FIELD OF THE INVENTION

The present invention relates to power tools, and is applicable to such tools that are hand-held, bench mounted, or free standing. The invention is particularly, but not exclusively, concerned with such tools that treat a work piece by, a cutting, grinding, or other material removal, process.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a front schematic view of a hand-held tool according to one embodiment of the invention;

FIG. 2 is a side schematic view of the tool of FIG. 1;

FIG. 3 is a side plan view of the tool of FIG. 1;

FIG. 4 is a bottom plan view of the tool of FIG. 1;

FIG. 5 is a bottom horizontal sectional view of the tool of FIG. 1;

FIG. 6 is a front vertical sectional view of the tool of FIG. 1;

FIG. 7 is a top horizontal partial sectional view of a front portion of the tool of FIG. 1;

FIG. 8 is a front vertical partial sectional view of a rear portion of the tool of FIG. 1;

FIG. 9 is a side vertical partial sectional view of a detent for connecting a head portion 3 and body portion 2 of the tool of FIG. 1; and

FIG. 10 is a front vertical partial sectional view of one end 10 of handle 9 secured to the head portion 3 of the tool of FIG. 1.

DETAILED DESCRIPTION

FIGS. 1 to 4 show an example hand-held tool incorporating one embodiment of the invention. That example tool is an angle-grinder, and it is to be understood that the invention can be applied to other types of tools, whether they be hand-held, bench mounted, or free standing.

The tool 1 shown by FIGS. 1 to 4 includes a body portion 2 and a head portion 3. An operative element in the form of a rotatable grinding disc 4 is carried by the head portion 3, and a protective guard or shroud 5 overlies and surrounds a substantial part of the disc 4. In that regard, a plate section 6 of the shroud 5 overlies the upper surface of the disc 4, and a skirt 7 of the shroud 5 extends around the periphery of the disc 4. An opening 8 is provided at the front of the shroud 5 to enable engagement between the disc 4 and a work piece (not shown). The disc 4 is arranged for rotation about an axis extending transverse to the longitudinal axis of the tool 1.

It is preferred that the shroud 5 is adjustable so as to enable the opening 8 to be placed at a convenient position relative to the longitudinal axis of the tool 1. By way of example, it may be convenient to place the opening 8 at one side of the tool 1 rather than at the front as shown by FIG. 1. For that purpose, the shroud 5 is capable of rotation about an axis substantially coincident with the rotational axis of the disc 4. In accordance with conventional practice, the shroud 5 may be releasably secured in a selected rotational position by means of a clamping plate (not shown) engaging against the under surface of the plate section 6. Fastening screws may be used to press the clamping plate against the plate section 6 and thereby hold the shroud 5 against rotation.

In the arrangement shown, a loop-type handle 9 extends transversely across the top of the head portion 3 and has each of its ends 10 attached to respective opposite sides of the head portion 3 as hereinafter described. Other types of handles could be used. By way of example, one or more laterally projecting stub handles of a conventional kind could be attached to the head portion 3. Selection of a particular type of handle may be influenced by the nature of the tool being used.

In the example tool shown, a press-button 11 is accessible at the top of the head portion 3. The button 11 is manually depressed to lock the disc 4 against rotation when the disc is being removed from or attached to the head portion 3. In accordance with standard practice, the button 11 is spring influenced to return to an inactive position when pressure is removed.

The example tool shown is electrically powered, and is connectable to a source of AC power through a flexible cord 12 extending from the rear of the body portion 2. A cord storage groove 13 may be provided at the rear underside of the body portion 2 so as to enable convenient wrapping of the cord 12 when the tool is not in use. That is, the cord 12 may be wound about the tool 1 by being looped over the shroud 5 and through the groove 13, and is thereby retained in a stored condition.

Power is connected to the drive motor 14 (FIG. 5) of the tool 1 by depressing a start button 15, which in the example shown is located at the top-front of the body portion 2. Other locations could be adopted. It is preferred however, that simple depression of the button 15 is not sufficient to operate the tool 1. In the arrangement shown, an automatic shut-down facility needs to be deactivated prior to depressing the start button 15. Such deactivation may be achieved by depressing a lever 16 (FIGS. 3 and 4) positioned at the underside of the body portion 2.

The lever 16 is arranged to automatically return to a non-depressed condition if the user of the tool releases grip on the body portion 2, or does not grip that body portion correctly. Under those circumstances, the shut-down facility is activated and power is disconnected from the drive motor 14.

If desired, an interlock switch 17 (FIG. 4) may be provided at the underside of the body portion 2 adjacent the lever 16. The switch 17 is selectively movable between a normal position and a lever lock position. When the switch 17 is in the normal position, the shut-down facility functions as described above. When the switch 17 is in the lever lock position, it locks-the lever 16 in a depressed condition and thereby retains the shut-down facility in a deactivated condition. It is preferred that the switch 17 automatically returns to the normal position if the lever 16 is depressed while the switch 17 is in the lever lock position.

