KR101506872B1 - Regenerative boiler having a external pump - Google Patents

Abstract

The present invention relates to a regenerative boiler with an outer mounted pump and, more specifically, to a regenerative boiler capable of circulating heating water discharged from a main heat exchanger via a three-way solenoid valve, a heating water supply pipe of a hot-water heat exchanger, a heating water supply pipe of a heat storage tank, and an inner mounted pump by connecting an outlet of the heating water supply pipe of the hot-water heat exchange to the heating water supply pipe of the heat storage tank connected to the inlet of the inner mounted pump in a hot water mode. In addition, the present invention makes the outer mounted pump supply the heating water stored inside the heat storage tank directly to a heating pipe to circulate the heating water in a heating mode and makes the inner mounted pump heat the main heat exchanger by continuously circulating the heating water inside the heat storage tank inside the main heat exchanger by directly connecting the end of a heating water return pipe and the heating water supply pipe connected to an inlet and an outlet of the heating pipe respectively. An outflow temperature sensor, a supply temperature sensor, and a return temperature sensor are installed on the heating water inlet, heating water supply pipe, and the heating water return pipe of the main heat exchanger respectively. The present invention is characterized in that a control unit automatically controls the amount of the heating water passing through the outer mounted pump corresponding to a result of comparing a preset temperature difference (ΔTSET) and a temperature difference (T1-T2=ΔTmea) measured by the supply temperature sensor and return temperature sensors. Therefore, the present invention is capable of preventing a waste of energy and noise due to the idle rotation of the outer mounted pump when a user uses hot water and economically and effectively heating indoors.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a regenerative boiler having an external pump,

The present invention relates to a regenerative boiler having an external pump, and more particularly, to a regenerative boiler having an external pump, in which, when a water flow sensing signal is input from a water flow sensor due to the use of hot water by a user, driving of an external pump installed outside the boiler In the case of stopping the use of hot water, the external pump is immediately activated and the heating water is immediately supplied to the heat storage tank, thereby preventing waste of energy and noise due to idling of the external pump. The temperature difference (T1-T2 =? Tmea) measured by the temperature sensor T1 and T2 provided in the heating water supply pipe and the water return pipe respectively and the set temperature difference? T _SET are compared with each other To adjust the flow rate through the external pump so that the appropriate amount of heat can be automatically supplied according to the heating load .

Generally, in a regenerative boiler in which a regenerative boiler or an external pump provided with an external pump between a heat storage tank (i.e., a heating water storage heat storage tank) having a predetermined volume and a heating pump is additionally provided on a heat recovery water supply side or a supply side pipe, And is configured to be operated simultaneously with the built-in pump.

FIG. 1 is a block diagram of a regenerative boiler having a conventional external pump. According to the block diagram of FIG. 1, a heat storage tank 1 having a predetermined volume is connected to the inlet of the main heat exchanger 21 in the boiler body 2, The supply pipe 4 is provided with a boiler main body 2 internal pump 23 whose operation is controlled by the control unit 25 and is installed between the outlet of the main heat exchanger 21 and the inlet of the heating pipe 6 The heating water supply pipe 5 is provided with an external pump 3 whose driving is controlled by the control unit 25 in the boiler body 2 and a boiler The hot water heat exchanger 22 is provided at the other side of the hot water heat exchanger 22 with a heating water supply and discharge pipe 22-1 passing through one side of the hot water heat exchanger 22 in the main body 2, And the heat of the heated water discharged from the main heat exchanger (21) And a heating water return pipe 7 provided between the heat storage tank heating water supply pipe 4 and the outlet of the heating pipe 6 is provided with a direct water heating water supply pipe 22-2, And a shutoff valve 26 for shutting off the heating water that is returned to the heat storage tank 1 side in the heating pipe 6 so that the water supplied to the main heat exchanger 21 and the heating water pass through the hot water heat exchanger.

However, in the regenerative boiler having the external pump having such a configuration, even when hot water is used, the hot water of the storage tank 1 is all heated by the main heat exchanger 21 and supplied to the hot water heat exchanger 22, The preheating time is prolonged and unnecessary energy is wasted, and the circulating external pump 3 continues to operate, thereby generating noise.

