JPH04136125A - Cooling device of plenum chamber - Google Patents

Abstract

PURPOSE:To uniformly discharge cooling flow and to execute uniform cooling by providing a flow straighting plate in the inlet part of a plenum chamber and connecting guide vanes provided in the curved part of a flow passage to a partition plate and this flow straighting plate. CONSTITUTION:The perforated flow straighting plate 1 is installed in the inlet part of the plenum chamber 2 connected to a circulating duct 5. The plenum chamber is provided with 3 pieces of the guide vanes 4 which are connected at one end to the flow straighting plate 1, extend horizontally and are bent downward in corner parts 2a. The other ends of two pieces of the outer guide vanes 4 are connected to the partition plate 3. The cooling gas entering from a circulating duct 5 to the plenum chamber 2 is straighted in flow by the flow straighting plate 1 in the inlet part to have a uniform flow velocity distribution so that the gas flows at an equal flow velocity in the respective flow passages. Then the cooling gas 6 is discharged evenly from plural circular hole nozzles (not shown in Fig.) of the plenum chamber 2 toward a strip and the strip is uniformly cooled.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a plenum chamber type cooling device used in a cooling zone of a continuous annealing furnace, continuous hot-dip galvanizing equipment, etc.

[Conventional technology]

The conventional plenum chamber cooling system used in the cooling zone of continuous annealing equipment and continuous hot-dip galvanizing equipment has been replaced with
This will be explained with reference to FIGS. 4 to 7.

Cooling gas 6 passing through horizontal circulation duct 5 is fed into plenum chamber 2 . The plenum chamber 2 branches parallel to the front and back, and a gap is provided between the branched parts.The part of the plenum chamber 2 that branches to the front and back is a corner part 2a that curves at a right angle downward from the horizontal direction. The direction of flow of the cooling gas 6 changes from the horizontal direction to the downward direction in the flow path formed within the plenum chamber 2.

A strip 8 passes vertically between the branched portions of the plenum chamber 2. A plurality of circular hole nozzles 7 are provided on the side of the plenum chamber 2 parallel to the flow direction of the cooling gas 6 and facing the strip 8 .

The cooling gas 6 is discharged from the circular hole nozzle 7 toward the strip in a direction perpendicular to the flow direction of the cooling gas 6 and perpendicular to the traveling direction of the strip 8. cooled by

Because the strip 8 tends to cool more easily in the edge portions 9 of the plenum chamber 2 in the portions of the plenum chamber 2 corresponding to both ends of the strip 80, that is, in the edge portions 9 of the plenum chamber 2 at both ends of the cooling gas 6 flowing downward, than in the center portion IO, The plenum chamber 2 is partitioned into a plurality of (three in the illustrated case) channels (chambers) in the width direction by a partition plate 3.3, and an edge damper 11 is provided in the channel of the edge portion 9. The flow rate is adjusted by restricting the flow rate with this edge damper 11, thereby achieving uniform cooling of the strip 8 in the width direction. In addition, since the cooling gas 6 is blown in from a direction perpendicular to the direction in which the strip travels, the corner part 2a
Since the flow separates at this point, causing an imbalance in the flow ffi toward the left and right edge portions 9 of the plenum chamber 2, a plurality of guide vanes 4 are installed at the corner portion 2a to rectify the flow.

[Problem to be solved by the invention]

As shown in FIG.
] When blowing the cooling gas 6 at right angles to the corner 2B, a plurality of guide vanes 4 are installed in the corner part 2B to rectify the flow. Since the distribution is transmitted rearward as it is, if the flow velocity distribution is uneven, it is not possible to equalize the flow rate to the left and right edge portions 9 of the plenum chamber 2 using only the guide vane 4. As shown in FIG. There is a tendency for the flow of the left and right edge portions 9 to become even, resulting in a flat angle).

Therefore, the cooling of the strip 8 is completely stopped.

The temperature distribution of the strip 8 was non-uniform between the ends and the center, causing cooling problems and nockles.

The present invention attempts to solve the above-mentioned problems of the conventional plenum chain/s1 type cooling device.

[Means to solve the problem]

In the present invention, a cooling fluid flow path having a curved portion is formed in a plenum chamber, the cooling fluid is discharged from an opening in the plenum chamber to the side in the flow direction of the cooling fluid, and edge dampers are provided in each of the plenum chambers. In a plenum chamber type cooling device in which flow paths partitioned by partition plates are formed at both ends of the flow of cooling fluid, a rectifying plate is provided at the inlet of the cooling fluid of the plenum chamber, and the above-mentioned? J
A guide vane connected to the rectifier plate and the partition plate was provided at the curved portion of L'tR.

(Function) In the present invention, the flow velocity distribution of the cooling fluid in the plenum chamber is made uniform by the baffle plate at the inlet of the plenum chamber. In addition, the flow path of the cooling fluid is regulated by the guide vane provided at the curved part in the plenum chamber that connects the rectifying plate and the partition plate, so that the flow of the cooling fluid in the plenum chamber is uniformly discharged at both ends. Uniform cooling occurs.

