EP2771268A1

EP2771268A1 - Sliding guide shoe for a lift

Info

Publication number: EP2771268A1
Application number: EP12770499.7A
Authority: EP
Inventors: Hans Kocher; Hubert Steiner; Stephan Hess
Original assignee: Inventio AG
Current assignee: Inventio AG
Priority date: 2011-10-24
Filing date: 2012-10-12
Publication date: 2014-09-03
Also published as: MX2014004834A; US9493325B2; CN103958386A; BR112014009260A8; WO2013060583A1; BR112014009260A2; RU2638336C2; RU2014120984A; IN2014CN02975A; US20130098714A1; MX346738B

Abstract

A sliding guide shoe for a lift for carrying people or goods has a guide-shoe housing (5) and a two-part insert (6), inserted into the guide-shoe housing (5), for guiding a lift car along a guide rail (3) extending in the longitudinal direction (z). The insert (6) comprises a sliding element (8), which is connected to a carrier element (7) such that it can be removed laterally from the sliding guide shoe (4) in the longitudinal direction (z). The sliding element (8) here can be pushed into the carrier element (7), or pulled out of the same, only from one longitudinal side (20).

Description

Sliding guide shoe for a lift

The invention relates to a sliding guide shoe for a lift for passenger or goods transport according to the preamble of claim 1. Furthermore, the invention relates to a method for maintenance or revision of an elevator system with such Gleitführungsschuhen.

Sliding guide shoes are often used to guide elevator cars. Elevator systems in buildings have a generally vertical elevator shaft, in which a respective guide rail is arranged on mutually opposite shaft walls. Sliding guide shoes arranged on the elevator car have inlays with sliding surfaces which slide with little play along a guide rail. Sliding guide shoes in which the inserts are configured as profiles of U-shaped cross-section are known and commonly used. In contrast to roller guide shoes, the sliding guide shoe basically has no moving parts. Since the deposits wear off over time, used or old sliding inserts must be replaced.

DE 203 15 915 U1 shows a sliding guide shoe with a two-part insert, which consists of a carrier element and a sliding element. The sliding element can be replaced, but after the first start-up of the elevator, the entire sliding guide shoe has to be removed. In practice, it has been found that even after the sliding guide shoe has been dismounted from the cabin, the sliding element inserted into a pocket-like recess in the carrier element towards the front side is difficult to remove from the carrier element. Also, the insertion or replacement of a sliding designed as difficult because of the special choice of material and design of receiving pocket and slider easy insertion into the bag is hardly possible.

From EP 1 880 968 AI a Gleitführungsschuh has become known with an insert which is received in a longitudinally extending channel-like receptacle in the guide shoe housing. For lateral securing of the insert holding elements are screwed to the guide shoe housing in the region of both longitudinal sides. These Insole can be removed from the guide shoe by removing it longitudinally along the guide rails without removing the entire guide shoe. The designed as wear parts deposits are, however, relatively expensive and expensive to manufacture.

JP 2006-103896 shows a sliding guide shoe with a sliding insert consisting of two side parts and a bottom part, wherein the two side parts and the bottom part in cross-section define a "U" in the inserted state. The slide insert has a profiling on the inside, the tread depth determines whether the worn slide insert needs to be removed, but it is difficult and cumbersome to remove the slide insert, for example because the bottom part is sandwiched between the rubber plates, can hardly be removed separately, so in practice the entire insert together with the sliding insert and rubber plates must be removed from the guide shoe housing.

From US 2,103,480 a two-part insert for a Gleitführungsschuh has become known. The sliding element is a U-profile made of hardwood, which is surrounded by a U-shaped rubber profile. Hardwood profiles of this type are difficult to produce and expensive, and they are no longer sufficient in terms of sliding properties. The hardwood profile is not supported by the rubber profile but is secured at the top and bottom only by plates bolted to the guide shoe housing.

