The present invention relates to a shredding machine, and more particularly relates to a shredding machine for shredding sheet material. Most preferably, the present invention relates to a shredding machine in the form of a paper-shredder suitable for home or office use.
Over recent years it has become customary to provide shredding machines in domestic homes or workplaces such as offices, in order to provide a convenient method of securely disposing of confidential documentation or other sensitive papers.
Conventional paper-shredders of the type mentioned above are provided with a paper feed-aperture, usually in the form of a feed-slot of elongate form, through which a plurality of paper sheets or the like can be fed towards a pair of rotating cutters which are located below the feed-slot and which serve to shred the paper sheets into a plurality of strips having a width of only a few millimetres. The resulting strips of paper fall downwardly and are collected in a basket or bin located below the cutters.
As will be appreciated, when using shredding machines of the general type mentioned above, it is necessary for a user periodically to empty the collecting bin as it becomes filled with paper shreds. If the paper bin is not regularly emptied in this manner, the volume of papers shreds in the bin becomes excessive, thereby preventing substantially unrestricted downward movement of the paper shreds during subsequent shredding operations. This can lead to paper jams.
It has therefore been proposed previously to provide shredding machines of this generally type where if an arrangement which operates to stop the electric motor powering the rotary cutters in the event that the collecting bin reaches a predetermined fill-level. One such prior proposed arrangement involves the use of optical sensors located just below the cutting mechanism, and at the top of the collecting bin. When the mass of paper shreds collected within the bin reaches the height effective to trigger the optical sensor, the cutting mechanism is stopped. At this point in time, the shredding machine cannot be used further until the collecting bin is either emptied, or a user opens the bin and presses the mass of paper shreds, which will be relatively loosely packed, down into the bin more firmly in order to deliberate more space above the shreds, whereupon the bin can be re-closed and shredding operations can continue.
As will be appreciated, the above-mentioned sensor arrangement does suffer from some disadvantages, for example, because the paper shreds collect in a relatively loose manner in the bin, they pile up relatively quickly within the bin, thereby triggering the optical sensor which necessitates frequent, and inconvenient, manual intervention on the part of the user by opening the bin and pressing the mass of shreds downwardly in order to deliberate more space.
It is therefore an object of the present invention to provide an improved shredding machine for shredding sheet material.
Accordingly, the present invention provides a shredding machine for shredding sheet material, the machine comprising an electric cutting mechanism operable to shred sheet material fed in to the machine, and a collection bin arranged for movement between a first position in which it permits operation of the cutting mechanism and collects shreds from the cutting mechanism, and a second position effective to stop operation of the cutting mechanism, wherein the bin is configured to move from the first position to the second position in response to a force acting on the shreds collected in the bin exceeding a predetermined threshold value.
Preferably, the weight of the shreds collected in the bin forms at least a component of said force.
Advantageously, pressure generated by shreds exiting the cutting mechanism and pushing against shreds collected in the bin forms at least a component of said force.
Conveniently, said force acts generally downwardly.
Advantageously, movement of the collection bin from the first position to the second position is effective to stop the cutting mechanism only after the passage of a predetermined period of time.
Preferably, the shredding machine comprises a catch effective to releasably engage the bin and retain it in its first position until said threshold value is exceeded, whereupon the catch releases the bin allowing the bin to move to its second position.
Advantageously, the catch is a magnetic catch.
Conveniently, the catch is a mechanical catch.
Preferably, the catch is configured to operate via friction.
Advantageously, the bin is located substantially below the cutting mechanism.
Conveniently, the bin is arranged for pivotal movement relative to the cutting mechanism.
Preferably, the first position of the bin is a substantially closed position in which access to the inside of the bin is prevented, and the second position is an at least partially-open position allowing access to the inside of the bin.
Advantageously, the bin is removable from the machine when in its second position.
Conveniently, removal of the bin from the machine is effective to disable the cutting mechanism, thereby preventing operation of the cutting mechanism in the absence of the bin.
Preferably, the shredding machine comprises a sensor configured to detect movement of the bin from its first position to its second position and to stop operation of the cutting mechanism in response to said movement.
Advantageously, the shredding machine comprises a sensor configured to detect removal of the bin from the machine and to disable the cutting mechanism in response to said removal.
Conveniently, the or each sensor is a micro-switch.
Preferably, the shredding machine takes the form of a paper-shredder suitable for home or office use.
