JP7454285B2 - Stepladder that doubles as a ladder - Google Patents

Description

The present invention relates to a stepladder that doubles as a ladder .

As an example of a structure for working at high places that includes a ladder body in which a plurality of rungs are stopped between two supports in a stepped manner, two ladder bodies are disclosed, for example, in Patent Document 1 below. A stepladder is known in which the upper ends of the stepladder are connected to each other by a hinge so that they can be opened and closed. Further, as one form of a stepladder, a stepladder that can also be used as a ladder is known by rotating one of the two ladder bodies so as to turn it upside down.

Japanese Patent Application Publication No. 2003-193780

It is an object of the present invention to provide a stepladder that can be used as a ladder and has a mechanism that can prevent an operating member provided on the ladder body from moving when the ladder body is turned upside down when used as a ladder. .

This invention consists of the following aspects in order to achieve the above object.

1) The upper ends of two ladder bodies each comprising two hollow pillars on the left and right and a plurality of rungs fixed in steps between the two pillars are connected to each other by a hinge so that they can be opened and closed. A stepladder that doubles as a ladder and can also be used as a ladder by rotating one of the two ladder bodies upside down,
Each ladder body further includes a telescoping leg member that is slidably inserted into each support column from its lower end and has a grounding portion at the end opposite to the insertion side, and locks the telescoping leg member at an arbitrary sliding position. The telescoping leg device includes a locking mechanism and a remote control mechanism that can unlock the telescoping leg member by the locking mechanism by remote control.
The remote control mechanism includes an operating member that is movable in a predetermined operating direction and that can unlock the telescopic leg member by the locking mechanism by moving in the same operating direction, and an operating member that can be turned upside down for use as a ladder. a swing stopper swingably provided to prevent movement of the operating member in the operating direction in the moved ladder body;
The swing stopper has a swing shaft at one end in a predetermined direction, a swing tip at the other end, and both sides in the swing direction from the swing shaft to the opposite side of the swing tip. A stepladder that doubles as a ladder, with parts whose widths gradually become smaller.

2) The stepladder of 1) above, wherein the swing stopper has a portion between the swing shaft and the swing tip where the width between both sides in the swing direction is the largest.

3) The swing stopper has a flat shape with a thickness smaller in the swing axis direction than the length in the predetermined direction and the maximum width between both sides in the swing direction, and can also be used as a ladder in 1) or 2) above. stepladder.

4) The swing stopper has an insertion part that protrudes from one end in the predetermined direction and is loosely inserted into a stopper mounting hole provided at a predetermined location of the ladder body, and the swing stopper allows the swing shaft to be rotated by the insertion part. A stepladder that doubles as a ladder according to any one of 1) to 3) above.

5) The swing stopper is configured to swing by its own weight from a first position where it does not block the movement of the operating member to a second position where it blocks the movement of the operating member when the ladder body is turned upside down; The swing stopper in the first position has a line connecting the swing axis and the swing tip inclined in the swing direction to the second position with respect to a vertical line passing through the swing axis, and the swing stopper is in the second position. In the swing stopper, the line connecting the swing axis and the swing tip is inclined in the swing direction toward the first position with respect to the vertical line passing through the swing axis, 1) to 4) above. A stepladder that doubles as a ladder.

According to the stepladder of the present invention, when one ladder body is turned upside down and used as a ladder, the swing stopper prevents the movement member provided on the same ladder body from moving in the movement direction. .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall perspective view of a ladder/stepladder equipped with a swing stopper according to an embodiment of the present invention. It shows the locked state of the telescoping leg device provided in the ladder-cum-stepladder, in which (a) is a partial front view and (b) is a sectional view taken along line BB in (a). FIG. 2 shows the telescopic leg device in an unlocked state, with (a) being a partial front view and (b) being a sectional view taken along line BB in (a). It is a perspective view showing the lower part of the telescoping leg device. It is an exploded perspective view showing the lower part of the telescopic leg device. (a) is a vertical cross-sectional view showing the lower part of the telescoping leg device, and (b) is a cross-sectional view taken along line BB in (a). It is a perspective view showing the upper part of the telescoping leg device. It is a perspective view showing an exploded upper part of the telescopic leg device. It is a perspective view showing an exploded upper operation lever of the telescopic leg device. FIG. 3 is a vertical cross-sectional view showing the upper part of the telescopic leg device, in which (a) shows a state in which the upper operating lever is in the unlocking non-operating position, and (b) shows a state in which the upper operating lever is in the unlocking operating position. , and (c) shows the state when the ladder body is turned upside down.

