KR101191758B1 - High efficency heat pump air conditioning unit controlled by remote controller of smart phone application - Google Patents

Abstract

PURPOSE: A high efficiency heat pump air conditioning apparatus using remote management for an application in a smart phone is provided to create an effective heating and cooling cycle simultaneously using a short and a long pipe. CONSTITUTION: A refrigerating medium temperature damper(171) connects to one side of a long pipe indoor heat exchanger(162). When a cooling cycle is operated, refrigerating medium temperature is increased. The refrigerating medium temperature damper reduces the increased refrigerating medium temperature. A refrigerating medium temperature compensator(172) connects to other side of the long pipe indoor heat exchanger. When a heating cycle is operated, the refrigerating medium temperature is decreased. The refrigerating medium temperature compensator increases the decreased refrigerating medium temperature. [Reference numerals] (130) Outdoor heat exchanger; (161) Short pipe indoor heat exchanger; (162) Long pipe indoor heat exchanger; (171) Refrigerating medium temperature damper; (172) Refrigerating medium temperature compensator; (Ct) Controller

Description

High efficiency heat pump air conditioning unit controlled by remote controller of smart phone application}

The present invention relates to a high-efficiency heat pump air conditioner using a smart phone application remote management, and more particularly, the short pipe length and pipe length is not limited by the distance when the refrigerant flows because the pipe length is short, when the refrigerant flows for a long time It is possible to form efficient air-conditioning cycle even though multiple air-conditioning system is provided by using long pipe which is constrained due to change in temperature characteristics of refrigerant, and high efficiency using remote management of smart phone application that can be monitored and controlled remotely. It relates to a heat pump air conditioner.

An air conditioner is a device that maintains indoor air in a comfortable state by controlling indoor air to a temperature, humidity, and airflow distribution suitable for human activity, and at the same time removing dust from the air.The air conditioner, air conditioner, constant temperature and humidity controller It is used as a concept to include and is designed using the principle of absorbing heat from the surroundings when the refrigerant evaporates.

Conventionally, a cooling device has been mainly used as such an air conditioner. Recently, a heat pump type air conditioner capable of simultaneously cooling and heating has been developed and commercialized. The heat pump type air conditioner is capable of simultaneously cooling and heating the indoor unit and the outdoor unit by a compressor and a four-way valve, and is known to have a power saving effect of about 60% compared to the existing air-conditioning equipment.

In addition, recently, one outdoor unit installed outdoors and a plurality of indoor units installed in each chamber of the room, the outdoor unit is provided with a compressor, a four-way valve, an outdoor heat exchanger and an electric expansion valve, each indoor unit is provided with an indoor heat exchanger At the same time, a multi-chamber heat pump air conditioner for cooling or heating several places is also provided.

As an example of such a multi-chamber air conditioner, Korean Patent No. 10-444971 discloses a compressor 10, a four-way valve 11, one outdoor heat exchanger 12, and each chamber as shown in FIG. A plurality of installed indoor heat exchangers (13, 23, 33) and electric expansion valves (14, 24, 34) connected to the indoor heat exchangers (13, 23, 33), respectively.

However, since the distance between the compressor 10 and each indoor heat exchanger 13, 23, 33 is different from each other in the related art as described above, the compressor 10 and any one indoor heat exchanger 13, 23, 33 are Although a short length pipe was formed, and the compressor 10 and the other indoor heat exchanger 13, 23, and 33 formed a long length pipe, the air conditioner was not formed by dividing them.

Therefore, in the case of single pipe, the circulating distance of the refrigerant is short, so it is not influenced by the surrounding environment while the refrigerant flows. In the case of long pipe, the refrigerant is not affected by friction or ambient temperature between the refrigerant and the pipe for a long time. Even though the temperature was changed inappropriately, there was a problem that does not reflect this in the system.

For example, in the cooling cycle, although the refrigerant is changed into a low temperature low pressure liquid through each of the electric expansion valves 14, 24, and 34, and in that state to be supplied to each of the indoor heat exchangers 13, 23, 33, In this case, since the coolant in the low-temperature low-pressure liquid state flows along the long pipe for a long time, there is a problem that cooling is not achieved until the set temperature even when supplied to the indoor heat exchanger (13, 23, 33).

In addition, when the refrigerant that is recovered again to the compressor 10 after the cooling or heating cycle is overheated in summer or undercooled in winter, a large load is applied to the compressor 10 and burnout of the compressor 10 occurs. In the case of the case of being affected by the surrounding environment compared to the single pipe there was a problem that often out of the temperature suitable for the compressor 10 as described above.

