RU2589776C2 - Concrete finishing machine for levelling floor bases - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: screeding machine for levelling floor bases comprising a frame or chassis (BB), to which means (AA) for supporting and moving machine frame (BB) in at least two directions and means (CC) for supporting and moving a milling device (DD) are associated; milling device (DD) has, as a terminal element, a rotary tool (EE) for levelling and smoothing a substrate screed to obtain a finished surface on which to lay floor.

EFFECT: in particular, support and moving means (CC) of milling device (DD) include at least one articulated arm (CC), able to move milling device (DD) along a straight line (GG) parallel to a further straight line (HH) joining two joints (J, K), which connect articulated arm (CC) to machine frame (BB), and in a direction which is substantially perpendicular to moving direction of machine frame (BB).

8 cl, 22 dwg

Description

The present invention relates to a concrete-leveling machine for leveling floors.

More specifically, the invention relates to an improved concrete-leveling machine for leveling floor foundations, comprising two caterpillar tracks parallel to each other, which support and move in two directions a frame or chassis on which an articulated arm supporting a rotating tool is mounted; Moreover, the electronic automatic adjustment system allows continuous height control with respect to the plane formed by the laser projector in such a way that the accuracy of the plane made with continuous height control is such that it does not affect the main effect of the continuity of the performed plane, despite the sequence several related concrete work.

Floors essentially consist of sand or concrete layers and they can be made with or without a base.

In particular, subfloors are placed on a cement screed (also called “seamless cement screed”), which is placed and smoothed on a layer to be laid on the floor, and which is usually a semi-moist mixture of sand, cement and water, in which the concentration of cement is low, and water is dosed in accordance with the requirements to obtain a mixture having a slow-moving consistency (a mixture of wet sand), to obtain a product with clearly defined geometric characteristics, while also avoiding Sobienie plasticity, which occur where the mixture was dosed over a large volume of water, and that will create unwanted motion of the mixture during and after installation on the floor, and therefore undesirable changes in the quality and linear floor plane size during and after drying.

The above mixtures are produced using pre-mixed products or they are manually dosed by the operator.

The mixture, laid on the unfinished floor of the building, with a thickness of about 3-15 cm and smoothed to obtain a treated surface, forms the foundation tab on which all types of coatings are placed, such as ceramics, marble, parquet, carpet, resins, etc .; An additional goal of cement screed is also to provide space for installing water pipes, electric cables and / or cables of other services.

Inactive mixtures have a thickness of 3-15 cm in a pasty state, have a compressive strength of 0.05 to 0.15 kg / cm ² , and the leveling operation of this mixture mainly consists of the following steps.

First of all, in the first step, the height and orientation of the plane are determined by determining at least three points intersecting the plane to be made; during this operation, in order to obtain the above control points, it is necessary to determine the plane that will be executed, with a predetermined height set by the construction site management personnel located on each floor of the building and used by all specialists (electricians, plumbers, carpenters, floor stackers and etc.) as a control point for installing various devices, used as a reference.

Small islands or points made using the same materials of cement screed are spaced so that an aluminum rod or bar of suitable length is located on at least two of these islands and so that their horizontal surface is placed with respect to the vertical line (plumb line ) at a predetermined distance from a reference height defined but at a construction site.

During the second work step, parallel strips (called beacons) appropriately spaced are made of the same material mixture and obtained manually using a rod, thereby creating a continuous plane between points that were previously determined.

During the third working stage, the mixed material is placed inside parallel strips or beacons that have been preformed, while during the fourth working stage, the so-called leveling operation is performed, i.e. an operation according to which the operator, kneeling, moves the rod along the beacons to remove excess material placed between the beacons during the previous stage, in order to create a unified and continuous plane in this way.

Such an alignment operation can also be carried out using suitable suitable mechanical equipment, such as concrete concrete machines of the type described, for example, in EP 1163408 B1, in which the respective carriages are moved forward along the side rails and connected to two sections located on the bridge structure, which slide on top of each other, and one of which is connected to a mechanical structure supporting the cutter; a suitable combination of the milling rotation movement (which rotates in a direction depending on the direction of the side carriages) and the movement of the carriage supporting the cutter and the side carriages of the machine allows for automatic displacement and compression of the cement screed to a suitable optimal alignment.

