阅读说明：本技术 用于排齐电梯设备的导轨的排齐装置和方法 (Alignment device and method for aligning guide rails of an elevator installation ) 是由 阿克塞尔·胡泽曼 克里斯蒂安·史都德 伊莱萨·奥尔泽克 于 2020-03-13 设计创作，主要内容包括：介绍了一种用于排齐电梯设备(1)的导轨(13)的排齐装置(3)。排齐装置(3)具有呈轨架下部件(19)和轨架上部件(27)形式的两个轨架部件(17)以及至少第一和第二移位元件(37)。轨架下部件(19)被构造用于固定在电梯竖井(7)的竖井壁(15)上。轨架上部件(27)被配置用于对电梯设备(1)的固定于其上的导轨(13)加以保持。轨架下部件(19)和轨架上部件(27)分别具有连接区域(33、35),并且可以通过各自的连接区域(33、35)彼此固定。移位元件(37)被配置以用于,使轨架下部件(19)相对于轨架上部件(27)移位。每个移位元件(37)既与轨架下部件(19)的连接区域(33)相配合,又与轨架上部件(27)的连接区域(35)相配合。移位元件(37)能够以绕转动轴线(39)转动,并且与轨架部件(17)中的至少一个相对于转动轴线(39)偏心地、以贴靠在轨架部件(17)的沿侧向彼此相对的贴靠面上的方式相配合。(An alignment device (3) for aligning guide rails (13) of an elevator installation (1) is described. The alignment device (3) has two rail parts (17) in the form of a rail lower part (19) and a rail upper part (27) and at least a first and a second displacement element (37). The rail lower part (19) is designed for fastening to a shaft wall (15) of an elevator shaft (7). The rail frame upper part (27) is configured to hold a guide rail (13) of the elevator device (1) fixed thereon. The rail lower part (19) and the rail upper part (27) each have a connecting region (33, 35) and can be fixed to one another by means of the respective connecting region (33, 35). The displacement element (37) is configured to displace the rail lower part (19) relative to the rail upper part (27). Each displacement element (37) cooperates with both a connection region (33) of the rail lower part (19) and a connection region (35) of the rail upper part (27). The displacement element (37) can be rotated about a rotational axis (39) and engages at least one of the rail parts (17) eccentrically with respect to the rotational axis (39) in such a way that it bears against laterally opposite bearing surfaces of the rail parts (17).)

1. An alignment device for aligning guide rails (13) of an elevator installation (1), wherein the alignment device (3) has:

two rail parts (17) in the form of a rail lower part (19) and a rail upper part (27); and

at least a first and a second displacement element (37);

wherein the content of the first and second substances,

the rail lower part (19) is configured for fixing on a shaft wall (15) of the elevator shaft (7);

the rail frame upper part (27) is configured to hold a guide rail (13) of the elevator equipment (1) fixed on the rail frame upper part;

the rail lower part (19) and the rail upper part (27) each have a connecting region (33, 35) and can be fixed relative to one another by means of the respective connecting region (33, 35);

the displacement element (37) is configured to displace the rail lower part (19) relative to the rail upper part (27);

each of the displacement elements (37) cooperates with both a connecting region (33) of the rail lower part (19) and a connecting region (35) of the rail upper part (27), the displacement elements (37)) being rotatable about a rotational axis (39) and cooperating with at least one of the rail parts (17) eccentrically with respect to the rotational axis (39) in such a way that they bear against laterally opposite bearing surfaces (41 ', 41 "') in the connecting regions (33, 35) of the rail parts (17).

2. The alignment device of claim 1,

round holes (43 ') are formed in the connecting regions (33, 35) of a first of the rail parts (17), and oblong holes (45' ) are formed in the connecting regions (35, 33) of a second of the rail parts (17),

the displacement element (37) has a first engagement region (47) which is cylindrical and centered on the axis of rotation (39) and a second engagement region (49) which is cylindrical and arranged eccentrically about the axis of rotation (39),

the displacement element (37) is arranged with a first engagement region (47) extending through a circular hole (43 ') of the first rail part (17) and with a second engagement region (49) extending through a long hole (45' ) of the second rail part.

3. The alignment device according to claim 2, wherein a plurality of circular holes (43) are configured for each displacement element (37) in the connection region (33, 35) of a first of the rail parts (17), which circular holes are preferably arranged in a straight line.

4. Aligning device according to one of the preceding claims, wherein the first displacement element (37 ') cooperates with at least one of the rail parts (17) eccentrically with respect to the axis of rotation (39) in such a way as to abut against first mutually parallel contact faces (41 '), and the second displacement element (37 ") cooperates with at least one of the rail parts (17) eccentrically with respect to the axis of rotation (39) in such a way as to abut against second mutually parallel abutment faces (41"), the first abutment faces (41 ') extending in a first direction and the second abutment faces (41 ") extending in a second direction, wherein the first and second directions are not parallel to each other.

5. The alignment device of claim 4, wherein the first and second directions are orthogonal to each other.

6. The alignment device according to any one of the preceding claims, further comprising a third displacement element (37 "').

