EP2651807A1

EP2651807A1 - Monitoring device for detecting an undesired travel of an elevator cab from a standstill

Info

Publication number: EP2651807A1
Application number: EP11796673.9A
Authority: EP
Inventors: Faruk Osmanbasic
Original assignee: Inventio AG
Current assignee: Inventio AG
Priority date: 2010-12-17
Filing date: 2011-12-09
Publication date: 2013-10-23
Anticipated expiration: 2031-12-09
Also published as: US9061865B2; BR112013013289B1; WO2012080103A1; AU2011344430B2; CN103370270B; CA2816359C; RU2013130306A; AU2011344430A1; BR112013013289A2; US20120152658A1; HK1185331A1; EP2651807B1; CL2013001693A1; MX2013006944A; CN103370270A; RU2587283C2; CA2816359A1; ES2526325T3

Abstract

An electromechanical monitoring device (12) is proposed for detecting an undesired travel of an elevator cab (3) from a standstill. The electromechanical monitoring device (12) for detecting an undesired travel of a elevator cab (3) from a standstill comprises a follower wheel (13), which, if required, is pressed against a running path (14, 8, 25) of the elevator cab, preferably against a running diameter (25) of the speed limiter. A sensor (15) detects a rotation of the follower wheel (13) and actuates a brake device (9, 10, 11) when a rotary angle of the follower wheel (13) exceeds a predetermined value. This electromechanical monitoring device (12) is suitable for being fitted to or installed in a speed limiter (24) and is suitable for retrofitting on elevator installations.

Description

Monitoring device for detecting unwanted driving away of an elevator car from a standstill

description

The invention relates to an electromechanical monitoring device for detecting an unwanted drive away an elevator car from a standstill, a suitably equipped speed limiter and elevator system, a Nachrüs- teinrichtung for retrofitting an elevator installation with such a device and a corresponding method according to the independent claims.

An elevator system is installed in a building. It consists essentially of an elevator car, which is connected via suspension means with a counterweight or with a second elevator car. By means of a drive which acts selectively on the suspension means, directly on the elevator car or the counterweight, the elevator car is moved along, substantially vertical, guide rails. The elevator system is used to transport people and goods within the building over single or multiple floors.

The elevator system includes devices to ensure safety of the elevator system. Such a device protects, for example, when stopping in one floor of the building, the elevator car from unwanted drifting away. For this purpose, for example, braking devices are used, which can slow down the elevator car in case of need.

From WO 2005/066058 such a device is known. The device consists of a clamping device which clamps a moving part at a standstill of the elevator car, a motion sensor which detects a movement of the clamping device and a control device which evaluates the movement and actuates a safety device in case of need.

The present invention aims to provide an alternative monitoring device for detecting an unwanted drive away of an elevator car from a standstill, which is easy to install and which is also suitable for retrofitting in an elevator system if necessary. According to one embodiment variant of an electromechanical monitoring device for detecting an unwanted drive away of an elevator car from a standstill, the electromechanical monitoring device includes a follower wheel, which is pressed in case of need to a track of the elevator car. Such a requirement is, for example, a stop in one floor. This can be advantageously determined by the fact that a drive of the elevator system is stationary, an associated first brake device, or a drive brake is actuated or an access door to the car is open. During a normal travel of an elevator car, the electromechanical monitoring device is in a normal position, ie the follower wheel is distanced from the track and thus does not touch the track. If necessary, the electromechanical monitoring device is brought into a standby position, ie the follower wheel is pressed against the track, whereby it is rotated in a movement of the elevator car according to a direction of movement.

The monitoring device further includes a sensor, which detects a rotation of the Mitlaufrads by a predetermined angle of rotation. If the sensor determines that the predetermined angle of rotation has been exceeded, a brake device, preferably a second brake device, is actuated or another action is initiated which fixes or brakes the elevator car. The electromechanical monitoring device is then in its release position.

The second braking device may be, for example, a car brake or a safety device which is arranged directly on the elevator car and which is able to hold the elevator car in cooperation with a wall of the elevator shaft or a guide rail of the elevator car, etc.

The use of the Mitlaufrades, which is pressed in case of need to the track of the elevator car, is advantageous because as a career any track or surface in question comes into question, which runs continuously over the travel path of the elevator car, or represents the route of the elevator car. The Mitlaufrad can be easily designed and is correspondingly low in procurement.

