JP6643003B2 - Telescopic leg device - Google Patents

Description

  BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a telescopic leg device provided at a lower portion of a post of a ladder body in a ladder, a stepladder, a work table, or the like having a ladder body in which a plurality of steps are interposed between a pair of right and left supports.

In a ladder, a stepladder, a workbench, or the like, a pair of left and right supports of the ladder body function as legs supporting the whole by grounding their lower ends.
Here, the support of the general ladder body is made of a single material such as an aluminum shape, and its length cannot be changed.
However, in the case of a ladder or the like provided with such a support, there is a problem in that if the ladder is installed on a stepped or sloping ground, the ladder is tilted or wobble and becomes unstable, so that it cannot be used safely.

Therefore, a ladder or the like in which a telescopic leg device is provided below a column of a ladder body has been proposed (for example, see Patent Document 1 below).
The telescopic leg device includes a telescopic leg member slidably inserted into a lower portion of the hollow column of the ladder body and having a grounding portion at a lower end, and a lock device for locking the telescopic leg member to the column at a required sliding position. It has.
The locking device includes a rack provided on the inner surface in the left-right direction of the telescopic leg member and having a number of teeth arranged along the length direction of the telescopic leg member, and a swing extending in the front-rear direction on the lowermost step beam of the ladder body. A locking claw, which is swingably mounted around the driving shaft and has teeth at its distal end for meshing with the teeth of the rack; and attaching the locking claw in a direction in which the teeth mesh with the teeth of the rack. The biasing elastic member and the elastic force of the elastic member are provided by branching inward in the left-right direction from the middle of the length of the lock claw and pressing upward through an operation window formed on the lower surface of the stepping bar. And an operating lever for swinging the lock claw in a direction in which its teeth are disengaged from the teeth of the rack.
According to the ladder or the like provided with the above-mentioned telescopic leg device, the telescopic leg member at the lower part of one or both struts of the ladder body is locked by the lock device at a required sliding position even when the ladder is installed on a stepped or sloped ground. As a result, as in the case of installation on a horizontal surface, it can be used safely in a stable state that stands almost vertically.

JP 2003-193780 A

However, in the above-mentioned telescopic leg device, since the operating lever of the lock device is incorporated in the lowest step of the ladder body, when the telescopic leg member is expanded or contracted, the operating lever is pressed upward with one hand. It is necessary to hold the telescopic leg member with the other hand and slide in the required direction while releasing the lock.
Therefore, for example, when the telescopic work of the telescopic leg member is performed while the ladder or the like is standing, the operator needs to squat deeply, and it is difficult to perform the work. There was a danger of falling down.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a telescopic leg device which can easily perform telescopic work of a telescopic leg member in a more comfortable posture, does not cause a ladder or the like to fall down during telescopic work, and is excellent in safety. To provide.

  The present invention has the following aspects to attain the object mentioned above.

1) A ladder body in which a plurality of step beams are interposed between a pair of right and left columns is slidably attached to a lower portion of at least one of the columns along the length direction of the column, and a grounding portion is provided at a lower end. Telescopic leg device comprising a telescopic leg member having, and a locking device for locking the telescopic leg member to a support at a required sliding position,
An extendable leg device, wherein an extendable leg member is slidably attached to a lower portion of a laterally outer surface of a column, and an operation unit of a lock device is provided on the extendable leg member.

2) A guide rail is attached to the lower part of the lateral outer surface of the column along the length direction of the column,
The guide rail has a base wall facing the lateral outer surface of the support, and a front and rear guide wall protruding outward in the left and right direction from both front and rear edges of the base wall,
A fitting portion is provided on the front and rear guide walls of the telescopic leg member and the guide rail so as to be slidably fitted to each other in the length direction.
The locking device includes a rack provided on a lateral outer surface of a base wall of the guide rail and having a number of teeth arranged along the length of the guide rail, and a swing shaft extending in the front-rear direction on the telescopic leg member. A locking claw that is swingably incorporated and has teeth at its tip end that mesh with the teeth of the rack, and an elastic member that urges the locking claw in the direction in which the teeth mesh with the teeth of the rack. The elastic member is provided by being extended in the left-right direction through an operation window formed on the left-right outer surface of the telescopic leg member and provided so as to extend in the opposite direction to the lock claw following the base end of the lock claw. The telescopic leg device according to 1) above, further comprising: an operation lever that swings the lock claw in a direction in which its teeth are disengaged from the rack teeth against the elastic force.

3) The guide rail is attached to a lower portion of the left and right outer surfaces of the column via a spacer so that the guide rail does not interfere with the end of the hollow stepping bar penetrating the column and crimped to the left and right outer surfaces of the column. The telescopic leg device according to 2) above.

