This application is based upon and claims the benefit of priority from Japanese Patent Application No. 2014-087921, filed Apr. 22, 2014, the entire contents of which are incorporated herein by reference.
Embodiments described herein relate generally to a refrigeration cycle apparatus which includes an accumulator, and a fusible plug is attached to a low-pressure-side pipe connected to the accumulator.
A refrigeration cycle apparatus is known in which a compressor, a condenser, a pressure reducing unit and an evaporator are connected to each other by pipes, and an accumulator and a fusing plug are provided at a low-pressure-side pipe between the evaporator and the compressor (Jpn. Pat. Appln. KOKAI Publication No. 2013-228129).
The fusible plug is provided to prevent the internal temperature and pressure of the accumulator from rising to high values because of an abnormal rise of atmospheric temperature which is caused by, for example, a fire, to thereby prevent the accumulator from being broken. When a detected temperature reaches a predetermined value, the fusible plug fuses to open the low-pressure-side pipe or the accumulator to the atmosphere. As a result, a high-pressure gas in the accumulator flows out therefrom to the outside, thus preventing the accumulator from being broken.
In a heat-pump-type refrigeration cycle apparatus which can perform heating, during heating, frost gradually adheres to a surface of an outdoor heat exchanger functioning as an evaporator, and a heat-exchange efficiency of the outdoor heat exchanger decreases if no countermeasures are taken. In view of this, in the heat-pump-type refrigeration cycle apparatus, if frost adheres to the outdoor heat exchanger, a so-called reverse-cycle defrosting operation is performed. In this defrosting operation, the flowing direction of refrigerant is reversed, and refrigerant discharged from the compressor is directly supplied to the outdoor heat exchanger.
However, if the reverse-cycle defrosting operation is performed, a low-pressure gas refrigerant flows into a pipe in which a high-pressure gas refrigerant flows to increase the temperature of the pipe to a high level. While the low-pressure gas refrigerant is absorbing heat of the pipe having a high temperature, its temperature of the low-pressure gas refrigerant rises to a high temperature. The low-pressure gas refrigerant having a high temperature flows into the low-pressure-side pipe. At this time, heat of the refrigerant flowing into the low-pressure-side pipe is transmitted to the fusible plug. Thus, although the inner pressure of the accumulator is not abnormal, there is a possibility that the fusible plug will fuse.
In general, according to one embodiment, a refrigeration cycle apparatus includes:
a refrigeration cycle in which a compressor, a condenser, a pressure reducing unit and an evaporator are connected to each other by pipes, and an accumulator is provided at a low-pressure-side pipe between the evaporator and the compressor;
a fusible plug attached to the low-pressure-side pipe; and
a heat-quantity reduction member which reduces quantity of heat to be transmitted to the fusible plug.
The first embodiment will be explained with reference to the accompanying drawings.
A packed valve 3 is connected to a discharge port of a compressor 1 by a pipe, with a four-way valve 2 interposed between the packed valve 3 and the compressor 1. Also, ends of a plurality of indoor heat exchangers 22 are connected to the packed valve 3 by pipes on their one side, with a gas-side pipe 11 and flow regulating valves 21 interposed between the indoor heat exchangers 22 and the packed valve 3. The other ends of the indoor heat exchangers 22 are connected to a packed valve 4, with a liquid-side pipe 12 interposed between the indoor heat exchangers 22 and the packed valve 4. Also, the packed valve 4 is connected to one of ends of an outdoor heat exchanger 6 by a pipe, with an expansion valve 5 interposed between the packed valve 4 and the outdoor heat exchanger 6. The other end of the outdoor heat exchanger 6 is connected to an intake of the compressor 1 by a pipe, with the four-way valve 2 and an accumulator 7 interposed between the outdoor heat exchanger 6 and the compressor 1. Furthermore, a fusible plug 9 is attached to a low-pressure-side pipe 8 between the four-way valve 2 and the accumulator 7.
The compressor 1, the four-way valve 2, the packed valves 3 and 4, the expansion valve 5, the outdoor heat exchanger 6, the accumulator 7, the low-pressure-side pipe 8 and the fusible plug 9 are provided in an outdoor unit A. The flow regulating valves 21 are provided in indoor units B1 to Bn, respectively, and the indoor heat exchangers 22 are also in the indoor units B1 to Bn, respectively.