At the additional processing stage, it is possible, using a hand trowel or using suitable mechanical equipment, to tamp the base and smooth and smooth the cement screed to obtain a uniform and level surface (which allows you to get a cement screed that is less porous and which can absorb less adhesive during stage of laying the covering material).

However, previously known operations that can be performed to level the cement screed have several drawbacks, including the disadvantages of having to place the concrete blocking machine in accordance with the cement screed that will be leveled for each part of the base to be treated.

In addition, such operations, whether they are manual or are implemented using known concrete-finishing machines, nevertheless, provide a cement screed that is not perfectly flat but wavy, while the same plane on which the machine or manual trowel rests is the only one standard for the operator.

The aim of the present invention is, therefore, to overcome the above technical disadvantages and, in particular, the provision of a concrete-leveling machine for leveling floor subfloors, which can be moved simply and quickly directly to the cement screed base without pre-made supporting rails or beacons for the entire surface to be leveled when the cementitious screed material is still in the mixture, and, in any case, before curing begins by drying.

Another objective of the present invention is the provision of a concrete-leveling machine for leveling the floor, which allows, simply and through a single operation, to obtain a surface layer of cement screed that is smooth, suitably compressed and perfectly aligned in the plane, without performing the tamping operation over the entire surface, over which will walk or which will be lined, for each type of material used as a base.

Another objective of the present invention is the provision of concrete-leveling machines for leveling the base of the floor, which can significantly reduce the processing time and the cost of installing the floor, in accordance with the prior art.

An additional objective of the invention is the provision of a method of manufacturing bases under the floor, which are provided by the above machine.

This and other objectives, which will become apparent from the following description, are achieved by means of a concrete-leveling machine for leveling the floor in accordance with paragraph 1 of the attached claims; additional detailed technical features are also contained in the dependent claims.

Advantageously sufficient is the placement of the cement screed mixture on the entire surface to be treated and the control of the concrete machine to obtain, by means of a single processing step and regardless of the size and linear dimensions of the surface, a cement screed layer having the desired thickness, dense, perfectly leveled and flat, so that subsequent floor laying is perfectly flat and / or free from bumps, seals, cracks or cavities.

Moreover, the size of the concrete-finishing machine allows it to pass through all the internal doors of the apartments, and this feature allows you to not lift or move the machine manually to go through the rooms, but ensures the continuation of work when passing through the doorway and along corridors continuously.

Additional characteristics and advantages of the concrete-leveling machine for leveling the base of the floor, which is the purpose of the present invention, will become apparent from the description of the preferred and illustrative, but not limiting, embodiments of the machine and from the graphic materials provided in the confirmation, where:

- figure 1 shows a perspective front view of a concrete-leveling machine for leveling the base of the floor in the first working position in accordance with the present invention;

- figure 2, 2A and 2B respectively show two partial side views and a partial perspective view from below of the machine of figure 1 in accordance with the present invention;

- figure 3 shows a partial perspective view of the machine of figure 1;

- figure 4 shows an enlarged detail A of figure 3 in accordance with the present invention;

- figure 5 shows a perspective front view of the machine of figure 1 in the second working position;

- Fig.6 is a General side view of the machine of Fig.5;

- Fig.7 shows an enlarged detail In Fig.6 in accordance with the present invention;

- Fig.8 is a front view of the machine of Fig.1 in accordance with the present invention;

- Fig.9 is a top view of the machine of Fig.1 in accordance with the invention;

- figure 10 shows a schematic diagram in an additional operating position of the machine in accordance with the present invention;

- figure 11 shows an enlarged detail C of figure 10 in accordance with the present invention;

- Fig.12 is a perspective top view of the machine of Fig.1 in the operating position shown in Fig.10, in accordance with the present invention;

- Fig.13 and 14 show additional technological schemes of the machine in accordance with the invention;

- Fig.15 is a partial side view of the machine shown in Fig.5, in accordance with the present invention;

- Fig.16 shows an enlarged detail D of Fig.15 in accordance with the present invention;

- Fig.17, 18, 19, 20 and 21 show perspective exploded views and views in section of part of the machine shown in figure 5, in accordance with the present invention;

- Fig.22 is a top plan view of a part of the machine shown in Fig.17-21, in accordance with the present invention.

