Award Winning Vacuum Pump Station Design

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The Hunua Views Flovac vacuum pump station located between Drury and Ramarama south of Auckland in New Zealand has taken out the highly commended award in the 2021 ADNZ Resene Architectual Awards. The design was done by Madushin Amarasekera of Construkt Associated for Classic Homes, a major developer in New Zealand.

The Hunua Views residential development , is serviced by a vacuum sewer system after deep gravity sewers and low pressure pumps were rejected by Watercare, the main utility looking after the Auckland area. Up to 1,000 houses will be connected to the new vacuum pump station.

The comment at the awards

A beautifully bold and intriguingly sculptural project by Madushin Amarasekera of Construkt Associates NZ took out a Commercial/Industrial accolade in the 2021 ADNZ Resene Architectural Design Awards. With a need to accommodate very specific engineering functions, Madushin took the opportunity to create not only a functional home to the pump station, but also a building to act as a site marker within its residential context. We love the irregular roof geometry which perfectly accompanies the textured precast concrete panels.
🏆 2021 ADNZ Resene Architectural Design Highly Commended for Commercial/Industrial Award.
Watercare are naturally very proud of the new infrastructure and were very involved in the coordination of everyone involved. When designing and creating the structure, specific engineering functions needed to be met and there was a lot of coordination between the architect, civil, structural, services & acoustic engineers, precast fabricator and Flovac, the vacuum system specialist. In fact, it’s so detailed that all the vents were acoustic rated while the control room is positioned on the south side, providing an acoustic buffer for nearby residential dwellings.

Flovac is the largest vacuum system supplier in New Zealand and has established a production facility on the north island of NZ to handle the business growth within the country.

Photos by Calvin Hui

Club de Mar Mallorca. The largest Superyacht dock in the Mediterranean

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Flovac’s vacuum sanitation system is going to be included in the remodelling taking place at the marina Club de Mar Mallorca, which will include the fitting out of a new superyacht pier. The pier will be able to accommodate four yachts between 170 and 136 meters and up to 24 beam lengths. Therefore, the marina will commemorate its 50th anniversary with an innovative, reliable and green sanitation solution.

Flovac will supply and install all of the vacuum sewerage equipment. This will be used for both the vessels at berth and for the buildings in the marina as well. Flovac was chosen for this major project due to their detailed experience with major marinas around the world. Flovac valves and equipment is built under European standards and ISO codes.

Vacuum sanitation is preferred for marinas because all pipework can reach the collection pits with shallow trenches and will not leak.  For luxury marinas, Flovac designed a AISI316 stainless steel bollard. Flovac bollards have accessories to connect hoses that suck wastewater from vessels. For the superyachts that have discharge pumps, Flovac will supply connection points with diverse dimensions to adapt to the pier. Bollards with a hose connection under vacuum pressure is for yachts without discharge pumps.

The vacuum system has sensors that notifies the marina manager of the vacuum valve condition as well as the pump and tank status. We also provide software to calculate the flow from the megayachts.

If you would like more information about Flovacs other marina projects please Click here

Gold Coast Marina Vacuum Pump Station Upgrade – A Challenge

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The Gold Coast Marine Precinct is a dedicated industrial zone in Coomera, on the Gold Coast of Queensland Australia. The precinct supports marine manufacturing, servicing, repairs and refits of recreational boats. It is one of the most advanced and respected marine industry cluster developments in the Southern Hemisphere. It is the only purpose built marine precinct in Australia. Covering 250 hectares, it it is home to some of Australias most prestigious motor yacht builders and industry leaders.

It includes Riviera Australia a winner of Australian Maritime Industry Exporter of the year on multiple occasions.

Maritomo  Handcrafted Luxury Offshore Motor Yachts

The Boat Works – a boatyard, marina and superyacht facility

The Gold Coast City Marina & Shipyard   has over 90 expert businesses looking after a wide range of clients. They have won numerous awards for their facilities.

 

Related: Barcelona Port vacuum Sewerage System

The Challenge

All of the wastewater within the facility is collected via a vacuum sewerage system. Over the years the facility has grown and the requirements of what a sewerage needs to do has changed. How to handle the larger superyachts for example. How to reduce energy costs. And how to ensure that all equipment was the latest technology and would reduce any risks of sewage entering the waterways.

