JP2023017218A - Fixture - Google Patents

Abstract

To suppress a sash from rattling and move the sash smoothly when the sash is moved by a linear monitor that is separated from the sash in in-door and out-door direction.SOLUTION: A sash 2 and a linear motor 30 are spaced apart in the indoor-outdoor direction S. The linear motor 30 has a stator 31 fixed to a wall portion 12 of a building 10 and a movable element 32 in relation to the stator 31 .A fitting 1 includes a bracket 40 connecting the movable element 32 and the sash 2, a guide roller 50 connected to the movable element 32, and a guide rail portion 80 that guides the guide roller 50 in the moving direction of the sash 2 in a state in which the guide roller 50 is sandwiched from above and below.SELECTED DRAWING: Figure 3

Description

TECHNICAL FIELD The present invention relates to a fitting that moves a shoji by a linear motor.

An automatic door uses a linear motor as a driving device for moving the door. The mover of the linear motor is connected to the door and moves relative to the stator of the linear motor when the door moves. Further, conventionally, an automatic door is known in which a mover is connected to a door by a moving body provided with rollers, and the rollers of the moving body run on a guide rail portion when the door moves (see Patent Document 1). ). In this conventional automatic door, the door is arranged below the mover and suspended vertically from the mover by a moving body. The roller of the moving body is separated downward from the projecting piece positioned above and is supported from below by the guide rail portion.

In this way, in a linear motor type automatic door, the door is suspended directly below the mover of the linear motor. On the other hand, if a linear motor is used for the driving device of the shoji of the window which is a fixture, it is necessary to hang the shoji directly under the mover regardless of whether it is an external window, a semi-external window, or an internal window. is difficult, and the shoji and the linear motor are placed apart in the indoor and outdoor direction. Therefore, it is necessary to connect the shoji and the mover with brackets extending in the indoor and outdoor directions. However, when the sliding door is moved by the linear motor in this state, the magnetic force between the stator and the mover pulls the mover upward. As a result, an upward force acts on the bracket, bending the bracket upward. A downward force also acts on the bracket due to the restoring force. These upward forces and downward forces act repeatedly on the brackets, causing the brackets and the shoji to rattle. As a result, there is a risk that noise will be generated during the movement of the shoji and smooth movement of the shoji will be hindered.

JP 2006-241671 A

The present invention has been made in view of the above-mentioned conventional problems, and its object is to suppress the rattling of the shoji when the shoji is moved by a linear motor that is separated from the shoji in the indoor and outdoor direction, and to smoothly move the shoji. is to move to

The present invention is a fitting in which a shoji and a linear motor for moving the shoji are arranged separately in the indoor and outdoor direction,
The linear motor has a stator fixed to a wall of a building and a mover that moves with respect to the stator,
a bracket that connects the mover and the shoji;
a guide roller connected to the mover;
A guide rail portion that guides the guide roller in a moving direction of the shoji while sandwiching the guide roller from above and below;
It is a fixture with

ADVANTAGE OF THE INVENTION According to this invention, when moving a shoji by the linear motor spaced|separated in the indoor-outdoor direction with respect to a shoji, the rattling of a shoji can be suppressed and a shoji can be smoothly moved.

It is a front view which shows the fittings of this embodiment seen from the outdoor side. It is a longitudinal cross-sectional view which shows the fittings of this embodiment. It is the longitudinal cross-sectional view to which some fittings of this embodiment shown in FIG. 2 were expanded. It is a front view which shows the fittings of this embodiment seen from the arrow X direction of FIG.

An embodiment of fittings of the present invention will be described with reference to the drawings.
The fittings of this embodiment are linear motor type fittings, and are provided with shoji sliding doors that move by sliding. The fittings are installed on the walls of the building and arranged between the interior (indoor) and the exterior (outdoor) of the building.

