KR200179781Y1 - Baffle for heat-proof pipe - Google Patents

Abstract

The present invention relates to a baffle device installed in an associated pipe or a heat pipe to improve heat radiation efficiency in a boiler or a heater using heat generated by burning oil or gas.

In the conventional case, the internal hot air flows in the form of waveforms only in the up and down directions, and is fed rapidly, and the thermal efficiency is low and the internal resistance is large, so the feeding efficiency is low.

The present invention feeds the heat flow through the baffle into the swirling flow inside the tube, and the centrifugal force is applied to the inner surface of the tube to make it evenly frictional and thus always improve the heat transfer efficiency. It improves the feeding efficiency and makes the burner have a good ignition rate so that it can be properly used in the boiler or heater field.

Description

Baffle unit inside the heat pipe of the boiler pipe or tubular heater

The present invention relates to a baffle device installed in an associated pipe or a heat pipe in order to increase heat dissipation efficiency in a boiler or a heater that requires heat generated by burning oil or gas. The present invention relates to a swing baffle device that improves the heating effect applied to the inner surface of the fin body while feeding the heat.

A baffle device which is generally used is perforated and bent in the plate body 1 every evening as shown in FIGS. 1 to 3 so that the distribution hole 2 and the upper and lower pins 3 and 4 are formed. The baffle 5 is comprised, it is installed in the pipe | tube 5, and is utilized. However, this type of baffle device, due to its structural weakness, as the internal heat passes through the distribution hole 2 and alternately hits the upper and lower pins 3 and 4, as shown in FIGS. 1 and 2. Since only the up and down flows in a wave form, the heat delivered to the tubular body 6 is mainly limited to the upper and lower parts, and the heat delivered alternatingly is mainly limited to the upper and lower parts, which are alternately transmitted. The thermal efficiency delivered to (6) is lowered, the efficiency of heat dissipation from the tubular body 6 to the outside, and also has a problem that can only be lowered. In addition, the flow of the internal heat from the front end to the rear end of the baffle (5) is made to feed in the form of up and down waveform, the internal resistance is increased, and eventually the internal efficiency is low, which adversely affects the initial ignition of the burner. Unfavorable problems also arise in the rate.

In addition, in the case of Korean Utility Model Publication No. 89-18008, semicircular baffle plates are arranged in a zigzag material, and adjacent baffle plates are installed to face each other at 180 ° angles so that the flow of internal heat is expedited in the form of left and right waves. The heat generated in the combustion chamber is concentrated only to the left and right sides, and internal heat is hardly transmitted to the front and rear sides, so that heat is not evenly transmitted throughout the combustion chamber, resulting in relatively low thermal efficiency. The internal resistance of the internal heat that is fed together is increased so that the fundamental problem that cannot be smoothly fed is not solved.

The present invention has been researched and developed to solve such a conventional problem, and has the following objectives.

The first object of the present invention is to improve the heat dissipation effect radiated from the tube to the outside by heating evenly over the entire area regardless of the upper, lower, left and right as the inner heat passing through the inner tube wraps the baffle I'm here.

The second object of the present invention is to improve the burn rate of the burner by making the feed of the internal heat smoother than the swirl flow while passing through the rear end from the front end of the baffle.

In order to achieve the above object, the present invention, when the flow of heat passing through the baffle inside the tube in the form of swirl flow, the centrifugal force is applied to the inner surface of the tube evenly and friction, thereby improving the heat transfer efficiency, baffle It was developed based on the principle that the feeding efficiency of the heat passing through the front and rear stages can also be improved.

In other words, the present invention is to install a plurality of baffle pipes at regular pitch intervals in the longitudinal direction in the pipe, such as the inside of the boiler or heater, or the heat radiating pipe using the heat generated by burning the oil or gas in order to enhance the heat radiating effect. In the conventional baffle apparatus used, a plurality of semi-circular baffle pins are fixedly installed on the central axis, and the installation angles of the baffle pins adjacent to each other among these baffle pins are installed at an installation angle of 90 ° instead of 180 °. It provides a baffle device made so that the internal heat is passed through the inside of the tube to have a swirl flow.

1 to 3 show a conventional baffle device,

1 is a partially omitted appearance perspective view of the baffle device shown with the flow of internal heat,

FIG. 2 is a longitudinal sectional view showing the state of engagement of the baffle device and the outer tube shown in FIG.

3 is a cross-sectional view of FIG. 2 showing the flow state of internal heat.

Figure 3a is a cross-sectional view showing a state where the pin is located on the top,

3b is a cross-sectional view showing a state where the pin is located at the bottom,

Figure 4 is a conceptual perspective view for explaining the baffle device of the present invention,

FIG. 5 is a longitudinal sectional view showing a state of flow of internal heat of the coupling state of the baffle device and the outer tube shown in FIG. 4;

6 is a cross-sectional view showing the flow state of the internal heat by separating according to the installation position of the inner pin as the baffle device and the outer tube in the present design,

Figure 7 is a longitudinal cross-sectional view showing an example in which the installation angle of the inner pin in the baffle device of the present invention is installed to have an inclination angle rather than vertical,

FIG. 8 is a partially omitted perspective view of the baffle device of the present invention, showing an example thereof as a fixed engagement state between the inner pin and the center side.

