KR102446455B1 - Hot water control appratus of cascade water heater and method thereof - Google Patents

Abstract

Disclosed is an apparatus and method for controlling hot water in a cascade water heater. The present invention, the first step of setting the set temperature of the heat source device after confirming the set temperature input by the integrated control unit; and a second step of calculating a bypass ratio and a bypass flow rate for bypassing at least one heat source by the integrated control device unit by the set temperature; It may be composed of

Description

Hot water control appratus of cascade water heater and method thereof

In the present invention, the lowest temperature at which the temperature of hot water supplied from the heat source can be controlled is limited in the temperature that can be lowered due to the safety and performance of the heat exchanger. It relates to a hot water control apparatus and method of a cascade water heater for supplying hot water temperature.

Existing water heaters controlled by a cascade system have limitations in lowering the minimum hot water temperature due to the limitation of the minimum amount of heat due to the characteristics of the drain or minimum heat amount control and burner inside the heat exchanger provided in the water heater. In addition, when the temperature is lower than the minimum temperature set in the heat source in the control of the hot water temperature, it is impossible to control the temperature below the set minimum temperature because an abnormality may occur in the heat source. That is, in order to supply the lowest hot water temperature, the water heater is designed by lowering the controllable amount of heat, but there is a problem in that the price increases due to the limitations of the burner's ability and combustion parts. Therefore, all heat source devices are limited to the minimum hot water temperature that can be supplied. In addition, in the past, a technique for lowering the temperature of hot water by mixing cold water with heated hot water is applied, but there is no problem in using low-temperature hot water, but overheating of the heat exchanger may occur if high temperature is used. For this purpose, control bypass control is used, but there is a problem that the price increases.

Patent Document 1. Domestic Registered Patent Publication No. 10-1233893 (published on February 15, 2013) Patent Document 2. Domestic Registered Patent Publication No. 10-1137556 (published on April 20, 2012) Patent Document 3. Domestic Registered Patent Publication No. 10-1532620 (published on June 30, 2015)

One of the technical problems to be solved in the present invention is that the lowest temperature at which the temperature of hot water supplied from the heat source can be controlled is limited in the temperature that can be lowered due to the influence of safety and performance of the heat exchanger, so it is installed as a cascade system. An object of the present invention is to provide a hot water control apparatus and method of a cascade water heater for supplying hot water temperature to a lower set temperature than that of the heat source unit.

In addition, in the present invention, when a set temperature lower than the controllable minimum set temperature of the heat source is input to the integrated control unit of the cascade system heat source, the heat source used in the cascade system performs combustion operation at the lowest controllable temperature, and is waiting for combustion An object of the present invention is to provide an apparatus and method for controlling hot water of a cascade water heater for controlling the temperature of hot water input to an integrated control unit by bypassing cold water from a heat source of

The above objects are, according to the present invention, a first step of setting the set temperature of the heat source device after confirming the set temperature input by the integrated control unit; and a second step of calculating the bypass ratio and the bypass flow rate for bypassing the at least one heat source by the integrated control device unit by the set temperature.

In addition, according to an embodiment of the present invention, after the second step, the third step of increasing, decreasing, and maintaining the required bypass heat source number by calculating the bypass flow rate through the integrated control device unit; can be

In addition, according to an embodiment of the present invention, the bypass ratio of the second step may be configured to be calculated by "(heat source hot water temperature - integrated control set temperature) ÷ (integrated control set temperature - water supply temperature)" .

The above objects, according to the present invention, a heat source group formed in a plurality of numbers; and setting the set temperature of the heat source after confirming the input set temperature, calculating the bypass ratio and bypass flow rate for bypassing at least one heat source by the set temperature, and calculating the bypass flow rate to calculate the required bypass It can be achieved from the hot water control device of the cascade water heater, including; an integrated control device unit for increasing, decreasing, and maintaining the pass heat source radix.

In addition, according to an embodiment of the present invention, the integrated control device unit may be configured to calculate the bypass flow rate to increase and decrease, decrease, and maintain the required number of bypass heat sources.

In addition, according to an embodiment of the present invention, the bypass ratio may be configured to be calculated by "(heat source hot water temperature - integrated control set temperature) ÷ (integrated control set temperature - water supply temperature)".

In addition, according to an embodiment of the present invention, the bypass ratio of the second step may be configured to be calculated by "(heat source hot water temperature - integrated control set temperature) ÷ (integrated control set temperature - water supply temperature)" .

