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Article

Impact of Illegal Application of Urea Regulator on Real-World Exhaust Nitrogen Oxygen and Particle Number Emissions

1
Hubei Key Laboratory of Advanced Technology for Automotive Components, School of Automotive Engineering, Wuhan University of Technology, Wuhan 430070, China
2
National Engineering Laboratory for Mobile Source Emission Control Technology, China Automotive Technology and Research Center Co., Ltd., Tianjin 300300, China
3
Light Vehicle Emission and Energy-Saving Testing and Research Department, CATARC Automotive Test Center (Tianjin) Co., Ltd., Tianjin 300300, China
4
Tianjin Key Laboratory of Urban Transport Emission Research, College of Environmental Science and Engineering, Nankai University, Tianjin 300071, China
*
Author to whom correspondence should be addressed.
Atmosphere 2022, 13(10), 1739; https://doi.org/10.3390/atmos13101739
Submission received: 19 September 2022 / Revised: 17 October 2022 / Accepted: 17 October 2022 / Published: 21 October 2022
(This article belongs to the Special Issue Vehicle Emissions: New Challenges and Potential Solutions)

Abstract

:
Urea regulators (UR) have generally been employed against diesel trucks to save urea usage and thus contribute to the reduction in excessive emissions, while their usage is generally difficult to supervise and enforce. By conducting real driving emission measurements on a China IV heavy-duty diesel truck, a “trade-off” effect caused by UR was found between nitrogen oxides (NOx) and particle number (PN) emissions. The usage of UR contributes to 1.04 times higher NOx but 0.28 times lower PN emissions for the whole trip. In particular, the increasing effects on NOx are most efficient on the highway and least effectual on the urban road, while the decreasing effects on PN exhibit an opposite trend under different road types. From low- and medium- to the high-speed bin, the peak average vehicle-specific power NOx emission rates exhibit markedly increasing but slightly decreasing trends for the truck with and without UR, respectively. Furthermore, the NOx emissions in units of CO2 and the linear correlational relationship between CO2 and NOx instantaneous mass emission rates, especially those on the highway, are significantly enhanced. This study directly clarifies the effects of UR on real-world emissions, providing a scientific basis for the real-time identification of the malfunction of the selective catalytic reduction system.