Next, with reference to FIGS. 1 to 10, an embodiment of a ladder-cum-stepladder equipped with a swing stopper according to the present invention will be described.
In addition, in the following explanation, the right side of FIG. 2(b), FIG. 3(b), and FIG. It refers to the left and right (for example, the left and right in FIG. 2(a), FIG. 3(a), and FIG. 6).

As shown in Fig. 1, the stepladder (1) is constructed by connecting the upper ends of two front and rear ladder bodies (2F) and (2R) so that they can be opened and closed by a hinge fitting (201), and one of the ladder bodies ( For example, by rotating the front ladder body (2F) upside down, it can also be used as a ladder.
Each of the front and rear ladder bodies (2F) (2R) consists of two hollow pillars (3) on the left and right, and a plurality of ladders suspended vertically at intervals between the pillars (3). It is equipped with five stepping stones (4A), (4B), (4C), (4D), and (4E). The top step ledge (4E) constitutes a top plate when used as a stepladder.
An opening stopper (202) is fixed between the upper parts of the left pillars (3) of the front and rear ladder bodies (2F) (2R) and between the upper parts of the right pillars (3). The opening stopper (202) consists of two links whose one ends are rotatably connected to each other, and a hook provided at the other end of one link is connected to a locking pin provided on the post (3). It is designed to be able to be attached and detached at will.
Telescoping leg devices (5) according to the present invention are provided at the lower portions of the left and right columns (3) of the front and rear ladder bodies (2A, 2B), respectively.

2 to 10 show the detailed structure of the front ladder body (2F). Note that since the rear ladder body (2R) is approximately symmetrical to the front ladder body (2F), detailed illustration and explanation will be omitted.
Each of the left and right columns (3) of the front ladder body (2F) is made of a metal section such as an aluminum alloy section, and has a substantially U-shaped cross section that opens inward in the left-right direction.
Each treadle (4A), (4B), (4C), (4D), and (4E) is also made of a metal profile such as an aluminum alloy profile, and is hollow with a substantially rectangular cross section.
The left and right ends of the lowest step (4A) and the second step from the bottom (second upper step) (4B) are connected to each other through a pair of front and rear brackets (101) (102), respectively. It is attached to the left and right pillars (3). A required gap (S) is formed between each of the left and right ends of these step bars (4A) (4B) and each of the left and right columns (3). The left and right ends of the third step from the bottom (first upper step) (4C) and the upper steps (4D) and (4E) are inserted into the left and right columns (3). For example, it is directly attached to the front and rear side walls of the support column (3) with rivets (11).

The telescopic leg device (5) installed at the bottom of each of the left and right columns (3) of the front ladder body (2F) is slidably inserted into each column (3) from the lower end and is grounded at the end on the side opposite to insertion. The telescopic leg member (6) has a portion (61), and a locking mechanism (7) that locks the telescopic leg member (6) at an arbitrary sliding position.

The telescopic leg member (6) is made of a metal profile such as an aluminum alloy profile, and has a substantially rectangular cross section. The front and rear walls of the telescopic leg member (6) are curved into a substantially U-shape so as to protrude toward each other. Slide guiding protrusions (63) are formed in an extended shape on the front and rear edges of the left and right outer walls of the telescopic leg members (6), and these protrusions (63) It is slidably fitted into a vertical groove (31) formed on the left-right outer edge of the inner surface of the front and rear walls (see FIG. 6(b)). An internal enlarged groove (62) that opens inward in the left-right direction is formed in the left-right inner wall portion of the telescoping leg member (6).

