CZ300599B6 - Suction nozzle - Google Patents

Abstract

In the present invention, there is disclosed a suction nozzle (1) for receiving sweepings (7) comprising a suction hole through which the sweepings (7) are sucked into the suction nozzle, as well as a rotatably mounted flap (2) having a flap (2) surface (2a, 2b) directing in the suction nozzle (1) direction of drive and forming outer side of the suction nozzle (1) wherein said flap (2) surface (2a, 2b) defining the suction nozzle (1) suction hole (1) moves butene a closed position and open position. When the flap (2) is open, said suction hole cross section is greater for suction than when the flap (2) is closed. The flap (2) surface (2a) is concave wherein the flap (2) concave surface (2a) forms a guide surface for sweepings (7) converging in the direction of suction and with narrowing cross section when the flap (2) is closed.

Description

Technical field

The present invention relates to a suction nozzle for receiving garbage, with a suction opening being suckable to the suction nozzle, as well as a rotatably mounted flap, which flap surface facing the suction tube forming the outer side of the suction nozzle delimits the suction opening of the suction nozzle. and which is movable between the closed position and the open half-position, the intake opening having a larger intake cross-section with the flap open than with the closed flap.

BACKGROUND OF THE INVENTION

For street cleaning, it is known to sweep garbage, such as glass, cardboard, cans, leaves or gravel, onto rotating brooms on a scrubber, into one elongated pile, the garbage being trapped by vacuum in a suction nozzle that moves from and transports the garbage to the garbage collection container.

A suction nozzle of the kind mentioned above is known from DE 94 15 472 U1. A flap is associated with the suction opening of the suction nozzle, the front side of which faces in the direction of travel, limits the cross section of the suction opening. When the suction nozzle moves in the direction of travel, the garbage pushes the flap upwards so that the cross section of the suction port increases, but on this already known suction nozzle it is disadvantageous that even small amounts of garbage that are trapped only on one side of the suction nozzle. The opening of the opening pushes the flap into its almost full opening, namely over its entire width, whereby the cross-section of the suction opening increases strongly despite only a small amount of debris. This suffers from suction efficiency.

A suction nozzle is known from WO 97/42378, to which a swivel flap is also associated with the suction opening. The flap surface, which limits the inlet opening of the suction nozzle, is convexly arched and, with its leading edge, arched upward, so that even with larger amounts of debris it does not burrow under the debris. The flap can be tilted by means of an adjusting roller to adjust the cross section of the suction nozzle opening. However, the continuous adaptation of the cross-section of the inlet opening to the amount of debris currently occurring is not envisaged or would require costly control of the adjusting roller.

Furthermore, a suction nozzle is known from DE 295 18 844 U1, to whose suction opening a rotary flap is also assigned. Although the adjusting device for the swiveling flap with a pulling cable allows active rotation of the flap, it is also associated with the disadvantages of the aforementioned suction nozzle flap according to WO 97/42378.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a suction nozzle which allows efficient collection of debris in a simple manner.

SUMMARY OF THE INVENTION

This object is achieved by a suction nozzle for receiving garbage, with a suction opening which is suckable by suction into the suction nozzle, as well as by a rotatably mounted flap which delimits the suction opening in the direction of travel of the suction tube forming the outside of the suction nozzle. a suction nozzle which is movable between a closed position and an open position, the suction opening having a larger intake cross-section with the flap open than with a closed flap, which according to the invention consists in that the flap surface is concave, the concave surface 300599 B6 damper, when the damper is closed, forms a guide surface for dirt converging in the suction direction with a tapering cross-section.

In this suction nozzle, the concave flap surface preferably has a continuous curvature.

L of this suction nozzle further preferably has a concave flap surface having two side surfaces which converge V-shaped in the suction direction as well as a central surface bordering the side surfaces which, when the flap is closed, forms an inclined surface in the suction direction. cross-section.

The suction nozzle further preferably has a pivoting device for pivoting the flap.