7. The alignment device according to claim 6 when dependent on one of claims 4 and 5, wherein the third displacement element (37 "') cooperates with at least one of the rail parts (17) eccentrically with respect to the axis of rotation (39) in such a way as to abut against mutually parallel third abutment surfaces (41"'), the first and third abutment surfaces (41 ', 41 "') extending in mutually parallel directions.

8. Aligning device according to any one of the preceding claims, wherein the connection area (33, 35) is plate-shaped.

9. The alignment device according to any one of the preceding claims, wherein each displacement element (37) has a screw head (53), a tool (73) being able to cooperate with the screw head (53) in order to rotate the displacement element (37) about its axis of rotation (39).

10. The alignment device according to any one of the preceding claims, wherein the displacement element (37) has a thread (51) centered on the axis of rotation (39).

11. The alignment device according to any one of the preceding claims, further comprising actuation means (65), the actuation means (65) being configured for rotating the displacement elements (37) about their respective axes of rotation (39) independently of each other.

12. The alignment device according to claim 11, wherein the actuating means (65) has at least one electric motor (67) for rotating the displacement elements (37) about their respective rotation axes (39) independently of each other.

13. The alignment device according to claim 11 or 12, wherein the actuating means (65) has a controller (69) for controlling the rotation of the displacement element (37) such that the rail upper part (27) is moved towards the reference position relative to the rail lower part (19).

14. An elevator installation (1) with an elevator car (5) guided in its vertical movement by guide rails (13) and an alignment device (3) according to one of the preceding claims, wherein the rail frame lower part (19) is fixed to a shaft wall (15) and the guide rails (13) are fixed to a rail frame upper part (27).

15. A method for aligning guide rails (13) of an elevator installation (1), wherein the guide rails (13) are fixed to a rail frame upper part (27) of an aligning device (3) according to any one of claims 1 to 12, wherein the method comprises:

the guide rails (13) are aligned by moving the rail upper part (27) relative to the rail lower part (19) of the alignment device (3) by rotating at least one of the displacement elements (37) of the alignment device (3).

Technical Field

The invention relates to an alignment device for aligning guide rails of an elevator installation. The invention also relates to a method for aligning guide rails of an elevator installation and to an elevator installation equipped with such an aligning device.

Background

In elevator installations, the elevator car is usually moved vertically in an elevator shaft between different levels or floors. Usually, the elevator car is guided by one or more guide rails during its displacement movement. The guide rails are anchored to the side walls of the guide shaft. The guide rails must be able to absorb the forces exerted by the elevator car on the guide rails, mainly in the horizontal direction, and to transmit them to the elevator shaft wall. The same guide rails or additional guide rails can be used for guiding one or more counterweights during their displacement movement through the elevator shaft.

In order to be able to guide the elevator car and/or the counterweight accurately, the guide rails must usually be aligned very accurately. Usually, the guide rails should be fixed precisely vertically, i.e. vertically, on the elevator shaft wall. The deviation from the exact positioning or orientation of the guide rails should here be as small as possible, for example less than a few millimeters, on the one hand in order to be able to keep the wear-inducing loads on the components of the elevator installation at a low level when the elevator car and/or counterweight moves and/or to minimize vibrations acting on the elevator car caused by guidance on the guide rails during travel of the elevator car, so that the ride comfort of the elevator installation is improved.

Traditionally, the guide rails are fixed to the wall of the shaft using so-called rail frame parts (brackets). In this case, the rail lower part is usually fastened directly to one of the shaft walls, for example by screwing to a mortise and tenon joint or to a previously cast counterpart. The upper rail member is then mounted on the lower rail member. The guide rail should then be able to be fixed to the rail frame upper part. The two parts can be displaced relative to each other before the rail upper part is firmly fixed to the rail lower part, for example by means of screws. By moving the two rail parts relative to each other, the rail upper part can be brought into a position and/or orientation such that the guide rail mounted or to be mounted thereon can be arranged in the elevator shaft in a desired position.

In the assembly of elevator installations, the rail lower part has hitherto been mounted in place in the elevator shaft, and the rail upper part is then loosely connected to the rail lower part and the guide rail is fixed to the rail upper part. The upper rail part can then be moved laterally, for example by a few millimetres or even a few centimetres, relative to the lower rail part, for example by shaking the rail fixed thereto or hammering it in the desired direction acting sideways on the rail.

WO2018/095739a1 describes a method and an alignment arrangement for mounting or aligning guide rails in an elevator shaft. An arrangement and a method for aligning and fixing elevator guide rails are described in JP2829194 (corresponding to JPH 06024667).

It has previously been difficult to calibrate guide rails in a guide shaft with high precision and/or with experienced installers.

Disclosure of Invention

First of all, there is a need for an alignment device and a method for aligning guide rails of an elevator installation, by means of which the guide rails can be aligned simply and/or with regard to their positioning and/or orientation with a high degree of accuracy. Furthermore, an elevator installation with such an alignment device would be required.

