KR20160060194A - Boiler having assembly structure of modularized water pipe parts - Google Patents

Abstract

The present invention relates to a boiler having an assembly structure where water pipe parts are modularized. The boiler comprises a main heat exchanger (30) and a hot-water supply heat exchanger (100). The hot-water supply heat exchanger (100) includes multiple plates stacked on one another, inside which a heating water flow path (P1) and a cold water flow path (P2) are individually formed so that heating water and cold water flow at each layer by turns to exchange heat. In a front plate (110), a heating water drain guide part (110c) and a hot water drain guide part (110d) are formed, wherein the heating water drain guide part (110c) forms a flow path of heating water so that a heating water drain pipe (L7), which is introduced through a heating water inlet pipe (L6), passes the heating water flow path (P1), and then is discharged, is positioned close to the heating water inlet pipe (L6) , and the hot water drain guide part (110d) forms a flow path of hot water so that a hot water feeding pipe (L11), which is introduced through a cold water inlet pipe (L10), passes the cold water flow path (P2), and then is discharged, is positioned close to the cold water inlet pipe (L10). The boiler further comprises: a first water pipe module (200) having one end detachably joined to the heating water inlet pipe (L6) and the heating water drain pipe (L7) and a flow path allowing heating water supplied from the main heat exchanger (30) to be collected via a heating consuming place or the hot-water supply heat exchanger (100); and a second water pipe module (300) having one end detachably joined to the cold water inlet pipe (L10) and the hot water feeding pipe (L11) of the hot-water supply heat exchanger (100) and providing flow paths for cold water and hot water passing through the hot-water supply heat exchanger (100).

Description

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

The present invention relates to a boiler having an assembled structure in which water pipe components are modularized, and more particularly, to improve the productivity of products by simplifying the assembly structure between the water pipe components by configuring each function product of the boiler water pipe as a module unit And to a boiler having a modularized assembly structure of a water pipe component in which heat exchange efficiency is improved by minimizing a pressure loss by shortening a length of a pipe connecting water pipe components.

Generally, a boiler is a device which heats heating water by the combustion heat of the burner, supplies the heated water to the heat source for heating and supplies hot water by heat exchange between the heated water and the direct water.

Conventional boilers include a main heat exchanger that heats the heating water by the heat of combustion of the burner, a circulation pump installed in the flow path of the heating water for forced circulation of the heating water, and a circulation pump that supplies the heating water heated by the main heat exchanger to a heating station, A three-way valve for switching the flow path of the heating water to selectively supply the heat to the heat exchanger side, a hot water heat exchanger for supplying hot water by heat exchange between the hot water heated by the main heat exchanger and the direct water, And an expansion tank in which heating water circulated through the hot water heat exchanger is recovered and stored.

The hot water heat exchanger includes a fin-tube type heat exchanger in which a plurality of tubes are inserted into a tank, and a plurality of plates are stacked so that heating water and direct water alternately flow in each layer and heat exchange is performed Plate type heat exchanger. The plate type heat exchanger is advantageous in that it can be assembled more easily than the pin-tube type heat exchanger, and the productivity and the number of parts can be reduced.

The general structure of a plate heat exchanger in which a plurality of plates are stacked is disclosed in, for example, Japanese Patent Application Laid-Open No. 10-1151754, Japanese Patent Application Laid-Open No. 10-2003-0071249, and the like.

The hot water inlet and the hot water outlet are formed on one side of the lower part of the plate and on the other side of the upper part, and the direct water inlet and the hot water outlet are connected to the other side of the plate and the upper part of the plate, respectively. In the conventional plate heat exchanger according to the prior art, So that the heating water and the direct water flow in opposite directions and heat exchange is performed. However, in the conventional plate type heat exchanger, since the water pipe through which the heating water flows and the water pipe through which the direct water (hot water) flows are spaced apart from each other at the diagonal positions of the plates, the water pipe connected to the heating water inlet and the heating water outlet And the water pipes connected to the direct water inlet and the hot water outlet are separately installed at the positions where they are separated from each other, the water pipe structure of the hot water and the water pipe structure of the direct water (hot water) become complicated, It is difficult to reduce the size of the pipe, and as the pipe length of the water pipe becomes longer, a pressure loss is generated and the thermal efficiency is lowered.

On the other hand, when the boiler is operated in the heating mode or the hot water mode, if the user arbitrarily closes the heating pipe or if the heating pipe is clogged due to accumulation of foreign matter in the heating pipe, overpressure exceeding the allowable pressure is generated in the heating pipe In this case, the boiler parts including the circulation pump will be damaged. In order to prevent overpressure in the heating pipe, Japanese Patent Laid-Open Publication No. 1998-016052 discloses that a bypass hole is formed at one side of an exhaust pipe between two upper and lower opening and closing holes formed in a discharge pipe of a bidirectional circulation pump, And a bypass pipe is connected between the heating water pipe and the heating water pipe.

