KR20000026279A - Method and apparatus for recycling waste heat from boiler - Google Patents

Abstract

PURPOSE: A method is provided to effectively recycle waste heat without difficulty in exhausting combustion gas in a gas flue by securing a closed area to recycle the waste heat. CONSTITUTION: Waste heat is recycled by the steps of; arranging a closed area(20) outward from the center of a gas flue(10), a flow path(30) and an exhaust path(40) in order; absorbing heat by convecting indoor air if the closed area is heated as waste heat passes the gas flue; transferring a part of the waste heat to the flow path; and directly transferring a part of the waste heat passing the exhaust path to the flow path. The waste heat is absorbed into the closed area or remained through the repetitive convection of the partial waste heat to continuously transfer the heat to the flow path and to directly transfer the waste heat passing the exhaust path to the flow path.

Description

Waste heat recovery method and apparatus of boiler

The present invention relates to a method and apparatus for recovering the remaining non-waste waste heat discharged to the outside in addition to the heat energy consumed to heat water of the heat energy generated from the heat source during operation of the boiler.

In general, as a waste heat recovery method of the boiler in the related art, as shown in FIG. 1, a preheating water chamber 2 is formed on the outer periphery of the flue 1 in which waste heat is discharged to the outside, and a supply port inside the preheating water chamber 2 is formed. The predominant way is to preheat the water 4 supplied through 3) and to receive the preheated water from the preheating water chamber 2 through the outlet 5 again.

However, in the conventional waste heat recovery method, since the waste heat discharged from the boiler body to the outside passes through the flue 1 at a high speed, the heat transferred to the flue 1 while passing is only a fraction of the total waste heat. Most of them are discharged to outside air, so waste heat recovery efficiency is extremely low. Of course, the heat transfer efficiency may be improved by using a material having excellent thermal conductivity such as copper or copper alloy in the year (1) itself, but the effect thereof is insignificant, and in addition, the year (1) and the preheating chamber (2) There is a method to extend the length and form a wider waste heat recovery area, in which case the waste heat recovery effect may be increased, but it may adversely affect the combustion efficiency of the heat source of the boiler body by bringing resistance to combustion gas discharge. There is a closure, which can be expensive and expensive to install.

The present invention has been researched and developed to solve such a conventional problem, to secure a sealed space that can absorb and retain the waste heat in the year in which waste heat is discharged, and through the accumulated heat of the sealed space and other parts of the sealed space. It is a main object of the present invention to provide a method and an apparatus capable of recovering waste heat more effectively without disturbing the discharge of combustion gas by allowing heat to be transmitted.

Another object of the present invention is to provide a waste heat recovery device that does not occupy a large amount of space of the waste heat recovery portion and is simple in structure and easy to manufacture and convenient to install and maintain.

In order to achieve the above object, in the method for recovering the waste heat by passing the waste heat discharged through the flue to the heat recovery medium such as water, the waste heat is absorbed in an outward direction from the inner center of the flue, It is formed and placed in the order of an enclosed space to stay in, a circulation path through which a heat recovery medium flows, and a discharge path through which waste heat is discharged. And it provides a waste heat recovery method in which a part of the waste heat to be retained is transferred to the distribution channel, and the part of the waste heat passing through the discharge passage directly to the distribution channel.

An apparatus embodying the above method is a device for recovering waste heat by transferring heat of waste discharged through the flue to a heat recovery medium such as water, wherein the waste heat is absorbed and retained in the center of the flue where the waste heat is discharged. A sealed mechanism having a sealed space inside is installed, and a recovery medium flow path for supplying and discharging waste heat recovery media is installed adjacent to the outer circumference of the sealed device, and the waste heat discharge is discharged between the year and the recovery medium flow path. It provides a device configured to form a passage.

1 is a schematic longitudinal cross-sectional view for explaining a conventional waste heat recovery method.

2 and 3 is a schematic view for explaining the principle of the waste heat recovery method of the present invention,

2 is an overall system diagram,

3 is a schematic view showing a state in which the heat flow in the interior and exterior of the sealed space when the preheating tube is installed outside the sealed space in FIG.

4 is a longitudinal sectional view showing a preferable example of an apparatus embodied by applying the waste heat recovery method of the present invention;

5 is a cross-sectional view of FIG. 4;

Figure 6 is a schematic diagram illustrating a state of use of the device of the present invention.