This need may be met by the subject-matter according to one of the independent claims. Advantageous embodiments are defined in the dependent claims and in the following description.

According to a first aspect of the invention, an aligning device for aligning guide rails of an elevator installation is proposed. The alignment device has at least two rail parts in the form of a rail lower part and a rail upper part and at least a first displacement element and a second displacement element. The lower rail part is designed for fastening to a shaft wall of an elevator shaft. The rail-carrier upper part is designed to hold a guide rail of the elevator installation fixed to it. The rail lower part and the rail upper part each have a connecting region and can be fixed to one another by means of corresponding connecting regions. The displacement element is designed to displace the rail lower part relative to the rail upper part. Each displacement element cooperates with both the connection region of the lower rail part and the connection region of the upper rail part, wherein the displacement element is rotatable about an axis of rotation and cooperates with at least one of the rails eccentrically with respect to the axis of rotation in such a way that it abuts against mutually opposite abutment surfaces in the connection region of the rail part.

According to a second aspect of the invention, an elevator installation is proposed, which has an elevator car guided with respect to its vertical movement by guide rails and an alignment appliance according to an embodiment of the first aspect of the invention. In this case, the rail lower part is fastened to the shaft wall and the guide rail is fastened to the rail upper part.

According to a third aspect of the invention, a method for aligning guide rails of an elevator installation is presented, the guide rails being fixed to a rail-carrier upper part of an aligning device according to an embodiment of the first aspect of the invention. The method comprises here aligning the guide rails by displacing the rail upper part relative to the rail lower part of the aligning device by rotating at least one of the displacing elements of the aligning device.

The feasible features and advantages of embodiments of the invention may be mainly, but not exclusively, considered as being based on the idea and insight presented below.

As already indicated in the introduction, the alignment of the guide rails of the elevator installation can be performed simply and/or more accurately, e.g. in the case of assembly or maintenance.

In short, an alignment device is proposed for this purpose, in which two rail parts can be displaced relative to one another by means of two displacement elements designed as eccentrics. The displacement element is thereby associated with two connection regions of each rail part and can be rotated about a rotational axis. In this case, at least one eccentrically designed part of the displacement element bears laterally against a contact surface in the connecting region of one of the rail parts, such that: when the displacement element is rotated about its axis of rotation, the eccentrically designed part of the displacement element pushes the contact surface of the respective rail part laterally and thus its connecting region. The displacement element can be simply and precisely rotated, for example by means of a tool, and the rotary movement can be simply and intuitively converted into a lateral displacement movement of the two rail parts relative to one another.

The two rail parts can be mechanically highly loaded components in order to be able to absorb without damage the forces exerted by the elevator car to be guided or the counterweight to be guided on the guide rails held thereon and to be able to transmit them, for example, to the elevator shaft wall. The rail parts can be made, for example, of metal, in particular steel. Each of the rail members may be one-piece. For example, the rail member may be formed from sheet metal, particularly thick sheet steel.

The rail part can be designed as a rail lower part on the one hand and as a rail upper part on the other hand. The two rail parts may have the same, similar or different design. The lower part of the rail is designed for fixing to the shaft wall of an elevator shaft. The lower part of the rail may be mounted directly on the wall of the shaft. Alternatively, the lower rail member may be secured to the wall of the shaft using other means, such as intermediate members, retainers, etc. For this purpose, the rail lower part can have, for example, a recess through which a screw or other fastening element can extend. In a similar manner, the rail upper part can be configured such that the guide rail of the elevator installation can be fixed and held on the rail upper part. Here, a direct or indirect connection is also possible, and for example recesses can be provided through which screws or similar fixing elements for fixing can be received or accommodated. Based on the names of the rail lower part and the rail upper part, the predetermined configuration of the two rail parts relative to each other cannot be deduced. These designations are used only to distinguish between two rail parts.

Each of the two rail parts has a connecting region. The two rail parts are fixed to each other by means of their two connecting regions. The connecting region has sufficient mechanical strength to be able to absorb and transmit forces acting on the rail part. In particular, the connecting region can be formed integrally with the rest of the associated rail part. For example, the connection region may be a partial region of a metal plate forming the rail member. According to an embodiment, the connection area may be plate-like, i.e. the connection area may extend along a plane. In particular, the rail part can be designed as an angular member, i.e. with an L-shaped cross section. In this case, the connection region can be formed by an arm or a wing of the angle element.

When the two rail parts are fixed to each other, the respective connection areas of the rail parts may extend parallel to each other. This applies in particular to the connection region of the plate-like design. The two connection regions may be directly adjacent to each other, i.e. in contact with each other. Alternatively, an intermediate layer, a complementary member, or the like may be interposed between the two connection regions. The two connecting regions should be designed such that the two rail parts can be displaced relative to one another parallel to the surfaces of their connecting regions.

