RU2343414C1 - Level - Google Patents

Abstract

FIELD: physics; measurement.

SUBSTANCE: level containing laser source, ring base including cantilever; case through the hole formed from its one side, tripod-borne rigidly connected to platform, from the other side the case includes two opposite angular through openings and one horizontal through cut. The level contains measuring scales, the first scale is supported. Two measuring scales are mounted on straight portion of the cantilever. Invention refers to construction and can be used for vertical and horizontal surfacing operations prior to plastering, flooring, etc. Invention meets the challenges as follows: improved performance of level due to possibility to use it for surface verticality and perpendicularity testing, as well as for testing of surface horizontal position. Besides declared level can be applied for vertical, horizontal and angular surfacing operations.

EFFECT: improved performance of level.

6 cl, 5 dwg

Description

The invention relates to construction and can be used when performing work on the alignment of vertical and horizontal surfaces before plastering, laying floors, etc.

Known level according to the patent of the Russian Federation No. 2171449 for the invention "Level", containing a housing in which the laser and level are located. The housing is connected to the stand through the axial system and has the ability to rotate. The stand has three adjusting screws and a horizontal dial. A cylindrical lens with a rotator and a vertical limb is mounted on the end surface of the housing at the laser output. In the known level, it is possible to horizontally scan the beam in a plane.

A disadvantage of the known level is the limited area of its use - only for determining slopes and checking the verticality and perpendicularity of building structures.

The problem solved by the invention is the expansion of the functionality of the level due to the possibility of its use both to check the level of verticality and perpendicularity of the surfaces, and to check the level of horizontal surfaces. In addition, the inventive level allows it to be used in the production of work on the alignment of vertical and horizontal surfaces, angles.

The problem is solved in that in the level containing the laser source installed in the housing, according to the invention, the laser source is made in the form of a laser builder of vertical and horizontal light planes, the level contains a base made in the form of a ring, a console mounted on the base with the possibility of rotation around axis of rotation coinciding with the central axis of symmetry of the base, while the console contains two parallel rectilinear sections, a platform is installed on the console with the possibility of movements along its straight sections, the housing through an opening made on one side of it is mounted on a tripod rigidly connected to the platform, on the other hand, two inclined through slots opposite each other are made at an angle of 90 ° with respect to each other and providing the transmission of the light beam in the form of a vertical light plane, and one horizontal through slot, while the laser is installed between the slots in such a way as to ensure the passage of the light beam in the form of a vert cial light through the inclined plane through slits or horizontal light plane through the horizontal slot level comprises measuring scales, the first measuring scale formed on a tripod, two measuring scales formed on straight sections console.

It is advisable to carry out the fourth measuring scale along the perimeter of the base.

In the housing with the possibility of transmitting a vertical light beam from the laser, a third inclined through slot can be made located in the middle between the first two through inclined slots at an angle of 90 ° to them.

In the housing with the possibility of transmitting a horizontal light beam from the laser, additional horizontal through-cuts can be made.

The base can be installed on at least three screws with the ability to adjust the position of the base relative to a horizontal surface.

The console can be connected to the base by means of a quotation screw, which provides control of the rotation of the console relative to the base.