FIG. 1 is a front view showing a fitting 1 of this embodiment as seen from the outdoor side, and FIG. 2 is a longitudinal sectional view showing the fitting 1 of this embodiment.
As shown, the fitting 1 is a single sliding window installed in an opening 11 of a building 10, and includes two shojis 2 and 3 (first shoji 2 and second shoji 3) and one screen door 4 (FIG. 1 ), and a frame 20 surrounding the shojis 2 and 3 and the screen door 4 . The first shoji 2 is an indoor shoji located on the indoor side, and the second shoji 3 is an outdoor shoji located on the outdoor side. The screen door 4 slides and moves in the lateral direction on the outdoor side of the shojis 2 and 3. - 特許庁

When the fitting 1 provided in the building 10 is viewed from the front (see FIG. 1), the up-down direction is the up-down direction, and the left-right direction is the left-right direction. In FIG. 1, the up-down direction is the vertical direction, and the left-right direction is the horizontal direction. The indoor/outdoor direction S (see FIG. 2) is the indoor/outdoor direction (indoor/outdoor direction) of the fittings 1 provided in the building 10 . The indoor-outdoor direction S is the front-rear direction (depth direction) when the fitting 1 provided in the building 10 is viewed from the front, and is the horizontal direction perpendicular to the left-right direction in FIG. In this way, the direction of the fittings 1 is specified by the direction in which the fittings 1 are installed in the building 10 . Further, the indoor side and the outdoor side with respect to the fittings 1 are the indoor side and the outdoor side in the state of being installed in the building 10 .

The first shoji 2 is a sliding movable shoji that moves by sliding, and is arranged movably (slidably) in the opening 21 of the frame 20 . The second shoji 3 is a fixed shoji that is fixed to the fittings 1 , is arranged on one side in the left-right direction of the opening 21 of the frame 20 , and is fixed to the frame 20 . The first shoji 2 is positioned within the opening 21 of the frame 20 between a fully open position at which the opening 21 of the frame 20 is fully opened and a fully closed position at which the opening 21 of the frame 20 is fully closed. to move. The first shoji 2 in the fully open position overlaps the second shoji 3 on the indoor side, and is arranged on one side in the left-right direction of the opening 21 of the frame 20 . The first shoji 2 in the fully closed position is arranged on the other side in the left-right direction of the opening 21 of the frame 20 . The opening 21 of the frame 20 is opened and closed by the first shoji 2, which is a one-sided shoji.

The first shoji 2 is opened and closed by moving in the moving direction K between the fully open position and the fully closed position. The movement direction K of the first shoji 2 is the direction in which the first shoji 2 moves when opening and closing the first shoji 2 (when opening and closing the opening 21 of the frame 20 by the first shoji 2) (sliding direction, opening and closing direction). , here in the left-right direction. The first shoji 2 moves from the fully open position to the fully closed position in one side (the closing direction side) in the moving direction K and is arranged at the fully closed position. Thereby, the first shoji 2 is closed, and the opening 21 of the frame 20 is fully closed (closed) by the first shoji 2 . Further, the first shoji 2 moves from the fully closed position to the fully open position in the other side (opening direction side) of the movement direction K and is arranged at the fully open position. Thereby, the first shoji 2 is opened, and the opening 21 of the frame 20 is fully opened (opened) by the first shoji 2 .

The shojis 2 and 3 respectively have rectangular frames 2A and 3A and panels 2B and 3B arranged in the frames 2A and 3A. The frames 2A and 3A have four frames 2C to 2F and 3C to 3F (upper frames 2C and 3C, lower frames 2D and 3D, door frames 2E and 3E, and combined frames 2F and 3F) that are combined with each other. are doing. Panels 2B and 3B are rectangular glass panels (for example, plate glass, multi-layer glass, or laminated glass) and are fitted in frames 2A and 3A, respectively.

The frames 2C to 2F and 3C to 3F of the frames 2A and 3A are frame members forming the frames 2A and 3A, and are made of shapes formed by extrusion molding, for example. The upper frames 2C, 3C and the lower frames 2D, 3D are horizontal frames above and below the frames 2A, 3A and extend in the left-right direction (horizontal direction) above and below the frames 2A, 3A. Door frames 2E, 3E and meeting frames 2F, 3F are left and right vertical frames of the frames 2A, 3A, and extend vertically (longitudinally) on the left and right sides of the frames 2A, 3A. The ends of the frames 2C to 2F and 3C to 3F are connected to form a framework for the frames 2C to 2F and 3C to 3F.

