Portfolio Volume 2 - Extended by Joe Watton

Joe Watton

Portfolio Vol. 2 14.12.20

‘To forget how to dig the earth and to tend the soil is to forget ourselves’

Gandhi

Contents:

1. The Plant Community energy centre Riverside Park, Bristol

2. Algae-Culture Flexible exhibition centre Brabazon, Bristol

3. Coalesce Mixed-use communty hub Campo Santi Apostoli, Venice

0km

1:25,000 @ A4

1. The Plant Riverside Park, Bristol

AR30022 - The Plant:

Year 4 Project 2, [51.462224N, -2.578710E] With the impacts of climate change becoming more apparent every year, it is now crucial that global carbon emissions are reduced to a level which does not cause the planet irreversible harm. One of the most promising areas for CO2 reductions is in the generation of energy for use in buildings, which currently accounts for around 34% of the UK’s annual carbon footprint. District heating and electricity from combined heat and power energy centres has the potential to reduce emissions of connected building by around 30%.

The construction of these centres presents a unique opportunity to reevaluate our relationship with energy. Instead of banishing them to lifeless metal boxes in the outskirts, could we harness the educational potential of such buildings and bring them into the heart of our towns and cities? Framing the CHP process like an exhibit in a museum, The Plant aims to prove that this is possible, bringing a community hub and an energy centre together under one roof to passively educate visitors about clean energy as they inhabit the building.

ST PAULS

7 8

1:1,000 @ A4

2 50

ST JUDES

Site Response Key Site Decisions

Retain existing treeline as buffer between Riverside Park and the M32/Newfoundland Way

Reconnect St Pauls and St Judes with wider, safer and more direct access across the M32, Riverside Park and the River Frome.

Widen and improve the path which follows the River Frome through the park to encourage more people to walk and cycle into the city rather than driving.

Locate all development towards the city centre end of the site, with the scale of the building decreasing towards the park to help it sit more comfortably within the open space.

Remove certain paths and trees to provide a large, uninterrupted green space within Riverside Park for play and recreation, as well as for events such as markets and festivals.

Access to the community canteen at the busy intersection of the primary circulation routes, with it positioned away from the other community facilities to preserve functionality during large events in the hall.

Access to the hall and classroom spaces from the path connecting the two communities who will use the building.

Riverside Yard to act as a vibrant communal urban space serving both the youth centre and the Plant, suitable for ball games, pop up markets and group games.

Riverside Walk to provide a peaceful green route into the city centre, with the River Frome landscaped and planted to encourage wildlife.

10. Riverside Piazza to serve as the main hive of activity around the building, with activities from the main hall spilling out and into the park.

8 11

4 7

6 5

Broad Plain Youth Club Riverside Yard 0.0m 12

to City Centre

Riverside W alk 0.0m

River Frome -5.0m

14 3a

Broad Plain Youth Club Riverside Yard 0.0m

to City Centre

Riverside W alk 0.0m

River Frome -5.0m

to St Pauls

2 Riverside Piazza +3.5m

Upper Ground Floor 1.

Reception

Community hall

Thermal storage tanks

Staff office

Storage

Classroom (activity layout)

Classroom (teaching layout)

Group rooms

CHP engine exhaust flues

10. WCs 11. Breakout space 12. Void over engine room 13. Void over boiler room

1:400 @ A4

to St Judes

Lower Ground Floor 8 9

9 3b

Community canteen

WCs

a) CHP engine exhaust flues

b) Backup boiler exhaust flues

Bar

Kitchen

Kitchen store & bins

Outdoor seating

Community support desk

Thermal storage tanks

10. Exhibition space 11. Storage

12. Battery room 6

13. Boiler room 14. Transformer room

to St Judes

15. Engine room

Plant Operation The CHP Process 9

1, 2 8, 11

3 4 10

Natural gas is fed into the boiler within the CHP engine and combined with preheated fresh air from the heat recovery unit above.

