The present embodiments to a motor-sweeper for cleaning large surfaces such as streets or industrial facilities.
In particular, it relates to an apparatus for collecting garbage and debris from a surface applied to a motor-sweeper.
In the field of motor-sweepers, it has long been known various structures that provide the possibility of regulating the position of the rotating brooms so that the distance between the surface being cleaned and their bristles is kept uniform despite their wear.
It is, in fact, known that the continuous friction with hard and rough surfaces involves the shortening of the bristles of the rotating brooms and consequently the pressure, with which the surface being cleaned is swept, is reduced.
In order to solve this drawback, the U.S. Pat. No. 4,219,901 describes a motor-sweeper provided with an articulated device or apparatus that allows the operator to adjust the distance from the ground for a cylindrical broom mounted below and transversally with respect to the longitudinal axis of the same motor-sweeper.
The apparatus is provided with an articulated arm comprising a cylindrical body and a rod. An adjusting knob is on the base of the cylindrical body protruding from the motor-sweeper in the operator direction. On the opposite base, the one that stays inside the body of the motor-sweeper, a first threaded end of said rod engages, whereas on a second end there is fixed a C-shaped support adapted to support said cylindrical broom.
On the body of the rod there are fixed arms apt at modifying the attitude of the articulated arm between a resting position wherein the broom is lifted from the ground, and operating positions wherein the broom touches the ground with various pressures.
Instead, the adjusting knob allows to modify the overall length of the articulated arm.
The operator can manipulate said knob in order to apply a rotation to the cylindrical body of the articulated arm into a first direction, so that the first threaded end of the rod screws itself in the cylindrical body, or in the direction opposed to the first one, so that the first threaded end of the rod exits from the cylindrical body. Consequently, the distance from the ground of the axis of the cylindrical broom is increased, such as in the case of a new broom, or reduced as the bristles wear more and more, so as to always obtain the required pressure for a proper cleaning of the ground.
The motor-sweeper further comprises an exhaust blower that generates an air flow that helps in conveying the dust portion of the debris into a collecting container.
Also patent application US 2010/291843 describes a motor-sweeper provided with devices to adjust the distance from the ground of rotating brooms. In particular the described motor-sweeper is provided with two groups of brooms, one mounted at the front and one located centrally under the motor-sweeper. The second group comprises a cylindrical broom mounted transversally with respect to the longitudinal axis of the motor-sweeper and designated for collecting and conveying the dirt into a container located at the rear of the motor-sweeper. The distance from the ground of said cylindrical broom can be adjusted by the operator by means of a knob that makes the support of said broom swing about an axis so as to make it keep a proper contact with the surface being cleaned. It is to note that the pivot whereon the support axis of the broom swings, is located before the same broom, with respect to the forward direction of the motor-sweeper, so as to move the broom at the same time downward and forward. This movement makes it possible to keep constant the distance with a front flap for retaining and collecting the dirt collected by the broom. In fact, in order to ensure an efficient collection it is necessary not only that the broom is properly in contact with the ground but also that there is not too much space between the same broom and the front flap otherwise its rotation could not ensure the necessary push of the dirt at the rear toward the container.
Such devices only partially solve the problem of keeping constant the capability of collecting debris and garbage from the surface being cleaned due to the wear of the brooms.
In fact, with reference to the motor-sweeper described in the above-mentioned second prior art document, the conveying apparatus is certainly capable of adjusting the position of the transverse broom so that it remains in contact with the surface being cleaned and near the surface of the chamber wherein it is housed so as to convey debris and garbage upward, but in doing so it distances said rotating broom from the collecting container (
A similar motor-sweeper is also described in European patent application EP 0843046, wherein it is described a machine for cleaning the floor comprising a cylindrical rotating broom mounted on a rotation axis or hub whose ends are supported by an articulated intermediate frame in a position on the support frame of the same motor-sweeper (see column 4, lines 24-30). The position or the articulation axis enables the intermediate frame to adjust the position of the rotating broom with respect to the ground as a consequence of its wear (see column 4, lines 53-54 and column 6, lines 53-56). Moreover a leverage system allows a front flap to be adjusted so as to follow the broom adjustment downward at the front in order to keep there a continuous controlled distance.
Now, with reference to
The technical problem at the core of the embodiments is therefore that of providing an apparatus capable of solving the performance deterioration of the garbage and debris collection in a simple and inventive way. In particular, the embodiments described hereinafter allow to greatly reduce, if not eliminate, the part of garbage and debris that falls back on the ground during the first pass of a motor-sweeper.
