Life-Cycle Assessment of Advanced Nutrient ... - ACS Publications

Feb 12, 2016 - Pollutant Discharge Elimination System (NPDES). The technology-based tier ... management,14,15 although their inclusion has not been co...
0 downloads 0 Views 2MB Size
Subscriber access provided by UNIV OF CALIFORNIA SAN DIEGO LIBRARIES

Article

Life Cycle Assessment of Advanced Nutrient Removal Technologies for Wastewater Treatment Sheikh M. Rahman, Matthew J. Eckelman, Annalisa Onnis-Hayden, and April Z Gu Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.5b05070 • Publication Date (Web): 12 Feb 2016 Downloaded from http://pubs.acs.org on February 12, 2016

Just Accepted “Just Accepted” manuscripts have been peer-reviewed and accepted for publication. They are posted online prior to technical editing, formatting for publication and author proofing. The American Chemical Society provides “Just Accepted” as a free service to the research community to expedite the dissemination of scientific material as soon as possible after acceptance. “Just Accepted” manuscripts appear in full in PDF format accompanied by an HTML abstract. “Just Accepted” manuscripts have been fully peer reviewed, but should not be considered the official version of record. They are accessible to all readers and citable by the Digital Object Identifier (DOI®). “Just Accepted” is an optional service offered to authors. Therefore, the “Just Accepted” Web site may not include all articles that will be published in the journal. After a manuscript is technically edited and formatted, it will be removed from the “Just Accepted” Web site and published as an ASAP article. Note that technical editing may introduce minor changes to the manuscript text and/or graphics which could affect content, and all legal disclaimers and ethical guidelines that apply to the journal pertain. ACS cannot be held responsible for errors or consequences arising from the use of information contained in these “Just Accepted” manuscripts.

Environmental Science & Technology is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.

Page 1 of 35

Environmental Science & Technology

1

Life Cycle Assessment of Advanced Nutrient

2

Removal Technologies for Wastewater Treatment

3

Sheikh M. Rahman1, Matthew J. Eckelman1*, Annalisa Onnis-Hayden1, and April Z. Gu1†

4

1

5

Engineering Center, 360 Huntington Ave, Boston, MA 02115, USA

6

* Corresponding Author: [email protected], Tel: +1 617 373 4256; Fax: +1 617 373 4419

7



Department of Civil and Environmental Engineering, Northeastern University, 400 Snell

Co-corresponding Author: [email protected], Tel: +1 617 373 3631; Fax: +1 617 373 4419

8

ACS Paragon Plus Environment

-1-

Environmental Science & Technology

9

Page 2 of 35

ABSTRACT

10

Advanced nutrient removal processes, while improving the water quality of the receiving water

11

body, can also produce indirect environmental and health impacts associated with increases in

12

usage of energy, chemicals, and other material resources. The present study evaluated three

13

levels of treatment for nutrient removal (N and P) using 27 representative treatment process

14

configurations. Impacts were assessed across multiple environmental and health impacts using

15

life cycle assessment (LCA) following the TRACI impact assessment method. Results show that

16

advanced technologies that achieve high-level nutrient removal significantly decreased local

17

eutrophication potential, while chemicals and electricity use for these advanced treatments,

18

particularly multi-stage enhanced tertiary processes and reverse osmosis, simultaneously

19

increased eutrophication indirectly and contributed to other potential environmental and health

20

impacts including human and ecotoxicity, global warming potential, ozone depletion and

21

acidification. Average eutrophication potential can be reduced by about 70% when Level 2

22

(TN=3 mg/L; TP=0.1 mg/L) treatments are employed instead of Level 1 (TN=8 mg/L; TP=1

23

mg/L) but the implementation of more advanced tertiary processes for Level 3 (TN=1 mg/L;

24

TP=0.01 mg/L) treatment may only lead to an additional 15% net reduction in life cycle

25

eutrophication potential.

