Gas flow rate determination method and apparatus and granular material dryer and method for control thereof
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F26B-003/06
출원번호
US-0540541
(2009-08-13)
등록번호
US-8141270
(2012-03-27)
발명자
/ 주소
Gera, Jr., Michael E.
출원인 / 주소
Maguire Products, Inc.
대리인 / 주소
Quinn, Esq., Charles N.
인용정보
피인용 횟수 :
0인용 특허 :
71
초록▼
Methods and apparatus for determining flow rate of air or other gas through a conduit independently of conduit cross sectional area include providing apparatus for and measuring temperature of the air or other gas at a first position along the conduit; providing apparatus for and heating the air or
Methods and apparatus for determining flow rate of air or other gas through a conduit independently of conduit cross sectional area include providing apparatus for and measuring temperature of the air or other gas at a first position along the conduit; providing apparatus for and heating the air or other gas in the conduit of the location downstream from the first position by application of a known power level to the air or other gas in the conduit; providing apparatus for and measuring air or other gas temperature at a second position downstream of the heating position along the conduit; providing apparatus for and subtracting air or other gas temperature at the second position from air or other gas temperature at the first position to obtain a temperature difference and thereafter providing apparatus for and dividing power applied to heat the air or other gas by the product of the temperature difference and the specific heat of the air or other gas.
대표청구항▼
1. A method for determining air flow rate through a conduit, independently of conduit cross-sectional area, comprising: a. providing a conduit for air flow therethrough, the flow rate of which is to be determined;b. measuring temperature of the air at a first position along the conduit;c. heating th
1. A method for determining air flow rate through a conduit, independently of conduit cross-sectional area, comprising: a. providing a conduit for air flow therethrough, the flow rate of which is to be determined;b. measuring temperature of the air at a first position along the conduit;c. heating the air in the conduit at a location downstream from the first position by application of a known power level to the air;d. measuring air temperature at a second position downstream of the heating position along the conduit;e. subtracting air temperature at the second position from air temperature at the first position to obtain a temperature difference;f. dividing the power applied to heat the air by the product of the temperature difference and the specific heat of air. 2. The method of claim 1 wherein step “f” is performed by a microprocessor, and further comprising: a. visually displaying the result of the division performed in step “f” of claim 1. 3. The method of claim 1 in which the first position is at the conduit inlet. 4. The method of claim 1 in which the first position is upstream of the conduit inlet. 5. The method of claim 1 in which the second position is at the conduit outlet. 6. The method of claim 1 in which the second position is downstream of the conduit outlet. 7. The method of claim 1 in which heating is performed using an electrical resistance heater. 8. The method of claim 6 in which the heater is cycled on and off while air flow rate is being determined. 9. A method for determining air flow rate comprising: a. measuring temperature of flowing air at a first position;b. heating the flowing air at a location downstream of the first position by application of known power to the air;c. measuring temperature of the flowing air at a second position downstream of the heating position;d. subtracting air temperature at the second position from air temperature at the first position to obtain a temperature difference;e. dividing the power applied to the flowing air by the product of the temperature difference and the specific heat of air. 10. A method for air drying granular resin and other granular and powdery materials with a known rate of application of heated air thereto, comprising: a. introducing the material to be dried into a closed hopper having an air inlet receiving heated air from an inlet conduit, with at least one heater positioned to heat air passing through the inlet conduit into the hopper, and having air temperature sensors positioned in the air stream upstream and downstream of the heater, and having an outlet for air to escape from the hopper after having contacted the material therein for heat transfer thereto;b. monitoring heated air flow rate into the hopper by: i. measuring temperature of the air at a first position along the inlet conduit;ii. heating the air in the inlet conduit at a location downstream from the first position by application of a known power to the heater to heat the air;iii. measuring air temperature at a second position along the inlet conduit that is downstream of the heater;iv. subtracting air temperature at the second position from air temperature at the first position to obtain a temperature difference;v. dividing the power applied to the heater to heat the air by the product of the temperature difference and the specific heat of air to provide air flow rate into the hopper. 11. A method for regulating a desiccant-type dryer for granular resin and other granular and powdery materials, comprising: a. introducing the material to be dried into a closed hopper having an air inlet receiving heated air from an inlet conduit, with at least one heater positioned to heat air passing through the inlet conduit into the hopper, and having air temperature sensors positioned in the air stream upstream and downstream of the heater, and having an outlet for air to escape from the hopper after having contacted the material therein for heat transfer thereto;b. determining heated air flow rate into the hopper by i. measuring temperature of the air at a first position along the inlet conduit;ii. heating the air in the inlet conduit at a location downstream from the first position by application of a known power to the heater to heat the air;iii. measuring air temperature at a second position along the inlet conduit that is downstream of the heater;iv. subtracting air temperature at the second position from air temperature at the first position to obtain a temperature difference;v. dividing the power applied to the heater to heat the air by the product of the temperature difference and the specific heat of air to provide air flow rate into the hopper; andc. regulating heated air flow rate into the hopper responsively to a desired maximum temperature for material in the hopper to be dried and the air temperature measured at the second position. 12. Apparatus for determining air flow rate in a conduit independently of the cross-sectional area of the conduit, comprising: a. a first temperature sensor for measuring temperature of the air at a first position along the conduit;b. an electrical resistance heater for heating air in the conduit downstream of the first temperature sensor with a known amount of power;c. a second temperature sensor for measuring temperature of the air downstream of the heater;d. a microprocessor for dividing the power applied to heat the air by the product of the temperature difference and the specific heat of air. 13. Apparatus of claim 12 wherein the first temperature sensor is at the inlet to the conduit. 