In the hot water control apparatus and method of a cascade water heater according to an embodiment of the present invention, the minimum temperature at which the temperature of the hot water supplied from the heat source can be controlled is limited in the temperature that can be lowered under the influence of safety and performance of the heat exchanger. , it provides the effect of supplying the hot water temperature at a lower set temperature than the heat source for the heat source installed as a cascade system.

In addition, the hot water control apparatus and method of a cascade water heater according to an embodiment of the present invention provides the effect of not only reducing the cost because a bypass servo motor is not required, but also providing the effect that low hot water and high hot water can be supplied. do.

In addition, the apparatus and method for controlling hot water of a cascade water heater according to an embodiment of the present invention provides an effect of stably supplying a lower temperature than the lowest hot water controllable by the heat source.

1 is a view showing a hot water control apparatus of a cascade water heater according to an embodiment of the present invention.
FIG. 2 is a view showing a case in which the integrated control set temperature of the integrated control unit among the hot water control apparatus of a cascade water heater according to an embodiment of the present invention is equal to or greater than the temperature at which the heat source can be controlled.
3 is a view showing a case in which the integrated control set temperature of the integrated control unit among the hot water control apparatus of the cascade water heater according to the embodiment of the present invention is less than the temperature that can be controlled by the heat source.
4 is a flowchart illustrating a hot water control method of a cascade water heater according to an embodiment of the present invention.

Hereinafter, 'a device and method for controlling hot water of a cascade water heater' according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a view showing a hot water control device 1 of a cascade water heater according to an embodiment of the present invention. 2 is a view showing a case in which the integrated control set temperature of the integrated control unit 200 of the hot water control device 1 of the cascade water heater according to the embodiment of the present invention is equal to or greater than the temperature at which the heat source can be controlled. 3 is a view showing a case in which the integrated control set temperature of the integrated control unit 200 among the hot water control apparatus 1 of the cascade water heater according to the embodiment of the present invention is less than the heat source controllable temperature.

First, referring to FIG. 1 , the hot water control device 1 of the cascade water heater includes a master heat source device 100m, a first slave heat source device 100s-1 to an Nth slave heat source device 100s-N, and integrated control. It may include a device unit 200 , a hot water temperature setting device unit 300 , and a hot water temperature detection device unit 400 .

And each of the master heat source device (100m), the first slave heat source device (100s-1) to the Nth slave heat source device (100s-N) is a hot water temperature detection unit 110, a water supply temperature detection unit 120, a flow rate detection unit 130. , the flame detection unit 140 , the fan driving unit 150 , the gas supply unit 160 , the flow rate control unit 170 , the communication unit 180 , the hot water temperature setting unit 190 , and each component 110 to 190 control In order to do this, it may include a control unit 100a having an operation module 110a.

On the other hand, the components of the master heat source device (100m), the first slave heat source device (100s-1) to the Nth slave heat source device (100s-N) used in the present invention are components used in the prior art. A detailed description will be omitted and will be described below focusing on important components used in the present invention.

Next, in the case where the integrated control set temperature of the integrated control unit 200 and the integrated control unit 200 of the hot water control device 1 of the cascade water heater according to the embodiment of the present invention in FIG. , the integrated control set temperature, which is the input set temperature provided on the integrated control unit 200, is 35 ° C, the minimum set temperature of the heat source that is the lowest possible set temperature for the heat source is 35 ° C, the water supply temperature is 20 ° C, and the hot water temperature is 35 If the bypass is not operated under the condition that the amount of hot water used is 10ℓ/min at ℃, the hot water of the integrated pipe can be supplied at the lowest hot water temperature of 35℃ that can be supplied from the heat source.

Next, when the integrated control set temperature of the integrated control unit 200 of the integrated control unit 200 of the hot water control device 1 of the cascade water heater according to the embodiment of the present invention in FIG. 3 is less than the heat source controllable temperature, The integrated control set temperature, which is the input set temperature provided on the integrated control unit 200, is 30 ° C. In order to match the input set temperature 30℃ of the integrated control device 200 for the hot water of the integrated pipe under the condition that the hot water usage is 10ℓ/min in the should make

At this time, the bypass ratio for supplying cold water to another combustion standby heat source in the present invention is calculated as follows.

Bypass ratio = (heat source hot water temperature - integrated control set temperature) ÷ (integrated control set temperature - water supply temperature) = (35-30) ÷ (30-20) = 0.500 Since this is 10 L/min, it is preferable that the bypass amount be 5.0 L/min.

