JP5802182B2 - Drain pipe connection structure and manufacturing method thereof - Google Patents

Description

  The present invention relates to a drain pipe connection structure and a manufacturing method thereof.

  In the rectangular drain pan used in air-conditioning equipment etc., in order to provide a drainage gradient concentrated at the drain outlet, the traditional manufacturing method of joining a plurality of triangular or trapezoidal metal plates by welding is improved, A method has been proposed in which the number of welds is reduced as much as possible by using a press (see Patent Document 1). In this drain pan, the drain outlet is disposed at the lower end of the side surface surrounding the pan. However, the drain outlet itself is an opening simply penetrating the plate surface of the side surface (that is, the opening peripheral portion of this opening). Is formed by the plate thickness of the side surface surrounding the pan), and only “welding” is described when the drain pipe is connected to the drain port.

  On the other hand, a pilot hole is provided in the plate surface of the metal plate (a flat region that is not the end of the plate), and a cylindrical flange is formed by burring on the opening periphery of the pilot hole, and the metal pipe is removed from the cylindrical flange. A method has been proposed in which both are stud-welded in a fitted state (see Patent Document 2). In this method, stud welding is performed in an annular shape between the outer peripheral annular surface of the cylindrical flange root on the metal plate side and the tip annular portion of the metal pipe.

JP 2010-78247 A JP-A-9-308971

  When connecting the drain pipe to the drain port formed in the drain pan and welding between them by tig welding or gas welding (Patent Document 1 etc.), the thickness of the pan is thin (eg 0.6 mm etc.) This is due to the fact that the drain pipe is thick (for example, 1.2 mm is common), and the pan side melts or the drain pipe bends due to thermal distortion. Was a frequent occurrence. For this reason, skill is required for welding, and there is a problem that the work efficiency is poor and the yield is poor, resulting in a considerable increase in cost.

  In addition, the bead generated at the welded portion rises and obstructs drainage, and there is a problem that residual water that cannot be drained is generated around the drainage port, causing mold and rust. The generation of residual water is accompanied by the trouble of requiring regular heater operation so that the residual water does not freeze, especially in the case of a drain pan used in a place where the use environment reaches an extremely low temperature, such as a refrigerator. In addition, even if the heater is operated, freezing cannot be completely prevented, and as a result, the frozen part is enlarged and accumulated, and in a severe case, the drain pipe is clogged. There was also a risk.

  On the other hand, a method of fitting a metal pipe to a cylindrical flange provided on a metal plate (Patent Document 2, etc.) involves burring. Conventionally, it has been a common premise that this burring process is performed on a flat region that is not the end of a metal plate. Therefore, in the drain pan, the cylindrical flange is formed so as to protrude to the lower surface such as the center of the pan. However, in this case, when the drain pipe is horizontally pulled, it is necessary to attach an elbow or the like to the lower surface of the drain pan, and there is a problem that the drain pan becomes bulky.

  In addition, in order to avoid this problem, if burring is performed on the side surface of the outer periphery of the pan, the burring cannot be disposed at the lowermost end of the side surface. ) Generated residual water that could not be drained, causing mold and rust. Naturally, various problems related to freezing of residual water cannot be solved at all, which is a big obstacle to the introduction of this structure.

  The present invention has been made in view of the above circumstances, and in a structure in which a drain pipe is connected to a drain main body such as a drain pan, a drainage basin or a drainage basin, the manufacture is easy and the manufacturing cost is low. Drainage pipe connection structure that can reduce costs and prevent the generation of residual water that cannot be drained to prevent mold, rust, etc., and solve all the problems associated with freezing of residual water And it aims at providing the manufacturing method.