As a sensor, a rotary encoder can be used, wherein a rotation angle of the follower wheel is detected. In this case, the braking device is triggered when exceeding a preset angle of rotation. If necessary, two or more rotary be preset. In this case, when exceeding a first angle of rotation on the follower wheel, the braking device is actuated and when exceeding a further value, for example, a hoe could be extended, which clings in the areas of the elevator door or rail fasteners, etc.

An elevator system equipped with such an override system is secured in a particularly safe and favorable manner with respect to a drifting away of the elevator car from a stop, and it is excellently suitable to be installed in or retrofitted into an existing elevator installation. If necessary, an existing braking device can be controlled. If no suitably controllable braking device is present in the elevator, at most an electromechanical actuation, as is known, for example from EP0543154, can be installed to form an existing braking device or, of course, a new remote-controlled brake can also be installed.

A corresponding retrofit device of the monitoring system advantageously includes a support, which includes the required bearings for moving parts, such as a rocker for receiving the Mitlaufrads, etc. Such a retrofit device can be easily made and attached to a track of the elevator car. Further mechanical adjustments are not required because a driving of the Mitlaufrads alone frictionally carried out by pressing the wheel to the track. Furthermore, the retrofitting device advantageously also includes a corresponding electronics box, which contains the necessary circuits for controlling the monitoring device and energy supply units with memory.

In an advantageous embodiment or further development, the follower wheel drives a cam disk. The cam can hereby be assembled directly with the Mitlaufrad. The sensor, advantageously an electromechanical switch in this embodiment, is now simply actuated by a cam of the cam disk when the follower wheel or the associated cam disk is rotated.

This is a particularly cost-effective design because no complex evaluation is needed. As soon as the follower wheel is pressed against the raceway of the elevator car and a movement of the elevator car follows, the follower wheel is rotated with the cam. Once the cam reaches the electromechanical switch, this is switched and a controlled by this switch braking device is actuated.

In an advantageous embodiment or further development, the follower wheel, if necessary together with the cam disc, is automatically moved to a neutral position or zero position as soon as the follower wheel is distanced from the raceway. This can be done for example by a spring device or advantageously the Mitlaufrad, or the associated cam plate is designed so that a center of gravity, the cam, or the cam inevitably twists back to the neutral position or zero position. It is particularly advantageous if the preset rotation angle corresponds to half a revolution of the follower wheel. Thus, a single electromechanical switch can detect a drifting away of the elevator car in both directions of travel. This embodiment makes it possible to provide a very cost-effective and safe monitoring device, since in particular its function is also easy to understand and comprehend.

In an advantageous embodiment or development of the electromechanical switch is a commercial latching or bistable switch. This means that the switch remains in the switched position after an actuation until it is returned to the normal or working position either manually or by a corresponding remote reset device. Advantageously, this switch is designed so that a circuit for controlling the braking device is closed in the normal or working position and is interrupted accordingly in the actuated or switched position. Thus, a best security can be achieved, as a break in the control always leads to a brake.

In an advantageous embodiment or development, the follower wheel is pressed by means of a pressure spring to the raceway of the elevator car and it is kept distant by means of an electromagnet of the track. Advantageously, the electromagnet is designed such that it can pull the follower against a spring force of the pressure spring. Thus, in the event of a power failure, the monitoring device automatically moves into the ready position, or a slippage of the elevator car is monitored, and at the same time different forms of attachment can be realized because of the pressure spring. In addition, this monitoring system is insensitive to conditions.

Of course, the control of the electromagnet is usually equipped with an energy storage, such as a battery, to keep at a power failure in the building the Mitlaufrad, at least during a run after the elevator car to a stop, distanced from the track.

Alternatively or additionally, the follower wheel is pressed by means of a weight mass to the track of the elevator car and it is held by means of an electromagnet away from the track. Advantageously, while the electromagnet is designed such that it can pull the counter-wheel against a weight mass of the track. This results in a particularly cost-effective and safe execution, since the weight is always safe and available worldwide. This system also corresponds otherwise to the embodiment as explained in connection with the pressure spring, wherein, of course, when installing in an elevator installation, the mounting position has to take into account the course of the weight.

