Method and arrangement for optimizing heat transfer properties in heat exchange ventilation systems
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01K-013/00
F28F-027/00
F28F-013/00
B01J-049/00
B01D-037/00
출원번호
US-0282384
(2007-03-09)
등록번호
US-8464783
(2013-06-18)
우선권정보
SE-0600569 (2006-03-10)
국제출원번호
PCT/SE2007/050141
(2007-03-09)
§371/§102 date
20080910
(20080910)
국제공개번호
WO2007/106030
(2007-09-20)
발명자
/ 주소
Nutsos, Mikael
출원인 / 주소
Nutsos, Mikael
대리인 / 주소
Young & Thompson
인용정보
피인용 횟수 :
2인용 특허 :
6
초록▼
The present invention relates to a method and arrangement of optimizing the level of anti freeze agent in a heat transfer fluid in a heat exchange system The method comprises determining (305) a wanted level of anti freeze agent at least partly based on the temperature of the media to which the heat
The present invention relates to a method and arrangement of optimizing the level of anti freeze agent in a heat transfer fluid in a heat exchange system The method comprises determining (305) a wanted level of anti freeze agent at least partly based on the temperature of the media to which the heat exchange system will deliver heat, controlling (310) the current level of the anti freezing agent in the heat transfer fluid. Anti freezing agent is added 315:1 to the heat transfer fluid if the current level is a predetermined amount lower than the wanted level, and removed 315:2 from the heat transfer fluid if the current level is a predetermined amount higher than the wanted level.
대표청구항▼
1. A method of optimizing a level of an antifreeze agent in a heat transfer fluid of a heat exchange system of a ventilation system, comprising the steps of: operating the heat exchange system of the ventilation system i) to deliver heat to incoming air by outgoing air heating the heat transfer flui
1. A method of optimizing a level of an antifreeze agent in a heat transfer fluid of a heat exchange system of a ventilation system, comprising the steps of: operating the heat exchange system of the ventilation system i) to deliver heat to incoming air by outgoing air heating the heat transfer fluid, and ii) for the heat transfer fluid to transfer the heat collected from the outgoing air to warm incoming air, the operating step including monitoring a temperature of the incoming air, wherein the level of the antifreeze agent in the heat transfer fluid is dependent on the temperature of the incoming air;monitoring a temperature of the heat transfer fluid;determining a wanted level of the antifreeze agent based on the monitored temperature of the incoming air; andcontrolling a current level of the antifreeze agent in the heat transfer fluid including i) adding further antifreeze agent to the heat transfer fluid when the current level is a predetermined amount lower than the wanted level, and ii) removing an amount of the antifreeze agent from the heat transfer fluid when the current level is a predetermined amount higher than the wanted level,wherein said determining step further comprises determining the wanted level of the antifreeze agent further based on long-term statistics over relations between the monitored incoming air temperature, previously chosen levels of the antifreeze agent associated with the monitored temperature of the incoming air, and a resulting temperature of the heat transfer fluid for a local installation, the long-term statistics being based on actual monitored incoming air temperature values and the monitored resulting temperature of the heat transfer fluid for the local installation in the operation of the heat exchange system of the ventilation system. 2. The method according to claim 1, wherein said determining step further comprises determining the wanted level of the antifreeze agent further based on long-time changes of the temperature of the incoming air. 3. The method according to claim 1, wherein said determining step further comprises determining the wanted level of the antifreeze agent further based on a temperature forecast from an external source. 4. The method according to claim 1, wherein said determining step further comprises determining the wanted level of the antifreeze agent further based on a temperature forecast from an external source. 5. The method according to claim 1, wherein said controlling step controls the current level of the antifreeze agent in the heat transfer fluid by the adding of the further antifreeze agent to the heat transfer fluid when the current level is the predetermined amount lower than the wanted level, the wanted level based on avoiding freezing of the heat transfer fluid based on the monitored temperature of the incoming air and a freezing point of the heat transfer fluid. 6. The method according to claim 1, wherein said controlling step controls the current level of the antifreeze agent in the heat transfer fluid by i) the adding of the further antifreeze agent to the heat transfer fluid when the current level is the predetermined amount lower than the wanted level, and ii) the removing of the amount of the antifreeze agent from the heat transfer fluid when the current level is the predetermined amount higher than the wanted level, the wanted level based on avoiding freezing of the heat transfer fluid based on the monitored temperature of the incoming air, a freezing point of the heat transfer fluid, and maximizing heat transfer efficiency of the heat transfer fluid. 7. A heat exchange system (200) of a ventilation system configured to deliver heat to incoming air by outgoing air heating a heat transfer fluid, for the heat transfer fluid to transfer the heat to warm incoming air, a level of an antifreeze agent in the heat transfer fluid being dependent on a temperature of the incoming air, the system comprising: a heat collector unit (225) configured to collect the heat from the outgoing air;a heat deliver unit (230) configured to deliver the heat collected from the outgoing air to the incoming air, the heat collector unit and the heat deliver unit in fluid communication with each other;a separator (250) adapted to separate and remove an amount of the antifreeze agent from the heat transfer fluid;a remixer (245) adapted to add a part of the antifreeze agent to the heat transfer fluid;a first temperature sensor (275) configured to monitor the temperature of the incoming air, the first temperature sensor located upstream of the heat delivery unit (230);a second temperature sensor (280) configured to monitor a temperature of the heat transfer fluid; anda control unit (285) operatively connected with the separator (250), the remixer (245), and the first and second temperature sensors (275, 280),the control unit adapted to analyse current temperature data