In order to achieve the above object, the present invention has taken the following measures.
That is, the drainage pipe connection structure according to the present invention is provided with a pan section and water flashing wall extension formed causing bending provided in the pan section, drain hole penetrating the water flashing wall the opening peripheral portion one part is formed one part of the drain hole is the opening peripheral portion extending through the or the pan portion is formed in an arrangement which circumscribes the upper surface of the pan portion in an arrangement which circumscribe the inner surface of the water flashing wall And a drain pipe that communicates with the drain hole of the drain main body and is connected in an outward projecting manner, and includes the extension before bending or the extension. The tray portion at the stage is provided with an arc-shaped flange formed by burring that pushes the opening peripheral portion of the drain hole outward, and the extension portion is provided at one location of the opening peripheral portion of the drain hole. Above the water return wall It is separated into two flap pieces adjacent to each other by a notch formed so as to be opened, and an opening portion is formed in the arc-shaped flange in an arrangement corresponding to the notch in the opening peripheral portion of the drain hole. As
By bringing the two flap pieces together to close the notch at the stage of bending the two flap pieces, the arcuate flange forms a cylindrical shape that conforms to the inner diameter of the drain pipe, The drain pipe is characterized in that it is connected to the drainage main body part by watertightly fitting to a cylindrical outer peripheral surface formed by the arc-shaped flange.

In the drainage body portion of the drainage body portion, the two flap pieces are brought together so as to close the notch when the two flap pieces are bent, and the drain hole opening peripheral portion on the saucer portion. It is preferable to have a configuration in which a valley fold line extending to the bottom and a drainage gradient partitioned by the valley fold line part are formed.
The valley fold line portion generated in the saucer portion has a sharp valley angle generated by further bending along the delicate lower stripe formed in the pretreatment with respect to the saucer portion. It is good to do.

On the other hand, the method for manufacturing a drain pipe connection structure according to the present invention forms a blank having a saucer part and an extension part extending from the saucer part in the same plane direction, and drains the extension part or saucer part of the blank. Forming a pilot hole in the hole, and forming a notch that extends in the radial direction from the lower hole to the extension portion of the blank and opens outward while separating the extension portion into two flap pieces, An arc-shaped flange projecting outward at the opening peripheral part of the lower hole is formed by performing burring with a deformed punch having an oval cross section in the direction straddling the two flap pieces with respect to the lower hole. The drain hole formed on the inner side of the arc-shaped flange circumscribes one portion of the opening peripheral portion to the upper surface of the tray portion or the inner surface of the water return wall formed by bending the two flap pieces from the tray portion. Be placed The two flap pieces are bent and raised from the tray part, and the two flap pieces are bent together to bring the arc-shaped flange into the inner diameter of the drain pipe so as to close the notch. The drain pipe is fitted in a watertight manner on the outer peripheral surface of the arc-shaped flange having the cylindrical shape.

  In the step of forming the water return wall by bending and raising two flap pieces per blank, the V groove is previously formed on a bending die having a V groove matched to the bending angle between the saucer portion and the water return wall. A relief recess is formed by digging a portion extending from the groove center to the groove wall on one side according to the outer width of the arc-shaped flange, and when the two flap pieces are bent up, the arc-shaped flange is The blank is set on the bending die so that it fits into the relief recess without any backlash and the outer corner position of the tray portion and the water return wall matches the groove center of the V groove in the bending die. The two flap pieces may be bent to form the water return wall.

  In the drain pipe connection structure and the manufacturing method thereof according to the present invention, in the structure in which the drain pipe is connected to a drain main body such as a drain pan, a drainage basin, and a drainage basin, manufacture is easy and the manufacturing cost is reduced It is possible to prevent generation of residual water that cannot be drained to prevent generation of mold, rust, etc., and to solve all the various problems related to freezing of residual water.

It is a perspective view of a drainage body part and a drain pipe which were connected by adopting a drainage pipe connection structure according to the present invention. It is a sectional side view (AA sectional drawing of FIG. 1) of a drain hole. It is front sectional drawing (BB sectional drawing of FIG. 1) of a saucer part. It is the perspective view which showed the arc-shaped flange by a burring process. It is the top view which showed the extension part used as the origin which forms a water return wall (two flap pieces). FIG. 2 shows a part of the manufacturing method according to the present invention over time, (A) is a perspective view of a stage where a pilot hole and a notch are provided in a blank, and (B) is a burring process performed on the pilot hole. (C) is a perspective view of a stage where two flap pieces are bent and raised. It is front sectional drawing which showed the press apparatus for performing a burring process. It is sectional drawing of a deformed punch. It is front sectional drawing which showed the implementation condition of the burring process. It is front sectional drawing which showed the bender process for forming a water return wall. It is the perspective view which showed the bending die employ | adopted by bender processing.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 to 3 show an embodiment in which a drain pipe 2 is connected to a rectangular drainage main body 1 in a horizontal manner by a drain pipe connection structure according to the present invention. The drainage main body 1 and the drain pipe 2 are both made of metal, but the drain pipe 2 is connected to the drainage main body 1 by non-welding.

