Did you know?

Did you know that adding forced aeration to you current composting method can increase your throughput by more than 200% ?

Active composting is an oxygen consuming, heat generating process primarily carried out by aerobic bacteria. Temperatures in energetic composting piles will rise rapidly and remain at levels that can inhibit these aerobes, slowing stabilization and increasing odor emissions.

There are two fundamental reasons that high temperatures inhibit efficient composting. First is the fact that high temperatures reduce the supply of oxygen to the aerobic bacteria, which require water, nutrients and oxygen to do their work. These conditions exist in the liquid film that surrounds the particles in a compost pile with adequate moisture (Figure 1). Oxygen, supplied to the free air space, must dissolve into this liquid film so the aerobes can respire. The solubility of oxygen in water goes down as temperatures go up — as they tend to early in composting process when the need for oxygen is highest (Sauer, 2013). In field studies, the authors of this article have measured a clear positive correlation between oxygen saturation levels in the liquid film layer and stabilization rates and odor control.

The second reason is that temperature determines the class of microbes that predominate in the composting process. The two classes of interest in active composting are mesophiles (moderate temperature loving) and thermophiles (high temperature loving). It has been well documented in peer-reviewed literature (Sundberg, 2005; Sundberg and Jonsson, 2008; Sauer, 2013) that when mesophilic temperatures are achieved early in the composting process, the pH rises to above 6 (a key performance indicator), nitrogen is more readily converted to nitrates, odor emissions are drastically reduced, and the rate of bio-oxidation of organic matter increases markedly.

On the other hand, when temperatures rise to, and are maintained in, the thermophilic range the opposite is true. Fortunately, composting is a robust process. A composting pile can spend a few days at the beginning of the active phase at elevated temperatures before it is cooled down to more mesophilic friendly temperatures without causing undue inhibition to the process or emitting unmanageable odors. It should not, however, spend weeks at thermophilic temperatures. Fortunately, temperature is the easiest composting parameter to measure.

Forced Aeration Floors

Prolonged elevated temperatures are an indicator of inadequate pile aeration. Forced aeration, using either the aerated static piles or windrow methods, is one approach to supplying oxygen to the composting process. A key element in a forced aeration system is the aeration floor. It serves as the primary working surface, and distributes air through the compost pile. Keeping the aerobes working efficiently requires that the aeration floor must uniformly and reliably supply enough air to match heat production in the pile.

Aeration floors can be designed to drain away excess water. Mixes with significant food waste content tend to release large volume of leachate early in the process. In addition to being acidic and odorous, this liquid tends to occupy the pore spaces, shown in Figure 1, near the bottom of the pile. This inhibits airflow through, the supply of oxygen to, and removal of gasses from, the free air space. A well-designed aeration floor will serve to efficiently drain off and capture leachate to reduce excess moisture.

Aeration systems come in three basic types: positive, negative or reversing (which alternates between positive and negative). Positive aeration refers to a system where air is forced out of the floor into the material. Negative aeration refers to a system where air is drawn into the floor from the material. Each has its strength: positive aeration is the simplest to implement; negative aeration has the highest air emissions and leachate capture efficiencies; and reversing aeration provides the most uniform conditions throughout the depth of the pile.

There are many variations of aeration floors, but they can generally be organized into the following groups: On-Grade versus In-Floor, and Sparger versus Low Friction.

By far the most common type of aeration floor is a Pipe-On-Grade (POG) Sparger. This aeration floor consists of a series of pipes with a designed series of perforations placed on top of the working surface and connected to an aeration system. These pipes are generally pulled from under the pile before it is broken down, then replaced and reconnected prior to building a new pile. A pipe is a sparger if it uses high back pressure across the orifices to overcome the pressure loss along the pipe and thus get semi-uniform air distribution along the length of the pipe.

In-floor type aeration floors can be either sparger or low-friction. In either case they are almost always permanently cast in concrete and provide a flat working surface that does not interfere with the wheel loader or require regular operator intervention. An aeration floor is low-friction if it relies on a balanced low pressure design to distribute air uniformly. Low-friction aeration floors require only 25 to 50 percent of the fan horsepower required for the same air flow from a sparger floor, but they are somewhat more expensive to build.