1. Introduction

Motor vehicles have gradually emerged as an increasingly prominent anthropogenic source of particulate matter (PM) and nitrogen oxides (NOx), thus leading to a negative effect on air quality and human health [1,2,3,4]. According to the latest source analysis against PM2.5 [5], mobile exhaust emissions mainly contributed by vehicles have become the primary or secondary regional source for some megacities in China. In particular, heavy-duty diesel trucks (HDDTs), accounting for about 7.0% of the total vehicle fleet, have been investigated to contribute to 70.1% of NOx and 51.5% of PM emissions from all vehicles across China in 2021 [6]. Moreover, as a vital precursor for ozone (O3) and PM, NOx emitted by diesel trucks will pose certain challenges to the collaborative governance of PM and O3 [7] during China’s 14th Five-Year Plan period. Consequently, emission control against HDDTs will still be essential to improve urban air quality in the future.
To alleviate the exhaust emissions of HDDTs, various efforts have been employed around the world, including the implementation of stringent standards for new vehicles [8], the retirement of old high-emission vehicles [6,9], and inspection and maintenance measures for in-use vehicles [10]. Considering the huge proportion of in-use vehicles and the relative lack of effective regulatory approaches, emission control against in-use diesel trucks will be essential to mitigate vehicle exhaust pollution. Nowadays, remote on-board diagnostic (OBD) is increasingly becoming an important way in China to monitor the real-time operating and emission conditions of in-use heavy-duty vehicles [11,12]. The data collected from OBD are also proven to be consistent with that obtained from portable emission measurement systems (PEMS) [13]. For now, the remote OBD system is mostly used to count fuel consumption, NOx emission, OBD fault information, etc. However, the effect of the remote OBD method is not fully realized due to its lack of supervision methods, such as the identification of causes of excessive emission.
As an important part of emission control against diesel trucks, the selective catalytic reduction (SCR) system was proven to effectively reduce NOx emissions [14,15] but also enhance the formation of ammonia-induced particles [16,17,18,19,20]. The NOx reduction effectiveness of the SCR can be influenced by factors such as the driving condition [15], fuel quality, urea injection [21], etc. Meanwhile, the urea injection can be reduced or avoided by taking cheating approaches including the illegal application of urea emulator [22], urea shielding, and urea regulator (UR). Due to its convenient installation and low cost, the UR that can reduce the amount of urea injection are widely applied to diesel trucks for urea-saving, but rarely receive effective supervision. In addition, most studies are focused on the mechanism of the SCR on the emission influence under laboratory test cycles for engines [19] but are rarely concentrated on the influence of the UR on NOx and particle number (PN) emissions emitted by diesel trucks under real-world driving conditions. Therefore, real-world emission measurements will be of immense necessity to clarify the changes in the NOx and PN emission characteristics and to obtain a scientific method for the real-time identification of the malfunction of the SCR caused by the usage of the UR.
This study aims at acquiring a scientific method for the real-time identification of SCR malfunction by investigating the characteristics of NOx and PN emissions emitted by diesel trucks both with and without the usage of UR. Real driving emission measurements with a PEMS against a China IV HDDT were conducted on a complicated route, consisting of urban roads, rural roads, and highways. The effectiveness of the UR on both NOx and PN emissions is directly investigated by driving the diesel truck on the test route with and without the UR. To fully obtain the effects of the UR on different components of the pollutants, the NOx was divided into nitric oxide (NO) and nitrogen dioxide (NO2), while the particles with an aerodynamic particle size ranging from 6 nm to 2.5 μm were divided into solid >23 nm and total <23 nm particles. Specifically, the effectiveness of the UR on those pollutants was investigated by successively comparing the differences in instantaneous volumetric concentration distribution, emission factors (EFs), and vehicle-specific power (VSP)-bin emission rates between the situation with and without UR. Moreover, the effects of the UR on the variations in the correlation between NOx and carbon dioxide (CO2) instantaneous mass emission rates under different road types are also clarified.

2. Materials and Methods

2.1. Test Vehicle and Route

Table 1 demonstrated the specifications of the tested China IV HDDT, which is equipped with SCR but without DOC and DPF [23]. Due to the large share in the diesel truck fleet, the poor emission control levels, and the susceptibility to illegal operations for China IV HDDTs, a China IV HDDT is thus selected to investigate the effect of the UR on emissions. The particle emission control of the tested truck was mainly achieved by reducing the generation of particulate matter during the combustion process of the engine through fuel injection and combustion optimization technology, while the NOx emission control relied on the SCR to reduce NOx emissions during the off-engine post-processing. Normally, an alarm system will be automatically activated when the truck lacks urea or the urea injection system is manually turned off, which can be supervised by the OBD. However, the alarm system can be bypassed through the illegal application of the urea regulating screw, called UR here. By installing a UR on the exhaust temperature sensor, the perceived temperature can be regulated by adjusting the depth of the exhaust temperature sensor, thereby reducing the urea injection. In addition, the fuel and urea employed here were obtained directly from the local market.
To fully investigate the influence of the UR on real driving NOx and PN emissions, a complicated test trip (~51 km) consisting of urban roads, rural roads, and highways was selected to perform real-world emission measurements in July 2018. The tested route mostly consisted of rural roads and highways compared to urban roads due to the main activity area of the tested truck being located in the non-urban area. To avoid the emission differences caused by the inconsistent driving behaviors between different drivers, one local driver was arranged to alternate driving the truck with and without UR on the trip during the test. The number of the tested trips both with and without UR was 3 on the selected route. To reflect the emission differences under different driving conditions, the road types herein were simply categorized as the urban road (V ≤ 30 km/h), rural road (30 < V ≤ 60 km/h), and highway (V > 60 km/h) based on the instantaneous vehicle speed and actual speed distribution in different activity areas. The summary of driving characteristics for the real driving tested truck with and without UR under different road types was demonstrated in Table 2. It was clear that no obvious differences in driving parameters can be found with and without UR, even regardless of road type.