The drainage main body 1 includes a tray portion 5 and three walls (a central water return wall 6 and side walls 7 adjacent to both sides of the water return wall 6 that surround the tray portion 5 in a U-shape along three outer peripheral positions. 7). A drain hole 8 penetrating through the water return wall 6 is formed in a central wall of the three walls, that is, the water return wall 6 at a portion closer to the rising edge. The drain hole 8 and the drain pipe 2 described above are completely aligned with each other and communicate with each other.

The drain hole 8 has an arrangement in which one part of the opening peripheral portion is circumscribed by a bent inner edge (an inner corner viewed from the tray portion 5 side) formed by the upper surface of the tray portion 5 and the inner surface of the water return wall 6. . Therefore, in the process from the saucer part 5 into the drain hole 8, there is no step that becomes a resistance against the drainage flow.
Further, the tray portion 5 is provided with a boat-bottom drainage gradient which is concentrated while being inclined downward toward the drain hole 8 in the entire region. This drainage gradient is provided with a plurality of lines provided extending to the two corners of the saucer 5 with the position where the opening peripheral portion of the drain hole 8 and the inner corner of the saucer 5 are circumscribed as apexes (see FIG. In the illustrated example, four trough crease portions 12 are formed so that the tray portion 5 is partitioned into a plurality of triangular inclined surfaces. Specifically, each valley crease 12 has a radial arrangement that opens in a V shape from the drain hole 8, and each V-shaped wing has two more valley crease 12 a, The leg is opened to 12b.

  Each valley crease 12 has a sharp trough angle (position indicated by an open arrow in FIG. 3) on the upper surface side of the saucer 5. Therefore, water drops received at a plurality of dispersed points on the tray 5 are efficiently collected in the valley folds 12 to effectively exhibit the surface tension of the water to form a coherent water drop, which is a straight and reliable flow down. The action of obtaining the state and facilitating induction to the drain hole 8 is obtained. In addition, visually, a clear lane marking such as cut glass is conspicuous, and it has the effect of substantially increasing the drainage capacity.

  As shown in FIGS. 2 and 3 (see also FIG. 4), the water return wall 6 is provided with an arc-shaped flange 15 so as to protrude outward along the opening peripheral portion of the drain hole 8. Yes. The arc-shaped flange 15 has a cylindrical shape corresponding to the inner diameter of the drain pipe 2 (substantially the same outer diameter), and the drain is formed so that the arc-shaped flange 15 is in surface contact with the surroundings in a watertight manner. The tube 2 is externally fitted. The arc-shaped flange 15 is integrally formed with the water return wall 6 by burring.

  The adhesive pipe is applied between the outer peripheral surface of the arc-shaped flange 15 and the inner peripheral surface of the drain pipe 2, or the drain pipe 2 is press-fitted (forcibly fitted) into the arc-shaped flange 15 to connect the two. Is achieved without welding. If there are special circumstances, this outer fitting may be fixed by spot welding or other means, but this may lead to difficulties in operation, inconvenience, poor appearance, and high costs. There is no need to bother to employ no welding.

As described above, the drain hole 8 has an arrangement in which the opening peripheral portion is circumscribed to the inner corner of the tray portion 5, and naturally, the arcuate flange 15 is the lowest portion of the inner peripheral surface. The upper surface of the lower end portion is formed so as to be flush with the upper surface of the saucer portion 5.
As shown in FIGS. 5 and 6, the water return wall 6 is formed by bending and raising an extension portion 17 provided in the same plane direction with respect to the saucer portion 5, and therefore the saucer portion 5 and the water return wall 6. Are in an integral relationship with each other. The extension 17 (the state before bending) of the water return wall 6 is separated as two adjacent flap pieces 17a and 17a by providing a notch 18 so as to match the position of the drain hole 8. It is.

