JP2005291696A - Condenser, heat pump, heat utilization device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a condenser that can obtain high energy efficiency and is excellent in space efficiency and maintainability, and a heat pump and a heat utilization device using the same.
In a condenser 100 that cools and liquefies a refrigerant R compressed at high temperature and high pressure, a refrigerant pipe 20 through which the refrigerant R flows, and a water cooling section 30 that cools the refrigerant pipe 20 by attaching water to the refrigerant pipe 20; And an air cooling unit 40 that cools the refrigerant pipe 20 to which water has adhered by blowing the air A.
[Selection] Figure 1

Description

  The present invention relates to a condenser that cools and liquefies refrigerant compressed to high temperature and pressure.

A heat pump is a device that pumps heat from a low-temperature object and applies heat to a high-temperature object by a cycle consisting of evaporation, compression, condensation, and expansion processes. Since energy utilization efficiency is relatively high, it is often used in heat utilization devices such as air-conditioning devices and refrigeration devices having a cooling / heating function.
In the case of an air conditioner, the heat absorbed at the time of evaporation is supplied from indoor air during cooling, and is used during heating. Supplied from the atmosphere. Further, in the case of air conditioning equipment, the heat generated during condensation is released to the atmosphere during cooling and released indoors during heating using the fact that heat is generated when the refrigerant condenses.
The heat pump is composed of a compressor, a condenser, an expansion valve, an evaporator, and piping connecting them, and as a refrigerant involved in heat transfer, for example, ammonia or the like is used in addition to a chlorofluorocarbon compound. The condenser is an air-cooling type that uses air as a coolant for cooling the refrigerant to directly exchange heat between the refrigerant and the atmosphere, and a coolant that uses water as an intermediary medium to heat the refrigerant and the atmosphere. There is a water-cooled type that exchanges indirectly. In addition, a method using both air cooling and water cooling has been proposed.
Japanese Patent Laid-Open No. 9-269154 JP 11-51503 A

In general, the air-cooled type performs heat exchange using fins (heat sinks), so that the apparatus is small in size and has excellent maintainability because it requires almost no maintenance. However, there is a problem that a coefficient of performance (COP) indicating energy use efficiency (ratio of output heat quantity to input power) is about 3, which is lower than that of the water-cooled type.
On the other hand, in the water-cooled type, COP is about 6 because heat is exchanged with water as an intermediary medium, and energy utilization efficiency is excellent. However, since equipment such as a cooling tower is required, the apparatus becomes large. Further, since maintenance of the cooling water is necessary, there is a problem that the maintainability is inferior and the running cost is high because the consumption of the cooling water is large.
In addition, air-cooled and water-cooled systems are simply lined up with air-cooled and water-cooled equipment, so air-cooled issues (larger equipment, poor maintainability, and increased running costs) It has not yet been solved.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to provide a condenser that can obtain high energy efficiency and is excellent in space efficiency and maintainability, a heat pump using the condenser, and a heat utilization device. To do.

The condenser, heat pump, and heat utilization apparatus according to the present invention employ the following means in order to solve the above-described problems.
In the first aspect of the invention, in the condenser (100, 300) that cools and liquefies the refrigerant (R) compressed to high temperature and high pressure, the refrigerant pipe (20, 320) through which the refrigerant flows and water ( A water-cooling part (30, 330) for attaching and cooling W) and an air-cooling part (40, 340) for blowing and cooling air (A) to the refrigerant pipe to which water adheres are provided.
According to this invention, since the refrigerant is simultaneously cooled by water and air, the energy utilization efficiency of the condenser can be improved.

