Alchatek Blog

Managing a diverse array of stormwater system components can be a daunting task. Maintenance managers must juggle curb inlets, drop inlets, manholes, and culverts, each with its unique set of issues and repair needs. Toss in a wide geographic coverage area, and the complexity escalates. Faced with limited resources and pressing timelines, how should a maintenance team prioritize which repairs to tackle first?

The Role of Condition Assessment

Accurate condition assessment stands as the cornerstone of effective asset management. The use of technology, such as closed-circuit television (CCTV) for inspections, can offer detailed insights into the current state of various stormwater system components. High-resolution images and videos facilitate the identification of leaks, cracks, and other structural weaknesses that may require immediate intervention.

Quantifying Repair Urgency

Once a thorough condition assessment has been performed, the next step involves quantifying the urgency of each repair. This involves developing a scoring system that takes into account factors such as:

• Severity of the leak or damage
• Impact on hydraulic efficiency
• Proximity to critical infrastructure
• Potential for environmental harm

The scores generated can then serve as a guide, allowing maintenance managers to address the most pressing issues first.

Risk-Based Prioritization

Taking a step further, integrating a risk-based approach adds another layer to the prioritization process. This involves assessing the risk of failure for each component and the associated consequences. For example, a leak in a manhole located near a critical roadway may warrant immediate action due to the higher risk and greater impact of potential failure.

Budgetary Constraints and Cost-Effectiveness

While urgency and risk are essential factors, budgetary constraints cannot be overlooked. Cost-effectiveness comes into play when determining the type of repair to be carried out. For example, polyurethane grout might offer long-term savings by reducing the need for frequent resealing while limiting the need to reenter a confined space.

Documenting and Updating Repair Records

Effective asset management requires meticulous record-keeping. After completing each repair, it is crucial to update the asset's condition in the maintenance database. This updated information will aid in future condition assessments

Necessity of Stakeholder Communication

Keeping stakeholders informed about the status of repairs and any changes in prioritization is essential for smooth operations. Whether it's the city council, environmental agencies, or the general public, transparent communication helps build trust and can sometimes even result in additional funding or support for critical repairs.

Expert Consultation for Complex Decisions

For particularly challenging prioritization decisions, consulting with experts in stormwater systems maintenance can provide invaluable insights. External audits of the asset management process can also identify areas for improvement and validate the existing prioritization methodology.

Future-Proofing the Stormwater System

Incorporating resilience into the stormwater system design helps future-proof assets. This involves considering factors like climate change and urbanization while prioritizing repairs. For instance, reinforcing structures that are likely to experience increased stress due to rising storm frequencies can be a wise long-term investment.

Key Takeaways

In summary, prioritizing stormwater system repairs is a multifaceted challenge that requires a strategic approach. Condition assessment, risk-based prioritization, and budgetary considerations all play crucial roles. Effective documentation, flexibility in resource allocation, transparent communication, and expert consultation further enhance the asset management process. By adopting a comprehensive and dynamic approach, maintenance teams can ensure that they address the most critical repairs first, thereby safeguarding the integrity and efficiency of the stormwater system.

Want more information on sealing leaks in municipal infrastructure? 

When it comes to sealing leaks in stormwater systems, one size does not fit all. Whether dealing with curb inlets, drop inlets, manholes, or culverts, the choice of sealing material plays a pivotal role in the success and longevity of the repair. Cementitious grouts and polyurethane grouts represent the main contenders in the field. Knowing when and where to use each is crucial for a sustainable solution.

Cementitious Grouts: Old but Gold?

Cementitious grouts have been around for quite some time and are often the go-to option for many maintenance teams. Composed of a mixture of cement, sand, and water, these grouts provide a robust but somewhat rigid seal. They are best suited for areas where minimal movement is expected post-repair, such as static joints or stable concrete structures.

