KR20120055842A - Heat pump type hot water supply system using waste heat - Google Patents

Abstract

PURPOSE: A hot water supply system for a heat pump using waste heat sources is provided to prevent a pipe from becoming frozen and bursting by controlling refrigeration cycles as temperature decreases. CONSTITUTION: A water supply system for a heat pump using waste heat sources comprises an air conditioner(210), a cooling tower(250), a heat pump(260), a heating boiler(220), a water-cooling refrigerator(240), a heat exchanger(240) for cooling water and circulating water heated by heat sources, a hot water supply tank(270), and a MICOM(280). The heat exchanger heat-exchanges the circulated water circulating inside the heat pump with the cooling water flowing into the cooling tower. Condensation heat is used as the heat source of the heat pump. The hot water supply tank stores heated circulated water and supplies the circulated water as hot water. The MICOM controls air conditioning and water boiling operations.

Description

Heat pump type hot water supply system using waste heat}

The present invention relates to a waste heat source heat pump hot water supply system, and more particularly, in providing a hot water supply by reusing a condensation array, which is a waste heat source, as a heat source of a heat pump, precisely controlling each component of the hot water supply system according to a change in load. This improves energy efficiency, prevents subcooled refrigeration cycle operation due to a drop in condensation temperature, and prevents damage to the equipment. It is about the system.

In general, there are year-round air-conditioning loads in various indoor spaces, including semiconductor production line plants and office-sized large buildings, which are operated throughout the four seasons by applying an air condition-ing system. Separately, hot water boilers are operated to provide hot water.

That is, as shown in FIG. 1, the air conditioning system 100 includes an air conditioner 110 for providing air for heating and cooling, a heating boiler 120 for supplying hot water for heating, and a water-cooled freezer 130 for supplying cooling cold water. And a cooling tower 140 for discharging the condensation array.

The air conditioner 110 includes a suction duct 111, a filter 112, a humidifier 113, a cooling coil 114, a heating coil 115, a blower 116, and the like, and includes a heating boiler 120. ) Supplies hot water forcedly circulated by the hot water circulation pump 121 to the heating coil 115, and the water-cooled refrigerator 130 supplies cold water forcedly circulated by the cold water circulation pump 131 to the cooling coil 114. do.

Therefore, when the blower 116 is operated in the state where the cold water is supplied to the cooling coil 114, the cool air is supplied to the room, and when the blower 116 is operated while the hot water is supplied to the heating coil 115. In order to provide warm air to the room, the filter 112 and the humidifier 113 is used in this process to filter the contaminated air and maintain proper humidity.

In addition, a hot water supply boiler 150 and a hot water tank 160 are provided for supplying hot water, and the hot water supplied from the hot water boiler 150 is temporarily stored in the hot water tank 160, and the user supplies the hot water whenever the user uses it. Doing.

However, the conventional air conditioning system 100 as described above passes the cold water through the evaporator (not shown) of the water-cooled refrigerator 130 and then supplies it to the cooling coil 114, the cold water recovered from the cooling coil 114 is again A cold water circulation closed circuit flowing into the evaporator (not shown) is formed. In addition, the cooling water circulating through the cooling tower 140 allows a separate refrigerant cycle to be made in the water-cooled refrigerator 130 by passing through a condenser (not shown), and in this case, the condensation array generated in the condenser of the water-cooled refrigerator 130 is cooled by the cooling water. After the endotherm was discarded in the cooling tower 140.

Therefore, there is a problem that the condensation arrangement is treated as simple waste heat and is discarded insignificantly through the cooling tower 140, as well as using fossil fuels to supply hot water while discharging the condensation arrangement as described above. There was a problem that an irrational method of providing a hot water supply by operating the hot water boiler 150 was applied.

On the other hand, in order to solve the above problems, although a hot water supply system employing a heat pump that can reuse the condensation array as a heat source is provided in some parts, each component of the hot water supply system can be precisely adjusted according to the load variation. There is a problem that the energy efficiency is rather low because it can not be controlled.

In addition, in operating the heat pump using the condensation arrangement generated by the water-cooled refrigerator 130 as a heat source, if the refrigeration cycle is repeated repeatedly, the condensation temperature is excessively lowered to form a sub-cooling refrigeration cycle, thereby liquefying the refrigerant (not shown). There was a problem in that it does not have a configuration for controlling the condensation temperature of the water-cooled refrigerator (130) even when damage occurs to various equipment, such as introduced into).

In addition, when the ambient temperature is low or the condensation temperature is excessively lowered, although the temperature of the cooling water may be lowered and the pipe or the heat exchanger may be freeze, there is a problem in the prior art that it is not provided with a configuration for preventing such damage.