In order to prevent this, a boiler provided with a part of an external pump has a heating water supply pipe 5 connected to the outlet of the main heat exchanger 21 and a heating water supply and exhaust unit provided through the one side of the hot water heat exchanger 22 In the case where the hot water is used, the three-way switching position may be grasped and the external pump may be stopped when the hot water is opened.

However, in the regenerative boiler equipped with the three-way and external pump, if hot water usage is stopped during hot water use, the hot water may be reused, so that the three-way hot water is not transferred to the heating mode, During this time, the external pump that circulates the heating water keeps stopping, and there is a problem that the conversion to the heating is not performed quickly.

A temperature sensor 11 connected to the control unit 25 in the boiler body 2 is provided in the heat storage tank 1 for heating using a regenerative boiler provided with an external pump so that the temperature of water heated in the heat storage tank And when the temperature of the heating water reaches the temperature, the operation of the boiler for supplying the heat source to the heat storage tank is stopped. When the temperature of the heating water that has been despooled in the storage tank falls below the set temperature, the boiler is operated again, The external pump is operated in accordance with the heating signal to supply the heating water. However, the external pump performs only a simple function of supplying and stopping the flow amount in a constant amount without considering the amount of heat of the load It is true.

Patent Document 0001. Korean Utility Model Registration No. 20-0274019 (Apr. 19, 2002)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems of the related art, and it is an object of the present invention to provide a heating water heat exchanger which directly supplies heated water discharged from a main heat exchanger to a heat storage tank through three- The heating water supply pipe, the heating pipe and the heating water supply pipe with the external pump are directly connected to the heat storage tank in which the heating water is desiccated. When the user inputs the water detection signal from the water sensor due to the use of the hot water, When the hot water is stopped, the external pump is immediately operated so that the heating water is immediately supplied to the heat storage tank, thereby wasting energy due to idling of the external pump when hot water is used, and Noise generation can be prevented, and in particular, more economical and efficient Typically there is provided a regenerative boiler provided with an external pump capable of heating.

Another object of the present invention is to compare the temperature difference (T1-T2 =? Tmea) measured through the temperature sensor provided in each of the heating water supply pipe and the water return pipe with the set temperature difference? T _SET , So that it is possible to automatically supply an appropriate amount of heat according to the heating load, thereby providing a regenerative boiler having an external pump capable of greatly improving the merchandise of the regenerative boiler itself and the reliability of the hot water and the heating operation .

In order to accomplish the above object, the present invention provides a regenerative boiler comprising: a heat storage tank having a predetermined volume and storing heated water required by heating pipes through respective heat exchangers; A built-in pump in the boiler body installed on the heat-storage tank water supply pipe provided between the storage tank and the inlet of the main heat exchanger, the driving of which is controlled by a control unit; A main heat exchanger in the boiler body for heating the heating water in the thermal storage tank with heating water having a predetermined temperature and for supplying heated water to the hot water heat exchanger as a heat source for heating hot water; The heating water discharged from the main heat exchanger is transferred to the heat storage tank through the heating water discharge pipe or to the hot water heat exchanger through the heating water supply pipe in response to the switching signal outputted from the control unit in response to the user's selection of the heating or hot water mode The main part of the boiler body has three defrosts; A hot water heat exchanger in the boiler body for heating the direct water to hot water using a heat source generated from the hot water of the main heat exchanger supplied through the three-way exchanger when the user uses hot water; A water flow sensor installed on a direct water and hot water supply pipe provided on the other side of the hot water heat exchanger and detecting whether the user uses hot water by an electric signal; A control unit in the boiler body that performs overall control functions for various electrical products corresponding to the heating or hot water mode selected by the user; And an external pump for circulating heating water through a heating water supply pipe, a heating pipe and a heating water pipe, wherein the heating water supply pipe outlet of the hot water heat exchanger is connected to the inlet of the internal pump When the hot water mode is selected, the heating water discharged from the main heat exchanger is circulated through the heating water supply pipe, the heat storage tank heating water supply pipe and the built-in pump of the hot water heat exchanger, The heating water supply pipe and the end portion of the heating water pipe connected to the inlet and the outlet of the heating water pipe are respectively connected directly to the heat storage tank. When the heating mode is selected, the external pump supplies the heating water stored in the heat storage tank directly to the heating pipe, Is characterized in that the heating water in the heat storage tank is continuously circulated and continuously heated in the main heat exchanger It shall be.