2.2. Measurement System

The real-time instantaneous and cumulative exhaust emissions of gaseous pollutants and particles were collected by a united PEMS consisting of a SEMTECH-DS Gas unit and a renewed electrical low-pressure impactor (ELPI+). The SEMTECH-DS [24], developed by Sensors Inc., adopts a non-dispersive ultraviolet (NDUV) sensor to acquire concentrations of NO and NO2, a non-dispersive infrared (NDIR) sensor to measure CO and CO2, and other detectors for other gaseous pollutants. Moreover, several other units fixed around the vehicle body were also included, such as a SEMTECH High-Speed Exhaust Flow Meter (SEMTECH EFM-HS) to continuously and directly monitor the vehicle exhaust flow, a temperature probe to monitor the exhaust temperature near the exit of the tailpipe, a GPS to acquire vehicle speed and location information (i.e., altitude, latitude, and longitude), and a weather probe for the ambient temperature and relative humidity. To prevent the generation of condensates and high molecular weight hydrocarbons during the test periods, the sampling tube between the EFM and SEMTECH-DS analyzer was heated and maintained at 190 °C. Meanwhile, the ELPI+ [25] (Dekati Ltd. Kangasala, Finland) with 14 stages was utilized to measure aerodynamic particle size distribution and number concentrations over a diameter range of 6 nm–10 μm. Additionally, a Dekati Engine Exhaust Diluter (DEED) [26], installed before the ELPI+, was used to remove semi-volatile particles. Two stages of dilution were selected and an overall dilution ratio of 100 was set during this test. Specifically, the sample flow was firstly heated to 150 °C and diluted 10 times at the first dilution stage, then heated to 300~400 °C to remove volatile organic compounds through the evaporation tube, and ultimately diluted 10 times and cooled to ambient temperature at the second dilution stage. On the basis of the nominal particle size measured by each stage, the first 6 stages with diameters below 23 nm and the stages 7–12 with a measuring range from 23 nm to 2.5 μm, were used to estimate, respectively, in total <23 nm and solid (23 nm~2.5 μm) particle emissions.
To ensure that the vehicle engine operation will not be affected by the power demand of the device, an extra gasoline generator was employed to power the PEMS instrument. All data acquired in this study were recorded at a frequency of 1 Hertz. The whole PEMS together with the co-driver and other cargo loads, with a total weight being around 2900 kg, resulted in around 22.8% of the curb weight of the tested truck. To ensure the accuracy of the PEMS, routine calibrations before and after tests of gaseous and particle pollutants were conducted by controlling for the zero and span drift of the gaseous analyzers, purging and verifying the zero flow of the EFM, and executing flush and zero calibrations for the electrometer in the ELPI+. Moreover, due to the different response times for instruments, time synchronization of data acquired by different devices was performed before data analysis. Moreover, a laptop computer, connected to the instrument by the local area network, was employed to monitor the real-time operational status of the device.

2.3. Vehicle-Specific Power (VSP)

To further reflect the effectiveness of the usage of UR on emissions under various driving conditions, VSP, namely the instantaneous engine power demand per vehicle unit mass (kW/ton), was used to illustrate the correlation between vehicle operating modes and exhaust emissions. According to the motor vehicle emission simulator (MOVES) [27], VSP can be calculated as the following Equation (1):
VSP = Av + Bv 2 + Cv 3 + Mv ( a + gsin θ ) f scale
where M is the gross vehicle weight (tons), v is the vehicle speed (m/s), a is the vehicle acceleration (m/s2), g is the gravitational acceleration (9.81 m/s2), θ is the road grade (radians), and f scale is the fixed mass factor (tons). Additionally, A (kW s/m), B (kW s2/m2), and C (kW s3/m3) represent the coefficients of the rolling resistance, rotational resistance, and aerodynamic drag, respectively. Obtained from the MOVES model [27], the values of A, B, C, and f scale coefficients are 2.0491, 0, 0.004195, and 17.1, respectively, for the tested truck.

