JPH0520880Y2 - - Google Patents

Description

[Detailed explanation of the invention] (Industrial application field) This invention is a multi-stage, such as two- or three-stage, used for work at high places, such as for mounting on a fire engine, for electrical work, or for painting work. This relates to a telescopic ladder.

(Prior art) Conventionally, ladders used for work at heights have been made of steel or aluminum alloy with two or three steps.
Step ladders are known. However, steel ladders have a relatively large weight and are inconvenient to transport and handle, and aluminum ladders have relatively low rigidity and lack strength to withstand heavy loads. For this reason, when ease of handling and high strength that can withstand heavy loads are required at the same time, such as in firefighting work,
None of the above ladders can fully satisfy that requirement.

Therefore, in order to reduce the weight and increase the strength of the ladder, it has been considered to form the ladder using titanium or a titanium alloy, which has a specific gravity that is approximately half that of steel (for example, titanium's 4.51 and steel's 7.85). It is being However, the abrasion resistance of titanium and the like is lower than that of steel or aluminum, and it is extremely susceptible to wear especially when titanium and titanium are brought into contact with each other and slid. For this reason, when a ladder is made of titanium or the like, the sliding portion generates relatively high temperature frictional heat during expansion and contraction operations, so it is likely to seize, and if it seizes, subsequent expansion and contraction operations cannot be performed.

(Purpose of the invention) This invention was made to solve these conventional problems, and it is a ladder for working at heights that can be reliably extended and contracted and has improved durability. It provides:

(Structure of the device) This device is composed of a plurality of box-shaped ladder portions made of titanium or titanium alloy pipes, and the ladder portion and other ladder portions arranged inside the ladder portion are connected to each other. In a ladder for working at high places that is extendably connected to each other by sliding in the length direction, a protective layer is provided on the rung members of the outer ladder parts of the parts that come into contact with each other when the ladder parts slide. is provided, and this protective layer is formed of a solid material that has high lubricity with respect to titanium or titanium alloy.

According to the above structure, since the ladder is constructed by forming a light titanium or titanium alloy pipe into a box shape, the ladder for working at heights is lightweight and strong overall. It will be done.

This idea was developed for such ladders by forming a protective layer on the parts where the ladder parts come into contact with each other when sliding, and this protective layer is made of a solid material such as titanium that has high lubricity. As a result, the frictional heat caused by sliding can be suppressed to a lower level than in the case without a protective layer, thereby preventing seizure during expansion and contraction operations.

In particular, since the protective layer is provided only on the outer rung member of the ladder part among the parts that come into contact with each other when the ladder part slides, the protection layer is provided only on the outer rung member of the ladder part, so that the inner side part that contacts and slides with the above rung member. Even if a protective layer is not formed on the entire length of the ladder section, the outer ladder section rung member and the inner ladder section do not come into direct contact with each other when sliding, and the protective layer is Titanium or titanium alloy ladders can be effectively protected with minimal formation.

(Example) In FIG. 1, FIG. 2, and FIG. 3, the ladder has a first ladder part 1, a second ladder part 2, and a third ladder part 3 each made of titanium. It consists of three ladder parts.

These ladder parts 1, 2, 3 are made up of four pillars 11, 21, 31 using pipes, and these pillars 11, 2.
A box-shaped frame is formed by a plurality of pipe cross members 12, 22, 32 arranged at regular intervals and connecting the pipes 1, 31 to each other. Supports 11 on the front and back of the first ladder part 1 and the third ladder part 3,
As shown in FIG. 3, diagonal members 13, 33 are fixed between the gusset plates 131, 331 between the crosspieces 12, 32, and the front and back sides of the second ladder part 2 are fixed. There are reinforcing columns 23 between the columns 21.
is arranged along almost the entire length of the second ladder section 2, and this reinforcing column 23 is fixed to the crossbar member 22 and each other. Further, the supports 11 and 21 on the back side of the first ladder part 1 and the second ladder part 2 are connected by strip-shaped crossbar members 12a and 22a, as shown in FIG. Therefore, the thickness between the front and back of the entire ladder is made smaller than if all the rung members were formed from pipes.

The second ladder part 2 is located inside the first ladder part 1, and the third
The size of the ladder part 3 is set so that it can be accommodated inside the second ladder part 2 so as to be retractable. The part 3 is configured to be able to extend and contract by sliding along the inner surface of the second ladder part 2.

