Water Booklet Detroit by Akoaki

A T R O O L E DETROIT

W E B K T

DETROIT

AINWATER

Contents Introduction .................................... 07 Measures ........................................ 20 Implements .................................... 46 Farmers Almanac .......................... 88 Other resources ..............................96

INTRODUCTION

Detroit’s name, French for ‘strait,’ points to the critical role water has always played in shaping the city’s identity. Located on the Detroit River, which connects directly into the Great Lakes Watershed, Detroit’s water management has from the city’s inception proved critical to the quality of the water resources in the region, particularly those of Lake Erie. Today, with sewage overflow from storm water exacerbating pressures on an already fatigued infrastructural system, Detroit has looked for ways to alleviate problems of water contamination, incentivizing green infrastructure and low impact development to mitigate large-scale problems one parcel at a time. Detroit’s plan is potent but also dependent on citizen implementation for its success. That’s where this little guide comes in. You don’t need to be an engineer or scientist to help relieve the city’s storm water challenges. You just need to know some basic facts about your parcel and your options to make design choices that are right for you and great for the environment. We’ve tried to stay graphic and illustrate all the ideas with simple tools. If you’re intrigued, want to learn more, or have questions not addressed in this brief introduction to storm water management, you’ll find additional resources at the end of the booklet. Individually, these solutions might seem humble, but if we all do our part, terrific impact can be made on our city and the region’s water resources.

Detroit

MICHIGAN

Where do you live?

Where does your rain go?

â&#x20AC;&#x153;Water that is everywhere before it is somewhere; water that is in rain before it is in rivers, soaks before it flows, spreads before it gathers, blurs before it clarifies; water that is ephemeral, transient, uncertain, interstitial, chaotic, omnipresent.â&#x20AC;? Design in the Terrain of Water, Anuradha Mathur , Dilip da Cunha

AVERAGE Temperature | Precipitation

Month

Low

High

Jan Feb Mar Apr May Jun

17.8°F 31.1°F 20.0°F 34.4°F 28.5°F 45.2°F 38.4°F 57.8°F 49.4°F 70.2°F 58.9°F 79.0°F

Preci

Month

Low

High

1.91in. 1.88in. 2.52in. 3.05in. 3.05in. 3.55in.

Jul Aug Sept Oct Nov Dec

63.6°F 83.4°F 62.2°F 81.4°F 54.1°F 73.7°F 42.5°F 61.2°F 33.5°F 47.8°F 23.4°F 35.9°F

Precip 3.16in. 3.10in. 3.27in. 2.23in. 2.66in. 2.51in.

DETROIT

Extremes

Averages

The feeling of home.

Hottest Month Coldest Month Wettest Month Driest Month

July January June February

83.4Â°F 17.8Â°F 3.55 inches 1.88 inches

Hottest Day Coldest Day Wettest Day

102.9 F - Jun 22, 1988 -21.4 F - Jan 21, 1984 2.8 inch - Aug 17, 1974

8.73" 8.58" 16.13" 6.50"

Stormwater Events

W Sp Su F

02 05 10 25

+07.36"

2014 Precipitation

W Sp Su F

7.17" 8.95" 12.78" 8.76" 02 05 10 25

- 2.21"

+0.14"

7.33" 8.34" 11.81" 5.24"

31.42"

- 01.16"

2015 Precipitation

W Sp Su F

5.83" 8.96" 10.25" 5.33" 02 05 10 25

- 01.16"

+01.43"

9.82" 6.18" 7.56" 10.45" 02 05 10 25

2012 Precipitation 33.61"

+01.03"

7.56" 6.83" 7.24" 5.50"

Stormwater Events

02 05 10 25

34.01"

W Sp Su F

7.94" 14.61" 10.77" 14.43"

31.42"

4.98" 12.44" 10.23" 5.96"

Stormwater Events

02 05 10 25

+01.03"

2008 Precipitation

W Sp Su F

2011 Precipitation

W Sp Su F

02 05 10 25

W Sp Su F

02 05 10 25

32.72"

33.61"

Stormwater Events

- 2.05"

3.95" 08.64" 11.97" 7.73"

30.37"

6.44" 10.36" 7.90" 5.83"

2004 Precipitation

02 05 10 25

2016 Precipitation 34.76" W Sp Su F

5.53" 9.37" 8.49" 11.37"

Stormwater Events

2013 Precipitation 39.94"

30.53"

Stormwater Events

02 05 10 25

- 01.16"

2007 Precipitation

W Sp Su F

2010 Precipitation

W Sp Su F

6.15" 12.09" 10.60" 5.33"

Stormwater Events

W Sp Su F

+01.93"

+06.71"

9.61" 10.54" 10.38" 8.76"

Stormwater Events

2009 Precipitation 34.51"

2006 Precipitation

W Sp Su F

02 05 10 25

W Sp Su F

02 05 10 25

39.29"

31.42"

Stormwater Events

8.94" 4.25" 8.66" 8.76"

Stormwater Events

W Sp Su F

-04.27"

2003 Precipitation

Stormwater Events

2005 Precipitation

- 2.05"

3.72" 8.26" 9.45" 9.99"

Stormwater Events

02 05 10 25

28.31"

30.53" W Sp Su F

5.82" 7.85" 7.44" 13.40"

Stormwater Events

W Sp Su F

+01.93"

Stormwater Events

34.51"

2002 Precipitation

Stormwater Events

2001 Precipitation

02 05 10 25

+02.18"

PRECIPITATION PATTERN CHANGES

How much rain are we talking about?

Left: precipitation data from 2001—2016. How have rainfall patterns changed and what should we prepare for?

Total Seasonal rainfall Winter Spring Summer Fall

The average annual rainfall in Detroit is 32.4” over the base period (1953 - 1999). Since 2001, the average rainfall is 34.5“, which is almost 1.3 inches more.

Driest year

jun

may

apr

mar

3.10”

2.56”

2.68”

3.10”

0.82”

3.03”

jun

may

apr

mar

feb

jan

5.39”

5.61”

3.61”

3.60”

1.54”

0.94”

Average Spring frost date: 10 May

Wettest year

1.31”

1.72”

2.15”

2.96”

feb

jan

2011

1.91”

3.00”

jun

may

apr

mar

feb

jan

WEATHER DYNAMICS

100˚ F

80˚ F

60˚ F

40˚ F

20˚ F

2007

Average year

2012

Daily Maximum Temperature

2.65”

0.72”

2.31”

2.47”

2.26”

3.67”

dec

nov

oct

sep

aug

jul

3.48”

1.78”

2.01”

1.45”

6.61”

2.10”

dec

nov

oct

sep

aug

jul

2.80”

6.00”

Average Fall frost date: 04 October

2.15”

6.28”

2.16”

7.67”

dec

nov

oct

sep

aug

jul

PRECIPITATION

Daily Minimum Temperature

jun

may

apr

jan

feb

mar

WEATHER DYNAMICS

rh- 55.1%

2011 90

125 54

3.60”

3.61”

5.61”

5.39”

87 88 39 51

Wettest year

Spring frost date 10 May

1.54”

3.03”

100

0.82”

3.10”

2.68”

rh- 52.4%

rh- 58.8%

rh- 47.0%

rh- 49.6%

2007 65 150

2.56”

jun

may 63

apr A

jan

feb

mar

Average year

Driest year

1.91”

2.96”

2.15”

rh- 46.25%

10 3.00”

rh- 53.3%

2012 73 142

1 1.72”

7 7.67”

2.16”

6.28”

dec

nov F

84 57

9 2.15”

6.00”

2.80”

2.01”

1.78”

3.48”

rh- 69.8%

nov

rh- 65.8%

2.47”

Dry Days

dec

oct H

95 59

2.26”

Wet Days

1.45”

97 59

89 52

rh- 59.6%

73 84 43 53

rh- 61.0%

rh- 62.8%

rh- 63.5%

sep

aug 62

3.67”

rh- 55.1%

101

rh- 57.1%

E rh- 49.6%

1.31”

6.61”

jul 98

rh- 57.8%

2.10”

rh- 53.4%

rh- 53.1%

3.10”

rh- 49.1%

rh- 52.0%

91 80 54 51

rh- 53.2%

rh- 49.6%

Fall frost date 04 October

0.94”

oct

sep D

rh- 72.7%

rh- 73.5%

rh- 62.5%

rh- 64.8%

rh- 56.6%

jul

aug

PRECIPITATION

2.31”

Stress Days

0.72”

2.65”

Growing degree days

WEATHER DYNAMICS INTRODUCTION

The three graphs compare an average year of temperature and rainfall for the Detroit area with a wet year (2011) and a dry year (2012). Storm events are predicted to become more irregular, but stronger.

