JPH1122351A - Extensible ladder positioning device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To carry out the positioning of an extensible support easily and the adjustment of the length of an extensible ladder reliably in the adjustment of the length of the extensible support and the positioning of the support. SOLUTION: The extensible ladder-positioning device is formed of the support of a ladder and an extensible support 14 that is mounted slidably. A fixing mechanism 17 is attached and fixed to the support. An engager 21 is stored withdrawably in a storing frame fixed inside a storing case 18. Rotating plates 30 are arranged on both sides of the engager 21, and supported by supporting shafts 28 fixed to the storing case 18 rotatably. An operating pin 23 is supported in the center of the engager 21, both ends of which are engaged with circular arc long holes 32 provided at the head of the rotating plates 30. The rotation of the rotating plates 30 guides the operating pin 23 to the long hole 32.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a telescopic ladder positioning apparatus for using a telescopic ladder at a place where scaffolds have different heights.

[0002]

2. Description of the Related Art Conventional ladders of this type include, for example,
A configuration as shown in Japanese Utility Model Laid-Open No. 5-47298 is known.

In this conventional configuration, a telescopic support is attached to each support of the ladder so as to be vertically slidable, and a rack surface is formed on a side surface of the telescopic support. A rack that slides vertically is attached to the column.
The telescopic strut is fixed to the strut by fitting the rack and the rack surface. Further, a vertically movable operation unit for fitting and separating the rack and the rack surface is attached to the rack, and the operation unit is provided with an operation lock means for locking the engagement between the rack and the rack surface. Have been.

When adjusting the length of each column of the ladder, first, the fitting between the rack and the rack surface is released by the operation unit. Next, the telescopic strut is adjusted to an arbitrary length.
Thereafter, the operating portion is operated to move the lacquer to a position where it fits on the rack surface, and the length can be adjusted by locking the fit between the lacquer and the rack surface.

[0005]

However, in this conventional configuration, when the support column and the telescopic strut are fitted or separated by the operating portion, the telescopic strut is adjusted to an arbitrary length and then provided on the operating portion. This is accomplished by inserting or removing a knob with the operating rod attached. For this reason, it is necessary to adjust the telescopic strut to an arbitrary length for each telescopic operation, move the operation unit to a predetermined position, and then insert or separate the knob,
There was a problem that the work was troublesome.

Further, since the column and the telescopic column are locked by fitting the knob, there is a problem that the lock is weak. In addition, there is a problem that the structure of the operation unit having the operation lock means is complicated as described above, and the number of parts is increased.

The present invention has been made by paying attention to such problems existing in the prior art. The purpose is to adjust the length of the telescopic ladder for positioning and to perform the positioning work easily and to position the telescopic ladder reliably. Is to provide.

It is another object of the present invention to provide a telescopic ladder positioning device which has a simple structure and can reduce the manufacturing cost.

[0009]

According to a first aspect of the present invention, there is provided a positioning device for a telescopic ladder, wherein the telescopic strut is slidably attached to a main body of the ladder. Between the main body and the telescopic strut, the telescopic strut is engaged at a predetermined position with respect to the strut main body by engaging in an uneven relationship,
A telescopic ladder positioning device having a fixing mechanism for fixing the telescopic strut to the strut main body at that position, wherein the fixing mechanism is supported so as to be able to advance and retreat in a support fixed to the strut main body or the telescopic strut, and has an end portion. An engaging body having an engaging portion formed of projections and depressions; a rotating member rotatably supported by a support shaft fixed to the support; and a rotating member or an engagement member such that a distance from the support shaft changes. It comprises an arc-shaped long hole provided in the united body, and an operating pin provided on the engaging body or the rotating member so as to engage with the long hole, and moving the engaging body forward and backward by the rotation of the rotating member.

According to a second aspect of the present invention, in the positioning device for a telescopic ladder according to the first aspect, the operating pin is disposed substantially at the center of the engaging body, and the support shaft is connected to the operating pin. It is fixed on a support on a line extending in the direction of movement of the engaging body.

According to a third aspect of the present invention, there is provided the telescopic ladder positioning device according to the first or second aspect, wherein the rotating member is connected so that a pair of plate members face each other, Both plate members are arranged on both sides of the engaging member, and a long hole is provided in each of the plate members, and an operating pin is inserted into the engaging member so that both ends thereof are engaged with the long holes of the plate member.

