Comprehensive Test and Evaluation Analysis of Permeable Concrete (PC) Clogging by Using Steel Slag

Institute of Alpine Economics and Botany, Yunnan Academy of Agricultural Sciences, Lijiang 674100, China School of Architecture and Civil Engineering, Yunnan Agricultural University, Kunming 650000, China Key Laboratory of Crop Growth and Intelligent Agriculture of Yunnan Province, Yunnan Agricultural University, Kunming 650000, China College of Hydraulic Engineering, Yunnan Agricultural University, Kunming 650000, China Jiangsu University of Science and Technology, School of Civil Engineering, Zhenjiang 212003, China


Introduction
Recently, due to the rapid urbanization and increasing consumption of natural resources, researchers are investigating various strategies to protect and restore natural ecosystems around the world to avail an economical and environmentally friendly way [1][2][3]. PC is the most widely used building material in sponge city construction because of its environmentally friendly characteristics. In recent years, the researcher has made considerable progress and development in PC, but there are still many problems in PC. It is necessary to develop its strengths and overcome its weaknesses. Permeable concrete pavement (PCP) is the type of concrete that features an open network of pores to allow penetrating the rainwater through the concrete pavement to the base/subbase [4][5][6][7][8]. e pore-clogging of PC is the most prominent problem in the use of PC [9]. Due to the lack of rainfall, strong wind, and sand, the PC pore-clogging will not only reduce the permeability effect but also seriously affect its service life after a long winter [10].
Urban areas are associated with impenetrable infrastructure, which increases the potential of surface water runoff and flooding during periods of heavy rainfall. Permeable concrete is generally an important, sustainable, and cost-effective urban sanitation system that can reduce rainwater runoff and alleviate local flood problems [11].
High permeability ensures good drainage. erefore, PC has been widely used in the quality and quantity management of urban runoff [12]. For the southern part of China, although there is more rainwater, the surface runoff generated by rainwater also carries the sediment of pavement, seeds of flowers and grass, and humus produced by road waste into the pore of PC, which also reduces the performance of PC [13]. Pratt found that when the road surface is dry, the accumulated particles will form a hard shell to seal the pore of PC. When the permeability coefficient of PC is less than the rainfall intensity, the pore-clogging will lead to the decrease of permeability rate, eventually leading to surface overflow and water accumulation [14]. Plant debris build-up is mainly responsible for physical clogging on the surface as well as in the pore structure; this is probably the most common mechanism. Similarly, biological clogging brought by bacteria and algae and penetration of plant roots can also happen [15]. Dry materials contain sand, silt, and clay sediments and cause clogging from surrounding areas [16], including waste from roads or other areas carried through a vehicle, small particles produced on the pavement due to surface wear or other degradation, and organic matter from plants [11,17]. Schaefer studied that sand resulted in a significant decrease in permeability, while fine silty clay had a little effect. e combination of silty clay and sandy soil will lead to a decrease in permeability, and PC will be completely blocked after a small amount of cycling. is is due to the wider particle size distribution, which increases the probability of retention of various particle size plugs [18].
Guthrie evaluated the freeze-thaw resistance of PC under different soil clogging and water saturation. e sand was collected near the actual PCP to simulate the site environment. It was found that the samples with blocked or fully saturated pavement or both were more susceptible to disease than those without blocked or unsaturated pavement [19]. A less amount of sand can improve the working capacity, strength, and durability of freezing/thaw and strength of PCP without losing their permeability [20]. Freezing/thaw tolerance of durable PC arranged with the crushed layer can be acceptable for tolerated of low traffic loads pavement [21]. In PC, ignore the use of fine aggregates to create a network of pores. Porous structure makes the pavement perform good permeability and the rain infiltrates quickly into the ground because it can reduce the estimated flood [22][23][24]. According to ACI when the particle size of sediment is close to the pore size of PC, the probability of clogging may be the highest [25,26]. Welker screened the materials from the pore of permeable asphalt and PC in the parking lot and found that there were few fine sediments. Because of the serious wear condition of PCP, most of the blocking materials came from the degradation of pavement [27].
Coughlin suggested that the coarse sand particles of PCP did not significantly reduce its permeability because the large particles were prevented from entering the surface pore [28]. A durable and strong PCP can be recognized by using less quantity of fine aggregates, consuming a somewhat higher w/c ratio, addition of polypropylene, making known to entraining air and increase the paste volume, and replacing fly ash [29] and silica fume [30] with Portland cement or use a latex admixture [31]. e compressive strength can be significantly increased by the addition of nanomaterials in PCP [32]. Wang et al. investigated the addition of steel slag as a partial aggregate, and the results showed an improvement in the mechanical properties of PC [33].
Concrete compressive strength behavior is depending on the size, distribution, and spacing of pores [34,35]. PCP has a wide range of features, e.g., 15-30% of effectual air voids, 20-500 m/day permeability, and 5.5-20.5 MPa compressive strength [36]. e permeability coefficients of PCP are usually from the range of 2-6 mm/s, and some of them increase even up to 10 mm/s, and the porosity varies between 15 and 25%. e suspended particles can block the pores of PCP, like debris and sediment in the surface runoff causing to reduce the permeability and also reducing the age of PC [17,37], and the compressive strength is generally between 3.5 MPa and 30 MPa. PC has been widely used in drainage facilities of municipal roads, park sidewalks, parking lots, and other places [38]. PCP can considerably advantage the environment in urban sites, which can reduce the rainwater runoff quantity and also can improve the quality of water regarding total [39,40]. e objective of this research article is to conduct a comprehensive test on the clogging of PC and evaluate and analyze it. e main objective is to critically review available studies on clogging, summarize, and understand the problem and mitigating strategies. e influence of porosity, w/c ratio, and freeze-thaw times on the compressive strength of PC after freeze-thaw is studied by the response surface method. Response surface methodology (RSM) is used to analyze the influence of three factors, namely, the height of rainwater runoff, the horizontal runoff velocity, and the porosity, on the clogging of PC.

