JP2019070248A - Support structure of door panel - Google Patents

Abstract

To provide a support structure of a door panel comprising a sash hanger type runner which exhibits a stable running characteristic by restricting a runner body from tilting forward/backward, right/left or around a hoisting shaft.SOLUTION: A sash hanger type runner 6 having a four-wheeled structure comprises: a runner body 15; a pair of roller shafts 16 inclined in reverse directions to each other; a large diameter roller 17 provided on an inclined upper end side of the roller shaft 16; a small diameter roller 18 provided on an inclined lower end side of the roller shaft 16; and a hoisting shaft 19. A guide rail 2 comprises: a rail body 10; a first rail wall 11 for the large diameter roller 17; and a second rail wall 12 for the small diameter roller 18 on the upper side of the first rail wall 11. When the runner 6 travels and moves, the second rail wall 12 receives the small diameter roller 18 to restrict forward/backward tilting and right/left tilting of the runner body 15. Furthermore, front and rear walls 10a, 10b of the rail body 10 receive each of the rollers 17, 18 to restrict rotation and tilting of the runner body 15 around the hoisting shaft 19.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a door panel support structure provided with a hanger type runner for supporting a door panel. The support structure of a door panel according to the present invention can be applied to a sliding door, a folding door, a rotating door, and the like.

  The runners constituting the door panel support structure according to the present invention arrange the rollers alternately on the front side and the rear side of the runner body to reduce the rail cross-sectional area and the runners. A runner of a kind is known for the suspension device of the patent document 1. There, axles are disposed at the front and back of the laterally long runner body, and rollers are rotatably supported on the front one side and the rear other side of each axle to make the runner a two-wheel structure. The roller has a bearing structure with an inner ring, an outer ring, and a ball.

  In the runner which comprises the support structure of the door panel which concerns on this invention, although a roller axis | shaft is made to incline diagonally, such a runner structure is well-known to the door roller of patent document 2. FIG. There, the axle body is rotatably supported by a support plate that inclines obliquely, and the traveling wheels are fixed to the inclined lower end of the axle body. The traveling wheel is formed in an abacus ball shape, and the lower circumferential surface of the conical traveling surface is supported by the sill groove.

JP, 2009-52196, A (paragraph number 0018, FIG. 1) JP, 2009-138458, A (paragraph number 0018, FIG. 2)

  According to the suspension system of Patent Document 1, since the rollers are disposed on the front one side and the rear other side of the runner main body, it is possible to reduce the distance between adjacent axles when the roller diameter is constant. The simplification of the structure can be realized to reduce the cost. However, since the rollers are arranged alternately with respect to the runner main body, the runner tends to tilt back and forth and right and left when opening and closing the door panel. In addition, when the runner is applied to the folding door, a large tilting moment acts on the runner when the door panel is opened, so one roller floats away from the traveling surface, and the door panel is properly opened and closed. There are times when it can not be done.

  In the door wheel of Patent Document 2, the traveling wheel is formed in an abacus ball shape, and the lower circumferential surface of the conical traveling surface is supported by the sill groove to prevent the traveling wheel from derailing from the sill groove There is. However, since the traveling wheels are alternately arranged with respect to the mounting frame (runner main body), it is easy to tilt when opening and closing the fixture as in the case of the suspension device of Patent Document 1.

  As described above, runners of two-wheeled construction are advantageous in simplifying their structure and downsizing as compared with runners of four-wheeled construction, and have the advantage of being able to move open and close more lightly. Easy to drive in a stable condition is difficult. In addition, while the four-wheeled runner can travel in a stable state while the four rollers are simultaneously transition-guided by the rail wall, the runner main body subjected to external force is back and forth, left and right, or suspended It can tilt significantly around the axis, and in such a case the running condition becomes unstable. The inventor of the present invention has proposed the present invention as a result of re-examining the features and disadvantages of the two-wheeled runner and the four-wheeled runner as described above and searching for a runner structure that can utilize both features. It is.

  An object of the present invention is to provide a door panel support structure capable of exhibiting a stable running characteristic even when the runner body can be moved open and closed smoothly and the runner body is tilted back and forth, left and right, or around a support shaft. is there.

  The support structure of the door panel according to the present invention comprises a guide rail 2 mounted on the opening frame 1 and a runner 6 of four wheel structure suspended and guided by the guide rail 2. The runner 6 has a runner main body 15, a pair of roller shafts 16 disposed adjacent to the main body 15, a large diameter roller 17 and a small diameter roller 18 supported by each roller shaft 16, and a suspension for suspending and supporting the door panel P. A holding shaft 19 is provided. As shown in FIG. 1, the pair of roller shafts 16 are inclined in mutually opposite directions with respect to the horizontal front and rear central axes of the runner main body 15, and the large diameter roller is inclined to the inclined upper end side of the roller shaft 16 The small diameter roller 18 is supported on the lower end side of the roller shaft 16 at the inclined lower end. The guide rail 2 is provided above the first rail wall 11 with a rail main body 10 having a C-shaped cross section, a pair of front and rear first rail walls 11 for transitionally guiding the large diameter roller 17, and a small diameter roller 18 A pair of front and rear second rail walls 12 are provided for guiding. The roller circumferential surface 18 a of the small diameter roller 18 is received by the second rail wall 12, and the roller circumferential surfaces 17 a and 18 a of the large diameter roller 17 or the small diameter roller 18 are received by the front and rear walls 10 a and 10 b of the rail main body 10 It is characterized in that it is configured.