Growing Degree Days

This is a measurement that can be useful for planning the growth and development of your plants.

rh- 46.25%

These are days when the temperature is high and the amount of precipitation is low. rh- 53.3%

Stress Days

84 57

dec

oct E

sep

aug

jul

jun

may

apr

mar

feb

jan

nov

2.15”

2.96”

3.60”

3.61”

5.61”

5.39”

0.94”

7.67”

2.16”

6.28”

rh- 72.7%

2.15”

6.00”

2.80”

2.01”

1.78”

3.48”

91 80 54 51

87 88 39 51

Fall frost date 04 October

rh- 73.5%

Spring frost date 10 May

1.54”

rh- 62.5%

125

rh- 56.6%

rh- 64.8%

rh- 55.1%

2011 90

73 84 43 53

89 52

97 59

95 59

dec

oct

nov

rh- 69.8%

rh- 59.6%

rh- 61.0%

101

1.45”

sep

aug

6.61”

jul 51

rh- 62.8%

2.10”

rh- 57.8%

rh- 53.1%

rh- 49.1%

rh- 52.0%

3.10”

rh- 49.6%

jun

may B

2.56”

rh- 53.2%

rh- 52.4%

2.68”

apr

feb

jan

3.10”

mar

0.82”

rh- 58.8%

10 3.03”

100

rh- 47.0%

65 150

rh- 49.6%

2007

3.00”

1.91”

2.96”

2.15”

1.72”

1.31”

3.67”

2.26”

9 2.47”

rh- 65.8%

rh- 63.5%

rh- 55.1%

rh- 57.1%

rh- 49.6%

rh- 53.4%

rh- 46.25%

rh- 53.3%

2012 73 142

2.31”

0.72”

2.65”

10 1.72”

rh- 49.6%

rh- 53.4%

PRECIPITATION SUBTITLE

1.31”

Over ten days, the highest temperature was 91˚F, while the lowest was 51˚F. The brackets indicate periods where, with the combined daily temperature and lack of rainfall, unirrigated crops cannot be supported.

When it rains...

Our systems are designed to hide, drain and remove the water as soon as possible. Once rainwater hits the ground and runs off, it picks up urban pollutants and is transformed into stormwater. Untreated stormwater can cause flooding, harms aquatic habitats and could also pollute the drinking water supply.

We can manage...

We can re-imagine our cities where we disconnect stormwater from sewer systems to treat and store rainwater where it falls. We can recharge the ground water, harvest roof water and improve the quality of all our water by integrating stormwater management techniques into our homes.

MAIN TITLE

CAN YOUR HOME CONTRIBUTE

SUBTITLE

TO DETROITâ&#x20AC;&#x2122;S STORMWATER SOLUTION?

LOT

HOUSE

STORE

Unpacking your parcel

ROOF AREA

D PLOT AREA

B C A

AREA CALCULATION

Measuring your parcel

PLOT AREA = A X B ROOF AREA = C X D CONCRETE PAVING = E X F TOTAL IMPERVIOUS AREA = [ ROOF AREA (E X F) + CONCRETE PAVING (G X H)]

RAINFALL

ROOF AREA

D PLOT AREA

B C A

VOLUME CALCULATION

How much rain can you collect?

RAINFALL = XYZ INCHES ROOF AREA = C X D GARDEN PLOT AREA = E X F TOTAL RAINFALL ON ROOF = [ ROOF AREA (E X F) X RAINFALL (XYZ INCHES / 12)] Rainfall value can be a weekly,monthly or yearly value. Refer pg 90-91 29

T1 T2 VACANT LOT

Pick your Parcel

SINGLE FAMILY HOUSE

T3 COMMERCIAL

WHATâ&#x20AC;&#x2122;S YOUR TYPE

T 1.1 Vegetated Landscape

T 1.2 Impervious patches > 25%

T 1.3 Impervious patches >75%

T 2.1 Single Family House A

T 2.2 Single Family House B

T 2.3 Single Family House C

T 3.1 Commercial Type A

T 3.2 Commercial Type B

T 3.3 Commercial Type C

Single family, regardless of shape of roof, but the area of the house.

IMPORTANT NOTES

1 ft = 12 inches 1 sq ft = 144 sq in 1000 sq ft = 0.023 acres 1 cu ft = 7.48052 gallon 1 Mcf = 1000 cu ft

T1.1

WHATâ&#x20AC;&#x2122;S YOUR TYPE

30 f

Vegetated Landscape

how much acreage? 3000 Sq Ft

Total Plot Area | 3000 Sq Ft Impervious Area | 0 Sq Ft or less than 870 Sq Ft acres Stormwater Calculations Drainage Charge = Impervious Area x $ 661 / Imp. Acre = 0.00 x 750 = $0.0 Monthly

$ 0 Yearly

Using green stormwater infrastructure to reduce 20 percent of storm water runoff from major roads in the City of Detroit can reduce treatment costs by approximately $2 million annually. Property owners could reduce drainage costs by up to 80%. Note : Parcels with less than 0.02 acres (871 sqft) of impervious area are exempt from drainage charges. Please refer [http://arcg.is/29KWCpY] to confirm city assessed impervious cover. 33

T1.2

Impervious patches = 30%

30 f

Alter the numbers

871 Sq Ft

Total Plot Area | 3000 Sq Ft Impervious Area | 870 Sq Ft Stormwater Calculations Drainage Charge = Impervious Area x $ 750 / Imp. Acre = 0.02 x 750 = $15 Monthly

$ 180 Yearly

Max 80% Credits | 40% Annual Volume of Flow | 40% Peak Flow rate $ 36 Yearly

If able to attain Max Credits up to 80% Drainage Charge

Note : Parcels with less than 0.02 acres (871 sqft) of impervious area are exempt from drainage charges. Please refer [http://arcg.is/29KWCpY] to confirm city assessed impervious cover. 34

T1.3

WHATâ&#x20AC;&#x2122;S YOUR TYPE

30 f

Impervious patches > 75%

3000 Sq Ft

Total Plot Area | 3000 Sq Ft Impervious Area | 3000 Sq Ft Stormwater Calculations Drainage Charge = Impervious Area x $ 750 / Imp. Acre = 0.068 x 750 = $51 Monthly

$ 612 Yearly

Max 80% Credits | 40% Annual Volume of Flow | 40% Peak Flow rate $ 122 Yearly

If able to attain Max Credits up to 80% Drainage Charge

Note : Parcels with less than 0.02 acres (871 sqft) of impervious area are exempt from drainage charges. Please refer [http://arcg.is/29KWCpY] to confirm city assessed impervious cover. 35

T2.1

30 f

Single family house A

845 Sq Ft

115 Sq Ft

Total Roof Area | 960 Sq Ft

Stormwater Calculations Drainage Charge = Impervious Area x $ 750 / Imp. Acre = 0.02 x 750 = $15 Monthly

$ 180 Yearly

Max 80% Credits | 40% Annual Volume of Flow | 40% Peak Flow rate $ 36 Yearly

If able to attain Max Credits up to 80% Drainage Charge

Note : Parcels with less than 0.02 acres (871 sqft) of impervious area are exempt from drainage charges. Please refer [http://arcg.is/29KWCpY] to confirm city assessed impervious cover. 36

BUILDING TYPOLOGIES

Growing months Rain Water Collection Statistics All calculations done at 75% Water Collection Efficiency for the 30 weeks of the growing season.

May

April

Impervious Area | 960 Sq Ft

June

Total Plot Area | 3000 Sq Ft

Rain Water Collection Statistics

To purchase the water from DWSD, the cost would be: Water Collected $ 25.5 Annual Svc Fee $ 79.32 Yearly $104.85 Weight

Farming Area

8387 Pounds Storage should be designed for the maximum weekly collection capacity as an appropiate residential size.

Area on which farming possible only with rain water for 30 weeks 300 Sq feet 37

August

| 0 Gallons / wk | 1005 Gallons / wk | 280 Gallons | 8389 Gallons

September

Min Collection Max Collection Ave Collection Total Collection

October

All calculations done at 75% Water Collection Efficiency, as a reasonable efficiency rate for collecting water.

July

2015 Weekly Rainfall

1400

1200

800

1000

600

400

2015

200

Data value derived from http://www.noaa.gov/

Gal

Wk 1

153

Wk 2

377

Wk 3

215

Wk 4

Wk 5

503

Wk 6

292

Wk 7

Wk 8

Wk 9

943

Wk 10

229

Wk 11

781

Wk 12

319

Wk 13

866

Wk 14

121

Wk 15

319

Wk 16

144

Wk 17

Wk 18

566

Wk 19

215

Wk 20

Wk 21

1005

Wk 22

Wk 23

530

Wk 24

117

Wk 25

144

Wk 26

206

Wk 27

Wk 28

Wk 29

Wk 30

T2.2

30 f

Single family house B

1320 Sq Ft

Total Roof Area | 1320 Sq Ft

Stormwater Calculations Drainage Charge = Impervious Area x $ 750 / Imp. Acre = 0.03 x 750 = $22.5 Monthly

$ 270 Yearly

Max 80% Credits | 40% Annual Volume of Flow | 40% Peak Flow rate $ 54 Yearly

If able to attain Max Credits up to 80% Drainage Charge

Note : Parcels with less than 0.02 acres (871 sqft) of impervious area are exempt from drainage charges. Please refer [http://arcg.is/29KWCpY] to confirm city assessed impervious cover. 38

BUILDING TYPOLOGIES

Rain Water Collection Statistics All calculations done at 75% Water Collection Efficiency for the 30 weeks of the growing season.

May

April

Impervious Area | 1320 Sq Ft

June

Total Plot Area | 3000 Sq Ft

Rain Water Collection Statistics

To purchase the water from DWSD, the cost would be: Water Collected $ 35.1 Annual Svc Fee $ 79.32 Yearly $114.41 Weight

Farming Area

11533 Pounds Storage should be designed for the maximum weekly collection capacity as an appropiate residential size.

Area on which farming possible only with rain water for 30 weeks 412 Sq feet 39

August

| 0 Gallons / wk | 1382 Gallons / wk | 384 Gallons | 11534 Gallons

September

Min Collection Max Collection Ave Collection Total Collection

October

All calculations done at 75% Water Collection Efficiency, as a reasonable efficiency rate for collecting water.