Furthermore, the suction nozzle is preferably designed such that a gap of 1 to 10 mm is provided between the flap and the side plate section of the suction nozzle on which the flap is mounted.

In the suction nozzle, water nozzles are also preferably provided in the inner region of the suction tube or suction hose of the suction nozzle.

In the suction nozzle, the lower edges of the suction nozzle are furthermore provided with a wear-resistant or abrasion-resistant layer, in particular a weld-on layer,

In the suction nozzle, furthermore, at the end of the suction nozzle facing the flap, a plate is provided which delimits the suction slot of the suction nozzle.

The suction nozzle is further preferably provided with a suction tube or suction hose for connection to a suction machine with a vacuum generating device.

The flap according to the invention for the suction nozzle has at least one concave-shaped surface, and the flap may, for example, have two sections that project forward on the right and left side to form a depression in the central region of the flap. Thereby, the flap has an inwardly directed camber or fold. Additionally, a device for pivotally attaching the damper to a holding device, such as, for example, one or more axes, which can, for example, be rotatably mounted in the apertures, is provided on the flap according to the invention so that the damper is pivotally mounted. The concave shaped surface is then, for example, so oriented that it faces in the direction of the axis of rotation thus determined. It is also conceivable to form the flap such that at least one surface normal of the concave surface has an intersection with a specified axis of rotation.

The flap for the suction nozzle provided in accordance with the invention allows the suction opening of the suction nozzle to increase or decrease as a function of the suction debris. As a result, the suction port surface can be adapted to the actually sucked up dust. The concave design of the at least one surface of the plate causes the sweeping strip to sweep the swept garbage strip from, for example, the right and left, projecting regions of the concave surface by moving the flap in the direction of travel towards the inwardly arched region. Due to the pivoting mounting of the flap, a concave surface which is at rest oriented, for example, in the direction of travel, can be staggered with a greater amount of debris, so that the deepest fold lies rearwardly continuously tilted to the open position. In the case of a maximum opening, the concave surface faces downwards, so that the concave maximum opening area is formed, for example, in the form of an arched arc.

It is possible to design the concave surface as a continuously curved surface or also as an approximately continuously curved surface, for example consisting of a plurality of curves. Furthermore, it is also possible to form a concave surface also in a V-shape, for example by two surfaces arranged at an angle to each other. Each of these embodiments makes it possible for the flap according to the invention to be scraped off as the flap moves along the garbage strip in the direction of the central region of the flap,

The rotation of the flap can be varied by the cross section of the suction opening of the suction nozzle so that it can actually be adapted to the accumulated amount of garbage. Furthermore, the flap may also have a guide surface extending vertically or obliquely to the concave surface, which in use leads to an accumulating amount of garbage, and with a greater amount of garbage supports the pivoting movement of the flap.

The suction nozzle according to the invention is concave in the first embodiment. The concave shape has the advantage that the suction nozzle with an approximately constant width moves over the surface to be cleaned so that not only the length of the y-path is available to catch the garbage, as would be the case with a straight suction nozzle running perpendicularly to the direction of movement. due to oblique adjustment, increased path length x, see Fig. 7.

The suction nozzle according to the invention may also have a holding device in which the flap described above can be pivoted or rotatably mounted. In this case, the suction nozzle can be both straight and concave. A vacuum generating device is attachable to the suction nozzle to suck up the accumulated garbage through the nozzle. The suction nozzle formed with a pivoting flap with a concave surface allows the suction cross-section to vary depending on the suction material lying in front of the suction nozzle or the flap. At the same time, due to the special shape of the flap, the trash is directed in the center of the nozzle. Laying the garbage aside can thus be prevented.