The frame 20 is a rectangular opening frame (window frame) and is installed in the rectangular opening 11 of the building 10 . In addition, the frame body 20 has four frames 22 to 25 (upper frame 22, lower frame 23, pair of vertical frames 24, 25) that are combined with each other, and the four frames 22 to 25 form a rectangular opening. It forms part 21 . The frames 22 to 25 are frame members forming the frame body 20, and are made of shapes formed by extrusion molding, for example. The upper frame 22 and the lower frame 23 are horizontal frames above and below the frame 20 and extend in the left-right direction (horizontal direction) at the upper and lower portions of the frame 20 . The pair of vertical frames 24 and 25 are side frames positioned on the left and right sides of the frame 20 and extend vertically (vertically) on the sides of the frame 20 . The ends of the upper frame 22, the lower frame 23, and the left and right vertical frames 24, 25 are connected to form frames 22-25.

FIG. 3 is a longitudinal sectional view enlarging a part of the fitting 1 of this embodiment shown in FIG. FIG. 4 is a front view showing the fitting 1 of this embodiment viewed from the direction of arrow X in FIG.
As shown, the frame 20 and the frames 22 to 25 of the fittings 1 are installed at the outdoor side of the opening 11 of the building 10 and protrude from the wall 12 of the building 10 to the outdoor side. The first shoji 2 is arranged on the indoor side of the opening 21 of the frame 20 and on the outdoor side of the opening 11 of the building 10 . The second shoji 3 and the screen door 4 are arranged on the outdoor side of the opening 21 of the frame 20 and on the outdoor side of the opening 11 and the wall 12 of the building 10 .

The fitting 1 includes a linear motor 30 that drives the first shoji 2, a plurality of brackets 40 that connect the first shoji 2 and the linear motor 30, a plurality of rotatable guide rollers 50 that are connected to the linear motor 30, A plurality of rotatable lower rollers 60 positioned below the guide rollers 50 and a guide body 70 that guides the guide rollers 50 and the lower rollers 60 are provided. The bracket 40, the guide roller 50, and the lower roller 60 are provided at two locations spaced apart from each other in the moving direction K of the first shoji 2, respectively.

The linear motor 30 is a linear driving device (actuator), and moves the first shoji 2 in the moving direction K. As shown in FIG. The linear motor 30 is provided on the wall surface portion 13 on the indoor side of the wall portion 12 of the building 10 and arranged above the opening 11 and the first shoji 2 of the building 10 . The 1st shoji 2 and the linear motor 30 are provided in the mutually different position of the indoor-outdoor direction S, and are mutually separated in the indoor-outdoor direction S, and are arrange|positioned. The linear motor 30 is provided at a position on the indoor side of the frame 20 of the fitting 1 and the first shoji 2, and the frame 20 of the fitting 1 and the first shoji 2 are provided at a position on the outdoor side of the linear motor 30. be done.

The linear motor 30 has a stator 31 that is directly or indirectly fixed to the wall 12 of the building 10 and a mover 32 that moves relative to the stator 31 . The stator 31 is an electromagnet section having a plurality of electromagnets, and is fixed to the wall section 13 on the indoor side of the wall section 12 . A gap (air gap) is provided between the stator 31 and the mover 32 . The mover 32 is a permanent magnet section having a plurality of permanent magnets, and is arranged below the stator 31 without contacting the stator 31 . The stator 31 and the mover 32 extend along the movement direction K of the first shoji 2 and are arranged parallel to each other. The stator 31 is shorter than the mover 32 in the moving direction K of the first shoji 2 and is located in the central area within the moving area of the mover 32 . The mover 32 is longer than the stator 31 in the moving direction K of the first shoji 2, and extends from the position on one side of the moving direction K of the first shoji 2 to the position on the other side with respect to the stator 31. 2 in the movement direction K.

