KR101957863B1 - Vacuum steam circulation system - Google Patents

Abstract

A vacuum steam circulation system is unveiled. The present invention relates to a method and apparatus for supplying and storing water and heating water contained in a waste fluid through a predetermined circulation path recovered with water to heat supplied from a heat source to receive steam from blisters and blisters that generate steam, A radiator for radiating the heat of the steam to the outside, a radiator for radiating heat from the radiator, a water separator for separating the water from the radiator, a blister, a radiator, A fluid circulation means for controlling the steam to be continuously circulated along the circulation path by supplying the gas delivered from the water separation tank to the blister to adjust the pressure inside the blister to be higher than the internal pressure of the water separation tank, A vacuum holding means for discharging the gas delivered from the water separator so as to be maintained within a set pressure range, In response to the pressure measured at the pressure sensor, through the suction line connected to the outside air to the blister it includes a pressure control means for supplying into the blister.

Description

{VACUUM STEAM CIRCULATION SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a steam circulation system, and more particularly to a vacuum steam circulation system including a vacuum holding means and a fluid circulating means separately.

Conventionally, the steam circulation system has a low energy efficiency and a risk of safety accidents by heating water at high pressure to generate and circulate high temperature steam. Therefore, a vacuum steam circulation system for generating and circulating steam at a low pressure is now emphasized. The vacuum steam circulation system can generate steam from a low temperature (for example, 80 ° C), can reduce the energy due to the high energy efficiency, can improve the steam circulation efficiency due to the vacuum, .

Fig. 1 shows an example of a conventional vacuum steam system, and Fig. 2 shows a detailed structure of the fluid recovery and replenishing means of Fig.

FIG. 1 shows the structure of a vacuum steam boiler of Korean Patent No. 10-1373830, which is an example of a conventional vacuum steam system. 1 includes a radiator 1, a main body 10, a condenser 20, a vacuum pump 30, and a fluid recovery and replenishing means 40. The main body 10 heats the water stored in the steam tank 11 by heat transmitted from the burner 12 as a heat source to generate steam and supplies the generated steam to the heater 1 through the steam supply pipe 13. The heater 1 circulates the steam supplied through the steam supply pipe 13 and discharges the heat to the outside. The water and the steam, which have been phase-converted due to the heat release, are circulated through the steam return pipe 21 to the condenser 20 ). The condenser 20 recovers water and steam from the radiator 1 and stores the water and steam in the condenser 22 and condenses the steam recovered in the condenser 22 into a cooler 23 provided therein, And supplies the water generated by the phase conversion to the steam tank 11 of the main body 1 through the condensate return pipe 14. [ Then, the condenser 20 supplies the waste fluid mixed with the steam and the air recovered in the condensing chamber 22 to the vacuum pump 30 through the waste fluid recovery pipe 31.

The vacuum pump 30 receives the waste fluid from the condenser 20 through the waste fluid recovery pipe 31 and supplies the supplied waste fluid to the steam tank 11 of the main body 10 through the fluid injection pipe 41 Supply. 1, the vacuum pump 30 is connected between the main body 10 and the condenser 20 by a separate path from the condensate return pipe 14 and is connected to the steam tank 11 of the main body 10 and the radiator 1, And the condenser 20 are brought into a vacuum state so that water in the steam tank 11 is converted into steam at a low temperature and the converted steam is supplied to the steam tank 11 and the heaters 1, (20).

2, the fluid recovery and replenishment means 40 includes a water separator 42 to separate the gas and moisture contained in the waste fluid supplied from the vacuum pump 30, While the gas is discharged to the outside through a pipe 42d connected to the water separator. At this time, the pipe 42d is provided with a valve for controlling the amount of gas discharged to the outside.

In this case, the fluid returning and replenishing means 40 may be omitted, but in this case, the piping and the valve are connected to the fluid injection pipe 41 to evacuate more gas than necessary, so that the pressure of the circulating path is properly maintained.

As a result, in the conventional vacuum steam system shown in FIG. 1, the vacuum pump 30 is configured to perform both the vacuum pressure control function of the circulation path and the steam circulation function. The vacuum pump 30 controls the vacuum pressure intensity in the vacuum steam system when the amount of the gas discharged to the outside is adjusted as the valve of the pipe connected to the fluid recovery and replenishing means 40 is adjusted, Together.