It is therefore an object of the present invention to avoid the disadvantages of the known and in particular to provide a sliding guide shoe of the type mentioned, which is easy to handle especially for inspection or maintenance. Furthermore, the wear parts of the Gleitführungsschuhs should be easily and inexpensively replaced and replaced. Finally, the Gleitführungsschuh should meet high demands in terms of sliding properties and damping behavior.

According to the invention, these objects are achieved with the sliding guide shoe with the features of claim 1. The two-part insert has a sliding element and a carrier element, wherein the sliding element is releasably connected to the carrier element. Preferably, the carrier element has sliding surfaces on which the guide rail contact with a small amount of play. The support member may have by appropriate choice of materials, structural design or shaping damping properties, whereby a low-vibration ride of the cabin can be ensured. The carrier element itself has at least in the normal case no sliding function. Characterized in that the at least one sliding element is connected to the support member or connectable that it can be removed laterally from the Gleitführungsschuh in the longitudinal direction or inserted into this, the sliding element can be exchanged and replaced as wear part even after the first commissioning of the elevator system and without elaborate arrangements , In particular, it is possible to remove the sliding element while the remaining sliding guide shoe remains on the longitudinally extending guide rail. After removal of the sliding element, the carrier element is still in the inserted position in the guide shoe housing.

Carrier element and optionally also the sliding element is designed at least in the inserted state as a cross-sectionally U-shaped profiles, wherein the profile longitudinal direction corresponds to the predetermined longitudinal direction by the guide rail. The U-profile may have two leg walls and a web wall connecting them. The carrier element and / or the sliding element can each be made of flat blanks, wherein the leg walls connect, for example via film hinges to the web wall. To form the profile shape of the blank can be erected from a flat rest position. Instead of designed as a one-piece component sliding element, however, the sliding surfaces could also be formed by separate components. The outer component of the insert, i. The support member may be made of a comparatively elastic plastic such as elastomers based on PU, rubbery materials such as synthetic rubber (e.g., EPDM or NBR) or natural rubber (NR). With the support element noise and vibration can be damped. The sliding element may consist of a comparatively stiff plastic material. Good sliding properties can be achieved if the sliding element is made for example of a material such as PTFE or UHMW-PE with low coefficients of friction.

The sliding guide shoe could be designed such that the sliding element can be pushed or pulled out from both sides in the longitudinal direction into the carrier element. Particular advantages, however, arise when the slider is insertable or retractable only from one longitudinal side into the carrier element. With this order can be created a simple, consisting of a few individual sliding guide shoe.

Particularly advantageously, the sliding element is supported with respect to the longitudinal direction on one side in each case by a stop, up to which the sliding element is limited in the carrier element can be inserted. The stop may be predetermined by the carrier element, by the guide shoe housing or possibly even by a separate part.

For this purpose, the support element has at least one up to a shoulder in the longitudinal direction extending recess for receiving the sliding element. In this recess, the respective sliding element can be inserted and inserted from the one longitudinal side. The shoulder thereby forms a stop for the sliding element, up to which the sliding element can be pushed into the carrier element. The longitudinally extending, non-continuous recess extends from an open longitudinal side to said shoulder, wherein the shoulder can be created for example by a step in the support element.

The support member may be fixed or fixable by means of fastening means positively or non-positively in the guide shoe housing. It would also be conceivable to fix the carrier element using adhesive in the guide shoe housing.

When the sliding guide shoe has opposite sliding surfaces and a sliding surface extending transversely thereto, which are slidably movable along guide surfaces of the guide rail with preferably little play, it may be advantageous for a sliding element to predetermine the three sliding surfaces, the sliding element preferably being monolithic and monolithic Component is designed.