4) A straight line extending from the engagement surface to the rocking center of the lock pawl from the engaging surface of the teeth of the rack and the teeth of the lock pawl, which are engaged with each other when an external force acts in the direction in which the telescopic leg member extends. The telescopic leg device according to 2) or 3), wherein the leg is formed so as to coincide with the perpendicular of the engaging surface or to be inclined toward the rack at an angle of 10 ° or less with respect to the perpendicular.

In the telescopic leg device of the above 1), when the telescopic leg member is expanded and contracted, the member may be slid in a required direction while operating the operating portion of the lock device while holding the member with one hand.
Therefore, according to the telescopic leg device of 1), for example, even when the ladder or the like is standing, the telescopic operation of the telescopic leg member can be easily performed with one hand, and the ladder or the like is supported by the other hand. Since it can be prevented from falling down, the work can be performed safely.
The operation unit of the locking device is more preferably provided on the upper surface of the telescopic leg member. By doing so, it is not necessary to squat down deeply when the telescopic leg member is extended or retracted, and the operation can be performed in a more comfortable posture.

According to the telescopic leg device of 2), since the telescopic leg member is attached to the lower part of the lateral outer surface of the column via the guide rail, there is no need to provide a complicated mounting structure on the column, and the column is generally used as a column. And a telescopic leg member can be easily attached.
According to the telescopic leg device of 2), the lock of the lock device can be easily released by pressing the operation lever with fingers through the operation window formed on the left and right outer surfaces of the telescopic leg member. Moreover, since the sliding of the telescopic leg member can be performed easily while performing the lock release, excellent operability can be obtained.

  According to the telescopic leg device of the above 3), even if the end of the hollow step beam is a ladder or the like having a ladder body that is caulked to the column, the guide rail is provided at the lower part of the lateral outer surface of the column. It can be easily installed without any hindrance, and the application range can be expanded.

According to the telescopic leg device of 4), the following problems can be avoided.
That is, when the external force acts in the direction in which the telescopic leg member is extended, the engaging surfaces of the teeth of the rack and the teeth of the locking pawl that are engaged with each other are straight lines extending from the engaging surfaces toward the rocking center of the locking pawl. Is formed so as to be inclined to the rack side at an angle exceeding 10 ° with respect to the perpendicular to the engagement surface, and when an external force acts in the direction in which the telescopic leg member extends, the lock claw is urged in the locking direction. When the elastic force exceeds the elastic force of the elastic member, a force for swinging the lock claw in the unlocking direction is likely to be generated. Then, for example, when the ladder or the like is being lifted and carried, the locking device may be inadvertently unlocked and the telescopic leg member may be extended.
On the other hand, if the engagement surface is formed so that a straight line extending from the engagement surface toward the center of swing of the lock claw is inclined to the lock claw side with respect to a perpendicular to the engagement surface, the telescopic leg member When an external force acts in the direction in which the lock is extended, a force is generated that swings the lock claw in the lock direction.Therefore, there is no danger that the lock of the lock device will be released unexpectedly. It is necessary to press, and operability may be impaired.

It is a perspective view of a ladder concerning a 1st embodiment of this invention. It is a front view which expands and shows the expansion-contraction leg apparatus provided in the lower part of the said ladder. FIG. 3 is an enlarged sectional view taken along a line III-III in FIG. 2. FIG. 4 is a view taken along line IV-IV in FIG. 2. FIG. 5 is a partially enlarged cross-sectional view taken along line VV of FIG. 4. FIG. 3 is an exploded perspective view of the telescopic leg device. (A) is an exploded perspective view of a unit such as a lock claw of a lock device in the telescopic leg device, and (b) is a perspective view showing an assembled state of the unit. It is a vertical sectional view showing a locked state of the above-mentioned lock device, in which (a) shows an engagement state of a lock claw and a tooth of a rack when an external force in a direction in which a telescopic leg member contracts acts. (B) is a vertical cross-sectional view showing the engagement state of the lock claws and the teeth of the rack when an external force is applied in the direction in which the telescopic leg member extends. 7A shows the force acting on the lock device in the locked state, and FIG. 7A shows the engagement surface between the lock claw and the teeth of the rack when an external force acts in the direction in which the telescopic leg member contracts. FIGS. 7B and 7C are vertical cross-sectional views showing forces generated in the locking claw and the engaging surface of the teeth of the rack when an external force acts in the direction in which the telescopic leg member extends. FIG. It is a left view of the stepladder concerning a 2nd embodiment of this invention. FIG. 11 is a partially enlarged horizontal sectional view taken along line XI-XI in FIG. 10.

(First embodiment)
1 to 9 show a first embodiment of the present invention.
In the first embodiment, the telescopic leg device according to the present invention is applied to a double ladder.
In the following description, “left and right” refers to the left and right in FIG. 2, “front” refers to the right side in FIG. 4, and “rear” refers to the left side in FIG.