With reference to these figures, the concrete base leveling machine, which is an object of the present invention, comprises two AA tracks, parallel to each other, which are directly moved along the cement screed for leveling, and which support and move the frame in at least two directions of the machine or BB chassis on which the CC pivot arm is mounted; furthermore, the rotary device or the adjusting device DD is in turn connected to said articulated lever CC and comprises a rotary tool EE as an end element.

While the machine is moving forward and backward, the total weight of the specified machine acts on the cement screed in accordance with the total area of the AA tracks, each of which is supported by sliding blocks B1, which are moved by the drive roller A1, and also contain a non-drive roller D1, a tension roller E1 and tape F1 (as shown in figures 1, 3, 4 and 5).

The drive roller A1 imparts movement to the belt F1, which rotates on the non-drive roller D1 and on the tension roller E1, and rests on the sliding blocks B1, so that the tangent of the drive roller A1 is a continuation of the tangent of the non-drive roller D1 (FIGS. 3-4); in addition, the quick displacement of the non-drive roller D1 simplifies mounting and dismounting operations for maintenance and / or replacement of the tape F1.

In particular, the size of the contact surface of the belt F1 of each track AA between the sliding blocks B1 is such that the track AA creates a certain pressure on the cement screed below at least 0.05 to 0.15 kg / cm ² , since paste-like inactive mixtures that form cement screeds having various thicknesses from 3 to 15 cm have a compression resistance between 0.05 and 0.15 kg / cm ² ; this allows the machine to move directly on the cement screed as well as the same machine does without immersion in the substrate under the cement screed and / or leaving no residue on the cement screed.

The machine also contains a plate C1, located under the frame BB of the machine and between the track AA (Fig.2, 2A, 2B), the size of which is such that a certain pressure exerted on the cement screed is less than at least a value in the range 0.05-0.15 kg / cm ² ; Slab C1 can also be moved beyond the plane defined by AA tracks of predefined FF measurements in order to raise the entire BB frame of the machine and to move the bottom surface of the A1 track belt F1 from the surface of the cement screed while changing the direction of the machine (by in fact, a change in direction occurs by performing mechanical rotation of the frame of the BB machine, which during lifting does not create any pressure and / or stripping of the material on the treated cement screed).

Moreover, the machine is extremely simple to control, since, due to the fact that the axis of rotation of the plate C1 passes through the center of gravity of the frame BB of the machine, lowering the specified plate C1 below the lower surface of the track AA and the subsequent mechanical rotation of the frame BB of the machine allows you to direct the above machine in all directions, including the ability to perform a full rotation of the machine itself.

Plate C1 is connected to the first gearbox RI2, which, in turn, is mounted on the drawbridge PS; moreover, the drawbridge PS is connected to two articulated joints SN1, SN2 mounted on the respective shafts AL1, AL2, so that the second gearbox RI1 rotates the first shaft AL1, which rotates at the same angular speed of the second shaft AL2 through the connecting rod TR.

Thus, the rotation of the shaft AL1 through the gearbox RI1 leads to the displacement of the hinges SN1, SN2, which, in turn, move the drawbridge PS and the plate C1 in series, while the gearbox RI2 causes the plate C1 to rotate and then the body BB of the machine and the whole machine (see ., in particular, Fig.6, 7, on which the slab C1 is in the initial position, and Fig.15, 16, on which the slab C1 moves in the vertical direction by the amount H for contact with the cement screed).

The articulated arm CC is able to move the adjusting rotary device DD and the attached tool EE in a straight line GG that is parallel to the line HH, the latter connecting the hinges J, K that connect the articulated arm CC to the frame BB of the machine (Figs. 13-14).