  In a state where the large diameter roller 17 is supported by the first rail wall 11, the roller circumferential surface 18a of the small diameter roller 18 and the front and rear second rail walls 12 face each other with the clearance C1 therebetween. When the large diameter roller 17 is supported by the first rail wall 11, the roller circumferential surfaces 17a and 18a of the large diameter roller 17 and the small diameter roller 18 and the front and rear walls 10a and 10b of the rail main body 10 have a clearance C2 between them. Are facing each other. The second rail wall 12 restricts the runner body 15 subjected to the external force from tilting back and forth and tilting left and right beyond the clearance C1. Furthermore, the runner 6 restricts the clearances C1 and C2 by the front and rear walls 10a and 10b of the rail main body 10 restricting the runner body 15 that receives the external force from rotating and tilting over the clearance C2 around the suspending shaft 19. Regulates movement in the three-dimensional direction beyond.

  A roller accommodating portion 20 for accommodating the large diameter roller 17 and a roller accommodating portion 21 for accommodating the small diameter roller 18 are concavely formed on the front and rear surfaces of the runner main body 15 with the central wall 22 supporting the roller shaft 16 interposed therebetween. There is.

  The overhang dimension of the second rail wall 12 is set smaller than the overhang dimension of the first rail wall 11, and the upper circumferential surface of the large diameter roller 17 is located above the upper surface of the second rail wall 12.

  Of the roller circumferential surfaces 17a and 18a of the large diameter roller 17 and the small diameter roller 18 housed in the roller housing portions 20 and 21, the circumferential surface on the side to be transition-guided by the corresponding first rail wall 11 and second rail wall 12 , Exposed outside the outline of the runner body 15.

  The first rail wall 11 and the second rail wall 12 of the guide rail 2 are respectively formed horizontally protruding from the rail main body 10. Each of the large diameter roller 17 and the small diameter roller 18 is formed in a truncated cone shape, and includes roller circumferential surfaces 17a and 18a each having a tapered surface. The large diameter roller 17 and the small diameter roller 18 are supported by the roller shaft 16 in a state where the small diameter end sides of the roller circumferential surfaces 17a and 18a are adjacent to each other with the runner main body 15 therebetween.

  As shown in FIG. 10, the first rail wall 11 at the front and the rear and the second rail wall 12 at the front and the rear of the guide rail 2 are inclined in the state in which they are inclined in the opposite direction to each other. It is done. The large diameter roller 17 and the small diameter roller 18 are each formed in a circular roller shape, and are provided with roller circumferential surfaces 17a and 18a formed by arc surfaces. The large diameter roller 17 and the small diameter roller 18 are supported by the roller shaft 16 in a back-to-back manner with the runner body 15 therebetween.

  The large diameter roller 17 is rotatably supported by a bearing 23 mounted on the roller shaft 16.

  In the present invention, in the runner-type runner 6 having a four-wheel structure, the pair of roller shafts 16 are inclined in opposite directions to each other, the large diameter roller 17 is supported on the inclined upper end side of the coaxial 16 and the inclined lower end side The small diameter roller 18 is supported. Further, the guide rail 2 is provided on the upper side of the rail main body 10, a pair of front and rear first rail walls 11 for transitionally guiding the large diameter roller 17 and the first rail wall 11, and back and forth for transitionally guiding the small diameter roller 18 A pair of second rail walls 12 is provided.

  According to such a door panel support structure, the door panel P can be opened and closed by the pair of large diameter rollers 17 traveling along the first rail wall 11 in the steady state. However, in a state where the runner main body 15 receiving the external force tilts back and forth or left and right, the roller circumferential surface 18a of the small diameter roller 18 is received by the second rail wall 12, and the runner main body 15 tilts back and forth or left and right The second rail wall 12 regulates the Furthermore, in a state where the runner main body 15 that receives the external force is rotationally tilted about the support shaft 19, the roller circumferential surfaces 17a and 18a of the large diameter roller 17 or the small diameter roller 18 are the front and rear walls 10a and 10b of the rail main body 10. It can be received, and it can control that the runner body 15 is rotationally tilted by the front and rear walls 10a and 10b. Therefore, in spite of being the runner 6 of 4 wheel structure, while exhibiting the light opening / closing function equivalent to the runner of 2 wheel structure, it is eliminated that the opening / closing movement is carried out in the state where the runner main body 15 was greatly inclined. Thus, it is possible to provide a door panel support structure provided with a runner 6 that exhibits stable traveling characteristics at all times.

  The roller circumferential surface 18a of the small diameter roller 18 and the front and rear second rail walls 12 face each other with the clearance C1 therebetween, and the circumferential surfaces 17a and 18a of the large diameter roller 17 and the small diameter roller 18 and the front and rear wall 10a of the rail body 10 10b is opposed to the clearance C2 in between. As described above, when an appropriate amount of clearance C1 or C2 is provided between each roller 17 or 18 and the guide rail 2, each roller 17 or 18 is rotated in the state where the runner 6 is tilted by the clearance C1 or C2. The two rail walls 12 or the front and rear walls 10a and 10b of the rail body 10 do not tilt any further. That is, the second rail wall 12 or the front and rear walls 10a and 10b can restrict the movement of the runner 6 in the three-dimensional direction beyond the clearances C1 and C2. Therefore, the runner 6 can open and close the door panel P in an orderly manner while exhibiting stable traveling characteristics. Moreover, since generation | occurrence | production of rattling noise accompanying a rocking movement can be suppressed, the support structure of the door panel excellent in silence can be provided.