The locking mechanism (7) includes a rack (locked part ) (71) and the vicinity of the lower end of each post (3) in the front ladder body (2F), more specifically, the left and right ends of the lowest rung (4A) for attaching to the post (3). Teeth (721a) are attached to the front and rear bracket (101) so as to be swingable about a swing shaft (720) extending in the front and back direction, and are provided at the outer ends in the left and right direction to mesh with the teeth (711) of the rack (71). A locking member (72) having a locking portion (721) formed therein; ) and a spring (biasing member) (73) that biases in the direction of engagement (counterclockwise direction in FIG. 6(a)).
An operating lever section (722) is provided at the inner end in the left-right direction of the locking member (72), and by pressing the operating lever section (722) upward, the spring elastic force ( The locking member (72) is moved in the direction in which the teeth (721a) of the locking portion (721) are disengaged from the teeth (711) of the rack (71) (clockwise direction in FIG. 6(a)) against the urging force (biasing force). is shaken.
In other words, the locking member (72) is in the locked position where the teeth (721a) of the locking part (721) mesh with the teeth (711) of the rack (71), and in the lock position where the teeth (721a) of the locking part (721) mesh with the teeth (721a) of the locking part (721). It is possible to switch between the lock release position where the rack (71) is disengaged from the teeth (711).
The spring (73) is interposed in the vertical direction between the inner side portion of the locking member (72) in the left-right direction and the lower surface of the lowermost treadle (4A). A spring holding portion (724) extending upward in a branched manner is formed at a mid-length position of the left-right inner portion of the locking member (72), and the spring holding portion (724) and the swing shaft ( The lower end of the spring (73) is inserted and held between the spring (720) and the center (723) through which the spring (720) is inserted.
A metal cover member (103) having a substantially U-shaped cross section is fitted onto the lower end of each support column (3) so as to cover the opening of each support column (3). The front and rear brackets (101) are attached to the front and rear walls of the support column (3) from above the front and rear walls of the cover member (103) with rivets or the like. A vertical rectangular communication window (103a) is formed in the cover member (103) to expose some of the teeth (711) of the rack (71). The teeth (721a) of the locking portion (721) of the locking member (72) are engaged with the teeth (711) of the rack (71) through this communication window (103a).
Note that the lock mechanism (7) is not limited to what is shown in the drawings, and can be modified as appropriate. For example, in addition to providing the locking member (72) below the lowest step (4A) as described above, the locking member (72) may be incorporated inside the step (4A) or placed above the step (4A). It may be provided.

The telescopic leg device (5) is equipped with a remote control mechanism having the following configuration.
That is, on the back of the first upper step rung (4C), which consists of the step rung located at the third step counting from the bottom of the front ladder body (2F), each of the left and right telescopic leg members (6) with the left and right lock mechanisms (7) ) is provided to perform a predetermined operation. Two left and right transmission members (9) are provided along each support column (3). By operating the upper operating member (8) to perform a predetermined operation, each locking member (72) can be switched to the unlocked position via each transmission member (9).
Considering the size of a normal ladder body, the third step from the bottom (4C) is considered to be appropriate for the first upper rung where the upper operating member (8) is provided on the back side. Depending on the size of the body, how it is used, etc., it may be the second step from the bottom or the fourth or higher step from the bottom.

The upper operating members are attached to the back surfaces of the substantially left half and substantially right half of the first upper step rung (4C) so as to be able to swing freely about shafts extending in the left-right direction and to be arranged in close proximity to each other. Consists of two flap-shaped upper operating levers (8) on the left and right. By swinging these upper operating levers (8) in the unlocking operation direction (counterclockwise direction in Figures 10(a) and (b)) (A) that approaches the back of the first upper step ledge (4C). , the locking member (71) can be switched to the unlocked position via the transmission member (9).
Each upper operating lever (8) has a lever body (81) made of a metal profile such as an aluminum alloy profile. The lever main body (81) is flat and hollow, and has an inclined wall part (811) extending diagonally forward and upward at its upper edge. A rearwardly curved hinge-forming fitting convex strip (811a) is formed at the tip edge of the inclined wall portion (811).
On the other hand, a groove forming fitting groove (41) extending in the left-right direction is formed on the upper edge of the back surface of the first upper step rung (4C). The hinge-forming fitting groove (41) has a cross section that extends diagonally upward and forward from the upper edge of the back surface of the first upper treadle (4C), and its deep part is curved toward the rear. I'm forced to.
Then, the hinge-forming fitting protrusion (811a) of the lever body (81) is inserted into the hinge-forming fitting groove (41) of the first upper treadle (4C) through its opening, and is rotatable. As a result, the lever main body (81) is attached to the back side of the first upper treadle (4C) so as to be able to swing around the fitting protrusion (811a).