So that the invention may be more readily understood, and so that further features thereof may be appreciated, an embodiment of the invention will now be described, by way of example, with reference to the accompanying drawings, in which:
Referring initially to
The upper, generally horizontally extending region of the frame 3 supports a housing 7 within which is provided an electric cutting mechanism 8 (seen more clearly in
Considering the base 2 in more detail, it should be appreciated that the base 2 has a generally ramped portion 9 which extends upwardly, towards the rear of the base 2. The result is that the front part of the base 2 is lower than the highest point of the rear part of the base 2. The raised rear part of the base 2 defines horizontal pivot axis 10 extending across the rear part of the shredder. In a preferred embodiment, the pivot axis 10 is defined by a horizontal bar extending between the two raised rear side portions of the base 2. The function of the pivot axis 10 will become clear in the following description.
As illustrated in
As illustrated more clearly in
By virtue of the open nature of the channel 12, it should be appreciated that the bin 11 is also removable from the base 2 and so, when in it is in its second position illustrated in
Turning now to consider
A catch 17 is provided which, in the embodiment illustrated in the drawings, is provided at a generally central location across the top of the front wall 14 of the bin 11. The catch 17 is configured to provide a releasable connection between the bin 11 and the housing 7, via co-operation with a corresponding catch component 18 provided at the front of the housing 7.
The preferred embodiment of the present invention uses a magnetic catch 17 which is configured to retain the bin 11 in its first position illustrated in
Referring again to
At the rear part of the slot 24, there is provided a first sensor 25 which, in the preferred embodiment illustrated, takes the form of a micro-switch, the operative part of which extends at least partially across the slot 24 so as to be actuated by the rear part of the blade element 21. In the position of the blade element 21 illustrated in
When the bin 11 is moved from its first position illustrated in
In the preferred embodiment, the micro-switch forms part of a clock circuit and, when opened, is effective to trigger the clock circuit which, in turn, is arranged to break the electrical circuit providing power to the cutting motor only after a predetermined time period; typically a few seconds. Thus, when the bin is moved to its second, open position, the cutting mechanism is allowed to continue running for a few seconds, which helps to ensure that the cutters are clear of paper by the time the mechanism stops.
As also illustrated in
The second sensor 26 is also electrically connected to the electric cutting mechanism of the shredder and serves to cut power to the cutting mechanism when it is not actuated by the blade element 21. However, due to the positioning of the sensor 26, and the configuration of the blade element 21, it should be appreciated that the blade element 21 actuates the sensor 26 both in the first position of the bin 11 illustrated in
Operation of the shredder described above will now be described, beginning with the consideration of
Normal operation of the shredder continues, as described above, as more and more sheets are shredded, such that the volume of shreds collected in the bin increases. The shreds build up into a generally pyramid-shaped pile within the bin 11, the pile increasing in weight and size until, as the bin becomes nearly full, the paper exiting the cutting mechanism applies generally downwards pressure to the mass of collected shreds as it presses against the growing mass of shreds in the bin. This continues until such time as the generally downwards force acting on the shreds, having a component attributable to the weight of the shreds and a component attributable to the pressure exerted on the mass of shreds by paper exiting the cutting mechanism, exceeds a predetermined threshold value as determined by the force necessary to release the catch 17. When this occurs, the bin 11 is free to move pivotally, about the pivot axis 10 so as to move from the first position illustrated in
It should therefore be appreciated that, without any optical sensors provided across the top of the bin 11, the bin 11 is allowed to fill more densely with paper shreds than in conventional shredders, and will only be stopped from further operation when the weight of collected shreds exceeds a predetermined threshold value, rather than simply when their volume becomes such as to actuate a sensing system. This has been found to obviate the rather frequent need to open the collection bins of conventional shredders and press the collected shreds down more densely in order to allow the remaining volume of the bin to be used during subsequent shredding operations.
As indicated above, when the bin 11 moves to its second, dropped-down position illustrated in
When the bin 11 has been emptied in this manner, it is then re-inserted into the shredder and closed, so as to adopt, once more, the position illustrated in
Whilst the present invention has been described in detail with reference to a preferred embodiment, it should be appreciated that modifications or alterations could be made without departing from the scope of the claimed invention. For example, whilst the preferred embodiment described above operates on the basis of pivotal movement of the collection bin, variants of the invention could alternatively use substantially translational, sliding, movement, either in a vertical or a horizontal sense.
When used in this specification and claims, the terms “comprises” and “comprising” and variations thereof mean that the specified features, steps or integers are included. The terms are not to be interpreted to exclude the presence of other features, steps or components.
The features disclosed in the foregoing description, or the following claims, or the accompanying drawings, expressed in their specific forms or in terms of a means for performing the disclosed function, or a method or process for attaining the disclosed result, as appropriate, may, separately, or in any combination of such features, be utilised for realising the invention in diverse forms thereof.
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