  When the roller accommodating portions 20 and 21 are formed in the front and rear surfaces of the runner main body 15 and the large diameter roller 17 and the small diameter roller 18 are accommodated in the respective accommodating portions 20 and 21, the whole of both rollers 17 and 18 is the front and rear of the runner main body 15 The runner 6 can be miniaturized by reducing the front-rear width of the runner 6 as compared to the case where the runner 6 is exposed to the surface. Moreover, the rail cross-sectional area of the guide rail 2 can be reduced by the amount that the runner 6 can be miniaturized, and the door panel support structure can be made compact. Furthermore, since the roller shaft 16 is supported using the central wall 22 between the front and rear roller accommodating portions 20 and 21, there is also an advantage that the structure of the runner main body 15 is not wasted.

  The overhang dimension of the second rail wall 12 is set smaller than the overhang dimension of the first rail wall 11 so that the upper circumferential surface of the large diameter roller 17 is positioned above the upper surface of the second rail wall 12. According to such a runner 6, the diameter of the large diameter roller 17 can be increased within the range permitted in the internal space of the guide rail 2, so the pair of left and right large diameter rollers 17 travel and move along the first rail wall 11 The traveling characteristics of the runner 6 at the time can be further stabilized to improve straightness.

  Of the roller circumferential surfaces 17a and 18a of the large diameter roller 17 and the small diameter roller 18, the circumferential surface on the side transition-guided by the corresponding first rail wall 11 and second rail wall 12 Exposed to According to such a runner 6, it is only necessary to expose only the roller circumferential surface on the side involved in travel movement and tilt control on the front and rear surfaces of the runner main body 15. Therefore, most of the portions of the respective rollers 17 and 18 It can be positioned within the outer contour of the runner body 15 in vision. Therefore, as in the case where the large diameter roller 17 and the small diameter roller 18 are housed in the roller housing portions 20 and 21, the longitudinal width of the runner 6 is reduced and the runner 6 is miniaturized accordingly, and the rails of the guide rail 2 The cross-sectional area can be reduced. In addition, when the runner 6 travels and moves, the roller peripheral surface not involved in travel movement and tilt regulation reliably prevents the inner wall of the guide rail 2 from coming into contact, and the runner 6 opens and closes lightly. It can move.

  The first and second rail walls 11 and 12 of the guide rail 2 are respectively horizontally extended, and the large diameter roller 17 and the small diameter roller 18 are each formed in a truncated cone shape, and a tapered roller circumferential surface 17a・ I added 18a. The rollers 17 and 18 are supported by the roller shaft 16 with the small diameter end sides of the roller circumferential surfaces 17a and 18a adjacent to each other with the runner main body 15 therebetween. According to such a runner 6, since the pair of large diameter rollers 17 and 17 rotating around the inclined central axis exerts a self-aligning action to always roll in a uniform state with respect to the first rail wall 11 The traveling characteristics can be further stabilized by improving the straightness of the runner 6.

  The first and second rail walls 11 and 12 of the guide rail 2 are inclined in opposite directions to each other in a state corresponding to the inclination angle of the roller shaft 16, and the large diameter roller 17 and the small diameter roller 18 Each was formed into a circular roller shape. According to such a runner 6, since the pair of large diameter rollers 17 and 17 rotating around the inclined central axis exerts a self-aligning action to always roll in a uniform state with respect to the first rail wall 11 Similarly to the runner 6 in which the rollers 17 and 18 are formed in a truncated cone shape, the straightness of the runner 6 can be improved to further stabilize the traveling characteristics.

  When the large diameter roller 17 is rotatably supported by the bearing 23 mounted on the roller shaft 16, the rotational resistance of the large diameter roller 17 is greater than when the large diameter roller 17 is directly supported by the roller shaft 16. To make the rotation operation smoother. In addition, since the generation of noise when the runner 6 travels can be reduced as the rotation operation of the large diameter roller 17 is facilitated, it is possible to provide a door panel support structure excellent in quietness. it can.

It is a vertical side view which shows the support structure of the door panel which concerns on Example 1 of this invention. It is a front view of a folding door to which the present invention is applied. It is a vertical side view of a folding door. It is a vertical front view of a runner. It is a top view of a runner. It is an exploded sectional view for explaining a roller support structure. It is a side view which shows the control effect | action of the 2nd rail wall when a runner tilts back and forth. It is a front view which shows the control effect | action of the 2nd rail wall at the time of a runner tilting to the left and right. It is a top view which shows the restriction | limiting effect | action of the front and back wall when a runner rotationally tilts around a suspending axis. It is a vertical side view which shows the support structure of the door panel which concerns on Example 2 of this invention.

EXAMPLE 1 FIGS. 1 to 8 show Example 1 in which the door panel support structure according to the present invention is applied to a free folding door. In the present invention, front / rear, left / right, upper / lower refers to the cross arrow shown in FIGS. 2 to 4 and the front / rear / left / right upper / lower notation near the cross arrow. In FIG. 2, the free folding door is constituted by a pair of left and right panels, and each panel pair is foldably foldable and guided and supported by guide rails 2 and 3 disposed above and below the opening frame 1. Each panel pair is configured by connecting adjacent edges of two door panels P with a hinge 4, and in the folded state of the door panels P, most of the door panels P is a vertical plane just below the guide rails 2 Project more forward than. The panel pair in this state can be freely moved in the left and right direction along the guide rails 2 and 3. A handle 5 for opening and closing the panel pair is fixed in the vicinity of the bending edge of the door panel P adjacent to the center of the opening in a state where the panel pair is fully developed. As shown in FIG. 3, runners 6 and an anti-vibration device 7 are provided at the upper and lower sides of each side of the panel pair.