Advantageously, a device for moving the flap, such as a pneumatic or hydraulic device for rotating the flap about its axis of rotation, may be provided on the suction nozzle. This makes it possible, on the one hand, to determine in advance the fixed opening angle of the suction nozzle by means of a corresponding flap adjustment. Thus, for example, a large opening area can be set in low-volume debris such as leaves or paper. On the one hand, the fluff flap consisting of larger pieces, such as cohesive ground clods or parts of the milled material, can be pulverized or crushed by the continuous swinging or impact movement of the dump flap, so that suction of the dirt by the suction nozzle is facilitated. However, it is also possible to operate the suction nozzle without the corresponding damper actuating device, so that the damper is folded down in various positions by means of the gathered garbage, whereby a self-adjusting opening of the suction nozzle adapted to the amount of garbage collected can be realized.

Preferably, a gap is provided between the flap and the suction nozzle, for example at the centers of rotation or edge areas of the flap, which can be large, for example, in the range of 1 to 10 mm. This ensures that the garbage does not act in the swivel range between the flap and the suction nozzle and does not lead to pinching. Furthermore, the gap causes the self-cleaning to occur continuously when the suction nozzle is used, thus preventing contamination or fouling of the device.

It is advantageous to arrange water jets in the suction nozzle so that the interior of the suction shaft can be switched off continuously! water. For this purpose, the water nozzles are located in the inner region of the suction shaft, preferably on its lower region. Since, according to the embodiment of the invention, water is not sprayed directly on the street, but rather into the suction shaft area of the suction nozzle, the sucked-in dust is bound directly in the nozzle, thereby reducing water consumption, since not the entire street has to be sprayed with water. Furthermore, the aspirated and water-bound dust tends to clog much less the following channels or to settle on the side walls than the water-bound dust, so that the self-cleaning of the suction nozzle as well as higher operational safety can be realized by the embodiment of the invention. As a result, the wear of the entire device can be reduced as well as the intensity of the suction noise.

Preferably, a wear-resistant or abrasion-resistant layer, in particular a weld-resistant layer, is disposed on the lower edges of the suction nozzle in order to protect the wear-prone parts from wear during operation. This can increase the life of the suction nozzle.

Preferably, on the side of the suction nozzle facing the flap, an approximately horizontally extending plate is provided on the rear lower region which, for example, when using the suction nozzle for cleaning the streets, leads subsequently in a direction of movement across the surface to be cleaned. Such a approximately flat plate with a preferably rearwardly bent edge, which causes the suction nozzle not attached to the garbage to lie, can additionally be collected by the suction effect produced by the plate at the rear of the suction nozzle. the efficiency of the suction nozzle increases.

The suction machine according to the invention for sucking material from the surface has a vacuum generating device and, as described above, a suction nozzle associated with it. Such a suction or sweeping machine can efficiently clean the streets. The suction nozzle according to the invention makes it possible to consider a greater distance to the ground, while requiring a lower blower power. Energy consumption and noise intensity can thus be further reduced. Faster driving is also possible.

Advantageously, suitable sweeping elements, such as fixed or rotating brooms, are arranged in the direction of movement on the suction machine in front of the suction nozzle, preferably in a row, so that the material lying on the surface to be cleaned is first swept onto the longitudinal pile. pick up the suction nozzle.

Preferably, the suction machine has a collection container for the aspirated material, and preferably a hose to connect the collection container to the suction nozzle so that the trash sucked in by the suction nozzle can be transported through the hose to the collection container and accumulated there so that liquidated.

The suction nozzle with a concave surface-mounted flap is preferably arranged on the suction machine so that the side regions of the concave surface face the direction of travel of the suction machine in the flap closing position. For this purpose, for example, in the case of a V-shaped flap, the side arms can be oriented to the left or right to the front, so that the tip formed by the non-colliding side arms points in the opposite direction to the travel direction. As a result, when the suction machine is moved by the side arms, it can be diverted to the central region of the concave surface and thus exactly to the suction tube, which in the case of a freely movable flap, under condensing conditions exerting force on the flap, leads to an opening movement.