According to such a configuration, there is an advantage that overpressure of the heating pipe can be prevented. However, since the bypass pipe connecting the bidirectional circulation pump and the heating water return pipe is always opened through the bypass hole, The heat exchange efficiency of the heating water is lowered because a part of the heating water heated in the heating mode and the hot water mode leaks to the heating water return pipe through the bypass pipe even in the non-closed steady state, and there is a disadvantage that the expensive bidirectional circulation pump There is a drawback that the manufacturing cost of the boiler is increased.

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the above problems, and it is an object of the present invention to provide a boiler water pipe system, And an object of the present invention is to provide a boiler having an assembled structure.

It is another object of the present invention to provide a boiler having a module structure in which a water pipe component capable of shortening the length of a pipe connecting water pipe components to minimize the pressure loss and improving the heat exchange performance is modularized.

In order to achieve the above object, the present invention provides a boiler having a modular assembly structure, comprising a main heat exchanger (30) for heating the heating water by the heat of combustion of the burner, a main heat exchanger And a hot water heat exchanger (100) for supplying hot water by heat exchange between the heated water and direct water, wherein the hot water heat exchanger (100) has a plurality of plates stacked, The front plate 110 disposed in front of the plurality of plates is provided with a heating water channel P1 and a direct water channel P2 separated from each other so that heat exchange is performed alternately for each layer. So that the heating water discharge pipe L7 which is introduced into the heating water inflow pipe L6 formed at the lower side of the heating water inflow pipe L6 and discharged after passing through the heating water flow path P1 is located close to the heating water inflow pipe L6 A hot water discharge guide part 110c which forms a waterproof flow path and a hot water supply pipe L10 which is introduced into the direct water inflow pipe L10 formed on the other side of the lower surface of the front plate 110, A hot water discharge guide portion 110d is formed to form a hot water flow path so that the hot water discharge port L11 is positioned close to the direct water inlet pipe L10; The heating water is supplied from the main heat exchanger (30) to the heating source or the hot water heat exchanger (30). The heating water inlet pipe (L6) and the heating water outlet pipe (L7) of the hot water heat exchanger A first water pipe module 200 for providing a flow path through which water is returned via the first water pipe module 100; And a second water pipe which is assembled so that one side is connected to and disconnected from the direct water inlet pipe L10 and the hot water supply pipe L11 of the hot water heat exchanger 100 and which provides a direct water passing through the hot water heat exchanger 100, Module 300 as shown in FIG.

A heating water inflow hole 111 connected to the heating water inflow pipe L6 is formed at a lower side of the front plate 110 and at one side of the heating water inflow hole 111, And the heating water discharge guide portion 110c is connected to the heating plate discharge port L7 and the heating water discharge guide portion 110c is connected to the front plate 110 so as to discharge the heating water discharged forward to the other side of the upper surface of the front plate 110, And may be formed to lead to the hole 112.

A direct water inflow hole 113 connected to the direct water inflow pipe L10 is formed on the lower side of the front plate 110 and the heated water discharge guide unit 110c is provided on the upper surface of the front plate 110 A hot water discharge hole 114 connected to the hot water supply pipe L11 is formed at a position adjacent to the direct water inflow hole 113 in the region where the hot water discharge guide unit 110d is not formed, To the hot water discharge hole (114).

A heating water inlet hole 121 is formed at a lower side of the front plate 110 and a heating water outlet hole 122 is formed at the other side of the front plate 110. A direct water inlet hole 123 is formed on the other side And the edge portion of the heated water discharge guide portion 110c and the hot water discharge guide portion 100d are stacked on the edge of the flat plate 120, And the inner side portion of the rim portion protrudes forward so as to form the heating water and the hot water discharge flow path.

A plurality of first plates 130 and a plurality of second plates 130 are formed in the rear of the flat plate 120 such that the bosses positioned in the diagonal direction cross each other such that the heating water channel P1 and the direct water channel P2 are alternately formed, A plurality of first beads 135 and a second bead 145 are formed in the first plate 130 and the second plate 140 in a direction opposite to the first plate 130 and the second plate 140, The first bead 135 and the second bead 145 may be structured to allow fluid to flow through the overlapping clearance between the first bead 135 and the second bead 145.

A first flow path switching plate (150) for switching the direct flow path from the rear to the front is provided at the rear of the second plate (140) stacked in the rearmost chamber so that the flow path of the heating water is forward And the second flow path switching plate 160 for switching can be sequentially stacked.

