KR102443689B1 - Combined conduit design method considering the flow force on clear sky - Google Patents

Abstract

The present invention is a sewage conduit design step of designing a sewage conduit using a complex cross section using the planned maximum sewage amount calculation step in consideration of the planned population, the planned rainfall amount calculation step, the planned time maximum sewage water amount and the planned storm water amount, the designed sewage pipe Converging conduit design considering small current in Cheongcheon, characterized in that the condition satisfaction determination step determines whether the condition satisfies provide a way

Description

{Combined conduit design method considering the flow force on clear sky}

The embodiment relates to a converging conduit design method in consideration of the small current in Cheongcheon. More specifically, it relates to a converging conduit design method in consideration of small currents in Cheongcheon to solve problems such as deposition, odor, and corrosion by securing an appropriate flow rate even in Cheongcheon.

In general, in Cheongcheon-si (dry season), only sewage flows into the combined sewage system (sewerage that drains rainwater and sewage into one pipe) and the entire amount is transferred to the sewage treatment plant. is introduced into the combined sewer system, and the amount of sewage discharge increases, and thus, a flow rate greater than the planned maximum sewage amount, which is the treatment capacity of the sewage treatment plant of the combined sewage system, may flow into the combined sewage system.

The standard for the flow rate of such a combined sewage pipe stipulates that the flow rate is 0.8 m/s to 3 m/s for the planned rainfall. If designed according to this standard, there is no problem with the flow as proper flow rate and flow rate are generated in rainy weather. A slow flow rate causes deposition, and there is a problem that odor is generated therefrom, and sulfuric acid is generated, which accelerates corrosion of sewer pipes.

The embodiment proposes a design method that can determine the pipe diameter and gradient of a combined sewage pipe in consideration of the amount of sewage in the city of Cheongcheon, and aims to reduce problems such as deposition, odor, and corrosion by securing an appropriate flow rate even in the city of Cheongcheon.

In addition, it aims to solve the problems that may occur in the merged conduit according to the environmental change by proposing a design method for the renovation and repair of the previously installed merging conduit to be able to respond to the changing environment.

The problems to be solved by the present invention are not limited to the problems mentioned above, and other problems not mentioned here will be clearly understood by those skilled in the art from the following description.

An embodiment of the present invention comprises: calculating the maximum amount of sewage water for a planned time in consideration of the planned population; planning stormwater calculation step; a sewage conduit design step of designing a sewage conduit using a complex cross-section using the maximum amount of sewage water during the planned time and the planned rainfall; Including; condition satisfaction determination step of determining whether the designed sewage conduit satisfies the predetermined condition A combined conduit design method considering small currents is provided.

Preferably, the condition satisfaction determination step may be characterized in that at least two conditions among conditions 2) to 6) are determined.

2) 0.8m/s ≤ the speed of the planned stormwater ≤ 3m/s

3) Slope of the design sewer pipe ≥ Slope of the downstream sewer pipe

4) Velocity of stormwater flow in design sewage pipe ≤ Velocity of downstream sewage pipe

5) Design sewage pipe planning time Maximum sewage rate ≤ Downstream sewage pipe speed

6) Spare rate of design sewer pipe (maximum amount of sewage during planned time + amount of planned rainfall) ≥ 100%

Preferably, when the condition is not satisfied in the condition satisfaction determination step, it may further comprise a pipe bottom height adjustment step of adjusting the pipe bottom height of the sewage pipe.

Preferably, the calculation of the maximum amount of sewage may be characterized in that the maximum amount of sewage for the planned time is calculated in consideration of the number of people per inter-conduit and the amount of water supplied per person per day.

Preferably, in the step of calculating the planned rainfall, the planned rainfall is calculated in consideration of the drainage area, rainfall intensity, and runoff coefficient.

In addition, the present invention is a calculation step of calculating the maximum amount of sewage for the planned time in consideration of the planned population; planning stormwater calculation step; A state diagnosis step of diagnosing the current state of the tube; a first condition satisfaction determination step of determining whether the condition of the tube diagnosed in the condition diagnosis step satisfies the conduit design condition; If the condition of the pipe does not satisfy the conduit design condition, a sewage pipe design step of designing a pipe by applying a complex cross-section; and a second condition satisfaction determination step of determining whether the conduit designed in the sewage conduit design step satisfies the conduit design condition; may be implemented as a converged conduit design method in consideration of small current in Cheongcheon, including.