Pros:

• Economical and readily available
• Easy to mix and apply
• Excellent for filling large gaps and voids

Cons:

• Limited flexibility; may crack under stress or movement
• Longer curing time, delaying return-to-service
• Potential for shrinkage, compromising the seal

Polyurethane Grouts: The Future of Sealing

Polyurethane grouts have emerged as a modern, versatile option for sealing leaks. These grouts react with water to expand, filling cracks and gaps with a flexible, water-resistant seal. They are particularly effective for dynamic systems that may experience ongoing stress or movement.

Pros:

• Excellent flexibility; adapts to structural movement
• Quick cure times facilitate rapid return-to-service
• Effective in a wide range of conditions and materials

Cons:

• More expensive upfront cost
• Requires specialized equipment for application
• Skill-intensive; necessitates trained personnel for effective application

Location-Specific Choices

Certain leaks necessitate specific sealing methods based on their location within the stormwater system. For example, curb inlets often fare better with polyurethane grouts due to the frequent movement from vehicular traffic. On the other hand, stable, non-dynamic structures like concrete walls may be adequately served by cementitious grouts.

Deciding Factors in Choice

When choosing a sealing method, maintenance teams should consider factors such as:

• Type and location of the leak
• Expected post-repair environmental conditions
• Budget constraints
• Availability of skilled labor and specialized equipment
• Required longevity of the repair

Training and Expert Consultation

Given the complexities involved in choosing the right sealing method, training and consultation with experts in the field are highly recommended. Properly trained personnel are more likely to make the right choice the first time, reducing the risk of future leaks and subsequent repairs.

Key Takeaways

The choice of sealing method is a multi-faceted decision that requires a comprehensive understanding of the leak's nature, the system's requirements, and the pros and cons of available options. Regular training and expert consultation can go a long way in ensuring that maintenance teams are equipped to make the best choice for sustainable and effective leak sealing.

Want more information on sealing leaks in municipal infrastructure? 

Leaks in stormwater systems can be elusive, often manifesting their symptoms far from the actual point of origin. This is especially true for interconnected systems like manholes or box culverts, where water can travel significant distances before showing visible signs of a leak. Accurate identification of the leak source is crucial for any effective repair operation. Failure to correctly locate the leak can result in wasted time, resources, and ultimately, unsuccessful repair.

Where to Begin the Search

To start the search for a leak, maintenance teams often look for visible signs like water pooling, erosion, staining, or the accumulation of sediment. These are valuable indicators but can be misleading if the leak's origin is not directly adjacent to these signs. Mapping out the stormwater system's topology can offer insights into how water flows through it, providing clues about where to begin the investigation.

Types of Leaks in Different Components

The types of leaks can vary depending on the component, making it essential to understand the characteristics of each. For example, leaks in curb inlets may manifest as localized pooling of water or sediment deposition around the inlet. In contrast, leaks in manholes could result in soil erosion around the manhole cover or even within the manhole structure. Each component has its own set of challenges when it comes to leak detection, so it's crucial to approach them individually yet systematically.

The Complexity of Interconnected Systems

Interconnected systems like box culverts and manholes add another layer of complexity to leak source identification. Water from a leak can travel through multiple channels before finally emerging, making it difficult to pinpoint the origin. In such cases, a systematic approach to eliminating potential leak sources is invaluable. Teams may have to inspect multiple connected components to rule out false positives and zero in on the real leak source.

Advantages of Correct Identification

Accurately identifying the leak source has several benefits. The first is, of course, the efficiency of the repair operation. Targeted repairs save time and materials. Additionally, accurate identification can also prevent further deterioration. When leaks go unaddressed or are incorrectly repaired, the risk of soil erosion, sinkholes, structural weakness, and even potential system failure increases.

A Highly Effective Sealing Material

After accurately identifying the leak source, polyurethane grouts serve as a highly effective sealing material. Their application is targeted, preventing waste and ensuring that the leak is completely sealed. Polyurethane grouts also offer the benefit of compatibility with different kinds of surfaces, making them suitable for a wide range of stormwater system components.

Key Takeaways

In summary, accurate leak source identification is critical for effective and efficient repair of stormwater systems. The process involves a deep understanding of the system's components and the benefits of polyurethane grouts for effective sealing. Maintenance teams can greatly benefit from a systematic approach to leak identification, backed by proper training and thorough documentation. This not only ensures successful repairs but also contributes to the long-term resilience and efficiency of the stormwater system.