A plurality of electromagnets of the stator 31 are arranged in order in the moving direction K of the first shoji 2 . The plurality of permanent magnets of the mover 32 are arranged in order in the movement direction K of the first shoji 2 so that the magnetic poles of adjacent permanent magnets are opposite to each other. A controller (not shown) that controls the movement of the linear motor 30 and the first shoji 2 controls the direction of the current flowing through the plurality of electromagnets of the stator 31 corresponding to the position of the mover 32 (first shoji 2). are respectively changed, and the magnetic poles of the plurality of electromagnets of the stator 31 are respectively exchanged. As a result, the magnetic force of repulsion and the magnetic force of attraction act repeatedly in order from the electromagnet of the stator 31 to the permanent magnet of the mover 32 , generating power for moving the mover 32 . The mover 32 moves relative to the stator 31 by the power received from the stator 31 and moves along the stator 31 .

The bracket 40 is a connecting member that connects the mover 32 of the linear motor 30 and the first shoji 2, and the mover 32, the bracket 40, and the first shoji 2 move integrally. The bracket 40 extends from the mover 32 to the first shoji 2 and is attached to the mover 32 and the first shoji 2 . In addition, the bracket 40 protrudes downward from the mover 32, is below the linear motor 30, the guide roller 50, the guide body 70, and the lower roller 60, and extends toward the outdoor side to the first shoji 2. .

The bracket 40 is attached to the mover 32 at a point on the indoor side of the opening 11 of the building 10, and extends from a point on the indoor side of the opening 11 of the building 10 to a point inside the opening 11 of the building 10. It is attached to the 1st shoji 2 in the location in the opening part 11 of 10. As shown in FIG. The linear motor 30 generates power in the moving direction K of the first shoji 2 and transmits the power from the mover 32 to the first shoji 2 via the bracket 40 . Thereby, the linear motor 30 moves the 1st shoji 2 to one side and the other side of the moving direction K, and opens and closes the 1st shoji 2. As shown in FIG.

The mover 32 has a plurality (here, two) of connecting portions 33 , and the bracket 40 is attached to each of the connecting portions 33 . The connecting portions 33 are protruding pieces (connecting pieces) protruding downward from the mover 32 and are spaced apart from each other in the longitudinal direction of the mover 32 (moving direction K of the first shoji 2). The bracket 40 includes an indoor mounting portion 41 attached to the mover 32, an outdoor mounting portion 42 attached to the first shoji 2, and projected from the indoor mounting portion 41 to the outdoor mounting portion 42 to the outdoor side. It has an overhang portion 43 .

The projecting portion 43 of the bracket 40 projects from a position below the linear motor 30, the guide roller 50, the guide body 70, and the lower roller 60 to the upper frame 2C of the first shoji 2 to the outside of the room. The projecting portion 43 extends in the indoor-outdoor direction S from a location on the indoor side of the opening 11 of the building 10 to a location within the opening 11 of the building 10 . The indoor-side mounting portion 41 of the bracket 40 protrudes upward from the indoor-side end portion of the projecting portion 43 at a location on the indoor side of the opening 11 of the building 10 and is attached to the connecting portion 33 of the mover 32. . The outdoor-side mounting portion 42 of the bracket 40 protrudes downward from the outdoor-side end portion of the projecting portion 43 at a location within the opening 11 of the building 10 and is attached to the upper frame 2C of the first shoji 2 . The first shoji 2 is connected to the connecting portion 33 of the mover 32 by the bracket 40 .

The guide roller 50 is the first roller of the fitting 1 and is connected to the mover 32 . The lower roller 60 is the second roller of the fitting 1 and is connected to the bracket 40 . The stator 31 of the linear motor 30, the mover 32 of the linear motor 30, the guide roller 50, and the lower roller 60 are arranged in the vertical direction and arranged in order from top to bottom. Therefore, in the vertical direction, the guide roller 50 is arranged below the linear motor 30 and the mover 32 (excluding the connecting portion 33), and the lower roller 60 is arranged below the guide roller 50. As shown in FIG.

The axis of the guide roller 50 is the center of rotation of the guide roller 50, and the axial direction of the guide roller 50 is the direction in which the axis of the guide roller 50 extends. The axial direction of the guide roller 50 is the indoor-outdoor direction S, and the guide roller 50 rotates in both directions around the axis extending in the indoor-outdoor direction S. The axial center of the lower roller 60 is the center of rotation of the lower roller 60, and the axial direction of the lower roller 60 is the direction in which the axial center of the lower roller 60 extends. The axial direction of the lower roller 60 is the vertical direction, and the lower roller 60 rotates in both directions around the axis extending in the vertical direction.