  In FIG. 1, the guide rail 2 on the upper frame side has a rail body 10 having a C-shaped cross section that opens downward, and a first rail wall 11 and a first rail wall 11 overhanging in a state facing the front and rear walls 10 a and 10 b of the rail body 10. It consists of an aluminum strip provided integrally with the 2 rail wall 12. While the first rail wall 11 is horizontally extended at the opening surface of the front and rear walls 10a and 10b of the rail main body 10, with the second rail wall 12 interposed therebetween. Is formed so as to extend horizontally in the middle of the front and rear walls 10a and 10b of the rail main body 10 with the moving area of the runner main body 15 described later interposed therebetween. The overhang dimension of the second rail wall 12 is set smaller than the overhang dimension of the first rail wall 11. The guide rail 2 in this embodiment is a small guide rail suitable for supporting a relatively light weight door panel P, having a height of 20.9 mm and a front / rear dimension of 20.6 mm. The guide rail 3 on the floor side is made of an aluminum strip provided with a shallow rail groove 13 which opens upward (see FIG. 3).

  In FIG. 4, the runner 6 includes a runner body 15, a pair of roller shafts 16 disposed adjacent to the runner body 15, large diameter rollers 17 and 17 rotatably supported by front and rear shaft portions of the roller shafts 16 and It consists of a four-wheeled suspension type runner provided with small diameter rollers 18 and 18 and a suspension shaft 19 connecting the runner body 15 and the door panels P1 and P2. The runner main body 15 is formed of a laterally long plastic molded product, and circular roller accommodating portions 20 and 21 for accommodating the rollers 17 and 18 are formed on the left and right of the front and rear surfaces thereof. As shown in FIG. 1, the front and rear roller accommodating portions 20 and 21 are divided by the central wall 22 supporting the roller shaft 16, and the roller shaft 16 is press-fit and fixed in the insertion hole formed in the wall 22 There is. As described above, the roller accommodating portions 20 and 21 are formed in the front and rear surfaces of the runner body 15 so as to be recessed with the central wall 22 supporting the roller shaft 16 therebetween. In this embodiment, when the left and right dimensions of the runner body 15 are 47 mm and the height dimension is 15 mm, the center-to-center distance between the roller shafts 16 adjacent to each other is 21 mm.

  As described above, when the roller accommodating portions 20 and 21 are formed in the front and rear surfaces of the runner main body 15 and the large diameter roller 17 and the small diameter roller 18 are accommodated in the respective accommodating portions 20 and 21, both rollers 17 and 18 are entirely Compared to the case where the runner 6 is exposed on the front and rear surfaces of the runner body 15, the runner 6 can be miniaturized by reducing the front-rear width of the runner 6 accordingly. Moreover, since the rail cross-sectional area of the guide rail 2 can be made small by the part which can miniaturize the runner 6, the support structure of a door panel can be made compact. In addition, since the roller shaft 16 is supported by utilizing the central wall 22 between the front and rear roller accommodating portions 20 and 21, there is an advantage that the structure of the runner body 15 is not wasted.

  As shown in FIG. 7, the roller shaft 16 is made of a stainless steel turning product integrally provided with a first shaft portion 16a formed on the upper end of the inclined side and a second shaft portion 16b formed on the lower end of the inclined side. The two shaft portions 16a and 16b are divided by a flange. The left and right roller shafts 16, 16 are inclined at an angle of 10 degrees in opposite directions with respect to the horizontal front and rear central axes of the runner main body 15, respectively. Specifically, the roller shaft 16 on the left side in FIG. 4 is fixed to the runner main body 15 with its central axis S1 inclined upward and backward (see FIG. 1), and the roller shaft 16 on the right side in FIG. Is fixed to the runner main body 15 in a state in which its central axis S2 inclines upward. A pair of rollers 17 and 18 accommodated in the roller accommodating portions 20 and 21 is fixed by caulking on the shaft portions 16a and 16b of the roller shaft 16 in this state.

  The large diameter rollers 17 and 17 are supported by the first shaft portion 16 a of the left and right roller shafts 16, and the small diameter rollers 18 and 18 are supported by the second shaft portion 16 b of the roller shaft 16. The large diameter rollers 17, 17 and the small diameter rollers 18, 18 are each formed of a plastic molded product formed in a truncated cone shape, and only the large diameter rollers 17, 17 are rotatably supported by the bearing 23 mounted on the roller shaft 16. ing. The large diameter rollers 17, 17 and the small diameter rollers 18, 18 respectively have tapered roller circumferential surfaces 17a, 18a and roller end surfaces 17b, 18b continuous with the large diameter end of the roller circumferential surface 17a. The small diameter end sides 17a and 18a are mounted on the roller shaft 16 in a back-to-back manner adjacent to each other with the central wall 22 of the runner body 15 therebetween. The corner portions between the roller circumferential surfaces 17a and 18a and the roller end surfaces 17b and 18b are rounded. The roller circumferential surfaces 17 a and 18 a are inclined by 10 degrees with respect to the central axis S 1 and S 2 of the roller shaft 16. Therefore, in a state where the runner 6 is assembled in the guide rail 2, the roller circumferential surface 17 a of the large diameter rollers 17, 17 is transitioned and guided by the upper surface of the first rail wall 11, and the roller circumferential surface 18 a of the small diameter rollers 18, 18 is The transition is guided on the lower surface of the second rail wall 12.

  The anti-vibration tool 7 accommodates the anti-vibration shaft 27 and the spring 28 for pressing the anti-rotation shaft 27 in the inside of the cylindrical case 26, and the anti-rotation roller 29 is rotatable at the lower end of the anti-vibration shaft 27. Is assembled. The swinging roller 29 can shift and guide the lower circumferential surface thereof with the rail groove 13 of the guide rail 3 to restrict the back and forth tilting of the door panel P.

