Energy Performance of Liquid Desiccant and Evaporative Cooling-Assisted 100% Outdoor Air Systems under Various Climatic Conditions

The main purpose of this study is to evaluate the applicability of a liquid desiccant and evaporative cooling-assisted 100% outdoor air system (LD-IDECOAS) in six typical cities in China. The six cities are located in different climatic zones in China and are selected because they are comparable owing to the outdoor air conditions. Many studies have shown that the annual operating energy consumption of LD-IDECOAS is nearly half compared with the conventional variable air volume (VAV) system. Because the climate characteristics of the six selected cities were different, the appropriate mode of operation of the LD-IDECAOS was applied to each studied city, and energy simulations were performed. Based on the design conditions of each region, the required cooling and heating loads were calculated for office buildings using transient system simulations (TRNSYS) 17, and the performance of the LD-IDECOAS and its energy consumption were simulated with a commercial engineering equation solver (EES) program. Depending on the climate characteristics of each city, adequate modifications were evaluated with simulations in terms of energy consumption. The proposed system was compared with the VAV system and the evaporative cooling assisted 100% outdoor air-conditioning system (IDECOAS) for detailed simulation results in the effort to evaluate the energy-saving potential. Finally, the results show that the proposed system saves considerable energy over conventional VAV systems and, in summer, the applications save even more energy than IDECOAS. However, there is a slight difference between the different geographical regions in terms of the annual operating energy consumption. In summary, the proposed system can yield significant energy-saving benefits in hot and humid regions whereas, in dry regions, the proposed system is more applicable in the summer. Consequently, LD-IDECOAS can be adopted for different climatic zones as a heating, ventilating, and air-conditioning (HVAC) system by introducing 100% outdoor air.


Introduction
Recently, indirect and direct evaporative cooler assisted 100% outdoor air systems (IDECOAS) have gained popularity as energy-efficient and environment-friendly air-conditioning systems compared with conventional variable air volume (VAV) systems. This system can reduce the required cooling energy by precooling the supplied air using evaporative cooling. Recent studies have investigated the possibility of significant cooling energy reduction [1][2][3]. Gilani and Poshtiri developed a mathematical model for two-stage evaporative coolers and studied the geometrical and physical properties of the proposed system under various outdoor conditions. It was also concluded that the proposed system could satisfy the thermal comfort conditions under the specified temperature the dehumidifying part removes the moisture from the air. After the dehumidification process, the weakened solution in the dehumidifier enters the regeneration section and reverts to a strong solution through the water evaporation process. During the evaporation process, the vapor pressure must be high and the weak solution first enters the SHE. It is first heated and then reheated by the HC. The HC and the SHE are located in the exhaust side of the system so that exhaust air can be sent to the secondary channel of the IEC. When the evaporative cooling system provides sensible cooling, on the secondary side of the IEC, the lower side of the WBT is selected from the outside air, and the exhaust air to be sent to the secondary channel and a better cooling effect can be attained by cooling the processed air that passes through the primary side. Depending on the thermal load required for the air-conditioning space, the flow rate of air supplied to the room fluctuates. The advantage is similar to the VAV system. The path highlighted in blue in Figure 1 is the path through which the cooler supplies air to the air-conditioning space. Additionally, the area marked in red indicates the path of the indoor return air and the exhaust air. solution through the water evaporation process. During the evaporation process, the vapor pressure must be high and the weak solution first enters the SHE. It is first heated and then reheated by the HC. The HC and the SHE are located in the exhaust side of the system so that exhaust air can be sent to the secondary channel of the IEC. When the evaporative cooling system provides sensible cooling, on the secondary side of the IEC, the lower side of the WBT is selected from the outside air, and the exhaust air to be sent to the secondary channel and a better cooling effect can be attained by cooling the processed air that passes through the primary side. Depending on the thermal load required for the air-conditioning space, the flow rate of air supplied to the room fluctuates. The advantage is similar to the VAV system. The path highlighted in blue in Figure 1 is the path through which the cooler supplies air to the air-conditioning space. Additionally, the area marked in red indicates the path of the indoor return air and the exhaust air. The proposed system has four operational modes corresponding to each of the four areas of the psychrometric chart ( Figure 2). The operating mode is selected according to the outdoor air conditions of the six regions selected to be studied when the system is in operation. The operation mode of the LD-IDECOAS was also mentioned in the literature [20].  The proposed system has four operational modes corresponding to each of the four areas of the psychrometric chart ( Figure 2). The operating mode is selected according to the outdoor air conditions of the six regions selected to be studied when the system is in operation. The operation mode of the LD-IDECOAS was also mentioned in the literature [20]. solution through the water evaporation process. During the evaporation process, the vapor pressure must be high and the weak solution first enters the SHE. It is first heated and then reheated by the HC. The HC and the SHE are located in the exhaust side of the system so that exhaust air can be sent to the secondary channel of the IEC. When the evaporative cooling system provides sensible cooling, on the secondary side of the IEC, the lower side of the WBT is selected from the outside air, and the exhaust air to be sent to the secondary channel and a better cooling effect can be attained by cooling the processed air that passes through the primary side. Depending on the thermal load required for the air-conditioning space, the flow rate of air supplied to the room fluctuates. The advantage is similar to the VAV system. The path highlighted in blue in Figure 1 is the path through which the cooler supplies air to the air-conditioning space. Additionally, the area marked in red indicates the path of the indoor return air and the exhaust air. The proposed system has four operational modes corresponding to each of the four areas of the psychrometric chart ( Figure 2). The operating mode is selected according to the outdoor air conditions of the six regions selected to be studied when the system is in operation. The operation mode of the LD-IDECOAS was also mentioned in the literature [20].   The red part in Figure 2 is the A mode of operation and the outdoor air is hot and humid in the summer. The high temperature and humidity of the outdoor air is dehumidified using the LD unit installed in the proposed system until it reaches the set air supply humidity ratio line indicated by the line denoted by the letter "a". After the dehumidification process is completed, the air passes through the IEC and DEC, and undergoes an adiabatic cooling process along the isentropic path until the air supply target temperature is reached. The heat of the adiabatically cooled air that passes through the primary channel of the IEC is removed by the water spray of the secondary channel. Finally, the processed air is cooled to a target supply air (SA) state (that is, 15 • C saturated conditions) via the DEC and is provided to the conditioned zone. Additionally, DEC does not always work. If only the LD and IEC operate and the supply air set point can be met, the operation of the DEC is not required. Otherwise, the processed air is cooled adiabatically by the DEC to the target supply air set point.
As shown in the green and purple colors in Figure 3, regions B and C indicate that the ambient conditions are intermediate seasons, the LD unit is deactivated, and the system is operated mainly by sensible cooling through the cold and neutral decks. Regions B and C are distinguished by the line denoted with the letter "b", and the WBT or the enthalpy of the set point (that is, saturation at 15 • C). The processed air bypasses the LD and is first sensibly cooled through the IEC to drop its temperature to the target temperature or the enthalpy of the SA set point (that is, 42.1 KJ/kg). DEC performs the adiabatic cooling process until the supply air set point is met. Area C corresponds to the condition where the outside air temperature is higher than the SA set point, and at which the enthalpy is lower than the target supply air condition, the LD unit and IEC operation are stopped and turned off and only the operation of DEC is satisfied by the target supply air temperature. Heat recovery through SHE will achieve the air supply set point temperature of the neutral deck. If only SHE is operating, and the set temperature cannot be achieved, additional heating will be performed with the use of the HC. The red part in Figure 2 is the A mode of operation and the outdoor air is hot and humid in the summer. The high temperature and humidity of the outdoor air is dehumidified using the LD unit installed in the proposed system until it reaches the set air supply humidity ratio line indicated by the line denoted by the letter "a". After the dehumidification process is completed, the air passes through the IEC and DEC, and undergoes an adiabatic cooling process along the isentropic path until the air supply target temperature is reached. The heat of the adiabatically cooled air that passes through the primary channel of the IEC is removed by the water spray of the secondary channel. Finally, the processed air is cooled to a target supply air (SA) state (that is, 15 °C saturated conditions) via the DEC and is provided to the conditioned zone. Additionally, DEC does not always work. If only the LD and IEC operate and the supply air set point can be met, the operation of the DEC is not required. Otherwise, the processed air is cooled adiabatically by the DEC to the target supply air set point.
As shown in the green and purple colors in Figure 3, regions B and C indicate that the ambient conditions are intermediate seasons, the LD unit is deactivated, and the system is operated mainly by sensible cooling through the cold and neutral decks. Regions B and C are distinguished by the line denoted with the letter "b", and the WBT or the enthalpy of the set point (that is, saturation at 15 °C). The processed air bypasses the LD and is first sensibly cooled through the IEC to drop its temperature to the target temperature or the enthalpy of the SA set point (that is, 42.1 KJ/kg). DEC performs the adiabatic cooling process until the supply air set point is met. Area C corresponds to the condition where the outside air temperature is higher than the SA set point, and at which the enthalpy is lower than the target supply air condition, the LD unit and IEC operation are stopped and turned off and only the operation of DEC is satisfied by the target supply air temperature. Heat recovery through SHE will achieve the air supply set point temperature of the neutral deck. If only SHE is operating, and the set temperature cannot be achieved, additional heating will be performed with the use of the HC. In the winter, LD and DEC do not work and heat is recovered by IEC and SHE installed on the exhaust side, as depicted in the yellow part of Figure 3. This shows the operation of the neutral deck of the proposed system and denotes as the role of the SHE without using water in the second side of the IEC. At this time, the IEC begins to function as the SHE will recover the sensible heat from the EA side and perform the primary preheating to meet the set point. However, if the target temperature is In the winter, LD and DEC do not work and heat is recovered by IEC and SHE installed on the exhaust side, as depicted in the yellow part of Figure 3. This shows the operation of the neutral deck of the proposed system and denotes as the role of the SHE without using water in the second side of the IEC. At this time, the IEC begins to function as the SHE will recover the sensible heat from the EA side and perform the primary preheating to meet the set point. However, if the target temperature is not reached when only IEC is used, the heating coil located on the exhaust side is used to ensure compliance with the set-point condition. The above description applies to all operating modes of the LD-IDECOAS which are modulated by the state of the outside air. Figure 4 depicts the IDECOAS proposed in this study. The proposed IDECOAS consists of the IEC, CC, and DEC. The HC and SHE were installed as the exhaust side configuration of the proposed LD-IDEOCAS. In the path of the outside air, the primary channel of the IEC passes first, followed by the CC and DEC. The flow rate of the SA is the same as that of the conventional VAV system, similar to the case of the proposed LD-IDECOAS and it fluctuates according to the heat load of the building space. not reached when only IEC is used, the heating coil located on the exhaust side is used to ensure compliance with the set-point condition.

