CA2291986A1 - An extension ladder with telescopic legs - Google Patents
An extension ladder with telescopic legs Download PDFInfo
- Publication number
- CA2291986A1 CA2291986A1 CA002291986A CA2291986A CA2291986A1 CA 2291986 A1 CA2291986 A1 CA 2291986A1 CA 002291986 A CA002291986 A CA 002291986A CA 2291986 A CA2291986 A CA 2291986A CA 2291986 A1 CA2291986 A1 CA 2291986A1
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- Canada
- Prior art keywords
- rung
- lock ensuring
- block
- locking
- extension ladder
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Abandoned
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Classifications
-
- E—FIXED CONSTRUCTIONS
- E06—DOORS, WINDOWS, SHUTTERS, OR ROLLER BLINDS IN GENERAL; LADDERS
- E06C—LADDERS
- E06C7/00—Component parts, supporting parts, or accessories
- E06C7/06—Securing devices or hooks for parts of extensible ladders
-
- E—FIXED CONSTRUCTIONS
- E06—DOORS, WINDOWS, SHUTTERS, OR ROLLER BLINDS IN GENERAL; LADDERS
- E06C—LADDERS
- E06C1/00—Ladders in general
- E06C1/02—Ladders in general with rigid longitudinal member or members
- E06C1/04—Ladders for resting against objects, e.g. walls poles, trees
- E06C1/08—Ladders for resting against objects, e.g. walls poles, trees multi-part
- E06C1/12—Ladders for resting against objects, e.g. walls poles, trees multi-part extensible, e.g. telescopic
- E06C1/125—Ladders for resting against objects, e.g. walls poles, trees multi-part extensible, e.g. telescopic with tubular longitudinal members nested within each other
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Ladders (AREA)
Abstract
Disclosed is an extension ladder mainly including a pair of telescopic legs consisting of a plurality pairs of straight round tube members, a plurality of rungs in the same numbers as that of the tube member pairs and each having two lateral ends for the two legs to pass therethrough, a plurality sets of locking mechanisms and lock ensuring mechanisms, and a general switch assembly disposed beneath the lowest rung. The tube member each has a sleeve member and a plug assembly disposed around a top end and in a bottom end, respectively. Each plug assembly includes a set of cover members and a set of inserts having an upper and a lower movable hook members connected thereto. The upper hook member in a lower tube member separately links with the lower hook member in a higher tube member, limiting the tube members of the telescopic legs to be sequentially extended stair by stair. The upper hook member each has an air cock provided at a bottom end thereof to close or open an air port formed on a base of the inserts. The air cocks and the air ports, together with two one-way valves separately disposed at a lower portion of the lowest tube member pairs, enable the ladder to be quickly extended from a collapsed state and be collapsed from an extended state at moderate speed. The locking mechanisms and lock ensuring mechansims are disposed beneath each rung to effectively prevent the ladder from unexpectedly collapsed due to any accidental touch of the locking mechanisms. The general switch assembly serves to actuate and control the sequential and moderate collapse of the rungs.
Description
'" , 1 This is a divisional of my co-pending Canadian Patent Application No. 2,157,842 filed September 8, 1995.
The present invention relates to an extension ladder with telescopic legs, and more particularly to an extension ladder which can be quickly extended for use or be telescoped in a slow and sequential manner for safe storage when it is not in use.
Moreover, the extension ladder of the present invention can be easily assembled and is provided with automatic locking and lock ensuring means to further ensure the safety in use.
The present invention relates to an extension ladder with telescopic legs, and more particularly to an extension ladder which can be quickly extended for use or be telescoped in a slow and sequential manner for safe storage when it is not in use.
Moreover, the extension ladder of the present invention can be easily assembled and is provided with automatic locking and lock ensuring means to further ensure the safety in use.
2. Description of the Prior Art Fig. 1 shows a conventional extension ladder with multiple rungs. The ladder includes a pair of legs 800, 900 each consisting of multiple tapered telescopic sections (in the drawing, four sections of each leg are shown, separately indicated by reference numerals 100A, 200A 300A, 400A and 100B, 200B, 300B, 400B, from bottom to top. Please see Fig. lA for the structure of these legs), multiple rungs (in the drawing three rungs are shown, separately indicated by reference numerals 500, 600, 700, from bottom to top) each having a reverse U-shaped cross section, and multiple sets of locking mechanism for firmly locking the telescopic sections of the legs in place after they are fully extended. The numbers of the rungs are equal to that of the telescopic sections of the legs.
The telescopic sections are provided at their upper and middle portions with locating holes (in the drawing, locating hole 111 on the upper portion of the telescopic section IOOA, locating holes 211, 221 respectively on the upper and the middle portions of the telescopic section 200A, and locating hole 321 on the middle section of the telescopic section 300A are shown). The rungs 500, 600, 700 each has two ring-like ends 500A and 5008, 600A and 6008, 700A and 7048, respectively, for tightly engaging with a pair of reduced parts 112, 212, or 312 at the upper portions of their corresponding telescopic sections 100A, 100B; 200A, 2008; or 300A, 3008. In addition, the ring-Like ends 500A, 5008; 600A, 6008; 700A, 7008 of the rungs 500, 600, 700, resepctively, are provided with a hole 50IA, 601A, 70IA, respectively, corresponding to the locating holes 111, 211, etc, on the upper portion of the telescopic sections.
Retaining rods 512, 612, etc. respectively having a push arm 514, 614, etc. and a return spring 513, 613, etc. are disposed near the ring-like ends 500A, 5008; 600A, 6008;
700A, 7008 of the rungs 500, 600, 700, respectively, to form the locking mechanisms. Moreover, wear-proof plug members 222, 322, 422 with vents 222A, 322A, 422A are separately plugged into a bottom end of the telescopic sections 100A, 200A, 300A, 400A, 1008, 2008, 300B, 4008.
Following disadvantages are found in the above-described conventional extension ladder:
1. To assemble the extension ladder, each tapered telescopic section thereof must be engaged into a lower section by inserting its top end into a lower end of the lower section one by one, and the rungs must be riveted to each top of the telescopic sections. Such assembling procedures can not be easily performed and the sections are not easily aligned with one another when they are assembled according to the above procedures.
The telescopic sections are provided at their upper and middle portions with locating holes (in the drawing, locating hole 111 on the upper portion of the telescopic section IOOA, locating holes 211, 221 respectively on the upper and the middle portions of the telescopic section 200A, and locating hole 321 on the middle section of the telescopic section 300A are shown). The rungs 500, 600, 700 each has two ring-like ends 500A and 5008, 600A and 6008, 700A and 7048, respectively, for tightly engaging with a pair of reduced parts 112, 212, or 312 at the upper portions of their corresponding telescopic sections 100A, 100B; 200A, 2008; or 300A, 3008. In addition, the ring-Like ends 500A, 5008; 600A, 6008; 700A, 7008 of the rungs 500, 600, 700, resepctively, are provided with a hole 50IA, 601A, 70IA, respectively, corresponding to the locating holes 111, 211, etc, on the upper portion of the telescopic sections.
Retaining rods 512, 612, etc. respectively having a push arm 514, 614, etc. and a return spring 513, 613, etc. are disposed near the ring-like ends 500A, 5008; 600A, 6008;
700A, 7008 of the rungs 500, 600, 700, respectively, to form the locking mechanisms. Moreover, wear-proof plug members 222, 322, 422 with vents 222A, 322A, 422A are separately plugged into a bottom end of the telescopic sections 100A, 200A, 300A, 400A, 1008, 2008, 300B, 4008.
Following disadvantages are found in the above-described conventional extension ladder:
1. To assemble the extension ladder, each tapered telescopic section thereof must be engaged into a lower section by inserting its top end into a lower end of the lower section one by one, and the rungs must be riveted to each top of the telescopic sections. Such assembling procedures can not be easily performed and the sections are not easily aligned with one another when they are assembled according to the above procedures.
2. When the ladder is extended for use, the higher rungs are always separated from each other and locked in place before the lower rungs are completely pulled out to their true positions. Therefore, the telescopic sections of the conventional extension ladder can not be sequentially extended and located in place one by one from bottom to top.
Also, the ladder might unexpectedly and dangerously collapse due to operational mistake by an operator.
3. To collapse the extension-ladder, the push arms of the locking mechanisms of the lowest rung is pulled to disengage the retaining rod thereof from the corresponding locating hole, allowing the next higher telescopic section to descend until the locking mechanisms of the next higher rung touches the lower rung below it. The contact of the higher rung with the lower rung shall release the higher telescopic sections from the locking mechanisms of the higher rung.
With the same movement, the remaining telescopic sections and rungs collapse and descend one by one. However, there is not any buffer provided between every two of the telescopic sections, the rungs descend at a speed high enough to unexpectedly and dangerously injure a user's fingers. A buffer member disposed at the bottom end of each telescopic sections might effectively slow the descending of the rungs, the extension of the telescopic sections will, however, become slow, too.