The present invention has been proposed to solve the problems described above, and in providing the hot water supply by reusing the condensation array, which is a waste heat source, as a heat source of the heat pump, by precisely controlling the respective components of the hot water supply system according to the load variation. Waste heat source heat pump hot water supply system to improve energy efficiency, prevent damage to equipment by preventing the operation of subcooled refrigeration cycle due to the drop of condensation temperature, and to prevent the condensation of the pipeline by cooling the temperature of the coolant according to the ambient temperature It is about.

To this end, the waste heat source heat pump hot water supply system according to the present invention comprises: an air conditioner for cooling or heating air by using a cooling coil and a heating coil and supplying it to an air-conditioned space; A cooling tower installed outdoors; A heat pump for heating or cooling the supplied water according to the circulation direction of the refrigerant; A heating boiler for supplying hot water used for heating; The cold water cooled while passing through the freezer evaporator provided therein is provided to the cooling coil of the air conditioner, and the cold water circulating water recovered after passing through the cooling coil transfers heat to the cooling water through the freezing cycle, and the cooling water is A water-cooled freezer passing through the freezer condenser and then sent to the cooling tower; A cooling water to heat source-side circulating water heat exchanger that heats the cooling water absorbing the condensation array sent to the cooling tower and the load-side circulation water circulating inside the heat pump, so that the condensation array is used as a heat source of the heat pump. ; A hot water tank in which the heat pump receives and stores the load-side circulating water heated using the condensation array as a heat source, and provides the heated load-side circulating water as hot water; And a microcomputer for controlling the air conditioning operation and the hot water supply operation.

In this case, the heat pump is divided into a load side connected to the hot water tank and a heat source side connected to the cooling water versus a heat source side circulating water heat exchanger, and a load inlet temperature sensor is installed on the circulating water inlet side of the load side or circulated among the load side. A load outlet temperature sensor is provided on the water outlet side, and the microcomputer is configured to control the operation of the heat pump according to the load side circulating water detection temperature at the load inlet temperature sensor or the load outlet temperature sensor.

The heat pump may be divided into a load side connected to the hot water tank and a heat source side connected to the cooling water versus a heat source side circulating water heat exchanger, and a heat source inlet temperature sensor is installed on the circulating water inlet side of the heat source side or the heat source. A heat source outlet temperature sensor is installed at the circulating water outlet side of the side, and the microcomputer is configured to control the operation of the heat pump according to the heat source side circulating water detection temperature at the heat source inlet temperature sensor or the heat source outlet temperature sensor. It is preferable.

In addition, the microcomputer sets different reference temperature values of the circulating water of the heat source side of the heat pump according to whether the water-cooled refrigerator is operated according to a change in the heating and cooling load, and is detected by the heat source inlet temperature sensor or the heat source outlet temperature sensor. It is preferable to control the operation of the heat pump by comparing a heat source side circulation water detection temperature value with a reference temperature value of the heat source side circulation water.

The heat pump may be divided into a load side connected to the hot water tank and a heat source side connected to the coolant versus heat source side circulating water heat exchanger, and between the heat source side and the coolant to heat source side circulating water heat exchanger of the heat pump. Three-way valve is installed, the common port of the first three-way valve is connected to the circulating water outlet side pipe of the heat pump heat source side, the first port of the first three-way valve is the cooling water to heat source side circulation water It is connected to the inlet side pipe of the heat exchanger, the second port of the first three-way valve is connected to the pipe connecting the intake side of the circulating water inlet side of the heat pump heat source side and the outlet side of the cooling water to the heat source side circulating water heat exchanger Connected, it is preferable to change the circulation direction of the heat source side circulation water of the heat pump.

The apparatus may further include a coolant inlet temperature sensor installed between the coolant versus heat source side circulating water heat exchanger and the cooling tower to measure a temperature of the coolant input to the cooling tower, wherein the microcomputer detects the coolant inlet temperature sensor. PID control of the opening direction of the first three-way valve according to the temperature value of.

In addition, a second three-way valve is installed between the cooling water to the heat source side circulation water heat exchanger and the inlet side of the cooling tower, the common port of the second three-way valve is the cooling water output side of the cooling water to heat source side circulation water heat exchanger It is connected to the pipe, the first port of the second three-way valve is connected to the cooling water inlet side pipe of the cooling tower, the second port of the second three-way valve is the cooling water output side of the cooling tower and the cooling water of the water-cooled refrigerator It is preferable to change the circulation direction of the cooling water discharged from the water-cooled refrigerator by connecting to the pipe connecting the inlet side to each other.