In other words, the notch 18 is formed by opening one portion of the opening peripheral portion of the drain hole 8 to above the water return wall 6. Accordingly, an opening portion 20 corresponding to the notch 18 is formed in the arc-shaped flange 15 provided in the opening peripheral portion of the drain hole 8.
The notch 18 has an opening shape that expands upward so that the opening width gradually increases as the water return wall 6 moves from a low position to a high position. Therefore, when the water return wall 6 is formed by bending the two flap pieces 17a, 17a, the two flap pieces 17a, 17a are moved toward the direction in which the notch 18 (opening portion 20) is closed. Try to match. As a result, it is possible to form a boat-bottom drainage gradient on the saucer unit 5 (a plurality of valley crease portions 12 are respectively generated with valley angles). When the two flap pieces 17a, 17a are brought together, the arc-shaped flange 15 has a cylindrical shape as described above, and the drain hole 8 formed inside the arc-shaped flange 15 becomes a circular hole.

The side wall 7 is also formed by bending and raising the extension 23 provided in the same plane direction with respect to the saucer portion 5, and therefore the saucer portion 5 and the side wall 7 are in an integral relationship with each other. Since the corner connection part by the water return wall 6 and the side wall 7 is present at a higher position from the drain hole 8 as a result of providing the drainage gradient with respect to the tray part 5 as described above, Is not essential. Of course, it is also possible to form a watertight joint by applying a caulking agent or the like.

In the drain pipe connection structure described above, the drain pipe 2 is connected to the drain main body 1 by external fitting (can be non-welded) or drained from the tray 5 to the drain pipe 2 through the drain hole 8. The fact that there is no level difference that becomes a resistance to the drainage flow in the process of leading to is achieved by adopting the following innovative manufacturing method.
Hereinafter, the manufacturing method of this drain pipe connection structure is demonstrated, combining the structure of the manufacturing equipment used for this manufacturing method.

First, as shown in FIG. 6A, a blank 25 having a tray part 5 and an extension part 17 projecting from the dish part 5 in a flush direction is formed. As the blank 25, for example, SPCC having a thickness of 0.6 mm can be used.
And the lower hole 26 is formed with respect to the extension part 17 of this blank 25 as a preparation for forming the drain hole 8. The lower hole 26 is preferably a circular hole. Further, a notch 18 is formed which extends from the lower hole 26 in the radial direction thereof, passes through the extension portion 17 and opens outward. By forming the notch 18, the extension 17 is separated into two flap pieces 17a and 17a adjacent to each other.

The formation of the lower hole 26 and the formation of the notch 18 may be performed simultaneously by, for example, one shot using a punching press device. In some cases, a procedure such as forming the prepared hole 26 after the formation of the notch 18 may be used, and the formation procedure is not limited at all.
Next, as shown in FIG. 6B, burring is performed on the lower hole 26 of the drain hole 8. For example, the burring process is performed by setting a deformed punch 31 and a die 32 corresponding to the deformed punch 31 to the press device 30 shown in FIG. In the illustrated example, the deformed punch 31 is fixed to the die set 35 of the lower die 34 via the punch plate 36 and the stripper plate 37, and the die set 41 of the upper die 40 is fixed to the die set 41 via the backing plate 42. 32 is fixed.

The stripper plate 37 of the lower die 34 is backed up by an air damper (not shown but having a balloon structure capable of controlling the internal pressure) provided below the die set 35 via a stripper bolt 45. There is an upward impact.
In the air damper, when the lower die 34 and the upper die 40 are combined (the arc-shaped flange 15 is squeezed out by fitting the die 32 and the deformed punch 31), the blank 25 is reduced by the amount of reduction of the die 32. Is not only clamped (pressed) with the stripper plate 37, but also the blank 25 is provided with a back pressure toward the die 32, so that the blank 25 is fixedly held. is there.

In other words, the lower hole 26 of the blank 25 is opened at one portion of the opening peripheral portion by the notch 18, but the engagement (positional restraint) with the deformed punch 31 is reduced at this opening portion. As a cause, this is a measure for preventing the blank 25 from being displaced.
The higher the internal pressure of the air damper, the larger the amount of squeezing of the arc-shaped flange 15 (the protruding length from the water return wall 6). However, if it is too large, the tip of the arcuate flange 15 may break so as to divide its circumferential direction, and a defect (so-called “flower bloom phenomenon”) that causes the flower to open may occur. The person knows through trial and error. In this embodiment, the internal pressure of the air damper is set to 0.5 kgf / cm ^{2 so} that the squeezing amount of the arc-shaped flange 15 is 5 to 7 mm.