When the regenerative boiler is operated in the heating mode, when the use of hot water is detected in the water sensor, the control unit switches the three-way valve to the hot water heat exchanger and simultaneously controls the operation of the external pump to operate in the hot water mode .

In addition, when it is detected that the direct water supply from the water sensor is stopped during the operation in the hot water mode, the control unit controls the outdoor pump to operate in the heating mode by driving the external pump.

The heating water outlet, the heating water supply pipe and the heating water supply pipe of the main heat exchanger are respectively provided with a hot water temperature detection sensor, a heating supply temperature detection sensor and a heat recovery water temperature detection sensor, And the temperature difference (T1-T2 =? Tmea) measured through the heat recovery water temperature detecting sensor is compared with the set temperature difference? T _SET , and the flow rate passing through the external pump is automatically adjusted corresponding to the result.

At this time, when the set temperature difference [Delta] T _SET is smaller than the measured temperature difference [Delta] Tmea (DELTA T _SET < Tmea), the control unit operates the external pump at maximum output to supply the heating water.

When the set temperature difference DELTA T _SET becomes equal to the measured temperature difference DELTA Tmea (DELTA T _SET = DELTA Tmea), the control unit controls the driving of the external pump so that the condition of DELTA T _SET = DELTA Tmea is maintained.

Further, when the set temperature difference? T _SET is larger than the measured temperature difference? Tmea (? T _SET >? T mea), the controller continuously limits the output of the external pump so that the condition of? T _SET =? T mea is maintained.

As described above, according to the regenerative boiler having the external pump of the present invention, the hot water discharged from the main heat exchanger is directly supplied to the heat storage tank through three-way switching, and the hot water heat exchanger and the main heat exchanger The heating water supply pipe, the heating pipe and the heating water supply pipe provided with the external pump are directly connected to the heat storage tank in which the heating water is desiccated. When the user inputs the water detection signal from the water sensor due to the use of the hot water, In order to circulate the water, the external pump installed on the outside of the boiler is immediately stopped, and when the hot water is stopped, the external pump is immediately operated so that the heating water is immediately supplied to the heat storage tank. As a result, And noise generation can be prevented, and in particular, a more economical It is possible to heat efficiently.

Further, in the present invention, the temperature difference (T1-T2 =? Tmea) measured through the temperature sensor provided in each of the heating water supply pipe and the water return pipe is compared with the set temperature difference? T _SET , It is possible to automatically supply an appropriate amount of heat according to the heating load by making it possible to regulate the flow rate passing therethrough, thereby remarkably improving the merchandise of the regenerative boiler itself and the reliability of the hot water and heating operation.

1 is a block diagram of a regenerative boiler having a conventional external pump.
2 is a block diagram of a regenerative boiler to which the present invention is applied.
FIG. 3 is a block diagram showing an operation state of each part when a regenerative boiler to which the present invention is applied is operated in a heating mode. FIG.
FIG. 4 is a block diagram showing operating states of parts when a regenerative boiler to which the present invention is applied is operated in a hot water mode. FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a block diagram of a regenerative boiler to which the present invention is applied, FIG. 3 is a block diagram showing an operating state of each part when a regenerative boiler to which the present invention is applied is operated in a heating mode, FIG. 2 is a block diagram showing an operating state of each part when the regenerative boiler to which the invention is applied operates in the hot water mode.

According to the present invention,

A heat storage tank (1) having a predetermined volume and storing the heated water through the main heat exchanger (21) in the heating water required by each heating pipe (6); A built-in pump 23 in a boiler body 2 which is installed on a regenerator hot water supply pipe 4 provided between the inlet of the heat storage tank 1 and the main heat exchanger 21 and whose drive is controlled by a control unit 25, Wow; A main heat exchanger (not shown) in the boiler main body 2 for heating the heating water in the heat storage tank 1 to the hot water heat exchanger 22 as a heat source necessary for heating hot water, 21); The heating water discharged from the main heat exchanger 21 is supplied to the storage tank 1 through the heating water discharge pipe 21-1 in response to the switching signal outputted from the control unit 25 in response to the user's selection of the heating or hot water mode (24) in the boiler body (2) for transferring or supplying the water to the hot water heat exchanger (22) side via the hot water supply pipe (22-3); A hot water heat exchanger 22 in the boiler body 2 for heating the direct water to hot water by using a heat source generated from the hot water of the main heat exchanger 21 supplied through the three-way valve 24 when the user uses hot water, ; A water flow sensor 27 installed on the direct water and hot water supply pipe 22-2 provided on the other side of the hot water heat exchanger 22 and detecting by an electric signal whether or not the user uses hot water; A control unit (25) in the boiler body (2) that performs overall control functions for various electrical products corresponding to the heating or hot water mode selected by the user; And an external pump (3) for circulating heating water through a heating water supply pipe (5), a heating pipe (6) and a heating water water pipe (7)