Tool function indicators 18 and 19 may be located adjacent the start button 15 as best seen in FIGS. 1 and 2. The indicator 18 may provide a visible signal when the tool 1 is subjected to maximum load during operation. The indicator 19 may provide a visible and/or audible signal when the tool reaches an overload condition. Maximum and overload conditions may be determined by monitoring the current being drawn by the tool.

It is a feature of the tool 1 that it includes propelling means operative to direct a flow of air over the working zone of the tool. In that regard, the working zone includes the face of the work piece being treated, and also includes the operative element of the tool 1, which is the disc 4 in the example tool shown.

It is preferred, but not essential, that the propelling means includes a blower-type device 20 (FIGS. 5 and 6). In the example shown, the blower 20 includes an impeller 21 rotatably mounted within a hollow housing 22 having an air inlet 23 (FIG. 5) and an air outlet 24 (FIG. 6). It is preferred, as shown, that both the impeller 21 and the inlet 23 are arranged substantially co-axial with the drive motor 14. It is further preferred that the impeller 21 is connected to a spindle 25 of the motor 14 so as to be driven by the motor 14.

A chamber 26 is formed between the periphery of the impeller 21 and an inner surface 27 of the housing 22. The impeller 21 includes a plurality of vanes 28, and the number and configuration of those vanes is selected to assist achievement of the result hereafter described. Similarly, proper selection of the space between the periphery of the impeller 21 and the housing surface 27 may influence achievement of the desired result. In the example arrangement shown by FIG. 6, it is intended that the impeller 21 be driven to rotate in a clockwise direction.

In the arrangement shown, the housing outlet 24 communicates with exhaust means including a duct 29 extending downwardly towards the shroud 5. The shroud plate section 6 includes a plurality of openings 30 to allow air to pass from the duct 29 to the upper surface and periphery of the disc 4. Such openings 30 may be provided around substantially the full extent of the plate section 6. It is preferred that an angled louvre 31 extends over each opening 30. Each louvre 31 is arranged to urge the air to flow through the respective opening 30 in a direction that is generally the same as the direction of rotation of the disc 4. Such an arrangement promotes attachment between the disc 4 and the air flowing into the shroud 5 through the openings 30, and thereby maximizes the cooling influence of that air flow. By way of example only, the louvres 31 may be disposed at approximately 45 degrees relative to the body of the plate section 6.

The head portion 3 of the tool 1 may be movable relative to the body portion 2 so as to allow selection of any one of a number of dispositions for the disc 4. In the arrangement shown, the head portion 3 is mounted on the body portion 2 for relative rotation about an axis substantially coincident with the axis of the motor spindle 25. Other arrangements could be adopted.

As best seen in FIG. 7, which is a diagrammatic illustration, the rotatable connection between the head portion 3 and the body portion 2 may include a bearing collar 32 secured to the body of the head portion 3, and two half-ring bearings 33 secured to a wall 34 of the body portion 2. It may be convenient to secure each half-ring bearing 33 to the body portion by means of fastening screws 35, as shown by FIG. 5. The collar 32 may have a channel section 36 (FIG. 7) to provide a location for the half-ring bearings 33.

Any suitable means may be adopted to selectively lock the head portion 3 in any one of the available positions of rotation. Also, the number of such positions can be selected to suit requirements. In the example embodiment shown, the head portion 3 is capable of 360 degree rotation relative to the body portion 2, and can be locked in any one of twelve equally spaced positions of rotation.

The head locking means for the head portion 3 may include a spring influenced detent that is engagable in any one of a number of co-operative openings, or recesses, provided in an indexing member. In the example arrangement shown, an end surface 37 (FIGS. 8 and 9) of the body portion 2 forms the indexing member, but other arrangements could be adopted. A series of equally spaced recess 38 is formed in the surface 37, and it is preferred that twelve recesses 38 constitute that series.

A spring influenced detent 39 mounted on the head portion 3 is adapted to engage in a selected one of the recesses 38 and thereby hold the head portion 3 against rotation relative to the body portion 2. FIG. 9 illustrates, in a diagrammatic manner, one particular arrangement of the detent 39. In that arrangement, the detent 39 is slidably mounted on the head portion 3 so as to be movable into and out of any one of the recesses 38. A compression spring 40 urges the detent 39 towards the surface 37, and into a recess 38 when the detent 39 is correctly aligned with that recess. Release movement of the detent 39 is achieved by applying finger pressure against an arm 41 connected to and extending laterally from the detent 39. When that finger pressure is removed, the spring 40 urges the detent 39 back towards the surface 37 so that it can again lock in any one of the recesses 38.

It is preferred that a detent 39 is provided at each of two opposite sides of the tool 1, and such an arrangement is shown by FIG. 5. The arrangement of the detent 39 at each side may be as described above in relation to FIG. 9.

Means may be provided to enable the handle 9 to be moved relative to the head portion 3 so as to adopt any one of two or more relative positions. The position of the handle 9 shown by FIGS. 1 to 4, can be regarded as the normal position of the handle 9.

