초록 ▼

Two vertically offset thermistors for sensing a fluid such as oil and refrigerant in a compressor shell are monitored by a method that takes into account rapidly changing conditions within the shell. The system can determine the fluid's sump temperature, high/low liquid levels, and can determine whe

Two vertically offset thermistors for sensing a fluid such as oil and refrigerant in a compressor shell are monitored by a method that takes into account rapidly changing conditions within the shell. The system can determine the fluid's sump temperature, high/low liquid levels, and can determine whether the thermistors are sensing the fluid as a liquid, gas, or a mixture of the two, such as a foam or mist of liquid and gas. For greater accuracy, thermistor readings can be dithered and filtered to provide temperature or voltage values having more significant digits than the readings originally processed through a limited-bit A/D converter. For faster response, limited microprocessor time is conserved by sampling thermistor readings at strategic periods that enable the microprocessor to identify certain conditions and temperatures via simple delta-temperature ratios and undemanding equations rather than resorting to exponential functions or lookup tables to determine time constants.

대표청구항 ▼

1. A method for sensing a fluid in a compressor, wherein the fluid exists in at least one of a plurality of states including at least one of a liquid state, a gaseous state, and a gas/liquid mixture, the method comprising: cyclically electrically heating and thermally cooling a thermistor that has a

1. A method for sensing a fluid in a compressor, wherein the fluid exists in at least one of a plurality of states including at least one of a liquid state, a gaseous state, and a gas/liquid mixture, the method comprising: cyclically electrically heating and thermally cooling a thermistor that has a temperature that varies and is in heat transfer relationship with the fluid so that the thermistor experiences a plurality of temperatures during a plurality of heating and cooling cycles, the temperature of the thermistor decreases during the cooling cycle;measuring the plurality of temperatures of the thermistor while the temperature of the thermistor decreases as a result of the temperature of the thermistor being greater than that of the fluid during the cooling cycle;calculating via a microprocessor, a delta-temperature ratio involving the plurality of temperatures that the thermistor experienced during the plurality of heating and cooling cycles; anddetermining, via the microprocessor, in which state the fluid exists based on magnitude of the delta-temperature ratio, wherein the magnitude of the delta-temperature ratio indicates in which of the liquid state, the gaseous state and the gas/liquid mixture that the fluid exists. 2. The method of claim 1, wherein the thermistor provides a signal that varies with a thermistor temperature of the thermistor; and within a single heating and cooling cycle, sampling the signal at a first point in time, a second point in time, and a third point in time, wherein a first period extending from the first point in time to the second point in time is shorter than a second period extending from the second point in time to the third point in time, and the step of determining in which state the fluid exists is further based on the signal at the first point in time, the second point in time, and the third point in time. 3. The method of claim 2, wherein the step of determining in which state the flu d exists is accomplished independent of any calculated time constant, exponential function, or exponential lookup table. 4. The method of claim 2, wherein the second period is substantially twice as long as the first period. 5. The method of claim 2, wherein the step of cyclically electrically heating and thermally cooling further comprising: electrically heating the thermistor to a heated temperature that is higher than a fluid temperature of the fluid;after electrically heating the thermistor, reducing a voltage applied to the thermistor;allowing the thermistor to cool toward the fluid temperature, wherein the thermistor cools at a cooling rate; andas the thermistor cools, determining the cooling rate of the thermistor by repeatedly sampling the temperature of the thermistor over a sample period, thus the cooling rate of thermistor becomes known. 6. The method of claim 5 wherein the delta temperature ratio includes a numerator and a denominator, the numerator having a first delta temperature based on the thermistor cooling during the first period, the denominator having a second delta temperature based on the thermistor cooling during the second period. 7. The method of claim 6 wherein the magnitude of the delta temperature ratio being below about 1.0 indicates a liquid state, the magnitude of the delta temperature ratio being above about 1.2 indicates a gaseous state, and the magnitude of the delta temperature ratio being between about 1.0 and 1.2 indicates the gas/liquid mixture in a foamy or misty state. 8. The method of claim 5, wherein the fluid temperature is based on the cooling rate of the thermistor, wherein the cooling rate of the thermistor is known. 9. The method of claim 8, wherein the thermistor is a first thermistor cooling at a first cooling rate and further comprising shielding the first thermistor within a tubular sheath disposed within a hermetically sealed shell of the compressor. 10. The method of claim 9 including: providing second shielded thermistor within the tubular sheath at an elevation or location different from the first thermistor;positioning the second thermistor in heat transfer relationship with the fluid;electrically heating the second thermistor to a heated temperature that is higher than a fluid temperature of the fluid;after electrically heating the second thermistor, allowing the second thermistor to cool toward the fluid temperature, wherein the second thermistor cools at a second cooling rate; anddetermining the fluid temperature based on the second cooling rate.