As shown in FIG. 1, the double ladder (1) is formed by connecting upper and lower two ladder bodies (2A) and (2B) in a stretchable manner.
Each of the upper and lower ladder bodies (2A) and (2B) is composed of two right and left columns (3) and a plurality of step bars (4) which are interposed between the two columns (3) at equal intervals in the vertical direction. Have.
The telescopic leg device (5) according to the present invention is provided below the left and right columns (3) of the lower ladder body (2B).

2 to 6 show the detailed structure of the lower part of the lower ladder body (2B).
The left and right columns (3) of the lower ladder body (2B) are made of a shape material such as aluminum. The left strut (3) has a substantially U-shaped cross section including a vertical left wall (31) and front and rear walls (32) extending rightward from the front and rear edges of the left wall (31) (FIG. 3). reference). The right support (3) is symmetrical to the left support (3), and has a substantially U-shaped cross section including a right side wall (31) and front and rear walls (32).
Each stepping bar (4) of the lower ladder body (2B) is made of a hollow aluminum or other shaped material, the upper part of which is flat, and the remaining part is of a downward convex arc shape. The stepping bar (4) has its left end passed through an insertion hole (not shown) formed in the left side wall (31) of the left column (3), and is subjected to bulging to leave the left side wall (31) of the left column (3). ), The right end of which is passed through an insertion hole (not shown) formed in the right wall (31) of the right column (3), and the right wall (31) of the right column (3) is formed by bulging. It is stopped by caulking. Therefore, the crimped left end (41) of the stepping bar (4) protrudes from the outer surface of the left wall (31) of the left support (3) (see FIG. 5), and the right end (41) is the right end (41). It protrudes from the outer surface of the right side wall (31) of the column (3).
The bottom stepping bar (4) is passed between the left side wall (31) of the left column (3) and the right side wall (31) of the right column (3) at a position slightly above the lower end. I have. Between the lower surface of the bottom stepping bar (4) and the lower end of the left wall (31) of the left support (3) and the lower end of the right wall (31) of the right support (3), each is made of a metal plate piece. Reinforcing brackets (21) are suspended diagonally.

The telescopic leg device (5) provided below the left and right columns (3) of the lower ladder body (2B) is completely symmetrical. Therefore, hereinafter, the telescopic leg device (5) provided below the left support (3) will be described in detail with reference to the drawings, and the description of the other telescopic leg device (5) will be omitted.
The telescopic leg device (5) is slidably mounted along the length of the left support (3) at the lower portion of the outer surface of the left wall (31) of the left support (3), and has a grounding portion (60) at the lower end. And a locking device (7) for locking the telescopic leg member (6) at a required sliding position.
A guide rail (8) is attached to a lower portion of the outer surface of the left wall (31) of the left support (3) along the length direction of the left support (3). The guide rail (8) is interposed with the left support (3) via a spacer (9) so as not to interfere with the left end (41) of the step beam (4) projecting from the outer surface of the left support (3) on the left support (3). ) Is attached to the lower part of the outer surface of the left side wall (31). The telescopic leg member (6) is slidably attached to the guide rail (8) in the length direction.

The guide rail (8) includes a base wall (81) facing the outer surface of the left wall (31) of the left support (3), and a front and rear guide wall (82) protruding leftward from the front and rear edges of the base wall (81). It has a substantially U-shaped cross section. A fitting projection (83) bent outward in the front-rear direction is provided at a front end of the front-rear guide wall (82). In the middle of the left and right widths of the opposing surfaces of the front and rear guide walls (82), short vertically protruding vertical ridges are provided so as to face each other. Is formed. On the right side surface of the base wall (81), a vertical fitting convex portion (85) is formed at a portion near the front and rear edges and extends shortly to the right and has a front end bent outward in the front and rear direction.
As shown in FIG. 6, a total of three spacers (9) are used, and the upper end, the lower end, and the middle of the length of the outer surface of the left wall (31) of the left support (3) to which the guide rail (8) is attached. In addition, it is arranged avoiding the left fixed end (41) of the stepping bar (4). These spacers (9) are made of vertical metal plate pieces, and the lower spacer (9) is slightly longer than the other two spacers (9). Each spacer (9) has the same horizontal cross section, is superposed on the outer surface of the left wall (31) of the left support (3), and its front and rear ends are bolts (B) and nuts (N). To the left side wall (31). A ridge (91) having a trapezoidal cross section is formed in the middle of the front and rear width of the outer surface (left side) of each spacer (9). In the raised portion (91), two vertical front and rear fitting concave portions (92) into which the front and rear two fitting convex portions (85 ) of the guide rail (8 ) are respectively slidably fitted in the vertical direction are formed. Have been.
The guide rail (8) is joined to the left wall (31) outer surface of the left support (3) by bolts (B) and nuts (N) with the spacer (9) sandwiched between the upper and lower ends thereof. It is fixed (see FIG. 6).
A cap (11) is attached to the upper end of the guide rail (8) so as to cover the upper end surface and the upper end surface of the spacer (9). The cap (11) is made of a synthetic resin, for example, and has a single-flow roof shape so as to release the force when it comes into contact with an obstacle.

