KR200324971Y1 - Processing Device for Condensation Water - Google Patents

Abstract

The present invention relates to a condensate treatment apparatus, and in the condensate treatment apparatus for recovering the condensate generated by the heat exchange operation of the heat exchanger using the steam supplied through the steam supply pipe from the boiler as a heat source in the condensate discharge pipe, a region An enclosed water collecting tank in which an inner space is connected to the heat exchanger through a condensate inlet pipe installed in the heat exchanger, and an inner space is exposed to the air through a collecting pipe provided in one region; The condensate discharge pipe is connected to the bottom portion, and connected to the water tank through the condensate guide pipe connected to form a straight line with the condensate discharge pipe, a low water level level sensor and a high water level level sensor is installed on the inner wall surface along the height direction, the high water level Sensor is installed on the support surface to maintain the altitude lower than the bottom surface of the sump, the internal space is exposed to the atmosphere through the pumping vent pipe installed on the upper surface, the internal space is a predetermined pumping drive steam through the pumping driving steam engine installed on the upper surface A closed pumping tank connected to a circle; A guide pipe check valve installed in the condensate guide pipe to form a one-way flow path from the water collection tank to the pumping tank; A steam pipe valve installed in the pumping drive engine so as to open and close the flow path of the pumping drive engine; A vent pipe valve installed at the pumping vent pipe to open and close the flow path of the pumping vent pipe; When the condensed water in the pumping tank reaches the high water level according to the detection signals from the low water level sensor and the high water level sensor, the flow path of the pumping vent pipe is closed and the flow path of the pumping driving steam engine is opened and the condensed water in the pumping tank is opened. And a valve control unit for controlling the steam pipe valve and the vent pipe valve so that the flow path of the pumping vent pipe is opened and the flow path of the pumping drive engine is closed when the water level is reached. As a result, the restriction of the collection tank installation area can be reduced, the condensate can be discharged efficiently, and the maintenance is easy.

Description

Processing Device for Condensation Water

The present invention relates to a condensate treatment apparatus, and more particularly, a heat exchanger of a heat exchanger interposed between a heat exchanger using a steam supplied from a boiler as a heat source and a condensate discharge tube (connected to a predetermined condensate storage tank). It relates to a condensate treatment apparatus for recovering the condensate generated by the operation and extruding the condensate discharge pipe.

In the case of a steam system that uses steam to raise the temperature of the heating element, the condensate generated when the heat exchange occurs between the steam and the heating element can be quickly removed to improve the efficiency of the steam system or to save energy or improve comfort. In order to create an environment, a condensate treatment device for recovering condensate is devised and used.

4 is a diagram illustrating a connection between a conventional condensate treatment device and a peripheral device, and FIG. 5 is a sectional view of a pumping tank of a conventional condensate treatment device, FIG. 5A is a sectional view when the rotor is at the lowest position, and FIG. Sectional view when the rotor is at the top.

The peripheral device of the conventional condensate treatment apparatus, as shown in Figure 4, is connected to the condensate storage tank (not shown) and the boiler 201 and the heat exchanger 203 interconnected through the heat exchange steam supply pipe 206 It has a condensate discharge pipe 205. The condensate discharge pipe 205 is provided with a ball valve 207. The ball valve 207 is for manually opening and closing the condensate flow path between the pumping tank 120 and the condensate storage tank (not shown) if necessary.

Conventional condensate treatment device having such a peripheral device, through the condensate inlet pipe 142 installed in one area through the condensate collection tank 111 and the condensate guide tube 141 connected to the heat exchanger 203. It has a sealed pumping tank 120 connected to the sump 111.

A collecting vent pipe 143 is formed on the upper surface of the collecting tank 111. The internal space of the collecting tank 111 is maintained at atmospheric pressure by the collecting vent pipe 143. And the sump 111 is provided with the overflow 149 of substantially "U" shape. The over flow 149 provides a path through which the condensed water collected in the sump 111 is discharged to the outside when the pumping tank 120 is stopped.

