CHAMBER LID TOOL

Abstract

A manhole cover tool useful in unsealing and moving a manhole cover over a predetermined distance along a surface, including: i) A handle end; accommodating an operator; ii) A fulcrum end distant the handle end; suitable for engagement and stabilizing the tool on the surface; iii) A rod of a predetermined length for connecting the handle end t o the fulcrum end; iv) A manhole cover engagement rod of a predetermined length having a first end and a second end; the first end connected to the rod, and said second end being a manhole cover engagement tool.

Claims

1. A manhole cover tool comprising: i) A handle end; ii) a fulcrum end distant said handle end; iii) a connecting rod of a predetermined length for connecting said handle end to said fulcrum end; iv) a manhole cover engagement rod of a predetermined length having a first end and a second end; said first end connected to said connecting rod, and said second end being a manhole cover engagement tool; wherein said handle end, fulcrum end and said first end of said engagement rod form a triangle when connected by a line.

2. The tool of claim 1 wherein at a resting position, said handle end is at a distance from said surface proximate waist height of an operator.

3. The tool of claim 1 wherein said tool further comprises an engagement rod channel for accommodating said engagement rod.

4. The tool of claim 3 wherein said engagement rod channel is substantially arcuate or “D” shape.

5. The tool of claim 4 wherein said engagement rod channel is connected to said connecting rod.

6. The tool of claim 1 wherein said engagement rod is flexible.

7. The tool of claim 1 wherein said manhole cover engagement tool is a hook.

8. The tool of claim 1 comprising of a lightweight and strong material.

9. The tool of claim 8 wherein the material is selected from the group consisting of aluminum, light steel, fiberglass, polypropylene and combinations thereof.

10. The tool of claim 1 wherein said tool is adjustable in length.

11. The tool of claim 1 wherein said engagement rod comprises a plurality of connection points for said first end.

12. The tool of claim 1 wherein said engagement rod is adjustable in length.

13. The use of the tool of claim 1 for maneuvering a manhole cover.

14. A method of maneuvering a manhole cover along a surface while reducing risk of injury to an operator, said method comprising: i) Positioning the tool of claim 1 proximate a manhole cover; ii) Connecting the tool of claim 1 to a manhole cover; iii) Pushing the tool of claim 1 towards said surface; iv) Pulling said tool of claim 1 away from said manhole cover; v) Repeating steps iii) and iv) until the manhole cover is at a desired location.

15. The method of claim 14 wherein when the operator is pushing said tool, said operator arms are substantially vertical to the surface and said operator: i)bends at the waist; ii) bends at the knees; or iii) a combination thereof.

16. A system for reducing injury to an operator when maneuvering a manhole cover, said system comprising the tool of claim 1 and the method of claim 14.

17. The tool of claim 1 wherein said tool is substantially triangular in shape.

18. The method of claim 14 in use with the tool of claim 17.

19. A system for reducing injury to an operator when maneuvering a manhole cover, said system comprising the tool of claim 17 and the method of claim 18.

20. The tool of claim 2 wherein said tool is substantially triangular in shape.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0032] FIG. 1 is a side view of the manhole cover tool in the resting position

[0033] FIG. 2 is a perspective view of the manhole cover tool in the resting position

[0034] FIG. 3 is a side view of the manhole cover tool engaged with a manhole cover in the resting position

[0035] FIG. 4 is a side view of the manhole cover tool engaged with a manhole cover and cracking the seal of the cover

[0036] FIG. 5 is a side view of the manhole cover tool engaged with a manhole cover and dragging the cover along the surface

[0037] FIG. 6 is a side view of a manhole cover tool engaged with a manhole cover and the manhole cover dragged off the manhole

[0038] FIG. 7 is a side view of the manhole cover tool (at rest) engaged with a manhole cover showing the manhole cover engagement tool remaining engaged with said manhole cover until the operator disengages same

[0039] FIG. 8 is a perspective view of the manhole cover tool (at rest) of another preferred embodiment

[0040] FIG. 9 is a perspective view of the manhole cover tool of FIG. 8 with the connecting rod with handle in an extended position

[0041] FIG. 10 is a perspective view of the manhole cover tool of FIG. 9 with an extendable connector

