This application claims priority to Chinese Patent Application No. CN201610616858.X , filed Aug. 1, 2016, and all the benefits accruing therefrom under 35 U.S.C. § 119, the contents of which in its entirety are herein incorporated by reference.
The present invention relates to the technical field of an elevator, to an elevator governor, and in particular, to a governor that does not need to be reset manually.
Installation apparatuses for an elevator include a safety gear, a governor, and the like. These apparatuses enable a car of the elevator to brake emergently when the car exceeds a particular speed, to avoid an extreme accident such as freefall of the car.
An existing governor mainly has the following two functions: In the first aspect, the governor triggers an electrical switch to disconnect a safety circuit when the car accelerates to a first limiting speed, so as to brake the car by using a holding brake of a traction machine. In the second aspect, if braking in the previous first aspect fails and the car continues to accelerate to a second limiting speed (the second limiting speed is greater than the first limiting speed), the governor draws a steel rope connected to a wedge of the safety gear, to actuate the safety gear, thereby braking the car thoroughly. The function in the second aspect needs to be implemented mechanically, so as to ensure extremely high reliability.
However, after completing the functions in the foregoing two aspects once, the governor needs to be reset to an original position so that it can still complete the functions in the foregoing two aspects during a subsequent operation process of the elevator. Especially, the governor needs to be mechanically reset to restore the function in the second aspect.
For an elevator in which the governor is installed at a position easily reachable to an operator, that is, for an elevator with a machine room, it is relatively easy to implement mechanical reset of the function in the second aspect. However, for an elevator in which the governor is installed at a position difficult to reach or unreachable for an operator, that is, for a machine room-less (MRL) elevator, implementation of the mechanical reset of the function in the second aspect needs to completely rely on the governor, that is, mechanical reset is implemented without a manual operation.
An objective of the present invention is to provide a governor which can implement mechanical reset without a manual operation.
To achieve the above objective or other objectives, the present invention provides following technical solutions.
According to a first aspect of the present invention, a governor of an elevator is provided, which includes a rope sheave; a ratchet wheel; and a centrifugal mechanism, a trip bar, and a rotatable pawl which are mounted on the rope sheave, the governor being able to work in a first state in which the rope sheave freely rotates with respect to the ratchet wheel or in a second state in which a safety gear is actuated; in the second state, the pawl being located in a first position in which a pawl head thereof mechanically acts on the ratchet wheel, so that rotation of the rope sheave in a first direction can act on the ratchet wheel via the pawl head,
wherein the governor further includes a reset push part which is disposed on the ratchet wheel and used for resetting the governor from the second state to the first state, wherein the reset push part and the pawl are set in such a manner that when the rope sheave rotates in a second direction opposite to the first direction, the reset push part pushes the pawl to reset the pawl to a position corresponding to the first state.
According to another aspect of the present invention, an elevator is provided, which uses the governor described above.
The foregoing features and operations of the present invention will become more evident according to the following description and the accompanying drawings.
In the following detailed description with reference to the accompanying drawings, the foregoing and other objectives and advantages of the present invention are clearer and more complete, wherein identical or similar elements are indicated with identical reference numerals.
The present invention will be described more comprehensively herein with reference to the accompanying drawings, wherein the accompanying drawings show exemplary embodiments of the present invention. However, the present invention can be implemented in different forms, and should not be construed as being limited to the embodiments illustrated herein. On the contrary, these provided embodiments make the disclosure thorough and complete, and fully convey the concept of the present invention to persons skilled in the art. In the accompanying drawings, identical numerals refer to identical elements or parts, and therefore, their descriptions will be omitted.
In the following description, to make the description clear and concise, not all of the parts shown in the figures are described in detail. The accompanying drawings show multiple parts which can be used by persons with ordinary skill in the art to implement the present invention, and operations of many parts are familiar and obvious to persons skilled in the art.
In the following description, for convenience, a direction of a rotation axis of a rope sheave of a governor is defined as y direction, a transverse direction of the governor is defined as x direction, and a longitudinal direction of the governor is defined as z direction. It should be appreciated that, definitions of these directions are used for relative descriptions and explanations and may be correspondingly changed according to a position change of the governor.