As illustrated in FIG. 5, the pumping tank 120 includes a support lever 161 on the tank housing 121 sealed by the cap 123 and a bracket 163 extending downward from the bottom of the cap 123. It has a float (160, Float) connected rotatably in the vertical direction through the (). A condensate discharge pipe 205 is connected to the bottom right side of the tank housing 121, and a condensate guide pipe 141 is connected to the condensate discharge pipe 205 on a bottom left side to form a straight line. The condensate guide tube 141 overcomes the load of the float 160 and the tensile repulsive force of the tension spring 144 which will be described later, and the suction head section H so that the condensed water stored in the sump 111 flows into the pumping tank 120. It is formed to have. The condensate guide pipe 141 is provided with a ball valve 146. The ball valve 146 is for manually opening and closing the condensate flow path between the water collecting tank 111 and the pumping tank 120 when necessary for cleaning.

The cap 123 is formed such that the exhaust hole 126 and the driving steam inlet hole 127 are adjacent to each other. A pumping vent pipe 144 is provided in the exhaust hole 126 of the cap 123, and a pumping drive steam engine 145 is provided in the driving steam inlet hole 127, respectively. Pumping vent pipe 144 is connected to the collection vent pipe 143, the pumping driving steam engine 145 is connected to the heat exchange steam supply pipe 206, respectively. The internal space of the pumping tank 120 is maintained at atmospheric pressure by the pumping vent pipe 144, and driving steam is introduced into the pumping tank 120 from the boiler 201 through the pumping driving engine 145.

The pumping tank 120 includes an air opening and closing operation unit 130 having an air opening and closing ball 133 disposed below the exhaust hole 126 and a steam opening and closing ball 134 disposed above the driving steam inlet hole 127. And an opening / closing drive link 140 for elevating the opening / closing operation unit 130 in accordance with the lifting operation of the float 160 via the opening / closing operation unit 130 and the support lever 161.

The opening and closing operation unit 130 is a semi-open valve housing 131, a guide plate coupled to the valve housing 131 so as to be parallel to the cap 123 and a pair of guide holes (not shown) are formed in the central area 132, and the air opening and closing ball 133 and the steam opening and closing ball 134 has a substantially depressed shaped lifting portion 135. The lifting unit 135 is coupled to the guide plate 132 so that the lifting unit 135 can move up and down along the guide hole (not shown) formed in the guide plate 132.

The opening and closing drive link 140 is a driven lever 131 and a connection ring 143 rotatably coupled to the coupling protrusion 147 formed at the bottom of the valve housing 131, respectively, and the bottom and the driven of the connection ring 143. It has a tension spring 144 connecting the free end region of the lever 131, and a driving lever 141 coupled to the connecting ring 143 and the support lever 161 so as to be rotatable, respectively. The lifting unit 135 is coupled to the central region of the driven lever 142.

Referring to the operation of the pumping tank 120 having such a configuration as follows.

In the initial state, when the float 160 is positioned at the lowest position, the connecting ring 143 and the driven lever 131 are connected to each other by upward tension due to the tension of the tension spring 144 (see FIG. 5A). At this time, the lifting unit 135 maintains the lowered state, and thus the driving steam inlet hole 127 is closed by the steam opening and closing ball 134 and the exhaust hole 126 is opened (see FIG. 5A).

As the float 160 rises from the bottom, the tension spring 144 gradually increases, and the connection ring 143 rotates clockwise with the coupling protrusion 147 as a supporting point. The extension spring 144 is extended, the float 160 is a critical position, that is, the connection point of the connection ring 143 and the tension spring 144 of the engaging projection 147 and the driven lever 131 and the tension spring 144 It continues until the position which rotates the connection ring 143 clockwise so that it may become in line with a connection point.

When the float 160 rises above the critical position, the connecting ring 143 and the driven lever 131 are connected to each other to form a downward slope in a short time by the compression force accumulated in the tension spring 144, and the lifting unit 135 ) Rises.

As the lifting unit 135 rises, the driving steam inlet hole 127 is opened, and the exhaust hole 126 is closed by the air opening and closing ball 133 (see FIG. 5B).