The odd-shaped punch 31 is formed with a straight shaft portion and a tapered head portion that becomes thinner toward the tip, and the shaft portion of the straight shaft portion is formed in an oval shape as shown in FIG. Has been. The tapered head has a rotationally symmetric shape with the axis of the straight shaft portion as the rotation center P.
The odd-shaped punch 31 is fixed to the die set 35 so that the direction of the major axis of the oval in the shaft section is aligned with the direction of the blank 25 across the two flap pieces 17a and 17a (the left-right direction in FIG. 5). To do. The oval cross-sectional shape of the odd-shaped punch 31 is substantially equal to a shape in which the inner diameter of the drain hole 8 is expanded laterally corresponding to the notch width of the notch 18 separating the two flap pieces 17a, 17a. For this reason, when the water return wall 6 is formed by bending the two flap pieces 17a and 17a in the blank 25, the notch 18 is closed (when the two flap pieces 17a and 17a are brought together). ), The drain hole 8 formed inside the arcuate flange 15 becomes a circular hole.

When performing the burring process, when the blank 25 is set on the lower die 34, the lower hole 26 of the blank 25 is inserted into the tapered head of the deformed punch 31. Since the tapered head of the deformed punch 31 is rotationally symmetric and the lower hole 26 is a circular hole, the positioning of the blank 25 can be made unambiguous and highly accurate.
Next, the press apparatus 30 is operated, and the lower mold 34 and the upper mold 40 are combined. At this time, the blank 25 is clamped between the upper and lower sides of the stripper plate 37 and the die 32, and the back pressure of the air damper mounted on the stripper plate 37 is applied to this clamping state. Therefore, the arc-shaped flange 15 comes to be formed in the opening peripheral part with respect to the pilot hole 26 of the blank 25, as shown in FIG.

  Here, the outer peripheral surface of the arc-shaped flange 15 being squeezed out is restrained in a cylindrical shape by the die 32 and is squeezed. In addition, since back pressure is applied by the air damper mounted on the stripper plate 37 during the ironing, the arc-shaped flange 15 is maintained in a state where play (backlash) and the like are not allowed. For these reasons, the arc-shaped flange 15 is finished into an elliptical cylindrical shape with high accuracy in terms of dimensions and shape on both the inner and outer peripheral surfaces thereof. Naturally, the “flower bloom phenomenon” does not occur in the arc-shaped flange 15. Thus, as shown in FIG. 6B, an arcuate flange 15 by burring can be provided on the opening peripheral portion of the drain hole 8.

Next, as shown in FIG. 6 (C), a bender process for bending and raising the two flap pieces 17a, 17a of the blank 25 is performed to form the water return wall 6 rising from the tray portion 5.
This bender processing is performed, for example, by setting the bending die 50 shown in FIGS. 10 and 11 to a bender device (not shown). The bending die 50 has a V-groove 51 that matches a bending angle (for example, 90 ° but is not limited) between the tray portion 5 and the water return wall 6, and the V-groove The relief recess 52 is formed so as to dig a part extending from the groove center 51 to the groove wall on one side. The escape recess 52 has a semicircular portion circumscribing the groove center of the V-groove 51, and the inner width W of the portion where the groove wall on one side is dug in accordance with the outer width of the arc-shaped flange 15. Is formed.

  Then, the blank 25 is set on the bending die 50 having such a configuration, and the bending punch 55 is pressed down to the blank 25, whereby the two flap pieces 17a and 17a are bent and raised. The blank 25 is set in such a manner that the arcuate flange 15 fits into the relief recess 52 without backlash in the process of bending and raising the two flap pieces 17a, 17a. Further, in the process of bending and raising the two flap pieces 17 a, 17 a, the outer corner position formed by the tray portion 5 and the water return wall 6 is arranged to coincide with the groove center of the V groove 51.