Also, the ladder might unexpectedly and dangerously collapse due to operational mistake by an operator.
3. To collapse the extension-ladder, the push arms of the locking mechanisms of the lowest rung is pulled to disengage the retaining rod thereof from the corresponding locating hole, allowing the next higher telescopic section to descend until the locking mechanisms of the next higher rung touches the lower rung below it. The contact of the higher rung with the lower rung shall release the higher telescopic sections from the locking mechanisms of the higher rung.
With the same movement, the remaining telescopic sections and rungs collapse and descend one by one. However, there is not any buffer provided between every two of the telescopic sections, the rungs descend at a speed high enough to unexpectedly and dangerously injure a user's fingers. A buffer member disposed at the bottom end of each telescopic sections might effectively slow the descending of the rungs, the extension of the telescopic sections will, however, become slow, too.
4. The locking mechanisms can be easily unlocked by pulling the push arm. In the case the push arm is unexpectedly pulled by someone, especially a child, accident might very possibly occur.
5. The telescopic sections of the extension ladder frictionally contact with one another when they are extended or collapsed and are therefore worn out and become loosely connected after being used for a long period of time.
Therefore, it is necessary to provide an improved extension ladder to eliminate the above shortcomings.
SUMMARY OF THE INVENTION
It is a primary object of the present invention to provide an extension ladder having a safer and more effective structure. The extension ladder of the present invention includes two legs which each consists of a plurality of sequentially telescoped sections. These telescopic sections each is a straight round tube having uniform diameter which facilitates the assembly of the telescopic sections and the rungs.
Another object of the present invention is to provide an extension ladder in which a plug assembly is mounted to a bottom end of each telescopic section thereof. The plug assembly each consists of an upper and a lower movable hook members. When the extension ladder is in a fully extended state, the upper hook'members may separately extend their pointed end into retaining holes formed on the telescopic sections. The upper hook member each has a bevelled projection formed at an upper corner thereof on which a lowe.= hook member of the plug assembly in the next higher telescopic section hooks when the extension ladder is in a fully collapsed state. When the ladder is extended and the upper hook members separately extends into the retaining holes on the telescopic sections, the lower hook members of the upper plug assemblies disengage from the bevelled projection of the upper hook member, allowing the telescopic sections of the ladder to be pulled upward one by one from bottom to top.
It is a further object of the present invention to provide the above-mentioned extension ladder in which the plug assembly each is provided at a bottom portion of the upper hook member with an air cock, and at a base thereof with an air port corresponding to the air cock, and the lowest telescopic sections and the lowest rung are provided with one-way valves and cooperating air tube, respectively, whereby when the extension ladder is extended and the upper hook members pivot to extend through the retaining holes on the telescopic sections with their bottom portions lifted, the air ports are opened to together with the one-way valves and the cooperating air tube allow the air in the telescopic sections to quickly flow through the legs and thereby permits the ladder to be quickly extended. Or, when the ladder is collapsed and the upper hook members pivot to disengage from the retaining holes on the telescopic sections with their bottom portions and accordingly the air cocks descended, the air ports are closed to slow the air flow in the telescopic sections and the collapse speed thereof.
It is still a further object of the present invention to provide an extension ladder in which locking mechanisms are separataely mounted below the rungs centered on each end thereof and a lock ensuring mechanism is disposed behind each locking mechanism, whereby when the lock ensuring mechanisms are in a locked state, the corresponding locking mechanisms would not be unexpectedly and dangerously unlocked by pulling an pushing arm thereof. When the top surface of a lower rung touches the lock ensuring mechanisms of the next higher rung, the lock ensuring mechanisms of the next higher rung are unlocked to free their associated locking mechanisms, permitting the rung and the telescopic sections of the next higher stair of the ladder to collapse.
Therefore, the rungs and the telescopic sections of other higher stairs of the ladder can be sequentially and safely collapsed from bottom to top in the same manner as described above.
It is still a further object of the present invention to provide an extension ladder in Which a wear-proof ring member is fitted around a bottom outer periphery of each telescopic section to prevent the same from directly fractionally contacting with each other at their wall surfaces lest the telescopic sections should become wearing and loosely contacting with each other which is dangerous to any user.
BRIEF DESCRIPTION OF THE DRAWINGS
The detailed structure and functions of the present invention can be best understood through the following detailed description of the preferred embodiments and the accompanying drawings, wherein:
Fig. 1 is a fragmentary perspective view of a conventional extension ladder, a part of which is cut away to show the manner in which the rungs are connected to the legs of the ladder;
Fig. lA is a fragmentary, exploded perspective view of Fig.
1 showing the structure of the leg of the ladder;
Fig. 2 is a fragmentary, exploded perspective view of an extension ladder according to the present invention, a part of which is cut away to show the assembling of a rung to two vertically telescoped sections of the legs;
Fig. 2A is a fragmentary, sectional view taken on line A-A
of Fig. 2;
Fig. 3 is an exploded perspective view of a plug assembly disposed at a bottom end of each telescopic section of the present invention;
Fig. 3A is a fragmentary, assembled, sectional view showing the positions of an upper and a lower hook members of the plug assembly in a telescopic section of the present invention;
Fig. 4A is a fragmentary, sectional view showing the manner in which the telescopic sections of the legs of the present invention is sequentially extended from a collapsed state;
Fig. 4B is a fragmentary, sectional view showing the manner in which the telescopic sections of the legs of the present invention is gradually collapsed from an extended state;
Fig. 5A is a fragmentary, exploded perspective view of a locking mechanism and an associated lock ensuring mechanism disposed in a rung other than the first or the lowest rung of the present invention;
Fig. 5B is a fragmentray, exploded perspective view of a general switch assembly and the associated locking mechanism disposed in the first or the lowest rung of the present invention;
Figs. 6A to 6E are fragmentary, sectional views showing the operation of the mechanisms at different stairs of the ladder of the present invention to collapse the same; and Fig. 7 schematically shows another embodiment of the present invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Please refer to Fig. 2. The extension ladder of the present invention mainly includes a pair of legs lA, 1B each consisting of a plurality of telescopic section pairs, a plurality of rungs each having a peripheral wall which gives the rung a substantially reverse U-shaped cross section, a plurality of locking mechanisms 80 for locking the telescopic section pairs of the legs lA, 1B in place, and a plurality of lock ensuring mechanisms 82 cooperating with the locking mechanisms 80. The numbers of the rungs are equal to that of the telescopic section pairs. In the first embodiment of the present invention, reference numerals 50A
and 50 are designated to the first (the lowest) and the other higher rungs, respectively. The telescopic sections of the legs lA, 1B each is formed from a straight round tube member having uniform diameter through its length. A lower telescopic section or tube member always has an inner diameter larger than an outer diameter of a telescopic section or tube member immediately above it, such that every higher telescopic section can always be fitly received in a telescopic section immediately below it. In this embodiment, the telescopic sections of the legs lA, 1B are sequentially named the first tube member 10, the second tube member 20, the third tube member 30,..... from bottom to top.
_ g _ A sleeve member 60 and a plug assembly 30A are disposed on a top end and a bottom end of each telescopic section, respectively. Figs. 2 and 2A illustrate the manner in which the next lower or the second rung 50 (that is, the rung immediately above the first rung 50A) and the next lower telescopic section pairs (that is, the second tube members 20) are assembled and locked in place. Since every other stairs of the ladder of the present invention and either lateral side thereof are assembled in the same manner, they are not repeatedly explained herein. Of course, in the actual assembling, it must begin with the lowest (that is, the first) pair of telescopic sections and the lowest rung from either side thereof.
I5 Please refer to Figs. 2 and 2A. To form the second stair of the extension ladder, first insert the third tube members downward to pass through the sleeve members 60 fitted over the top end of the second tube members 20. The third tube members 30 each is premounted at its lower end with a plug assembly 30A. The manner in which the plug assembly 30A
is assembled and functions will be described in more details later in this specification. Then, the second rung is put over and engaged with a top end of the third tube members 30. Allow the third tube members 30 and the plug assemblies 30A at their bottom ends to e xtend into the second tube members 20. The sleeve member 60 each is formed at a top end with an outward extended upper flange on which an upper and a lower locating bosses 61A, 6 1B are provided to respectively engage with a first loca ting recess formed on the second rung 50 and a second loc ating recess formed near an upper edge of the second t ube member 20, causing a first locating hole 62 to aligne with a locating hole 54 formed at one end of the second rung 50. The second tube members 20 are firmly engaged into two ends of the second rung 50 with the sleeve members 60 between them without the risk of turning relative to the the second rung 50. An elongated slot 51 is formed at either end of the second rung 50 and a pair of threaded holes 52 are oppositely formed on the peripheral wall of the second rung 50 at two sides of each slot 51, whereby fastening screws 53 can be passed through the threaded holes 52 to narrow the slots 51 and thereby tightly bind the second rung 50 with the second tube members 20.