The hardest part of the challenge was to fit new vacuum pump station equipment into a very tight existing space. The upgrade needed to take place with minimal disruption to any of the businesses in the precinct.

Related: Sydney Superyacht Marina Upgrade

As the Vacuum Pump Station is located outside of the precinct’s grounds it is operated and maintained by Gold Coast Council.

Power Saving and Efficiency

The goal set by Council was to reduce the vacuum pump cycle time from around 6 minutes to less than 3 minutes. This would give a 50{f2ac4d1e1d40dc2e2d9280a1dfa90d854b2d8c80eba743affa37fc4ce2e16def} reduction in power usage throughout the day.

There was also a request to increase the discharged flow from the system by 15{f2ac4d1e1d40dc2e2d9280a1dfa90d854b2d8c80eba743affa37fc4ce2e16def} by using exactly the same specified discharge pumps that were currently installed. We managed to increase their flow from 18 L/S to 21 L/S.

Flovac’s engineers worked on the problem creating 3D modeling of the station to ensure that the equipment would fit the space. Then the operations group went over the plans to make sure that the operability of the system would not be compromised.

In the months after commissioning there has been a clear improvement and lowering of energy costs. Vacuum pump run times have decreased from 17 hours per day and are now running for only 6.7 hours per day. They previously had been running 3 x 500 m3/hr pumps most of the day with huge energy costs.

More information on Flovac’s Marina and Port Projects

Sheltering Sewers from the Rain

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Pacific Northwest community optimizes its vacuum sewer system with cutting-edge telemetry monitoring

Full Article Click here

Making the switch from a purely septic-based wastewater handling model to a publicly owned and operated vacuum sewer system solved problems for the small community of Miles Crossing, Oregon. It also brought unforeseen inflow and infiltration issues.

Rain events revealed the need for tracking down operational overload issues in the system, which could only effectively be accomplished via automation tools. Retrofitting a monitoring system has given the district’s operators a real-time view of their system, potential sources of I&I, and a means to protect the mechanical health of this key community infrastructure investment.

Below sea level

The Miles Crossing Sanitary District is fairly new, incorporated when the community decided to shift from private septic systems to a public sewer system. The decision to convert the community — home to a population of approximately 800 — was based upon several factors:

 The town’s topography — situated on Youngs Bay, between the Youngs River and the Lewis and Clark River, is completely flat with elevation from 1 to 10 feet below sea level.

 Dikes are situated between properties to prevent them from going underwater during high tide or rain events.

 The high-water table was causing the area to experience a rapidly rising number of septic system failures, affecting groundwater quality.

The district opted for an vacuum sewer system versus a traditional gravity system. The latter would not have been feasible due to the depths required for installation combined with high-water table levels. The vacuum system implementation process, which cost the community approximately $4 million, began in 2000 and was fully in service by 2010. It comprises 372 gravity pit connections (323 of these being residential), and a single pump station that receives the entire flow from 7.25 miles of vacuum mainline. From the pump station, two 75 hp pumps move the effluent 1.75 miles under Youngs Bay to the town of  Astoria, Oregon, for treatment.

Not quite right

On normal, dry days, Miles Crossing would pump an average of 36,000 gallons per day; but during rain events, that would jump dramatically, sometimes by more than 150,000 gallons. Unlike a traditional system where I&I can exist between joints, cracks in manholes or other conveyance structures, a vacuum system is closed. Brandon Smith, pump station operator, and Carl Gifford, superintendent for the Miles Crossing Sanitary Sewer District, suspected stormwater was entering the system.

“One of the biggest challenges with a system like this is that not only do we not want the stormwater — the system simply cannot handle it indefinitely — but since we don’t handle our own treatment, we were sending extra effluent to Astoria that created extra costs,” Smith says. “Our job became finding out where that excess water was entering the system, and then correcting it.”

Gifford and Smith learned that when the system was put in place, contractors had taken each line that was tied into the property’s existing septic, severed it, and then tied it into the new vacuum system. On many properties, storm drains and gutters, as well as other forms of outside drainage, had been run into the septic system. The impact of bringing all these lines into the new vacuum system — instead of just the sanitary line — was unknown to the contractors.

