A drive system for an elevator installation includes a drive and a drive suspension for fastening the drive to a support element of the elevator installation. The drive suspension includes a rotary joint for tiltably mounting the drive on the support element and an adjustment device for setting a tilt of the drive about the rotary joint. The support element can be a guide rail wherein the drive system is arranged in an upper end region of the elevator installation.

Elevator systems including an elevator car moveable within an elevator shaft, the elevator car having a first elevator car component, the first elevator car component having a first side facing an interior of the elevator car and a second side opposite from the first side and a structural sound-generation system. The structural sound-generation system having at least one audio actuator coupled to the second side of the first elevator car component and an audio system controller in communication with the at least one audio actuator. The structural sound-generation system is configured to generate vibrations within the first elevator car component such that sound waves are produced therefrom and projected into the interior of the elevator car.

A device for checking guides of an elevator car that can be moved along guide rails may include means for measuring contact forces of the guides on the guide rails. The device may further include an evaluation unit. The means for measuring contact forces may be configured to make measured values determined by the means for measuring contact forces available to the evaluation unit, either through wired connection or wireless connection. In some cases, the means for measuring contact forces may measure contact forces on the guide rails in at least two different directions. Also disclosed are methods for balancing elevator cars.

An elevator element manufacturing method, an elevator element and an elevator are disclosed. The manufacturing method includes providing in powder and/or granulate form a material comprising compound comprising silicon and a second divalent metal, filling a mould with a mixture including the material and water, adding CO.sub.2 in the mixture in the mould, allowing water and CO.sub.2 to react with the material under overpressure, thereby creating bonding structures based on metal carbonates (MCO.sub.3).

A drive system for an elevator installation includes a drive and a drive suspension for fastening the drive to a support element of the elevator installation. The drive suspension includes a rotary joint for tiltably mounting the drive on the support element and an adjustment device for setting a tilt of the drive about the rotary joint. The support element can be a guide rail wherein the drive system is arranged in an upper end region of the elevator installation.

An example elevator system may include at least one elevator cage that is displaceable in an elevator shaft, a connection means that has a first elevator cage-side end and a second end, and a suspension disposed on the elevator cage. The connection means may include, for instance, a balance chain or belt. The first end of the connection means may be fastened to the suspension on the elevator cage. Further, the example elevator system may include a support unit that exerts a force on the suspension that counteracts a force acting on the suspension due to a mass of the connection means. The support unit may include a rope, a deflection roller, and a counterweight, wherein the rope is fastened to the counterweight and the suspension and is guided over the deflection roller.

A pneumatic vacuum elevator cylinder has a cabin inserted therein. A structural plate of the cabin has a liner attached thereto. This liner has an integral bumper formed on an external surface thereof for impact the inner surfaces of the pneumatic vacuum elevator cylinder. The bumpers have a variety of features that facilitate the smooth ride of the cabin within the elevator cylinder.

Elevator systems including an elevator car moveable within an elevator shaft, the elevator car having a first elevator car component, the first elevator car component having a first side facing an interior of the elevator car and a second side opposite from the first side and a structural sound-generation system. The structural sound-generation system having at least one audio actuator coupled to the second side of the first elevator car component and an audio system controller in communication with the at least one audio actuator. The structural sound-generation system is configured to generate vibrations within the first elevator car component such that sound waves are produced therefrom and projected into the interior of the elevator car.

A device may be employed to damp vibrations in elevator installations. The device may include two metal plates that are spaced apart from one another by an insulator made of an elastomer. An inner side of at least one of the two metal plates may have a structure that is formed by projections. In some cases, both of the metal plates may include such structures, and the projections of each metal plate may engage with one another. Due to the flexibility of the insulator, the insulator can fit in the structure formed by the projections. Geometric sizes of the projections, arrangement of the projections, shapes of the projections, and spacings between the projections can all affect a level of damping.