IDECOAS
The above description applies to all operating modes of the LD-IDECOAS which are modulated by the state of the outside air. Figure 4 depicts the IDECOAS proposed in this study. The proposed IDECOAS consists of the IEC, CC, and DEC. The HC and SHE were installed as the exhaust side configuration of the proposed LD-IDEOCAS. In the path of the outside air, the primary channel of the IEC passes first, followed by the CC and DEC. The flow rate of the SA is the same as that of the conventional VAV system, similar to the case of the proposed LD-IDECOAS and it fluctuates according to the heat load of the building space. In the proposed IDECOAS, similar to the LD-IDECOAS proposed above, the operation is divided into four operation modes. Depending on the outdoor air conditions, the operation mode is selected and the system is operated according to the selected mode, as shown in the psychrometric chart of Figure 5.  In the proposed IDECOAS, similar to the LD-IDECOAS proposed above, the operation is divided into four operation modes. Depending on the outdoor air conditions, the operation mode is selected and the system is operated according to the selected mode, as shown in the psychrometric chart of Figure 5. not reached when only IEC is used, the heating coil located on the exhaust side is used to ensure compliance with the set-point condition.

IDECOAS
The above description applies to all operating modes of the LD-IDECOAS which are modulated by the state of the outside air. Figure 4 depicts the IDECOAS proposed in this study. The proposed IDECOAS consists of the IEC, CC, and DEC. The HC and SHE were installed as the exhaust side configuration of the proposed LD-IDEOCAS. In the path of the outside air, the primary channel of the IEC passes first, followed by the CC and DEC. The flow rate of the SA is the same as that of the conventional VAV system, similar to the case of the proposed LD-IDECOAS and it fluctuates according to the heat load of the building space. In the proposed IDECOAS, similar to the LD-IDECOAS proposed above, the operation is divided into four operation modes. Depending on the outdoor air conditions, the operation mode is selected and the system is operated according to the selected mode, as shown in the psychrometric chart of Figure 5.   First, mode A is used to represent the cooling season ( Figure 5) and the operation of this mode is mainly performed by IEC and CC. The ambient air belonging to region A is higher than the set temperature and the absolute humidity is higher than the set absolute humidity. The air that passes through the secondary side of the IEC is subjected to scavenged air with a relatively lower wet bulb temperature in the outdoor air and the EA. In order to reduce the energy consumption of the CC, IEC simulated it with the highest efficiency setting. The processed air passing through the IEC passes through the CC and the latent heat and the sensible heat loads of the air are treated to maintain the set air condition. This process involves the process of passing through the cold deck.