The locking mechanisms 80 are disposed near the ends of the second rung 50 on a central axis thereof and the lock ensuring mechanisms 82 are separately disposed just behind the locking mechanisms 80. For the first (lowest} stair of the ladder, a general switch assembly 90 can be additionally provided beneath the first rung 50A to cooperate with the lock ensuring mechanism to control the extension or collapse of the entire ladder.
Fig. 3 illustrates in details the manner in which the plug assembly 30A and the third tube member 30 are assembled.
The plug assembly 30A each consists of a front cover 33A, a rear cover 33B, a front insert 31A, and a rear insert 31B.
Both the front insert 31A and the rear insert 31B are formed at their lower outer wall with a lower flange. A first pin 32I is used to pass an inner side of the front insert 31A
while threading through a first return spring 32H and pivotally connecting an upward extended and movable upper hook member 32A to the front insert 3IA. The upper hook member 32A is provided on its one side surface at an upper corner thereof with a bevelled projection 32G. A roller 32F is disposed in a hollow space formed at a front portion of the upper hook member 32A with a somewhat flexible cover plate 32J fitted in front of the roller 32F, such that when the upper hook member 32A extends into a locating hole 33C formed on the front cover 33A, the locating hole 33C is airtightly sealed. An air cock 32E is provided at a bottom end of the upper hook member 32A. An air port 31D is formed on a base of the front insert 31A
corresponding to the air cock 32E, whereby the air port 31D
is opened or closed when the upper hook member 32A is pivotally turned about the first pin 32F to lift or lower the bottom end, respectively.
A ring ear 31E is connected to an underside of the front insert 31A. A downward extended and movable lower hook member 32B is pivotally connected to the ring ear 31E by means of a second pin 32D Which is threaded through a scond reuturn spring 32C and an upper portion of the lower hook member 32B and the ring ear 31E. The lower hook member 32B
is eccentrically positioned below the front insert 31A and is vertically aligned With the bevelled projection 32G of the upper hook member 32A. A projected block 31C is formed near a front portion of the front insert 31A such that when the front insert 3IA is placed into the third tube member 30 and fitted into a locating hole 30B thereof, the front cover 33A is engaged at its bottom flange 33H with the bottom end of the third tube member 30 with a locating projection 33E
thereof extending into the locating hole 30B of the third tube member 30 and vertically abutting against the projected block 3IC of the front insert 3IA just beneath it, permitting a front half of the plug assembly 30A to be firmly fixed to the third tube member 30.
Then, the rear insert 31B having an air outlet 31F is inserted into the third tube member 30, permitting an opening 33F on the rear insert 31B to communicate with an opening 30C on the third tube member 30. Then, the rear cover 33B is fitted around the third tube member 30 with a bottom flange 33G of the rear cover 33B engaging into a clearance between the bottom end of the third tube member 30 and the rear insert 31B. At this point, a locating projection 33D on an inner wall of the rear cover 33B
extends through the opening 33F of the rear insert 31B and engages into the opening 30C, permitting the rear half of the plug assembly 30A to be firmly fixed to the third tube member 30.
As shown in Fig. 4A, when the assembled ladder is to be extended from a collapsed state, the lower hook members 32B
of the plug assemblies 30A in the next higher tube members that are connecting with the upper hook members 32A of the plug assemblies 30A in the lowest tube members 10 by means of the bevelled projections 32G shall became disengaged from the upper hook members 32A after one-way 20 valves 70 disposed near bottom ends of the first tube members 10 are opened due to a pressure differential resulted from the extending operation. The open of the valves 70 permits air to be supplied to the first tube members 10. Due to the air flowing in the tube members forming the legs of the ladder, the telescopic sections of the legs can be quickly extended. When the upper hook members 32A of the plug assemblies 30A in the second tube members 20 are moved to a point in alignment with locating holes l0A formed on the first tube members 10, the upper hook members 32A are sprung toward the locating holes l0A
under the spring force of the first return springs 32H
and thereby open the air ports 31D. At this point, the air further flows upward. Meanwhile,~the lower hook members 32B
of the immediately higher telescopic sections 30 are released from the bevelled projections 32G of the upper hook members of the second tube members 20 because they move upward along with their upper hook members 32A. At this point, the next higher rung, that is, the second rung 50 can be pulled upward. After the upper hook members of the next higher tube members 30 are moved upward and engaged into the corresponding locating holes formed on the lower tube members 20, the next higher rung, that is, the third rung 50, can be further pulled upward. In the same manner, other higher telescopic sections and rungs can be sequentially extended.
Reversely, when the ladder is downward pushed to collapse it, the rollers 32F in front of the upper hook members 32A
in the second tube members 20 rotate when they are pressed against an inner wall of the tube members 20, allowing the upper hook members 32A to disengage from the locating holes l0A of the tube members 10. A compression effect similar to the function of a piston will be created on each of the plug assemblies at the bottom of the tube members, forcing the one-way valves 70 to close. Air in the tube members is compressed and can only escape from the relatively small air outlet 31F on the rear insert, permitting the ladder to be collapsed slowly. When the tube members 20 are collapsed to such an extent that the lower hook members 32B thereof engage with the bevelled projections 32G of the upper hook members 32A of the plug assemblies 30A in the first tube members 10 due to the spring force of the return springs 32H
and the bevel surfaces of the bevelled projections 32G, the higher tube members 20 are therefore connected to the Iower tube members 10. In the same manner, the other higher tube members are sequentially collapsed and connected to their respective immediate lower tube members, permitting the completely collapsed ladder to be carried by just holding its highest rung- without the risk of unexpectedly extending again. Moreover, with the locking mechanisms, the lock ensuring mechanisms, and the general switch assembly which will be described in more details later, the ladder can be automatically and sequentially collapsed stair by stair from bottom to top.
Fig. 5A shows the locking mechanism and the lock ensuring mechanism of the present invention, wherein the locking mechanism 80 each consists of a sleeve member 80A, a locking pin 81, a touch arm S1A, a push block 81B, a first pin member 81C, and a spring 81D. The sleeve member 80A is fitted into the locating hole 54 formed at each end of the second rung 50. One end of the locking pin 81 is inserted into the sleeve member 80A while the other end of the locking pin 81 is threaded through the spring 81D to extend into a substantially reverse U-shaped stopper 57 disposed in the second rung 50.~ Below the locking pin 81, the first pin member 81C is used to connect the touch arm 81A to the push block 81B and fixedly locate them in the rung 50, such that when the touch arm 81A is touched, the locking pin 81 can be moved backward so as to unlock the locking mechanism 80.
The lock ensuring mechanism 82 each is composed of a locking block 83, an unlocking touch arm 83D, a first stop screw 56, and a third return spring 83E. The lock ensuring block 83 is formed at each side with a straight slide channel 83B to receive a slide block 58 in the second rung 50, whereby the lock ensuring block 83 can be vertically slided relative to the second rung 50. The lock ensuring block 83 has an indicating block 83C projecting from a top thereof, whereby when the lock ensuring block 83 is moved upward to a top position of the second rung 50, the indicating block 83C
protrudes beyond a warning opening 59 formed on a top surface of the second rung 50 to indicate the actual operating state of the lock ensuring mechanism 82.
The lock ensuring block 83 has a pin hole 83A
provided at a .front end thereof to receive one end of the locking pin 81 extending through the reverse U-shaped stopper 57. The third return spring 83E and the unlocking touch arm 83D are disposed on a side of the locking block 83 near a rear end thereof. The unlocking touch arm 83D is formed at an outer side facing the peripheral wall of the second rung 50 with a recess. A notch 83F is provided on a peripheral wall surrounding the recess of the unlocking touch arm 83D, such that when the lock ensuring block 83 is glaced into the second rung 50 and the first stop screw 56 is screwed through the peripheral wall of the second rung 50, a lower side of the screw 56 abuts against the peripheral wall of the recess of the unlocking touch arm 83D
to limit the lock ensuring block 83 to travel only within a distance defined by the unlocking touch arm 83D.
Fig. 5B shows the general switch assembly 90 and the locking mechanism 80 mounted in the first (the lowest) rung 50A of the present invention. Since these components are somewhat different from those mounted in other rungs 50, they are separately described herein. The general switch assembly 90 includes a shifting wheel 90K having a shifting arm 90B, two lock ensuring push plates 90J separately disposed at two ends of the first rung 50A, two resilient engaging pieces 90C, and two pull rods 90A each being connected at one end to the shifting wheel 90K and at the other end to a locking pin 81 of the locking mechanism 80 by extending through a central pin hole 90I formed on each lock ensuring push plate 90J.