The guide roller 50 is positioned on the outdoor side (on the side of the guide body 70 ) of the indoor mounting portion 41 of the bracket 40 and the connecting portion 33 of the mover 32 and attached to the connecting portion 33 of the mover 32 . Further, the guide roller 50 has an engaging groove 52 formed in the outer peripheral portion 51 and a shaft portion 53 positioned at the axial center of the guide roller 50 . The engagement groove 52 is a concave portion continuously extending in the circumferential direction of the guide roller 50 and is formed in an annular shape on the outer peripheral portion 51 of the guide roller 50 . The shaft portion 53 is a support shaft for the guide roller 50 and protrudes in the axial direction of the guide roller 50 .

A shaft portion 53 of the guide roller 50 is attached to the mover 32 and the bracket 40 , and the shaft portion 53 connects the mover 32 and the bracket 40 to each other. The shaft portion 53 protrudes into the room, passes through the connecting portion 33 of the mover 32 and the indoor mounting portion 41 of the bracket 40 in the indoor-outdoor direction S, and connects the connecting portion 33 of the mover 32 and the indoor mounting portion 41 of the bracket 40 . It is attached to the portion 41 . The guide roller 50 is connected to the connecting portion 33 of the mover 32 by a shaft portion 53 . The indoor-side attachment portion 41 of the bracket 40 is attached to the connecting portion 33 of the guide roller 50 and the mover 32 by the shaft portion 53 .

The lower roller 60 is positioned above the portion (overhanging portion 43 ) of the bracket 40 extending in the indoor/outdoor direction S and attached to the overhanging portion 43 of the bracket 40 . Further, the lower roller 60 has an engaging groove 62 formed in the outer peripheral portion 61 and a shaft portion 63 located at the axial center of the lower roller 60 . The engaging groove 62 is a concave portion continuously extending in the circumferential direction of the lower roller 60 and is formed in an annular shape on the outer peripheral portion 61 of the lower roller 60 . The shaft portion 63 is a support shaft for the lower roller 60 and protrudes in the axial direction of the lower roller 60 . The shaft portion 63 protrudes downward, passes vertically through the projecting portion 43 of the bracket 40 , and is attached to the projecting portion 43 of the bracket 40 . The lower roller 60 is connected to the projecting portion 43 of the bracket 40 by a shaft portion 63 .

The fitting 1 includes a housing portion 71 provided in the guide body 70 , a guide rail portion 80 and a lower rail portion 90 . The guide body 70 and each part 71 , 80 , 90 of the guide body 70 are directly or indirectly fixed to the wall 12 of the building 10 . Here, the guide body 70 and the parts 71, 80, and 90 of the guide body 70 are attached to the wall surface portion 13 on the indoor side of the wall portion 12 of the building 10 and fixed to the wall portion 12 of the building 10. It is arranged at a position on the indoor side of the opening 11 . The housing portion 71, the guide rail portion 80, and the lower rail portion 90 are arranged in the vertical direction and provided in order from top to bottom. Therefore, in the vertical direction, the guide rail portion 80 is arranged below the housing portion 71 , and the lower rail portion 90 is arranged below the guide rail portion 80 .

The guide body 70 and each part 71 , 80 , 90 of the guide body 70 extend along the moving direction K of the first shoji 2 . The accommodation portion 71 is a recessed groove (accommodation groove) that opens toward the interior of the room, and is partitioned between an upper partition portion 72 positioned above the linear motor 30 and the guide rail portion 80 . The upper partition portion 72 is an upper surface portion of the guide body 70 and the housing portion 71 that protrudes toward the interior side of the room. The stator 31 of the linear motor 30 is attached to the upper partition portion 72 of the housing portion 71 of the guide body 70, and is fixed to the wall portion 12 (wall surface portion 13) of the building 10 by the housing portion 71 of the guide body 70. there is The stator 31 and mover 32 of the linear motor 30 are housed in the housing portion 71 and arranged between the upper partition portion 72 and the guide rail portion 80 in the vertical direction.