If necessary, the follower wheel or the raceway to which the follower wheel can be pressed, structured, grooved, roughened or be randriert to ensure safe driving of the follower. It can of course also be made of a material with a high coefficient of friction, such as polyurethane or coated.

In an advantageous embodiment or development, the track of the elevator car corresponds to a circumference of a speed limiter and the speed limiter is connected to a limiter rope to the elevator car, or connected. This rope rotates the speed limiter in accordance with a movement of the elevator car, whereby the movement of the circumference of the speed limiter directly represents the career of the elevator car. The electromechanical monitoring device is accordingly arranged at the speed limiter or installed directly at the speed limiter, wherein the idler is pressed in case of need to the periphery of the speed limiter.

In this embodiment, the monitoring device is particularly easy to insert into a standing elevator installation or attachable, since the device can be mounted stationary in the building and associated electrical wiring can be guided in an elevator control. In addition, a replacement speed limiter for an existing elevator installation can now be provided directly. Thus, for the purpose of retrofitting an elevator installation, only an existing speed limiter without monitoring device can be exchanged with the new speed limiter with monitoring device.

Combinations of the illustrated embodiments allow for individual needs solutions. Of course, the monitoring device can also be attached to any other disc which is in connection with the elevator car and rotates in accordance with a movement of the elevator car. Such a disk may be, for example, a traction sheave, a reversing or deflecting roller, a carrying roller or a guide roller.

In the following, the invention will be explained by way of example with reference to an embodiment in conjunction with the figures.

Show it:

1 is a schematic view of an elevator installation in the side view, with a mounted on the elevator car monitoring device,

2 shows a schematic view of an elevator installation in a side view, with a monitoring device attached to a speed limiter,

3 shows an electromechanical monitoring device in normal position,

4 shows the electromechanical monitoring device of FIG. 3 in the ready position, FIG.

3 in the release position, FIG. 6 the electromechanical monitoring device of FIG. 3 in cooperation with a raceway of a speed limiter, FIG.

Fig. 7 is an attached to a speed limiter electromechanical monitoring device.

In the figures, the same reference numerals are used across the figures for equivalent parts. Fig. 1 shows an elevator system in the overall overview. The elevator installation 1 is installed in a building, preferably in an elevator shaft 2. It consists essentially of an elevator car 3, which is connected via suspension means 5 with a counterweight 4 or alternatively also with a second elevator car (not shown). By means of a drive 6, which preferably acts on the suspension means 5, the elevator car 3 and accordingly also the counterweight 4 are moved along, substantially vertical, guide rails 8. The elevator installation 1 is used to transport persons and goods within the building over single or multiple floors.

The drive 6 is connected to an elevator control 7 which controls and controls the drive 7 and thus the elevator installation 1. The elevator control 7 is connected in the example via a suspension cable 32 to the elevator car 3 to exchange required signals.

The elevator installation 1 includes braking devices 9 in order to hold the elevator car in case of need and to ensure safety of the elevator installation. In the example, a first braking device 10 is arranged in the region of the drive 6. This first brake device 10 holds, for example, the elevator installation, or the elevator car 3, in the case of a stop in one floor. This first braking device 10 is usually a part of the drive 6 and it is controlled by the elevator control 7. Of course, this first braking device 10 may also be separated from the drive 6, for example, be arranged on the elevator car counterweight or on a pulley. The elevator installation 1 includes a further second braking device 11, which is arranged directly on the elevator car 3 and which can advantageously act directly on the guide rail 8 for the purpose of braking the elevator car 3. This second braking device 11 is in the example a safety gear, which is controlled by means of an electronic limiter via a safety device 27.

The elevator installation 1 further includes an electromechanical monitoring device 12, which is arranged on the elevator car 3 and which, in cooperation with a track 14 defined by the guide rails 8 of the elevator car 3, can detect an unexpected slippage or drifting away of the elevator car 3 and can actuate the second brake device 11 via the safety device 27. Any required energy storage 28 are advantageously arranged in the safety device. In the case of a failure of the energy network, this energy store ensures at least the function of the electromechanical monitoring device 12 until the elevator installation is at a standstill. Details of the electromechanical monitoring device 12, as it is advantageously used in the elevator installation according to FIG. 1, are explained in FIGS. 3 to 5.