Want more information on sealing leaks in municipal infrastructure?

Hydraulic inefficiency in stormwater systems can wreak havoc in urban settings, especially during times of heavy rainfall or storms. When stormwater systems become less effective in draining water, it increases the risk of localized flooding and may even contribute to infrastructure failure. The problem often boils down to leaks and cracks in crucial components like curb inlets, drop inlets, manholes, and culverts.

Recognizing Symptoms

Identifying hydraulic inefficiency starts with a keen observation of several signs that indicate a system is not operating optimally. These symptoms may include but are not limited to, reduced flow rates, unexpected pooling of water near stormwater inlets, or even backups in areas where there was previously a smooth flow of water. Regular monitoring can help pinpoint these indicators and flag them for further investigation. This is a proactive step that can be taken to prevent inefficiencies from escalating into larger issues.

Role of Leaks and Cracks

Leaks and cracks in system components directly contribute to the reduction in hydraulic efficiency. For example, when a curb inlet has a crack, not only does it allow an unwanted inflow of sediment and debris, but it also reduces the capacity of the inlet to channel stormwater effectively. Similarly, leaks in manholes can lead to soil infiltration, adding unnecessary volume to the stormwater, thereby reducing the system's overall capacity. Each of these issues diminishes the stormwater system's efficiency, making it critical to address them promptly.

Analyzing Flow and Capacity

The key parameters that suffer due to leaks and cracks are the flow rate and capacity of the stormwater system. Flow rate refers to the speed at which water moves through the system, while capacity denotes how much water the system can handle at any given time. Reduced flow rates can slow down the drainage of water from streets, leading to surface pooling and flooding. On the other hand, diminished capacity means that the system becomes overwhelmed more quickly during heavy rainfall, exacerbating the problem. Maintenance teams should periodically measure these parameters to assess the health of the stormwater system.

Potential Consequences

The immediate consequences of ignoring hydraulic inefficiency can be severe. Reduced flow and capacity increase the risk of localized flooding, especially during heavy rainfall. This flooding can damage properties, disrupt traffic, and in extreme cases, pose risks to public safety. In addition, an inefficient stormwater system places extra strain on adjacent infrastructure, making them more susceptible to wear and tear, or even failure.

Solving the Issue with Polyurethane Grouts

One highly effective solution for sealing leaks in these crucial components is the use of polyurethane grouts. These grouts offer several advantages over traditional sealing methods. They can be applied with precision, allowing for targeted sealing of leaks and cracks. Once applied, polyurethane grouts expand to fill the gap, providing a watertight seal that prevents further leakage or infiltration. This in turn enhances the flow rate and capacity of the system, making it more efficient, especially during times when it is most needed, such as heavy rainfall or storms.

Actionable Steps for Maintenance Teams

Maintenance managers and teams can take several actionable steps to tackle the issue of hydraulic inefficiency effectively. Firstly, incorporate regular monitoring and inspections into the maintenance schedule to catch signs of inefficiency early. Secondly, prioritize the repair of leaks and cracks in components that are key to maintaining optimal flow rate and capacity. Utilize polyurethane grouts to seal these leaks (or hire a waterproofing specialist to do the work). Finally, after any repair, conduct a comprehensive assessment to ensure that the applied solutions have successfully restored the system’s hydraulic efficiency.

Reaping the Benefits

Taking timely action to fix hydraulic inefficiencies is not just about preventing immediate issues like flooding; it’s also an investment in the long-term durability and effectiveness of a city’s stormwater management infrastructure. A well-maintained system requires less emergency intervention, reduces maintenance costs in the long run, and most importantly, ensures the safety and well-being of the community it serves.

The Importance of Continuous Learning

For maintenance managers and teams, staying updated on the latest technologies and methods for addressing hydraulic inefficiency is essential. Training programs, workshops, and seminars offer valuable insights into new materials and techniques that could be more effective and cost-efficient. Polyurethane grouts are a testament to how advancements in materials science can offer superior solutions for age-old problems.