The combustion heats coils of water passing

Electricity is sent through the transformers to be

through the boiler, creating a jet of high-pressured

stepped up to voltages suitable for local and national

steam.

transmission.

Pressurised steam passes through the high,

Hot steam leaving the turbines is taken to the heat tanks

intermediate and low pressure turbine sets,

through insulated pipes, and passes through another

causing the axial shaft to rotate.

coil to transfer heat to the district heating water supply.

The turning shaft is connected to a generator at

Hot exhaust gases from the boiler are taken through

the end of the CHP engine. Current induced in the

the heat exchanger to preheat incoming fresh air,

turning rotor creates a usable potential difference.

increasing the rate of complete combustion.

After recycling the heat energy, exhaust gases are

11. A large battery reserve will harness any excess

passed through a series of chemical converters

electricity when the CHP engines are running at a

and reducers in the basement to filter out harmful

surplus, and will conversely help bridge the gap

pollutants.

at times of deficit.

Once filtered, the clean gases are taken a safe

12. Stands exhibiting key parts from the equipment

height above the public realm and released

being used in The Plant, with explanatory text

through the exhaust flues.

accompanying each to help visitors understand the process going on around them.

10. The backup boilers will lie dormant for most of their lifetime, producing steam to directly feed the heat tanks on rare occasions when the CHP

13. A full steam turbine removed from its acoustic housing and exposed for visitors to see.

engines fail. 14. Cycling machines hooked up to small scale generators for visitors to see how their human power output compares to the CHP generators.

14 12

Getting sidetracked on the way to yoga

Detailed Short Section 1:250 @ A4

Detailed Long Section 1:250 @ A4

River Elevation 1:400 @ A4

20m

Road Elevation 1:400 @ A4

Park Elevation 1:400 @ A4

Yard Elevation 1:400 @ A4

1. Roof Finishes

Sedum roof build up over the community wing with standing seam corten wrapping over the gable of the portal frame.

2. Upper Ground Floor

Dowel laminated timber floor internally, with prefabricated structurally glazed waffle slab panels forming Riverside Piazza.

3. Primary Structure

Glulam portal frame joined at flitched connections and held in place by steel base plates cast into the concrete floor slab and retaining walls.

4. Groundworks

Reinforced concrete floor slab and retaining wall sitting on a layer of rigid foam glass insulation and tanked up to ground floor level throughout.

- Thermal tank circulation core -

- Riverside Piazza north approach -

Gable Ridge Detail Prefabricated Roof Panel

1. Finish

2. Fabric

3. Structure

Screw-fixed standing seam corten cladding over the gable of the portal frame, with corten coping profile fixed to the ridge

270mm SIPS panel with single 15mm OSB sheet on top side and double on lower side, taped on the inner leaf at corner junctions to ensure airtightness

800x250mm glulam portal with flitched steel plate connection and recess cut for ridge beam to provide longitudinal stability

Riverside Facade Detail Prefabricated Wall Panel

2. Fabric

3. Finish

1. Structure

800x250mm glulam portal with steel baseplate cast into concrete floor slab to create a rigid moment connection at the foot of the column

2m band of triple glazing with automated openings; 1.2m band of low-g polycarbonate panels; 200mm rigid insulation with openings into engine room

Timber framework acting as structural support for prefabricated wall panel, with glazing and polycarbonate being fixed in from behind

- Community hall/exhibition boiler room -

- Classroom/community canteen -

Canteen Roof Detail Prefabricated Waffle Slab

1. Finish

2. Fabric

3. Structure

Pre-cast concrete pavers raised on pedestals to sit flush with double layer of toughened laminated safety glass, with both draining onto a waterproof breather membrane

150mm rigid foamglass insulation with triple glazed panels in openings and channels cut out to create space for MVHR ducts

250mm lightweight concrete waffle slab sitting across two grid bays, with steel reinforcement bars running in both directions

Ventilation Strategy Air Changes by Space

The Plant will use a mechanical ventilation heat recovery unit (MVHR) to provide all spaces with a sufficient supply of fresh air throughout the year. Additional mechanical heating and cooling can be introduced to the supply during particularly hot or cold days where the air needs to be preconditioned. The MVHR unit will have an efficiency of 95%, meaning the large majority of outgoing heat will be recovered, substantially reducing the energy demand of the building during the heating season. It will run on the ‘low’ setting, with users able to increase the ventilation rate as required.