The outlet of the heating water supply pipe 22-3 of the hot water heat exchanger 22 is connected to the heat storage tank heating water supply pipe 4 which is in contact with the inlet of the internal pump 23 and is discharged from the main heat exchanger 21 The heating water is circulated through the three-way diverter 24 and the heating water supply pipe 22-3 of the hot water heat exchanger 22, the heat storage tank heating water supply pipe 4 and the built-in pump 23,

And the other end of the heating water supply pipe 5 and the other end of the heating water supply pipe 7 connected to the inlet and the outlet of the heating pipe 6 are directly connected to the heat storage tank 1, 3 causes the heating water stored in the heat storage tank 1 to be supplied directly to the heating pipe 6 to circulate the water and the built-in pump 23 continuously circulates the heating water in the heat storage tank 1 through the main heat exchanger 21 And is continuously heated.

When the regenerative boiler is operated in the heating mode and the use of hot water is detected by the water sensor 27, the control unit 25 switches the three-way valve 24 to the hot water heat exchanger 22, 3) is shut off to operate in a hot water mode.

In addition, when it is detected that the direct water supply from the water flow sensor 27 is stopped while operating in the hot water mode as described above, the control unit 25 controls the external pump 3 to operate in the heating mode.

The heating water outlet of the main heat exchanger 21 and the heating water supply pipe 5 and the heating water supply water pipe 7 are connected to the hot water temperature detection sensor 28 and the heating supply temperature detection sensor 5-1, The control unit 25 sets the temperatures T1 and T2 to be measured through the heating supply temperature detection sensor 5-1 and the heating return temperature detection sensor 7-1, T2) and a set temperature difference (DELTA T _SET ) are compared with each other, and the flow rate passing through the external pump (3) is automatically adjusted corresponding to the result.

At this time, when the set temperature difference? T _SET is smaller than the measured temperature difference? Tmea (? T _SET <? T mea), the controller 25 operates the external pump 3 at maximum output to supply the heating water .

If the set temperature difference? T _SET becomes equal to the measured temperature difference? Tmea (? T _SET =? T mea), the controller 25 controls the driving of the external pump 3 so that the condition of? T _SET =? T mea is maintained .

If the set temperature difference? T _SET is larger than the measured temperature difference? Tmea (? T _SET >? T mea), the control unit 25 continuously restricts the output of the external pump 3 so that the condition of? T _SET = .

Here, the set temperature difference? T _SET means an optimum target temperature difference that is determined to be appropriately heated.

The operation and effect of the thus constructed regenerative boiler of the present invention will be described below.

In the regenerative boiler having a known external pump, the outlet of the heating water supply pipe (22-3) of the hot water heat exchanger (22) is connected to the storage tank heating water supply pipe (4 And the other end of the heating water supply pipe 7 and the heating water supply pipe 5 provided at the inlet and the outlet of the heating pipe 6 at one end are respectively connected directly to the heat storage tank 1, When the water flow sensor signal is inputted from the water flow sensor 27 due to the use of the hot water, the external pump 3 installed outside the boiler is immediately stopped to circulate the heating water. When stopping the use of the hot water, 3) immediately so that the heating water is immediately supplied to the heat storage tank.

The known regenerative boiler is composed of a heat storage tank 1 and a boiler body 2 and an external pump 3 in which various components are incorporated. The boiler body 2 is provided with a main heat exchanger 21, The heat exchanger 22, the three-way valve 24, the water flow sensor 27, and the control unit 25.