provided by the first and second temperature sensors (275) and to selectively order i) the separator to remove the amount of the antifreeze agent from the heat transfer fluid, and ii) the remixer to add the part of the antifreeze agent to the heat transfer fluid, based on the analysis of the current temperature data,wherein the heat collector unit i) delivers heat to incoming air by outgoing air heating the heat transfer fluid, and ii) transfers the heat from the heat transfer fluid to transfer to warm incoming air,wherein the control unit, in the analysis of the current temperature data, is adapted to further analyse long-term statistics over relations between the monitored incoming air temperature, previously chosen levels of the antifreeze agent associated with the monitored temperature of the incoming air, and a resulting temperature of the heat transfer fluid for a local installation, the long-term statistics being based on actual monitored incoming air temperature values and the monitored resulting temperature of the heat transfer fluid for the local installation in the operation of the heat exchange system of the ventilation system. 8. The heat exchange system of claim 7, wherein the control unit comprises an external communication unit for receiving at least one of external temperature and weather forecasts, the received at least one of the external temperature and the weather forecasts being used in the analysis of the current temperature data. 9. The heat exchange system according to claim 7, wherein said control unit controls a current level of the antifreeze agent in the heat transfer fluid by ordering the remixer to add the part of the antifreeze agent to the heat transfer fluid when the current level is a predetermined amount lower than a wanted level, the wanted level based on avoiding freezing of the heat transfer fluid based on the monitored temperature of the incoming air. 10. The heat exchange system according to claim 7, wherein said control unit controls the current level of the antifreeze agent in the heat transfer fluid by i) ordering the the remixer to add the part of the antifreeze agent to the heat transfer fluid when the current level is a predetermined amount lower than a wanted level, and ii) ordering the separator to remove the amount of the antifreeze agent from the heat transfer fluid when the current level is a predetermined amount higher than the wanted level, the wanted level based on avoiding freezing of the heat transfer fluid based on the monitored temperature of the incoming air while maximizing heat transfer efficiency of the heat transfer fluid. 11. The heat exchange system according to claim 9, wherein the wanted level is based on avoiding freezing of the heat transfer fluid based on i) the monitored temperature of the incoming air and ii) a freezing point of the heat transfer fluid. 12. The heat exchange system according to claim 10, wherein the wanted level is further based on a freezing point of the heat transfer fluid. 13. A heat exchange system (200) of a ventilation system configured to deliver heat to incoming air by outgoing air heating a heat transfer fluid, for the heat transfer fluid to transfer the heat received from the outgoing air to warm incoming air, a level of an antifreeze agent in the heat transfer fluid being regulated dependent on a temperature of the incoming air, the system comprising: a heat collector unit (225) located with an outgoing air duct and configured to collect the heat from the outgoing air;a heat deliver unit (230) located in an incoming air duct and configured to deliver the heat collected from the outgoing air to the incoming air, the heat collector unit and the heat deliver unit in fluid communication with each other;a separator (250) connected to the heat deliver unit and adapted to separate and remove an amount of the antifreeze agent from the heat transfer fluid;a remixer (245) connected to the separator and to the heat collector unit, the remixer adapted to add a part of the antifreeze agent removed from by the separator back into the heat transfer fluid;a first temperature sensor (275) configured to monitor the temperature of the incoming air, the first temperature sensor located upstream of the heat delivery unit (230);a second temperature sensor (280) configured to monitor a temperature of the heat transfer fluid; anda control unit (285) operatively connected with the separator (250), the remixer (245), and the first and second temperature sensors (275, 280),the control unit adapted to analyse current temperature data provided by the first and second temperature sensors (275) and order i) the separator to remove the amount of the antifreeze agent from the heat transfer fluid, and ii) the remixer to add the part of the antifreeze agent to the heat transfer fluid, based at on the analysis of the current temperature data,wherein the heat collector unit i) delivers heat to incoming air by outgoing air heating the heat transfer fluid, and ii) transfers the heat from the heat transfer fluid to transfer to warm incoming air,wherein said control unit controls a current level of the antifreeze agent in the heat transfer fluid by ordering the remixer to add the part of the antifreeze agent to the heat transfer fluid when the current level is a predetermined amount lower than a wanted level, the wanted level based on avoiding freezing of the heat transfer fluid based on the monitored temperature of the incoming air, andwherein the wanted level is based on avoiding freezing of the heat transfer fluid based on i) the monitored temperature of the incoming air, ii) a freezing point of the heat transfer fluid, and iii) the monitored temperature of the heat transfer fluid,wherein the control unit, in the analysis of the current temperature data, is adapted to further analyse long-term statistics over relations between the monitored incoming air temperature, previously chosen levels of the antifreeze agent associated with the monitored temperature of the incoming air, and a resulting temperature of the heat transfer fluid for a local installation the long-term statistics being based on actual monitored incoming air temperature values and the monitored resulting temperature of the heat transfer fluid for the local installation in the operation of the heat exchange system of the ventilation system. 14. The heat exchange system according to claim 13, wherein the wanted level is based on avoiding freezing of the heat transfer fluid based while maximizing heat transfer efficiency of the heat transfer fluid.
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이 특허에 인용된 특허 (6)
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