The apparatus may further include a cooling water outlet temperature sensor installed between the cooling tower and the water cooling unit to measure the temperature of the cooling water discharged from the cooling tower, wherein the microcomputer according to the temperature value of the cooling water sensed by the cooling water output temperature sensor. It is preferable to PID control the opening direction of the said 2rd triangular valve.

The apparatus may further include a cooling water circulation pump configured to circulate the cooling water along the cooling water circulation pipe and the cooling water circulation pipe through which the cooling water flows, wherein the microcomputer performs the cooling water circulation pump when the temperature of the cooling water falls below a predetermined value. It is preferable to forcibly operate to prevent freezing of the cooling water circulation pipe.

In addition, a hot water boiler 271 connected to the hot water tank 270 to provide hot water to the hot water tank 270 auxiliary, the hot water boiler 271 is operated by the microcomputer 280 This is preferably controlled.

According to the waste heat source heat pump hot water supply system according to the present invention as described above, in providing the hot water supply by reusing the condensation arrangement, which is a waste heat source, as a heat source of the heat pump, by precisely controlling the respective components of the hot water supply system according to the load variation Improve energy efficiency.

In addition, the present invention prevents the operation of the subcooled refrigeration cycle according to the drop of the condensation temperature to prevent damage to the equipment, as well as to maintain the maintenance by allowing the cooling water temperature to be lowered according to the ambient temperature to prevent the conduit from freezing To facilitate.

1 is a block diagram showing a hot water supply system according to the prior art.
2 is a block diagram showing a waste heat source heat pump hot water supply system according to the present invention.
3 is a block diagram showing a heat pump of the waste heat source heat pump hot water supply system according to the present invention.
Figure 4 is a block diagram showing a heat source side circulating water flow control state of the waste heat source heat pump hot water supply system according to the present invention.
5 is a graph showing a heat source side circulation water flow opening rate of the waste heat source heat pump hot water supply system according to the present invention.
Figure 6 is a block diagram showing a cooling water flow control state of the waste heat source heat pump hot water supply system according to the present invention.
7 is a graph showing the cooling water flow opening rate of the waste heat source heat pump hot water supply system according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail for the waste heat source heat pump hot water supply system according to a preferred embodiment of the present invention.

As shown in FIG. 2, the waste heat source heat pump hot water supply system 200 according to the present invention includes an air conditioner 210, a heating boiler 220, a water-cooled refrigerator 230, and a coolant versus heat source as a configuration for heat exchange. Side circulation water heat exchanger 240, cooling tower 250, waste heat source heat pump 260 (hereinafter referred to as "heat pump") and a hot water tank 270. However, it may further include a hot water boiler 271 as needed.

Further, the load outlet temperature sensor S1, the load inlet temperature sensor S2, the heat source inlet temperature sensor S3, the heat source outlet temperature sensor S4, and the cooling water as means for measuring the temperature of the circulating or cooling water. And an inlet temperature sensor S5 and a coolant outlet temperature sensor S6.

In addition, the first three-way valve (3W1), the second three-way valve (3W2), hot water circulation pump 221, cold water circulation pump 231 as a configuration for adjusting or forcibly circulating the flow direction of the circulation water or cooling water. And a cooling water circulation pump 232, a load side circulation pump 261 and a heat source side circulation pump 262.

Of course, it also includes a microcomputer (MICOM, 280) to control the configuration as described above to enable the air conditioning and hot water operation in the optimal state.

On the other hand, the air conditioner 210 of the configuration as described above is to supply the air-conditioned space by cooling or heating the air, but there are various types of things, as shown in Figure 2 usually suction duct 211, filter 212, humidifier 213, a cooling coil 214, a heating coil 215, a blower 216, and the like.

Therefore, when the blower 216 is operated in the state where the cold water is supplied to the cooling coil 214, the cooler is provided to the room, and when the blower 216 is operated when the hot water is supplied to the heating coil 215. In order to provide warm air to the room, the filter 212 and the humidifier 213 is used in this process to filter the contaminated air and maintain proper humidity.

Cold water is provided by the water-cooled freezer 230, hot water is provided by the heating boiler 220, air supplied to the air conditioning space from the air conditioner 210 is circulated back through the suction duct 211 and, if necessary, Fresh air is mixed and circulated together.

The heating boiler 220 supplies hot water used for heating and operates when the heating load is very large, such as in winter, or when maintaining a constant temperature / humidity state of the room.