Among the above components, the thermal storage tank 1 has a tank shape having a predetermined volume and stores heated water through the main heat exchanger 21 in the boiler body 2, and is required in each of the heating pipes 6 As the heating water to be supplied to the outdoor unit.

The built-in pump 23 is installed on the heat storage tank heating water supply pipe 4 provided between the heat storage tank 1 and the inlet of the main heat exchanger 21, The heating water in the heat storage tank 1 is circulated through the main heat exchanger 21 under the control of the control unit 25 so as to heat the water in the heat storage tank 21. In the hot water mode, unlike the conventional regenerative boiler, (1) The operation of circulating only a part of water in the main heat exchanger (21) through the hot water heat exchanger (22) and itself (that is, the built-in pump (23)) is repeated while water remains.

The main heat exchanger 21 heats the heating water in the storage tank 1, which is supplied through the built-in pump 23, in the heating mode to heating water having a predetermined temperature and sends the heating water back into the storage tank 1 A part of the heated water is supplied to the hot water heat exchanger 22 as a heat source necessary for heating hot water.

The three-way valve 24 supplies the heating water discharged from the main heat exchanger 21 to the heating water discharge pipe 21-2 corresponding to the switching signal of the control unit 25 outputted in response to the user's selection of heating or hot water mode. 1 to the heat storage tank 1 or to the hot water heat exchanger 22 through the heating water supply pipe 22-3.

The hot water heat exchanger 22 has a function of heating the hot water to hot water by using a heat source generated from the hot water of the main heat exchanger 21 supplied through the three-way valve 24 when hot water is used by the user .

When the user uses hot water in a state where the water flow sensor 27 is installed on the direct water and hot water supply pipe 22-2 provided on the other side of the hot water heat exchanger 22, To control the operation of the hot water mode related components.

In addition, the control unit 25 performs a general control function for various electrical products corresponding to the heating or hot water mode selected by the user.

In addition, the external pump 3 functions to circulate the heating water in the heating mode through the heating water supply pipe 5, the heating pipe 6, and the heating water water pipe 7.

Meanwhile, one of the main technical elements of the present invention is to allow the heating water heated by the main heat exchanger (21) to be supplied directly to the heating pipe (6) side when the user heating mode is selected, (That is, when a water flow detection signal is detected by the water flow sensor 27), the heating water discharged from the main heat exchanger 21 is supplied to the heat storage tank 1 through the heating water supply pipe 22-3 of the hot water heat exchanger 22 Unlike the conventional heat storage room boiler in which a shutoff valve is provided between the heat storage tank heating water supply pipe 4 and the heating water storage water pipe 7, the installation of the shutoff valve is eliminated, The outlet of the heating water supply pipe 22-3 is connected to the heat storage tank heating water supply pipe 4 which is in contact with the inlet of the internal pump 23 and the heating water discharged from the main heat exchanger 21 The heating water supply pipe 22-3 of the hot water heat exchanger 22, The tank so that the heating water circulation via a feed pipe 4 and the built-in pump 23 to the main technical elements of the invention.

The other end of the heating water return pipe 7 and the heating water supply pipe 5 connected to the inlet and the outlet of the heating pipe 6 are connected to the outlet of the main heat exchanger 21 and the shut- The heating water supply pipe 5 and the heating water supply water pipe 7 provided at the inlet and the outlet of the heating pipe 6 are connected to the water supply pipe 4, The external pump 3 directly supplies the heating water stored in the heat storage tank 1 to the heating pipe 6 and circulates the heated water directly to the heating pipe 6, Is another important technical component that the heating water in the heat storage tank 1 is continuously circulated and continuously heated in the main heat exchanger 21. [

3, when the heating request signal is input to the control unit 25 in the boiler body 2 from outside the regenerative boiler having the above-described configuration, the built-in pump 23 supplies water in the heat storage tank 1 to the main heat exchanger The main heat exchanger 21 continuously supplies the heat to the heat storage tank 1 and the hot water is stored again in the heat storage tank 1 while the external pump 3 The heating water in the storage tank 1 is supplied to the heating pipe 6 of the room requiring heating so that the heating water that has been exchanged with the heat pipe through the heating pipe installed in the room, (1). &Lt; / RTI &gt;