The output of the vacuum pump 30 is increased in proportion to the circulating path length of the steam tank 11 and the circulating path of the heater 1 and the condenser 20 because the vacuum pump 30 also functions as a circulating steam in the vacuum steam system The vacuum pressure control and the steam circulation control can both be performed smoothly. However, increasing the output of the vacuum pump 30 is limited due to size constraints, power consumption and cost of the vacuum steam system. If the length of the circulation path becomes long, the circulation of steam and water becomes slow, and water is accumulated in the circulation path. In addition, due to the slow circulation speed, the steam delivered from the steam tank 11 to the heater 1 consumes a large amount of heat on the transmission path or the front end of the heater 1, and reaches the rear end of the heater 1 There arises a problem that sufficient heat can not be transmitted. This results in a large temperature difference between the front end and the rear end of the radiator 1, which should emit as much heat as possible in all areas.

Further, since the vacuum pump 30 can not confirm the pressure (particularly the heater pressure) in the piping of the circulation path, there is a limit in that it is difficult to stably maintain the pressure of the circulation path. If the pressure of the circulation path is not stably maintained, steam generation in the steam tank 11 is not smoothly performed, and the efficiency of the vacuum steam system is greatly reduced.

In addition, in the vacuum steam system of FIG. 1, the condenser 20 includes a cooler 23 to condense the steam recovered in the heater 1. The cooler 23 can be constructed in a closed cylindrical structure similar to the condenser chamber 22 and includes a flow path for circulating the cooling water and a flow path for discharging the air in the condensation chamber 22 through the electric heater 50 and the vacuum pump 30. [ So that the two flow paths meet to perform heat exchange. Inside the cooler 23, an electric heater 50 for performing heat exchange and a level sensor (not shown) for maintaining the level of the cooling water are provided. The cooler 23 cools the steam which has not been converted into water in the condensation chamber 22 to be supplied to the vacuum pump 30 for the durability of the vacuum pump 30.

The components such as the cooler 23 complicate the structure of the vacuum steam system and the restriction that the condenser 20 should be placed on top of the steam tank 11 for stable circulation causes the structure of the vacuum steam system There is a problem that it is constrained.

Korean Registered Patent No. 10-1373830 (Registered on Mar. 03, 2014)

It is an object of the present invention to provide a vacuum steam circulation system capable of greatly increasing the efficiency with a simple structure by separately controlling the vacuum and the circulation.

According to an aspect of the present invention, there is provided a vacuum steam circulation system, comprising: a steam supply unit for supplying and storing water, heating water contained in the waste fluid to heat supplied from a heat source through a predetermined circulation path, Blisters to generate steam; A heater for receiving the steam from the blister and delivering the steam according to a predetermined path therein to discharge heat of the steam to the outside; A water separator for receiving and discharging the waste fluid from which the heat is discharged from the heater; Wherein the water in the blister is supplied to the blister to form a circulation path together with the blister, the heater and the water separation passage, and the gas in the blister is supplied to the blister to adjust the pressure inside the blister to be higher than the internal pressure of the water separation bottle, Fluid circulation means for controlling the steam to be continuously circulated along the circulation path; And a vacuum holding means for discharging the gas delivered from the water separator so that the pressure inside the circulation path is maintained within a predetermined pressure range; .

The vacuum steam circulation system comprising at least one pressure sensor disposed on the circulation path and measuring an internal pressure of the circulation path; Wherein the vacuum holding means is driven in response to a pressure value measured at the at least one pressure sensor.

Pressure regulating means for supplying external air into the blister through a suction pipe connected to the blister, in response to a pressure value measured at the at least one pressure sensor; Further comprising:

Therefore, the vacuum steam circulation system of the present invention is provided with the vacuum holding means for properly maintaining the pressure on the circulation path inside the vacuum steam circulation system and the fluid circulation means for stably maintaining the circulation speed of the steam on the circulation path , The vacuum and the circulation can be individually controlled. Therefore, even when the length of the circulation path is long, the vacuum state can be stably maintained and the steam can be circulated smoothly, and the efficiency of the vacuum steam circulation system can be greatly increased. And the vacuum holding means is configured to adjust the internal pressure of the circulation path in the vacuum steam circulation system so that the control of the vacuum pressure can further increase the circulation efficiency. As a result, the water is not accumulated in the circulation path and the durability is increased.

In addition, it is possible to perform the function of the condenser of a conventional vacuum steam circulation system including a cooler or an electric heater with a very simple structure, and the vacuum steam circulation system can be reduced in size and relatively unrestricted. In addition, the water supplied from the outside can be transferred to the blister through the water separator, thereby improving the water separation performance and improving the heat efficiency and circulation efficiency.