The refrigerant pipe (20, 320) includes a plurality of refrigerant branch pipes (21, 321) extending in the vertical direction or the horizontal direction, and realizes efficient cooling of the refrigerant while matching the installation location. Thus, the extending direction of the refrigerant pipe can be set.
Further, the water cooling part (30, 330) is arranged above the refrigerant pipe (20, 320) through which the refrigerant (R) flows, and the air cooling part (40, 340) is arranged below or on the side of the refrigerant pipe. In the thing, a refrigerant | coolant piping can be efficiently cooled from an up-down direction. Furthermore, since the water cooling part and the air cooling part can be arranged efficiently, the apparatus can be configured compactly. In particular, water can be supplied to the refrigerant pipe by gravity by disposing the water cooling part above the refrigerant pipe.
Further, in the case where the water cooling part (30) includes the water sprinkling part (31) for adhering water (W) substantially uniformly toward the refrigerant pipe (20), the water is equally distributed over the whole refrigerant pipe, The refrigerant piping can be cooled evenly.
Moreover, in the case where the water sprinkling part (31) includes a water distribution pipe (31) formed with a plurality of water spray holes (32) for spraying water (W) toward the refrigerant pipe (20), water is supplied to the refrigerant pipe. Can be released almost uniformly.
Moreover, in the case where the water sprinkling part (31) includes the dropping member (332) for dropping water (W) toward the refrigerant pipe (320), water can be discharged substantially uniformly toward the refrigerant pipe.
In addition, in the case where the air cooling unit (40, 340) includes a blowing unit (42, 341) that blows air (A) substantially uniformly toward the refrigerant pipe (20, 320), the air is equal to the entire refrigerant pipe. The refrigerant pipes can be evenly cooled so as to spread.
Further, when the air (A) blown to the refrigerant pipe (20) is self-cooled before contacting the refrigerant pipe, the temperature of the air contacting the refrigerant pipe can be lowered.
In addition, in the case where the air blowing section (42) includes an air feeding pipe (42) in which a plurality of air vent holes (44) for releasing air (A) is formed, by flowing air around the air feeding pipe, Since the air pipe is cooled, the air flowing in the air pipe can be easily self-cooled.
In addition, when the air (A) blown to the refrigerant pipe (20) has a temperature gradient along the air flow direction in the air pipe (42), for example, the temperature from the upstream to the downstream of the refrigerant pipe By making the temperature gradient so as to be low, it can be gradually cooled as the refrigerant flows.
In addition, the air feeding tube (42) includes a plurality of air feeding branches (43) having different lengths, and the air feeding pipes are arranged so as to be stacked on top or side in the order of short length. According to the structure, the contact area between the air feeding tube and the air can be adjusted along the flow direction.
Further, in the case where the air feeding pipe (42) includes a plurality of partition plates (46) that maintain the temperature gradient of the air (A) blown to the refrigerant pipe (20), the heat change of the air with the temperature gradient added. Therefore, the refrigerant can be efficiently cooled.

  A second invention is a heat pump (HP, HP2, HP3) having a condenser, an expansion valve (110), an evaporator (120), and a compressor (130). The condenser (100, 300) was used. According to the present invention, since a condenser having high thermal efficiency, excellent maintainability, and a compact size is used, the efficiency of the heat pump is improved, and the apparatus cost and running are suppressed.

  In the third invention, the heat pump (HP, HP2, HP3) of the second invention is used in the heat utilization device (C, C2, C3) that transfers heat to and from the heat source. According to the present invention, the energy efficiency of a heat utilization device such as an air conditioner or a refrigeration device having an air conditioning function can be improved.

According to the present invention, the following effects can be obtained.
1st invention is a condenser which cools and liquefies the refrigerant compressed at high temperature and high pressure, a refrigerant pipe through which the refrigerant flows, a water cooling part for cooling by attaching water (W) to the refrigerant pipe, water And an air cooling section that cools the refrigerant piping to which air is attached by blowing air.
As a result, the energy utilization efficiency of the condenser is improved, and a cooling tower is not required, so that the apparatus can be made more compact than the conventional water-cooled type.

Further, since the refrigerant pipe is provided with a plurality of refrigerant branch pipes extending in the vertical direction or the horizontal direction, the refrigerant pipe is extended in accordance with the installation location while realizing efficient cooling of the refrigerant. Can be set.
In addition, since the water cooling part is arranged above the refrigerant pipe through which the refrigerant flows, and the air cooling part is arranged below or on the side of the refrigerant pipe, the refrigerant pipe is efficiently cooled and the apparatus is made compact. Can be achieved.
Moreover, since the water cooling part is provided with the water sprinkling part which adheres water substantially uniformly toward the refrigerant pipe, the refrigerant pipe is cooled uniformly and the cooling efficiency is improved.
In addition, since the water sprinkling part is provided with a water distribution pipe formed with a plurality of water sprinkling holes for spraying water toward the refrigerant pipe, the water circulates in the entire refrigerant pipe and evaporates. Is unnecessary, and an increase in device cost can be suppressed. Moreover, since water is not circulated, running cost can be suppressed.
In addition, since the water sprinkling part is provided with a dripping member for dripping water toward the refrigerant pipe, the water spreads evenly over the entire refrigerant pipe, thus eliminating the need for a water circulation device and increasing the equipment cost. Can be suppressed. Moreover, since water is not circulated, running cost can be suppressed.
Moreover, since the air cooling part is provided with the ventilation part which blows air substantially uniformly toward the circumference | surroundings of refrigerant | coolant piping, refrigerant | coolant piping is cooled equally and cooling efficiency improves.
Further, since the air blown to the refrigerant pipe is self-cooled before coming into contact with the refrigerant pipe, the temperature difference between the air and the refrigerant is widened, so that the refrigerant can be cooled more efficiently.
In addition, since the air blowing section is provided with an air pipe having a plurality of air holes for releasing air, the air can be easily self-cooled with a simple structure. The cooling efficiency can be improved without increasing.
In addition, since the air blown to the refrigerant pipe has a temperature gradient along the air flow direction in the air pipe, the refrigerant can be cooled more efficiently by providing the temperature gradient.
In addition, since the air feeding pipe includes a plurality of air feeding pipes having different lengths, and the air feeding pipes are arranged so as to overlap each other in the order of short length, the air feeding pipe is arranged in a simple structure. Since the contact area between the feeding pipe and the air can be adjusted along the flow direction, the cooling efficiency can be improved without increasing the device cost.
In addition, since the air feeding pipe is provided with a plurality of partition plates that maintain the temperature gradient of the air blown to the refrigerant pipe, the refrigerant can be cooled more efficiently and the running cost can be suppressed.
Further, when the cycle of the heat pump is reversed and used for heating or heating, the watering can be stopped and the condenser 100 can be used as a heat exchanger (evaporator) for absorbing heat from the atmosphere.