When the float 160 descends above the critical position and descends toward the critical position, the tensile force of the tension spring 144 accumulates, and the connecting ring 143 and the driven lever 131 continue to be inclined downward. At this time, the connection ring 143 rotates in the counterclockwise direction with the coupling protrusion 147 as a supporting point.

When the float 160 descends beyond the critical position, the connecting ring 143 and the driven lever 131 are connected to each other to form an upward inclination in a short time by the compression force accumulated in the tension spring 144, and the lifting unit 135 ) Descends.

As the lifting unit 135 descends, the driving steam inlet hole 127 is closed by the steam opening and closing ball 134 and the exhaust hole 126 is opened.

In addition, the conventional condensate treatment apparatus has a steam trap 148 connected to the pumping driving engine 145 and the collection tank 111 through a trap pipe 150. The steam trap 148 performs a valve function of guiding the condensate generated by the driving steam not supplied to the pumping tank 120 to the water collecting tank 111.

Referring to the operation of the conventional condensate treatment device having such a configuration as follows.

First, the condensate generated in the heat exchanger 203 is collected in the water collecting tank 111 and then flows into the pumping tank 120 through the condensate guide tube 141.

When the condensate is introduced into the pumping tank 120 and the level of the condensate reaches a critical position, the lift part 135 is raised. Accordingly, the exhaust hole 126 is closed and the driving steam inlet hole 127 is opened.

When the driving steam inlet hole 127 is opened and the driving steam is introduced into the pumping tank 120, the condensed water stored in the popping tank 120 is discharged through the condensate discharge pipe 205.

When the condensate is discharged through the condensate discharge pipe 205 and the level of the condensate stored in the pumping tank 120 reaches the critical position, the lifting unit 135 is lowered and the exhaust hole 126 is opened, thereby driving the steam inlet. 127 is closed.

As the exhaust hole 126 is opened, the inside of the pumping tank 120 again becomes atmospheric pressure, and condensate is introduced into the pumping tank 120 through the condensate guide tube 141 from the water collecting tank 111.

Thereafter, the condensate inflow into the pumping tank 120 and the condensate discharge through the condensate discharge pipe 205 are repeatedly performed in the same manner as described above.

By the way, according to the conventional condensate treatment apparatus, the condensate guide tube 141 to overcome the load of the float 160 and the tensile repulsive force of the tension spring 144 and the condensate stored in the water collecting tank 111 is introduced into the pumping tank 120 Since the suction head section (H) to be formed, there is a problem that the installation area of the water collecting tank 111 is limited.

As the contact between the driving steam inlet hole 127 and the steam opening and closing ball 133 is repeated, the sealing property of the driving steam inlet hole 127 is deteriorated, so that the driving steam inlet hole 127 is pumped in the closed state. Is introduced into the tank 120 there is a fear that the back pressure of the pumping tank 120 is increased. When the back pressure of the pumping tank 120 increases due to the abnormal inflow of the driving steam, the condensed water stored in the collection tank 111 cannot flow into the pumping tank 120 and thus loses its function as an apparatus.

In addition, since the lowering of the elevating part 135 is limited by the tension repulsive force of the tension spring 144 in addition to the back pressure applied to the inside of the pumping tank 120 from the condensate discharge pipe 205, the condensed water through the condensate discharge pipe 205. There was a problem that is not discharged efficiently. This problem becomes more serious as the height difference between the highest installation position of the condensate discharge pipe 205 and the installation position of the pumping tank 120 increases.

In addition, there is a problem that maintenance is difficult because mechanical elements (float, etc.) for opening and closing the exhaust hole 126 and the driving steam inlet hole 127 are installed in the pumping tank 120.

Therefore, an object of the present invention is to provide a condensate treatment apparatus that can reduce the restriction of the collection tank installation position, can efficiently discharge the condensate, and is easy to maintain.

