Heat source apparatus and method of starting the apparatus
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F25B-041/06
F25B-041/04
출원번호
US-0641364
(2009-12-18)
등록번호
US-8191377
(2012-06-05)
우선권정보
JP-2005-273672 (2005-09-21)
발명자
/ 주소
Aiyama, Masayuki
Kikuchi, Shouji
Ishibane, Kyuuhei
Ishiki, Yoshikazu
Okamoto, Mitsue
출원인 / 주소
Hitachi Appliances, Inc.
대리인 / 주소
Antonelli, Terry, Stout & Kraus, LLP.
인용정보
피인용 횟수 :
4인용 특허 :
20
초록▼
After a chiller unit is started, an opening command of 10 pulses is output to an electronic expansion valve, and after a predetermined period of time (at the time of starting with unload) elapses, an opening command of 100 to 150 pulses is output to open the electronic expansion valve up to a predet
After a chiller unit is started, an opening command of 10 pulses is output to an electronic expansion valve, and after a predetermined period of time (at the time of starting with unload) elapses, an opening command of 100 to 150 pulses is output to open the electronic expansion valve up to a predetermined opening degree. Thereafter, a discharge side refrigerant super-heat TdSH is monitored and a closing command of 1 pulse/sec is output to the electronic expansion valve to drive the same in a closing direction in a short time until TdSH becomes 20 K. After TdSH has reached 20 K, a closing command of 1 pulse/3 sec is output to the electronic expansion valve, until TdSH becomes 25 K, to drive the electronic expansion valve 3 at a smaller speed in the closing direction than that speed in the closing direction until TdSH becomes 20 K. After TdSH reaches 25 K, it is judged that an operation has shifted to a stable operation, and the opening degree of the electronic expansion valve is controlled while a suction side refrigerant super-heat TsSH is monitored.
대표청구항▼
1. A method of starting a heat source apparatus that includes a compressor, a condenser, an electronic expansion valve, an evaporator, a detector for detecting temperature of refrigerant at a suction-side of the compressor, a detector for detecting suction pressure of the compressor, a detector for
1. A method of starting a heat source apparatus that includes a compressor, a condenser, an electronic expansion valve, an evaporator, a detector for detecting temperature of refrigerant at a suction-side of the compressor, a detector for detecting suction pressure of the compressor, a detector for detecting temperature of refrigerant at a discharge-side of the compressor, and a detector for detecting discharge pressure of the compressor, the method comprising the following steps: opening the electronic expansion valve to a predetermined opening degree at the time of starting of the heat source apparatus;driving the electronic expansion valve in a direction in which the electronic expansion valve is closed, until a compressor discharge-side refrigerant super-heat reaches a predetermined temperature for the compressor discharge-side refrigerant super-heat; andcontrolling the opening degree of the electronic expansion valve so that the compressor suction-side refrigerant super-heat reaches a predetermined temperature for the compressor suction-side refrigerant super-heat after the compressor discharge-side refrigerant super-heat has reached the predetermined temperature for the compressor discharge-side refrigerant super-heat;wherein said step of driving the electronic expansion valve includes a step of slowing down a closing speed of the electronic expansion valve as the compressor discharge-side refrigerant super-heat approaches the predetermined temperature for the compressor discharge-side refrigerant super-heat;wherein said slowing down a closing speed of the electronic expansion valve includes:driving the electronic expansion valve at a first speed in the closing direction until the compressor discharge-side refrigerant super-heat reaches a first temperature smaller than the predetermined temperature for the compressor discharge-side refrigerant super-heat, andafter the compressor discharge-side refrigerant super-heat has reached the first temperature, driving the electronic expansion valve at a second speed, slower than the first speed, until the compressor discharge-side refrigerant super-heat reaches the predetermined temperature for the compressor discharge-side refrigerant super-heat. 2. The method according to claim 1, wherein said slowing down a closing speed of the electronic expansion valve further includes: outputting a drive signal for closing the electronic expansion valve for a first period until the compressor discharge-side refrigerant super-heat reaches a first temperature smaller than the predetermined temperature for the compressor discharge-side refrigerant super-heat, andafter the compressor discharge-side refrigerant super-heat has reached the first temperature, outputting a drive signal for closing the electronic expansion valve for a second period, longer than the first period, until the compressor discharge-side refrigerant super-heat reaches the predetermined temperature for the compressor discharge-side refrigerant super-heat. 3. The method according to claim 1, wherein during said controlling the opening degree of the electronic expansion valve, and wherein when a temperature of the compressor discharge-side refrigerant super-heat exceeds a predetermined temperature range for the compressor discharge-side refrigerant super-heat,the opening degree of the electronic expansion valve is controlled such that the compressor discharge-side refrigerant super-heat temperature is disposed within the predetermined temperature range for the compressor discharge-side refrigerant super-heat; andwherein when a temperature of the compressor suction-side refrigerant super-heat exceeds a predetermined temperature range for the compressor suction-side refrigerant super-heat,the opening degree of the electronic expansion valve is controlled such that the compressor suction-side refrigerant super-heat temperature is disposed within the predetermined temperature range for the compressor suction-side refrigerant super-heat. 4. The method according to claim 1, wherein during the driving of the electronic expansion valve, whenever a suction pressure of the compressor becomes less than a predetermined value for the suction pressure of the compressor, the step of driving the electronic expansion valve in a direction in which the electronic expansion valve is closed is interrupted, the electronic expansion valve is driven in an opening direction of the electronic expansion valve to a predetermined opening degree, and then the opening degree of the electronic expansion valve is controlled until the temperature of a compressor suction-side refrigerant super-heat becomes a predetermined temperature of the compressor suction-side refrigerant super-heat. 5. The method according to claim 1, wherein the compressor comprises a screw compressor. 