KR830002704B1 - Heat recovery device - Google Patents

Abstract

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Description

Heat recovery device

Figure is a schematic diagram of a steam compression cooling circuit and a heat recovery device used in the present invention.

The present invention relates to a heat recovery device, in particular a device for recovering the normal waste heat discharged by the refrigerant of the cooling circuit.

Steam compression refrigeration systems generally consist of a cooling circuit in which one compressor, one condenser, one expansion device and one evaporator are connected by suitable refrigerant pipes. The refrigerant vapor is compressed by a compressor and supplied to the condenser where the refrigerant releases heat to the cooling medium and the condensate. At this time, the condensed refrigerant flows through the expansion device so that the pressure and temperature of the refrigerant drop. The refrigerant from the expansion device flows into the evaporator to absorb heat from the medium so that the medium is cooled and the refrigerant evaporates. Steam refrigerant is sucked into the compressor and the circuit is completed

Cooling circuits of the type described above are usually designed to be cooled by using a fluid such as water circulating in various rooms and spaces of a building, that is, water cooling these spaces. Sometimes the refrigerant in such a circuit will release a relatively large amount of heat from the condenser of the circuit. The heat thus released is usually released to the atmosphere either directly or via a cooling fluid circulating between the condenser and the cooling tower. In the past, exhaust heat was considered to be a significant loss of energy, and in the present, much attention has been paid to recovering or recovering this heat.

One common attempt to recover this heat is to draw off a portion of the refrigerant vapor exiting the compressor and pass the refrigerant refrigerant vapor through a heat recovery condenser that is separate from the condenser of the cooling circuit. The heat exchanger has a plurality of heat exchanger tubes located in the heat recovery condenser, in which water circulating through the heat exchanger heat transfers with the steam in the heat recovery condenser. Heat travels from the steam to the water to heat the water and condense the steam. The heated water is led to a storage tank and stored for later use, and the condensed refrigerant is returned to the cooling circuit for reuse. Under certain conditions, the condensed refrigerant accumulates in the heat recovery condenser to immerse the heat exchanger tube installed inside the condenser. In this case, the water passing through the heat exchanger tube condenses the refrigerant without direct heat exchange with the refrigerant vapor, which is hotter than the fluid. As a result, the amount of heat absorbed by the water is reduced, and the amount of heat recovered in the cooling circuit is reduced.

It is an object of the present invention to improve an apparatus for recovering heat from a vapor compression cooling circuit.

Another object of the present invention is to provide a low cost, reliable and effective heat recovery device.

Another object of the present invention is to prevent the refrigerant from condensing by submerging the heat exchange tube of the heat recovery condenser.

Another object of the present invention is to change the amount of heat transfer fluid circulating through the heat recovery condenser so as to correspond to the change in the amount of refrigerant to be condensed.

These objectives will be achieved as a heat recovery device using steam compression cooling circuits and delivery fluids and heat storage facilities. The heat recovery device is composed of a heat recovery condenser connected to receive the refrigerant vapor from the cooling circuit and a device for discharging the refrigerant condensed in the circuit, and is connected to a heat transfer fluid source for receiving the fluid and heat storage for discharging the heat transfer fluid. It is configured in connection with the facility. The refrigerant vapor therein passes through the heat transfer fluid while forming heat transfer to heat the fluid and condense the refrigerant vapor. The heat recovery device also has a valve device that regulates the flow of the transfer fluid to the heat recovery condenser, and also the valve device to reduce the amount of heat transfer fluid flowing to the heat recovery condenser when the refrigerant condensed in the heat recovery condenser reaches a predetermined level. Consists of a control device for controlling.

An embodiment according to the drawings will be described below. In the drawings, the vapor compression cooling circuit 10 and the heat recovery device 12 are illustrated in association with the present invention. The cooling circuit 10 is formed by connecting the compressor 14, the condenser 16, the variable expansion device 18, and the evaporator 20 by cooling lines 22, 24, and 26. Compressor 14 is hot in line 22 and discharges compressed refrigerant vapor, which is directed to condenser 16. Part of the refrigerant vapor passes through the heat recovery device 12 via line 30, which will be described in greater detail below and the remaining refrigerant vapor

The heat transfer medium moving through the coil 36 of the evaporator 20 is used for a variety of different purposes, for example to cool (not shown) the rooms of the building and return to the evaporator. The load on the cooling circuit indicated by the medium passing through the coil 36 changes, and the evaporator 20 cools the medium to a nearly constant final temperature. Any suitable means is used to control the operation of the evaporator 20 to suit this purpose. In the system shown in the figure, the control device comprises an expansion device 18 and any suitable form of positioning means 38 such as electric pneumatic and hydraulic. The positioning device adjusts the amount of refrigerant passing through the expansion device 18 to be indicated by a change in steam temperature leaving the evaporator 20 in response to a load change on the circuit 10. This temperature is sensed by any suitable form, for example the temperature sensing device 40.