On the other hand, such a heating boiler 220 is made of hot water and supplied to the heating coil 215 of the air conditioner 210, while the heat is lost to the air supplied to the room in the process of circulating the heating coil 215, the return water is lowered Reheat.

In order to form a circulating cycle of the heating boiler 220 and the heating coil 215, the heating boiler 220 and the heating coil 215 are connected to form a closed circuit by a water pipe, and the hot water is connected to the water pipe. Forced circulation by the circulation pump 221, the operation of the hot water circulation pump 221 is controlled by the microcomputer 280.

The water-cooled refrigerator 230 is for making cold water and providing it to the cooling coil 214 of the air conditioner 210. Inside the refrigerator, a compressor for a refrigerator (not shown), an expander for a refrigerator (not shown), an evaporator for a refrigerator (not shown) And a condenser (not shown) for a refrigerator to form a refrigeration cycle. The water-cooled refrigerator 240 for circulation with the cooling coil 214 on one side A closed circuit is formed, and a cooling circuit on the other side and a heat source side circulating water heat exchanger 250 and a cooling tower 260 and a closed circuit for circulation are respectively formed.

Therefore, the cold water cooled while passing through the freezer evaporator is supplied to the cooling coil 214 of the air conditioner 210 to provide cool air to the air conditioning space, and in this process, the endothermic heat is raised to increase the temperature, and then the recovered cold water circulating water is Heat is transferred to the cooling water through the freezing cycle, and the cooling water is sent to the cooling tower 250 after passing through the condenser for the freezer.

For this refrigeration cycle, a closed circuit is formed between the one side of the water-cooled refrigerator 230 and the cooling coil 214 of the air conditioner 210 by a water pipe, and the cold water circulation pump 231 is installed in the water pipe so that the cold water and its circulating water are provided. Force circulation.

Of course, on the opposite side, a closed circuit is formed so as to pass through the cooling water to the heat source side circulating water heat exchanger 240 and the cooling tower 250 sequentially, and then return, and a cooling water circulation pump 232 is installed in the water pipe to force circulation of the cooling water. .

On the other hand, the refrigerant is continuously circulated to form a refrigeration cycle in the refrigerator compressor, freezer expander, freezer evaporator and freezer condenser of the water-cooled refrigerator 230 as described above. Then, a condensation arrangement occurs in the process of condensing the refrigerant in the condenser for the refrigerator, and the condensation arrangement absorbs the cooling water sent from the water-cooled refrigerator 230 to the cooling tower 250.

Therefore, the present invention has a configuration in which the heat pump 260 can be operated using the cooling water having a high temperature by absorbing the condensation array generated in the water-cooled refrigerator 230 as a heat source as described below.

To this end, the coolant-to-heat source side circulating water heat exchanger 240 exchanges the cooling water sent from the water-cooled refrigerator 230 to the cooling tower 250 and the water circulating in the heat pump 260 to each other, as described above. While passing through the condenser of the water-cooled refrigerator 230, the condensation arrangement in which the cooling water is absorbed is used as the heat source of the heat pump 260.

That is, the heat source-side circulating water in the process of water-to-water heat exchange between the cooling water and the heat source-side circulating water circulating inside the heat pump 260 as the endothermic heat absorbs the condensation array while passing through the freezer condenser of the water-cooled refrigerator 230 By increasing the temperature of the heat pump 260 to be used as a heat source.

Cooling tower 250 is installed on the roof or the like as is known, and the remaining condensation array included in the cooling water is removed during heat exchange with the air in the process of ejecting and recovering water in the form of spray or thin stream, The coolant having a lower temperature is discharged back to the water-cooled refrigerator (230).

The heat pump 260 heats or cools the water supplied according to the circulation direction of the refrigerant, and includes a load side circulation pump 261 provided at one outside thereof and a heat source side circulation pump 262 provided at the other side of the load side. Circulate circulating water and heat source side circulating water respectively.

In addition, as shown in FIG. 3 as an example, a two-way refrigerant cycle is performed including a compressor 263, a condenser 264, an evaporator 265, an expander 266, and the like.

In addition, both ports 265a and 265b provided in the evaporator 265 are connected 1: 1 to both ports provided on one side of the cooling water versus the heat source side circulating water heat exchanger 240, and at the same time, the condenser ( Both ports 264a and 264b provided at 264 may be connected 1: 1 to both ports provided at one side of the hot water tank 270, respectively.

Accordingly, the load-side circulating water is heated by the heat source-side circulating water that has absorbed the condensation array while passing through the condenser 264 of the heat pump 260, and is then supplied to the hot water supply tank 270 as hot water supply water, and to the hot water tank 270. When the user is using the stored hot water supply, when the hot water is insufficient, direct water flows in through the water supply line, and the direct water flows through the heat pump 260 as the load-side circulation water to be heated by the condensation arrangement as described above.