At the heart of all modern laser levels is a laser LED, which is a point source of light. Separately from the device, the LED can be correlated with a laser pointer or a laser direction indicator. Using a laser LED in conjunction with a variety of mechanical and optical-electronic devices, they achieve the possibility of building directions and planes, as well as bringing them to the horizon or other working position. All laser levels can be combined into two subgroups: direction builders, plane builders (www.feslaser.ru/usage/). The invention uses a laser level, which is a static plotter of planes (vertical and horizontal). In static plane builders, the laser beam is stationary and deployed into a plane. The laser light beam in these devices is stationary and deployed into the plane with a cylindrical lens. The devices are equipped with compensators with magnetic damping, which allows you to automatically set horizontal and vertical planes. When projecting onto an obstacle, static plane builders form a visible line. The PLS360 laser level simultaneously with a horizontal plane builds two mutually perpendicular vertical planes. The apparent line length of such devices is determined by the sweep angle of the laser beam. At a large sweep angle, the vertical planes intersect at the zenith point, forming a cross whose center is above the instrument’s standing point. All devices of this group can be mounted on a tripod, suspended on the wall, mounted on the floor. The scope is wide enough. It includes almost all types of work performed by a rotational plane builder with a visible range of the laser beam when working indoors. At the same time, the possibility of simultaneously constructing several planes increases the usability and scope of these devices. The construction of a “picture” of intersecting lines makes it convenient to use these devices in the manufacture of tile work, the breakdown of working horizons and mounting axes of vertical structures. Devices are light in weight and small in size; they are well-deservedly popular among room designers, fitters of plumbing and other equipment. They are widely used in the installation of communications communications, electrical wiring and even furniture. The use of instruments is limited by the scanning angle of the laser beam and the laser power.

In the claimed invention can be used laser projection levels PLS360 and PLS360E (www.feslaser.ru/usage/), which are used as a geodetic instrument and can rightfully be called universal devices for setting the reference horizontal and / or vertical laser plane. They are very convenient for geodetic work, requiring the task of a single horizontal level over a large area. The most typical examples are pouring screeds and foundations, installing floors and suspended ceilings, marking fasteners of various designs, leveling and leveling the surface, and much more.

One of the design features of the 360 series geodetic instruments is that they “beat off” the horizontal plane by 360 degrees. That is why these geodetic instruments are especially convenient for the above works - they set a single level immediately in the entire room. For example, a rather laborious procedure for setting beacons for pouring screeds is accelerated many times.

The inventive level contains a laser - a laser plotter of vertical and horizontal planes mounted in the housing. The laser emits light rays in the form of vertical and horizontal light planes. The laser level housing has at least two inclined through slots located opposite each other at an angle of 90 degrees relative to each other. The slots are designed to transmit a vertical light beam, which, passing through these vertical slots, forms a vertical plane projecting onto two opposite vertical surfaces. The location of these slots at an angle of 90 degrees with respect to each other is necessary so that light rays in the form of vertical light planes, passing through the corresponding inclined slots, intersect at the zenith point - at a point located exactly above the central axis of the laser. The location of these slots opposite each other is necessary so that the vertical light rays passing through them form a single vertical light plane. This will ensure the formation of a single vertical light plane, allowing you to control the verticality of the entire machined vertical surface (wall) from one wall to another. The housing may contain a third vertical through-slot, located between the first two and located at an angle of 90 degrees relative to them. This slot is optional and provides the ability to control perpendicularity in the presence of bindings to mutually perpendicular surfaces. Thus, inclined through-cuts are designed to pass a laser beam through them in the form of a vertical light plane with the possibility of projecting this beam onto obstacles (surface of walls, floor and ceiling).

The housing also contains a horizontal through slot designed to transmit a horizontal light beam in the form of a horizontal plane with the possibility of projecting this beam on obstacles - the surface of the walls. To increase the area covered by a horizontal beam (in the form of a horizontal light plane), horizontal slots can also be made along the perimeter of the casing, ensuring the transmission of the laser light beam.

The housing is mounted through the hole made in it, on a tripod, which is rigidly connected to the platform. The housing is fixed relative to the tripod, for example, by means of a clamping screw through an opening made in the housing. The tripod has a measuring scale.

The level contains a base in the form of a ring having two concentric sections - external and internal. The level of the outer section is located above the level of the inner section. A console is installed on the base on its inner section, having two parallel rectilinear sides of equal length, and two arcuate sides located between them. The arched sides are formed by arcs that are concentric with respect to the inner and outer sections of the base and having a diameter equal to the outer diameter of the inner section of the base (or the inner diameter of the outer section). The console is mounted on the inner section of the base with the possibility of rotation around its axis of rotation, while the console has the ability to move along the inner section of the base as along the guides. A 360-degree measuring scale is plotted around the perimeter of the outer (protruding) portion of the ring. The base is mounted on at least three supports. In order to align the position of the level relative to the surface, it is advisable to carry out supports with the possibility of changing their size in height in order to compensate for surface irregularities, for this purpose the supports can be made in the form of screws.