Ventilation Requirement High

Medium

Low

Fresh air supply

Exhaust air e

Air changes per hour Zone

Boost

Middle

Low

Kitchen

Canteen

Plant areas*

WCs

Main hall

Classroom spaces

Circulation areas

Volume weighted building air changes per hour

1.5ac/h

*CHP engines and boilers will have sepa direct supply of preheated fresh air

extract

arate

MVHR

Through floor

Through wall/ceiling

Duct drop

winter p Ventilation Losses: Reception/circ Reception/circ Total ventilation losses:

Q = Vv x neff x c x Gt x e Vv (ventilation volume) = 8489m3 neff (air changes per hour) = 1.5/h c (heat capacity of air) = 0.33 Wh/m³K Gt (degree hours per year) = 50 kKh/yr e (heat recovery unit efficiency) = 95% Q = 8489 x 1.5 x 0.33 x 50 x 0.05 = 28,014 kWh/year ÷ 3395m2 treated floor area

Main Main Hall hall

Classroom 11 Classroom Upper Ground Floor Spaces

Classroom 2 Classroom 2

Group Room Group room 11

Group room Room 2 Group

- 8.25 kWh/m2year Staff Office Staff office

Breakout space Space Breakout

Occupancy Gains: WCs WCs Total no. occupied hours per day: 2138 hours Heat generated by the average person: 80W Total heat gained from occupants per day:

Canteen Canteen

Lower Ground Floor Spaces

Kitchen Kitchen

Exhibition Exhibition space Space

171 kWh/day x 168 days per year in the heating season:

WCs WCs

28,734 kWh/year ÷ 3395m2 treated floor area

+ 8.46 kWh/m2year

00:00 00:00

02:00 02:00

04:00 04:00

06 06

Projected occupancy profile for The P gains, as stale warm air from high oc

preheating

6:00 6:00

summer cooling

5 Cleaners

Morning zumba

Toddler group

Choir rehearsal

Youth group

Meditation classes

Martial arts

Evening fitness classes

Language drop in classes

After school club

Evening fitness classes

Company conference

Morning yoga

SEN class

Art group

15 Morning yoga

5 people Gen. occupancy

Visiting school classes

Music lessons

Cultural groups

Board games club

Music rehearsals

Community support groups

University societies

Office work

Lunch

Office work

2 Gen. occupancy

2 Gen. occupancy 50

50 20

Morning service

50 20

General service

Lunch service

Evening service

General service

Morning service

General service

Lunch service

General service

Evening service

Morning occupancy

Daytime occupancy

Evening occupancy

2 Gen. occupancy

08:00 08:00

10:00 10:00

12:00 12:00

14:00 14:00

16:00 16:00

18:00 18:00

20:00 20:00

22:00 22:00

00:00 00:00

Plant during an average weekday. A large proportion of the building’s heating will come through occupancy ccupancy areas is run through the MVHR to heat the fresh incoming air.

Summer Operation Mixed Mode Conditioning

1. During the summer months the plant space will receive significant solar gains from the morning and early afternoon sun. Automated opening windows will run along the river facade with parallel automated roof lights along the ridge to allow hot air to escape through buoyancy driven stack ventilation.

