steel or aluminum angles.
Medal Cap with continouse cleat.
Bonding adhesive.Reinforced EPTDM membrain flashing.
Splicing cement
70 mm minimumLap sealant
Mechanical Fasteners at 30 cm o.c. muct penetrate into roof deck.
100 mm Rigid Insulation
300 mm reinforced concrete roof deck
11
ECO Titanic
Title
Date: October 2010Drawn By: Christopher Derringer
Size36 x 66
Number Revision
Sheet 1 of 1A
UK Building Regulations and Codes
N-387
A1 (1) The building shall be constructed so that the combined dead, imposed and wind loads are sustained and transmitted by it to the ground:
(a) safely; and(b) without causing such deflections or deformation of any part of the building, or such movement of the ground, as will impair the stability of any part of another building.
(2) In assessing weather a building complies with sub paragraph (1) regard shall be had to the imposed wind loads to which it is likely to be subject in the ordinary course of its use for the purpose for which it is intended.
A2 The building shall be constructed so that ground movement caused by:
(a) swelling, shrinkage or freezing of the subsoil; or(b) land-slip or subsidence ( other than subsidence arising from shrinkage, in so far as the risk can be reasonably foreseen en), will not impair stability of any part of the building.
A3 The building shall be constructed so that in an event of an accident the building will not suffer to an extent disproportionate to the cause.
B1 The building shall be designed and constructed so that there are appropriate provisions for early warning of fire, and appropriate means of escape outside the building capable of being safely and effectively used at all material times.
B2 (1) To inhibit the spread of fire within the building, the internal lining shall:
(a) Adequately resist the spread of flame over their surfaces; and(b) have, if ignited, a rate of heat or a rate of fire growth, which is reasonable in the circum-stances.
(2) In this paragraph “internal linings” mean the materials or products used in lining any parti-tion, wall, ceiling or other internal structure
B3 (1) The building shall be designed and constructed so that, in the event of fire, it’s stability will be maintained for a reasonable period.
(2) A wall common to two or more buildings shall be designed and constructed so that it ad-equately resists the spread of fire between those buildings. For the purpose of this sub-paragraph a house in a terrace and a semi-detached house are each to be treated as a separate building. (3) Where reasonably necessary to inhabit the spread of fire within the building, measures shall be taken, to an extent appropriate to the size and intended use of the building, comprising either or both of the following: (a) sub-division of the building with fire-resisting construction;(b) installation of suitable automatic fire suppression systems.
(4) The building shall be designed and constructed so that the unseen spread of fire and smoke within concealed spaces in its structure and fabric is inhibited.
B4 (1) The external walls of the building shall adequately resist the spread of fire over the walls and from one building to another, having regarded to the height, use and position of the building.
(2) The roof of the building shall adequately resist the spread of fire over the roof and from one building to another, having regard to the use and position of the building.
B5 (1) The building shall be designed and constructed so as to provide reasonable facilities to assist firefighters in the protection of life.
(2) Reasonable provisions shall be made within the site of the building to enable fire appliances to gain access to the building.
C1 (1) The ground to be covered by the building shall be reasonably free from any material that might damage the building or affect stability, including vegetable matter, topsail and pre-existing foun-dations. (2) Reasonable precautions shall be taken to avoid danger to health and safety caused by con-tainments on or in the ground covered, or to be covered be the building and any land associated with the building.
(3) Adequate subsoil drainage hall be provided if it’s needed to provide: (a) the passage of ground moister to the interior of the building;(b) damage to the building including damage through the transport of water-borne contaminants to the foundation of the building.
(4) For the purpose of this requirement, “containment” means any substance which may become harmful to persons or building includes substance are corrosive, explosive, flammable, radioactive or taxic.
C2 The floors, walls and roof of the building shall adequately protect the building and people who use the building from harmful effects caused by:
(a) ground moister;(b) precipitation and wind-driven spray;(c) interstitial and surface condensation ; and(d) spilling of water from or associated with sanitary fittings or fixed appliances.