In order to be able to fix the two rail parts to one another, recesses can be provided in each of their connection regions, through which recesses fixing elements can extend. By means of such a fixing element, the two connection regions can be pressed mechanically against each other or pressed mechanically against each other and thus fixed to each other. For example, screws, bolts, etc. may be used as the fixing elements. For example, the fixation element may directly engage or mate with one of the connection regions via threads or the like. Alternatively, the fastening elements can be equipped with suitable counterparts, such as nuts, cotter pins, snap locks, etc., in order to be able to mechanically press the connecting regions extending between them against one another. In a possible embodiment, the fastening element can also be formed integrally with one of the connection regions or on one of the rail parts. As a further possible configuration, one of the displacement elements can also be designed such that it can also serve as a fixing element as a supplement.

The main task of the displacement element is to be able to move the two rail parts relative to each other. For this purpose, a displacement element is associated with the connecting region of the rail lower part and the connecting region of the rail upper part. The displacement element can be rotated about an axis of rotation. In the assembled state, the axis of rotation is preferably oriented orthogonally to the plane of extension of one of the connection regions.

The displacement element is designed at least in a partial region such that it engages eccentrically with at least one of the rail parts. In other words, when the displacement element is rotated about its axis of rotation relative to the rail part, the side surfaces of the eccentrically formed partial regions of the displacement element bear against the contact surfaces, which are laterally opposite one another, in the connecting region of the rail part. Since the eccentrically formed partial region is displaced laterally on account of the rotation of the displacement element, a lateral force is exerted by its side surface on the contact surface of the respective rail part. Due to the transverse force, the two rail parts are displaced relative to each other.

Finally, a linear displacement of the two rail parts relative to each other can be achieved by a simple and precise rotational movement of the displacement element.

According to a specific embodiment, a circular hole may be formed in the connecting region of the first of the rail members, and a long hole may be formed in the connecting region of the second rail member. The displacement element can have a first engagement region which is cylindrical and centered on the axis of rotation and a second engagement region which is cylindrical and arranged eccentrically around the axis of rotation. The displacement element can then be arranged to extend with a first engagement region through the circular hole of the first rail part and with a second engagement region through the elongated hole of the second rail part.

In other words, a circular hole, i.e., a substantially cylindrical through hole, may be formed in one of the rail members, and at a position corresponding thereto, an elongated hole, i.e., a through hole having an elongated cross section, may be formed in the other rail member. In this case, the inner circumference of the round hole and at least a part of the inner circumference of the elongated hole form an abutment surface, by means of which a transversely acting force can be applied to the rail part or its connection region.

Then, one of the displacement elements may have a first and a second joining region. Both joining regions can be of substantially cylindrical design. The joining zones may have structures close to the surface, such as threads, which, however, have dimensions that are negligible compared to the overall dimensions of the joining zones and represent only minor deviations from the cylindrical shape of these joining zones.

The first engagement area extends centered on the axis of rotation of the displacement element. The cross-section of the first joining region may substantially correspond to the cross-section of the circular hole in the rail upper part connecting region. Thus, the first engagement region may be received within the circular bore and rotated about an axis of rotation therein.

The second engagement region is arranged eccentrically with respect to the axis of rotation. The diameter of the second joining region can correspond substantially to the distance between the mutually opposite contact surfaces, since these are formed by the inner sides of the elongated holes in the connecting region of the associated rail part. Thus, the second engagement region can be accommodated within the elongated hole.

The oppositely directed regions of the surface on the outer circumference of the second joining region bear against opposite contact surfaces of the slot in the connecting region and can exert a force on these contact surfaces in order to displace the associated rail part transversely in a direction transverse to the longitudinal direction of the slot, in which case the second joining region can be displaced in the longitudinal direction of the slot within the slot without a significant force being exerted on the associated rail part.

According to a specific embodiment, a plurality of circular holes may be formed for each displacement element in the connection area of the first rail part. Preferably, the circular holes may be arranged along a straight line.

For example, two, three, four, five or more circular holes may be provided in the connection region of the first rail part for each displacement element. The associated displacement element can be inserted through one of these circular holes. The relative positioning between the first and second connecting regions and thus also between the two rail parts can thus be varied as desired. The circular holes may be arranged adjacent to each other. The circular holes may be arranged adjacent to each other along a line, in particular along a straight line. A distance may be provided between the circular holes. These distances may be greater than, equal to, or less than the diameter of the circular hole. Alternatively, the circular holes may overlap in a straight line, thereby creating a locally variable width slot.

According to one embodiment, the first displacement element can engage with at least one of the rail parts eccentrically with respect to the axis of rotation in such a way that it rests against first mutually parallel abutment surfaces, and the second displacement element can engage with at least one of the rail parts eccentrically with respect to the axis of rotation in such a way that it rests against second mutually parallel abutment surfaces. The first contact surface can extend in a first direction and the second contact surface can extend in a second direction. The first and second directions may be non-parallel to each other, i.e. extend at a non-zero angle to each other. In particular, the first and second directions may extend orthogonal to each other, i.e. at right angles to each other.

In other words, the at least two displacement elements of the alignment device can be eccentrically designed such that the second engagement region of each displacement element, for example, which is eccentrically arranged, cooperates with the contact surface on the connection region of the associated displacement element. In this case, however, the abutment surface cooperating with the first displacement element and the abutment surface cooperating with the second displacement element are not arranged parallel but at an angle to one another.