IDECOAS
Regions B and C, which are listed under the outdoor air conditions, describe the intermediate season. At this time, the outside air is higher than the set temperature, the air is sufficiently dry, and the operation of CC is determined according to the degree of humidity of the outside air. If the enthalpy of the outdoor air is higher than the enthalpy of the set point, it is placed in the B region, and the CC works to handle the latent heat load in the processed air. Additionally, DEC then performs a cooling process along the enthalpy line to maintain the set temperature. Conversely, if the enthalpy is lower than the set enthalpy, it enters region C, whereby only the DEC operates and adiabatic cooling occurs.
There are two possible situations when ambient air is in Mode B ( Figure 6). If it is located in region B, the IEC will operate first. At this time, there are two cases. In the case of situation a in region B, the set point enthalpy cannot be reached even after IEC is applied, and CC works to handle the latent load in the air. After CC is cooled to the set point enthalpy, the cooling process is executed along the enthalpy line to maintain the set DEC temperature. If the IEC has been sufficiently cooled to reach the enthalpy line of the set point or has cooled more than the set point enthalpy, DEC is immediately used to achieve cooling to the set point temperature. First, mode A is used to represent the cooling season ( Figure 5) and the operation of this mode is mainly performed by IEC and CC. The ambient air belonging to region A is higher than the set temperature and the absolute humidity is higher than the set absolute humidity. The air that passes through the secondary side of the IEC is subjected to scavenged air with a relatively lower wet bulb temperature in the outdoor air and the EA. In order to reduce the energy consumption of the CC, IEC simulated it with the highest efficiency setting. The processed air passing through the IEC passes through the CC and the latent heat and the sensible heat loads of the air are treated to maintain the set air condition. This process involves the process of passing through the cold deck.
Regions B and C, which are listed under the outdoor air conditions, describe the intermediate season. At this time, the outside air is higher than the set temperature, the air is sufficiently dry, and the operation of CC is determined according to the degree of humidity of the outside air. If the enthalpy of the outdoor air is higher than the enthalpy of the set point, it is placed in the B region, and the CC works to handle the latent heat load in the processed air. Additionally, DEC then performs a cooling process along the enthalpy line to maintain the set temperature. Conversely, if the enthalpy is lower than the set enthalpy, it enters region C, whereby only the DEC operates and adiabatic cooling occurs.
There are two possible situations when ambient air is in Mode B ( Figure 6). If it is located in region B, the IEC will operate first. At this time, there are two cases. In the case of situation a in region B, the set point enthalpy cannot be reached even after IEC is applied, and CC works to handle the latent load in the air. After CC is cooled to the set point enthalpy, the cooling process is executed along the enthalpy line to maintain the set DEC temperature. If the IEC has been sufficiently cooled to reach the enthalpy line of the set point or has cooled more than the set point enthalpy, DEC is immediately used to achieve cooling to the set point temperature. If the enthalpy of the outdoor air is lower than the set enthalpy, as shown in the blue portion of Figure 5, that is, when it matches situation b in region B and enters region C, adiabatic cooling is performed only based on the DEC operation.
The green portion of Figure 5 shows the system's operation during the winter when the outside air temperature is lower than the set temperature. At this time, heating is required and the CC and DEC responsible for the cooling operation are turned off. The IEC is used like SHE and the air passing through the secondary side preheats the air passing through the primary channel by the wasted heat recovered from the EA stream. Similar to the proposed LD-IDECOAS, in the heating season, the SHE If the enthalpy of the outdoor air is lower than the set enthalpy, as shown in the blue portion of Figure 5, that is, when it matches situation b in region B and enters region C, adiabatic cooling is performed only based on the DEC operation.
The green portion of Figure 5 shows the system's operation during the winter when the outside air temperature is lower than the set temperature. At this time, heating is required and the CC and DEC responsible for the cooling operation are turned off. The IEC is used like SHE and the air passing through the secondary side preheats the air passing through the primary channel by the wasted heat recovered from the EA stream. Similar to the proposed LD-IDECOAS, in the heating season, the SHE located on the exhaust side recovers heat in the effort to heat the processed air before it sends it to the air-conditioning unit. If the set temperature is not satisfied, even if it passes through the IEC preheating and neutral deck, the HC is turned on to satisfy the set conditions.

VAV System
In order to compare the energy performance with LD-IDECOAS, a VAV system with a reheating coil (RHC) was used to prevent overcooling problems in the cooling section of the CC (Figure 7). The economizer on the air side was used in this simulation. The cooling process of the air-conditioning space was mainly carried out by CC. On the cooling coil side, a water-cooled chiller was applied and was operated to maintain the supply air temperature (that is, 15 • C saturated). If the temperature of the processed air was lower than the set point temperature after CC, the RHC starts to operate. In the summer, when the undesired overcooling occurs owing to the operation of the cooling coil, the RHC is operated to raise the temperature of the processed air. When it is extremely hot and humid, not only is the required cooling load increased, but the energy consumption is also increased at the heating side, and the energy consumption of the entire system is increased. The supply air flow of the VAV is basically changed according to the heat load of the room and the minimum ventilation requirement is determined according to the information provided in the ASHRAE standard 62.1-2013 [22]. located on the exhaust side recovers heat in the effort to heat the processed air before it sends it to the air-conditioning unit. If the set temperature is not satisfied, even if it passes through the IEC preheating and neutral deck, the HC is turned on to satisfy the set conditions.

VAV System
In order to compare the energy performance with LD-IDECOAS, a VAV system with a reheating coil (RHC) was used to prevent overcooling problems in the cooling section of the CC (Figure 7). The economizer on the air side was used in this simulation. The cooling process of the air-conditioning space was mainly carried out by CC. On the cooling coil side, a water-cooled chiller was applied and was operated to maintain the supply air temperature (that is, 15 °C saturated). If the temperature of the processed air was lower than the set point temperature after CC, the RHC starts to operate. In the summer, when the undesired overcooling occurs owing to the operation of the cooling coil, the RHC is operated to raise the temperature of the processed air. When it is extremely hot and humid, not only is the required cooling load increased, but the energy consumption is also increased at the heating side, and the energy consumption of the entire system is increased. The supply air flow of the VAV is basically changed according to the heat load of the room and the minimum ventilation requirement is determined according to the information provided in the ASHRAE standard 62.1-2013 [22].

Selection of the Region to be Simulated
Because of its vast land area of 9.6 million square kilometers, China has a very complex terrain and a diverse and distinct climate. Owing to the complexity of the terrain, China has created a very diverse and distinct climate. China's climate classification is largely divided into five major climatic zones for thermal environmental design according to the GB50176-93 "Thermal Design Code for Civil Building standards" [23]. The monthly average temperatures of the hottest month and coldest month in each region were the criteria for dividing the entire country into different regions. As shown in Figure 8, these regions include the severe cold, mild, hot summer, cold winter, hot summer, warm winter regions, and the very cold regions. In this study, the cities were located in six different climatic zones and were selected for simulations of the energy performance of the proposed system in regions with different outdoor conditions, as shown in Figure 8.

Selection of the Region to be Simulated
Because of its vast land area of 9.6 million square kilometers, China has a very complex terrain and a diverse and distinct climate. Owing to the complexity of the terrain, China has created a very diverse and distinct climate. China's climate classification is largely divided into five major climatic zones for thermal environmental design according to the GB50176-93 "Thermal Design Code for Civil Building standards" [23]. The monthly average temperatures of the hottest month and coldest month in each region were the criteria for dividing the entire country into different regions. As shown in Figure 8, these regions include the severe cold, mild, hot summer, cold winter, hot summer, warm winter regions, and the very cold regions. In this study, the cities were located in six different climatic zones and were selected for simulations of the energy performance of the proposed system in regions with different outdoor conditions, as shown in Figure 8. As a representative city for each climate area, there is a significant difference in outdoor conditions, as shown in Figures 9 and 10, which indicate the changes in the annual outdoor conditions of each city. Beijing, Urumqi, Kunming, and Xi'an, all belong to relatively dry climate regions, while Guangzhou and Shanghai are classified as humid regions. In addition, Urumqi has lengthy winter climate features and Guangzhou's annual temperature difference is very low and it has a very warm climate in winter. The meteorological data of the six selected regions were exported by the TMY2 weather data provided in TRNSYS 17 [24] and the thermal load of buildings, outdoor air (OA) conditions, and return air conditions were applied to the simulation to calculate the air flow in each region.