A first end cap (82) is fitted over the outer end in the left-right direction, which is the side closer to the pillar (3), of both ends of the lever body (81). The first end cap (81) is made of a synthetic resin molded product, and is secured by a tapping screw (not shown) that passes through the end cap (81) and is screwed into the tapping screw hole (812) at the bottom of the lever body (81). It is fixed to the lever body (81).
The first end cap (82) is integrally provided with an arm portion (821) that extends forward from its lower portion so as to protrude into the space below the first upper treadle (4C).
A cam shaft (821a) extending into the opening of each support column (3) is integrally formed at the intermediate position (or tip position) of the arm part (821).
Furthermore, a swing stopper (84) is provided at the base end of the arm portion (821), which is swingable about a shaft extending in the left-right direction. As shown in FIG. 10, the swing stopper (84) is approximately bell-shaped when viewed from the side, and is a half-split insert formed to protrude outward in the left-right direction from one end of the swing stopper (84). (841) is loosely inserted into the hole made in the vertical wall portion of the arm portion (821), so that the insertion portion (841) (swinging) is accommodated in the swinging stopper accommodating portion (820). It is made to be able to swing freely around the (moving axis). As shown in FIGS. 10(a) and 10(b), when the ladder/stepladder (1) is used as a stepladder, the swing stopper (84) moves in the first direction in the clockwise direction in the figure due to its own weight. The first abutting portion (842) that swings in the swinging direction and is provided on the side in the first swinging direction is the first abutted portion made of the horizontal lower wall portion of the arm portion (821). (822) (first position), so as not to interfere with the first upper treadle (4C) when the upper operation lever (8) swings. On the other hand, as shown in FIG. 10(c), when one ladder body (for example, the front ladder (2F)) is turned upside down to use the ladder/stepladder (1) as a ladder, the same ladder body The swing stopper (84) swings in the second swing direction, which is the counterclockwise direction in FIG. The contact portion (843) is brought into contact with a second contact portion (823) consisting of a part (the upper part in FIG. 10(c)) of the first end cap (82), and the upper operating lever (8) is positioned so as to be sandwiched between the lever main body (81) and the back surface of the first upper treadle (4C) (second position). Therefore, when the ladder body is upside down as shown in the figure, the third contact portion (844) provided at the other end of the swing stopper (84) is connected to the back surface of the first upper rung (4C). By being brought into contact with the third abutted part (42) consisting of a corner part between the lower surface and the lower surface, the upper operating lever (8) moves in the unlocking operation direction (counterclockwise direction in FIG. 10(c)). Since rocking is prevented, for example, even if the upper operating lever (8) is pressed while climbing or descending a ladder, the locking mechanism (7) of the telescopic leg member (6) will be accidentally released. It can be used safely without any damage.

A second end cap (83) is fitted over the inner end in the left-right direction, which is the side closer to the center of the length of the first upper treadle (4C), of both ends of the lever body (81). The second end cap (83) is made of a synthetic resin molded product, and has an insertion portion (832) protruding from one side and having a substantially cross-shaped cross section inside the inner end in the left and right direction of the lever body (81). It is fixed to the same end by fitting it into the same end.
A lever return plate spring portion (lever return biasing member) (831) is integrally formed with the second end cap (83). The leaf spring part (831) has a substantially tongue-like shape when viewed from the front, and extends in a curved shape from the second end cap (83) outward in the left-right direction and obliquely forward, and is connected to the upper operating lever (83). ) and the back of the first upper step (4C), and its spring elastic force biases the upper operating lever (8) in the direction away from the back of the first upper step (4C). .

Each transmission member (9) has a gap (S ) is provided with a lift bar (91) that is slidable along the length of each support column (3). The elevating bar (91) has a substantially band-like shape with front and rear edges bent outward in the left-right direction. The length of the elevating bar (91) is slightly shorter than the length from the bottom surface of the first upper treadle (4C) to the top surface of the lowest step treadle (4A) at the left and right inner side of the column (3). being done. The width of the lift bar (91) is slightly smaller than the width of the inner portion of the support column (3) in the left-right direction.
A vertically long strip-shaped communication window (911) is formed at the lower end of the lift bar (91). This communication window (911) is used when fitting and fixing the retaining cap (62) to the upper end of the telescopic leg member (6) inserted into the support column (3). The retaining cap (62) has a retaining portion (621) that protrudes inward in the left-right direction, and when the retaining portion (621) comes into contact with the upper edge of the cover member (103), it expands and contracts. The leg member (6) is prevented from falling off the support column (3). By providing a communication window (911) on the lifting bar (91), the retaining cap (62) can be fitted and fixed to the upper end of the telescopic leg member (6) in the final step of assembling the front ladder body (2F). This makes assembly work easier.

