新型室内铺地材料石木塑复合地板生产过程的环境影响评价

doi:10.11707/j.1001-7488.LYKX20250082

Abstract

Abstract:

Objective: This study aims to establish a life cycle dataset for stone-wood-polymer composite flooring to comprehensively quantify the environmental impacts and biological carbon storage of the production process of such flooring, and to compare the environmental performance of this new type of flooring with that of traditional indoor flooring materials to understand its environmental advantages and disadvantages, and to propose measures to enhance the environmental performance of stone-wood-polymer composite flooring, quantify its improvement potential, and provide support for the green and low-carbon development of the industry. Method: This study established a cradle-to-gate life cycle model of stone-wood-polymer composite flooring and quantified its environmental impacts, including primary energy demand (PED), abiotic depletion potential (ADP), global warming potential (GWP), water use (WU), acidification potential (AP), eutrophication potential (EP), respiratory inorganics (RI), ozone depletion potential (ODP), photochemical oxidation formation potential (POFP), ionizing radiation potential (IRP), ecotoxicity (ET), energy conservation and emission reduction (ECER) index, and biogenic carbon stock. Result: The raw material acquisition stage was the largest contributor to midpoint environmental indicators, accounting for over 63% of all indicators. The flooring manufacturing stage contributed 35.76% to the ET, while the transportation stage was a relatively minor contributor. The cradle-to-gate ECER index of 1 m² of stone-wood-polymer composite flooring was 4.12E?11. Polyvinyl chloride and polyethylene were the main environmental hotspots during the raw material acquisition stage, while electricity, natural gas, and diesel were the main hotspots during the flooring manufacturing stage. One square meter of stone-wood-plastic composite flooring had a biogenic carbon stock of 0.12 kg CO₂ eq, accounting for 1.1% of its GWP. To enhance environmental performance, future efforts should focus on improving material efficiency by reducing the consumption of polyvinyl chloride, polyethylene, and calcium carbonate during the production of stone-wood-plastic composite flooring. In addition, energy utilization efficiency should be enhanced by lowering electricity consumption during the manufacturing stage, in order to enhance the environmental performance of stone-wood-polymer composite flooring. Conclusion: This study fills the gap in existing research on the environmental performance of flooring materials. It helps relevant parties such as flooring manufacturers, property developers, designers, consumers, and researchers to understand the comprehensive environmental performance of stone-wood-polymer composite flooring. Based on the production practices of enterprises, feasible improvement measures are proposed, which can provide valuable references for the green and low-carbon development of the stone-wood-polymer composite flooring industry.

Key words: stone-wood-polymer composite flooring, environmental performance, carbon footprint, life cycle assessment, carbon stock

CLC Number:

S788
F326.2

Wanli Lao,Bin Lü,Xiaoling Li,Xinfang Duan,Junfeng Wang. Environmental Impact Assessment of the Production Process of a Novel Stone-Wood-Polymer Composite Floor for Indoor Flooring[J]. Scientia Silvae Sinicae, 2026, 62(2): 204-213.

Figures/Tables 11

Table 1

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Table 2

Environmental performance of 1 m2 other types of flooring materials (from cradle to gate)"

指标Indicators	石木塑地板Stone-wood-polymer composite flooring	陶瓷地板Ceramic flooring	天然石材地板Natural stone flooring	花岗岩地板Granite flooring	石灰石地板Limestone flooring	大理石地板Marble flooring	实木地板Solid wooden flooring	多层实木复合地板Multi-layer engineered wood flooring	三层实木复合地板Three-layer engineered wood flooring	强化地板Laminate flooring
全球变暖潜值Global warming potential (GWP)/kg CO₂ eq	1.07E+01	7.78E+03	2.20E+01	2.40E+01	9.18E+00	3.28E+01	3.06E?02	9.70E?02	9.49E?02	1.90E?01
一次能源消耗Primary energy demand (PED)/MJ	2.32E+02	—	—	—	—	—	2.39E+00	8.04E+00	5.34E+00	4.87E+00
非生物资源消耗潜值Abiotic depletion potential (ADP)/ kg antimony eq	4.26E?05	—	—	—	—	—	2.40E?07	1.05E?06	5.61E?07	2.97E?06
水资源消耗Water use (WU)/kg	1.02E+02	6.08E+01	—	—	—	—	8.03E?02	2.01E?01	3.53E?01	1.12E?01
酸化Acidification potential (AP)/ kg SO₂ eq	4.81E?02	3.87E+01	1.07E?01	1.29E?01	6.13E?02	1.11E?01	1.33E?04	7.45E?04	4.63E?04	1.34E?03
富营养化潜值Eutrophication potential (EP)/kg PO₄^3-eq	6.72E?03	—	1.51E?02	1.66E?02	7.40E?03	1.91E?02	7.18E?05	3.93E?04	1.79E?04	9.60E?01
可吸入无机物Respiratory inorganics (RI)/kg PM_2.5 eq	1.30E?02	1.66E+01	2.75E?02	1.27E?02	1.24E?02	4.09E?02	4.17E?05	2.37E?04	1.32E?04	2.58E?04
臭氧层消耗Ozone depletion potential (ODP)/kg CFC-11 eq	2.63E?07	2.97E?04	1.13E?06	1.10E?06	4.22E?07	2.46E?06	2.06E?09	9.94E?09	5.01E?09	1.97E?08
光化学臭氧合成Photochemical oxidation formation potential (POFP)/kg NMVOC eq	2.37E?02	—	—	—	—	—	1.45E?04	6.17E?04	3.53E?04	7.61E?04
生态毒性Ecotoxicity (ET)/CTUe	1.06E+00	5.54E+01	2.38E+01	2.87E+01	1.09E+01	1.74E+01	2.71E?02	6.30E?02	7.93E?02	1.30E?01
电离辐射?人体健康Ionizing radiation potential (IRP)/ kg U235 eq	2.32E?01	—	—	—	—	—	—	—	—	—
节能减排综合指标Energy conservation and emission reduction (ECER)	4.12E?11	—	—	—	—	—	2.52E?12	4.19E?12	3.59E?12	6.76E?12
参考文献Reference	本研究 This study	Sangwan et al.， 2018	Adhikari et al.， 2022b	Adhikari et al.， 2022a			Lao，2024