  In the second invention, in the heat pump having the condenser, the expansion valve, the evaporator, and the compressor, the condenser of the first invention is used as the condenser. Thereby, since the heat efficiency is high, the maintainability is excellent, and the compact condenser is used, the efficiency of the heat pump is improved, and the apparatus cost and running are suppressed. Moreover, it can be favorably applied to a small-scale heat pump.

  In a third aspect of the present invention, the heat pump according to the second aspect of the present invention is used in a heat utilization device that transfers heat to and from a heat source. Thereby, the energy efficiency of heat | fever utilization apparatuses, such as an air conditioning apparatus which has an air-conditioning function, and a freezing apparatus, can be improved. In particular, it can be favorably applied to a small-scale heat utilization apparatus.

Hereinafter, embodiments of a condenser, a heat pump, and a heat utilization device of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic cross-sectional view showing a condenser 100 according to the first embodiment of the present invention. 2 is a cross-sectional view taken along a line PP in FIG. 1, and FIG. 3 is a cross-sectional view taken along a line QQ in FIG.
The condenser 100 cools and liquefies the refrigerant R compressed at high temperature and high pressure, and is opposed to the rectangular columnar container 10 extending in the horizontal direction from the longitudinal end surface (side wall 10a) of the container 10. A refrigerant pipe 20 extending through the container 10 toward the end surface (side wall 10b), a water cooling unit 30 disposed above the refrigerant pipe 20 in the container 10, and a refrigerant pipe 20 in the container 10 The air-cooling part 40 arrange | positioned below this.
And in the container 10, the water W is sprayed from the water cooling part 30 with respect to the refrigerant | coolant piping 20 through which the refrigerant | coolant R flows, and the air R is simultaneously sprayed from the air cooling part 40, and the refrigerant | coolant R in the refrigerant | coolant piping 20 is thereby made. To be cooled.

The refrigerant pipe 20 is a pipe through which the refrigerant R compressed to a high temperature and high pressure flows in the container 10, and includes a plurality of refrigerant branch pipes 21 having the same shape. That is, the refrigerant pipe 20 is branched (divided) from a single pipe 22 to a plurality of refrigerant branch pipes 21 having the same shape in the vicinity (upstream side) of the side wall 10a, and further in the vicinity of the side wall 10b (downstream side). It is integrated (joined) into the pipe 23. In addition, the plenum parts 24 and 25 which are once filled with the refrigerant R are provided in the branch part and the integration part of the refrigerant pipe 20, and the flow of the refrigerant R is made smooth.
As a result, the refrigerant R fed under pressure in the pipe 22 is divided into a plurality of refrigerant branch pipes 21 via the plenum portion 24. Then, when passing through the refrigerant branch pipe 21 (inside the container 10) (flowing from the left hand to the right hand in the drawing), it is cooled and liquefied by the water cooling section 30 and the air cooling section 40, and further pumped from the pipe 23 via the plenum section 25. Is done.
The refrigerant R may be any of, for example, chlorofluorocarbon, ammonia, hydrocarbon, and water.

The refrigerant pipe 20 is configured by the plurality of refrigerant branch pipes 21 in the container 10 to increase the contact area between the water W and the air A discharged from the water cooling unit 30 and the air cooling unit 40 and improve the cooling efficiency of the refrigerant R. It is for aiming at.
That is, as shown in FIG. 2, the plurality of refrigerant branch pipes 21 are arranged in a plurality of stages in the vertical and horizontal directions, and a gap is formed between the refrigerant branch pipes 21. Then, by flowing water W and air A through the gap, the heat of the refrigerant R flowing in the refrigerant branch pipe 21 is moved to the water W and air A, and the refrigerant R is cooled.
Therefore, for example, in addition to the case where a plurality of linear refrigerant branch pipes 21 having a diameter of about 10 mm are arranged (see FIG. 2), the refrigerant branch pipes 21 may meander in an S shape. In addition, a plurality of fins, protrusions, and the like may be provided on the surface of the refrigerant branch pipe 21.
In addition, as a forming material of the refrigerant | coolant branch pipe 21, it is preferable to use metals, such as copper and aluminum with high heat conductivity.