Alternatively, the sliding guide shoe may comprise three sliding elements, each sliding element each forming a sliding surface. This arrangement has on the one hand manufacturing advantages, since the simple-shaped sliding elements can be easily and inexpensively manufactured. The sliding elements made of suitable plastics can be produced for example by extrusion. Depending on the choice of material, the sliding elements could also be designed as injection-molded parts made of plastic. Of course, other manufacturing processes would be conceivable. On the other hand, this arrangement leaves one use-dependent replacement of wearing parts too. Any new sliding elements must therefore not be replaced in every maintenance interval. The arrangement with a plurality of sliding elements is further advantageous in that it is particularly suitable for oil-free operation. In principle, it would even be conceivable that only the opposing sliding surfaces are used for the sliding guide of the cabin, while the guide surface of the guide rail extending transversely thereto would not be acted upon by, for example, a roller guide from the sliding guide shoe. In this case, the sliding guide shoe would comprise only two sliding elements.

The individual sliding elements can be designed as a plate-shaped body. Such sliding elements can be produced in a particularly simple and cost-effective manner.

Furthermore, it can be advantageous if three fastening grooves are provided in the carrier element for preferably (in relation to the insertion direction or longitudinal direction) positive reception of a respective sliding element. Particularly advantageously, the fastening groove undercuts and the sliding element to the undercuts have complementary wedge-shaped edge portions, resulting in a dovetail connection between the sliding element and the carrier element. The combination of the three fastening grooves forming the above-mentioned recesses with the sliding elements which can be accommodated therein could also be advantageous for sliding guide shoes having other configurations of the recesses. For example, it is not absolutely necessary for certain applications that sliding elements are supported on a shoulder formed by the carrier element. Such Gleitführungsschuh could thus have longitudinally extending, continuous recesses (without shoulder).

An advantageous fixation results when the support member has at least one preferably monolithically formed on the support member bearing pin and when the guide shoe housing has a bearing pin complementary recess for receiving the retaining pin.

To secure the sliding element, a retaining element can be provided which is fastened or fastened in the region of a longitudinal side on the guide shoe housing. The gliding Ment can thus be included between the support member and the aforementioned stop, whereby the sliding member is securely held in the guide shoe housing.

Further, it may be advantageous if the holding element has a surface on the guide shoe housing resting or auflegbaren mounting wall portion and a spaced from the guide shoe housing retaining wall portion for holding the insert. The retaining wall portion and the mounting wall portion can lie on plane-parallel planes.

The holding element may be a bent part made of metal. The holding element can thus be made from a single sheet metal blank and formed by Blechumformverfahren.

The sliding guide shoe may further comprise a preferably separate protective element for protecting the sliding surfaces against contamination from the outside. The protective element can be positioned on an inner side facing the at least one sliding element on the holding element or, for example, attached by gluing. In a fully assembled position, the protective element bears against the sliding element or on the sliding elements and protects itself sealingly therefrom.

The protective element is preferably made of a non-metallic material. It may be made of plastic, and preferably of a plastic having elastic properties (e.g., elastomers). For example, PUR, EPDM, NBR or NR are particularly suitable. Furthermore, it is conceivable that the protective element was made of a felt or a non-woven.

The sealing effect for protecting the sliding surfaces can be further improved if the protective element is designed flat and has a first surface portion and a subsequent inside, a smaller thickness than the first surface portion having sealing portion which defines a contact surface to the sliding element. Between the surface portion and sealing portion may be a step. An outer edge of one end of the slider may be fitted in the step. In addition or as an alternative, the sealing section can form a type of sealing lip inwards which prevents the guide rail acted upon.

In a further embodiment, the protective element and the retaining element can each have an incision at least partially enclosing the guide rail in the operating position. The protective effect can be increased if the incision of the protective element is tapered relative to that of the retaining element.

For handling, it may be advantageous if the sliding element used projects beyond the carrier element and / or via the guide shoe housing. The part of the sliding element projecting beyond the carrier element and / or the guide shoe housing can be easily grasped and pulled out. For easy gripping, for example, with forefinger and thumb or with a pair of pliers, the supernatant should preferably be at least 5 mm and more preferably about 10 mm. The support member may be configured such that it has an upper end which is offset in the inserted position against an adjacent housing surface and / or an edge of the sliding member in the region of the longitudinal side inwardly, whereby a recess or an open towards the longitudinal side cavity between Guide shoe housing and sliding element is created. The sliding element can be easily grasped via the mentioned cavity and then pulled out.