ACS Paragon Plus Environment

-2-

Page 3 of 35

Environmental Science & Technology

26

INTRODUCTION

27

EPA’s initiatives to develop nutrient water quality guidelines are mostly technology driven that

28

often encourages the adoption of conventional, easily applicable, and economically feasible

29

processes. Total maximum daily load (TMDL) and waste-load allocations in watersheds

30

established under the Clean Water Act (CWA) drive new technological challenges to keep the

31

nutrients in wastewater within acceptable limits. A two-tiered approach- technology based and

32

water quality based approaches is followed to issue effluent permit for wastewater discharge in

33

the U.S. under the National Pollutant Discharge Elimination System (NPDES). The technology-

34

based tier is based on the limits achievable while the water-quality based tier limits nutrient

35

discharges depending on quality of the receiving water body. While technology-based limits

36

have specific guidelines, water quality-based limits may vary widely depending on location,

37

leading to very strict nutrient limits for some sites.1 EPA-recommended eco-regional criteria

38

provide a starting point for states to identify precise nutrient levels needed to protect aquatic life

39

and maintain recreational or other uses on a site-specific or regional basis.2-4

40

In order to comply with increasingly stringent regulation on nutrient discharges (N and

41

P), WWTPs are facing the requirements to increase the level of treatment by adopting advanced

42

tertiary treatment processes to further remove nutrients beyond conventional secondary processes

43

with nutrient removal.5-6 Tertiary processes require additional usage of energy, chemicals, and

44

other material resources in order to meet effluent targets. Advanced wastewater treatment

45

processes improve the water quality of the receiving water body but can also lead to deleterious

46

environmental and health impacts elsewhere in the technological life cycle that need to be

47

evaluated.

ACS Paragon Plus Environment

-3-

Environmental Science & Technology

Page 4 of 35

48

When advanced tertiary processes are used to remove nutrients from wastewater to very

49

low levels, direct greenhouse gas (GHG) emissions occur from the WWTP,7 as well as indirect

50

emissions from the production and distribution of the additional electricity and chemicals

51

required.8 Indirect impacts are typically distributed regionally or even globally, different

52

locations from location other than the WWTP itself.

53

The central goal of the present work is to evaluate the balance between the local benefits

54

achieved from removal of nutrients (e.g., reduced eutrophication) and potential indirect and

55

distributed environmental damages due to additional chemical, energy and materials usage. In

56

addition to eutrophication and GHG emissions, other life cycle energy, environmental and

57

human health impacts will also be considered to help comprehensively assess the implications

58

and trade-offs of newly proposed effluent limits across a range of treatment technologies and

59

process configurations.

60

Life Cycle Assessment (LCA) is a multi-stage, multi-criteria modeling framework under

61

international standards (ISO 14040 and 14044) that has been widely used to characterize and

62

quantify the potential environmental impacts of wastewater treatment processes and plants.8-12

63

LCA inventories emissions that occur both directly at WWTPs themselves, as well as indirectly

64

that are associated with the supply chain of WWTPs and that may occur far from the actual plant

65

(e.g., impact from the power plants that supply the electricity).13 Emissions are then linked to

66

midpoint (problem-oriented) or endpoint (damage-oriented) metrics for environmental quality

67

and public health.14-17 LCA studies of WWTPs have been conducted in various countries,

68

particularly in Europe and Australia, with relatively fewer studies based in the U.S. LCA studies

69

have covered various scales and levels of wastewater treatment processes, including nutrient

70

removal,8,10 emerging contaminants,18 selected tertiary processes,19-20 resource recovery,21 and

ACS Paragon Plus Environment

-4-

Page 5 of 35

Environmental Science & Technology

71

water reuse technology.22-24 Some studies were conducted to reveal impacts of the entire

72

treatment plants,14-15,22,25-26 while others were designed as decision support tools for treatment

73

plant management.12,27

74

There are several challenges in conducting and comparing LCA of WWTPs, as discussed

75

recently in Corominas et al.11, including internal assumptions, system boundaries, plant size,

76

operational conditions, and the technologies being analyzed. While there are emerging standards

77

and recommendations for scoping LCAs of wastewater treatment, past studies have made a

78

variety of assumptions concerning scope or system boundaries.11 Studies have generally

79

considered infrastructure materials and equipment for construction and maintenance, as well as

80

chemicals and energy required for operation.8,11 Transportation of chemicals and materials from

81

the manufacturer to treatment plants has also been included in several studies,15 as has sludge

82

generation and management,14-15 although their inclusion has not been consistent.