The telescopic leg member (6) is made of a shape material such as aluminum, for example, and has a hollow base (61) having a substantially rectangular cross section that is long in the front and back, and a right and left edge from the front and rear edges of the right wall of the base (61). It has two front and rear projections (62) projecting and having a hollow shape with a substantially rectangular cross section.
The front wall of the base portion (61) and the front wall of the front convex portion (62) connected to the base portion extend diagonally forward toward the right as a whole. Similarly, the rear wall of the base portion (61) and the rear wall of the rear convex portion (62) connected to the rear wall extend obliquely rearward toward the right as a whole.
The right side wall of the front convex portion (62) extends diagonally rightward toward the rear, and has a rear edge protruding more rearward than the rear wall. The front fitting recess (63) is formed by the rear wall of the front convex portion (62) and the rear edge of the right wall, and the right wall portion of the base (61) facing the rear edge. The front fitting concave portion (63) is slidably fitted in the front fitting convex portion (83) of the guide rail (8) in the length direction.
Similarly, the right side wall of the rear convex portion (62) extends diagonally rightward toward the front, and has a front end edge protruding forward from the front wall. Then, the front fitting edge of the front wall and the right side wall of the rear convex portion (62), and the right side wall portion of the base (61) facing the front edge form a rear fitting concave portion (63). The fitting concave portion (63) is slidably fitted in the rear fitting convex portion (83) of the guide rail (8) in the longitudinal direction.
With the above-described fitting structure, the telescopic leg member (6) is slidably attached to the guide rail (8) along its length.
An upper cap (64) is attached to the upper end of the telescopic leg member (6) so as to close the upper end openings of the base (61) and the two front and rear protrusions (62). The upper cap (64) is made of, for example, a synthetic resin, and has a gable roof shape so as to release the force upon contact with an obstacle.
A lower cap (65) is attached to a lower end of the telescopic leg member (6). The lower cap (65) is made of, for example, a synthetic resin, and includes a horizontal plate portion (651) for closing the lower end openings of the base (61) of the telescopic leg member (6) and the two front and rear protrusions (62). And a fitting portion (652) projecting upward from the portion (651) and fitted into the base (61).
At the lower end of the telescopic leg member (6), a substantially disc-shaped ground member (60) is attached via a U-shaped bracket (66) by a bolt and a nut so as to be swingable in the front-rear direction. ing. The grounding member (60) forms a grounding portion at the lower end of the telescopic leg member (6). A non-slip sheet (60a) made of, for example, rubber is attached to a lower surface of the grounding member (60).

The locking device (7) is provided on the left side of the base wall (81) of the guide rail (8) and has a rack (71) having a number of teeth (711) arranged along the length direction of the guide rail (8). And teeth (721) and (722) which are incorporated in the telescopic leg member (6) so as to be swingable around a swing axis extending in the front-rear direction and which mesh with the teeth (711) of the rack (71) at the tip. A locking claw (72) and an elastic member (73) for urging the locking claw (72) in a direction in which its teeth (721) and (722) are engaged with the teeth (711) of the rack (71). ), And are pushed through an operation window (672) provided so as to extend in the opposite direction to the lock claw (72) so as to extend to the base end of the lock claw (72) and formed on the surface of the telescopic leg member (6). As a result, the operating lever (74) swings the lock claw (72) in a direction in which its teeth (721) (722) are disengaged from the teeth (711) of the rack (71) against the elastic force of the elastic member (73). ) (Operation unit).
The rack (71) is fitted into the internal enlarged groove (84) of the guide rail (8) so that the surface having the teeth (711) faces leftward, and both upper and lower ends thereof are rivet or the like. To the base wall (81).
As shown in FIGS. 5 and 7, the lock claw (72) , the elastic member (73) and the operation lever (74) are incorporated in a bracket (75) to constitute one unit.
The bracket (75) is made of a bent metal piece having a substantially U-shaped horizontal cross section opened to the left. The upper part of the right side wall (751) of the bracket (75) is cut away to expose the tip of the lock claw (72). At the lower end of the right side wall (751) of the bracket (75), a bottom wall (752) bent at right angles to the left is continuously provided. An insertion hole (753a) is formed at an intermediate portion of the height of the front and rear walls (753) of the bracket (75) so as to face each other. At the upper end of the front wall (753) of the bracket (75), an upper mounting portion (754) bent rearward at a right angle toward the rear wall (753) is continuously provided. At the lower ends of the front and rear walls (753) of the bracket (75), a lower mounting portion (755) bent at right angles outward in the front-rear direction is continuously provided.
The lock claw (72) and the operation lever (74) are constituted by one rocking piece (70). The oscillating piece (70) has an insertion hole (701) penetrating in the front-rear direction at the center of its length. Then, the swinging piece (70) is inserted into the bracket (75) and straddles the insertion hole (701) of the swinging piece (70) and the insertion hole (753a) of the front and rear walls (753) of the bracket (75). When the pin (76) is inserted, the swinging piece (70) is attached to the bracket (75) so as to be swingable about the pin (76). The lock claw (72) is constituted by an upper part of the swinging piece (70), and the operation lever (74) is constituted by a lower part of the swinging piece (70).
At the tip of the lock claw (72), four teeth (721) and (722) arranged vertically at intervals are formed so as to face the rack (71), that is, to the right.
At the distal end of the operation lever (74), two bent portions (741) that are bent substantially at right angles to the right are formed at a slight interval vertically.
The left side surface of the operation lever (74) forms a pressing portion (74a) that is pressed by a finger when unlocking. In the pressing portion (74a), a plurality of horizontal grooves (742) having a concave cross section are formed at equal intervals in the vertical direction in order to prevent slippage of fingers.
The elastic member (73) is formed of a compression coil spring, and is interposed between the right side wall (751) of the bracket (75) and the operation lever (74) at the lower portion of the swinging piece (70), and swings. The piece (70) is urged toward the locking direction in which the teeth (721) and (722) of the lock claw (72) on the upper part are engaged with the teeth (711) of the rack (71).