July

2015 Weekly Rainfall

1400

1200

800

1000

600

400

2015

200

Data value derived from http://www.noaa.gov/

Gal

Wk 1

210

Wk 2

518

Wk 3

296

Wk 4

Wk 5

691

Wk 6

401

Wk 7

117

Wk 8

Wk 9

1296

Wk 10

315

Wk 11

1074

Wk 12

438

Wk 13

1191

Wk 14

167

Wk 15

438

Wk 16

197

Wk 17

Wk 18

778

Wk 19

296

Wk 20

Wk 21

1382

Wk 22

Wk 23

728

Wk 24

160

Wk 25

197

Wk 26

284

Wk 27

111

Wk 28

Wk 29

Wk 30

T2.3

30 f

Single family house C

860 Sq Ft

120 Sq Ft 10

Total Roof Area | 980 Sq Ft

Stormwater Calculations Drainage Charge = Impervious Area x $ 750 / Imp. Acre = 0.07 x 750 = $52.5 Monthly

$ 630 Yearly

Max 80% Credits | 40% Annual Volume of Flow | 40% Peak Flow rate $ 126 Yearly

If able to attain Max Credits up to 80% Drainage Charge

Note : Parcels with less than 0.02 acres (871 sqft) of impervious area are exempt from drainage charges. Please refer [http://arcg.is/29KWCpY] to confirm city assessed impervious cover. 40

BUILDING TYPOLOGIES

Rain Water Collection Statistics All calculations done at 75% Water Collection Efficiency for the 30 weeks of the growing season.

May

April

Impervious Area | 2938 Sq Ft

June

Total Plot Area | 6000 Sq Ft

Rain Water Collection Statistics

To purchase the water from DWSD, the cost would be: Water Collected $ 26.1 Annual Svc Fee $ 79.32 Yearly $105.38 Weight

Farming Area

8562 Pounds Storage should be designed for the maximum weekly collection capacity as an appropiate residential size.

Area on which farming possible only with rain water for 30 weeks 306 Sq feet 41

August

| 0 Gallons / wk | 1026 Gallons / wk | 285 Gallons | 8563 Gallons

September

Min Collection Max Collection Ave Collection Total Collection

October

All calculations done at 75% Water Collection Efficiency, as a reasonable efficiency rate for collecting water.

July

2015 Weekly Rainfall

1400

1200

800

1000

600

400

2015

200

Data value derived from http://www.noaa.gov/

Gal

Wk 1

156

Wk 2

385

Wk 3

220

Wk 4

Wk 5

513

Wk 6

298

Wk 7

Wk 8

Wk 9

962

Wk 10

234

Wk 11

797

Wk 12

325

Wk 13

884

Wk 14

124

Wk 15

325

Wk 16

147

Wk 17

Wk 18

577

Wk 19

220

Wk 20

Wk 21

1026

Wk 22

Wk 23

541

Wk 24

119

Wk 25

147

Wk 26

211

Wk 27

Wk 28

Wk 29

Wk 30

T3.1

Commercial type A

30 f

5400 Sq Ft

Total Roof Area | 3000 Sq Ft

Stormwater Calculations Drainage Charge = Impervious Area x $ 750 / Imp. Acre = 0.07 x 750 = $52.5 Monthly

$ 630 Yearly

Max 80% Credits | 40% Annual Volume of Flow | 40% Peak Flow rate $ 126 Yearly

If able to attain Max Credits up to 80% Drainage Charge

Note : Parcels with less than 0.02 acres (871 sqft) of impervious area are exempt from drainage charges. Please refer [http://arcg.is/29KWCpY] to confirm city assessed impervious cover. 42

BUILDING TYPOLOGIES SUBTITLE

Rain Water Collection Statistics All calculations done at 75% Water Collection Efficiency for the 30 weeks of the growing season.

May

April

Impervious Area | 3000 Sq Ft

June

Total Plot Area | 3000 Sq Ft

Rain Water Collection Statistics

To purchase the water from DWSD, the cost would be: Water Collected $ 83.16 Annual Svc Fee $ 79.32 Weight

Farming Area

26235 Pounds Storage should be designed for the maximum weekly collection capacity as an appropiate residential size.

Area on which farming possible only with rain water for 30 weeks 900 Sq feet 43

August

| 0 Gallons / wk | 3142 Gallons / wk | 874 Gallons | 26215 Gallons

September

Min Collection Max Collection Ave Collection Total Collection

October

All calculations done at 75% Water Collection Efficiency, as a reasonable efficiency rate for collecting water.

July

2015 Weekly Rainfall

3500

3000

2000

2500

1500

1000

2015

500

Data value derived from http://www.noaa.gov/

Gal

Wk 1

477

Wk 2

1178

Wk 3

673

Wk 4

Wk 5

1571

Wk 6

912

Wk 7

266

Wk 8

112

Wk 9

2945

Wk 10

715

Wk 11

2441

Wk 12

996

Wk 13

2707

Wk 14

379

Wk 15

996

Wk 16

449

Wk 17

168

Wk 18

1767

Wk 19

673

Wk 20

126

Wk 21

3142

Wk 22

Wk 23

1655

Wk 24

365

Wk 25

449

Wk 26

645

Wk 27

252

Wk 28

Wk 29

Wk 30

T3.2

Commercial type B

30 f

5400 Sq Ft

Total Roof Area | 5400 Sq Ft

Stormwater Calculations Drainage Charge = Impervious Area x $ 750 / Imp. Acre = 0.1 x 750 = $75 Monthly

$ 900 Yearly

Max 80% Credits | 40% Annual Volume of Flow | 40% Peak Flow rate $ 180 Yearly

If able to attain Max Credits up to 80% Drainage Charge

Note : Parcels with less than 0.02 acres (871 sqft) of impervious area are exempt from drainage charges. Please refer [http://arcg.is/29KWCpY] to confirm city assessed impervious cover. 44

BUILDING TYPOLOGIES SUBTITLE

Rain Water Collection Statistics All calculations done at 75% Water Collection Efficiency for the 30 weeks of the growing season.

May

April

Impervious Area | 5400 Sq Ft

June

Total Plot Area | 6000 Sq Ft

Rain Water Collection Statistics

To purchase the water from DWSD, the cost would be: Water Collected $ 149.68 Annual Svc Fee $ 79.32 Weight

Farming Area

47215 Pounds Storage should be designed for the maximum weekly collection capacity as an appropiate residential size.

Area on which farming possible only with rain water for 30 weeks 1620 Sq feet 45

August

| 0 Gallons / wk | 5655 Gallons / wk | 1573 Gallons | 47186 Gallons

September

Min Collection Max Collection Ave Collection Total Collection

October

All calculations done at 75% Water Collection Efficiency, as a reasonable efficiency rate for collecting water.

July

2015 Weekly Rainfall

6000

5000

4000

3000

2000

2015

1000

Data value derived from http://www.noaa.gov/

Gal

Wk 1

858

Wk 2

2121

Wk 3

1212

Wk 4

Wk 5

2828

Wk 6

1641

Wk 7

480

Wk 8

202

Wk 9

5302

Wk 10

1288

Wk 11

4393

Wk 12

1793

Wk 13

4873

Wk 14

682

Wk 15

1793

Wk 16

808

Wk 17

303

Wk 18

3181

Wk 19

1212

Wk 20

227

Wk 21

5655

Wk 22

Wk 23

2979

Wk 24

656

Wk 25

808

Wk 26

1161

Wk 27

454

Wk 28

101

Wk 29

Wk 30

151

T3.3

30 f

Commercial type C

5400 Sq Ft

30 f

5400 Sq Ft

Total Roof Area | 3000 Sq Ft

Stormwater Calculations Drainage Charge = Impervious Area x $ 750 / Imp. Acre = 0.14 x 750 = $105 Monthly

$ 1260 Yearly

Max 80% Credits | 40% Annual Volume of Flow | 40% Peak Flow rate $ 252 Yearly

If able to attain Max Credits up to 80% Drainage Charge

Note : Parcels with less than 0.02 acres (871 sqft) of impervious area are exempt from drainage charges. Please refer [http://arcg.is/29KWCpY] to confirm city assessed impervious cover. 46

BUILDING TYPOLOGIES SUBTITLE

Rain Water Collection Statistics All calculations done at 75% Water Collection Efficiency for the 30 weeks of the growing season.

May

April

Impervious Area | 6000 Sq Ft

June

Total Plot Area | 6000 Sq Ft

Rain Water Collection Statistics

To purchase the water from DWSD, the cost would be: Water Collected $ 83.16 Annual Svc Fee $ 79.32 Yearly $162.48 Weight

Farming Area

26235 Pounds Storage should be designed for the maximum weekly collection capacity as an appropiate residential size.

Area on which farming possible only with rain water for 30 weeks 900 Sq feet 47

August

| 0 Gallons / wk | 3142 Gallons / wk | 874 Gallons | 26215 Gallons

September

Min Collection Max Collection Ave Collection Total Collection

October

All calculations done at 75% Water Collection Efficiency, as a reasonable efficiency rate for collecting water.