[0012]

Embodiments of the present invention will be described below in detail with reference to the drawings. As shown in FIG. 7, the pair of support columns 11 a and 11 b and the support columns 11 c and 11 d constituting the telescopic ladder are formed of aluminum,
A tread plate 12 is provided at regular intervals between the support columns 11a and 11b and between the support columns 11c and 11d. The support plate 13 includes a pair of support columns 11a and 11b.
And it is rotatably supported on the pillar main bodies 11c and 11d.

Similarly, a pair of telescopic struts 14a and 14b and a telescopic strut 14c and 14d, which constitute a telescopic ladder, are slidably mounted on the pair of post main bodies 11a and 11b and the post main bodies 11c and 11d, respectively. The length of the ladder can be adjusted. In the grounds 15a, 15b, 15c, and 15d having different heights, the pair of support bodies 11a and 11b and the support bodies 11c and 11d are
The corresponding telescopic struts 14a and 14b, telescopic strut 1
4c and 14d are slid to predetermined positions, and each scaffold is placed so as to be stable. A non-slip member 16 made of synthetic rubber is attached to the lower end of each telescopic strut 14, and prevents each telescopic strut 14 from slipping on the ground 15a, 15b, 15c, 15d.

As shown in FIG. 1, the fixing mechanism 17 is attached and fixed to the lower end of each column body 11, positions the telescopic column 14 at a predetermined position with respect to the column main body 11, and then moves the telescopic column 14 to that position. It is designed to be fixed. Therefore,
The fixing mechanism 17 will be described.

As shown in FIGS. 1, 3 and 4, a rectangular box-shaped housing case 18 as a support is made of aluminum, and is fixed to the lower end of the support body 11 by welding.

As shown in FIGS. 1, 3 and FIGS. 6 (a) and 6 (b), the housing frame 19 is formed in a U-shaped cross section and is fixed in the housing case 18. The housing frame 19 is provided with a plurality of lightening holes 20 to save material. The engagement body 21 is housed in the housing recess 22 of the housing frame 19 so as to be able to advance and retreat. The engaging body 21 is formed in a rectangular box shape, and a mounting hole 24 for inserting and supporting the operating pin 23 is provided at a substantially central position. The engaging portion 25 having an uneven shape is formed on the outer end surface of the engaging body 21 so as to be able to engage with the uneven surface 26a of the uneven plate 26 joined to the side surface of the telescopic strut 14. A plurality of lightening holes 27 are provided in the engagement body 21 to save material. The support shaft 28 is inserted through the insertion hole 29 of the housing frame 19,
Both ends are fixed to the storage case 18.

The support shaft 28 is disposed on a line extending through the operating pin 23 in the moving direction of the engagement body 21.
8 is fixed. As shown in FIGS. 5 (a) and 5 (b), a turning plate 30 as a plate material is formed in a fan shape from aluminum, and is centered on the support shaft 28 inserted into a support hole 31 provided on one side thereof. To be rotatable. An arc-shaped long hole 32 is formed on the tip side of the rotating plate 30. The long hole 32, the distance between the support hole 31 has a shortest distance L ₁ at one end, and is formed to have a longest distance L ₂ at the other end. The operating pin 23 is engaged with the elongated hole 32, and the operating pin 23 is guided by the elongated hole 32 and moves by the rotation of the rotating plate 30.

As shown in FIG. 1, FIG. 2 and FIG.
In a state where the pair of rotating plates 30 are arranged to face each other, a connecting plate 33 is joined to their end surfaces. A rotating member 34 is constituted by the pair of rotating plates 30, the connecting plate 33, and the like. The finger hook 35 is formed by cutting out the lower end surface of the connecting plate 33 in an arc shape. The spring hooks 36 are formed so as to protrude from the outer surfaces of the rotating plates 30. A pair of winding springs 37 are wound around both ends of the support shaft 28, one end of each of which is attached to a spring hook 36, and the other end of which is attached to the housing case 18. The helical spring 37 biases the rotating plate 30 so as to hold it in the state shown in FIG. 1, that is, to rotate the rotating plate 30 clockwise. And always the engagement body 2
One engaging portion 25 is adapted to engage with the uneven surface 26 a of the telescopic strut 14.

