초록 ▼

Provided is an air conditioner, particularly, an apparatus and method for controlling a super-heating degree in a heat pump system for preventing a liquid refrigerant from flowing into a compressor. The method includes: operating the heat pump system; receiving a present outdoor temperature, a pipe

Provided is an air conditioner, particularly, an apparatus and method for controlling a super-heating degree in a heat pump system for preventing a liquid refrigerant from flowing into a compressor. The method includes: operating the heat pump system; receiving a present outdoor temperature, a pipe absorption temperature and a low pressure value of a compressor, respectively; computing a present absorption super-heating degree from a difference between the absorption temperature of the compressor and a saturated temperature at a low pressure side; and comparing an targeted absorption super-heating degree set in advance, with the computed present absorption super-heating degree according to the received outdoor temperature, and controlling the system so that the present absorption super-heating degree may follow the targeted absorption super-heating degree.

대표청구항 ▼

What is claimed is: 1. A method for controlling a super-heating degree in a heat pump system, comprising: operating the heat pump system; receiving a low pressure at a low pressure part of a compressor, a high pressure at a high pressure part of the compressor, and a discharging temperature of the

What is claimed is: 1. A method for controlling a super-heating degree in a heat pump system, comprising: operating the heat pump system; receiving a low pressure at a low pressure part of a compressor, a high pressure at a high pressure part of the compressor, and a discharging temperature of the compressor; computing an absorption temperature of the compressor by adding a stored absorption super-heating degree value at the low pressure part to a saturated temperature value of a refrigerant at the low pressure part; computing a reversible compression point which would result from a reversible compressing process being performed on a refrigerant at the absorption temperature; computing a present discharging super-heating degree from a difference between a reversible compression temperature at the reversible compression point and the received discharging temperature of the compressor; and controlling the system so that the present discharging super-heating degree of the compressor remains within a predetermined range. 2. The method according to claim 1, wherein the absorption temperature of the compressor at the low pressure side is obtained by computing a saturated temperature of the refrigerant from a low pressure sensor of the compressor and adding an absorption super-heating degree to the computed saturated temperature of the refrigerant. 3. The method according to claim 2, wherein the absorption super-heating degree is a value that satisfies a condition for maintaining the refrigerant absorbed to the compressor in a super-heated state. 4. The method according to claim 2, wherein the absorption super-heating degree is set to a value that is inversely proportional to an outdoor temperature. 5. The method according to claim 1, wherein if the absorption temperature of the compressor is computed, a reversible compressing process is performed with use of a position of the refrigerant used, on a p-h chart, for a starting point, so that the reversible compression point at the high pressure side and the reversible compression temperature at that point are computed. 6. The method according to claim 1, wherein if the present discharging super-heating degree at the high pressure side is not within a predetermined range, an openness of an outdoor EEV (Electronic Expansion Valve) is adjusted. 7. The method according to claim 5, wherein if the present discharging super-heating degree is less than a predetermined targeted range, an openness of an outdoor EEV is reduced, and if the present discharging super-heating degree is greater than a predetermined targeted range, the openness of the outdoor EEV is increased. 8. The method according to claim 1, wherein for control of the discharging super-heating degree of the compressor, data received from an absorption sensor at the low pressure side of the compressor, a high pressure sensor at a high pressure side of the compressor, and a discharging pipe temperature sensor, are used. 9. An apparatus for controlling a super-heating degree in a heat pump system, comprising: one or more indoor units; one or more outdoor units each including a compressor, a channel switching valve that selectively switches a channel of a refrigerant depending on cooling and heating modes, an outdoor heat exchanger that exchanges heat with outdoor air, and an outdoor EEV (Electronic Expansion Valve); low and high pressure sensors that detect a low and a high pressure of the compressor, respectively; a discharging pipe temperature sensor that detects a discharging temperature of the compressor; an absorption temperature detector that computes an absorption temperature of the compressor by adding a stored absorption super-heating degree value at a low pressure part to a saturated temperature value of refrigerant at the low pressure part; a discharging super-heating degree detector that computes a reversible compression temperature which would result from a reversible compressing process being performed on a refrigerant at the absorption temperature, and a discharging temperature at a high pressure part of the compressor, from the absorption temperature of the compressor, and computes a present discharging super-heating degree from a difference between the discharging temperature of the compressor and the reversible compression temperature; and a controller that compares the present discharging super-heating degree computed by the discharging super-heating degree detector, with a targeted discharging super-heating degree set in advance, and controls the system so that the present discharging super-heating degree follows the targeted discharging super-heating degree. 10. The apparatus according to claim 9, wherein the controller adjusts an openness of the outdoor EEV (Electronic Expansion Valve) so that the present discharging super-heating degree is in agreement with the targeted discharging super-heating degree. 11. The apparatus according to claim 10, wherein the controller reduces the openness of the outdoor EEV if the present discharging super-heating degree is less than the targeted discharging super-heating degree, and increases the openness of the outdoor EEV if the present discharging super-heating degree is greater than the targeted discharging super-heating degree. 12. The apparatus according to claim 9, wherein the absorption super-heating degree is set to a high value as an outdoor temperature is low. 13. The apparatus according to claim 9, wherein the controller reduces an openness of an outdoor EEV (Electronic Expansion Valve) if an outdoor temperature is low and increases the openness of the outdoor EEV if the outdoor temperature is high. 14. The apparatus according to claim 9, wherein the controller adjusts an openness of an outdoor EEV (Electronic Expansion Valve) within a range that satisfies both the absorption super-heating degree and the discharging super-heating degree.