[0042] FIG. 11 is a perspective view of the manhole cover tool of FIG. 10 with a fixed extended connector

DETAILED DESCRIPTION

[0043] Referring now to the Figures, there is provided a preferred embodiment of a manhole cover tool 10 and a manhole cover 20. The manhole cover tool 10 has a handle 30 and a fulcrum 40 connected to each other by a connecting rod 50. The tool 10 further includes a manhole engagement rod 60 connected to an engagement rod channel 70 of arcuate or “D” shape. The radius formed between the connecting rod 50 and the engagement rod channel 70, in one instance, is greater than the radius of the manhole cover 20. This provides a mechanical advantage when moving said manhole cover 20. When the tool 10 is at rest, the connecting rod 50 forms a 45 degree angle with the surface 80 or the ground. This angle may be any angle which maintains the handle 30 proximate waist level of the operator 90, when said tool is at rest. The handle 30, in this instance, extends along the engagement rod channel 70 and beyond the connecting rod 50 and is made up of a left handle portion 31 and a right handle portion 32, each handle portion being substantially normal to and equidistant from said rod channel 70. Although not shown, the handle portions 31 and 32 may further include grip material to assist the operator in gripping the tool.

[0044] The fulcrum 40 is essentially ski shaped and is an extension of the engagement rod channel 70, extending beyond the fulcrum end 40 of the connecting rod 50. The fulcrum has a left ski portion 41 and a right ski portion 42 extending equidistant from said rod channel 70 and connecting rod 50, allowing for the lateral stabilization of the tool 10 when being used by an operator 90. The centre of the fulcrum 40 is at the terminus of the connecting rod 50 fulcrum end. Optional brace 43 further rigidifies fulcrum 40 with connecting rod 50, and in particular, when the tool 10 is in use. The engagement rod 60 is a steel chain connected at one end to the rod channel 70 and the other end having a hook 61 for engagement with an aperture 21 of the manhole cover 20.

[0045] In use, the operator 90 moves the tool 10 proximate the manhole cover and engages the hook 61 to an aperture 21 of the manhole cover 20. The operator 90 positions the tool 10 in the direction of choice to move the manhole cover 20, and pushes the handle 30 towards the surface 80 causing the tool to rotate along the ski portions 41 and 42 of the fulcrum 40, which in turn cracks the seal of the manhole cover. At this point, when the operator pulls the tool 10 away from the manhole cover 20 by dragging the fulcrum 40 along the surface 80, the operator 90 only experiences the weight of the tool 10 and not the weight of the manhole cover 20, and sets the tool 10 to its resting position where it forms a 45 degree angle with the surface 80. The operator pushes down on the handle 30 keeping the arms 91 substantially vertical to the surface 90 and back substantially straight while bending at the waist causing the tool 10 to pivot on the fulcrum 40 and in turn causing the engagement rod 60 to pull the manhole cover 20 and be dragged along the surface 80. In another embodiment, when pushing down on the handle 30, the operator 90 may also maintain the back substantially normal to the surface 80 while bending at the knees. The operator 90 continues these steps until the desired location for the manhole cover 20 is reached.

[0046] When the operator 90 wants to return the manhole cover 20 to its original position or to the manhole 22, the same actions are repeated as above except the direction will be towards the manhole 22 and the tool 10 is placed on the surface 80 proximate the side of the manhole 22 distant the manhole cover 20 (i.e. the open manhole 20 is between the tool 10 and the manhole cover 20).

[0047] As best seen in FIGS. 2 and 7, in one embodiment, the hook 61 is constructed such that the hook end 62 is lighter that the hook handle end 63. This configuration allows the hook 61 to remain engaged with the manhole cover 20, when there is no tension between the hook 61 and the engagement rod 60, until the operator disengages the hook 61 from the cover 20 via the handle 63. In yet another embodiment, the engagement rod 60 is further connected to the hook 61 such that when there is tension between the hook 61 and engagement rod 60, the hook 61 is urged to remain engaged with the cover 20 when the operator 90 is moving the handle 30 downwards towards the surface 80. The configuration of the present hook 61 reduces the likelihood of injury to the operator 90 due to the hook 61 coming away from the cover 20 while in operation.