A slider (92) is housed in the lower part of the first upper step (4C) in the support (3) so as to be slidable through the opening of the support (3). Further, the slider (92) is connected to the upper end of the lift bar (91).
The slider (92) is made of a synthetic resin molded product in the shape of a substantially rectangular block, and the upper end of the lift bar (91) is connected and fixed to the lower part of the inner side surface in the left and right direction with a rivet or the like.
A cam surface (921) that slopes forward is formed on the upper surface of the slider (92). The cam shaft (821a) is configured to slide on this cam surface (921) as the upper operating lever (8) swings. These cam surfaces (921) and cam shafts (821a) form a cam mechanism (upper interlocking mechanism) that converts the swinging motion of the upper operating lever (8) into vertical motion of the slider (92) and the lifting bar (91). It consists of In other words, when the upper operation lever (8) is swung in the unlock operation direction (counterclockwise direction in FIGS. 10(a) and 10(b)), the cam shaft (821a) moves over the cam surface (921) at its lower end. The slider (92) is pushed down by sliding the slider (92) from the lower end toward the upper end, which in turn causes the lift bar (91) to slide downward.
The slider (92) is provided with a locking state retaining stopper portion (922) located above the lower end of the cam surface. The stopper part (922) is a substantially horizontal bar-shaped part that is provided on an outer wall part rising from the left-right outer edge of the cam surface (921) of the slider (92) so as to protrude toward the cam surface (921). The upper operating lever (8) is positioned above the camshaft (821a) when the upper operating lever (8) is swung in a direction away from the back surface of the first upper treadle (4C). Therefore, even if an unintended downward external force is applied to the lift bar (91) due to, for example, touching the lift bar (91) with a hand, the stopper portion (922) will be applied to the camshaft (821a) from above. This prevents the slider (92) and the lifting bar (91) from sliding downward and unlocking the telescopic leg member (6).

A pressing member (93) is attached to the lower end of the lift bar (91). The pressing member (93) has a substantially longitudinal plate shape and is made of, for example, a synthetic resin molded product. The pressing member (93) has a stepped portion (932) at an intermediate height position on its back surface to receive the lower end surface of the lifting bar (91), and is connected and fixed to the lower end of the lifting bar (91) with, for example, a rivet. has been done.
The lower end of the pressing member (93) is narrower than the upper part, and the lower end is close to or in contact with the upper surface of the locking part (721) of the locking member (72). This is a pressing part (931) that can be positioned.

Next, a procedure for unlocking the telescopic leg member (6) by the locking mechanism (7) using the above remote control mechanism will be described.
That is, when the upper operation lever (8) is held together with the first upper step (4C) with one hand and swung in the direction of the unlock operation, the cam shaft (821a) moves forward on the cam surface (921). The slider (92), the lift bar (91), and the pressing member (93) are thereby slid downward. Then, the pressing part (931) of the pressing member (93) presses the upper surface of the locking part (721) of the locking member (72), and the locking member (72) is rotated in the unlocking direction, and the rack is The meshing (engagement) between the teeth (711) of (71) and the teeth (721a) of the locking portion (721) is released. This allows the telescopic leg member (6) to slide freely relative to the support column (3), so that the telescopic leg member (6) can be extended or contracted by the required length.
When you release your hand from the upper operating lever (8), the locking member (72) is rotated in the locking direction by the elastic force of the spring (73), and the teeth (721a) of the locking portion (721) engage the rack ( 71), and the telescopic leg member (6) is locked again. Further, due to the rotation of the locking member (72), the locking portion (721) presses the pressing portion (931) of the pressing member (93) upward. Accordingly, the slider (92), the lift bar (91), and the pressing member (93) are slid upward, and the cam shaft (821a) is also slid backward on the cam surface (921). , whereby the upper operating lever (8) is swung in the direction away from the back surface of the first upper step rail (4C). The spring elastic force of the lever return plate spring part (831) also acts on the swinging of the upper operating lever (8) in the above direction, so the upper operating lever (8) quickly returns to the standby position when not operated. Will definitely return.
As described above, according to the telescoping leg device (5) of this embodiment, the unlocking operation of the telescoping leg member (6) is performed at the first upper part located at the third step from the bottom of the ladder body (2F) (2R). Since the operation is performed using the upper operating lever (8) provided on the back of the treadle (4C), it can be easily performed while standing in a comfortable position.
In addition, the above-mentioned lock release operation can be performed individually for the left and right telescopic leg members (6), and if the left and right upper operating levers (8) are simultaneously held with one hand together with the first upper treadle (4C), the left and right telescopic leg members (6) can be It is also possible to unlock the telescopic leg members (6) at the same time, which is highly convenient.
Furthermore, according to the telescoping leg device (5) of this embodiment, even when using the ladder/stepladder (1) as a ladder by inverting one of the ladder bodies (2F) vertically, the upper operating lever (8) Since it does not appear on the front or top surface (tread surface) of the first upper tread (4C), there is no risk of interfering with the use of the ladder.