14. Apparatus of claim 12 wherein the first temperature sensor is upstream of the conduit. 15. Apparatus of claim 12 wherein the second temperature sensor is at the outlet from the conduit. 16. Apparatus of claim 12 wherein the second temperature sensor is downstream of the conduit. 17. A desiccant-based dryer for granular and powdery materials, comprising: a. a hopper containing the granular or powdery material to be dried;b. a conduit for introducing hot air into the hopper for passage through and around the material to be dried, thereby heating the material and evaporating moisture therefrom to affect drying thereof;c. an air flow rate measuring device connected to the conduit for measuring the rate of heated air flow into the hopper, comprising: i. a first temperature sensor for measuring temperature of the air at a first position along the conduit;ii. an electrical resistance heater for heating air in the conduit downstream of the first temperature sensor with a known amount of power;iii. a second temperature sensor for measuring temperature of the air downstream of the heater and prior to the connection of the conduit to the hopper; andd. a microprocessor for dividing the power applied to heat the air by the product of the temperature difference and the specific heat of air and providing a signal indicative of the rate of heated air flow through the hopper. 18. Apparatus of claim 17 wherein the signal is a visually discernable number in selected units of volume per unit of time. 19. Apparatus for drying granular and powdery materials, comprising: a. a hopper containing the granular or powdery material to be dried;b. an air filterc. an air dryer; andd. conduits serially connecting the hopper, the filter and the dryer, for air flow thereamong; ande. at least one air flow rate measuring device, each connected to one of the conduits, for measuring the rate of air flow through the conduit to which the device is connected, each device comprising: i. a first temperature sensor for measuring temperature of the air at a first position along the conduit;ii. a heater for heating air in the conduit downstream of the first temperature sensor with a known amount of power;iii. a second temperature sensor for measuring temperature of the air downstream of the heater; andf. a microprocessor receiving inputs from all of the temperature sensors and the power furnished to all of the heaters, for dividing the power applied to each heater to heat the air by the product of the temperature difference as measured by the temperature sensors associated with the heater and the specific heat of air and providing visually discernable numerical signals indicative of the rate of air flow through conduit sections associated with given heaters. 20. A method for determining gas flow rate comprising: a. measuring temperature of flowing gas at a first position;b. heating the flowing gas at a location downstream of the first position by application of known power to the gas;c. measuring temperature of the flowing gas at a second position downstream of the heating position;d. subtracting temperature at the second position from temperature at the first position to obtain a temperature difference;e. dividing the power applied to the flowing gas by the product of the temperature difference and the specific heat of the gas. 21. Apparatus for determining gas flow rate in a conduit independently of the cross-sectional area of the conduit, comprising: a. a first temperature sensor for measuring temperature of the gas at a first position along the conduit;b. a heater for heating gas in the conduit downstream of the first temperature sensor with a known amount of power;c. a second temperature sensor for measuring temperature of the gas downstream of the heater;d. a processor for dividing the power applied to heat the gas by the product of the temperature difference and the specific heat of the gas. 22. A vacuum dryer for drying granular and powdery materials, comprising: a. a canister for receiving containing the granular or powdery material to be heated to a desired temperature prior to having vacuum drawn thereover;b. a conduit for supplying heated air to the canister for raising the temperature of granular or powdery material in the canister to the desired temperature for air flow thereamong; andc. at least one air flow rate measuring device, each connected to the conduit, for measuring the rate of air flow through the conduit to which the device is connected, comprising: i. a first temperature sensor for measuring temperature of the air at a first position along the conduit;ii. a heater for heating air in the conduit downstream of the first temperature sensor with a known amount of power;iii. a second temperature sensor for measuring temperature of the air downstream of the heater prior to entry into the canister; andd. a microprocessor receiving inputs from the temperature sensors and the power furnished to the heater, for dividing the power applied to the heater to heat the air by the product of the temperature difference as measured by the temperature sensors associated with the heater and the specific heat of air. 23. The vacuum dryer of claim 22 further comprising a video screen for display of visually desirable numbers indicated of the rate of air flow through the conduit section with the numbers being furnished by the microprocessor. 24. A method for regulating a vacuum dryer for granular resin and other granular and powdery materials, comprising: a. introducing the material to be dried into a canister portion of the dryer having an air inlet receiving heated air from an inlet conduit, with at least one heater positioned to heat air passing through the inlet conduit into the canister, and having air temperature sensors positioned in the air stream upstream and downstream of the heater, with the downstream sensor being upstream of the air inlet to the canister;b. determining heated air flow rate into the canister by: i. measuring temperature of the air at a first position along the inlet conduit;ii. heating the air in the inlet conduit at a location downstream from the first position by application of a known power to the heater to heat the air;iii. measuring air temperature at a second position along the inlet conduit that is downstream of the heater but upstream of the air inlet to the canister;iv. subtracting air temperature at the second position from air temperature at the first position to obtain a temperature difference;v. dividing the power applied to the heater to heat the air by the product of the temperature difference and the specific heat of air to provide air flow rate into the canister; andc. regulating heated air flow rate into the canister responsively to a desired maximum temperature for material in the canister to be dried and the air temperature measured at the second position; and drawing a vacuum over the material having reached the desired maximum temperature, for sufficient time and at a sufficient level of vacuum to dry the material to a desired level of dryness.
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