[0048] As best seen in FIG. 3, the fulcrum end 40, the handle 30 and the first end of the engagement rod 60, when connected to each other with a line, form a triangle. Also, in one embodiment, the distance rT is greater than the distance rM, preferably rT is at least twice rM

[0049] As best seen in FIG. 8, in this embodiment, the tool 10 is substantially triangular in shape (as opposed to the “D” shaped discussed above) with the handle engagement rod 71 connected directly to the connecting rod 50 at the handle end 30, and the handle engagement rod 71 connected to the connecting rod 50 via a connector 72 proximate the fulcrum end 40, such that the handle engagement rod 71, connecting rod 50 and connector 72 form a triangle. In this instance, the first end of the engagement rod 60 is connected at the joint formed by the handle engagement rod 71 and connector 72.

[0050] As best seen in FIG. 9, the handle 30 is extended via extender 73 in said handle engagement rod 71. In this instance, extender 73 fits in said handle engagement rod 71 allowing for the extension of the length of the handle engagement rod 71 facilitating users of various heights. Although not depicted, the extender 73 could fit in the engagement rod 60.

[0051] As best seen in FIG. 10, in this embodiment, the connector 72 is extended beyond the end of the handle engagement rod 71 allowing for accommodating longer engagement rods 60, in this instance a steel chain and for manhole covers of significant weight and size. The connector 72 may be fixed at the extended length or may be extendable via a telescopic manner for example such as that seen with the handle engagement rod 71. When extendable, a locking mechanism is preferred to lock the connector at the desired position when in use.

[0052] As best seen in FIG. 11, when the connector 72 length is fixed and is extended beyond the end of the handle engagement rod 71, the tool may further comprise and corner brace 74 to reinforce the strength of the connector 72 when extended beyond the end of the handle engagement rod 71.

[0053] The hook 61 is releasably attachable to said tool 10 via a magnetic area on at least one of said engagement rod 71, connecting rod 50, connector 72 or a combination thereof.

EXAMPLES

[0054] The following are examples of the forces applied to the joints of the operator when using the tool as described herein and the tools of the prior art.

Example 1

Comparison of Moments Between Prior Art Tools and Present Tool

[0055] Initial comparison of the present tool and prior art tools was performed using 3DSSPP (3D static strength prediction program). This program estimates joint loading based on body position and forces applied. 3DSSPP combines force data with the posture and predicts the percent of the population who have the strength to do the job. In biomechanics research, increased joint moments often indicate increased risk of injury due to increased strain on the musculoskeletal system. [0056] A comparison of the present tool with other available tools with respect to initial analysis with 3DSSPP and ergonomic and biomechanic factors is provided below. All moment data is given for the saggital plane (i.e. flexion/extension of the spine) as this is the plane where most movement occurs during the lid lift.

[0057] The tool currently used by most of hydro electronic services for removal of chamber lids is the pickaxe. Initial examination of the use of the pickaxe with a force meter indicates a requirement of 130-220 lbs of lifting force when using the pickaxe to lift a chamber lid. As shown in the graph below, this force results in a moment production in the spine of approximately 400N*m at L5/S1 and 360N*m at L4/L5. The moment produced at the shoulder is approximately 30N*m. Moments produced when using the pickaxe are much higher than moments produced using the present tool, which are approximately 20N* for both L5/S1 and L4/L5, and approximately 15N*m for the shoulder. In addition to decreased moments when using the present tool, the present tool allows the operator to push in a downwardly direction, recruiting the core muscles and allowing use of their body weight to apply the force, rather than using the back extensor muscles, as is done with the pickaxe.

[0058] Another prior art tool includes the tools found in U.S. Pat. No. 4,512,554 and U.S. patent publication 20120027559. Both of these prior art tools include a straight bar between the fulcrum and the handle as well as the handle orientation being horizontal. The straight bar of these prior art tools forces the operator to pull backwards using the shoulder and back extensor muscles, causing the pectoral muscles to contract and form a tight angle between the pectoral muscles and the arm muscles, along with the upper back muscles causing significant strain, wherein the muscle strain increases as the vertical handle gets closer to the operator. The present tool allows the operator to push down using the body core and body weight for assistance during operation. As shown in the graph below, the prior art tool of U.S. Pat. No. 4,512,554 and U.S. 20120027559 (T-lift) produces larger moments at L4/L5 (315N*m for T-lift; 20N*m for present tool) and L5/S1 (360N*m for T-lift, 20N*m for present tool). Large production of force by the back extensor muscles (as is the case for the T-lift and pickaxe) results in large compression and shear forces in the spine, which may increase the risk of musculoskeletal injury, such as a dislocated disc, or the like.