1 is a connection diagram of a condensate treatment device and a peripheral device according to an embodiment of the present invention,

Figure 2 is a cross-sectional view of the pumping tank of the condensate treatment apparatus according to an embodiment of the present invention,

3 is a control block diagram of a condensate treatment device according to an embodiment of the present invention;

4 is a connection diagram of a conventional condensate and a peripheral device;

5 is a sectional view of a pumping tank of a conventional condensate treatment apparatus;

5A is a cross-sectional view when the rotor is at the lowest position,

Fig. 5B is a sectional view when the rotor is at the top.

Explanation of symbols on the main parts of the drawings

11, 111: sump tank 13: vent pipe valve

14: steam pipe valve 16: guide pipe check valve

17: discharge pipe check valve 20, 120: pumping tank

21, 121: tank housing 23, 123: cap

26, 126: exhaust hole 27, 127: driving steam inlet

28: low water level sensor 29: high water level sensor

30: valve control unit 41, 141: condensate guide tube

43, 143: collection vent pipe 48, 148: steam trap

130: opening and closing operation unit 135: lifting unit

140: opening and closing drive link 160: float

201: boiler 203: heat exchanger

The above object, according to the present invention, in the condensate treatment apparatus for recovering the condensate generated by the heat exchange operation of the heat exchanger using the steam supplied through the steam supply pipe from the boiler as a heat source and extruding the condensate discharge pipe, in one region An enclosed water collecting tank in which an inner space is connected to the heat exchanger through a condensate inlet pipe installed and the inner space is exposed to the air through a collecting pipe provided in one region; The condensate discharge pipe is connected to the bottom portion, and is connected to the water collection tank through a condensate guide tube installed to face the condensate discharge pipe, and a low water level sensor and a high water level level sensor are installed on the inner wall along the height direction, and the high water level sensor Is installed on the support surface to maintain a lower altitude than the bottom surface of the sump, the internal space is exposed to the atmosphere through the pumping vent pipe installed on the upper surface, the internal space is a predetermined pumping drive steam source through the pumping driving steam engine installed on the upper surface A closed pumping tank connected to the pump; A guide pipe check valve installed in the condensate guide pipe to form a one-way flow path from the water collection tank to the pumping tank; A steam pipe valve installed in the pumping drive engine so as to open and close the flow path of the pumping drive engine; A vent pipe valve installed at the pumping vent pipe to open and close the flow path of the pumping vent pipe; When the condensed water in the pumping tank reaches the high water level according to the detection signals from the low water level sensor and the high water level sensor, the flow path of the pumping vent pipe is closed and the flow path of the pumping driving steam engine is opened and the condensed water in the pumping tank is opened. When the pump reaches the low water level, the flow path of the pumping vent pipe is opened and the flow path of the pumping drive engine is achieved by a condensate treatment device comprising a valve control unit for controlling the steam pipe valve and the vent pipe valve.

Here, the steam pipe valve and the vent pipe valve may be configured as a solenoid valve.

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

1 is a connection diagram of a condensate treatment apparatus and a peripheral device according to an embodiment of the present invention, Figure 2 is a cross-sectional view of the pumping tank of the condensate treatment apparatus according to an embodiment of the present invention, Figure 3 is an embodiment of the present invention The control block diagram of the condensate treatment apparatus according to.

The peripheral device of the condensate treatment apparatus according to the embodiment of the present invention, as shown in Figure 1, the boiler 201 and the heat exchanger 203 interconnected via the heat exchange steam supply pipe 206, and the condensate storage tank (shown) And a condensate discharge pipe 205 connected thereto. The condensate discharge pipe 205 is provided with a ball valve 207. The ball valve 207 is for manually opening and closing the condensate flow path between the pumping tank 20 and the condensate storage tank (not shown), if necessary.

Condensate treatment apparatus according to an embodiment of the present invention having the above-described peripheral device, as shown in Figure 1, through the condensate inlet pipe 42 is installed in one area of the sealed type connected to the heat exchanger 203 It has a collection tank 11 and a sealed pumping tank 20 connected to the collection tank 11 through the condensate guide tube 41.

