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A beverage syrup pump system is disclosed including a pump housing having an internal pumping chamber, a pump motor, and a pumping mechanism driven by the motor within the pumping chamber. The pumping mechanism receives a syrup fluid at a first pressure and discharges the fluid at a second pressure

A beverage syrup pump system is disclosed including a pump housing having an internal pumping chamber, a pump motor, and a pumping mechanism driven by the motor within the pumping chamber. The pumping mechanism receives a syrup fluid at a first pressure and discharges the fluid at a second pressure which is greater than the first pressure. A pressure transducer adjacent a sensor port and in contact with a quantity of the fluid at the second pressure generates an electrical signal based upon the second pressure. A programmable micro controller receives the electrical signal from the pressure transducer and is capable of starting and stopping the pump motor. The micro controller will immediately stop the pump motor if the second pressure exceeds a predetermined maximum pressure level. The micro controller will also stop the pump motor if the second pressure falls and remains below a predetermined minimum pressure level for a predetermined first time interval.

대표청구항 ▼

1. A pump and controller system comprising: a pump housing having an internal pumping chamber, an inlet port, an outlet port, and a sensor port, each of the ports being in flow communication with the pumping chamber;a pump motor;a pumping mechanism driven by the pump motor and at least partially dis

1. A pump and controller system comprising: a pump housing having an internal pumping chamber, an inlet port, an outlet port, and a sensor port, each of the ports being in flow communication with the pumping chamber;a pump motor;a pumping mechanism driven by the pump motor and at least partially disposed within the pumping chamber, the pumping mechanism being capable of receiving a fluid through the inlet port into the pumping chamber at a first pressure and discharging the fluid from the pumping chamber through the outlet port at a second pressure which is greater than the first pressure;a pressure transducer disposed adjacent the sensor port, the transducer being in contact with a quantity of the fluid at the second pressure and generating an electrical signal based upon the second pressure;a programmable micro controller, which receives the electrical signal from the pressure transducer, and is electrically connected to the pump motor and capable of starting and stopping the pump motor,wherein the micro controller is programmed to immediately stop the pump motor when the second pressure exceeds a predetermined maximum pressure level, andwherein the micro controller is programmed to stop the pump motor when the second pressure falls below a predetermined minimum pressure level and remains below the minimum pressure level for a predetermined first time interval. 2. The pump and controller system of claim 1, wherein the pumping mechanism comprises: a drive gear, having a plurality of drive gear teeth, disposed within the pumping chamber and rotatably driven by the pump motor; andan idler gear, having a plurality of idler gear teeth intermeshed with the drive gear teeth, disposed within the pumping chamber and attached to an idler shaft disposed within the pumping chamber,and wherein the sensor port is located downstream of the drive gear and the idler gear. 3. The pump and controller system of claim 1, wherein the pressure transducer comprises a ceramic piezo disc. 4. The pump and controller system of claim 1, wherein the micro controller is programmed restart the pump motor when, after exceeding the predetermined maximum pressure level, the second pressure falls below the predetermined maximum pressure level. 5. The pump and controller system of claim 1, further comprising a temperature transducer disposed adjacent the sensor port, the temperature transducer being in contact with a quantity of the fluid and generating an electrical signal based upon a temperature of the fluid which is received by the programmable micro controller. 6. The pump and controller system of claim 1, further comprising a data port electrically connected to the micro controller for transmitting data from the micro controller to an external device. 7. The pump and controller system of claim 1, further comprising a wireless transmitter and receiver electrically connected to the micro controller for transmitting data from the micro controller to an external device. 8. A post-mix beverage dispenser comprising: a beverage mixing and dispensing nozzle;a supply of carbonated water in flow communication with the beverage mixing and dispensing nozzle;a supply of beverage syrup; anda beverage syrup pump system having a pump housing having an internal pumping chamber, an inlet port in flow communication with the supply of beverage syrup and with the pumping chamber, an outlet port in flow communication with the pumping chamber and with the beverage mixing and dispensing nozzle, and a sensor port in flow communication with the pumping chamber;a pumping mechanism driven by a pump motor and at least partially disposed within the pumping chamber, the pumping mechanism being capable of receiving a syrup fluid through the inlet port into the pumping chamber at a first pressure and discharging the fluid from the pumping chamber through the outlet port at a second pressure which is greater than the first pressure;a pressure transducer disposed adjacent the sensor port, the transducer being in contact with a quantity of the fluid at the second pressure and generating an electrical signal based upon the second pressure;a programmable micro controller, which receives the electrical signal from the pressure transducer, and is electrically connected to the pump motor and capable of starting and stopping the pump motor,wherein the micro controller is programmed to immediately stop the pump motor when the second pressure exceeds a predetermined maximum pressure level, andwherein the micro controller is programmed to stop the pump motor when the second pressure falls below a predetermined minimum pressure level and remains below the minimum pressure level for a predetermined first time interval. 9. The post-mix beverage dispenser of claim 8, wherein the pumping mechanism comprises: a drive gear, having a plurality of drive gear teeth, disposed within the pumping chamber and rotatably driven by the pump motor; andan idler gear, having a plurality of idler gear teeth intermeshed with the drive gear teeth, disposed within the pumping chamber and attached to an idler shaft disposed within the pumping chamber,and wherein the sensor port is located downstream of the drive gear and the idler gear. 10. The post-mix beverage dispenser of claim 8, wherein the pressure transducer comprises a ceramic piezo disc. 11. The post-mix beverage dispenser of claim 8, wherein the micro controller is programmed restart the pump motor when, after exceeding the predetermined maximum pressure level, the second pressure falls below the predetermined maximum pressure level. 12. The post-mix beverage dispenser of claim 8, further comprising a temperature transducer disposed adjacent the sensor port, the temperature transducer being in contact with a quantity of the fluid and generating an electrical signal based upon a temperature of the fluid which is received by the programmable micro controller. 13. The post-mix beverage dispenser of claim 8, further comprising a data port electrically connected to the micro controller for transmitting data from the micro controller to an external device. 14. The post-mix beverage dispenser of claim 8, further comprising a wireless transmitter and receiver electrically connected to the micro controller for transmitting data from the micro controller to an external device.