To assemble the general switch assembly 90 and the locking mechanisms 80 to the first rung 50A, the shifting wheel 90K
is fixed to a bottom central portion of the first rung 50A
by means of extending a second pin member 90M through the peripheral wall of the first rung 50A and through the shifting wheel 90K. The lock ensuring push plates 90J each is disposed in the first rung 50A With two lateral edges thereof separately received in slide channels 90N formed on the geripheral wall of the first rung 50A near each end thereof, allowing the lock ensuring push plates 90J to vertically move in the first rung 50A up and down. Second stop screws 900 are separately screwed into the peripheral wall of the first rung 50A to extend into dents 90P
separately formed on a side edge of the two ensuring push plates 90J, so as to limit the lock ensuring push plates 90J
to vertically move within a distance defined by the dents 90P. The lock ensuring push plates 90J each has a tog indicating block 83C which protrudes beyond the warning opening 59 formed on the first rung 50A. The Iock ensuring push plate 90J each is formed with a central pin hole 90I
and a projected block 90D. The central pin hole 90I each has a vertical length larger than a diameter of the locking pin 81, whereby the locking pin 81 can be moved into or out of the central pin hole 90I. The resilient engaging pieces 90C each is engaged with the projected block 90D while its two lower ends are received in slide channels 90Q formed in the first rung 50A.
With the above arrangements, the extension ladder of the present invention. can be automatically and sequentially collapsed in a manner as shown in Figs. 6A, 6B, 6C, 6D and 6E, wherein the plug assemblies 30A are only schematically illustrated.
Fig. 6A illustrates the extension ladder in an extended and locked state. At this point, the lock ensuring blocks 83 of the rungs 50 and the lock ensuring push plates 90J of the rung 50A serve to disengage the locking pins 81 from the gin holes 83A and the central pin holes 90I, respectively, allowing the rungs 50 and 50A to be in a firmly locked position relative to the higher tube members and the first tube members, respectively. Meanwhile, the resilient engaging pieces 90C separately engage with the projected blocks 90D of the lock ensuring push plates 90J.
Fig. 6B illustrataes the first step to collaps the extension ladder. First, the lock ensuring push plates 90J are pushed upward to disengage the resilient engaging pieces 90C from the projected blocks 90D of the lock ensuring push plates 90J. At this point, the indicating blocks 83C on the top of the lock ensuring push plates 90J moves upward to protrude beyond the warning openings 59, indicating the rungs and the telescopic tube members of legs are released from the safely locked position. The indicating blocks 83C can be painted in red color or with any other warning mark. Before using the extension ladder, first check for any indicating blocks 83C protruded beyond the rungs. Any protruded indicating block 83C means the ladder is not in a locked position for safe use. At this point, the locking pins 81 each abuts against a lower edge of the central pin holes 90I, leaving a gap between the locking pin 81 and an upper edge of the central pin hole 90I. The locking pins 81 at this position are allowed to extend into the central pin holes 90I to interact with the pull rods 90A and the shifting wheel 90K.
That is, as shown in Fig. 6C, when the shifting arm 90B of the shifting wheel 90K~is shifted to pull the pull rods 90A, causing the locking pins 81 to move toward the center of the rung 50A until the locking pins 81 abut against the resilient engaging pieces 90C. At this point, the resilient engaging pieces 90C are pushed by the locking-pins 81 to disengage from the projected blocks 90D of the lock ensuring push plates 90J. Meanwhile, the gaps between the locking pins 81 and the upper edge of the central pin holes 901 cause the lock ensuring push plates 94J to move downward which further causes the resilient engaging pieces 90C to separate from the projected blocks 90D. Therefore, when the locking pins 81 are further inserted into the lock ensuring push plates 90J and be locked thereto, the lock ensuring push plates 90J will not be stopped by the resilient engaging pieces 90C and are therefore, permitted to slide downward to a firmly and safely locked position. When the shifting wheel 90K is shifted to an upper position, a retaining leaf spring 90H on the shifting wheel 90K is stopped by a retaining projection 90U formed on a bottom center of the first rung SOA and the shifting wheel 90K is prevented from further rotating and is restricted to a fully unlocked position. This avoids undesired partial collapse of the extension ladder due to instantaneous extension by manual operation.
When the immediate higher rung 50 descends and the unlocking touch arms 83D touch the first (lowest) rung 50A, as shown in Fig. 6D, the lock ensuring blocks 83 are forced to move upward. At the same time, the indicating blocks 83C
protrude beyond the warning openings 59. When the lock ensuring blocks 83 move to an upmost position, the pin holes ' - I9 -83A are aligned with the locking pins 81, allowing the locking pins 8I to move into the pin holes 83A. Meanwhile, the notches 83F of the unlocking touch arms 83D are aligned with the first stop screws 56. At this point, a downward projected gin 90F disposed on a central position of the upper rung 50 approaches to and is aligned with a hole 90E
formed on the first {lowest) rung 50A.
As shown in Fig. 6E, before the upper rung 50 is collapsed to its lowest position, the unlocking touch arms 83D and the touch arms 81A connected to the locking pins 81 are forced to pivotally turn sideward away from the lock ensuring blocks 83 and the locking pins 81 are further moved into the pin holes 83A, leaving the telescopic tube.members in an unlocked state and permitting the upper rung 50 to descend.
At this point, the projected pin 90F fitly engages into the hole 90E to press the retaining leaf spring 90H of the shifting wheel 90K and disengage the same from the retaining projection 90U. The shifting wheel 90K shall restore to its home position due to the springs 81D at two ends of the rung. At this point, the locking pins 81 are in a position with their outer ends closing to the tube members for readily springing into the tube members and lock the same and the rung together.
Fig. 7 illustrates another embodiment of the present invention, wherein a hollow fixing beam 95 is connected between the two one-way valves 70 oppositely disposed near the bottom of the first tubes 10 below the first rung 50.
An air tube 95A is disposed in the fixing beam 95 to communicate with the two one-way valves 70. In addition, a quick breather adapter 95B is provided at a center of the fixing beam 95 to communicate the air tube 95A with the atmosphere. As mentioned previously, the upper hook member 32A may extend into the locating hole 33C on the front cover 33A and airtightly seals the locating hole 33C, whereby a compressed air source can be connected to the quick breather adapter 95B for the air pressure in the ladder to automatically and quickly increase.
In conclusion, the extension ladder of the present invention can be sequentially extended for safe use. In addition, the extension of the ladder can be performed quickly while the collapse thereof can be achieved in a slower manner.
Moreover, the extension ladder of the present invention can be easily manufactured. Therefore, the shortcomings and possible dangers in using the conventional extension ladders as mentioned in the beginning of the specification can be effectively eliminated.
What to be noted is the above embodiments are only used for 2D illustrating the present invention, not intended to limit the scope thereof. Many modifications of the embodiments can be made without departing from the spirit of the present invention.
Therefore, it is necessary to provide an improved extension ladder to eliminate the above shortcomings.
SUMMARY OF THE INVENTION
It is a primary object of the present invention to provide an extension ladder having a safer and more effective structure. The extension ladder of the present invention includes two legs which each consists of a plurality of sequentially telescoped sections. These telescopic sections each is a straight round tube having uniform diameter which facilitates the assembly of the telescopic sections and the rungs.
Another object of the present invention is to provide an extension ladder in which a plug assembly is mounted to a bottom end of each telescopic section thereof. The plug assembly each consists of an upper and a lower movable hook members. When the extension ladder is in a fully extended state, the upper hook'members may separately extend their pointed end into retaining holes formed on the telescopic sections. The upper hook member each has a bevelled projection formed at an upper corner thereof on which a lowe.= hook member of the plug assembly in the next higher telescopic section hooks when the extension ladder is in a fully collapsed state. When the ladder is extended and the upper hook members separately extends into the retaining holes on the telescopic sections, the lower hook members of the upper plug assemblies disengage from the bevelled projection of the upper hook member, allowing the telescopic sections of the ladder to be pulled upward one by one from bottom to top.
It is a further object of the present invention to provide the above-mentioned extension ladder in which the plug assembly each is provided at a bottom portion of the upper hook member with an air cock, and at a base thereof with an air port corresponding to the air cock, and the lowest telescopic sections and the lowest rung are provided with one-way valves and cooperating air tube, respectively, whereby when the extension ladder is extended and the upper hook members pivot to extend through the retaining holes on the telescopic sections with their bottom portions lifted, the air ports are opened to together with the one-way valves and the cooperating air tube allow the air in the telescopic sections to quickly flow through the legs and thereby permits the ladder to be quickly extended. Or, when the ladder is collapsed and the upper hook members pivot to disengage from the retaining holes on the telescopic sections with their bottom portions and accordingly the air cocks descended, the air ports are closed to slow the air flow in the telescopic sections and the collapse speed thereof.