2. All community rooms will have manually openable windows, with the stack effect in the plant room drawing air through to provide passive ventilation and cooling where necessary. 3. On overcast days when stack ventilation is less effective, the MVHR system will switch on fully to provide all fresh air for the building. 4. The undercroft spaces on the lower ground floor will have no windows on the retaining wall faces, so the MVHR will provide fresh air, supplemented with mechanical cooling where necessary. 5. Underfloor heating will run through all habitable spaces and will activate automatically when natural gains from sunlight, occupancy and plant equipment are not sufficient to maintain a comfortable internal temperature.

A B

5 3

Section A-A

3 4

Section B-B

Winter Operation Minimizing Heat Losses

1. The low U-value thermal envelope, combined with the extensive earth sheltering on the lower ground floor, will mean The Plant loses far less heat through infiltration and thermal bridging than other buildings of a similar scale. This will significantly reduce the energy required to heat it during the winter months. 2. The MVHR system will deliver warmed fresh air through ducts in the wall and floor fabric, with extract points over areas such as the plant, hall and kitchen which are more likely to experience occupancy gains. 3. Underfloor heating will preheat the inhabited spaces each morning during winter, and will also be available during the day on occasions where natural gains from sunlight, occupancy and plant equipment are not sufficient to maintain a comfortable internal temperature.

A B

3 3

Section A-A

2 3

Section B-B

Passive Lighting Daylighting Strategies

The classrooms and other spaces on the roadside wing will receive secondary daylight from the solar core, supplemented by ambient daylight from their windows and artificial lighting where necessary.

Summer sunpath

Winter sunpath

Polycarbonate panels with a low g value allow light into the engine room whilst keeping it from overheating - something which is important for the effective functioning of the combined heat and power engines.

Minimal shading to the south and east of the site means there is high potential for natural light to illuminate the habitable spaces through the morning and early afternoon.

Active lighting will become necessary in the late afternoon and into the evening as the treeline and form of the terrain means limited light will be available from the west.

Being recessed into the ground on the North side and fully exposed on the south, the building’s orientation minimizes heat losses through cooler north façades and makes the most of the available sunlight entering the site along façades with a south-facing aspect.

Solar core

Midday sun position

The upper row of triple glazing will allow light to reach deep into the plan, whilst the band of low g value polycarbonate below will moderate the sunlight to protect those nearer the facade.

The hall, boiler room and engine room will be finished with bright, reflective surfaces to act as a solar atrium, gathering a large amount of natural light from openings in the walls and roof throughout the day and passing it on to the community rooms on the more shaded side of the building.

Solar

Total sol

Q = ΣG x

G - average annua surface (k A - area of opening, r - reduction factor g - fraction of solar i

Q = 9,312

Protection from Overheating The glulam columns and timber framework along the riverside facade will provide solar shading around the middle of the day when the sun is coming from the south and the building needs most protection from overheating. Ambient daylight will still be able to enter from the east, preserving a good quality of light in the main hall and boiler room when combined with the effect of the roof lights.

÷ 3395m2 trea

+2.81 kW

Direct sunlight Diffuse/ ambient light Automated roller blind

Gains:

lar gains:

x A x r x g

al solar irradiation on kWh/m²yr) , including frame (m²) for dirt, shading etc irradiation transmitted

2 kWh/year

ated floor area

Wh/m2year

Protection from Glare There is potential for the low morning sun to cause glare in spaces which look out to the east. Automated light sensitive roller blinds will be concealed between the structure and the curtain wall and will activate when a light sensor detects there is glare in the habitable spaces. Diffuse light will still be able to pass through the polycarbonate panels, giving sufficient illumination when combined with the roof lights.