The water cooling unit 30 cools the refrigerant R by spraying water W onto the plurality of refrigerant branch pipes 21 from above, and the water W flows and the water W is substantially evenly directed toward the plurality of refrigerant branch pipes 21. It comprises a plurality of water distribution pipes 31 having a plurality of water spray holes 32 that discharge (water discharge).
A plurality of water distribution pipes (sprinkling units) 31 are arranged above the refrigerant branch pipe 21 in the container 10 in parallel with the refrigerant branch pipe 21, and water W is pumped into the water distribution pipe 31 from a water supply or the like. Water W is sprayed (sprinkled) from the water spray hole 32 toward the refrigerant branch pipe 21.
Since the water cooling part 30 should just discharge the water W so that it may spread over the whole refrigerant | coolant piping 20 (several refrigerant | coolant branch pipes 21), for example, arrange | position the some water distribution pipe 31 in the direction orthogonal to the refrigerant | coolant branch pipe 21. A plurality of water distribution pipes 31 may be arranged in a lattice pattern. In addition to providing a plurality of water spray holes 32 in the water distribution pipe 31, the water distribution pipe 31 may be formed of a porous body. In addition, a flat shelf with holes at regular intervals may be provided to spray water.
In addition, a drain port 14 for draining water W discharged from the water cooling unit 30 to the outside of the container 10 is formed on the bottom surface 10 c of the container 10.

The air cooling unit 40 cools the refrigerant pipe 20 (the plurality of refrigerant branch pipes 21) by blowing air A from below, and the fan 41 for pumping the air A and the air A to the plurality of refrigerant branch pipes 21. It is composed of an air feeding tube 42 and the like that spray substantially uniformly. The container 10 that houses the air cooling unit 40 and the like functions as a flow path for the air A that is blown onto the refrigerant pipe 20, and is also a component of the air cooling unit 40.
The container 10 has an air supply port 12 for taking outside air (air A) into the container 10 below the side wall 10a, and an exhaust port 13 for releasing the air A in the container 10 to the outside above the side wall 10b. . A fan 41 that pumps the air A is installed in the air supply port 12.
The air supply pipe (air blowing section) 42 is a pipe through which the air A taken in from the air supply port 12 flows, and is arranged below the refrigerant branch pipe 21 in the container 10 and has a different length and the refrigerant branch pipe 21. Are comprised of a plurality of air-feed branch pipes 43 in parallel. In addition, a plenum portion 45 that temporarily fills the air A is provided at a connecting portion between the air supply port 12 and the air feeding pipes 42 (a plurality of air feeding pipes 43). To be pumped.
As shown in FIG. 2, the plurality of air feeding and branching pipes 43 are arranged so as to overlap in three stages in the vertical direction. In addition, the length of the air supply branch pipes 43A, 43B, and 43C arranged in each stage is formed to be the same. Further, the air feeding pipes 43A, 43B, 43C are arranged so as to increase in length from the lowermost stage toward the uppermost stage, and a gap is formed between the air feeding pipes 43.
Further, the air feeding pipes 43A, 43B, and 43C include a plurality of air vent holes 44 that release the air A flowing through the air feeding pipes 43A, 43B, and 43C downward. In other words, a plurality of vent holes 44 are formed on the bottom side of the air feeding pipes 43A, 43B, 43C. The plurality of air discharge holes 44 are formed in the entire air supply tube 43A and only in the respective tip regions of the air supply tubes 43B and 43C. The entire air pipe 42 is formed such that the plurality of air discharge holes 44 are arranged substantially evenly in the plane direction.
In addition, a plurality of pipes arranged at predetermined intervals in a direction perpendicular to the arrangement direction of the air supply branch pipes 43 below the refrigerant pipe 20 in the container 10, that is, in a space where the plurality of air supply pipes 43 are formed. A partition plate 46 is provided. Since each partition plate 46 is joined to the inner wall of the container 10 and the air feeding tube 43, the space in which the plurality of air feeding tubes 43 are formed is arranged in the direction in which the air feeding tube 43 is arranged as shown in FIG. Is partitioned into a plurality of spaces (spaces S _{1 to} S ₁₅ ) in a direction orthogonal to the direction.
In addition, it is preferable to use metals, such as copper with high heat conductivity, as a forming material of the air supply branch pipe 43. FIG. Moreover, as a forming material of the container 10 and the partition plate 46, a material with high heat insulation is preferable.

Then, the effect | action of the condenser 100 provided with the above structures is demonstrated.
First, for example, the refrigerant R having a temperature of about 60 ° C. is pumped through the refrigerant pipe 20. Specifically, the refrigerant R is pumped through the pipe 22 and is divided into the plurality of refrigerant branch pipes 21 through the plenum portion 24 substantially evenly. And the refrigerant | coolant R heats the refrigerant | coolant piping 20 with the heat | fever, when the inside of the refrigerant | coolant branch pipe 21 is pumped. On the other hand, as will be described later, the refrigerant R is deprived of heat (cooled) by the water cooling unit 30 and the air cooling unit 40 via the refrigerant pipe 20, so that the refrigerant R is gradually liquefied and travels downstream. Flowing.

