US20090023380A1 - Apparatus and method for air circulation - Google Patents
Apparatus and method for air circulation Download PDFInfo
- Publication number
- US20090023380A1 US20090023380A1 US11/778,114 US77811407A US2009023380A1 US 20090023380 A1 US20090023380 A1 US 20090023380A1 US 77811407 A US77811407 A US 77811407A US 2009023380 A1 US2009023380 A1 US 2009023380A1
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- United States
- Prior art keywords
- air
- airflow
- circulation
- housing
- circulation valve
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Abandoned
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F7/00—Ventilation
- F24F7/04—Ventilation with ducting systems, e.g. by double walls; with natural circulation
- F24F7/06—Ventilation with ducting systems, e.g. by double walls; with natural circulation with forced air circulation, e.g. by fan positioning of a ventilator in or against a conduit
- F24F7/08—Ventilation with ducting systems, e.g. by double walls; with natural circulation with forced air circulation, e.g. by fan positioning of a ventilator in or against a conduit with separate ducts for supplied and exhausted air with provisions for reversal of the input and output systems
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05K—PRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
- H05K7/00—Constructional details common to different types of electric apparatus
- H05K7/20—Modifications to facilitate cooling, ventilating, or heating
- H05K7/20536—Modifications to facilitate cooling, ventilating, or heating for racks or cabinets of standardised dimensions, e.g. electronic racks for aircraft or telecommunication equipment
- H05K7/20554—Forced ventilation of a gaseous coolant
- H05K7/20572—Forced ventilation of a gaseous coolant within cabinets for removing heat from sub-racks, e.g. plenum
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B1/00—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
- H04B1/02—Transmitters
- H04B1/03—Constructional details, e.g. casings, housings
- H04B1/036—Cooling arrangements
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05K—PRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
- H05K7/00—Constructional details common to different types of electric apparatus
- H05K7/20—Modifications to facilitate cooling, ventilating, or heating
- H05K7/20536—Modifications to facilitate cooling, ventilating, or heating for racks or cabinets of standardised dimensions, e.g. electronic racks for aircraft or telecommunication equipment
- H05K7/207—Thermal management, e.g. cabinet temperature control
Definitions
- Enclosures are used to retain different types of electronic components and protect these components from extreme environmental conditions or hazards.
- base station components are typically housed in enclosures to protect the components from extreme heat or cold.
- the components may include circuit boards that perform the various functions of the base stations.
- Other components may also be used within the enclosures.
- heaters may be used to heat the electronic components when the temperature of the enclosure drops below a threshold.
- the enclosures also may include fans to cool the electronic components as the components within the enclosure generate heat.
- microprocessors or other types of programmable controllers to operate the heating and cooling components of the system. Specifically, microprocessors were used to activate and deactivate the fans and heaters in the system based upon factors such as the measured temperature within the enclosure. However, because of the costs associated with programming the microprocessors, these microprocessor-based systems were expensive to design and build. Additionally, when operational, these systems were often difficult to maintain. For example, the microprocessors used in these previous systems were themselves often vulnerable to extreme environmental conditions.
- previous systems used air circulation modules (e.g., using fans) to circulate air within enclosures.
- air circulation modules e.g., using fans
- various types of fan arrangements that were controlled by microprocessors were sometimes provided to circulate the air within enclosures.
- microprocessors were sometimes provided to circulate the air within enclosures.
- these arrangements were often expensive and difficult to implement and suffered from the same shortcomings of the microprocessor-based system described above.
- an additional, separate, and non-integrated component was sometimes provided in order to re-circulate the air within the module. This separate arrangement was often difficult to install and could interfere with the functioning of other components within the enclosure.
- FIG. 1 comprises an electrical diagram of a system for controlling the environmental conditions within an enclosure in accordance with various embodiments of the invention
- FIG. 2 comprises a diagram of a system for controlling the environmental conditions within an enclosure according to various embodiments of the invention
- FIG. 3 comprises a diagram of a damper arrangement according to various embodiments of the invention.
- FIG. 4 comprises a side view of the damper arrangement of FIG. 3 according to various embodiments of the invention.
- FIG. 5 is flowchart of an approach for regulating environmental conditions within an enclosure according to various embodiments of the invention.
- FIG. 6 comprises a state diagram showing various states of a system for regulating environmental conditions of an enclosure according to various embodiments of the invention
- FIG. 7 is an exploded perspective view of an air circulation module according to various embodiments of the present invention.
- FIG. 8 is a perspective view of a re-circulation valve and spring according to various embodiments of the present invention.
- FIG. 9 is a cutaway perspective view showing the re-circulation valve of the air circulation module open according to various embodiments of the present invention.
- FIG. 10 is a cutaway perspective view showing the re-circulation valve of the air circulation module closed according to various embodiments of the present invention.
- An apparatus and method are provided that circulate and re-circulate air efficiently within an enclosure. More specifically, the approaches provided herein integrate a recirculation valve with the air circulation module in order to re-circulate air. These approaches achieve the effective circulation and re-circulation of air within enclosures in a simple and cost effective manner, and require a minimum of additional parts.
- an air circulation module includes a housing and at least one fan that is enclosed within the housing.
- the fan receives an airflow moving through the housing.
- An airflow re-circulation valve is disposed within the housing so as to not substantially interfere with the airflow moving through the housing.
- the airflow re-circulation valve is selectively opened so as to divert a first portion of the airflow into and through the airflow re-circulation valve and out of the housing via an exhaust port. A second portion of the airflow is directly exhausted from the housing after being received by the fan.
- the airflow re-circulation valve comprises a bi-metallic spring.
- the bi-metallic spring expands and contracts a predetermined amount and the predetermined amount is based at least in part upon a temperature change.
- the air re-circulation valve may further include a rotary member and the bi-metallic spring is arranged to rotate the rotary member.
- the air circulation module may also include a feeder arrangement and the feeder arrangement communicates with the airflow re-circulation valve.
- the feeder arrangement is adapted to direct the first portion of the airflow into the airflow re-circulation valve.
- the feeder arrangement includes a re-circulation plate.
- an airflow is drawn into the air circulation module.
- the airflow is moved along a direct path about at least one fan enclosed within the air circulation module.
- a re-circulation valve positioned within the air circulation module is automatically and selectively opened so as to not substantially interfere with the direct path of the air flow in order to exhaust a first portion of the air flow from the air circulation module.
- the amount of opening of the re-circulation valve can be determined at least in part based upon a temperature. The amount of opening may be determined by other factors as well.
- the temperature within a cellular base station enclosure is regulated.
- any other type of environmental condition can be regulated.
- the enclosures described herein are described as including base station components for a cellular communication system, it will be understood that the enclosures may house any type of electrical and/or mechanical components.
- the temperatures or temperature ranges described herein are approximate and can also be varied according to the needs of the user or the system. Additionally, the temperatures and temperature ranges recited herein are examples only and can be varied according to the needs of the user or the system.
- a backplane 102 includes a first thermostat 104 , a second thermostat 106 , and a third thermostat 108 .
- the first thermostat 104 and the second thermostat 106 are over-temperature devices that are open at temperatures of greater than 85 degrees Celsius and are closed otherwise.
- the third thermostat 108 is a high-temperature device and is open at temperatures of 70 degrees Celsius or greater and is closed otherwise.
- the backplane 102 also includes a first switch 110 , a second switch 112 , a fourth thermostat 114 , and a fifth thermostat 116 .
- the fourth thermostat 114 and the fifth thermostat 116 are closed at temperatures of above 0 degrees Celsius and are open otherwise.
- the backplane 102 also includes a sixth thermostat 120 and seventh thermostat 121 that are open at temperatures above 20 degrees Celsius and are closed otherwise.
- the backplane 102 additionally includes an eighth thermostat 122 that opens at temperatures of less than 0 degrees Celsius and is closed otherwise.
- the backplane 102 is connected to a heater module 124 .
- the heater module 124 includes a first heater 126 and a second heater 128 .
- the first heater 126 is controlled by a third relay 130 and the second heater 128 is controlled by a fourth relay 132 .
- the purpose of the third relay 130 and the fourth relay 132 are to act as safety disconnect devices if any of the heaters enter a run away condition and/or the thermostat 108 malfunctions or has a significant time lag.
