What your manufacturer owes you before the truck leaves the dock, and what a smooth startup looks like.
Blog Summary: The installation problems that derail wet scrubber projects almost never start on-site. They start weeks earlier — in an incomplete specification, a factory that didn't test before shipping, or a contractor who arrived without ever seeing the unit assembled. This guide covers the full arc of a scrubber installation so you know where accountability should sit at every stage, and what to demand from your manufacturer before the truck leaves the dock.
Most installation problems with industrial wet scrubbers aren't installation problems. They're design problems. Or shipping problems. Or specification gaps that nobody caught until the contractor showed up on-site with a unit that doesn't quite match the drawings.
By the time a scrubber reaches your facility, the decisions that determine whether installation goes smoothly have largely already been made. That's worth understanding. Because it shifts accountability to an earlier stage in the process, and toward the right party: your manufacturer.
This guide covers the full arc of a wet scrubber installation, from the data your engineer needs before putting pen to spec sheet, through factory assembly, shipping, field reassembly, and startup. At each stage, there's a clear standard for what should happen and what commonly goes wrong when it doesn't.
Before a corrosive exhaust scrubber can be accurately designed or quoted, your manufacturer needs eight things:
That last one matters more than most engineers expect. The answer to each of these questions changes the scrubber design — the vessel sizing, the packing depth, the pump selection, the piping configuration, the structural design for wind and seismic loads. An incomplete intake means an incomplete quote, and a quote built on assumptions tends to produce surprises on-site.
If your manufacturer isn't asking for all eight upfront, that's a flag.
Two configuration choices get locked in early and directly affect how the installation plays out in the field.
Recirculation system: self-contained vs. remote. Self-contained units mount the pump on the scrubber sump, the right call for warm climates and indoor installations. Remote systems locate the recirculation tank separately inside the building, which eliminates the risk of freezing and the need for scrubber heaters in cold-weather regions. The trade-off is more field piping. Climate and facility layout drive the decision.
Secondary containment level. A base containment pan catches leaks at the bottom of the scrubber, the industry standard and adequate for most applications. Full encapsulation is a different category. A fiberglass shell built around all process piping means any valve, fitting, or pump seal failure stays inside the unit and drains to the containment pan.
Access doors handle routine maintenance. Removable wall panels handle major work. It adds cost, roughly $30,000 to $40,000, depending on scrubber size. It also eliminates a category of safety and environmental risk the standard pan approach doesn't fully address. For applications handling aggressive acids or caustics, that trade-off deserves a direct conversation with your engineer, not a line item deleted in value engineering.
This is where a lot of industrial air pollution control projects quietly go wrong.
A Viron scrubber system (FRP, PVC, or SSTeelcoat-ducted), for instance, arrives completely pre-plumbed. Every valve, pump, and sensor is mounted and tested in our shop before we break the unit down for shipping. All field connections are flanged or union-type. The contractor doesn't do field fabrication on plumbing; they connect, bolt, and commission.
The alternative is common in the industry. Many manufacturers ship the scrubber body. The installing contractor handles all the plumbing on-site — sourcing compatible components, making field cuts, running their own leak checks. It extends the installation schedule, introduces compatibility questions that should have been resolved at the factory, and puts the performance risk on a crew that didn't design the system.
Factory water testing is the other step that matters here. Every Viron scrubber is filled with water and runs through a complete functional test before it leaves our facility. Every pump is operated. Every valve cycled. Every sensor verified. By the time that unit reaches your site, it has already worked. What remains is reassembly and connection to your system — not discovery.
Large scrubbers ship in pre-assembled sections with all plumbing connections gasket-flanged at the break points. The contractor sets the base section, bolts the seam, connects the gaskets on the flanged piping, and sets the next section.
That's the sequence. No field welding. No cutting. No guessing about what connects where.
Shrink wrapping (the same material used to ship pontoon boats) protects fittings, gaskets, and exposed surfaces during transit and on-site storage. When a scrubber arrives in January in Michigan and sits on the dock for three weeks before the building is ready, that protection matters.
For PVC scrubbers, temperature during transit matters. PVC warps in sustained heat and can become brittle in extreme cold. If your unit is shipping in summer to Texas or in winter to the northern Midwest, controlled transport (refrigerated or heated truck) is the right call. Not every manufacturer thinks about it. Worth asking.
One step that consistently shortens field installation time: have the installing contractor come to the factory before shipment. They see how the scrubber was assembled. They walk through every major connection point with our team. When they get to the job site, they already know what they're looking at. Installations run faster.
Questions that would have surfaced as delays get answered before they become delays.
The work at the job site is largely mechanical. Set the base, plumb the sections together, make the inlet and outlet duct connections, and connect the electrical. Clean flanged connections and documented connection points mean this goes the way it should.
Expansion joints at the inlet and outlet are worth specifying upfront. Scrubbers in corrosive exhaust applications see thermal cycling and fan vibration on a daily basis. Those loads accumulate at the connection points. Expansion joints absorb them. Skipping them to save cost is a common decision that shows up later as flange wear and eventual leaks.
The ductwork connecting to the scrubber inlet and outlet is a separate conversation. Material compatibility between your duct and scrubber matters — thermal expansion coefficients, chemical resistance across the full spectrum of your exhaust stream, pressure ratings. When the duct and the scrubber come from the same manufacturer, that compatibility is engineered in. When they come from different vendors, someone has to verify it explicitly. Typically, that verification happens during commissioning, when it's harder to fix.
Commissioning a wet scrubber — particularly one with a full instrumentation package, PLC controls, and automated makeup and blowdown management — requires someone who knows the system intimately.
Viron builds all the control programming in-house.
When a project warrants it, we send our controls engineer to the job site for startup. That's the person who designed the control panel, wrote the logic, and can tune the pH controller, verify the conductivity system is reading correctly, confirm the VFDs are running at design flow, and walk your operations team through the HMI.
Large competitors typically don't do this. The scrubber ships, the documentation ships, and you work through issues with a support line.
Startup support from the manufacturer's own team isn't a luxury. On systems designed to handle semiconductor acid exhaust, chrome scrubbing in metal finishing operations, or hydrogen sulfide control at municipal wastewater facilities, it's the step that confirms the system is actually doing what it was designed to do before you release the contractor and sign off on the installation.
A wet scrubber doesn't operate in isolation. The fan moving air through your corrosive exhaust system needs to be sized to the scrubber's actual pressure drop, not an estimate, not a catalog number. The ductwork running from your hoods to the scrubber inlet needs to be specified for the same chemical environment the scrubber is handling. Dampers, stacks, and controls need to be coordinated.
When those components come from different vendors, performance accountability gets complicated fast. When airflow doesn't match the design, everyone points somewhere else. The scrubber manufacturer questions the fan sizing. The fan supplier questions the ductwork resistance. You're in the middle of it, and your facility isn't running.
Single-source procurement for industrial air cleaning systems (ductwork, scrubber, fan, dampers, controls from one manufacturer) eliminates that dynamic. One engineer knows the whole system. One company is accountable for whether it works.
You've now seen where installations succeed and where they break down. The variables that drive those outcomes — inlet flow, chemical mix, location, containment requirements, recirculation configuration — are specific to your application.
That's where the conversation with our engineering team starts.
Viron has manufactured corrosive air handling systems for over 50 years across semiconductor fabs, municipal wastewater facilities, metal finishing operations, and industrial chemical applications. We'll tell you what we need to design your system correctly and what a realistic schedule looks like from order through startup. Request a quote today.