In the water cooling unit 30, for example, water W at about 25 ° C. is pumped from the water supply or the like into the water distribution pipe 31. Then, the water W pumped through the water distribution pipe 31 is sprinkled into the container 10 through a plurality of water spray holes 32 formed in the water distribution pipe 31.
The water W sprayed from the water distribution pipe 31 falls according to gravity and adheres to the surface of the refrigerant pipe 20 (the uppermost refrigerant branch pipe 21) arranged below the water distribution pipe 31. Since the surface of the refrigerant branch 21 is heated by the refrigerant R, the adhering water W evaporates, and heat is absorbed from the refrigerant branch 21 by the latent heat of evaporation. The water W remaining without being evaporated flows down to the surface of the lower refrigerant branch pipe 21 and is heated and evaporated on the surface. Similarly, water W adheres and evaporates on the surface of the lowermost refrigerant branch pipe 21 and absorbs heat from the refrigerant branch pipe 21.
In this way, water W is sprinkled almost evenly from the water cooling unit 30 to the surface of the refrigerant pipe 20, thereby removing heat from the refrigerant R flowing through the refrigerant branch pipe 21 via the refrigerant branch pipe 21 and cooling the refrigerant R. .
The water W remaining without being evaporated on the surface of the lowermost refrigerant branch pipe 21 adheres to the surface of the air supply branch pipe 43 and evaporates to cool the air A flowing in the air supply branch pipe 43. Further, the remaining water W drips down to the bottom surface 10 c of the container 10 and is drained out of the container 10 from the drain port 14 provided on the bottom surface 10 c of the container 10.

Next, in the air cooling unit 40, outside air (for example, air A at about 25 ° C.) is taken into the plenum unit 45 by the fan 41 from the air supply port 12 formed in the container 10. Then, it is almost uniformly pumped to the plurality of air-feeding branch pipes 43. Then, the air A pressure-fed into each air feeding tube 43 is blown out into the spaces S _{1 to} S ₁₅ partitioned by the partition plate 46 from the air discharge holes 44 formed on the bottom side of each air feeding tube 43.
Then, the air A is discharged into the space _S 1 to S ₅ flows toward the air transfer branch pipes 43A, 43B, the outer periphery of 43C upward. Air A is discharged into the space _S 6 _{to S 10} flows toward pneumatically branch pipes 43B, the outer periphery of 43C upward. Air A is discharged into the space _S 11 _{to S 15} flows toward the outer periphery of the pneumatically branch pipe 43C upwards. As the entire pneumatic tube 42, a plurality of discharge pores 44 are formed so as to be substantially uniformly disposed in the planar direction, the flow rate of the air A is discharged to the space S ₁ to S ₁₅ are It is almost uniform.
The air A flowing into the space _S 1 _{to S 15,} when passing through the outer periphery of the branch pipe 43 feeding air flows each space _S 1 _{to S 15.,} absorbing heat from the air transfer branch pipe 43, air transfer branch pipe 43 The air A flowing inside is self-cooled. That is, the air A released into the spaces S _{1 to} S ₅ takes heat from the air feeding pipes 43A, 43B, and 43C. Air A is discharged into the space _S 6 _{to S 10} deprives heat from the pneumatically branch pipe 43B, 43C. The air A released into the spaces S _{11 to} S ₁₅ takes heat from the air supply branch pipe 43C.
Accordingly, the temperature becomes lower in the order of the air feeding pipes 43C, 43B, and 43A, and the air A gradually becomes lower toward the downstream. Then, the respective spaces S ₁ to S _15, the air A becomes low toward the downstream flows.
State Each space _S 1 _{to S 15,} because they are divided by a partition plate 46, which without air A respective spaces _S 1 _{to S 15} are mixed, air A becomes low toward the downstream That is, a state with a temperature gradient is maintained.

The air A which has flowed into the space _S 1 _{to S 15} flows around from a downward toward the upper side of the refrigerant pipe 20 located above the spaces _S 1 _{to S 15} (plurality of refrigerant branch pipes 21). When the air A flows around the refrigerant branch pipes 21, heat is absorbed from the surfaces of the respective refrigerant branch pipes 21. Therefore, the refrigerant R flowing in the refrigerant branch 21 and further in the refrigerant branch 21 is cooled.
In particular, the air A blown from the air cooling unit 40 toward the refrigerant pipe 20 is self-cooled along the direction of the flow of the refrigerant R flowing through the refrigerant pipe 20 and has a temperature gradient. Can be efficiently cooled. That is, compared with the case where the refrigerant R is cooled by the air A having the same temperature as the outside air temperature, the temperature difference from the refrigerant R can be increased in the air A to which the temperature gradient is given by self-cooling. . And since a cooling efficiency improves, so that a temperature difference is large, the refrigerant | coolant R can be cooled efficiently. Moreover, since the temperature gradient of the air A is maintained by providing the partition plate 46, the refrigerant | coolant R can be cooled efficiently.
Furthermore, since the water W sprinkled by the water cooling unit 30 adheres to the surface of each refrigerant branch 21, the evaporation of the water W is promoted by flowing air A around each refrigerant branch 21. The cooling efficiency of the refrigerant branch pipe 21 and the refrigerant R is improved.
Then, the air A deprived of heat from the plurality of refrigerant branch pipes 21 joins at the upper part in the container 10 and is discharged from the exhaust port 13 to the outside of the container 10.