In this state, the operation pin 23 is moved along the elongated hole 32 by placing a finger on the finger rest 35 of the connecting plate 33 and rotating the rotating plate 30 against the urging force of the winding spring 37. The engaging member 21 is moved backward. Then, the engaging body 21 with the uneven surface 26a of the telescopic strut 14 is
Is disengaged, and the telescopic strut 14 can be slid with respect to the engaging portion 25 to an arbitrary position.

Next, the operation of the telescopic ladder positioning device of this embodiment will be described. As shown in FIG. 7, the telescopic ladders are grounded at different heights 15a, 15b, 15c, 15
d, each pair of telescopic struts 1 corresponding to each
It is necessary to slide the 4a and 14b and the telescopic columns 14c and 14d to predetermined positions so that the scaffolds are stabilized.

Therefore, as shown in FIGS. 3 and 5 (a) and 5 (b), the connecting plate 33 joined to the end face of the rotating plate 30 is used.
And pulls it to the right in the figure against the urging force of the winding spring 37 to rotate the rotating plate 30 about the support shaft 28 in the counterclockwise direction in the figure. The operation pin 23 is guided by the long hole 32 and moves by the rotation of the rotation plate 30. At this time, the distance between the elongated hole 32 and the support shaft 28 is determined by the longest distance L ₂ between one end where the operating pin 23 was engaged before the rotation of the rotation plate 30 and the support shaft 28, actuating pin 23 after 30 rotation the changes to the shortest distance L ₁ between the other end and the support shaft 28 to be engaged.

Accordingly, the distance between the support shaft 28 and the elongated hole 32 is reduced, and the engaging body 21 retreats in the housing frame 19. Moving distance of the engaging body 21 at this time is the longest distance L ₂ and the actuating pin 23 after rotation of one end of the operating pin 23 is engaged with the front rotation of the rotary plate 30 and the support shaft 28 it is the shortest distance difference L ₁ between the other end and the support shaft 28 to be engaged. As a result, the engaging portion 25 of the engaging body 21 is separated from the uneven surface 26a of the telescopic strut 14. In this state, the telescopic strut 14 is slid with respect to the strut body 11 to a predetermined position.

Next, as shown in FIG.
The pivot plate 30 is pulled clockwise around the support shaft 28 by the urging force of the winding spring 37 to return to the original state. As a result, the operation pin 23 is guided by the long hole 32 and moves leftward in FIG. That is, the engaging body 21 moves in the advance direction again, the engaging portion 25 is fitted to the uneven surface 26a of the telescopic strut 14, and the telescopic strut 14 and the strut main body 11 are fixed at a predetermined position.

In this manner, the telescopic struts 14 are positioned and fixed at predetermined positions with respect to the strut body 11, respectively, and the telescopic ladders are stably arranged on the grounds 15a to 15d having different heights.

