Magnetic flowmeter with vapor permeation sensor

The invention claimed is: 1. A magnetic flowmeter comprising: a pipe having a non-conductive liner on an inner surface; a field coil adjacent to the pipe and configured to generate a magnetic field across a fluid flowing through the pipe; a first electrode located in a first tunnel passing through the pipe and into the non-conductive liner, and a second electrode located in a second tunnel passing through the pipe and into the non-conductive liner, the first electrode and the second electrode configured to sense a voltage induced by the magnetic field across the fluid flowing through the pipe; a first sealed compartment attached to an outer surface of the pipe, the first sealed compartment enclosing at least one of the field coil, the first electrode, and the second electrode; a first vapor sensor located within the sealed compartment and configured to sense relative humidity in the first sealed compartment; and an electronics compartment having transmitter circuitry connected to the field coil, the first electrode, the second electrode, and the first vapor sensor, wherein the transmitter circuitry generates a first output representing a flow rate of the fluid as a function of the voltage sensed by the first electrode and the second electrode, and generates a second output based upon the relative humidity sensed by the first vapor sensor, the second output providing an alert indicating vapor permeation in the first sealed compartment. 2. The magnetic flowmeter of claim 1 , wherein the fluid is a conductive fluid. 3. The magnetic flowmeter of claim 1 , wherein the vapor sensor is a MEMS device. 4. A magnetic flowmeter comprising: a pipe having a non-conductive liner on an inner surface; a field coil adjacent to the pipe and configured to generate a magnetic field across a fluid flowing through the pipe; a first electrode located in a first tunnel passing through the pipe and into the non-conductive liner, and a second electrode located in a second tunnel passing through the pipe and into the non-conductive liner, the first electrode and the second electrode configured to sense a voltage induced by the magnetic field across the fluid flowing through the pipe; a first sealed compartment attached to an outer surface of the pipe, the first sealed compartment enclosing at least one of the field coil, the first electrode, and the second electrode; a first vapor sensor located within the sealed compartment and configured to sense relative humidity in the first sealed compartment; and an electronics compartment having transmitter circuitry connected to the field coil, the first electrode, the second electrode, and the first vapor sensor, wherein the first sealed compartment comprises a magnetics compartment surrounding the pipe and enclosing the field coil, the first electrode, the second electrode, and the vapor sensor. 5. The magnetic flowmeter of claim 4 , wherein the first vapor sensor is configured to sense relative humidity in the magnetics compartment due to vapor permeation through the non-conductive liner into the magnetics compartment. 6. A magnetic flowmeter comprising: a pipe having a non-conductive liner on an inner surface; a field coil adjacent to the pipe and configured to generate a magnetic field across a fluid flowing through the pipe; a first electrode located in a first tunnel passing through the pipe and into the non-conductive liner, and a second electrode located in a second tunnel passing through the pipe and into the non-conductive liner, the first electrode and the second electrode configured to sense a voltage induced by the magnetic field across the fluid flowing through the pipe; a first sealed compartment attached to an outer surface of the pipe, the first sealed compartment enclosing at least one of the field coil, the first electrode, and the second electrode; a first vapor sensor located within the sealed compartment and configured to sense relative humidity in the first sealed compartment; and an electronics compartment having transmitter circuitry connected to the field coil, the first electrode, the second electrode, and the first vapor sensor, wherein the first sealed compartment comprises a first electrode well enclosing the first electrode and the first vapor sensor. 7. The magnetic flowmeter of claim 6 , wherein the first vapor sensor is configured to sense relative humidity in the first electrode well due to vapor permeation through the non-conductive liner into the first electrode well. 8. The magnetic flowmeter of claim 7 , and further comprising a second sealed compartment and a second vapor sensor connected to the transmitter circuitry, wherein the second sealed compartment encloses the second electrode and the second vapor sensor. 9. The magnetic flowmeter of claim 8 , wherein the second vapor sensor is configured to sense relative humidity in the second electrode well due to vapor permeation through the non-conductive liner into the second electrode well. 10. The magnetic flowmeter of claim 9 , wherein the transmitter circuitry generates the second output based upon the relative humidity sensed by the first vapor sensor and/or the second vapor sensor, the second output alerting a user to vapor permeation in the first electrode well and/or the second electrode well. 11. A method comprising: sensing flow of a fluid through a pipe of a magnetic flowmeter; sensing a relative humidity in a first sealed compartment with a first vapor sensor, the first sealed compartment attached to the pipe and enclosing at least one of a field coil, a first electrode, or a second electrode; and generating a first output representing a flow rate of the fluid through the pipe and a second output based upon the relative humidity sensed by the first vapor sensor, the second output alerting a user to vapor permeation in the first sealed compartment, wherein the first sealed compartment comprises a first electrode well enclosing the first electrode and the first vapor sensor. 12. The method of claim 11 , wherein the first vapor sensor senses relative humidity in the first electrode well due to vapor permeation through a non-conductive liner into the first electrode well. 13. The method of claim 12 , and further comprising sensing a relative humidity in a second sealed compartment with a second vapor sensor, the second sealed compartment comprising a second electrode well enclosing the second electrode and the second vapor sensor. 14. The method of claim 13 , wherein the second vapor sensor senses relative humidity in the second electrode well due to vapor permeation through a non-conductive liner into the second electrode well. 15. The method of claim 14 , wherein a second output is generated based upon the relative humidity sensed by the second vapor sensor, the second output alerting a user to vapor permeation in the second electrode well. 16. A method comprising: sensing flow of a fluid through a pipe of a magnetic flowmeter; sensing a relative humidity in a first sealed compartment with a first vapor sensor, the first sealed compartment attached to the pipe and enclosing at least one of a field coil, a first electrode, or a second electrode; and generating a first output representing a flow rate of the fluid through the pipe and a second output based upon the relative humidity sensed by the first vapor sensor, the second output alerting a user to vapor permeation in the first sealed compartment, wherein the first sealed compartment comprises a magnetics compartment surrounding the pipe and enclosing the field coil, the first electrode, the second electrode, and the