05/500409

08/05/1975

08/26/1974

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15/104.330

B08B9/04; B08B9/02; B08B9/02

15/14.3R,14.3SN,14.1R

2042407	Drain cleaner	May 1936	Kugelman
2355733	Pipe cleaning device	August 1944	Johnson et al.
2470225	Plumber's sewer snake apparatus	May 1949	Silverman
2661489	Pipe cleaning apparatus	December 1953	Rudolph et al.
3268937	Power driven plumber snake	August 1966	Bollinger

Roberts, Edward L.

Babcock, William C.

I claim

1. In combination with an electric motor driven drill having a chuck and pistol type grip, a pipe clean out accessory that includes:

2. A pipe clean out accessory as defined in claim 1 in which said hollow container is defined by a first outer shell and a second inner shell radially spaced from said first shell, said first and second shells having rearward edges, that are in abutting contact, and rigidly secured to one another, said first shell developing into a restricted neck on the forward portion thereof to which said first elongate tube is secured, and said second shell having a closed forward end, with said first and second shells cooperating to define a confined space in which a portion of said cable is at all times disposed in a coiled configuration and said cable due to the resilience thereof being in frictional pressure contact with the interior of said first shell and rotating concurrently as said container is rotated.

3. A pipe clean out accessory as defined in claim 2 in which said first means includes a bracket secured in a centered position to an exterior surface of said second shell, and an elongate member rigidly supported by said bracket in alignment with the axis of rotation of said second shell and said member capable of being removably gripped by said chuck to rotate said container when said motor driven drill is electrically energized.

4. A pipe clean out accessory as defined in claim 1 in which said longitudinal guide means is a longitudinal slot formed in said second tube and said second means is a rigid member that extends inwardly from said first end of said first tube to slidably engage said slot.

5. A pipe clean out accessory as defined in claim 1 which in addition includes a transverse rigid member secured to said second end of said third tube and to which said pair of laterally spaced plates are secured with said transverse member capable of being gripped by one hand of a user when one hand of the user is in engagement with said pistol grip of said motor driven drill and said member when so engaged permitting said control assembly and third tube to be reciprocated longitudinally relative to said first and second tubes and said container to advance and retract cable from or into said container.

6. A pipe clean out accessory as defined in claim 1 which in addition includes:

BACKGROUND OF THE INVENTION

1. Field of the Invention

Pipe cleanout accessory for use with an electric motor driven drill.

2. Description of the Prior Art

In the past, various types of sewer cleaning machines have been designed and used that are intended solely for this purpose, and in the main are employed by commercial establishments such as plumbers, sewer cleaning companies and the like. These prior art machines are of heavy duty construction and are so expensive that they are out of reach of the average homeowner who may have need for such a piece of equipment but once or twice a year.

Furthermore, the prior art devices are of bulky construction and require a substantial space when stored.

The primary purpose in devising the present invention is to supply a small, lightweight, inexpensive sewer or drain line clean out accessory that may be removably mounted on the chuck of an electric motor driven drill, and the device when so mounted capable of being used for sewer or drain line cleanout purposes. After the clean out operation is completed, the accessory is removed from the drill, with the drill then capable of being used for its intended purpose.

The present invention, after being removed from the electric drill may be stored in a relatively small space until it is again needed for cleanout purposes, whereupon it is again removably mounted on the drill.

SUMMARY OF THE INVENTION

The pipe clean out accessory includes a hollow container in which an external thread defining cable that is stiff but somewhat resilient is maintained in a coiled configuration. The device is used with an electric drill of the type that includes a pistol grip, and a power driven rotatable chuck. The chuck engages a driving member that is rigidly secured to the container.

The container has a first elongate rigid tube projecting forwardly therefrom, which tube terminates in a circumferentially extending stop of the free end thereof. A second tube is mounted on the first tube between the stop and container, with the second tube having a longitudinal guide formed therein. A third tube is slidably mounted on the second tube, and with the third tube having a rigid member projecting inwardly therefrom that is at all times in slidable engagement with the longitudinal guide.

A control assembly is rigidly secured to the forward end of the third tube and has the cable extending therethrough. When the device is being used, one hand engages the pistol grip of the electric drill, with the other hand being in engagement with the control assembly.