When the regenerative boiler in which the present invention is applied operates in the heating mode, when the use of hot water is detected in the water sensor 27, the control unit 25 switches the three-way valve 24 to the hot water heat exchanger 22 The supply of the heating water is completely cut off in the hot water mode and the amount of heating water heated in the main heat exchanger 21 in response to the driving of the built-in pump 23 is 3 Is circulated through the defrosting 24 and the heating water supply pipe 22-3 of the hot water heat exchanger 22, the heat storage tank heating water supply pipe 4 and the internal pump 23 and is installed on the other side of the hot water heat exchanger 22 And the direct water passing through the inside of the direct water and hot water supply pipe 22-2 is heated by the hot water and then supplied to the user as hot water.

That is, when the water flow is detected (that is, the use of the hot water is detected) from the water flow sensor 27 provided in the direct water and hot water supply pipe 22-2, the control unit 25 switches the three way exchange 24 to the hot water heat exchanger 22 so as to circulate a part of the heating water in the main heat exchanger 21 through the built-in pump 23 as shown in FIG. 4 so that the direct water passing through the hot water heat exchanger 22 is heated to the hot water. The driving of the external pump 3 is stopped.

Therefore, it is possible to prevent waste of energy and generation of noise due to idling of the external pump 3 when hot water is used.

When the direct water supply from the water flow sensor 27 is detected to be stopped (that is, when the user stops using the hot water), the heating water in the storage tank 1 is subjected to main heat exchange The built-in pump 23 for circulating the unit 21 drives the external pump 3 while the unit is continuously driven so that the unit is immediately operated in the heating mode so that the hot water heated in the storage tank 1 is discharged to the heating pipe (6) so that the heating is continuously performed, so that the heating can be performed more economically and effectively.

In the present invention, the hot water outlet port of the main heat exchanger 21, the hot water supply pipe 5 and the hot water return pipe 7 are respectively provided with a hot water temperature detection sensor 28 and a heating supply temperature detection sensor 5-1 And the heating water return temperature detecting sensor 7-1 are provided to detect the tap water temperature of the hot water discharged from the main heat exchanger 21 and the heating water supply temperature T1 supplied from the thermal storage tank 1, (T2) of the heating water that is returned to the heat storage tank (1) through the control unit (25).

The control unit 25 is also provided with a heating water supply temperature T1 and a heating water heat exchange water temperature Tc measured in real time via the heating supply temperature detection sensor 5-1 and the heating water return temperature detection sensor 7-1, T2 = ΔTmea) is calculated and compared with the set temperature difference (ΔT _{S ET} ), and the flow rate passing through the external pump (3) is automatically adjusted in accordance with the result.

That is, the control unit 25 calculates the temperature difference (T1-T2 =? Tmea) and the set temperature difference? T _{S ET} measured through the heating supply temperature detection sensor 5-1 and the heat recovery water temperature detection sensor 7-1 As a result of the mutual comparison, when the set temperature difference? T _SET is smaller than the measured temperature difference? Tmea (? T _SET <? Tmea), the external pump 3 currently operating is operated at the maximum output, So that the heating water of the high temperature can be supplied at the maximum, so that the heating temperature of the room can be rapidly increased.

By the way, are compared as a result, the measurement is set, the temperature difference (ΔT _SET) the feed and water exchange temperature difference (T1-T2 = ΔTmea) and set the temperature difference (ΔT _SET) for the number of heating giving supply to a particular room in the control unit 25 If the temperature difference DELTA Tmea is equal to (DELTA T _SET = DELTA Tmea), the control unit 25 performs control to maintain the output of the external pump 3 in the current state so that the condition of DELTA T _SET = DELTA Tmea is maintained.

In addition, the cross-batching, measuring a set temperature difference (ΔT _SET) the feed and water exchange temperature difference (T1-T2 = ΔTmea) and set the temperature difference (ΔT _SET) for the number of heating giving supply to a particular room in the control unit 25 When the temperature difference DELTA Tmea is larger than DELTA Tmea (DELTA T _SET > DELTA Tmea), the control unit 25 performs control to continuously restrict the output of the external pump 3 (i.e., deceleration control) so that the condition of DELTA T _SET = DELTA Tmea is maintained .