- the third relay 130 and fourth relay 132 are connected to a ninth thermostat 150 and tenth thermostat 152 respectively (controlling the first heater 126 and the second heater 128 ).
- the ninth thermostat 150 and tenth thermostat 152 activate at approximately 150 degrees Celsius.
- a fan module 134 is coupled to the backplane 102 and to system components 136 .
- the fan module 134 may include one or more air circulation elements (e.g., fans).
- the system components 136 include one or more electrical components that perform or implement the functions of an electronic system. For example, these components may implement base station functions for a cellular communication system.
- the system components 136 include a card power inhibit circuit 138 and an alarm board 140 .
- Power supplies 142 supply power to the various components of the system.
- a Circuit Breaker Card (CBC) 141 includes fuses and/or breakers that are coupled to the backplane 102 , the fan module 134 , and the heater module 124 . Power is provided to but not necessarily utilized by the system when a user activates the circuit breakers on the CBC 141 and the power supplies 142 .
- CBC Circuit Breaker Card
- the system of FIG. 1 may also utilize a re-circulation valve (not shown in FIG. 1 ) to selectively re-circulate air within the enclosure. Additionally, the system of FIG. 1 may use a moveable damper (not shown in FIG. 1 ) to selectively exhaust air from the enclosure.
- a cold start may occur (at temperatures of below 0 degrees Celsius to 0 degrees Celsius) when a user throws the main breaker, turns on the power supplies, and/or engages the sub-system level circuit breakers on the CBC 141 .
- the fourth thermostat 114 and fifth thermostat 116 are open, which de-activates the first switch 110 and the second switch 112 .
- power is provided to and utilized by the second heater 128 .
- the sixth thermostat 120 and seventh thermostat 121 are closed, in one example, based upon temperature alone (e.g., when the temperature within the enclosure is less than 20 degrees Celsius).
- the sixth thermostat 120 and seventh thermostat 121 When the sixth thermostat 120 and seventh thermostat 121 are closed, power is provided to and utilized by the first heater 126 .
- one or more of the fans in the fan module 134 starts up and runs, in one example, at 750 rpm. Air is moved through a re-circulation valve (e.g., the re-circulation valve 207 shown in FIG. 2 ), through a re-circulation path (e.g., the re-circulation path 218 shown in FIG. 2 ), back across the heaters 126 and 128 , and through the system components 136 . As the air is further re-circulated and passed over the first heater 126 , second heater 128 , and system components 136 , its temperature rises.
- a re-circulation valve e.g., the re-circulation valve 207 shown in FIG. 2
- a re-circulation path e.g., the re-circulation path 218 shown in FIG. 2
- the fourth thermostat 114 and the fifth thermostat 116 close.
- the first switch 110 and second switch 112 are energized.
- the system inhibit line 144 is de-activated and the system utilizes the power provided to it by the CBC 141 .
- the second heater 128 is de-activated.
- the second heater 128 is not re-energized.
- the system inhibit line is de-activated, and the system is in a run state and will not re-start the second heater 128 .
- all heating functions are dealt with by the first heater 126 and the system components 136 within the enclosure. The second heater 128 will only re-start if power is lost to the system and it experiences a new, cold start event thereby re-setting the first switch 110 and second switch 112 to a de-energized state.
- the third thermostat 108 opens. The occurrence of this condition causes an alarm to be sent to the alarm board 140 on alarm lines 146 .
- An alarm indictor 148 e.g., light emitting diode (LED)
- LED light emitting diode
- the first thermostat 104 , second thermostat 106 are opened. The power input to the backplane 102 from the power supplies 142 is deactivated. The second heater 128 , the first heater 126 , the system components 136 , and the fan module 134 then turn off. The occurrence of these conditions causes an alarm to be sent to the alarm board 140 on alarm lines 146
- the eighth thermostat 122 opens when the temperature within the enclosure falls below a threshold (e.g., the temperature within the enclosure is less than 0 degrees). This occurrence sends an alarm signal 146 to the alarm board.
- An alarm indictor 148 e.g., light emitting diode (LED)
- LED light emitting diode
- the system may operate in a transitional operation or cold maintenance operation (e.g., at temperature ranges of 0 to 20 degrees Celsius).
- a transitional operation or cold maintenance operation e.g., at temperature ranges of 0 to 20 degrees Celsius.
- the re-circulation valve begins to close, the damper begins to open, a small quantity of air is drawn in through the filter, and the rate of internal temperature rise is slowed.
- the first heater 126 turns off and system heating is handled by the system components 136 .
- the first heater 126 remains energized. If the temperature of the air rises above 20 degrees Celsius, the first heater turns off, if over time the temperature falls again to below 20 Celsius, the first heater 126 turns back on to provide energy to the re-circulated and incoming air streams. The first heater 126 will continue to cycle with hysterisis. During this transitional state, re-circulation valve, exhaust damper, and fan module 134 are in various states of operation all combining to maintain the optimal temperature within the enclosure while minimizing hysterisis.
- the system starts at ambient temperatures between 0 degrees Celsius and 20 degrees Celsius.
- the system may experience a power up condition when a user throws the main breaker, turns on the power supplies, and/or engages the sub-system level circuit breakers on the CBC (Circuit Breaker Card).
- Power is provided to and utilized by the system when a user activates the circuit breakers and power supplies.
- the fourth thermostat 114 and fifth thermostat 116 are closed, which activates the first switch 110 and the second switch 112 .
- the first switch 110 and second switch 112 are activated, power is not provided to the second heater 128 .
- the sixth thermostat 120 and seventh thermostat 121 are closed, in one example, based on temperature alone (e.g., temperatures of less than 20 degrees Celsius).
- the sixth thermostat 120 and seventh thermostat 121 When the sixth thermostat 120 and seventh thermostat 121 are closed, power is provided to and utilized by the first heater 126 .
- one or more of the circulation elements of the fan module 134 start up and runs, for example, at 750 rpm. The speed is variable and depends upon the air temperature, for instance, speeding up to an rpm of 1090 rpm at an air temperature of 20 degrees Celsius.
- Air is moved through a re-circulation valve (e.g., valve 207 , discussed in connection with FIG. 2 below), through a re-circulation path (e.g., re-circulation path 218 , discussed in connection with FIG.
- the re-circulation valve position is also variable and reacts according to air temperature so as to reduce and finally close the flow stream through the re-circulation path at 50 degrees Celsius. At 10-12 degrees Celsius, the exhaust damper will start to break seal and a small inflow of cold ambient air will be pulled in through the filter. As the fan speed rises this effect increases.
- both the first heater 126 and second heater 128 are off. Start up would proceed as described above, but without the first heater 126 or second heater 128 being activated.
- the re-circulation valve is still open to some extent and would allow a decreasingly small amount of flow through the re-circulation path eventually diminishing to zero flow.
- the fan speed increases in response to higher temperatures caused by increased system load, environmental conditions, or other factors thereby causing the exhaust damper to rise thereby increasing the amount of exhaust flow out of the enclosure.
- the enclosure 200 includes a filter 202 that accepts an air flow 204 .
- the filter 202 removes particulate matter from the air (e.g., smoke, dust, dirt) and water in the liquid phase before the matter or liquid water enters the enclosure 200 .
- the filter 202 outputs a filtered air flow 206 , which is received by a heater 208 .
- the heater 208 selectively heats the filtered air flow 206 and creates a heated air flow 209 , which moves over, across, and around circuit boards 210 .
- the circuit boards 210 are the electronic functional components of a cellular base station communication system.
- the heater 208 may be activated to heat the filtered air flow 206 .
- the heater may be deactivated and the filtered air flow 206 may be drawn (unheated) over, across, and around the circuit boards 210 in order to cool these components.
- the heated air flow 209 (or the unheated filtered air flow) is drawn past power supplies 212 and through a fan 214 .
- the fan 214 is coupled to and/or includes a re-circulation valve 207 that selectively allows a return air flow 216 to pass into a conduit 218 and return to the heater 208 .