The present invention has been proposed to solve the above problems, the short pipe length and the length of the pipe is not limited by the distance when the flow of the refrigerant due to the short pipe length is changed in the temperature characteristics of the refrigerant during a long flow of the refrigerant To provide efficient air-conditioning cycle even though multiple air-conditioning systems are used simultaneously by using restricted long pipes, and to provide high-efficiency heat pump air conditioners using remote management of smart phone applications that can be monitored and controlled remotely. do.

To this end, the high-efficiency heat pump air conditioner using the smart phone application remote management according to the present invention comprises a compressor for compressing the refrigerant; A four-way valve for switching the circulation direction of the refrigerant according to a cooling cycle or a heating cycle; An outdoor heat exchanger installed outdoors and configured to exchange heat between the outside air and the refrigerant; An expansion valve for expanding the refrigerant to lower the pressure; A first three-way valve having a common port connected to said expansion valve; A single pipe internal heat exchanger having one end connected to the first branch port of the first three-way valve and installed in a refrigerant cycle including the single pipe; A long pipe indoor heat exchanger having one end connected to a second branch port of the first three-way valve and installed in a refrigerant cycle consisting of a long pipe; A common port is connected to the compressor, a first branch port is connected to the other end of the single-pipe indoor heat exchanger, and a second branch port is connected to the other end of the long-pipe indoor heat exchanger; A refrigerant temperature attenuator connected to one side of the long heat pipe indoor heat exchanger and lowering the temperature of the increased coolant when the temperature of the coolant increases as the coolant flows along the long pipe for a long time during operation of a cooling cycle; A refrigerant temperature compensator connected to the other side of the long heat pipe indoor heat exchanger and increasing a temperature of the lowered coolant when the temperature of the coolant drops as the coolant flows along the long pipe for a long time during operation of a heating cycle; During operation of the heating cycle, the refrigerant flows through the first branch port of the first three-way valve after circulating the single pipe and the second branch port of the first three-way valve after circulating the long pipe. A first mixer for mixing the refrigerant having a second temperature introduced therethrough and returning the refrigerant to the compressor; During the cooling cycle, the refrigerant flows through the first branch port of the second three-way valve after circulating the single pipe and the second branch port of the second three-way valve after circulating the long pipe. A second mixer for mixing the refrigerant having a fourth temperature introduced therethrough and returning the refrigerant to the compressor; A controller for controlling the operation of the cooling cycle or the heating cycle; And a remote control terminal connected to the controller through a communication network to receive information about the cooling cycle or the heating cycle from the controller or to remotely control the cooling cycle or the heating cycle through the controller. .

At this time, the first mixer and the second mixer is preferably made of a tube having a coil shape, respectively.

In addition, it is preferable that bypass pipes are connected in parallel to both ends of the first mixer and the second mixer, respectively.

Further, a first temperature sensor installed between the long pipe indoor heat exchanger and the refrigerant temperature attenuator and detecting the temperature of the refrigerant, and a second temperature sensor installed between the long pipe indoor heat exchanger and the refrigerant temperature compensator for detecting the temperature of the refrigerant. The controller may further include lowering the temperature of the refrigerant to a low temperature reference value by the refrigerant temperature attenuator when the temperature detected by the first temperature sensor is higher than the low temperature reference value, and the temperature detected by the second temperature sensor is lower than the high temperature reference value. In other words, it is preferable to increase the temperature of the refrigerant to a high temperature reference value by the refrigerant temperature compensator.

Further, a third temperature sensor installed between the single pipe internal heat exchanger and the first three-way valve and detecting the temperature of the refrigerant and a third temperature sensor installed between the single pipe internal heat exchanger and the second three-way valve to detect the temperature of the refrigerant. And a four temperature sensor, wherein the controller controls the refrigerant temperature compensator if the average of the temperatures detected by the first temperature sensor and the third temperature sensor is different from the compressor input reference value, and the second temperature sensor And controlling the refrigerant temperature attenuator if the average of the temperatures detected by the fourth temperature sensor differs from the compressor input reference value.

In addition, it is preferable that a fifth temperature sensor is installed at an input side of the compressor to detect a temperature of a refrigerant input to the compressor and transmit the detected temperature to the controller.

According to the present invention as described above by providing a coolant temperature attenuator and a coolant temperature compensator on the long pipe side when the coolant flows through the long pipe for a long time the refrigerant temperature is changed to the optimum state. Therefore, it is possible to form an efficient cooling and heating cycle even when providing a multiple air conditioning system by using a single pipe and a long pipe at the same time.