In the vertical direction, the stator 31 is arranged between the upper partition portion 72 and the mover 32 , and the mover 32 is arranged between the stator 31 and the guide rail portion 80 . In the indoor-outdoor direction S, the connecting portion 33 of the mover 32 and the indoor-side mounting portion 41 of the bracket 40 are arranged on the indoor side of the guide rail portion 80 . The guide rail portion 80 is the first rail portion of the fitting 1 , and the lower rail portion 90 is the second rail portion of the fitting 1 . In the vertical direction, the guide rail portion 80 and the guide roller 50 are positioned between the housing portion 71 and the lower rail portion 90 and below the mover 32 of the linear motor 30 . The lower rail portion 90 and the lower roller 60 are arranged below the guide roller 50 and the guide rail portion 80 .

The guide rail portion 80 and the guide roller 50 are positioned between the mover 32 of the linear motor 30 and the lower roller 60 in the vertical direction. The guide rail portion 80 is a recessed groove portion (guide groove) opened toward the indoor side, and supports the guide roller 50 movably in the movement direction K of the first shoji 2 . The guide roller 50 is guided by the guide rail portion 80 and moves in the moving direction K of the first shoji 2 . The mover 32 is supported by the guide rail portion 80 via the guide roller 50 and is guided in the moving direction K of the first shoji 2 by the guide roller 50 and the guide rail portion 80 .

The guide rail portion 80 includes an upper portion 81 positioned above the guide roller 50, a lower portion 82 positioned below the guide roller 50, an upper rail 83 projecting downward from the upper portion 81, and a lower portion. It has a lower rail 84 projecting upwardly from 82 . The upper portion 81 and the lower portion 82 are wall portions (upper wall portion, lower wall portion) of the guide rail portion 80 that protrude into the room, and are arranged to face each other in the vertical direction. The upper rail 83 and the lower rail 84 protrude toward each other and are arranged to face each other in the vertical direction. The guide rollers 50 are arranged between the upper part 81 and the lower part 82 and between the upper rail 83 and the lower rail 84 .

The guide roller 50 is placed on the lower rail 84 and sandwiched between the upper rail 83 and the lower rail 84 . In that state, the guide roller 50 moves in the moving direction K of the first shoji 2 along the upper rail 83 and the lower rail 84 of the guide rail portion 80 . The upper rail 83 is arranged in the engagement groove 52 of the guide roller 50 on the upper side of the guide roller 50 and fits into the engagement groove 52 of the guide roller 50 . The lower rail 84 is arranged in the engagement groove 52 of the guide roller 50 below the guide roller 50 and fits into the engagement groove 52 of the guide roller 50 .

With the engaging groove 52 of the guide roller 50 placed on the lower rail 84 , the upper rail 83 is arranged in the engaging groove 52 of the guide roller 50 and comes into contact with the guide roller 50 . As a result, the upper rail 83 and the lower rail 84 of the guide rail portion 80 are engaged with the engagement grooves 52 of the guide roller 50 , and the guide rail portion 80 is engaged with the guide roller 50 . The guide rail portion 80 restricts displacement of the guide roller 50 in the vertical direction and the indoor/outdoor direction S by means of an upper rail 83 and a lower rail 84 . When the first shoji 2 is moved, the guide rail part 80 guides the guide roller 50 in the movement direction K of the first shoji 2 in a state in which the guide roller 50 is sandwiched between the upper rail 83 and the lower rail 84 from above and below. .

The guide rail portion 80 and the lower rail portion 90 are integrally formed in the guide body 70 . The lower rail portion 90 is formed integrally with a portion of the guide rail portion 80 located below the guide roller 50 (here, the lower portion 82). located on the lower side. The lower rail portion 90 is a concave groove portion (lower groove) opened downward, and supports the lower roller 60 movably in the moving direction K of the first shoji 2 . The lower roller 60 moves in the moving direction K of the first shoji 2 while being guided by the lower rail portion 90 . The bracket 40 is supported by the lower rail portion 90 via the lower roller 60 and guided in the moving direction K of the first shoji 2 by the lower roller 60 and the lower rail portion 90 .