The rectilinear sides of the console are also divided into two longitudinal sections located at different levels, the inner sections and the outer ones protruding above the inner sections (i.e., the outer longitudinal sections are located above the inner longitudinal sections). On the inner longitudinal sections, a platform is installed with the ability to move along the internal longitudinal sections as along the guides. Measuring scales are applied on the outer longitudinal sections. Marks corresponding to zero marks on the console (on the measuring scales) are also marked on the sides of the platform, marking the initial position of the platform relative to the console. Those. zero marks on the console and on the platform are visually pairwise combined.

A measuring scale on a tripod is used to determine the level of horizontal surfaces. A horizontal through-slot allows transmission of a horizontal light beam, but the plane of the beam is of limited size (determined by the size of the through-horizontal slot). To increase the inspection sweep area, for example, when leveling horizontal surfaces, it is possible to rotate the console with the platform relative to the base (along the inner ring section), and to measure the rotation angle, a measuring scale is provided on the outer ring section of the base. The axis of rotation of the console and the vertical longitudinal central axis of the laser coincide. Thus, when conducting work on leveling horizontal surfaces, the following structural elements of the level work - a horizontal laser beam, a horizontal slot in the body, a console rotating relative to the measuring scale on the outer annular section of the base.

When aligning the vertical surfaces, the light beam is transmitted (in the form of a vertical plane) through two vertical through slots, which allow the light beam to be projected onto two opposite vertical surfaces, which makes it possible to control their level of verticality.

The ability to control the angle between two adjacent vertical surfaces (or the ability to build an adjacent vertical surface at a given angle with respect to the existing wall) is provided by an annular measuring scale on the outer section of the level base.

The measuring scale on the console is designed to control the level of “overflow” of vertical surfaces intended for processing (leveling, plastering).

The feature of controlling the level of horizontal surfaces is determined by the fact that when leveling horizontal surfaces, the highest point on the surface being machined is determined. This point will be only one. The level of excess ("overfill") of this point is determined by the height of the location of this point. Further, having determined the height of a given point on a measuring scale on a tripod, setting the level of the horizontal light beam (light plane) in relation to this point, the horizontal surface is aligned with the set level of the light beam. Those. To align horizontal surfaces, only the vertical measuring scale on a tripod is actually used.

The peculiarity of processing (leveling) of vertical surfaces is that in the presence of adjacent vertical surfaces or any bindings (for example, to the axis of the building), the “overgrowing” of the surface must be controlled both with respect to horizontal surfaces (floor and / or ceiling), and relatively adjacent vertical surfaces. To do this, on the vertical surface to be machined determine two "littered" points. At the same time, by moving the platform along the console along the measuring scales of the console and simultaneously turning the console with the platform relative to the annular measuring scale, the user is able to optimally set the vertical light beam (vertical light plane) relative to the two “littered” points, thus setting the level relative to which vertical surface will be processed.

An additional inclined through-slot, located at an angle of 90 degrees with respect to the first two, is used, for example, to control perpendicularity in the presence of appropriate bindings (two adjacent vertical surfaces between which it is necessary to observe an angle of 90 degrees).

In the level, a so-called quotation screw can be provided, with the help of which a controlled rotation of the console by a small angle is provided, which is important when processing large surfaces, because turning the console a small angle will cause a significant shift in the projection of the beam on the surface over a long distance.

The base of the level can be installed on at least three screws, which makes it possible to adjust the position of the level on uneven horizontal surfaces.

The inventive level has significant advantages compared with those known for the following reasons:

- the level allows you to control both the vertical and horizontal surfaces, as well as control the angle between two adjacent vertical surfaces or relative to any bindings;

- the level provides the possibility of using together with it various special building laths (rules, etc.), the position of which is controlled at the level set by the level;

- the level is simple in design and reliable in operation, as it lacks structural elements that are subject to breakdowns or significant loads during operation.