These extra tie-ins created an unnecessary burden on the system and the pump station operations, so they needed to be located and removed. The task of finding the sources of these I&I culprits was labor-intensive and slow, so the district began looking for a technology solution that would assist in this discovery process.

Trial and error

As a first attempt, Gifford and Smith utilized individual pit-fire counters. Each time an individual property’s vacuum pit fired, it would trigger an analog or digital display to track the number of firings. This method proved expensive and unreliable as a measurement or pinpointing technique. As they continued to research other solutions, they were contacted by FLOVAC.

FLOVAC had been well established globally in the field of successful vacuum sewer system installations and was seeking connections in the North American market. It was able to offer Miles Crossing a telemetry system that could be connected to each vacuum pit and would deliver the detailed data the district needed to help pinpoint and mitigate its I&I issue.

Each vacuum interface valve or connection has a magnet located inside of the top section of the valve body. The FLOVAC monitoring system works by attaching a special sensor to the valve body to detect the movement of this magnet. It detects each time the valve opens and closes, as well as how long each valve stays open.

Numbers tell all

As vacuum valves tend to fire when 10 gallons of effluent have entered the sump, the volume of flows can be calculated from the number of activations. When an unusually high volume of water enters the sump, the valve will take in a larger quantity of fluid during that one cycle. The district could detect such occurrences by how long the valve stayed open. Depending on how many properties are connected to a single collection pit, they would be able to narrow down the point of infiltration to a small area.

Related: Flood Affected Sewer Systems

With the installation of the FMS, monitoring and telemetry data now lets operators see what the entire system is doing in real time. It allows them to view individual homes and their pits, and provides information on how many times it has fired, and when.

“This is especially helpful during a rain event,” Smith says. “We can see average trends for a property. For example, if a home that normally fires 30 times a day during a weather event starts showing 5,000 fires instead, we know there’s a problem and can deploy immediately to the property while the rain event is still happening to see exactly what’s taking place.”

One big discovery uncovered by monitoring involved a property with a partially collapsed lateral. Although it was functioning sufficiently to serve the home, it had been crushed in some areas. Where it ran from the home under the rock driveway, it was acting like a natural storm drain, pulling water straight from the surface into the sewer system pit. Using CCTV push cameras to inspect and document the line’s condition, the utility team was able to show the property owner the extent of the damage, its effects, and then work with them to develop a plan of action to resolve it.

Subtle adjustments

Normally, the monitoring units are connected to a transmitting antenna that sends data to the central monitoring system wirelessly. Due to the flat terrain and steel manhole covers on the pits, Miles Crossing ran conduit pipe out to a utility pedestal at the roadsides and installed the wireless telemetry equipment there. Everything works wirelessly through the latest Gateway, Bluetooth and LoRaWAN technology and is tied into the district’s SCADA system.

“We can set parameters as far as what we are asking it for, and to send us text messages when there are different alarms. This extra information is especially helpful when we are experiencing a lot of rainfall,” Smith says.

Since its installation, the system has required minimal maintenance. A yearly visual inspection of each valve pit is typically all that has been needed. Rare mishaps can occur, but — due to the very nature of the sealed system’s construction — if things happen, the pumping equipment operation and vacuum attributes make pinpointing issues quick.

Moving forward

Nearly 60{f2ac4d1e1d40dc2e2d9280a1dfa90d854b2d8c80eba743affa37fc4ce2e16def} of the system has been fitted with the telemetry monitoring system, and phase two of the project, a complete system rollout, is commencing shortly.

“By retrofitting the entire system with the FMS, we will know when there’s a problem before the homeowner does,” Gifford says. The monitoring system also provides a high-level float that can alert the operators when a pit begins to have an issue. Now Gifford and Smith can be more proactive versus reactive in keeping the system in peak operating status, while cutting down on field time and hunting down overflows.

With just a little more than half the system being monitored, the district has already seen significant savings in treatment costs, Gifford says.

“The vacuum system was a great solution for this community and now with the telemetry tools, we will have a sustainable, high-performing and affordable sanitary system for our district for generations to come.”

Related: Information about Flovacs Monitoring System

Flovac Collection Pits are Preferred by Vacuum Sewer Installers

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Many Contractors find installing vacuum sewers much easier to install than traditional gravity sewers and low-pressure pumping systems.