D1 If the insulation material is inserted in a cavity wall reasonable precautions shall be taken to pre-vent the subsequent permeation of any toxic fumes from the material into any part of the building occupied by people.
K1 Stairs, Ladders and ramps shall be designed, constructed and installed as to be safe for people moving between different levels in or about the building.
K2 (a) Any stairs, ramps, and balconies and any roof to which people have access, and (b) any light well, basement area or similar sunken area connected to a building, shall provide with barriers where it is necessary to protect people in or about the building from falling.
L1 Reasonable provisions shall be made for the conservation of fuel and power in building by:
(a) limiting heat gains and losses: i. through thermal elements and other parts of the building fabric; and ii. from pipes, ducts and vessels used for space heating, space cooling and hot water ser-vices.
(b) providing and commissioning energy fixed building services with effective controls; andproviding to the owner sufficient information about the building, the fixed building services and their maintenance requirements so that the building can be operated in such a manner as to use no more fuel and power than is reasonable in the circumstances.
N1 Glazing, with which people are likely to come into contact whilst moving in or about the building shall:
(a) if broken on impact, break in a way which is unlikely to cause injury; or(b) resist impact without breaking; or(c) be shielded or protected from impact.
N4 Provisions shall be made for any windows, skylights, or any transparent or translucent walls, ceil-ings or roofs to be safely accessible for cleaning.
Target carbon dioxide Emission Rate (TER)
The Target CO2 Emissions Rate (TER) is the minimum energy performance required specified in Regulation 17B. It is the mass of CO2 emitted per year per square meter of total useful floor area of the building (kg/m2/year). The TER must be calculated using one of the calculation tools included in the methodology for calculating the energy performance of buildings ap-proved by the Secretary of State pursuant to regulation 17A. Those tools include: (a) The Simplified Building Energy Model (SEBEM) for those buildings whose design features are capable of being adequately modeled by SBEM or (b) Other ap-proved software tools. These procedures for approving such software are set out in Annex 1 of ODPM Circular 03/2006.
U Value Calculation : (W/m2k)
8 mm recycled Oak flooring, oiled and waxed with biological products10 x 30 mm Battens30 mm ventilation cavity30 mm screed with under floor heating system polyethylene separation membrane200 mm reinforced concrete200 mm wood framed drop ceiling 120 mm thermal and sound impact insulation10 mm gypsum board finished with biological paintLow energy affiant lighting
20 mm cladding, clay constructed panels100 mm battens
100 mm thermal insulation polyethylene separation membrane
300 mm reinforced concrete 10 mm gypsum board, finished with
biological paint
20 mm slate pavers, adhesive fixed30 mm screed with under floor heating systempolyethylene separation membrane100 mm thermal and sound impact insu-lation 20 mm cladding, clay constructed panels with 100 mm battens
20 mm gipson board finished with biological paint200 mm reinforced concrete20 mm gipson board finished with biological paint
8 mm recycled oak flooring, oiled and waxed with biological products10 x 30 mm battens30 mm ventilation cavity30 mm screed with under floor heating systempolyethylene separation membrane200 mm reinforced concrete200 mm wood framed drop ceiling120 mm thermal and sound impact insulation10 mm gypsum board finished with biological paintlow energy efficient lighting
20 mm slate pavers, adhesive fixed30 mm Screed with under floor hating systempolyethylene separation membrane 130 mm thermal and sound impact insulation 300 mm reinforced concrete floor slab
solar vortex panels 20 mm steel sheeting100 mm thermal insulationRoof membrane with double polyethylene reinforcement 110 mm screed300 mm reinforced concrete180 mm wood framed drop ceiling80 mm thermal and sound impact insulation
2 layers 20 x100 Double glazed switch able windows (“smart” win-
dows), with 400 mm gap sealed with silicone adhesive supported joined
together with 04 mm stainless steel tension cable system
20 mm slate pavers, adhesive fixed30 mm Screed polyethylene separation membrane 200 mm concrete floor slab
2000 mm x 20 mm Glass landing supported by steel trusts welded to 200 mm round steel tubing
20 mm slate pavers, adhesive fixed30 mm Screed polyethylene separation membrane 180 mm reinforced concrete floor slab
20 mm thick glass platform supported by 40 x 3000 glass supporting beams with 40 mm x 260 glass steps
20 mm thick glass platform supported by 40 x 3000 glass supporting beams with 40 mm x 260 glass steps
N4
A1-3
B5 Fire Alarm System
K1
K2
N1
L1
L1
Low growing vegetation improves air quality,offers aesthetic qualities, and provides natural habitat for wildlife.