A collecting vent pipe 43 is formed on the upper surface of the collecting tank 11. The internal space of the collecting tank 11 is maintained at atmospheric pressure by the collecting vent pipe 43. The water collecting tank 11 is provided with an overflow 49 having a substantially "U" shape. The overflow 49 provides a path through which the condensed water collected in the sump 11 is discharged to the outside when the pumping tank 20 is stopped.

The pumping tank 20 is composed of a tank housing 21 and a cap 23 coupled to the upper portion of the tank housing 21. A condensate discharge pipe 205 is connected to the bottom right side of the tank housing 21, and a condensate guide pipe 41 is connected to the condensate discharge pipe 205 in a straight line at the bottom left side. On the inner wall of the pumping tank 20, a low water level sensor 28 and a high water level sensor 29 are provided along the height direction, and the cap 23 has an exhaust hole 26 and a driving steam inlet hole 27. Formed. A pumping vent pipe 44 is provided in the exhaust hole 26, and a pumping drive steam engine 45 is provided in the driving steam inlet hole 27, respectively. The internal space of the pumping tank 20 is maintained at atmospheric pressure by the pumping vent pipe 44, and the driving steam flows into the interior of the funnel tank from the boiler 201 through the pumping driving steam engine 45. The pumping tank 20 having such a configuration is provided on the support surface (bottom surface) such that the high water level sensor 29 maintains a lower altitude than the bottom surface of the water collecting tank 11.

And the condensate treatment apparatus according to an embodiment of the present invention is a guide pipe check valve 16 and the discharge pipe check valve 17 is installed in the end region of the condensate guide pipe 41 and the start region of the condensate discharge pipe 205, and In accordance with the detection signals from the steam pipe valve 14 and the vent pipe valve 13 and the low water level sensor 28 and the high water level sensor 29 respectively provided in the pumping drive engine 45 and the pumping vent pipe 44. The valve control part 30 which controls the opening / closing operation | movement of the steam pipe valve 14 and the vent pipe valve 13 is provided.

The one-way flow path from the collection tank 11 to the pumping tank 20 is formed by the guide pipe check valve 16 and the one-way flow path from the pumping tank 20 to the condensate discharge pipe 205 is formed by the discharge pipe check valve 17. do.

The pumping vent pipe 44 is connected to the collecting vent pipe 43, and the pumping driving steam pipe 45 is connected to the heat exchange steam supply pipe 206, respectively.

The condensate guide tube 41 is provided with a ball valve 46. The ball valve 46 is for manually opening and closing the condensed water flow path between the water collecting tank 11 and the pumping tank 20 when necessary for cleaning.

The steam pipe valve 14 and the vent pipe valve 13 may be implemented using a valve capable of performing an opening and closing operation by itself according to a control signal input from the outside such as a conventionally known solenoid valve.

The valve control unit 30 controls the steam pipe valve 14 and the vent pipe valve so that the flow path of the pumping vent pipe 44 is opened and the flow path of the pumping drive engine 45 is closed when a detection signal is input from the low water level sensor 28. (13), and when the detection signal is input from the high water level sensor 29, the flow path of the pumping vent pipe 44 is closed, and the valve drive unit 31 is driven to open the flow path of the pumping drive engine 45 The steam pipe valve 14 and the vent pipe valve 13 are controlled (see Fig. 3). The valve driving voltage power source 33 is connected to the valve driving unit 31.

And the condensate treatment apparatus according to an embodiment of the present invention has a steam trap 48 is connected to the pumping drive engine 45 and the collection tank 11 through the trap pipe 50. The steam trap 48 performs a valve function of guiding the condensate generated by the driving steam not supplied to the pumping tank 20 to the water collecting tank 11.

Referring to the operation of the condensate treatment apparatus according to an embodiment of the present invention having such a configuration as follows.

First, the condensate generated in the heat exchanger 203 is collected in the water collecting tank 11 and then flows into the pumping tank 20 through the condensate guide tube 41.