83

LCA studies of nutrient removal are of particular relevance. Several studies have

84

evaluated the comparative impacts of different degrees of nutrient removal;5,8,10 however, they

85

predominantly evaluated secondary processes and focused on energy use, eutrophication, and

86

GHG emissions, while other categories of environmental impact were not considered. Foley et

87

al. conducted comprehensive life cycle inventory study of nine different treatment cases that

88

were focused on achieving different effluent N and P levels. Target effluent levels in that study

89

ranged from 50 mg N/L to 3 mg N/L for total nitrogen and 12 mg P/L to 1 mg P/L for total

90

phosphorous. The treatment options consisted of biological processes for N and P removal

91

without any tertiary processes for nutrient removal.8-9

92

The present study complements and extends previous work by conducting treatment

93

process modeling and LCA for an array of secondary and state-of-the-art tertiary process

ACS Paragon Plus Environment

-5-

Environmental Science & Technology

Page 6 of 35

94

configurations that meet proposed limits for effluent nutrient levels in the United States.6 These

95

effluent levels range from 8 mg N/L to 1 mg N/L for N and 1 mg P/L to 0.01 mg P/L for P, more

96

stringent than those considered in previous LCA work, and thus requiring more advanced

97

treatment approaches. In addition to biological nutrient removal, external carbon addition is

98

required for further N removal, and energy and chemical-intensive tertiary processes are used for

99

higher P removal.

Here we evaluate and compare the environmental and health impacts

100

associated with different levels of wastewater nutrient removal technologies that have been

101

specifically designed for three different levels of effluent limits, spanning 27 treatment

102

technologies and process scenarios for nutrient removal. The objective of the present study is to

103

provide a comprehensive view of potential trade-offs associated with advanced nutrient removal

104

processes across a broad range of impact categories, including human health effects,

105

acidification, ecotoxicity, and ozone depletion that are less frequently reported. Variations

106

associated with influent characteristics, operating energy, and chemical usage were evaluated via

107

uncertainty analysis using a stochastic modeling approach, since modeling the uncertainty

108

associated with this variability is critical for proper interpretation.

109

In a previous conference paper, we reported preliminary results for LCA modeling of 15

110

treatment scenarios covering three levels of treatment, which demonstrated potential increases

111

and trade-off among environmental impacts from tertiary nutrient removal processes at different

112

step changes in effluent limits.28 In the present work we have extended the scope in the present

113

study by incorporating additional treatment configurations, updating and modifying the treatment

114

plant designs, updated the life cycle impact assessment model employed, and included a robust

115

statistical analysis of uncertainty. Direct (local) environmental benefits resulting from decreasing

116

nutrient concentrations in effluent are compared against indirect environment impacts at regional

ACS Paragon Plus Environment

-6-

Page 7 of 35

Environmental Science & Technology

117

and global scales that result from the requisite material and energy use to construct and operate

118

tertiary treatment processes. Managing trade-offs between local benefits and regional or global

119

impacts to environmental quality and human health have implications both for modeling and

120

environmental policy.17,29

121 122

METHODOLOGY

123

Nutrient Removal Treatment Level Classification

124

Nutrient removal processes for municipal wastewater have been designed and classified based on

125

their ability to meet three Levels based on the targeted effluent concentrations for total N and P

126

(Table 1), which are representative of those prescribed by NPDES permits.6 Level 1 treatment is

127

achievable with conventional nutrient removal technologies, such as biological nitrogen removal

128

along with chemical phosphorus removal or biological nutrient removal without any external

129

carbon addition. In order to achieve Level 2 effluent limits, a supplemental carbon source is

130

generally required to enhance denitrification and achieve the target effluent nitrogen

