KR101960156B1 - Condensate and steam recovery system of closed circuit circulation steam boiler - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a condensate water and steam recovery apparatus for a closed circuit circulation type steam boiler for recovering and recycling condensed water generated by heat exchange of high temperature and high pressure steam generated in a closed circuit circulation type steam boiler for heating water , It is possible to circulate the condensed water and saturated steam generated by the heat exchange in the heat exchanger without discharging the saturated steam of high temperature and high pressure to the inside of the condensate water collection tank while circulating the condensed water in the condensed water collection tank, will be.
To this end, the present invention provides a condensate water and steam recovery apparatus for a closed circuit circulation type steam boiler, comprising: a condensate water collection unit for collecting condensate water (52) generated by heat exchange in the heat exchanger (61) A pump 53 for pumping condensed water 52 collected in the condensed water vortex tank 71 and both ends connected to the suction side of the condensed water vortex tank 71 and the pump 53 A condensate circulation suction pipe 54 for transferring the condensed water 52 in the condensate water collection tank 71 to the pump 53 side and a condenser water circulation suction pipe 54 connected at both ends to the discharge side of the pump 53 and the condensate water collection tank 71, A condensate circulation discharge pipe 55 for sucking the condensed water 52 in the condensate water collection tank 71 through the condensed water circulation suction pipe 54 and discharging it to the condensed water collection tank 71 side in accordance with the driving of the condensate water collection tank 71, The condensed water 52, which is installed on the circulation discharge pipe 55, (TVR) 56 for reducing the pressure when passing through the tubular pipe 561 and the condensed water 52 connected to the thermal vapor recompression booster 56 and generated in the heat exchanger 61, And a saturated vapor recovery pipe (62) for allowing the saturated vapor to be forcedly sucked by the falling pressure as it passes through the thermal vapor recompression booster (56), and a condenser and a saturated vapor recovery pipe And a temperature sensor (63) for controlling the driving of the pump,
The inside of the condensate water collection tank 71 is partitioned into an upper tank 71a and a lower tank 71b by partition walls 73 to connect a condensate circulation suction pipe 54 to the upper tank 71a, 52 for reducing the pressure of the condensate water circulating and discharging pipe 56 extends to the inside of the condensate water collection tank 71 so as to be located inside the condensed water collection tank 71, The condensed water and the saturated vapor recovery pipe 62 in which the condensed water and the saturated steam are recovered to the thermal vapor recompression booster 56 are placed in the lower tank 71b and are discharged through the other condensate and saturated vapor recovery pipes 62a, The condensed water 52 and the saturated steam recovered to the boiler 71b are supplied to the boiler 51,
The condensed water circulation suction pipes 54 and 54a are connected to both sides of the condensate water collection tank 71 and the condensed water circulation discharge pipes 55 and 55a are connected to both sides of the discharge side of the pump 53, The heat vapor recompression boosters 56a and 56a having different inner diameters of the venturi pipes 561 and 561a are installed in the discharge pipes 55 and 55a and condensed water collection pipes 55 and 55a are provided through the respective condensate circulation discharge pipes 55 and 55a. And the condensed water and the saturated vapor having different pressures are collected to the tank 71 side.

Description

[0001] DESCRIPTION [0002] COUPLED WATER AND VAPOR RECOVERY APPARATUS FOR A CIRCUIT CIRCULATING STEAM BOILER

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a condensate water and steam recovery apparatus for a closed circuit circulation type steam boiler for recovering and recycling condensed water generated by heat exchange of high temperature and high pressure steam generated in a closed circuit circulation type steam boiler for heating water More specifically, without discharging high-temperature and high-pressure saturated steam to the outside, saturated steam and condensed water generated by heat exchange in the heat exchanger are recovered into the condensate water collection tank while circulating the condensed water in the condensate collection tank, To a condensed water and steam recovery device of a closed loop circulating steam boiler.

Generally, high-pressure steam obtained by heating water is widely used in various fields such as indoor heating, laundry, sewing factory, kitchen, etc. Such steam is usually obtained by a steam boiler.

FIG. 1 is a longitudinal sectional view showing a main portion of a conventional apparatus (Patent No. 613397), in which a steam supply pipe 3 is installed on an upper part of a boiler 1, and a heat exchanger 4 is connected to an end of the steam supply pipe 3 And a condensate return pipe 5 connected to the other end of the heat exchanger for recovering condensed water generated in the heat exchanger by the steam 22 in the heat exchanger. At this time, a trap 6 is disposed on the condensate return pipe Is installed.