As shown in
If the temperature and pressure of the inside of the accumulator 7 both rise to high levels, and the temperature of the low-pressure-side pipe 8 also rises, heat generated by the rising temperature of the low-pressure-side pipe 8 is transmitted to the fusible plug 9. The metallic plug portion 9c fuses when a detected temperature reaches a predetermined value (melting point). When the metallic plug portion 9c fuses, the inside of the low-pressure-side pipe 8 is opened to the atmosphere through the fusible plug 9. As a result, a high-temperature, high-pressure gas in the accumulator 7 flows out therefrom to the outside through the low-pressure-side pipe 8 and the fusible plug 9.
After the fusible plug 9 is fixed to the low-pressure-side pipe 8, as shown in
After the endothermic member 31 is wound on the fusible plug 9, a sheet-like endothermic member (second endothermic member) 32, which is another heat-quantity reduction member, is also wound on the endothermic member 31. One end portion of the endothermic member 32 (which is an end portion thereof in the axial direction of the fusible plug 9) is also in contact with the peripheral surface of the low-pressure-side pipe 8.
After the endothermic members 31 and 32 are wound in the above manner, elastic bands 33 and 34 are wound and tightened on the endothermic member 32. As a result, the endothermic members 31 and 32 are fixed to the fusible plug 9. The fixed endothermic members 31 and 32 cover the pipe-like portion 9a and the annular portion 9b, but do not cover the metallic plug portion 9c.
The endothermic members 31 and 32 are formed of, for example, butyl rubber, which is a combination of isobutylene and isoprene, and absorbs heat. The endothermic members 31 and 32 are wound on the pipe-like portion 9a and the annular portion 9b of the fusible plug 9, to thereby reduce the quantity of heat to be transmitted from the low-pressure-side pipe 8 to the metallic plug portion 9c of the fusible plug 9.
The quantity of heat to be transmitted from the low-pressure-side pipe 8 to the metallic plug portion 9c of the fusible plug 9 can be increased or decreased to an optimal value by adjusting the thicknesses and areas of the endothermic members 31 and 32 and also changing the number of circles in which the endothermic members 31 and 32 are wound.
Next, the operation and advantage of the heat-pump-type refrigeration cycle and the operation of the fusible plug 9 will be explained.
During heating, as indicated by solid arrows in
During air-cooling, as indicated by a dashed arrow, the gas refrigerant discharged from the compressor 1 flows into the outdoor heat exchanger (condenser) 6 through the four-way valve 2. The refrigerant flowing in the outdoor heat exchanger 6 radiates heat to outside air and condenses. A liquid refrigerant flowing out from the outdoor heat exchanger 6 passes through the expansion valve 5, the packed valve 4, the packed valve 3 and the liquid-side pipe 12, and flows into the indoor heat exchangers (evaporators) 22. The liquid refrigerant flowing in each of the indoor heat exchangers 22 takes heat from indoor air and evaporates. A gas refrigerant flowing out from each of the indoor heat exchangers 22 passes through the gas-side pipe 11, the packed valve 3, the four-way valve 2, the low-pressure-side pipe 8 and the accumulator 7, and is sucked to the compressor 1.
Furthermore, during heating, frost gradually adheres to a surface of the outdoor heat exchanger 6 serving as the evaporator, and the heat-exchange efficiency of the outdoor heat exchanger 6 decreases if no countermeasures are taken. In view of this point, formation of frost on the outdoor heat exchanger 6 is monitored based on the temperature of the outdoor heat exchanger 6. If the amount of frost forming on the outdoor heat exchanger 6 reaches a predetermined value or more, a flow path to be set by the four-way valve 2 is switched, and a reverse-cycle defrosting operation is performed in which refrigerant flows in a direction indicated by dashed arrows. To be more specific, a gas refrigerant having a high temperature, which is discharged from the compressor 1, passes through the four-way valve 2, and then directly flows into the outdoor heat exchanger 6, as a result of which the frost on the outdoor heat exchanger 6 thaws because the gas refrigerant has a high temperature. If the temperature of the outdoor heat exchanger 6 rises because of the frost thawing, the reverse-cycle defrosting operation is stopped, and an ordinary heating operation is restarted.
