KR200451178Y1 - Steam boiler connected by double pipe - Google Patents

Abstract

The present invention relates to a steam boiler connected by a double pipe, and more particularly, by installing a steam pipe inside a hot water pipe to allow steam and water to flow independently, and to heat and discharge the steam and water in the propulsion tank pump It also relates to a steam boiler connected by a double pipe that allows hot water to be circulated by the pressure of steam without installing a motor.

According to the present invention, since the water is automatically circulated without the motor or the pump, the boiler volume or equipment is reduced, the cost is reduced, and there is no effect of using electricity, thereby reducing the operating cost.

Boiler, double pipe, steam, make-up water

Description

STEAM BOILER CONNECTED BY DOUBLE PIPE}

The present invention relates to a steam boiler connected by a double pipe, and more particularly, by installing a steam pipe inside a hot water pipe to allow steam and water to flow independently, and to heat and discharge the steam and water in the propulsion tank pump It also relates to a steam boiler connected by a double pipe that allows hot water to be circulated by the pressure of steam without installing a motor.

A boiler is a device for heating a room or room while boiling water and circulating through a pipe, and a steam boiler is a device that circulates steam to generate heat.

In general, a steam boiler circulates steam through a pipe, and heats condensed water, which is heated again in a heater and recycled through a pipe. A pump or motor is used to pass steam or condensate through the pipe.

1 is a configuration diagram of a circulating steam boiler according to a conventional embodiment, the configuration of which is as follows.

A steam supply pipe 3 is installed at the top of the boiler 1 in which the pressure gauge 2 is installed, and a heat exchanger 4 is connected to an end of the steam supply pipe 3, and steam is connected to the other end of the heat exchanger. Condensate pipe (5) is connected to the heat exchange in the condensate to recover the condensate generated by the other, the steam trap 6 is provided on the condensate pipe.

The condensate return tank 8 is connected to the condensate return tank 8 having a float switch 7 at the end of the condensate pipe 5, and the water level in the condensate return tank 8 is connected to a connection pipe 9 connected to one side of the condensate return tank. As the float switch 7 detects that the water level is higher than the set water level, a condensate recovery pump 12 is installed to operate by driving the motor 10 to pump condensate in the condensate return tank 8 to the condensate steam separation tank 11. There is a check valve 14 on the connecting pipe 9 to prevent the condensate 13 in the condensate steam separation tank 11 from flowing back to the condensate return tank 8.

In addition, on one side of the boiler 1, a condensate steam separation tank 11 for supplying the condensate 13 recovered through the connecting pipe 9 to the inside of the boiler 1 is irrigation water located inside the boiler 1. A pressure equalizing pipe is installed at a position higher than the head 15 so that the pressure of steam is acted on the inside of the condensate steam separation tank 11 between the upper portion of the condensate steam separation tank 11 and the steam supply pipe 3. 16 is connected to the solenoid valve 19 is installed on the condensate water supply pipe 17 is opened and closed by an automatic pressure control switch 18 installed on the upper portion of the condensate steam separation tank (11).

Therefore, when steam (2) is generated by the operation of the boiler (1), the generated steam 20 is supplied to the heat exchanger (4) along the steam supply pipe (3) for heating and some steam is a separate steam It is supplied through a pipe.

When the steam is converted into the condensate 13 by heat exchange in this process, the wet steam is removed from the steam trap 6 in the process of being recovered to the condensate recovery tank 8 through the condensate pipe 5.

When the generated condensate 13 is filled in the condensate recovery tank 8 to detect that the float switch 7 is above the set level, power is automatically applied to the motor 10 to operate the condensate recovery pump 12, thereby recovering the condensate. The condensate 13 in the tank is recovered to the condensate steam separation tank 11 through the connecting pipe 9.

The condensate 13 recovered in this way is filled to the boiler 1 side as the solenoid valve 19 is opened by the water head difference between the boiler 1 and the condensate steam separation tank 11.

However, such a conventional water supply device allows the steam pressure generated according to the operation of the boiler 1 to be acted on the upper portion of the condensate steam separation tank 11 by the pressure equalizing tube 16 and at the same time separates the boiler 1 and the condensate steam. Condensed water is replenished to the boiler 1 side due to the head difference of the tank 11, so that the steam pressure and the temperature of the condensed water are increased to above the set value when the boiler is temporarily restarted. It takes a long time that the water supply from the condensate steam separation tank to the boiler does not occur smoothly frequently, there is a problem that forced water supply by installing a separate pump or motor.