The unit is housed in the telescopic leg member (6) through a substantially rectangular hole (611) formed in the upper part of the left side wall of the base (61) in the telescopic leg member (6), and the bracket (75) The upper and lower mounting portions (754) and (755) are fixed to the telescopic leg member (6) by being joined to the left side wall of the base (61) with rivets or the like.
The right side portion of the bracket (75) and the tip of the lock claw (72) pass through a vertically rectangular hole (612) formed in the upper part of the right side wall of the base (61) of the telescopic leg member (6). The member (6) is projected to the back side.
A substantially rectangular frame-shaped cover (67) is put on the outer surface (left side) of the left side wall of the base (61) of the telescopic leg member (6) so as to cover the hole (611) and a part of the unit. I have. At the upper edge of the cover (67), two hooks (671) are formed to be engaged with the upper edge of the hole (611) in the inner surface of the left side wall of the base (61) of the telescopic leg member (6). I have. The lower edge of the cover (67) is joined and fixed to the left side wall of the base (61) of the telescopic leg member (6) by rivets or the like.
At the central opening (672) of the cover (67), a pressing portion (74a) of the operating lever (74) of the swinging piece (70) is arranged so as not to protrude toward the surface of the cover (67). The central opening constitutes the operation window (672). The cover (67) prevents the pressing portion (74a) of the operation lever (74) from being inadvertently pressed and unlocked.

As the telescopic leg member (6) is slid in the extension direction, the bottom wall (752) of the bracket (75) secures the guide rail (8) to the lower end of the left support (3) by bolts ( B) abuts on the head, thereby preventing the telescopic leg member (6) from falling below the guide rail (8) (see FIG. 2). At this time, the telescopic leg member (6) is in the maximum telescopic state in which the downwardly projecting portion is the longest.
On the other hand, when the telescopic leg member (6) is slid in the contracting direction, the upper end of the fitting portion (652) of the lower cap (65) attached to the lower end of the telescopic leg member (6) is ), Thereby preventing the telescopic leg member (6) from penetrating above the guide rail (8) (see FIG. 2). At this time, the telescopic leg member (6) is in the minimum telescopic state in which the downwardly projecting portion is the shortest.

When the above-mentioned ladder (1) is installed on a stepped land where the right installation surface (G1) is higher than the left installation surface (G2), for example, as shown in FIG. 2, the left telescopic leg device ( By extending the telescopic leg member (6) of (5) by a required length, it can be used safely in a stable state almost vertically, as in the case of installation on a flat horizontal surface.
Here, when the telescopic leg member (6) is extended, while pushing the operating lever (74) of the lock device (7) provided on the upper surface of the telescopic leg member (6) with one hand, the lock is released, It is sufficient to hold the telescopic leg member (6) with the same hand and slide it in the extension direction, so work safely while supporting the ladder (1) support (3) and stepping bar (4) with the other hand. It can be carried out.