The first flow path switching plate 150 is formed with a heating water inflow hole 151 at a lower side thereof and a heating air outlet hole 152 at an upper side of the first flow path switching plate 150, And the second flow path switching plate 150 may have a configuration in which the entire area is closed in the front and rear directions.

The first water piping module 200 is supplied with heating water supplied through the heating water main supply pipe L1 heated by the main heat exchange 30 to the heating destination through the heating water supply pipe L2, A three-way valve 210 for switching the flow path of the hot water to selectively supply the hot water to the hot water heat exchanger 100 via the water inlet pipe L6 and a three-way valve 210 for connecting the three-way valve 210 and the hot water return pipe L3 And a heating pipe connected to the heating water supply pipe (L2) or a heating pipe connected to the hot water heat exchanger (100) side is closed in a duct line of the bypass pipe (L8) A check valve 220 may be provided to allow the fluid to flow only in one direction from the three-way valve 210 to the heating water return pipe L3.

The heating pipe connected to the heating water L3 may be provided with a circulation pump 20 for feeding the heating water toward the main heat exchanger 30 in one direction.

The second water pipe module 300 is provided with a flow sensor 310 for sensing the flow of the direct water flowing into the direct water inflow pipe L10 and a flow sensor 310 for receiving the direct water at the time of shortage of the heating water, A water replenishment pipe L12 and a replenishing water valve 320 provided in a channel of the water replenishing pipe L12 for interrupting the direct water flow.

According to the boiler having the modularized assembled structure of the water pipe component according to the present invention, it is possible to provide a first flow path for the heating water in the heating or hot water mode and a first path for providing the bypass path for the heating water in the case where overpressure is generated in the heating pipe, And a second water pipe module for providing a flow path for direct water and hot water in the hot water mode and a supplementary flow path for the heating water can be constructed in module units so as to be removable in the hot water heat exchanger, The number of parts can be reduced and the productivity of the product can be improved.

The hot water discharge guide portion and the hot water discharge guide portion are formed on the front plate of the hot water heat exchanger so that the interval between the heating water inlet pipe and the heating water outlet pipe and the distance between the direct water inlet pipe and the hot water supply pipe are close to each other, The first water pipe module and the second water pipe module can be attached to and detached from the hot water heat exchanger, thereby making it possible to downsize the boiler and shorten the connecting flow path of the water pipe, thereby reducing the pressure loss due to the pressure drop of the fluid, Performance can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing the construction of a boiler having a modularized assembly structure of a water pipe component according to the present invention;
FIG. 2 is a perspective view showing a main part of a boiler according to the present invention,
FIG. 3 is a perspective view of FIG. 2,
FIG. 4 is an exploded perspective view of the heat exchanger shown in FIG. 3,
5 is a front view of the heat exchanger,
6 is a sectional view taken along line AA in Fig. 5,
Fig. 7 is a sectional view taken along line BB of Fig. 5,
FIG. 8 is a plan view of the first water pipe module shown in FIG. 3,
Fig. 9 is a cross-sectional view taken along line CC of Fig. 8,
10 is a cross-sectional view taken along line DD of Fig. 8,
Fig. 11 is a sectional view taken along line EE of Fig. 8,
Fig. 12 is an exploded perspective view of the check valve shown in Fig. 11,
13 is a view showing a flow path of heating water in a heating mode in a boiler according to the present invention,
FIG. 14 is a view showing the number of heating water and the flow of direct / hot water in the hot water mode in the boiler according to the present invention,
15 is a view showing a flow path in which heating water is bypassed in order to prevent occurrence of overpressure when the heating water supply side of the boiler of the present invention or the heating pipe of the hot water heat exchanger side is closed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 3, a boiler according to an embodiment of the present invention includes an expansion tank 10 for storing heating water circulated through a boiler in a heating mode or heating water returned through a heating target in a heating mode A circulation pump 20 for feeding the heating water discharged from the expansion tank 10 in one direction and a main heat exchanger 30 for heating the heating water flowing through the circulation pump 20 by the combustion heat of the burner 30 A hot water heat exchanger 100 for supplying hot water by heat exchange between heated water and direct water heated in the main heat exchanger 30; and a hot water supply unit for supplying hot water supplied from the main heat exchanger 30 to the heating destination or the hot water heat exchanger A first water piping module 200 for providing a bypass path for returning via the hot water heat exchanger 100 and a bypass path for preventing overpressure in the heating pipe, And supplementation of heating water It is configured to include a second water pipe module 300 for providing a.