  In this way, the refrigerant R pumped through the refrigerant pipe 20 is cooled by the water cooling unit 30 and the air cooling unit 40 in the container 10, gradually liquefied, and flows downstream. The liquefied refrigerant R is pumped through the respective refrigerant branch pipes 21, and then merged in the plenum portion 25 and is pumped out of the container 10 through the pipe 23.

Next, a second embodiment of the condenser of the present invention will be described with reference to the drawings.
FIG. 4 is a schematic cross-sectional view showing a condenser 300 according to the second embodiment of the present invention. 5 is a cross-sectional view taken along the line VV in FIG. In addition, about the component etc. which are the same as the condenser which concerns on 1st Embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.
The condenser 300 includes a substantially rectangular columnar container 310 extending in the vertical direction, a refrigerant pipe 320 extending from the bottom to the top in the container 310, and a water cooling unit 330 disposed above the refrigerant pipe 320. And an air cooling unit 340 disposed on the side of the refrigerant pipe 320.

The refrigerant pipe 320 includes a plurality of plate-like refrigerant branch pipes 321 branched in the container 310. Each refrigerant branch 321 is arranged so as to overlap in parallel through a predetermined gap. Thus, when the refrigerant R pumped in the pipe 322 is divided into the plurality of refrigerant branch pipes 321 and passes through the refrigerant branch pipes 321 (flows upward from below in the drawing), the water cooling unit 330 and the air cooling unit It is cooled and liquefied by 340 and further fed by pressure from the pipe 323.
Note that fins and protrusions may be provided on the inner and outer surfaces of each refrigerant branch 321 in order to increase the surface area and improve the cooling efficiency.

The water cooling unit 330 cools the refrigerant R by dripping water W from above onto the plurality of refrigerant branch pipes 321. The water cooling unit 330 stores the water W in the tank 331 and the tank 331 that stores the water W. It comprises a plurality of dropping portions 332 to be dropped. The dropping unit 332 includes a minute hole 332a provided on the side surface or the bottom surface of the tank 331, and a member 332b that causes water W leaking from the hole to flow downward and be dropped.
The water W dropped from the member 332b adheres to the upper ends of the plurality of refrigerant branch pipes 321, flows downward through the plurality of refrigerant branch pipes 321, and drains to the outside from the opening 310d provided on the side of the container 310. It has come to be.
The amount of water W dripped from the water cooling section 330 toward the refrigerant branch 321 can be adjusted by the water head value of the water W stored in the tank 331, the number of dripping sections 332, and the size of the hole 332a.

The air cooling unit 340 cools the refrigerant R by blowing air A from the side to the plurality of refrigerant branch pipes 321, and includes a fan 341 for pumping the air A. In addition, the container 310 that houses the air cooling unit 340 and the like functions as a flow path of the air A blown to the refrigerant pipe 320, and is also a component of the air cooling unit 340.
An opening 310d is provided on the side of the container 310, and an exhaust port 313 for releasing the air A in the container 310 to the outside is formed in the opposite side wall 310a. A fan 341 that pumps air A is installed at the exhaust port 313.
In the present embodiment, the container 310 is the main element of the air-cooling unit 340, but an air feeding tube 42 as in the first embodiment may be used. That is, the air feeding pipe 42 may be arranged on the side of the refrigerant pipe 320 so as to extend in the vertical direction.
The fan 341 is desirably arranged on the downstream side of the refrigerant pipe 320 as shown in FIG. 5 in that the flow of the air A passing through the refrigerant pipe 320 is made uniform. However, when there are restrictions on the arrangement, the fan 341 may be arranged on the upstream side of the refrigerant pipe 320.

Then, the effect | action of the condenser 300 provided with the above structures is demonstrated.
First, the refrigerant R having a temperature of about 60 ° C. is pumped through the refrigerant pipe 320. Specifically, the refrigerant R is pumped through the pipe 322, is divided approximately evenly into the plurality of refrigerant branch pipes 321, and flows downstream (upward). The refrigerant R is liquefied because it is deprived of heat (cooled) by the water cooling section 330 and the air cooling section 340 through the refrigerant pipe 320 when being fed through the refrigerant branch pipe 321.

In the water cooling unit 330, the water W stored in the tank 331 is dropped from the dropping unit 332 toward the refrigerant branch 321. The water W dropped from the dropping part 332 falls according to gravity and adheres to the upper end of the refrigerant branch 321. The water W adhering to each refrigerant branch 321 absorbs heat from the refrigerant branch 321 and gradually evaporates while flowing down along the surface of the refrigerant branch 321.
In this way, by dripping water W almost uniformly onto the surface of the refrigerant pipe 320 from the water cooling section 330, heat is taken from the refrigerant R flowing in the refrigerant branch 321 and the refrigerant R is cooled.
In addition, the water W remaining without being evaporated on the surface of each refrigerant branch 321 is dripped down to the bottom surface 310 c of the container 310 and drained out of the container 310 through the opening 310 d of the container 310.