3 is an example of a two-stage heat pump 260 having two compressors 263, except that the condensation array is reused as a heat source. Detailed description will be omitted.

The microcomputer 280 controls the air conditioning and the hot water supply operation of the waste heat source heat pump hot water supply system 200 according to the present invention. Such a microcomputer 280 usually displays a display unit for displaying a set temperature or a current temperature and various control buttons. It is integrally provided in a control panel (not shown) provided with a command from the administrator.

On the other hand, when the heat pump 260 as described above is divided into one side that is connected to the hot water tank 270 'load side' and the other side that is connected to the cooling water to the heat source side circulating water heat exchanger 240, that is, the heat source A load inlet temperature sensor S2 is provided on the circulating water inlet side of the load side of the pump 260, and a load outlet temperature sensor S1 is provided on the circulating water outlet side of the load side to monitor the temperature of the circulating water, respectively.

In addition, the microcomputer 280 adaptively responds to the fluctuation of the hot water supply load by controlling the operation of the heat pump 260 according to the load side circulating water temperature sensed by the load inlet temperature sensor S2 or the load outlet temperature sensor S1. To be able. Of course, when the hot water supply boiler 271 is further provided, the operation of the hot water boiler 271 is also controlled.

For example, the heat pump 270 alone operates in response to the hot water load. However, by manually operating the control panel, the temperature of the load-side circulating water is set upward, or the temperature of the load-side circulating water is automatically sensed so that it is determined that the temperature of the load-side circulating water is lower than a predetermined set value than the desired temperature. In this case, or when the difference between the temperature of the load-side circulating water and the desired temperature is larger than a predetermined set value, it is determined that the hot water pump 270 alone cannot cope with the hot water load, and the hot water boiler 271 is further operated as an auxiliary heat source.

In the present invention, the heat source inlet temperature sensor S3 is provided on the circulating water inlet side of the heat source side of the heat pump 260, and the heat source outlet temperature sensor S4 is provided on the circulating water outlet side of the heat source side.

The microcomputer 280 controls the operation of the heat pump 260 according to the heat source side circulating water detection temperature at the heat source inlet temperature sensor S3 or the heat source outlet temperature sensor S4.

For example, when the temperature of the heat source side circulating water is lower than the threshold, the operating capacity of the heat pump 260 is lowered to excessively lower the heat source side circulating water to prevent freezing of the cooling water to the heat source side circulating water heat exchanger 240. Of course, in order to reduce the operating capacity of the heat pump 260 as described above, it is preferable to further include the above-mentioned hot water boiler 271 so as to cope with the hot water load.

Lowering the operating capacity of the heat pump 260 lowers the amount of absorbing the condensation arrangement of the cooling water in the heat pump 260 also limits the excessive decrease in the temperature of the cooling water, thereby cooling water to heat source side circulating water heat exchanger 240 It is possible to prevent the freezing of.

In addition, the present invention monitors whether the microcomputer 280 operates the water-cooled refrigerator 230 according to the change in the heating and cooling load, and sets the reference temperature values of the heat source side circulation water of the heat pump 260 differently according to the result. (I.e., reset) and store it in a memory (not shown).

The operation of the heat pump 260 is controlled by comparing the heat source side circulation water detection temperature value detected by the heat source inlet temperature sensor S3 or the heat source outlet temperature sensor S4 with a reference temperature value of the heat source side circulation water. .

That is, when the cooling load is low and the water-cooled refrigerator 230 is temporarily stopped and the heat pump 260 is operated alone without condensation arrangement, the temperature of the heat source side circulating water is continuously lowered, thereby cooling water to heat source side circulating water heat exchanger ( In this case, the microcomputer 280 automatically resets the reference temperature value of the heat source-side circulating water as described above.

For example, when the water-cooled refrigerator 230 is operated and a condensation arrangement exists, when the heat source side outlet temperature of the heat pump 260 falls below 2 ° C., the heat pump 260 is stopped and the heat source side outlet temperature is 5 ° C. or more. If the water-cooled refrigerator 230 stops and there is no condensation arrangement, when the heat source side outlet temperature of the heat pump 260 falls below -13 ° C, the heat pump 260 is stopped and the heat source side outlet If the temperature is above -10 ° C, reset the reference temperature value to restart.