First and second members are pivotally supported from the control assembly, with these members being spring loaded, and at all times tending to move to a position where they are in engagement with the external threads on the cable. The first and second members have handles associated therewith, and the handles capable of being used to selectively move the first or second members to first positions where they are not in engagement with the cable, and the members being held in the first positions by stop means that are operatively associated with the control assembly.

When it is desired to advance the cable forwardly from the control assembly, the electric drill is caused to rotate the chuck in a first direction to concurrently rotate the container and first tube as a unit relative to the second and third tubes and the control assembly. The first member as such rotation takes place is allowed to pivot to a second position where it is in contact with the threads on the cable. Upon it being desired to retract the cable into the container, the chuck is caused to rotate the container and first tube as a unit relative to the second and third tubes and control assembly in a second direction, and as such rotation takes place in a second direction, the second member is allowed to pivot to a second position where it is in engagement with the external threads on the cable.

The third tube and control assembly may be reciprocated as a unit relative to the first and second tubes, container and drill. When such reciprocation takes place with the first member in a spring loaded second position, the second member advances the cable from the container on the forward motion of each reciprocal stroke. The cable may be retracted into a container by allowing the second member to pivot to a second position where it is in spring loaded contact with the external threads on the cable, and reciprocating the third tube and control assembly as a unit relative to the first and second tubes, container, and the electric motor driven drill. When such reciprocation takes place with the second member in the second position and in contact with the threads on the cable, the cable is retracted into the container on each rearward stroke of the control assembly and third tube rearwardly towards the electric drill.

The reciprocal movement of the control assembly and third tube relative to the first and second tubes and container is carried out when it is desired to advance or retract the cable from the invention at a more rapid rate than is achievable by causing the drill to rotate the container in either a first or second direction.

The cable may be advanced or retracted by reciprocating the control assembly and third tube, either when the container is rotating in a first or second direction or when the container is stationary. The cable as it is forced from the invention either by rotation of the container, or reciprocal movement of the control assembly and third tube, is directed into the pipe from which foreign material is to be cleared by contact with the stiff cable.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of the pipe cleaning assembly operatively associated with the chuck of an electric drill having a pistol type grip;

FIG. 2 is an end elevational view of the device taken rearwardly of the pistol grip of the electric drill;

FIG. 3 is a second end elevational view of the invention;

FIG. 4 is a fragmentary side elevational view of the portion of the control assembly illustrating one of the spring loaded handles thereon;

FIG. 5 is a longitudinal cross sectional view of the invention mounted on the chuck of an electric drill having a pistol grip;

FIG. 6 is a second longitudinal cross sectional view of the invention as illustrated in FIG. 5, but with the control assembly and third tube in an advanced position relative to the container and first and second tubes;

FIG. 7 is a transverse cross sectional view of the invention taken on the line 7--7 of FIG. 6;

FIG. 8 is an enlarged side elevational view of the control assembly with the first member occupying a second position whereby the cable will be advanced relative to the container either by forward movement of the control assembly relative to the container, or the cable being driven by the drill in a first direction;

FIG. 9 is a second side elevational view of the control assembly, with the first member held in a first position by a stop, and the second member occupying a second position in which it is in spring loaded contact with the threads on the cable, and the second member when so disposed causing the cable to retract into the container either by rotation of the container or by reciprocating the control assembly and third tube, relative to the container and first and second tubes;

FIG. 10 is a transverse cross sectional view of the invention taken on the line 10--10 of FIG. 6.

DESCRIPTION OF THE PREFERRED EMBODIMENT

The clean out accessory A as shown in FIGS. 1, 5 and 6 includes a container B that serves to house a length of cable C in a coiled configuration, which cable has threads formed on the external surface thereof. An electric drill D is provided that includes a pistol grip E and chuck F that is in engagement with a driving member G that is secured to the container B.

The container B has a first elongate rigid tube H secured to a forwardly disposed neck portion thereof, and the tube on the forward end developing into a stop 10. The first tube H is in rotatable engagement with the interior of the second tube J, which second tube occupies a fixed longitudinal position relative to the first tube, and is situated between the stop 10 and container B. The second tube J has a longitudinal guide 12 defined on the external surface thereof. A third tube K is slidably mounted on the second tube J. The third tube K includes a rigid member 14 that extends inwardly therefrom to at all times slidably engage the guide 12. A control assembly L is mounted on the forward end of the third tube K as may be seen in FIGS. 1, 5 and 6.