A governor 10 of an elevator in the embodiment of the present invention is described in detail below with reference to
In this embodiment, the governor 10 is used for triggering corresponding operations when a car of the elevator exceeds a predetermined speed, to limit the speed of the car of the elevator. Therefore, the governor 10 in this embodiment is provided with a rope sheave 110 for monitoring an operation speed of the ca. A steel rope (not shown in the figures) is disposed in a rope sheave groove of the rope sheave 110, and when the elevator is in a normal operation condition, the steel rope is basically synchronized with the monitored car in the vertical movement, and drives the rope sheave 110 to rotate simultaneously. For example, when the car goes up, the rope sheave 110 rotates in a counterclockwise direction shown in
The governor 10 is further provided with a ratchet wheel 120 and a centrifugal mechanism 140 (refer to
The centrifugal mechanism 140 is provided with a centrifugal swing component 141. The centrifugal mechanism 140 starts to work while the ratchet wheel 120 rotates, and as the ratchet wheel 120 accelerates, the centrifugal swing component 141 of the centrifugal mechanism 140 moves, within the ratchet wheel 120, closer to the circumference of the ratchet wheel 120. That is, as the ratchet wheel 120 accelerates, the centrifugal swing component 141 can outwardly reach a farther position in a radial direction of the ratchet wheel 120. In this way, the governor 10 can monitor an operation speed of the car by using the centrifugal mechanism 140. It should be noted that, a specific implementation structure of the centrifugal mechanism 140 is not limited in the embodiment of the present invention. The main function of the centrifugal mechanism 140 is that its action corresponds to a rotation speed of the ratchet wheel 120 and it can mechanically trigger corresponding parts of the governor 10 when the ratchet wheel reaches a particular speed. Any centrifugal mechanism which can implement this function can be used in the governor 10 of the present invention.
In this embodiment, the governor 10 can optionally implement the following function: preventing the elevator from further speeding up when an operation speed of the car of the elevator is greater than or equal to a first limiting speed.
Therefore, an electrical switch 190 is disposed on the governor 10. Specifically, the electrical switch 190 is provided with a protruding trigger arm 191 facing the rope sheave 110. When the operation speed of the car reaches the first limiting speed, a tail end of the centrifugal swing component 141 can reach a first radial position in a radial direction of the rope sheave 110, rotate, and mechanically act on the trigger arm 190 in the first radial position, to trigger the electrical switch 190 to disconnect a safety circuit, so as to brake the car by using, for example, a holding brake of a traction machine.
In this embodiment, the governor 10 can further implement the following function: mechanically actuating a safety gear disposed on the car when the operation speed of the car of the elevator is greater than or equal to a second limiting speed, so as to brake the car emergently. The reason is that, the electrical switch 190 probably fails to operate normally and becomes unreliable when braking is triggered by using the electrical switch 190. Therefore, the governor 10 needs to actuate the safety gear in a completely mechanical manner, to avoid an extreme accident, such as the falling of the car, in the most reliable manner. The second limiting speed is greater than the first limiting speed, and their values may be correspondingly set according to a specific application of the elevator.
