How to make dry well for effective drainage solutions

How to make dry well is an essential guide for homeowners and environmental enthusiasts alike, providing you with the knowledge to effectively manage excess water in your area. Understanding the significance of dry wells can lead to improved drainage systems that not only benefit your property but also contribute positively to the environment.

In this comprehensive overview, we will delve into the various aspects of constructing a dry well—from selecting the right materials and site to following a step-by-step construction process. By the end of this guide, you’ll be equipped with all the necessary information to create a dry well that enhances your property and promotes sustainable water management.

Importance of Dry Wells

In the realm of residential development, the implementation of dry wells has emerged as a vital component in managing water runoff and enhancing environmental sustainability. These underground structures serve a dual purpose: mitigating flooding and replenishing groundwater supplies. The increasing frequency of severe weather events accentuates the necessity for effective drainage solutions like dry wells, which can significantly improve water management in urban settings.The benefits of having a dry well in residential areas extend beyond immediate flood control.

They play a crucial role in ensuring that excess rainwater is absorbed back into the ground rather than being directed into storm drains. This not only reduces the risk of urban flooding but also aids in maintaining the natural water cycle. Dry wells are particularly beneficial in areas with heavy rainfall or high water tables, as they provide an effective solution for managing surplus water.

Environmental Conservation Contributions

The environmental benefits of dry wells are manifold, primarily focusing on water management and conservation. By facilitating the absorption of stormwater, dry wells help to reduce surface runoff, which can carry pollutants and sediment into local waterways. This natural filtration process is essential for maintaining water quality in streams, rivers, and lakes. To illustrate their impact, consider the following:

• Groundwater Recharge: Dry wells promote groundwater recharge by allowing water to seep into the aquifer, which is crucial for maintaining water supplies, especially in drought-prone areas.
• Pollution Mitigation: By reducing surface runoff, dry wells minimize the transport of contaminants into nearby water bodies, thus preserving aquatic ecosystems.
• Habitat Preservation: The installation of dry wells can support local flora and fauna by maintaining groundwater levels, which are essential for the survival of various species.

Successful examples of dry well implementation can be seen in various communities. For instance, in Portland, Oregon, the city has integrated dry wells into its stormwater management strategy, resulting in reduced flooding and improved water quality in the Willamette River. Similarly, in San Diego, California, neighborhoods have adopted dry well systems to manage runoff from heavy rains, protecting both residential areas and local waterways.

“Investing in dry wells is investing in the future of our water resources.”

Materials Needed for Constructing a Dry Well

Constructing a dry well requires careful selection of materials to ensure effective drainage and longevity. The choice of materials not only impacts the functionality of the dry well but also its resistance to erosion and wear over time. Below is a comprehensive list of essential materials along with their specifications.

Essential Materials for Dry Well Construction

The following materials are crucial for building a durable and efficient dry well. Each material has specific characteristics that enhance the overall structure and performance of the dry well.

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Material	Specifications
Stone or Gravel	Size: 1-2 inches in diameter; Type: Coarse aggregate to allow for proper drainage.
Perforated PVC Pipe	Diameter: 4-6 inches; Length: Varies based on depth; Type: Schedule 40 for durability.
Geotextile Fabric	Type: Non-woven; Weight: 4-6 oz; Purpose: Prevents soil from clogging the gravel.
Concrete or Block	Size: Standard blocks (16x8x8 inches); Type: For forming the structure of the dry well.
Sand	Type: Clean, coarse sand; Purpose: Fills gaps between stones and aids drainage.
Drainage Fittings	Type: Elbows and connectors; Purpose: To connect pipes and direct water flow efficiently.
Gravel Screen	Type: Wire mesh; Size: ½ inch openings; Purpose: Prevents debris from entering the dry well.

“The right combination of materials not only maximizes the efficiency of the dry well but also minimizes maintenance issues in the long run.”

Selecting the right materials is fundamental to the successful construction of a dry well. Each component serves a specific purpose that contributes to the overall effectiveness of the drainage system.

Site Selection for a Dry Well

Selecting the right site for a dry well is crucial for its effectiveness and longevity. The chosen location significantly influences the well’s ability to manage stormwater and promote groundwater recharge. Identifying key factors during site selection can prevent future complications and ensure optimal performance.When evaluating potential sites for a dry well, several critical criteria should be considered. This evaluation will help to ensure that the dry well functions as intended, facilitating efficient drainage and minimizing environmental impact.