1 is a heating water main supply pipe in which the heating water heated in the main heat exchanger 30 is supplied to the three-way valve 210, and 'L2' is heated in the three-way valve 210 in the heating mode, 'L3' is a heating water return pipe through which the heating water passed through the heating destination is returned to the expansion tank (10), 'L4' is a heating water supply pipe through which the heating water discharged from the expansion tank (10) circulates 'L5' is a heating water circulation outlet pipe through which the heating water fed by the circulation pump 20 is supplied to the main heat exchanger 30, 'L6' is a heating water circulation inlet pipe supplied with the three- L7 denotes a heating water outlet pipe through which the heating water is joined to the heating water return pipe L3 in the hot water heat exchanger 100, Way valve 210 to the heating water return pipe L3 in order to prevent the overpressure state in the heating pipe 'L10' is a flow rate sensor that senses the flow of direct water, and a direct water inflow pipe that receives direct water from the flow rate sensor 310 to the hot water heat exchanger 100 'L11' is a hot water supply pipe through which the hot water heated by the hot water heat exchanger 100 is supplied to the hot water supplying source, and 'L12' flows into the expansion tank 10 through the direct water supply pipe L9 when the hot water is short Respectively.

3, in the present invention, the first water pipe module 200 and the second water pipe module 300 are constructed in units of modules and are detachably assembled to the hot water heat exchanger 100, And is configured to simplify the piping structure of the piping and the direct / hot water. The first water piping module 200 is connected to the first water piping module 200 through a heating water supply pipe L2 through a heating water main supply pipe L1 heated by the main heat exchange 30, Way valve 210 for switching the flow path of the hot water to selectively supply the hot water to the hot water heat exchanger 100 via the hot water inlet pipe L6, A heating water supply pipe L2 provided in the bypass pipe L8 and connected to the heating source or a heating water inlet pipe L2 connected to the hot water heat exchanger 100, The check valve 220 is provided to allow the fluid to flow only in one direction from the three-way valve 210 to the water heating water return pipe L3 when the overflow path is closed in the heating pipe.

The second water pipe module 300 includes a flow sensor 310 for sensing the flow of the direct water flowing through the direct water supply pipe L9 in the hot water mode, And a replenishing water valve 320 provided in a channel of the water replenishing pipe L12 for controlling the flow of the direct water.

4 to 7, the hot water heat exchanger 100 includes a plurality of plates 110, 120, 130-1, 140-1, 130-2, 140-2, 130-3, 140-3, 130-4, 140-4, 150 and 160 stacked thereon, And a plate-like heat exchanger in which a heating water passage (P1) and a direct water passage (P2) are separated from each other so that heat exchange is performed. In FIGS. 3 and 4, the solid line arrows represent the flow paths of the heating water, the dashed arrows represent the flow paths of the direct water and the hot water, and the heating water passage P1 and the direct water passage P2, Which are separated and formed alternately for each layer.

4, the plurality of plates 110, 120, 130-1, 140-1, 130-2, 140-2, 130-3, 140-3, 130-4, 140-4, 150 and 160 are laminated on the rear surface of the front plate 110, A first plate 130 (130-1, 130-2, 130-3, 130-4) and a second plate 140 (140-1, 140-2, 140-3, 140-4) are alternately stacked on the rear side of the plate 120. That is, the first plate 130-1, the second plate 140-1, the first plate 130-2, the second plate 140-2, the first plate 130-1, 130-3, a second plate 140-3, a first plate 130-4, and a second plate 140-4 are sequentially stacked. Although the first plate 130 and the second plate 140 are formed of four pairs of plates in the present embodiment, the first plate 130 and the second plate 140 may be stacked It goes without saying that the number may be configured differently.

A first flow path switching plate 150 for switching the hot water flow path from the rear to the front and a second flow path switching plate 160 for switching the flow path of the heating water from the rear to the front are stacked on the rear side.

The plurality of plates 110, 120, 130-1, 140-1, 130-2, 140-2, 130-3, 140-3, 130-4, 140-4, 150 and 160 are respectively formed in rectangular planar parts 110a, 120a, 130a, 140a, 150a, 160a, And the flange portions 110b, 120b, 130b, 140b, 150b and 160b protruding by a predetermined length from the flange portions 110b, 120b, 130b, 140b, 150b and 160b, And the adjacent plates are spaced apart from each other by a predetermined distance to form the heating water passage P1 and the direct water passage P2 while the fluid flowing through the heating water passage P1 and the direct water passage P2 flows outward Thereby preventing leakage.

The hot water heat exchanger 100 is provided with a heating unit 110 for heating the front plate 110 of the hot water heat exchanger 100 so that the first water pipe module 200 and the second water pipe module 300, The two-way flow path structures 110c and 110d, that is, the heating water discharge guide portion 110c and the hot water discharge guide portion 110d, which form the water discharge flow path and the hot water discharge flow path, are formed.

A heating water inflow hole 111 connected to the heating water inflow pipe L6 is formed at a lower side of the front plate 110 and a heating water inflow hole 111 is formed at one side of the heating water inflow hole 111, And the heating water discharge guide portion 110c is connected to the heating water passage P1 by way of the heating water passage P1 and then discharged toward the other side of the upper surface of the front plate 110 To the heating water discharge hole (112).