6. The method according to claim 1, wherein the refrigerant comprises a pseudo azeotropic refrigerant or a single refrigerant. 7. The method according to claim 3, wherein the opening degree of the electronic expansion valve is controlled such that the compressor suction-side refrigerant super-heat temperature is disposed within the predetermined temperature range for the compressor suction-side refrigerant super-heat,when the compressor discharge-side refrigerant super-heat temperature is disposed within the predetermined temperature range for the compressor discharge-side refrigerant super-heat. 8. A method of starting a heat source apparatus that includes a compressor, a condenser, an electronic expansion valve, an evaporator, a detector for detecting temperature of refrigerant at a suction-side of the compressor, a detector for detecting suction pressure of the compressor, a detector for detecting temperature of refrigerant at a discharge-side of the compressor, and a detector for detecting discharge pressure of the compressor, the method comprising the following steps: opening the electronic expansion valve to a predetermined opening degree at the time of starting of the heat source apparatus;driving the electronic expansion valve in a direction in which the electronic expansion valve is closed, until a compressor discharge-side refrigerant super-heat reaches a predetermined temperature for the compressor discharge-side refrigerant super-heat; andcontrolling the opening degree of the electronic expansion valve so that the compressor suction-side refrigerant super-heat reaches a predetermined temperature for the compressor suction-side refrigerant super-heat after the compressor discharge-side refrigerant super-heat has reached the predetermined temperature for the compressor discharge-side refrigerant super-heat;wherein said step of driving the electronic expansion valve includes a step of slowing down a closing speed of the electronic expansion valve as the compressor discharge-side refrigerant super-heat approaches the predetermined temperature for the compressor discharge-side refrigerant super-heat;wherein said controlling the opening degree of the electronic expansion valve includes:when at least one of: (1) a temperature of the compressor discharge-side refrigerant super-heat exceeds a predetermined temperature range for the compressor discharge-side refrigerant super-heat, and (2) a temperature of the compressor discharge-side refrigerant super-heat exceeds a predetermined temperature range for the compressor discharge-side refrigerant super-heat,changing the predetermined temperature for the compressor suction-side refrigerant super-heat used to control the opening degree of the electronic expansion valve, so that the temperature of the compressor suction-side refrigerant super-heat becomes equivalent to the temperature of the changed predetermined compressor suction-side refrigerant super-heat. 9. The method according to claim 8, wherein said slowing down a closing speed of the electronic expansion valve further includes: outputting a drive signal for closing the electronic expansion valve for a first period until the compressor discharge-side refrigerant super-heat reaches a first temperature smaller than the predetermined temperature for the compressor discharge-side refrigerant super-heat, andafter the compressor discharge-side refrigerant super-heat has reached the first temperature, outputting a drive signal for closing the electronic expansion valve for a second period, longer than the first period, until the compressor discharge-side refrigerant super-heat reaches the predetermined temperature for the compressor discharge-side refrigerant super-heat. 10. The method according to claim 8, wherein during said controlling the opening degree of the electronic expansion valve, and wherein when a temperature of the compressor discharge-side refrigerant super-heat exceeds a predetermined temperature range for the compressor discharge-side refrigerant super-heat,the opening degree of the electronic expansion valve is controlled such that the compressor discharge-side refrigerant super-heat temperature is disposed within the predetermined temperature range for the compressor discharge-side refrigerant super-heat; andwherein when a temperature of the compressor suction-side refrigerant super-heat exceeds a predetermined temperature range for the compressor suction-side refrigerant super-heat,the opening degree of the electronic expansion valve is controlled such that the compressor suction-side refrigerant super-heat temperature is disposed within the predetermined temperature range for the compressor suction-side refrigerant super-heat. 11. The method according to claim 8, wherein during the driving of the electronic expansion valve, whenever a suction pressure of the compressor becomes less than a predetermined value for the suction pressure of the compressor, the step of driving the electronic expansion valve in a direction in which the electronic expansion valve is closed is interrupted, the electronic expansion valve is driven in an opening direction of the electronic expansion valve to a predetermined opening degree, and then the opening degree of the electronic expansion valve is controlled until the temperature of a compressor suction-side refrigerant super-heat becomes a predetermined temperature of the compressor suction-side refrigerant super-heat. 12. The method according to claim 8, wherein the compressor comprises a screw compressor. 13. The method according to claim 8, wherein the refrigerant comprises a pseudo azeotropic refrigerant or a single refrigerant. 14. The method according to claim 10, wherein the opening degree of the electronic expansion valve is controlled such that the compressor suction-side refrigerant super-heat temperature is disposed within the predetermined temperature range for the compressor suction-side refrigerant super-heat,when the compressor discharge-side refrigerant super-heat temperature is disposed within the predetermined temperature range for the compressor discharge-side refrigerant super-heat.
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