A first pulley 41 is attached to the upper end of the first ladder section 1, a second pulley 42 is attached to the lower end of the second ladder section 2, and a third pulley 43 is attached to the upper end of the second ladder section 2. It is being These pulleys 41, 42, 43
, a rope 5 with one end fixed to the lower end of the third ladder section 3 is passed over the third pulley 43, the second pulley 42, and the first pulley 41 in this order.
The other end extends above the ground. By pulling this rope 5, the third ladder part 3 and the second ladder part 2 slide and protrude in this order, and conversely, by loosening the rope 5, the second ladder part 2 and the third ladder part 3 are arranged to slide and descend in this order.

A latch 6 is provided on the outer surface of the upper end of the first ladder section 1 and the inner surface of the lower end of the third ladder section 3, and is removably hooked to the rung member 22 of the second ladder section 2.
1 and 62 are attached, the first latch 61 regulates the position of the second ladder part 2 with respect to the first ladder part 1, and the second latch 62 regulates the position of the second ladder part 2 with respect to the second ladder part 2. 3, the positions of the ladder portions 3 are regulated respectively.

As shown in FIG. 1 and FIG. Protective layer) 7 is attached.
This thin strip plate 7 is a crosspiece member near the supports 11, 21 of the first ladder part 1 or the second ladder part 2, which are opposed to the supports 21, 31 of the second ladder part 2 or the third ladder part 3. It is arranged so as to cover the surfaces of 12, 12a, 22, 22a. This results in the second
When the ladder part 2 or the third ladder part 3 slides, it is the material of the first ladder part 1 and the second ladder part 2, and the second ladder part 2 and the third ladder part 3. This prevents the titanium from touching each other.

The thin strip plate 7 is fixed to the crosspiece member 1 by means of fixing means 8.
As shown in FIG.
1 and a bolt 82 screwed into this locking metal fitting 81
and a contact member 83. Fixing by this fixing means 8 is achieved by bringing the tip of the bolt 82 into contact with the crosspiece members 12, 22 via the abutment member 83, and attaching the locking fitting 82 in this state to the crosspiece members 12, 22.
Hook both ends of the thin strip plate 7 wrapped around 2,
After that, by tightening the bolt 82, the thin strip plate 7
tension, and attach this thin strip plate 7 to the crosspiece members 12, 22.
This is done by placing it in close contact with the surface of the Further, the thin strip plate 7 is fixed to the crossbar members 12a, 22a on the back side with embedded screws.

In the ladder for working at heights having the above configuration, when not in use, the third ladder part 3 is retracted into the inside of the second ladder part 2, and the second ladder part 2 is retracted into the inside of the first ladder part 1. When stored and used, rope 5
By pulling, the second ladder part 2 and the third ladder part 3 protrude from the first ladder part 1 and the second ladder part 2, respectively, and their positions are regulated by the latches 61 and 62 at the required length. It is put into an extended state by doing this.

During the above use, the first ladder part 1 and the third ladder part 3 are provided with gusset plates 131, 331.
A truss structure is formed between the front and back supports 11, 31, and the second ladder part 2 is provided with a reinforcing support 23 in its axial direction, so that only four supports 11, 21, 31 and crosspiece members 12, 22,
32, the strength against bending is greater and deformation such as deflection can be reduced compared to the case of only a square frame constructed by 32. Therefore, titanium has a longitudinal elastic modulus that is almost half that of steel (for example, titanium has a modulus of longitudinal elasticity of 1.1×10 ⁶ Kg/cm ² while steel has a
Each ladder part 1 ^{, 2} ,
3 is formed, work on the ladder can be performed in a stable state, contributing to improvement of work efficiency and safety.

Furthermore, when the ladder parts 2 and 3 are extended and contracted, the supports 21 and 31 of the ladder parts 2 and 3 slide while contacting any one of the plurality of thin strip plates 7 fixed to the ladder parts 1 and 2, so that Titanium, which is the material of the thin strip plate 7, and copper alloy, which is the material of the thin strip plate 7, come into contact and slide. This copper alloy is softer than titanium, and when sliding, the copper alloy acts as a solid lubricant, wears out before the titanium, and reduces friction, so they can slide smoothly against each other, and the problems that occur at that time Frictional heat is also relatively small. Therefore, the frictional heat generated can be suppressed compared to the conventional case where titanium and titanium slide in contact with each other, thereby preventing the occurrence of seizure.

Furthermore, by replacing the thin strip plate 7 as the ladder is used, maintenance can be performed more easily than when using a liquid lubricant such as grease. Supports 11, 21, 31 and horizontal members 12, 22, 3
2 etc. can be maintained in a state close to that before use, and the durability of the ladder can be improved.

In addition, the thin strip plate 7 has horizontal members 12, 12a,
They do not need to be provided on all of the 22, 22a; for example, they may be provided on every other wire at regular intervals.

