M&M Grouting Service will install your chocking system according to your specification and needs, whether it be full bed grout, epoxy chocks, steel chocks and sole plates,

or the newer composite material chocks such as the the adjustable Tri Chocks and Vibratherm shim-able chocks.

We have worked extensively with re-metallizers such as Belzona and Resistalloy that increase the life of chocking systems and engine bases.

We have the ability and skill to grout the engines in place or move them over for full block replacement.

M&M Grouting Service, Inc has proven expertise in placing special regular concrete mixtures or the new fast-curing crete's.

For a better understanding,

it is helpful to analyze the different types of grout.

Different Types Of Grout

Machinery Grout
Inorganic Grout
Organic Grout

                                                             grouting and chocks

Grout has to be used in conjunction with a properly torqued anchor bolt system when both static and dynamic loading is involved, such as with compressors, turbines, pumps, gear boxes,

and most heavy industrial machines. It takes both good grout and good bolts to properly hold the modern machines industry uses today.

Inorganic Grout are by far the oldest grouts and are used in a broad range of industrial applications. Sometimes referred to as sand and cement grouts, which are mixed with

no water, this description does not do justice to the sophisticated properties some modern-day, proprietary brands possess. Plain sand, cement and water mixes shrink.

By the addition of other materials to the formula, however, the natural shrinkage can be offset by various expansive mechanisms.

The resulting product will actually expand very slightly, in the range of .03%.

Since a lot of the shrinkage and expansion reactions take place in the plastic stage, before final cure, some expansive formulations can lose part of the net gain against shrinkage

when the hydration process moves beyond the plastic stage. There are even proprietary brands that offer double expansive mechanisms, with the second taking over in the later stages of cure.

Certainly such formulations are much more complex than a simple sand and cement mixture. The formulators goal is to produce a product that, when properly mixed and installed,

will provide excellent base plate contact (95% to 100%), good compressive properties (5,000 psi to 8,000 psi), and the ability to be installed in a range of environments from 50 F to 100 F.

In a lot of industrial applications, a good inorganic grout will be stronger and more dense than the underlying concrete foundation.

Being less expensive, by perhaps 30% to 50% of what an organic-based epoxy grout costs, inorganic grouts are used quite broadly where operating conditions permit.

Organic Grouts are the second general class of grouts because of a polymer binder, which is organic, is substituted for the cement binder in a inorganic grout.

Organic grouts often contain the same inorganic fillers (sand, silica flour, and quartz) found in pure inorganic cement grout formulas.

If inorganic grouts are stronger than concrete and cheaper than organic grouts, why even use an organic grout?

The reason is very simple; the organic grout gives much better chemical resistance which allows it to perform where inorganic grouts can't.

Even something as simple as lubricating oil can eventually destroy the physical properties of inorganic grouts.

Organic grouts are stronger in compressive, shear and tensile strength, so they can perform longer under heavy dynamic loading conditions.

There is a place for this more expensive class of grout in machinery grouting, particularly for the right angle drive reciprocating compressors, large diesel and gas engines,

some turbines and gear boxes, as well as a host of equipment in the steel and paper industries where wet operating conditions are prevalent.

Organic grouts, also called polymer grouts, are usually based on a thermosetting plastic resin system, such as epoxy. Other thermosetting resins, such as polyesters, phenolics

and furanes, have been used as well. These materials are used  in specialty grouts requiring a particular resistance to strong chemicals beyond the usually good chemical resistance offered by epoxies.

The most common type of organic grouting systems are based on epoxy resins. Because of the popularity of this class of grout, we will deal with the proper use and application of epoxy grouts.

These grouts can be summarized as having almost no shrinkage, compressive strengths of 10,000 psi to 14,000 psi or better , tensile strengths of 2,000 psi or better, and they are essentially

impervious to penetration or chemical attack by oils, detergents, water, mild acids and most alkaline solutions. However, with a coefficient of expansion of at least twice that of concrete and steel,

care in the design, use and installation of epoxy grouts that must be taken.


Machinery Grout 

 Isa material; either organic (such as epoxy) or inorganic (in case of cement-based materials) that serves as a filler between the bottom of the machine base and the top of the concrete foundation or metal equipment skid. Typical machinery grouts are flowable, virtually non-shrinking or slightly expanding, and serve to support the equipment base at a precise elevation within .001" over the life of a machine. Usually installed 1" to 2" in thickness, they fill the gap between a non-precise top elevation of the concrete block and the machined bottom of the equipment base. Grouts only keep the machinery base from moving downward. An integral right angle drive gas compressor produces loads in the horizontal and vertical directions. Horizontal movement is restrained by the clamping action of the properly torqued anchor bolts against the machinery grout. You can see why a machinery grout has to be a tough material. It must be able to withstand prolonged compressive loads, at equipment-operating temperatures, without creeping or allowing the base to deflect, as this will disturb the alignment of the moving parts of the machine.