Corten Roof and Walls: • Standing seam corten sheet • 25x50mm battens aligned with seams @ 937.5mm centres • 270mm SIPS panel with 15mm OSB on either side • 50mm service cavity (walls only) • 2x 12.5mm gypsum board

Area: 1341 m² U-Value: 0.08 W/m²K Heat Loss: 106.9 W/K

Area: 494 m² U-Value: 0.08 W/m²K Heat Loss: 39.4 W/K

Double Polycarbonate Layer:

• 2x 60mm 6 layer polycarbonate panel

Area: 190 m² U-Value: 0.35 W/m²K * Heat Loss: 66.9 W/K

Area: 641 m² U-Value: 0.70 W/m²K * Heat Loss: 485.9 W/K

Concrete Wall Panels: • 100mm reinforced concrete panel • 200mm rigid insulation • 50mm service cavity • 2x 12.5mm gypsum board

Area: 233 m² U-Value: 0.09 W/m²K Heat Loss: 22.0 W/K

Area: 738 m² U-Value: 0.10 W/m²K Heat Loss: 51.0 W/K **

Sedum Roof:

Waffle Slab Roof:

• • • • •

Sedum and wildflower blend Lightweight growing substrate Filter fabric & reservoir layer Waterproof membrane 240mm SIPS panel with 15mm OSB on either side • 12.5mm gypsum board • 50mm sq timber acoustic battens

• 25mm paving slab on drainage pedestal • Waterproof membrane • 150mm rigid foamglass insulation • 250mm reinforced concrete waffle slab

Area: 703 m² U-Value: 0.60 W/m²K Heat Loss: 421.8 W/K

Triple Glazed Openings:

Plant Access Door:

• • • • •

• 480mm aluminium sheet covering • 80mm lightweight insulation • 480mm aluminium sheet covering

6mm glazed panel 12mm argon cavity 6mm glazed panel 12mm argon cavity 6mm glazed panel

Area: 19 m² U-Value: 0.80 W/m²K Heat Loss: 15.2 W/K

Retaining Walls:

Concrete Floor Slab:

• 500mm reinforced concrete retaining wall • 300mm rigid draining insulation • Min 500mm recycled hardcore backfill

• 200mm reinforced concrete floor slab • 300mm rigid foamglass insulation • Min 500mm recycled hardcore backfill

Area: 2451 m² U-Value: 0.06 W/m²K Heat Loss: 101.2 W/K **

* Membranes not included in thermal calcs

Fabric Losses: Total fabric losses:

Q = Σ AiUi + Σ lk Ψk + Σ xj Σ AiUi (losses through component build ups) Σ lk Ψk (losses through linear thermal bridges) Σ xj (losses through point thermal bridges)

Riverside Park Home to Britain’s first Passivhaus Energy Centre

Building designed with near thermal bridgefree construction, meaning component losses can be taken as the total value.

Q = Σ AiUi = 1310 W/K x heating degree hours in Bristol for base temperature of 16°C: = 65,522 kWh/year ÷ 3395m2 treated floor area

Glazing Losses -8.14 kWh/m²yr

- 19.30 kWh/m2year

Appliance Gains:

Other Fabric Losses -11.16 kWh/m²yr

Total appliance gains:

Q = ΣP + ΣA Σ P (heat given off by plant equipment) Σ A (heat given off by building appliances) = 8,488 kWh/year ÷ 3395m treated floor area 2

+2.50 kWh/m year 2

Ventilation and Infiltration Losses -8.25 kWh/m²yr

Passivhaus Energy Criteria: “The annual Space Heating Energy Demand is not to exceed 15 kWh per square meter of net treated floor area”. The Plant will comply with the Passivhaus requirement, with 13.78 kWh per m²yr used to heat the building and up to 1.22 kWh per m²yr available to provide mechanical cooling over summer if necessary.

Underfloor Heating +13.78 kWh/m2year

Solar Gains +2.81 kWh/m²yr

Appliance Gains +2.50 kWh/m²yr

Occupancy Gains +8.46 kWh/m²yr

Losses

Gains

0km

1:25,000 @ A4

2. Algae-Culture Brabazon, Bristol

Team Members: • • • • • •

Sam Betteridge Rachel Foreman Bradley Smith (Civ Eng) Ella Thorns Kevin Tse (Civ Eng) Joe Watton

Team Role: Scheme design and 3D modelling, environmental and structural strategy and detailing in conjunction with civil engineering group members.