Therefore, the governor 10 is provided with corresponding parts for mechanically actuating the safety gear, specifically including a trip bar 150 and a pawl 160 which are disposed on the rope sheave 110, and further including a braking spring 131, a rope-pressing holder 132, and a pull rod 133. In one embodiment, the trip bar 150 is disposed near an edge of the circumference of the rope sheave 110 and can rotate with respect to the rope sheave 110, and a pivotal shaft 151 of the trip bar is disposed on the rope sheave 110 along a y direction. The pawl 160 is disposed near the trip bar 150 and on the same side with the ratchet wheel 120, and can rotate with respect to the rope sheave 110. A pivotal shaft 161 of the pawl is disposed on the rope sheave 110 along the y direction. Two ends of the pawl 160 are a pawl head 163 and a pawl tail 164 respectively, which can both rotate about the pivotal shaft 161. When the operation speed of the car reaches the second limiting speed, the tail end of the centrifugal swing component 141 can reach a second radial position (the second radial position is farther away from an axial center of the rope sheave 110 than the first radial position) in the radial direction of the rope sheave 110, rotate, and mechanically act on the trip bar 150 in the second radial position. The trip bar 150 then triggers the pawl 160 to rotate, and the pawl head 163 falls into the ratchet groove (as shown in
Herein, a first state and a second state of the governor 10 are defined. In the first state (as shown in
In one embodiment, specific structures of the trip bar 150 and the pawl 160 are set as shown in
Moreover, in this embodiment, a torsion spring 153 corresponding to the trip bar 150 is disposed on the pivotal shaft 151 of the trip bar, and under the effect of a force exerted by the torsion spring 153, the trip bar 150 may rotate about the pivotal shaft 151 at a particular angle in a direction N5 shown in
Specifically, when the elevator is in a normal operation condition, the governor 10 is in the first state; and blocked by the trip bar 150, the pawl 160 is located in the second position. When the operation speed of the car reaches the second limiting speed, the centrifugal swing component 141 swings outwardly to a second radial position in which the trip bar 150 can be triggered at this time, and drives the trip bar 150 to rotate at a particular angle in a direction N4 shown in
Continue to refer to
Therefore, in the governor 10 in this embodiment, the ratchet wheel 120 is further provided with a reset push part 170 for resetting the governor 10 from the second state to the first state. In this embodiment, one end of the reset push part 170 is rotatably fixed on the ratchet wheel 120 by using the pivotal shaft 171. The ratchet wheel 120 is further provided with a first rotation limiting portion 173 and a second rotation limiting portion 174, and by the first rotation limiting portion 173 and the second rotation limiting portion 174, the reset push part 170 is limited to rotating within a particular angle range. The angle range within which the reset push part 170 rotates may be set by setting positions of the first rotation limiting portion 173 and the second rotation limiting portion 174 with respect to the pivotal shaft 171. The other end of the reset push part 170 is a push portion 172, and the pawl 160 is provided with a reset pin 162 corresponding to the push portion 172 of the reset push part 170. The reset pin 162 is disposed in a certain position on the pawl head 163.
The resetting operation process of the governor 10 in the embodiment of the present invention is described by using an example below with reference to
First, the rope sheave 110 may be driven to rotate in a direction N1; the trip bar 150 and the whole pawl 160 rotate with respect to the ratchet wheel also in the direction N1, and reach a position shown in
When the rope sheave 110 continues to rotate in the direction N1, the reset pin 162 on the pawl 160 drives the reset push part 170 to rotate in a direction N2 shown in
When the rope sheave 110 continues to rotate in the direction N1, as shown in
When the rope sheave 110 continues to rotate in the direction N1, after the reset pin 162 of the pawl 160 goes across the top of the push slope 1721, the pawl 160 is pushed to a farthest position away from the ratchet wheel 120, and the top of the pawl tail 164 of the pawl 160 at least slides over the top of the protruding stop portion 152 of the trip bar 150 already. Driven by the torsion spring 153 of the trip bar, the trip bar 150 rotates in a direction N5 shown in
When the rope sheave 110 continues to rotate in the direction N1, as shown in
It should be construed that, with the above teaching of the embodiment of the present invention, persons skilled in the art may specifically set structural parameters such as a position of the pivotal shaft 171, a length of the reset push part 170, a bevel angle of the push slope 1721, a position of the first rotation limiting portion 173, and/or a position of the second rotation limiting portion 174; and correspondingly, may further specifically set structural parameters such as a position of the reset pin 162, a shape of the pawl tail 164, and/or a shape of the protruding stop portion 152.
The foregoing resetting process is implemented mechanically, and the governor can be automatically reset by driving the rope sheave 110 in the direction N1. Therefore, the implementation is completely independent of manual operations. The governor 10 in this embodiment is extremely applicable to an MRL elevator.
