KR102516716B1 - Heat exchanging system - Google Patents

Abstract

A heat exchange system according to an embodiment disclosed in this document heats preheated water supplied along a second pipe using a first heat source hot water among hot water supplied along a first pipe to obtain set hot water having a set temperature. A first heat exchanger for discharging, a first valve for controlling the flow rate of hot water from the first heat source supplied to the first heat exchanger along the first pipe, and supplied as a heating load along a third pipe branching from the first pipe. Preheating by heating the direct water supplied along the second pipe using a second valve for controlling the flow rate of hot water from the second heat source, and mixed hot water containing at least one of the hot water from the first heat source and the hot water from the second heat source. A second heat exchanger generating the preheated water having a temperature and supplying the preheated water to the first heat exchanger, and a second heat exchanger sensing a flow rate of the mixed hot water discharged along the first pipe through the second heat exchanger. 1 may include a flow sensor and a control unit for controlling an operation of at least one of the first valve and the second valve based on the flow rate of the mixed hot water sensed by the first flow sensor.

Description

Heat exchange system {HEAT EXCHANGING SYSTEM}

Embodiments disclosed herein relate to a heat exchange system.

The two-pipe hot water and heating supply system is a system that supplies hot water and heating water to households using a heat source of a predetermined temperature supplied from central heating or district heating. In a general system, heating water is indirectly provided to users through pipes, whereas hot water is provided in direct contact with users, so the supplied heat source is used first for temperature control of hot water and the remaining heat source is used for heating. It is used for control of numbers.

However, in the past, it was difficult to accurately know the flow rate of the supplied heat source, so a part of the heat source had to be supplied to the hot water side heat exchanger that exchanges heat with the heat source first, and the flow rate supplied to the heating load side could be predicted based on the flow rate supplied to the hot water side heat exchanger. I had no choice but to As a result, there is a problem in that the heat source is unnecessarily supplied to the hot water side heat exchanger depending on the situation.

One object of the embodiments disclosed in this document is to provide a heat exchange system capable of efficiently controlling hot water and heating.

Technical problems of the embodiments disclosed in this document are not limited to the above-mentioned technical problems, and other technical problems not mentioned above will be clearly understood by those skilled in the art from the description below.

A heat exchange system according to an embodiment disclosed in this document heats preheated water supplied along a second pipe using a first heat source hot water among hot water supplied along a first pipe to obtain set hot water having a set temperature. A first heat exchanger for discharging, a first valve for controlling the flow rate of hot water from the first heat source supplied to the first heat exchanger along the first pipe, and supplied as a heating load along a third pipe branching from the first pipe. Preheating by heating the direct water supplied along the second pipe using a second valve for controlling the flow rate of hot water from the second heat source, and mixed hot water containing at least one of the hot water from the first heat source and the hot water from the second heat source. A second heat exchanger generating the preheated water having a temperature and supplying the preheated water to the first heat exchanger, and a second heat exchanger sensing a flow rate of the mixed hot water discharged along the first pipe through the second heat exchanger. 1 may include a flow sensor and a control unit for controlling an operation of at least one of the first valve and the second valve based on the flow rate of the mixed hot water sensed by the first flow sensor.

In one embodiment, the control unit may include a first required amount of heat required for the first heat exchanger to heat the preheated water to generate the set hot water and a required amount for the second heat exchanger to heat the direct water to generate the preheated water. A second required calorie can be calculated.

In one embodiment, the control unit sets the first heat exchanger based on the first necessary heat amount, the temperature of the first heat source hot water, the temperature of the preheated water, and the difference between the set temperature of the hot water and the temperature of the preheated water. Calculate the flow rate of the first heat source hot water required to generate hot water, and based on the second required heat amount, the temperature of the mixed hot water, the temperature of the direct water, and the temperature difference between the temperature of the preheated water and the direct water, the second A flow rate of the mixed hot water required for the heat exchanger to generate the preheated water may be calculated.

In one embodiment, the control unit may control the operation of at least one of the first valve and the second valve based on the calculated flow rate of the mixed hot water and the flow rate of the mixed hot water sensed by the first flow sensor. .

In one embodiment, the control unit calculates the amount of heat provided by the second heat exchanger using the flow rate of the mixed hot water detected by the first flow sensor, and the second heat exchanger calculates the amount of heat based on the calculated amount of heat and the second necessary heat amount. 1 valve operation can be controlled.