The inventive level is illustrated by drawings.

Figure 1 shows the inventive level, top view.

Figure 2 shows the inventive level, side view.

Figure 3 shows the installation diagram of the inventive level when aligning horizontal surfaces.

Figure 4 shows a top view of the installation diagram of the inventive level when leveling horizontal surfaces.

Figure 5 shows the installation diagram of the inventive level when leveling vertical surfaces.

The level contains a laser 1, which is a laser plotter of vertical and horizontal planes, - a laser projection level PLS360 (www.feslaser.ru/usage/), housing 2, base 3, console 4, platform 5. Housing 2 through hole 6, made with one side of the housing 2 is mounted on a tripod 7, rigidly connected to the platform 5. The housing 2 is made with a cavity 8, in which the laser is installed 1. In the housing 2 there are three through inclined slots 9 and horizontal slots 10. The laser 1 is mounted in the cavity 8 so in such a way as to ensure transmission e vertical light beam (in the form of a vertical light plane) through the slots 9 and the transmission of a horizontal light beam (in the form of a horizontal light plane) through the slots 10.

The base 3 is made in the form of a ring, divided along the perimeter into two sections: the outer section 11 and the inner section 12 located at different levels, the outer section 11 is located above the section 12, thus, in cross section the base has a Z-shape.

The console 4 is mounted on the inner section 12 of the base 3 with the possibility of rotation relative to the base 3. The axis of rotation 13 of the console 4 coincides with the central axis of symmetry of the base 3, which, in turn, coincides with the central longitudinal axis of symmetry of the laser 1. For ease of installation of the console 4 it is made with two opposite arcuate sides 14, the radius of which coincides with the large radius of the section 12 of the base 3. That is, the console 4 is installed on the base 3 by means of arcuate sides 14 on the plot 12, which ensures the reliability of the installation of the console 4 on the base 3 and the possibility of its rotation relative to the base 3 along the plot 12 as on the guides without the use of other special structural elements.

Between the arcuate sides 14 of the console 3 are two parallel rectilinear sides 15, also having a Z-shape in cross section. The straight sides 15 have two adjacent longitudinal sections located at different levels relative to each other, the outer section 16 is located above the inner section 17. On the inner section 17, a platform 5 is installed, which can be moved along the sides 15 along the section 17 as guides.

The base 3 is mounted on three screws 18, providing an adjustment of the position of the base 3 on a horizontal surface in case of unevenness. The housing 2 is pressed against the tripod 7 by means of a screw 19.

The level contains measuring scales: on a tripod - scale 20, on the perimeter of the base in section 11 - scale 21, along the straight sides 15 of the console 4 in sections 16 - scale 22. On the sides of the platform 5, make marks that coincide with zero marks on the scales 22 ( scales 22 are identical, i.e., the corresponding divisions equally identify the distance from the division to the surface relative to which the measurement is carried out). When combining zero marks, the axis of the level and the base are combined.

Work with the inventive level is as follows.

When aligning horizontal surfaces, such as floors (Fig.3, 4), the level is used as follows.

The level is installed at the point where the maximum circular view of the horizontal surface to be processed is provided 23. The laser 2 is turned on to project the horizontal light beam 24, which is a horizontal light plane. Next, by measuring with a ruler, they find the highest point “X” with respect to the level of the horizontal light beam 24. Determine the excess b level of the location of the point "X" in relation to the zero mark on the scale 20. Lift the housing 2 with the laser 1 on a tripod 7 by the value of b from the zero level. The screw 2 is fixed to the housing 2 relative to the tripod 7 at a given height. Next, a solution of 25 is applied to the horizontal surface 23, from which the paths are formed, the first path being formed along the wall, the next one parallel to the first at a certain distance, depending on the length of the leveling rail 26. The paths are formed so that their height exceeds the required height of the floor screed by 10 -50 mm. Further on the tracks from above, guide rails 27 are installed parallel to each other, the level of arrangement of which is controlled relative to the light beam 24 (light plane). A solution 25 is applied between the guide rails 27 and the rail 26 aligns the surface 23 with a level set relative to the light beam 24. The usability of the level is manifested in the fact that the guide rails 27 are installed relative to the horizontal beam 24 and their installation level is clearly defined along their entire length, those. by completing the guide rails on the rails 27 along which the leveling rail 26 will slide, the horizontal alignment of the surface to be leveled will be strictly observed, while the use of level beacons, the installation of which is a separate complex technological process, is excluded, while the horizontal level accuracy is much lower than with the use of the inventive level.