Where in the gas-side pipe 11, a high-pressure gas refrigerant flows to cause the gas-side pipe 11 to have a high temperature (for example, 105° C.), when the reverse cycle operation is started by switching the flow path to be set by the four-way valve 2, a low-pressure gas flows into the gas-side pipe 11 having the high temperature. The low-pressure gas refrigerant flowing in the gas-side pipe 11 absorbs heat of the gas-side pipe 11 having the high temperature, and thus its temperature rises to the high level. The gas refrigerant then passes through the packed valve 3 and the four-way valve 2 to flow into the low-pressure-side pipe 8. As a result, the temperature of the low-pressure-side pipe 8 rises to, for example, approximately 72° C. due to the gas refrigerant whose temperature rises to a high level. If heat of the low-pressure-side pipe 8 is transmitted to the metallic plug portion 9c of the fusible plug 9 without taking countermeasures, there is a possibility that the metallic plug portion 9c will fuse, although the internal pressure of the accumulator 7 does not abnormally rise.
It should be noted that the longer the gas-side pipe 11, the larger the quantity of heat absorbed by the low-pressure gas, and the greater the degree to the temperature of the low-pressure-side pipe 8 rises.
However, the quality of heat transmitted from the low-pressure-side pipe 8 to the metallic plug portion 9c of the fusible plug 9 is reduced by a heat absorbing action of the endothermic members 31 and 32 wound on the fusible plug 9. Therefore, even if the temperature of the low-pressure-side pipe 8 rises at the time of starting the reverse-cycle defrosting operation, the metallic plug portion 9c does not fuse. It is therefore possible to prevent the metallic plug portion 9c from unnecessarily fusing.
On the other hand, if an ambient atmospheric temperature of the accumulator 7 abnormally rises, or an internal pressure of the accumulator 7 abnormally rises, the temperature of the low-pressure-side pipe 8 more greatly rises than at the time of staring the reverse-cycle defrosting operation. Thus, regardless of the heat absorbing action of the endothermic members 31 and 32, the temperature of the metallic plug portion 9c reaches a predetermined value (melting point), and thus the metallic plug portion 9c fuses. Due to fusing of the metallic plug portion 9c, the inside of the low-pressure-side pipe 8 is opened to the atmosphere through the fusible plug 9. Therefore, a high-temperature, high-pressure gas in the accumulator 7 flows out therefrom to the outside through the low-pressure-side pipe 8 and the fusible plug 9, thus preventing the accumulator 7 from being broken.
The thickness, the area of each of the endothermic members 31 and 32 and the number of circles in which each endothermic member is wound are set to optimal values ascertained in advance by an experiment, so that the metallic plug portion 9c reliably fuses when the ambient atmospheric temperature of the accumulator 7 abnormally rises or the internal pressure of the accumulator 7 abnormally rises, and the metallic plug portion 9c does not fuse even when the temperature of the low-pressure-side pipe 8 rises at the time of starting the reverse-cycle defrosting operation.
In the second embodiment, as shown in
Then, the bands 33 and 34 are wound and tightened on the endothermic member 32. Also, when the band 34 is tightened, a distal end of the end portion of the low-pressure-side pipe 8, which is wound in a single circle with the endothermic member 32, is bound by the band 34. Due to winding and tightening of the bands 33 and 34, the endothermic members 31 and 32 are firmly fixed to the fusible plug 9 and the low-pressure-side pipe 8.
The other structural features of the second embodiment are the same as those of the first embodiment.
The end portion of the endothermic member 32 is also wound on the low-pressure-side pipe 8. Thus, the endothermic members 31 and 32 function not only as heat-quantity reduction members, but as shock-absorbing members which absorb vibration created in an operation or movement such as transport of the outdoor unit A. In such a manner, since vibration is absorbed, it is possible to prevent a fatigue breaking of an attachment portion of the fusible plug 9. The other advantages of the second advantage are the same as those of the first embodiment.
In the third embodiment, as shown in
In general, a capillary tube is a small tube wound in circles, and used as a pressure reducing mechanism for a refrigeration cycle. In the third embodiment, the capillary tube 42 is provided between the low-pressure-side pipe 8 and the fusible plug 9, to thereby reduce the quantity of heat to be transmitted from the low-pressure-side pipe 8 to the fusible plug 9.