Accordingly, forces can be applied by the displacement elements via their respective eccentric engagement regions to the respective contact surfaces and thus to the associated rail part in different transverse directions by rotating the respective displacement element. Preferably, the first abutment surface and the second abutment surface are arranged orthogonally to each other.

Due to the orientation of the first and second contact surfaces extending at an angle to each other, a force can be exerted on the first contact surface by rotating one of the displacement elements in a first direction, and a force can be exerted on the second contact surface in a second direction, which is transverse to the first direction, in particular orthogonal to the first direction, by rotating the other displacement element. The rail parts can thus be moved relative to each other in two spatial directions extending perpendicular to each other in a plane parallel to the surface of their connection region.

According to one embodiment, the alignment device may further have a third displacement element.

The third displacement element can be designed identically or similarly to the other two displacement elements and cooperates in the same or similar manner with the connecting region of the rail part. In particular, like the other two displacement elements, the third displacement element can have a first and a second engagement region and extend through additional round holes and elongated holes which are provided for this purpose in the connecting region of the rail part.

By means of the third displacement element, a further force can be applied to the rail parts in order to displace the rail parts relative to each other. These further forces can be guided and used in particular in such a way that the rail parts can be moved not only linearly relative to one another, but also can be changed in orientation relative to one another by a rotational movement.

In this case, according to one embodiment, the third displacement element can cooperate with at least one of the rail parts eccentrically with respect to the axis of rotation, bearing against third bearing surfaces parallel to one another. The first contact surface and the third contact surface can extend for this purpose in mutually parallel directions.

In other words, two oblong holes can be formed in one of the connecting regions of the two rail parts, the inner surfaces of which form the first and third contact surfaces. The two elongated holes can extend in the same direction or in directions parallel to each other in their respective longitudinal directions. Thus, by rotating the first and third displacement elements via their respective eccentrically arranged engagement regions, forces can be exerted on the respective connection regions in mutually parallel directions transverse to the respective first and third abutment surfaces.

Since the two oblong holes are preferably arranged in a mutually offset position with respect to their longitudinal direction, a torque acting on the respective connecting region can be achieved by means of such a force. Due to the torque thus generated, the two rail parts can be reoriented with respect to each other by suitably rotating the first and third displacement elements.

In principle, this can also be achieved if the first and third abutment surfaces are not arranged in a direction parallel to each other. In the case of a first and a third abutment surface arranged in mutually parallel directions, the rotation of the rail frame parts relative to one another can be achieved in a particularly intuitive manner for the skilled person by suitably rotating the first and third displacement elements, which are laterally spaced apart from one another, about their respective axes of rotation.

According to one embodiment, each displacement element has a screw head, with which a tool can be fitted in order to rotate the displacement element about its axis of rotation.

In other words, a structure may be provided at one end of one of the displacement elements with which a tool can be engaged in order to be able to apply a torque to the displacement element about its axis of rotation. For example, the screw head can be designed in a polygonal shape, for example a hexagon, to which a corresponding number of tool wrenches can be fitted. With the aid of this tool, the technician can easily and precisely apply a torque to the respective displacing element, if necessary with great force.

According to one embodiment, the displacement element has a thread centered on the axis of rotation.

In other words, for example, a thread may be provided at one end of the displacement element. The thread can extend helically about the rotational axis of the displacement element. For example, a nut can be screwed onto the thread, by means of which nut the displacement element can be held on one of the connection regions of the rail part or can be supported on one of the connection regions. Alternatively, the displacement element with the thread can be screwed into a thread provided on one of the connection regions of the rail part.

According to an embodiment, the alignment device further has actuation means configured to rotate the displacement elements about their respective axes of rotation independently of each other.

In other words, the alignment device may have an actuation means with one or more actuators. The actuator is capable of cooperating with one of the displacement elements. Alternatively, the actuator may be selectively coupled to different displacement elements by a transmission. One or more actuators can cooperate with one of the displacement elements, respectively, to rotate the displacement element about its axis of rotation, so that in this way a displacement of the two rail parts relative to each other is achieved.

Since the actuating means are configured for being able to rotate the displacement elements independently of one another and since the displacement elements preferably cooperate with the connection regions of the rail parts in such a way that a rotation of each displacement element causes a relative displacement of the two connection regions in a direction different from the direction caused by the other displacement elements, a desired displacement of the two rail parts relative to one another can be achieved by the targeted operation of the actuators and thus the targeted rotation of the different displacement elements.

According to a specific embodiment, the actuating means have one or more electric motors to rotate the displacing elements around their respective axes of rotation independently of each other. Here, each electric motor may act as an actuator to rotate one or more displacement elements. Preferably, the number of electric motors may be equal to the number of displacement elements, and one electric motor may be assigned to each displacement element.

According to a further embodiment, the actuating means has a controller which controls the rotation of the displacement element in such a way that the rail upper part is moved into the reference position relative to the rail lower part.