Image by Sam Betteridge and the author

AR30021 (group project) - Algae-Culture: Year 4 Project 1, [51.518494N, -2.571795E]

Located at the entry point of the emerging Brabazon masterplan in Bristol, Algae-Culture is an new kind of exhibition centre for a greener society. With a form sculpted deliberately to gather maximum sunlight, the building’s algae-covered roof promotes a fast growing, underutilised food source which has the potential to drastically reduce the UK’s carbon footprint.

In its first lifetime the building will serve as a centre for the developing community in Filton, hosting lectures and exhibitions for the new low carbon homes and infrastructure in the area. Once the masterplan is complete, the building will transform into a centre for low emission aerospace research, promoting a greener future for Bristol’s historic aerospace industry.

Graphic by Sam Betteridge and the author

1. Maximum Area

2. Material Efficiency

Full site used to maximise production.

Primary steel arch structure.

3. Surface Area

4. Light Provision

Concertina for larger production area.

Roof tapered to reduce self-overshadowing

5. Structural Efficiency

6. Architectural Intervention

Pairing arches to reduce number required.

Forming an clear entrance point for visitors.

Plan by Rachel Foreman and the author

1 4 7

Reception

Bar

Large exhibition space

Cloak desk

Small exhibition space

Small auditorium

Large auditorium

Office breakout space

m in m ut

FLOOR

1:200 @ A4

First Floor

Ground Floor

30M

1 Liberating the Land 1.

Algae pipework integrated within the building envelope and showcased to building users and those passing on the Gloucester Road.

High-nutrient animal feed created from the harvested algae, requiring 1/40th the growing area of traditional feed crops.

60% of the area of the UK is used to grow animal feed crops. Millions of hectares could be freed up if algae was adopted as an alternative on a nationwide scale.

Space for Sustainability 4.

More space for tree planting, rewilding and other habitat restoration to absorb CO2 and enhance biodiversity across the country.

More space to grow crops for the increasing population, avoiding the need to import from overseas and

benefitting the economy. 6.

More space for renewable methods of energy generation such as solar and wind power, reducing the UK’s dependancy on fossil fuels.

Graphic by Ella Thorns and the author

Image by Sam Betteridge and the author

- Flexible lecture/workshop space -

0km

1:25,000 @ A4

3. Coalesce Campo Santi Apostoli, Venice

AR30019 - Coalesce:

Year 3 Project 2, [45.440251N, 12.336659E] A fire damaged group of buildings around Campo Santi Apostoli in Venice needed sensitive reconstruction to restore the historic community hub. All internal structure had been destroyed though some of the external stone walls remained intact.

The previously successful tavern and ice cream parlour were to be reinstated on the ground floor alongside a new gondola repair workshop. The upper floors needed to contain two new medical services and a mixture of 1, 2 and 3 bed apartments.

Land Usage

Commercial Community Residential

Site Views

Exposed Wing Secluded Wing Views out Visible boundary

Site Circulation

Gondolas Pedestrians

- Arrival of the Gondola -

Third Floor

2 1

Two bed private apartment

Three bed private apartment

Second Floor

2 1 3

Two bed apartment for recovery centre

Three bed apartment for workshop

Resident’s courtyard

First Floor 5

1 2 4

Reception and waiting area

Physiotherapist

Recovery studio

Resident’s courtyard

Workshop gangway

Ground Floor

3 4 2 6 5

Gelato di Natura

Tavern - Osteria del Riocco Peoco

Tavern courtyard

Gondola workshop

Break room

Storage and materials

- External Venetian roller shutter -

Work in Practice

- Sketch scheme for alterations to existing hillside residence. Designscape, 2020 -

- Render for seafront restaurant replacing derelict hall. Grainge, 2019 -

A range of work from recent architectural placements. 2019-20

- Tensile fabric research project using Kangaroo for Rhino. Designscape, 2020 -

Dimensions are not to be scaled from this d

O P T IO N 3 B - O V E R V IE W

Rev Date

Description

Issued for initial comments

02.04.19

Option 3B:

Wadham becomes the sole Secondary School with Maiden Beech, Greenfylde, Swanmead Ashlands serving as Primary Sc and the rest being considered closure.

