초록 ▼

An energy recovery ventilation system is described which allows for continuous fan speed control through pulse width modulation of direct current fans. The energy recovery ventilation described is capable of fine motor speed control without the disadvantages of high noise, low efficiency and a fixed

An energy recovery ventilation system is described which allows for continuous fan speed control through pulse width modulation of direct current fans. The energy recovery ventilation described is capable of fine motor speed control without the disadvantages of high noise, low efficiency and a fixed number of speeds present in commonly-used speed-varying techniques used with alternating current (AC) fans. This may be accomplished through the use of direct current (DC) fans and pulse width modulation. A controller is used to optimize the ventilation and energy efficiency of the system through the use of several temperature sensors. The energy recovery ventilation also provides a control process for self-optimization of the energy recovery ventilation, in case the supply and exhaust airflows are unequal. An unbalance may be detected by calculating the thermal efficiencies of the exhaust and supply airflows.

대표청구항 ▼

1. A ventilation system comprising: a ventilator;a first direct current (DC) fan drawing air from an exterior of a building for circulation into an interior of the building, the first DC fan producing a supply airflow through the ventilator;a second DC fan drawing a return air from the interior of t

1. A ventilation system comprising: a ventilator;a first direct current (DC) fan drawing air from an exterior of a building for circulation into an interior of the building, the first DC fan producing a supply airflow through the ventilator;a second DC fan drawing a return air from the interior of the building for exhausting to the exterior of the building, the second DC fan producing an exhaust airflow through the ventilator enclosure, said supply airflow and said exhaust airflow undergoing an energy exchange therebetween in the ventilator; anda controller controlling a first speed of the first DC fan and a second speed of the second DC fan, the controller including means for calculating a thermal efficiency for each of the supply airflow and the exhaust airflow for balancing the supply airflow and the exhaust airflow, thereby separately adjusting the supply airflow and the exhaust airflow in response to a first input received from a first temperature sensor in the supply airflow positioned upstream of the energy exchange in the ventilator, a second input received from a second temperature sensor in the supply airflow positioned downstream of the energy exchange in the ventilator and a third temperature sensor in an exhaust airflow positioned downstream of the energy exchange in the ventilator, said first, second and third temperature sensors each independently outputting temperature signals to the controller to optimize the supply airflow and the exhaust airflows by balancing the supply airflow and the exhaust airflow;wherein the supply airflow and the exhaust airflow are balanced if the thermal efficiency of the supply airflow and the thermal efficiency of the exhaust airflow are equal to pre-determined efficiencies. 2. The ventilation system according to claim 1, further comprising a first humidity sensor in the supply airflow positioned upstream of the energy exchange in the ventilator and a second humidity sensor in the supply airflow positioned downstream of the energy exchange in the ventilator, said first and second humidity sensors each independently outputting humidity signals to the controller for use in optimizing the supply airflow and the exhaust airflow. 3. The ventilation system of claim 1, wherein the ventilator comprises at least one energy exchange core. 4. The ventilation system of claim 1, wherein the supply airflow and the exhaust airflow are separate in the ventilator and wherein heat and/or moisture exchange occurs between the supply and exhaust airflows. 5. The ventilation system according to claim 1, further comprising a recirculation fan for drawing a portion of the return air from the interior the building for recirculation in the interior of the building. 6. The ventilation system according to claim 1, further comprising a fourth temperature sensor positioned in the exhaust airflow at a position proximate to the exhaust inlet of the ventilator, the fourth temperature sensor outputting a signal to the controller for use in optimizing the supply airflow and the exhaust airflow. 7. The ventilation system according to claim 1, further comprising a continuous fan speed control. 8. The ventilation system according to claim 1, wherein means for fine control of the fan speed of each of the first and the second DC fan comprises pulse width modulation (PWM). 9. A ventilator comprising: a ventilator enclosure comprising a supply inlet receiving a supply airflow from an exterior of a building, a supply outlet discharging the supply airflow to the interior of the building, an exhaust inlet receiving an exhaust airflow from an interior of the building, and an exhaust outlet discharging the exhaust airflow to the exterior of the building,a first direct current (DC) fan drawing supply air through the supply inlet and discharging supply air through the supply outlet, said first DC fan producing a supply airflow through the ventilator enclosure;a second DC fan drawing return air through the exhaust inlet and discharging the exhaust air from the exterior of the building thereby creating the exhaust airflow through the ventilator enclosure;a first temperature sensor, proximate to the supply inlet, determining a first temperature of supply air entering the ventilator enclosure;a second temperature sensor, proximate to the supply outlet, measuring a second temperature of supply air exiting the ventilator enclosure;a third temperature sensor, proximate to the exhaust outlet, measuring a third temperature of return air exiting the ventilator enclosure; anda controller controlling the fans and regulating the supply airflow and the exhaust airflow, said controller comprising receiver receiving a first input from the first temperature sensor, a second input from the second temperature sensor, and a third input from a third temperature sensor, means for calculating a thermal efficiency for each of the supply airflow and the exhaust airflow for balancing the supply airflow and the exhaust airflow and drivers for independently adjusting a first fan speed for the first DC fan and a second fan speed for the second DC fan in response to each of said first, second and third inputs, thereby optimizing the supply airflow and the exhaust airflow by balancing the supply airflow and the exhaust airflow,wherein the supply airflow and the exhaust airflow are balanced if the thermal efficiency of the supply airflow and the thermal efficiency of the exhaust airflow are equal to pre-determined efficiencies.