Referring now to the heat recovery device 12, the device is configured to receive a heat recovery condenser 42 connected to the cooling circuit 10 via lines 30 and 34 to receive refrigerant steam from the circuit 10 and to recover the condensed refrigerant. The circuit 10 is discharged. In the preferred embodiment shown in the figure, the heat recovery condenser 42 is connected to the condenser 16 of the circuit 10 by lines 30 and 34, where both condensers operate to condense the refrigerant vapor in parallel. do. Alternatively, as shown by the dotted lines in the figure, the line 30 may be connected directly to the lower pressure line 22. fitness

The heat exchanger 50 has a plurality of heat exchange tubes 52, which are located in the heat recovery condenser 42. The heat exchanger 50 is connected to fluid lines 44 and 46 where heat transfer fluid is introduced from the fluid source flowing through the pipe 52 through which the fluid flows to the heat storage 48. do. The steam refrigerant flowing into the heat recovery condenser 42 via the line 30 passes downward of the condenser and forms a heat transfer relationship with the heat transfer fluid flowing in the heat exchange tube 52, and flows outside the heat exchange tube 52. . Heat is transferred from the steam to the heat exchanger tube 52

The refrigerant condensed in the heat recovery condenser 42 is returned to the condenser 16 of the cooling circuit 10 via the line 34.

The heat recovery condenser 42 is installed above the condenser 16 so that the liquid refrigerant flows to the heat condenser 42 to the heat condenser 42 via the line 34 by gravity. In addition, since the steam pressure in the heat recovery condenser 42 is lower than the steam pressure in the condenser 16, an auxiliary pump is not necessary and flows from the condenser 16 to the heat recovery condenser 42 through the line 30. As also shown, line 34 has a lower portion 34a underneath condenser 16. This arrangement ensures that liquid is filled in line 34 to prevent the flow of steam therethrough and to help maintain the pressure differential between the condenser 16 and the heat recovery condenser 42. The pressure difference between the condensers 42 and 16 also raises the pressure level of the liquid refrigerant in the line 34 above the pressure level of the refrigerant condensed in the condenser. As the pressure between condensers 42 and 16 rises, the liquid refrigerant pressure level in line 34 rises. When the pressure difference is sufficiently large, the liquid refrigerant begins to accumulate in the heat recovery condenser 42 and the heat exchange tube 52 starts to be immersed in the liquid refrigerant. The condensed refrigerant may accumulate in the heat recovery condenser when the condensation ratio is exceeded due to the size and shape of the line 34 through which the whole flows. If the liquid refrigerant accumulates in the heat recovery condenser 42 and the heat exchange tube 52 is locked, the vapor refrigerant in the condenser 42 cannot directly contact the locked heat exchange tube. Since the vapor refrigerant is much hotter than the condensed refrigerant, preventing direct contact between the heat exchange tube 52 and the steam refrigerant reduces the amount of heat transferred to the liquid through the heat exchange tube. This reduces the amount of heat recovered by the heat recovery device 12 from the cooling circuit 10. The heat recovery apparatus of the present invention for preventing the above-mentioned water immersion of the heat exchange tube 52 includes a control valve 54 and a control device 56. The control valve 54 is in line 44

In more detail, the sensing device 62 is connected to a heat recovery condenser 42 for sensing the level of the condensed refrigerant and also sends a display signal of this level to the positioning device 60. The sensing device 62 may be formed in the following form. For example, the sensing device 62 may comprise a float located within the float chamber 66, which is connected to the heat recovery condenser 42 by a flow path and via the pilot lines 68, 70. Connect with By this connection, the liquid refrigerant accumulates in the float chamber 66 at the same level as the liquid refrigerant accumulated in the condenser 42, and the float apparatus 64 is electrically or air pressure corresponding to the level of the condensation refrigerant in the chamber 66. It will have an array that can generate a positive signal.