In the example arrangement shown, each end 10 of the handle 9 is pivotally connected to a respective one of the two sides of the head portion 3. That pivotal connection can be achieved in any suitable manner. A preferred form of pivotal connection is shown, in diagrammatic form, by FIG. 10. An internally threaded sleeve 42 having a flange 43 at one end, is secured to each side of the head portion 3 in a manner such as to be held against rotation. As shown by FIG. 10, the flange 43 bears against an outside surface of the head portion 3. Each end 10 of the handle 9 is secured to a respective one of the sleeves 42 by means of a fastening screw 44. It is preferred that a spacer sleeve 45, is located between the head 46 of the screw 44 and the flange 43 so as to ensure that the handle end 10 is left sufficiently free to be rotatable about the axis of the screw 44.

Handle locking means may be provided to enable the handle 9 to be releasably locked in any one of two or more positions of rotation relative to the head portion 3. In the FIG. 10 arrangement, the handle locking mean includes a lever 47 mounted between the handle end 10 and the pivot mounting flange 43 in a manner such as to be movable between lock and release positions. Lever 47 is mounted on the handle end 10 in such a way that it cannot rotate relative to that end 10 about the axis 48 of the pivotal connection. FIG. 10 shows the lever 47 in the release position, and FIG. 5 shows the lever 47 in the lock position. As shown by FIG. 5, it is preferred that handle locking means is provided at each end 10 of the handle 9.

Lever 47 is biased towards the lock position by suitable biasing means, which in the example shown includes a hollow resilient member 49 interposed between the lever 47 and an opposed surface 50 of the handle 9. The biasing member 49 collapses in the axial direction when the lever 47 is manually lifted into the release position as shown by FIG. 10. When manual pressure is released, internal stress within the member 49 causes that member to expand axially and thereby push the lever 47 back to the lock position as shown by FIG. 5. In the lock position, a laterally projecting lug 51 of the lever 47 locates in a recess or hole 52 provided in the flange 43 as shown by FIG. 5. Since the lever 47 cannot rotate relative to the handle end 10, and the sleeve 42 cannot rotate relative to the head portion 3, location of the lug 51 in the recess or hole 52 prevents rotation of the handle 9 about the pivot axis 48.

In circumstances where the handle 9 is to be capable of being locked in more than one position, the flange 43 will be provided with a number of recesses or holes 52, and that number will be equal to the number of handle positions. The spacing between those recesses or holes 52 can be determined according to the desired positions of the handle 9. By way of example, in one such position, the handle 9 may be located forwardly of the normal position as shown by FIGS. 1 to 4, so as to provide a surface engaging rest if the tool is to be supported on a surface in an upside down position. When the handle 9 is in that forward location, the handle 9 and the top surface of the body portion 2 can engage an underlying surface to support the tool 1 in a substantially horizontal inverted disposition.

It is preferred that the head portion detents 39 cannot be released, at least in a convenient manner, while the handle 9 is in the normal position as shown by FIGS. 1 to 4. Release of the detents 39 is made possible, or convenient to achieve, by moving the handle 9 out of the normal position, and preferably forward of that position.

The pivot mountings for the handle ends 10 are preferably constructed so as to be capable of accepting the fastening screw of a standard stub handle. That permits one or two stub handles to be substituted for the loop handle 9. If desired, one or more additional handle mounting points may be provided around the head portion 3 so as to extend the choice of the positions for stub handles, and possibly also provide two or more alternative positions for the loop handle.

When the tool 1 as described above is operated, rotation of the impeller 21 causes air to be induced to flow into the body portion 2 through openings 53 provided at or near the rear end of the tool 1. The inducted air flows from the openings 53 to the housing inlet 23 by way of a passage or passages 54. Air flow through the passage or passages 54 has a cooling influence on the motor 14. Air received within the housing 22 is driven to the outlet 24, possibly in a compressed state, and from there into the shroud 5 by way of the duct 29 and the shroud openings 30. The air flow into the shroud 5 provides a cooling influence at the working zone of the tool.

Rotation of the disc 4 in the shroud 5 also tends to induce air to flow into the shroud 5 by way of the openings 30.

Swarf and debris tends to be removed from the disc 4 by centrifugal action, but air flow through the shroud 5 can-assist that removal and also assist in removing swarf and debris from the working zone in general.

It is an aim of the tool design to maximise air flow to the working zone, and thereby maximise the cooling influence of the air flow. Factors contributing to that result include the design of the impeller 21 and the design of the housing 22.

It will be apparent from the foregoing description that a power tool incorporating the invention has several benefits. Cooling at the working zone is particularly beneficial in that it promotes a longer working life for the operative element of the tool. The automatic shut-down facility has a valuable safety benefit, and adjustment of the head position and the handle position enables the tool to be used with maximum comfort and efficiency in a wide variety of working situations.

It is to be understood that various alterations, modifications and/or additions may be introduced into the constructions and arrangements of the parts previously described without departing from the spirit or ambit of the invention as defined by the appended claims.