A water inlet hole 113 connected to the direct water inlet pipe L10 is formed on the lower side of the front plate 110 and a heating water outlet guide 110c is formed on the front plate 110 A hot water discharge hole 114 connected to the hot water supply pipe L11 is formed at a position close to the direct water inflow hole 113. The hot water discharge guide portion 110d passes through the direct water passage P2 And the hot water discharged forward toward one side of the upper surface of the front plate 110 is guided to the hot water discharge hole 114.

The flat plate 120 stacked on the rear side of the front plate 110 has a heating water inlet hole 121 formed at one side of the bottom plate and a heating water outlet hole 122 formed at the other side of the top plate 120, An inflow hole 123 is formed, and a hot water discharge hole 124 is formed on one side of the upper side. The edge portions of the heating water discharge guide portion 110c and the hot water discharge guide portion 100d are closely welded to the flat surface portion 120a of the flat plate 120 and welded to the hot water discharge guide portion 110c, The inner side of the rim of the discharge guide portion 100d protrudes forward to form the heating water and the hot water discharge passage.

The first plate 130 stacked on the rear side of the flat plate 120 is formed with a heating water inlet hole 131 at a lower side and a heating water outlet hole 132 at an upper side of the first plate 130, A direct water inflow hole 133 is formed, and a hot water discharge hole 134 is formed at an upper side. The heating water inflow hole 131 and the heating water discharge hole 132 of the first plate 130 protrude frontward and are connected to the heating water inflow hole 121 of the flat plate 120 and the heating water discharge hole Bosses 131a and 132a are formed in close contact with the rim of the first plate 130. A plurality of first beads 135 bent to one side are protruded forward from the flat surface 130a of the first plate 130 have.

The second plate 140 stacked on the rear side of the first plate 130 is formed with a heating water inlet hole 141 at a lower side and a heating water outlet hole 142 at an upper side of the second plate 140, And a hot water discharge hole 144 is formed on one side of the upper side. The first plate 130 and the second plate 140 protrude forward from the front and rear sides of the direct water inflow hole 143 and the hot water discharge hole 144, And a plurality of second beads 145 bent in a direction opposite to the first beads 135 are formed on the flat surface portion 140a of the second plate 140. The bosses 143a, Respectively.

The heating water flow path P1 and the direct water flow path P2 are formed by the bosses 131a and 132a formed on the first plate 130 and the bosses 143a and 144a formed on the second plate 140, And can be alternately formed. That is, the bosses 131a and 132a formed on the first plate 130 allow direct flow between the flat plate 120 and the first plate 130, but the flow of the heating water is blocked, P2 and the bosses 143a and 144a formed on the second plate 140 allow the flow of hot water between the first plate 130 and the second plate 140. However, And the heating water flow path P1 is formed.

When the first plate 130 and the second plate 140 are overlapped with each other, the first bead 135 formed on the first plate 130 and the second bead 145 formed on the second plate 140, And the heat exchange efficiency between the heating water and the direct water is improved by promoting the generation of turbulence in the flow of the fluid flowing through the overlapped clearance between the heating water and the direct water.

A plurality of first plate 130 and second plate 140 are alternately stacked and a first flow path switching plate 150 stacked on the rear side of a second plate 140-4 positioned in the last room, The heating water discharge hole 152 is formed on the other side of the upper part of the heating water inflow hole 151, and the other side and the upper side of the lower part are formed in a closed shape in the fore and aft direction, The direct flow path is switched from the direct flow path P2 between the flow path switching plates 150 toward the front. A plurality of first beads 155 are formed on the flat portion 150a of the first flow path switching plate 150 so as to be bent to one side and projecting forward.

The planar portion 160a of the second flow path switching plate 160 stacked on the rear side of the first flow path switching plate 150 is formed in a shape in which the entire area is blocked in the fore and aft direction and the first flow path switching plate 150 and the second The flow path of the heating water is switched from the heating water flow path P1 between the flow path switching plates 160 toward the front. A plurality of second beads 165 are formed on the flat portion 160a of the second flow path switching plate 160 and are bent toward the other side and projected forward.

According to the configuration of the above-described hot water heat exchanger 100, it is possible to heat the inside of the plurality of stacked plates 110, 120, 130-1, 140-1, 130-2, 140-2, 130-3, 140-3, 130-4, 140-4, The flow path P1 and the direct flow path P2 communicating from the lower side to the upper side are alternately formed and the fluid flowing through the overlapping gap between the first beads 135 and 155 and the second beads 145 and 165 It is possible to improve the heat exchange efficiency between the heating water and the direct water by promoting turbulent flow in the flow.