In other words, the actuating means may be provided with a controller by means of which the operation of the actuator or actuators may be controlled. The controller can know the reference position, at which the guide rail of the component held on the rail holder should be arranged, for example. Based on the information about the reference position, the controller can then turn the displacing element of the alignment device by suitably controlling the actuator such that the rail upper part is moved to the reference position, if necessary together with the guide rail to which it is connected. For example, the reference position may be determined by measuring the lateral distance to a previously tightened plumb line.

According to an embodiment of the second aspect of the invention, the embodiment of the alignment device described here can be used in an elevator installation. The elevator installation has an elevator car which is guided laterally by at least one guide rail when moving vertically through the elevator shaft. In this case the lower part of the rail frame of the aligning device is intended to be fixed to the wall of the shaft and the guide rail is fixed to the upper part of the rail frame.

Thus, by means of the embodiments of the method also presented here according to the third aspect of the invention, the position and/or orientation of the guide rail can be adjusted by rotating one or more of the displacement elements of the aligning device to properly align the components on the rail holder.

It is particularly possible to arrange more than one alignment device with actuating means on the rail part at the same time. In particular, at least three alignment devices with actuating means are provided on the rail-carrier part of the guide rail. It is particularly advantageous to arrange an alignment device with an actuating means on each pair of carriage parts of the guide rail.

The arrangement of a plurality of alignment devices with actuating means on the guide rail makes it possible to achieve particularly precise automatic alignment of the guide rail, since the alignment on one rail part can affect the prior alignment of the guide rail on the other rail part. Arranging a plurality of alignment devices with actuating means on different carriage parts of the guide rail achieves: simultaneously aligning different rail parts or quickly checking the effect of alignment on one carriage part on a previous alignment with another carriage part. The alignment of the guide rails can be carried out automatically, for example, in an iterative (repeating) process in which the alignment is repeated one after the other on different rail frame parts.

It is to be noted that some possible features and advantages of the invention are described herein with reference to different embodiments of the alignment appliance, the elevator installation equipped therewith or the alignment method performed therewith. Those skilled in the art realize that these features can be combined, modified, transferred, or exchanged in a suitable manner to arrive at further embodiments of the present invention.

Drawings

Embodiments of the present invention will now be described with reference to the accompanying drawings, which are not intended to limit the invention.

Fig. 1 shows an elevator installation according to an embodiment of the invention.

Fig. 2 shows a perspective view of an alignment device according to an embodiment of the invention.

Fig. 3 shows a cross-sectional view of the alignment device of fig. 2.

Fig. 4 shows a top view of the alignment device of fig. 2.

Fig. 5 shows a top view of fig. 4 with the shifting element removed.

Fig. 6(a) to (c) show different views of a displacement element for an alignment device according to the invention.

Fig. 7 shows the way in which the connection region of the alignment device is constructed according to an alternative embodiment of the invention.

Fig. 8 shows a lining-up device with an actuating means according to the invention.

Fig. 9 shows a rail lower member in which a plurality of circular holes are formed.

The figures are schematic only and are not drawn to scale. In the figures, like reference numerals designate identical or functionally similar features.

Detailed Description

Fig. 1 shows an elevator installation 1 with an alignment device 3 according to one embodiment of the invention.

In the elevator installation 1, the elevator car 5 can be moved vertically in the elevator shaft 7. The elevator car is moved here by means of a rope-like support means 9 driven by a drive machine 11.

In particular, to prevent lateral movements of the elevator car 5, e.g. swinging within the elevator shaft 7, the elevator car is guided by guide rails 13 during its vertical displacement. The elevator car 5 is supported on the guide rails 13 by guide shoes 14 or similar. The guide rails 13 are anchored in the shaft wall 15, respectively. In order to simplify the correct positioning of the guide rail 13 or to be able to change said positioning later, the guide rail 13 is here not mounted directly on the shaft wall 15, but is connected to the shaft wall 15 via one of the alignment devices 3.

In fig. 2 to 5, embodiments of the alignment device 3 are shown in different views. The alignment device 3 has two rail parts 17.

One of the rail frame members 17 serves as a rail frame lower member 19 for attachment to the hoistway wall 15. For this purpose, the rail lower part 19 has suitable recesses 21 in the form of elongated holes 23 and/or round holes 25. Through these recesses 21, fixing elements (for example screws) can be passed with which the rail lower part 19 can be anchored to the shaft wall 15.

The other rail frame part 17 serves as a rail frame upper part 27 for holding the guide rail 13 to be fixed thereto. For this purpose, suitable recesses 29 in the form of oblong holes 31 and/or round holes (not shown) can also be provided on the rail upper part 27, for example.

Each rail part 17 can be designed as a member with an L-shaped cross section. For example, the rail part 17 can be designed as a thick steel plate which is bent (bent) and provided with the recesses 21, 29. Here, the recesses 21, 29 each extend through one of the arms of such an L-shaped part. The respective other arm of the member forms a connecting region 33, 35. The rail lower part 19 can be connected with its connecting region 33 to the connecting region 35 of the rail upper part 27, so that the two rail parts 17 are fixed relative to each other.