FIG. 8 shows a locking state of the locking device (7) of the telescopic leg device (5) in which the teeth (721) and (722) of the locking claw (72) and the teeth (711) of the rack (71) are engaged. It is.
A large number of teeth (711) of the rack (71) are vertically arranged at a predetermined pitch. The teeth (711) are all the same shape and the same size, and have a substantially inverted truncated trapezoidal cross section. More specifically, the top surface (711a) of the tooth (711) is a flat vertical surface. The upper and lower sides of the teeth (711) are tapered such that the top half thereof is a flat horizontal surface (711b), and the other half is tapered so that the teeth (711) gradually become thinner toward the base. Surface (711c).
On the other hand, in the case of the lock claw (72), the shape and size are different between the upper two teeth (721) and the lower two teeth (722).
The two teeth (721) on the upper side of the lock claw (72) have a substantially inverted inequality trapezoidal cross section, and the top surface is a flat vertical surface (721a). Consists of a flat horizontal surface (721b), and a tapered surface (721c) inclined so that the teeth (721) gradually become thinner as the top half of the lower surface approaches the base, and the remaining lower surface Consists of a flat horizontal surface (721d). The maximum thickness of the upper two teeth (721) is made slightly smaller than the maximum thickness of the teeth (711) of the rack (71) so that the teeth (711) of the rack (71) can be inserted between the teeth (711). I have.
The lower two teeth (722) of the lock claw (72) have a substantially rectangular cross section, and the top surface is a flat vertical surface (722a), and the upper and lower sides are flat. It consists of a horizontal plane (722b). The thickness of the lower two teeth (722) is slightly smaller than the maximum thickness of the upper two teeth (721).

When the ladder (1) is placed on a wall, a roof or the like, an external force acts on the ladder (1) in a direction in which the telescopic leg member (6) contracts. In this case, as shown in FIG. 8A, the lock claw 72 moves upward and the rack 71 moves downward. The upper surface (721b) (722b) (engagement surface) of the four teeth (721) (722) of the lock claw (72) is aligned with the lower surface of the four teeth (711) of the rack (71). It is engaged with the horizontal surface portion (711b) (engagement surface).
FIG. 9A shows the force generated on the engagement surface (721b) of the uppermost tooth (721) of the lock claw (72) in the installed state of the ladder (1). A radially outward force (P1) extending from the swing center (C) of the lock claw (72) through the engagement surface (721b) acts on the engagement surface (721b). This force (P1) is the force acting in the direction to swing the lock claw (72), that is, the tangential force (P2) of the engagement surface (721b) and the teeth (721) of the lock claw (72). Is divided into a force for vertically pushing the engaging surface (711b) of the teeth (711) of the rack (71), that is, a force (P3) in a direction perpendicular to the engaging surface (721b). Then, the force (P2) in the tangential direction of the engagement surface (721b) is clockwise in FIG. 9A, that is, the tooth (721) of the lock claw (72) is further pressed against the rack (71). It turns out that it is facing the locking direction. Although not shown, forces in the same direction also act on the engagement surfaces (721b) (722b) of the second and subsequent teeth (721) (722) from the top of the lock claw (72). . Although not shown in FIG. 9, the elastic force of the elastic member (73) formed of a compression coil spring also acts on the engagement surfaces (721b) and (722b) in the locking direction. Therefore, in the installation state where the ladder (1) is leaned against a wall or the like, the locked state by the locking device (7) is reliably maintained, and there is no possibility that the lock is accidentally released.