Such problem is solved by an apparatus that adjusts both the position of the rotating broom and that of a conveyor so that, on the one hand, the distance between a peripheral surface of said broom and the surface being cleaned basically remains the same and on the other hand, that the distance between the broom and the conveyor and between the broom and the container does not increase considerably due to the progressive wear of the broom, so as to achieve that the capability of removing the debris is constant.
The apparatus object of the embodiments is normally applied to a rear load machine. Garbage and debris are lifted by the broom which rotates in the opposite direction with respect to the forward direction and, by means of a curved surface, or conveyor they are conveyed toward the collecting container.
Further characteristics and advantages of the apparatus for collecting garbage and debris having an adjustable conveyor for a motor-sweeper object will become more apparent from the following description of an embodiment, for exemplification only but not limited to, with reference to the following figures, wherein:
The idea the embodiments are based on is that of providing an apparatus capable of carrying out two adjustments so as to keep uniform the sweeping action quality carried out by a motor-sweeper that is, the adjustment of the distance of a transverse sweep broom from the surface and the adjustment of the conveyor shape that is, the distance between the sweep broom and the conveyor and between the sweep broom and the container is kept uniform.
After a great number of experimental tests it has been developed an apparatus which allows the conveyor to modify its arrangement or shape, in order to keep uniform the optimal distance between its free edge and the sweep broom. In other words, the space between the conveyor and the sweep broom in correspondence of the surface has to be uniform. To this purpose, the conveyor has to move along with the rotating sweep broom movement realized by suitable means in response to the progressive reduction of its diameter because of wear. At the same time, the space between the sweep broom and the rear container must be kept uniform.
Thanks to this apparatus it has been proved that, even with a worn sweep broom, it is possible to both avoid worsening the performance of the debris and garbage collection, and exploit effectively the capacity of a collecting container.
With reference to
It is to note that in the present description the terms front and rear, upper and lower and the like are used to show the relative position of any element or device of the motor-sweeper with respect to the front, rear, upper, lower part of the same motor-sweeper in the usual working conditions, that is moving forward on a surface being cleaned.
In the lower part of the body 101, in a position included between the front wheel 104 and the rear wheels 105, there is installed an apparatus 1 for collecting debris and garbage and for conveying them toward a compartment or container 11 to collect said garbage and debris collected from the surface being cleaned.
In particular, the apparatus 1 comprises a sweep broom support 2 adapted to correctly position, with respect to the surface, a sweep broom 3 having a rotating axis X-X substantially parallel to a surface G being cleaned, a leverage assembly 4 apt to adjust the pressure of said sweep broom 3 on the surface, a device 5, 7 (
The sweep broom support 2, in the embodiment shown for exemplification in
It is to note that said first bar 2C and the respective first portion 21 of the first side 2A and of the second side 2B, is mounted at the rear with respect to the forward motion of motor-sweeper 100, while the second bar 2D, and the respective second portion 22 of the first side 2A and of the second side 2B, is mounted at the front with respect to the motor-sweeper 100. Furthermore, the first bar 2C is rotatably mounted on the frame (not shown) of the motor-sweeper body 101 through two suitable supports 21C each one placed in correspondence of each end of the same bar.
Advantageously, moreover, the first side 2A and the second side 2B are mounted on the first bar 2C at a height L1 from the surface G higher than the height L2 from the surface G of the rotating axis X-X of the broom 3 (
The first side 2A and the second side 2B also comprise third portions 23A and 23B respectively that extend lower with respect to said first portion 21 and second portion 22 of the first side 2A and second side 2B. The third portions 23A and 23B, preferably protrude frontward with respect to said second portions 22 so as to define two support arms between which the sweep broom 3 is rotatably mounted. In particular, the third portion 23A of the first side 2A is preferably hinged to the respective first and second portions 21, 22 so as to be able to rotate and allow the installation and removal of the sweep broom 3. The third portion 23B of the second side 2B is, on the contrary, designed to support an electric motor 8 and preferably a gearmotor 9 that causes said transverse sweep broom 3 to rotate.
The transverse sweep broom 3 is made according to the known art, and comprises a cylindrical body 3A from the side surface of which bristles 3B, suitably spaced one from the other, protrude. The bases of said cylindrical body 3A engage on suitable supports (not shown) fixed on the first side 2A and on the second side 2B. In particular, the support mounted on the second side 2B is realized so as to engage, directly or by means of other known mechanisms, with a shaft of said gearmotor 9. It is to note, as shown in
The pressure with which the transverse sweep broom 3 acts on the surface is adjusted by the leverage 4. In the preferred embodiment shown in
Each of the two elements, first 4B and second 4C of the first arm 4A comprises one or more first slots 4I (
The first end 41B of the first element 4B is, further, joined to said second side 2B by means of a respective bolt 42B which engages said second slot 4L so as to allow the mutual sliding of the first arm 4A and of the broom support 2. A first end 41C of the second element 4C, opposite to the first end 41D of the first element 4B, is rotatably connected to said second arm 4D thus forming a compass structure.