- the re-circulation valve 207 includes a bi-metallic spring or coil that expands and contracts to alternatively allow the air to flow through the conduit 216 (back to the heater 208 ) or prevent the air flow from entering the conduit 216 .
- the air flow is re-circulated back to the heater 208 at temperatures of between ⁇ 40 degrees Celsius and 50 degrees Celsius.
- the damper 220 is arranged and constructed to alternatively rise and fall to allow an exhaust air flow 222 to be exhausted from the enclosure 200 .
- the damper may be a plastic or other suitable material configured as a plate-like lid that rises or falls into position depending upon the air pressure inside the enclosure 200 .
- the air pressure inside the enclosure 200 may depend upon the temperature, the amount of air being re-circulated, and the amount of air being drawn into the enclosure 200 through the air filter 202 . Other factors may also determine or influence the pressure within the enclosure 200 .
- the air flow 222 may be exhausted from the enclosure 200 at temperatures of 12 degrees Celsius or greater. In another example, the air flow 222 may be exhausted from the enclosure at temperatures of 10-12 degrees Celsius or greater.
- the approaches described herein incorporate passive elements to maintain substantially constant environmental conditions (e.g., a substantially constant temperature) within enclosures.
- a substantially constant temperature may be achieved and maintained. If the temperature is above a threshold value (e.g., the damper 220 is open, the fan 214 is turning at a predetermined speed) air is drawn into the enclosure and the air is selectively heated.
- a threshold value e.g., the damper 220 is open, the fan 214 is turning at a predetermined speed
- air is drawn into the enclosure and the air is selectively heated.
- the heater 208 may be activated at a cold start and the heater 208 may be deactivated when a predetermined temperature (e.g., 20 degrees Celsius) is reached. Additionally, the heater 208 may be reactivated when the temperature within the enclosure falls below a predetermined threshold.
- FIG. 2 shows one possible component layout and the selection of components that can be used to achieve a predetermined environmental goal (e.g., the maintenance a predetermined temperature range within the enclosure).
- a predetermined environmental goal e.g., the maintenance a predetermined temperature range within the enclosure.
- the dimensions of the structure including the relative sizing of the components e.g., the diameter or shape of the damper 220 , or size of the conduit 218 ) may be adjusted according to the needs and requirements of the system or user.
- the types of components chosen may change and the operation of these components may also be varied according to the goals of the system.
- the temperature ranges indicated above may be varied by the use of additional heaters or fans.
- the placement of the electronic components 210 may be varied relative to the other components.
- some of the components e.g., the filter 202 ) may be removed.
- the damper structure includes a lid 302 .
- the lid includes grooves 304 , 306 , and 308 .
- the grooves 304 , 306 , and 308 communicate with rods 310 , 312 , and 314 .
- the lid 302 rises and falls in the directions indicated by the arrows 316 .
- the amount of pressure in the enclosure 300 affects the amount of lift of the lid 302 .
- a relatively high amount of pressure causes the lid 302 to rise to its greatest height (i.e., to its fully open position) and, consequently, release the greatest amount of air from the enclosure 300 .
- the lid 302 falls to its lowest point (i.e., to its closed position) and substantially no air flows out through the damper.
- the lid 302 may be raised by the pressure within the enclosure to a middle position and a medium amount of air exhausts from the enclosure.
- the amount of pressure inside the enclosure 300 may depend upon various factors. For example, the amount of pressure may depend directly or indirectly upon the temperature of the enclosure 300 , whether the fan is running, the number of heaters running, the amount of electronics in the enclosure 300 , and the amount of air re-circulation provided by the system (e.g., by a re-circulation valve).
- the weight, structure, and material used in the enclosure 300 and/or the lid 302 of the enclosure 300 may also affect the pressure as may environmental conditions outside of the enclosure 300 . Other factors or conditions may also influence the pressure within the enclosure 300 .
- external air is selectively drawn into the enclosure, which in one example is an electronic component housing.
- the external air that is drawn into the enclosure is selectively heated to form heated air.
- the extent of the heating is based at least in part upon the temperature within the electronic component housing. For example, no heating may be needed at some temperatures while a maximum amount of heating may be used at other temperatures.
- the heated air is selectively drawn across at least one electronic component positioned within the electronic component housing. Unheated air may also be drawn under selected circumstances.
- a first flow of the heated air (or unheated air, when the heater is deactivated) that has been drawn across the at least one electronic component is selectively re-circulated. The amount of the first flow is based at least in part upon the temperature within the housing.
- a second flow of the heated air (or unheated air, when the heater is deactivated) that has been drawn across the at least one electronic component is selectively exhausted from the electronic component housing.
- the amount of the second flow is based at least in part upon the temperature within the electronic component housing.
- the heating, exhausting, and re-circulating operate so as to cause the temperature within the electronic component housing to stay within a predetermined temperature range.
- FIG. 6 an example of transitioning between states in a system that regulates environmental conditions in an enclosure is described. Similar to the example of FIG. 2 , two heaters (a first heater and a second heater) and a fan are used. Additionally, a damper is arranged to exhaust air at the top of the enclosure. Further, a re-circulation valve and conduit are arranged to re-circulate air from the top of the enclosure through the heater.
- a cold start state 602 the fan is off, the first heater is on, the second heater is on, and the damper is closed. If the temperature remains below ⁇ 10 degrees Celsius, the system remains in the state 602 . If the temperature within the enclosure rises above ⁇ 10 degrees Celsius, then the system transitions to state 604 .
- the fan In the state 604 , the fan is on, the first heater is on, the second heater is on, re-circulation is being performed, and the damper is closed. If the temperature goes above 0 degrees Celsius, the system transitions to state 606 . If the temperature remains between ⁇ 10 and 0 degrees Celsius, the system remains in the state 604 . If the temperature falls below ⁇ 10 degrees Celsius the system transitions back to the previous state 602 .
- the fan In the state 606 , the fan is on, the first heater is on, the second heater is off, re-circulation is being performed, the damper is closed and the system components are active. If the temperature goes above 0 degrees Celsius but does not exceed 19 degrees Celsius the damper transitions from a closed to partially open state 607 and exhaust from the enclosure is being performed. If the temperature within the enclosure reaches 20 degrees Celsius, the system transitions to state 608 . If the temperature of the enclosure falls below 0 degrees Celsius, then the system transitions to state 616 .
- the fan In the state 608 , the fan is on, the first heater is off, the second heater is off, the system components are active, re-circulation is transitioning from partially open to closed, and the damper is transitioning from partially open to open. If the temperature in the enclosure goes above 50 degrees Celsius then the system transitions to state 610 . If the temperature falls below 20 degrees Celsius, then the system returns to state 607 .
- the fan In the state 610 , the fan is on, the first heater is off, the second heater is off, the system components are active, re-circulation has halted and the damper is open. If the temperature within the enclosure is between 50 degrees and an over-temperature threshold of 70 degrees Celsius, the system remains at state 610 and the fan moves from full speed to boost mode as the temperature within the enclosure approaches the over temperature threshold. If the temperature reaches an over-temperature threshold, the system transitions to state 612 . If the temperature falls below 50 degrees Celsius the system transitions back to state 608 .
- the fan In the state 612 , the fan is on, the first heater is off, the second heater is off, the system components are active, re-circulation is halted, and the damper is open.
- the temperature within the enclosure has reached a high temperature threshold and the fan is in “boost” mode. Additionally, an alarm is sent to the user so that the user may be informed of the high-temperature condition. If the temperature within the enclosure reaches an over-temperature threshold of 85 degrees Celsius the system transitions to state 614 . If the temperature within the enclosure falls below the high-temperature threshold, the system returns to state 610 .
- state 614 the fan is on and in boost mode, the first heater is off, the second heater is off, the system components are active, re-circulation is halted, and the damper is open.
- An over-temperature alarm is sent and the system begins a shut down sequence to de-energize all functions provided by the backplane so as to disable all heat generating components. If the temperature within the enclosure falls below the high temperature threshold the system returns to state 612 .
- state 616 the fan is on, the first heater is on, the second heater is off, re-circulation is being performed, the damper is closed, and the system components are active. Additionally, a low temperature alarm is sent to the user so that the user may be informed of the low temperature condition. If the temperature within the enclosure rises above 0 degrees Celsius, the system transitions to state 606 .