* Explanation of symbols for main parts of the drawings

6: tube 10: centerline

12: baffle pin 14: central axis

Next will be described in more detail with respect to a preferred example of the present invention according to the accompanying drawings.

According to a preferred example of the present invention as shown in Figures 4 to 8, the present invention uses the heat generated by burning the flow path or gas pipe 6, such as the inside of the boiler or heater, or the heat dissipation tube In the baffle apparatus commonly used to increase the heat dissipation effect by installing a plurality of baffle pins 12, 12 ... at regular pitch intervals in the longitudinal direction therein, a plurality of semi-circular baffle apparatuses 12, 12 ... It is fixedly installed on the central axis 14, and the installation angles between the baffle pins 12, 12 ... adjacent to each other among the plurality of baffle pins 12, 12 ... are 90 ° instead of 180 °. Installed at an installation angle is made so that the internal heat is passed through the inside of the tubular body (6) to have a swirl flow.

At this time, the installation angle of the mutually adjacent baffle pins (12, 12 ...) may be installed to have a positional change by 90 ° on the central axis 14 located in the longitudinal center line 10, but not shown The installation angles between the baffle pins 12 and 12 can be selectively used appropriately such as 30 °, 45 °, 60 °, and 120 ° such that the internal heat flow passing through the inside of the tube 6 has a swirl flow. have.

Further, by adjusting the pitch spacing between the baffle pins 12 and 12 or by installing the baffle pins 12 in an inclined state not vertically about the center line 10 as shown in FIG. ) The flow of heat passing through the inside may have a longer residence time, and although not shown, it is installed in a spiral direction around the center line 10 so that the flow of heat inside the pipe 6 is stronger. It may also have a swirl flow.

In addition, the installation method of the baffle pin 12, as shown in FIG. 8, inserts the mounting groove 12a of the semi-circular baffle pin 12 on the central axis 14, and screw or spot the bent end (12b) Can be fixedly installed by welding, and can be selected and installed in an appropriate manner so as not to interfere with the installation angle difference between the baffle pin 12 and the adjacent baffle pin 12, the inclination angle of the baffle pin 12 itself, and the installation pitch interval. I will.

Moreover, the shape of the baffle pin 12 has been described so far about a semi-circle (180 ° circular), but can be used within a circular shape in the range of 90 ° to 135 ° by varying its use range. The flow of heat passing through the baffle device can be appropriately selected and used within the range of maintaining the retention time partially generated at the installation site of the baffle pin 12 while having a swirl flow.

Thus, when installing and utilizing the baffle device of the present invention inside the tubular body 6, the flow of the internal heat passing through the tubular body 6 is as shown in FIGS. 4 to 6 of the baffle fin 12 Since the installation angles are formed differently from one another, the main flow is changed into a swirl flow form, and due to the characteristics of the swirl flow form, the main flow has a centrifugal concern, which increases the amount of internal heat that collides with the inner surface of the tubular body 6, and some of them When it collides with the baffle pin 12, it disperses in the inner surface direction of the tube 6 and then returns to the center of the tube 6 and appears as a partial retention phenomenon of heat delivered with the main stream. It is possible to increase the heat transfer effect of the internal heat through the), and to improve the feeding effect of the internal heat.

As described above, the baffle device of the present invention is different from the installation method such as the shape of the baffle pin 12 and the installation angle, pitch (pitch), position, etc. of the internal heat passing through the baffle device as the inside of the tubular body 12. The flow is transformed into a swirling flow, the centrifugal force is applied and friction is evenly applied to the inner surface of the tubular body 6, and the temporary partial retention phenomenon occurs at the front end of the baffle pin 12, so as to the upper, lower, left, right side as the inner surface of the tubular body 6; Irrespective of the heating, the heat dissipation effect of the heat dissipation from the tubular body 6 to the outside is improved, and the internal heat is smoothly fed to improve the ignition rate of the burner.

Claims (2)

Heat dissipation by installing a plurality of baffle pins (12, 12 ...) at regular pitch intervals in a lengthwise manner inside the pipe (6), such as an inside of a boiler heater or a heat pipe, using heat generated by burning oil or gas. In a conventional baffle device commercially used to increase the effect, a plurality of semicircular baffle pins 12, 12 ... are fixedly installed on the central axis 14, and a plurality of these baffle pins 12, 12 ... Of the baffle pins (12, 12, ...) adjacent to each other is installed at an installation angle of 90 ° instead of 180 ° so that the internal heat fed through the inside of the pipe (6) has a swirl flow An internal baffle device for heat dissipation of an associated boiler or tubular heater, characterized in that the boiler. 2. The internal baffle device for heat dissipation tubes according to claim 1, characterized in that the baffle fins (12, 12 ...) are inclined about the central axis (14).