Preferably, the design condition may be characterized in that at least two of 1) and 2) to 6) of the following conditions 1) to 6) are satisfied.

1) Shear force ≥ 0.5mm limit shear force of the maximum amount of sewage in the planning time

2) 0.8m/s ≤ the speed of the planned stormwater ≤ 3m/s

3) Slope of the design sewer pipe ≥ Slope of the downstream sewer pipe

4) Velocity of stormwater flow in design sewage pipe ≤ Velocity of downstream sewage pipe

5) Design sewage pipe planning time Maximum sewage rate ≤ Downstream sewage pipe speed

6) Spare rate of design sewer pipe (maximum amount of sewage during planned time + amount of planned rainfall) ≥ 100%

Preferably, when it is determined that the condition is satisfied in the second condition satisfaction determination step, the method may further include a tube condition determination step of determining a tube condition using an imaging device.

Preferably, the tube state determination step may be characterized in that the tube state is determined in consideration of the number of cracks, the tube strain rate, and the degree of corrosion.

Preferably, when it is determined that the pipe state is bad in the pipe state determination step, it may be characterized in that a concrete composite cross-section is applied.

Preferably, when it is determined that the pipe state is good in the tube state determination step, a simple complex cross-section applying step of applying a simple complex cross-section; and a margin ratio determination step of examining the margin ratio using the applied simple composite cross-section; may further include.

According to the embodiment, it is possible to design a design capable of exhibiting a fast flow rate even with a small flow rate during clearing.

In addition, it is possible to check whether sufficient small current is exerted in clear and rainy weather, thereby increasing the efficiency of design review.

In addition, it is possible to provide a rationale for logically applying a complex cross-section by providing a design methodology that can apply a multi-section sewer pipe.

Also, by increasing the flow rate, sewage odor can be reduced.

In addition, it is possible to extend the life of the sewage pipe by slowing down the corrosion rate of the sewage pipe.

In addition, it is possible to reduce the dredging costs of local governments.

In addition, by applying a complex cross-section, it is possible to lower the level of pollution in the river by reducing the amount of sediment in the pipe.

Various and advantageous advantages and effects of the present invention are not limited to the above, and will be more easily understood in the course of describing specific embodiments of the present invention.

1 is a flowchart showing a converging conduit design method in consideration of small current in Cheongcheon according to an embodiment of the present invention;
2 is a view showing a method of calculating the maximum amount of sewage water during the planned time in FIG. 1;
3 is a flowchart illustrating a method for designing a conduit conduit considering small currents in Cheongcheon according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

However, the technical spirit of the present invention is not limited to some embodiments described, but may be implemented in various different forms, and within the scope of the technical spirit of the present invention, one or more of the components may be selected between the embodiments. It can be combined and substituted for use.

In addition, terms (including technical and scientific terms) used in the embodiments of the present invention may be generally understood by those of ordinary skill in the art to which the present invention pertains, unless specifically defined and described explicitly. It may be interpreted as a meaning, and generally used terms such as terms defined in advance may be interpreted in consideration of the contextual meaning of the related art.

In addition, the terms used in the embodiments of the present invention are for describing the embodiments and are not intended to limit the present invention.

In this specification, the singular form may also include the plural form unless otherwise specified in the phrase, and when it is described as “at least one (or more than one) of A and (and) B, C”, it is combined with A, B, and C It may include one or more of all possible combinations.

In addition, in describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used.

These terms are only for distinguishing the component from other components, and are not limited to the essence, order, or order of the component by the term.

And, when it is described that a component is 'connected', 'coupled' or 'connected' to another component, the component is not only directly connected, coupled or connected to the other component, but also with the component It may also include the case of 'connected', 'coupled' or 'connected' due to another element between the other elements.

In addition, when it is described as being formed or disposed on “above (above) or under (below)” of each component, the top (above) or bottom (below) is one as well as when two components are in direct contact with each other. Also includes a case in which another component as described above is formed or disposed between two components. In addition, when expressed as “up (up) or down (down)”, the meaning of not only the upward direction but also the downward direction based on one component may be included.