When aligning vertical surfaces, such as walls, work with the inventive level is as follows (figure 5).

The level is installed in the right or left corner of the processed wall 28, while the outer edge of the base 3 should be pressed against the wall 28. The distance from the wall 28 to the projection of the vertical light beam 29 (vertical light plane) onto the wall 30 adjacent to the wall 28, next to which a level is installed, - the distance "a", which is determined by the diameter of the base 3. Next, by circular rotation of the console 4 relative to the base 3, we set the position of the vertical light beam 29 so that in the opposite corner from the wall 28 the distance "a '" about beam 29 was equal to the distance "a". Then, using a ruler, we look at the vertical line above the level and look for a point on the wall 28 located closer to the vertical beam 29 than point “a”. If such a point is found, denote it by the point "b". We determine the value of "y" = "a" - "b". We move the platform 5 along the scales 22 to the distance "y" from the zero mark. Next, look at the opposite edge of the wall and find the point “b ¹ ” closest to the beam 29, after which by turning the console 4 relative to the scale 21 we move the beam 29 to the distance “a” at the point “b ¹ ”. Next we look at the entire wall, if we find an excess on the wall relative to point “a”, then we find the distance “d” = “a” - “b” + “c”, where c is the layer of leveling plaster (in accordance with the technical requirements). We move the beam on a scale of 22 to a distance of "d".

At the next stage of work, guide rails are installed with spacer units (for example, according to the utility model patent No. 60108). Provide a distance from the beam 29 to the end surface of the leveling rail 30, equal to "a". The leveling rails 30 are set so that the beam 29 is visually aligned with the line of the rails, the rails 30 are fixed using spacer units. In order that the rails 30 do not close the projection of the beam 29, the installation of the rails should begin with the farthest from the level guide rail 31.

Claims (6)

1. A level containing a laser source installed in the housing, characterized in that the laser source is made in the form of a laser builder of vertical and horizontal light planes, the level contains a base made in the form of a ring, a console mounted on the base with rotation around the axis of rotation, coinciding with the central axis of symmetry of the base, while the console contains two parallel straight sections, a console is installed on the console with the ability to move along its straight lines kov, the case through an opening made on one side of it is mounted on a tripod rigidly connected to the platform, on the other hand, in the case there are two inclined through slots opposite each other, arranged at an angle of 90 ° with respect to each other and ensuring the transmission of the light beam in the form of a vertical light plane, and one horizontal through slot, while the laser is installed between the slots in such a way as to ensure the passage of the light beam in the form of a vertical light plane through the slope nye through slits or horizontal light plane through the horizontal slot level comprises measuring scales, the first measuring scale formed on a tripod, two measuring scales formed on straight sections console. 2. The level according to claim 1, characterized in that the fourth measuring scale is made along the perimeter of the base. 3. The level according to claim 1, characterized in that in the housing with the possibility of transmitting a vertical light beam from the laser, a third inclined through slot is made located in the middle between the first two through inclined slots at an angle of 90 ° to them. 4. The level according to claim 1, characterized in that in the housing with the possibility of transmitting a horizontal light beam from the laser, additional horizontal through slots are made. 5. The level according to claim 1, characterized in that the base is installed on at least three screws with the ability to adjust the position of the base relative to a horizontal surface. 6. The level according to claim 1, characterized in that the console is connected to the base by means of an adjusting screw, providing control of the rotation of the console relative to the base.

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