Fig. 2 shows another embodiment of an electromechanical monitoring device 12 in an elevator installation. The elevator system is constructed in the basic concept as explained in FIG. 1. However, this elevator installation 1 includes a second braking device 11, which is essentially a known conventional safety gear. This safety gear is actuated in case of need by a speed limiter 24. The speed limiter 24 is connected via a limiter rope 26 to the safety gear. The governor rope 26 is thus moved by the elevator trolley 3, on which the safety gear is arranged, and the speed limiter 24 is moved accordingly by the governor cable 26. As soon as the speed limiter 24 detects too high a speed, the speed limiter 24 blocks the governor rope 26 and the now decelerated governor rope 26 is actuated, as a rule via a corresponding lever mechanism (not shown), the safety gear or the second brake device 11.

In the embodiment according to FIG. 2, the electromechanical monitoring device 12 is arranged at this speed limiter 24. In cooperation with a defined by a scope of the speed limiter 24 track 14, the electromechanical monitoring device 12 can detect an unexpected slipping or drifting of the elevator car 3 and they can press the second brake device 11 via an auxiliary release 34 The auxiliary release is in the example via the elevator control 7 and the hanging cable 32 is controlled by the electromechanical monitoring device 12. The auxiliary release 34 is for example a terminal which acts on the guide rail 8 in case of need and actuates the safety gear. Such an auxiliary clutch is known for example from the publication EP0543154. Alternatively, it is also possible to attach a second brake 11, which is additional to the safety gear, to the elevator car, which then is for example merely a hindrance a drift is actuated by the electromechanical monitoring device 12.

Details of the electromechanical monitoring device 12, as it is now advantageously used in the elevator installation according to FIG. 2, are explained in FIGS. 6 and 7 in connection with FIGS. 3 to 5.

In Fig. 3 to 5, a structure and the function of an electromechanical monitoring device 12 is explained as it can be used in the elevator system according to Fig. 1 or, mutatis mutandis, in Fig. 2. The electromechanical monitoring device 12 includes a support 29 which can be attached to a part of the elevator installation, for example to the elevator car, the speed limiter or a frame of the drive. On the support 29, a rocker 30 is pivotally mounted about a pivot axis 21. In the rocker 30, a follower wheel 13 is rotatably mounted and on the axis of rotation of the follower wheel 13 runs a cam plate 17 with a cam 18 with.

The weight proportion of the cam 18 rotates, because of the weight, the cam disc 17 in the normal position, as long as no external forces are present. The rocker 30 is moved by means of an electromagnet 22 between a normal position as shown in Fig. 3 and a standby position, as shown in Fig. 4 moves. In the example, a spring 20 pushes the rocker 30 together with the follower wheel 17 in the ready position (see FIG. 4) and the solenoid 22 pulls the rocker 30 against the spring force of the spring 20 back to the normal position.

The electromechanical monitoring device 12, or the support 29 is arranged with respect to the track 14 such that in the normal position, the follower wheel 13 at a distance to the track 14, that is non-contact. In the standby position, the follower wheel 13 is pressed against the raceway 14. The control of the electromagnet 22 takes place, for example, via the safety device 27 or directly via the elevator control 7. Thus, for example, as soon as a door of the elevator car 3 is opened by a certain amount, switched off via a corresponding switch the solenoid 22 and the follower wheel 13 to the Runway 14 is pressed or the electromagnet is de-energized when the first brake device 10 gets a closing command.

In one embodiment, the safety device 27 for controlling the electromechanical Niche monitoring device 12 constructed such that it takes into account a combination of the signals of the first braking device 10 and the closing or Offhungszustands the door of the elevator car 3. Alternatively, instead of or in addition to the closing or opening state of the door of the elevator car 3, floor information, for example a floor switch, which is switched when the elevator car 3 is located in the area of a floor or a floor, can be used. This is useful, for example, in old elevator systems, where elevator cars are still partly used without a car door. Thus, the response of the electromechanical monitoring device 12 can be tailored to specific properties of the elevator system.

If the elevator car 3 now remains properly at standstill, the idler wheel 13 remains with the cam 18 in the ready position shown in FIG. 4.

But moves the elevator car 3 unintentionally from standstill away, as shown in Fig. 5 by the movement arrow s, the cam plate 17 is rotated together with the cam 18 by a rotation angle 16. The position of this rotation, or the angle of rotation 16 is determined by a sensor 15, in the example designed as an electromechanical switch 19. Now, when the switch 15 is actuated by the cam 19, the electromechanical monitoring device 12 is in the release position and thereby the second braking device (see Fig. 1 or Fig. 2) is actuated.

