Patent Description:
The present invention is characterized by the special configuration and design of each of the parts of the mechanism such that the electromechanical fail-safe drive is arranged in a smaller volume, wherein the assembly thereof inside the longitudinal member of the frame is possible without protruding from the longitudinal member thereof.

The electromechanical activation system comprises a safety gear protective plate incorporating all the electromechanical drive elements in the vertical position for any type of elevator safety gear, i.e., progressive one-way, two-way or even instantaneous.

This vertical arrangement and configuration of elements on the protective plate itself causes the assembly to be compact enough for the safety gear assembly and its electromechanical drive to be received within the longitudinal member of the frame of the elevator.

Therefore, the present invention is comprised within the field of elevators, and particularly among the safety means used for stopping an elevator.

There are certified and functional electromechanical safety gear on the market. Said safety gear must be used together with electronic governors which in turn are absolute position sensors. These electronic governors replace conventional mechanical governors, as well as the governor rope and its tension pulley.

In conventional mechanical systems, the governor rope activates the system safety gear. In the case of electronic systems, an electromechanical activation system is in charge of activating the safety gear. As discussed before, a spring is in charge of keeping the safety gear in the activation position, and a coil is in charge of keeping the safety gear in the non-activation position.

The activation assembly currently used consists of the use of a reset coil, a holding coil associated with a spring which is preloaded during normal operation waiting to be deployed in the event of a power failure and transmission means for transmitting drive to the wedging roller.

Said transmission means for transmitting the drive of the safety gear to the wedging roller are based on the use of levers and cams, which results in an increase in the necessary final dimensions, causing the electromechanical activation system to emerge from the longitudinal member wherein it is assembled. This part of the activation takes up a space in the chassis which may be a problem in some cases since it may collide with another element of the installation. In turn, it may represent a problem for the client because it forces said client to modify the chassis.

Moreover, the existing electromechanical safety gear and drive are complex in their design and manufacture; they furthermore require coils of a larger size and higher power. <CIT>, discloses a safety brake for an elevator, a lifting device comprising the safety break and a method for braking the lifting device. The safety brake does not comprise a reset coil. The present application provides an alternative technical solution to existing elevator safety gear electronic activation systems, not requiring a speed limiter and being more reliable and robust.

Therefore, an object of the present invention relates to overcoming the drawbacks of the state of the art by developing a compact electromechanical activation system for the safety gear of an elevator having a smaller final volume, which can be used in any type of safety gear given its versatility, developing a compact assembly such as the one described below.

An object of the present invention relates to a fail-safe compact electromechanical activation system or device for the safety gear of an elevator having smaller dimensions configuring an emergency stop device of an elevator which is based on the use of drive means associated with mobile wedging means which translate the drive into a wedging of a roller on a guide.

The drive means are preferably based on a coil, that is, a holding coil, which is preferably is a suction cup type coil, which is no longer receiving current at the time of activating the stop, causing the movement of the mobile wedging means of one or several interlock rollers such that they are positioned to cause the wedging of a guide.

The drive means and the mobile wedging means are aligned in a parallel manner and positioned parallel to the guide of the elevator such that, once the drive means are activated, the mobile wedging means move, driving a wedging roller in the movement thereof.

The compact electromechanical activation system for the safety gear of an elevator comprises:.

Wherein all the above-mentioned means are arranged on the same vertical of a safety gear, eliminating accessories which increase the volume and complicate the installation.

If used in one-way safety gear, the compact electromechanical activation system for the safety gear of an elevator has the following particularities.

If used in double roller two-way safety gear, the compact electromechanical activation system for the safety gear of an elevator greatly reduces the need for levers if compared to other solutions of the state of the art. This design has the following particularities:.

Using a reset coil serves for being able to reduce the physical requirements, i.e., power and size of the holding coil or holding to enable resetting the drive, as well as to consume less during the time the spring is compressed waiting to be released.

As a result of the described features, there is developed a new electromechanical safety gear design that improves existing the electromechanical safety gear in the following aspects:.

Unless otherwise indicated, all the technical and scientific elements used in the present specification have the meaning that is normally understood by a person skilled in the art to which this invention pertains. Methods and materials similar or equivalent to those described in the specification can be used when putting the present invention into practice, and this within the scope of the appended claims.

Throughout the description and claims, the word "comprises", and its variants do not intend to exclude other technical features, accessories, components or steps. For those skilled in the art, other objects, advantages and features of the invention will be inferred in part from the description and in part from putting the invention into practice.

To complement the description that is being made and for the purpose of better understanding the features of the invention according to a preferred practical embodiment thereof, a set of drawings is attached as an integral part of said description in which the following is depicted in an illustrative and non-limiting manner:.

In view of the figures, a preferred embodiment of the proposed invention is described below.

<FIG> and <FIG> show front view and rear view, respectively, of an electromechanical one-way safety gear of the state of the art.

Said safety gear comprises a reset coil (<NUM>) which compresses a wedging activation spring (<NUM>) on a holding coil (<NUM>) fixed on a support (<NUM>), wherein once thespring is compressed, the holding coil (<NUM>) holds the activation spring (<NUM>) waiting to be activated by means of the loss of the power supply of the holding coil (<NUM>). The movement of the activation spring (<NUM>) is controlled by means of an inductive monitoring sensor (<NUM>).

<FIG> shows the rear face, and it can be seen how the movement of the activation spring (<NUM>) is transmitted to a wedging roller (<NUM>) by means of a series of levers (<NUM>) associated with a limit switch (<NUM>), where the mechanical safety gear (<NUM>) can be observed on said rear face.