Materials and Methods
According to the construction requirements of Honghe Avenue, the low-alkali P.O 42.5 cement produced by Lafaji Dongjun Cement Co., Ltd., Kunming city, is selected for the test. e standards of cement that meet the requirements of ordinary Portland cement are the American ASTM C159. Its physical and mechanical properties of cement are given in Table 1. While, the coarse aggregate used in this test is steel slag, produced in Kunming Iron and Steel Holding Co., Ltd. Steel slag is a by-product of the steelmaking process, which mainly consists of tricalcium silicate, dicalcium silicate, calcium magnesium olivine, calcium magnesium rosopyroxene, dicalcium ferrite, and other minerals. Chemical composition of cement and steel slag is given in Table 2. e size of steel slag selected in this test is 4.75-9.5 mm, which conformed to ASTM D5106-15, and the physical properties of steel slag are given in Table 3. Similarly, the mineral admixture used in this experiment is fly ash; the physical properties are given in Table 4; the fine ash is collected from the flue gas after coal combustion. e main oxide composition is SiO 2 , Al 2 O 3 , FeO, Fe 2 O 3 , CaO, and TiO 2 . Its related indicators comply with the "Technical specifications for the application of fly ash concrete" (ASTM C618- 19), and its physical parameters are given in Table 4. e w/c ratio in 2 Advances in Civil Engineering this experiment is 0.38, 0.40, and 0.42, respectively, and the water used in the test mixing concrete is the local tap water, which meets the requirements of concrete mixing.

Mix Proportion.
Various mix proportioning methods have been recommended, and the most key necessity is to provide satisfactory cement paste to bind aggregates and achieve the high void content and required strength. e absolute volume method is used to calculate the mix design [25,34]. Less than 15% porosity of concrete tends to provide a very slow water filtration due to lacking interlocked voids [42]. Porosity is more than 35%, very highly permeable, but the strength of concrete decreases; therefore, the target porosity of this research experiment is divided into three groups as 15%, 20%, and 25%, respectively. e mix proportions are given in Table 5. e air-entraining agent used in this test comes from Hongxiang Building Admixture Factory, Laiyang city, Shandong Province. e general content of the airentraining agent is not more than 0.3% of the cement quality. is study selects 0.1% gel strength agent, fly ash, polymer emulsion, and cement must be mixed in a certain proportion to improve the strength of PC. e specimens were demolded after 48 hours of casting, and then, the specimen was placed in the standard curing room until the required age. e standard curing adopted in this experiment was to put the specimen blocks together in the standard curing room with a temperature of 20 ± 2°C and relative humidity of 95% for 48 hours.