That is, heat source devices such as water heaters and boilers have a limit on the lowest temperature that can be controlled for reasons of performance and safety. Therefore, although the temperature of the hot water that can be supplied differs depending on the type and type of the heat source, it is determined according to the performance of the heat source, and the minimum hot water temperature that can be supplied is determined.

When the heat source device as described above is installed in the cascade system method according to the present invention, when a set temperature lower than the heat source device is input to the integrated control device unit 200 that controls the entire cascade system method, one heat source device (The first slave heat source device 100s-1 in FIGS. 2 and 3 performs combustion and heat quantity control at the minimum hot water temperature that can be supplied, and is waiting for combustion to adjust the hot water temperature supplied to the integrated hot water pipe to the set temperature. of the heat source device (the second slave heat source device 100s-2 in FIGS. 2 and 3) receives the control command from the integrated control unit 200 from the communication unit 180, and then the control unit 100a controls the flow rate. By controlling the section 170 to open, it is desirable to bypass the necessary cold water.

Since we know the supply temperature, hot water usage, water supply temperature, and set temperature of the heat source device in combustion (100s-1) and the heat source device (100s-2) waiting for combustion, the required bypass flow rate is calculated and integrated control unit 200 It is controlled by the set temperature entered in

That is, when hot water is used, the integrated control set temperature input to the integrated control device unit 200 is checked to set the set temperature of the heat source device as the integrated control set temperature, or when a lower temperature than the heat source device is set, the heat source device is set Set to the lowest possible temperature and ignite one heat source that is waiting for combustion to control the amount of heat, calculate the target flow, and operate the flow control unit 170. In order to calculate and supply the amount of heat required to meet the set temperature The integrated control unit 200 may increase and decrease the required number of combustion heat sources through calculation.

If more heat than the maximum amount of heat of the burning heat source is required, the quantity of heat source is increased, and if the amount of heat of each heat source in combustion is the minimum combustion region, the amount of heat source is decreased.

In this way, by checking the integrated control set temperature input to the integrated control device unit 200, if it is a set temperature controllable by the heat source device, repeat the above steps, and if it is less than the set temperature controllable by the heat source device, it is necessary to adjust the set temperature Calculate the pass ratio and calculate the target bypass flow rate by the bypass ratio to calculate the number of heat source units required to increase and decrease the heat source units and control the operation of the flow rate controller 170 to meet the required bypass flow rate have.

The increase and decrease of the heat source for bypass by the integrated control unit 200 is limited in the maximum bypass flow rate possible per heat source unit, and it is necessary than the bypass flow rate of the heat source device currently performing the bypass operation. If the bypass flow rate is high, it increases, and if the required bypass flow rate is less than the maximum bypass flow rate except for one of the heat source units currently performing bypass operation, the operation decreases. is to keep

The integrated control unit 200 calculates the ratio of hot water and water (cold water) to match the set temperature by checking the temperature temperature, the set temperature, and the water supply temperature, that is, the bypass ratio, and calculates the required bypass quantity (target flow rate). The flow control unit 170 of the heat source in standby mode is adjusted to the bypass amount (target flow rate), and in this operation, the end user can use the included configuration of the heat source without directly detecting the temperature of the integrated pipe It can supply hot water at the set temperature.

4 is a flowchart illustrating a hot water control method of a cascade water heater according to an embodiment of the present invention. Referring to FIG. 4 , the integrated control device 200 detects the water supply temperature and the current hot water temperature through the hot water temperature detection device 400 by receiving a hot water use input from the hot water temperature setting device 300 . can be (S11).

After the step (S11), the integrated control unit 200 includes the integrated control set temperature input to the hot water temperature setting unit 300, the master heat source unit 100m, the first slave heat source unit 100s-1 connected in a cascade manner. ) to the Nth slave heat source device 100s-N, it is possible to analyze whether the “integrated control set temperature < the heat source minimum set temperature” or not through comparison with the preset minimum set temperature of the heat source device (S12).

If the result of the analysis in step S12 is "integrated control set temperature < heat source minimum set temperature", the integrated control device 200 includes the master heat source device 100m, the first slave heat source device 100s-1 to the Nth By changing the set temperature of all heat source devices corresponding to the slave heat source device (100s-N) to the lowest setting (the lowest temperature that the heat source device can set) (S13), after performing a process differentiated from the prior art, step (S15) proceed with

On the other hand, if the analysis result of step S12 is not "integrated control set temperature < heat source minimum set temperature", the integrated control unit 200 controls all heat source integrated control temperatures to perform a process differentiated from the prior art. By changing the setting for (S14), it is possible to perform standby until the integrated control set temperature < the lowest set temperature of the heat source for the integrated control set temperature.