131

concentration. In addition, enhanced tertiary chemical phosphorus removal process is required in

132

order to deliver the lower Level 2 Phosphorus concentration.6,30-32 Level 3 is known as the best

133

achievable performance level and targets extremely low effluent nutrient levels to comply with

134

ongoing or anticipated regulations. A WERF–sponsored survey and independent studies on

135

advanced phosphorus removal technologies6,31,33 have indicated that, in order to attain these

136

extremely low level of nutrient levels, multiple tertiary processes for chemical P removal are

137

necessary and addition of more external carbon for post-denitrification is required.3,26,28 WWTPs

138

performance at this level of treatment are also dependent on local weather conditions, process

139

implementation, wastewater characteristics, as well as skilled operation and maintenance.6

ACS Paragon Plus Environment

-7-

Environmental Science & Technology

Page 8 of 35

140 141

Treatment Plant Process Configurations Design Alternatives

142

Based on the reviews of current and leading-edge treatment technologies for advanced

143

nutrient removal from municipal wastewater,6 a set of 27 treatment technologies and process

144

scenarios representing three different level of treatments were designed for this study (Figure 1

145

and Table S1). For all the treatment scenarios, an influent flow of 10 MGD and U.S. average

146

representative influent properties were chosen as the design influent parameters,34 as summarized

147

in Table 2. A design life of 20 years was also chosen, which is typical for wastewater works in

148

U.S. For Level 1 treatment, a total of seven treatment scenarios were considered that include

149

chemical P removal process with Biological Nutrient Removal (BNR) and combined chemical-

150

biological P-removal processes. Chemical P removal processes were selected considering

151

different chemical addition strategies: as addition to the primary clarifier, to the secondary

152

clarifier, or prior to both primary and secondary clarifiers. Two of the most widely used BNR

153

processes―5-stage Bardenpho and The University of Cape Town (UCT)―were selected as

154

representative secondary treatment with nutrient removal configurations. Ten treatment

155

alternatives were considered each for Level 2 and Level 3 treatments. In order to achieve Level 2

156

treatment, a tertiary process is adopted following the BNR process. Tertiary processes were

157

chosen to cover each of the commonly applied processes including chemically enhanced

158

sedimentation, ballasted sedimentation, various filtration processes, and membrane filtration

159

technologies. For Level 3 treatment, multi-stage tertiary processes were considered in order to

160

meet the most stringent effluent phosphorus and nitrogen limits.6,31,33

161

Process design parameters for all the primary, secondary and tertiary processes were

162

selected based on MOP, related literature,34-35 and manufacturer specifications. For secondary

ACS Paragon Plus Environment

-8-

Page 9 of 35

Environmental Science & Technology

163

treatment with nutrient removal processes, design simulation tools (e.g., BioWin or in-house

164

spreadsheet models) were applied to assist the design process. The Total Solid Retention Time

165

(SRT) selected for each of the 27 plants was 10 days. Influent characteristics and typical kinetic

166

parameter values of microbial communities used in BioWin model were obtained from the

167

literature.34 External carbon addition for enhanced nitrogen removal, chemical doses and P

168

removal rates for different tertiary processes, and other design parameters were collected from

169

the literature and are listed in the Tables S2–S4 in the Supporting Information.30-32,34,36 In

170

addition, data regarding the sizes of the commercial tertiary treatment processes were obtained

171

from their respective vendors’ websites, as noted in Table S2.

172 173

Life Cycle Assessment

174

The process units included in the LCA model of nutrient removal processes were

175

preliminary, primary, secondary treatment with nutrient removal, and tertiary processes, where

176

applicable. The system boundary included the influent pumping to effluent discharge and sludge

177

pumping to sludge treatment facilities, while the functional unit was taken as 1 m3 of influent

178

wastewater. Construction and operation phases were included, while plant maintenance and

179

decommissioning after the 20-year design life were excluded. Downstream sludge management

180

was also excluded, for two reasons. First, the impacts of sludge treatment and disposal facilities

181

on eutrophication (