Solids level indicator

What is claimed is: 1. A solids level indicator assembly comprising: a shaft housing having a housing interior end oppositely disposed a housing exterior end, wherein the shaft housing exterior end is disposed outside a vessel, and wherein the shaft housing fixedly engages the vessel so as to resist torsional movement; a torsion shaft having a shaft interior end and a shaft exterior end, wherein the torsion shaft is disposed within the shaft housing such that the shaft interior end extends past the housing interior end to engage a paddle cap disposed within the vessel; a paddle engaging the paddle cap perpendicularly to a length of the torsion shaft so as to cross a path of solids in the vessel, wherein the paddle torsionally communicates with the shaft interior end; a modular external sensor having a rotary end adjacently disposed to a stationary end, wherein the rotary end is adjacently disposed to the shaft exterior end and the shaft exterior end torsionally communicates with the adjacently disposed rotary end, and wherein the modular external sensor is configured to be disengaged from the shaft exterior end, wherein the modular external sensor being adjacently disposed to the shaft exterior end defines a torsion rod; a support structure engaged to the solids level indicator assembly, and; a shear lock configured to engage the support structure to the torsion rod, wherein the shear lock is configured to withstand a maximum shear force and wherein the support structure and the shear lock are configured to prevent the torsion rod from rotating when the shear force does not exceed the maximum shear force. 2. The assembly of claim 1 , wherein the support structure is selected from the group consisting of mounting arms, a mounting cone, and a support sleeve, shaft housing, or a combination thereof. 3. The assembly of claim 1 further comprising an indicator adaptor having a protective sleeve extending over the paddle cap, wherein the indicator adaptor is configured to fixedly engage a solids level indicator to a vessel wall so as to resist torsional movement. 4. The assembly of claim 1 further comprising a plug cap adjacently disposed to the stationary end of the modular external sensor wherein the plug cap torsionally communicates with the stationary end of the modular external sensor, wherein the plug cap has areas defining a bore hole, and wherein the shear lock is a shear pin extending through a shear pin hole in the support structure into the bore hole of the plug cap to prevent the plug cap from rotating as long as the shear force does not exceed the maximum shear force. 5. The assembly of claim 4 , wherein the plug cap has multiple bore holes arranged at intervals. 6. The assembly of claim 1 further comprising a torsion spring having a first spring end and a second spring end, wherein the first spring end engages a cover plate and is in torsional communication with the torsion shaft and the second spring end engages the support sleeve so as to store torsional force transmitted through the torsion shaft. 7. The assembly of claim 6 , wherein the shear lock is a shear pin extending into the shaft housing and wherein the second spring end is configured to convey excess stored torsional force through the support structure to the shear pin. 8. The assembly of claim 1 , wherein the modular external sensor is selected from the group consisting of a strain gauge, a piezoelectric sensor, an angle gauge, torque transducer, or a combination thereof. 9. The assembly of claim 1 further comprising multiple modular external sensors in torsional communication with the torsion shaft and wherein each modular external sensor is configured to be slidably removed from the solids level indicator assembly. 10. The assembly of claim 1 , wherein the vessel is selected from the group consisting of a vapor phase chemical digester, a hydraulic phase chemical digester, and an impregnation vessel. 11. The assembly of claim 1 , wherein the shear lock is selected form the group consisting of a shear pin, a magnet, a rare earth magnet, torsion spring, or other structure configured to permit the torsion rod to rotate once the shear force exceeds a preconfigured shear force threshold. 12. A solids level indicator comprising: a shaft housing having a housing interior end and a housing exterior end, wherein the shaft housing exterior end is disposed outside a vessel, and wherein the shaft housing fixedly engages the vessel so as to resist torsional movement; a torsion shaft having a shaft interior end and a shaft exterior end, wherein the torsion shaft is disposed within the shaft housing such that the shaft interior end extends past the housing interior end to engage a paddle cap disposed within the vessel; a paddle engaging the paddle cap perpendicularly to a length of the torsion shaft so as to cross a path of solids in the vessel, wherein the paddle torsionally communicates with the shaft interior end; a modular external sensor having a rotary end adjacently disposed to a stationary end, wherein the rotary end is adjacently disposed to the shaft exterior end and the shaft exterior end torsionally communicates with the adjacently disposed rotary end, and wherein the modular external sensor is configured to be slidably disengaged from the shaft exterior end; a support structure engaged to the solids level indicator assembly; and a torsion spring disposed around the support structure, wherein the torsion spring has a first spring end distally disposed from a second spring end, wherein the first spring end is in torsional communication with the modular external sensor, and wherein second spring end fixedly engages the support structure such that the torsion spring bends to store torsional energy when solids exert a downward force on the paddle and wherein the torsion spring releases the stored energy into the torsion shaft in a direction opposite the direction of the torsional force exerted on the paddle by the mass of solids when the force exerted by the solids subsides. 13. The solids level indicator of claim 12 further comprising a shear pin extending through the support structure into the shaft housing. 14. The solids level indicator of claim 12 , wherein the support structure is selected from the group consisting of mounting arms, a mounting cone, shaft housing, and a support sleeve, or a combination thereof. 15. The solids level indicator of claim 12 , wherein the modular external sensor is selected from the group consisting of a strain gauge, a piezoelectric sensor, an angle gauge, torque transducer, or a combination thereof. 16. The solids level indicator of claim 12 further comprising multiple modular external sensors in torsional communication with the torsion shaft wherein each modular external sensor is configured to be slidably removed from the solids level indicator assembly. 17. A solids level indicator comprising: a shaft housing having a housing interior end and a housing exterior end, wherein the shaft housing exterior end is disposed outside a vessel, and wherein the shaft housing fixedly engages the vessel so as to resist torsional movement; a torsion shaft having a shaft interior end and a shaft exterior end, wherein the torsion shaft is disposed within the shaft housing such that the shaft interior end extends past the housing interior end to engage a paddle cap disposed within the vessel; a paddle engaging the paddle cap perpendicularly to a length of the torsion shaft so as to cross a path of solids in the vessel, wherein the paddle torsionally communicates with the shaft interior