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中点环境指标Midpoint environmental indicators	原材料获取阶段Raw material acquisition stage	地板制造阶段Flooring manufacturing stage	原材料运输阶段Raw material transportation stage	合计 Total
一次能源消耗Primary energy demand (PED)/MJ	2.23E+02	7.80E+00	1.58E+00	2.32E+02
非生物资源消耗潜值Abiotic depletion potential (ADP)/kg antimony eq	4.09E?05	1.08E?06	5.56E?07	4.26E?05
水资源消耗Water use (WU)/kg	1.01E+02	5.86E?01	1.37E?01	1.02E+02
酸化Acidification potential (AP)/kg SO₂ eq	4.46E?02	1.84E?04	3.31E?03	4.81E?02
富营养化潜值Eutrophication potential (EP)/kg PO₄^3-eq	6.11E?03	1.73E?05	5.95E?04	6.72E?03
可吸入无机物Respiratory inorganics (RI)/kg PM_2.5 eq	1.23E?02	2.19E?05	6.26E?04	1.30E?02
臭氧层消耗Ozone depletion potential (ODP)/kg CFC-11 eq	2.49E?07	9.16E?11	1.41E?08	2.63E?07
光化学臭氧合成Photochemical oxidation formation potential (POFP)/kg NMVOC eq	2.27E?02	7.40E?06	1.00E?03	2.37E?02
电离辐射?人体健康Ionizing radiation potential (IRP)/kg U235 eq	2.15E?01	1.55E?02	8.78E?04	2.32E?01
生态毒性Ecotoxicity (ET)/CTUe	6.73E?01	3.79E?01	6.70E?03	1.06E+00
全球变暖潜值Global warming potential (GWP)/kg CO₂ eq	1.03E+01	2.87E?01	1.65E?01	1.07E+01

材料类别 Material categories	原材料获取阶段 Raw material acquisition stage			摇篮到大门阶段 Cradle to gate
材料类别 Material categories	情景1 Scenario 1	情景2 Scenario 2	情景3 Scenario 3	情景1 Scenario 1	情景2 Scenario 2	情景3 Scenario 3
聚氯乙烯Polyvinyl chloride	1.90	4.43	6.32	1.80	4.20	6.00
碳酸钙Calcium carbonate	0.23	0.53	0.75	0.21	0.50	0.72
聚乙烯Polyethylene	0.77	1.79	2.55	0.73	1.69	2.42
综合 Total	2.90	6.75	9.62	2.74	6.39	9.14

能源类别Energy categories	地板制造阶段 Flooring manufacturing stage			摇篮到大门阶段 Cradle to gate
能源类别Energy categories	情景1 Scenario 1	情景2 Scenario 2	情景3 Scenario 3	情景1 Scenario 1	情景2 Scenario 2	情景3 Scenario 3
电Electricity	1.97	4.59	6.55	0.03	0.07	0.10
天然气Natural gas	0.39	0.92	1.32	0.01	0.01	0.02
柴油Diesel oil	0.49	1.15	1.64	0.01	0.02	0.02
综合 Total	2.85	6.66	9.51	0.05	0.10	0.14

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Environmental Impact Assessment of the Production Process of a Novel Stone-Wood-Polymer Composite Floor for Indoor Flooring

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