In one embodiment, the control unit controls to further open the first valve when the calculated amount of heat is less than or equal to the second required amount of heat, and closes the first valve when the calculated amount of heat exceeds the second required amount of heat. You can control it to be more closed.

In one embodiment, in a state in which the control unit controls the first valve to a minimum open state, the second heat exchanger heats the direct water supplied along the second pipe using the mixed hot water to correspond to the set temperature. When it is possible to generate preheated water having a temperature of the above, the first valve may be closed.

In one embodiment, the control unit may allow the second heat exchanger to select the preheated water based on the second required heat amount, the temperature of the second heat source hot water, the temperature of the direct water, and the temperature difference between the temperature of the preheated water and the direct water. A flow rate of hot water from the second heat source required to be generated may be calculated.

In one embodiment, the controller may control the operation of the second valve based on the calculated flow rate of hot water from the second heat source and the flow rate of hot water from the second heat source sensed by the first flow sensor.

In one embodiment, the control unit controls to further open the second valve when the flow rate of the second heat source hot water detected by the first flow sensor is less than or equal to the calculated flow rate of the second heat source hot water, and the first flow rate sensor When the flow rate of hot water from the second heat source detected by the controller exceeds the calculated flow rate of hot water from the second heat source, the second valve may be further closed.

In one embodiment, it may further include a second flow sensor for detecting the flow rate of direct water supplied along the second pipe.

In one embodiment, the set temperature and the preheating temperature of the preheating water may be preset.

A heat exchange system according to an embodiment disclosed in this document may efficiently control hot water and heating.

1 and 2 are diagrams showing a heat exchange system according to an embodiment disclosed in this document.
3 is a diagram showing a heat exchange system according to another embodiment disclosed in this document.

Hereinafter, embodiments disclosed in this document will be described in detail through exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings. In addition, in describing the embodiments disclosed in this document, if it is determined that a detailed description of a related known configuration or function interferes with understanding of the embodiment disclosed in this document, the detailed description thereof will be omitted.

Terms such as first, second, A, B, (a), and (b) may be used to describe components of the embodiments disclosed in this document. These terms are only used to distinguish the component from other components, and the nature, order, or order of the corresponding component is not limited by the term. In addition, unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the art to which the embodiments disclosed in this document belong. . Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in the present application, it should not be interpreted in an ideal or excessively formal meaning. don't

1 and 2 are diagrams showing a heat exchange system according to an embodiment disclosed in this document.

First, referring to FIG. 1 , the heat exchange system 100 according to an embodiment disclosed in this document includes a first heat exchanger 110, a first valve 120, a second valve 130, and a second heat exchanger. 140, a first flow sensor 150, a controller 160, and a second flow sensor 170 may be included.

The first heat exchanger 110 may receive hot water from the first heat source through the first pipe 11 . For example, the first heat source hot water may be at least a portion of hot water supplied from the central heating or district heating. The first heat exchanger 110 may receive preheated water through the second pipe 12 . For example, the preheating water may be hot water supplied from the outside and heated to a predetermined preheating temperature through the second heat exchanger 140 .

The first heat exchanger 110 may generate set hot water by heating the preheated water using the first heat source hot water. For example, the first heat exchanger 110 may generate set hot water by heating preheated water to have a set temperature using the first heat source hot water as a heat source. Specifically, the first heat exchanger 110 may generate set hot water by heating the preheated water according to the amount of heat based on the flow rate of the first heat source hot water. Here, the set temperature may mean the temperature of hot water provided to the user, and may be preset by the user or a controller (not shown). The set hot water discharged through the first heat exchanger 110 may be provided to the user.

That is, the heat exchange system 100 uses the first heat exchanger 110 and the second heat exchanger 140 based on the supplied heat source hot water to heat the direct water supplied to the second heat exchanger 140 twice. By heating through the set hot water having a set temperature can be provided to the user. The amount of heat required to supply set hot water by heating direct water may be provided from the amount of heat of each of the first heat exchanger 110 and the second heat exchanger 140 . In addition, the heat exchange system 100 may provide heating water by supplying at least a portion of the supplied heat source hot water to a heating load.