  A hanging unit 32 is provided at an upper corner portion of the facing surface of the door panel P in a state where each panel pair is folded, for hanging the panel pair on the hanging shaft 19 by only one worker. The hanging unit 32 includes a holder embedded in the upper corner portion of the door panel P, and a holding lever for holding and engaging the holding shaft 19 therein, a torsion coil type holding spring, and a holding lever are provided therein. Although the lock structure etc. which hold | maintain a lock | rock are provided, the description is abbreviate | omitted.

  Between the opening frame 1 and the runner 6 facing the closed end, in order to restrict bending of the panel pair in the fully closed state and to hold the panel pair in the fully closed state flush without gaps. A catch structure is provided. 4, the catch structure includes a runner catcher 35 fixed to the closed end of the guide rail 2, an engagement structure 36 provided on the runner body 15 corresponding to the runner catcher 35, and the runner body 15 as a door panel P. And a biasing structure 37 that moves and biases in the direction of opening.

  The runner catcher 35 is a plastic molded product provided with a vertical wall 38 sandwiched and fixed by the guide rail 2 and the opening frame 1 and a catch arm 39 protruding from the top of the vertical wall 38 over the upper surface of the engagement structure 36. Become. A guide frame 40 for assembling the biasing structure 37 is protruded toward the runner main body 15 on the vertical wall 38 which faces the side end of the runner main body 15. Further, an engaging groove 41 engaged with the ball 43 of the engaging structure 36 is formed on the lower surface of the end of the catching arm 39 in a recessed manner. A resilient engagement claw 42 engaged integrally with an engagement hole provided on the upper wall of the guide rail 2 is integrally provided near the proximal end of the capture arm 39.

  The engagement structure 36 includes a metal ball 43 and a ball spring 44 for pushing up and urging the ball 43, both of which 43 and 44 are assembled in the set hole 45 of the runner main body 15, and the set hole 45 is formed. It is held and fixed by a set screw 46 screwed to the lower part of the. The spherical upper portion of the ball 43 always protrudes from the upper end surface of the runner main body 15, so that when the door panel P is moved to the closed position, the ball 43 falls into and engages with the engaging groove 41 of the catching arm 39. , Restricts the movement of the door panel P in the opening direction.

  The biasing structure 37 includes a cap-like pressing body 48 which is guided and supported only by the guide frame 40 so as to allow left and right slide, and a biasing spring 49 disposed between the vertical wall 38 and the pressing body 48. In the biasing structure 37, in a state in which the door panel P is moved to the closed position, the pressing body 48 receives the side end surface of the runner main body 15 and compresses and deforms the biasing spring 49. Accordingly, the door panel P is urged to move in the opening direction, but the engagement relationship between the ball 43 and the engagement groove 41 is not released, and the user starts opening the handle 5 and the ball 43 engages the engagement groove Separate from 41

  The relationship between the large diameter roller 17 and the first rail wall 11, and the small diameter roller 18 and the second rail wall 12 in the state where the runner 6 is assembled to the guide rail 2 is shown in FIGS. The large diameter roller 17 and the small diameter roller 18 are respectively accommodated in the corresponding roller accommodating portions 20 and 21 of the runner main body 15, and the roller circumferential surfaces 17a and 18a are transition-guided by the first rail wall 11 and the second rail wall 12, respectively. Among them, the peripheral surface of the side on which the transition is guided by the corresponding first rail wall 11 and second rail wall 12 is exposed outside the outline of the runner body 15.

  In the case of the large diameter roller 17, the lower half side of the roller circumferential surface 17 a is exposed outside the outline of the runner body 15, and the upper circumferential surface of the roller circumferential surface 17 a is above the upper surface of the second rail wall 12 It is located at. Further, in the case of the small diameter roller 18, the upper half side of the roller circumferential surface 18a is exposed to the outside of the outline of the runner main body 15, and the entire small diameter roller 18 is the first rail wall 11 and the second rail wall 12 Located between the As described above, when the roller circumferential surfaces 17a and 18a transition-guided by the rail walls 11 and 12 are exposed outside the outline of the runner main body 15, only the roller circumferential surface on the side involved in the tilt control is It may be exposed on the front and rear surfaces of the runner body 15. Therefore, the majority of the rollers 17 and 18 can be positioned within the outer line of the runner body 15 in side view to reduce the longitudinal width of the runner 6, and the runner 6 can be made smaller by that amount. The cross-sectional area can be reduced. In addition, when the runner 6 travels and moves, the roller peripheral surface not involved in travel movement and tilt regulation reliably prevents the inner wall of the guide rail 2 from coming into contact, and the runner 6 opens and closes lightly. It can move.

  The small diameter roller 18 of the runner 6 assembled to the guide rail 2 is positioned between the upper surface of the first rail wall 11 and the second rail wall 12, and the upper half roller circumferential surface 18 a is the second It is directly opposite to the lower surface of the rail wall 12. Furthermore, since the central axes S1 and S2 of the roller shaft 16 are inclined by 10 degrees, the large diameter roller 17 is inclined away from the second rail wall 12, and the upper circumferential surface of the roller circumferential surface 17a is the second rail wall It is located above the upper surface of 12. Thus, in order to position the upper circumferential surface of the large diameter roller 17 above the upper surface of the second rail wall 12, the overhang dimension of the second rail wall 12 is set smaller than the overhang dimension of the first rail wall 11. Thus, the roller end face 17 b of the large diameter roller 17 is prevented from contacting and interfering with the second rail wall 12. According to such a runner 6, the diameter of the large diameter roller 17 can be increased within the range permitted in the internal space of the guide rail 2, so the pair of left and right large diameter rollers 17 travel and move along the first rail wall 11 The traveling characteristics of the runner 6 at the time can be further stabilized to improve straightness.