- an airflow re-circulation valve 701 includes a bi-metallic spring 706 that is coupled to a rotary member 704 .
- a re-circulation plate 702 covers the combination of the rotary member 704 and the bi-metallic spring 706 , and the combination is positioned within a first portion 710 of the fan assembly housing.
- the re-circulation plate 702 may also be part of a feeder arrangement that communicates with the re-circulation valve 701 and directs a flow of air into the airflow re-circulation valve 701 .
- a second portion 711 of the fan housing attaches to the first portion 710 to form the housing of the air circulation module 700 .
- a fan 712 is positioned within the air circulation module 700 in order to exhaust air from the air circulation module 700 and/or to re-circulate air.
- the air circulation module 700 can be used as part of the environmental control system for any of the enclosures that are described elsewhere in this specification.
- the rotary member 704 is formed with openings 705 .
- the bi-metallic spring 706 expands and contracts, it causes the rotary member 704 to rotate in the direction of the arrow denoted by reference numeral 707 .
- the rotary member 704 is responsively rotated to an open or partially open position allowing an airflow 709 to pass though the openings 705 and exhaust out of an exit portal 713 (formed in the air circulation module 701 ).
- FIG. 9 the rotary member 704 is responsively rotated to an open or partially open position allowing an airflow 709 to pass though the openings 705 and exhaust out of an exit portal 713 (formed in the air circulation module 701 ).
- the bi-metallic spring 706 may not contract (or not contract enough) thereby causing the rotary member 704 to remain in a closed position (i.e., so that air can not pass through the openings 705 of the rotary member 704 and out through the exit portal 713 of the air circulation module 700 ).
- the bi-metallic spring 702 may be formed from any suitable metal or material (or combination thereof) that expands and contracts according a pre-determined amount for a given temperature thereby allowing the rotary member 704 to rotate.
- the other elements of the system may be formed from plastic, metal, wood, or some other suitable material.
- other types of arrangements not using a bi-metallic valve and/or rotary member are possible.
- the air circulation module described herein is not limited to use in telecommunication system enclosures. Specifically, the air circulation module as described herein can be used in any type of enclosure to re-circulate air.
- an airflow 721 is drawn into the air circulation module 700 .
- the airflow 721 is moved along a direct path about the fan 712 enclosed within the air circulation module 700 .
- the re-circulation valve 701 is automatically and selectively opened so as to not substantially interfere with the direct path of the air flow in order to exhaust a first portion 709 of the air flow 721 from the air circulation module 700 .
- the amount of opening of the re-circulation valve 701 is determined based upon a temperature in the enclosure. However, the amount of opening may also be determined by other factors (e.g., pressure) as well.
- a second portion 719 of the airflow 721 may also be exhausted out of the air circulation module 700 .
- an integrated air circulation module and methods of using the module are provided that circulate and re-circulate air efficiently within an enclosure.
- the approaches described herein are cost-effective to implement and utilize a minimum of parts. In so doing, the dynamic circulation and re-circulation of air is achieved in a simple and cost effective manner.
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Abstract
An air circulation module (700) includes a housing and at least one fan (712) that is enclosed within the housing. The at least one fan (712) receives an airflow moving through the housing. An airflow re-circulation valve (701) that is disposed within the housing so as to not substantially interfere with the airflow moving through the housing. The airflow re-circulation valve (701) is selectively opened so as to divert a first portion of the airflow into and through the airflow re-circulation valve (701) and out of the housing via an exhaust port (713).
Description
- This application is related to a co-pending application entitled “SYSTEM AND METHOD FOR ENVIRONMENTAL CONTROL OF AN ENCLOSURE,” filed on even date herewith, assigned to the assignee of the present application, and hereby incorporated by reference.
- The field of the invention relates generally to environmental enclosures and more particularly to managing the environmental conditions within enclosures
- Enclosures are used to retain different types of electronic components and protect these components from extreme environmental conditions or hazards. For example, in cellular communication systems, base station components are typically housed in enclosures to protect the components from extreme heat or cold. In this case, the components may include circuit boards that perform the various functions of the base stations. Other components may also be used within the enclosures. For example, heaters may be used to heat the electronic components when the temperature of the enclosure drops below a threshold. Additionally, the enclosures also may include fans to cool the electronic components as the components within the enclosure generate heat.
- Maintaining satisfactory operating conditions within enclosures has been difficult to achieve in previous systems. For instance, it is frequently difficult to maintain the proper temperature within enclosures using conventional heating and cooling components and still efficiently operate the system. In one example of these problems, if a heater within the enclosure is activated for long periods of time, the components within the enclosure may overheat. In another example, operating the fans more often than needed may waste substantial amounts of energy and lead to increased operating costs for the system.
- Prior systems have sometimes used microprocessors or other types of programmable controllers to operate the heating and cooling components of the system. Specifically, microprocessors were used to activate and deactivate the fans and heaters in the system based upon factors such as the measured temperature within the enclosure. However, because of the costs associated with programming the microprocessors, these microprocessor-based systems were expensive to design and build. Additionally, when operational, these systems were often difficult to maintain. For example, the microprocessors used in these previous systems were themselves often vulnerable to extreme environmental conditions.
- Other previous systems omitted the use of microprocessors for controlling the heating and cooling components of the system. However, these systems typically could not maintain a constant or nearly constant temperature within the enclosure under at least some operating conditions. Consequently, these previous systems proved inadequate in preventing temperature swings within the enclosure and/or preventing the occurrence of over-temperature or under-temperature conditions within the enclosure.
- In addition, previous systems used air circulation modules (e.g., using fans) to circulate air within enclosures. For example, various types of fan arrangements that were controlled by microprocessors were sometimes provided to circulate the air within enclosures. Unfortunately, these arrangements were often expensive and difficult to implement and suffered from the same shortcomings of the microprocessor-based system described above. Additionally, an additional, separate, and non-integrated component was sometimes provided in order to re-circulate the air within the module. This separate arrangement was often difficult to install and could interfere with the functioning of other components within the enclosure.
- The above needs are at least partially met through provision of a method and apparatus for air circulation described in the following detailed description, particularly when studied in conjunction with the drawings, wherein:
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FIG. 1 comprises an electrical diagram of a system for controlling the environmental conditions within an enclosure in accordance with various embodiments of the invention; -
FIG. 2 comprises a diagram of a system for controlling the environmental conditions within an enclosure according to various embodiments of the invention; -
FIG. 3 comprises a diagram of a damper arrangement according to various embodiments of the invention; -
FIG. 4 comprises a side view of the damper arrangement ofFIG. 3 according to various embodiments of the invention; -
FIG. 5 is flowchart of an approach for regulating environmental conditions within an enclosure according to various embodiments of the invention; -
FIG. 6 comprises a state diagram showing various states of a system for regulating environmental conditions of an enclosure according to various embodiments of the invention; -
FIG. 7 is an exploded perspective view of an air circulation module according to various embodiments of the present invention; -
FIG. 8 is a perspective view of a re-circulation valve and spring according to various embodiments of the present invention; -
FIG. 9 is a cutaway perspective view showing the re-circulation valve of the air circulation module open according to various embodiments of the present invention; and -
FIG. 10 is a cutaway perspective view showing the re-circulation valve of the air circulation module closed according to various embodiments of the present invention. - Skilled artisans will appreciate that elements in the figures are illustrated for simplicity and clarity and have not necessarily been drawn to scale. For example, the dimensions and/or relative positioning of some of the elements in the figures may be exaggerated relative to other elements to help to improve understanding of various embodiments of the present invention. Also, common but well-understood elements that are useful or necessary in a commercially feasible embodiment are often not depicted in order to facilitate a less obstructed view of these various embodiments of the present invention. It will further be appreciated that certain actions and/or steps may be described or depicted in a particular order of occurrence while those skilled in the art will understand that such specificity with respect to sequence is not actually required. It will also be understood that the terms and expressions used herein have the ordinary meaning as is accorded to such terms and expressions with respect to their corresponding respective areas of inquiry and study except where specific meanings have otherwise been set forth herein.