In addition, the present invention can remotely monitor and control the system through a remote control terminal such as a smart phone to increase the ease of use.

1 is a block diagram showing a multi-chamber heat pump air conditioner according to the prior art.
Figure 2 is a block diagram showing a high efficiency heat pump air conditioner using a smart phone application remote management according to the present invention.
3 is a block diagram showing a remote control system of a high efficiency heat pump air conditioner using a smart phone application remote management according to the present invention.
4 is a view showing a cooling cycle of the high efficiency heat pump air conditioner using a smart phone application remote management according to the present invention.
5 is a view showing a heating cycle of the high efficiency heat pump air conditioner using a smart phone application remote management according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail for a high efficiency heat pump air conditioner using a smart phone application remote management according to an embodiment of the present invention.

First, as shown in Figure 2, the high efficiency heat pump air conditioner using the smart phone application remote management according to the present invention is a compressor 110, four-way valve 120, outdoor heat exchanger 130, expansion valve ( 140, the first three-way valve 151, the second three-way valve 152, single pipe indoor heat exchanger 161, long pipe indoor heat exchanger 162, refrigerant temperature attenuator 171 and refrigerant temperature compensator ( 172).

At this time, the compressor 110, four-way valve 120, outdoor heat exchanger 130, expansion valve 140, the first three-way valve 151, single pipe indoor heat exchanger 161 and the second three-way valve Reference numeral 152 is connected to each other to form a closed loop by the refrigerant circulation pipe, and the refrigerant circulation pipe forming a short closed loop in this way is referred to as a short pipe.

In addition, the compressor 110, four-way valve 120, outdoor heat exchanger 130, expansion valve 140, the first three-way valve 151, refrigerant temperature attenuator 171, long pipe indoor heat exchanger 162 ), The refrigerant temperature compensator 172 and the second three-way valve 152 are also connected to each other to form a closed loop by the refrigerant circulation pipe. It is called a long pipe.

In the present invention, the first mixer (MIX1) is provided in the common port (C) of the first three-way valve 151, the refrigerant in the long pipe and the single pipe through the first mixer (MIX1) in the heating cycle The mixture is mixed to an appropriate temperature and then returned to the compressor 110.

In the present invention, the second mixer (MIX2) is provided in the common port (C) of the second three-way valve 152, in the cooling cycle the refrigerant in the long pipe and the single pipe through the second mixer (MIX2) The mixture is mixed to an appropriate temperature and then returned to the compressor 110.

In addition, the present invention is the first temperature sensor 181 and the second temperature sensor 182 for detecting the temperature of the refrigerant passing through the long-pipe indoor heat exchanger 162 and the short-pipe indoor heat exchanger 161 And a third temperature sensor 183 and a fourth temperature sensor 184 for detecting the temperature of the refrigerant, and a fifth temperature sensor 185 for detecting the temperature of the refrigerant recovered to the input side of the compressor 110.

More specifically, the compressor 110 compresses the refrigerant into a gas of high pressure and high pressure, and the four-way valve 120 switches the circulation direction of the refrigerant output from the compressor 110 according to a cooling cycle or a heating cycle.

The outdoor heat exchanger 130 is installed outdoors to exchange heat between the outside air and the refrigerant. The outdoor heat exchanger 130 is used as a condenser in the cooling cycle of the heat pump and as an evaporator in the heating cycle in which the refrigerant circulates in the opposite direction to the cooling cycle. do. The expansion valve 140 expands the introduced refrigerant to lower the pressure.

The first three-way valve 151 branches the refrigerant passing through the compressor 110, the four-way valve 120, the outdoor heat exchanger 130, and the expansion valve during the cooling cycle, and connects the indoor pipe heat exchanger 161 with the single pipe. The pipes are classified into an indoor heat exchanger (162).

To this end, the common port C of the first three-way valve 151 is connected to the expansion valve 140, the first branch port N1 is connected to the single pipe indoor heat exchanger 161, and the second branch port. N2 is connected to the long pipe indoor heat exchanger 162, and the first three-way valve 151 is an electric valve, and the opening and closing is controlled by the controller Ct.

The single pipe indoor heat exchanger 161 is installed at one side of the room (eg, the first room) to exchange heat with indoor air, and the long pipe indoor heat exchanger 162 is installed at the other side of the room (eg, the second room). They exchange heat with indoor air, which are used as evaporators in cooling cycles and as condensers in heating cycles, respectively.