Vacuum sewers are installed in shallow trenches and have an easy connection point at a property boundary for homeowners to connect up to. Gravity flow from a number of houses, usually between 2 and 6, depending on the flow rate from the property, flows to a collection pit.

The Collection Pit houses the vacuum valve which provides a pneumatic interface between the gravity side of the network and the vacuum, negative pressure, side of the network.

In older systems, concrete manholes were used as well as fibreglass collection pits. Both have had issues with I&I (Infiltration and Inflow) becoming an increasing problem. This has been picked up very well with Flovacs monitoring system. 

The Flovac collection pit has been designed by operators and is built under ISo conditions to a standard for collection pits using PE materials.

Have a look around one of our collection pits recently being installed in Florida.

The first and most applauded by operators is the shut-off valve for testing and service work on the pit. As Flovac is a world leader in vacuum technology, this is now the standard in many countries. The shut-off valve is an essential tool to keep your team safe.

The vacuum stub out is welded to the side of the pit, eliminating inflow to the valve pit and ensuring alignment with the valve is 100{f2ac4d1e1d40dc2e2d9280a1dfa90d854b2d8c80eba743affa37fc4ce2e16def} every time. Thus, reducing instillation errors and eliminating no-hub couplings coming off. Additionally, if the valve closes on water, creating a water hammer, all the energy is suppressed.

Flovac uses either H20 rated hinged or HDPE lids; both seal the valve pit from water getting in. Keeping the upper valve pit dry protects your valve and controller and eliminates operators from having to fish in stagnant water during serving. Additionally, the sump of the valve pit has a 30{f2ac4d1e1d40dc2e2d9280a1dfa90d854b2d8c80eba743affa37fc4ce2e16def} larger holding capacity on average, which is just one of our design philosophies to ensure adequate response time during an emergency.

Lastly, the feedback we receive from contractors includes how easy the pit is to set and connect. With many more connection points, clock position is not an issue.

Hard to believe, but the highest praise from contractors is that our valve pit has lifting lugs, a crucial must-have.

You can read more about our Collection Pit Here

Why is a Vacuum Sewer the Best Collection System for the Environment

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Gravity/Low-Pressure/Vacuum – which has the Greenest Credentials

It is very clear that septic tanks and cesspools are a disaster for the environment for a number of reasons. Leaking into waterways, poisoning fish and water birds, creating algae blooms. Affecting the overall health of the community.

The choice of a gravity sewer, low pressure sewer (grinder pump) or vacuum system is not as clear in many peoples minds. In many communities the health of the

Clean waterways are essential

community is important, but even more so, the health of the environment. Many people move to coastal communities because of their love of the natural environment. Maybe the beautiful lake, their favorite beach or special fishing spot. If the area is being affected by sewage spills or sewage smells on a regular basis, closing beaches or impacting local shellfish, how will that affect their property prices and quality of life.

Naturally, the cost of sewerage infrastructure is a critical factor, lets take that as a given, if costs are close to equal, what type of system would be best for the environment?

When clients have done carbon footprint studies in the past, the main areas they look at are in construction, materials and whole of life operational costs which include product replacements and energy use.

Construction

Gravity sewers tend to be either laid deep in the ground or have multiple pump stations. Deep sewers can mean pipes laid at 5-10 metres (15-30 feet deep trenches), we have seen deeper. In coastal areas this can mean dewatering which can impact the water table. If a contractor is dewatering the trench, that water goes somewhere else. This can impact the overall watertable which can kill off vegetation or impact the aquifer. Whole eco systems can be affected.

Both vacuum and low pressure systems tend to have shallow pipework and construction time is short. That means that equipment at site is much shorter. A project might be installed in a matter of months rather than years. A major carbon impact.

 

Construction Environmental Impact

Materials

Coastal area’s gravity sewers need either large diameter pipes or multiple pump stations. One of our earlier costal communities we used one vacuum pump station to replace 17 gravity pump stations. The amount of equipment required in 17 stations would be tremendous.

Low pressure systems it’s even worse. In a community of 1,000 houses, you would need 1,000 pumps and pump chambers. In a vacuum system you would require only 200-250 chambers. Vacuum collection pits are not filled with metal pumps and electrical components. They house vacuum valves which have a 50-year design life with minor parts changes every 10 years. The valves bodies from Flovac have a recycle stamp on them as the PP and GP can be recycled.