- An apparatus and method are provided that circulate and re-circulate air efficiently within an enclosure. More specifically, the approaches provided herein integrate a recirculation valve with the air circulation module in order to re-circulate air. These approaches achieve the effective circulation and re-circulation of air within enclosures in a simple and cost effective manner, and require a minimum of additional parts.
- In many of these embodiments, an air circulation module includes a housing and at least one fan that is enclosed within the housing. The fan receives an airflow moving through the housing. An airflow re-circulation valve is disposed within the housing so as to not substantially interfere with the airflow moving through the housing. The airflow re-circulation valve is selectively opened so as to divert a first portion of the airflow into and through the airflow re-circulation valve and out of the housing via an exhaust port. A second portion of the airflow is directly exhausted from the housing after being received by the fan.
- In some of these approaches, the airflow re-circulation valve comprises a bi-metallic spring. In these examples, the bi-metallic spring expands and contracts a predetermined amount and the predetermined amount is based at least in part upon a temperature change. The air re-circulation valve may further include a rotary member and the bi-metallic spring is arranged to rotate the rotary member.
- The air circulation module may also include a feeder arrangement and the feeder arrangement communicates with the airflow re-circulation valve. The feeder arrangement is adapted to direct the first portion of the airflow into the airflow re-circulation valve. In one example, the feeder arrangement includes a re-circulation plate.
- In others of these embodiments, an airflow is drawn into the air circulation module. The airflow is moved along a direct path about at least one fan enclosed within the air circulation module. A re-circulation valve positioned within the air circulation module is automatically and selectively opened so as to not substantially interfere with the direct path of the air flow in order to exhaust a first portion of the air flow from the air circulation module. The amount of opening of the re-circulation valve can be determined at least in part based upon a temperature. The amount of opening may be determined by other factors as well.
- Thus, approaches are provided that circulate and re-circulate air efficiently within an enclosure. These approaches integrate a re-circulation valve and use a minimum amount of additional parts. The dynamic circulation and re-circulation of air associated with the enclosure is achieved in a simple and cost effective manner.
- Referring now to
FIG. 1 , an example of a system for controlling the environmental conditions of an enclosure is described. In particular, in the examples described herein, the temperature within a cellular base station enclosure is regulated. However, it will be appreciated that any other type of environmental condition can be regulated. Additionally, although the enclosures described herein are described as including base station components for a cellular communication system, it will be understood that the enclosures may house any type of electrical and/or mechanical components. Furthermore, it will be understood that the temperatures or temperature ranges described herein are approximate and can also be varied according to the needs of the user or the system. Additionally, the temperatures and temperature ranges recited herein are examples only and can be varied according to the needs of the user or the system. - A
backplane 102 includes afirst thermostat 104, asecond thermostat 106, and athird thermostat 108. Thefirst thermostat 104 and thesecond thermostat 106 are over-temperature devices that are open at temperatures of greater than 85 degrees Celsius and are closed otherwise. Thethird thermostat 108 is a high-temperature device and is open at temperatures of 70 degrees Celsius or greater and is closed otherwise. - The
backplane 102 also includes afirst switch 110, asecond switch 112, afourth thermostat 114, and afifth thermostat 116. Thefourth thermostat 114 and thefifth thermostat 116 are closed at temperatures of above 0 degrees Celsius and are open otherwise. Thebackplane 102 also includes asixth thermostat 120 andseventh thermostat 121 that are open at temperatures above 20 degrees Celsius and are closed otherwise. Thebackplane 102 additionally includes aneighth thermostat 122 that opens at temperatures of less than 0 degrees Celsius and is closed otherwise. - The
backplane 102 is connected to aheater module 124. Theheater module 124 includes afirst heater 126 and asecond heater 128. Thefirst heater 126 is controlled by athird relay 130 and thesecond heater 128 is controlled by afourth relay 132. The purpose of thethird relay 130 and thefourth relay 132 are to act as safety disconnect devices if any of the heaters enter a run away condition and/or thethermostat 108 malfunctions or has a significant time lag. Thethird relay 130 andfourth relay 132 are connected to aninth thermostat 150 andtenth thermostat 152 respectively (controlling thefirst heater 126 and the second heater 128). Theninth thermostat 150 andtenth thermostat 152 activate at approximately 150 degrees Celsius. - A
fan module 134 is coupled to thebackplane 102 and tosystem components 136. Thefan module 134 may include one or more air circulation elements (e.g., fans). Thesystem components 136 include one or more electrical components that perform or implement the functions of an electronic system. For example, these components may implement base station functions for a cellular communication system. Thesystem components 136 include a card power inhibitcircuit 138 and analarm board 140. Power supplies 142 supply power to the various components of the system. A Circuit Breaker Card (CBC) 141 includes fuses and/or breakers that are coupled to thebackplane 102, thefan module 134, and theheater module 124. Power is provided to but not necessarily utilized by the system when a user activates the circuit breakers on theCBC 141 and the power supplies 142. - The system of
FIG. 1 may also utilize a re-circulation valve (not shown inFIG. 1 ) to selectively re-circulate air within the enclosure. Additionally, the system ofFIG. 1 may use a moveable damper (not shown inFIG. 1 ) to selectively exhaust air from the enclosure. - In one example of the operation of the system of
FIG. 1 , a cold start may occur (at temperatures of below 0 degrees Celsius to 0 degrees Celsius) when a user throws the main breaker, turns on the power supplies, and/or engages the sub-system level circuit breakers on theCBC 141. In this situation, thefourth thermostat 114 andfifth thermostat 116 are open, which de-activates thefirst switch 110 and thesecond switch 112. In addition, when thefirst switch 110 and thesecond switch 112 are de-activated, power is provided to and utilized by thesecond heater 128. When thefirst switch 110 and thesecond switch 112 are de-activated, power is inhibited to thesystem components 136. Independent of thefirst switch 110 andsecond switch 112, thesixth thermostat 120 andseventh thermostat 121 are closed, in one example, based upon temperature alone (e.g., when the temperature within the enclosure is less than 20 degrees Celsius). - When the
sixth thermostat 120 andseventh thermostat 121 are closed, power is provided to and utilized by thefirst heater 126. At a temperature of −10 degrees Celsius, one or more of the fans in thefan module 134 starts up and runs, in one example, at 750 rpm. Air is moved through a re-circulation valve (e.g., there-circulation valve 207 shown inFIG. 2 ), through a re-circulation path (e.g., there-circulation path 218 shown inFIG. 2 ), back across theheaters system components 136. As the air is further re-circulated and passed over thefirst heater 126,second heater 128, andsystem components 136, its temperature rises. - Once the temperature of the air reaches 0 degrees Celsius, the
fourth thermostat 114 and thefifth thermostat 116 close. When thefourth thermostat 114 and thefifth thermostat 116 close, thefirst switch 110 andsecond switch 112 are energized. When thefirst switch 110 andsecond switch 112 are energized, the system inhibitline 144 is de-activated and the system utilizes the power provided to it by theCBC 141. Additionally, when thefirst switch 110 andsecond switch 112 are energized, thesecond heater 128 is de-activated. - In another example, if the system were to drop below 0 degrees Celsius (e.g., a maintenance person leaves the front door open or ajar and the door alarm is defeated or malfunctions), the
second heater 128 is not re-energized. Once thefirst switch 110 andsecond switch 112 are energized, the system inhibit line is de-activated, and the system is in a run state and will not re-start thesecond heater 128. In one example, all heating functions are dealt with by thefirst heater 126 and thesystem components 136 within the enclosure. Thesecond heater 128 will only re-start if power is lost to the system and it experiences a new, cold start event thereby re-setting thefirst switch 110 andsecond switch 112 to a de-energized state. - When a high-temperature condition occurs (e.g., the temperature exceeds a predetermined threshold), the
third thermostat 108 opens. The occurrence of this condition causes an alarm to be sent to thealarm board 140 on alarm lines 146. An alarm indictor 148 (e.g., light emitting diode (LED)), may be activated to visually inform the user of the alarm condition. When an over-temperature condition occurs, thefirst thermostat 104,second thermostat 106 are opened. The power input to thebackplane 102 from the power supplies 142 is deactivated. Thesecond heater 128, thefirst heater 126, thesystem components 136, and thefan module 134 then turn off. The occurrence of these conditions causes an alarm to be sent to thealarm board 140 onalarm lines 146 - When an under-temperature condition occurs (e.g., the temperature falls below a predetermined threshold), the