Further, water can be stably supplied regardless of the vacuum state or the circulation state by providing the water supply means for supplying the water stored in the water separation tank to the blisters separately from the vacuum holding means and the fluid circulation means. As a result, the efficiency of the vacuum steam circulation system can be maximized.

1 shows an example of a conventional vacuum steam system.
Fig. 2 shows the detailed structure of the fluid recovery and replenishing means of Fig.
3 shows a structure of a vacuum steam circulation system according to an embodiment of the present invention.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described in detail with reference to the preferred embodiments of the present invention with reference to the accompanying drawings. However, the present invention can be implemented in various different forms, and is not limited to the embodiments described. In order to clearly describe the present invention, parts that are not related to the description are omitted, and the same reference numerals in the drawings denote the same members.

Throughout the specification, when an element is referred to as "including" an element, it does not exclude other elements unless specifically stated to the contrary. It should be noted that terms such as " part, "" module," " module, Or software or a combination of hardware and software.

3 shows the structure of a vacuum steam circulation system according to an embodiment of the present invention.

3, the vacuum steam circulation system of the present invention includes a heater 100, a pressure sensor PS, a blister 200, a water separation tank 300, a water supply means 400, a fluid circulation means 500, A vacuum holding means 600, a pressure adjusting means 700 and two valves V1 and V2.

First, the heater 100 transmits steam supplied from the blister 200 through the steam supply pipe 210 along a predetermined circulation path, as in the conventional radiator 1, To the outside. The radiator 100 is supplied with steam at one end and has at least one connection pipe (CP) for transmitting the supplied steam to the other end to form a circulation path. The steam supplied to one end of at least one connection pipe CP discharges heat to the outside while being transferred to the other end along the circulation path, and the temperature is lowered according to the discharge of heat and is transferred to the other end. Here, the number and size of the at least one connecting piping (CP), the shape of the circulation path, and the like can be variously designed in a heat-efficient manner. The waste fluid from which the heat is discharged from the heater 100 is transferred to the water separator 300 through the steam recovery pipe 110.

The pressure sensor (PS) measures the pressure inside the circulation path in the vacuum steam circulation system. In FIG. 3, for example, the pressure sensor PS is disposed in the steam recovery pipe 110 between the heater 100 and the water separator 300. However, the present invention is not limited to the arrangement position of the pressure sensor PS, and in FIG. 3, the area on the circulation path on which the pressure sensor PS can be arranged is indicated by the circulating pressure measurement area CPA. 3, the pressure sensor PS may be disposed in at least one position in the circulation path of the steam recovery pipe 110, the blister 200, the steam supply pipe 210, have.

When the pressure sensor PS is disposed in the steam return pipe 110 as shown in FIG. 3, the position of the pressure sensor PS has the least influence on the circulation path of the waste heat discharged from the heater 100 It is preferable to select the receiving place.

The ninth water separator 300 receives waste heat from the heater 100, separates the gas and moisture, delivers steam, which is a separated gas, to the fluid circulating means 500, To the blister (200) through the water supply means (400). In the present invention, the water separator 300 may have a simple closed cylindrical structure similar to the condenser chamber 22 of FIG.

At least one water level sensor (not shown) for measuring the water level may be provided inside the water separator 300, and a water pipe 310 for receiving water from the outside may be connected. The direct water pipe (310) is provided with a direct water supply valve (V1) to adjust the amount of water supplied to the water separator (300). The water supply valve V1 may be configured to supply or shut off water to the water separator 300 in response to a detection value of a water level sensor provided inside the water separator 300. [

If the direct water pipe 310 is connected to the blister 200 and the low temperature water supplied from the outside is directly supplied to the blister 200, the temperature change in the blister 200 for supplying steam to the heater 100 And the steam circulation may be obstructed. That is, in the structure in which the steam is supplied to the heater 100 by the pressure inside the blister 200, the steam inside the heater is condensed, so that the pressure is lowered and the circulation can be obstructed. In addition, the temperature inside the blister is lowered and the efficiency of the vacuum steam circulation system is greatly reduced.

In the present invention, the direct water pipe 310 receiving water from the outside is connected to the water separator 300, so that the water in the water separator 300 can be easily discharged from the steam recovered using the supplied water The temperature of the separated water can be increased by using the heat of the recovered steam and supplied to the blister 200. The temperature change of the blister 200 is minimized.

In the meantime, the water separator 300 may be configured to directly supply the separated water to the blisters 200, but in FIG. 3, the water is supplied through the water supply means 400.