The fully inserted carrier element can connect approximately flush or infinitely to the housing surface in the region of the longitudinal side of the guide shoe housing.

Another aspect of the invention could relate to a cab for an elevator with at least one sliding guide shoe in the manner previously described.

Another aspect of the invention relates to a method for the revision of an elevator system equipped in particular with the previously described guide shoes. The method is characterized in particular by the fact that when renewing an at least one sliding element and a carrier element comprehensive insert for the Gleitführungsschuh the sliding element is replaced. During the replacement process, the guide shoe remains together with the carrier element on the guide rail. The sliding element to be renewed is removed by lateral withdrawal in the longitudinal direction of the guide shoe. A new slider is inserted from the same side into the guide shoe used. Of course, a deposit secured with one or at most two retaining elements must be removed beforehand.

Further advantages and individual features will become apparent from the following description of an embodiment and from the drawings. Show it:

FIG. 1 shows a simplified representation of an elevator according to the invention with an elevator car guided on guide rails via sliding guide shoes in a top view,

FIG. 2 shows a perspective view of a sliding guide shoe of the elevator according to FIG. 1,

FIG. 3 shows the sliding guide shoe from FIG. 2 with a detached holding element and protective element,

FIG. 4 shows the sliding guide shoe with disassembled sliding element, FIG. 5 shows a carrier element for the sliding guide shoe,

Figure 6 shows an alternative Gleitführungsschuh with detached holding element and

protection element

FIG. 7 shows a perspective view of a sliding guide shoe according to a further exemplary embodiment,

FIG. 8 shows a variant of the sliding guide shoe according to FIG. 7,

FIG. 9 shows the sliding guide shoe from FIG. 8 with disassembled sliding elements, and FIG

Figure 10 is a plan view of the Gleitführungsschuh.

Figure 1 shows a generally designated 1 elevator with an elevator car 2, the vertically guided between two guide rails 3 in an elevator shaft, not shown, up and down in the z-direction is movable. The linear guide with the guide rail 3 is presently exemplified by a longitudinally extending z extending T-profile. At least one guide shoe 4 for guiding the car 2 to the guide rails 3 is arranged on the elevator car 2 on each side. For optimum guidance, elevator cars generally have four (two per side) or more sliding guide shoes. The Gleitführungsschuh has a cross-sectionally U-shaped insert 6, which includes the guide rail 3 and which - like the guide rail - in the longitudinal direction z extends. The insert 6 described in more detail below is secured in position by a retaining element designated 9.

Details of a possible structural design of the sliding guide shoe 4 according to the invention can be taken from FIG. The sliding guide shoe 4 has a channel-like receptacle extending in the longitudinal direction z for the guide rail (not shown here). The respective guide surfaces of the guide rail are slidably acted upon in a sliding movement in the z-direction by opposing, approximately plane-parallel sliding surfaces 18 and a transverse thereto extending sliding surface 22 with little play. The two sliding surfaces 18 are formed by the inner side facing the guide rail of the designated sliding element 8, which forms the insert 6 together with a carrier element 7. The insert 6 is fixed via bearing pins 14, which engage in corresponding recesses 15 of a guide shoe housing 5, in the guide shoe housing 5 of the guide shoe. The guide shoe housing 5 embodied in one piece in this case consists of a metallic material (eg steel). The outer insert component 7 is made of a material with which noise and vibration can be damped during the cabin ride. For example, an elastic plastic (e.g., PUR, EPDM, NBR, NR) can be used. The sliding element 8, however, consists of a comparatively rigid plastic, which is further characterized by a low coefficient of friction (PTFE, UHMW-PE, etc.). The sliding guide shoe 4 is characterized in that an oil-free guidance is made possible.