Single pipe internal heat exchanger 161 is installed in the refrigerant cycle consisting of single pipe and one end is connected to the first branch port (N1) of the first three-way valve 151, the other end of the second three-way valve 152 It is connected to the first branch port (N1) of.

On the other hand, the long pipe indoor heat exchanger 162 is installed in a refrigerant cycle consisting of a long pipe, one end of which is connected to the second branch port N2 of the first three-way valve 151 and the other end of the second three-way valve 152. Is connected to the second branch port (N2).

The second three-way valve 152 branches the refrigerant output from the compressor 110 during the heating cycle and classifies the refrigerant into the single-pipe indoor heat exchanger 161 and the long-pipe indoor heat exchanger 162, respectively. ) Is connected to the compressor 110, the first branch port (N1) is connected to the other end of the single pipe internal heat exchanger 161, the second branch port (N2) is the other end of the long pipe indoor heat exchanger (162). Is connected to.

The refrigerant temperature attenuator 171 is connected to one side of the long heat pipe indoor heat exchanger 162, and when the coolant cycle operates (i.e., cool air operation), the coolant flows for a long time along the long pipe and the coolant temperature rises. Lower the temperature of the refrigerant in preparation.

When the refrigerant made of low temperature and low pressure liquid moves for a long time along the long pipe by the expansion valve 140 during the cooling cycle in summer, the temperature rises above the medium temperature due to the friction between the refrigerant and the pipe or endothermic heat. Even if the refrigerant is supplied to the long pipe indoor heat exchanger 162, the room cannot be cooled to an appropriate temperature.

Therefore, the present invention provides a coolant temperature attenuator 171 having a function of cooling a coolant, such as a cooling device or a supercooler, so that even when a cooling cycle is formed in the long pipe, the room in which the long pipe is installed can be sufficiently cooled. do.

The refrigerant temperature compensator 172 is connected to the other side of the long pipe indoor heat exchanger 162 so that the coolant flows for a long time along the long pipe when the heating cycle is operated (that is, during the heating operation), so that the coolant temperature decreases. Increase the temperature of the refrigerant to the appropriate temperature.

When the refrigerant in the high temperature and high pressure gas moves for a long time along the long pipe by the compressor 110 during the heating cycle in winter, as the refrigerant radiates heat to the surroundings, the temperature is lowered. ) Can not be heated to an appropriate temperature.

Accordingly, the present invention provides a coolant temperature compensator 172 having a function of heating a coolant, such as an electric heating coil, to sufficiently heat a room in which the long pipe is installed even when a heating cycle is formed in the long pipe. .

The first mixer MIX1 circulates the single pipe during the heating cycle and then circulates the refrigerant and the long pipe of the first temperature introduced through the first branch port N1 of the first three-way valve 151 and then the first pipe. The refrigerants of the second temperature introduced through the second branch port N2 of the three-way valve 151 are mixed with each other and returned to the compressor 110.

For example, a coil having a coil shape may be used as the first mixer MIX1. When the coil wound in the coil shape is used, the refrigerant having the first temperature circulated through the short pipe and the refrigerant having the second temperature circulated through the long pipe may be used. In the course of passing through the coil-shaped tube is sufficiently mixed with each other.

Therefore, even when the second temperature of the refrigerant is abnormally changed by circulating the long pipe, the refrigerant is mixed with the refrigerant of the first temperature circulated through the short pipe, thereby preventing a sudden change in the temperature of the refrigerant, and thus the compressor 110. By mitigating the impact on the) to prevent the compressor (110) burn out.

However, although the first bypass pipe BP1 connecting both ends of the first mixer MIX1 is connected to the first mixer MIX1, the first bypass pipe BP1 is connected to the first mixer MIX1. Side by side are connected in parallel, the opening and closing is controlled through the first bypass valve 153.

Therefore, during the heating cycle operation, the refrigerant discharged through the single pipe indoor heat exchanger 161 and the long pipe indoor heat exchanger 162 is introduced into the first mixer MIX1 through the first three-way valve 151. On the contrary, during the cooling cycle operation, the refrigerant discharged through the expansion valve 140 flows to the first three-way valve 151 through the first bypass pipe BP1 without passing through the first mixer MIX1.

The second mixer MIX2 circulates the single pipe during the operation of the cooling cycle, and then circulates the refrigerant and the long pipe of the third temperature introduced through the first branch port N1 of the second three-way valve 152. The refrigerant of the fourth temperature introduced through the second branch port N2 of the two-way valve 152 is mixed and returned to the compressor 110.