3. Results and Discussion

3.1. Effects on Nitrogen Oxides Emissions

3.1.1. Effects on NOx Instantaneous Volumetric Concentrations

Obvious differences occurred in the density distributions of NO and NO2 instantaneous volumetric concentrations for the situation with and without UR (Figure 1). The height of the histogram herein represents the density, while the kernel density estimation curve represents a smoothed histogram that can demonstrate the distribution characteristics of data. Since the differences in driving conditions with and without UR are negligible (Table 2), it can be assumed that the change in concentration distribution is caused by the use of UR. For NO concentrations, an obvious bimodal distribution (mode concentration: 50 and 400 ppm) occurred for the vehicle without UR, while a trimodal distribution (mode concentration: 500, 950, and 1200 ppm), mostly attributed to the various driving conditions during the tested trip with different road types, was observed for the vehicle with UR. Consistent with the larger mode concentrations caused by the usage of the UR, the distribution of the NO concentrations around 500 ppm and above 800 ppm also exhibited larger densities. For NO2 concentrations, a unimodal distribution occurred for the vehicle both without and with UR, but the mode concentration of the vehicle with UR (7 ppm) was relatively larger than that without UR (4 ppm). Additionally, larger distribution densities of NO2 concentrations above 7 ppm were observed due to the usage of UR. Associated with increased mode concentrations and distribution densities at high concentrations, the min, max, 25th, 50th, and 75th percentile of the NO and NO2 concentrations were also found to be markedly increased by the illegal application of the UR (Figure 1). These phenomena are probably related to the fact that the NO and NO2 with large concentrations mostly emitted under severe driving conditions cannot be effectively reduced by the malfunction of the SCR caused by the UR.

3.1.2. Effects on Distance-Based NOx Emission Factors

The trip-average NO, NO2 and NOx EFs under different road types for the tested truck with and without UR are displayed in Table 3. The increase ratio (IR: %) in Table 3 was utilized to describe the increased effect of the application of the UR on NOx emissions. From the real-world emission results, we observe that the usage of the UR can contribute to enormously increased effects on NO, NO2, and NOx emissions but negligible decreased effects on CO2 emissions. This fact may further prove that the differences in pollutant emissions between the situations with and without UR are mainly caused by the application of the UR rather than the subtle differences in driving behaviors between the trip tests with and without UR (Table 2). The application of the UR can result in 3.8 and 2.1, 0.7 and 0.9, and 0.3 and 0.7 times higher NO and NO2 EFs under highways, rural roads, and urban roads, respectively. The increased effect of the UR on NO and NO2 both exhibited a decreasing trend from the highway and rural roads to urban roads. This fact was mainly due to the increasing benefit of increased exhaust gas temperature on urban roads, rural roads to highways for improving the NOx conversion efficiency of SCR with appropriate urea [15,28].
Despite the slightly higher increased effects of the UR on NO2 (117.7%) compared to that on NO (104.0%) for the whole trip, distinct different increased effects between NO and NO2 emissions occurred for different road types. The increased effect on NO was higher than that on NO2 for highways, while lower for rural roads and especially for urban roads. This is probably because the active operation window with a working temperature between 300 and 400 °C for the main NOx-SCR reaction of 4 NH 3 + 4 NO + O 2 4 N 2 + 6 H 2 O (the “standard SCR” reaction) against NO conversion [19] is more achievable in highway driving conditions, thus leading to obvious higher increased effects on NO compared to NO2 on the highway. For rural and urban roads, however, the “fast SCR” reaction of 2 NH 3 + NO + NO 2 2 N 2 + 3 H 2 O mainly controlled by the availability of NO2 will be considerably faster than the “standard SCR” reaction due to the decreasing working temperature from highway, rural road to urban road [19]. Meanwhile, excess NO2 will also react with NH3 via the “NO2-SCR” reaction of 4 NH 3 + 3 NO 2 3.5 N 2 + 6 H 2 O for those on rural and urban roads [19]. These phenomena thus resulted in distinguished higher increased effects of the UR on NO2 compared to that on NO on the rural road, especially on the urban road with extremely low exhaust temperature.