Whole of Life Operational Costs

Energy costs are the largest component of operational costs in sewer systems.

In cases such as the one in the section above where one vacuum pump station replaced 17 gravity stations, you can be sure that the energy costs of 17 stations were a lot more than a single vacuum station. That system looked after 1,800 houses. A low pressure pump system would require 1,800 pumps, each one requiring electricity.

Due to the low energy requirements, some vacuum systems are now being powered by solar.

The Bigger Risks

Sewerage leaking into the waterways.

In gravity sewers, you could have leaks for months before someone reports a bad smell or something nasty floating in the lake.

Low pressure sewers use a positive pressure and if there is a pipe break sewage can be squirt meters into the air and can be very hard to contain. Contamination of waterways can occur quickly.

Vacuum sewers cannot leak. They operate under a negative pressure and in some projects you will see water and vacuum sewer pipes in the same trench as you cannot get sewage leaking out of the pipe. This video shows how that is possible.

Other benefits

When we installed the vacuum system at the Eco Resort Couran Cove south of the Great Barrier Reef in Australia there were a number of reasons why a vacuum sewer was chosen – You can read about the project here. 

The environmental benefits that they looked at were:

  • Ability to handle low flush toilets thus reducing the ultimate treated water disposal problem
  • Minimal impact on the landscape during construction with shallow trenches
  • Maximum water recovery for reuse in the re-vegetation irrigation system
  • Construction route flexibility thus minimizing the damage to vegetation
  • Ability to transport grey and black water in the one small bore pipe
  • Ability to safely lay all services in the one trench with minimal spacing
  • Zero infiltration and exfiltration
  • Ability of the system to service the entire site with one centralized pump station
  • Ability of the scheme to service the Boardwalk accommodation and even the boat sullage

Flovac vacuum systems are referenced as The Green Future of Sewerage. It is easy to see why. What outcome do you want for your community, lets hope its the Green one.

My Vacuum Pumps are Due for an Upgrade – What Next ?

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When a vacuum sewer system was planned in your area, there was probably an options study done showing whole of life costs. There was an expectation that over the life of the system (100 years) there would be items that would wear out and need replacing. Just as there would be components that would needs parts replaced through normal maintenance. (Asset Life)

For the rotary vane vacuum pumps, that would mean oil and filter changes. According to the pump manuals you would expect to do a fairly extensive motor overhaul at year 5 with a possible replacement at year 15. Through good care, we have seen many vacuum pumps have their lives extended considerably. That has been especially true of liquid ring pumps.

Many of the systems built prior to 1996 used liquid ring pumps (the days when water wasn’t considered a scarce resource). Since then, there has been a mixture of mainly rotary vane pumps for larger systems with smaller systems using dry running claw pumps. There have been a few outlier pumps like oil sealed screw pumps and even some rotary lobe pumps.

The vacuum pumps in your system would have been sized based on an air to liquid calculation based on the length of vacuum mains and the volume of the mains. Operationally we always look to the amount of air it takes to move the liquid through the system. A well run fully developed system should run at about an 8 to 1, or 10 to 1 air to liquid ratio. We know that if that creeps up to 30 to 1 that there is too much air in the system, and it should be tuned. A high rate like that would suggest that the vacuum pumps would be running far more than they need to. If the ratio though was lower at about 4 to 1 or 6 to 1, we would know there was too much water relative to air. This might mean the discharge pumps are running longer than they should, relative to the vacuum pumps. This might be due to I&I (infiltration and inflow) or higher flows than expected in the catchment. (Ask us for the calculation sheet for the air to liquid ratio)

With a good air to liquid ratio, we would expect the vacuum pumps to run at about 6 to 8 hours per day, in total, in a fully developed system. If your pumps are running longer than that you should check your air to liquid ratio to see what is impacting your system.

Two of the biggest mistakes that we commonly see when utilities are looking to upgrade their pumps is

  • Increasing the size of the pumps as the current run time is excessively long
  • Changing from a oil lubricated pump (R5) to a dry pump (Mink) to reduce operational costs.

Increasing the size of your pumps

This might be a great idea if done for the right reason. Talk to your engineers. If you can increase capacity at the station maybe that will allow you to accept more flows from subdivisions, new areas, higher density (more revenue).