In addition, in the above embodiment, the supports 11, 21, 31 and the crossbar members 12, 12 of each ladder part 1, 2, 3
The material for forming a, 22, 22a, and 32 may be a titanium alloy in addition to titanium. Further, in the above embodiment, the first to third ladder parts 1, 2, and 3 form a three-step ladder, but the ladder is not limited to this, and may be formed into two steps or four steps.

Further, the thin strip plate 7 and the fixing means 8 in the above embodiment
The protective layer formed by the above can also be constructed as follows.

(a) As shown in FIG. 6, a copper alloy thin plate 7a of a predetermined size is adhered to the surfaces of the crosspiece members 12 and 22.

(b) As shown in FIG. 7, pads 7b made of copper alloy of a predetermined size are fastened to crossbar members by bands 84 that are tightened by a combination of locking fittings 81 and bolts 82 similar to those of the fixing means 8. The position is fixed on the surfaces of 12 and 22.

(c) The thin strip plate 7, the thin plate 7a, and the pad 7b are made of synthetic resin such as fluororesin or phenol resin. When the thin plate 7a and the like are formed of fluororesin, they may be bonded to the crossbar members 12, 22. As the adhesive, for example, a two-component adhesive containing a modified silicone polymer as a main component is preferable. In addition, when adhering, as a pretreatment before adhesion, the adhesion surfaces are polished with a file or sandpaper to increase the surface roughness, and then washed with acetone etc. to improve the adhesion. It can be made more reliable. In addition, when a protective layer is formed from a fluororesin using an adhesive means, a so-called Teflon (trade name of Dupont) tape, which is a tape-shaped fluororesin member coated with an adhesive on one side (for example, A protective layer made of fluororesin may be formed by simply wrapping Nitoflon adhesive tape (trade name, Nitto Denko Co., Ltd., thickness 0.18 mm) around the crossbar members 12, 22.

(d) A layer of copper alloy is formed on the surface of the crossbar members 12, 22 at predetermined positions by plating or ion plating. In this case, a layer of nickel, aluminum, chromium, carbon, etc. may be formed in addition to the copper alloy.

(e) Form a synthetic resin layer on the surface of the crossbar members 12, 22 at predetermined positions by coating.

(Effects of the invention) According to the ladder for working at heights of this invention, a protective layer with high lubricity against titanium etc. is formed on the parts of the ladder parts that are slidingly connected to each other, so there is no protective layer. The frictional heat caused by sliding can be suppressed to a lower level than in the case of sliding, which prevents seizure during expansion and contraction operations, and allows the expansion and contraction operations to be performed smoothly and reliably. . Therefore, the operability and durability of the ladder can be improved.

In particular, since the protective layer is provided only on the outer rung member of the ladder part among the parts that come into contact with each other when the ladder part slides, the protection layer is provided only on the outer rung member of the ladder part, so that the inner side part that contacts and slides with the above rung member. Even if the protective layer is not formed on the entire length of the ladder support, the outer ladder crosspiece member and the inner ladder support do not come into direct contact with each other when sliding, and the protective layer is not formed on the entire length of the ladder support. It is advantageous to be able to effectively protect titanium or titanium alloy ladders while minimizing the formation of titanium or titanium alloys.

[Brief explanation of drawings]

Figure 1 shows an embodiment of this invention.
2 is a front view of the ladder shown in FIG. 1, FIG. 3 is a side view of FIG. 2, FIG. 4 is an enlarged view corresponding to FIG. 1, and FIG. 6 is a diagram corresponding to FIG. 5 showing another embodiment, and FIG. 7 is a diagram corresponding to FIG. 5 showing another embodiment different from the above embodiment. 1, 2, 3...Ladder part, 7...Thin strip plate (protective layer).

Claims (1)

[Claims for Utility Model Registration] 1. Consisting of a plurality of box-shaped ladder parts made of titanium or titanium alloy pipes, the ladder part and other ladder parts arranged inside the ladder part are In a ladder for working at high places that is extendably connected to each other by sliding in the length direction, a protective layer is provided on the rung members of the outer ladder parts of the parts that come into contact with each other when the ladder parts slide. 1. A ladder for working at high places, characterized in that the protective layer is formed of a solid material having high lubricity with respect to titanium or a titanium alloy. 2. A ladder for working at heights according to claim 1, wherein the protective layer is made of a copper alloy. 3. A ladder for working at heights according to claim 1, wherein the protective layer is made of synthetic resin. 4. Utility model registration claim 1, 2 or 3, characterized in that the protective layer is formed by winding a band plate-like member.
Ladders for working at heights as described in Section 1. 5. A ladder for working at heights as set forth in claim 1, 2, or 3 of the utility model registration, characterized in that the protective layer is formed by adhesive.