3.1.3. Effects on VSP-Bin NOx Emission Rates

Figure 2 shows the average mass emission rates of NO and NO2 of the truck with and without UR in various VSP and speed bins. Compared to the variations in the average VSP-bin NO and NO2 emission rates of the vehicle without UR, those average emission rates with UR also exhibited more distinguished increasing trends in all speed ranges, especially in the high-speed ranges. Moreover, the average emission rates of NO and NO2 in different bins, especially those in the high-speed ranges, are generally higher for the truck with UR compared to that without UR. Specifically, the application of the UR resulted in 0.2 and 0.7, 1.6 and 1.5, and 5.1 and 2.1 times higher average NO and NO2 emission rates under low-, medium-, and high-speed bins, respectively. Obvious higher increased effects of the UR occurred in the high-speed range for NO compared to NO2, while in the low-speed range for NO2 compared to NO.
The highest emission rates of NO and NO2 are both located in the high-VSP and high-speed bin for the truck with UR, which is mainly related to the fact that the increased combustion temperature caused by severe engine load can contribute more to the production of NOx [29]. However, the highest emission rates of NO and NO2 are both located in the high-VSP and low-speed bin for the truck without UR, which is likely due to the reduced effect of the SCR on NOx emissions, especially those in high-speed driving conditions with high exhaust temperature. Meanwhile, the peak VSP-bin NOx emission rates exhibited markedly increasing but slightly decreasing trends from low and medium to the high-speed bin for those with UR and without UR, respectively.

3.2. Effects on Particle Number Emissions

3.2.1. Effects on PN Instantaneous Volumetric Concentrations

As demonstrated in Figure 3, the density of solid >23 nm and total <23 nm PN instantaneous volumetric concentrations for the vehicle with and without UR both exhibited a unimodal distribution. Contrary to the negative effect on the control of NO and NO2 emissions due to the usage of the UR, a positive control effect occurred for PN emissions. This is mainly attributed to the fact that the limited urea injection caused by the employment of the UR can reduce exhaust ammonia which can form particles [30]. This evidence also indicates that a large number of HDDTs on the road today may produce extra particles related to the urea-SCR operation [19].
Compared to the slight differences in the density distribution between with and without UR for solid >23 nm PN concentrations, an obvious smaller mode concentration and lower density of the particle with concentrations above 2.0 × 106 #/cm3 occurred for the total <23 nm PN concentrations when the UR was applied. Meanwhile, the minimum, maximum, 25th, 50th, and 75th percentiles of the total <23 nm PN concentrations were also found to be markedly reduced, due to the illegal application of UR as shown in Figure 3. The usage of the UR can more effectively weaken the production of the total <23 nm particles compared to solid >23 nm particles, mainly explained due to the nanoparticles being more easily produced during the SCR normal working conditions with proper urea injection [31].

3.2.2. Effects on Distance-Based PN Emission Factors

Table 4 presents the trip-average EFs of total <23 nm and solid >23 nm PN under different road types for the tested truck with and without UR. The total <23 nm PN EFs for the vehicle with and without UR contribute 33.3% and 40.0%, 28.8% and 38.3%, 29.6% and 36.4%, and 30.3% and 38.5% of the PN2.5 EFs under the highway, rural road, urban road, and the whole trip, respectively. A major part of PN2.5 is clearly attributed to the fraction of particles <23 nm. Considering that the current PN limits are referred to solid >23 nm particles based on the electric mobility diameter [20,32], more attention should thus be paid to nanoparticles in the future limit. Relatively higher ratios of total <23 nm PN to PN2.5 were observed for the vehicle without UR compared to that with UR, indicating the total <23 nm particles are more generated for the vehicle without UR that possesses normal urea injection [31].
The decrease ratio (DR: %) in Table 4 was utilized to describe the reduction effect of the application of the UR on PN emissions. Lower total <23 nm and solid >23 nm PN emissions were observed for the situation with the application of the UR (Table 4), which is probably because much less NH3 decomposed by urea over catalyst on the SCR can be achieved to contribute to the formation of particles. Meanwhile, the reduction effect on both total <23 nm and solid >23 nm PN emissions exhibited upward trends from the highway and rural roads to urban roads, which is opposite to the variation trend of the increasing effect on NOx emissions. This is likely because the NH3 decomposed by urea can be more active in reducing NOx rather than forming particles in driving conditions with higher exhaust temperatures [19,33]. In particular, higher DRs occurred for the total <23 nm particles compared to solid >23 nm particles for those under various road types, which is consistent with the above findings, namely that the formation effect of NH3 on total <23 nm particles is better than that on solid >23 nm particles. Furthermore, the reduction effect on total <23 nm particles is higher than that on solid >23 nm particles emitted under highways and rural roads compared to urban roads. This phenomenon is probably related to the fact that ammonium nitrate formed by the reaction of NH3 and NO2 can tend to form more solid >23 nm particles in SCR catalyst pores under urban driving conditions with low exhaust temperature [34] compared to that under highway and rural roads.