The present invention for solving the above problems is to pass the steam and water in a separate pipe while passing the heat of the steam to the water, and by mixing the steam and water passing through the heat dissipation unit to proceed to the pressure of the steam to separate pump or It is an object of the present invention to provide a steam boiler connected by a double pipe that allows hot water to be circulated without a motor.

In addition, an object of the present invention is to provide a steam boiler connected by a double pipe to prevent backflow of steam or water by providing a backflow prevention valve in the pipe connecting the tank for storing steam and water.

The present invention for solving the above problems is a boiler for heating by using steam and hot water at the same time, the steam generating tank for generating steam by heating the water stored therein; A heating tank installed to penetrate the storage space inside the steam generating tank and configured to heat water in the internal storage space by heat radiated from the steam passing through the steam pipe; A propulsion tank for supplying water to the heating tank and the steam generating tank; Both ends are connected to the heating tank and the propulsion tank, respectively, the hot water pipe for dissipating heat from the heat dissipation portion while passing through the water from the heating tank to guide the entry into the propulsion tank; The steam pipe from the steam generating tank extends along the inside of the hot water pipe and is connected to the propulsion tank, and the water passing through the hot water pipe and the steam passing through the steam pipe are mixed in the propulsion tank. do.

Transparent water level confirmation window is installed on one side wall, the supplementary water storage tank for supplying water so that the water above the predetermined level is stored in the propulsion tank; further includes.

The pipe connecting the propulsion tank and the steam generating tank and the pipe connecting the propulsion tank and the heating tank may be provided with a non-return valve for preventing backflow of water.

According to the present invention, since the water is automatically circulated without the motor or the pump, the boiler volume or equipment is reduced, the cost is reduced, and there is no effect of using electricity, thereby reducing the operating cost.

In addition, according to the present invention, since the steam pipe is installed in the hot water pipe in a double manner to separate the steam and water, it is effective to maintain the warming time.

In addition, according to the present invention there is an effect that the noise or vibration does not occur because the circulation is naturally made without installing a pump or a motor.

Hereinafter, a steam boiler (hereinafter, referred to as a "steam boiler") connected by a double pipe according to an embodiment of the present invention will be described with reference to the drawings.

2 is a perspective view showing the structure of a steam boiler according to an embodiment of the present invention, Figure 3 is a cross-sectional view showing the internal structure of the steam boiler of FIG.

Steam boiler 100 of the present invention is composed of a body 102 for receiving the tank and the pipe, and a lid 104 for sealing the opening of the upper portion of the body (102).

One side surface of the body 102 is connected to the pipe 112 flowing the hot water for heating, the two pipes 112 are connected to both ends of the heat dissipation unit 200.

The heat dissipation unit 200 is a pipe that is installed on the floor of a room, a floor, or an office, and is a part that heats the room by dissipating heat. Therefore, the shape or location of the heat dissipation unit 200 will vary depending on the purpose of the building.

An accommodation space is formed inside the body 102, and a propelling tank 106 is installed at one side of the accommodation space.

The propulsion tank 106 is a place where water and steam for heating are mixed, and steam condenses and mixes with water after dissipating heat. Water mixed in the propulsion tank 106 enters the steam generating tank 108 and the heating tank 110 through the pipe 118, respectively.

The amount of water entering the steam generating tank 108 and the heating tank 110 can be appropriately adjusted, the pipe 118 connecting each is provided with a non-return valve 120 to prevent the back flow of water.

The steam generating tank 108 is a device for generating steam by heating water, and is provided with a heater 108a connected to a power supply 108b for supplying current. The heater 108a may be any device that generates heat, such as a ceramic heating pipe, and may be submerged in water, but may be heated in contact with the outer wall surface of the steam generating tank 108.

The power supply unit 108b is provided with a control unit (not shown) for adjusting heating temperature and time.

Steam generated in the steam generating tank 108 enters the heating tank 110 through the pipe 118. The pipe 118 through which the steam from the steam generating tank 108 flows passes through the inside of the heating tank 110 and is connected to the steam pipe 114.