Overview of the drawings

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT OF THE INVENTION The invention will now be described in more detail with reference to the accompanying drawings, in which: FIG. 1 shows the suction nozzle of the invention with a hinged flap in the closed position; 3 is a front view of the suction nozzle with the flap closed; FIG. 4 shows the suction nozzle of FIG. 3 along the cross-sections A, B and C shown; FIG. 5 a front view of the suction nozzle with the flap open; FIG. 5 along the cross-sectional views A, B and C shown in FIG. 7a of a conventional suction nozzle in plan view; and FIG. 7b of the suction nozzle according to the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Giant. 1 shows a suction nozzle 1 according to the invention with a flap 2 which is pivotally connected to it by a joint. The flap 2 is folded down in the position shown and has a concave V-shaped side face 2 facing in the direction of travel. In the central region of the flap 2, an inclined central surface 2 extends upwards, which serves as a concave surface 2 for the introduction of garbage 7. Above the edges, the first upper surface 2 and the second upper surface 2 are provided, The flap 2 is rotatably mounted on both sides in the side plate 8 by means of the axes 6. The flap 2 is in its closed position with a small amount of debris 7 and leaves between the lower edge of the concave surface 2 and the surface to be cleaned. a free suction slot 3, for example 30 mm. If there is a larger amount of garbage on the street 7, then

The flaps 2 move slowly towards the garbage 7 by moving the suction nozzle 1 in the direction of travel, and this material slowly moves from the side ends of the flaps 2 along the surface 2 towards the center of the flaps 2 as a result of the V-shaped flap 2. shaped by surfaces 2, which extend obliquely on the upper edge of the flap 2.

The flap 2 formed in the illustrated V-shaped embodiment is rotated around the axes 6 by the pressure of the trash 7 on the surfaces 2 and 2 with a larger amount of garbage 7. By moving the flap 2 towards the garbage 7 a certain force is applied to the flap 2. below the pivot axes defined by the axes 6 or the pivot points, forcing the flap 2 into the open position, see FIG. 2. The cone taper causes the flap 2 to open in the center farther than in the peripheral regions. Since the preformed garbage 7 and the flap 2 have a similar contour in their open position due to the garbage 2 abutting the flap 2, there is no sudden major change in the suction cross section, so that the suction flow or suction force on the garbage 7 can be maintained approximately constant. This can, on the one hand, optimize the suction result and, on the other hand, reliably prevent the suction flow from being interrupted. A sufficiently large gap 5 ensures that there is no contamination in the edge area of the flap 2.

The flap 2, opened by the litter 7 resistance, allows the combined and combined suction flow of the litter 7 to be fed together in the region of the center of the flap 2 to the suction tube or suction hose 9 arranged in the central region of the suction nozzle. that the garbage 2 comes into contact with other parts of the suction nozzle 1 other than the flap 2 as well as with the suction hose 9, thereby reducing wear. In Fig. 2, water nozzles 10 are shown in the inner region of the suction hose 9, which serve to bind the dust.

The concave design of the flap 2 causes shaping of the garbage 2 along a predetermined path so that the garbage 2 guided by the flap 2 is guided by a longer suction path so that it can be absorbed by the suction flow. Thus, the suction device is available for a longer period of time compared to conventional suction nozzles arranged transversely to the direction of travel to catch debris 2- The test results have shown that the suction nozzle 1 according to the invention can achieve about 35% greater suction power, for example, it will allow faster sweeping or a higher suction machine speed.

Giant. 3 shows a front view of the suction nozzle 1 according to the invention, with the flap 2 in the closed position. As can be seen from section AA in FIG. 4, a horizontal approximately 50 mm wide sheet metal plate 4 is arranged on the rear lower region of the suction nozzle 1, under which the suction nozzle 1 as well as the suction slot 3 of the flap 2, creating a suction effect. The possibly lying sucking nozzle 2, which has been passed through the suction nozzle 1, can be additionally captured by the suction stream thus generated in order to increase efficiency. This can, for example, increase the distance of the suction nozzle even from the road, without adversely affecting the sweeping result. The speed of flow between the shaft £ 1 of the car can thus decrease, resulting in a reduction in noise levels.