Model Building Information
For this simulation, one office building located in Guangzhou, China was set up as a model building for simulations. This selected building was located on the upper floor and the total area was approximately 300 m 2 . Table 1 summarizes the various basic conditions for the building model. As a representative city for each climate area, there is a significant difference in outdoor conditions, as shown in Figures 9 and 10, which indicate the changes in the annual outdoor conditions of each city. Beijing, Urumqi, Kunming, and Xi'an, all belong to relatively dry climate regions, while Guangzhou and Shanghai are classified as humid regions. In addition, Urumqi has lengthy winter climate features and Guangzhou's annual temperature difference is very low and it has a very warm climate in winter. The meteorological data of the six selected regions were exported by the TMY2 weather data provided in TRNSYS 17 [24] and the thermal load of buildings, outdoor air (OA) conditions, and return air conditions were applied to the simulation to calculate the air flow in each region. As a representative city for each climate area, there is a significant difference in outdoor conditions, as shown in Figures 9 and 10, which indicate the changes in the annual outdoor conditions of each city. Beijing, Urumqi, Kunming, and Xi'an, all belong to relatively dry climate regions, while Guangzhou and Shanghai are classified as humid regions. In addition, Urumqi has lengthy winter climate features and Guangzhou's annual temperature difference is very low and it has a very warm climate in winter. The meteorological data of the six selected regions were exported by the TMY2 weather data provided in TRNSYS 17 [24] and the thermal load of buildings, outdoor air (OA) conditions, and return air conditions were applied to the simulation to calculate the air flow in each region.

Model Building Information
For this simulation, one office building located in Guangzhou, China was set up as a model building for simulations. This selected building was located on the upper floor and the total area was approximately 300 m 2 . Table 1 summarizes the various basic conditions for the building model. As a representative city for each climate area, there is a significant difference in outdoor conditions, as shown in Figures 9 and 10, which indicate the changes in the annual outdoor conditions of each city. Beijing, Urumqi, Kunming, and Xi'an, all belong to relatively dry climate regions, while Guangzhou and Shanghai are classified as humid regions. In addition, Urumqi has lengthy winter climate features and Guangzhou's annual temperature difference is very low and it has a very warm climate in winter. The meteorological data of the six selected regions were exported by the TMY2 weather data provided in TRNSYS 17 [24] and the thermal load of buildings, outdoor air (OA) conditions, and return air conditions were applied to the simulation to calculate the air flow in each region.

Model Building Information
For this simulation, one office building located in Guangzhou, China was set up as a model building for simulations. This selected building was located on the upper floor and the total area was approximately 300 m 2 . Table 1 summarizes the various basic conditions for the building model.

Model Building Information
For this simulation, one office building located in Guangzhou, China was set up as a model building for simulations. This selected building was located on the upper floor and the total area was approximately 300 m 2 . Table 1 summarizes the various basic conditions for the building model. In the energy simulation program TRNSYS 17, the set indoor conditions and sensible heat load and latent heat loads of the buildings in each selected area are calculated. In the process of the building energy simulations, standardized thermal transmittance was set according to the Chinese national standard GB 50189-2015 [25]. The window-to-wall ratio was also set according to this standard. In all areas it is prescribed that the area of the window should not exceed 0.8 when it is proportional to the wall. In addition, the JG67-2006 standard, "Office Building Design Criteria" in China, also standardizes the standard room temperature and relative humidity of the cooling and heating seasons in various regions [26]. According to JG67-2006, the standard room temperature is 26 • C in the summer and 18 • C in the winter. The relative humidity of the summer should be less than 60% and in winter it should be more than 30%. The thermal transmittance of the exterior walls of the buildings in Beijing, Guangzhou, Urumqi, and Xi'an were 0.50 W/m 2 K, 0.80 W/m 2 K, 0.43 W/m 2 K, and 0.50 W/m 2 K, respectively. The thermal transmittance of the outer wall of Kunming was determined to be 0.80 W/m 2 K. Similarly, the thermal transmittance of the outer wall in Shanghai was 0.6 W/m 2 K. In accordance with the standard ISO 7730, residents of office buildings were assumed to perform light duties, with the sensible heat and latent heat of a 75 W/person considered. The building's computer type, lighting, and lighting/work schedule, are were set according to the values listed in Table 1.