  Next, in the air cooling unit 340, air A is taken in from the opening 310 d of the container 310 by the fan 341. The air A taken into the container 310 flows toward the exhaust port 313. When the air A flows around the refrigerant branch pipes 321, heat is absorbed from the surfaces of the respective refrigerant branch pipes 321, whereby the refrigerant R flowing through the refrigerant branch pipes 321 is cooled.

  In this way, the refrigerant R that is pumped through the refrigerant pipe 320 is cooled by the water cooling unit 330 and the air cooling unit 340 in the container 310, gradually liquefied, and flows downstream. The liquefied refrigerant R is pumped through the refrigerant branch pipes 321 and then pumped out of the container 310 via the pipe 323.

As described above, the water cooling units 30 and 330 do not need to circulate the water W for cooling the refrigerant R unlike the conventional water-cooled condenser. Excellent in properties. Furthermore, since equipment such as a cooling tower is not necessary, only simple equipment such as the water distribution pipe 31 is required, and the equipment is made compact and equipment costs can be reduced.
In addition, the amount of water W sprayed or dripped from the water-cooling units 30 and 330 toward the refrigerant pipes 20 and 320 needs to be attached to the surfaces of the plurality of refrigerant branch pipes 21 and 321 almost uniformly and evaporated. There is no need for large quantities. That is, when a large amount of water W adheres to the surfaces of the refrigerant branch pipes 21 and 321, the thermal resistance due to the water film increases, so that the attached water W becomes difficult to evaporate and the cooling efficiency is lowered. Therefore, the supply amount of the water W may be such that all the water W is completely evaporated on the surfaces of the refrigerant branch pipes 21 and 321. In other words, it may be a level where there is almost no water W drained from the drain port 14 and the opening 310d. Therefore, since the supply amount of water W is small, the running cost can be suppressed.

Further, since the air A flowing from the air cooling units 40 and 340 to the periphery of the refrigerant branch pipes 21 and 321 can promote the evaporation of the water W adhering to the surfaces of the refrigerant branch pipes 21 and 321, the cooling efficiency of the refrigerant R is further increased. Can be improved.
In particular, unlike the conventional air-cooled condenser, the air-cooling units 40 and 340 are capable of improving the cooling efficiency because the self-cooled air A is blown onto the refrigerant pipes 20 and 320.
In addition, since the air cooling units 40 and 340 have a simple structure, it is possible to easily suppress an increase in size of equipment and an increase in equipment cost.
As a result, the temperature of the refrigerant R can be cooled to near the dew point of the air A.

Next, a heat pump and a cooling device using the condenser 100 will be described.
6 is a conceptual diagram showing the heat pump HP and the cooling device C, and FIG. 7 is a conceptual diagram showing the heat pumps HP2 and HP3 and the cooling devices C2 and C3.
As shown in FIG. 6, the heat pump HP is composed of a condenser 100, an expansion valve 110, an evaporator 120, a compressor 130, and a pipe 140 connecting them, and from each step of condensation, expansion, evaporation and compression. In this cycle, heat is drawn from a low-temperature object, and heat is applied to a high-temperature object.
And since the condenser 100 mentioned above is used for heat pump HP, a coefficient of performance COP can be made high in a condensing process, and it can be excellent in space efficiency, a low price, and maintainability. Therefore, a small and highly efficient heat pump HP can be configured.
When configuring a large-scale heat pump HP, for example, a large amount of the refrigerant R can be efficiently cooled by connecting the condensers 100 in series or in parallel. In particular, since the condenser 100 has high space efficiency, a high-capacity and space-saving condenser can be realized by stacking and arranging the condensers 100. For this reason, it can be suitably installed in a limited space such as the roof of a building.

Further, as shown in the heat pump HP2 shown in FIG. 7A, a heat exchanger 200 that indirectly cools the refrigerant R2 circulating through the heat pump HP2 by the refrigerant R cooled by the condenser 100 may be provided.
Further, as shown in the heat pump HP3 shown in FIG. 7B, when water is used as the refrigerant R circulating through the heat pump HP3, the condenser 100 cools the water condensed and liquefied in the condenser 210. May be used as

  As shown in FIGS. 6 and 7, by applying these heat pumps HP, HP2, and HP3 as cooling devices C, C2, and C3, when the refrigerant R evaporates in the evaporator 120, the latent heat of vaporization causes Therefore, it is possible to cool the air in the room or the like efficiently while suppressing the running cost. Moreover, you may use together the water distribution apparatus using a capillary phenomenon.

  In addition, although preferred embodiment which concerns on this invention was described referring drawings, it cannot be overemphasized that this invention is not limited to the example which concerns. Various shapes, combinations, and the like of the constituent members shown in the above-described examples are examples, and various modifications can be made based on design requirements and the like without departing from the gist of the present invention.