The first valve 120 may be connected to the first heat exchanger 110 . The first valve 120 may be provided on the first pipe 11 . The first valve 120 may control the flow rate of the first heat source hot water supplied to the first heat exchanger 110 along the first pipe 11 . The first valve 120 may be opened or closed in response to a control command transmitted from the controller 160 . Also, the degree of opening and closing of the first valve 120 may be controlled in response to a control command transmitted from the control unit 160 . That is, the first valve 120 may control the flow rate of hot water from the first heat source according to a control command transmitted from the control unit 160 .

The second valve 130 may be connected to a heating load. For example, the second valve 130 may be provided on a third pipe 13 branching from the first pipe 11 toward the heating load. The second valve 130 may control the flow rate of hot water from the second heat source supplied to the heating load along the third pipe 13 . The third pipe 13 may be connected to the first pipe 11 extending to the rear end of the first valve 11 . Accordingly, hot water from the second heat source flowing along the third pipe 13 may be combined with warm water from the first heat source in the first pipe 11 to form mixed hot water. Meanwhile, when the first or second heat source hot water is blocked as the first valve 110 or the second valve 130 is closed, the mixed hot water is only hot water from one of the first heat source hot water and the second heat source hot water. may also include

The second valve 130 may be opened or closed in response to a control command transmitted from the controller 160 . Also, the degree of opening and closing of the second valve 130 may be controlled in response to a control command transmitted from the controller 160 . That is, the second valve 130 may control the flow rate of hot water from the second heat source according to a control command transmitted from the controller 160 .

The second heat exchanger 140 may be provided on the first pipe 11 . That is, the first heat exchanger 110 , the first valve 120 , and the second heat exchanger 140 may be disposed along the first pipe 11 . The second heat exchanger 140 may generate preheated water by heating direct water supplied along the second pipe 12 using mixed hot water including at least one of the first heat source hot water and the second heat source hot water. . For example, the second heat exchanger 140 may generate preheated water by heating supplied direct water to have a preset preheating temperature. Specifically, the second heat exchanger 140 may generate preheated water by heating the direct water according to the amount of heat obtained based on the flow rate of the mixed hot water.

The second heat exchanger 140 may supply preheated water to the first heat exchanger 110 . In addition, the second heat exchanger 140 may discharge mixed hot water including at least one of the first heat source hot water and the second heat source hot water to the outside. For example, mixed hot water discharged from the second heat exchanger 140 may be returned to central district heating.

The first flow sensor 150 may be connected to the second heat exchanger 140 . The first flow sensor 150 may be provided on the first pipe 11 and may detect the flow rate of mixed hot water discharged from the second heat exchanger 140 . The first flow sensor 150 may transfer the sensed flow rate of mixed hot water to the control unit 160 .

The controller 160 may control the operation of the first valve 120 and the second valve 130 . For example, the controller 160 may control the operation of at least one of the first valve 120 and the second valve 130 based on the flow rate of mixed hot water detected by the first flow sensor 150. .

The second flow sensor 170 may detect the flow rate of direct water supplied to the second heat exchanger 140 . The second flow sensor 170 may be provided in the second pipe 12 . The second flow sensor 170 may transmit the detected flow rate of direct water to the control unit 160 .

Hereinafter, specific operations of the controller 160 will be described.

First, referring to the first operation of the control unit 160, the control unit 160 operates the first valve 120 and the second valve 130 based on the flow rate of the mixed hot water detected by the first flow sensor 150. can control the operation of

To this end, the controller 160 may first calculate the first necessary heat amount Q1 required for the first heat exchanger 110 to heat the preheated water to generate the set hot water. For example, the controller 160 may calculate the first required heat amount Q1 based on Equation 1 below.

[Equation 1]

1st heat required (Q1) = (T3set-T2)*m*60

Here, T3set may be defined as the set temperature, T2 is the temperature of the preheated water, and m may be defined as the flow rate of the direct water. As described above, the set temperature may be preset, and the temperature of the preheated water is It can be obtained by a temperature sensor (not shown) provided.

The controller 160 may calculate the flow rate of hot water from the first heat source required for the first heat exchanger 110 to obtain the first necessary heat quantity Q1 using the first necessary heat quantity Q1. For example, the controller 160 may set a characteristic table of the heat exchanger that is already generated based on the first required heat Q1, the temperature of the first heat source hot water, the temperature of the preheated water, and the difference between the set temperature of the hot water and the preheated water. A flow rate of hot water from the first heat source required for the first heat exchanger 110 to obtain the first necessary heat amount Q1 may be calculated using a lookup table.