<FIG> correspond with a first embodiment and show different views and states of the electromechanical activation system for a one-way safety gear of an elevator.

As observed in <FIG>, the system comprises a fixed protective plate (<NUM>) provided with a double bend defining an upper part and a lower part, such that a reset coil (<NUM>) and a holding coil (<NUM>) are fixed in the upper part arranged in alignment and separated from one another, with an activation spring (<NUM>) being arranged on the holding coil (<NUM>), such that when the holding coil (<NUM>) is released from its power supply, the drive spring moves vertically.

In the lower part of the fixed protective plate (<NUM>) there is housed a wedging roller (<NUM>) (<FIG> and <FIG>) the guiding shaft (<NUM>) of which emerges through a guiding groove (<NUM>) made in the fixed protective plate (<NUM>).

<FIG> and <FIG> shows the electromechanical activation system provided with a mobile protective plate (<NUM>) having an upper bend (<NUM>) which defines a horizontal surface (<NUM>), this horizontal surface (<NUM>) being housed between the space defined by the reset coil (<NUM>) and the holding coil (<NUM>).

The mobile protective plate (<NUM>) has guiding means for the vertical movement thereof with respect to the fixed protective plate (<NUM>); to that end, in the embodiment shown three guiding pins (<NUM>) are arranged on the fixed protective plate (<NUM>), whereas in the mobile protective plate there is a first guiding groove (<NUM>) through which a guiding pin (<NUM>) runs and a second guiding groove (<NUM>) through which two guiding pins (<NUM>) run, said guiding grooves (<NUM>) and (<NUM>) having a vertical arrangement for the purpose of producing a vertical movement of the mobile protective plate (<NUM>).

Furthermore, said mobile protective plate (<NUM>) has an elongated hole (<NUM>) having a section comparable to a trapezoid for the purpose of guiding the movement of the wedging roller (<NUM>) along the guiding groove (<NUM>) by means of the guiding shaft (<NUM>) of the wedging roller.

<FIG> shows the interlock position, in which when the holding coil (<NUM>) is deactivated, the activation spring (<NUM>) is released, causing the lifting of the mobile protective plate (<NUM>) by means of the horizontal surface (<NUM>), and accordingly, the lifting and existing movement of the wedging roller (<NUM>).

<FIG> shows the position of the activation system in the operating position, waiting to be activated, in which the activation spring (<NUM>) is compressed as a result of a first drive of the reset coil (<NUM>) and a subsequent drive of the holding coil (<NUM>), with the mobile protective plate (<NUM>) being in its lower position and, accordingly, with the wedging roller also being in its lower position and without laterally protruding.

<FIG>, <FIG>, <FIG> show the front view and rear view of an electromechanical activation system in a second embodiment, corresponding with a pre-interlock position, non-locking position and wedging position, respectively, of a two-way safety gear.

Said figures show the fixed protective plate (<NUM>) where the drive means consisting of the reset coil (<NUM>) and the holding coil (<NUM>), which is a double solenoid coil in this embodiment, are assembled. Mobile wedging means (<NUM>) activated by the drive means are also located on said fixed protective plate (<NUM>), wherein these mobile wedging means are arranged in parallel with respect to the drive means.

The drive means are connected with release means, which in the embodiment shown consist of a vertically movable core (<NUM>) which is connected at its lower end with a vertically movable pulley (<NUM>) of a pulley system (<NUM>), as observed in <FIG>.

The mobile wedging means (<NUM>) comprise two pivotable levers (<NUM>) which pivot with respect to an intermediate point of their length, and which have at the free ends respective connection arms (<NUM>), wherein these connection means are in turn attached by means of a discrimination lever (<NUM>), with the wedging rollers (<NUM>) being assembled at the ends of the connection arms (<NUM>). Said pivotable levers (<NUM>) are furthermore attached to one another by means of a closing-in spring (<NUM>) fixed at the ends thereof at the pivoting or rotation points of the pivotable levers (<NUM>).

These figures show how the two-way safety gear (<NUM>) and the guide (<NUM>) of the elevator are contained in the same vertical plane of the electromechanical drive system object of the invention.

The mobile wedging means (<NUM>) are operated by a pulley system (<NUM>), comprising a vertically movable pulley (<NUM>), two first auxiliary pulleys (<NUM>), a second auxiliary pulley (<NUM>) and a rope (<NUM>) running through said pulleys and the ends of which are attached to the articulation or rotation points (<NUM>) of the pivotable levers (<NUM>), such that once the holding exerted by the holding coil (<NUM>) is released, the lifting of the movable core (<NUM>) and hence the lifting of the vertically movable pulley (<NUM>) take place, which translates into a pivoting of the pivotable levers (<NUM>) and, accordingly, the wedging rollers (<NUM>) moving closer together. That is, both rollers touch the guide (<NUM>); however, if the elevator car were to be moving downwards, then the lower roller would be wedged. If the car were to be moving upwards, then the upper roller would be wedged.

Claim 1:
A compact electromechanical activation system for the safety gear of an elevator, comprising:
- a fixed protective plate (<NUM>) having drive means fixed to it, based on a holding coil (<NUM>) and release means arranged in alignment;
- mobile wedging means activated by the drive means, wherein these mobile wedging means are arranged in parallel with respect to the drive means;
- one or two wedging rollers (<NUM>) for a one-way safety gear system or for a two-way safety gear system respectively,
the compact electromechanical activation system being characterized in that the drive means fixed to the fixed protective plate (<NUM>) further comprise a reset coil (<NUM>).