Key Factors in Site Selection

The following key factors play an essential role in selecting a suitable location for a dry well:

• Soil Type: Sandy or loamy soils are preferable as they allow for easier water infiltration. Clay soils, on the other hand, can hinder drainage and should be avoided.
• Proximity to Structures: Ensure that the dry well is located at a safe distance from buildings, foundations, and other structures to prevent water damage.
• Elevation and Drainage Patterns: An ideal site should be situated in an area where natural drainage flows towards the dry well, minimizing the risk of flooding.
• Groundwater Levels: The dry well must be placed above the seasonal high groundwater level to prevent interference with its functioning.
• Land Use: Evaluate the surrounding land use to mitigate risks of contamination from nearby sources, such as industrial areas or septic systems.

Each of these factors contributes to the overall effectiveness of a dry well. Understanding these elements can help guide the selection process, ensuring both functionality and compliance with local regulations.

Site Evaluation Criteria

A systematic checklist can streamline the site evaluation process. The following criteria should be assessed during site selection:

• Soil Permeability: Conduct percolation tests to assess how quickly water will move through the soil.
• Potential for Contamination: Identify nearby sources of pollutants to evaluate the risk of groundwater contamination.
• Access for Maintenance: Ensure that the site is accessible for regular inspections and maintenance activities.
• Environmental Impact: Consider the ecological implications of placing a dry well in the selected area.
• Local Regulations: Verify compliance with local building codes and regulations regarding stormwater management.

Utilizing this checklist fosters a thorough understanding of potential risks and benefits associated with the selected site, guiding effective decision-making.

Challenges in Site Selection

Site selection for a dry well may pose various challenges, which, if not addressed, could hinder its performance. Some common challenges include:

• Inadequate Soil Conditions: If the soil does not permit adequate drainage, consider alternatives such as soil amendments or a different site altogether.
• High Groundwater Levels: If groundwater is too close to the surface, developers might need to design a different stormwater management system.
• Urban Development Constraints: In urban areas, finding a suitable site might be challenging due to space limitations. Collaboration with local authorities can help identify feasible solutions.
• Regulatory Hurdles: Navigating the complex web of local regulations can be daunting. Engaging with local agencies early in the planning process can smoothen compliance.

Addressing these challenges through careful planning and consultation can lead to successful dry well implementation, ensuring effective stormwater management and sustainability.

Step-by-Step Construction Process

Constructing a dry well involves a systematic approach that ensures efficiency and effectiveness in managing excess water. By following the steps Artikeld here, you can successfully build your own dry well, designed to alleviate drainage issues while promoting groundwater recharge.The process requires careful planning and the right tools to achieve the desired outcome. Below, the steps are detailed to guide you through the construction of a dry well from start to finish, ensuring that you have a clear understanding of each phase.

Preparation and Planning

The first phase is crucial as it lays the foundation for the entire project. This step involves determining the location and size of the dry well.

1. Select a Suitable Location

Identify an area away from structures and utilities where the dry well can effectively capture water.

2. Determine Size and Depth

Calculate the dimensions based on the amount of runoff water expected. A common size is a 3-4 foot diameter and depth. Tools Required:

• Measuring tape
• String and stakes (for marking)
• Shovel
• Level

Excavation

Once the planning phase is complete, the next step is to excavate the site for the dry well.

3. Mark the Area

Use string and stakes to Artikel the excavation area based on the determined size.

4. Dig the Hole

Start digging with a shovel, maintaining the sides as vertical. Aim for a depth of at least 3-4 feet. Tools Required:

• Shovel
• Pickaxe (if necessary)
• Wheelbarrow (for removing soil)
• Level (to ensure even depth)

Setting the Base and Lining

With the hole excavated, you need to prepare the base for the dry well.

5. Create a Base

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Place a layer of gravel at the bottom of the pit to facilitate drainage.

6. Line the Pit

Use a landscaping fabric to line the sides of the hole. This prevents soil from clogging the gravel. Tools Required:

• Gravel (clean, coarse gravel works best)
• Landscaping fabric (geotextile)
• Rake (for leveling gravel)

Installing the Dry Well Structure

The structure of the dry well is essential for its function.