The container B as may be best seen in FIGS. 5 and 6 is defined by an external shell 16 that preferably has a cylindrical rearwardly disposed portion 16a that develops on the forward end into an inwardly tapering portion 16b. The portion 16 b develops into a forwardly extending restricted neck 16c, which neck has the rearward portion of a first tube H rigidly secured thereto by conventional means. The container B also includes a second shell 18 of substantially smaller diameter than the first shell 16, which second shell includes a cylindrical portion 18a and forwardly disposed portion 18b of conical shape, as best seen in FIG. 5.

The cylindrical portion 18a on the rearward periphery thereof develops into a circumferential outwardly extending extension 18 c that merges on the rearward portion thereof into a flat circular flange 18d that abuts against the interior surface of the cylindrical portion 16a. The second shell 18 is held in a fixed position within first shell 16 by a number of fasteners 20 of conventional design. The rearward edges of the shell portion 16a and 18a are preferably doubled over to define beads 16d and 18e for reinforcing shells 16 and 18. The shells 16 and 18 cooperate to define a confined space 22 therebetween as shown in FIG. 5, in which the cable C is stored when the major portion thereof is retracted into the container B. The cable C due to the resilience thereof is at all times in frictional pressure contact with the interior surface of the first shell B, and as a result tends to rotate therewith when the shell is rotated by the drill D.

The second shell 18 as can best be seen in FIG. 5 supports the driving member G in a central axially aligned position therefrom due to a bracket 24 that engages a forward end of the driving member G. The bracket 24 is secured to the center interior end portion of the second shell 18 as shown in FIG. 5 by conventional means such as welding or the like (not shown).

The rearward end of the cable C is secured to the interior of the first shell 16 by a rivet or pin 26 that extends through the shell and is shown in FIG. 5. The pin 26 prevents the entire length of the cable C being displaced from the confined space 22, as it is moved forwardly therefrom by means that will be explained later in detail. The member 14 shown in FIG. 6 is preferably supported from the third tube K by a band 28 that extends around the rearward portion of the third tube and is secured thereto.

The control assembly L as best seen in FIGS. 3, 8 and 9 includes a transverse rigid member 30, preferably of circular shape, that has a bore 32 therein into which the forward end portions of the third tube K project, and the third tube being secured to the member by conventional means (not shown). The member 30 supports two parallel, laterally spaced, forwardly extending first and second plates 34 and 36, which plates are best seen in FIG. 3. The first and second plates 34 and 36 as shown in FIG. 3 have an inverted U-shaped rigid cable support 38 situated therebetween on which the cable C slidably rests as it is moved into and out of the container B. The cable support 38 is secured to plates 34 and 36 by screws 39. A sheet of resilient material 40 is mounted on the forward surface of the member 30 and has an opening 42 therein through which the cable C may move. The sheet 40 serves as a wiper to remove foreign material from the cable C prior to it being retracted into the confined space 22 of the container B.

First and second cable engaging members 42 and 44 are rigidly secured to first and second transverse shafts 46 and 48 that extend between the first and second plates 34 and 36 and are pivotally supported therefrom. The first shaft 46 on one end develops into a handle 46a that is normally disposed to the shaft and adjacently disposed to the first plate 34 as shown in FIG. 3. The second shaft 48 also has an outwardly extending end portion that defines a second handle 48a that is adjacently disposed to the second plate 36 as shown in FIG. 3.

Each of the shafts 46 and 48 has a tensioned coiled spring 50 operatively associated therewith, with one end of the spring being affixed to the shaft and the other end 50a occupying a fixed position relative to the plate 34 or 36 most adjacent thereto as shown in FIG. 4. The spring 50 associated with the first shaft 46 at all times tends to pivot the member 42 into a second position shown in FIG. 8, where a lower sharp edge 42a of the member is in pressure contact with the threads 52 formed on the external surface of the cable C. The cable C is preferably formed from resilient stiff wire that is helically wound in a tight configuration to define the threads 52 on the external surface of the cable.

The spring 50 operatively associated with the shaft 46 at all times tends to pivot the first member 42 from the first position shown in FIG. 9 to the second position shown in FIG. 8, where the edge 42a of the member is in pressure contact with the thread 52.