Accordingly, it is possible to automatically supply an appropriate amount of heat according to the heating load, thereby greatly improving the merchandise of the regenerative boiler itself and the reliability according to the hot water and the heating operation.

Although the preferred embodiments of the present invention have been described for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. Which will be apparent to those skilled in the art.

1: heat storage tank
2: Boiler body
21: main heat exchanger 21-1: heating water discharge pipe
22: hot water heat exchanger 22-1: direct water and hot water supply pipe
22-3: Heating water supply pipe
23: built-in pump 24: 3 variant
25: control unit 27: water flow sensor
28: Hot water temperature detection sensor
3: External pump
4: Heat water heating water supply pipe
5: Heating water supply pipe 5-1: Heating supply temperature detection sensor
6: Heating piping
7: Heating water return pipe 7-1: Heating return temperature detecting sensor

Claims (7)

A heat storage tank for storing the heated water through the main heat exchanger as heating water; A built-in pump installed on a heat storage tank heating water supply pipe installed between the heat storage tank and the inlet of the main heat exchanger in the boiler body and controlled to be driven by a control unit; A main heat exchanger for heating the heating water in the thermal storage tank with heating water having a predetermined temperature and for providing the heated water to the hot water heat exchanger as a heat source necessary for heating hot water; A three-way valve for supplying the heating water discharged from the main heat exchanger to the heat storage tank through the heating water discharge pipe or supplying the heated water discharged from the main heat exchanger to the hot water heat exchanger through the heating water supply pipe in response to the heating or hot water mode; A hot water heat exchanger for heating the direct water to hot water using a heat source generated from the hot water of the main heat exchanger supplied through the three-way exchanger when hot water is used; A water flow sensor installed on a direct water and hot water supply pipe provided on the other side of the hot water heat exchanger and detecting whether a user uses hot water; A control unit for performing overall control functions for various electrical products; And an external pump for circulating the heating water through a heating water supply pipe, a heating pipe and a heating water supply pipe. In the regenerative boiler having an external pump,
The outlet of the heating water supply pipe of the hot water heat exchanger is connected to the storage tank heating water supply pipe communicated with the inlet of the built-in pump. When the hot water mode is selected, the heating water discharged from the main heat exchanger is circulated through the heat exchanger, A supply pipe and a built-in pump,
The heating water supply pipe and the end portion of the heating water supply pipe connected to the inlet and outlet of the heating pipe are respectively connected directly to the heat storage tank. When the heating mode is selected, the external pump supplies the heating water stored in the heat storage tank directly to the heating pipe, And the internal pump continuously circulates the heating water in the heat storage tank and continuously heats the main heat exchanger,
A hot water temperature detection sensor, a heating supply temperature detection sensor, and a heat recovery water temperature detection sensor are provided in the heating water outlet port of the main heat exchanger, the heating water supply pipe and the heating water water return pipe, respectively, Wherein a temperature difference (T1-T2 =? Tmea) measured through a return water temperature sensor is compared with a set temperature difference (? T _SET ), and the flow rate passing through the external pump is automatically adjusted corresponding to the result. Equipped regenerative boiler.
The method according to claim 1,
Wherein when the hot water use is detected by the water sensor during operation in the heating mode, the control unit controls the three pumps to be switched to the hot water heat exchanger side while shutting off the external pump to operate in the hot water mode One regenerative boiler.
The method of claim 2,
Wherein when the direct water supply from the water sensor is detected to be stopped in the hot water mode, the control unit controls the external pump to operate in the heating mode by driving the external pump.
delete The method according to claim 1,
Wherein when the temperature difference (ΔT _SET ) set by the control unit is smaller than the measured temperature difference (ΔTmea) (ΔT _SET <ΔTmea), the external pump is operated at the maximum output to supply the heating water.
The method according to claim 1,
When the set temperature difference? T _SET becomes equal to the measured temperature difference? Tmea (? T _SET =? T mea), the control unit controls the driving of the external pump so that the condition of? T _SET =? T mea is maintained Regenerative boiler.
The method according to claim 1,
An external pump, characterized in that to continue limiting the output of the external pump to greater than predetermined temperature difference (ΔT _SET) measuring the temperature difference _{(ΔTmea) (ΔT SET> ΔTmea} ), the control unit maintains a condition of ΔT _SET = ΔTmea Equipped regenerative boiler.

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