For example, a coil having a coil shape may be used as the second mixer MIX2, and the refrigerant having a third temperature circulating through the single pipe and the refrigerant having a fourth temperature circulating through the long pipe pass through the coil-shaped pipe. Are mixed enough with each other.

Therefore, even when the fourth temperature of the refrigerant is abnormally changed by circulating the long pipe, the refrigerant is mixed with the refrigerant of the third temperature circulated through the single pipe, thereby preventing a sudden change in the temperature of the refrigerant. By mitigating the impact on the) to prevent the compressor (110) burn out.

Similarly to the above-described first mixer MIX1, the second bypass pipe BP2 is connected in parallel to the second mixer MIX2, and the second bypass pipe BP2 of the second mixer MIX2 is formed in the second mixer MIX2. Opening and closing is controlled through the 2 bypass valve 154.

Therefore, during the heating cycle operation, the refrigerant discharged through the compressor 110 flows to the second three-way valve 152 through the second bypass pipe BP2 without passing through the second mixer MIX2 and is cooled. During cycle operation, the refrigerant discharged through the single pipe indoor heat exchanger 161 and the long pipe indoor heat exchanger 162 is introduced into the second mixer MIX2 through the second three-way valve 152.

The controller Ct controls the operation of the cooling cycle or the heating cycle as described above, and the compressor 110, the four-way valve 120, the expansion valve 140, the first three-way valve 151, and the second three Various configurations are electronically controlled including directional valve 152, refrigerant temperature attenuator 171 and refrigerant temperature compensator 172.

The remote control terminals 194 and 195 remotely manage the heat pump according to the present invention. The remote control terminals 194 and 195 are connected to the controller Ct through a communication network to receive information about a cooling cycle or a heating cycle, or a cooling cycle through the controller Ct. Or remotely control the heating cycle operation.

As shown in FIG. 3, the remote control terminals 194 and 195 may use an operation server 194 having a database server 194a or a mobile communication terminal 195 such as a smart phone.

The heat pump of the present invention including the thermo-hygrostat 186 and the first temperature sensor 181 to the fifth temperature sensor 185 installed in each chamber includes wired and wireless remote collectors 191a and 191b, and wired and wireless remote collector 191a, It is connected to the remote control terminals 194 and 195 through the concentrators 192a and 192b for collecting data transmitted from 191b and the switch 193 which is a network switching device.

Therefore, by developing a remote web dedicated software and smart phone applications and installed in the remote control terminal (194, 195), operating and operating status monitoring, temperature and humidity monitoring, alarm occurrence information reception, system operation status and operation settings, system current It is possible to manage the history, system remote control and database, etc. In particular, the administrator's smart phone (195) can inform the relevant information in a text message (SMS or MMS, etc.).

On the other hand, the present invention further includes the first temperature sensor 181 to the fifth temperature sensor 185 in addition to the above configuration, to more precisely control the heat pump system.

For example, the present invention includes a first temperature sensor 181 and a long pipe indoor heat exchanger 162 and a refrigerant temperature compensator installed between the long pipe indoor heat exchanger 162 and the refrigerant temperature attenuator 171 to detect the temperature of the coolant. A second temperature sensor 182 is installed between the 172 to detect the temperature of the refrigerant.

Therefore, in the cooling operation, if the temperature detected by the first temperature sensor 181 is higher than the low temperature reference value, the controller Ct controls the refrigerant temperature attenuator 171 to lower the temperature of the refrigerant to the low temperature reference value to flow along the long pipe. While lowering the temperature of the high temperature refrigerant while being supplied to the long pipe indoor heat exchanger (162).

On the other hand, during the heating operation, if the temperature detected by the second temperature sensor 182 is lower than the high temperature reference value, the controller Ct controls the refrigerant temperature compensator 172 to increase the temperature of the refrigerant to the high temperature reference value and thus along the long pipe. The temperature of the refrigerant having a low temperature while flowing is increased and then supplied to the long pipe indoor heat exchanger 162.

In addition, the present invention is installed between the single pipe internal heat exchanger 161 and the first three-way valve 151 and the third temperature sensor 183 and the single pipe indoor heat exchanger 161 to detect the temperature of the refrigerant. And a fourth temperature sensor 184 installed between the two three-way valves 152 to detect the temperature of the refrigerant.