When the first member 42 is in the second position, it will be noted that the forward edge 42b of the member is angularly disposed relative to the longitudinal axis 52a of the cable C. The first member 42 is not able to pivot counter-clockwise beyond the second position shown in FIG. 8 due to pressure contacting the cable which rests on the support 38. The first and second plates 34 and 36 have transversely aligned, longitudinally spaced first and second openings 54 and 56 formed therein, which openings may be alternately occupied by a rod 58. When the rod 58 is removed from the aligned openings 54, the spring 50 automatically pivots the first member 42 to the second position shown in FIG. 8. However, when it is desired to have the first member 42 occupy the first position shown in FIG. 9, the first handle 46a is pivoted in an appropriate direction to dispose the first member as shown in FIG. 9. The first member 42 has a pin 60 extending outwardly therefrom on which a head 52 is supported. When the rod 58 is extended through the first openings 54 as shown in FIG. 9, the rod is contacted by the head 62 and the member 42 is held in the first position.

When the rod 58 is removed from the second openings 56, the spring 50 operatively associated with the second shaft 48 automatically pivots the second member 44 clockwise from the first position shown in FIG. 8 to the second position shown in FIG. 9. The second member 44 when in the second position has a a sharp edge thereof in pressure contact with the threads 52 on the cable C. It will be noted in FIG. 9 that the position of the shaft 48 and the length of the second member 44 are so related that the longitudinal edge 44b of the second member 44 is angularly positioned relative to the longitudinal axis 52a of cable C. The second member 44 has a second pin 64 extending outwardly therefrom that has a second head 66 on the outer extremity thereof, and the head being urged into pressure contact with the rod 58 by spring 50 when the member 44 is in the first position shown in FIG. 8 and the rod is disposed in the opening 56. The springs 50 are of sufficient strength as to maintain the first and second member 42 and 44 in substantial pressure contact with the threads 52 when the members are in the second position.

The use and operation of the invention is extremely simple. When it is desired to advance the cable C from the container B, the rod 58 is removed from the openings 54 and placed in the openings 56 to hold the second member 44 in the first position shown in FIG. 4. The drill D is now energized to rotate the container B and first tube H relative to the second aand third tubes J and K and the control assembly L. The edge 42a of the first member 42 is engagement with the threads 52 of cable C and the cable is advanced forwardly from the control assembly L into the pipe (not shown) to be cleaned.

If it is desired to advance the cable C more rapidly from the container B than is possible by rotation of the cable, the control assembly L and third tube K are reciprocated as a unit relative to the first and second tubes H and J and container B, with the edge 42a of the first member sliding over the threads 52 on the rearward portion of the reciprocatory stroke, but engaging the threads on the forward portion of the stroke to advance the cable forwardly from the control member L. When it is desired to retract the cable C into the container B, the rod 58 is removed from the second openings 56, with the first member 42 then being pivoted to the first position shown in FIG. 8 and held in this first position by the rod 58 being inserted in the opening 54. As this manipulating of the rod 58 takes place, the second member 44 immediately pivots to the second position shown in FIG. 9 due to the action of the springs 50 associated with shaft 48.

When the cable C is caused to rotate in a second direction by use of the drill D, the edge 44a of the second member is in pressure contact with the threads 52 of the cable C, and the cable is moved rearwardly through the control assembly L into the container B to assume a coiled configuration in the latter. Should it be desired to retract the cable into the container B at a more rapid rate than is possible by rotation of the cable C, the control assembly L and third tube K are reciprocated as a unit relative to the first and second tubes H and J and container B. On each rearward stroke of reciprocatory motion, the edge 44a engages the threads 52 to retract the cable into the coiled configuration in container B as shown in FIG. 5, and on the forward portion of the reciprocatory stroke the edge 44a of second member 44 merely slides over the thread 52 without engaging the same.

After the invention has been used to clean the pipe or tubular member (not shown) the invention A is disengaged from the chuck B, and the drill D and the invention may then be stored in a relatively compact space until again needed. The forward end of the cable C is preferably formed into a head C-1 of spiral configuration to dig into foreign material (not shown) in a pipe (not shown) that is to be cleaned.

The use and operation of the invention has been explained previously in detail and need not be repeated.