It is still a further object of the present invention to provide an extension ladder in which locking mechanisms are separataely mounted below the rungs centered on each end thereof and a lock ensuring mechanism is disposed behind each locking mechanism, whereby when the lock ensuring mechanisms are in a locked state, the corresponding locking mechanisms would not be unexpectedly and dangerously unlocked by pulling an pushing arm thereof. When the top surface of a lower rung touches the lock ensuring mechanisms of the next higher rung, the lock ensuring mechanisms of the next higher rung are unlocked to free their associated locking mechanisms, permitting the rung and the telescopic sections of the next higher stair of the ladder to collapse.
Therefore, the rungs and the telescopic sections of other higher stairs of the ladder can be sequentially and safely collapsed from bottom to top in the same manner as described above.
It is still a further object of the present invention to provide an extension ladder in Which a wear-proof ring member is fitted around a bottom outer periphery of each telescopic section to prevent the same from directly fractionally contacting with each other at their wall surfaces lest the telescopic sections should become wearing and loosely contacting with each other which is dangerous to any user.
BRIEF DESCRIPTION OF THE DRAWINGS
The detailed structure and functions of the present invention can be best understood through the following detailed description of the preferred embodiments and the accompanying drawings, wherein:
Fig. 1 is a fragmentary perspective view of a conventional extension ladder, a part of which is cut away to show the manner in which the rungs are connected to the legs of the ladder;
Fig. lA is a fragmentary, exploded perspective view of Fig.
1 showing the structure of the leg of the ladder;
Fig. 2 is a fragmentary, exploded perspective view of an extension ladder according to the present invention, a part of which is cut away to show the assembling of a rung to two vertically telescoped sections of the legs;
Fig. 2A is a fragmentary, sectional view taken on line A-A
of Fig. 2;
Fig. 3 is an exploded perspective view of a plug assembly disposed at a bottom end of each telescopic section of the present invention;
Fig. 3A is a fragmentary, assembled, sectional view showing the positions of an upper and a lower hook members of the plug assembly in a telescopic section of the present invention;
Fig. 4A is a fragmentary, sectional view showing the manner in which the telescopic sections of the legs of the present invention is sequentially extended from a collapsed state;
Fig. 4B is a fragmentary, sectional view showing the manner in which the telescopic sections of the legs of the present invention is gradually collapsed from an extended state;
Fig. 5A is a fragmentary, exploded perspective view of a locking mechanism and an associated lock ensuring mechanism disposed in a rung other than the first or the lowest rung of the present invention;
Fig. 5B is a fragmentray, exploded perspective view of a general switch assembly and the associated locking mechanism disposed in the first or the lowest rung of the present invention;
Figs. 6A to 6E are fragmentary, sectional views showing the operation of the mechanisms at different stairs of the ladder of the present invention to collapse the same; and Fig. 7 schematically shows another embodiment of the present invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Please refer to Fig. 2. The extension ladder of the present invention mainly includes a pair of legs lA, 1B each consisting of a plurality of telescopic section pairs, a plurality of rungs each having a peripheral wall which gives the rung a substantially reverse U-shaped cross section, a plurality of locking mechanisms 80 for locking the telescopic section pairs of the legs lA, 1B in place, and a plurality of lock ensuring mechanisms 82 cooperating with the locking mechanisms 80. The numbers of the rungs are equal to that of the telescopic section pairs. In the first embodiment of the present invention, reference numerals 50A
and 50 are designated to the first (the lowest) and the other higher rungs, respectively. The telescopic sections of the legs lA, 1B each is formed from a straight round tube member having uniform diameter through its length. A lower telescopic section or tube member always has an inner diameter larger than an outer diameter of a telescopic section or tube member immediately above it, such that every higher telescopic section can always be fitly received in a telescopic section immediately below it. In this embodiment, the telescopic sections of the legs lA, 1B are sequentially named the first tube member 10, the second tube member 20, the third tube member 30,..... from bottom to top.
_ g _ A sleeve member 60 and a plug assembly 30A are disposed on a top end and a bottom end of each telescopic section, respectively. Figs. 2 and 2A illustrate the manner in which the next lower or the second rung 50 (that is, the rung immediately above the first rung 50A) and the next lower telescopic section pairs (that is, the second tube members 20) are assembled and locked in place. Since every other stairs of the ladder of the present invention and either lateral side thereof are assembled in the same manner, they are not repeatedly explained herein. Of course, in the actual assembling, it must begin with the lowest (that is, the first) pair of telescopic sections and the lowest rung from either side thereof.
I5 Please refer to Figs. 2 and 2A. To form the second stair of the extension ladder, first insert the third tube members downward to pass through the sleeve members 60 fitted over the top end of the second tube members 20. The third tube members 30 each is premounted at its lower end with a plug assembly 30A. The manner in which the plug assembly 30A
is assembled and functions will be described in more details later in this specification. Then, the second rung is put over and engaged with a top end of the third tube members 30. Allow the third tube members 30 and the plug assemblies 30A at their bottom ends to e xtend into the second tube members 20. The sleeve member 60 each is formed at a top end with an outward extended upper flange on which an upper and a lower locating bosses 61A, 6 1B are provided to respectively engage with a first loca ting recess formed on the second rung 50 and a second loc ating recess formed near an upper edge of the second t ube member 20, causing a first locating hole 62 to aligne with a locating hole 54 formed at one end of the second rung 50. The second tube members 20 are firmly engaged into two ends of the second rung 50 with the sleeve members 60 between them without the risk of turning relative to the the second rung 50. An elongated slot 51 is formed at either end of the second rung 50 and a pair of threaded holes 52 are oppositely formed on the peripheral wall of the second rung 50 at two sides of each slot 51, whereby fastening screws 53 can be passed through the threaded holes 52 to narrow the slots 51 and thereby tightly bind the second rung 50 with the second tube members 20.
The locking mechanisms 80 are disposed near the ends of the second rung 50 on a central axis thereof and the lock ensuring mechanisms 82 are separately disposed just behind the locking mechanisms 80. For the first (lowest} stair of the ladder, a general switch assembly 90 can be additionally provided beneath the first rung 50A to cooperate with the lock ensuring mechanism to control the extension or collapse of the entire ladder.
Fig. 3 illustrates in details the manner in which the plug assembly 30A and the third tube member 30 are assembled.
The plug assembly 30A each consists of a front cover 33A, a rear cover 33B, a front insert 31A, and a rear insert 31B.
Both the front insert 31A and the rear insert 31B are formed at their lower outer wall with a lower flange. A first pin 32I is used to pass an inner side of the front insert 31A
while threading through a first return spring 32H and pivotally connecting an upward extended and movable upper hook member 32A to the front insert 3IA. The upper hook member 32A is provided on its one side surface at an upper corner thereof with a bevelled projection 32G. A roller 32F is disposed in a hollow space formed at a front portion of the upper hook member 32A with a somewhat flexible cover plate 32J fitted in front of the roller 32F, such that when the upper hook member 32A extends into a locating hole 33C formed on the front cover 33A, the locating hole 33C is airtightly sealed. An air cock 32E is provided at a bottom end of the upper hook member 32A. An air port 31D is formed on a base of the front insert 31A
corresponding to the air cock 32E, whereby the air port 31D
is opened or closed when the upper hook member 32A is pivotally turned about the first pin 32F to lift or lower the bottom end, respectively.
A ring ear 31E is connected to an underside of the front insert 31A. A downward extended and movable lower hook member 32B is pivotally connected to the ring ear 31E by means of a second pin 32D Which is threaded through a scond reuturn spring 32C and an upper portion of the lower hook member 32B and the ring ear 31E. The lower hook member 32B
is eccentrically positioned below the front insert 31A and is vertically aligned With the bevelled projection 32G of the upper hook member 32A. A projected block 31C is formed near a front portion of the front insert 31A such that when the front insert 3IA is placed into the third tube member 30 and fitted into a locating hole 30B thereof, the front cover 33A is engaged at its bottom flange 33H with the bottom end of the third tube member 30 with a locating projection 33E
thereof extending into the locating hole 30B of the third tube member 30 and vertically abutting against the projected block 3IC of the front insert 3IA just beneath it, permitting a front half of the plug assembly 30A to be firmly fixed to the third tube member 30.
Then, the rear insert 31B having an air outlet 31F is inserted into the third tube member 30, permitting an opening 33F on the rear insert 31B to communicate with an opening 30C on the third tube member 30. Then, the rear cover 33B is fitted around the third tube member 30 with a bottom flange 33G of the rear cover 33B engaging into a clearance between the bottom end of the third tube member 30 and the rear insert 31B. At this point, a locating projection 33D on an inner wall of the rear cover 33B
extends through the opening 33F of the rear insert 31B and engages into the opening 30C, permitting the rear half of the plug assembly 30A to be firmly fixed to the third tube member 30.