The movement of the articulated lever CC, starting from the initial position, in accordance with which the dimensions of the lever CC of the control rotary device DD and the tool EE, describe the cylinder M, which includes the entire machine (Figs. 8-9), allows the tool EE to travel along the line GG, which is equal to the distance X + Y, moving the weight of the tool EE, the adjusting rotary device DD and the same articulated lever CC near the center of gravity of the frame BB of the machine (Fig.13-14); the distances X, Y and X + Y are adjustable and in any case the distance X + Y is greater than the entire width U of the frame BB of the machine, while the tool EE is larger than any other mechanical device to support the adjusting rotary device DD (which thus has a width smaller than the overall dimensions of the tool EE by at least Z).

In addition, the articulated arm CC is formed by two parallelograms having sides E, L, N, O and P, Q, R, S, respectively, where the lengths of the arms E, L, P and Q are equal, the length O is equal to the length N, the length R is equal to the length S, and the hinges 1, 2, 3 and 4 of the levers E, L, P, Q are placed on the same straight line JJ; under such conditions, the straight line GG passes through the hinges 5 and 6 of the levers P and Q on the rotary device DD, is always parallel to the line HH passing through the hinges J, K of the levers E, L on the frame BB of the machine, and the distance KK between the lines JJ and HH changes when the angle α changes (α is the angle between the lever E or L and the straight line LL perpendicular to the lines JJ and HH), since KK = cos α (see FIGS. 10, 11 and 12 for details).

The cross member T1 of the articulated arm CC is connected to the levers E, L at a distance F from the hinges 1 and 4 of the articulated cross member MM, and the cross member T2 is connected to the levers P and Q at the same distance F from the hinges 2 and 3 of the articulated crossbar MM, while the strut G of the articulated arm the lever CC is connected to the cross member T1 and is equipped with a linear guide YL on which the cross member T2 slides.

The angular change in α between the levers E, L and the straight line LL, which is perpendicular to the connecting cross member T2, displaces the cross member T1 with respect to the hinged cross member MM, and the cross member T1 communicates the cross member T2 through the guide YL with the same offset.

However, since the cross member T2 is connected to the levers P and Q, the same cross member T2 causes an angular displacement on said levers P and Q, which is equal to the indicated angle of change α; in fact, the angular movement by the predetermined angle α of the levers E, L causes the same angular movement by the same angle α of the levers P and Q, and therefore, the straight line DD is spatially parallel to the line HH (whereas the plane containing the straight line HH is parallel to the surface NN contact track AA on cement screed).

Finally, the angular movement of the levers E, L is created by the angular movement of the rod TR, which is connected with the cross member T3 of the articulated arm CC, said cross member T3 is parallel to the cross members T1 and T2, and the articulated cross member MM; since the angular movement rod TR is driven by a gear motor, the movement of the entire articulated lever CC can be stopped in any position, including a useful position that meets the conditions regarding the starting position and the total weight of the tool EE of the adjusting rotary device DD and the lever CC next to the center of gravity of the BB machine frame.

The adjusting rotary device or DD device provides continuous control of the height of the EE tool according to a plane formed by a laser projector of a known type, and the accuracy of the plane realized by said continuous height control is such that it does not significantly affect the continuity of the cement screed, despite that the concrete machine is capable of performing more related activities.

Altitude control is performed by using at least 3 SE sensors located on the same PR plane and oriented, separated by 120 ° from each other, which are able to receive the radiation generated by the laser source coming from any direction (as shown in detail in FIG. 20 -21-22).

Since conventional type laser projectors create a plane that has a different thickness (from 2 to 10 mm), depending on the distance between the laser source and the reading point (in contrast to the ideal plane, which should have zero thickness), the adjusting rotary device DD allows you to achieve significant levels of accuracy (of the order of tenths of a millimeter) for the implementation of the base of the floor (for the implementation of the base of the floor you can not accept deviations of 2-10 mm between many points that are adjacent and / or located nearby with each other) using the aforementioned sensors SE.