When the temperature value of the heat source side circulating water detected by the heat source inlet temperature sensor S3 or the heat source outlet temperature sensor S4 becomes lower than the reset reference temperature value, the operation of the heat pump 260 is temporarily stopped to provide a coolant volume. It prevents freezing of the heat source side circulating water heat exchanger (240).

Of course, it is obvious that the hot water boiler 271 can be operated independently to cope with the hot water load.

However, in order to operate the heat pump 260 alone without the condensation arrangement as described above, a buffer tank (not shown) is provided on the heat source side of the heat pump 260 and a brine is provided in the buffer tank. It is preferable to fill antifreeze such as).

This is because heat production and heat supply do not occur at the same time (or evenly), resulting in a shortage of condensation arrangements when an unbalanced supply and demand occurs, so storing hot water in a buffer tank allows it to be discharged when needed. This is because thermal buffering can occur, bringing a balance between supply and demand.

In addition, the present invention further includes a first three-way valve (3W1) installed between the heat source side and the coolant to heat source side circulation water heat exchanger 240 of the heat pump 260, the first three-way valve (3W1) The common port AB is connected to the circulating water outlet side pipe of the heat pump 260 heat source side, and the first port A is connected to the inlet side pipe of the coolant to heat source side circulating water heat exchanger 240. The two ports B are connected to a pipe connecting the circulating water inlet side of the heat pump side of the heat pump 260 and the outlet side of the coolant versus heat source side circulating water heat exchanger 240 to each other.

Therefore, as shown in FIG. 4, the heat source side circulating water discharged through the heat source side of the heat pump 260 passes through the cooling water to the heat source side circulating water heat exchanger 240 (first port A), and the second port. (B) to bypass and bypass the bypass path (first port (A) closed, second port (B) open) without passing through the coolant to heat source side circulating water heat exchanger (240). By circulating through or adjusting the opening rate, it is possible to simultaneously circulate through all of these paths (part of the first port A and part of the second port B). That is, the circulation direction of the heat source side circulation water of the heat pump 260 can be changed.

Therefore, in the related art, when the heat pump 260 is operated using the condensation array as a heat source, the temperature of the cooling water is gradually lowered. If the temperature is kept at this state, the temperature of the cooling water is lowered below the threshold, so that the temperature is excessively increased. In the process of cooling the lowered cooling water in the water-cooled refrigerator 230, the refrigerant is liquefied and introduced into the compressor for the refrigerator, thereby causing damage to various equipment including the water-cooled refrigerator 230. By varying the circulation direction of the water to adjust the recovery rate of the condensation arrangement through the heat source side circulation water, it is possible to prevent the cooling water from being excessively deprived of the condensation arrangement.

In this case, however, the cooling water further includes a cooling water inlet temperature sensor S5 installed between the cooling water to the heat source side circulating water heat exchanger 240 and the cooling tower 250 to measure the temperature of the cooling water input to the cooling tower 250. It is preferable that the microcomputer 280 controls the opening direction of the first three-way valve 3W1 as described above according to the temperature value of the cooling water sensed by the intake temperature sensor S5.

For example, as shown in FIG. 5, when the coolant temperature is 32 ° C., the first port A is opened by 0%, and as the temperature is gradually increased, the opening ratio is also increased. When the temperature reaches 37 ° C., the first port A is 100. On the contrary, if the cooling water temperature is 32 ° C, the second port B is opened by 100% to bypass all of them, and as the temperature increases, PID control is performed to open the second port B by 0%.

Of course, when the water-cooled load is reduced and the water-cooled refrigerator 230 is stopped, only the heat pump 260 is operated alone in the absence of condensation arrangement. At this time, the cooling water circulation pump 232 is stopped to reduce the pump power consumption. In this situation, the cooling water to the heat source side circulating water heat exchanger 240 may have a problem of freezing. Therefore, when the water-cooled refrigerator 230 is stopped and only the heat pump 260 is operated alone, The two ports B may be opened 100% and the first port A may be 0% open.

In addition, the present invention further includes a second three-way valve (3W2) installed between the cooling water to the heat source side circulation water heat exchanger 240 and the inlet side of the cooling tower 250, the common of the second three-way valve (3W2) Port AB is connected to the cooling water outlet side pipe of the cooling water to the heat source side circulation water heat exchanger 240, and the first port A is connected to the cooling water inlet side pipe of the cooling tower 250, and the second port B ) Connects to the pipe connecting the cooling water outlet side of the cooling tower 250 and the cooling water inlet side of the water-cooled refrigerator 230 to each other.