A governor 20 of an elevator in the embodiment of the present invention is described in detail below with reference to
In this embodiment, the governor 20 is used for triggering corresponding operations when a car of the elevator exceeds a preset speed, so as to limit the speed of the car of the elevator. Therefore, the governor 20 in this embodiment is provided with a rope sheave 110 for monitoring an operation speed of the car. A steel rope (not shown in the figures) is disposed in a rope sheave groove of the rope sheave 110, and when the elevator is in a normal operation condition, the steel rope is synchronized with the monitored car in the vertical movement and drives the rope sheave 110 to rotate simultaneously. For example, when the car goes up, the rope sheave 110 rotates in a counterclockwise direction shown in
The governor 20 is further provided with a ratchet wheel 120 and a centrifugal mechanism 140. The ratchet wheel 120 and the rope sheave 110 are both disposed on a rack 100 of the governor 20. In this embodiment, the ratchet wheel 120 and the rope sheave 110 may be disposed coaxially, but the ratchet wheel 120 stays still when the elevator is in the normal operation condition. Several ratchet grooves are disposed on the circumference of the ratchet wheel 120. An outer diameter of the ratchet wheel 120 is obviously less than that of the rope sheave 110, and the ratchet wheel 120 is disposed on one axial side of the ratchet wheel 120. The centrifugal mechanism 140 may be disposed on the ratchet wheel 120 and located on the other axial side of the ratchet wheel, that is, located on a side opposite to the side provided with the ratchet wheel 120.
The centrifugal mechanism 140 is provided with a centrifugal swing component 141. The centrifugal mechanism 140 starts to work while the ratchet wheel 120 rotates, and as the ratchet wheel 120 accelerates, the centrifugal swing component 141 of the centrifugal mechanism 140 moves, within the ratchet wheel 120, closer to the circumference of the ratchet wheel 120. That is, as the ratchet wheel 120 accelerates, the centrifugal swing component 141 can outwardly reach a farther position in a radial direction of the ratchet wheel 120. In this way, the governor 20 can monitor an operation speed of the car by using the centrifugal mechanism 140. It should be noted that, a specific implementation structure of the centrifugal mechanism 140 is not limited in the embodiment of the present invention. The main function of the centrifugal mechanism 140 is that its action corresponds to a rotation speed of the ratchet wheel 120 and it can mechanically trigger corresponding parts of the governor 20 when the ratchet wheel reaches a particular speed. Any centrifugal mechanism which can implement this function can be used in the governor 20 of the present invention.
In this embodiment, the governor 20 optionally can implement the following function: preventing the elevator from further speeding up when an operation speed of the car of the elevator is greater than or equal to a first limiting speed.
Therefore, an electrical switch 190 is disposed on the governor 20. Specifically, the electrical switch 190 is provided with a protruding trigger arm 191 facing the rope sheave 110. When the operation speed of the car reaches the first limiting speed, a tail end of the centrifugal swing component 141 can reach a first radial position in a radial direction of the rope sheave 110, rotate, and mechanically act on the trigger arm 190 in the first radial position, to trigger the electrical switch 190 to disconnect a safety circuit, so as to brake the car by using, for example, a holding brake of a traction machine.
In this embodiment, the governor 20 can further implement the following function: mechanically actuating a safety gear disposed on the car when the operation speed of the car of the elevator is greater than or equal to a second limiting speed, so as to brake the car emergently. The reason is that, the electrical switch 190 probably fails to operate normally and becomes unreliable when braking is triggered by using the electrical switch 190. Therefore, the governor 20 needs to actuate the safety gear in a completely mechanical manner, so as to avoid an extreme accident, such as the falling of the car, in the most reliable manner. The second limiting speed is greater than the first limiting speed, and their values may be correspondingly set according to a specific application of the elevator.