In fact, each SE sensor measures a change in the intensity of the laser radiation from the thickness of the plane created by the known laser projector, and the radiation intensity diagram V as a function of the height W has a shape that is detected instrumentally.

Therefore, by analyzing the emission peak and by developing a calculation system capable of calculating the two semi-regions of the AR1, AR2 peak, it is possible to obtain a direction in which the SE sensor will be moved by calculating the height variable W (responsive to the radiation peak), assuming that AR1 = AR2, and taking into account the fact that the intensity V of the radiation, the direction of motion of the sensor SE and the variable W of the height appear in the integral calculation of the regions AR1 and AR2.

Thus, the system does not depend on the thickness of the radiation plane created by the laser, nor on the intensity of the laser radiation.

Thus, the microprocessor control system processes the information from the SE sensors and generates a command to activate the MT motor of the rotary device DD to adjust the continuous height so that the tool EE performs the provided work and is able to create a cement screed that is perfectly flat.

In particular, the MT motor rotates the worm screw VI, which rotates inside the spiral CH, creating a displacement of the housing PP with respect to the support QQ; the housing PP is connected through the middle part of the housing RR and the spindle SS with the tool EE, while the support QQ is an integral part of the end hinges 5 and 6 of the levers P and Q on the frame of the rotary device DD (Fig.17-18-19). Consequently, the offset of the tool EE always refers to the NN plane of contact between the AA tracks and the cement floor screed.

Said cement screed is thus essentially made using the following method.

First, a laser of a known type, equipped with a support, is positioned at a predetermined height and guided in accordance with the desired plane where the cement screed will be made, also in accordance with the plane determined at the construction site.

Further, the concrete machine according to the present invention through a milling operation performed by combining the speed of the rotary tool EE, rotating it in the opposite direction and shifting the articulated arm CC, as well as by continuously monitoring the height of said tool EE, which is performed by the adjusting rotary device DD, is able to create a plane always parallel to the control plane previously determined by the laser source.

The rotational speed of the EE tool, which is programmable in accordance with the invention, creates a relative speed between the specified EE tool (rotary cutting device) and the cement screed so as to obtain a machined surface whose accuracy is extremely higher than that which could be obtained by manual or mechanical tampering operation.

Therefore, using the machine according to the invention, the implementation of parallel beacons, which allow to create a continuous plane in accordance with the prior art, is not necessary, just as there is no need to distribute the mixed material in the beacons, since the filling operation is replaced by simply feeding the mixture to the cement screed in required quantities.

Moreover, the milling operation performed by the concrete-finishing machine replaces the conventional floor leveling operation, thereby greatly improving the accuracy of the flatness of the cement screed.

Finally, since using the machine in accordance with the invention, the finishing operation is performed simultaneously with the milling operation, and they always provide continuous control in determining the plane, it seems possible to completely avoid all inaccuracies resulting from a mechanical or manual finishing operation; in addition, the geometry of the cutting device creates torque torques, the resultant of which create localized pressing of the cement screed, while simultaneously displacing the mixed material during the processing of the cement screed.

The invention conceived in this way allows for numerous modifications and variations, all of which fall within the scope of the attached claims; also, all parts can be replaced by other elements that are technically equivalent, and finally, the materials used, provided that they are compatible with a specific application, as well as measurements, can be any in accordance with the requirements and in accordance with the prior art.

Where the aforementioned features and methods in any claim are accompanied by reference numerals, these reference numerals were included for the sole purpose of increasing understanding of the claims and, accordingly, such reference numerals do not limit the understanding of each element that is identified as an example by such reference numerals positions.