Hereinafter, the embodiment will be described in detail with reference to the accompanying drawings, but the same or corresponding components are given the same reference numerals regardless of reference numerals, and overlapping descriptions thereof will be omitted.

1 to 3, in order to clearly understand the present invention conceptually, only the main characteristic parts are clearly shown, and as a result, various modifications of the illustration are expected, and the scope of the present invention is limited by the specific shape shown in the drawings it doesn't have to be

1 is a flowchart illustrating a converging conduit design method in consideration of small flow force in Cheongcheon according to an embodiment of the present invention, and FIG. 2 is a diagram illustrating a method of calculating the maximum amount of sewage water during planned time in FIG. 1 .

Referring to FIG. 1 , the method for designing a converged conduit in consideration of the small current in Cheongcheon according to an embodiment of the present invention includes a maximum sewage amount calculation step (S110), a planned rainfall amount calculation step (S120), a sewage conduit design step (S130) and conditions. It may include a satisfaction determination step (S140).

The maximum amount of sewage calculation step S110 may calculate the maximum amount of sewage for a planned time in consideration of the planned population.

Referring to FIG. 2 , the maximum amount of sewage calculation step (S110) is a step step (S111) of water supply per person calculated in consideration of the planned target year, and the average amount of sewage per person per day considering the sewage conversion rate to the amount of water supplied per person per day (S111). Calculating the average amount of sewage per person per day (S112), calculating the maximum amount of sewage per person per day (S113), calculating the amount of groundwater (S1140, calculating the planned population (S115), calculating the amount of factory wastewater and other displacements) S116), and a calculation step of calculating the maximum amount of sewage per day (S117), and a calculation step of calculating the maximum amount of sewage for a planned time (S118) may be included.

The calculation of the maximum amount of sewage per person per day ( S113 ) may be obtained by calculating the average amount of sewage per person per day/peak load rate. The peak load rate is a factor to determine the maximum daily water supply.

Peak load ratio = daily maximum water supply / daily average water supply * 100

The peak load ratio can be obtained by the above formula. At this time, the peak load rate can be analyzed by analyzing the daily supply of the local government for more than three years, and in the national or regional plan, a sample survey by population size for a representative city can be analyzed, and the climate (temperature, drought, etc.) of the year can be affected. Therefore, it is possible to determine the future peak load using the historical data of the relevant area. In addition, it can be corrected by referring to the guidelines for establishing the basic sewerage maintenance plan, foreign data, and related research. If the record age is small, the largest value among the last 2-3 years is applied, and in some cities, the 10-year probability frequency is used (AWWA) can do. The peak load can be determined according to facilities such as water purification plants, drainage basins, and drainage pipes.

The groundwater amount calculation step (S114) may be determined by multiplying the maximum amount of sewage per person per day by a certain ratio (0.1 to 0.2).

The planned population calculation step (S115) may be calculated by predicting the development situation in the planned area in the planned target year. The planned population is determined based on the population determined by national land planning and urban planning, etc. If there is no plan, it can be determined by considering the past population growth trend by administrative district unit within the planned district.

Population distribution estimation is estimated after allocating the planned total population by referring to the population density according to the land use plan. For the daytime population, it is basic to consider the resident population. can decide

The plant wastewater and other wastewater calculation step (S116) may be calculated through individual wastewater surveys or the P side.

The plan 1 day maximum amount of sewage calculation step ( S117 ) may be calculated by the following formula.

Planned maximum amount of sewage per day = (Maximum amount of sewage per person + amount of groundwater) * Planned population + factory wastewater + other displacements

The planning time maximum amount of sewage calculation step (S118) may be calculated by the following equation.

Maximum amount of wastewater during planning time = Maximum amount of wastewater per day/24 * (1.3~1.8)

In this way, the maximum amount of wastewater calculation step S110 may be calculated by sequentially performing the calculation steps.

The planned rainfall amount calculation step ( S120 ) may be calculated by vomiting the following equation.

(Where Q: maximum planned stormwater runoff (m ³ /s), C: runoff coefficient, I: mean rainfall intensity (mm/h) within runoff time (t), A: drainage area.)