This invention is suitably used as a stepladder that also serves as a ladder .

(1): Stepladder that doubles as a ladder
(2F): Front ladder body
(2R): Rear ladder body
(3): Support
(4A): Bottom stile
(4B): 2nd upper treadle (2nd step treadle counted from the bottom)
(4C): 1st upper treadle (3rd step treadle counted from the bottom)
(41): Fitting groove for hinge formation
(42): Third abutted part
(5): Telescopic leg device
(6): Telescopic leg member
(61): Grounding part
(7)：Lock mechanism
(71): Rack (locked part)
(711): Teeth (of rack)
(72): Locking member
(721): Locking part
(73): Spring (biasing member)
(8): Upper operation lever (upper operation member)
(81): Lever body
(811a): Fitting protrusion for hinge formation
(82): 1st end cap
(820): Swing stopper housing section
(821): Arm part
(821a): Camshaft (cam mechanism, upper interlocking mechanism)
(822): First abutted part
(823): Second abutted part
(83): 2nd end cap
(831): Lever return leaf spring (lever return biasing member)
(84): Swing stopper
(841): Insertion part (swing shaft)
(842): 1st contact part
(843): Second contact part
(844): Third contact part
(9)：Transmission member
(91): Lifting bar
(92): Slider
(921): Cam surface (cam mechanism, upper interlocking mechanism)
(922): Stopper part for maintaining locked state
(10)(11): Bracket
(S): Gap between the left and right ends of the lowest step and the left and right ends of the second upper step and each support.

Claims (5)

The upper ends of two ladder bodies each comprising two hollow pillars on the left and right and a plurality of rungs suspended in a stepped manner between the two pillars are connected to each other by a hinge so that they can be opened and closed. , a stepladder that can also be used as a ladder by rotating either one of the two ladder bodies upside down,
Each ladder body further includes a telescoping leg member that is slidably inserted into each support column from its lower end and has a grounding portion at the end opposite to the insertion side, and locks the telescoping leg member at an arbitrary sliding position. The telescoping leg device includes a locking mechanism and a remote control mechanism that can unlock the telescoping leg member by the locking mechanism by remote control.
The remote control mechanism includes an operating member that is movable in a predetermined operating direction and that can unlock the telescopic leg member by the locking mechanism by moving in the same operating direction, and an operating member that can be turned upside down for use as a ladder. a swing stopper swingably provided to prevent movement of the operating member in the operating direction in the moved ladder body;
The swing stopper has a swing shaft at one end in a predetermined direction, a swing tip at the other end, and both sides in the swing direction from the swing shaft to the opposite side of the swing tip. A stepladder that doubles as a ladder, with parts whose widths gradually become smaller. 2. The ladder-cum-stepladder according to claim 1, wherein the swing stopper has a portion between the swing shaft and the swing tip where the width between both sides in the swing direction is the largest. 3. The ladder/stepladder according to claim 1, wherein the swing stopper has a flat shape with a thickness smaller in the swing axis direction than the length in the predetermined direction and the maximum width between both sides in the swing direction. The swing stopper has an insertion portion that protrudes from one end in the predetermined direction and is loosely inserted into a stopper mounting hole provided at a predetermined location of the ladder body, and the insertion portion constitutes a swing shaft. The ladder-cum-use stepladder according to any one of claims 1 to 3, wherein the ladder doubles as a stepladder. When the ladder body is turned upside down, the swing stopper swings by its own weight from a first position where it does not block the movement of the operating member to a second position where it blocks the movement of the operating member. The swing stopper in the second position is such that the line connecting the swing axis and the swing tip is inclined in the swing direction to the second position with respect to the vertical line passing through the swing axis. Any one of claims 1 to 4, wherein the movable stopper has a line connecting its pivot shaft and its pivot tip inclined in the pivot direction toward the first position with respect to a vertical line passing through the pivot shaft. A stepladder that doubles as a ladder as described in item 1.

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