eighth thermostat 122 opens when the temperature within the enclosure falls below a threshold (e.g., the temperature within the enclosure is less than 0 degrees). This occurrence sends analarm signal 146 to the alarm board. An alarm indictor 148 (e.g., light emitting diode (LED)), may be activated to visually inform the user of the alarm condition. - In another example of the operation of the system of
FIG. 1 , the system may operate in a transitional operation or cold maintenance operation (e.g., at temperature ranges of 0 to 20 degrees Celsius). In a transition from a cold start event, as the air is further heated the temperature rises, the re-circulation valve begins to close, the damper begins to open, a small quantity of air is drawn in through the filter, and the rate of internal temperature rise is slowed. When and if the internal air temperature reaches 20 degrees Celsius thefirst heater 126 turns off and system heating is handled by thesystem components 136. - If the temperature of the air never reaches 20 degrees Celsius, the
first heater 126 remains energized. If the temperature of the air rises above 20 degrees Celsius, the first heater turns off, if over time the temperature falls again to below 20 Celsius, thefirst heater 126 turns back on to provide energy to the re-circulated and incoming air streams. Thefirst heater 126 will continue to cycle with hysterisis. During this transitional state, re-circulation valve, exhaust damper, andfan module 134 are in various states of operation all combining to maintain the optimal temperature within the enclosure while minimizing hysterisis. - In another example of the operation of the system of
FIG. 1 , the system starts at ambient temperatures between 0 degrees Celsius and 20 degrees Celsius. In this case, the system may experience a power up condition when a user throws the main breaker, turns on the power supplies, and/or engages the sub-system level circuit breakers on the CBC (Circuit Breaker Card). Power is provided to and utilized by the system when a user activates the circuit breakers and power supplies. Thefourth thermostat 114 andfifth thermostat 116 are closed, which activates thefirst switch 110 and thesecond switch 112. When thefirst switch 110 andsecond switch 112 are activated, power is not provided to thesecond heater 128. Additionally, when thefirst switch 110 andsecond switch 112 are activated, power is not inhibited to thesystem 138. Independent of the operation of thefirst switch 110 andsecond switch 112, thesixth thermostat 120 andseventh thermostat 121 are closed, in one example, based on temperature alone (e.g., temperatures of less than 20 degrees Celsius). - When the
sixth thermostat 120 andseventh thermostat 121 are closed, power is provided to and utilized by thefirst heater 126. At a temperature of 0 degrees Celsius, one or more of the circulation elements of thefan module 134 start up and runs, for example, at 750 rpm. The speed is variable and depends upon the air temperature, for instance, speeding up to an rpm of 1090 rpm at an air temperature of 20 degrees Celsius. Air is moved through a re-circulation valve (e.g.,valve 207, discussed in connection withFIG. 2 below), through a re-circulation path (e.g.,re-circulation path 218, discussed in connection withFIG. 2 below), back across thefirst heater 126 andsecond heater 128 and through the electronics (e.g.,electronics 210 discussed in connection withFIG. 2 below). The re-circulation valve position is also variable and reacts according to air temperature so as to reduce and finally close the flow stream through the re-circulation path at 50 degrees Celsius. At 10-12 degrees Celsius, the exhaust damper will start to break seal and a small inflow of cold ambient air will be pulled in through the filter. As the fan speed rises this effect increases. As the air is further re-circulated, exhausted, and introduced through the filter and passed over thefirst heater 126,second heater 128, andsystem components 134 its temperature changes until it reaches an equilibrium point determined by all of the afore mentioned system effects as well as ambient air temperature, system power load, external wind speed, sunlight, and other ambient effects. - In still another example of the operation of the system of
FIG. 1 , at temperatures above 20 degrees Celsius, both thefirst heater 126 andsecond heater 128 are off. Start up would proceed as described above, but without thefirst heater 126 orsecond heater 128 being activated. At temperatures from 20 degrees Celsius up to approximately 50 degrees Celsius, the re-circulation valve is still open to some extent and would allow a decreasingly small amount of flow through the re-circulation path eventually diminishing to zero flow. The fan speed increases in response to higher temperatures caused by increased system load, environmental conditions, or other factors thereby causing the exhaust damper to rise thereby increasing the amount of exhaust flow out of the enclosure. - Referring now to
FIG. 2 , one example of anenclosure 200 and approaches for maintaining environmental conditions within theenclosure 200 are described. Theenclosure 200 includes afilter 202 that accepts anair flow 204. Thefilter 202 removes particulate matter from the air (e.g., smoke, dust, dirt) and water in the liquid phase before the matter or liquid water enters theenclosure 200. Thefilter 202 outputs a filteredair flow 206, which is received by aheater 208. Theheater 208 selectively heats the filteredair flow 206 and creates aheated air flow 209, which moves over, across, and aroundcircuit boards 210. In this example, thecircuit boards 210 are the electronic functional components of a cellular base station communication system. Depending upon the temperature (or other conditions) within the enclosure, theheater 208 may be activated to heat the filteredair flow 206. Alternatively, the heater may be deactivated and the filteredair flow 206 may be drawn (unheated) over, across, and around thecircuit boards 210 in order to cool these components. - The heated air flow 209 (or the unheated filtered air flow) is drawn
past power supplies 212 and through afan 214. Thefan 214 is coupled to and/or includes are-circulation valve 207 that selectively allows areturn air flow 216 to pass into aconduit 218 and return to theheater 208. In one example, there-circulation valve 207 includes a bi-metallic spring or coil that expands and contracts to alternatively allow the air to flow through the conduit 216 (back to the heater 208) or prevent the air flow from entering theconduit 216. In one example, the air flow is re-circulated back to theheater 208 at temperatures of between −40 degrees Celsius and 50 degrees Celsius. - The
damper 220 is arranged and constructed to alternatively rise and fall to allow anexhaust air flow 222 to be exhausted from theenclosure 200. The damper may be a plastic or other suitable material configured as a plate-like lid that rises or falls into position depending upon the air pressure inside theenclosure 200. The air pressure inside theenclosure 200 may depend upon the temperature, the amount of air being re-circulated, and the amount of air being drawn into theenclosure 200 through theair filter 202. Other factors may also determine or influence the pressure within theenclosure 200. In one example, theair flow 222 may be exhausted from theenclosure 200 at temperatures of 12 degrees Celsius or greater. In another example, theair flow 222 may be exhausted from the enclosure at temperatures of 10-12 degrees Celsius or greater. - The approaches described herein incorporate passive elements to maintain substantially constant environmental conditions (e.g., a substantially constant temperature) within enclosures. By selectively activating and deactivating the components (e.g., the
heater 208,fan 214, and re-circulation valve 207), a substantially constant temperature may be achieved and maintained. If the temperature is above a threshold value (e.g., thedamper 220 is open, thefan 214 is turning at a predetermined speed) air is drawn into the enclosure and the air is selectively heated. For example, theheater 208 may be activated at a cold start and theheater 208 may be deactivated when a predetermined temperature (e.g., 20 degrees Celsius) is reached. Additionally, theheater 208 may be reactivated when the temperature within the enclosure falls below a predetermined threshold. - The example of
FIG. 2 shows one possible component layout and the selection of components that can be used to achieve a predetermined environmental goal (e.g., the maintenance a predetermined temperature range within the enclosure). It will be appreciated that other example layouts for theenclosure 200 and other component selections are possible. Additionally, it will be understood that the dimensions of the structure including the relative sizing of the components (e.g., the diameter or shape of thedamper 220, or size of the conduit 218) may be adjusted according to the needs and requirements of the system or user. Further, it will be appreciated that the types of components chosen may change and the operation of these components may also be varied according to the goals of the system. For example, the temperature ranges indicated above may be varied by the use of additional heaters or fans. In another example, the placement of theelectronic components 210 may be varied relative to the other components. In still another example, some of the components (e.g., the filter 202) may be removed. - Referring now to both
FIG. 3 andFIG. 4 , one example of a damper structure at the top of anenclosure 300 is described. The damper structure includes alid 302. The lid includesgrooves grooves rods lid 302 rises and falls in the directions indicated by thearrows 316. - The amount of pressure in the