3.2.3. Effects on VSP-Bin PN Emission Rates

The average emission rates of total <23 nm and solid >23 nm PN of the truck with and without UR in various VSP and speed bins are demonstrated in Figure 4. The average VSP-bin total <23 nm and solid >23 nm PN emission rates of the vehicle without and with UR both generally exhibited obvious increasing trends in all speed ranges. Compared to the neglective differences in the VSP-bin peak emission rates among different speed ranges for the total <23 nm particles, the peak VSP-bin solid >23 nm PN emission rate of the low-speed range was higher than that in the other speed ranges. It was clear that the total <23 nm particles are more sensitive to the high engine load under high-speed driving conditions when compared to the solid >23 nm particles [31]. Moreover, compared to average solid >23 nm PN emission rates, the average total <23 nm PN emission rates without UR exhibit higher values than those with UR for all VSP and speed bins. Consequently, the usage of the UR resulted in obvious reductions in the average VSP-bin total <23 nm PN emission rates but fewer reductions in solid >23 nm PN emission rates. As shown in Figure 5, larger differences also occurred between the situation with and without UR for the <23 nm PN concentrations when compared to solid >23 nm PN concentrations. This may be explained by the presence of NH3 being more conducive to the formation of total <23 nm rather than solid >23 nm particles [35].

3.3. Variation in the Correlation between NOx and CO2

As described above, more distinguished effects of the UR can be obtained on NOx compared to PN emissions. Together with the easier access to obtain NOx emissions related to PN during the emission testing and other measurements such as the remote OBD [11], the variations in the correlation of CO2 and NOx mass emission rates between the truck with and without UR under urban roads, rural roads, and the highway are thus analyzed. Figure 6 demonstrates the scatter plot diagram of CO2 (X-axis) and NOx (Y-axis) mass emission rates. The density distributions of emission rates and the fitting lines with intercept set to 0 under different road types with and without UR are also shown here. Clearly, most of the scatter for the truck with UR is located above those without UR, resulting in higher slopes for the fitting line with UR compared to that without UR. Obvious increasing differences in scatter distribution occurred between the situation with and without UR from urban roads, rural roads to the highway. This is mainly related to the increasing reduction effect of the SCR on NOx from urban roads and rural roads to the highway. The density distribution is thus more concentrated on the lower emission rates of NOx without UR compared to that with UR, especially for those emitted under the highway.
Associated with the promoted efficiency in decreasing NOx of the SCR from urban roads and rural roads to the highway, the slopes of the fitting line without UR exhibited a distinguished downward trend. On the contrary, a slightly upward trend occurred for the slopes of the fitting lines with UR, which is attributed to the deficiency of the SCR without proper urea caused by the usage of the UR. Furthermore, the emission rates of NOx and CO2 for the vehicle with UR possessed good linear correlations under all road types, with the determination coefficient R2 ranging from 0.8191 to 0.898. For the vehicle without UR, however, the determination coefficients R2 exhibited an obvious downward trend from urban roads (0.8245) and rural roads (0.6931) to the highway (0.2544). This is probably related to the cumulatively poor positive responsiveness of NOx to CO2 caused by the increasing reduction efficiency of the SCR on NOx from urban roads and rural roads to the highway [36].

4. Conclusions

Real-world emission measurements on a China IV HDDT were conducted to investigate the characteristics of NOx and PN emissions under the situation both with and without the usage of UR. An obvious increased effect on NOx and a decreased effect on PN emissions were caused by UR. Specifically, the distribution of volumetric concentration was more concentrated at high and low concentrations for NOx and PN, respectively. From urban roads and rural roads to highways, an obvious rising increased effect on NOx while a decreasing decreased effect on PN emissions was clarified. Meanwhile, the peak VSP-bin NOx emission rates exhibited markedly increasing but decreasing trends from low- and medium- to the high-speed bin for those with UR and without UR, respectively. However, no similar findings can be observed for peak VSP-bin PN emission rates. Furthermore, the UR resulted in higher NOx emissions in-unit CO2 and linear correlations of NOx and CO2 emission rates. The slopes of the fitting line between NOx and CO2 emission rates exhibited a distinguished downward but slight upward trend from urban roads and rural roads to the highway for the situation without and with UR, respectively. These findings have potential employment prospects in the real-time identification of the malfunction of the SCR caused by the UR.