As shown in Fig. 4A, when the assembled ladder is to be extended from a collapsed state, the lower hook members 32B
of the plug assemblies 30A in the next higher tube members that are connecting with the upper hook members 32A of the plug assemblies 30A in the lowest tube members 10 by means of the bevelled projections 32G shall became disengaged from the upper hook members 32A after one-way 20 valves 70 disposed near bottom ends of the first tube members 10 are opened due to a pressure differential resulted from the extending operation. The open of the valves 70 permits air to be supplied to the first tube members 10. Due to the air flowing in the tube members forming the legs of the ladder, the telescopic sections of the legs can be quickly extended. When the upper hook members 32A of the plug assemblies 30A in the second tube members 20 are moved to a point in alignment with locating holes l0A formed on the first tube members 10, the upper hook members 32A are sprung toward the locating holes l0A
under the spring force of the first return springs 32H
and thereby open the air ports 31D. At this point, the air further flows upward. Meanwhile,~the lower hook members 32B
of the immediately higher telescopic sections 30 are released from the bevelled projections 32G of the upper hook members of the second tube members 20 because they move upward along with their upper hook members 32A. At this point, the next higher rung, that is, the second rung 50 can be pulled upward. After the upper hook members of the next higher tube members 30 are moved upward and engaged into the corresponding locating holes formed on the lower tube members 20, the next higher rung, that is, the third rung 50, can be further pulled upward. In the same manner, other higher telescopic sections and rungs can be sequentially extended.
Reversely, when the ladder is downward pushed to collapse it, the rollers 32F in front of the upper hook members 32A
in the second tube members 20 rotate when they are pressed against an inner wall of the tube members 20, allowing the upper hook members 32A to disengage from the locating holes l0A of the tube members 10. A compression effect similar to the function of a piston will be created on each of the plug assemblies at the bottom of the tube members, forcing the one-way valves 70 to close. Air in the tube members is compressed and can only escape from the relatively small air outlet 31F on the rear insert, permitting the ladder to be collapsed slowly. When the tube members 20 are collapsed to such an extent that the lower hook members 32B thereof engage with the bevelled projections 32G of the upper hook members 32A of the plug assemblies 30A in the first tube members 10 due to the spring force of the return springs 32H
and the bevel surfaces of the bevelled projections 32G, the higher tube members 20 are therefore connected to the Iower tube members 10. In the same manner, the other higher tube members are sequentially collapsed and connected to their respective immediate lower tube members, permitting the completely collapsed ladder to be carried by just holding its highest rung- without the risk of unexpectedly extending again. Moreover, with the locking mechanisms, the lock ensuring mechanisms, and the general switch assembly which will be described in more details later, the ladder can be automatically and sequentially collapsed stair by stair from bottom to top.
Fig. 5A shows the locking mechanism and the lock ensuring mechanism of the present invention, wherein the locking mechanism 80 each consists of a sleeve member 80A, a locking pin 81, a touch arm S1A, a push block 81B, a first pin member 81C, and a spring 81D. The sleeve member 80A is fitted into the locating hole 54 formed at each end of the second rung 50. One end of the locking pin 81 is inserted into the sleeve member 80A while the other end of the locking pin 81 is threaded through the spring 81D to extend into a substantially reverse U-shaped stopper 57 disposed in the second rung 50.~ Below the locking pin 81, the first pin member 81C is used to connect the touch arm 81A to the push block 81B and fixedly locate them in the rung 50, such that when the touch arm 81A is touched, the locking pin 81 can be moved backward so as to unlock the locking mechanism 80.
The lock ensuring mechanism 82 each is composed of a locking block 83, an unlocking touch arm 83D, a first stop screw 56, and a third return spring 83E. The lock ensuring block 83 is formed at each side with a straight slide channel 83B to receive a slide block 58 in the second rung 50, whereby the lock ensuring block 83 can be vertically slided relative to the second rung 50. The lock ensuring block 83 has an indicating block 83C projecting from a top thereof, whereby when the lock ensuring block 83 is moved upward to a top position of the second rung 50, the indicating block 83C
protrudes beyond a warning opening 59 formed on a top surface of the second rung 50 to indicate the actual operating state of the lock ensuring mechanism 82.
The lock ensuring block 83 has a pin hole 83A
provided at a .front end thereof to receive one end of the locking pin 81 extending through the reverse U-shaped stopper 57. The third return spring 83E and the unlocking touch arm 83D are disposed on a side of the locking block 83 near a rear end thereof. The unlocking touch arm 83D is formed at an outer side facing the peripheral wall of the second rung 50 with a recess. A notch 83F is provided on a peripheral wall surrounding the recess of the unlocking touch arm 83D, such that when the lock ensuring block 83 is glaced into the second rung 50 and the first stop screw 56 is screwed through the peripheral wall of the second rung 50, a lower side of the screw 56 abuts against the peripheral wall of the recess of the unlocking touch arm 83D
to limit the lock ensuring block 83 to travel only within a distance defined by the unlocking touch arm 83D.
Fig. 5B shows the general switch assembly 90 and the locking mechanism 80 mounted in the first (the lowest) rung 50A of the present invention. Since these components are somewhat different from those mounted in other rungs 50, they are separately described herein. The general switch assembly 90 includes a shifting wheel 90K having a shifting arm 90B, two lock ensuring push plates 90J separately disposed at two ends of the first rung 50A, two resilient engaging pieces 90C, and two pull rods 90A each being connected at one end to the shifting wheel 90K and at the other end to a locking pin 81 of the locking mechanism 80 by extending through a central pin hole 90I formed on each lock ensuring push plate 90J.
To assemble the general switch assembly 90 and the locking mechanisms 80 to the first rung 50A, the shifting wheel 90K
is fixed to a bottom central portion of the first rung 50A
by means of extending a second pin member 90M through the peripheral wall of the first rung 50A and through the shifting wheel 90K. The lock ensuring push plates 90J each is disposed in the first rung 50A With two lateral edges thereof separately received in slide channels 90N formed on the geripheral wall of the first rung 50A near each end thereof, allowing the lock ensuring push plates 90J to vertically move in the first rung 50A up and down. Second stop screws 900 are separately screwed into the peripheral wall of the first rung 50A to extend into dents 90P
separately formed on a side edge of the two ensuring push plates 90J, so as to limit the lock ensuring push plates 90J
to vertically move within a distance defined by the dents 90P. The lock ensuring push plates 90J each has a tog indicating block 83C which protrudes beyond the warning opening 59 formed on the first rung 50A. The Iock ensuring push plate 90J each is formed with a central pin hole 90I
and a projected block 90D. The central pin hole 90I each has a vertical length larger than a diameter of the locking pin 81, whereby the locking pin 81 can be moved into or out of the central pin hole 90I. The resilient engaging pieces 90C each is engaged with the projected block 90D while its two lower ends are received in slide channels 90Q formed in the first rung 50A.
With the above arrangements, the extension ladder of the present invention. can be automatically and sequentially collapsed in a manner as shown in Figs. 6A, 6B, 6C, 6D and 6E, wherein the plug assemblies 30A are only schematically illustrated.
Fig. 6A illustrates the extension ladder in an extended and locked state. At this point, the lock ensuring blocks 83 of the rungs 50 and the lock ensuring push plates 90J of the rung 50A serve to disengage the locking pins 81 from the gin holes 83A and the central pin holes 90I, respectively, allowing the rungs 50 and 50A to be in a firmly locked position relative to the higher tube members and the first tube members, respectively. Meanwhile, the resilient engaging pieces 90C separately engage with the projected blocks 90D of the lock ensuring push plates 90J.
Fig. 6B illustrataes the first step to collaps the extension ladder. First, the lock ensuring push plates 90J are pushed upward to disengage the resilient engaging pieces 90C from the projected blocks 90D of the lock ensuring push plates 90J. At this point, the indicating blocks 83C on the top of the lock ensuring push plates 90J moves upward to protrude beyond the warning openings 59, indicating the rungs and the telescopic tube members of legs are released from the safely locked position. The indicating blocks 83C can be painted in red color or with any other warning mark. Before using the extension ladder, first check for any indicating blocks 83C protruded beyond the rungs. Any protruded indicating block 83C means the ladder is not in a locked position for safe use. At this point, the locking pins 81 each abuts against a lower edge of the central pin holes 90I, leaving a gap between the locking pin 81 and an upper edge of the central pin hole 90I. The locking pins 81 at this position are allowed to extend into the central pin holes 90I to interact with the pull rods 90A and the shifting wheel 90K.