A condensate water collection tank 8 having a float switch 7 is connected to an end of a condensate water recovery pipe 5 and a condensate water collection tank 8 is connected to a condensate water collection tank 8 on a connection pipe 9 connected to one side of the condensed water collection tank. The float switch 7 detects that the water level is equal to or higher than the set water level and operates the motor 10 to drive the condensate water collection pump 12 for feeding the condensed water in the condensate water collection tank 8 to the replenishment water tank 11 side A check valve 14 is provided on the connection pipe 9 to prevent the condensed water 13 in the condensed water collection tank 11 from flowing back to the condensed water collection tank 8 side.

A supplementary water tank 11 for supplying the condensed water 13 recovered through the connection pipe 9 to the inside of the boiler 1 is connected to one side of the boiler 1 at a side of the boiler 1, And an automatic level detecting sensor 15 is installed on one side of the boiler 1 for detecting the level of the condensed water 13 located inside the boiler.

A compressed air supply pipe 16 is connected to an upper portion of the replenishing water tank 11 provided at one side of the boiler 1 without a difference in head between the boiler 1 and the replenishing water tank 11 And a compressor 19 for generating compressed air 18 by driving the automatic pressure regulating switch 17 installed in the automatic pressure regulating switch 17 on the basis of the sensed pressure being below the set pressure.

The condensed water in the replenishing water tank 11 is supplied to another boiler (not shown) on the condensed water supply pipe 20 for supplying the condensed water 13 in the replenishing water tank 11 to the inside of the boiler 1 A preliminary valve 21 is provided for branching so as to be as small as possible.

Accordingly, the steam 22 generated when the steam 22 is generated by the operation of the boiler 1 is supplied to the heat exchanger 4 along the steam supply pipe 3 to perform heating, and a part of the steam is supplied to a separate steam pipe Lt; / RTI >

In this process, when the steam is changed into the condensed water 13 by heat exchange, the wet steam is removed from the trap 6 in the process of being recovered to the condensate water collection tank 8 side through the condensed water recovery pipe 5.

When the condensed water 13 is filled in the condensate water collection tank 8 and the float switch 7 senses that the float switch 7 is at the set water level or higher, the power is automatically applied to the motor 10 to operate the condensate water collection pump 12, The condensed water 13 is recovered to the side of the make-up water tank 11 via the connection pipe 9. [

After the condensed water 13 is recovered to the makeup water tank 11, the high pressure compressed air (higher than the steam pressure in the boiler) generated by driving the compressor 19 is supplied to the upper portion of the makeup water tank 11, The compressor 19 is driven by the automatic pressure regulating switch 17 provided on the upper part of the replenishing water tank 11 and the pressure in the replenishing water tank 11 is detected by the boiler 1 If the pressure in the make-up water tank 11 becomes lower than the steam pressure in the boiler 1 due to the supply of the condensed water, the automatic pressure control switch 17 replenishes the boil- The pressure in the make-up water tank 11 is always higher than the vapor pressure in the boiler 1 since the compressor 19 is restarted until the pressure in the water tank 11 is detected to be higher than the steam pressure in the boiler 1 State.

When the automatic level detecting sensor 15 detects that the level of the condensed water 13 in the boiler is lower than the predetermined level due to the continuous operation of the boiler 1 in this state, the electromagnetic valve 23 provided on the condensed water supply pipe 20 The condensed water in the replenishing water tank 11 is introduced into the boiler 1. At this time, even if the water level of the replenishing water tank 11 is kept lower than the water level of the boiler 1 located at one side, Since the pressure of the compressed air higher than the steam pressure in the boiler 1 is applied to the upper portion of the tank 11, the condensed water in the makeup water tank 11 is filled in the boiler 1 through the condensed water supply pipe 20.

Korean Registered Patent No. 10-613397 (Registered on August, 2006)

However, in this conventional apparatus, unless the humid vapors contained in the condensed water are removed, the pressure in the condensed water pipe 5 is high and the condensed water 13 is not collected by the condensed water vortex tank 8 side due to gravity. An expensive trap 24 for removing humid vapors contained in the condensed water 13 must be provided on the evaporator 5.

However, even if an expensive trap is installed, components constituting the trap are corroded by impurities contained in high-temperature, high-pressure condensed water or condensed water, so that high-temperature and high-pressure condensed water and steam escape to the outside. And there was a problem in use.