Simulation Overview
In the proposed system, the highest energy conservation benefit comes from the LD system. After an exothermic dehumidification process, an undesired heat transfer to the processed air will occur, thereby raising the temperature of the dehumidifier and making it impossible to maintain its set temperature. Therefore, the regenerated dehumidified solution is cooled by the cooling device and then supplied to the dehumidifier. Herein, it is believed that free cooling on the water side using a CT can save more energy to reduce the energy consumption of the cooling system. The dehumidification solution of the dehumidifier removes the moisture from the incoming air and then becomes a diluted solution. It enters the regenerator, regenerates it, and then makes it into a dehumidifier. In the process of regenerating the solution, a large amount of heat is usually required. In most cases, a gas boiler or an electric water heater is used as the heating device. In recent years, more energy efficient and more environmentally friendly renewable energy system heat sources, such as solar thermal systems, have achieved widespread usage. Since coal resources are high in China, it has been determined that using coal as a district heating source has significant advantages in terms of energy conservation. It is expected that the setting of the cooling unit of the dehumidifying cooling part of the LD system and the heating part of the regeneration heating part have considerable energy potential.
The dehumidification efficiency of the LD system is based on the equilibrium humidity ratio, denoted by the actual removal rate of the moisture to the maximum moisture removal rate. The humidity ratio of the air from the dehumidifier (w ab.out ) can be found based on the expression of the dehumidifier's efficiency (Equation (1)). For this calculation, the dehumidification efficiency (ε ab ), the humidity ratio of the air entering the dehumidifier (w ab.in ), and the equilibrium humidity ratio of the dehumidifier (w ab.e ) must all be known.
The regenerative efficiency is the ratio of the actual evaporation rate to the maximum evaporation rate based on the equilibrium humidity ratio. The humidity ratio of the air from the regenerator (w reg.out ) can also be obtained from the efficiency of the regenerator, in accordance to Equation (2). Equations (1) and (2) were verified by various experimental studies [17,18,[27][28][29][30]. When calculating the humidity ratio, the regeneration efficiency (ε reg ), the humidity ratio of the air entering the regenerator (w reg.in ), and the equilibrium humidity ratio of the generator (w reg.e ) must all be given.
Equation (3) shows the equilibrium humidity ratio (w e ) of the dehumidifier and regenerator mentioned above. The saturated vapor pressure (p s ) in this equation was derived from Equation (4), as proposed by Fumo and Goswami [30]. Various parameters applied in Equation (4) are also known in the literature and depend on the dehumidification process and the regeneration process. This is summarized in Table 2 [31].
w e = 0.622 p s 101.325 − p s (3) In this study, the application of the efficiency equation of the dehumidifier (Equation (5)) was chosen in accordance to the experimental model of Chung and Luo [31], and the efficiency equation of the regenerator (Equation (6)) was modeled by Martin and Goswami [32].  The temperatures of the air passing through the dehumidifier or the regenerator were confirmed using Equation (7), which expresses a temperature difference ratio. In this case, the temperature ratio (ε T_LD ), the temperature of the air entering the dehumidifier or the regenerator (T LD.in ), and the temperature of the solution entering the dehumidifier (T sol.in ) should be given.
The current literature shows that the temperatures of the dehumidifier and the regenerator are similar [13,33].
In this study, the liquid-to-gas ratio (L/G ratio) was set to values in the range of 0.5 to 1 and the solution concentration at the dehumidifier inlet was set to 40%. The efficiency of the SHE of the LD system is was assumed to be 70% and the solution temperature at the inlet is was assumed to be 30 • C. On the regeneration side, the inlet temperature was set to 55 • C and the liquid-to-gas ratio (L/G ratio) was set to 4.
The processed air passes through the LD system and through the evaporative cooler. Because the dehumidified air passes through the IEC's primary panel, there is no humidity change and the humidity ratio of the air from the IEC is equal to the humidity ratio of the air passing through the LD system. The air passing through the IEC is cooled and the exit temperature of the IEC can be derived in accordance to Equation (8). In this simulation, the IEC efficiency was set to 80%, while the efficiency of the DEC was set to 95%. Correspondingly, the temperature of the wet bulb from the IEC can be calculated using Equation (9). Equations (8) and (9) were also verified by literature studies [17,18].
All of the processes mentioned above were used in EES for simulation and energy performance analyses [34]. Figure 11 shows the simulation diagram of IDECOAS and Figure 12 shows the simulation process of the proposed system. The temperatures of the air passing through the dehumidifier or the regenerator were confirmed using Equation (7), which expresses a temperature difference ratio. In this case, the temperature ratio (ε _ ), the temperature of the air entering the dehumidifier or the regenerator ( . ), and the temperature of the solution entering the dehumidifier ( . ) should be given.
The current literature shows that the temperatures of the dehumidifier and the regenerator are similar [13,33].
In this study, the liquid-to-gas ratio (L/G ratio) was set to values in the range of 0.5 to 1 and the solution concentration at the dehumidifier inlet was set to 40%. The efficiency of the SHE of the LD system is was assumed to be 70% and the solution temperature at the inlet is was assumed to be 30 °C. On the regeneration side, the inlet temperature was set to 55 °C and the liquid-to-gas ratio (L/G ratio) was set to 4.
The processed air passes through the LD system and through the evaporative cooler. Because the dehumidified air passes through the IEC's primary panel, there is no humidity change and the humidity ratio of the air from the IEC is equal to the humidity ratio of the air passing through the LD system. The air passing through the IEC is cooled and the exit temperature of the IEC can be derived in accordance to Equation (8). In this simulation, the IEC efficiency was set to 80%, while the efficiency of the DEC was set to 95%. Correspondingly, the temperature of the wet bulb from the IEC can be calculated using Equation (9). Equations (8) and (9) were also verified by literature studies [17,18].
All of the processes mentioned above were used in EES for simulation and energy performance analyses [34]. Figure 11 shows the simulation diagram of IDECOAS and Figure 12 shows the simulation process of the proposed system.

Comparative Analyses of Seasonal Results
The simulation of the proposed system was carried out annually to evaluate how regions with various climatic characteristics were constructed in operational mode, and to compare the energy savings between the systems. Figures 13-18 compare the seasonal results of the three systems operating in each city. In order to analyze the results accurately, all simulation results were converted into primary energy according to the first energy conversion standard in China, GB/T2589-2008 [35]. In this standard, the conversion coefficient is 0.1229 kgce/KWh when the electric energy is converted to coal energy. The conversion coefficient is 0.03412 kgce/KWh when the thermal energy of the district heating used in the regeneration side of the LD system is converted to coal energy. When the thermal energy was changed to the appropriate unit, the conversion factor was changed to 0.009485 kgec/KWh. The conversion standard of primary energy, that is, the energy consumption of coal, is shown in Table 3.

Energy Type
Transfer Factor ( / ) Electrical energy 0.1229 Thermal energy (district heating) 0.0095 Figure 13 shows a comparison of energy consumption when three systems are applied in the Beijing region. In the summer, the VAV and IDECOAS systems are both subjected to load handling by the cooling coil, while in Beijing, IDECOAS consumes more energy than the conventional VAV system. The energy change of the cooling coil part in the IDECOAS is mainly due to the pre-cooling effect of the IEC. If the IEC efficiency is high, the cooling coil consumption in the IDECOAS is reduced and if the IEC efficiency is low, the cooling coil is used extensively. In this simulation, the IEC efficiency was set to 80%, but the IEC efficiency did not reach 80% during the operation of the actual system. In the summer in the Beijing region, the cooler consumption is high owing to the slightly hot and humid conditions, and the limited cooling performance of the IEC. However, the proposed