<Description of the code | symbol about the principal part of drawing>

10: year 20: confined space

30: distribution passage 40: discharge passage

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

2 and 3 is a schematic diagram for explaining the basic principle of the present invention waste heat recovery method, looking at this waste heat recovery principle according to the present invention, the closed space 20 in the outward direction from the inner center of the year (10), The flow path 30 and the discharge passage 40 are respectively formed and positioned in order, so that when the waste heat passes through the flue 10, the closed space 20 is heated, and the air inside is convex so that heat is absorbed and stays. The step of transferring some waste heat to the flow passage 30 and the step of transferring some waste heat directly through the discharge passage 40 to the flow passage 30 are performed at the same time.

That is, the waste heat passing through the year 10 is partially transmitted to the distribution path 30 through the sealed space 20 and the other part is discharged through the discharge passage 40 to be directly transmitted to the distribution path 30. At this time, the waste heat delivered to the sealed space 20 is in contact with the sealed space 20 as shown in FIG. 3, where the waste heat is located at the bottom of the sealed space 20 and the flow path 30. Since the outer circumference is heated, the inner circumference of the airtight space 20 of the inner air is deprived of heat to the distribution path 30 so that the temperature of the inner circumference is lower than the temperature of the lower and center of the airtight space 20. As a result, convection occurs in the up and down directions of the sealed space 20 as indicated by the arrows, but repeated convection occurs in which the lower air rises and falls.

Such transfer degree inside the sealed space 20 is a part of the waste heat is absorbed and stayed inside the sealed space 20 by the repeated convection phenomenon, it is possible to continuously heat transfer to the distribution path (30), Waste heat passing through the discharge passage 40 as the outer circumferential edge of 30 becomes direct heat transfer to the distribution passage 40.

Next, a preferable example of an apparatus embodying the above-described principles and methods will be described.

That is, as shown in FIGS. 4 and 5, a sealing mechanism 22 having a sealed space 20 therein for absorbing and retaining waste heat is installed at the center of the flue 10 in which waste heat is discharged. In the outer circumferential edge of the), a recovery medium flow path 30 for supplying and discharging waste heat recovery medium is installed adjacent to each other, and a waste heat discharge path 40 is disposed between the year 10 and the recovery medium flow path 30. To be formed, but the sealing mechanism 22 is made of a cylindrical shape in the same longitudinal direction as the flue 10, the recovery medium flow path 30 is the coil body in the form of a coil wrapped around the outer periphery of the closure mechanism (22) Winding and fixing, the inlet 24 and the outlet 26 is made to be drawn out through the flue 10, the sealing mechanism 22 and the flue 10 is by a plurality of longitudinal brackets (50) Are mutually fixed.

At this time, the sealing mechanism 22 and the recovery medium flow path 30 are preferably made of a metal conductor having excellent thermal conductivity, and in the case of the recovery medium flow path 30, it is preferable to use a corrugated pipe having a wide thermal conductive surface area. In addition, the flue 10 is formed to the diameter of the outlet 12 and the inlet 14 of the waste heat located in the upper, lower than the middle portion and wrap the outer periphery with the heat insulating material 16, waste heat passes through the inlet (14) When it flows in, it firstly hits the bottom of the sealing mechanism 22 and spreads outwardly and ascends through the waste heat discharge passage 40 and ascends surrounding the recovery medium flow passage 30 to again pass through the upper portion of the sealing mechanism 22 adjacently. By discharging to the outside via the discharge port 12, it is preferable to configure to improve the thermal efficiency.

In the drawings, reference numeral 52 denotes a flange for installing the flue 62 of the boiler 60, 64 denotes a circulation pump, 65, 66, 67, and 68 valves, and 70 denotes a heating or heating unit, respectively. Indicates.

6 is a view illustrating the use state of the present invention device, the operation relationship with reference to the contents shown in Figures 2 to 5 as follows.

When the boiler 60 is operated for the first time, the water prepared in the boiler 60 is heated, and heated water or steam is supplied to the heating unit 70 by the feeding pump 64, and heating or heating unit ( While the heat dissipated and cooled and recovered via 70) is recovered to the boiler 60 via the valve 68, the water is reheated and has a circulation process which is supplied to the heating unit 70 again. In the case of using the apparatus, the water recovered from the heating unit 70 flows into the recovery medium flow path 30 through the inlet 24 and is preheated, and then supplied to the boiler 60 through the outlet 26. Preheating process will be added.