  When the two flap pieces 17a and 17a are bent and raised, the semicircular portion of the relief recess 52 (the portion circumscribing the groove center of the V-groove 51) has an upper edge that is approximately a half circumference of the outer surface of the arcuate flange 15. Will come into contact with and support. Further, after the two flap pieces 17a, 17a are bent and raised (that is, after the water return wall 6), the inner end of the water return wall 6 and the saucer portion 5 are bent, and the pointed end of the bending punch 55 is firmly held. . Therefore, the outer peripheral surface of the arc-shaped flange 15 and the lower surface of the saucer portion 5 are neatly connected and shaped to be flush with each other.

This places one opening peripheral portion of the drain hole 8 so as to circumscribe the bent inner edge of the upper surface of the saucer portion 5 and the inner surface of the water return wall 6, and the inner peripheral surface of the arcuate flange 15 It works extremely effectively in connecting the lowest part to the upper surface of the saucer part 5.
After the two flap pieces 17a and 17a are bent and raised in this manner, the two flap pieces 17a and 17a are brought together so that the notch 18 (opening portion 20 of the arcuate flange 15) is closed. .

  At this time, a drainage gradient having a boat bottom shape is simultaneously given to the saucer unit 5. In order to generate the drainage gradient in the saucer part 5, as shown in FIG. 6, a plurality of valley crease parts 12 are formed in advance on the saucer part 5. The valley crease portion 12 forms a delicate lower streak with respect to the saucer portion 5 as pre-processing using a flat chisel-shaped punch tool (either manual operation or mechanical operation using a turret punch press or the like). Further, a bend is added along the lower line.

  By adopting such a procedure, it is possible to generate the valley fold line portion 12 having a sharp valley angle. The valley crease 12 has a clear fold line that is not comparable to a streak having a slow bending angle obtained when bending is applied from the beginning without forming a lower streak. As a reference, a slow bending bar formed only by bending without forming the lower line can cause the stagnation in the middle of the flow even though the drainage can be brought to the vicinity. There is a significant difference in the operational effect from the valley crease portion 12 of the present invention in which a straight and reliable flow-down state is obtained.

  By providing the valley crease 12 on the tray 5 in this way, a bottom-shaped drainage gradient can be formed on the tray 5 and the two flap pieces 17a and 17a are brought together. It is something that can be done. At the same time, the arc-shaped flange 15 has a cylindrical shape corresponding to the inner diameter of the drain pipe 2, and the drain hole 8 formed inside the arc-shaped flange 15 is a circular hole.

Finally, the drain pipe 2 is fitted on the outer peripheral surface of the arcuate flange 15. You may make it apply | coat an adhesive agent between the outer peripheral surface of the circular-arc-shaped flange 15 and the inner peripheral surface of the drain pipe 2 as needed.
Such a method of manufacturing a drain pipe connection structure is easy to manufacture and can reduce the manufacturing cost. Further, the manufactured drainage pipe connection structure prevents generation of residual water that cannot be drained, and can prevent generation of mold, rust, and the like. Moreover, since there is no generation of residual water, all the various problems related to freezing of the residual water are all solved.

The present invention is not limited to the above embodiment.
For example, in the drainage main body 1, the drain hole 8 is not limited to be provided on the water return wall 6, but can be provided on the tray 5. In this case, the drain hole 8 is disposed so that a part of the opening peripheral portion is circumscribed to the inner corner (the outer edge as the tray portion 5) where the water return wall 6 rises from the tray portion 5. Naturally, the arc-shaped flange 15 is formed so as to protrude downward from the tray portion 5 with respect to the opening peripheral portion of the drain hole 8.

In the drainage main body 1, it is sufficient that the tray 5 is provided with at least one water return wall 6. In addition, you may make it provide the water return wall 6 and the side wall 7 so that all four rounds of the saucer part 5 may be surrounded.
The drainage main body 1 is not limited to a drain pan, and can be implemented as connecting drainage pipes such as a drainage basin and a drainage basin.

The number and arrangement of the valley crease portions 12 provided in the tray portion 5 are not limited.
In the drain pipe connection structure and the manufacturing method thereof according to the present invention, the drain pipe 2 can be connected to the drain main body 1 by external fitting (non-welding is also possible), so the material for forming the drain pipe 2 is It is not limited at all. Therefore, for example, the drain pipe 2 can be made of resin in addition to being made of metal (for example, SS400).