The front plate 110 is connected to a heating water discharge hole 112 formed adjacent to one side of the heating water inflow hole 111 for circulating the heating water discharged through the heating water passage P1, A discharge guide 110c and a hot water discharge guide 110d for guiding the hot water discharged after passing through the direct water passage P2 to the hot water discharge hole 114 formed at a position as close as possible to the direct water inflow hole 113 The first water pipe module 200 and the second water pipe module 300 can be easily attached to and detached from the hot water heat exchanger 100.

The distance between the heating water inlet pipe L6 connected to the hot water heat exchanger 100 and the heating water outlet pipe L7 is set to be close to the heating water inlet pipe L6 and the heating water outlet pipe L7 The size of the first water pipe module 200 coupled to the first water pipe module 200 can be reduced.

The distance between the direct water inflow pipe L10 connected to the hot water heat exchanger 100 and the hot water supply pipe L11 is made to be close to the second water inflow pipe L10, The size of the piping module 300 can be reduced.

In this case, the heating water inlet hole 111 and the heating water outlet hole 112 are formed at one side of the hot water heat exchanger 100, and the direct water inlet hole 113 and the hot water outlet hole 114 are connected to the heating water inlet The first water pipe module 200 and the second water pipe module 300 are formed at positions spaced apart from each other in the region where the holes 111 and the water discharging holes 112 are formed, And can be coupled to both sides.

Hereinafter, the flow path switching and bypass structure of the heating water provided in the first water pipe module 200 will be described in detail with reference to FIGS. 8 to 12. FIG.

The first water piping module 200 is connected to the heating water supply pipe L2 or the housing 201 connected to the lower side of the housing 201 by a flow path of heating water flowing from the heating water main supply pipe L1 connected to one side of the housing 201, Way valve 210 for selectively switching to a heating water inlet pipe L6 connected to the other side of the three-way valve 201 and a bypass pipe 210 connected to the side wall of the housing 201, And a check valve 220 is provided in the pipeline of the bypass pipe L8.

As described above, the housing 201 of the first water pipe module 200 is connected to the heating water main supply pipe L1, the heating water supply pipe L2, the heating water inflow pipe L6, and the bypass pipe L8, It is possible to construct the water piping structure of the heating water compactly and to shorten the pipeline length of the water piping compared to the structure in which the water piping is conventionally installed separately to reduce the pressure loss of the heating water, It is possible to improve the thermal efficiency.

The three-way valve 210 includes a motor 211, a cam member 212 coupled to the rotation shaft, a shaft 213 supported and supported by the cam member 212, An elastic member for applying an upward force to the shaft 213 so as to maintain a state in which the upper end of the shaft 213 is in contact with the lower end of the cam member 212, An upper stopping jaw 216a to which the upper end of the valve body 214 is hooked and a lower stopping jaw 216b to which the lower end of the valve body 214 is hooked is formed by the lifting and lowering of the shaft 213 And a valve seat 216 for selectively switching the flow path of the heating water flowing into the housing 201 through the heating water main supply pipe L1 to the heating water supply pipe L2 or the heating water inflow pipe L6 .

The bypass pipe L8 is formed so as to pass through the side wall of the housing 201 in the area between the upper stopping jaw 216a and the lower stopping jaw 216b of the valve seat 216 to be communicated with the heating water return pipe L3 do.

11 and 12, the check valve 220 includes a body 221 having an inlet 221a communicating with a bypass pipe L8 formed in a side wall of the housing 201, A valve body 222 which is composed of a shaft portion 222a and a valve portion 222b which are inserted into the inlet portion 221 and opens and closes the flow path of the heating water flowing through the inlet port 221a, An elastic member 223 provided around the valve element 222 to provide an elastic force to the valve part 222b in a direction of closing the flow path of the heating water and an insertion groove 224a to which the shaft part 222a of the valve element 222 is coupled, And a fastening part 224 formed in the body part 221 and fastened to the body part 221.

According to such a configuration of the check valve 220, only when the overpressure in the heating pipe occurs when the water pressure of the heating water flowing into the inlet port 221a of the body portion 221 exceeds the elastic force of the elastic member 223, The body 222 opens the flow path of the heating water so that the heating water flows through the bypass pipe L8 to the heating water return pipe L3 and the water pressure of the heating water is lower than the elastic force of the elastic member 223 The valve body 222 maintains the state in which the flow path of the heating water is closed.

Hereinafter, the heating mode and the hot water mode of the boiler and the heating water and the flow path of the hot water when the overpressure occurs will be described with reference to FIG. 13 to FIG.