At this time, the waste heat discharged to the outside of the heat generated from the heating source of the boiler 60 while the water supplied to the recovery medium flow path 30 is moved as the waste heat recovery medium is a waste heat discharge passage (40) by the flue (10) While passing through), one side hits the bottom of the sealing mechanism 22 and is delivered to the sealing mechanism 22 to heat the air in the sealed space 20 inside the sealing mechanism 22, absorbing the waste heat by the internal convection phenomenon, And continuously heat transfer is made to the diesel flow passage 30 through the inside of the distribution passage 30, the other side via the discharge passage 40 while the heat transfer through the outer periphery of the distribution passage 30 at the same time rapid heat transfer This is done.

Further, as shown in FIG. 4, when the diameter of the outlet 12 is small, the upper portion of the distribution passage 30 before the waste heat passing through the outlet passage 40 is discharged to the outside through the outlet 12. Local heat transfer may also be made locally via the upper portion of the closing mechanism 22 and adjacent.

As described above, the present invention is formed and placed in the order of a closed space for absorbing and retaining waste heat from the inner center of the year to the outside direction, a distribution passage through which a heat recovery medium flows, and a discharge passage through which waste heat is discharged. During the passage of the year, the closed space is heated and condensed air is absorbed and heat is absorbed and retains some waste heat to the flow passage, and some waste heat passing through the discharge passage is directly transferred to the flow passage. Waste heat recovery method is performed at the same time, and as a device incorporating the waste heat recovery method is installed in the center of the year in which waste heat is discharged, the sealed mechanism having a sealed space for absorbing and retaining the waste heat therein, And a recovery media flow path for supplying and discharging gas to be disposed adjacent to each other, and waste heat distribution between the year and the By providing a device that allows the passageway to be formed, to ensure a sealed space that can absorb and retain the waste heat in the year in which waste heat is discharged, it is possible to receive the accumulated heat in the sealed space and the heat passing through other parts of the sealed space. In the year, waste heat can be recovered more effectively without disturbing the emission of combustion gas, while the structure of the waste heat recovery area does not occupy much space, and its structure is simple, making it easy to install and maintain, etc. Has an excellent effect.

Claims (5)

In the method of recovering the waste heat by heat transfer to the heat recovery medium, such as water waste heat discharged to the outside through the flue, A sealed space that absorbs and retains waste heat from the inner center of the flue to the outside, and is formed in a flow path through which the heat recovery medium flows, and a discharge passage through which waste heat is discharged. While the heating is convection inside the heat is absorbed and the heat is absorbed and some of the waste heat is delivered to the flow channel, and the waste heat passing through the discharge passage is directly characterized in that the step is carried out at the same time Waste heat recovery method. In the device for recovering waste heat by heat transfer to the heat recovery medium such as water waste heat discharged to the outside through the flue, Install a sealed mechanism with a sealed space inside the center of the year where waste heat is discharged to absorb and heat the waste heat, and adjacent to the recovery medium flow path for supplying and discharging waste heat recovery media at the outer periphery of the sealed mechanism. And a waste heat discharge passage is formed between the year and the recovery medium flow passage. The method of claim 2, wherein the sealing mechanism 22 is formed in a cylindrical shape in the same longitudinal direction as the flue 10, and the recovery medium flow passage 30 coils the tubular body in a state in which the outer circumference of the sealing mechanism 22 is wrapped. Winding and fixed in the form, the inlet 24 and the outlet 26 are made to be drawn out through the flue 10, the sealing mechanism 22 and the flue 10 is a plurality of longitudinal brackets (50) Waste heat recovery apparatus characterized in that the mutually fixed by. The waste heat recovery apparatus according to claim 2 or 3, wherein the recovery medium flow passage (30) is made of a corrugated pipe. The method of claim 2, wherein the flue 10 is formed by forming the diameter of the outlet 12 and the inlet 14 of the waste heat located in the upper and lower than the middle portion and wrap the outer periphery with a heat insulating material (16) Waste heat recovery system.