〔Example〕

A first embodiment of the present invention will be described with reference to FIG.

This embodiment is a plenum chamber type cooling device of the same type as the conventional cooling device shown in FIGS. 4 to 7, and the same parts in both are given the same reference numerals and the explanation thereof will be omitted.

In this embodiment, a perforated or wire mesh type rectifier plate l is installed at the entrance of the plenum chamber 2 connected to the circulation duct 5. In the plenum chamber 2, there is a plate 3 whose l end is connected to the rectifying plate l and which extends horizontally and then bends downward at a corner part 2a.
Four guide vanes 4 are provided in the chamber 2.
A number of channels are formed. Further, the other ends of the two outer guide vanes 4 are connected to the partition plate 3. outer 2
The widths of the two channels are set to be equal, and the widths of the two channels at the center are set to be equal. The guide vanes 4 are arranged so that the widthwise division ratio of the plenum chamber 2 population section matches the widthwise division ratio of the plenum chamber 2, that is, the width ratio of the four downward flow paths. In Figure 1, the relationship between the cross-sectional areas of the channels is A:B:B:A-A':B'l':^
’).

In this embodiment, the cooling gas 6 entering the plenum chamber 2 from the Wjpit duct 5 is rectified by the baffle plate 1 at the inlet, resulting in a uniform flow velocity distribution. This cooling gas flows within the flow path formed by the guide vane 4, and the width ratio of the downward flow path (A j B + B:A) is determined by the widthwise division ratio (A) of the inlet of the plenum chamber 2 ( A': B'
: II' : A'), the cooling gas 6 flows in each channel at the same flow rate. Also, corner part 2a
The guide vanes 4 at both ends provided in the plenum chamber 2 are connected to the rectifier Fi1 and the partition plate 3, and the guide vanes 4 restrict the flow path in the plenum chamber 2, thereby reducing the influence of the corner portion 2a. The flow rate in the outer flow path at both ends of the flow of the cooling gas 6 becomes equal without being affected.

Therefore, in this embodiment, the cooling gas 6 is evenly discharged toward the strip from the plurality of circular hole nozzles (indicated by reference numeral 7 in FIG. 5) of the plenum chamber 2, and the strip is evenly distributed.
cooling can be performed.

A second embodiment of the invention will be described with reference to FIG.

This embodiment differs from the first embodiment in that the edge damper 11 is installed immediately downstream of the rectifier Fi1, and can provide the same functions and effects as the first embodiment.

A third embodiment of the present invention will be described with reference to FIG.

In this embodiment, in order to effectively take the cooling length in the first embodiment, a circular hole nozzle 7 is also provided in the corner part 2a of the plenum chamber 2, and the cooling gas is also discharged from the corner part 2a. I decided to do it. Furthermore, by blocking a part 20 of the opening of the circular hole nozzle 7 of the plenum chamber 2, the opening area from which the cooling gas is blown out from the plenum chamber 2 is made bilaterally symmetrical, and the cooling gas is discharged from the flow paths (edge portions) at both left and right ends. I try to equalize the gas flow rate.

In this embodiment as well, the same functions and effects as in the first and second embodiments can be achieved.

Note that although each of the above embodiments uses cooling gas, a liquid such as cooling water may also be used. Furthermore, a slit nozzle or the like may be used instead of the circular hole nozzle for discharging the cooling fluid.

〔Effect of the invention〕

By providing a rectifying plate at the inlet of the plenum chamber, and connecting the guide vanes provided at the curved part of the flow path within the plenum chamber to the partition plate of the plenum chamber and the rectifying plate, the flow rate of the cooling fluid within the plenum chamber can be distributed. This ensures uniform flow and rectification, and as a result, uniform cooling fluid is discharged from the plenum chamber, resulting in uniform cooling.

[Brief explanation of drawings]

1, 2, and 3 respectively show the first embodiment of the present invention. 4 is a perspective view of a conventional plenum chamber type cooling device, and FIG. 5 is a side wall stand provided with a circular hole nozzle of the plenum chamber of the conventional cooling device. 6 is a sectional view taken along the line AA in FIG. 4, and FIG. 7 is a sectional view taken along the line BB in FIG. 4. 1... Rectifier plate. 2a...Corner part 4...Guide vane. agent

Claims (1)

[Claims] A cooling fluid flow path with a curved portion is formed in the plenum chamber, and the cooling fluid is discharged from the openings of the plenum chamber on the sides in the flow direction of the cooling fluid, and each plenum chamber has an edge damper and is divided by a partition plate. In a plenum chamber type cooling device in which a flow path is formed at both ends of the cooling fluid flow, a rectifying plate is provided at the inlet of the cooling fluid of the plenum chamber, and the rectifying plate is provided at a curved portion of the flow path. A plenum chamber type cooling device, characterized in that a guide vane connected to the partition plate is provided.