13, in the heating mode, the heating water heated in the main heat exchanger 30 is supplied to the three-way valve 210 along the heating water main supply pipe L1. In this case, the three- Is closed to the pipe L6 side and opened to the heating water supply pipe L2 side so that the heating water passed through the three-way valve 210 is supplied to the heating destination along the heating water supply pipe L2. The heating water that has transferred heat via the heating source enters the expansion tank 10 through the heating water return pipe L3 and the heating water stored in the expansion tank 10 is heated by the operation of the circulation pump 20 Is supplied to the main heat exchanger (30) along the water circulation inlet pipe (L4) and the heating water circulation outlet pipe (L5), heated and circulated.

14, in the hot water mode, the heating water heated in the main heat exchanger 30 is supplied to the three-way valve 210 along the heating water main supply pipe L1. In this case, the three- And the heating water flowing through the three-way valve 210 is supplied to the hot water heat exchanger 100 along the heating water inlet pipe L6. The heating water that has transferred heat to the direct water from the hot water heat exchanger 100 flows into the expansion tank 10 along the heating water outlet pipe L7 and the heating water water return pipe L3, Is supplied to the main heat exchanger (30) along the heating water circulation inlet pipe (L4) and the heating water circulation outlet pipe (L5) by the operation of the circulation pump (20), heated and circulated.

At the same time, the direct water flowing through the direct water supply pipe L9 is supplied to the hot water heat exchanger 100 through the direct water inflow pipe L10 via the flow sensor 310, passes through the hot water heat exchanger 100, The hot water heated by the heat is supplied to the hot water source through the hot water supply pipe L11.

15, in the heating mode, the heating water supply pipe L2 connected to the heating destination in the three-way valve 210 is closed or the heating water supply pipe L2 connected to the hot water heat exchanger 100 side in the hot water mode, When the overflow pipe L6 is closed and overpressure is generated in the heating pipe, the check valve 220 provided in the pipe line of the bypass pipe L8 is opened and the three-way valve 210 Is allowed to flow into the expansion tank 10 through the bypass pipe L8 and the heating water return pipe L3 to release the overpressure state generated in the heating pipe. Therefore, it is possible to prevent breakage of the circulation pump 20 and other parts caused by overpressure in the heating pipe, thereby improving the durability.

Although the heat exchange between the hot water and the direct water is performed in the hot water heat exchanger 100 in the present specification, the hot water heat exchanger 100 may be applied to a case where heat exchange is performed between two different fluids other than water .

As described above, the present invention is not limited to the above-described embodiments, and various changes and modifications may be made without departing from the scope of the present invention as defined in the appended claims. And such modifications are within the scope of the present invention.

10: expansion tank 20: circulation pump
30: main heat exchanger 100: hot water heat exchanger
110: front plate
110a, 120a, 130a, 140a, 150a, 160a:
110b, 120b, 130b, 140b, 150b, 160b:
110c: Heating water discharge guide part 110d: Hot water discharge guide part
111, 121, 131, 141, 151:
131a, 132a, 143a, 144a, 151a, 161a:
112, 122, 132, 142, 152:
113,123,133,143: direct water inlet hole 114,124,134,144: hot water outlet hole
120: flat plate 130: first plate
135, 155: first bead 145, 165: second bead
140: second plate 150: first flow path switching plate
160: second flow path switching plate 200: first water piping module
201: housing 210: three-way valve
211: motor 212: cam member
213: shaft 214: valve body
215: elastic member 216: valve seat
216a, 216b: latching jaw 220: check valve
221: body portion 222: valve body
223: elastic member 224:
300: second water piping module 310: flow sensor
320: Replenishing water valve L1: Heating water main supply pipe
L2: Heating water supply pipe L3: Heating water supply pipe
L4: Heating water circulation inlet pipe L5: Heating water circulation outlet pipe
L6: Heating water inlet pipe L7: Heating water outlet pipe
L8: Bypass pipe L9: Direct supply pipe
L10: Direct water inlet pipe L11: Hot water supply pipe
L12: water supplement pipe P1: heating water flow channel
P2: Direct water flow

Claims (10)

