JP2007187189A - Screw fastening structure and screw fastening method in thin metal plate - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform sound fastening without causing failure fastening, while improving fastening torque, by realizing a fastening structure press-fitted to a reentrant part forming surface by pushing a lower end edge part of a tip plate thickness surface of a dished lip in a lower reentrant part of a root surface between upper-lower male threads of a screw. <P>SOLUTION: This screw fastening structure in a thin metal plate has a structure press-fitted to the reentrant part forming surface by pushing the lower end edge part 21" of the tip plate thickness surface 21' in the reentrant part 17' formed of the root surface 18 between the upper-lower male threads 14 and an upper side surface 16 of the lower male thread 14, when screwing the screw 10 in a prepared hole 19, by forming the tip plate thickness surface 21' as an inclined face having a biting angle toward the lower edge part 21" of a parallel surface or the plate thickness surface 21' to the axis X of the prepared hole 19, while capturing the tip plate thickness part between the upper-lower male threads 14 of the screw 10, by screwing the screw 10 in the prepared hole 19 defined by the tip plate thickness surface 21' of the dished lip 21 formed on the thin metal plate 20. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a screw fastening structure used when a part or the like is attached to a thin metal plate such as a home appliance or an automobile without a nut.

In Patent Document 1, as shown in FIGS. 2 and 3, a plate-shaped lip 21 is formed on a thin metal plate 20, and a pilot hole 19 defined by the thick plate surface of the plate-shaped lip 21. There is provided a screw fastening structure in a thin metal plate in which the screw 10 is screwed into the plate, the tip plate thickness portion of the dish-shaped lip 21 is captured between the upper and lower male screw threads 14 of the screw 10 and the fastening is performed. .
Japanese Patent Publication No. 5-9647

  Thus, the above-described screw fastening structure is compared with a fastening structure in which a cylindrical lip is formed by burring a cylindrical pilot hole in a thin metal plate, and a female screw is screwed while self-tapping using a tapping screw on the cylindrical lip, A good fastening effect can be obtained without tapping, and there is an advantage of effectively eliminating the problem that the cylindrical lip is cracked or broken to cause a fastening failure.

  On the other hand, the front plate thickness surface of the dish-shaped lip 21 in Patent Document 1 always forms a plane perpendicular to the plate surface and the back surface (the surface and the back surface of the dish-shaped lip 21). In other words, a surface having a clearance angle toward the lower edge with respect to the axis of the pilot hole 19 is formed.

  Conventionally, as shown in FIG. 1A, the plate-shaped lip is formed by first punching a pilot hole 19 having a required diameter in a flat plate of a thin metal plate 20, and then, as shown in FIG. 19 is the simplest technically to project the peripheral portion of the plate 19 toward the back surface of the plate, and the tip plate thick surface 21 'of the dish-shaped lip 21 is necessarily perpendicular to the plate surface and the back surface. On the other hand, a surface having a clearance angle toward the lower edge with respect to the axis X of the pilot hole 19 is generated.

  In addition, it is difficult to avoid the phenomenon that R1 <R2 between the diameter R1 of the pilot hole 19 punched out on the flat plate and the diameter R2 of the pilot hole 19 after the plate-shaped lip 21 is formed.

  Therefore, the diameter R1 of the pilot hole 19 punched into the flat plate causes an adverse phenomenon that the diameter is slightly increased by the protrusion of the dish-shaped lip 21. This diameter expansion phenomenon has a risk of causing gap formation (adhesion failure) with the valley surface between the male screw threads 14 of the screw 10.

  The tip plate thick surface 21 'of the dish-shaped lip 21 generates a surface having a clearance angle toward the lower edge with respect to the axis X of the prepared hole 19, and the diameter R1 of the prepared hole 19 punched into a flat plate and the dish shape. The phenomenon in which the diameter R2 of the pilot hole 19 after the protrusion of the lip 21 becomes R1 <R2 is as shown in FIG. A gap is generated between the valley surfaces between the male screw threads 14, and it is difficult to obtain close contact between the valley surface and the tip plate thickness surface 21 ′, and there is a concern that the fastening force may be adversely affected. There is a risk that it may cause an inclination and cause a fastening failure.