Determination of Porosity of PC.
In combination with the test conditions, the gravimetric method is used to determine the porosity of PC. e cured test specimens were placed in a drying box for 24 hours, the mass m1 after drying is weighed, and the size of the test specimens was measured with a ruler to calculate the volume V of the test specimen. en, the test specimen is placed in water for 6 hours, and then, the mass m2 of the test specimen in the water is weighed by an electronic scale with a hook. e difference in mass before and after weighing is the actual buoyancy of the specimen due to the filling of the pores by water. If the porosity of the specimen is zero, then the buoyancy of the specimen is theoretically subtracted from the buoyancy received by the specimen. e porosity P is obtained by the following formula: where P is the porosity of PC (%), m1 is the mass of the test specimen in water (g), m2 is the quality of the test specimen after drying in the drying box for 24 h (g), Ρ w is the density of water (g/cm 3 ), and V is the volume of the test specimen (cm 3 ). e porosity measured by the gravimetric method and the measurement data is shown in Figure 1.

Determination of Compressive Strength of PC.
e compressive strength is measured according to the standards (ASTM C39/39M-18). e concrete mix design ratio for C20    and C30 was calculated for all specimens [43,44], with a 0.38 water-cement ratio. Clean and free of deleterious matter tap water was used in the concrete mix, as given in Table 6, which requires the standard specimen to have compressive strengths of 20 MPa and 30 MPa, respectively, after reaching the curing period. e mixtures were prepared and cast into 150 mm × 150 mm × 150 mm cubical and cylindrical specimen Φ100 mm × 100 mm molds into layers per the ASTM C 1435 standard. e test loading speed is controlled at 0.3-0.8 MPa/s. e compressive strength of PC is given in Table 6, which was determined by using the following formula: where f is the permeability of the PC cube (MPa), F is PC cube test specimen damage load (N), and A is the bearing area of the PC specimen (mm 2 ).

Determination of Water Permeability of PC.
e fixed water head method was used to determine the permeability coefficient. To record the change of the permeability coefficient of PC in real-time, the device is equipped with two electronic water pressure sensors and one ultrasonic flow sensor, all measured data. When the permeability coefficient test is carried out, the two water pressure sensors can record the pressure changes on the upper and lower surfaces of the test specimen in real-time, which can reflect the head loss. e hydraulic gradient is obtained by using the following formula: where h 1 and h 2 are the pressure values of the upper and lower surfaces of the PC specimen (KPa), h w is the head loss after water flowing through the PC specimen (KPa); L is the height of the test specimen (mm), and i is the hydraulic gradient. e outlet pipe of the device is equipped with an ultrasonic flow sensor; it can dynamically collect and transmit the flow velocity v2 of the water pipe, and then, the flow velocity v1 in the PC specimen block can be derived by the formula, according to Darcy's law and formula (4). It is concluded that the permeability coefficient k is determined by the hydrostatic concrete method. e derivation formula is [45] where k is the permeability coefficient of PC specimen (mm/ s), v1 is the water flow velocity in the PC specimen (mm/s), v2 is the water flow velocity in the outlet pipe (mm/s), i is the hydraulic gradient, L is the height of the test specimen (mm), h w is the head loss after water flowing through the PC  specimen (KPa), A ou is the cross-sectional area (the outlet pipe is mm 2 ), and A s is the effective area of the cross-section after applying Vaseline on the PC specimen (mm 2 ).