A plurality of displacement elements 37 ', 37 "' extend between the lower rail part 19 and the upper rail part 27. The displacement elements 37 ', 37 ", 37'" are configured for displacing the lower carriage displacement part 19 transversely with respect to the carriage upper part 27, i.e. parallel to the extension plane of its connection regions 33, 35. In this case, each of the displacement elements 37 ', 37 ", 37'" cooperates with both the connection region 33 of the rail lower part 19 and the connection region 35 of the rail upper part 27. As described more precisely below with reference to fig. 6, the displacement elements 37 ', 37 ", 37'" are designed as structural elements which are eccentrically designed at least in partial regions. The displacement elements 37 ', 37 "' are rotatable about a rotation axis 39 and engage in abutment with at least one of the rail parts 17, eccentrically with respect to the rotation axis 39, on abutment surfaces 41 ', 41"' which are laterally opposite one another in the connecting region 35 of the rail part 17.

In the example shown, circular holes 43 ', 43 "are provided in the connecting region 33 of the rail lower part 19 for each of the three displacement elements 37 ', 37" ', respectively. In the corresponding position, elongated holes 45 ', 45 "' are provided in the connecting region 35 of the rail upper part 27. The circular holes 43 ', 43 "' and the elongated holes 45 ', 45"' are arranged laterally next to one another and laterally spaced apart from one another.

As shown in fig. 6(a) to (c), each displacement element 37 has a first engagement region 47 which is cylindrical and a second engagement region 49 which is preferably likewise cylindrical. The first engagement region 47 extends centrally about the axis of rotation 39, while the second engagement region 47 is formed eccentrically 49 with respect to the axis of rotation 39. The diameter of the second joining region 49 is here significantly greater than the diameter of the first joining region 47. The first engagement area 47 is provided with a thread 51. On the side opposite the first joining region 47, an abutment region 55 is present adjacent to the second joining region 49. The contact region 55 can likewise be of cylindrical design. The contact region 55 can have a significantly larger diameter than the second joining region 49. The displacement element 47 also has a screw head 53, with which screw head 53 a tool can cooperate in order to be able to rotate the displacement element 37 about its axis of rotation 39.

In the assembled state (as shown in fig. 2 to 4), each of the displacement elements 37 ', 37 "' is arranged such that it extends with its first engagement region 47 through a corresponding circular hole 43 ', 43"' in the connection region 33 of the rail frame lower part 19 and with its second engagement region 49 through a corresponding elongated hole 45 ', 45 "' in the rail frame upper part 27. The diameter of the circular holes 43 ', 43 ", 43'" corresponds substantially to the diameter of the first joining region 47, so that the displacement element 37 with its first joining region 47 engages in the circular holes 41 ', 41 ", 41'" with a positive fit with respect to the plane of extent of the connecting region 33. The width of the elongated holes 45 ', 45 ", 45'" corresponds approximately to the diameter of the second joining region 49. The inner longitudinal sides of the elongated holes 45 ', 45 "' form contact surfaces 41 ', 41"', against which the displacement element 37 laterally contacts with its second contact area 49 the contact surfaces 41 ', 41 "'. The length of the long holes 45 ', 45 ", 45'" is significantly greater than the width thereof, so that the second engagement region 49 together with the entire displacement element 37 ', 37 ", 37'" can be displaced in the long holes 45 ', 45 ", 45'" along their respective longitudinal extension displacement direction and thus parallel to the respective contact surface 41 ', 41 ", 41'".

By rotating one of the displacement elements 37 ', 37 ", 37'" about its axis of rotation 39, a force acting on the bearing surfaces 41 ', 41 ", 41'" of the associated elongated hole 45 ', 45 ", 45'" cooperating with this second engagement region 49 can be achieved on the basis of the second engagement region 49 displaced transversely thereto. In other words, by rotating the displacement element 37, a transverse force can be generated between the two connecting regions 33, 35 of the rail-carrier part 17 by means of an eccentric effect. By means of which the rail parts 17 can be moved relative to each other. The direction and extent of this relative displacement can be influenced here, depending on which of the three displacement elements 37 ', 37 ", 37'" is turned to which extent. The rail parts 27 can be displaced in different spatial directions in a straight line parallel to the interface between their connecting regions 33, 35. Furthermore, the rail parts 27 can be turned relative to each other with appropriate operation of the displacement elements 37 ', 37 "'.

After bringing the rail parts 17 into the desired position by a suitable rotation of the displacement elements 37 ', 37 ", 37'", the displacement elements can be fixed to each other. For this purpose, for example, the nut 57 can be screwed and tightened onto the thread 51 of the displacement element 37 ', 37 ", 37'". Alternatively or additionally, additional recesses, for example in the form of round holes 59, 61, can be provided in the two connecting regions 33, 35, through which fixing elements, for example screws, can extend. By means of the nut 57 and/or the fixing element, the two connection regions 33, 35 can be mechanically pressed against one another and thus fixed relative to one another.