As long as the switch 19 is not actuated, the solenoid 22, the rocker 30 at any time withdraw and the cam 18 is due to its weight back to the normal position. However, once the switch 19 is actuated, the intervention of a knowledgeable person is usually required to reset the device. It will be appreciated that in this embodiment a responsiveness of the device is determined by the geometry of the follower wheel. Preferably, we have chosen a diameter of the follower wheel so that a Ansprechverzug corresponding to a path deviation s of about 30 to 100mm (millimeters) is formed in an example carried out, a diameter of the follower wheel is about 50mm. This detects a path deviation s of about 75mm. Thus, the usual small movements of the elevator car can be collected at a standstill. These small movements arise, for example, by stretching the suspension elements during loading and unloading operations. The same electromechanical monitoring device 12, as explained with reference to FIGS. 3 to 5 can also be arranged on a curved track 14. In Fig. 6 this is based on the release position, analogous to FIG. 5. The solenoid 22 has released the rocker 30 and the spring 20 presses the follower wheel 13 against the track 14. In the example, this track 14 is a running diameter 25 of the speed limiter 24. The track 14 may alternatively be defined by a pulley or a guide roller.

In FIG. 7, the electromechanical monitoring device 12 is installed in a speed limiter 24. The illustration shows the electromechanical monitoring device 12 in the standby position according to FIG. 4. The speed limiter 24 is driven by means of the limiter cable 26 and connected to the elevator car. At the speed limiter 24, the rocker 30 is pivotally arranged about the pivot axis 21. On the rocker 30, the follower wheel 13 is rotatably mounted together with the cam plate 17 and the cam 18. The electromagnet 22, which is fastened in the example according to FIG. 7 via an auxiliary console 29.1 to the speed limiter 24, is de-energized in the standby position shown, and the dead weight of the rocker 30 presses the follower wheel 13 against a running diameter 25 of the speed limiter 24. The running diameter 25 forms thus the track 14 for the electromechanical monitoring device 12th

Would now move the elevator car from a standstill, the follower 13 would turn the cam 18 and after about half a revolution of the follower 13, the cam 18 would operate the safety switch 19, or the sensor 15, which, as already explained several times, a braking device would be brought into effect.

On the other hand, in the example shown in FIG. 7, the solenoid 22 in the on state, the rocker 30 with the follower wheel 13 away from the running diameter 25, whereby the electromechanical monitoring device 12 can be brought into its normal position.

The electrical parts of the electromechanical monitoring device 12 can be connected via electrical connecting cable 33 to the elevator control 7 or to the safety device 27. With knowledge of the present invention, the elevator expert can arbitrarily change the set shapes and arrangements. For example, the cam disk 17 may be designed with a plurality of cams, or a plurality of sensors 15 or switches 19 may be arranged above the rotation angle 16 of the cam disk. The skilled person designs the constructive shapes and chooses useful materials. So he can complain parts of the rocker to get sufficient pressure forces.

Claims

claims

1. Electromechanical monitoring device for detecting an unwanted drive away of an elevator car (3) from a standstill, wherein the electromechanical monitoring device (12) includes a Mitlaufrad (13), which in case of need to a track (14, 8, 25) of the elevator car (3) is pressed, and wherein the monitoring device (12) includes a sensor (15) which detects a rotation of the follower wheel (13) by a predetermined angle of rotation and when exceeding the predetermined angle of rotation a braking device (9, 10, 11) is actuated.

2. Electromechanical monitoring device according to claim 1, wherein the follower wheel (13) drives a cam disc (17) and the sensor (15) is an electromechanical switch (19), which upon rotation of the cam disc (17) by a cam (18) the cam disc (17) is actuated and which actuates the braking device (9, 10, 11).

3. Electromechanical monitoring device according to claim 1 or 2, wherein the monitoring device (12) includes a spring (20) and an electromagnet (22), wherein the spring (20) is designed to the follower wheel (13) to the raceway (14, the eighth 25) of the elevator car (3) and the electromagnet (22) is designed to keep the follower wheel (13) at a distance from the track (14, 8, 25) against a spring force of the spring (20).