In the above guide structure, the diameter of the circumferential surface of the small diameter roller 18 can be increased as the extended position of the second rail wall 12 is on the upper side, and the runner 6 can be traveled in a stable state. However, since the roller shaft 16 is inclined, the diameter of the peripheral surface of the large diameter roller 17 becomes larger in proportion to the diameter of the peripheral surface of the small diameter roller 18 becoming larger, and the inside of the guide rail 2 It disappears. In order to avoid such a problem, in this embodiment, the diameter dimension of the large diameter end side of the circumferential surface of the large diameter roller 17 is set to the internal height dimension (18 mm) of the guide rail 2
About 88% of the The diameter of the large diameter end of the circumferential surface of the small diameter roller 18 is about 66% of the diameter of the large diameter end of the circumferential surface of the large diameter roller 17.

  As shown in FIG. 1, when the runner 6 travels in a steady state, basically, the roller circumferential surface 17a of the large diameter roller 17 on the near side and the large diameter roller 17 on the back side is the first rail While being supported by the upper surface of the wall 11, it moves laterally. Since the pair of large diameter rollers 17 and 17 rotate around the inclined central axis when the runner 6 moves to the left and right, a self-aligning action to always roll in a uniform state with respect to the first rail wall 11 Demonstrate. As a result, compared with a runner having a conventional structure in which a circular roller supported by a horizontal runner shaft rolls on a horizontal rail wall, the straightness of the runner 6 can be improved and the traveling characteristics can be stabilized.

  In order to more flexibly move the runner 6 when the left and right large diameter rollers 17 travel and move along the first rail wall 11, the roller circumferential surface 18a of the front and rear small diameter rollers 18 and the front and rear second rail walls 12, as shown in FIG. 1, the clearance (floating clearance) C1 (0.2 mm) is opposed to the other, and since it is also separated from the upper surface of the first rail wall 11, the small diameter roller 18 rotates. There is no. For the same reason, the roller circumferential surfaces 17a and 18a of the large diameter roller 17 and the small diameter roller 18 and the front and rear walls 10a and 10b of the rail main body 10 face each other with a slight clearance (floating clearance) C2 (0.2 mm) doing. The clearances C1 and C2 are clearance dimensions when the large diameter roller 17 is properly supported by the first rail wall 11.

  Incidentally, when the above-mentioned clearances C1 and C2 are not provided, the two large diameter rollers 17 and the two small diameter rollers 18 simultaneously rotate in opposite directions at different rotational speeds, so that the runner 6 travels. The resistance increases sharply and the running noise increases. The runner 6 swings back and forth in response to an external force acting on the door panel P, swings left and right, or swings around the lifting shaft 19 when traveling and moving. However, according to the runner 6 configured as described above, stable traveling characteristics can be exhibited by restricting the swinging motion in the three-dimensional direction as described above.

  For example, in the folded state of the door panel P, most of the door panel P protrudes forward beyond the vertical plane just below the guide rail 2, so that the central axis Q of the suspension shaft 19 in the runner 6 inclines forward. A moment of direction is generated. Also, when the central axis Q of the suspension shaft 19 starts to tilt forward with respect to the vertical line, as shown in FIG. 7A, the roller circumferential surface 17a of the large diameter roller 17 on the front side The roller circumferential surface 18a of the small diameter roller 18 on the near side is tilted away from the lower surface of the second rail wall 12 on the front side. However, the roller circumferential surface 17a of the large diameter roller 17 on the back side is supported by the upper surface of the first rail wall 11 on the front side, and the central axis Q of the suspension shaft 19 is tilted to the front side with respect to the vertical line. Immediately after the start, the roller circumferential surface 18a of the back side small diameter roller 18 is slightly tilted by the clearance C1 and received by the lower surface of the rear second rail wall 12. Therefore, the runner main body 15 and the suspension shaft 19 do not tilt forward beyond the previous clearance C1. At this time, the large diameter roller 17 on the back side tilts to the front side as much as the small diameter roller 18 on the back side tilts, but does not contact the second rail wall 12 on the front side. The tilt angle of the above-mentioned suspension shaft 19 is 2 degrees.

  In the runner 6 in the case where a person is leaning on the rear surface side of the door panel P, a moment is generated in a direction in which the central axis Q of the suspension shaft 19 is inclined backward. Then, as shown in FIG. 7 (b), immediately after the central axis Q of the suspension shaft 19 starts to tilt rearward with respect to the vertical line, the roller circumferential surface 17a of the large diameter roller 17 on the front side Supported by the upper surface of the first rail wall 11 on the side, and further, the roller circumferential surface 18a of the small diameter roller 18 on the near side is slightly tilted by the clearance C1 and received by the lower surface of the second rail wall 12 on the front side Be Therefore, in the same manner as described above, the runner body 15 and the suspension shaft 19 do not tilt rearward beyond the previous clearance C1. At this time, the large diameter roller 17 on the front side tilts to the rear side as much as the small diameter roller 18 on the front side tilts, but does not contact the rear second rail wall 12. As described above, when the runner 6 tilts either forward or backward, either the left or right small-diameter roller 18 is received by the second rail wall 12, and the runner body 15 that receives the external force has the clearance C1. The second rail wall 12 can be restricted from swinging back and forth.