7. Place the Dry Well Container

If using a prefabricated dry well unit, position it in the center of the pit. If constructing one, stack concrete blocks or use a plastic or metal container.

8. Fill Around the Container

Add more gravel around the sides of the container, ensuring it is stable and secure. Tools Required:

• Prefabricated dry well unit or concrete blocks
• Shovel
• Gravel

Finalizing the Installation

The final steps complete your dry well, ensuring it functions as intended.

9. Cover with More Gravel

Add a final layer of gravel above the container, leaving it slightly below ground level.1

0. Seal the Top

Use soil or mulch to cover the gravel, making the area look natural and preventing debris from entering the well. Tools Required:

• Soil or mulch
• Shovel
• Rake

“A well-constructed dry well can significantly enhance drainage, reduce flooding, and support local ecosystems.”

Maintenance and Inspection

Regular maintenance and inspection are crucial for the long-term functionality and efficiency of a dry well. Proper care ensures that the system continues to manage water drainage effectively, preventing issues such as flooding or groundwater contamination. By adhering to a well-defined maintenance schedule, homeowners and property managers can protect their investment and safeguard the surrounding environment.Necessary maintenance tasks for keeping a dry well in optimal condition include clearing debris, ensuring proper drainage, and checking for blockages.

Over time, sediment can accumulate, leading to reduced efficiency. Therefore, it is essential to routinely inspect the dry well, removing any leaves, dirt, or other materials that could impede water flow.

Maintenance Tasks

Regular upkeep of a dry well involves several key tasks essential for maintaining its function. The following points Artikel these tasks and their importance:

• Debris Removal: Regularly remove leaves, twigs, and any other debris from the top of the dry well. This prevents clogs that could lead to overflow.
• Inspecting the Inlet: Ensure that the inlet to the dry well is clear. This is where water enters the structure, so blockages can significantly diminish performance.
• Checking the Permeable Layer: Examine the surrounding soil to ensure it remains permeable. Compaction can hinder the drainage process.

Establishing a timeline for inspections is equally vital for effective maintenance. Scheduling inspections on a seasonal basis or after significant rainfall events can help catch potential issues early.

Inspection Timeline

The following schedule provides a clear timeline for conducting regular inspections and maintenance tasks:

• Seasonal Inspections: Conduct thorough inspections at the beginning of each season to assess any changes or necessary maintenance.
• Post-Rainfall Checks: After heavy rainfall, check the dry well to ensure that it has properly drained and that there are no visible issues.
• Annual Maintenance: Perform an in-depth cleaning and inspection once a year, including the removal of sediments and debris accumulation.

Common problems can arise with dry wells, but many can be resolved with simple troubleshooting techniques. Identifying issues early can prevent costly repairs and ensure the system operates efficiently.

Troubleshooting Common Issues

Understanding typical issues associated with dry wells enables effective troubleshooting. Here are common problems and their remedies:

• Standing Water: If water remains at the surface, investigate possible blockages in the inlet or downspout. Clear any obstructions to restore flow.
• Odors: Unpleasant smells may indicate stagnant water. Inspect for leaks or backups and ensure proper drainage is established.
• Soil Erosion: If the surrounding area shows signs of erosion, it may indicate improper installation or capacity issues. Evaluate the design and consider adjustments to increase effectiveness.

Each maintenance task, inspection, and troubleshooting method contributes to the resilience of the dry well system, ensuring that it remains a functional component in the management of stormwater and groundwater. By adhering to these practices, property owners can enjoy the benefits of a well-maintained dry well for years to come.

Legal and Regulatory Considerations: How To Make Dry Well

Understanding the legal framework surrounding the installation of dry wells is essential for homeowners and contractors alike. Regulations vary significantly across regions, reflecting local environmental concerns and land use policies. Failing to comply with these regulations can result in costly penalties and project delays. Therefore, a comprehensive grasp of the necessary permits and guidelines is paramount before commencing construction.

Regulations Governing Installation

Regulatory frameworks for dry wells are designed to protect groundwater from contamination and manage stormwater effectively. Various jurisdictions set specific criteria that must be adhered to, including the location, design, and maintenance of dry wells. It is crucial to consult local regulations to ensure compliance. Here are notable points related to these regulations:

• Some regions may require dry wells to be a certain distance from property lines, septic systems, or wells to prevent contamination.
• In many municipalities, the design of dry wells must consider soil type and drainage capacity to ensure effectiveness.
• Regular inspections and maintenance may be mandated to ensure the dry well operates properly over time.