The water supply means 400 is configured to receive water supplied from the water separator 300 and to supply the supplied water to the blister 200, and may be implemented by a pump or the like.

In the present invention, the water supply means 400 is a component included to overcome the restriction on the internal structure of the vacuum steam circulation system. If the water stored in the water separating cylinder 300 can be transferred to the blister 200 even if the water separating cylinder 300 is disposed at the upper end of the blister 200 and the separate means are not provided, 400 may be omitted. However, in the case where the water supply means 400 is provided, water stored in the water separation can 300 can be transferred to the blister 200 regardless of the position where the water separation can 300 is disposed. The constraints on the layout design for the components of the vacuum steam circulation system can be minimized.

A water supply valve V2 is provided between the water supply means 400 and the blister 200 to supply the amount of water supplied from the water separation tank 300 to the blister 200 in conjunction with the water supply means 400 Can be adjusted. The water supply valve V2 supplies or blocks the water stored in the water separator 300 to the blister 200 in response to the detection value of the water level sensor provided inside the blister 200. [

On the other hand, the fluid circulating means (500) supplies the gas supplied from the water separator (300) to the blister (200). The fluid circulating means 500 does not merely serve to supply the gas in the waste fluid recovered from the heater 100 to the blister 200 but also functions as a steam circulation control. The fluid circulating means (500) regulates the amount of steam supplied to the heater (100) by controlling the steam circulation speed inside the vacuum steam circulation system.

At this time, since the fluid circulation means 500 controls the circulation speed of the steam irrespective of the pressure in the circulation path, the steam can be stably circulated even when the circulation path length is increased. Accordingly, the circulation speed of the steam in the circulation path can be kept constant, and the amount of heat of the steam can be delivered to the rear end of the heater 100 faster than the existing system. That is, it is possible to maximize the heating efficiency in the vacuum steam circulation system that measures the heating efficiency as the heat emitted from the heater 100 to the outside. In addition, since the circulation speed of the steam is stabilized, it is possible to prevent the water from sticking to at least one connection pipe (CP) in the heater, thereby greatly increasing the durability of the vacuum steam circulation system.

The vacuum holding means 600 is connected to the water separator 300 and controls the pressure inside the circulation path to maintain the vacuum pressure by discharging more gas than necessary in the circulation path. The vacuum holding means 600 may be driven or stopped in accordance with the pressure value measured by the pressure sensor PS. The vacuum holding means 600 may be configured to be driven when the pressure value measured by the pressure sensor PS is equal to or less than a preset reference value.

In the present invention, the vacuum holding means 600 is connected to the water separator 300 so as to control the vacuum pressure so as not to adversely affect the circulation of the steam circulating in the circulation path.

That is, the fluid circulating means 500 supplies gas to the blisters 200 for circulating the steam to increase the pressure of the blisters higher than the ninth water separating cylinder 300, and the steam generated in the blisters 200 circulates to the heater 100 When the vacuum holding means 600 discharges the gas of the water separator 300 to the outside and the pressure is lowered, the force generated by the steam generated in the blister 200 is supplied to the heater 100 It strengthens and helps the circulation of steam.

In the present invention, the water supplying means, the fluid circulating means, and the vacuum holding means may be realized by a pump or the like.

The blister 200 stores water supplied from the water supply means 400 and generates steam by heating water stored in the heat transferred from the heat source 230. That is, the blister 200 heats the stored water to generate steam, and while the circulation path is circulated, the temperature is lowered to reheat the phase-transformed water to generate steam and supply it to the heater 100.

The blister 200 may be connected to a suction pipe 220 for sucking outside air and the suction pipe 220 may be connected to a pressure regulating means 700. The blister 200 may also include an internal temperature sensor, an internal pressure sensor, and at least one internal level sensor for measuring the internal temperature and pressure and the amount of stored water.

The pressure regulating means 700 coupled to the suction pipe 220 sucks or cuts outside air into the blister 200 in response to a pressure value measured by an internal pressure sensor provided inside the blister 200. That is, the pressure inside the blister 200 is maintained at a predetermined pressure value. This is to adjust the pressure inside the blister 200 to a predetermined pressure value through the pressure regulating means 700 in accordance with the number and size of the connecting piping CP and the shape of the circulation path to maintain an appropriate steam generating pressure.

And the heat source 230 heats the water in the blister 200 in response to the internal temperature value measured by the internal temperature sensor, and the water supply valve V2 controls the water level in accordance with the internal level value measured by the at least one internal level sensor, And supplies or cuts off water to the blister 200 in cooperation with the supply means 400.