  When the door panel P is suddenly opened and closed to the left and right in the folded state, the central axis Q of the suspension shaft 19 may tilt to the right with respect to the vertical line as shown in FIG. . In that case, the roller circumferential surface 17 a of the large diameter roller 17 on the left side floats away from the upper surface of the rear side first rail wall 11. However, at the same time the large diameter roller 17 on the left side floats away from the upper surface of the first rail wall 11, the roller circumferential surface 18a of the small diameter roller 18a on the left side is slightly tilted by the clearance C1 and the second rail on the front side It is received by the lower surface of the wall 12. Therefore, the runner body 15 and the suspension shaft 19 do not tilt further to the right.

  Contrary to the above case, the central axis Q of the support shaft 19 may tilt to the right with respect to the vertical line. In that case, as shown in FIG. 8B, the roller circumferential surface 17a of the large diameter roller 17 on the right side floats away from the upper surface of the first rail wall 11 on the front side. However, at the same time when the large diameter roller 17 on the right side floats away from the upper surface of the first rail wall 11, the roller circumferential surface 18a of the small diameter roller 18a on the right side is slightly tilted by the clearance C1 and the second rail on the front side It is received by the lower surface of the wall 12. Therefore, the runner body 15 and the suspension shaft 19 do not tilt further to the left. Therefore, the second rail wall 12 can restrict the lateral movement of the runner body 15 and the hanging shaft 19 subjected to the external force beyond the clearance C1.

  When the door panel P is in the fully closed state and the handle 5 is suddenly opened, the runner main body 15 may tilt in the clockwise direction about the support shaft 19 as shown in FIG. 9A. In that case, the peripheral edge on the large diameter end side of the roller circumferential surface 17a of the large diameter roller 17 on the left side is slightly tilted backward by the clearance C2, and the base end corner of the first rail wall 11 on the rear side It is received by the rear wall 10b of the rail main body 10 facing the section. At the same time, the peripheral edge of the roller circumferential surface 17a of the large-diameter roller 17 on the right side tilts slightly forward by the clearance C2, and the front wall of the rail main body 10 faces the proximal corner of the first rail wall 11 on the front side. It is received by 10a. Therefore, the runner main body 15 is not further tilted in the clockwise direction.

  Contrary to the above case, when the runner main body 15 is tilted in the counterclockwise direction about the support shaft 19 as shown in FIG. 9B, the roller circumferential surface 18ab of the small diameter roller 18 on the left side The peripheral edge on the large diameter end side is inclined forward slightly by the clearance C2, and is received by the front wall 10a of the rail main body 10 facing the proximal corner portion of the front second rail wall 12. At the same time, the peripheral edge of the roller circumferential surface 18a of the small diameter roller 18 on the right side tilts slightly backward by the clearance C2, and the rear wall of the rail body 10 faces the proximal corner of the rear second rail wall 12 It is received by 10b. Therefore, the runner body 15 is not further tilted in the counterclockwise direction. Therefore, the base of the first rail wall 11 and the second rail wall 12 that the runner main body 15 subjected to the external force swings in the clockwise direction or the counterclockwise direction around the support shaft 19 over the clearance C2. By restricting with the front and rear walls 10a and 10b of the rail main body 10 facing the end corner portion, the runner 6 can be prevented from meandering.

  As described above, when the runner 6 travels and travels in an appropriate posture, of course, even if it is attempted to travel and travel with the runner main body 15 tilted in the three-dimensional direction, the four rollers 17 and 18 must be used. The two rollers can be transitioned and guided by the first and second rail walls 11 and 12 to restrict the swing of the runner 6 beyond the clearances C1 and C2. Therefore, even when the door panel P is opened and closed or left and right moved while being folded, the runner 6 can always exhibit stable traveling characteristics to open and close the door panel P neatly and horizontally moved. Moreover, since generation | occurrence | production of rattling noise accompanying a rocking movement can be suppressed, the support structure of the door panel excellent in silence can be provided.

Second Embodiment FIG. 10 shows a second embodiment of the door panel support structure according to the present invention. There, the first rail wall 11 at the front and the rear and the second rail wall 12 at the front and the rear of the guide rail 2 are inclined in the oppositely inclined state in a state in which they coincide with the inclination angle of the roller shaft 16 respectively. . Further, the large diameter roller 17 and the small diameter roller 18 are respectively formed in a circular roller shape, and are provided with roller circumferential surfaces 17a and 18a formed by arc surfaces. The large diameter roller 17 and the small diameter roller 18 are supported by the roller shaft 16 in a back-to-back manner with the runner main body 15 therebetween. The other components are the same as those of the first embodiment, so the same reference numerals are given to the same members and the description thereof will be omitted.

  According to the door panel support structure of the second embodiment, the self adjustment in which the pair of large diameter rollers 17 and 17 rotating around the inclined central axis tends to roll in a uniform state with respect to the first rail wall 11 at all times. I can exert my heart function. As a result, as in the runner 6 of the first embodiment, the straightness of the runner 6 is improved compared to a runner having a conventional structure in which a circular roller supported by a horizontal runner shaft rolls on a horizontal rail wall. Driving characteristics can be stabilized. In the second embodiment, even when the first rail wall 11 before and after the guide rail 2 and the second rail wall 12 before and after the guide rail 2 are formed horizontally, the large diameter rollers 17 and 17 are self-regulating. It exerts a heart function. However, in that case, since the large diameter roller 17 and the first rail wall 11 are in point contact with each other, the runner 6 is easily shaken back and forth.