July

2015 Weekly Rainfall

6000

5000

4000

3000

2000

2015

1000

Data value derived from http://www.noaa.gov/

Gal

Wk 1

858

Wk 2

2121

Wk 3

1212

Wk 4

Wk 5

2828

Wk 6

1641

Wk 7

480

Wk 8

202

Wk 9

5302

Wk 10

1288

Wk 11

4393

Wk 12

1793

Wk 13

4873

Wk 14

682

Wk 15

1793

Wk 16

808

Wk 17

303

Wk 18

3181

Wk 19

1212

Wk 20

227

Wk 21

5655

Wk 22

Wk 23

2979

Wk 24

656

Wk 25

808

Wk 26

1161

Wk 27

454

Wk 28

101

Wk 29

Wk 30

151

MAIN TITLE

LET’S RE-IMAGINE DETROIT’S

SUBTITLE

RELATIONSHIP TO RAINWATER

FLOW CONTROL

Stormwater flow controls are passive, non-mechanical devices used to control stormwater flows entering or exiting stormwater treatment or detention systems to a designed rate.

DETENTION

A stormwater management practice that temporarily stores water before discharging into a surface-water body. Primarily used to reduce flood peaks.

RETENTION

A stormwater management practice that captures stormwater runoff and does not discharge directly to a surface water body. The water is â&#x20AC;&#x153;dischargedâ&#x20AC;? by infiltration, transpiration and evaporation.

FILTRATION

Stormwater filters capture, temporarily store, and treat stormwater runoff by passing it through either an engineered or natural filter media and then returning it back to the storm drainage system.

INFILTRATION

Stormwater infiltration is the process by which rainfall and stormwater runoff flows into and through the subsurface soil.

TREATMENT

Stormwater treatment is the process of removing undesirable chemicals, biological contaminants, suspended solids and gases from water.

References - Low Impact development : a design manual for urban areas (UACDC) - Low Impact Development Manual for Michigan - Sustainable Sanitation and Water Management - Minnesota Urban Small Sites BMP Manual 51

Maximizing Credits

FC RT

FLOW CONTROL

DETENTION

FC 1 Flow Control Devices

RETENTION

FL 2 Surface Sand Filter

RT 1 Wet Vault

RT 2 Rainwater Harvesting

FL 4 Vegetated Wall

FL 3 Vegetated Roof

TREATMENT

IF 3 Rain Garden 54

TR 1 Bioswale

STORMWATER MANAGEMENT TYPOLOGIES

DT 1 Dry Swale

FL DT 2 Underground Detention

DT 3 Detention Pond

FILTRATION

IF RT 3 Retention Pond

FL 1 Filter Strip

INFILTRATION IF 1 Pervious Paving

TR 2 Constructed Wetland 55

IF 2 Infiltration Trench

FC1

Flow Control Devices

BUILDING TYPOLOGIES

T1 T2

Flow control devices are used to control stormwater flows entering or exiting stormwater treatment or detention systems to a designed rate. They reduce peak discharges, disperse concentrated stormwater flows. These devices are placed in areas where there is a large collection of stormwater. Flow control devices slow down the concentrated runoff and pipe discharge, BUILDINGsurface TYPOLOGIES thus preventing overflow, and erosion.

Function

T 1.1

Vegetated Landscape Used to reduce the flow of water

T 1.2 Impervious patches < 25%

T 1.3 Impervious patches > 75%

Cost

Relatively lower cost. Requires land grading for efficiency. BUILDING TYPOLOGIES

Maintenance Careful design and construction required to function properly. Trash and TT 1.22.1 T T1.32.2 T 2.3 removal needed. Impervious patches < 25% Impervious patches > 75% Single Family House A Single Family House B Single Family House C

T 1.1 sediment Vegetated Landscape

Sites Applicable

TT1.2 2.1 Impervious patches Single Family House<A25%

TT1.3 2.2 T 3.1 Impervious patches Single Family House Commercial Type >AB75%

TT 2.3 3.2 Single Family House Commercial Type BC

T 3.3 Commercial Type C

Stones reduce the speed of flow

Temporarily hold water

IMPLEMENTS

Various types of flow control devices include flow splitter, level spreader, mounds, checkdams, and splash blocks. The main aim is to slow down the water. They are generally located downstream where there is maximum concentration of water.

References - Low Impact Development Manual for Michigan - Sustainable Sanitation and Water Management - Minnesota Urban Small Sites BMP Manual Sources - Low Impact Development : a design manual for urban areas University of Arkansas Community Design Center (UACDC) , 2010

DT1

Dry Swale

A dry swale is a shallow, gently sloping channel with broad, vegetated, side slopes. Water flow is slowed by a series of check dams. It filters , attenuates, and detains stormwater runoff as it moves downstream. Dry swale, when combined with check dams and underdrains,detain stormwater, and increase infiltration. It is a cost effective way to convey water between buildings,landuses along BUILDING and TYPOLOGIES roadsides.

Function Detain stormwater runoff as it moves downstream. Good for detention / filtration and infiltration

T1 T2 T1 Cost

Low cost.

BUILDING BUILDING TYPOLOGIES TYPOLOGIES

Maintenance Regular inspection required to check erosion and removal of sediments and T 1.1 T 1.2 T 1.3 debris. Vegetated Landscape Impervious patches < 25% Impervious patches > 75%

Sites Applicable

2.1 TT1.11.1 Single Family House A Vegetated Vegetated Landscape Landscape

2.2 TT1.2 1.2 Single Family House<<B25% Impervious Impervious patches patches 25%

2.3 TT1.3 1.3 Single Family House>>C75% Impervious Impervious patches patches 75%

Small check dams

Pervious soil

IMPLEMENTS

10 years

to drainage pipes

Swales can be designed for 100 year storm water events, though the norm is up to 10 year. The water quality is optimized when the channel profile is two to eight foot maximum in bottom width, holding a four inch water volume depth. Dry swales can improve site aesthetics and provide wildlife habitat, depending on the type of grasses planted. References - Low Impact Manual for Michigan - Sustainable Sanitation and Water Management - Minnesota Urban Small Sites BMP Manual Sources - Low Impact Development : a design manual for urban areas University of Arkansas Community Design Center (UACDC) , 2010

DT2

Underground Detention

BUILDING TYPOLOGIES

Underground detention systems are an underground structure designed to manage excess stormwater runoff on a developed site, often in an urban setting. These storage systems store and slowly release runoff water, thus reducing the load on the main system. Some systems can infiltrate stormwater if the soil beneath is permeable. This system is employed in places where available surface area for ongrade storage is limited.

Function

T 1.1 To detain Vegetated Landscape

system.

T 1.2

T 1.3

Stormwater underground prior topatches its entrance into a conveyance Impervious patches < 25% Impervious > 75%

Cost Higher costs.

BUILDING TYPOLOGIES

Maintenance Inspection and sedimentation clean out.

T 2.1 Single Family House A

T 2.2 Single Family House B

T 2.3 Single Family House C

T 1.3 3.2 Impervious Commercialpatches Type B > 75%

T 3.3 Commercial Type C

Sites Applicable

T 1.2 3.1 Impervious Commercialpatches Type A< 25%

Impervious cover

Detention Cell

Pervious soil

IMPLEMENTS

to drainage pipes

Underground storage discharges water slowly and reduces the peak flow. Improved water quality is achieved by sedimentation, or the settling of suspended solids. Generally they are placed after filtration facilities to prevent excessive sedimentation.

DT3

Detention Pond

BUILDING TYPOLOGIES

A detention pond is a low lying area that is designed to temporarily hold a set amount of water while slowly draining to another location. . Detention ponds are designed to completely evacuate water from storm events, usually within 24 hours. BUILDING TYPOLOGIES

Function

T 1.1 VegetatedDetention Landscape

T 1.2

Impervious patches < 25% of water

T 1.3 Impervious patches > 75%

Cost Costs per acre are reduced when implemented at larger scales.

Maintenance Regular trash and sediment removal is required.

T 1.2 T 2.1 Impervious patches < 25% Single Family House A

T 1.3 T 2.2 Impervious patches > 75% Single Family House B

T 2.3 Single Family House C

T 2.3 T 3.2 Single Family House Commercial TypeCB

T 3.3 Commercial Type C

Sites Applicable

T 2.2 T 3.1 Single Family House Commercial TypeBA

Inlet Pipe

Detention Area

Metered Discharge outlet

IMPLEMENTS

They primarily provide runoff volume control reducing peak flows that cause downstream scouring and loss of aquatic habitat. Detention ponds do not provide infiltration, unless designed for specific soil types, and therefore best used within a network that provides biological treatment.

RT1

Wet Vault

BUILDING TYPOLOGIES

Wet Vaults are subterranean structures for stormwater runoff retention where a permanent pool is maintained. Wet vaults contribute to stormwater flow attenuation, as well as minor treatment. As a result of permanent water retention, wet vaults are able to remove more sediment than other subterranean storage devices, which drain completely.

Function

T 1.1 Vegetated Landscape Used

T 1.2

Impervious patches < 25% for retaining water.

T 1.3 Impervious patches > 75%

Cost High initial cost.

BUILDING TYPOLOGIES

Maintenance Requires special equipment for trash and sediment removal.

T 2.1 Single Family House A

T 2.2 Single Family House B

T 2.3 Single Family House C

T 1.3 3.2 Impervious Commercialpatches Type B > 75%

T 3.3 Commercial Type C

Sites Applicable

T 1.2 3.1 Impervious Commercialpatches Type A< 25%

Impervious Surface

Inlet Drain

Retention Vault

IMPLEMENTS

Wet vaults are used where there is minimum surface area for to implement biological methods. It provides runoff volume control, peak discharge reduction, sedimentation control and harvesting potential. Generally located upstream of overflow basins and downstream from filtration facilities.