In the No trap type, which does not use a trap, high-temperature and high-pressure steam is discharged to the atmosphere to reduce the pressure in the condensate water collection tank, thereby recovering the condensed water generated in the heat exchanger to the condensate collection tank side.

However, as the system forcibly drops the pressure of the condensate reservoir tank, the condensed water generated in the heat exchanger is smoothly recovered to the condensate reservoir tank side. However, if the pressure inside the condensate reservoir tank or the condensate water pipe is lowered due to the defect of the steam supply pipe or the condensate pipe, The condensate is present as condensate in the condensate reservoir tank at normal pressure, but when the pressure of the condensate reservoir tank falls below the set pressure, the condensate inside the condensate reservoir tank begins to vaporize and the water level is rapidly reduced. That is, the condensed water evaporates to a temperature at which it exists as water and is reduced.

As the pressure in the condensate water collection tank drops below the set pressure and the condensate water level is reduced, when the pump is driven and the condensed water is pumped, cavitation damage is generated in the pump, resulting in a fatal result that the motor of the pump is burned out .

Therefore, the condensate reservoir tank is designed to be higher than necessary because the low water level of the condensate reservoir tank must be set higher than necessary to prevent cavitation damage to the pump.

SUMMARY OF THE INVENTION The present invention has been made in order to overcome the above-mentioned problems, and it is an object of the present invention to dramatically improve the structure and to circulate the condensed water recovered to the condensed water collection tank by the pump while maintaining the internal pressure of the entire piping, It is an object of the present invention to recover condensed water and saturated steam generated by heat exchange in a heat exchanger by a vacuum pressure generated by using a thermo-vapor recompression (TVR) and re-supply it to a boiler.

Another object of the present invention is to discharge the high-pressure saturated steam contained in the condensed water to the outside, thereby recovering the condensed water together with the condensed water without reducing the pressure, thereby greatly reducing the cost of operating the boiler.

According to an aspect of the present invention, there is provided a condensate water and vapor recovery apparatus for a closed circuit circulation type steam boiler, comprising: a condensate water collection tank for collecting condensed water and saturated steam generated by heat exchange in a heat exchanger, A pump for pumping condensed water collected inside the condensate water collection tank, a condensate water circulation suction pipe connected to the suction side of the condensed water collection tank and the pump so as to transfer the condensed water in the condensed water collection tank to the pump side, A condensate circulating and discharging pipe connected to both ends of the condensate collection vat tank and connected to both ends of the condensate collection vat tank so that the condensed water in the condensate vat tank is sucked through the condensate circulation suction pipe and discharged again to the condensate collection vat tank; When the condensate passes through the Venturi tube, it releases the pressure (TVR) connected to the thermal vapor recompression booster, condensed water and saturated steam generated by the heat exchanger, and saturated steam, which is forced to be sucked by the falling pressure as it passes through the thermal vapor recompression booster And a temperature sensor installed in the condensed water and saturated vapor recovery pipe for sensing the temperature and controlling the operation of the pump by the control unit, wherein the condensate water collection tank is partitioned into an upper tank and a lower tank by partition walls A heat vapor recompression booster for connecting the condensate circulation suction pipe to the upper tank and lowering the pressure of the circulating condensate water is disposed inside the condensate water collection tank by extending the condensed water circulation discharge pipe to the inside of the condensate water collection tank, Condensate and saturated steam recovery tubes, where condensate and saturated steam are recovered by thermal vapor recompression booster, The condensate and the saturated steam recovered to the lower tank through another condensate and saturated steam recovery pipe are supplied to the boiler so as to be located in the tank and the condensate circulation suction pipe is connected to both sides of the condensate collection tank, The condensate circulation discharge pipe is connected to each condensate circulation discharge pipe, and a heat vapor recompression booster having a different inner diameter of the venturi pipe is installed in each of the condensate circulation discharge pipes, and the condensed water and the saturated steam recovered from the condensate water collection tank side through the respective condensate circulation discharge pipes And a condenser for condensing the condensed water and the steam.

The present invention has various advantages as compared to the prior art.

First, the condensed water is recovered to the condensate collection tank together with the condensed water without reducing the pressure of the saturated steam, which is heat-exchanged in the heat exchanger, and is re-supplied to the boiler, thereby maximizing thermal efficiency.

Second, since expensive trap for reducing the pressure of saturated steam is not used, it is possible to reduce the construction cost of the closed circuit circulation type steam boiler, and it is not necessary to periodically replace the trap.

Third, it is economical because one pump can recover saturated steam and condensed water that are heat-exchanged in two heat exchangers using different steam at different operating pressures.