After the step (S14), the integrated control unit 200 may control the ignition of one of the heat source devices in the combustion standby state (S15).

According to the step (S15), the integrated control device unit 200 controls the heat source controlled by itself according to combustion for the lowest set temperature of the heat source that does not reach the integrated control set temperature by transmitting and receiving signals and data with the control unit 100a. Perform calorie control (S16), a target flow rate calculation process according to combustion (S17), an operation process of the flow rate control unit 170 according to combustion (S18), and a required heat quantity calculation process according to combustion (S19), combustion It is also possible to calculate the number of required calorie groups according to (S20).

After the step S20 , the integrated control unit 200 may control the increase, decrease, and maintenance of the heat source according to the required number of combustion heat sources calculated in the step S20 ( S21 ).

After step S21, the integrated control device 200 compares the integrated control set temperature input to the hot water temperature setting device 300 corresponding to the same process as in step S12 and the hot water temperature of the controlled heat source. It is possible to analyze whether the "integrated control set temperature < hot water temperature" through (S22).

If the analysis result of step S22 is not "integrated control set temperature < hot water temperature", that is, if the integrated control set temperature is equal to the hot water temperature or the integrated control set temperature is greater than the hot water temperature, the integrated control unit 200 ) waits for the input from the hot water temperature setting device 300 for whether to stop the hot water (S23), and controls the fire extinguishing of the combustion of the heat source when the hot water stop is input (S24), and conversely, step ( If the analysis result of S22) is "integrated control set temperature < hot water temperature", it may proceed to step S26.

That is, the integrated control device unit 200 calculates the required bypass ratio required for the integrated control set temperature by transmitting and receiving signals and data to and from the control unit 100a, and calculates the target bypass flow rate for the heat source that is added and controlled (S26) (S27), additionally calculate the required number of heat source units (S28), analyze the increase and decrease of the required number of bypass heat source units, and maintain (S29), as well as the flow rate control unit 170 according to the target bypass flow rate calculation It is also possible to control the operation (S30). After the step (S30), the integrated control device unit 200 waits for an input from the hot water temperature setting device unit 300 for the above-described hot water stoppage (S23), and when the hot water stop is inputted, the combustion of the heat source device can control digestion.

The present invention can also be implemented as computer-readable codes on a computer-readable recording medium. The computer-readable recording medium includes all types of recording devices in which data readable by a computer system is stored.

delete

Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage device, etc. also includes

In addition, the computer-readable recording medium is distributed in a computer system connected through a network, so that the computer-readable code can be stored and executed in a distributed manner. In addition, functional programs, codes, and code segments for implementing the present invention can be easily inferred by programmers in the technical field to which the present invention pertains.

Although the present invention has been described with reference to one embodiment shown in the drawings, it is not limited to the embodiment and can be implemented by modification and modification within the scope of the present invention, and the modifications and variations are within the technical spirit of the present invention. Included.

1: Hot water control device of cascade water heater
100m : Master heat source
100s-1 to 100s-N: 1st to Nth slave heat source group
100a: control unit
110a: arithmetic module
110: hot water temperature detection unit
120: water supply temperature detection unit
130: flow rate detection unit
140: flame detection unit
150: fan drive unit
160: gas supply
170: flow control unit
180: communication department
190: hot water temperature setting unit
200: integrated control unit
300: hot water temperature setting device unit
400: hot water temperature detection device unit

Claims (6)

A first step of setting the set temperature of the heat source device after confirming the set temperature input by the integrated control unit; a second step of calculating a bypass ratio and a bypass flow rate for the integrated control unit to bypass at least one heat source according to a set temperature; and a third step of increasing, decreasing, and maintaining the required number of bypass heat sources by calculating the bypass flow rate through the integrated control unit after the second step; . delete The method of claim 1,
The bypass ratio of the second step is a hot water control method of a cascade water heater, characterized in that calculated by "(heat source hot water temperature - integrated control set temperature) ÷ (integrated control set temperature - water supply temperature)". a heat source group formed in a plurality of numbers; and setting the set temperature of the heat source after confirming the input set temperature, calculating the bypass ratio and bypass flow rate for bypassing at least one heat source by the set temperature, and calculating the bypass flow rate to calculate the required bypass The hot water control device of a cascade water heater comprising a; an integrated control unit for increasing, decreasing, and maintaining the pass heat source radix. delete 5. The method of claim 4,
The bypass ratio is calculated by "(heat source hot water temperature - integrated control set temperature) ÷ (integrated control set temperature - water supply temperature)".

Images