enclosure 300 affects the amount of lift of thelid 302. For example, a relatively high amount of pressure causes thelid 302 to rise to its greatest height (i.e., to its fully open position) and, consequently, release the greatest amount of air from theenclosure 300. In contrast, when the pressure inside theenclosure 300 is relatively low, thelid 302 falls to its lowest point (i.e., to its closed position) and substantially no air flows out through the damper. In middle pressure ranges, thelid 302 may be raised by the pressure within the enclosure to a middle position and a medium amount of air exhausts from the enclosure. - The amount of pressure inside the
enclosure 300 may depend upon various factors. For example, the amount of pressure may depend directly or indirectly upon the temperature of theenclosure 300, whether the fan is running, the number of heaters running, the amount of electronics in theenclosure 300, and the amount of air re-circulation provided by the system (e.g., by a re-circulation valve). The weight, structure, and material used in theenclosure 300 and/or thelid 302 of theenclosure 300 may also affect the pressure as may environmental conditions outside of theenclosure 300. Other factors or conditions may also influence the pressure within theenclosure 300. - Referring now to
FIG. 5 , one example of an approach for maintaining optimum environmental conditions within an enclosure is described. Atstep 502, external air is selectively drawn into the enclosure, which in one example is an electronic component housing. Atstep 504, the external air that is drawn into the enclosure is selectively heated to form heated air. The extent of the heating is based at least in part upon the temperature within the electronic component housing. For example, no heating may be needed at some temperatures while a maximum amount of heating may be used at other temperatures. - At
step 506, the heated air is selectively drawn across at least one electronic component positioned within the electronic component housing. Unheated air may also be drawn under selected circumstances. Atstep 508, a first flow of the heated air (or unheated air, when the heater is deactivated) that has been drawn across the at least one electronic component is selectively re-circulated. The amount of the first flow is based at least in part upon the temperature within the housing. - At
step 510, a second flow of the heated air (or unheated air, when the heater is deactivated) that has been drawn across the at least one electronic component is selectively exhausted from the electronic component housing. The amount of the second flow is based at least in part upon the temperature within the electronic component housing. The heating, exhausting, and re-circulating operate so as to cause the temperature within the electronic component housing to stay within a predetermined temperature range. - Referring now to
FIG. 6 , an example of transitioning between states in a system that regulates environmental conditions in an enclosure is described. Similar to the example ofFIG. 2 , two heaters (a first heater and a second heater) and a fan are used. Additionally, a damper is arranged to exhaust air at the top of the enclosure. Further, a re-circulation valve and conduit are arranged to re-circulate air from the top of the enclosure through the heater. - Initially, at a
cold start state 602, the fan is off, the first heater is on, the second heater is on, and the damper is closed. If the temperature remains below −10 degrees Celsius, the system remains in thestate 602. If the temperature within the enclosure rises above −10 degrees Celsius, then the system transitions tostate 604. - In the
state 604, the fan is on, the first heater is on, the second heater is on, re-circulation is being performed, and the damper is closed. If the temperature goes above 0 degrees Celsius, the system transitions tostate 606. If the temperature remains between −10 and 0 degrees Celsius, the system remains in thestate 604. If the temperature falls below −10 degrees Celsius the system transitions back to theprevious state 602. - In the
state 606, the fan is on, the first heater is on, the second heater is off, re-circulation is being performed, the damper is closed and the system components are active. If the temperature goes above 0 degrees Celsius but does not exceed 19 degrees Celsius the damper transitions from a closed to partiallyopen state 607 and exhaust from the enclosure is being performed. If the temperature within the enclosure reaches 20 degrees Celsius, the system transitions tostate 608. If the temperature of the enclosure falls below 0 degrees Celsius, then the system transitions tostate 616. - In the
state 608, the fan is on, the first heater is off, the second heater is off, the system components are active, re-circulation is transitioning from partially open to closed, and the damper is transitioning from partially open to open. If the temperature in the enclosure goes above 50 degrees Celsius then the system transitions tostate 610. If the temperature falls below 20 degrees Celsius, then the system returns tostate 607. - In the
state 610, the fan is on, the first heater is off, the second heater is off, the system components are active, re-circulation has halted and the damper is open. If the temperature within the enclosure is between 50 degrees and an over-temperature threshold of 70 degrees Celsius, the system remains atstate 610 and the fan moves from full speed to boost mode as the temperature within the enclosure approaches the over temperature threshold. If the temperature reaches an over-temperature threshold, the system transitions tostate 612. If the temperature falls below 50 degrees Celsius the system transitions back tostate 608. - In the
state 612, the fan is on, the first heater is off, the second heater is off, the system components are active, re-circulation is halted, and the damper is open. The temperature within the enclosure has reached a high temperature threshold and the fan is in “boost” mode. Additionally, an alarm is sent to the user so that the user may be informed of the high-temperature condition. If the temperature within the enclosure reaches an over-temperature threshold of 85 degrees Celsius the system transitions tostate 614. If the temperature within the enclosure falls below the high-temperature threshold, the system returns tostate 610. - In
state 614 the fan is on and in boost mode, the first heater is off, the second heater is off, the system components are active, re-circulation is halted, and the damper is open. An over-temperature alarm is sent and the system begins a shut down sequence to de-energize all functions provided by the backplane so as to disable all heat generating components. If the temperature within the enclosure falls below the high temperature threshold the system returns tostate 612. - In
state 616, the fan is on, the first heater is on, the second heater is off, re-circulation is being performed, the damper is closed, and the system components are active. Additionally, a low temperature alarm is sent to the user so that the user may be informed of the low temperature condition. If the temperature within the enclosure rises above 0 degrees Celsius, the system transitions tostate 606. - It will be appreciated that variations of the state transition sequence are possible and may depend upon (among other things) the objectives (e.g., temperature or pressure levels) that are desired to be obtained within the enclosure. It will also be understood that these objectives may be achieved by operating the components in other states, in other ways, or according to other transition sequences.
- Referring now to
FIGS. 7-10 , an example of anair circulation module 700 is described. As shown inFIG. 7 , anairflow re-circulation valve 701 includes abi-metallic spring 706 that is coupled to arotary member 704. Are-circulation plate 702 covers the combination of therotary member 704 and thebi-metallic spring 706, and the combination is positioned within afirst portion 710 of the fan assembly housing. There-circulation plate 702 may also be part of a feeder arrangement that communicates with there-circulation valve 701 and directs a flow of air into theairflow re-circulation valve 701. Asecond portion 711 of the fan housing attaches to thefirst portion 710 to form the housing of theair circulation module 700. Additionally, afan 712 is positioned within theair circulation module 700 in order to exhaust air from theair circulation module 700 and/or to re-circulate air. Theair circulation module 700 can be used as part of the environmental control system for any of the enclosures that are described elsewhere in this specification. - Referring now specifically to
FIG. 8 , therotary member 704 is formed withopenings 705. As thebi-metallic spring 706 expands and contracts, it causes therotary member 704 to rotate in the direction of the arrow denoted byreference numeral 707. As can be seen inFIG. 9 , therotary member 704 is responsively rotated to an open or partially open position allowing anairflow 709 to pass though theopenings 705 and exhaust out of an exit portal 713 (formed in the air circulation module 701). Alternatively, as shown inFIG. 10 , thebi-metallic spring 706 may not contract (or not contract enough) thereby causing therotary member 704 to remain in a closed position (i.e., so that air can not pass through theopenings 705 of therotary member 704 and out through theexit portal 713 of the air circulation module 700). - The
bi-metallic spring 702 may be formed from any suitable metal or material (or combination thereof) that expands and contracts according a pre-determined amount for a given temperature thereby allowing therotary member 704 to rotate. The other elements of the system may be formed from plastic, metal, wood, or some other suitable material. In addition, other types of arrangements not using a bi-metallic valve and/or rotary member are possible. - It will be further appreciated that the air circulation module described herein is not limited to use in telecommunication system enclosures. Specifically, the air circulation module as described herein can be used in any type of enclosure to re-circulate air.