Determination of Freeze-aw Resistance of PC.
In this experiment, the quick-freezing method is used for the freeze-thaw test. e KDR-V9 rapid freeze-thaw test machine is used, and the concrete has a cubical shape with the size of 150 mm × 150 mm × 150 mm. Dry the surface with a dry cloth to record the transverse fundamental frequency, modulus of elasticity, and mass of the specimens used to characterize the freeze-thaw durability of PC. e minimum temperature was −18°C, the maximum temperature was 7°C, the temperature difference between the inside and outside of the test specimen should not be greater than 28°C, the freezethaw is controlled within 10 min, and the time for each freeze-thaw cycle test is controlled to about 4 hours. e quick freeze-thaw of the PC weight loss after the test (called the Cantabro loss) is calculated in percentage by using the following formula: where W is the mass loss rate of the PC specimen after n freeze-thaw cycles (%), G 0 is the initial mass of PC specimen before freeze-thaw cycle test (Kg), G n is the quality of the PC specimen after n freeze-thaw cycle test (Kg).

Comprehensive Test of PC Clogging.
e PC clogging experiment uses the aforementioned permeability coefficient test equipment, and the test is carried out according to the following steps: before performing the test, put the test specimen into clean water and soak it for 24 hours, so that the test specimen reaches the saturated water state. After the soaking time is reached, take out the test specimen, wipe the moisture on the surface of the test specimen with a dry cloth, then apply petroleum jelly to the test specimen, pack the test specimen, and then put the test specimen into the plexiglass sleeve inside the tube. To prevent water leakage between the flanges and affect the test data, a rubber gasket can be added between the sleeve and the base, and finally, tighten the screws between the flanges to fix the upper and lower parts of the device. Turn off the ball valve switch on the base of the equipment, turn on the water pump, and spray the water evenly into the sleeve with a spray device. When the water head reaches the predetermined water head height, open the ball valve on the base again, which will let the sleeve a relatively stable head height is generated inside, and there are no bubbles in the water flow. At this time, the pressure sensor and the flow sensor are connected to the power supply, and the two sensors are connected to the seepage test pressure and the flow test system with a data cable, so that the measured flow value and the water pressure on the upper and lower surfaces of the test specimen can be transmitted to the data collection in realtime in the system.

Advances in Civil Engineering
After the permeability coefficient becomes stable, add 50 g of the plugging material uniformly into the sleeve. At this time, record the start time and end time of adding the plugging material and then test until the permeability coefficient approaches stability. To simulate the effect of rainwater runoff depth on the pore-clogging of PC, this set of test equipment is equipped with three different head heights, which are 100 mm, 150 mm, and 200 mm, respectively. Considering that horizontal runoff at different speeds will also affect pore-clogging, the spiral action of the blades is used to produce a horizontal rotation disturbance on the upper surface of the specimen. e diameter of the propeller blade is 60 mm, and its distance from the upper surface of the specimen is 10 mm. In this test, a total of 3 different speeds are set, which are divided into low-speed, mediumspeed, and high-speed rotation. e maximum runoff velocity and average runoff velocity produced by each rotation speed are given in Table 7. Adding blocking substances and a certain rotation speed can simulate the clogging of PC in a real rainfall environment.

Permeability Test and Test Plan of PC Blocked.
e main factors affecting the permeability coefficient after clogging of PC are the height of the head, the porosity of the test specimen, and the horizontal runoff generated by the different water flow velocities on the surface of the test specimen. e test scheme is given in Table 8, and the actual operation of the test is shown in Figure 2. Before and after, the test specimen is blocked, as shown in Figure 3.

Analysis of the Influence of Rainwater Runoff Head Height on the Clogging of Permeable Concrete.
is test analyzes the influence of the head height generated by surface rainwater runoff on the clogging of PC by changing the height of the water head. Take the test schemes 1, 2, and 3 in Table 8 as examples. e height of the test water head was set to 100 mm, 150 mm, and 200 mm, without stir, to simulate the process of plugging with low speed just as normal rainfall condition, and the permeability of PC used in this set of tests was 20%. Figure 4 shows the normalized permeability coefficient of PC under different head heights. It can be seen from Figure 3 that PC under the high head is more prone to clogging, mainly because the higher the head height, the higher the seepage velocity. e larger the clogging material, the easier it is to block as the water under high permeation forces enters the pores. Due to the surface runoff with different flow rates generated by heavy rains, the blocking material will aggravate the clogging of the permeable concrete under the synergistic effect of surface runoff. In this experiment, the speed of the blade is used to simulate different runoff velocities, taking schemes 2, 4, and 5 in Table 8 as examples.

