Surface solids system

What is claimed is: 1. A system comprising: a component of solids control equipment operable in a drill rig system for a wellbore, the component of solids control equipment having a fluid flow input and a fluid flow output; micro-electro-mechanical (“MEM”) devices disposable in a fluid flow stream from the wellbore, the MEM devices being of various types differing in at least one of sizes, shapes, or densities so as to be representative of a plurality of non-desirable solids in the wellbore; a first MEM reader positionable proximate to the fluid flow stream and between the fluid flow input and the wellbore for detecting an amount and types of the MEM devices in the fluid flow stream prior to the fluid flow input; a second MEM reader positionable proximate to the fluid flow stream and the fluid flow output for detecting at least an amount and types of a subset of the MEM devices in the fluid flow stream subsequent to the fluid flow output; and a processing module comprising a non-transitory computer-readable medium with machine-readable code for comparing the amount and types of the MEM devices in the fluid flow stream prior to the fluid flow input and the amount and types of MEM devices in the fluid flow stream subsequent to the fluid flow output to determine the amount and types of the MEM devices removed from the fluid flow stream by the component of solids control equipment and for outputting, in response to the comparing, an indication of an efficiency of the component of solids control equipment in removing the plurality of non-desirable solids. 2. The system of claim 1 , wherein the component of solids control equipment includes at least one of a shale shaker, a desander, a desilter, a centrifuge, or a mud cleaner. 3. The system of claim 1 , wherein the processing module is communicatively coupled to the first MEM reader for receiving data corresponding to the amount and types of MEM devices in the fluid flow stream prior to the fluid flow input and the processing module is communicatively coupled to the second MEM reader for receiving data corresponding to the amount and types of MEM devices in the fluid flow stream subsequent to the fluid flow output. 4. The system of claim 1 , wherein the outputting comprises producing an alarm. 5. The system of claim 1 , wherein the processing module is communicatively coupled to the first MEM reader for receiving data corresponding to a distribution of the various types of MEM devices, and densities in the fluid flow stream prior to the fluid flow input and the processing module is communicatively coupled to the second MEM reader for receiving data corresponding to a distribution of the types of MEM devices in the fluid flow stream subsequent to the fluid flow output. 6. The system of claim 5 , wherein the processing module comprises machine-readable code for comparing the distribution of the amount and types of MEM devices in the fluid flow stream prior to the fluid flow input and the distribution of the amount and types of MEM devices in the fluid flow stream subsequent to the fluid flow output to determine a distribution of the efficiency of the plurality of non-desirable solids removed from the fluid flow stream by the component of solids control equipment. 7. The system of claim 1 , wherein the second MEM reader is positionable proximate to the fluid flow stream and between the fluid flow output and the wellbore and further comprising: a third MEM reader positionable proximate to the fluid flow stream and subsequent to the fluid flow output and subsequent to the second MEM reader for detecting at least a subset of the MEM devices in the fluid flow stream returning to the wellbore after exiting the fluid flow output. 8. The system of claim 1 , further comprising: a magnetic system, positionable subsequent to the second MEM reader, the magnetic system having at least one magnet for retrieving any MEM devices remaining in the fluid flow stream subsequent to the fluid flow output. 9. A method comprising: detecting, by a first micro-electro-mechanical (“MEM”) reader, an amount and types of MEM devices in a fluid flow stream from a wellbore prior to a fluid flow input of a component of solids control equipment, the MEM devices being of various types differing in at least one of sizes, shapes, or densities so as to be representative of a plurality of non-desirable solids in the wellbore; detecting, by a second MEM reader, at least an amount and types of a subset of the MEM devices in the fluid flow stream subsequent to a fluid flow output of the component of solids control equipment; and determining, by a processing module comprising a non-transitory computer-readable medium embodying machine-readable code, an efficiency of the component of solids control equipment in removing the plurality of non-desirable solids by comparing the amount and types of MEM devices in the fluid flow stream prior to the fluid flow input and the amount and types of MEM devices in the fluid flow stream subsequent to the fluid flow output. 10. The method of claim 9 , further comprising: transmitting first data from the first MEM reader to the processing module, the first data corresponding to a distribution of the various types of MEM devices and densities in the fluid flow stream prior to the fluid flow input; and transmitting second data from the second MEM reader to the processing module, the second data corresponding to a distribution of the types of MEM devices in the fluid flow stream subsequent to the fluid flow output. 11. The method of claim 10 , further comprising: comparing, by the processing module, the distribution of the amount and types of MEM devices in the fluid flow stream prior to the fluid flow input and the distribution of the amount and types of MEM devices in the fluid flow stream subsequent to the fluid flow output to determine a distribution of the efficiency of the component of solids control equipment in removing the plurality of non-desirable solids from the fluid flow stream. 12. The method of claim 9 , further comprising: outputting, by the processing module, an alarm in response to the efficiency of the component of solids control equipment in removing the plurality of non-desirable solids being below a threshold. 13. The method of claim 9 , further comprising retrieving, by a magnetic system having at least one magnet, any MEM devices remaining in the fluid flow stream subsequent to the fluid flow output. 14. A system comprising: a first micro-electro-mechanical (“MEM”) reader positionable proximate to a fluid flow stream from a wellbore for detecting an amount and types of MEM devices in the fluid flow stream prior to a fluid flow input of a component of solids control equipment operable with a drill rig system for the wellbore, the MEM devices being of various types representative of a plurality of non-desirable solids in the wellbore; and a second MEM reader positionable proximate to the fluid flow stream for detecting an amount and types of MEM devices in the fluid flow stream subsequent to a fluid flow output of the component of solids control equipment, the first MEM reader and the second MEM reader being communicatively coupled with a processing module todetermine an efficiency of the component of solids control equipment in removing the plurality of non-desirable solids by comparing the amount and types of MEM devices in the fluid flow stream prior to the fluid flow input and the amount and types of MEM devices in the fluid flow stream subsequent to the fluid flow output. 15. The system of claim 14 , further comprising the MEM devices disposable in th