- In another example of the operation of the system of
FIGS. 7-10 , anairflow 721 is drawn into theair circulation module 700. Theairflow 721 is moved along a direct path about thefan 712 enclosed within theair circulation module 700. There-circulation valve 701 is automatically and selectively opened so as to not substantially interfere with the direct path of the air flow in order to exhaust afirst portion 709 of theair flow 721 from theair circulation module 700. In one example, the amount of opening of there-circulation valve 701 is determined based upon a temperature in the enclosure. However, the amount of opening may also be determined by other factors (e.g., pressure) as well. Asecond portion 719 of theairflow 721 may also be exhausted out of theair circulation module 700. - Thus, an integrated air circulation module and methods of using the module are provided that circulate and re-circulate air efficiently within an enclosure. The approaches described herein are cost-effective to implement and utilize a minimum of parts. In so doing, the dynamic circulation and re-circulation of air is achieved in a simple and cost effective manner.
- Those skilled in the art will recognize that a wide variety of modifications, alterations, and combinations can be made with respect to the above described embodiments without departing from the spirit and scope of the invention, and that such modifications, alterations, and combinations are to be viewed as being within the scope of the invention.
Claims (17)
1. An air circulation module comprising:
a housing;
at least one fan enclosed within the housing, wherein the at least one fan receives an airflow moving through the housing; and
an airflow re-circulation valve that is disposed within the housing so as to not substantially interfere with the airflow moving through the housing, the airflow re-circulation valve being selectively opened so as to divert a first portion of the airflow into and through the airflow re-circulation valve and out of the housing via an exhaust port.
2. The air circulation module of claim 1 wherein the airflow re-circulation valve comprises a bi-metallic spring.
3. The air circulation module of claim 2 wherein the bi-metallic spring expands and contracts a predetermined amount, the predetermined amount based at least in part upon a temperature change.
4. The air circulation module of claim 3 wherein the air re-circulation valve further comprises a rotary member and the bi-metallic spring is arranged to rotate the rotary member.
5. The air circulation module of claim 1 further comprising a feeder arrangement, the feeder arrangement being coupled to the airflow re-circulation valve, the feeder arrangement being adapted to direct the first portion of the airflow into the airflow re-circulation valve.
6. The air circulation module of claim 5 wherein the feeder arrangement comprises a re-circulation plate.
7. The air circulation module of claim 1 wherein a second portion of the airflow is directly exhausted from the housing after being received by the fan.
8. A system for circulating air comprising:
a housing having an entrance portal and a first exit portal;
at least one fan enclosed within the housing;
an airflow moving though the entrance portal and being received by the at least one fan; and
an air re-circulation valve positioned within the housing so as to not interfere with the movement of the airflow, the air re-circulation valve communicating with the first exit portal, the air re-circulation valve selectively being opened to divert a first portion of the airflow through the air re-circulation valve and out of the housing via the first exit portal.
9. The system of claim 8 wherein the housing further comprises a second exit portal and wherein a second portion of the airflow is directly exhausted from the housing through the second exit portal after being received by the at least one fan.
10. The system of claim 8 wherein the airflow re-circulation valve comprises a bi-metallic spring.
11. The system of claim 10 wherein the bi-metallic spring expands and contracts a predetermined amount, the predetermined amount based at least upon a temperature change.
12. The system of claim 11 wherein the air re-circulation valve further comprises a rotary member and the bi-metallic spring is arranged to rotate the rotary member.
13. The system of claim 8 further comprising a feeder arrangement, the feeder arrangement being coupled to the air re-circulation valve, the feeder arrangement being adapted to direct at least a portion of the airflow into the air re-circulation valve.
14. The system of claim 13 wherein the feeder arrangement comprises a re-circulation plate.
15. A method of moving air through an air circulation module comprising:
drawing an airflow into the air circulation module;
moving the airflow along a direct path about at least one fan enclosed within the air circulation module; and
automatically and selectively opening a re-circulation valve positioned within the air circulation module so as to not substantially interfere with the direct path of the air flow in order to exhaust a first portion of the air flow from the air circulation module, an amount of opening of the re-circulation valve determined at least in part based upon a temperature.
16. The method of claim 15 wherein the amount of the opening is determined by an amount of deflection of a bi-metallic spring.
17. The method of claim 15 further comprising exhausting a second portion of the airflow directly from the air circulation module along the direct path.
Priority Applications (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US11/778,114 US20090023380A1 (en) | 2007-07-16 | 2007-07-16 | Apparatus and method for air circulation |
EP08012410A EP2018093A1 (en) | 2007-07-16 | 2008-07-09 | Apparatus and method for air circulation |
KR1020080068717A KR20090008140A (en) | 2007-07-16 | 2008-07-15 | Apparatus and method for air circulation |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US11/778,114 US20090023380A1 (en) | 2007-07-16 | 2007-07-16 | Apparatus and method for air circulation |
Publications (1)
Publication Number | Publication Date |
---|---|
US20090023380A1 true US20090023380A1 (en) | 2009-01-22 |
Family
ID=39831693
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US11/778,114 Abandoned US20090023380A1 (en) | 2007-07-16 | 2007-07-16 | Apparatus and method for air circulation |
Country Status (3)
Country | Link |
---|---|
US (1) | US20090023380A1 (en) |
EP (1) | EP2018093A1 (en) |
KR (1) | KR20090008140A (en) |
Families Citing this family (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
EP2182789B1 (en) * | 2008-10-29 | 2013-09-18 | Huawei Device Co., Ltd | Heat dissipation window and communication equipment |
GB2464354B (en) * | 2009-03-13 | 2011-06-08 | 4Energy Ltd | Equipment enclosure |
WO2021083493A1 (en) * | 2019-10-29 | 2021-05-06 | Huawei Technologies Co., Ltd. | A device for controlling an air flow for cooling an electrical component |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4147299A (en) * | 1977-09-26 | 1979-04-03 | International Business Machines Corporation | Air flow system for a disk file |
US6330155B1 (en) * | 2000-03-28 | 2001-12-11 | Qtera Corporation | Method and apparatus for temperature control of electrical devices mounted on circuit boards |
US20060172685A1 (en) * | 2004-08-26 | 2006-08-03 | O'brien Paul | Internal environmental control system and uses thereof |
Family Cites Families (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
GB8704411D0 (en) * | 1987-02-25 | 1987-04-01 | Gen Electric Co Plc | Cabinet |
US5294049A (en) * | 1993-02-22 | 1994-03-15 | Temp-Vent Corporation | Power temp vent duct system |
JP2692648B2 (en) * | 1995-06-01 | 1997-12-17 | 日本電気株式会社 | Outdoor equipment enclosure |
DE102004013318B4 (en) * | 2004-03-17 | 2006-03-23 | Rittal Rcs Communication Systems Gmbh & Co. Kg | Cooling system, for a switchbox with a fan and filter, has an electric setting unit for flaps and slides to control part warm air flows to overlay the cold air to give two operating modes |
-
2007
- 2007-07-16 US US11/778,114 patent/US20090023380A1/en not_active Abandoned
-
2008
- 2008-07-09 EP EP08012410A patent/EP2018093A1/en not_active Withdrawn
- 2008-07-15 KR KR1020080068717A patent/KR20090008140A/en not_active Application Discontinuation
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4147299A (en) * | 1977-09-26 | 1979-04-03 | International Business Machines Corporation | Air flow system for a disk file |
US6330155B1 (en) * | 2000-03-28 | 2001-12-11 | Qtera Corporation | Method and apparatus for temperature control of electrical devices mounted on circuit boards |
US20060172685A1 (en) * | 2004-08-26 | 2006-08-03 | O'brien Paul | Internal environmental control system and uses thereof |
Also Published As
Publication number | Publication date |
---|---|
KR20090008140A (en) | 2009-01-21 |
EP2018093A1 (en) | 2009-01-21 |
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Owner name: MOTOROLA, INC., ILLINOIS Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:GUTIERREZ, GREG M.;LARSEN, KEVIN J.;NESTOR, MARC N.;REEL/FRAME:019643/0979;SIGNING DATES FROM 20070721 TO 20070801 |
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