Permits Required Prior to Construction

Before constructing a dry well, obtaining the appropriate permits is often a requirement. Different regions have varying permit requirements, which might include:

• Stormwater management permits to ensure proper handling of runoff.
• Building permits, particularly if the installation modifies the land significantly.
• Environmental impact assessments, depending on the scale of the project and its potential effects on local ecosystems.

Legal Guidelines Summary Table

To provide a clear understanding of the legal guidelines governing dry well installations across various regions, the following table summarizes key requirements:

Region	Permit Required	Regulatory Body	Key Guidelines
California	Stormwater Management Permit	California Regional Water Quality Control Board	Minimum distance from wells and septic systems is 100 feet.
Texas	None, but local permits may apply	Local Municipalities	Follow local regulations regarding soil testing and water drainage.
New York	Building Permit	New York State Department of Environmental Conservation	Must comply with the State Environmental Quality Review Act.
Florida	Environmental Resource Permit	Florida Department of Environmental Protection	Consider stormwater management and habitat preservation.

“Compliance with local regulations not only safeguards the environment but also ensures the longevity and efficiency of your dry well.”

Alternative Solutions and Comparisons

In the pursuit of effective stormwater management, several options stand as alternatives to dry wells. Among these, soakaways and rain gardens present viable solutions, each with distinct characteristics and functionalities. Understanding these alternatives helps in selecting the most suitable method tailored to specific environmental conditions and land usage.Comparing these drainage solutions allows for informed decisions based on their respective advantages and disadvantages.

Each method serves the common goal of managing excess water but does so through different mechanisms, influencing effectiveness, maintenance, and ecological impact.

Comparison of Dry Wells, Soakaways, and Rain Gardens

A comprehensive evaluation of these drainage solutions reveals their strengths and weaknesses. Below is a detailed comparison highlighting the primary features of each method.

Feature	Dry Wells	Soakaways	Rain Gardens
Functionality	Collects and stores stormwater for gradual absorption	Allows water to infiltrate through gravel into the soil	Utilizes vegetation to absorb and filter runoff
Installation	Requires excavation and a basin; often more complex	Less complex, usually requires less excavation	Involves planting and soil amendments; can be labor-intensive
Maintenance	Regular inspection needed to avoid clogging	Minimal maintenance; designed for self-cleaning	Requires care for plants, including weeding and watering
Cost	Higher installation costs; material-heavy	Moderate costs; less material required	Varies widely based on plant selection and design
Space Requirements	Requires significant space; depth can be an issue	More flexible regarding space; installed below ground	Space-intensive; depends on garden design
Environmental Impact	Effective for localized drainage, but not natural	Can enhance groundwater recharge	Supports biodiversity and improves aesthetics

Each method presents unique benefits. Dry wells are effective for immediate drainage needs, while soakaways promote natural infiltration, minimizing surface runoff. Rain gardens not only serve functional purposes but also enhance landscape aesthetics and biodiversity. Understanding these differences aids in selecting the best solution for individual drainage challenges.

Environmental Impact Assessment

The integration of dry wells into urban landscapes has become increasingly vital for effective stormwater management. These structures not only mitigate flooding but also enhance local ecosystems by promoting groundwater recharge and improving water quality. Understanding the ecological benefits and conducting thorough environmental impact assessments are essential steps for communities considering the installation of dry wells.Dry wells serve as significant tools in managing excess stormwater runoff, reducing the likelihood of urban flooding while replenishing aquifers.

By allowing rainwater to percolate into the ground, they help maintain the natural hydrological cycle. Moreover, the ecological benefits extend beyond mere water management; dry wells can foster biodiversity by creating microhabitats for various organisms. Assessing their environmental impact encompasses a discussion of these benefits, alongside the factors that contribute to a successful implementation.