  In addition to the above, the door panel support structure according to the present invention can be applied to a sliding door, a rotating door, and the like in addition to the folding door. When the weight of the door panel P to be suspended increases, the guide rails 2 and the runners 6 also need to be formed large, but in such a case, the small diameter roller 18 is the same as the large diameter roller 17, It may be rotatably supported by a bearing 23 mounted on the roller shaft 16. If necessary, the runner 6 can be used as a sliding door or a revolving door, and in such a case, the runner 6 always exhibits stable traveling characteristics so as to open and close the door panel P in an orderly manner and can move side by side in an orderly manner .

  In the state in which the door panel P is suspended in the guide rail 2, adjacent door panels P may be misaligned back and forth or up and down. In order to adjust the positional deviation of the door panel P back and forth or up and down, it is possible to provide a back and forth adjustment structure and an up and down adjustment structure between the runner main body 15 and the suspension shaft 19.

DESCRIPTION OF SYMBOLS 2 guide rail 6 runner 10 rail main body 10a front wall 10b of rail main body rear wall of rail main body 11 first rail wall 12 second rail wall 15 runner main body 16 roller shaft 17 large diameter roller 17a (17) roller circumferential surface 18 small diameter Roller 18a (18) roller circumferential surface 19 hanging shaft 20 (for 17) accommodation portion 21 (for 18) accommodation portion 22 central wall P door panel C1 clearance C2 clearance

Claims (8)

A door panel support structure comprising a guide rail (2) attached to the opening frame (1) and a four wheel suspension type runner (6) transition-guided by the guide rail (2),
The runner (6) comprises a runner body (15), a pair of roller shafts (16) disposed adjacent to the body (15), a large diameter roller (17) and a small diameter roller supported by each roller shaft (16) (18) and a hanging shaft (19) for hanging and supporting the door panel (P),
The pair of roller shafts (16) are inclined in mutually opposite directions with respect to the horizontal longitudinal central axis of the runner body (15), and the large diameter roller ( 17) is supported, and a small diameter roller (18) is supported on the lower end side of the roller shaft (16),
The guide rail (2) includes a rail body (10) having a C-shaped cross section, a pair of front and rear first rail walls (11) for transitionally guiding the large diameter roller (17), and an upper side than the first rail wall (11) And a pair of front and rear second rail walls (12) for transitionally guiding the small diameter roller (18).
The roller circumferential surface (18a) of the small diameter roller (18) is received by the second rail wall (12), and the roller circumferential surfaces (17a, 18a) of the large diameter roller (17) or the small diameter roller (18) A support structure for a door panel, characterized in that it is configured to be received by the front and rear walls (10a and 10b). In a state where the large diameter roller (17) is supported by the first rail wall (11), the roller circumferential surface (18a) of the small diameter roller (18) and the front and rear second rail walls (12) Are facing each other,
With the large diameter roller (17) supported by the first rail wall (11), the roller circumferential surface (17a, 18a) of the large diameter roller (17) and the small diameter roller (18) and the front and back of the rail body (10) The walls (10a and 10b) face each other with the clearance (C2) therebetween,
The second rail wall (12) restricts the runner body (15) subjected to external force from tilting back and forth and tilting left and right beyond the clearance (C1),
The front and rear walls (10a and 10b) of the rail body (10) restrict the runner body (15) that has received an external force from rotating and tilting beyond the clearance (C2) around the support shaft (19),
The door panel support structure according to claim 1, wherein the runner (6) is restricted from swinging in three dimensions over the clearance (C1, C2).   A roller accommodating portion (20) for accommodating the large diameter roller (17) and a roller accommodating portion (21) for accommodating the small diameter roller (18) are interposed between the central wall (22) for supporting the roller shaft (16) 3. The door panel support structure according to claim 1, wherein the front and rear surfaces of the runner body (15) are recessed.   The overhang dimension of the second rail wall (12) is set smaller than the overhang dimension of the first rail wall (11), and the upper circumferential surface of the large diameter roller (17) is above the upper surface of the second rail wall (12) The door panel support structure according to any one of claims 1 to 3, which is located in   Of the roller circumferential surfaces (17a, 18a) of the large diameter roller (17) and the small diameter roller (18) housed in the roller housing portion (20, 21), corresponding first rail wall (11) and second rail wall ((11) The door panel support structure according to claim 3 or 4, wherein the peripheral surface on the side transition-guided in 12) is exposed outside the outline of the runner body (15). The first rail wall (11) and the second rail wall (12) of the guide rail (2) are respectively formed horizontally extending from the rail body (10),
Each of the large diameter roller (17) and the small diameter roller (18) is formed in a truncated cone shape, and has a roller circumferential surface (17a, 18a) consisting of a tapered surface,
The large diameter roller (17) and the small diameter roller (18) are supported by the roller shaft (16) in a state where the small diameter end sides of the roller circumferential surfaces (17a, 18a) are adjacent to each other with the runner main body (15) in between. The door panel support structure according to any one of claims 1 to 5. With the first rail wall (11) before and after the guide rail (2) and the second rail wall (12) before and after with the roller shaft (16), respectively, in a state in which they are inclined in opposite directions It is inclined and
The large diameter roller (17) and the small diameter roller (18) are respectively formed in a circular roller shape, and are provided with roller circumferential surfaces (17a, 18a) formed of an arc surface,
A large diameter roller (17) and a small diameter roller (18) are supported on the roller shaft (16) in a back-to-back manner with the runner body (15) therebetween. Door panel support structure as described.   The door panel support structure according to any one of claims 1 to 7, wherein the large diameter roller (17) is rotatably supported by a bearing (23) attached to the roller shaft (16).

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