The signal generated by the sensing device 62 is sensed by the device 60 via the line 72 between the positioning device 60. The positioning device 60 may also be configured as an electric, hydraulic or pneumatic positioning device, and control the control valve 54 in response to the magnitude of the signal detected by the positioning device. In this way, the sensing device 62, the positioning device 60, and the control valve 54 move and pass through the heat exchange pipe 52 in response to a change in the level of the liquid condensation refrigerant in the heat recovery condenser 42. Reverse the flow rate of the additive. Therefore, when the amount of heat transfer fluid passing through the heat exchanger 50 is reduced, the flow rate of the fluid passing therethrough is reduced. The heat transfer fluid consumes more time in the heat exchanger 50, whereby as the fluid flows, the temperature of the fluid rises more than before the fluid flow is restricted. As the temperature rises in this way, the cooling effect of the heat transfer fluid on the refrigerant vapor in the condenser 42 is reduced, thereby raising the temperature of the steam. As the steam temperature rises, the pressure increases or increases. The rise in temperature of the condenser 42 lowers the level of the condensation refrigerant. The control valve 54 and the control device 56 start to restrict the flow of the heat exchange fluid through the heat exchanger 50 before the level of the condensation refrigerant in the heat exchange tube 52 begins to lower. If the heat exchanger tube 52 is submerged in the liquid refrigerant, the coolant level is lowered to expose more heat exchanger tube to the refrigerant vapor, thereby increasing the proportion of the condensate of the refrigerant in the condenser 42. The heat of condensation formed in the condenser 42 increases, which raises the temperature of the heat transfer fluid flowing through the heat exchanger 59 and the temperature of the steam in the condenser 42. This of course increases the pressure of the steam and lowers the refrigerant level in the condenser 42. The temperature of heat transfer fluid and steam

As described above, the control valve 54 and the control device 56 begin to restrict the flow of the heat transfer fluid before the liquid refrigerant in the condenser 42 rises to the level of the heat exchange tube 52. In addition, by properly arranging the control valve 54 sensing device 62 and the position adjusting device 60, the flow of the heat transfer fluid is proportionally further limited as the level of the condensation refrigerant in the heat recovery condenser 42 increases. do. This arrangement operates to maintain equilibrium, where the level of the liquid refrigerant in the condenser 42 is below the heat exchanger tube 52 and the maximum or near maximum heat recovery from the cooling circuit 10 by the heat recovery device 12. Will be provided. The condensation refrigerant in the condenser 42 is kept at a low water level and also helps to properly maintain the supply of liquid refrigerant in the condenser 18 of the circuit 10 and obtains effective operation.

As described above, the heat recovered from the cooling circuit 10 by the heat recovery device 12 is transferred to the heat storage device 48 via the line 46. The heat storage device 48 can be installed satisfactorily, for example in a commercial or residential building. Suitably, a supplemental heat source (not shown) such as an oil or gas combustor (not shown) is disposed in the heat storage device 48 and transfers heat therethrough via the heat recovery device 12 so that the heat storage facility recovers heat from the cooling circuit 10. It is possible to meet the demand irrespective of the variation in the amount of heat recovered by the apparatus 12.

The heat recovery device 12 suitably also includes a bypass device having a bypass line 74, inducing heat transfer fluid from the fluid source of the heat storage device 48 to the bypass yalcon condenser 42, and controlling it. The valve 54 regulates the flow of heat transfer fluid flowing through the line 44, thereby diverting the heat transfer fluid from the line 44 by bypass means. In this way, the heat transfer fluid can, for example, cool or limit the fluid temperature entering or storing the storage 48. The bypass device also regulates the flow of fluid into the line 44 and the pope 50 regardless of the increase in the fluid pressure in the line 44 upstream of the control valve 54.

Moreover, the recirculation apparatus consists of lines 76 and 78 and a pump 80, which selectively induces heat transfer fluid from the heat storage device 48 to return to the heat recovery condenser 45 for reheating the heat transfer fluid. And, if necessary, raise the temperature. More specifically, the recirculation of the heat transfer fluid causes the pump 80 to operate to flow fluid from the reservoir 48 via line 76 and to discharge into line 44 via line 78. Done. The fluid thereby flows through line 44, valve 54 and heat exchanger 50. The heat transfer fluid is returned to the storage device 45 via line 46 to complete the closed fluid circuit. Check valve 82 is disposed in line 76 to prevent fluid from flowing when pump 80 is not running, and check valve 84 is arranged in line 44 via line 44 Prevents fluid from leaking in the closed fluid circuit.

It is to be understood that the above description will make the gist of the present invention clear and that the above objects are well met, and that many imitations will be possible by those skilled in the art, and that these are possible within the spirit and scope of the present invention.

Claims (1)

In the heat recovery apparatus consisting of a vapor compression refrigerant circuit (10), a heat transfer medium, and a heat storage device (48), a vapor compression cooling circuit (10) for receiving refrigerant vapor and releasing condensed refrigerant, and a heat transfer for receiving a heat transfer fluid A heat recovery condenser 42 connected to a fluid source and a heat storage device 48 for discharging the heat transfer fluid, a control valve 54 for adjusting the flow rate of the heat transfer fluid to the heat recovery condenser, and condensation in the heat recovery condenser And a sensing device (62) for sensing the coolant level, and a positioning device (60) for operating the control valve (54) according to the condensed coolant level.

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