Results
e analytical test design includes contour lines and response surface diagrams for quadratic terms of data such as analysis of variance, quadratic regression equation fitting, and residuals. ree factors are optimized: water-cement ratio, porosity, and the number of freeze-thaw cycles, and finally, the maximum response value, the value of the corresponding three factors, and the predicted result are obtained. e target porosity (A), w/c ratio (B), and the number of freeze-thaw cycles (C) were used as the three influencing factors to freeze and thaw PC. e design test factor and its level for determining the compressive strength are given in Table 9.
e response surface test plan and results are given in Table 10.
Perform analysis of variance and test the significance of the regression equation, and the results are given in Table 11. Observe the analysis of variance table, where P < 0.0001; the model can be considered to be extremely significant; the lack of fit in the table reflects the degree of difference between the model and test; the lack of fit in this test P � 0.0593 > 0.05; it can be concluded that the model is related to the test data and is significant. Adj R 2 � 0.9481 represents the model's correction determination coefficient, which shows that the model can explain 94.81% of the response value change; the multiple correlation coefficient R 2 � 0.9773, which proves that the model fits well; the coefficient of variation (CV) represents the confidence of the model. e smaller the value, the higher the confidence of the test. In this test, CV � 4.51%, which shows that the model can reflect the test situation. Based on the above analysis, it can be concluded that the reliability of this model is high, and the regression equation can analyze the test results very well.
It can be seen from Figure 5 that when the A(B) factor is a certain value, the compressive strength of PC after freezethaw increases with the increase of the value of the factor B(A), indicating that the slope of the surface is steep at this time. e contour line is more concentrated, which can explain that factors A and B have a significant effect on the compressive strength of PC after freeze-thaw [46], but from the trend of the three-dimensional surface map, it can be seen that the A factor is resistant to freeze-thaw of PC. e compressive strength is significantly higher than factor B [47,48]. As can be seen from Figure 6, the density of the medium-high line of the abscissa is higher than that of the contour of the ordinate, indicating that the influence of factor A on the compressive strength of PC after freeze-thaw is higher than that of the C factor. It can be seen from Figure 7 that the distortion of the three-dimensional surface is small, indicating that the interaction between the two factors B and C is not obvious, and the contour of the abscissa is higher than the contour of the middle coordinate, indicating the influence of factor B on the compressive strength of PC after freezing and thawing is greater than factor C. 6 Advances in Civil Engineering It can be seen from the data in Table 10 that the compressive strength of PC after freeze-thaw is less than the compressive strength before freeze-thaw, which is mainly because the freeze-thaw cycle test destroys the skeleton structure inside PC. e order of influence of three factors on the compressive strength of PC after freeze-thaw is as follows: A porosity > B w/c ratio > freeze-thaw cycle C, which appears as a steep curve in the three-dimensional response surface. Flat, the absolute value of the coefficient in the model regression equation can be verified by sorting A > B > C as given in Table 11. e above contours cannot compare the significance of the interaction of various factors, but the absolute value comparison of the interaction factor coefficients in the model regression equation can be known: AB > BC > AC, indicating that the interaction between the two factors of AB    Advances in Civil Engineering is the greatest. After the Box-Behnken center combination design and response surface optimization, it can be predicted that the PC pores are at 18.31%, the w/c ratio is at 0.41, and the strength is the largest after 75 freeze-thaw cycles, and the value reached 18.73 MPa, which indicates that PC is more suitable for engineering use.   Figure 6: Influence of porosity A and freeze-thaw C on compressive strength after freeze-thaw. e process of the permeability coefficient of PC after clogging can be divided into three stages: in the first stage, the permeability coefficient drops sharply after the clogging material is added; in the second stage, the permeability coefficient shows a certain rise, phenomenon; in the third stage, the permeability coefficient begins to slowly decrease and finally approaches stability [49]. As can be seen from Figure 8, the first phase can be considered as a fast-clogging phase, which lasts for approximately 160 seconds. e second stage can be considered as a partial clogging phase, which lasts for approximately 90 s. e oscillating rebound of the permeability coefficient at this stage is because the smaller particle size clogging material will flow out of the pore channel with the pore water flow. As the clogging material accumulates in the pore channel inside PC [50], its permeability coefficient approaches stability, and this stage can be regarded as a progressive clogging stage.
is test simulates different runoff flow rates by the rotational speed of the blades, taking schemes 2, 4, and 5 in Table 8 as examples.
e height of the test head was set to 100 mm, 150 mm, and 200 mm [51], and the permeability of PC used in this set of tests was 20%. e normalized permeability coefficient is shown in Figures 9 and 10. It can be seen from the experimental results that after the horizontal runoff of different speeds, the high-level flow rate appears to be faster than the other two types of runoff speeds. is is mainly because high-level runoff will cause the clogging material to suspend. In the water body, when the clogging material approaches the low flow velocity region on the surface of the test specimen, it enters the pore of the test specimen with the action of the penetrating force. In addition, their permeability coefficients are approximately equal during the progressive stabilization phase, indicating that the high horizontal flow rate delays the clogging of PC.