Therefore, if the average of the temperatures detected by the first temperature sensor 181 and the third temperature sensor 183 is different from the designed compressor 110 input reference value, the controller Ct controls the refrigerant temperature compensator 172. If the average of the temperatures detected by the second temperature sensor 182 and the fourth temperature sensor 184 is different from the designed compressor 110 input reference value, the controller Ct controls the refrigerant temperature attenuator 171. .

In addition, the present invention is installed by the fifth temperature sensor 185 on the input side of the compressor 110 to directly detect the temperature of the refrigerant input to the compressor 110 to be transmitted to the controller (Ct), the first as described above After the refrigerant temperature attenuator 171 or the refrigerant temperature compensator 172 are controlled by the temperature sensors 181 to 4th temperature sensor 184, further precise control is possible.

Hereinafter, the cooling operation of the high efficiency heat pump air conditioner using the smart phone application remote management having the above configuration will be described.

As shown in FIG. 4, during a cooling operation (ie, a cooling cycle), the refrigerant is converted into a high temperature and high pressure gas by the compressor 110, and then provided to the outdoor heat exchanger 130 through a four-way valve 120. The refrigerant becomes a high temperature and high pressure liquid while passing through the heat exchanger 130.

Next, the refrigerant of the high temperature and high pressure liquid that has passed through the outdoor heat exchanger 130 is supplied to the expansion valve 140 to be converted into a low temperature low pressure liquid as the pressure is reduced, and the refrigerant of the low temperature low pressure liquid output from the expansion valve 140 is removed. 1 is supplied to the bypass valve 153.

At this time, since the common port C and the first branch port N1 of the first bypass valve 153 are opened by the controller Ct, the refrigerant flows through the first bypass pipe BP1 to the first three-way valve. It is input to the common port C of 151.

Next, the refrigerant input to the first three-way valve 151 passes through the first branch port N1 and the second branch port N2 to the single pipe indoor heat exchanger 161 and the long pipe indoor heat exchanger 162. Is distributed.

Accordingly, the refrigerant supplied to the single pipe indoor heat exchanger 161 is converted into a low temperature low pressure gas while cooling the room, and then is input to the first branch port N1 of the second three-way valve 152, and the indoor pipe indoors. The refrigerant supplied to the heat exchanger 162 is converted into a low temperature low pressure gas while cooling the room, and then input to the second branch port N2 of the second three-way valve 152.

In particular, in the case of the long pipe, the length of the pipe is long, so that the temperature rises in the process of flowing the refrigerant of the low-temperature low-pressure liquid to the long heat pipe indoor heat exchanger 162, by using the refrigerant temperature attenuator 171 to lower the temperature in advance Supply.

The temperature attenuation characteristic in the refrigerant temperature attenuator 171 is calculated in consideration of various parameters α including the length L of the long pipe, the ambient temperature T, and the friction characteristic with the pipe in the controller Ct. The value may be determined using the value, or may be determined by directly referring to the measured temperature value of the first temperature sensor 181.

Although the coolant temperature compensator 172 is installed on the flow path through which the refrigerant output through the long pipe indoor heat exchanger 162 is input to the second branch port N2 of the second three-way valve 152, During the cooling operation, only the refrigerant temperature attenuator 171 is operated by the controller Ct, and the refrigerant temperature compensator 172 is stopped, and thus passes without any action.

Meanwhile, the refrigerant passing through the single pipe indoor heat exchanger 161 and the long pipe indoor heat exchanger 162 is discharged through the common port C of the second three-way valve 152 and is controlled by the controller Ct. The common port C and the second branch port N2 of the 2 bypass valve 154 are open and the first branch port N1 is closed so that these refrigerants are sufficiently supplied during the passage of the second mixer MIX2. After mixing, the mixture is returned to the compressor 110 through the four-way valve 120.

In particular, the second temperature sensor 182 and the fourth temperature sensor 184 are provided at the output side of the long-pipe indoor heat exchanger 162 and the output side of the short-pipe indoor heat exchanger 161 during the cooling operation. In Ct), the refrigerant temperature attenuator 171 is additionally controlled by obtaining an average value of the temperatures of these two sensors 182 and 184 and predicting the refrigerant temperature input to the compressor 110.

Of course, when the temperature of the fifth temperature sensor 185 installed on the input side of the compressor 110 is large compared with the average value of the second temperature sensor 182 and the fourth temperature sensor 184, the second mixer ( While passing through the installed portion MIX2) is analyzed as being affected by the environment and further controls the refrigerant temperature attenuator 171.

