Hot melt level sensor and sensor housing

The invention claimed is: 1. An adhesive melting system comprising: a melter configured to contain and melt adhesive; an ultrasonic level sensor positioned to sense a level of adhesive in the melter; a feed system configured to supply unmelted adhesive to the melter as a function of the sensed level of adhesive in the melter; and a sensor housing comprising: a tower extending along a tower axis and spacing the ultrasonic level sensor away from the adhesive; an insert holding the ultrasonic level sensor atop the tower; and an air passage disposed between the tower and the insert, the air passage extending between an air channel disposed to receive cooling air through an air inlet in the tower, and a plurality of air ports disposed at acute angles with respect to the tower axis to expel the cooling air into an enclosed interior region of the tower between the ultrasonic level sensor and the melter. 2. The adhesive melting system of claim 1 , wherein the air ports are disposed to create a positive pressure region that deflects dust and debris away from the ultrasonic level sensor in the fully inclosed interior region. 3. The adhesive melting system of claim 1 , wherein the air ports are disposed circumferentially about the tower axis, and extend axially past a sensor face of the ultrasonic level sensor. 4. The adhesive melting system of claim 1 , wherein the tower has an angled wall near the air ports configured to avoid impeding air flow from the air ports or causing turbulence that might hinder sensitivity or reliability of the level sensor. 5. A method for sensing level in an adhesive melter, the method comprising: melting adhesive pellets within a melter; sending and receiving ultrasonic pulses from an ultrasonic level sensor to determine location of an adhesive surface within the melter; replenishing adhesive pellets in the melter as a function of the determined location of the adhesive surface; flowing air into an air channel of an air passage between a tower and an insert of a sensor housing supporting the level sensor to cool the level sensor and deflect dust and debris away from the level sensor; and expelling air from the air channel at an acute angle with respect to an axis of the sensor housing, through a plurality of circumferentially distributed air ports, into an interior region of the sensor housing between the ultrasonic level sensor and the melter. 6. The method of claim 5 , further comprising deflecting dust and debris away from the ultrasonic sensor via a positive pressure region created between the level sensor and the adhesive surface by expelling the air through the air ports. 7. The method of claim 5 , wherein sending and receiving ultrasonic pulses though the sensor housing comprises sending and receiving ultrasonic pulses through the interior. 8. A level sensing system comprising: a level sensor with a sensor face; and a sensor housing comprising: a tower extending along a tower axis from an open end distant from the sensor face to a sensor end proximate to the sensor face, wherein the sensor end holds the level sensor a distance from the open end; and an air passage for providing airflow to cool and protect the level sensor, the air passage comprising: an air channel configured to receive and distribute pressurized air flow to convectively cool the level sensor; and a plurality of air ports extending at acute angles with respect to the tower axis, from the air channel to an region interior of the tower. 9. The level sensing system of claim 8 , wherein the level sensor is an ultrasonic depth sensor configured to transmit and receive ultrasonic pulses. 10. The level sensing system of claim 8 , wherein the air ports are disposed circumferentially about the tower axis to create a positive pressure region between the sensor face and open end of the tower. 11. The level sensing system of claim 10 , wherein the air ports are symmetrically disposed about the tower axis. 12. The level sensing system of claim 8 , wherein the sensor housing further comprises a face section adjacent the level sensor at the sensor face, and configured to allow ultrasonic pulses to pass through the sensor housing. 13. The level sensing system of claim 12 , wherein the face section is a section of thin material through which the level sensor can transmit and receive ultrasonic pulses. 14. The level sensing system of claim 12 , wherein the face section is a region of the sensor housing with an aperture through which the level sensor can transmit and receive ultrasonic pulses. 15. The level sensing system of claim 8 , further comprising a melter configured to receive and melt an industrial process material; and a feed hose configured to draw the industrial process material into the melter when a reading of the ultrasonic level sensor indicates that a level of the industrial process material in the melter has dropped below a target level. 16. The level sensing system of claim 15 , wherein the industrial process material is adhesive. 17. The level sensing system of claim 8 , wherein the tower has an wall near the air ports that is angled acutely with respect to the tower axis so as not to impede air flow or cause turbulence near the sensor face.