In the embodiment shown in fig. 2 to 5, the three elongated holes 45 ', 45 "' are aligned in such a way that the contact surfaces 41 ', 41"' of adjacent elongated holes 45 ', 45 "' extend in directions that are not parallel to each other. For example, the contact surface 41 ″ of a first elongated hole 45' extends perpendicularly to the contact surface 41 ″ of an adjacent second elongated hole 45 ″. The contact surfaces 41 ', 41 "' of the two outer, and therefore not directly adjacent, elongate holes 45 ', 45"' extend in mutually parallel directions.

By means of this arrangement of the elongated holes 45 ', 45 "' and the displacement elements 37 ', 37"' extending through them, the alignment of the rail upper part 27 relative to the rail lower part 19 can be carried out, for example, by a technician, in particular in an intuitive manner. For example, to move the rail upper member 27 to the left or right (based on the illustration in fig. 4), the intermediate shifting element 37 "must be rotated accordingly. If the upper part 27 of the rail should be moved upwards or downwards, the two outer displacement elements 37 ', 37 "' should be turned in the same way. If the upper rail part 27 is to be reoriented, i.e. rotated in its orientation relative to the lower rail part 19, the two outer displacement elements 37 ', 37 "' should be rotated in the opposite way.

Fig. 7 shows a perspective view of the connection regions 33, 35 of an alternative embodiment of the alignment device 3. In this case, a plurality of pins 63 are coupled to the connecting region 33 of the rail lower part 19. At least three of these pins 63 are held so as to be rotatable relative to the connecting region 33 of the rail lower part 19. These pins 63 can engage directly with the connecting region 33 of the rail lower part 19, for example by themselves engaging into round holes provided therein (not visible in fig. 7). Alternatively, the pin 63 may indirectly engage with the connection region 33 of the rail lower part 19, although it cannot engage itself in this connection region 33. For example, these pins 63 may mechanically cooperate with other ones of the pins 63 that are embedded in the attachment region 33 of the rail lower member 19.

In the example shown in fig. 7, two long holes 45 ', 45 "extend in directions perpendicular to one another, while the third long hole 45 '" extends obliquely, in particular at an angle of 45 ° to the other two long holes 45 ', 45 ".

In fig. 8, an embodiment of the alignment device 3 is schematically shown, which has an actuating means 65. The actuating means 65 has an electric motor 67 controlled by a controller 69. The electric motor 67 cooperates with a tool 73 via a transmission 71. The tool 73 in turn cooperates with the screw head 53 of the displacement element 37.

The shifting element 37 can thus be automatically rotated by the actuator 65 by means of the electric motor 67 and under the control of the controller 69. A separate electric motor 67 may be provided for each shifting element 37, so that the shifting elements 37 can be rotated about their respective axes of rotation independently of each other. Alternatively, a single electric motor 67 can suffice to selectively rotate each of the shifting elements 37, for example by means of a transmission structure which also needs to be controlled by the controller 69.

If desired, the controller 69 may have information about the reference position to be reached during the alignment. In this case, the controller may automatically control the rotation of the shifting element 37 by means of the electric motor 67. The alignment process can thus be as fully automated or even as possible.

It is possible to arrange more than one alignment device with actuating means on the rail parts at the same time. In particular, an alignment device with an actuating means is provided on each pair of carriage parts of the guide rail. In this way, it is possible to align the different rail parts simultaneously and also to check quickly the effect of the alignment on one rail part on the previous alignment on the other rail part. The alignment of the guide rails can then be carried out automatically in an iterative process, in which the alignment is repeated one after the other on the different rail carrier parts.

Fig. 9 shows the rail lower part 19, in the connecting region 33 of which a plurality of circular holes 43 are formed. A plurality of circular holes 43 are provided for each displacement element 37. The circular holes 43 provided for the displacement elements 37 are arranged adjacent to each other along a straight line. The straight lines associated with the circular holes 43 for adjacent displacement elements 37 extend substantially parallel to each other. In the illustrated example, the circular holes 43 are laterally spaced from one another. Alternatively, adjacent circular holes 43 may partially overlap each other, i.e., the center distance between adjacent circular holes 43 may be smaller than their diameters. Due to the plurality of available circular holes 43, the rail upper part 27 and the rail lower part 19 can be roughly pre-positioned in different positions relative to one another, depending on which circular hole 43 the associated displacement element 37 is guided through.

By way of example only, the dimensions of the rail portion 17 may be in the range of a few centimeters or decimeters in the transverse direction and a few millimeters in the thickness direction. For example, in the example of fig. 9, the sheet metal for the rail lower member 19 may be 250mm 30mm in length, 110mm 20mm in width, and 5mm 2mm in thickness.

Finally, it should be noted that terms such as "having," "including," and the like do not exclude any other elements or steps, and that terms such as "a" or "an" do not exclude a plurality. It should also be pointed out that characteristics or steps which have been described with reference to one of the above exemplary embodiments can also be used in combination with other characteristics or steps of other exemplary embodiments described above. Reference signs in the claims shall not be construed as limiting.