The cross-sectionally U-shaped sliding element 8 in the assembled state according to FIG. 2 is provided between a shoulder 11 and a lid-like arrangement with a protective element 10 for protecting the sliding surfaces 18 from contamination and a sheath. element 9 included. The holding element 9 is designed as a bent part made of metal, which is secured by means of screws (not shown here) on the guide shoe housing 5. Corresponding holes, through which screws are feasible, are designated by 28.

When Gleitführungsschuh 4 according to Figure 3, the holding element 9 and the protective element 10 were replaced, whereby further structural features of the invention can be seen. For example, it is evident from FIG. 3 that the sliding element 8 projects beyond the guide shoe housing. The supernatant, which may be 5 mm and more, is indicated by u. By contrast, the support element 7 closes approximately flush with the housing surface designated by 21 in the region of the longitudinal side 20. After removal of the cover containing holding element 9 and protective element 10, the upper longitudinal side 20 of the sliding element 8 is exposed and can be easily grasped. This supernatant makes it possible that, for example, for maintenance-related replacement of the sliding element maintenance personnel, the slider 8 can easily remove from the guide shoe. For this purpose, only the part of the sliding element 8 projecting beyond the guide shoe housing 5 has to be grasped and pulled out in the z direction. Since the sliding element 8 can be pulled out even if the remainder of the sliding guide shoe remains on the guide rail, there are significant advantages for time-saving and manageability for revisions and maintenance. The tedious and time-consuming dismantling of the entire sliding guide shoe from the cabin need not be made.

The retaining element 9 has a fastening section 16 provided with through-holes 28 and a retaining wall section 17 extending plane-parallel to the plane of the fastening section. Furthermore, in the region of the longitudinal side 20 of the guide shoe housing 5, two holes 29 can be seen, which can be designed for fastening the holding element 9 as through holes or threaded holes into which (not shown) screws can be inserted or screwed. The protective element 10 is designed to be flat and consists of a soft non-metallic material (eg plastics or felt). The protective element 10 has a first surface portion 23 and a subsequent thereto, a smaller thickness having sealing portion 24. The sealing portion 24 defines a contact surface with the sliding member (see Fig. 2). Between surface portion 23 and sealing portion 24 is inside a step. The edge of the sliding element end facing the retaining element is complex. designed mentally and in the level einpassbar. Furthermore, it can be seen in FIG. 4 that the protective element 10 and the retaining element 9 each have an incision 27 or 26 enclosing the guide rail. The incision 27 of the protective element 10 is tapered for optimum protection against the incision 26 of the retaining element 9.

FIG. 4 shows a residual sliding guide shoe designated 4 ', from which the sliding element has been removed laterally. In the present case, the sliding element 8 is designed as a profile body which defines a U-shape both in the inserted state and outside the guide shoe. But it would also be conceivable to separate the individual walls by means of film hinges. Thus, the slider would be erectable from a flat position by raising the leg walls to a U-profile. The carrier element 7 has a recess 12 which extends up to a shoulder 11 and which forms a receiving section for receiving the sliding element. The shoulder forms the stop, to which a sliding element can be inserted. With t the distance of the shoulder 11 is referred to the lower longitudinal side of the guide shoe, which corresponds approximately to the desired projection of the sliding element. To re-insert (or insert a new) sliding element 8 this must be inserted only in the direction indicated by an arrow e insertion direction from the longitudinal side 20 into the support member 7. Furthermore, it can be seen that at both longitudinal ends of the inner walls of the sliding element are angephphast. In Figure 5, the support member 7 again shown in a single view.

FIG. 6 shows a variant of the first exemplary embodiment. The sliding guide shoe 4 shown in FIG. 6 is characterized in that the end 30 of the carrier element facing the upper longitudinal side 20 is offset inwards relative to the corresponding housing upper side 20 or surface 21. By this inward displacement creates a depression over which the slider 8 can be easily grasped or detected and then pulled out. Since the upper edge 31 of the fully inserted sliding element 8 ends approximately on the same plane as the surface 21 in the region of the longitudinal side 20, the retaining element 9 can be formed by a simple plate-like component. The likewise flat protective element 10 can be made, for example, from a felt blank.