RT2

Rainwater Harvesting

Rainwater harvesting involves collection, storage, and reuse of runoff from roofs. It reduces runoff volume and peak flows. Filtration and purification equipments should be installed if the water is reused for drinking purposes. Storage capacity can be designed as per the usage and as per the rainfall pattern. These units can also be interconnected. BUILDING BUILDING BUILDING TYPOLOGIES TYPOLOGIES TYPOLOGIES

Function Retention of water and reuse

T1 T1 T2 T2 Cost

Relatively lower cost.

Maintenance Seasonal cleaning and inspection required. Connections need to be carefully TT1.1T1.11.1 TT1.2 T1.21.2 TT1.3 T1.31.3 cleaned. Vegetated Vegetated Vegetated Landscape Landscape Landscape Impervious Impervious Impervious patches patches patches < <25% <25% 25% Impervious Impervious Impervious patches patches patches > >75% >75% 75%

Sites Applicable

TT2.1 T2.12.1 Single Single Single Family Family Family House House House AAA

TT2.2 T2.2 2.2 Single Single Single Family Family Family House House House BBB

TT2.3 T2.3 2.3 Single Single Single Family Family Family House House House CCC

Cistern

Gutter

IMPLEMENTS

BUILDING TYPOLOGIES BUILDING TYPOLOGIES

T 1.1 T 1.1 Vegetated Landscape Vegetated Landscape

T 1.2 T 1.2 Impervious patches < 25% Impervious patches < 25%

T 1.3 T 1.3 Impervious patches > 75% Impervious patches > 75%

T 2.1 T 2.1 Single Family House Single Family House AA

T 2.2 T 2.2 Single Family House Single Family House BB

T 2.3 T 2.3 50 gallons and Single Family House Single Family House CC

T 3.2 T 3.2 Commercial Type Commercial Type BB

References - Low Impact Development Manual for Michigan - Sustainable Sanitation and Water Management T 3.3 T 3.3 - Minnesota Urban Small Sites BMP Manual Commercial Type C Impact Development : a design manual for Commercial Type Sources -CLow urban areas University of Arkansas Community Design Center (UACDC) , 2010

T 3.1 T 3.1 Commercial Type Commercial Type AA

Rain Barrels are available in sizes of can be attached to each downspouts. Bigger cisterns/tanks can also be used to store rain water. These tanks can be placed above and below the ground. Storage devices can be reused and are modular in nature.

RT3

Retention Pond

BUILDING TYPOLOGIES

Retention ponds, a type of wet pond, are constructed stormwater ponds that retain a large quantity of water and have biological treatment that also treats the water. These ponds remove large amount of pollutants through sedimentation and natural processes. They are generally applied at bigger sites. Unlike detention ponds, another type of BUILDING wet pond, these are more permanent. TYPOLOGIES

Function

T 1.1 VegetatedRetention Landscape

T 1.2

T 1.3

Impervious patches < 25% Impervious patches > 75% and treatment of stormwater

Cost Relatively lower cost. Requires land grading.

Maintenance Careful design and construction required to function properly. Trash and T 2.3 of water required. Single Family House C

TT 1.22.1 TT 1.32.2 sediment removal needed. Aeration Impervious patches < 25% Impervious patches > 75% Single Family House A Single Family House B

Sites Applicable

TT 2.23.1 Single Family House B Commercial Type A

TT 2.33.2 Single Family House Commercial Type BC

T 3.3 Commercial Type C

Overflow spout

Emergent Plants

IMPLEMENTS

100 years 50 years 25 years

to drainage pipes

Retention ponds are best constructed in areas with low precipitation or where the soil is highly permeable. They are located downstream of catchment and runoff. Usually constructed at the lowest point of the site. Can be designed to store water for 100 year storm water events or more.

References - Low Impact Manual for Michigan - Sustainable Sanitation and Water Management - Minnesota Urban Small Sites BMP Manual Sources - Low Impact Development : a design manual for urban areas University of Arkansas Community Design Center (UACDC) , 2010

FL1

Filter Strip

BUILDING TYPOLOGIES

T1 T2

Filtration strip helps in filtration of water. It is a sloped surface that reduces the stormwater runoff flow thus increase the surface area in contact water and also the time that water stays in contact with ground. Filter strips use vegetation to reduce the speed of runoff, allowing suspended sediments and debris loads to drop out of the runoff flow. BUILDING TYPOLOGIES

Function

T 1.1

T 1.2

Vegetated Impervious patches Filter water before it Landscape enters the stormwater pipes.< 25%

T 1.3 Impervious patches > 75%

Cost

Relatively lower cost. Requires land grading for efficiency. BUILDING TYPOLOGIES

Maintenance Trash and sediment removal needed. Strip needs to be mowed frequency.

T 1.1 Vegetated Landscape

TT 1.22.1 Single Family House A Impervious patches < 25%

TT 1.32.2 Single Family House B Impervious patches > 75%

T 2.3 Single Family House C

T 1.3 T 2.23.1 Impervious patches Commercial Type >A Single Family House B75%

TT 2.33.2 Commercial Type BC Single Family House

T 3.3 Commercial Type C

Sites Applicable

T 1.2 2.1 Impervious patches Single Family House<A25%

Drainage Area

Permeable Soils

IMPLEMENTS

Filter strips are typically located parallel to an impervious surface such as parking lot, driveway or roadway. Generally these must be placed in areas where there is ample amount of sunshine so that they can dry out between rain events. It is important to minimize foot traffic or any disruption to the vegetation.

FL2

Surface Sand Filter

BUILDING TYPOLOGIES

T1 T2

Surface sand filter, also known as a filtration basin, utilizes sand surface as a filter that manages nutrient loads in the first runoff load. Generally used for smaller watershed runoff areas. It traps nitrates, phosphates, hydrocarbons, metals and various sediments. It also reduces the velocity of the runoff as water BUILDING flows through the filter. TYPOLOGIES

Function

T 1.1

T 1.2

Vegetated Impervious water patches < 25% Filters the first flushLandscape of runoff. Also detains

T 1.3 Impervious patches > 75%

Cost

Average cost.

BUILDING TYPOLOGIES

Maintenance Trash, pollutants and sediment removal needed regularly.

T 1.1 Vegetated Landscape

TT 1.22.1 Single Family House A Impervious patches < 25%

TT 1.32.2 Single Family House B Impervious patches > 75%

T 2.3 Single Family House C

T 1.3 T 2.23.1 Impervious patches Commercial Type >A Single Family House B75%

TT 2.33.2 Commercial Type BC Single Family House

T 3.3 Commercial Type C

Sites Applicable

T 1.2 2.1 Impervious patches Single Family House<A25%

FL3

IMPLEMENTS

Vegetated Roof

BUILDINGTYPOLOGIES TYPOLOGIES BUILDING TYPOLOGIES BUILDING

T1 T2

A green roof or living roof is a roof of a building that is partially or completely covered with vegetation and a growing medium, planted over a waterproofing membrane. Vegetated roofs collect rainwater at its source, slow its release, and reduce its volume through evapotranspiration from plants. Vegetated roofs also regulate building temperature through additional thermal insulation, reducing heating and cooling loads.

Function

T1.11.1 TT1.1

T1.2 1.2 TT1.2

Vegetated Landscape Impervious patches <25% 25% Vegetated Landscape Impervious patches Vegetated Landscape patches <<25% Filters , treats and detains water atImpervious the source.

T1.3 1.3 TT1.3 Impervious patches >75% 75% Impervious patches Impervious patches >>75%

Cost

Average cost. Waterproofing cost are higher.

Maintenance Regular inspection of the roof membrane, as well as routine vegetation T2.1 2.1 T2.2 2.2 T2.3 2.3 2.1 TT2.2 TT2.3 inspection isTTSingle required. SingleFamily FamilyHouse HouseAA SingleFamily FamilyHouse HouseBB SingleFamily FamilyHouse HouseCC Single Single

Single Family House A

Single Family House B

Single Family House C

T3.1 3.1 TT3.1 Commercial Type Commercial Type Commercial Type AAA

T3.2 3.2 TT3.2 Commercial Type Commercial Type Commercial Type BBB

T3.3 3.3 TT3.3 Commercial Type Commercial Type Commercial Type CCC

Sites Applicable

FL4

Vegetated Wall

A vegetated wall, also known as a living or green wall or vertical garden, is an extension of the building envelope covered with vegetation. Vegetated walls harvest water to reduce stormwater runoff loads. Roof water travels through the vegetated wall thus reducing the speed and increasing filtration. Vegetated walls also regulate building temperature through additional thermal insulation, reducing heating and BUILDING BUILDING BUILDING TYPOLOGIES TYPOLOGIES TYPOLOGIES cooling loads.

Function Filter water before it enters the stormwater pipes.

T1 T1 T2 T2 Cost

Cheaper to expensive techniques.