In summary, hydraulic inefficiency poses a significant challenge for stormwater systems, especially during periods of heavy rainfall. Recognizing the symptoms early, understanding the role of leaks and cracks, and choosing the most effective sealing methods like polyurethane grouts can make a significant difference and help to avoid costly emergency repairs. Actionable steps and a focus on continuous learning can go a long way in ensuring that a stormwater system operates at its peak efficiency, safeguarding communities from the risks of flooding and infrastructure failure.

Want more information on sealing leaks in municipal infrastructure? 

For contractors seeking productive work during the slower winter months, Alchatek is here to help every step of the way.

Our team can provide guidance on expanding your services to take on new projects during cold weather. When you’re undertaking new winter work, we're available to consult on important logistics like site evaluations, scheduling, equipment selection, and material adjustments for colder temperatures.

We offer personal consultation to equip you with any new skills required for off-season jobs. We also collaborate with contractors to build relationships with local engineers, associations, municipalities, and other potential lead sources. Our staff can assist with tailored presentations and outreach efforts to position you as the go-to contractor for these clients.

Properly winterizing your slab lifting equipment is equally crucial if you’re winding down for an off-season. Our technical experts can advise you on prepping your slab lifting rig and/or PolyBadger lifting system for winter storage.

Contact the Alchatek support team today to for assistance with your winter game plan.

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This guide outlines a step-by-step process for setting up your PolyBadger system for winter storage. Following these recommendations will not only preserve the integrity of your equipment but also make it easier to get it running when the warm weather returns.

Preparing a PolyBadger for Winter Storage

1. Establish power to the cabinet and heat the hose (A heater, B heater, and hose) to the target temperature of 130° F.
2. Introduce material to the cabinet.
3. Turn the air supply on and recirculate to heat up the ISO and resin.
4. Once the PolyBadger is up to temperature, turn off the air supply and remove the airlines from the stick pumps.
5. Remove the supply and the recirculation line from the A-side stick pump.
6. Drain all the remaining material from the pump and clean it with brake cleaner.
7. Place the stick A side stubby stick pump into a 5-gallon pail of AP Pump Flush.
8. Reconnect the supply line and leave the recirculation line to drain in a purge pail.
9. Repeat steps 5-8 on the B-side stick pump.
10. Reconnect the air supply to the stick pumps, hold the return lines in a purge pail, and slowly open the air valve on the stick pumps.
11. You will notice material slowly pushed out of the recirculation line into the purge pail. Continue to pump AP Pump Flush through the system until it comes out of the recirculation line clear, with no added color or debris.
12. Shut the air valve supplying the stick pumps. This will stop the flow of material.
13. Reconnect the recirculation lines to the appropriate stick pump and tighten.
14. Turn the recirculation pump valves to supply the hose.
15. You can remove the Handi Gun or leave it on for this stage, holding the hose in the purge pail. Turn on the supply valves on the end of the hose just before the Handi Gun. Slowly open the air valve on the stick pumps and pull the trigger on the gun.
16. You will notice material slowly pushed out of the hose line into the purge pail. Continue to pump AP Pump Flush through the system until it comes out of the hose line clear, with no added color or debris.
17. Shut the air valve supplying the stick pumps. This will stop the flow of material.
18. Remove the stick pumps from the AP Pump Flush. (Make sure to mark your pails A and B for future use).
19. Insert stick pumps into AP Pump Saver 195. (Make sure to mark your pails A and B for future use).
20. Push the AP Pump Saver 195 through the hose line. You will notice the AS Pump Flush slowly pushed out of the hose line into the purge pail. Continue to pump AP Pump Saver 195 through the system until it comes out of the hose line clear (you will notice a thick, clean fluid).
21. Turn off the supply valves on the hose just before the Handi Gun.
22. Disconnect the air supply to the stick pumps.
23. Move the hose supply valve into the recirculation position to depressurize the system.
24. Shut off supply valves to the cabinet.
25. Turn off heat zones.
26. Turn off the main disconnect.
27. Remove residual grease from interior cabinet pumps.
28. Replace with new grease.