[0059] The tool of U.S. Pat. No. 4,978,103 (magnetic dolly) or similar systems requires the application of multiple chains and the complete lifting of the entire weight of the chamber lid above the surface, whereas the present tool slides the chamber lid out of place with the chamber lid maintaining contact with the surface throughout the procedure. In this instance, the full weight of the chamber lid never needs to be supported by the operator. The requirement to lift the full weight of the chamber lid when using the prior art dolly systems results in moment production of over 700N*m at L4/L5 and L5/S1 (see the graph below). In addition, the use of the dolly system requires much more space than the present tool, making it less feasible in urban areas where streets cannot be completely shut down for removal of chamber lids. Dolly systems are also larger and heavier than the present tool when in storage, making transportation on a packed utility van more difficult. Further the dolly systems are not as stable as the present tool in moving a heavy load such as a chamber lid. The wheels make the dolly system extremely unstable in comparison to the present tool. The instability of the dolly system, in particular, when the operator walks with the load, increases the chance of low back injury. The present tool movements however, are completed intermittently and as mentioned earlier the load is slid on the ground by the operator and the fulcrum ski aligns the operator with the load facilitating the optimal operation of the present tool.

Example 1

Comparison of Shoulder and Low Back Moments Among Different Chamber Tools

Example 2

Comparison of Prior Art and Present Tool

[0060] The present tool was compared to the prior art in use with two chamber lids of different mass. One chamber lid (CL) has a mass of 300-320 lbs. A second chamber lid (NL) has a mass of approximately 150 lbs.

[0061] The force required to remove each of the two lids with prior art tools and the present tool was recorded with a handheld force meter (Chatillon E-DFE, Ametek, Berwyn, Pa., USA).

[0062] 13 male utility workers were outfitted with an inertial motion capture system (IGS-180 Animazoo, Synertial, Brighton, UK).

[0063] 4 conditions were tested (3 trials each): [0064] CL with Pickaxe (PICK)=CL+PICK; [0065] CL with present tool (CLRT)=CL+CLRT; [0066] NL with J-hook (JH)=NL+JH; and [0067] NL with present tool (CLRT)=NL+CLRT.

[0068] Kinetic and kinematic data collected were combined in a modelling program (MatLab) which calculates 3D joint moments via inverse dynamics.

[0069] Spine L4/L5 and shoulders were selected for analysis. The resultant moment was calculated using the equation RM=√{square root over ((x{circumflex over (-)}v{circumflex over (-)} z{circumflex over (-)}))} where RM=resultant moment; x=x-axis co-ordinate; y=y-axis co-ordinate and z=z-axis co-ordinate, where peak force was applied during the procedure or lid removal. Mean values were compared using a one-way repeated measures ANOVA.

[0070] The above chart depicts the force required to remove a chamber lid (CL or NL) with various tools. The Force (N) is significantly lower (p<0.05) with the present tool (CLRT) versus PICK and JH.

[0071] The above L4/L5 Resultant Moment Charts 1 and 2 depict that the resultant moment is significantly lower with the present tool when compared to the prior art (PICK and JH).

[0072] The Shoulder Resultant Moment Charts 1 and 2 depict that the shoulder resultant moments were significantly (p<0.0001) lower with the present tool (CLRT) when compared to the prior art (PICK and JH).

[0073] The L4/L5 Kinematic chart 1 depicts there is significantly more flexion at Sagittal with PICK when compared to all other tools (p<0.05)* and significantly more lateral bend at Frontal with PICK compared to the present tool (CLRT) when removing CL (p=0.048)**.

[0074] As many changes can be made to the preferred embodiment of the invention without departing from the scope thereof; it is intended that all matter contained herein be considered illustrative of the invention and not in a limiting sense.