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Ecological Benefits and Role in Stormwater Management

The installation of dry wells contributes positively to the surrounding environment and plays a critical role in stormwater management strategies. Key ecological benefits include:

• Groundwater Recharge: Dry wells facilitate the absorption of rainwater, replenishing local aquifers and ensuring a sustainable water supply for flora and fauna.
• Flood Mitigation: By capturing excess stormwater, dry wells reduce surface runoff, which can lead to urban flooding and waterlogging of ecosystems.
• Improved Water Quality: These systems filter pollutants from stormwater, preventing contaminants from entering local water bodies and enhancing overall water quality in the area.
• Biodiversity Support: Dry wells can create habitats that support various plant and animal species, contributing to greater ecosystem diversity.

The positive impact of dry wells on local ecosystems can be illustrated through various case studies. For instance, in cities like Portland, Oregon, the implementation of dry wells has led to a measurable decrease in urban flooding incidents while simultaneously promoting wildlife habitats. Similarly, in Chicago, the integration of dry well systems in green spaces has not only managed stormwater but also enhanced the aesthetic and ecological value of neighborhoods, attracting pollinators and other wildlife.

Guide for Assessing Environmental Impact

Conducting an environmental impact assessment for the installation of a dry well involves a systematic evaluation of potential effects on local ecosystems. Key steps to consider include:

• Site Assessment: Evaluate the proposed site for its hydrological characteristics, soil types, and existing ecosystems. This includes understanding the natural drainage patterns and potential ecological sensitivities.
• Water Quality Testing: Prior to installation, assess the quality of existing groundwater and surface water to establish baseline conditions and monitor any changes post-installation.
• Impact Prediction: Analyze how the dry well will affect local groundwater levels, surface runoff, and potential interactions with nearby ecosystems, including flora and fauna.
• Mitigation Strategies: Develop plans to address any identified negative impacts, which may include additional landscaping or habitat restoration efforts to support local biodiversity.

In summary, the environmental impact assessment of dry wells is a crucial process that ensures these structures not only serve their intended purpose of managing stormwater but also harmonize with and support the surrounding ecosystems. The careful consideration of ecological benefits and impacts can lead to enhanced sustainability in urban development.

Case Studies Illustrating Positive Effects

Several real-world examples demonstrate the successful implementation of dry wells and their beneficial effects on local ecosystems. Notable cases include:

Location	Description	Results
Portland, Oregon	Integration of dry wells in residential areas to manage stormwater runoff.	Reduction in flooding incidents and improved local groundwater levels.
Chicago, Illinois	Use of dry wells in city parks to capture rainwater.	Enhanced biodiversity and increased habitat for pollinators.
Seattle, Washington	Installation of dry wells in combined sewer overflow areas.	Decrease in overflow events and improved water quality in local waterways.

These case studies illustrate that with thoughtful planning and execution, dry wells can provide substantial environmental benefits while enhancing the resilience of local ecosystems against the challenges posed by urbanization and climate change.

Cost Analysis of Building a Dry Well

Constructing a dry well is an effective way to manage stormwater runoff and recharge groundwater. However, understanding the costs involved is crucial for effective budgeting and planning. This section will break down the estimated costs associated with building a dry well, highlighting not only the direct expenses but also the hidden costs that may arise during the process.Building a dry well involves several key costs, including materials, labor, permits, and potential site preparation.

Each of these costs can vary significantly based on location, the size of the dry well, and other site-specific factors. Additionally, certain unforeseen expenses may arise, impacting the overall budget. By analyzing these factors, prospective builders can better prepare for the financial commitment involved in their project.

Estimated Costs of Constructing a Dry Well

The costs associated with constructing a dry well can be categorized into several components, each contributing to the total expenditure. Below is a detailed breakdown of these costs:

• Materials: The primary materials required include gravel, perforated piping, and geotextile fabric. The total material cost can range from $500 to $1,500, depending on the dry well’s size and design.
• Labor: Hiring professionals for installation can cost between $1,000 to $3,000, depending on local labor rates and the complexity of the project.
• Permits and Fees: Local regulations may necessitate permits, which can range from $100 to $500.
• Site Preparation: This may involve excavation and grading, with costs averaging between $500 and $2,000 based on site conditions.

In summary, the estimated total cost for constructing a dry well typically ranges from $2,100 to $7,000, depending on various factors.

Potential Hidden Costs

While the primary costs are easily quantifiable, several hidden costs can unexpectedly arise during construction. Awareness of these potential expenses can help in creating a more accurate budget.