Next, in a state where the ladder (1) is lifted while supporting portions other than the extensible leg members (6), for example, during transportation or the like, an external force is applied to the ladder (1) in a direction in which the extensible leg members (6) extend. Works. In this case, as shown in FIG. 8B, the lock pawl 72 moves downward and the rack 71 moves upward. The lower tapered surface portion (721c) (engaging surface) of the upper two teeth (721) of the four teeth (721) (722) of the lock claw (72) is the corresponding rack (71). Are respectively engaged with the tapered surface portions (711c) (engagement surfaces) of the upper surfaces of the two teeth (711). However, the lower side (722b) of the lower two teeth (722) is not engaged with the upper side of the corresponding two teeth (711) of the rack (71).
FIG. 9B shows the force generated on the engagement surface (721c) of the uppermost tooth (721) of the lock claw (72) when the ladder (1) is lifted. A radially inward force (P1) extending from the swing center (C) of the lock claw (72) through the engagement surface (721c) acts on the engagement surface (721c). This force (P1) is the force acting in the direction to swing the lock claw (72), that is, the tangential force (P2) of the engagement surface (721c) and the teeth (721) of the lock claw (72). Of the engaging surface (721c) of the rack (71) vertically presses the engaging surface (711c) of the tooth (711), that is, the force (P3) in the perpendicular direction of the engaging surface (721c). Then, the force (P2) in the tangential direction of the engagement surface (721c) is changed in the counterclockwise direction in FIG. 9A, that is, the lock release where the teeth (721) of the lock claws (72) separate from the rack (71). Facing the direction. When this force (P2) is larger than the elastic force of the elastic member (73) acting in the locking direction, the engaging surface (721c) of the tooth (721) of the lock claw (72) and the tooth ( 711) is disengaged from the engagement surface (711c), the teeth (721) of the lock claws (72) are released from the teeth (711) of the rack (71), and the telescopic leg member (6) is released. A situation occurs in which careless growth occurs.
Therefore, in the telescopic leg device (5) according to the present invention, when the external force acts in the direction in which the telescopic leg member (6) extends, the teeth (721) and the rack (71) of the lock claw (72) are engaged with each other. A straight line (L1) extending from the engagement surface (721c) (711c) toward the swing center (C) of the lock claw (72) is associated with the engagement surface (721c) (711c) of the tooth (711). It is formed so as to coincide with the perpendicular (L2) of the mating surfaces (721c) and (722c) or to be inclined toward the rack (72) at an angle (A1) within 10 ° with respect to the perpendicular (L2).
In this embodiment, the tapered surface portion (721c) on the lower surface of the two teeth (721) on the upper side of the locking claw (72) and the tapered surface portion (711c) on the upper surface of the tooth (711) of the rack (71). Correspond to the engagement surface. In the case of the uppermost tooth (721) of the lock claw (72) and the engaging surface (721c) (711c) of the corresponding tooth (711) of the rack (71), as shown in FIG. The angle (A1) is about 3 °. In the case of the engagement surface (721c) (711c) of the second tooth (721) from the top of the lock claw (72) and the corresponding tooth (711) of the rack (71), FIG. As shown, the angle (A1) is about 9.5 °. In any case, the force (P2) acting in the unlocking direction on the engagement surfaces (721c) (711c) is sufficiently smaller than the elastic force of the elastic member (73) acting in the locking direction. Further, the angle (A1) increases as the position of the teeth of the lock claw (72) decreases, and accordingly, the force (P2) acting on the engagement surface in the unlocking direction also increases. However, the lower surface (722b) of the lower two teeth (722) of the lock claw (72) is not engaged with the upper surface of the teeth (711) of the rack (71) as described above. .
With the above configuration, in the telescopic leg device (5) of this embodiment, even when an external force acts in the direction in which the telescopic leg member (6) extends, a large force is applied to the lock claw (72) in the unlocking direction. Since it does not act, the locked state is reliably maintained by the elastic force of the elastic member (73), and the problem that the extendable leg member (6) is inadvertently extended does not occur.
Further, according to the telescopic leg device (5) of this embodiment, the lock device (5) is unlocked because the elastic member (73) does not have to have an elastic force larger than necessary. Therefore, the force for pressing the pressing portion (74a) of the operation lever (74) is not so large, and the operability is not impaired.

(Second embodiment)
FIG. 10 and FIG. 11 show a second embodiment of the present invention.
In the second embodiment, the telescopic leg device according to the present invention is applied to a stepladder.
In the following description, “front” refers to the right side of FIG. 9, “rear” refers to the left side of FIG. 9, and “left / right” refers to left and right when viewed from the front.

As shown in FIG. 10 , the stepladder (10) has upper and lower ends of two front and rear ladder bodies (20A, 20B) connected to each other by a hinge fitting (201) so as to be freely opened and closed.
Each of the front and rear ladder bodies (20A) (20B) is composed of two right and left columns (30) and a plurality of step bars (not shown) which are interposed between both columns (30) at equal intervals in the vertical direction. It has.
The struts (30) and the stepping bars of the front and rear ladder bodies (20A) (20B) are the struts of the upper and lower ladder bodies (2A) (2B) in the ladder (1) of the first embodiment, except for the following points. (3) and stepping bar (4) are substantially the same.
That is, the right and left ends of each stepping bar are fixed to the front and rear walls (32) of the left and right columns (30) by rivets (not shown) or the like, and penetrate the side walls (31) of each column (30). It has no protruding portion on its outer surface.

Telescopic leg devices (50) are provided below the left and right columns (30) of the front and rear ladder bodies (20A) (20B).
The telescopic leg device (50) has substantially the same structure as the telescopic leg device (5) of the first embodiment except for the following points, and is substantially the same as the device (5). The operation and effect of the present invention are achieved.
That is, in the case of the telescopic leg device (5) of this embodiment, as shown in FIG. 11 , the guide rail (80) is directly attached to the outer surface of the side wall (31) of the column (30) without using a spacer. I have. More specifically, a fitting projection is not formed on the left-right inner surface of the base wall (81) of the guide rail (80), and instead, the base wall (81) of the guide rail (80) is A front / rear mounting portion (86) is formed extending from the front / rear edge portion inward in the left / right direction and bent at a right angle outward in the front / rear direction. The front and rear mounting portions (86) are fixed to the side wall (31) of the column (30) by bolts (B) and nuts (N).

  It should be noted that each of the above embodiments is merely an example, and it is needless to say that the present invention can be embodied as appropriately modified forms without departing from the gist of the claims.