Therefore, as shown in FIG. 6, the cooling water discharged from the cooling water to the heat source side circulation water heat exchanger 240 circulates through the cooling tower 250 to the water-cooling refrigerator 230 (the first port A opens, and the second Port B closed), or the cooling water is circulated through the bypass path to the water-cooled freezer 230 (first port A closed, second port B open) without passing through the cooling tower 250, Alternatively, by adjusting the opening degree, it is possible to simultaneously cycle through all of these paths (part of the first port A and part of the second port B). That is, the circulation direction of the cooling water discharged from the water-cooled refrigerator 230 can be changed.

Therefore, in the related art, when the temperature of the cooling water is excessively lowered, additional temperature drop of the cooling water is prevented by adjusting the capacity of the cooling tower (not shown), so that the cooling water is unnecessarily raised to the cooling tower installed on a high place such as a rooftop. Compared to the waste of power consumption in the process of operating the cooling water circulation pump 232, the present invention provides an underground machine room through a bypass path without having to raise the cooling water to the cooling tower 250 when additional cooling of the cooling water is unnecessary. Do not waste the power of consumption by allowing circulation (ie low head) only on the back.

In this case, however, the cooling water outlet temperature sensor S6 is installed between the cooling tower 250 and the water cooling refrigerator 230 to measure the temperature of the cooling water discharged from the cooling tower 250. It is preferable that the microcomputer 280 PID control the opening direction of the second three-way valve 3W2 according to the detected temperature of the coolant.

For example, as shown in FIG. 7, when the coolant temperature is 27 ° C., the first port A is opened by 0%, and as the temperature is gradually increased, the opening ratio is also increased. When the temperature reaches 32 ° C., the first port A is 100. On the contrary, if the cooling water temperature is 27 ° C, the second port B is opened 100% to bypass all of them, and as the temperature increases, PID control is performed to open the second port B by 0%.

Furthermore, the present invention includes a cooling water circulation pump 232 for forcibly circulating the cooling water along the cooling water circulation pipe, the microcomputer 280 forcibly operates the cooling water circulation pump 232 when the temperature of the cooling water falls below the set value. This prevents freezing of the cooling water circulation pipe piped outdoors in winter.

In the above, the specific Example of this invention was described above. However, the spirit and scope of the present invention is not limited to these specific embodiments, and various modifications and variations can be made without departing from the spirit of the present invention. Those who have it 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.

210: air conditioner 220: heating boiler
230: water-cooled freezer
240: cooling water to heat source side circulating water heat exchanger
250: cooling tower 260: heat pump
270: hot water tank
S1: load inlet temperature sensor
S2: load outlet temperature sensor
S3: heat source inlet temperature sensor
S4: heat source outlet temperature sensor
S5: heat source outlet temperature sensor
S5: coolant inlet temperature sensor
S6: coolant output temperature sensor
3W1: first three-way valve 3W2: second three-way valve
221: hot water circulation pump 231: cold water circulation pump
232: cooling water circulation pump 261: load side circulation pump
262: heat source side circulation pump 280: microcomputer

Claims (10)