• Site Conditions: Unforeseen conditions such as rocky soil or high water tables can increase excavation costs significantly.
• Maintenance and Repairs: After construction, routine maintenance may be necessary, which can incur annual costs that should be factored into the budget.
• Environmental Assessments: If local regulations require environmental assessments, these can add additional costs ranging from a few hundred to several thousand dollars.
• Insurance Adjustments: Depending on the project’s scale, additional insurance coverage may be required, leading to increased premiums.

Cost Comparison with Alternatives to Dry Wells

When considering the construction of a dry well, it’s beneficial to compare its costs with those of alternative stormwater management systems. Below is a table that provides a comparative analysis of the costs associated with various options:

Stormwater Management Option	Estimated Cost Range	Notes
Dry Well	$2,100 – $7,000	Effective for residential use; requires proper site analysis.
Infiltration Basin	$5,000 – $20,000	Requires more land area; effective for larger sites.
Rain Garden	$1,500 – $5,000	Natural solution; may require ongoing maintenance.
Retention Pond	$15,000 – $50,000	Large-scale solution; can address significant runoff.

Community Involvement and Education

The essence of a sustainable dry well project lies not just in its construction but in the collective effort of the community. Engaging local residents fosters a sense of ownership and responsibility, ensuring the longevity and effectiveness of water management systems. By actively involving the community, we not only enhance the project’s success but also cultivate awareness and appreciation for vital water conservation practices.A crucial strategy for engaging communities in dry well projects is through collaborative planning and participation.

This involves inviting community members to share their insights and preferences during project design and implementation. Their input can provide valuable context and relevance to the project, ensuring it meets local needs effectively. Additionally, establishing partnerships with local organizations and schools can amplify outreach efforts and create a broader impact.

Educational Workshops and Programs, How to make dry well

Educational workshops and programs play a vital role in ensuring community members are well-informed about dry wells and their significance in water management. These initiatives can serve as platforms for knowledge sharing, skills development, and hands-on experience. The following ideas can help structure effective educational sessions:

• Workshops on Construction Techniques: Hands-on workshops can teach community members how to construct and maintain dry wells, focusing on practical skills and local materials.
• Water Management Seminars: Organize seminars that discuss the importance of water conservation, the role of dry wells, and broader sustainable water management strategies. Guest speakers from environmental organizations can provide expert insights.
• School Programs: Develop educational programs for schools that include interactive activities like building miniature dry wells or conducting water-related experiments. This can engage younger generations and instill values of conservation early on.

Resources for Community Learning

To empower communities with knowledge about water management techniques, a variety of resources can be made accessible. Providing materials that are both informative and engaging will enhance understanding and application. Consider the following resources:

• Online Courses: Platforms offering courses on water conservation and management can be beneficial. These courses often include interactive modules and community forums for discussion.
• Informational Booklets: Distributing booklets that Artikel step-by-step processes for creating and maintaining dry wells, alongside best practices for water conservation, serves as a handy reference.
• Local Resource Centers: Setting up dedicated centers where community members can access information, tools, and support for dry well projects can foster ongoing engagement and learning.

“The success of any community project lies in the active participation and informed action of its members.”

Through targeted educational efforts and community involvement strategies, dry well initiatives can flourish, ensuring that communities not only benefit from effective water management but also become stewards of their water resources.

Closure

In conclusion, mastering how to make dry well not only empowers you to improve your own drainage issues but also fosters a sense of community involvement and environmental responsibility. As we reflect on the benefits and processes Artikeld, remember that investing in a dry well is investing in the future of our ecosystems and local communities.

Clarifying Questions

What is the primary purpose of a dry well?

A dry well is designed to manage excess stormwater runoff, allowing it to infiltrate into the ground and reduce flooding risks.

How deep should a dry well be?

The depth of a dry well typically ranges from 3 to 6 feet, depending on local soil conditions and drainage requirements.

Can I install a dry well myself?

Yes, with the right tools and knowledge, you can install a dry well yourself, but consulting with a professional is advisable for complex drainage issues.

Are there any maintenance requirements for a dry well?

Regular inspections and maintenance such as cleaning debris and ensuring proper drainage flow are essential for the longevity of a dry well.

What are the signs that my dry well needs attention?

Signs include standing water in the area, slow drainage during heavy rain, or a noticeable increase in flooding.