Maintenance Occasional watering and trimming is required depending on species. TT1.1T1.11.1 Vegetated Vegetated Vegetated Landscape Landscape Landscape

TT1.2 T1.21.2 Impervious Impervious Impervious patches patches patches < <25% <25% 25%

TT1.3 T1.31.3 Impervious Impervious Impervious patches patches patches > >75% >75% 75%

TT2.1 T2.12.1 Single Single Single Family Family Family House House House AAA

TT2.2 T2.2 2.2 Single Single Single Family Family Family House House House BBB

TT2.3 T2.3 2.3 Single Single Single Family Family Family House House House CCC

Sites Applicable

Irrigation

Planter Box Module

IMPLEMENTS

BUILDING TYPOLOGIES BUILDING TYPOLOGIES

T 1.1 T 1.1 Vegetated Landscape Vegetated Landscape

T 1.2 T 1.2 Impervious patches < 25% Impervious patches < 25%

T 1.3 T 1.3 Impervious patches > 75% Impervious patches > 75%

T 2.1 T 2.1 Single Family House Single Family House AA

T 2.2 T 2.2 Single Family House Single Family House BB

T 2.3 T 2.3 ofFamily network. They Single Family House Single House CC

T 3.2 T 3.2 Commercial Type Commercial Type BB

T 3.1 T 3.1 Commercial Type Commercial Type AA

Vegetated walls are located at the beginning are directly attached to the roof runoff. Their application ranges from small residential applications to larger commercial structures. Solar orientation for plants types and structural loads must be considered for better efficiency.

IF1

Pervious Paving

BUILDING TYPOLOGIES

Pervious pavement or permeable paving is designed to allow percolation or infiltration of stormwater through the surface into the soil below where the water is naturally filtered and pollutants are removed. They allow water to vertically flow through hard surfaces. A pervious paving system includes a subsurface base made of course aggregate for stormwater storage. It acts to reduce and distribute stormwater volume, encouraging groundwater infiltration.

T1 T2

Function

T 1.1

Vegetated Landscape Infiltrates water.

T 1.2 Impervious patches < 25%

T 1.3 Impervious patches > 75%

Cost

Cost varies as per area. Generally lower costs.

BUILDING BUILDING TYPOLOGIES TYPOLOGIES

Maintenance Vacuum-based sediment removal from paving is required periodically. Turf T 2.2 2.3 paver systemsT 2.1 need to be mowed and irrigated to maintain Tvegetation.

Single Family House A

Single Family House B

TT1.2 1.23.1 T Impervious patches Impervious patches 25% Commercial Type<<A25%

TT1.3 1.33.2 T Impervious patches Impervious patches 75% Commercial Type>> B75%

Single Family House C

Sites Applicable

TT1.11.1 Vegetated VegetatedLandscape Landscape

T 3.3 Commercial Type C

IF2

IMPLEMENTS

Infiltration Trench

BUILDING TYPOLOGIES

T1 T2

Infiltration trenches are linear ditches that collect rain water from adjacent surfaces, and their highly permeable soils allow the water to quickly seep into the ground. Infiltration trenches also reduce the amount of stormwater that would enters the sewer system and ultimately go to a treatment facility. It does this by storing the water in the soil, which acts as an underground BUILDING TYPOLOGIES reservoir, until it can percolate down and recharge the water table.

Function

T 1.1

T 1.2

T 1.3

< 25% Impervious Infiltrates andVegetated treats Landscape water before itImpervious enters patches the stormwater pipes. patches > 75%

Cost

Average to higher cost. Requires land grading for efficiency.

Maintenance Trash and sediment removal annually.

T 1.1 Vegetated Landscape

TT 1.22.1 Single Family House A Impervious patches < 25%

TT 1.32.2 Single Family House B Impervious patches > 75%

T 2.3 Single Family House C

TT 2.23.1 Commercial Type A Single Family House B

TT 2.33.2 Commercial Type BC Single Family House

T 3.3 Commercial Type C

Sites Applicable

T 2.1 Single Family House A

IF3

Rain Garden

Rain gardens are an easy and effective tool that we can use to help reduce stormwater runoff from residential properties. These gardens are strategically placed to intercept pollutant laden stormwater runoff until it can be fully absorbed into the ground. Their design allows the rain garden to serve almost as a bowl that collects water from downspouts or overland flow across a property. The water is BUILDING BUILDING BUILDING TYPOLOGIES TYPOLOGIES TYPOLOGIES then able to slowly infiltrate into the underlying soil.

Function Filter water before it enters the stormwater pipes.

T1 T1 T2 T2 Cost

Relatively lower cost. Requires land grading for efficiency.

Maintenance Trash and sediment removal needed. Strip needs to be mowed frequency. TT1.1T1.11.1 Vegetated Vegetated Vegetated Landscape Landscape Landscape

TT1.2 T1.21.2 Impervious Impervious Impervious patches patches patches < <25% <25% 25%

TT1.3 T1.31.3 Impervious Impervious Impervious patches patches patches > >75% >75% 75%

TT2.1 T2.12.1 Single Single Single Family Family Family House House House AAA

TT2.2 T2.2 2.2 Single Single Single Family Family Family House House House BBB

TT2.3 T2.3 2.3 Single Single Single Family Family Family House House House CCC

Sites Applicable

Roof water

Vegetation, permeable soil

Deep Berm

IMPLEMENTS

BUILDING TYPOLOGIES BUILDING TYPOLOGIES

T 1.1 T 1.2 T 1.1 T 1.2 to drainage pipespatches Vegetated Landscape Impervious patches < 25% Vegetated Landscape Impervious < 25%

T 1.3 T 1.3 Impervious patches > 75% Impervious patches > 75%

T 2.1 T 2.1 Single Family House Single Family House AA

T 2.2 T 2.2 Single Family House Single Family House BB

sandy soil for infiltration, and T 2.3 T 2.3 Single Family House Single Family House CC promote microbial activity. Native

T 3.2 T 3.2 Commercial Type Commercial Type BB

References - Low Impact Manual for Michigan - Sustainable Sanitation and Water Management T 3.3 T 3.3 - Minnesota Urban Small Sites BMP Manual Commercial Type C Impact Development : a design manual for Commercial Type Sources -CLow urban areas University of Arkansas Community Design Center (UACDC) , 2010

T 3.1 T 3.1 Commercial Type Commercial Type AA

Rain gardens combine layers of organic mulch to plants are recommended based upon their intrinsic synergies with local climate, soil, and moisture conditions without the use of fertilizers and chemicals. If the site allows, they should be located at least 10 feet away from buildings.

TR1

Bioswale

BUILDING TYPOLOGIES

Bioswale are linear, vegetated ditches which allow for the collection, conveyance, filtration and infiltration of stormwater. The can also be referred to as “grass swales,” “vegetated swales,” and also similar to “filter strips.” A bioswale replaces the traditional concrete gutter with an earthen one. The vegetation reduces the water’s velocity allowing for treatment and infiltration. Bioswale are usually located BUILDING TYPOLOGIES along roads, drives, or parking lots where the contributing acreage is less than five acres.

T1 T2

Function

T 1.1

T 1.2

T 1.3 Impervious patches > 75%

Vegetated Impervious patches Filter water before it Landscape enters the stormwater pipes.< 25%

Cost

Relatively lower cost. Requires land grading for efficiency.

BUILDING TYPOLOGIES

Maintenance Requires occasional removal of trash and pruning of vegetation.

T 1.1 Vegetated Landscape

T1 T3

TT 1.22.1 Single Family House A Impervious patches < 25%

TT 1.32.2 Single Family House B Impervious patches > 75%

T 2.3 Single Family House C

TT1.1 T 2.23.1 Vegetated Landscape Commercial Type A Single Family House B

TT1.2 T 2.33.2 Impervious patches Commercial Type<BC25% Single Family House

T 1.3 T 3.3 Impervious patches Commercial Type>C75%

Sites Applicable

T 2.1 Single Family House A

TR2

IMPLEMENTS

Constructed Wetland

Constructed wetlands are artificial marshes or swamps with permanent standing water that offer a full range of ecosystem services to treat polluted stormwater. They are wetland systems designed to maximize the removal of pollutants from stormwater runoff through settling and both uptake and filtering by vegetation. Constructed stormwater wetlands temporarily store runoff in relatively shallow BUILDING TYPOLOGIES pools that support conditions suitable for the growth of wetland plants.

Function Retention/filtration/infiltration/treatment

Cost High cost. Low maintenance cost.

Maintenance Requires removal of trash and sediment between two and ten years, and

T 1.2 T 1.3 semiannually during first three years. Impervious patches < 25% Impervious patches > 75%

Sites Applicable

T 2.2 Single Family House B

T 2.3 Single Family House C

MAIN TITLE

PLANNING TO FARM? A FEW

SUBTITLE

THINGS TO KEEP IN MIND...