Fourth, when the thermal vapor recompression booster is installed inside the condensate collection tank, the thermal booster decompression booster is prevented from being damaged by the external force, so it is easy to manage.

Fig. 1 is a longitudinal sectional view showing a main portion of a conventional apparatus, Patent No. 613397
2 is a block diagram showing another conventional embodiment
3 is a schematic view of a condensate and vapor recovery apparatus of a closed circuit circulation type steam boiler provided with the present invention
4 is a longitudinal sectional view showing a first embodiment of the present invention
Fig. 5 is a plan view of Fig. 4
6 is a plan view showing a second embodiment of the present invention.
7 is a longitudinal sectional view showing a third embodiment of the present invention
8 is a longitudinal sectional view showing a fourth embodiment of the present invention
9 is a longitudinal sectional view showing a fifth embodiment of the present invention

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described herein. The drawings are schematic and illustrate that they are not drawn to scale. The relative dimensions and ratios of the parts in the figures are shown exaggerated or reduced in size for clarity and convenience in the figures, and any dimensions are merely illustrative and not restrictive. And to the same structure, element or component appearing in more than one drawing, the same reference numerals are used to denote similar features.

FIG. 3 is a structural view of a condensed water and steam recovery apparatus of a closed circuit circulation type steam boiler provided with the present invention, FIG. 4 is a longitudinal sectional view showing the first embodiment of the present invention, and FIG. 5 is a plan view of FIG. The condensed water 52 collected in the heat exchanger 61 and the condensed water 52 collected in the condensed water vortex tank 71 at one side of the condensed water vortex tank 71 for recovering the saturated steam and supplying it to the boiler 51 side, And a condensate circulation suction pipe (not shown) for transferring the condensed water 52 in the condensed water collection tank 71 to the pump 53 side is provided on the suction side of the condensed water collection tank 71 and the pump 53 54 are connected to both ends of the pump 53 and the condensed water in the condensed water collection tank 71 is connected to the condensed water circulation suction pipe 54 in the condensed water collection tank 71, And is again sucked into the condensate collection tank 71 side And a condensate circulating and discharging pipe 55 for discharging the condensed water.

A thermo vapor recompression (TVR) 56 for reducing the pressure of the condensed water 52 when the condensed water 52 passes through the venturi tube 561 is installed on the condensate circulation discharge pipe 55 And the thermal vapor recompression booster 56 is provided with condensed water 52 and saturated vapor generated by the heat exchanger 61 and forced to be sucked by the pressure dropped while passing through the thermal vapor recompression booster 56, And a temperature sensor 63 for controlling the driving of the pump 53 by a control unit (not shown) is installed in the condensed water and saturated steam recovery pipe 62. The temperature sensor 63 is connected to the steam recovery pipe 62, .

The temperature sensor 63 detects the temperature of the saturated steam and the condensed water 52 generated in the heat exchanger 61 and drives the pump 53 by a control unit (not shown) The operation of the pump 53 is stopped.

At this time, a condensate water 52 and a check valve 72 for supplying saturated steam to the boiler 51 are installed on the discharge side of the condensate water collection tank 71 as shown in FIG. 4 to set the pressure in the condensate water collection tank 71 The condensed water 52 and the saturated steam may be automatically supplied to the boiler 51 side only when the pressure rises above the pressure.

Accordingly, even if the driving of the pump 53 is temporarily stopped, it is possible to prevent the condensed water and the saturated steam from flowing back to the condensed water collection tank 71 side.

A thermal vapor recompression booster (TVR) 56 installed on the condensate circulation discharge pipe 55 for dropping the pressure when the condensed water 52 passes through the venturi pipe 561 is provided as a first embodiment of the present invention 6, which is shown in FIG. 4, the second embodiment, and FIG. 8, which is shown in the fourth embodiment, may be provided on the condensate circulation discharge pipe 55 located outside the condensate water collection tank 71, The thermal vapor recompression booster 56 is installed inside the condensate vowel tank 71 and the thermal vapor recompression booster 56 is installed in the condensate vowel tank 71 as in the third embodiment of the present invention. The condensed water and the saturated steam recovery pipe 62 installed to penetrate into the inside may be connected.