  For example, the water cooling units 30 and 330 may be sprayed so that the water W is evenly distributed throughout the refrigerant pipes 20 and 320. Therefore, a sprinkler or the like may be provided in place of the water distribution pipe 31.

  Moreover, what is necessary is just to spray the air A over the whole refrigerant | coolant piping 20 and 320 as the air cooling parts 40 and 340 so that it may spread equally. Therefore, for example, a plurality of fans or the like may be provided above, below, or on the side of the refrigerant pipes 20 and 320. Moreover, it is not restricted to the case where the air A is self-cooled.

  Further, the present invention is not limited to the case where a temperature gradient is provided in the air A blown to the refrigerant pipe 20. Therefore, instead of the plurality of air feeding pipes 43 configured in multiple stages, air feeding pipes with holes evenly arranged may be arranged.

  Further, although the partition plate 46 is provided only in the arrangement region of the air feeding pipe 42 in the container 10, the partition plate 46 may be partitioned up to the arrangement region of the refrigerant pipe 20.

  The refrigerant pipe 20 is not limited to being extended in the horizontal direction, and may be extended in the vertical direction. Further, the refrigerant pipe 320 is not limited to be extended in the vertical direction, but may be extended in the horizontal direction.

  The condensers 100 and 300 are provided with a plurality of refrigerant branch pipes 21 and 321 in order to cool a large amount of the refrigerant R. However, as a minimum configuration, only one refrigerant pipe may be provided. Moreover, each of the water distribution pipe 31 and the air supply branch pipe 43 may be only one.

2 is a schematic cross-sectional view showing a condenser 100. FIG. It is PP sectional drawing of FIG. It is QQ sectional drawing of FIG. 3 is a schematic cross-sectional view showing a condenser 300. FIG. It is VV sectional drawing of FIG. It is a conceptual diagram which shows the heat pump HP and the cooling device C. It is a conceptual diagram which shows heat pump HP2, HP3 and cooling device C2, C3.

Explanation of symbols

R ... Refrigerant A ... Air W ... Water 20, 320 ... Refrigerant piping 30, 330 ... Water cooling part 31 ... Water distribution pipe (watering part)
32 ... Sprinkling holes 40, 340 ... Air cooling part 42 ... Pneumatic pipe (blower part)
43 (43A, 43B, 43C) ... air feeding pipe 44 ... vent hole 46 ... partition plate 100 ... condenser 110 ... expansion valve 120 ... evaporator 130 ... compressor 200 ... condenser 331 ... tank (watering part)
332 ... Dropping part (dropping member)
341 ... Fan (blower)
HP, HP2, HP3 ... Heat pump C, C2, C3 ... Cooling device

Claims (14)

In the condenser that cools and liquefies the refrigerant compressed to high temperature and pressure,
Refrigerant piping through which the refrigerant flows;
A water-cooling unit that cools the coolant pipe by attaching water thereto;
An air-cooling unit that blows air to cool the refrigerant pipe to which water is attached; and
A condenser comprising:   The condenser according to claim 1, wherein the refrigerant pipe includes a plurality of refrigerant branch pipes extending in a vertical direction or a horizontal direction.   The condenser according to claim 1 or 2, wherein a water-cooling unit is disposed above the refrigerant pipe, and the air-cooling unit is disposed below or laterally of the refrigerant pipe.   The condenser according to any one of claims 1 to 3, wherein the water-cooling unit includes a sprinkling unit that adheres water substantially uniformly toward the refrigerant pipe.   The condenser according to claim 4, wherein the water sprinkling unit includes a water distribution pipe in which a plurality of water sprinkling holes for spraying water toward the refrigerant pipe are formed.   The condenser according to claim 4, wherein the water sprinkling part includes a dropping member that drops water toward the refrigerant pipe.   The said air cooling part is provided with the ventilation part which blows air substantially uniformly toward the said refrigerant | coolant piping, The condenser as described in any one of Claims 1-6 characterized by the above-mentioned.   The condenser according to claim 7, wherein the air blown to the refrigerant pipe is self-cooled before coming into contact with the refrigerant pipe.   The condenser according to claim 7 or 8, wherein the blower unit includes an air feeding tube in which a plurality of air discharge holes for discharging air are formed.   The condenser according to claim 9, wherein the air blown to the refrigerant pipe has a temperature gradient along a flow direction of air in the air pipe.   The said air feeding pipe is provided with several air feeding branch pipes from which length differs, and it arrange | positions so that the said air feeding branch pipe may be piled up upward or a side in order with a short length. 10. The condenser according to 10.   The condenser according to claim 10 or 11, wherein the air pipe includes a plurality of partition plates that maintain a temperature gradient of air blown to the refrigerant pipe. In a heat pump having a condenser, an expansion valve, an evaporator, and a compressor,
The heat pump using the condenser as described in any one of Claims 1-12 as the said condenser. In a heat utilization device that exchanges heat with a heat source,
A heat utilization apparatus using the heat pump according to claim 13.

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