100 mm Lightweight growing medium formulated to absorb 40% of its volume in rainwater.
Filter fabric helps prevent fine grained soil from clogging the drainage layer.
60 mm Dainage layer carring rainwater away from the serface of the roof deck to a rainwater harvesting system.
Sheet barrier protects the waterproof membrane mechanical abrasion and root attachment or penetration.
Waterproof membrane the waterproofing of the roof.
100 mm thermal insulation provining the required resistance to heat flow through the roof assem-bly.300 mm Reinforced concrete roof slab.
Angled welded bars support pannel to pockets milled into edges of facade pannels.
Clip angled with slotted hole for ex-pansion bolt, welded or bolted to angle cast into edge of slab.
Pannels mounted on a steel subframe are designed to transmit gravity and lateral loads from the facade slabs to the structural frame of the building. The subframe consists of steel struts that support stainless steel or aluminum angles.
Medal Cap with continouse cleat.
Bonding adhesive.Reinforced EPTDM membrain flashing.
Splicing cement
70 mm minimumLap sealant
Mechanical Fasteners at 30 cm o.c. muct penetrate into roof deck.
100 mm Rigid Insulation
300 mm reinforced concrete roof deck
12
Front Elevation
Elevation B
elevation A
a
Floor Plan
B
KEY:
[1.] Female W/C[2.] Male W/C[3.] Dishwashing area [4.] Office Space[5.] Refrigerated storage[6.] Employee / mechanical room
Restaurant Design London, England
Outside seating
DRY STORAGE
COVERED COURTYARD
LOUNGE SEATING
1
2
3
FOOD PREP AREA
4
5
5
6
ENTRANCE
B
BAR
13
PROD
UCED
BY A
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PRODUCED BY AN AUTODESK EDUCATIONAL PRODUCT
PRODUCED BY AN AUTODESK EDUCATIONAL PRODUCT
PRODUCED BY AN AUTODESK EDUCATIONAL PRODUCT
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BY
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PRODUCED BY AN AUTODESK EDUCATIONAL PRODUCT
PR
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PRODUCED BY AN AUTODESK EDUCATIONAL PRODUCT
PROD
UCED
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PRODUCED BY AN AUTODESK EDUCATIONAL PRODUCT
PRODUCED BY AN AUTODESK EDUCATIONAL PRODUCT
PRODUCED BY AN AUTODESK EDUCATIONAL PRODUCT
The brief was to design a restaurant/disco as past of an existing hotel that infuses modern design elements without losing the historic characteristics of the building. The existing courtyard was enclosed with a glass structure so that it can be utilized year round for events. The design elements incorporate fluid motions throughout. This is evident in the bar design and the seating that rapes around the entire space. The overall design is light and airy with a mixture of modern and rustic elements.
14
Retail DesignLondon, England
The overall design incorporates fluid movements within a set con-straint mimicking the fashion de-signers’ style and collections. The curved surfaces draw you through-out the space allowing you to have a new experience around every corner.
15
Restaurant
Underground floor:
Ground Floor
Dressing Rooms
storage
Retail Space
Male / Female Rest rooms
Seedling Room
Lookout point
Indoor Garden
16
Roof Deck
First and Second floors
Retail Space
17
Work Studio
Solar Panels
Sky Lights
Sky Lights
Christopher Derringer
105 Sheffield PL, Cartersville, GA 30121Telephone: (678) 956-0088E-mail: [email protected]: : http://www.linkedin.com/in/christopherderringer