That is, as shown in Fig. 6C, when the shifting arm 90B of the shifting wheel 90K~is shifted to pull the pull rods 90A, causing the locking pins 81 to move toward the center of the rung 50A until the locking pins 81 abut against the resilient engaging pieces 90C. At this point, the resilient engaging pieces 90C are pushed by the locking-pins 81 to disengage from the projected blocks 90D of the lock ensuring push plates 90J. Meanwhile, the gaps between the locking pins 81 and the upper edge of the central pin holes 901 cause the lock ensuring push plates 94J to move downward which further causes the resilient engaging pieces 90C to separate from the projected blocks 90D. Therefore, when the locking pins 81 are further inserted into the lock ensuring push plates 90J and be locked thereto, the lock ensuring push plates 90J will not be stopped by the resilient engaging pieces 90C and are therefore, permitted to slide downward to a firmly and safely locked position. When the shifting wheel 90K is shifted to an upper position, a retaining leaf spring 90H on the shifting wheel 90K is stopped by a retaining projection 90U formed on a bottom center of the first rung SOA and the shifting wheel 90K is prevented from further rotating and is restricted to a fully unlocked position. This avoids undesired partial collapse of the extension ladder due to instantaneous extension by manual operation.
When the immediate higher rung 50 descends and the unlocking touch arms 83D touch the first (lowest) rung 50A, as shown in Fig. 6D, the lock ensuring blocks 83 are forced to move upward. At the same time, the indicating blocks 83C
protrude beyond the warning openings 59. When the lock ensuring blocks 83 move to an upmost position, the pin holes ' - I9 -83A are aligned with the locking pins 81, allowing the locking pins 8I to move into the pin holes 83A. Meanwhile, the notches 83F of the unlocking touch arms 83D are aligned with the first stop screws 56. At this point, a downward projected gin 90F disposed on a central position of the upper rung 50 approaches to and is aligned with a hole 90E
formed on the first {lowest) rung 50A.
As shown in Fig. 6E, before the upper rung 50 is collapsed to its lowest position, the unlocking touch arms 83D and the touch arms 81A connected to the locking pins 81 are forced to pivotally turn sideward away from the lock ensuring blocks 83 and the locking pins 81 are further moved into the pin holes 83A, leaving the telescopic tube.members in an unlocked state and permitting the upper rung 50 to descend.
At this point, the projected pin 90F fitly engages into the hole 90E to press the retaining leaf spring 90H of the shifting wheel 90K and disengage the same from the retaining projection 90U. The shifting wheel 90K shall restore to its home position due to the springs 81D at two ends of the rung. At this point, the locking pins 81 are in a position with their outer ends closing to the tube members for readily springing into the tube members and lock the same and the rung together.
Fig. 7 illustrates another embodiment of the present invention, wherein a hollow fixing beam 95 is connected between the two one-way valves 70 oppositely disposed near the bottom of the first tubes 10 below the first rung 50.
An air tube 95A is disposed in the fixing beam 95 to communicate with the two one-way valves 70. In addition, a quick breather adapter 95B is provided at a center of the fixing beam 95 to communicate the air tube 95A with the atmosphere. As mentioned previously, the upper hook member 32A may extend into the locating hole 33C on the front cover 33A and airtightly seals the locating hole 33C, whereby a compressed air source can be connected to the quick breather adapter 95B for the air pressure in the ladder to automatically and quickly increase.
In conclusion, the extension ladder of the present invention can be sequentially extended for safe use. In addition, the extension of the ladder can be performed quickly while the collapse thereof can be achieved in a slower manner.
Moreover, the extension ladder of the present invention can be easily manufactured. Therefore, the shortcomings and possible dangers in using the conventional extension ladders as mentioned in the beginning of the specification can be effectively eliminated.
What to be noted is the above embodiments are only used for 2D illustrating the present invention, not intended to limit the scope thereof. Many modifications of the embodiments can be made without departing from the spirit of the present invention.
Claims (20)
1. An extension ladder comprising a pair of legs each consisting of a plurality of telescopic tube members, a plurality of rungs having a substantially reverse U-shaped cross section and two ring-like ends for separately receiving said legs therein, a plurality of locking mechanisms disposed beneath said rungs near said two ends thereof, and a plurality of lock ensuring mechanisms separately disposed behind said locking mechanisms;
said locking mechanisms each comprising a locking pin capable of resiliently extending and engaging into a corresponding locating hole formed on each said tube member and a touch arm pivotally connected to said locking pin for moving said locking pin out of said corresponding locating hole by pulling said touch arm;
said locking ensuring mechanisms each comprising a lock ensuring block having the form of a block stop and an unlocking touch arm pivotally connected to said lock ensuring block; and said locking pin of said locking mechanism, after extending into said corresponding locating hole on said tube member, being stopped by said lock ensuring block without being easily moved out of said corresponding locating hole by pulling said touch arm unless said unlocking touch arm is pushed to displace said lock ensuring block.
said locking mechanisms each comprising a locking pin capable of resiliently extending and engaging into a corresponding locating hole formed on each said tube member and a touch arm pivotally connected to said locking pin for moving said locking pin out of said corresponding locating hole by pulling said touch arm;
said locking ensuring mechanisms each comprising a lock ensuring block having the form of a block stop and an unlocking touch arm pivotally connected to said lock ensuring block; and said locking pin of said locking mechanism, after extending into said corresponding locating hole on said tube member, being stopped by said lock ensuring block without being easily moved out of said corresponding locating hole by pulling said touch arm unless said unlocking touch arm is pushed to displace said lock ensuring block.
2. An extension ladder as claimed in claim 1, wherein a push block is fixedly disposed in each said touch arm of said locking mechanism with an arcuated surface thereof abutting against said locking pin, whereby when said touch arm is pivotally moved, said arcuated surface of said push block is pivotally turned to translate said locking pin toward or away from said corresponding locating hole on said tube member.
3. An extension ladder as claimed in claim 1, wherein each said lock ensuring block is formed at each lateral surface with a straight slide channel and wherein each said rung is formed on each side wall with a slide block corresponding to said slide channel on said lock ensuring block, such that the engagement of said slide block with said corresponding slide channel allowing said lock ensuring block to vertically move up and down below said rung.
4. An extension ladder as claimed in claim 3, wherein said unlocking touch arm has a recess formed on a surface thereof facing an inner surface of said side wall of said rung, forming a peripheral wall surrounding said recess; wherein a stop screw is threaded through said side wall of said rung facing said unlocking touch arm and presses against said peripheral wall of said recess, and thereby limits said lock ensuring block to vertically move in said rung only within a limited distance.
5. An extension ladder as claimed in claim 4, wherein said unlocking touch arm is formed with a dent on said peripheral wall surrounding said recess thereof and said peripheral wall has a curved lower portion, such that when said unlocking touch arm is subjected to an upward force from a lower end thereof, said lock ensuring block is moved to slide upward along said slide blocks inside said rung until it abuts against a top wall of said rung, and when said unlocking touch arm is further forced to move upward, said stop screw moves along said curved lower portion and into said dent on said peripheral wall permitting said unlocking touch arm to idle without damaging the entire lock ensuring mechanism.
6. An extension ladder as claimed in claim 5, wherein a return spring is connected to said unlocking touch arm at where said unlocking touch arm is pivotally connected to said lock ensuring block, such that whenever said unlocking touch arm is released from said upward force applied to it, said return spring immediately causes said unlocking touch arm to return to its home position, allowing said lock ensuring block to move down again.
7. An extension ladder as claimed in claim 3, wherein said lock ensuring block has a pin hole formed on one end facing said locking pin such that when said lock ensuring block is moved upward to a certain position, said pin hole becomes aligned with said locking pin, allowing said locking pin to move into said pin hole and at the same time to disengage from said corresponding locating hole formed on said tube member.
8. An extension ladder as claimed in claim 3, wherein each said lock ensuring block is provided with an indicating panel projected from a top portion thereof and each said rung is provided at its top surface with a warning hole corresponding to said indicating panel for the latter to project therefrom when said lock ensuring block is moved upward to contact said top portion of said rung, whereby a user is warned that said rung is in a collapsible state.
9. An extension ladder comprising a pair of legs each consisting of a plurality of telescopic tube members, a plurality of rungs having a substantially reverse U-shaped cross section and two ring-like ends for separately receiving said legs therein, a plurality of locking mechanisms disposed beneath said rungs near said two ends thereof, and a general switch assembly provided beneath one of said rungs forming the lowest or the first stair of said ladder;
said locking mechanisms each comprising a locking pin capable of resiliently extending and engaging into a corresponding locating hole formed on each said tube member and means capable of pulling said locking pin out of said corresponding locating hole at a moment when said means is pushed upward by one of said rungs immediately below said means, allowing said telescopic tube members of that stair to be collapsed; and said general switch assembly comprising a general switch and pull rods for pulling said locking pin of said locking mechanism out of said corresponding locating hole, whereby an operation of said general switch shall actuate said lowest rung and said tube members forming the second stair of said ladder to collapse, and, the collapse of said tube members of said second stair shall, with said locking mechanisms separately mounted beneath each said rung, automatically actuate said rungs and said telescopic tube members of higher stairs of said ladder to collapse stair by stair from bottom to top.
said locking mechanisms each comprising a locking pin capable of resiliently extending and engaging into a corresponding locating hole formed on each said tube member and means capable of pulling said locking pin out of said corresponding locating hole at a moment when said means is pushed upward by one of said rungs immediately below said means, allowing said telescopic tube members of that stair to be collapsed; and said general switch assembly comprising a general switch and pull rods for pulling said locking pin of said locking mechanism out of said corresponding locating hole, whereby an operation of said general switch shall actuate said lowest rung and said tube members forming the second stair of said ladder to collapse, and, the collapse of said tube members of said second stair shall, with said locking mechanisms separately mounted beneath each said rung, automatically actuate said rungs and said telescopic tube members of higher stairs of said ladder to collapse stair by stair from bottom to top.
