Merkinch Welfare Hall Technical Details

REVISIONS: DATE: DESCRIPTION:

DRAWING STATUS:

PROJECT: MERKINCH WELFARE HALL

TITLE: LOCATION PLAN

EDWARD BROWN 15003518 ・UHI INVERNESS ・1 INVERNESS CAMPUS ・INVERNESS ・IV2 5NAREV:

DATE: NOV 2016

SCALE: 1:2500 @ A3

DRAWN:

CHECKED: TC

EB

108001_1

P1

PLANNING

N

0 150m 250m100m 200m50m 50m

1:2500

E L E V T I O N

V

A

N

D

E

R

S

O

N

S

T

Tap Lane Car Park

P

o

s

t

s

G

R

A

N

T

S

T

R

E

E

T

B

R

O

W

N

S

T

R

E

E

T


DRAWING STATUS:


TITLE: SITE PLAN


DATE: NOV 2016

SCALE: 1:500 @ A3

DRAWN:

CHECKED: TC

EB

108001_2

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PLANNING

N

010m 10m 20m 30m 40m 50m

1:500

E L E V T I O N

V


DRAWING STATUS:


TITLE: GROUND FLOOR PLAN

E L E V T I O N


DATE: DEC 2016

SCALE: 1:100 @ A3

DRAWN:

CHECKED: TC

EB

108001_3

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PLANNING

V

02m 2m 4m 6m 8m 10m

1:100

N

A

A

1 MWH Gym Area

2 Hallway

3 Exit to Grant Street

4 Stairs to Office Space

5 Lift to Office Space

6 Reception Area

7 Accessible WC

8 Extension Gym Area

9 Male Changing Room

10 Female Changing Room

11 Plant Room

12 Exit to Brown Street

1

8

2

3

4

5

7

6

9

106

7

12


DRAWING STATUS:


TITLE: FIRST FLOOR PLAN

E L E V T I O N


DATE: DEC 2016

SCALE: 1:100 @ A3

DRAWN:

CHECKED: TC

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108001_4

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PLANNING

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02m 2m 4m 6m 8m 10m

1:100

N

1 Office Space

2 Kitchenette Area

3 Stairs to Gym Area

4 Lift to Gym Area

4 Lobby

1

2

3

4

5

Light Switch (1100mm above FFL)

LV Recessed Light (motion sensor activation for changing

rooms)

Twin 13amp flush socket outlet unit (450mm above FFL)

Twin 13amp flush socket outlet unit (high level - 150mm

above worktop)

Mechanical extract fan - 15L/sec

Electric unit & meter

Smoke alarm installed in accordance with BS 5446-1: 2000

& wired via permanent & protected circuit & interconnected

to any other smoke alarm or optical fire alarm within the

building - minimum distance to light fixture & walls to be

300mm.

Optical fire detector installed & tested to BS 5839-1: 2002

& wired via permanent & protected circuit & interconnected

to any other smoke or optical fire alarm within the building -

minimum distance to light fixture & walls to be 300mm.

Carbon monoxide detectors should comply with BS EN

50291-1: 2010 & be powered by a battery designed to

operate for the working life of the detector & incorporate a

warning device to alert users when its working life is due to

expire. Hard wired main operated carbon monoxide

detectors complying with BS EN 50291-1: 2010 (Type A)

with fixed wiring (not plug in types) may be used as an

alternative, provide they are fitted with a sensor failure

warning device.

British Telecom outlet (450mm above FFL)

Television point (450mm above FFL)

All electric installations to be

designed, installed and tested in

accordance with BS 7671: 2008.

A minimum of 50% of the fixed light fittings

and lamps to be installed must be of low

energy type designation.