  The present invention pays attention to the above-mentioned problems of the thin metal plate in the above-mentioned conventional example, and provides a screw fastening structure and a fastening method for accurately solving the problems.

  As a means for this, a dish-shaped lip is formed on a thin metal plate, a screw is screwed into a pilot hole defined by the thick-plate surface of the dish-shaped lip, and the thick-plate portion of the dish-shaped lip is threaded. In a screw fastening structure in a thin metal plate that is captured between the upper and lower male screw threads of the above structure and fastened, the tip plate thickness surface of the countersunk lip is parallel to the axis of the pilot hole or the lower edge of the tip plate thickness surface The tip plate is thick at the corner formed by the valley surface between the upper and lower male screw threads and the upper side surface of the lower male screw thread when the screw is screwed into the pilot hole. It is conceived of a configuration in which the lower end edge portion of this is pressed and crimped to the entry corner forming surface.

  The above-mentioned screw fastening structure forms a bottomed plate-shaped upset on a flat plate of a thin metal plate, punches out the bottom plate of the plate-shaped upset to form a plate-shaped lip, and lowers the thickness of the tip plate of the plate-shaped lip. A plane parallel to the axis of the hole or an inclined surface having a bite angle toward the lower edge of the thick plate at the tip, and when the screw is screwed into the lower hole, the valley surface between the upper and lower male threads of the screw and lower This is achieved by a method in which the lower end edge portion of the front end plate thick surface is pushed into the entrance corner portion formed by the upper side surface of the male screw thread and is crimped to the entrance corner formation surface.

  According to the present invention, while obtaining the effect of capturing the tip plate thick portion of the countersunk lip in the above-mentioned Patent Document 1 between the upper and lower male screw threads, the upper and lower male screw of the screw is used as the lower end edge portion of the tip plate thick surface of the countersunk lip. A fastening structure is obtained in which the lower end edge portion of the tip plate thick surface is pressed into the corner formed by the valley surface of the mountain and the upper side surface of the lower male thread, and is crimped to the surface of the corner of the joint. It is possible to effectively solve the problem that the gap generated between the thick plate surface of the lip and the valley surface of the screw and the diameter of the pilot hole expand.

  The best mode for carrying out the present invention will be described below with reference to FIGS.

  As shown in FIG. 3, the screw 10 has a screw head 12 at one end of a shaft portion 13 on which a male thread 14 is formed, and a conical pointed head 11 at the other end.

  A low-profile male thread 14 ′ is formed on the peripheral surface of the large-diameter portion of the pointed head 11, and the height of the male thread is gradually increased from the low-profile male thread 14 ′. A male thread 14 having a normal height is formed on the peripheral surface.

  As shown in FIG. 4, the upper side surface 16 of the male thread 14 has an inclined surface in which an angle θ3 with respect to a horizontal line orthogonal to the axis of the screw 10 is a slight downward slope of 7 to 11 degrees toward the tip of the male thread 14. The lower surface 15 of the male screw thread 14 is an inclined surface in which an angle θ2 with respect to a horizontal line orthogonal to the axis of the screw 10 is an upward gradient of 30 to 40 degrees toward the tip of the male screw thread 14.

  As a preferred example, the angle θ3 is set to 9 degrees, and the angle θ2 is set to 36 degrees. On the other hand, as shown in FIG. 5, the inclination angle θ1 with respect to the horizontal line orthogonal to the axis X of the pilot hole 19 of the dish-shaped lip 21 described below is set to approximately 25 to 35 degrees.

  Between the external thread 14 of the shaft portion 13, there is a wide valley surface 18 parallel to the axis of the shaft portion 13, and the width W in the axial direction of the wide valley surface 18 is set in the direction of the pilot hole axis X shown in FIG. The width is equal to or less than the width t of the front plate thickness surface 21 ′ of the dish-shaped lip 21.

  In other words, the width W in contact with the valley surface 18 of the wide groove 17 between the male screw threads 14 is made slightly narrower than the width t of the distal plate thickness surface 21 '. That is, W ≦ t is set.