If though you are only increasing the size because your pumps are running a long time then you need to fix the problem first. Why are the pumps running so long? Is the system tuned correctly? Are there leaks in the valves or pipework? Oversized pumps can increase the problems in a network by creating more leaks.

Once the system is tight and you have an accurate idea of your air to liquid ratio then you can make a more informed decision.

Changing to Mink Pumps

If the change is because you are using too much oil and too many filters, then it would suggest that your pump run hours are too long and you should take the steps mentioned above.

In small systems Mink pumps and their equivalent have improved substantially but in large systems where you are changing over from R5 630 pumps or their equivalent there are a number of downsides that utilities are now discovering.

In the larger sizes the Mink pumps run a lot hotter and potentially noisier. The heat has an impact on pipe materials in the station, venting of the station, and will badly affect odour control measures.

On larger systems there is a limit to the depth of vacuum that these type of pumps will achieve and often the result is an increase in energy use and pump run hours.

Some utilities have also tried the addition of variable speed drives in their pumps as a way of increasing vacuum in the lines and decreasing line flooding. The speed is often varied due to the amount of vacuum pressure in the lines or at the end. It is rare to see this used in wet/sewer type systems and is more common in dry/food processing applications. As vacuum sewers are based on a ratio of air to liquid, the use of a VSD disguises problems in the system and can ultimately increase problems in the networks.

Upgrading of your vacuum pumps is inevitable – we can help you with finding the right solution for your system

Call our Engineering or Operations Group to organise the following as a first step.

  • System Audit To correctly size the vacuum pumps an analysis of the air to liquid ratio is needed. The system needs to be air tight to do this. If there are leaking vacuum valves, due to old age, air leaks in the pump station or elsewhere, these need to be fixed prior to any upgrade as any larger or new vacuum pumps could make these harder to find and just lead to higher energy costs and high oil use. An Audit will check the current state of your system; give you an understanding of what will be required to accomplish the outcomes you want
  • Capacity Audit What was the system designed to handle, what can it potentially handle for the next 15 years.

To read more about Upgrades Click Here

Interview with a Utility Ops Team Leader

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A recent interview with team leader David Parkinson of Byron Shire Council gives insights into their vacuum sewer system and just how installing a monitoring system can have time saving and financial benefits to councils.

The Byron Bay community on the north eastern coast of New South Wales is listed as one of the top ten destinations in Australia for tourists from around the world. Its pristine beaches and popular cafes and restaurants ensured that even through covid, domestic tourism has kept the area as busy as usual.

A vacuum system was installed in 1993 in a section of Byron Bay which encompasses light industrial, commercial and residential users. Increasingly heavy rainfalls on the coast revealed the need to pinpoint operational overload issues in the system, this could only be accomplished via the use of automation tools. Retrofitting their system with a monitoring system has given the Council operators a better overview of their systems operation, and a means to protect the mechanical health of this key community infrastructure investment.

A recent interview with Team leader Dave Parkinson of Byron Bay Council gives further insight into just how installing an electronic monitoring system can have time saving and financial benefits to councils.

  1. What has been your role at Byron Bay Council what has been your involvement in implementing the Flovac Sewerage System there and the monitoring system?

“Essentially my job as Team Leader was to oversee the install of the telemetry pillars to the 89 pits. Also overseeing the installation of antennae to receive telemetry from the pits, and also the roll-out of training and instructions on installation to staff. I deliver an overview to new staff on the system and how it works”.

  1. How long has your Flovac system and the monitoring devices been installed?

“The Flovac system commenced being installed in 1993. The monitoring system in 2020”.

  1. How does your monitoring system work?

“It’s a great system which has empowered staff to monitor the system in operation using their iPads and mobiles on a daily basis. They are able to fix and rectify faults quickly and seamlessly”.

Saving Operational Hours

  1. What, in your opinion is the main advantage of the Flovac system itself, and in particular their monitoring system?

“The main advantage is in time saving after hours. Staff can monitor the issue before leaving home and drive straight to the pinpointed problem pit or pits”.

  1. Is the monitoring device a time and cost saving system?

“Yes, it’s benefits are both; in time and cost savings for operations staff. For example, when it’s extreme weather like our recent big storm event on the East Coast of NSW you can locate the problem much quicker, lessening the time spent in poor weather/working conditions for our teams”.