If you follow these steps, your PolyBadger should be ready for secure storage during the winter months.

For in-depth information on geotech polyurethane applications...

As temperatures drop, contractors in certain areas need to winterize their slab lifting rigs for storage during the off-season. Below are the step-by-step guidelines to properly store your equipment.

Important Note

• Extra attention is devoted to the A-side of the system, which is standard practice.
• This guide assumes you're using a PMC pump for your slab lifting rig.

Preparing a Slab Lifting Rig for Winter Storage

1. Remove and clean the A and B stick pumps. Clean the exterior of the pumps with brake cleaner to remove as much residual resin and polyol as possible.
2. Place the A-Side transfer pump into a 5-gallon pail of the AP Pump Flush.
3. Remove the recirculation hose from the A-Side drum and place it in a purge pail.
4. Open A-Side inlet valve and recirculation valve on your PMC machine.
5. Slowly open the air valve on the A-Side transfer pump to start introducing the AS Pump Flush through the A-Side of the machine.
6. You will notice iso material being pushed out of the recirculation line into the purge pail. Continue to pump AS Pump Flush through the system until it comes out of the recirculation line clear, with no added coloring or debris.
7. Shut the air supply feeding the transfer pump. This will stop all flow of material.
8. Un-cap the A-Side of the PMC whip hose. Once un-capped, place the hose into the purge pail.
9. Close the recirculation valve on the A-Side of the PMC machine.
10. Slowly open the air valve on the A-Side transfer pump to start the flow of AS Pump Flush through the heated hose.
11. You will notice iso material being pushed out of the whip hose into the purge pail. Continue to pump AS Pump Flush through the system until it comes out of the recirculation line clear, with no added coloring or debris.
12. Now that this process is complete, the A-Side has been completely cleaned of any iso material.
13. Remove the A-Side transfer pump from the pail of AS Pump Flush and place it into a 5-gallon pail of AP Pump Saver 195.
14. Slowly open the air valve on the A-Side transfer pump to start introducing the AP Pump Saver 195 through the A-Side of the machine. Continue to pump the AP Pump Saver 195 until you have pure and clean AP Pump Saver 195 coming out of the end of the whip hose.
15. Place the B-Side stick pump into a separate 5-gallon pail of AP Pump Saver 195.
16. Slowly open the air valve on the B-Side transfer pump to start introducing the AP Pump Saver 195 through the B-Side of the machine and heated hose. Continue to pump AP Pump Saver 195 through the system until it comes out of the end of the whip hose, with no added coloring or debris.
17. Once the entire system is full of clean AP Lube 190, slowly start to recirculate the AP Pump Saver 195 through the entire system. When doing this, it is best to let the PMC machine cycle while recirculating the AP Pump Saver 195.
18. Once all these steps are complete, close the air on each transfer pump and re-cap the heated PMC whip hoses.

If you follow these steps, your slab lifting rig should be well-prepared for the winter storage period.

For in-depth information on geotech polyurethane applications...

It's time to revisit the idea of remaining profitable during the winter months, but where does one begin?

Engaging with Engineers and Consultants

Networking with engineers is a cornerstone for securing a consistent flow of projects. Engineers are usually involved in any sizable geotechnical or waterproofing project. From industrial settings to property management companies and hydroelectric plants, an engineering firm is almost always the first port of call for problem-solving.

Alchatek offers presentations designed for engineers that cover a range of polyurethane applications like leak sealing, soil stabilization, and concrete lifting. These presentations often qualify for continuing education credits, offering engineers added value. We prefer to collaborate with local contractors for these presentations, creating a link between suppliers, contractors, and engineers.

With diligent follow-up, such activities typically yield smaller-scale projects, which, when successfully completed, pave the way for larger undertakings. Engineers are the go-to professionals for property owners facing issues. If you establish yourself as a reliable, punctual, and skilled contractor, you are more likely to secure jobs without having to go through the bidding process.

Networking Through Professional Associations

A wealth of professional associations exists across various fields and trades. Becoming a member provides an excellent platform for networking and discovering new opportunities.