Claims (8)

1. A concrete finishing machine for leveling the floor, comprising a support frame or body (BB), support and transport means (AA) of the frame (BB) in at least two directions, connected to the specified frame or body (BB), and support and transport means (CC) of at least one milling device (DD), which are also attached to said frame or housing (BB), wherein said milling device (DD) contains at least one rotary tool (EE) as an end part designed for in leveling and smoothing the base of the floor to obtain a machined surface with the possibility of placing at least one type of covering surface on it, where said support and transport means (CC) of said milling device (DD) comprise at least an articulated lever (CC), which can move the specified device (DD) for milling along the first line (GG), which is parallel to the second line (HH), connecting at least two first swivel joints (J, K) that connect the specified w a pivot arm (CC) with a frame or body (BB) of the machine in a direction substantially perpendicular to the direction of movement of said frame (BB), wherein the concrete finishing machine is characterized in that said pivot arm (CC) consists of two parallelograms connected by a common arm ( N) where
- the first parallelogram contains four levers (E, L, N, O), while the first lever (O) runs along the specified second line (HH) and connects the specified at least two first articulated joints (J, K), the second and third the levers (E, L) are parallel to each other and connected to the frame (BB) by means of the at least two first articulated joints (J, K), and the fourth lever (N) extends along the third line (JJ), while the fourth lever (N) is the indicated common lever (N) between two parallelograms,
- the second parallelogram contains four levers (N, P, Q, R), while the first lever (N) is common to the specified fourth lever (N) of the first parallelogram, and which, therefore, also runs along the specified third line (JJ) while the second and third levers (P, Q) are parallel and extend from the specified third line (JJ) and the fourth lever (R),
- said second and third levers (E, L) of said first parallelogram are connected to said common lever (N) by means of corresponding articulated joints (1, 4), and / or
- said second and third levers (P, Q) of said second parallelogram are connected to said common lever (N) by means of corresponding articulated joints (2, 3),
and where the distance (KK) between the specified second and third lines (HH, JJ) in the direction (LL) perpendicular to the plane of movement of the machine changes by an angle (α) between the specified second and third levers (E, L) of the first parallelogram and the specified direction (LL). 2. Concrete-finishing machine according to claim 1, characterized in that in the initial position, said articulated lever (CC), said milling device (DD) and said rotating tool (EE) have overall dimensions that describe the cylinder (M) into which the machine is on. 3. Concrete-finishing machine according to any one of the preceding paragraphs, characterized in that said rotary tool (EE) covers a distance along said first line (GG) equal to a predetermined value (X + Y) that is greater than the total width (U) of said frames or enclosures (BB). 4. Concrete-finishing machine according to claim 1 or 2, characterized in that the said rotating tool (EE) has overall dimensions larger than the overall dimensions of the specified device (DD) for milling. 5. Concrete-finishing machine according to claim 1 or 2, characterized in that said articulated arm (CC) comprises at least one first cross member (T1) to which at least two first arms (E, L) are attached at a predetermined distance (F) from the hinge cross member (MM), and at least one second cross member (T2) to which at least two second arms (P, Q) are attached at a specified predetermined distance (F) from the specified hinge cross member (MM) wherein said articulated cross member (MM) is perpendicular to said optional fourth line (LL). 6. Concrete-finishing machine according to claim 1 or 2, characterized in that said articulated arm (CC) comprises at least one vertical rod (G), which is connected to said first cross member (T1) and which comprises a linear guide (YL), along which the indicated second cross member (T2) moves. 7. Concrete-finishing machine according to claim 1 or 2, characterized in that said first cross-member (T1) moves under operating conditions of the machine at a predetermined angle in accordance with said articulated cross-member (MM), and said angular change of the same predetermined value is transmitted from said first cross member (T1) to said second cross member (T2) through said linear guide (YL), said second cross member (T2) being able to provide angular displacement of at least two of said levers (P, Q), respectively corresponding to the indicated angular change (α) so that said first line (GG) is parallel to said second line (HH) and a plane containing said second line (HH) is parallel to a contact plane (NN) between said support and transport means (AA ) machines and the base of the floor. 8. Concrete-finishing machine according to claim 1 or 2, characterized in that said articulated arm (CC) is connected to at least one third cross member (T3), which is parallel to said articulated cross member (MM), as well as to said first cross member (T1 ) and said second cross member (T2), and which is connected to an angular displacement rod (TR), which is driven by a device to achieve the initial position of said articulated arm (CC) and / or to move the entire weight of said articulated arm (CC) and said rotationally Osya tool (EE) adjacent to the center of gravity of said frame or housing (BB) of the machine.

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