  1. Would you recommend it to other councils with similar low-lying coastal terrain as you have?

“Absolutely if you’re going to install this type of system, we would recommend you have the monitoring system on it. We asked our maintenance staff to assist us with the choice of systems when we needed to replace the old one and the Flovac system was selected because of the whole package that was offered. After five years we gradually moved over to this system”.

  1.  How did you hear about this system?

“Flovac approached Council when we were deciding to replace the ageing valves. We were impressed by the ongoing support offered by John Radinoff and his team when he presented the Flovac system’s many benefits to the Management and Operational teams”.

  1. Do Flovac provide good operational support when you need it?

“Yes, they have followed through with their ongoing support 24/7. Flovac also offered us the first monitoring service. The company is innovative and developed it to assist us in more efficient delivery of services to our residents”.

  1. Has the addition of a monitoring system helped you operationally? If so, in what way?

“Yes, absolutely it allows the operational team guys to take control of the system themselves. There are definitely long-term savings which we should recoup within a five-to-seven-year period”.

  1. Would you suggest that any new vacuum system automatically should have monitoring built in from the start?

“For sure, it’s helped us considerably”.

  1. Do you prefer having a vacuum system, or would you prefer a low-pressure pump system and why?

“We have both systems in Byron, each has their own specific purpose”.

  1. Would you like to add anything that is not covered in the questions?

“As the monitoring system is more refined we will be able to better assess the current Flovac system for even more benefits”.

 

To read how the monitoring system saved Byron’s vacuum system during major flooding earlier in the year please Click Here

For more information about Flovac’s Wireless monitoring system Click Here

1,000,000 cycles. How long should your vacuum valve last.

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A vacuum interface valve is located in a collection pit usually outside of the property boundary at the side of the road. In most systems this collection pit is connected to 4 to 6 homes via a gravity pipe connection.

Although the vacuum system is designed so that the vacuum valve allows for a flow of .25 litres per second (4 gallons per minute) from the houses. There are some occasions where parts of a system may be designed for higher flows. This may come from schools, commercial areas, gravity fed or pumped flows. Our engineers are very careful about how these higher flows enter the system.

The vacuum valve is designed to activate pneumatically once 40 litres (10 gallons) enters the collection pit. This allows for a mix of air and water to enter the system with the correct air to liquid ratio so that the vacuum mains do not flood with too much liquid. In an average residential community, the vacuum valve will activate between 80 and 100 times per day. This is based on the average flow per house and the number of houses per collection pit.

Flovac Manager Georg Sarap checking the monitoring system via the touch screen at the vacuum pump station

For maintenance we recommend that certain parts in the valve and controller are replaced every 10 years or 300,000 cycles. The body itself has a design life of 50 years. European Standard EN 16932 calls for an endurance test with 250,000 cycles, as does the Australian Standard AS 4310 Details Here

Flovac has independant testing of the valve at 700,000 cycles, significantly more than required by the standards and represents 23 years of activation without failure.

We know that in a number of our systems we have some very high flow situations. With some its been due initially to infiltration which clients have since resolved. With others the system has been designed to cater for very high flows. High Flow Projects .

One Million Cycles

Monitoring screen showing over 1 million cycles

At our project at Leppneeme in Estonia our team has been watching one of our high flow valves closely. It has a Flovac cable monitoring system which can tell the operator the number of times the valve has operated (Tsuklite arv:). It can also alert the operator to any faults, tell the temperature in the pit, the power use and location. The pit is located very close to the vacuum station which makes it easier to handle very high flows. This week the valve passed its 1 million mark with number of cycles. Based on these activations it has done 34 years worth of work in just 8 years and is still going strong.

Fortunately the operator would be able to tell from the monitoring system if any parts were wearing as the open time of the valve would start to change.

Although we have other systems that have valves which have recorded over 1 million cycles as well as achieving this result on our test bench it has been great watching it tick over via our monitoring system.