Therefore, the governor 20 is provided with corresponding parts for mechanically actuating the safety gear, specifically including a trip bar 150 and a pawl 160 which are disposed on the rope sheave 110, and further including a braking spring 131, a rope-pressing holder 132, and a pull rod 133. In one embodiment, the trip bar 150 is disposed near an edge of the circumference of the rope sheave 110 and can rotate with respect to the rope sheave 110, and a pivotal shaft 151 of the trip bar is disposed on the rope sheave 110 along a y direction. The pawl 160 is disposed near the trip bar 150 and on the same side with the ratchet wheel 120, and can rotate with respect to the rope sheave 110. A pivotal shaft 161 of the pawl is disposed on the rope sheave 110 along the y direction. Two ends of the pawl 160 are a pawl head 163 and a pawl tail 164 respectively, and can both rotate about the pivotal shaft 161. When the operation speed of the car reaches the second limiting speed, the tail end of the centrifugal swing component 141 can reach a second radial position (the second radial position is farther away from an axial center of the rope sheave 110 than the first radial position) in the radial direction of the rope sheave 110, rotate, and mechanically act on the trip bar 150 in the second radial position. The trip bar 150 then triggers the pawl 160 to rotate, and the pawl head 163 falls into the ratchet groove (as shown in
Herein, a first state and a second state of the governor 20 are defined. In the first state (as shown in
In one embodiment, specific structures of the trip bar 150 and the pawl 160 are set as shown in
Moreover, in this embodiment, a torsion spring 153 corresponding to the trip bar 150 is disposed on the pivotal shaft 151 of the trip bar, and under the effect of a force exerted by the torsion spring 153, the trip bar 150 may rotate about the pivotal shaft 151 at a particular angle in a direction N5 shown in
Specifically, when the elevator is in a normal operation condition, the governor 20 is in the first state; and blocked by the trip bar 150, the pawl 160 is located in the second position. When the operation speed of the car reaches the second limiting speed, the centrifugal swing component 141 swings outwardly to a second radial position where the trip bar 150 can be triggered, and drives the trip bar 150 to rotate at a particular angle in a direction opposite to the direction N5 shown in
Continue to refer to
Therefore, in the governor 20 in this embodiment, the ratchet wheel 120 is further provided with a reset push part 270 for resetting the governor 20 from the second state to the first state. In this embodiment, the reset push part 270 is rotatably fixed on the ratchet wheel 120 by using the pivotal shaft 271, one end of the reset push part 270 is a push portion 272, the other end of the reset push part 270 is a push rod tail 273, and the pivotal shaft 271 is positioned in the middle of the reset push part 270 and is close to the end provided with the push rod tail 273. In order that the reset push part 270 can return to an original position shown in
The resetting operation process of the governor 20 in the embodiment of the present invention is described by using an example below with reference to
First, the rope sheave 110 may be driven to rotate in a direction N1; the trip bar 150 and the whole pawl 160 rotate with respect to the ratchet wheel also in the direction N1, and reach a position shown in
When the rope sheave 110 continues to rotate in the direction N1, the reset pin 162 on the pawl 160 contacts the push portion 272 when passing through the push portion 272 of the reset push part 270. In this embodiment, the push portion 272 is provided with a groove, and therefore, the reset pin 162 falls into the groove of the push portion 272 at this time, and the pawl 160 continues to rotate with respect to the ratchet wheel 120 in the direction N1 to drive the reset push part 270 to rotate in a direction N2 shown in
Specifically, a length of the reset push part 270 and/or a position of a second end of the reset tension spring 280 on the ratchet wheel 120 may be set, so that when the rope sheave 110 rotates in the direction N1, the pawl 160 in the first position can drive the reset push part 270 to rotate.
When the rope sheave 110 continues to rotate in the direction N1, as shown in
When the rope sheave 110 continues to rotate in the direction N1, as shown in
It should be appreciated that, with the above teaching of the embodiment of the present invention, persons skilled in the art may specifically set structural parameters such as a position of the pivotal shaft 271, a length of the reset push part 270, and/or a shape of the groove of the push portion 272; and correspondingly, may further set structural parameters such as a position of the reset pin 162, a shape of the pawl tail 164, and/or a shape of the protruding stop portion 152. The reset push part 270 may be, but is not limited to, a plate-like reset push plate.
The foregoing resetting process is implemented mechanically, and the governor can be automatically reset by driving the rope sheave 110 in the direction N1. Therefore, the implementation is completely independent of manual operations. The governor 20 in this embodiment is extremely applicable to an MRL elevator.
It should be appreciated that, directional terms such as “inside”, “outside”, “up”, and “down” are used in the disclosure are relative concepts, are used for relative descriptions and explanations, and may be correspondingly changed according to a position change of the governor.
The foregoing examples mainly describe various kinds of governors of the present invention. Although only some embodiments of the present invention are described, persons with ordinary skill in the art should understand that the present invention can be implemented in many other forms without departing from the principle and scope of the present invention. Therefore, the described examples and embodiments are considered to be illustrative rather than restrictive, and various modifications and replacements may be made to the present invention without departing from the spirit and scope defined in the appended claims.
Number | Date | Country | Kind |
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201610616858.X | Aug 2016 | CN | national |