Take, for instance, your local chapter of BOMA (Building Owners and Managers Association), which represents the expansive commercial real estate industry. BOMA members are mainly property owners, facility managers, and building engineers—a perfect audience for discussions on topics like elevator pits, parking structures, and tripping hazards.

IFMA (International Facility Management Association) is another noteworthy association. While BOMA represents the "landlords," IFMA represents the "tenants," who are often the first to report issues. Presenting to IFMA allows you to inform facility managers about problem-solving polyurethane technologies.

Don't overlook ASCE (American Society of Civil Engineers) either. It's not just for engineers; they offer a category called Organization Partners for non-engineers. Your presentation here can also be facilitated by Alchatek.

Reaching Out to Government Agencies

Sometimes old-school techniques like making phone calls and doing online research are invaluable. Connecting with local municipalities and Departments of Transportation (DOTs) can give you insights into upcoming projects. Attend bid meetings to network with general contractors and engineers.

Don't ignore mass transit authorities in cities with train or subway systems. These authorities regularly release projects for bidding and have engineering departments that could benefit from your solutions in leak sealing and geotechnical applications.

The cold months are an opportunity if you're a contractor seeking winter work. Not only will these strategies help you find winter projects, but they will also positively impact your business all year round. Reach out to the Alchatek support team for guidance.

For in-depth information on geotech polyurethane applications...

Contractors specializing in chemical grouting in the northern United States are often constrained by the seasons when it comes to outdoor soil stabilization and slab lifting tasks. However, with strategic planning, they can also find profitable avenues to keep busy during winter.

Winter Geotechnical Projects

• Warehouses and Distribution Centers: Interior slab lifting and void filling. Concrete floors and loading docks.
• Office and Retail Spaces: Interior concrete leveling.
• Infrastructure: Below the frost line where groundwater seepage impacts the density of soil and the stability of pavement.
• Agricultural Facilities: Slabs in structures like grain-drying bunkers.
• Commercial/Industrial Settings: Void filling and slab leveling in manufacturing plants and factories.

Expanding the Scope: Other Polyurethane Injection Applications

Winter also provides an opportune time to acquire new skills in areas like crack injection, slab undersealing, and curtain wall grouting. Cold weather conditions make concrete contract, widening cracks and joints, thus making them easier targets for injection work. Here are additional applications requiring attention:

• Subterranean Parking Garages: Leaks through cracks, expansion joints, and cold joints can be treated with specialized leak seal resins.
• Elevator Shafts: Particularly in areas with high water tables, elevator pits are prone to leaks.
• Tunnels: Whether for pedestrians, vehicles, or mass transit, tunnels often face water seepage issues, solvable via polyurethane grout.
• Dams: Despite their massive structure, dams are not immune to leaks. Winter is a suitable time for crack injection maintenance.
• Residential and Commercial Basements: Treat leaks in cracks and joints.
• Slab Undersealing: Similar to curtain wall grouting, but it's done through the floor.

Consult the Alchatek support team for technical assistance with your next project.

For in-depth information on geotech polyurethane applications...

Effectively repairing and sealing leaks in dams requires specialized expertise and high-quality materials. At Alchatek, we have spent decades developing and manufacturing premium polyurethane grouts designed specifically for waterproofing and protecting critical infrastructure like dams.

If you own, operate, or manage a dam, we encourage you to contact us to discuss your unique requirements. We can provide custom recommendations tailored to your dam's needs and specifications. Our team has in-depth knowledge of the latest techniques and materials for effective, long-lasting leak sealing and waterproofing.

In addition to insights and product recommendations, we also offer referrals to qualified contractors. These contractors have extensive experience in services like:

• Crack and Joint Repair
• Curtain Wall Grouting
• Waterproofing

We ensure they are properly trained in utilizing our products for optimal results.

Don't leave your dam's structural integrity to chance. Let our experts provide insights on an effective maintenance plan using premier sealant products. Get started on enhancing your dam's safety, longevity, and operational efficiency. Call 404-618-0438 or fill out this form to contact Alchatek today.

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