Flovac Vacuum Valve and Controller

International Womens’s Day – Interview with one of the Industry Founders and Legends

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In 1984, with her husband Geoffrey Radinoff, Pat Radinoff formed the Australian company RSM (now Flovac), looking to develop the new vacuum sewerage industry and take it to the world. Eventually becoming Flovac, one of the largest designers, suppliers and operators of vacuum systems in the world and with two of her sons still involved. We thought it appropriate on this International Women’s Day to hear her thoughts on 37 years associated with the vacuum sewer industry.

  1. How did you become involved in the Vacuum Sewerage Industry?

    Sylvania Waters Australia’s first vacuum system

Environmental issues were important in Scandinavia where in 1981 Geoffrey Radinoff, Australia’s Trade Commissioner, and I, attended a National Day Reception in

Stockholm. We met Joel Liljendahl, the modern inventor of vacuum sewers, that in a designed system sucked away wastewater. Follow up meetings coincided with our decision to retire diplomatic life and find a new ‘later in life career’. Joel knew of an Australian canal scheme recently built near our home in Sydney, Australia at Sylvania Waters. It used his 50mm vacuum valve.  He mentioned that a 90mm valve designed for sewage transit was ready for the market. Enthusiastic, we joined other international ‘suckers’, so-called in the vacuum sewerage industry.

  1. How was it received when you began marketing it to authorities in Australasia?

Frustrating! After two thousand years of gravity, vacuum systems were not highly regarded as early systems using the too small 50mm valve, designed for liquid wastes, required more maintenance to clear solids flowing through the 50mm plastic pipes.  The 90mm was designed for that job. After three years of calls, info newsletters and conference attendances, an order – the Water Police boats dumping sewerage into Sydney Harbour was unacceptable. We built the vacuum pump station. An early visitor from Hindmarsh Island in South Australia declared this clean, easy to install vacuum technology perfect for a planned, staged development at Hindmarsh Island. In 1990 a tender put out by Sydney Water for the growing beachside and industrial suburb of Kurnell was won.  Three projects after a lot of unpaid for design work over ten years of effort.

  1. How were you received as being a woman in a very male dominated engineering world?

I never noticed that I was any different than anyone else. After a number of different careers in fashion, media and International trade I felt that if you knew what you were talking about, people listened. The vacuum industry was new so I was considered something of an expert.

Internation Vacuum Conference, Queensland, Australia 1998. In attendance, Pat and Geoff Radinoff, Peter Radinoff, David Saunders, Willem Gooren, Mark Jones, Frank Mathias and others.

  1. What did you enjoy about the business?

The challenges: we had the right product at the time when pollution, the environment and water saving were serious issues. Canal developments were popular. There were backlogs of projects to replace odorous septic tanks with vacuum. W.A. had $800 million put aside to fix their sewage deficiencies. Wastewater experts were reassessing the benefits of the technology moving into the digital age as installation damage was minimal, with flexibility to go around, under or over obstacles and easy maintenance were winners. An industry of people who did care.

  1. Did you expand outside the Australian region?

Systems were built for many communities with health and pollution problems, seaside communities in KawaKawa Bay and Christchurch in N.Z. In Brunei, dwellings were built on stilts over waterways where people defecated, washed, and fished for food.  Healthier now with a vacuum system installed the pipes slung under their walkways to the pump station built on the land, no longer industrial looking but fitting into the ethnic architectural surroundings.   A high-rise development on a flat area in Thailand required a large innovative pit to house eight robust 90mm valves working simultaneously.  In Bahrain, Oman and Dubai sewerage was sucked through pipes, through narrow allies in busy bazaars, marketplaces and dense housing. At times going uphill, hung from rock walls and under bridges serving communities on both sides of a river. Flexible vacuum sewerage systems serviced army units and workers on the move. The waste from the collection tank, treated to be re-used.

  1. Are you still involved with the company?

As the Matriarch, I have attended International conferences and whilst no longer hands on, am fully aware of developments in the expanding Flovac world enough to enthusiastically break out the bubbles to celebrate major, even minor, progress. The monitoring development alone is a major innovation for all vacuum systems.

  1. Do you have any message for those in waste water industry or looking to become involved in vacuum sewerage technology?

Population growth in cities and towns, remote villages and eventually out to other planets, dealing with human waste will always be essential. In this 21st century cost effective ideas flowing from creative thinkers will continue to keep the Flovac company a caring, competitive, and innovative group.

For more information about some of Flovacs International Projects Click Here.