4. Electromechanical monitoring device according to claim 1 or 2, wherein the monitoring device (12) includes a weight mass (21) and an electromagnet (22), wherein the weight mass (21) is designed to the follower wheel (13) to the raceway (14, the eighth , 25) of the elevator car and the electromagnet is designed to pull the idler wheel (14, 8, 25) against the mass force of the weight mass (21) away from the raceway (14, 8, 25).

5. Electromechanical monitoring device according to one of claims 1 to 4, wherein the follower wheel (13) is moved to a neutral position or zero position when the follower wheel (13) from the track (14, 8, 25) is distanced.

6. Electromechanical monitoring device according to claim 5, wherein the cam disc (17) has a single cam (18) and this cam (18) forms a mass fraction of the cam disc (17) together with the follower wheel (13) go to the neutral position or zero position when the follower wheel (13) is spaced from the raceway (14, 8, 25).

7. Electromechanical monitoring device according to one of claims 2 to 6, wherein the electromechanical switch (19) is a latching or bistable switch, which is reset by an operation by the cam (18) of the cam disc (17) manually or by means of a remote reset.

8 speed limiter with an electromechanical monitoring device according to one of claims 1 to 7, which speed limiter (24) with a limiter rope (26) to an elevator car (3) is connectable and this limiter rope (26) the speed limiter (24) corresponding to a movement of the Aufzugskabme ( 3), wherein the track (14, 8, 25) of the elevator car (3) is a running diameter (25) of the speed limiter and the electromechanical monitoring device (12) is arranged at or at the speed limiter (24).

9. elevator installation with at least one elevator car which is movably arranged in an elevator shaft (2), comprising:

a first braking device (10), which is provided to keep the elevator car (3) at a standstill,

a second, electrically operable braking device (1 1), which is preferably arranged on the elevator car (3), and which is suitable to brake and hold the elevator car (3) in case of need, and

An electromechanical monitoring device (12) according to one of claims 1 to 7, wherein the electromechanical monitoring device (12) is pressed against the raceway (14, 8, 25) of the elevator car (3) when the first braking device (10) is actuated, and the sensor ( 15) of the electromechanical monitoring device (12) upon detection of the rotation of the follower wheel (13) by a predetermined angle of rotation, the second brake device (11) is actuated.

10. Elevator installation according to claim 9, characterized in that the Towing cab (3) by means of a limiter rope (26) drives a speed limiter (24) and the electromechanical monitoring device (12) is attached to or at the speed limiter (24) and the track (14, 8, 25) of the elevator car (3) a running diameter (25) of the speed limiter.

11. Lift installation according to one of claims 9 or 10, characterized in that the sensor (15) of the electromechanical monitoring device (12) to an electronic safety device (27) is connected, and this electronic safety device (27) upon detection of rotation of the follower wheel ( 13) by a predetermined angle of rotation a braking device (9, 10, 11), preferably a safety device controls, or

in that the sensor (15) of the electromechanical monitoring device (12) directly actuates a brake device (9, 10, 11), preferably a safety device, upon determining the rotation of the follower wheel (13) by a predetermined angle of rotation.

12. Elevator installation according to one of claims 9 to 11, characterized in that the electromechanical monitoring device (12) via an energy store (28) is supplied with electrical energy to keep the monitoring device (12) open during a power failure over a minimum period.

13. retrofit device for retrofitting an elevator system, preferably the speed limiter (24) of an elevator system, with an electromechanical monitoring device (12) according to one of claims 1 to 7, wherein the monitoring device (12) has a support (29) with electromagnet (22) and a Bearing point (31) for a rocker (30) and on the rocker (30) a Mitlaufrad (13) is arranged, which Mitlaufrad (13) in case of need to a track (14, 8, 25) of the elevator car, preferably to a running diameter (25) of the speed limiter, is pressed

14. A method for controlling a braking device to prevent unintentional driving away of an elevator car (3) from a standstill,

- If necessary, a follower wheel (13) to a track (14, 8, 25) of the elevator car (3) is pressed, and

- Wherein by means of a sensor (15), which a rotation of the follower wheel (13) to a determine predetermined rotation angle, unintentional driving away of the elevator car (3) is determined from a standstill, and

- When exceeding the predetermined angle of rotation, a braking device (9, 10, 11) is actuated.