In addition, the controller 160 may calculate the second necessary heat quantity Q2 required for the second heat exchanger 140 to heat the direct water to generate the preheated water. For example, the controller 160 may calculate the second required heat quantity Q2 based on Equation 2 below.

[Equation 2]

Second heat required (Q2) = (T2set-T1)*m*60

Here, T2set may be defined as the preheating temperature, T1 is the temperature of the direct water, and m is the flow rate of the direct water. As described above, the preheating temperature may be preset, and the temperature of the direct water is provided in the second pipe 12 It can be obtained by a temperature sensor (not shown).

The controller 160 may calculate the flow rate of the mixed hot water necessary for the second heat exchanger 140 to obtain the second necessary heat quantity Q2 by using the second necessary heat quantity Q2. For example, the control unit 160 calculates a lookup table of the heat exchanger generated based on the second required heat Q2, the temperature of the mixed hot water, the temperature of the direct water, and the difference between the temperature of the preheated water and the direct water. It is possible to calculate the flow rate of the mixed hot water required for the second heat exchanger 110 to obtain the second necessary heat quantity Q2 using .

The control unit 160 controls the flow rate of the mixed hot water required for the second heat exchanger 140 to obtain the second necessary heat amount Q2 calculated based on the flow rate of the mixed hot water detected by the first flow sensor 150. The operation of at least one of the first valve 120 and the second valve 130 may be controlled. For example, the control unit 160 controls the flow rate of the mixed hot water required for the second heat exchanger 140 obtained by calculating the flow rate of the mixed hot water sensed through the first flow sensor 150 to obtain the second necessary heat quantity Q2. If it is smaller than this, the opening rate of the first valve 120 can be controlled to increase. This is because the flow rate of the first heat source hot water required for the first heat exchanger 110 to generate the set hot water provided to the user is controlled through the control of the first valve 120, thus controlling the hot water that comes into direct contact with the user. This is to set the priority of higher than the temperature control on the heating load side. Meanwhile, the control unit 160 controls that the flow rate of the mixed hot water detected by the first flow sensor 150 is smaller than the flow rate of the mixed hot water required for the calculated second heat exchanger 140 to obtain the second necessary heat quantity Q2. Otherwise, the opening rate of at least one of the first valve 120 and the second valve 130 may be controlled to increase.

Accordingly, accurate and fast control of the first valve 120 and the second valve 130 may be possible. That is, the temperature of the hot water generated through the heat exchanger is based on the flow rate of the heat source hot water supplied to the heat exchanger. Conventionally, since the flow rate of the heat source supplied to the heat exchanger cannot be known, the valve controls the supply of the heat source by assuming the maximum flow rate. It was inevitable to control the flow rate through repetitive feedback control according to the opening rate. On the other hand, in the case of the present invention, since the flow rate of the mixed hot water detected through the first flow sensor 150 is used, accurate and fast control of the first valve 120 and the second valve 130 may be possible.

Hereinafter, the second operation of the controller 160 will be described.

As described in the first operation of the control unit 160, the control unit 160 controls the first heat exchanger 110 to heat the preheated water to generate the set hot water (Q1) and the second heat exchanger ( 140) may calculate the second necessary heat amount Q2 required to generate preheated water by heating the direct water.

The control unit 160 may calculate the amount of heat Q2' provided by the second heat exchanger 140 based on the flow rate of the mixed hot water sensed through the first flow sensor 150 . The controller 160 controls the first valve 120 and the second valve 130 based on the result of comparing the calculated amount of heat provided by the second heat exchanger 140 (Q2′) and the amount of second necessary heat (Q2). ) It is possible to control at least one of the operations.

For example, the controller 160 may control the first valve 120 to be further opened when the amount of heat provided (Q2′) is equal to or less than the second amount of heat required (Q2). Since the flow rate of the first heat source hot water required for the first heat exchanger 110 to generate the set hot water provided to the user is controlled through the control of the first valve 120, control of the hot water directly contacting the user This is to set the priority higher than the heating load side.