Author Contributions

Conceptualization, J.L. and F.Y.; methodology, Z.Y.; software, N.W.; validation, M.F., Z.Y. and H.M.; formal analysis, F.Y.; investigation, J.L.; resources, H.M.; data curation, Z.L.; writing—original draft preparation, J.L.; writing—review and editing, F.Y.; visualization, N.W.; supervision, F.Y.; project administration, M.F.; funding acquisition, F.Y. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Data is contained within the article.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Comparison of the density distributions for NO (a) and NO2 (b) volumetric concentrations with and without the illegal application of urea regulator.
Figure 1. Comparison of the density distributions for NO (a) and NO2 (b) volumetric concentrations with and without the illegal application of urea regulator.
Atmosphere 13 01739 g001
Figure 2. Comparison of average VSP-bin NO (a) and NO2 (b) mass emission rates between the situation with and without the illegal application of urea regulator.
Figure 2. Comparison of average VSP-bin NO (a) and NO2 (b) mass emission rates between the situation with and without the illegal application of urea regulator.
Atmosphere 13 01739 g002
Figure 3. Comparison of the density distributions for total <23 nm (a) and solid >23 nm (b) PN volumetric concentrations with and without the illegal application of urea regulator.
Figure 3. Comparison of the density distributions for total <23 nm (a) and solid >23 nm (b) PN volumetric concentrations with and without the illegal application of urea regulator.
Atmosphere 13 01739 g003
Figure 4. Comparison of average total <23 nm (a) and solid >23 nm (b) PN emission rates of different VSP-bins with and without the illegal application of urea regulator.
Figure 4. Comparison of average total <23 nm (a) and solid >23 nm (b) PN emission rates of different VSP-bins with and without the illegal application of urea regulator.
Atmosphere 13 01739 g004
Figure 5. Variations in the PN size distribution under different VSP and speed bins both with and without the illegal application of urea regulator.
Figure 5. Variations in the PN size distribution under different VSP and speed bins both with and without the illegal application of urea regulator.
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Figure 6. Scatter correlation diagrams of NOx instantaneous mass emission rates as a function of CO2 for the vehicle with and without the UR under urban (a), rural (b), and highway (c) driving conditions.
Figure 6. Scatter correlation diagrams of NOx instantaneous mass emission rates as a function of CO2 for the vehicle with and without the UR under urban (a), rural (b), and highway (c) driving conditions.
Atmosphere 13 01739 g006
Table 1. Test vehicle specifications.
Table 1. Test vehicle specifications.
ParametersTruck
Vehicle brandJiefang
Vehicle typeBox stake
Fuel typeDiesel
Gross/Curb weight (t)31.0/12.7
Displacement (L)7.7
After-treatmentSCR
Emission standardChina IV
Model year2016
Odometer (km)185,205
Gearmanual 8
Table 2. Driving characteristics.
Table 2. Driving characteristics.