As in the fifth embodiment of the present invention, the interior of the condensate water collection tank 71 is divided into an upper tank 71a and a lower tank 71b by partition walls 73, and the condensed water is circulated in the upper tank 71a. The heat vapor recompression booster 56 for connecting the suction pipe 54 and dropping the pressure of the circulating condensate 52 extends the condensate circulation discharge pipe 55 to the inside of the condensate water collection tank 71, And the condensed water and the saturated vapor recovery pipe 62 in which the condensed water and the saturated steam are recovered to the thermal vapor recompression booster 56 and the saturated vapor recovery pipe 62 are positioned in the lower tank 71b, It is understandable that the condensed water 52 and the saturated steam recovered to the lower tank 71b through the saturated steam recovery pipe 62a may be supplied to the boiler 51 again.

Since the thermal vapor recompression booster 56 is located inside the condensate water collection tank 71 as described above, there is no fear of being damaged by an external impact, which is advantageous in management.

As shown in FIG. 4, the condensate circulation suction pipe 54 is extended inside the condensate water collection tank 71. A plurality of suction holes 54 are formed in the bottom of the condensed water circulation suction pipe 54 located inside the condensed water collection tank 71, A hole 541 is formed.

The reason why the plurality of suction holes 541 are formed on the bottom surface of the condensed water circulation suction pipe 54 is that even if the pump 53 pumps the condensed water 52 collected in the condensed water collection tank 71 to the low water level, A portion of the steam in the tank 71 is prevented from flowing into the pump 53 side so that cavitation damage is not generated in the pump 53. [

6 is a plan view showing a second embodiment of the present invention in which condensate circulation suction pipes 54 and 54a are connected to both sides of the condensate water collection tank 71 and condensed water circulation pipes 54 and 54a are connected to the discharge side of the pump 53, The heat pipes 56 and 56a having different inner diameters of the venturi pipes 561 and 561a are installed in the respective condensate circulation discharge pipes 55 and 55a while the discharge pipes 55 and 55a are connected to each other, This is because the steam generated in one boiler (51) is supplied to two heat exchangers having different working pressures, so that even if condensed water and saturated steam having different pressures are generated, each condensate circulation discharge pipe 55) 55a to the condensate water collection tank 71 side.

Therefore, on the side where the heat vapor recompression booster 56 provided with the venturi tube 561 having a large inner diameter is installed, the saturated steam and the condensed water 52 with high pressure are recovered and, on the contrary, The side on which the recompression booster 56a is installed recovers the low pressure saturated steam and condensed water 52.

Reference numeral 74 denotes a steam supply pipe for supplying the steam generated in the boiler to the heat exchanger. Reference numeral 75 denotes a makeup water tank for replenishing water to the boiler. Reference numeral 76 denotes a pump for pumping the makeup water in the makeup tank. And reference numeral 77 denotes a makeup water supply line.

The operation of the present invention will be described below.

First, when the high-temperature and high-pressure steam generated in the boiler 51 is supplied to the heat exchanger 61 and heat exchanged, the steam is changed into saturated steam and the condensed water 52 is generated.

The saturated steam and the condensed water 52 generated when the saturated steam and the condensed water 52 are generated in the heat exchanger 61 are recovered into the condensed water collection tank 71 by the driving of the pump 53.

That is, when the pump 53 is driven by the control unit due to the detection of the temperature sensor 63 in the process of heat exchange of the high temperature and high pressure steam generated in the boiler 51 by the heat exchanger 61, The condensed water 52 flows into the condensed water collection tank 71 through the condensed water circulation and discharge pipe 55. [

Accordingly, the condensed water 52 is fed by the rotation of the impeller (not shown) according to the driving of the pump 53 and is supplied to the venturi pipe (not shown) of the heat vapor compression apparatus 50 provided on the condensate water circulation pipe 55 The internal pressure of the heat vapor recompression booster 56 is lowered so that the saturated steam and the condensed water 52 generated in the heat exchanger 61 are condensed through the condensed water and the saturated steam return pipe 62, Is introduced into the venturi pipe 561 of the compression booster 56 and flows into the condensate water collection tank 71 together with the condensed water 52 flowing through the condensed water circulation and discharge pipe 55 as the pump 53 is driven. The operation is continuously repeated while the pump 53 is driven by the control unit.

The saturated steam and the condensed water 52 recovered into the condensate water collection tank 71 are re-supplied to the boiler 51 by the pressure-feeding force resulting from the driving of the pump 53.

The condensate water 52 is introduced into the condensate water collection tank 71 while the condensed water circulation suction pipe 54 sucked into the pump 53 is extended to the inside of the condensate water collection tank 71, In the case where a plurality of suction holes 541 are formed, saturated steam does not flow into the pump 53 side even if the water level of the condensate water collection tank 71 drops, so that the impeller of the pump 53 is damaged by cavitation phenomenon .