Porosity Analysis of Clogging of PC.
e clogging test is carried out with PC specimens of different porosities [52,53]. Taking schemes 2, 6, and 7 in Table 8 as examples, the test results are shown in Figure 10. It can be seen that the larger the porosity of the specimen block, the more easy the specimen is clogged. is is because the larger the porosity of the test specimen, the greater the seepage velocity inside the pore [54,55]. More clogging materials will enter the internal pore with high penetration force, which increases the possibility of clogging of the test specimen. It can also be seen from the image that the permeability coefficient of the 25% porosity of the test specimen after clogging has a certain fluctuation.
It can be known from the above analysis that the factors affecting the permeability coefficient after clogging of PC are the porosity of the test specimen, the height of the head, and the horizontal runoff velocity of the surface. To analyze the weight of the three factors in this experiment, the above three factors are analyzed based on Design-Expert 8.0.6 software, and the experiment was conducted by using Box-Behnken in the Design-Expert 8.0.6 software [56]. e target porosity, head height, and surface horizontal runoff velocity were used as the three influencing factors to penetrate the PC after clogging. e coefficient is the response surface, and the test factors and design are given in Table 12. Regression fitting analysis of the permeability coefficient data of the PC in the table by Design-Expert software can be used to obtain the quadratic multiple regression equation of the coded value of the permeability coefficient after clogging: permeation rate after e response surface test protocol and results are given in Table 13. e regression equation and the significance test were performed on the regression equation. e results are given in Table 14.
In the analysis of variance table, P < 0.0001, P � 0.0533 > 0.05; it can be concluded that the model is related to the test data and significant. Adj R 2 � 0.9798, complex correlation coefficient R 2 � 0.9911, coefficient of variation, CV � 4.51%; it can be further explained that the test reliability is high and the model fitting degree is good. e response surface and contour plots 28 Figure 7: Effect of w/c ratio B and freezing-thawing times C on compressive strength after freeze-thaw.
for the above three factors are shown in Figures 11, 12, and 13. It can be seen from Figure 11 that when the A factor is constant, the permeability coefficient of PC is reduced as the value of the factor B increases, indicating that the slope of the curved surface is steep and the contour line is more concentrated. e factor B permeability coefficient after clogging of PC is more significant, so for PCP that are not cleaned for a long time.
Correlation coefficient: R 2 � 0.9911, Adj R 2 � 0.9798, CV � 4.86%, Adeq precision � 30.033. In the case of strong rain, there will still be water accumulation on the road. From the trend of the three-dimensional surface map, it can be seen that the B factor has a significantly higher permeability coefficient after clogging of PC [57]. e shape of the contour line in Figure 12 is approximately elliptical, indicating that the   interaction between factor A and factor C is obvious. is can reflect the interaction between target porosity and surface horizontal runoff. e degree of influence on the permeability coefficient after clogging is large, but from the viewpoint of the contour mass, it is impossible to discriminate the degree of influence of the A factor and C factor. Figure 13 shows that when the C factor is fixed, the slope of the B factor is steep and the contour is dense, indicating     Figure 11: Influence of target porosity A and head height B on the permeability coefficient after clogging. Advances in Civil Engineering 13 that the B factor is more influential than the C factor. e order of influence of three factors on the permeability coefficient after clogging of PC is as follows: B head height is higher than A target porosity and C surface horizontal runoff speed, but the degree of influence of A and C factors cannot be discerned [58].