  On the other hand, the front plate thickness surface 21 ′ of the dish-shaped lip 21 is parallel to the axis X of the pilot hole 19. Alternatively, when the tip plate thickness surface 21 ′ of the dish-shaped lip 21 is an inclined surface having a bite angle toward the lower edge portion 21 ″ of the tip plate thickness surface 21 ′ and the screw 10 is screwed into the pilot hole 19. The lower end edge portion 21 ″ of the tip plate thick surface 21 ′ is pushed into a corner 17 ′ formed by the valley surface 18 between the upper and lower male screw threads 14 and the upper side surface 16 of the lower male screw thread 14 of the screw 10. It is configured to be crimped to the entrance corner forming surface.

  Further, the diameter R1 of the pilot hole 19, that is, the diameter R1 of the tip plate thick surface 21 'of the dish-shaped lip 21, is equal to or slightly larger than the diameter of the shaft portion 13 of the screw 10.

  Thus, as shown in FIG. 5A and FIG. 6, the tip plate thickness surface 21 ′ of the dish-shaped lip 21 is parallel to the axis X of the pilot hole 19, and the screw 10 is screwed into the pilot hole 19. The tip plate thick portion of the countersink lip 21 is captured between the upper and lower male threads 14 of the screw 10 and at the same time the tip plate thick surface 21 'of the countersink lip 21 is parallel to the axis X of the pilot hole 19. The lower edge portion 21 ″ of the screw 10 is pushed into a corner 17 ′ formed by the valley surface 18 between the upper and lower male threads 14 of the screw 10 and the upper side surface 16 of the lower male thread 14 and is crimped to the surface where the inner corner is formed. Realize the configuration.

  Alternatively, as shown in FIGS. 5B and 6, the plate thickness lip 21 ′ of the dish-shaped lip 21 is slightly inclined with respect to the axis X of the pilot hole 19 by an angle θ 4 that is a biting angle. Therefore, by screwing the screw 10 into the lower hole 19, the tip plate thickness portion of the countersunk lip 21 is captured between the upper and lower male threads 14 of the screw 10, and at the same time, the biting angle with respect to the axis X of the lower hole 19 is set. The bottom edge portion 21 ″ of the tip plate thick surface 21 ′ of the countersunk lip 21 is formed by a corner 17 formed by a valley surface 18 between the upper and lower male screw threads 14 of the screw 10 and an upper surface 16 of the lower male screw thread 14. Improve the realization of a structure that is positively pressed into the ′ and crimped to the surface where the corners are formed.

  2 is formed by the method shown in FIG. 2 which is the biting angle of the thickened surface 21 'of the tip lip 21. That is, it can be formed by a restoring force due to the material of the thin metal plate 20 of the lip 21 after punching the pilot hole 19.

  More specifically, as shown in FIG. 2A, a bottomed plate-like upset 19 'is formed on the flat plate of the thin metal plate 20, and the bottom plate of the plate-type upset 19' is punched out as shown in FIG. 2B. A hole 19 is formed, and the distal end plate thick surface 21 ′ is made lower with respect to the axis X of the lower hole 19 by the slight restoring force of the dish-shaped lip 21 after the formation of the lower hole 19. An inclined surface having a biting angle toward 21 ″ is generated.

  According to the present invention, the tip plate thick surface 21 ′ of the dish-shaped lip 21 is a plane parallel to the axis X of the pilot hole 19 or an inclined surface having a biting angle toward the lower edge portion 21 ″ of the tip plate thick surface. When the screw 10 is screwed into the pilot hole 19, the above-described corner 17 'formed by the valley surface 18 between the upper and lower male screw threads 14 of the screw 10 and the upper side surface 16 of the lower male screw thread 14 is described above. A configuration is achieved in which the lower end edge portion 21 ″ of the distal end plate thickness surface 21 ′ is pressed and pressed against the surface where the entrance corner is formed.