Comparative Analyses of Seasonal Results
The simulation of the proposed system was carried out annually to evaluate how regions with various climatic characteristics were constructed in operational mode, and to compare the energy savings between the systems. Figures 13-18 compare the seasonal results of the three systems operating in each city. In order to analyze the results accurately, all simulation results were converted into primary energy according to the first energy conversion standard in China, GB/T2589-2008 [35]. In this standard, the conversion coefficient is 0.1229 kgce/KWh when the electric energy is converted to coal energy. The conversion coefficient is 0.03412 kgce/KWh when the thermal energy of the district heating used in the regeneration side of the LD system is converted to coal energy. When the thermal energy was changed to the appropriate unit, the conversion factor was changed to 0.009485 kgec/KWh. The conversion standard of primary energy, that is, the energy consumption of coal, is shown in Table 3.  Figure 13 shows a comparison of energy consumption when three systems are applied in the Beijing region. In the summer, the VAV and IDECOAS systems are both subjected to load handling by the cooling coil, while in Beijing, IDECOAS consumes more energy than the conventional VAV system. The energy change of the cooling coil part in the IDECOAS is mainly due to the pre-cooling effect of the IEC. If the IEC efficiency is high, the cooling coil consumption in the IDECOAS is reduced and if the IEC efficiency is low, the cooling coil is used extensively. In this simulation, the IEC efficiency was set to 80%, but the IEC efficiency did not reach 80% during the operation of the actual system. In the summer in the Beijing region, the cooler consumption is high owing to the slightly hot and humid conditions, and the limited cooling performance of the IEC. However, the proposed system consumed more fan energy owing to the introduction of LD. The energy-saving system, such as the CT and district heating, was applied in the proposed system, and the energy used for the fan part was thus complemented by this. As a result, in the summer in the Beijing region, the proposed system yielded an energy saving of approximately 35.25% compared to the VAV system and can save an additional energy of approximately 20.44% compared to IDECOAS. In the winter, it consumes 38.19% less energy than the conventional VAV system. system consumed more fan energy owing to the introduction of LD. The energy-saving system, such as the CT and district heating, was applied in the proposed system, and the energy used for the fan part was thus complemented by this. As a result, in the summer in the Beijing region, the proposed system yielded an energy saving of approximately 35.25% compared to the VAV system and can save an additional energy of approximately 20.44% compared to IDECOAS. In the winter, it consumes 38.19% less energy than the conventional VAV system. As it can be observed from Figure 14, the summer energy consumption in the Urumqi area is much smaller than that for the Beijing area, as mentioned above. This is also due to the special ambient conditions in the Urumqi area. Because the summer in the Urumqi area is shorter than the winter period, the energy consumption is smaller than in other areas. As this is a very dry area, the dehumidification part of the proposed system is considered to be unnecessary. As a result, in the summer, the energy saving of the LD-IDECOAS is 12.96% compared to the energy used by the VAV system and 14.54% compared to the energy used by IDECOAS. It is, thus, not necessary to add the dehumidification part separately and IDECOAS is more profitable. The winter is long in this region, and the temperatures are very low. In the winter, the proposed system saves approximately 91% of the energy consumed by the conventional VAV system. The seasonal energy consumed in Xi'an, as shown in Figure 15, is similar to that consumed in the Beijing region, and because of the precooling of the IEC part of IDECOAS, the energy consumed in the cooler section is slightly lower than that of the VAV. Here too, the proposed system consumes more energy in the fan section owing to the system configuration, but this can be offset by the thermal energy consumption in the proposed system. In terms of the total energy consumption, the proposed system saves approximately 39.4% of the energy consumed by the VAV system, and approximately 22.96% less energy compared to IDECOAS. As it can be observed from Figure 14, the summer energy consumption in the Urumqi area is much smaller than that for the Beijing area, as mentioned above. This is also due to the special ambient conditions in the Urumqi area. Because the summer in the Urumqi area is shorter than the winter period, the energy consumption is smaller than in other areas. As this is a very dry area, the dehumidification part of the proposed system is considered to be unnecessary. As a result, in the summer, the energy saving of the LD-IDECOAS is 12.96% compared to the energy used by the VAV system and 14.54% compared to the energy used by IDECOAS. It is, thus, not necessary to add the dehumidification part separately and IDECOAS is more profitable. The winter is long in this region, and the temperatures are very low. In the winter, the proposed system saves approximately 91% of the energy consumed by the conventional VAV system. system consumed more fan energy owing to the introduction of LD. The energy-saving system, such as the CT and district heating, was applied in the proposed system, and the energy used for the fan part was thus complemented by this. As a result, in the summer in the Beijing region, the proposed system yielded an energy saving of approximately 35.25% compared to the VAV system and can save an additional energy of approximately 20.44% compared to IDECOAS. In the winter, it consumes 38.19% less energy than the conventional VAV system. As it can be observed from Figure 14, the summer energy consumption in the Urumqi area is much smaller than that for the Beijing area, as mentioned above. This is also due to the special ambient conditions in the Urumqi area. Because the summer in the Urumqi area is shorter than the winter period, the energy consumption is smaller than in other areas. As this is a very dry area, the dehumidification part of the proposed system is considered to be unnecessary. As a result, in the summer, the energy saving of the LD-IDECOAS is 12.96% compared to the energy used by the VAV system and 14.54% compared to the energy used by IDECOAS. It is, thus, not necessary to add the dehumidification part separately and IDECOAS is more profitable. The winter is long in this region, and the temperatures are very low. In the winter, the proposed system saves approximately 91% of the energy consumed by the conventional VAV system. The seasonal energy consumed in Xi'an, as shown in Figure 15, is similar to that consumed in the Beijing region, and because of the precooling of the IEC part of IDECOAS, the energy consumed in the cooler section is slightly lower than that of the VAV. Here too, the proposed system consumes more energy in the fan section owing to the system configuration, but this can be offset by the thermal energy consumption in the proposed system. In terms of the total energy consumption, the proposed system saves approximately 39.4% of the energy consumed by the VAV system, and approximately 22.96% less energy compared to IDECOAS. The seasonal energy consumed in Xi'an, as shown in Figure 15, is similar to that consumed in the Beijing region, and because of the precooling of the IEC part of IDECOAS, the energy consumed in the cooler section is slightly lower than that of the VAV. Here too, the proposed system consumes more energy in the fan section owing to the system configuration, but this can be offset by the thermal energy consumption in the proposed system. In terms of the total energy consumption, the proposed system saves approximately 39.4% of the energy consumed by the VAV system, and approximately 22.96% less energy compared to IDECOAS. Seasonal energy consumption figures of Kunming are shown in Figure 16. The outside air of the city is said to be warm and comfortable. It is a relatively dry area. The annual temperature variation is not large and the cold and hot weather conditions are not extreme. In the summer, this system consumes approximately 18.81% less energy than the existing VAV system. As shown in Figure 17, the climate characteristics of the area can be observed in the Guangzhou area, whereby the cooling energy consumption occurs in winter. This area is a hot and humid area and the winter season is absent. Therefore, IDECOAS consumes more cooling energy than VAV owing to the latent and the sensible heat loads of the introduced outdoor air. In this region, the proposed system is absolutely necessary. Owing to the dehumidification effect of LD, the proposed system energy savings are approximately 22% in the summer and 15.73% in the winter. Compared with IDECOAS, the energy consumption was 25.63% less than that consumed by VAV in the summer period. The Shanghai area has four distinct seasons ( Figure 18) and its cities are representative of hot and humid cities similar to the Guangzhou area discussed above. Hot and humid days mainly occur in the summer. Therefore, when compared to the VAV system and IDECOAS, 31% and 34.17% of energy savings were achieved compared to Guangzhou, respectively. Seasonal energy consumption figures of Kunming are shown in Figure 16. The outside air of the city is said to be warm and comfortable. It is a relatively dry area. The annual temperature variation is not large and the cold and hot weather conditions are not extreme. In the summer, this system consumes approximately 18.81% less energy than the existing VAV system. Seasonal energy consumption figures of Kunming are shown in Figure 16. The outside air of the city is said to be warm and comfortable. It is a relatively dry area. The annual temperature variation is not large and the cold and hot weather conditions are not extreme. In the summer, this system consumes approximately 18.81% less energy than the existing VAV system. As shown in Figure 17, the climate characteristics of the area can be observed in the Guangzhou area, whereby the cooling energy consumption occurs in winter. This area is a hot and humid area and the winter season is absent. Therefore, IDECOAS consumes more cooling energy than VAV owing to the latent and the sensible heat loads of the introduced outdoor air. In this region, the proposed system is absolutely necessary. Owing to the dehumidification effect of LD, the proposed system energy savings are approximately 22% in the summer and 15.73% in the winter. Compared with IDECOAS, the energy consumption was 25.63% less than that consumed by VAV in the summer period. The Shanghai area has four distinct seasons ( Figure 18) and its cities are representative of hot and humid cities similar to the Guangzhou area discussed above. Hot and humid days mainly occur in the summer. Therefore, when compared to the VAV system and IDECOAS, 31% and 34.17% of energy savings were achieved compared to Guangzhou, respectively. As shown in Figure 17, the climate characteristics of the area can be observed in the Guangzhou area, whereby the cooling energy consumption occurs in winter. This area is a hot and humid area and the winter season is absent. Therefore, IDECOAS consumes more cooling energy than VAV owing to the latent and the sensible heat loads of the introduced outdoor air. In this region, the proposed system is absolutely necessary. Owing to the dehumidification effect of LD, the proposed system energy savings are approximately 22% in the summer and 15.73% in the winter. Compared with IDECOAS, the energy consumption was 25.63% less than that consumed by VAV in the summer period. Seasonal energy consumption figures of Kunming are shown in Figure 16. The outside air of the city is said to be warm and comfortable. It is a relatively dry area. The annual temperature variation is not large and the cold and hot weather conditions are not extreme. In the summer, this system consumes approximately 18.81% less energy than the existing VAV system. As shown in Figure 17, the climate characteristics of the area can be observed in the Guangzhou area, whereby the cooling energy consumption occurs in winter. This area is a hot and humid area and the winter season is absent. Therefore, IDECOAS consumes more cooling energy than VAV owing to the latent and the sensible heat loads of the introduced outdoor air. In this region, the proposed system is absolutely necessary. Owing to the dehumidification effect of LD, the proposed system energy savings are approximately 22% in the summer and 15.73% in the winter. Compared with IDECOAS, the energy consumption was 25.63% less than that consumed by VAV in the summer period. The Shanghai area has four distinct seasons ( Figure 18) and its cities are representative of hot and humid cities similar to the Guangzhou area discussed above. Hot and humid days mainly occur in the summer. Therefore, when compared to the VAV system and IDECOAS, 31% and 34.17% of energy savings were achieved compared to Guangzhou, respectively. The Shanghai area has four distinct seasons ( Figure 18) and its cities are representative of hot and humid cities similar to the Guangzhou area discussed above. Hot and humid days mainly occur in the summer. Therefore, when compared to the VAV system and IDECOAS, 31% and 34.17% of energy savings were achieved compared to Guangzhou, respectively. In conclusion, IDECOAS could be more profitable in very dry areas, whereas the proposed system has more energy potential in hot and humid areas. Even in warmer areas like Kunming, the proposed system would be more advantageous in terms of energy when only the summer period is considered. Figure 19 compares the system's energy consumption for the LD-IDECOAS, VAV, and the IDECOAS systems, when they are applied in the Beijing region throughout the year. In the LD-IDECOAS, it is easy to observe in the figure that CC is not used, and the CT in the LD system is much smaller than the other two systems that use CCs. The system fan consumption owing to a highpressure drop will be greater than the other two systems. However, this deficiency is considered to be supplemented by the energy saved in the cooler section. As a result, the proposed system saves approximately 36.7% of the system's operating energy over the VAV system and reduces the energy of the system by approximately 8.55% compared to IDECOAS.  Figure 20 compares the energy consumption of the three systems operating in the Urumqi region. In Urumqi, it is possible to confirm that LD-IDECOAS is much more energy-efficient than the VAV system even though it has shorter summer and longer winter periods compared to the other regions. It has been confirmed that the CT usage in the LD section is much smaller than the CC application, which is similar to the Beijing region, and it is also related to the use of evaporative In conclusion, IDECOAS could be more profitable in very dry areas, whereas the proposed system has more energy potential in hot and humid areas. Even in warmer areas like Kunming, the proposed system would be more advantageous in terms of energy when only the summer period is considered. Figure 19 compares the system's energy consumption for the LD-IDECOAS, VAV, and the IDECOAS systems, when they are applied in the Beijing region throughout the year. In the LD-IDECOAS, it is easy to observe in the figure that CC is not used, and the CT in the LD system is much smaller than the other two systems that use CCs. The system fan consumption owing to a high-pressure drop will be greater than the other two systems. However, this deficiency is considered to be supplemented by the energy saved in the cooler section. As a result, the proposed system saves approximately 36.7% of the system's operating energy over the VAV system and reduces the energy of the system by approximately 8.55% compared to IDECOAS. In conclusion, IDECOAS could be more profitable in very dry areas, whereas the proposed system has more energy potential in hot and humid areas. Even in warmer areas like Kunming, the proposed system would be more advantageous in terms of energy when only the summer period is considered. Figure 19 compares the system's energy consumption for the LD-IDECOAS, VAV, and the IDECOAS systems, when they are applied in the Beijing region throughout the year. In the LD-IDECOAS, it is easy to observe in the figure that CC is not used, and the CT in the LD system is much smaller than the other two systems that use CCs. The system fan consumption owing to a highpressure drop will be greater than the other two systems. However, this deficiency is considered to be supplemented by the energy saved in the cooler section. As a result, the proposed system saves approximately 36.7% of the system's operating energy over the VAV system and reduces the energy of the system by approximately 8.55% compared to IDECOAS.  Figure 20 compares the energy consumption of the three systems operating in the Urumqi region. In Urumqi, it is possible to confirm that LD-IDECOAS is much more energy-efficient than the VAV system even though it has shorter summer and longer winter periods compared to the other regions. It has been confirmed that the CT usage in the LD section is much smaller than the CC application, which is similar to the Beijing region, and it is also related to the use of evaporative  In Urumqi, it is possible to confirm that LD-IDECOAS is much more energy-efficient than the VAV system even though it has shorter summer and longer winter periods compared to the other regions. It has been confirmed that the CT usage in the LD section is much smaller than the CC application, which is similar to the Beijing region, and it is also related to the use of evaporative coolers. Owing to the shorter summertime, the application time to the air-conditioning system in the summer is shorter and the energy-saving potential of the cooling side is not seen much. Therefore, the analyzed annual energy consumption is similar to IDECOAS. The proposed system used approximately 34.55% less energy than VAV and 0.04% less energy than IDECOAS. coolers. Owing to the shorter summertime, the application time to the air-conditioning system in the summer is shorter and the energy-saving potential of the cooling side is not seen much. Therefore, the analyzed annual energy consumption is similar to IDECOAS. The proposed system used approximately 34.55% less energy than VAV and 0.04% less energy than IDECOAS. Shown in Figure 21 are the simulation results for the Xi'an region. Xi'an is located in the same climate zone as the Beijing region and the energy consumption results are also similar. The LD section and the evaporative cooler were used to reduce the energy consumption by approximately 76.42% compared to the CC part of the VAV system. The penalty associated with the fan cannot be avoided equally, but it seems to be offset by the saved cooling energy. Therefore, the proposed system reduced the energy consumption by approximately 41.78% compared to VAV and saved energy by approximately 15.13% compared to IDECOAS.  Shown in Figure 21 are the simulation results for the Xi'an region. Xi'an is located in the same climate zone as the Beijing region and the energy consumption results are also similar. The LD section and the evaporative cooler were used to reduce the energy consumption by approximately 76.42% compared to the CC part of the VAV system. The penalty associated with the fan cannot be avoided equally, but it seems to be offset by the saved cooling energy. Therefore, the proposed system reduced the energy consumption by approximately 41.78% compared to VAV and saved energy by approximately 15.13% compared to IDECOAS.