Hereinafter, the heating operation of the high-efficiency heat pump air conditioner using the smart phone application remote management consisting of the above configuration will be described.

As shown in FIG. 5, during the heating operation (ie, the heating cycle), the refrigerant becomes a high temperature and high pressure gas by the compressor 110 and is input to the common port C of the second three-way valve 152. At this time, opening and closing of the second bypass valve 154 is controlled by the controller Ct, and the refrigerant is input to the second three-way valve 152 through the second bypass pipe BP2.

Next, the refrigerant input to the second three-way valve 152 passes through the first branch port N1 and the second branch port N2 to the single pipe indoor heat exchanger 161 and the long pipe indoor heat exchanger 162. Is distributed.

Therefore, the refrigerant supplied to the single pipe indoor heat exchanger 161 is input to the first branch port N1 of the first three-way valve 151 after being used to heat the room, and the long pipe indoor heat exchanger 162. The refrigerant supplied thereto is input to the second branch port N2 of the second three-way valve 152 after being used to heat the room.

In particular, the present invention, in the case of the long pipe length of the pipe length is long, such as in winter, when the temperature of the room is low, since the refrigerant flows in the process of flowing to the long heat pipe heat exchanger 162, using the refrigerant temperature compensator 172 The temperature is supplied in advance.

The temperature compensation characteristic of the refrigerant temperature compensator 172 is calculated in consideration of various parameters β including the length L of the long pipe, the ambient temperature T and the friction characteristics with the pipe in the controller Ct. The value may be determined using the value, or may be determined by directly referring to the measured temperature value of the second temperature sensor 182.

Although the refrigerant temperature attenuator 171 is installed on the flow path through which the refrigerant output through the long pipe indoor heat exchanger 162 is input to the second branch port N2 of the first three-way valve 151, During the heating operation, only the refrigerant temperature compensator 172 is operated by the controller Ct, and the refrigerant temperature attenuator 171 is stopped so that the refrigerant is passed without any action.

Next, as described above, the refrigerant passing through the single pipe indoor heat exchanger 161 and the long pipe indoor heat exchanger 162 is discharged through the common port C of the first three-way valve 151, and these refrigerants are controlled by the controller. The opening and closing of the first bypass valve 153 is controlled by (Ct) to pass through the first mixer (MIX1), and then sequentially expands the expansion valve 140, the outdoor heat exchanger 130, and the four-way valve 120. It is recovered to the compressor 110 through.

In particular, the first temperature sensor 181 and the third temperature sensor 183 are provided at the output side of the long-pipe indoor heat exchanger 162 and the output side of the short-pipe indoor heat exchanger 161 during the heating operation, respectively. The coolant temperature compensator 172 may be additionally controlled by obtaining the average value of the temperatures of these two sensors at Ct) and predicting the coolant temperature input to the compressor 110.

Of course, when the temperature of the fifth temperature sensor 185 installed at the input side of the compressor 110 is large compared with the average value of the first temperature sensor 181 and the third temperature sensor 183, the first mixer MIX1. ) Is analyzed as being affected by the surrounding environment while passing through the installed portion, and the refrigerant temperature compensator 172 may be further controlled.

The specific embodiments of the present invention have been described above. It is to be understood, however, that the scope and spirit of the present invention is not limited to these specific embodiments, and that various modifications and changes may be made without departing from the spirit of the present invention. If you have, you will understand.

Therefore, it should be understood that the above-described embodiments are provided so that those skilled in the art can fully understand the scope of the present invention. Therefore, it should be understood that the embodiments are to be considered in all respects as illustrative and not restrictive, The invention is only defined by the scope of the claims.

110: compressor 120: four-way valve
130: outdoor heat exchanger 140: expansion valve
151: first three-way valve 152: second three-way valve
153: first bypass valve 154: second bypass valve
161: single pipe indoor heat exchanger 162: long pipe indoor heat exchanger
171: refrigerant temperature attenuator 172: refrigerant temperature compensator
181 to 185: temperature sensor 186: constant temperature and humidity
191a, 191b: remote collector 192a, 192b: concentrator
193: Switch 194: Operation Server
194a: database server 195: mobile communication terminal
MIX1, MIX2: Mixer

Claims (6)