However, the present invention is not limited thereto, and other well-known stormwater runoff calculation methods may be used in addition to Equation 1 above when calculating the planned rainfall amount, and rainfall interval calculation data for each region may be referred to.

In the sewage conduit design step (S130), a sewage conduit using a complex cross-section may be designed using the maximum amount of sewage water during the planned time and the planned rainfall. In the sewage pipe design step ( S130 ), the sewage pipe may be designed by selecting the diameter of the sewage pipe in consideration of the margin ratio and determining the initial value of the gradient.

The existing sewage pipe uses a round pipe or a box pipe. However, the conventional sewage pipe structure does not have a problem with the flow rate in rainy weather, but a low flow rate problem occurs in clear weather. In the sewage conduit design step (S130), there is an advantage of increasing the flow rate by increasing the hydraulic radius so as to maintain sufficient small current even in the city of Cheongcheon by using a complex cross section.

The condition satisfaction determination step ( S140 ) may determine whether the designed sewage conduit satisfies a predetermined condition.

In the condition satisfaction determination step ( S140 ), the following conditions 1) to 6) may be considered.

1) Shear force ≥ 0.5mm limit shear force of the maximum amount of sewage in the planning time

2) 0.8m/s ≤ the speed of the planned stormwater ≤ 3m/s

3) Slope of the design sewer pipe ≥ Slope of the downstream sewer pipe

4) Velocity of stormwater flow in design sewage pipe ≤ Velocity of downstream sewage pipe

5) Design sewage pipe planning time Maximum sewage rate ≤ Downstream sewage pipe speed

6) Spare rate of design sewer pipe (maximum amount of sewage during planned time + amount of planned rainfall) ≥ 100%

In the above condition, the downstream sewer pipe means a relative relationship with the design sewer pipe.

In the condition satisfaction determination step ( S140 ), condition 1) is always determined, and the remaining conditions 2) to 6) may determine whether at least two conditions are satisfied.

In the condition satisfaction determination step ( S140 ), the pipe diameter and gradient of the level at which the appropriate sewage can flow even in the clearing city is determined in consideration of the planned sewage amount and the planned maximum sewage amount in rainy weather. In the present invention, there is an advantage that rainwater and sewage can be considered at the same time because the planned sewage amount is based on rain.

In addition, considering the maximum amount of sewage for the planned time, a strong small current is generated at least once a day so that the particles deposited can erode, thereby preventing problems due to deposition.

From this point of view, condition 1) can determine that sufficient small current is exerted when the shear force of the maximum amount of sewage water during the planned time is higher than the limit shear force. At this time, the limit shear force can be determined based on the composite cross-section tube auxiliary tube.

In addition, by determining whether at least two of the existing design conditions 2) to 6) are satisfied, the reliability of the design may be increased.

When it is determined that the designed sewage conduit does not satisfy the predetermined condition, the condition satisfaction determination step S140 may further include a pipe bottom height adjustment step S150 of adjusting the pipe bottom height of the sewage pipe.

The pipe bottom height adjustment step (S150) may satisfy a predetermined condition by adjusting the pipe bottom height of the designed sewage pipe to change the flow rate.

3 is a flowchart illustrating a method for designing a conduit conduit considering small currents in Cheongcheon according to another embodiment of the present invention.

The converging conduit design method in consideration of the small current in Cheongcheon shown in FIG. 3 aims at designing the confluent conduit when renovating and repairing the sewage conduit.

Referring to FIG. 3 , the converging conduit design method in consideration of the small flow power in Cheongcheong-si according to another embodiment of the present invention includes the calculation of the maximum amount of sewage for the planned time in consideration of the planned population (S210), the calculation of the planned rainfall (S220), and the current pipe In the state diagnosis step (S230) of diagnosing the state of If the conduit design condition is not satisfied, the sewage conduit design step (S250) of designing a conduit by applying a complex cross section and the second condition satisfaction determination for determining whether the conduit designed in the sewage conduit design step satisfies the conduit design condition It may include step S260.

The calculation step (S210) and the calculation step (S220) of the maximum amount of sewage water for the planned time considering the planned population may be calculated in the same way as described above.