Effect of the Freeze-aw Cycle Test on the Performance of PC after
Clogging. e connection form between the PC aggregates is a point contact connection; the special skeleton structure relies on the connection of the cementing material. When PC is frozen and thawed after being blocked, the internal structure will change. Kevern et al. [20] believed that clogging will not only lead to a decrease in the permeability coefficient but also accelerate the process of PC under freeze-thaw conditions. Soil particles and other clogging substances will saturate and expand by 2-3% under freezing conditions. In response to this, the freeze-thaw test of the PC after clogging becomes critical. e PC after the clogging of the 6 test plans is subjected to the freeze-thaw test. It can be known from the previous conclusion that the horizontal surface runoff velocity has a little effect on the clogging degree of the PC. erefore, medium-speed surface runoff is used in this test. To make the PC block full and achieve the most unfavorable effect, each test specimen is blocked under the high head. Table 15 provides the compressive strength data of PC before and after clogging.
It can be seen from the above table that the PC specimen block undergoes freeze-thaw action after clogging, and its compressive strength decreases. It can be explained that clogging shortens the service life of PC, so the clogging of PC pores becomes clear.

Conclusions
is study carefully observes the PC specimens after clogging, and there is a small period of flattening of the permeability coefficient at the beginning of clogging. en, the plugging particles continue to enter the pores of the test specimen under the action of permeability, and the permeability coefficient of the test specimen drops sharply, entering the rapid clogging stage [59]. Under the action of horizontal runoff, part of the clogging material remains on the surface of the test specimen returned to the water flow. At this time, the permeability coefficient of the test specimen had a short recovery stage. With the passage of time and the continuous accumulation of blocking substances in the pores inside the specimen, the PC specimen finally enters the gradual clogging stage [60].
In this study, related experiments are done in three aspects: different rainwater runoff head heights, different horizontal runoff velocities, and different porosities. e test shows that at different rainwater runoff head heights, the clogging of the PC specimens under high water heads is the most serious. is is mainly because a high water head will produce greater penetration force, and small particle blocking substances will enter the test under the action of penetration force. In the clogging test of PC by horizontal runoff at different speeds, due to the different carrying capacities of the clogging material by the horizontal runoff at different speeds, combined with the effect of inertia, the rapid clogging stage of the high-speed horizontal runoff is slightly later than the other two speed tests, but with time, the clogging effect of the specimen is roughly the same.
In the plugging test of PC with different porosities, it can be seen from the images obtained from the test that after the test specimens with different porosities are blocked, the clogging of the test specimens with large porosity is the most serious. is is mainly because the higher the seepage velocity inside the PC specimen with larger porosity, the more clogging material will enter the internal pores with high permeability, which increases the possibility of specimen clogging.
After the test, it is found that the quadratic regression equation of the compressive strength of the specimens has a better fit after freeze-thaw. It can be seen from the obtained response surface that the porosity of the PC specimen has a higher degree of influence on the compressive strength of the specimen after freeze-thaw than the other two factors and the interaction between the porosity of the PC and the w/c ratio. e effect also has a higher degree of influence on the compressive strength of the specimen after freeze-thaw.
rough the analysis of the test data, it is predicted that when the porosity of the PC is 18.31% and the w/c ratio is 0.41, the resistance strength value of the specimen is the largest after 75 freeze-thaw cycles, and its value can reach 18.73 MPa.
is study uses the same test indicators to perform related tests on the blocked permeable concrete. From the test data, the compressive strength of the blocked permeable concrete has decreased. In a freeze-thaw environment, the destruction process is faster than that of unblocked specimens.
Utilizing steel slag and recycled concrete as fine aggregate could save the consumption of natural resources and reduce environmental pollution; the successful use of slag steel as a permeable pavement provides a new and more cost-effective method for increased resources and reduces the threat from solid waste to the environment.
However, more studies should be carried out on the mechanical characteristics of PCP with different additives, recycled materials, and wastes.

Data Availability
e data used to support the findings of this study are included within the article.

Conflicts of Interest
e authors declare that they have no conflicts of interest.