A compressor 110 for compressing the refrigerant;
A four-way valve 120 for switching the circulation direction of the refrigerant according to a cooling cycle or a heating cycle;
An outdoor heat exchanger (130) installed outdoors and configured to exchange heat between the outside air and the refrigerant;
Expansion valve 140 for expanding the refrigerant to lower the pressure;
A first three-way valve 151 having a common port C connected to the expansion valve 140;
A single pipe internal heat exchanger (161) having one end connected to a first branch port (N1) of the first three-way valve (151) and installed in a refrigerant cycle consisting of a single pipe;
A long pipe indoor heat exchanger (162) having one end connected to a second branch port (N2) of the first three-way valve (151) and installed in a refrigerant cycle consisting of a long pipe;
The common port C is connected to the compressor 110, the first branch port N1 is connected to the other end of the single pipe indoor heat exchanger 161, and the second branch port N2 is connected to the long pipe interior. A second three-way valve 152 connected to the other end of the heat exchanger 162;
A refrigerant temperature attenuator 171 connected to one side of the long heat pipe indoor heat exchanger 162 and lowering the temperature of the increased coolant when the temperature of the coolant rises as the coolant flows along the long pipe for a long time during operation of a cooling cycle. Wow;
A refrigerant temperature compensator 172 connected to the other side of the long heat pipe indoor heat exchanger 162 and raising the temperature of the lowered coolant when the temperature of the coolant drops as the coolant flows along the long pipe for a long time when the heating cycle is operated. Wow;
After circulating the single pipe in operation of the heating cycle, the refrigerant having the first temperature introduced through the first branch port N1 of the first three-way valve 151 and the long pipe are circulated in the first three directions. A first mixer (MIX1) for mixing the refrigerant of the second temperature introduced through the second branch port (N2) of the valve (151) and returning it to the compressor (110);
After the cooling cycle is circulated, the single pipe is circulated and the refrigerant having a third temperature introduced through the first branch port N1 of the second three-way valve 152 and the long pipe are circulated in the second three directions. A second mixer (MIX2) for mixing the refrigerant of the fourth temperature introduced through the second branch port (N2) of the valve (152) and returning it to the compressor (110);
A controller (Ct) for controlling the operation of the cooling cycle or the heating cycle; And
Remote control terminal that accesses the controller Ct through a communication network and receives information about the cooling cycle or the heating cycle from the controller Ct, or remotely controls the cooling cycle or the heating cycle through the controller Ct. (194, 195); high efficiency heat pump air conditioner using a smart phone application remote management comprising a. The method of claim 1,
The first mixer (MIX1) and the second mixer (MIX2) is a high efficiency heat pump air conditioning apparatus using a smart phone remote management, characterized in that each consisting of a tube having a coil shape. The method of claim 2,
Both ends of the first mixer (MIX1) and the second mixer (MIX2) bypass pipes (BP1, BP2) are respectively connected in parallel, high efficiency heat pump air conditioner using the smart phone application remote management. The method of claim 1,
A first temperature sensor 181 installed between the long pipe indoor heat exchanger 162 and the coolant temperature attenuator 171 and the long pipe indoor heat exchanger 162 and the coolant temperature compensator 172. Further installed between the second temperature sensor 182 for detecting the temperature of the refrigerant,
When the temperature detected by the first temperature sensor 181 is higher than the low temperature reference value, the controller Ct lowers the temperature of the refrigerant to a low temperature reference value by the coolant temperature attenuator 171, and at the second temperature sensor 182. If the detected temperature is lower than the high temperature reference value, the high-efficiency heat pump air conditioner using the smart phone application remote management, characterized in that to increase the temperature of the refrigerant to a high temperature reference value by the refrigerant temperature compensator (172). The method of claim 4, wherein
A third temperature sensor 183 installed between the single pipe indoor heat exchanger 161 and the first three-way valve 151 and detecting the temperature of the refrigerant, and the single pipe indoor heat exchanger 161 and the second three direction Further comprising a fourth temperature sensor 184 is installed between the valve 152 to detect the temperature of the refrigerant,
The controller Ct controls the refrigerant temperature compensator 172 when the average of the temperatures detected by the first temperature sensor 181 and the third temperature sensor 183 is different from the input reference value of the compressor 110. And controlling the refrigerant temperature attenuator 171 when the average of the temperatures detected by the second temperature sensor 182 and the fourth temperature sensor 184 is different from the input reference value of the compressor 110. High efficiency heat pump air conditioner using smart phone remote management. The method of claim 5,
The fifth temperature sensor 185 is installed at the input side of the compressor 110 to detect the temperature of the refrigerant input to the compressor 110 and transmit the smart phone application to the controller Ct. High efficiency heat pump air conditioner using.

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