When the inflow of condensate into the pumping tank 20 progresses and the water level of the condensate reaches the installation position of the high water level sensor 29, the valve control unit 30 pumps the vent pipe 44 according to a detection signal from the high water level sensor 29. ) Control the steam pipe valve 14 and the vent pipe valve 13 to be closed and the flow path of the pumping drive engine 45 is open.

When the steam pipe valve 14 is opened and the driving steam flows into the pumping tank 20, the condensed water stored in the pumping tank 20 is discharged through the condensed water discharge pipe 205.

When condensate is discharged through the condensate discharge pipe 205 and the water level of the condensate stored in the pumping tank 20 reaches the installation position of the low water level sensor 28, the valve control unit 30 detects from the low water level sensor 28. In response to the signal, the flow path of the pumping vent pipe 44 is opened and the flow path of the pumping drive engine 45 is controlled to control the steam pipe valve 14 and the vent pipe valve 13.

As the vent pipe valve 13 is opened, the inside of the pumping tank 20 is again at atmospheric pressure, and condensate is introduced into the pumping tank 20 through the condensate guide tube 41 from the water collecting tank 11.

Thereafter, the condensate inflow into the pumping tank 20 and the condensate discharge through the condensate discharge pipe 205 are repeatedly performed in the same manner as described above.

According to the embodiment of the present invention as described above, the low water level sensor 28 and the high water level sensor 29 is installed in the pumping tank 20 and the driving steam supply pipe 45 and the pumping vent pipe 44 The vent pipe valve 13 and the steam pipe valve 14 are respectively provided to selectively open and close the flow paths of the pumping vent pipe 44 and the steam pipe valve 14 according to the detection signals of the sensors 28 and 29. It is not necessary to form a suction head section in the pipe 41, the pumping vent pipe 44 can be opened regardless of the back pressure applied to the inside of the pumping tank 20 from the condensate discharge pipe 205 side, the pumping tank It is possible to reduce the number of mechanical elements installed in the interior of the 20. In addition, since the sealing property of the driving steam inlet 27 can be stably maintained, an increase in the back pressure of the pumping tank 20 due to abnormal inflow of the driving steam can be prevented.

Therefore, according to the present invention, it is possible to reduce the limitation of the collection tank installation area, to efficiently discharge condensate, and to facilitate maintenance.

Claims (2)

In the condensate treatment apparatus for recovering the condensate generated by the heat exchange operation of the heat exchanger using the steam supplied through the steam supply pipe from the boiler as a heat source and extruding the condensate discharge pipe, An airtight collection tank in which an internal space is connected to the heat exchanger through a condensate inlet pipe installed in one region, and the internal space is exposed to the atmosphere through a water collecting vent pipe installed in one region; The condensate discharge pipe is connected to the bottom portion, is connected to the water tank through the condensate guide pipe installed to face the condensate discharge pipe, a low water level sensor and a high water level sensor is installed on the inner wall along the height direction, the high water level sensor Is installed on the support surface to maintain a lower altitude than the bottom surface of the sump, the internal space is exposed to the atmosphere through the pumping vent pipe installed on the upper surface, the internal space is a predetermined pumping drive steam source through the pumping driving steam engine installed on the upper surface A closed pumping tank connected to the pump; A guide pipe check valve installed in the condensate guide pipe to form a one-way flow path from the water collection tank to the pumping tank; A steam pipe valve installed in the pumping drive engine so as to open and close the flow path of the pumping drive engine; A vent pipe valve installed at the pumping vent pipe to open and close the flow path of the pumping vent pipe; When the condensed water in the pumping tank reaches the high water level according to the detection signals from the low water level sensor and the high water level sensor, the flow path of the pumping vent pipe is closed and the flow path of the pumping driving steam engine is opened and the condensed water in the pumping tank is opened. And a valve control unit controlling the steam pipe valve and the vent pipe valve so that the flow path of the pumping vent pipe is opened and the flow path of the pumping drive engine is closed when the low water level is reached. The method of claim 1, The steam pipe valve and the vent pipe valve is a condensate treatment device, characterized in that the solenoid valve.