The lower rail portion 90 includes an indoor side portion 91 positioned on the indoor side of the lower roller 60, an outdoor side portion 92 positioned on the outdoor side of the lower roller 60, and a chamber projecting from the indoor side portion 91 to the outdoor side. It has an inner rail 93 and an outdoor rail 94 projecting from the outdoor side portion 92 to the indoor side. The indoor side portion 91 and the outdoor side portion 92 are wall portions (indoor side wall portion, outdoor side wall portion) of the lower rail portion 90 projecting downward, and are arranged to face each other in the indoor/outdoor direction S. The indoor-side rail 93 and the outdoor-side rail 94 protrude in a direction approaching each other, and are arranged to face each other in the indoor-outdoor direction S. The lower rollers 60 are arranged between the indoor side portion 91 and the outdoor side portion 92 and between the indoor side rail 93 and the outdoor side rail 94 .

The lower roller 60 is sandwiched between the indoor rail 93 and the outdoor rail 94 . In this state, the lower roller 60 moves in the movement direction K of the first shoji 2 along the indoor rail 93 and the outdoor rail 94 of the lower rail portion 90 . The indoor rail 93 is arranged in the engaging groove 62 of the lower roller 60 on the indoor side of the lower roller 60 and fits into the engaging groove 62 of the lower roller 60 . The outdoor rail 94 is arranged in the engaging groove 62 of the lower roller 60 on the outdoor side of the lower roller 60 and fits into the engaging groove 62 of the lower roller 60 .

The indoor rail 93 and the outdoor rail 94 are arranged in the engagement groove 62 of the lower roller 60 and come into contact with the lower roller 60 . As a result, the indoor rail 93 and the outdoor rail 94 of the lower rail portion 90 are engaged with the engaging grooves 62 of the lower roller 60 , and the lower rail portion 90 is engaged with the lower roller 60 . The lower rail portion 90 regulates displacement of the lower roller 60 in the vertical direction and the indoor-outdoor direction S by means of the indoor rail 93 and the outdoor rail 94 . When the first shoji 2 is moved, the lower rail portion 90 moves the lower roller 60 to the first shoji 2 while sandwiching the lower roller 60 from the indoor-outdoor direction S with the indoor-side rail 93 and the outdoor-side rail 94 . in the direction of movement K of .

In the fitting 1 of the present embodiment described above, the guide rollers 50 are sandwiched from above and below by the guide rails 80, so that the guide rollers 50, the movers 32, and the brackets 40 move in the moving direction K of the first shoji 2. It can be moved stably. Moreover, when moving the 1st shoji 2 by the linear motor 30, the rattling of the bracket 40 and the 1st shoji 2 can be suppressed, and the 1st shoji 2 can be moved smoothly. As a result, the sound generated during the movement of the first shoji 2 can be reduced.

The lower roller 60 is sandwiched between the lower rail portions 90 in the indoor/outdoor direction S, and the bracket 40 is supported at two points, the guide roller 50 and the lower roller 60 . Therefore, the bracket 40 can be stably supported, and rattling of the bracket 40 and the first shoji 2 can be reduced. By forming the lower rail portion 90 on the lower side portion 82 of the guide rail portion 80, the number of components of the fitting 1 can be reduced, and the guide rail portion 80 and the lower rail portion 90 can be made compact.

A shaft portion 53 of the guide roller 50 is attached to the mover 32 and the bracket 40, and the mover 32 and the bracket 40 are stably supported by the shaft portion 53 of the guide roller 50, and the bracket 40 and the first shoji 2 are supported. The moving direction K of the 1st shoji 2 can be stably moved. The guide roller 50 is arranged below the linear motor 30 and the lower roller 60 is arranged below the guide roller 50 . Therefore, the linear motor 30, the guide roller 50, and the lower roller 60 can be arranged compactly.

Note that the guide rail portion 80 and the lower rail portion 90 may be formed as separate members and fixed to the wall portion 12 of the building 10, respectively. Also, the bracket 40 may be attached to a portion of the first shoji 2 other than the upper frame 2C. The guide roller 50 and the lower roller 60 may be provided at different positions in the indoor/outdoor direction S. For example, the lower roller 60 may be provided at a position on the outdoor side of the guide roller 50 . The fittings may be a single sliding window having one shoji, or fittings other than the single sliding window (for example, a double sliding window).