FARMERâ&#x20AC;&#x2122;S ALMANAC

CROPS THAT YOU CAN GROW

Asparagus

Green Onions

Squash

Strawberry

Pepper

Garlic

Blueberries

Broccoli

Garlic

Tomatoes

Carrot

Onions

Kale

Cherry

Grapes

Cucumber

Peas

Lettuce

Cabbage

Pear

Spinach

Cauliflower

Squash small

Peach

DELICIOUS BUT DELICATE CROPS

Pepper

Tomatoes

Garlic

WATER LOVING PLANTS

Cucumber

Cabbage

Cauliflower

Peas

EASY TO GROW CROPS

Squash

Broccoli

Garlic

Carrot

Onions

LOW WATER DEMAND

Kale

Grapes

Spinach

jun

may A

apr

jan

feb

mar

WEATHER DYNAMICS

1.46”

1.35”

0.80”

2.61”

rh- 52.7%

rh- 57.62%

2015 75 140

5.55”

Calculation year

WK 01

WK 02

WK 03

WK 04

Average Temp | 45 Precipitation | 0.34”

Average Temp | 50 Precipitation | 0.84”

Average Temp | 53 Precipitation | 0.48”

Average Temp | 42 Precipitation | 0.00”

Water Demand @ 1” / week

WK 05

WK 06

WK 07

WK 08

Average Temp | 58 Precipitation | 1.12”

Average Temp | 65 Precipitation | 0.65”

Average Temp | 62 Precipitation | 0.19”

Average Temp |61 Precipitation | 0.08”

Water Demand @ 1” / week

Water Demand @ 1.5” / week

Water Demand @ 1.2” / week

Water Demand @ 1.1” / week

WK 09

WK 10

WK 11

WK 12

Average Temp | 62 Precipitation | 0.34”

Average Temp | 66 Precipitation | 0.34”

Average Temp | 70 Precipitation | 2.10”

Average Temp | 70 Precipitation | 0.51”

Water Demand @ 1.2” / week

Water Demand @ 1.6” / week

Water Demand @ 2” / week

WK 13

WK 14

WK 15

WK 16

Average Temp | 66 Precipitation | 1.74”

Average Temp | 67 Precipitation | 0.71”

Average Temp | 69 Precipitation | 1.93”

Average Temp | 73 Precipitation | 0.27”

Water Demand @ 1.6” / week

Water Demand @ 1.7” / week

Water Demand @ 1.9” / week

Water Demand @ 2.3” / week

5.33”

3.16”

1.30”

dec

nov I

rh- 57.7%

rh- 69.7%

82 48

91 52

rh- 72.7%

oct

sep

1.76”

87 61

rh- 72.7%

rh- 65.4%

rh- 56.5%

84 53

rh- 62.6%

jul

aug

PRECIPITATION

1.97”

2.06”

3.02”

2015

WK 17

WK 18

WK 19

WK 20

Average Temp | 74 Precipitation | 0.71”

Average Temp | 74 Precipitation | 0.32”

Average Temp | 70 Precipitation | 0.12”

Average Temp | 75 Precipitation | 1.26”

Water Demand @ 2.4” / week

Water Demand @ 2” / week

Water Demand @ 2.5” / week

WK 21

WK 22

WK 23

WK 24

Average Temp | 69 Precipitation | 0.48”

Average Temp | 69 Precipitation | 0.09”

Average Temp | 78 Precipitation | 2.24”

Average Temp | 64 Precipitation | 0.01”

Water Demand @ 1.9” / week

Water Demand @ 2.8” / week

Water Demand @ 1.4” / week

WK 25

WK 26

WK 27

WK 28

Average Temp | 66 Precipitation | 1.18”

Average Temp | 67 Precipitation | 0.26”

Average Temp | 54 Precipitation | 0.32”

Average Temp | 59 Precipitation | 0.04”

Water Demand @ 1.6” / week

Water Demand @ 1.7” / week

Water Demand @ 1” / week

WK 29

WK 30

Average Temp | 49 Precipitation | 0.00”

Average Temp | 54 Precipitation | 0.06”

Water Demand @ 1” / week

Note:

Think about temperatures and precipitation and plan accordingly.

30 f

Farming - Water supply dependent

3000 Sq Ft

Total Plot Area | 3000 Sq Ft Farming Area | 1792 Sq Ft Water Usage Calculations Collection Area - 0 Sq Ft Water Demand - 52,192 Gal Water Collection - 0.0 Gal Water Balance - 52,192 Gal Cost to purchase balance water Water $ 163.94 Annual Svc Fee $ 79.32 Yearly $243.26

10 ft

April May

3500

3000

- 1116 Gallons

Week 3

@ 1” / week Average Temp - 53

+ Collected | 0 gal - Consumed | 1116 gal

- 1116 Gallons

@ 1” / week Average Temp - 42

+ Collected | 0 gal - Consumed | 1116 gal

- 1116 Gallons

Week 5

@ 1” / week Average Temp - 58

+ Collected | 0 gal - Consumed | 1116 gal

- 1116 Gallons

Week 6

@ 1.5” / week Average Temp - 65

+ Collected | 0 gal - Consumed | 1675 gal

- 1675 Gallons

Week 7

@ 1.2” / week Average Temp - 62

+ Collected | 0 gal - Consumed | 1340 gal

- 1340 Gallons

@ 1.1” / week Average Temp - 61

+ Collected | 0 gal - Consumed | 1228 gal

- 1228 Gallons

Week 9

@ 1.2” / week Average Temp - 62

+ Collected | 0 gal - Consumed | 1340 gal

-1340 Gallons

Week 10

@ 1.6” / week Average Temp - 66

+ Collected | 0 gal - Consumed | 1786 gal

- 1786 Gallons

Week 11

@ 2” / week Average Temp - 70

+ Collected | 0 gal - Consumed | 2233 gal

- 2233 Gallons

@ 2” / week Average Temp - 70

+ Collected | 0 gal - Consumed | 2233 gal

- 2233 Gallons

Week 13

@ 1.6” / week Average Temp - 66

+ Collected | 0 gal - Consumed | 1786 gal

- 1786 Gallons

Week 14

@ 1.7” / week Average Temp - 67

+ Collected | 0 gal - Consumed | 1898 gal

- 1898 Gallons

Week 15

@ 1.9” / week Average Temp - 69

+ Collected | 0 gal - Consumed | 2233 gal

- 2233 Gallons

@ 2.3” / week Average Temp - 73

+ Collected | 0 gal - Consumed | 2568 gal

- 2568 Gallons

@ 2.5” / week Average Temp - 75

+ Collected | 0 gal - Consumed | 2791 gal

- 2791 Gallons

Week 18

@ 2.4” / week Average Temp - 74

+ Collected | 0 gal - Consumed | 2512 gal

- 2512 Gallons

Week 19

@ 2” / week Average Temp - 70

+ Collected | 0 gal - Consumed | 2233 gal

- 2233 Gallons

Week 20

@ 2.5” / week Average Temp - 75

+ Collected | 0 gal - Consumed | 2791 gal

- 2791 Gallons

Week 21

@ 2” / week Average Temp - 69

+ Collected | 1026 gal - Consumed | 2233 gal

- 2233 Gallons

Week 22

@ 2” / week Average Temp - 69

+ Collected | 0 gal - Consumed | 2233 gal

-2233 Gallons

Week 23

@ 2.8” / week Average Temp - 78

+ Collected | 0 gal - Consumed | 3126 gal

-3126 Gallons

Week 24

@ 1.4” / week Average Temp - 64

+ Collected | 0 gal - Consumed | 1675 gal

-1675 Gallons

Week 25

@ 1.6” / week Average Temp - 66

+ Collected | 0 gal - Consumed | 1675 gal

-1675 Gallons

Week 26

@ 1.7” / week Average Temp - 67

+ Collected | 0 gal - Consumed | 1675 gal

-1675 Gallons

Week 27

@ 1” / week Average Temp - 54

+ Collected | 0 gal - Consumed | 1116 gal

-1116 Gallons

Week 28

@ 1” / week Average Temp - 59

+ Collected | 0 gal - Consumed | 1116 gal

-1116 Gallons

Week 29

@ 1” / week Average Temp - 49

+ Collected | 0 gal - Consumed | 1116 gal

-1116 Gallons

Week 30

@ 1” / week Average Temp - 54

+ Collected | 0 gal - Consumed | 1116 gal

-1116 Gallons

Precipitation | 0.48”

Week 4

Precipitation | 0.65”

Precipitation | 0.19”

Week 8 Precipitation | 0.08”

Precipitation | 0.34”

June

2500

+ Collected | 0 gal - Consumed | 1116 gal

Precipitation | 1.12”

Precipitation | 2.10”

Week 12 Precipitation | 0.51”

Precipitation | 1.74”

Precipitation | 0.71”

July

2000

Week 2

@ 1” / week Average Temp - 50

Precipitation | 0.00”

Precipitation | 1.93”

Week 16 Precipitation | 0.27”

Week 17

Precipitation | 0.71”

Precipitation | 0.32”

August

Water Requirement Avg Temperature + Collected | - Consumed |

Precipitation | 0.84”

Precipitation | 0.12”

Precipitation | 1.26”

Precipitation | 0.48”

Precipitation | 0.09”

September

Water Requirement Avg Temperature @ 1” / week Average Temp - 45

Week 1 Precipitation | 0.34”

Precipitation | 2.24”

Precipitation | 0.01”

Precipitation | 1.18”

Precipitation | 0.26”

October

1500

1000

500

Water Requirement Avg Temperature

Precipitation | 0.32”

Precipitation | 0.04”

Precipitation | 0.00”

Precipitation | 0.06”

Collection

Demand

0 gal 0 gal

0 Gallons

Effective Gallons required from another source -52,192 Gallons

Collection Efficiency @ 75% | Water Demand 1” @ 60F | 10F rise in Average Temperature leads to 1” Increase in water demand

30 f

Farming - Self Sufficient

2000 Sq Ft

1000 Sq Ft 600 Sq Ft

Total Plot Area | 3000 Sq Ft Farming Area | 600 Sq Ft

10 ft

Water Usage Calculations Collection Area - 2000 Sq Ft Water Demand - 17475 Gal Water Collection - 17476 Gal Water Balance 1 Gal Cost to purchase Balance water Water Collected $ 0.0 Annual Svc Fee $ 0.0 Yearly $0.0 Total Savings 96