On the other hand, when the steam generated in one boiler (51) is used in two heat exchangers (one heat exchanger is not shown) having different working pressures, the steam is configured as shown in FIG. 6 shown in the second embodiment, The steam and condensed water 52 can be recovered to the condensate collection tank 71.

For example, steam is produced at a pressure of 10 kg / cm 2 in the boiler 51, steam is used at the same pressure in one heat exchanger, and steam is supplied to one heat exchanger using a pressure reducer (not shown) It is assumed that the pressure is used at a pressure of 5 kg / cm 2.

In this case, although the pressures of the saturated steam and the condensed water generated by the heat exchanging in the two heat exchangers are different from each other, the pressures of the evaporator 56 and the evaporator 56a of the heat vapor recompression compressors 56 and 56a provided in the condensate circulation discharge pipes 55 and 55a, The single pump 53 is driven to return the saturated steam and the condensed water 52 generated in the two heat exchangers to the inside of the condensate water collection tank 71 at the same time, To be supplied again.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention may be embodied with various changes and modifications without departing from the scope of the invention. will be.

It is therefore to be understood that the embodiments described above are to be considered in all respects only as illustrative and not restrictive, the scope of the invention being described in the foregoing specification is defined by the appended claims, Ranges and equivalents thereof are to be construed as being included within the scope of the present invention.

51: boiler 53: pump
54, 54a: Condensate circulation suction pipe 541, 541a: Suction hole
55, 55a: Condensate circulation discharge pipe 56, 56a: Thermal vapor recompression booster
561, 561a: Venturi tube 61: Heat exchanger
62, 62a: condensate and saturated vapor recovery pipe 63: temperature sensor
71: condensate collection tank 71a: upper tank
71b: Lower tank 72: Check valve
73: partition wall

Claims (7)

A condensate water collecting apparatus for a closed circuit circulating steam boiler, comprising: a condensate water collection tank (71) for collecting condensed water (52) and saturated steam produced by heat exchange in a heat exchanger (61) A pump 53 for pumping condensed water 52 collected in the condensate water collection tank 71 and a condensate water collection tank 71 connected at both ends to the suction side of the condensed water collection tank 71 and the pump 53, A condensate circulation suction pipe 54 connected to both the discharge side of the pump 53 and the condensate water collection tank 71 so as to transfer the condensed water 52 in the pump 53 to the pump 53 side, A condensate circulation discharge pipe 55 for sucking the condensed water 52 in the condensate water collection tank 71 through the condensate circulation suction pipe 54 and discharging it to the condensed water collection tank 71 side, And the condensed water 52 passes through the venturi pipe 561 (TVR) 56 for reducing the pressure when the steam is recirculated and the condensed water 52 and the saturated steam generated in the heat exchanger 61 connected to the thermal vapor recompression booster 56 are heated and recompressed A condensing water and a saturated vapor recovery pipe 62 which are forced to be sucked by the pressure falling while passing through the booster 56 and a condenser and a saturated vapor recovery pipe 62 installed at the condensed water and saturated vapor recovery pipe, Sensor 63,
The inside of the condensate water collection tank 71 is partitioned into an upper tank 71a and a lower tank 71b by partition walls 73 to connect a condensate circulation suction pipe 54 to the upper tank 71a, 52 for reducing the pressure of the condensate water circulating and discharging pipe 56 extends to the inside of the condensate water collection tank 71 so as to be located inside the condensed water collection tank 71, The condensed water and the saturated vapor recovery pipe 62 in which the condensed water and the saturated steam are recovered to the thermal vapor recompression booster 56 are placed in the lower tank 71b and are discharged through the other condensate and saturated vapor recovery pipes 62a, The condensed water 52 and the saturated steam recovered to the boiler 71b are supplied to the boiler 51 again,
The condensed water circulation suction pipes 54 and 54a are connected to both sides of the condensate water collection tank 71 and the condensed water circulation discharge pipes 55 and 55a are connected to both sides of the discharge side of the pump 53, The heat vapor recompression boosters 56a and 56a having different inner diameters of the venturi pipes 561 and 561a are installed in the discharge pipes 55 and 55a and condensed water collection pipes 55 and 55a are provided through the respective condensate circulation discharge pipes 55 and 55a. And the condensed water and the saturated steam having different pressures are collected to the tank (71) side. The condensate and steam recovery apparatus of the closed circuit circulation type steam boiler. delete delete delete delete delete delete

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