1, the conventional vacuum steam system includes a condenser 20 to condense the recovered steam, thereby converting the steam into water. The steam is circulated through the condenser 20, , And transferred the phase-transformed water to the steam tank (11). And to transfer the waste fluid not phase-transformed to the water separator (42) through the vacuum pump (30). At this time, the condenser 20 includes a condenser 22 for temporarily storing the recovered steam, and a cooler 23 for cooling the steam in a heat exchange manner, thereby converting the steam into water. And the cooler 23 has an electric heater 50 for heat exchange. That is, the number of components of the condenser 20 is large and complicated. This is because in the conventional vacuum steam system, the vacuum pump 30 is configured to perform both the vacuum pressure control function and the steam circulation control function in parallel.

In addition, the existing vacuum steam system includes a fluid recovery and replenishing means 40 including a water separator 42 for separating gas and liquid from the waste fluid discharged from the vacuum pump 30 to regulate the internal steam circulation pressure Respectively.

In contrast, in the vacuum steam circulation system of the present invention, the vacuum holding means 600 performing the vacuum pressure control function and the fluid circulating means 500 performing the steam circulation control function are separately provided, so that the vacuum pressure control and the steam circulation control Can be performed separately. Therefore, the present invention can maintain the durability of the fluid circulating means 500 and the vacuum holding means 600 even if only the water separating cylinder 300 having a relatively simple structure is provided as compared with the condenser 20, Pressure and circulation can be easily controlled.

In addition, since the steam is condensed in the condensing chamber 22 and the temporarily stored water is supplied to the steam tank 10 in a natural supply manner, the condenser 20 is always disposed at a position higher than the steam tank 10 The structure of the vacuum steam system is limited. However, in the present invention, since the water supply means 400 is additionally provided, there is little restriction on the arrangement position of the water separator 300, and the arrangement can be freely designed.

As a result, the vacuum steam circulation system of the present invention can have a simple and simple structure and high efficiency.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

Claims (7)

A blister for supplying and storing water and heating the water contained in the waste fluid to heat supplied from the heat source through a predetermined circulation path recovered with the water to generate steam; A heater for receiving the steam from the blister and delivering the steam according to a predetermined path therein to discharge heat of the steam to the outside; A water separator for receiving and discharging the waste fluid from which the heat is discharged from the heater; Wherein the water in the blister is supplied to the blister to form a circulation path together with the blister, the heater and the water separation passage, and the gas in the blister is supplied to the blister to adjust the pressure inside the blister to be higher than the internal pressure of the water separation bottle, Fluid circulation means for controlling the steam to be continuously circulated along the circulation path; A vacuum holding means for discharging the gas delivered from the water separator so that the pressure inside the circulation path is maintained within a predetermined pressure range; A direct water pipe connected to the water separator, for receiving water from the outside and supplying the water to the water separator; And a direct water supply valve coupled to the direct water pipe and being opened or closed in response to at least one water level sensor disposed in the water separator, for adjusting an amount of water supplied to the water separator through the direct water pipe; Wherein the water separation cistern connected to the direct water pipe is connected to the fluid circulation means, the vacuum holding means, and the water supply means, respectively,
Wherein the vacuum holding means controls the pressure inside the circulation path to maintain the vacuum pressure and includes a pressure sensor inside the circulation path and is driven and stopped according to the pressure value measured by the pressure sensor A vacuum steam circulation system. delete The system of claim 1, wherein the vacuum steam circulation system
Pressure regulating means for supplying external air into the blister through a suction pipe connected to the blister, in response to a pressure value measured by the at least one pressure sensor; Further comprising: a vacuum system for supplying steam to the vacuum system. The method of claim 1,
At least one internal level sensor disposed inside the blister to measure an amount of water stored in the blister; And,
The vacuum steam circulation system
A water supply valve that opens or closes a path through which water stored in the water separator is supplied to the blister according to the measured value of the at least one internal water level sensor; Further comprising: a steam generator for generating steam; The water treatment system according to claim 4, wherein the water supply means
And the water in the water separation tank is disposed between the water separation and the water supply valves to supply the water in the water separation tank to the blister. delete The apparatus of claim 1, wherein the heater
At least one connection pipe for forming an internal transfer path for allowing the heat of the steam to be discharged to the outside and delivering the steam applied along the internal transfer path; Wherein the vacuum steam circulation system comprises:

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