At this time, the water in the heating tank 110 and in contact with the outside of the pipe (steam pipe) will be heated by the heat released from the steam pipe.

The water heated to be used as the heating water by the steam flows to the heat dissipation unit 202 through the hot water pipe 112, and the steam passing through the steam tube 114 also passes the heat dissipation unit 202.

Since the steam pipe 114 is installed while maintaining a constant interval with the inner wall surface of the hot water pipe 112, only heat is exchanged between steam and water without steam and water mixing with each other. That is, heat is transferred from the high temperature steam flowing through the steam pipe 114 to the low temperature water flowing through the hot water pipe 112, and the heat is again emitted to the heat dissipating part 202.

In this way, by installing another pipe in one pipe to pass the steam and water separately to facilitate the flow of fluid and to maintain the pressure of the steam and water independently of each other.

The water and steam flowing out of the hot water pipe 112 and the steam pipe 114 are mixed with each other in the propulsion tank 106.

The gaseous steam passing through the steam tube 114 is mostly condensed while dissipating heat to change to liquid water. However, compared to the water passing through the hot water pipe 112, the temperature and pressure is high, when entering the propulsion tank 106 is sprayed at a higher speed than the water of the hot water pipe 112.

Therefore, since the pressure inside the propulsion tank 106 is higher than the liquid water alone, the water inside the propulsion tank 106 flows back to the steam generating tank 108 and the heating tank 110 by this pressure. .

The non-return valve 120 installed between the propulsion tank 106 and the steam generating tank 108 and between the propulsion tank 106 and the heating tank 110 prevents water from flowing back to the propulsion tank 106 again. Do it.

The replenishment water storage tank 116 serves to replenish water so that water above a predetermined level is filled in the propulsion tank 106.

The replenishment water storage tank 116 installs a cap 116a at the top to put water, and a water level confirmation window 116b formed of a transparent window is formed at one side to determine how much water is stored therein. It makes it easy for administrators to understand.

Attaching a water level sensor (not shown) inside the propulsion tank 106, it may be configured to allow water to automatically flow from the replenishment water storage tank 116 when the water level drops below a certain height.

The water refilling device using the sensor may be applied to replenish water by measuring the water level of the steam generating tank 108 or the heating tank 110 in addition to the propulsion tank 106.

Although the preferred embodiments of the present invention have been described above with reference to the accompanying drawings, the technical configuration of the present invention described above may be modified by the person skilled in the art to which the present invention belongs without changing the technical spirit or essential features of the present invention. It will be appreciated that the present invention may be practiced as. Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the utility model registration claims to be described later rather than the detailed description, and the scope of the utility model registration claims. All changes or modifications derived from the meaning and scope and equivalent concepts shall be construed as being included in the scope of the present invention.

1 is a block diagram of a circulating steam boiler according to a conventional embodiment.

Figure 2 is a perspective view showing the structure of a steam boiler according to an embodiment of the present invention.

3 is a cross-sectional view showing the internal structure of the steam boiler of FIG.

Claims (3)

A boiler that uses steam and hot water at the same time for heating. A steam generation tank for generating steam by heating the water stored therein; A heating tank installed to penetrate the storage space inside the steam generating tank and configured to heat water in the internal storage space by heat radiated from the steam passing through the steam pipe; A propulsion tank for supplying water to the heating tank and the steam generating tank; Both ends are connected to the heating tank and the propulsion tank, respectively, the hot water pipe for dissipating heat from the heat dissipation portion while passing through the water from the heating tank to guide the entry into the propulsion tank; The steam pipe from the steam generating tank extends along the inside of the hot water pipe is connected to the propulsion tank, Water passing through the hot water pipe and the steam passing through the steam pipe is a steam boiler connected to the double pipe, characterized in that mixed in the propulsion tank. The method of claim 1, Transparent water level confirmation window is installed on one side wall, the supplementary water storage tank for supplying water so that water above a certain level is stored in the propulsion tank; Steam boiler connected by a double pipe further comprising. The method of claim 1, And a pipe connecting the propulsion tank and the steam generating tank and a pipe connecting the propulsion tank and the heating tank to install a non-return valve for preventing backflow of water.

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