Meanwhile, the control unit 160 may control the first valve 120 to be further closed when the amount of heat provided Q2′ exceeds the second amount of required heat Q2. In this case, it can be understood as a situation in which set hot water can be provided to the user only with the second heat exchanger 140 . In addition, even though the first valve 120 is controlled to be less than the minimum open state through this control, if the amount of heat provided (Q2′) still exceeds the amount of second necessary heat (Q2), the control unit 160 opens the second valve 130. You can control it to be more closed. That is, in the prior art, since the flow rate of the heat source supplied to the hot water side and the heat source supplied to the heating side could not be known, the flow rate was assumed to be a specific value, and the flow rate was controlled by repeatedly feedback-controlling the opening rate of the valve accordingly. , In the case of the present invention, since the flow rate of the mixed hot water detected through the first flow sensor 150 is used, accurate and fast control of the first valve 120 and the second valve 130 may be possible.

Hereinafter, a third operation of the controller 160 will be described with reference to FIG. 2 .

For example, in a state in which the control unit 160 controls the first valve 120 to the minimum open state according to the second operation, the second heat exchanger 140 opens the second pipe 12 using mixed hot water. When it is possible to generate preheated water having a temperature corresponding to the set temperature by heating the direct water supplied according to the method, the controller 160 may close the first valve 120 . This case may be understood as, for example, a case where the set temperature is low and the set hot water can be sufficiently provided only by the second heat exchanger 140 . In addition, in one aspect, it may be understood as a case in which a sufficient amount of heat can be provided to both the hot water side and the heating load side by using the supplied heat source hot water.

That is, the control unit 160 may control the operation of the first valve 120 to block the supply of hot water from the first heat source to the first heat exchanger 110 . When the first valve 120 is closed, the flow rate of the first heat source hot water becomes 0, and the control unit 160 controls the operation of the second valve 130 to provide enough heat source hot water for the heating load (ie, the second heat source hot water). ) can be supplied. Also, in this case, the mixed hot water will include only the second heat source hot water provided to the heating load.

In the prior art, it was difficult to accurately know the flow rate of the supplied heat source hot water, so a part of the heat source had to be supplied to the hot water side heat exchanger. Since the flow rate of the side heat exchanger cannot be controlled and the flow rate of the heat source hot water supplied to the heating load side can only be controlled, a sufficient flow rate can be provided to both the hot water side and the heating load side using the supplied heat source hot water. There was no choice but to reduce the flow rate of the heat source hot water supplied to the heating load side.

On the other hand, referring to FIG. 2 , in this case, the control unit 160 closes the first valve 120 and controls the flow rate of the second heat source hot water supplied to the second heat exchanger 140 to provide set hot water to the user. In addition, it can provide enough heat even for the heating load. Therefore, efficient heating and hot water control may be possible.

Specifically, the control unit 160 controls the second necessary heat amount Q2 required for the second heat exchanger 140 to heat the direct water to generate the preheated water, the temperature of the second heat source hot water, the temperature of the direct water, and the preheated water. The flow rate of hot water from the second heat source required for the second heat exchanger 140 to generate the preheated water may be calculated based on the temperature difference between the temperature and the direct water.

The controller 160 may control the operation of the second valve 130 based on the calculated flow rate of hot water from the second heat source and the flow rate of hot water from the second heat source detected by the first flow sensor 150 . For example, the control unit 160 controls the second valve 130 to be further opened when the flow rate of the second heat source hot water detected by the first flow sensor 150 is equal to or less than the calculated flow rate of the second heat source hot water, When the flow rate of hot water from the second heat source detected by the first flow sensor 150 exceeds the calculated flow rate of the hot water from the second heat source, the second valve 130 may be further closed.

3 is a diagram showing a heat exchange system according to another embodiment disclosed in this document.

Referring to FIG. 3 , a heat exchange system 200 according to another embodiment disclosed in this document includes a first heat exchanger 210, a first valve 220, a second valve 230, and a second heat exchanger 240 ), a first flow sensor 250, a control unit 260, and a second flow sensor 270 may be included.

The heat exchange system 200 according to another embodiment disclosed in this document may have a difference in the arrangement of the first flow rate sensor 250 compared to the heat exchange system 100 disclosed in FIG. 1 .

For example, unlike the first flow sensor 150 , the first flow sensor 250 may be disposed between the first valve 250 and the second heat exchanger 240 . An operation of the first flow sensor 250 may be substantially the same as that of the first flow sensor 150 . For example, the first flow sensor 250 may detect the flow rate of mixed hot water and transmit the detection result to the control unit 260 .

The above description is only an illustrative example of the technical idea disclosed in this document, and those skilled in the art to which the embodiments disclosed in this document belong will be within the scope of the essential characteristics of the embodiments disclosed in this document. Many modifications and variations will be possible.