10. An extension ladder as claimed in claim 9, wherein said means for pulling said locking pin out of said corresponding locating hole each is a touch arm pivotally connected at a position immediately below said locking pin, said touch arm having an upper end contacting with said locking pin and a lower end pointing downward, and, said touch arm being pivotally movable when an upward force is applied to said lower end.
11. An extension ladder as claimed in claim 10, wherein said touch arm has a curved bottom periphery extending from a substantially vertical upper portion of said touch arm to a substantially horizontal lower portion thereof, pointing toward said rung immediately below said touch arm and providing an increased distance within which said rung immediately below said touch arm keeping in contact with said touch arm.
12. An extension ladder as claimed in claim 10 or 11 wherein a push block is fixedly disposed in each said touch arm of said locking mechanism with an arcuated surface thereof abutting against said locking pin, whereby when said touch arm is pivotally moved, said arcuated surface of said push block is pivotally turned to translate said locking pin toward or away form said corresponding locating hole on said tube member.
13. An extension ladder as claimed in claim 9, wherein said locking pins beneath said rung of said lowest stair of said ladder is formed with a hole at one end and said means for pulling said locking pins out of said corresponding locating holes formed on said tube members of said lowest stair are said pull rods of said general switch assembly; said pull rods pulling said locking pins by separately extending their one end to hook in each said hole on said locking pins.
14. An extension ladder as claimed in claim 9, wherein said general switch of said general switch assembly is a shifting wheel pivotally rotatably mounted to a central position beneath said lowest rung, said shifting wheel being formed at two lateral side surfaces with two holes for receiving the other end of said pull rods opposite to those ends hooking in said locking pins and further having a shifting arm extending from an outer periphery thereof, such that when said shifting arm is pushed to move said shifting wheel, said locking pins are pulled by said pull rods to disengage from their corresponding locating holes on said tube members, allowing said ladder to be collapsed sequentially.
15. An extension ladder as claimed in claim 14, wherein said shifting wheel has a retaining leaf spring disposed opposite to said shifting arm, said retaining leaf spring being stopped by a retaining projection formed beneath said lowest rung when said shifting wheel is moved to its upmost position below said lowest rung by pushing said shifting arm, preventing said shifting wheel from further rotating while said shifting arm being prevented from any undesired quick release before said first stair of said extension ladder is completely collapsed.
16. An extension ladder as claimed in claim 15, wherein said lowest rung is formed at a top surface with a hole corresponding to said retaining leaf spring and a second rung immediately above said lowest rung is formed beneath a top surface with a downward projected pin corresponding to said hole of said lowest rung, whereby when said second rung is collapsed to touch said lowest rung, said projected pin extends through said hole to touch said retaining leaf spring and disengage the same from said retaining projection of said lowest rung, releasing said shifting wheel and permitting the same to return to an operative state.
17. An extension ladder as claimed in claim 9, wherein a lock ensuring push plate is disposed between each said locking pin and each said pull rod, said lock ensuring push plate each being formed with a central pin hole having a vertical length larger than a diameter of said locking pin for said locking pin to extend therethrough while allowing said lock ensuring push plate to vertically move below and within said lowest rung with two lateral ends of said push plate received in two slide channels formed on two inner side walls of said lowest rung at a position corresponding to said lock ensuring push plate, each said locking pin becoming aligned with said pin hole of said lock ensuring push plate when the later is pushed upward, allowing each said pull rod of said shifting wheel to pull said locking pin out of said corresponding locating hole on said telescopic tube members, and each said locking pin becoming out of alignment with said pin hole when said lock ensuring push plate is moved downward, causing said general switch assembly to be in a securely locked state.
18. An extension ladder as claimed in claim 17, wherein said lock ensuring push plate each has a top indicating block and said lowest rung in formed at said top surface with a warning opening corresponding to said indicating block for the latter to protrude therefrom when said lock ensuring push plate is pushed upward to abut against said top surface of said lowest rung, serving as a warning to a user that said ladder is in a collapsible state.
19. An extension ladder as claimed in claim 17 or 18, wherein said lock ensuring push plate each is formed at one of said lateral ends with a dent to just receive a stop screw threaded through said lowest rung to limit said lock ensuring push plate to vertically move only within a distance defined by said dent.
20. An extension ladder as claimed in claim 19, wherein said lock ensuring push plate each is provided below said pin hole with a transverse projected block and below said projected block with a resilient engaging piece, each said engaging piece having two lower ends which are separately slidably engaged with said inner side walls of said lowest rung, and a resilient bent portion which is engaged with said projected block to retain said lock ensuring push plate in place when the latter is pushed upward and thereby facilitates the operation of said general switch assembly, and each said engaging piece being pushed to disengage from said lock ensuring push plate by each said locking pin when said locking pin is pulled out of said corresponding locating hole and backward extends through said pin hole of said lock ensuring push plate, allowing said lock ensuring push plate to slide down and return to a lock ensuring state.
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CA 2157842 CA2157842C (en) | 1995-09-08 | 1995-09-08 | Extension ladder with telescopic legs |
Related Parent Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CA 2157842 Division CA2157842C (en) | 1995-09-08 | 1995-09-08 | Extension ladder with telescopic legs |
Publications (1)
Publication Number | Publication Date |
---|---|
CA2291986A1 true CA2291986A1 (en) | 1997-03-09 |
Family
ID=4156576
Family Applications (2)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CA002291986A Abandoned CA2291986A1 (en) | 1995-09-08 | 1995-09-08 | An extension ladder with telescopic legs |
CA 2157842 Expired - Fee Related CA2157842C (en) | 1995-09-08 | 1995-09-08 | Extension ladder with telescopic legs |
Family Applications After (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CA 2157842 Expired - Fee Related CA2157842C (en) | 1995-09-08 | 1995-09-08 | Extension ladder with telescopic legs |
Country Status (1)
Country | Link |
---|---|
CA (2) | CA2291986A1 (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2017034399A1 (en) * | 2015-08-24 | 2017-03-02 | Lampe Holding B.V. | Telescopic ladder assembly |
WO2018160064A1 (en) * | 2017-02-28 | 2018-09-07 | Lampe Holding B.V. | Telescopically extendable and collapsible ladder with air dampers |
Families Citing this family (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US8225906B2 (en) | 2008-08-22 | 2012-07-24 | Core Distribution, Inc. | Extendable/retractable ladder |
CN103291205B (en) * | 2013-05-03 | 2015-06-24 | 浙江迈尔工具有限公司 | Telescopic bamboo joint ladder locking mechanism |
US10233692B2 (en) | 2014-12-02 | 2019-03-19 | Core Distribution, Inc. | Foldable ladder |
US9416591B2 (en) * | 2014-12-02 | 2016-08-16 | Core Distribution, Inc. | Telescoping ladder with stabilizers |
US11174678B2 (en) | 2017-11-08 | 2021-11-16 | Core Distribution, Inc. | Locking assembly for a telescoping ladder |
US11795760B2 (en) | 2019-10-24 | 2023-10-24 | Core Distribution, Inc. | Ladder tripod assembly and system |
-
1995
- 1995-09-08 CA CA002291986A patent/CA2291986A1/en not_active Abandoned
- 1995-09-08 CA CA 2157842 patent/CA2157842C/en not_active Expired - Fee Related
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2017034399A1 (en) * | 2015-08-24 | 2017-03-02 | Lampe Holding B.V. | Telescopic ladder assembly |
NL2015340B1 (en) * | 2015-08-24 | 2017-03-16 | Lampe Holding Bv | Telescopic ladder assembly. |
CN108026755A (en) * | 2015-08-24 | 2018-05-11 | 兰普控股私人有限公司 | Extension ladder component |
CN108026755B (en) * | 2015-08-24 | 2020-06-30 | 兰普控股私人有限公司 | Extension ladder assembly |
WO2018160064A1 (en) * | 2017-02-28 | 2018-09-07 | Lampe Holding B.V. | Telescopically extendable and collapsible ladder with air dampers |
NL2018437B1 (en) * | 2017-02-28 | 2018-09-19 | Lampe Holding Bv | Telescopically extendable and collapsible ladder with air dampers |
Also Published As
Publication number | Publication date |
---|---|
CA2157842A1 (en) | 1997-03-09 |
CA2157842C (en) | 2000-06-13 |
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Legal Events
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FZDE | Dead |