A damper 4H, for example a gas spring shown in
The second arm 4D comprises a first end 41D connected to the first end 41B of the first element 4B of the first arm 4A and a second end 42D joined with suitable means to the body 101 of the motor-sweeper 100. In addition, said first end 41D preferably further comprises a slot 43D for engaging the rod 4E.
The rod 4E comprises a longitudinal stem portion 41E and an end knob 4F. The rod 4E is slidably fastened to a frame portion (not shown) of the motor-sweeper in the traditional way. The stem portion 41E engages said second arm 4D pulling or pushing it along the direction of the axis of the same stem. Preferably, the stem portion 41E is provided with a transverse pin 43E engaging the slot 43D of the second arm 4D. Therefore, in this configuration, by rotating the knob 4F integral to the rod 4E it is possible to change the incline of the second arm 4D that, consequently changes the incline of the articulated arm 4A and in cascade it changes the incline of the broom support 2 causing it to rotate pivoted on the first bar 2C. Hence, the distance of the sweep broom 3 from the surface is in turn changed.
In particular, the above said manipulation of the broom support 2 and of the respective sweep broom 3 for changing the distance of the broom from the surface, and consequently its pressure on the same surface in order to achieve an efficient cleaning, is commanded by the operator of the motor-sweeper 100 in the following way. By rotating the knob 4F, the second arm 4D moves its first end 41D away from the same knob (
Advantageously, according to the an embodiment, the rotation of the broom support 2 is transmitted by means of said device 5, 7 to the guide assembly 6. In fact, the device comprises a bracket 7 fixed with a first end to the third portion 23B of the second side 2B of the broom support 2 and with a second end to a pantograph structure 5.
In particular, the pantograph 5 is preferably positioned before the sweep broom 3 with respect to the forward motion of the motor-sweeper 100 and comprises two pairs of parallel first and second arms 5A, 5B. These pairs of arms are each placed substantially in-line with a respective first side 2A and second side 2B of the broom support 2. Furthermore, they are oriented so as to have upper ends of each first arm 5A and second arm 5B bound to the body 101 of the motor-sweeper 100, and lower ends linked by a connecting element 5C formed by two sides 51C connected each other by a beam 52C. Preferably, the beam 52C is, in its turn, formed by a bar having an inverted L-shape section with a first portion 53C generally plate-like provided with one face facing the broom and one facing the opposite direction (not numbered in the drawings), both faces being slightly inclined with respect to the perpendicular to the surface G (
The guide assembly 6 or guide of the debris and garbage of the collecting apparatus 1 of an embodiment advantageously comprises an assembly including a flap 6A, a connecting portion 6B and a guiding portion 6C to guide the debris uplifted by the sweep broom 3 toward the container 11.
In particular, the flap 6A (
A connecting portion 6B (
The guiding portion 6C (
In its movement, the pantograph structure 5 changes the position of the flap 6A fixed on said element 5C, so that said flap 6A remains close to the peripheral surface of said transverse sweep broom 3. In the same way and at the same time, the movement of the broom support 2 commanded by the leverage 4 also commands the guiding portion 6C of the guide assembly 6.
In other words, as shown in
As it can be seen comparing
Differently from what occurs in the motor-sweepers of the known art, wherein the movement of the sweep broom takes place downward and in a direction that distances the broom from the container (
Finally, on the motor-sweeper 100 there is also mounted an exhaust blower (not shown) adapted to guide toward the filters (not shown) housed in the motor-sweeper body 101 the dusts generated and/or lifted by the scraping of the bristles 3B of the rotating sweep broom 3 against the surface being cleaned.
A further embodiment includes a motor-sweeper 100 comprising the apparatus 1 for collecting garbage previously described.
Still a further embodiment is a method for collecting garbage from a surface G comprising the steps of:
Preferably, the last two steps of moving the broom and the guide assembly are carried out not only at the same time, but also through just one command.
Preferably, said method is realized with a motor-sweeper 100 provided with the apparatus previously described.
From the foregoing, it is apparent that all the drawbacks linked to the prior art previously described have been solved.