CASTLE Primary School

12. ST MARY'S & ST PETER'S Potential Closure

SOUTH PETHERTON Infants School

11. SHEPTON BEAUCHAMP Potential Closure 0

STANCHESTER ACADEMY Secondary School SOUTH PETHERTON Junior School

NORTON SUB HAMDON Primary School

NEROCHE Primary School

03. GREENFYLDE Primary School

1890

630

Primary School Places (4-11)

ILMINSTER 420 WEST CHINNOCK Primary School

04. SWANMEAD Primary School

1103

07. MERRIOT Potential Closure

Secondary School Places (11-16)

08. HINTON ST GEORGE Potential Closure

0 0

09. HASELBURY PLUCKNETT Potential Closure

Pupil Places Required: 29 Pupil Places Provided: 29

06. ASHLANDS Primary School

THE REDSTART Primary School

01. WADHAM Secondary School

1103

210 HOLYROOD ACADEMY Secondary School

CREWKERNE AVISHAYES Primary School

02. MAIDEN BEECH ACADEMY Primary School

05. ST BARTHOLOMEWS Potential Closure

630

CHARD 0 MANOR COURT Primary School

FOR COMMENT

10. MISTERTON Potential Closure

Crewkerne & Ilminster Schools Review for

Futures for Somerset TWO TIER SYSTEM: Infant School (4-7)

THREE TIER SYSTEM: Junior School (7-11)

Primary School (4-11)

Secondary School (11-16)

First School (4-9)

Middle School (9-13)

Upper School (13-16)

- Masterplan for student number allocations between schools. Grainge, 2019 -

C R EW K E R N E

A N D

I L M I N ST E R

SC H O O LS

5km

Capacity Overview Option 3B Scale: 1:50,000 @ A1

R EV I EW

Drawing No:

1404 /

00-102 Rev -

The Boat Shed, Michael Browning Way Exeter EX2 8DD 01392 438051 mail@g-a.uk.com

Artwork

- Watercolour -

- Charcoal -

- Mixed Med

- Pen

dia Collage -

ncil -

A selection of work from Art A Level. Various media, 2015-16

- Pencil -

- Oil Paint -

Catching Dreams

- Sleeping Giants -

- Marco

- Wax on, Wax off -

- Walk on

o Polo -

n Water -

Snapshots of daily life in the illusive worlds we visit during our sleep. Photoshop, 2018

- Concrete Jungle -

- The Harvest -

Second Glance

- Mountain/Towel -

- Stargazing/Pepper -

- Shoreline/

- Microspaghe

/Droplets -

etti/Spaghetti -

Looking at everyday objects from a different angle to expose new identities. Smartphone camera, 2020

- Jupiter/Mug -

- Cliff Edge/Ice -

Making

- Woodland Path, 2016 -

- Revision Pe

- Den no.4, 2017 -

- Garden St

Some of the things I’ve built. Some useful, some less so. All loved.

erch, 2016 -

- Post-Exam Perch, 2016 -

tairs, 2019-

- Garden Seating, 2020 -

- Duke of Edinburgh Expedition, 2015 -

- University of Bath Ski Trip, 2018 -

- Lyme to Lands End C

- France Cycle

My favourite recent trips outside of Secondary School and Unievrsity

Charity Cycle, 2016 -

- Prague Marathon, 2017 -

e Tour, 2019 -

- Lockdown in Bath, 2020 -

Joe Watton Portfolio Vol. 2 Phone: +44 (0) 77414 04938

Email: joewatton98@gmail.com

Website: issuu.com/joewatton