DESCRIPTION OF SYMBOLS 1 Drainage body part 2 Drain pipe 5 Receptacle part 6 Water return wall 7 Side wall 8 Drain hole 12 Valley crease part 15 Arc-shaped flange 17 Extension part 17a Flap piece 18 Notch 20 Opening part 23 Extension part 25 Blank 26 Lower hole 30 Press Equipment 31 Deformed punch 32 Die 34 Lower die 35 Die set 36 Punch plate 37 Stripper plate 40 Upper die 41 Die set 42 Backing plate 45 Stripper bolt 50 Bending die 51 V groove 52 Escape recess 55 Bending punch

Claims (5)

Pan portion and provided with a water flashing wall extension formed causing bending provided in the pan section, drain hole penetrating the water flashing wall thereby enclosing the one position of the opening periphery on the upper surface of the pan portion a drain body portion comprising formed in the arrangement drain hole is to circumscribe the one position of the opening periphery to the inner surface of the water flashing wall penetrating or the pan portion is formed in the arrangement,
A drain pipe that communicates with the drain hole of the drainage body portion and is connected in an outward projecting manner;
An arcuate flange formed by burring that pushes the opening peripheral portion of the drain hole outward is provided in the receiving portion at the stage provided with the extension portion or the extension portion before bending ,
The extension part is separated into two flap pieces adjacent to each other by a notch formed so as to open one part of the opening peripheral part in the drain hole to above the water return wall,
The arc-shaped flange has an opening portion formed in an arrangement corresponding to the notch in the opening peripheral portion of the drain hole,
A cylinder conforming to the inner diameter of the drain pipe by the arc-shaped flange by bringing the two flap pieces together so as to close the notch when the two flap pieces are bent and raised.
As the shape is formed,
The drain pipe connection structure according to claim 1, wherein the drain pipe is connected to the drainage main body portion by watertightly fitting to a cylindrical outer peripheral surface formed by the arc-shaped flange. In the drainage body portion of the drainage body portion, the two flap pieces are brought together so as to close the notch when the two flap pieces are bent, and the drain hole opening peripheral portion on the saucer portion. The drainage pipe connection structure according to claim 1 , wherein a valley crease portion extending to the bottom and a drainage gradient partitioned by the valley crease portion are formed. The valley crease portion generated in the tray portion has a sharp valley angle generated by further bending along the delicate lower stripe formed in the pretreatment with respect to the tray portion. The drain pipe connection structure according to claim 2, wherein: Forming a blank having a saucer part and an extension part extending from the saucer part in a flush direction,
While forming a pilot hole for the drain hole with respect to the extension part or saucer part of the blank,
Forming a notch that extends in the radial direction from the lower hole with respect to the extension of the blank and opens outward while separating the extension into two flap pieces,
An arc-shaped flange that protrudes outward at the opening peripheral part of the lower hole is formed by performing burring with a deformed punch having an oval cross section in the direction straddling the two flap pieces with respect to the lower hole. Let
A drain hole formed inside the arc-shaped flange is arranged so as to circumscribe one part of the opening peripheral part to the upper surface of the saucer part or the inner surface of a water return wall formed by bending the two flap pieces from the saucer part. Bending the two flap pieces from the saucer so that
In bending up of the two flap pieces, the arc-shaped flange is made into a cylindrical shape conforming to the inner diameter of the drain pipe by bringing the two flap pieces together to close the notch,
A drain pipe connection structure manufacturing method, wherein the drain pipe is water-tightly fitted to the outer peripheral surface of the circular-arc-shaped flange having a cylindrical shape. In the step of forming the water return wall by bending the two flap pieces per blank,
For a bending die having a V-groove matched to the bending angle between the tray portion and the water return wall, a portion extending from the groove center to the groove wall on one side of the V-groove is dug in advance according to the outer width of the arc-shaped flange. I made a relief recess like that,
When the two flap pieces are bent and raised, the arc-shaped flange fits into the relief recess without rattling, and the outer corner position of the tray portion and the water return wall is at the groove center of the V groove in the bending die. in order to to Consistently, claim 4 sets the blank with respect to said bending die, characterized in that characterized in that to form the two bending the water flashing wall performed raised flap piece The manufacturing method of the drainage pipe connection structure of description.

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