The state diagnosis step ( S230 ) may diagnose the state of the pre-installed sewage pipe. In one embodiment, the state diagnosis step (S230) may diagnose the state of the current sewage pipe by measuring the pipe height, pipe diameter, pipe straight length, and illuminance coefficient.

After diagnosing the tube state, the first condition satisfaction determination step S240 is performed.

The first condition satisfaction determination step S240 may determine the conditions of 1) to 6) below.

1) Shear force ≥ 0.5mm limit shear force of the maximum amount of sewage in the planning time

2) 0.8m/s ≤ the speed of the planned stormwater ≤ 3m/s

3) Slope of the design sewer pipe ≥ Slope of the downstream sewer pipe

4) Velocity of stormwater flow in design sewage pipe ≤ Velocity of downstream sewage pipe

5) Design sewage pipe planning time Maximum sewage rate ≤ Downstream sewage pipe speed

6) Spare rate of design sewer pipe (maximum amount of sewage during planned time + amount of planned rainfall) ≥ 100%

In one embodiment, in the first condition satisfaction determination step (S240), it is determined that the design condition is satisfied when at least two of the conditions 1) and 2) to 6) among the conditions 1) to 6) are satisfied. can do. The description of the design conditions is the same as described above.

When it is determined that the condition is satisfied in the first condition satisfaction determination step S240 , the tube condition determination step S241 of determining the tube condition through the imaging apparatus may proceed.

In the pipe state determination step S241, the inside of the pipe may be detected by using an image image for detecting the inside of the pipe, and through this, the state of a pre-installed pipe may be determined.

In one embodiment, the tube state determination step (S241) may determine the state of the pre-installed tube in consideration of the number of cracks, tube strain, and corrosion degree.

When it is determined that the pre-installed pipe condition is good in the pipe condition determination step (S241), the pipe condition is maintained, and when it is determined that the pipe condition is bad, the pre-installed pipe can be repaired.

In addition, when it is determined that the conduit design condition is not satisfied in the first condition satisfaction determination step ( S240 ), the sewage conduit design step ( S250 ) of designing a conduit by applying a complex cross-section is performed.

The sewage pipe design step (S250) can increase the flow rate by increasing the hydraulic radius to maintain sufficient small current even in the city of Cheongcheon by using a complex cross section. Through this, it is possible to prevent the accumulation of foreign substances by securing a certain small current even in the city of Cheongcheon.

After the sewage conduit is designed with a complex cross section, a second condition satisfaction determination step (S260) of re-determining whether the designed conduit satisfies the conduit design condition is performed.

In the second condition satisfaction determination step S260 , it may be determined whether the condition is satisfied in the same manner as the first condition satisfaction determination step S240 .

When it is determined that the condition is satisfied in the second condition satisfaction determination step S260 , the tube state determination step S261 using the imaging apparatus may proceed again.

When it is determined that the pre-installed pipe state is suitable in the pipe condition determination step (S261), a simple composite cross-section application step (S262) of applying a simple composite cross-section and a spare rate determination step (S264) of reviewing the spare rate using the applied simple composite cross-section (S264) can proceed.

If the margin ratio is sufficient in the margin ratio determination step (S264), the simple composite cross-section is used as it is, and when it is determined that the margin ratio is insufficient, it moves to the concrete composite cross-section application step (S263).

In addition, even when it is determined that the pipe state is bad in the tube state determination step (S261), it moves to the compound cross-section application step (S264) to apply the composite cross-section using concrete.

If the condition is not satisfied in the second condition satisfaction determination step (S260), the office height adjustment step (S270) proceeds.

The pipe bottom height adjustment step (S270) may satisfy a predetermined condition by changing the flow rate by adjusting the pipe bottom height of the designed sewage pipe. When the sewage pipe whose pipe bottom height is adjusted goes through the condition satisfaction determination step (S280) again, the design conditions described above are re-determined. If not, the government base height adjustment step (S270) is again adjusted to adjust the official base height.

As described above, the embodiments of the present invention have been described in detail with reference to the accompanying drawings.