The effects exerted by the above embodiment will be described below. -As shown in FIG. 7, in the telescopic ladder of this embodiment, the telescopic strut 14 is slid with respect to the strut body 11 to a predetermined position, and is fixed by the fixing mechanism 17 at that position, whereby the ladder is moved up and down the stairs. Alternatively, it can be easily used by being placed on a stepped ground or the like. In the telescopic ladder of this embodiment, the operating pin 23 is disposed substantially at the center position of the engaging body 21, and the housing case 1 on a line passing through the operating pin 23 and extending in the moving direction of the engaging body 21.
Since it is fixed on the upper surface 8, the rotating power of the rotating plate 30 can be transmitted most efficiently and accurately to the reciprocating motion of the engagement body 21, and the fixing mechanism 17 can be made compact. -In the telescopic ladder of this embodiment, the rotating plate 30
A pair of aluminum plates are connected so as to face each other, and are disposed on both sides of the engagement body 21. Furthermore, both ends of the operating pin 23 inserted into the engaging body 21 are engaged with the arc-shaped long holes 32 provided at the distal ends of the two rotating plates 30. Therefore, the rotating plate 30 can be smoothly rotated without being twisted, and the force can be evenly transmitted to the operating pin 23. In the positioning device of the telescopic ladder of this embodiment,
By pulling or releasing the connecting plate 33 with a finger, the rotating plate 30 rotates about the support shaft 28 and
Is moved by being guided by the elongated hole 32. In this manner, since the engaging body 21 advances and retreats, the engaging body 21 is merely operated by pulling or releasing the connecting plate 33 with a finger.
Can be easily moved back and forth. Therefore, the conventional screw is not required, and the telescopic ladder can be easily positioned and fixed at a predetermined position. In the positioning device of the telescopic ladder of this embodiment,
The state of engagement between the telescopic strut 14 and the engagement body 21 is maintained by the urging force of the winding spring 37. For this reason, the telescopic strut 14
And the pillar main body 11 can be reliably positioned and fixed. In the positioning device of the telescopic ladder of this embodiment,
The fixing mechanism 17 includes the rotating plate 30, the engaging body 21, and the winding spring 3.
7. The structure is simple because it is composed of a small number of members such as the housing frame 19. Therefore, the manufacturing cost of the positioning device for the telescopic ladder can be reduced. In the positioning device of the telescopic ladder of this embodiment,
Since the connecting plate 33 comes into contact with the housing frame 19, the urging force of the winding spring 37 on the rotating plate 30 can be restricted. In the positioning device of the telescopic ladder of this embodiment,
An elongated hole 32 is formed at the tip of the rotating plate 30 so as to extend in an arc shape. Therefore, the rotation of the rotation plate 30 can be smoothly performed,
Moreover, it can be performed in a stable state. In the positioning device of the telescopic ladder of this embodiment,
Since the connecting plate 33 is joined to the end surface of the rotating plate 30,
When the finger hook 35 is pulled, a force can be directly transmitted to the rotating plate 30.

The above-described embodiment can be modified and embodied as follows. · The engaging portion 25 of the engaging body 21 has the uneven surface 26 of the telescopic strut 14
The holding means for holding at a position apart from the housing a is provided between the housing case 18 and the rotating member 34 or between the housing frame 19 and the engaging body 21, for example, in an uneven relationship.

By doing so, the engaging portion 2 of the engaging body 21
There is no need to keep pulling the connecting plate 33 of the rotating member 34 with a finger so that the telescopic strut 5 is kept at a position separated from the uneven surface 26a of the telescopic strut 14, and the telescopic strut 14 is easily slid with respect to the strut main body 11. be able to. The fixing mechanism 17 is provided inside each column main body 11, and the uneven plate 26 is joined inside each telescopic column 14.

With this configuration, it is possible to prevent the engagement from being released due to external contact or the like. An arc-shaped long hole 32 is formed through both side walls of the engaging body 21;
An operation pin is provided on the rotation plate, and the engagement body is moved forward and backward by the rotation of the operation pin.

Also in the case of such a configuration, the engaging body 21 can be easily moved forward and backward by pulling the connecting plate 33. An uneven plate 26a having an uneven surface is attached and fixed to the side surface of the column main body 11, and the telescopic column 14 is provided with a fixing mechanism 17. The lengths of the support body 11 and the telescopic support 14 are set to the same length so that the length is the shortest when contracted and the longest when extended.

In this way, the distance of the column main body 11 itself is increased, so that the width of use can be expanded. -The support plate 13 of the embodiment is omitted, and each support body 11a,
11b, 11c, and 11d are configured to extend linearly.

In the case of such a configuration, it can be used as a long ladder. When the engagement spring force is desired to be increased, a spring having a strong urging force is used, and when the engagement force is not so required, the winding spring 37 is changed to one having a weak urging force. The engaging portion 25 of the engaging body 21 of the fixing mechanism 17 or the uneven plate 2
6. The length of the concave and convex surface 26a and the depth of the groove are changed according to a desired engagement strength. A frame having a predetermined strength is used as the support 18 to save material.

Further, the technical idea grasped from the above embodiment will be described below. The stretchable ladder according to any one of claims 1 to 3, wherein the elongated hole is formed such that a distance between the elongated hole and the support shaft is the shortest at one end of the elongated hole and the longest at the other end of the elongated hole. Positioning device.