Comparison of Annual Energy Consumption
coolers. Owing to the shorter summertime, the application time to the air-conditioning system in the summer is shorter and the energy-saving potential of the cooling side is not seen much. Therefore, the analyzed annual energy consumption is similar to IDECOAS. The proposed system used approximately 34.55% less energy than VAV and 0.04% less energy than IDECOAS. Shown in Figure 21 are the simulation results for the Xi'an region. Xi'an is located in the same climate zone as the Beijing region and the energy consumption results are also similar. The LD section and the evaporative cooler were used to reduce the energy consumption by approximately 76.42% compared to the CC part of the VAV system. The penalty associated with the fan cannot be avoided equally, but it seems to be offset by the saved cooling energy. Therefore, the proposed system reduced the energy consumption by approximately 41.78% compared to VAV and saved energy by approximately 15.13% compared to IDECOAS.  Out of the six selected areas, the Kunming area is a warm and very dry region, unlike the other areas. In Kunming, similarly to other dry areas, the potential for energy savings in the cooling area is clearly visible and the fan consumption is high ( Figure 22). However, because of the dry ambient air, the requirement of the LD is also small. It has been confirmed that the amount of dehumidification used is much lower than in other areas. Unlike other regions, the energy consumption of LD-IDECOAS is energy efficient as it saves energy compared to VAV but consumes more energy than IDECOAS. This is because it is the smallest of the six regions where the total energy consumption is chosen. The final simulation results in this area show elicited reductions in energy consumption of approximately 26.05% compared to VAV, and approximately 12.05% compared to IDECOAS. Out of the six selected areas, the Kunming area is a warm and very dry region, unlike the other areas. In Kunming, similarly to other dry areas, the potential for energy savings in the cooling area is clearly visible and the fan consumption is high ( Figure 22). However, because of the dry ambient air, the requirement of the LD is also small. It has been confirmed that the amount of dehumidification used is much lower than in other areas. Unlike other regions, the energy consumption of LD-IDECOAS is energy efficient as it saves energy compared to VAV but consumes more energy than IDECOAS. This is because it is the smallest of the six regions where the total energy consumption is chosen. The final simulation results in this area show elicited reductions in energy consumption of approximately 26.05% compared to VAV, and approximately 12.05% compared to IDECOAS.  Figure 23 is the total annual energy consumption of each system in the Guangzhou area. Guangzhou can yield energy savings in reference to the LD part owing to the hot and humid weather condition throughout the year. Correspondingly, the LD part is used more and the fan usage is also increased. Therefore, although the advantages of the proposed system are better than those of the other systems, the usage of the proposed system is also high. The final annual data analysis shows that the energy saving is approximately 18.91% compared to VAV and that the energy consumption is approximately 15.83% less than IDECOAS. Figure 24 shows the annual energy consumption of each system in Shanghai with hot and humid summer atmospheric conditions. Shanghai was hot and humid in the summer and the use of the LD system was able to save energy. Together with Guangzhou, Shanghai has four distinct seasons during the year, which can be seen to be even more beneficial in terms of their energy-saving capacity. The energy savings are approximately 24.86% compared to VAV, and approximately 24.56% compared to IDECOAS.