The above description is merely illustrative of the technical idea of the present invention, and various modifications, changes and substitutions are possible within the scope that does not depart from the essential characteristics of the present invention by those of ordinary skill in the art to which the present invention pertains. will be. Accordingly, the embodiments disclosed in the present invention and the accompanying drawings are for explanation rather than limiting the technical spirit of the present invention, and the scope of the technical spirit of the present invention is not limited by these embodiments and the accompanying drawings. . The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

Claims (11)

Calculating the maximum amount of wastewater during the planning time considering the planned population;
planning stormwater calculation step;
a sewage conduit design step of designing a sewage conduit using a complex cross-section using the maximum amount of sewage water during the planned time and the planned rainfall;
Including; condition satisfaction determination step of determining whether the designed sewage conduit satisfies a predetermined condition;
The condition satisfaction determination step includes determining at least two of the conditions 1) and 2) to 6) among the conditions of 1) to 6) below.
1) Shear force ≥ 0.5mm limit shear force of the maximum amount of sewage in the planning time
2) 0.8m/s ≤ the speed of the planned stormwater ≤ 3m/s
3) Slope of the design sewer pipe ≥ Slope of the downstream sewer pipe
4) Velocity of stormwater flow in design sewage pipe ≤ Velocity of downstream sewage pipe
5) Design sewage pipe planning time Maximum sewage rate ≤ Downstream sewage pipe speed
6) Spare rate of design sewer pipe (maximum amount of sewage during planned time + amount of planned rainfall) ≥ 100% delete The method of claim 1,
If the condition is not satisfied in the condition satisfaction determination step,
A converging conduit design method in consideration of small flow in Cheongcheon, characterized in that it further comprises a pipe bottom height adjustment step of adjusting the pipe bottom height of the sewage pipe. The method of claim 1,
The step of calculating the maximum amount of sewage is,
A converging conduit design method considering small flow in Cheongcheon-si, characterized in that the maximum amount of sewage water during the planning time is calculated in consideration of the number of people per conduit and the amount of water per person per day. The method of claim 1,
The step of calculating the planned rainfall is,
A converging conduit design method considering small current in Cheongcheon, characterized in that the planned rainfall is calculated in consideration of the drainage area, rainfall intensity and runoff coefficient. Calculating the maximum amount of wastewater during the planning time considering the planned population;
planning stormwater calculation step;
A state diagnosis step of diagnosing the current state of the tube;
a first condition satisfaction determination step of determining whether the condition of the tube diagnosed in the condition diagnosis step satisfies the conduit design condition;
If the condition of the pipe does not satisfy the conduit design condition, a sewage pipe design step of designing a pipe by applying a complex cross-section; and
a second condition satisfaction determination step of determining whether the conduit designed in the sewage conduit design step satisfies the conduit design condition;
including,
The design condition is a converging conduit design method considering small current in Cheongcheon, characterized in that it satisfies at least two of the conditions 1) and 2) to 6) among the conditions of 1) to 6) below.
1) Shear force ≥ 0.5mm limit shear force of the maximum amount of sewage in the planning time
2) 0.8m/s ≤ the speed of the planned stormwater ≤ 3m/s
3) Slope of the design sewer pipe ≥ Slope of the downstream sewer pipe
4) Velocity of stormwater flow in design sewage pipe ≤ Velocity of downstream sewage pipe
5) Design sewage pipe planning time Maximum sewage rate ≤ Downstream sewage pipe speed
6) Spare rate of design sewer pipe (maximum amount of sewage during planned time + amount of planned rainfall) ≥ 100% delete 7. The method of claim 6,
When it is determined that the condition is satisfied in the second condition satisfaction determination step,
A converging conduit design method in consideration of small current in Cheongcheon-si, further comprising the step of determining the condition of the tube by using an imaging device. 9. The method of claim 8,
The tube state determination step is a converged conduit design method considering small currents in Cheongcheon, characterized in that the tube state is determined in consideration of the number of cracks, tube strain, and corrosion degree. 10. The method of claim 9,
When it is determined that the tube state is bad in the tube state determination step,
A converging conduit design method considering small current in Cheongcheon, characterized by applying a concrete composite cross-section. 10. The method of claim 9,
When it is determined that the tube condition is good in the tube condition determination step,
A simple complex cross-section application step of applying a simple complex cross-section; and
a margin ratio determination step of examining the margin ratio using the applied simple composite cross-section;
A converging conduit design method taking into account the small flow force of Cheongcheon-si further comprising a.

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