ParametersUrea StateUrbanRuralHighwayWhole Trip
Trip distance (km)with UR5.5 ± 0.225.9 ± 1.019.5 ± 0.250.9 ± 0.6
without UR5.2 ± 0.126.1 ± 0.719.7 ± 0.751.2 ± 0.3
Avg. speed (km/h)with UR10.7 ± 044.9 ± 0.977.2 ± 5.037.8 ± 1.3
without UR10.4 ± 0.744.5 ± 1.280.4 ± 1.338.2 ± 0.8
Avg. RPA (m/s2)with UR0.17 ± 0.040.09 ± 0.010.04 ± 00.08 ± 0.01
without UR0.19 ± 0.020.09 ± 0.010.05 ± 00.08 ± 0.01
Idle (%)with UR30.0 ± 1.50011.6 ± 0.9
without UR27.9 ± 1.00010.6 ± 1.2
Acceleration (%)with UR29.7 ± 4.628.8 ± 3.011.2 ± 1.625.9 ± 3.5
without UR31.7 ± 1.228.1 ± 4.711.6 ± 0.226.3 ± 2.1
Cruise (%)with UR17.8 ± 5.948.4 ± 4.577.8 ± 1.142.1 ± 4.3
without UR14.5 ± 2.349.3 ± 8.877.5 ± 0.641.5 ± 4.9
Deceleration (%)with UR22.6 ± 2.722.9 ± 1.511.0 ± 0.420.6 ± 1.8
without UR26.0 ± 0.122.7 ± 4.211.0 ± 0.521.7 ± 1.6
Table 3. On-road nitrogen oxides EFs of the tested truck on different road types.
Table 3. On-road nitrogen oxides EFs of the tested truck on different road types.
Road TypeUrea StateCO2 (g/km)NO (g/km)NO2 (mg/km)NOx (g/km)
Highwaywith UR726.4 ± 52.510.6 ± 1.3102.7 ± 9.010.7 ± 1.3
without UR726.6 ± 6.62.2 ± 0.132.9 ± 8.92.2 ± 0.1
IR (%)0385.0212.2382.4
Ruralwith UR770.9 ± 14.910.9 ± 0.1106.9 ± 2.911 ± 0.1
without UR771.5 ± 23.66.5 ± 0.254.9 ± 6.96.5 ± 0.2
IR (%)−0.169.294.569.5
Urbanwith UR1430.3 ± 62.921.6 ± 0.4277.7 ± 1021.9 ± 0.4
without UR1506.9 ± 86.516.9 ± 0.7160.3 ± 20.817.1 ± 0.6
IR (%)−5.127.973.228.3
Whole tripwith UR825.4 ± 30.312.0 ± 0.6123.7 ± 412.1 ± 0.6
without UR828.0 ± 17.15.9 ± 0.156.8 ± 10.35.9 ± 0.1
IR (%)−0.3104.0117.7104.1
Table 4. On-road PN EFs of the tested truck on different road types.
Table 4. On-road PN EFs of the tested truck on different road types.
Road TypeUrea StateTotal <23 nm PN (×1013 #/km)Solid >23 nm PN (×1013 #/km)PN2.5 (×1013 #/km)
Highwaywith UR1.4 ± 0.12.8 ± 0.14.2 ± 0.1
without UR2.2 ± 0.43.4 ± 0.45.5 ± 0.8
DR (%)36.916.924.7
Ruralwith UR1.7 ± 0.24.2 ± 0.95.9 ± 1.1
without UR3.1 ± 0.55.2 ± 0.88.1 ± 1.3
DR (%)45.819.227.3
Urbanwith UR2.9 ± 0.26.9 ± 2.39.8 ± 2.1
without UR7.9 ± 0.113.8 ± 0.321.7 ± 0.5
DR (%)63.150.455.0
Whole tripwith UR1.7 ± 0.14.0 ± 0.85.6 ± 0.8
without UR3.0 ± 0.74.8 ± 1.07.8 ± 1.7
DR (%)43.318.427.8
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Li, J.; Fang, M.; Yang, Z.; Lv, Z.; Wei, N.; Yan, F.; Mao, H. Impact of Illegal Application of Urea Regulator on Real-World Exhaust Nitrogen Oxygen and Particle Number Emissions. Atmosphere 2022, 13, 1739. https://doi.org/10.3390/atmos13101739

AMA Style

Li J, Fang M, Yang Z, Lv Z, Wei N, Yan F, Mao H. Impact of Illegal Application of Urea Regulator on Real-World Exhaust Nitrogen Oxygen and Particle Number Emissions. Atmosphere. 2022; 13(10):1739. https://doi.org/10.3390/atmos13101739

Chicago/Turabian Style

Li, Jingyuan, Maodong Fang, Zhiwen Yang, Zongyan Lv, Ning Wei, Fuwu Yan, and Hongjun Mao. 2022. "Impact of Illegal Application of Urea Regulator on Real-World Exhaust Nitrogen Oxygen and Particle Number Emissions" Atmosphere 13, no. 10: 1739. https://doi.org/10.3390/atmos13101739

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