The new apparatus 1 having a moveable guide assembly 6 makes it possible to keep to a minimum the space between the rotating sweep broom 3, the same moveable guide assembly 6 and the collecting container 11, despite the progressive wear of said rotating broom 3, thanks to the combination of a mechanism regulating the broom position operatively connected to a regulating mechanism of the guide assembly of the debris collected by the broom. In fact, the mechanism regulating the position of the broom, that is the leverage 4 and the broom support 2, acts in a coordinate way with the mechanism regulating the guide assembly, in particular the pantograph 5 in order to keep uniform the distance between the guide assembly 6 and the broom 3 and between the broom and the garbage container 11. This makes it possible to ensure a constant capability of filling the collecting container even when the broom bristles are worn out. Furthermore, the command given by the sole knob advantageously allows to operate all the above said regulations in a coordinate way.
In a further embodiment, and with respect to
A leverage assembly 4 acts on the support to regulate the distance of the sweep broom 3 from the surface G. A motor is provided and is configured to activate the sweep broom 3. A guide assembly 6 is arranged to guide the debris uplifted by the broom 3 towards the collecting container 11. A rear guide assembly 13 in communication with the rear guide 12 is configured to regulate the distance of the rear guide 12 to the rotating sweep broom 3. In response to the bristles of the sweep broom 3 becoming worn, the leverage assembly 4 commands the sweep broom support 2 to move the rotating sweep broom 3 towards the surface G to be cleaned. The rear guide assembly 13 commands the rear guide 12 to move towards the rotating sweep broom 11. In addition, the guide assembly 6 follows the movement moving the rotating broom 3 so as to maintain a uniform space between the sweep broom 3 and the guide assembly 6, and to maintain a uniform space between the sweep broom 3 and the rear guide 12.
In another embodiment, in response to bristles of the sweep broom 3 becoming worn, the leverage assembly 4 commands the sweep broom support 2 to move the sweep broom 3 towards the surface G to be cleaned and towards the guide assembly 6 so as to maintain a uniform space between the sweep broom 3 and the guide assembly 6. In addition, the rear guide assembly 13 commands the rear guide 12 to move towards the guide assembly 6, so as to maintain a uniform space between the sweep broom 3 and the rear guide 12.
With respect to
In yet another embodiment, the method includes, in response to the bristles of the wearing, moving the sweep broom 3 toward the surface G and towards the guide assembly 6 so as to maintain a uniform space between the sweep broom 3 and the guide assembly 6, and moving the rear guide 12 towards the guide assembly 6 so as to maintain a uniform space between the sweep broom 3 and the rear guide 12.
In yet another embodiment as shown in
In yet another embodiment, the method includes, in response to the bristles of the sweep broom 3 becoming worn, moving the sweep broom 3 toward the surface G and towards the guide assembly 6 so as to maintain a uniform space between the sweep broom 3 and the guide assembly 6, and moving the collecting container 11 towards the guide assembly 6 so as to maintain a uniform space between the sweep broom 3 and the collecting container 11.
In further embodiments, the distance between the guide assembly 6 and the broom 3 may be set by the user, and based on the size of the debris to be collected. For example, if the debris to be collected is relatively large, a greater distance between the guide assembly 6 and the broom 3 may be set by the user. Likewise, if the debris to be collected is relatively small, a smaller distance between the guide assembly 6 and the broom 3 may be set by the user.
While an exemplary embodiment has herewith been described, the present invention is not limited to this preferred embodiment, but comprises any and all the embodiments having equivalent elements, changes, omissions, combinations, adaptations and/or alterations as they would be considered by those skilled in the art based on the present description. For example, the materials used to realize the various components of the leverage 4, broom support 2, pantograph 5, guide assembly 6 are preferably metal, but they can also be plastic particularly suitable to resist wearing, such as plastic material reinforced with carbon fiber. The movement of sweep broom 3 and guide assembly 6 and rear guide 12 and collecting container 11 may be controlled by any suitable linkage. For example, the movement of guide assembly 6 and rear guide 12 or collecting container 11 may be linked mechanically to the movement of the sweep broom 3, or movement may be controlled separately with independent linkages, and movement may be controlled by for example manual adjustment or actuator or electric motor as would be understood by those skilled in the art. The forms and dimensions of each piece or component may vary according to particular constructive or dimensional requirements in order to adapt the device to motor-sweepers for instance with or without an operator. It is therefore intended that all such modifications are embraced within the scope of the embodiments as defined in the appended claims.
Number | Date | Country | Kind |
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PN2015A000007 | Apr 2015 | IT | national |
This application is a continuation-in-part application of U.S. application Ser. No. 15/560,761, filed on Sep. 22, 2017, which is a national stage application of International Application No. PCT/IB2016/051128, filed on Mar. 1, 2016, which claims priority from Italian Application No. PN2015A000007, filed on Apr. 16, 2015. The disclosure of the foregoing application is hereby incorporated by reference in its entirety.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 15560761 | US | |
Child | 16700545 | US |