(1): Double ladder
(2A): Upper ladder body
(2B): Lower ladder body
(3): Support
(4): Stepping bar
(41): The end of the step
(5): Telescopic leg device
(6): Telescopic leg member
(60): Grounding member (grounding part)
(63): Mating recess
(672): Operation window
(7): Lock device
(71): Rack
(711): Tooth (of rack)
(711c): Tapered surface (engaging surface) on the upper surface (of the teeth)
(72): Lock claw
(721): Upper two teeth (of lock claw)
(721c): Tapered surface part (engagement surface) on the lower surface (of the tooth)
(722): The lower two teeth (of the lock claw)
(73): Elastic member
(74): Operation lever (operation unit)
(8): Guide rail
(83): Mating protrusion
(9): Spacer
(L1): A straight line extending from the engagement surface to the center of swing of the lock claw.
(L2): perpendicular to the engagement surface
(10): Stepladder
(20A): Front ladder body
(20B): Rear ladder body
(30): Support
(50): Telescopic leg device
(80): Guide rail

Claims (4)

A ladder body in which a plurality of treads are interposed between a pair of left and right supports is slidably attached along a length direction of the support at a lower portion of at least one of the supports and has a grounding portion at a lower end. Telescopic leg member, and a telescopic leg device comprising a locking device for locking the telescopic leg member to a support in a required sliding position,
The telescopic leg member is hollow, extending along the length of the column,
A guide rail is attached to the lower part of the outer side surface of the column along the length direction of the column,
The guide rail has a base wall facing the lateral outer surface of the support, and a front and rear guide wall protruding outward in the left and right direction from both front and rear edges of the base wall,
A fitting portion is provided on the front and rear guide walls of the telescopic leg member and the guide rail so as to be slidably fitted to each other in the length direction.
The locking device includes a rack provided on a lateral outer surface of a base wall of the guide rail and having a number of teeth arranged along the length of the guide rail, and a swing shaft extending in the front-rear direction on the telescopic leg member. A locking claw, which is swingably incorporated and has teeth at its distal end to be meshed with the teeth of the rack; and a direction in which the locking claw is housed in the telescopic leg member and the teeth of the locking claw are meshed with the teeth of the rack. An elastic member that urges toward the lock claw and an operation window that is provided so as to extend in the opposite direction to the lock claw so as to extend in a direction opposite to the lock claw and that is formed on an outer surface in the left and right direction of the telescopic leg member. An operating lever that swings the lock claw in a direction in which its teeth are disengaged from the rack teeth by pressing against the elastic force of the elastic member,
The telescopic leg device , wherein the operation lever has a pressing portion disposed on the operation window so as not to protrude from a laterally outer surface of the telescopic leg member . The telescopic leg member has a hollow base having a substantially rectangular cross section, a hole is formed at a predetermined position on the left and right outer wall of the base, and a frame-shaped cover is provided around the hole. The telescopic leg device according to claim 1, wherein the operation window is configured to be covered, and the operation window is configured by a central opening of the cover. The teeth of the rack were inclined so that the top surface was a flat vertical surface, the top and bottom portions of the upper and lower sides were flat horizontal surfaces, and the remaining portion gradually became thinner toward the base. It has a tapered surface,
The teeth of the locking claw have an upper tooth and a lower tooth having different shapes and sizes from each other, and the upper tooth has a flat vertical surface on the top surface and a horizontal surface on the upper surface. The top surface of the lower surface has a tapered surface inclined so that the teeth gradually become thinner toward the base, and the remaining portion of the lower surface is a flat horizontal surface, and the upper teeth are formed. The maximum thickness of the teeth is set to be large enough to fit between the teeth of the rack, and the lower teeth are formed with a flat vertical surface on the top surface and flat horizontal surfaces on both upper and lower surfaces. , The thickness of the lower teeth is smaller than the maximum thickness of the upper teeth,
When an external force acts on the ladder body in the direction in which the telescopic leg member contracts, the upper surfaces of the upper teeth and the lower teeth of the lock claws are engaged with the horizontal surfaces of the lower surfaces of the corresponding rack teeth, respectively. ,
When an external force acts on the ladder body in the direction in which the telescopic leg member extends, the tapered surface portion of the lower surface of the upper tooth of the lock claw is engaged with the tapered surface portion of the upper surface of the corresponding rack tooth. The telescopic leg device according to claim 1 or 2, wherein the lower surface of the lower tooth of the locking claw is not engaged with the lower surface of the corresponding tooth of the rack. An engaging portion comprising a tapered surface portion on an upper surface of a tooth of a rack and a tapered surface portion on a lower surface of an upper tooth of a lock claw that are engaged with each other when an external force acts on the ladder body in a direction in which the telescopic leg member extends. The mating surface is formed such that a straight line extending from the engaging surface toward the pivot center of the lock claw coincides with a perpendicular of the engaging surface, or is inclined toward the rack at an angle of 10 ° or less with respect to the perpendicular. The telescopic leg device according to claim 3 , wherein the leg device is provided.

Images