A main heat exchanger (30) for heating the heating water by the combustion heat of the burner; and a hot water heat exchanger (100) for supplying hot water by heat exchange between the hot water heated by the main heat exchanger (30) ,
In the hot water heat exchanger 100, a plurality of plates are stacked, and the heating water flow path P1 and the direct water flow path P2 are separated from each other so that the heating water and the direct water alternately flow in the respective layers, Formed,
The front plate 110 located at the front of the plurality of plates is connected to a heating water inflow pipe L6 formed at a lower side of the front plate 110 to be heated A heating water discharge guide portion 110c for forming a flow path for the heating water so that the water discharge pipe L7 is located close to the heating water inlet pipe L6 and a direct water inflow A hot water discharge guide part 110d which forms a hot water flow path so that the hot water supply pipe L11 which is introduced into the pipe L10 after passing through the direct water flow path P2 is located close to the direct water inflow pipe L10, Lt; / RTI >
The heating water is supplied from the main heat exchanger (30) to the heating source or the hot water heat exchanger (30). The heating water inlet pipe (L6) and the heating water outlet pipe (L7) of the hot water heat exchanger A first water pipe module 200 for providing a flow path through which water is returned via the first water pipe module 100;
And a second water pipe which is assembled so that one side is connected to and disconnected from the direct water inlet pipe L10 and the hot water supply pipe L11 of the hot water heat exchanger 100 and which provides a direct water passing through the hot water heat exchanger 100, A module (300) comprising: a water pipe component having a modular assembly structure. The method according to claim 1,
A heating water inflow hole 111 connected to the heating water inflow pipe L6 is formed at a lower side of the front plate 110,
A heating water outlet hole 112 connected to the heating water outlet pipe L7 is formed at one side of the heating water inlet hole 111,
The heating water discharge guide part 110c is formed to guide the heating water discharged forward to the other side of the upper surface of the front plate 110 to the heating water discharge hole 112. [ Boiler having an assembled structure. 3. The method of claim 2,
A direct water inflow hole 113 connected to the direct water inflow pipe L10 is formed on the lower side of the front plate 110,
A hot water discharge hole 114 connected to the hot water supply pipe L11 is provided in the upper part of the front plate 110 at a position close to the direct water inflow hole 113 in an area where the heating water discharge guide part 110c is not formed, Is formed,
The hot water discharge guide part (110d) is formed to guide the hot water discharged forward toward one side of the upper surface of the front plate (110) to the hot water discharge hole (114). / RTI > The method of claim 3,
A heating water inlet hole 121 is formed at a lower side of the front plate 110 and a heating water outlet hole 122 is formed at the other side of the front plate 110. A direct water inlet hole 123 is formed on the other side And a flat plate 120 having a hot water discharge hole 124 formed on one side thereof,
The edge portion of the heating water discharge guide portion 110c and the hot water discharge guide portion 100d are in close contact with the edge of the flat plate 120 and the inner side portion of the edge portion protrudes forward, Wherein the water piping part has a modular assembly structure. 5. The method of claim 4,
A plurality of first plates 130 and a plurality of second plates 130 are formed in the rear of the flat plate 120 such that the bosses positioned in the diagonal direction cross each other such that the heating water channel P1 and the direct water channel P2 are alternately formed, Plates 140 are alternately stacked,
A plurality of first beads 135 and second beads 145 are formed in the first plate 130 and the second plate 140 in the opposite directions and the first beads 135 and the second beads 145, Wherein the bead (145) is configured to allow fluid to flow into the overlapping clearance. 6. The method of claim 5,
A first flow path switching plate (150) for switching the direct flow path from the rear to the front is provided at the rear of the second plate (140) stacked in the rearmost chamber so that the flow path of the heating water is forward And a second flow path switching plate (160) for switching between the first and second flow path switching plates are sequentially stacked. The method according to claim 6,
The first flow path switching plate 150 is formed with a heating water inflow hole 151 at a lower side and a heating air outlet hole 152 at an upper side of the first flow path switching plate 150. The other side and the upper side of the first flow path switching plate 150 are closed Lt; / RTI &
Wherein the second flow path switching plate (150) has a configuration in which the entire area is closed front and rear. The method according to claim 1,
In the first water pipe module 200,
The heating water supplied from the main heat exchange 30 through the heating water main supply pipe L1 is supplied to the heating destination through the heating water supply pipe L2 or the heating water supplied through the heating water inlet pipe L6 is supplied to the hot water heat exchanger Way valve (210) for switching the flow path of the heating water to selectively supply the water to the heating water supply side (100)
A bypass pipe L8 for connecting the three-way valve 210 to the heating water return pipe L3,
When a heating pipe connected to the heating water supply pipe (L2) or a heating pipe connected to the hot water heat exchanger (100) is closed to generate an overpressure in the duct of the bypass pipe (L8) And a check valve (220) is provided to allow fluid to flow only in one direction from the heating water return pipe (L3) to the heating water return pipe (L3). 9. The method of claim 8,
And a circulating pump (20) for feeding the heating water to the main heat exchanger (30) side in one direction is provided in the heating pipe connected to the heating water water return pipe (L3). / RTI > The method according to claim 1,
In the second water pipe module 300,
A flow sensor 310 for sensing the flow of the direct water flowing into the direct water inflow pipe L10, a water replenishment pipe L12 for receiving direct water at the time of insufficient heating water and supplementing the heating water, And a replenishing water valve (320) provided in a pipe of the pipe (L12) for controlling the flow of the direct water.

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