It should be noted that the capillary tube 42 is located along the pipe-like portion 9a of the fusible plug 9. Furthermore, a band (first band) 35 is wound and tightened on the capillary tube 42 and the pipe-like portion 9a. Due to this tightening of the band 35, the capillary tube 42 and the pipe-like portion 9a of the fusible plug 9 are bound together.
Furthermore, an adiathermanous tube 43 is provided on an outer peripheral surface of the low-pressure-side pipe 8, and the pipe-like portion 9a of the fusible plug 9 is provided on an outer peripheral surface of the adiathermanous tube 43. Then, a band (second band) 36 is wound and tightened on the adiathermanous tube 43 and the pipe-like portion 9a of the fusible plug 9. Due to tightening of the band 36, the pipe-like portion 9a and the adiathermanous tube 43 are bound together, and also the capillary tube 42 and the fusible plug 9 are held on the low-pressure-side pipe B.
The other structural features of the third embodiment are the same as those of the first embodiment.
Where in the gas-side pipe 11, a high-pressure gas flows to cause the gas-side pipe 11 to have a high temperature (e.g., 105° C.), when the reverse-cycle defrosting operation is started by switching the flow path to be set by the four-way valve 2, a low-pressure gas refrigerant flows into the gas-side pipe 11 having the high temperature. The low-pressure gas refrigerant flowing into the gas-side pipe 11 absorbs heat of the gas-side pipe 11 having the high temperature, and its temperature thus rises to a high level. It then passes through the packed valve 3 and the four-way valve 2, and flows into the low-pressure-side pipe 8. Because the gas refrigerant has a high temperature, the temperature of the low-pressure-side pipe 8 rises.
At this time, the quantity of heat transmitted from the low-pressure-side pipe 8 to the fusing plug 9 through the pipe 41 and the capillary tube 42 is reduced by a thermal resistance action of the capillary tube 42. Also, heat to be directly transmitted from the outer peripheral surface of the low-pressure-side pipe 8 to the fusible plug 9 is shut out by the adiathermanous tube 43.
Therefore, at the time of starting the reverse-cycle defrosting operation, even if the temperature of the low-pressure-side pipe 8 rises, the metallic plug portion 9c does not fuse. Thus, the metallic plug portion 9c is prevented from unnecessarily fusing.
On the other hand, when the ambient atmospheric temperature of the accumulator 7 rises abnormally or the internal pressure of the accumulator 7 abnormally rises, the temperature of the low-pressure-side pipe 8 more greatly rises than at the time of starting the reverse-cycle defrosting operation. Thus, regardless of the thermal resistance action of the capillary tube 42, the temperature of the metallic plug portion 9c reaches a predetermined value (melting point), and the metallic plug portion 9c fuses. Because of the fusing of the metallic plug portion 9c, the inside of the low-pressure-side pipe 8 is opened to the atmosphere through the pipe 41, the capillary tube 42 and the fusible plug 9. Therefore, a high-pressure and high-temperature gas in the accumulator 7 flows out therefrom to the outside through the low-pressure-side pipe 8, the pipe 41, the capillary tube 42 and the fusible plug 9. Thus, the accumulator 7 is prevented from being broken.
The thickness and length of the capillary tube 42 are set to optimal values ascertained in advance by an experiment, so that the metallic plug portion 9c reliably fuses when the ambient atmospheric temperature of the accumulator 7 rises abnormally or the internal pressure of the accumulator 7 rises abnormally, and the metallic plug portion 9c does not fuse even when the temperature of the low-pressure-side pipe 8 rises at the time of starting the reverse-cycle defrosting operation.
In the explanations of the above embodiments, the refrigeration cycle apparatus provided in the air conditioner is referred to by way of example. However, the embodiments can also be applied to a refrigeration cycle apparatus provided in another apparatus such as a hot-water supply apparatus.
Also, in each of the above embodiments, as the heat-quality reduction members, the sheet-like endothermic members 31 and 32 and the capillary tube 42 are applied; however, another member may be applied as long as it has a heat-quantity reduction function.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
Number | Date | Country | Kind |
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2014-087921 | Apr 2014 | JP | national |