LEGEND


DRAWING STATUS:


TITLE: ELECTRIC + FIRE PLAN

E L E V T I O N


DATE: DEC 2016

SCALE: 1:100 @ A3

DRAWN:

CHECKED: TC

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108001_5

P1

PLANNING

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02m 2m 4m 6m 8m 10m

1:100

N

Electric supply in

AutoCAD SHX Text

mef

AutoCAD SHX Text

mef

AutoCAD SHX Text

mef

AutoCAD SHX Text

mef

AutoCAD SHX Text

BT

AutoCAD SHX Text

TV

AutoCAD SHX Text

TV

AutoCAD SHX Text

BT

AutoCAD SHX Text

mef

450mm diameter polydrop inspection chamber

(max. depth 900mm) Class C CI Cover

100mm diameter rainwater pipe with access pipe

(access hatch at the top of every bend at base of

soil stacks and rainwater pipes)

Rodding eye terminal

110mm uPVC drains laid to minimum fall 1:60

LEGEND

RWPRWP

RWP

RWPRWP RWP RWP

SVP

SVP

SVP

SVP

SVP

SVP

IC

RE

RE

RE

IC

IC

RWP

Foul water drainage

Surface water

drainage


DRAWING STATUS:


TITLE: WATER SUPPLY + DRAINAGE PLAN

E L E V T I O N


DATE: DEC 2016

SCALE: 1:100 @ A3

DRAWN:

CHECKED: TC

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108001_6

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02m 2m 4m 6m 8m 10m

1:100

N

Water supply in


DRAWING STATUS:


TITLE: GRANT STREET ELEVATION

E L E V T I O N


DATE: DEC 2016

SCALE: 1:50 @ A3

DRAWN:

CHECKED: TC

EB

108001_7

P1

PLANNING

V

0 1m 2m 3m 4m 5m1m

1:50

Ground Level

0

First Floor

3750

Ridge Height

8780


DRAWING STATUS:


TITLE: BROWN STREET ELEVATION

E L E V T I O N


DATE: DEC 2016

SCALE: 1:50 @ A3

DRAWN:

CHECKED: TC

EB

108001_8

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PLANNING

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0 1m 2m 3m 4m 5m1m

1:50

Ground Level

0

Ridge Height

6268


DRAWING STATUS:


TITLE: MWH SECTION DETAILS

E L E V T I O N


DATE: NOV 2016

SCALE: 1:10/1:50 @ A3

DRAWN:

CHECKED: TC

EB

108001_9

P1

PLANNING

0 1m 2m 3m 4m 5m1m

1:50

V

MWH Roof (1:10)

6mm Slate Roof Tiles

25mm C24 Timber Battens

25mm C24 Counter Battens

- Visqueen FB Vapour Barrier

---------

50mm Celotex FR5000 Insulation (0.21W/m²K)

60mm Rockwool Sound Insulation

100mm SuperFOIL SF60 (0.13W/m²K) with service cavity

---------

2x12.5mm Plasterboard with scrim tape (for 60mins. fire protection)

MWH Ground Floor (1:10)

20mm Floor Finish

50mm Concrete Screed

100mm Concrete Slab using 50% GGBS

- Underfloor Heating System attached to insulation board

150mm Celotex CL5000 Underfloor Insulation Board (0.21 W/m²K)

- Visqueen Ecomembrane DPM

50mm Ecosand Binding

- Hardcore to Structural Engineer's specifications

MWH Wall (1:10)

20mm Render (Not in view)

600mm Stone


50mm Celotex RS5000 Insulation Board (0.20 W/m²K) between timber studs @ 600mm centres

60mm Rockwool Sound Insulation between timber studs @ 600mm centres

100mm SuperFOIL SF60 (0.13W/m²K) with service cavity between 50mm timber studs @ 600mm centres


MWH Intermediate Floor (1:10)


70mm Timber Batten placed with 50mm Rockwool Sound Insulation

253mm Pasquill Posi-Joist

®

placed with 50mm Celotex FI5000 Insulation (0.21W/m²K)


Posi-Joist

®

attached to I-Beam for stability + bolted to stonewall

0 1000mm800mm600mm400mm200mm200mm

1:10

MWH Critical Section (1:50)

A DEC 2016EDIT VALLEY GUTTER BETWEEN MWH & EXTENSION


DRAWING STATUS:


TITLE: EXTENSION SECTION DETAILS

E L E V T I O N


DATE: NOV 2016

SCALE: 1:10/1:50 @ A3

DRAWN:

CHECKED: TC

EB

108001_10

P1

PLANNING

0 1m 2m 3m 4m 5m1m

1:50

V

Extension Roof (1:10)

50mm Corrugated Aluminium Sheeting

- Vapour Barrier



50mm Celotex RS5000 Insulation Board (0.21 W/m²K)

150mm Walltite

®

CL100 Insulation (0.13 W/m²K)

160mm IPE 160

60mm Rockwool

®

Sound Insulation Slab

2x12.5mm Plasterboard (for 60mins. fire protection)

Extension Wall (1:10)

- Zinc Gutter

10mm Corrugated Aluminium Sheeting

- Vapour Barrier



Visqueen Ecomembrane DPM

15mm OSB Sheathing

50mm Celotex RS5000 Insulation Board (0.20 W/m2K)

between timber studs @ 600mm centres

60mm Rockwool Sound Insulation between timber studs

@ 600mm centres

100mm SuperFOIL SF60 (0.13W/m²K) with service cavity

between 50mm timber studs @ 600mm centres

2x12.5mm Plasterboard (for 60mins. fire protection)

Extension Floor (1:10)

20mm Floor Finish

50mm Concrete Screed

100mm Steel Reinforced Concrete Slab using 50% GGBS

150mm Celotex CL5000 Underfloor Insulation Board (0.21 W/m²K)


50mm Ecosand Binding

- Hardcore to Structural Engineer's specifications

0 1000mm800mm600mm400mm200mm200mm

1:10

Extension Critical Section (1:50)

A DEC 2016EDIT VALLEY GUTTER BETWEEN MWH & EXTENSION


DRAWING STATUS:


TITLE: OPENING DETAILS

E L E V T I O N


DATE: NOV 2016

SCALE: 1:5 @ A3

DRAWN:

CHECKED: TC

EB

108001_11

P1

PLANNING

V

0 500mm100mm 200mm 300mm 400mm100mm

1:5

MWH Sash Windows (1:5)

B-B : Window Jamb

A-A : Head + Cill

A

B B

MWH Front Door (1:5)

B-B : Door Jamb

A-A : Head + Cill

A

A

B B

Extension Casement Windows (1:5)

Extension Roof Windows - Velux

®

(1:5)


DRAWING STATUS:


TITLE: THERMAL BRIDGING + AIR TIGHTNESS

E L E V T I O N


DATE: NOV 2016

SCALE: 1:100 @ A3

DRAWN:

CHECKED: TC

EB

108001_12

P1

PLANNING

V

Thermal Bridging

Junctions and connections within a building envelope can typically provide a

route for heat loss, which must be reduced, or if possible, eliminated. The

diagram opposite illustrates common areas in a building where thermal bridging

may occur. Careful design and implementation is required to ensure that these

particular areas do not create unnecessary heat loss paths.

The proposed design aims to reduce thermal bridging in the building. The

insulation is added in response to avoid any penetration from external weather

and prevent heat loss internally. It is important to focus in extending the

insulation around the MWH in the roof, walls, and floor to prevent any heat loss

from the building.

Air Tightness

A high level of air tightness within the building reduces the heating demand and

prevents moisture-laden air from entering the fabric. Achieving air tightness can

be achieved by using airtight membranes/barriers within the building elements

such as a vapour barrier layer. Where layers could be interrupted, like windows,

propriety tape can be attached to the barrier layer ensuring that around

openings continue to be air tight.

Ensuring the building envelope is air tight to reduce the risk of structural

damage, careful design and installation of components such as windows and

doors is imperative. It is aimed to not allow air to flow randomly through walls of

the envelope. This is important because changing temperatures of air flow is not

sufficient to provide consistently air quality for both the occupant and the

building itself. Poor acoustic insulation and heat loss are further disadvantages.

A new ventilation system and acoustic insulation is added to the

extension/sports hall.

02m 2m 4m 6m 8m 10m

1:100

Design

Merkinch Welfare Hall Technical Details