As can be seen from FIG. 7, the sliding guide shoe can also have a plurality of sliding elements. In the present case, each of the three sliding surfaces 18 is a single sliding element 8 ', 8 ", The three sliding elements 8 ', 8 "and 8"' in the present case have the same shape and consist for example of UHMW-PE or Teflon.RTM ^.. The sliding elements 8 ', 8 "and 8"' are designed in three complementary configurations Mounting grooves used in the support member 7 and can be removed by pulling in the longitudinal direction z from the guide shoe.

To illustrate the connection between the sliding elements 8 ', 8 "and 8"' and the carrier element 7, the Gleitführungsschuh is shown in Figure 8 without holding element and protective element. Evidently, the sliding elements 8 ', 8 ", 8"' are inserted via a dovetail connection in the carrier element 7. Compared to the embodiment of Figure 7, the support member 7 is shortened with respect to the longitudinal direction, so that in the region of the longitudinal side 20, a cavity is formed, via which the sliding elements can be grasped or grasped and then pulled out in the longitudinal direction of the individual mounting grooves.

The Gleitführungsschuh 4 allows an advantageous process for the revision of an elevator system. To renew the deposits of Gleitführungsschuhe the (not shown here) elevator car is first stopped, whereupon the following steps are performed: The sliding elements 8 ', 8 ", 8"' are replaced, wherein during the replacement process, the Gleitführungsschuh together with the support member 7 on the guide rail remains and to be renewed sliding elements 8 ', 8 ", 8"' are removed from the Gleitführungsschuh 4 by lateral pulling in the z direction. Then, new sliding elements can be inserted from the longitudinal side 20 in the opposite direction to the arrow z in the Gleitführungsschuh.

In FIG. 9, in the region of the longitudinal side, the carrier element 7 adjoins steplessly the planar housing surface designated by 21. Furthermore, the dovetail configuration for the connection between the sliding elements 8 ', 8 ", 8"' and the carrier element 7 is clearly recognizable in this illustration. The carrier element 7 has, as is apparent, three recesses running in the longitudinal direction z, into which the sliding elements can be inserted in each case. In the support member 7 recesses in the form of three mounting grooves 32, 33 are provided for the positive reception of a respective sliding element. The sliding elements 8 ', 8 ", 8"' are designed as a plate-shaped body. The fastening grooves have in the longitudinal direction z extending undercuts; the gliding Mente have complementary to the undercuts wedge-shaped edge portions. In Figure 9, the undercuts of the mounting groove 32 are designated 34, the edge portions of the corresponding sliding member are designated 35. The present multi-part arrangement and the dovetail configuration differs further from the one-piece embodiments by smaller contact surfaces (or sliding surfaces) opposite or to the guide rail.

As can be seen above all from the plan view according to FIG. 10, the sliding elements 8 ', 8 ", 8"' of the insert 6 are each received in a form-fitting manner in the fastening grooves 32, 33 of the carrier element 7 in a special manner. 10, on the right side, the sliding element designated 8 "is removed from the fastening groove also designated 32. The fastening groove 32 has an undercut 34 extending in the longitudinal direction, the sliding element 8" has accordingly wedge-shaped edge portions 35. With this dovetail connection, the sliding elements are held captive in a simple manner inwardly in the support element. It can further be seen from FIG. 10 that the sliding surfaces 18, 22 protrude with respect to the respective, inwardly facing surfaces of the carrier element 7 by a distance s, which may amount to approximately 2 mm. Between the individual sliding elements 8 ', 8 ", 8"' beyond open spaces are formed in the edge region. Test tests have shown that surprisingly results in a further improved sliding behavior of the guide shoe during the cabin ride.