Cost to purchase Demand water Water Collected $ 54.64 Annual Svc Fee $ 79.32 Yearly $133.96

$ 133.96

April May

3500

3000

+ 412 Gallons

Week 3

@ 1” / week Average Temp - 53

+ Collected | 449 gal - Consumed | 374 gal

@ 1” / week Average Temp - 42

+ Collected | 0 gal - Consumed | 374 gal

- 374 Gallons

Week 5

@ 1” / week Average Temp - 58

+ Collected | 1047 gal - Consumed | 374 gal

+ 673 Gallons

Week 6

@ 1.5” / week Average Temp - 65

+ Collected | 608 gal - Consumed | 561 gal

Week 7

@ 1.2” / week Average Temp - 62

+ Collected | 178 gal - Consumed | 449 gal

- 271 Gallons

@ 1.1” / week Average Temp - 61

+ Collected | 75 gal - Consumed | 411 gal

- 336 Gallons

Week 9

@ 1.2” / week Average Temp - 62

+ Collected | 1964 gal - Consumed | 449 gal

+ 1515 Gallons

Week 10

@ 1.6” / week Average Temp - 66

+ Collected | 477 gal - Consumed | 598 gal

- 121 Gallons

Week 11

@ 2” / week Average Temp - 70

+ Collected | 1627 gal - Consumed | 748 gal

+ 879 Gallons

@ 2” / week Average Temp - 70

+ Collected | 664 gal - Consumed | 748 gal

Week 13

@ 1.6” / week Average Temp - 66

+ Collected | 1805 gal - Consumed | 598 gal

+ 1207 Gallons

Week 14

@ 1.7” / week Average Temp - 67

+ Collected | 252 gal - Consumed | 635 gal

- 383 Gallons

Week 15

@ 1.9” / week Average Temp - 69

+ Collected | 664 gal - Consumed | 748 gal

@ 2.3” / week Average Temp - 73

+ Collected | 299 gal - Consumed | 860 gal

- 561 Gallons

@ 2.5” / week Average Temp - 75

+ Collected | 112 gal - Consumed | 935 gal

- 822 Gallons

Week 18

@ 2.4” / week Average Temp - 74

+ Collected | 1178 gal - Consumed | 841 gal

+ 337 Gallons

Week 19

@ 2” / week Average Temp - 70

+ Collected | 449 gal - Consumed | 748 gal

- 299 Gallons

Week 20

@ 2.5” / week Average Temp - 75

+ Collected | 84 gal - Consumed | 935 gal

- 850 Gallons

Week 21

@ 2” / week Average Temp - 69

+ Collected | 2095 gal - Consumed | 748 gal

+1347 Gallons

Week 22

@ 2” / week Average Temp - 69

+ Collected | 9 gal - Consumed | 748 gal

- 738 Gallons

Week 23

@ 2.8” / week Average Temp - 78

+ Collected | 1103 gal - Consumed | 1047 gal

+ 57 Gallons

Week 24

@ 1.4” / week Average Temp - 64

+ Collected | 243 gal - Consumed | 561 gal

- 318 Gallons

Week 25

@ 1.6” / week Average Temp - 66

+ Collected | 299 gal - Consumed | 561 gal

- 261 Gallons

Week 26

@ 1.7” / week Average Temp - 67

+ Collected | 430 gal - Consumed | 561 gal

- 131 Gallons

Week 27

@ 1” / week Average Temp - 54

+ Collected | 168 gal - Consumed | 374 gal

- 205 Gallons

Week 28

@ 1” / week Average Temp - 59

+ Collected | 37 gal - Consumed | 374 gal

- 336 Gallons

Week 29

@ 1” / week Average Temp - 49

+ Collected | 0 gal - Consumed | 374 gal

- 374 Gallons

Week 30

@ 1” / week Average Temp - 54

+ Collected | 54 gal - Consumed | 374 gal

- 318 Gallons

Precipitation | 0.48”

Week 4

Precipitation | 0.65”

Precipitation | 0.19”

Week 8 Precipitation | 0.08”

Precipitation | 0.34”

June

2500

Week 2

+ Collected | 785 gal - Consumed | 374 gal

Precipitation | 1.12”

Precipitation | 2.10”

Week 12 Precipitation | 0.51”

Precipitation | 1.74”

Precipitation | 0.71”

July

2000

+ 318 Gallons

@ 1” / week Average Temp - 50

Precipitation | 0.00”

Precipitation | 1.93”

Week 16 Precipitation | 0.27”

Week 17

Precipitation | 0.71”

Precipitation | 0.32”

August

Water Requirement Avg Temperature + Collected | 318 gal - Consumed | 0 gal

Precipitation | 0.84”

Precipitation | 0.12”

Precipitation | 1.26”

Precipitation | 0.48”

Precipitation | 0.09”

September

Water Requirement Avg Temperature @ 1” / week Average Temp - 45

Week 1 Precipitation | 0.34”

Precipitation | 2.24”

Precipitation | 0.01”

Precipitation | 1.18”

Precipitation | 0.26”

October

1500

1000

500

Water Requirement Avg Temperature

Precipitation | 0.32”

Precipitation | 0.04”

Precipitation | 0.00”

Precipitation | 0.06”

Collection

Demand

75 Gallons

47 Gallons

84 Gallons

Effective Gallons required from another source +1.2 Gallons

Collection Efficiency @ 75% | Water Demand 1” @ 60F | 10F rise in Average Temperature leads to 1” Increase in water demand

MAIN TITLE

To learn more...

SUBTITLE

DWSD - Drainage Charge and Credit Program. - http://detroitmi.gov/Portals/0/docs/DWSD/FAQ%20-%20Drainage%20Charge%20and%20Credit%20 Program%20-%2011232016.pdf A Guide to the Drainage Charge - http://www.detroitmi.gov/Portals/0/docs/DWSD/A%20Guide%20 to%20Drainage%20Charge%20 Credits%20-%20Web.pdf?ver=2016-09-06-093601-287 NOAA - National Oceanic and Atmospheric Administration

STORMWATER MANAGEMENT GUIDEBOOK- Bruce E. Menerey, P.E. https://www.michigan.gov/documents/ deq/lwm-smg-all_202833_7.pdf LOW IMPACT DEVELOPMENT : A DESIGN MANUAL FOR URBAN AREAS (UACDC)

LOW IMPACT DEVELOPMENT MANUAL FOR MICHIGAN - http://www.swmpc. org/mi_lid_manual.asp

MINNESOTA URBAN SMALL SITES BMP MANUAL: STORMWATER BEST MANAGEMENT PRACTICES https://www.pca.state.mn.us/water/ stormwater-best-management-practices-manual

MAIN TITLE

100

SUBTITLE

Keeping costs down

1 - Department of Environmental Quality 2 - The Kresge Foundation 3 - Fred A. And Barbara M. Erb Family Foundation

101

MAIN TITLE

102

SUBTITLE

Water Booklet was developed for the Detroit Cultivator project, a six-acre civic commons sited at the Oakland Avenue Urban Farm in Detroitâ&#x20AC;&#x2122;s historic North End. Combining food production, cultural activity, and civic assets, Detroit Cultivator works to create an economically and ecologically sustainable environment for the benefit of the neighborhood and the city at large. The project shares and showcases best practices for urban stewardship through publications, public programs, events, and other experimental prototypes.

About the Oakland Avenue Urban Farm For the past decade, against a backdrop of extreme social and economic need, the Oakland Avenue Urban Farm has established a reputation as a stabilizing anchor for the community. By growing healthy food, offering mentorships, conducting educational programs, supporting outdoor gathering spots and art spaces, and generating jobs, the farm helped create a safety net where virtually no other was available. The farm started with just one city lot in 2000; today it includes over 30 lots and structures ready for civic programming. 9227 Goodwin St. Detroit, MI 48211; oaklandurbanfarm.org

Credits MAde Architects, water consultants Akoaki, Detroit Cultivator architectural design leads Nishant Mittal, Detroit Water Booklet design

Water Booklet is made possible through the generous support of ArtPlace America.

103

BIBLIOGRAPHY

BOOKS Farr, Douglas. Sustainable Urbanism: Urban Design with Nature. Hoboken, New Jersey: John Wiley & Sons, Inc., 2008. Low Impact Development : a design manual for urban areas University of Arkansas Community Design Center (UACDC) , 2010 Smith, Carl, Andy Clayden, and Nigel Dunnett. Residential Landscape Sustainability: A Checklist Tool. Oxford, UK: Blackwell Publishing, 2008.

MANUALS Barr Engineering Company. Minnesota Urban Small Sites BMP Manual. St. Paul, Ml: Metropolitan Council, 1993, http:// www.metrocouncil.org/environment/water/BMP/ manual.htm Chicago Department of Transportation. The Chicago Green Alley Handbook. Chicago: City of Chicago, 2006, http://brandavenuc. type pad. com/brand_avenue/files/ greenalleyhandbook. pdf Low Impact Development Manual for Michigan , http://www.swmpc.org/mi_lid_manual. asp Minnesota Urban Small Sites BMP Manual: Stormwater Best Management Practices, https://www.pca.state.mn.us/water/stormwater-best-management-practices-manual