As mentioned above, the fittings are
A fitting in which a shoji and a linear motor for moving the shoji are spaced apart in the indoor and outdoor direction,
The linear motor has a stator fixed to a wall of a building and a mover that moves with respect to the stator,
a bracket that connects the mover and the shoji;
a guide roller connected to the mover;
A guide rail portion that guides the guide roller in a moving direction of the shoji while sandwiching the guide roller from above and below;
It is a fixture with
Therefore, when the sash is moved by the linear motor that is separated from the sash in the indoor-outdoor direction, it is possible to suppress the rattling of the sash and smoothly move the sash.

fittings are
a lower roller positioned below the guide rail portion and connected to the bracket;
a lower rail portion that is located below the guide rail portion and guides the lower roller in a moving direction of the shoji while sandwiching the lower roller from the indoor and outdoor directions;
Prepare.
Therefore, the bracket can be stably supported, and rattling of the bracket and the shoji can be reduced.

The lower rail portion is formed in a portion of the guide rail portion below the guide roller.
Therefore, the number of fitting parts can be reduced, and the guide rail portion and the lower rail portion can be made compact.

The guide roller has a shaft portion positioned at the axial center of the guide roller and attached to the mover and the bracket.
Therefore, the mover and the bracket can be stably supported by the shaft portion of the guide roller, and the bracket and the shoji can be stably moved in the moving direction of the shoji.

The guide roller is arranged below the linear motor,
The lower roller is arranged below the guide roller.
Therefore, the linear motor, guide rollers, and lower rollers can be arranged compactly.

1... fitting, 2... first shoji, 2A... frame body, 2B... panel, 2C... upper frame, 2D... lower frame, 2E... door frame, 2F ... meeting frame, 3 ... second shoji, 3A ... frame body, 3B ... panel, 3C ... upper frame, 3D ... lower frame, 3E ... door frame, 3F: meeting frame, 4: screen door, 10: building, 11: opening, 12: wall, 13: wall surface, 20: frame, 21: Opening 22 Upper frame 23 Lower frame 24 Vertical frame 25 Vertical frame 30 Linear motor 31 Stator 32 Mover 33 Connecting portion 40 Bracket 41 Indoor mounting portion 42 Outdoor mounting portion 43 Overhang 50 Guide roller 51... Peripheral part, 52... Engagement groove, 53... Shaft part, 60... Lower roller, 61... Periphery part, 62... Engagement groove, 63... Shaft Part, 70... Guide body, 71... Accommodating part, 72... Upper partition part, 80... Guide rail part, 81... Upper part, 82... Lower part, 83... Upper rail 84 Lower rail 90 Lower rail portion 91 Indoor side portion 92 Outdoor side portion 93 Indoor rail 94 Outdoor side Rail, K: moving direction, S: indoor/outdoor direction.

Claims (5)

A fitting in which a shoji and a linear motor for moving the shoji are spaced apart in the indoor and outdoor direction,
The linear motor has a stator fixed to a wall of a building and a mover that moves with respect to the stator,
a bracket that connects the mover and the shoji;
a guide roller connected to the mover;
A guide rail portion that guides the guide roller in a moving direction of the shoji while sandwiching the guide roller from above and below;
fittings with In the fitting according to claim 1,
a lower roller positioned below the guide rail portion and connected to the bracket;
a lower rail portion that is located below the guide rail portion and guides the lower roller in a moving direction of the shoji while sandwiching the lower roller from the indoor and outdoor directions;
fittings with In the fitting according to claim 2,
The lower rail portion is a fitting formed in a portion below the guide roller of the guide rail portion. In the fitting according to any one of claims 1 to 3,
The said guide roller is a fixture which has the axial part which was located in the axial center of the said guide roller, and was attached to the said mover and the said bracket. In the fitting according to any one of claims 1 to 4,
The guide roller is arranged below the linear motor,
The lower roller is a fitting arranged below the guide roller.

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