Claims

claims

Sliding guide shoe for a lift for passenger or goods transport with a guide shoe housing (5) and in the guide shoe housing (5) inserted or insert insert (6) for guiding an elevator car along a in travel or longitudinal direction (z) extending guide rail (3) wherein the insert (6) is formed at least in two parts and at least one sliding element (8, 8 ', 8 ", 8"') and a carrier element (7), wherein the carrier element (7) at least in the inserted state as in Cross-section U-shaped profile is configured, characterized in that the at least one sliding element (8, 8 ', 8 ", 8"') so releasably connected to the carrier element (7) or is connectable, that it only from one longitudinal side (20 ) laterally from the Gleitführungsschuh (4) in the longitudinal direction (z) is removable or insertable into this, wherein the carrier element (7) at least one in the longitudinal direction (z) to a shoulder (11) extending Recess (12, 32, 33), wherein the at least one recess (12, 32, 33) forms a receptacle for the at least one sliding element (8, 8 ', 8 ", 8"') and wherein the at least one sliding element (12) 8, 8 ', 8 ", 8"') is supported or can be supported on the shoulder (11) formed by the carrier element (7).

2. Sliding guide shoe according to claim 1, characterized in that the carrier element (7) has a to the shoulder (11) extending recess (12) which forms a receiving portion for receiving the sliding element (8).

3. sliding guide shoe according to claim 2, characterized in that the Gleitführungsschuh opposing sliding surfaces (18) and a transverse thereto extending sliding surface (22), wherein a sliding element (8), which is designed as a one-piece and preferably monolithic component, the three Defines sliding surfaces (18, 22).

4. Sliding guide shoe according to claim 1, characterized in that the Gleitführungsschuh opposing sliding surfaces (18) and a transverse thereto extending sliding surface (22), and in that it further comprises three sliding elements (8 ', 8 ", 8"'), each sliding element (8 ', 8 ", 8"') each having a sliding surface (18, 22) forms.

5. Sliding guide shoe according to claim 4, characterized in that the sliding elements (8 ', 8 ", 8"') are designed as a plate-shaped body.

6. sliding guide shoe according to claim 4 or 5, characterized in that in the carrier element (7) three fastening grooves (32, 33) as recesses for preferably positive reception of a respective sliding element (8 ', 8 ", 8"') are provided.

7. sliding guide shoe according to one of claims 4 to 6, characterized in that for forming a dovetail connection between the sliding element and the carrier element, the fastening groove (32, 33) undercuts (34) and the sliding element (8 ', 8 ", 8"') have complementary wedge-shaped edge portions (35) to the undercuts.

8. sliding guide shoe according to one of claims 1 to 7, characterized in that for securing the at least one sliding element (8, 8 ', 8 ", 8"'), a holding element (9) is provided which in the region of a longitudinal side (20). on the guide shoe housing (5) is fastened or fastened.

9. Sliding guide shoe according to one of claims 1 to 8, characterized in that it further comprises a protective element (10) for protecting the sliding surfaces (18, 22) from contamination, which is positioned on a slider facing the inside of the holding element (9) or attached is.

10. Sliding guide shoe according to claim 9, characterized in that the protective element (10) consists of a non-metallic material and in particular of plastic.

11. Sliding guide shoe according to one of claims 1 to 10, characterized in that the inserted sliding element (8, 8 ', 8 ", 8"') on the support element (7) and / or on the guide shoe housing (5) protrudes. Method for overhauling an elevator installation (1), in particular with at least one sliding guide shoe (4) according to one of Claims 1 to 11, characterized by the following steps:

Stopping an elevator car (2) guided by sliding guide shoes (4) along guide rails (3) in the travel or longitudinal direction,

- Renewing a least one sliding element (8, 8 ', 8 ", 8"') and a support member (9) comprehensive insert for the Gleitführungsschuh (4) by replacing at least one sliding element (8, 8 ', 8 ", 8"' ), wherein during the replacement process, the sliding guide shoe (4) together with the carrier element (7) on the guide rail (3) remains and wherein the renewed sliding element (8, 8 ', 8 ", 8"') from the Gleitführungsschuh (4) removed laterally in the longitudinal direction and a new sliding element (8, 8 ', 8 ", 8"') from the side (20) forth in the longitudinal direction in the sliding guide shoe (4) is inserted.