[0033] With this configuration, the turning range of the turning plate can be set, and the engaging or disengaging of the engaging body with the column main body or the telescopic strut can be reliably performed within the turning range. Can be. The positioning device for a telescopic ladder according to claim 3, wherein the pair of plate members are connected by a connecting plate, and the connecting plate is cut out to form a finger hook.

With this configuration, the plate can be rotated directly and easily by pulling the finger hook, and the force can be directly transmitted to the plate. The positioning of the telescopic ladder according to claim 3, wherein a spring hook is formed projectingly on the two plate members, a winding spring is wound around the support shaft, one end of the winding spring is attached to the spring hook, and the other end is attached to the support. apparatus.

With this configuration, the biasing force can be applied to the plate material so that the engaging body is held at the advanced position by the winding spring and the engaging body can always be engaged with the column main body or the telescopic column.

[0036]

The present invention is configured as described above, and has the following effects. According to the positioning device of the telescopic ladder according to claim 1, when the position is adjusted by adjusting the length of the telescopic ladder on the ground or stairs formed in a step shape, the positioning operation can be easily performed, The length of the telescopic ladder can be reliably determined. Further, the structure is simple, and the manufacturing cost can be reduced.

According to the positioning device of the telescopic ladder according to the second aspect, in addition to the effect of the first aspect, the rotating power of the rotating member is most efficiently and accurately applied to the reciprocating motion of the engaging body. The transmission can be performed, and the fixing mechanism can be made compact.

According to the positioning device of the telescopic ladder of the third aspect, in addition to the effects of the first or second aspect, the pair of plate members can be smoothly rotated without being twisted. At the same time, the force can be evenly transmitted to the operating pin.

[Brief description of the drawings]

FIG. 1 is a partially enlarged front sectional view showing a positioning device of a telescopic ladder in an engaged state.

FIG. 2 is a plan sectional view showing a positioning device of the telescopic ladder.

FIG. 3 is a partially enlarged front sectional view showing a positioning device of a telescopic ladder in a disengaged state.

FIG. 4 is a side view showing the storage case.

FIG. 5A is a sectional view showing a rotating plate in an engaged state;
(B) is sectional drawing which shows the rotation board in an engagement release state.

FIG. 6A is a side view showing a storage frame, and FIG.
The side view which shows an engagement body, (c) is a front view which shows a rotation member.

FIG. 7 is a perspective view showing a telescopic ladder on the ground.

[Explanation of symbols]

11 ... pillar main body, 14 ... telescopic pillar, 17 ... fixing mechanism, 1
8 ... accommodation case as a support, 21 ... engagement body, 23 ...
Actuating pin, 25 engaging part, 28: support shaft, 30: rotating plate,
32: long hole, 34: rotating member.

Claims (3)

[Claims] 1. A telescopic strut is slidably mounted on a strut main body of a ladder, and is engaged between the strut main body and the telescopic strut in an uneven relationship to position the telescopic strut at a predetermined position with respect to the strut main body. A positioning device for a telescopic ladder provided with a fixing mechanism for fixing the telescopic strut to the column main body at that position, wherein the fixing mechanism is supported so as to be able to advance and retreat in a support fixed to the column main body or the telescopic strut, An engaging body having an engaging portion having irregularities, a rotating member rotatably supported by a support shaft fixed to the support, a rotating member or a rotating member so that a distance from the support shaft changes. A telescopic ladder comprising: an arc-shaped elongated hole provided in the engaging body; and an operating pin provided in the engaging body or the rotating member so as to be engaged with the elongated hole, and configured to advance and retreat the engaging body by rotating the rotating member. Positioning device. 2. The apparatus according to claim 1, wherein the operating pin is disposed at a substantially central position of the engaging body, and the support shaft is fixed on a support on a line extending through the operating pin in the moving direction of the engaging body. Positioning device for telescopic ladder. 3. The rotating member is configured such that a pair of plate members are connected so as to face each other, and both plate members are arranged on both sides of an engagement body.
The positioning device for a telescopic ladder according to claim 1 or 2, wherein a long hole is provided in each of the plate members, and an operating pin is inserted into the engaging body so that both ends thereof are engaged with the long holes of the plate member.