Giant. 4 and 4 show further sections of the suction nozzle 1 shown in FIG. 3.

Fig. 5 shows the suction nozzle I shown in Fig. 3 with the flap 2 in the open position, with the garbage 2 lying on the surface to be cleaned abutting the open flap 2.

Giant. Figures 6 to 6 show sections A-A, B-B and C-C of Figure 5.

Giant. 7 shows a plan view of a known, rectilinear suction nozzle 1 having a width y. If this suction nozzle 1 is moved in the direction of travel, then a path of width y is available for picking up the garbage 2. Giant. 7 shows a plan view of the concave suction nozzle 1 of the present invention, and it can easily be seen that due to the concave suction nozzle 1, a larger path x is available over the surface to be cleaned as the suction nozzle 1 moves. In the example shown, the suction nozzle 1 forms an angle of approximately 90 ° so that the path x is a factor 12 greater than the width in the shaft of the suction nozzle 1.

-5 CZ 300599 B6

Thus, the garbage 7 can be sucked in for a longer period of time than the conventional suction nozzle 1 at the same speed. In order to maintain the wider path x over the entire width of the suction nozzle 1, the suction nozzle 1 can be made wider in the curved region in order to increase the effective width even in the central region of the suction nozzle 1. The described effect of increasing the effective path for picking up the garbage 7 can also be achieved by other shapes of the suction nozzle 1, such as, for example, a continuously curved suction nozzle or a straight-running suction nozzle arranged obliquely to the direction of travel.

Claims (8)

PATENT CLAIMS A suction nozzle (1) for receiving garbage (7), with a suction opening, which is suckable (7) sucked into the suction nozzle (1), as well as with a rotatably mounted flap (2), which has a flap surface (2), facing in the direction of travel of the suction tube (1) which forms the outside of the suction nozzle (1), delimits the suction opening of the suction nozzle (1) and is movable between a closed position and an open position The flap (2) has a larger intake cross-section than when the flap (2) is closed, characterized in that the surface (2a) of the flap (2) is concave and the concave surface (2a) of the flap (2) forms 15, the guide surface for the garbage (7), converging in the suction direction, has a narrowing cross-section. Suction nozzle (1) according to claim 1, characterized in that the concave surface (2a) of the flap (2) has a continuous curvature. Suction nozzle (1) according to claim 1, characterized in that the concave surface (2a, 2b) of the flap (2) has two lateral surfaces (2a) that converge in a V-shaped direction as well as the central surface (2b) bordering the side surfaces (2a), which, when the flap (2) is closed, form an inclined surface in the suction direction with a tapering cross-section contour. Suction nozzle (1) according to one of the preceding claims, characterized in that it has a pivoting device for pivoting the flap (2). Suction nozzle (1) according to one of the preceding claims, characterized in that: 30, a gap (5) having a width of 1 to 10 mm is provided between the flap (2) and the side plate section (8) of the suction nozzle (1) on which the flap (2) is mounted. Suction nozzle (1) according to one of the preceding claims, characterized in that water nozzles are provided in the inner region of the suction pipe or suction hose (9) of the suction nozzle (1). 35 (10). Suction nozzle (1) according to one of the preceding claims, characterized in that the lower edges of the suction nozzle (1) are provided with a wear-resistant or abrasion-resistant layer, in particular a welded-on layer. Suction nozzle (1) according to one of the preceding claims, characterized in that a plate (4) is provided at the end of the suction nozzle (1) facing the flap (2), which delimits the suction slot (3) of the suction nozzle (3). nozzle (1). Suction nozzle (1) according to one of the preceding claims, characterized in that it is provided with a suction tube or suction hose (9) for connection to a suction machine with a vacuum generating device.