Shown in
Overall, the above denote a section on the comparative analyses of the results of the three systems in each region as the result outcomes of the simulations conducted throughout the period of the year.  Figure 23 is the total annual energy consumption of each system in the Guangzhou area. Guangzhou can yield energy savings in reference to the LD part owing to the hot and humid weather condition throughout the year. Correspondingly, the LD part is used more and the fan usage is also increased. Therefore, although the advantages of the proposed system are better than those of the other systems, the usage of the proposed system is also high. The final annual data analysis shows that the energy saving is approximately 18.91% compared to VAV and that the energy consumption is approximately 15.83% less than IDECOAS. Figure 24 shows the annual energy consumption of each system in Shanghai with hot and humid summer atmospheric conditions. Shanghai was hot and humid in the summer and the use of the LD system was able to save energy. Together with Guangzhou, Shanghai has four distinct seasons during the year, which can be seen to be even more beneficial in terms of their energy-saving capacity. The energy savings are approximately 24.86% compared to VAV, and approximately 24.56% compared to IDECOAS.

Shown in
Overall, the above denote a section on the comparative analyses of the results of the three systems in each region as the result outcomes of the simulations conducted throughout the period of the year.

Conclusions
In this study, the integrated LD system in IDECOAS was proposed and evaluated for applicability based on energy simulations through its application in different climate and outdoor conditions. LD-IDECOAS with district heating has been simulated and the energy consumption results were compared with the conventional IDECOAS and VAV systems. The conditions were set according to the various Chinese standards that were applied at the stage of the simulation. The results of this study are as follows;

Conclusions
In this study, the integrated LD system in IDECOAS was proposed and evaluated for applicability based on energy simulations through its application in different climate and outdoor conditions. LD-IDECOAS with district heating has been simulated and the energy consumption results were compared with the conventional IDECOAS and VAV systems. The conditions were set according to the various Chinese standards that were applied at the stage of the simulation. The results of this study are as follows;

Conclusions
In this study, the integrated LD system in IDECOAS was proposed and evaluated for applicability based on energy simulations through its application in different climate and outdoor conditions. LD-IDECOAS with district heating has been simulated and the energy consumption results were compared with the conventional IDECOAS and VAV systems. The conditions were set according to the various Chinese standards that were applied at the stage of the simulation. The results of this study are as follows;

•
The results of the seasonal analysis show that LD-IDECOAS can save considerable energy when applying LD-IDECOAS in all regions compared with the conventional VAV system.

•
In addition, in seasonal results, IDECOAS is better in the Urumqi region, which has a very cold and dry condition, and Kunming region with special ambient conditions, compared to LD-IDECOAS. In hot and humid areas, the application of LD-IDECOAS is much better.

•
The annual results show that LD-IDECOAS saved much more energy than the VAV systems in all regions. • When LD-IDECOAS is compared with IDECOAS in the annual results, the energy consumption results in the dry areas are not much different, but they may vary depending on the area characteristics. The more the drying, the less the dehumidification performance of the LD system is needed, so the application of IDECOAS is more advantageous. In this study, it was found that the application of LD-IDECOAS is more advantageous in hot and humid areas.
Overall, the application of LD-IDECOAS shows better energy-saving potential in most areas, and IDECOAS may be more advantageous in very dry climatic regions, depending on local characteristics. Additionally, in hot and humid areas, using LD-IDECOAS can achieve high energy savings.

Conflicts of Interest:
The authors declare no conflict of interest. Greek symbols ε effectiveness (%)