  The lower end edge portion 21 ″ of the tip plate thick surface 21 ′ of the dish-shaped lip 21 is pushed into the entrance corner portion 17 ′ to be slightly crushed and deformed to ensure a pressure-bonded state with respect to the entrance corner formation surface. The tip plate thick surface 21 'is positively pressed against the valley surface 18 between the male screw threads 14 of the screw 10 as much as possible, and the reaction force of the dish-shaped lip 21 accompanying the screwing of the screw 10 is ensured. Increase the tightening torque.

  In addition, the adhesiveness between the valley surface 18 and the tip plate thick surface 21 'of the dish-shaped lip 21 is ensured as much as possible, and the gap generation and the inclination of the screw 10 in the same place are effectively prevented, and the fastening failure occurs. It is possible to prevent the occurrence of sound fastening.

A and B are sectional views for explaining a conventional method for forming a dish-shaped lip. A and B are sectional views illustrating a method for forming a dish-shaped lip according to the present invention. The side view which illustrates the screw concerning the present invention. The expanded sectional view of the external thread of the said screw. A is a cross-sectional view showing a case where the tip plate thickness surface of the prepared hole formed by the countersunk lip according to the present invention is parallel to the axis of the prepared hole, and B is a tip of the prepared hole formed by the countersunk lip according to the present invention. Sectional drawing which shows the case where a plate | board thickness surface is made into an inclined surface with respect to a pilot hole axis line. Sectional drawing which shows the state which screwed and fastened the screw in the pilot hole of the plate-shaped lip which concerns on this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Screw, 11 ... Point head, 12 ... Screw head, 13 ... Shaft part, 14, 14 '... Male screw thread, 15 ... Lower side surface of male screw thread, 16 ... Same side surface, 17 ... Wide groove, 17' ... Corner , 18 ... Valley surface, 19 ... Pilot hole, 19 '... Dish-shaped installation, 20 ... Thin metal plate, 21 ... Dish-shaped lip, 21' ... Thick surface of the tip of the plate-shaped lip, 21 "... Thickness of the same tip Lower end edge of the surface, R1, R2 ... diameter of the pilot hole, t ... width of the tip plate thick face of the countersunk lip, W ... width of the trough, X ... axis of the pilot hole, θ1 ... inclination angle of the countersunk lip , Θ2: Inclination angle of the lower surface of the male screw thread, θ3: Inclination angle of the upper surface of the male screw thread, θ4: Inclination angle of the thick plate at the tip of the countersunk lip.

Claims (2)

A flat plate lip is formed on a thin metal plate, a screw is screwed into a pilot hole defined by the thick plate surface of the flat plate lip, and the thick plate portion of the flat plate lip is positioned between the upper and lower male screw threads of the screw. In the screw fastening structure in a thin metal plate that is captured and secured by the above-described fastening, the tip plate thick surface of the dish-shaped lip bites into a plane parallel to the axis of the pilot hole or the lower edge of the tip plate thick surface. An inclined surface having a corner, and when the screw is screwed into the pilot hole, a lower edge portion of the thick plate at the leading end is formed at a corner formed by a valley surface between the upper and lower male screw threads and an upper side surface of the lower male screw thread. A screw fastening structure in a thin metal plate characterized by having a structure in which is pressed and pressed against the surface where the same corner is formed. A flat plate lip is formed on a thin metal plate, a screw is screwed into a pilot hole defined by the thick plate surface of the flat plate lip, and the thick plate portion of the flat plate lip is placed between the upper and lower male screw threads of the screw. In the screw fastening method for a thin metal plate that is captured and fastened at the bottom, a bottomed dish-shaped upset is formed on the flat plate of the thin metal plate, and the bottom plate of the dish-shaped upset is punched to form a dish-shaped lip. When the tip plate thickness surface of the dish-shaped lip is parallel to the axis of the pilot hole or an inclined surface having a biting angle toward the lower edge of the tip plate thickness surface, the screw is screwed into the pilot hole. A thin metal, characterized in that a lower edge of the tip plate thick surface is pressed into a corner formed by a valley surface between the upper and lower male threads of the screw and an upper surface of the lower male thread, and is crimped to the corner forming surface. Screw fastening method on the plate.

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