Therefore, the embodiments disclosed in this document are not intended to limit the technical idea disclosed in this document, but to explain, and the scope of the technical idea disclosed in this document is not limited by these embodiments. The scope of protection of technical ideas disclosed in this document should be interpreted according to the scope of the following claims, and all technical ideas within the equivalent scope should be construed as being included in the scope of rights of this document.

100, 200: heat exchange system
110, 210: first heat exchanger
120, 220: first valve
130, 230: second valve
140, 240: second heat exchanger
150, 250: first flow sensor
160, 260: control unit
170, 270: second flow sensor
11: first pipe
12: second pipe
13: third pipe

Claims (12)

a first heat exchanger that heats the preheated water supplied along the second pipe using the first heat source hot water of the supplied hot water supplied along the first pipe and discharges the set hot water having a set temperature;
a first valve controlling a flow rate of hot water from the first heat source supplied to the first heat exchanger along the first pipe;
a second valve controlling a flow rate of hot water from a second heat source supplied to a heating load along a third pipe branching from the first pipe;
Direct water supplied along the second pipe is heated using mixed hot water containing at least one of the first heat source hot water and the second heat source hot water to generate the preheated water having a preheating temperature, and a second heat exchanger supplying the first heat exchanger;
a first flow sensor for sensing a flow rate of the mixed hot water discharged along the first pipe after passing through the second heat exchanger; and
and a control unit controlling an operation of at least one of the first valve and the second valve based on the flow rate of the mixed hot water sensed by the first flow sensor. According to claim 1,
The control unit determines a first necessary heat amount required for the first heat exchanger to heat the preheated water to generate the set hot water and a second required heat amount required for the second heat exchanger to heat the direct water to generate the preheated water. A heat exchange system, characterized in that for calculating. According to claim 2,
The control unit may be configured to generate the set hot water by the first heat exchanger based on the first necessary heat amount, the temperature of the first heat source hot water, the temperature of the preheated water, and the temperature difference between the set hot water temperature and the preheated water. Calculate the flow rate of the first heat source hot water,
The flow rate of the mixed hot water required for the second heat exchanger to generate the preheated water is determined based on the second required heat amount, the temperature of the mixed hot water, the temperature of the direct water, and the temperature difference between the temperature of the preheated water and the direct water. A heat exchange system, characterized in that for calculating. According to claim 3,
The control unit controls an operation of at least one of the first valve and the second valve based on the calculated flow rate of the mixed hot water and the flow rate of the mixed hot water sensed by the first flow sensor. . According to claim 2,
The control unit calculates the amount of heat provided by the second heat exchanger using the flow rate of the mixed hot water detected by the first flow rate sensor, and controls the operation of the first valve based on the calculated amount of heat and the second required amount of heat. Heat exchange system, characterized in that for controlling. According to claim 5,
The control unit further controls the first valve to open when the calculated amount of heat is less than or equal to the second required amount of heat, and controls the first valve to be further closed when the calculated amount of heat exceeds the second required amount of heat A heat exchange system, characterized in that. According to claim 2,
In a state where the control unit controls the first valve to the minimum open state, the second heat exchanger uses the mixed hot water to heat the direct water supplied along the second pipe to preheat water at a temperature corresponding to the set temperature. When it is possible to generate a heat exchange system, characterized in that for closing the first valve. According to claim 7,
The control unit controls the second heat exchanger to generate the preheated water based on the second necessary heat amount, the temperature of the second heat source hot water, the temperature of the direct water, and the temperature difference between the temperature of the preheated water and the direct water. A heat exchange system characterized in that for calculating the flow rate of the second heat source hot water. According to claim 8,
The control unit controls the operation of the second valve based on the calculated flow rate of hot water from the second heat source and the flow rate of hot water from the second heat source sensed by the first flow sensor. According to claim 9,
The control unit controls the second valve to be further opened when the flow rate of hot water from the second heat source sensed by the first flow sensor is less than or equal to the calculated flow rate of hot water from the second heat source, and the second flow rate sensor detects the second flow rate. and controlling the second valve to be further closed when the flow rate of hot water from the heat source exceeds the calculated flow rate of hot water from the second heat source. According to claim 1,
The heat exchange system further comprising a second flow rate sensor for sensing the flow rate of the direct water supplied along the second pipe. According to claim 1,
The set temperature and the preheating temperature of the preheating water are preset, characterized in that the heat exchange system.

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