An air conditioner 210 that cools or heats air by using the cooling coil 214 and the heating coil 215 and supplies the air to an indoor air conditioner space;
A cooling tower 250 installed outdoors;
A heat pump 260 (heat pump) for heating or cooling the supplied water according to the circulation direction of the refrigerant;
A heating boiler 220 for supplying hot water used for heating;
The cold water cooled while passing through the freezer evaporator provided therein is provided to the cooling coil 214 of the air conditioner 210, and the cold water circulating water recovered after passing through the cooling coil 214 is cooled through the freezing cycle. A water-cooled freezer (240) passing heat to the cooling water and passing the condenser for a freezer to the cooling tower (260);
By heat-exchanging the cooling water absorbing the condensation array sent to the cooling tower 250 and the load side circulation water circulating in the heat pump 260, the condensation array is used as a heat source of the heat pump 260. A cooling water to heat source side circulating water heat exchanger 240;
A hot water tank 270 that the heat pump 260 receives and stores the load-side circulating water heated by using the condensation array as a heat source, and provides the heated load-side circulating water as hot water; And
A waste heat source heat pump hot water supply system 200 comprising a; microcomputer (280) for controlling the air conditioning operation and hot water operation. The method of claim 1,
The heat pump 260 is divided into a load side connected to the hot water tank 270 and a heat source side connected to the coolant versus heat source side circulating water heat exchanger 240,
The load inlet temperature sensor S2 is installed on the circulating water inlet side of the load side, or the load outlet temperature sensor S1 is installed on the circulating water outlet side of the load side,
The microcomputer 280 is a waste heat source heat pump, characterized in that configured to control the operation of the heat pump according to the load-side circulating water detection temperature at the load inlet temperature sensor (S2) or load outlet temperature sensor (S1). Hot water system 200. The method of claim 1,
The heat pump 260 is divided into a load side connected to the hot water tank 270 and a heat source side connected to the coolant versus heat source side circulating water heat exchanger 240,
The heat source inlet temperature sensor S3 is installed on the circulating water inlet side of the heat source side or the heat source outlet temperature sensor S4 is installed on the circulating water outlet side of the heat source side,
The microcomputer 280 is configured to control the operation of the heat pump 260 according to the heat source side circulating water detection temperature at the heat source inlet temperature sensor S3 or the heat source outlet temperature sensor S4. Waste heat source heat pump hot water supply system (200). The method of claim 3,
The microcomputer 280 sets different reference temperature values of the circulating water of the heat source side of the heat pump 260 according to whether the water-cooled refrigerator 230 is operated according to a change in a heating and cooling load.
The operation of the heat pump 260 is controlled by comparing the heat source side circulation water detection temperature value detected by the heat source inlet temperature sensor S3 or the heat source outlet temperature sensor S4 with a reference temperature value of the heat source side circulation water. Waste heat source heat pump hot water supply system, characterized in that (200). The method of claim 1,
The heat pump 260 is divided into a load side connected to the hot water tank 270 and a heat source side connected to the coolant versus heat source side circulating water heat exchanger 240,
The first three-way valve (3W1) is installed between the heat source side of the heat pump 260 and the cooling water to heat source side circulating water heat exchanger 240,
The common port AB of the first three-way valve 3W1 is connected to the circulating water output side pipe on the heat source side of the heat pump 260, and the first port A of the first three-way valve 3W1. Is connected to the inlet side pipe of the cooling water to the heat source side circulating water heat exchanger 240, the second port (B) of the first three-way valve (3W1) is the inlet of the circulating water on the heat source side of the heat pump 260 Connected to the pipe connecting the water outlet side and the cooling water to the heat source side circulating water heat exchanger 240,
Waste heat source heat pump hot water supply system 200, characterized in that for changing the circulation direction of the heat source-side circulation water of the heat pump (260). The method of claim 5,
Further comprising a cooling water inlet temperature sensor (S5) is installed between the cooling water versus heat source side circulation water heat exchanger 240 and the cooling tower 250 to measure the temperature of the cooling water input to the cooling tower 250,
The microcomputer 280 controls the opening direction of the first three-way valve 3W1 according to the temperature value of the cooling water detected by the cooling water inlet temperature sensor S5. Waste heat source heat pump hot water supply system (200). The method of claim 1,
The second three-way valve (3W2) is installed between the cooling water to the heat source side circulating water heat exchanger 240 and the inlet side of the cooling tower 250,
The common port AB of the second three-way valve 3W2 is connected to the cooling water outlet side pipe of the cooling water-to-heat source side circulation water heat exchanger 240, and is a first port of the second three-way valve 3W2. (A) is connected to the cooling water inlet side pipe of the cooling tower 250, the second port (B) of the second three-way valve (3W2) is the cooling water outlet side of the cooling tower 250 and the water cooling refrigerator 230 Is connected to a pipe connecting the cooling water inlet side of the
Waste heat source heat pump hot water supply system 200, characterized in that for varying the circulation direction of the cooling water discharged from the water-cooled refrigerator (230). The method of claim 7, wherein
Further comprising a cooling water discharge temperature sensor (S6) is installed between the cooling tower 250 and the water-cooled freezer 230 to measure the temperature of the cooling water discharged from the cooling tower 250,
The microcomputer 280 is a waste heat source heat pump hot water supply system, characterized in that for controlling the opening direction of the second three-way valve (3W2) according to the temperature value of the cooling water detected by the cooling water discharge temperature sensor (S6). (200). 9. The method according to any one of claims 1 to 8,
A cooling water circulation pump 232 for forcibly circulating the cooling water along the cooling water circulation pipe and the cooling water circulation pipe through which the cooling water flows,
The microcomputer 280 is a waste heat source heat pump hot water supply system 200, characterized in that for preventing the freezing of the cooling water circulation pipe by forcibly operating the cooling water circulation pump 232 when the temperature of the cooling water falls below a set value. ). 9. The method according to any one of claims 1 to 8,
A hot water boiler 271 is connected to the hot water tank 270 to provide hot water to the hot water tank 270 in an auxiliary manner, and the hot water boiler 271 is controlled by the microcomputer 280. Waste heat source heat pump hot water supply system, characterized in that the 200.

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